TENNESSEE VALLEY AUTHORITYCHATTANOOGA, TENNESSEE 37401

1630 Chestnut Street Tower II

December 20, 19841Director of' Nuclear Reactor RegulationAttention: Ms. E. Adensam, Chief

Licensing Branch No. 41Division of Licensing

U.S. Nuclear Regulatory CommissionWashington, D.C. 20555

Dear Ms. Adensam:

In the Matter of the Application of ) Docket Nos. 50-390Tennessee Valley Authority )50-39 1

By letter dated August 19, 1983, TVA provided, in accordance with 10 CFR50.419 and NUREG-0588, information demonstrating compliance with theequipment qualification requirements for the Watts Bar Nuclear (WBN) unit1. By letters dated July 241 and August 141, 19811, TVA provided updated andadditional information, respectively, to that submitted by the August 19,1983 letter.

A meeting was held between TVA and NRC representatives on September 5, 19841to discuss the status and results-to-date of NRC's ongoing revie*.i of theWBN unit 1 equipment qualification program. During this meeting, and inpreceding conference calls, NRC representatives identified several areas ofconcern with TVA's equipment qualification efforts at WBN (refer to T. J.Kenyon's meeting summary dated September 12, 19811). The enclosure to thisletter addresses the concerns identified at the September 5th meeting andprovides an update of that information submitted by the July 241th andAugust 141th letters. The enclosure consists of three attachments.Attachment 1 briefly addresses each of the NRC's concerns and referencesAttachments 2 and 3, as appropriate. Attachment 2 provides TVA's safetyevaluation addressing the issue of subme~rgence of Class 1E electricalequipment at WBN. Attachment 3 provides a select update of the informationsubmitted by the July 241th and August 111th letters. Fifteen (15) copies ofAttachment 3 are provided. This update reflects changes resulting from theresolution of the NRC's concerns and changes in equipment qualificationstatus and/or implementation plans which have occurred since the July 241thand August 111th submittals. Attachment 3 also includes an effective pagelisting and instruction sheet to assist in updating the July 241th andAugust 141th submittals. (The July 241th and August 141th submittals wereassigned an effective date of July 19811. The updated information providedin Attachment 3 has been assigned an effective date of October 19811.)

It should be noted that some of the NRC's concerns could not be fullyaddressed at this time due to the present unavailability of informationand/or the need for additional calculations /analyses. These concerns arenoted in Attachment 1 to the enclosure of this letter and will require anadditional response. It should also be noted that available data for unit2 equipment is included; however, due to the construction status of unit 2,it should not be reviewed at this time. A separate submittal will beprepared and provided to support the unit 2 fuel load schedule. Asindicated in TVA's letter dated September 11, 19811, a target date ofJanuary 3, 1986 has been established for submittal of the unit 2information. a A8412270114 841220 1le0APDR AOK0009'Equal Opportunity Employert

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Director of Nuclear Reactor Regulation

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December 20, 19841

If you have any questions concerning this matter, please get in touch withD. B. Ellis at FTS 858-2681.

Very truly yours,

TENNESSEE VALLEY AUTHORITY

4J. W. Hu am Manageriensing anm Regulations

Sworn l~~d subscri~e before methis OL day of 198~4

Notary PublicMy Commission Expires 9-21-1001

Enclosurecc: U.S. Nuclear Regulatory Commission (Enclosure)

Region IIAttn: Mr. James P. O'Reilly Administrator101 Marietta Street, NW, Suite 2900Atlanta, Georgia 30323

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ENCLOSURE

ATTACHMENT 1

NRC CONCERNS/COMMEhITS

The various references below to Sections, Tables, EQSs, etc., refer to thevarious parts of the revised WEN EEEQR contained in Attachment 3.

1. Recalculation of Primary Containment and Valve Vault Room Temperature

Section 3.0 discusses the issues of the recalculation of the primarycontainment and valve vault room temperatures for superheat conditionsr Iesulting from a main steamline break (MSLB) and provides justificationfor interim operation for these issues until initial criticality. Abrief summary of these two issues follows:

a. A preliminary calculation of the peak temperature for a MSLB insideprimary containment based upon Westinghouse data for the CatawbaNuclear Plant, a similar plant to WEN, reveals a peak temperatureof 3240F which is less than the present design temperature of3270F which TVA used for qualification.

b. A preliminary calculation of the peak temperature for a MSLBinside the valve vault room based upon Westinghouse data forCatawba revealed a peak temperature of 446QF which is greater thanthe 325OF TVA used for qualification. 'I safety evaluation wasperformed on all Class lE equipment, including cables, to determinewhich equipment inside the valve vault room was required to operateor not fail adversely for the-specified break causing this hightemperature. This safety evaluation revealed that only the PAMinstrumentation on EQS-NEB-XX-48 was required to operate at thishigh-temperature. The other equipment was determined to be eithernot required to operate or to operate before reaching its quali-fication temperature and fail in a safe manner. To qualify the PAM,instruments, a thermal blanket will be used to prevent temperaturesfrom rising above their qualification valves for the duration ofaccident. This is discussed in the referenced EQS.

The final resolution of the superheat problem in containment andthe valve vault rooms and the thermal analysis of the thermalblankets will be provided prior to initial criticality.

2. Submerzence

Section 3.0 discusses submergence both inside and outside primarycontainment including the annulus. 'For inside primary containment, alist of Class 1E equipment below the flood level was generated. Asafety evaluation was performed (Attachment 2) on all submerged equip-ment to determine which equipment was required to operate and/or notfail adversely for the specified DBAs causing the flooding. 'This listof components requiring qualification for submergence and the actions

taken to qualify these components are given in Table 3.1. From Table3.1, it is seen that only the wide range temperature detectors on EQS-WBN-NEB-68-23 need be qualified for submergence. These detectors willbe fully qualified before fuel load and are discussed in further detailon the referenced EQS.

For outside primary containment, no equipment was subjected toflooding. For the anniulus, all high-energy lines are sleeved and anybreak will drain to outside the annulus (Auxiliary Building). In allother areas outside containment, the building drains, stairwells,equipment mounting, etc., have been designed such that all water willbe drained away before it can flood any equipment as a result of theworst pipe breaks.

3. NSSS Instrument Accuracies

Section 14.0 discusses the methodology used to determine the requiredand demonstrated accuracies for NSSS equipment. These accuracies arefactored into Table 3.11-14, 5, 6, 7, and 8 for the NSSS equipment, asappropriate.

By letter dated September 5, 19814, TVA supplemented its previousresponses to the generic audit finding on instrument accuracyacceptability. TVA noted that the Westinghouse statistical setpointstudy for Watts Bar flSSS equipment had been issued. A description ofthe methods employed in determining inaccuracies was provided for theNSSS protection equipment and postaccident monitoring equipment.

For the NSSS protection equipment, TVA indicated that in order toensure that the demonstrated accuracies are acceptable, a comparisonwould be performed between the assumed environmental errors used in thesetpoint study and the accuracies recorded in the equipment testreports. This comparison has been completed with no unacceptableresults identified.

For the NSSS postaccident monitoring instrumentation, TVA indicatedthat the total indicated accuracies would be verified to be within theaccuracy requirements established for PAM channels in FSAR 7.5-1. Thisverification has been performed and the NSSS PAM instruments were foundto meet their accuracy requirements in all but three instances: widerange reactor coolant system pressure transmitters, steam line pressuretransmitters, and containment pressure transmitters. Appropriatecorrective measures will be undertaken to resolve these exceptions bythe unit 1 fuel load date.

14. Table 1.1 and EQS Updates

All parts of the EEEQB (Table 1.1, EQSs, Section Write-ups, etc.) havebeen revised, as appropriate, to resolve all of NRC's concerns andcomments given to TVA in the various telecons and one meeting.

5. Qualified Life *Aerature

a. Section 3.0 provides the basis on which TVA expects abnormaltemperatures to occur only 1 percent of plant life and eight hoursper excursion. With this basis, TVA, in some cases, used themaximum normal temperatures instead of the abnormal temperatures todetermine qualified life based upon the reasoning that the abnormaloccurs such a small fraction of the time it would have little, ifany, effect on qualified life.

b. ASCO Solenoid Valves Qualified Life - Energized VersusNon-Energized Position

TVA has recalculated the qualified life for all qualified ASCOvalves to account for self-heating in normally energized coils.This recalculation has not changed the qualification status of anyvalve; however, it has shortened their qualified life.

6. Non-Class 1E Equipment

TVA has revised the non-Class 1E EQSs, identified below, to incorporateNRC comments and to provide further justification (additional testdates, further analysis, etc.) that this equipment will operate and/ornot fail in any manner detrimental to plant safety. The non-Class 1EEQS are as follows:

EQS EEB-BD-2~42EEB-PNL- 1EEB-BD-1, 2, 3, 4IEEB-MC- 1, 2, 3, 14, 5

and are identified in Table 1 .1 .

7. Justifications for Interim Operation (JIOs) Based on Manufacturer'sSpecifications

TVA has revised and provided additional qualification information(partial test data, further analysis, etc.), where possible, to resolveNRC concerns/comments on EQSs that used manufacturer's specifications,in part or in whole, for JIOs. However, there are several EQSs whereno further EQ information could be provided for revised J105 . TheseEQSs are identified below and contain temperature switches, heaterelements, and motors.

EQS-WBN-MEB-30 -006EQS-WBN-MEB-65 -009EQS-WBN-MEB-65 -0010EQS-WBN-MEB-30 -0011EQS-WBN-MEB-30 -001 2EQS-WBN-MEB-30 -0013EQS-WBN-MEB-30 -0015EQS -WBN-MEB-30 -0016

All devices identified on the EQSs above will be replaced with qualifieddevices by initial criticality.

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ATTACMIENT 2

SAFETY EVALUATIONSUBMERGENCE

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ATTACHMENT 3

WBN - EEEQR

EFFECTIVE PAGE LISTINGORIGINAL ISSUE - JULY 1983

REVISIED - OCTOBER 1984

Section and/or Description

WBN EEEQR Unit 1&2ForwardTable of Contents1.0 Title Page1.11.2

Table 1.12.0 Title Page2.1Table 2.1-12.22.3Table 2.3-12.4Table 2.4-12.5.2.62.73.0 Title Page3.1Table 3.1Figure 3.1.2.1.1-1Figure 3.01-1 thru 3.01-464.0 Title Page4.14.24.35.0 Title Page5.15.2 NEB-NSSS EQSNEB-EQS IndexNEB-83-1 R2Appendix 1 R2NEB-68-3 R3Appendix I R3Attachment 1 R2NEB-3-4 R2Appendix I R2Appendix 2 R2NEB-XX-5 R3Appendix 1 R3

Title Page

Page Effective Date

- Title Page

iii- iv

1 -21.2-11.2-21-111

1-2111111I1-21

1-23111-46

1-21-31

1-3

1

1-2

1-31

11-3

1

7/847 /847 /847 /847 /84

10/847/84

10/847 /847 /847 /847/847/847 /847 /847 /847/847 /847 /847 /84

10/8410/847/847 /847 /847 /847 /84

10/847 /847 /847 /84

10/847 /847 /84

10/8410/847 /84

10/8410/8410/8410/8410/84

-1I-

Section and/or Description Page Effective Date

NEB-XX-6 R2 7/84Appendix I R2 1 7/84Appendix 2 R2 1 7/84NEB-XX-8 R3 10/84Appendix 1 R3 1 10/84NEB-XX-11 R3 10/84Appendix I R2 1 7/84Appendix 2 R2 1-2 7/84NEB-XX-13 R2 7/84Appendix 1 R2 1 7/84NEB-68-14 R3 10/84Appendix 1 R3 1-2 10/84NEB-1-21 Ri 7/84Appendix I Ri 1-3 7/84NEB-68-23 R3 10/84Appendix 1 P3 1 10/84Appendix 2 R3 1-3 10/84NEB-68-24 R3 10/84Appendix I R2 1 7/84Appendix 2 R2 1-3 7/84NEB-62-26 R3 10/84Appendix 1 R3 1-2 10/84NEB-30-27 RI 7/84Appendix 1 Ri 1 7/84Appendix 2 Ri 1-3 7/84NEB-XX-31 RI 7 /84Appendix 1 RI 1 7/84Appendix 2 RO 1-3 7/84NEB-68-33 R2 10/84Appendix 1 R2 1 10/84Appendix 2 R2 1-3 10/84NEB-XX-36 R2 7 /84Appendix I R2 1 7/84Appendix 2 R2 1-3 7/84NEB-XX-37 R3 10/84Appendix 1 R3 1-2 10/84Appendix 2 R2 1-4 10/84NEB-XX-38 R3 10/84Appendix 1 R3 1 10/84Appendix 2 R2 1-2 10/84NEB-1-40 RI 7/84Appendix 1 RI 1-3 7/84NEB-68-43 Ri 7 /84Appendix 1 RI 1 7/84Appendix 2 Ri 1-2 7/84NEB-68-44 RI 7 /84Appendix 1 RI 1 7/84NEB-74-45 RI 7 /84Appendix 1 RI 1 7/84Attachment 1 1 7/84

- 2-

Section and/or Description Page Effective Date

NEB-XX-47 Ri 10/84Appendix 1 RI 1 10/84Appendix 2 RI 1-2 10/84NEB-XX-48 RI 10/84Appendix I RI 1 10/84Appendix 2 Ri 1-3 10/84NEB-94-48 RI 10/84Appendix 1 RI 1-2 10/84Attachment 1 Ri 1-5 10/84NEB-XX-49

7/84Appendix I RO 1 7/84Appendix 2 RO 1-2 7/84Attachment 1 1-15 7/845.3 EEB EQS Title Page 1 7/84EEB EQS Index 1-7 10/84WBNEEBOOO1 R2 10/84Appendix 1 R2 1 10/84Appendix 2 R2 1-5 10/84Appendix 3 R2 1 10/84WBNEEB0002 R3 10/84Appendix 1 R3 1 10/84Appendix 2 R3 1-2 10/84Appendix 3 R3 1 10/84

S WBNEEB0006 R3 10/84Appendix I R3 1 10/84Appendix 2 R3 1-7 10/84Appendix 3 R3 1 10/84WBNEEB0007 RI 10 /84Appendix I Ri 1-1 10/84Appendix 2 RI 1-8 10/84Appendix 3 Ri 1 10/84WBNEEB0009 RI 10/84Appendix 1 Ri 1 10/84Appendix 2 Ri 1-6 10/84Appendix 3 RI 1 10/84WBNEEBOOii R3 10/84Appendix I R3 1 10/84Appendix 2 R3 1-3 10/84WBNEEB0015 R2 10/84Appendix 1 R2 1 10/84Appendix 2 R2 1-4 10/84Appendix 3 R2 1 10/84WBNEEB0016 R2

7/84Appendix 1 R2 1 7/84Appendix 2 R2 1-2 7/84WBNEEB0018 R2

10/84Appendix I R2 1 10/84Appendix 2 R2 i-il 10/84Appendix 3 R2 1 10/84WBNEEB0019 R3

10/84

- 3-

Section and/or Description Page Effective Date

Appendix I R3 1 10/84Appendix 2 R3 1-9 10/84Appendix 3 R2 1 10/84WBNEEB0020 R3 10/84Appendix 1 R3 1-3 10/84Appendix 2 R3 1-19 10/84Appendix 3 R3 1 10/84WBNEEB0022 R3 10/84Appendix I R3 1 10/84Appendix 2 R3 1-3 10/84WBNEEB0023 R3 7 /84Appendix 1 R3 1-5 7/84Appendix 2 R3 1 7/84WBNEEB0026 R3 1 10/84Appendix 1 R3 1 10/84Appendix 2 R3 1-4 10/84WBNEEB0027 RI 7 /84Appendix 1 Ri 1 7/84Appenidx 2 Ri 1-3 7/84WBNEEB0028 R3 10/84Appendix I R3 1 10/84Appendix 2 R3 1-13 10/84Appendix 3 R3 1 10/84WBNEEB0029 R13 10/84Appendix 1 R3 1-2 10/84Appendix 2 R3 1-18 10/84Appendix 3 R3 1 10/84WBNEEB0030 R13 10/84Appendix I R3 1 10/84Appendix 2 R3 1-2 10/84WBNEEB0033 R2 10/84Appendix 1 R2 1 10/84Appendix 2 R2 1-5 10/84Appendix 3 R2 1 10/84WBNEEB0035 1R3 10/84Appendix 1 R3 1 10/84Appendix 2 R3 1-7 10/84WBNEEB0036 R2 7/84Appendix 1 R2 1 7/84Appendix 2 R2 1-5 7/84Appendix 3 R2 1 7/84WBNEEB0037 R13 10/84Appendix I R3 1 10/84Appendix 2 R3 1-7 10/84WBNEEB0038 R2 7/84Appendix I R2 1 7/84Appendix 2 R2 1-3 7/84WBNEEB0039 R13 10/84Appendix 1 R3 1-2 10/84Appendix 2 R13 1-11 10/84

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Section and/or Description Page Effective I

Appendix 3 R3 1 10/84WBNEEB0043 R2 7/84Appendix 1 R2 1 7/84Appendix 2 R2 1-4 7/84WBNEEB0044 R3 10/84Appendix 1 R3 1 10/84Appendix 2 R3 1-7 10/84WBNEEB0046 Ri 10/84Appendix 1 RI 1 10/84Appendix 2 Ri 1-6 10/84Appendix 3 Ri 1 10/84WBNEEB0047 Ri 10/84Appendix 1 RI 1 10/84Appendix 2 RI 1-6 10/84Appendix 3 Ri 1 10/84WBNEEB0049 R3 10/84Appendix 1 R3 1 10/84Appendix 2 R3 1-6 10/84WBNEEB0051 R3 10/84Appendix 1 R3 1-2 10/84Appendix 2 R3 1-12 10/84Appendix 3 R3 1 10/84WBNEEB0053 R2 7 /84Appendix 1 R2 1-2 7/84Appendix 2 RI 1 7/84WBNEEB0054 Ri 10/84Appendix 1 Ri 1 10/84Appendix 2 Ri 1-6 10/84WBNEEB0056 R2 7 /84Appendix 1 R2 1 7/84Appendix 2 R2 1-3 7/84Appendix 3 R2 1 7/84WBNEEB0057 R2 7 /84Appendix 1 R2 1 7/84Appendix 2 R2 1-2 7/84WBNEEB0058 R2 7 /84Appendix 1 R2 1 7/84Appendix 2 R2 1-2 7/84Appendix 3 R2 1-2 7/84WBNEEB0059 R2 10/84Appendix 1 R2 1 10/84Appendix 2 R2 1-3 10/84Appendix 3 R2 1 10/84WBNEEB0060 R2 7/84Appendix I R2 1 7/84Appendix 2 R2 1 7/84WBNEEB0061 R2 7/84Appendix 1 R2 1 7/84Appendix 2 R2 1-5 7/84WBNEEB0063 Ri 10/84

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Appendix 2 RI 1 10/84Appendix 2 RI 1-5 10/84WBNEEB0065 R3 10/84Appendix 1 R3 1-2 10/84Appendix 2 R3 1-11 10/84Appendix 3 R3 1 10/84WBNEEB0067 RO 7 /84Appendix 1 RO 1 7/84Appendix 2 RO 1-3 7/84WBNEEB0068 RO 7 /84Appendix 1 RO 1 7/84Appendix 2 RO 1-3 7/84Appendix 3 RO 1 7/84WBNEEB0072 R2 7/84Appendix I R2 1 7/84Appendix 2 R2 1-4 7/84WBNEEB0073 RI 7 /84Appendix 1 Ri 1 7/84Appendix 2 Ri 1 7/84WBNEEB0074 RI 7/84Appendix 1 RI 1 7/84Appendix 2 RI 1-9 7/84WBNEEB0076 RI 7 /84Appendix 1 Ri 1 7/84Appendix 2 Ri 1 7/84WBNEEB0077 RO 7 /84Appendix 1 RO 1 7/84Appendix 2 RO 1-6 7/84WBNEEB0079 RI 10/84Appendix 1 Ri 1 10/84Appendix 2 RI 1-2 10/84WBNEEB0080 RO 7 /84Appendix 1 RO 1 7/84Appendix 2 RO 1-4 7/84WBNEEB0081 RO 7/84Appendix 1 RO 1 7/84Appendix 2 RO 1 7/84WBNEEB0085 R2 10/84Appendix 1 R2 1 10/84Appendix 2 R2 1-2 10/84WBNEEB0086 RO 7/84Appendix I RO 1 7/84Appendix 2 RO 1-3 7/84WBNEEB0087 Ri 10/84Appendix 1 Ri 1 10/84Appendix 2 RI 1-5 10/84Appendix 3 RI 1 10/84WBNEEB0088 Ri 10/84Appendix 1 RI 1 10/84Appendix 2 RI 1-5 10/84

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WBNEEB0089 RI 10/84Appendix I Ri 1 10/84Appendix 2 Ri 1-3 10/84WBNEEB0090 RO 7/84Appendix 1 RO 1 7/84Appendix 2 RO 1-3 7/84WBNEEB0091 RO 7/84Appendix I RO 1 7/84Appendix 2 RO 1 10/84WBNEEB0093 RO 10/84Appendix 1 RO 1-5 10/84Appendix 2 RO 1 10/84EEB-CBL-1 RO 7 /84Appendix 1 RO 1 7/84Appendix 2 RO 1-2 7/84EEB-CBL-2 RO 7/84Appendix I RO 1 7/84Appendix 2 RO 1-4 7/84EEB-CBL-3 RO 7/84Appendix 1 RO 1 7/84Appendix 2 RO 1-4 7/84EEB-CBL-3.l RO 7/84Appendix 1 RO 1 7/84Appendix 2 RO 1-2 7/84EEB-CBL-4 RI 7/84Appendix 1 RI 1 7/84Appendix 2 Ri 1-5 7/84EEB-CBL-5 RO 7 /84Appendix 1 RO 1 7/84Appendix 2 RO 1-6 7/84EEB-CBL-6 RO 7/84Appendix 1 RO 1 7/84Appendix 2 RO 1-6 7/84EEB-CBL-7 RO 7/84Appendix I RO 1 7/84Appendix 2 RO 1-2 7/84EEB-CBL-7.1 RO 7/84Appendix I RO 1 7/84Appendix 2 RO 1-3 7/84EEB-CBL-7.2 RO 7/84Appendix I RO 1 7/84Appendix 2 RO 1-7 7/84EEB-CBL-8.0 RO 7/84Appendix 1 RO 1 7/84Appendix 2 RO 1-2 7/84EEB-CBL-8.1 RO 7/84Appendix 1 RO 1 7/84Appendix 2 RO 1-2 7/84EEB-CBL-8.2 RO 7/84Appendix 1 RO 1 7/84

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Appendix 2 RO 1-2 7/84EEB-CBL-8.3 RO 1 7/84Appendix 1 RO 1 7/84Appendix 2 RO 1-3 7/84EEB-CBL-8.5 RO 7/84Appendix 1 R0 1 7/84Appendix 2 RO 1-3 7/84EEB-CBL-9 Ri 10/84Appendix 1 Ri 1-2 10/84Appendix 2 RI 1-10 10/84EEB-CBL-12 RI 10/84Appendix I Ri 1-2 10/84Appendix 2 Ri 1-10 10/84EEB-CBL-13 Ri 10/84Appendix 1 R2 1-2 10/84Appendix 2 R2 1-19 10/84EEB-CBL-15 Ri 10/84Appendix 1 R2 1-2 10/84Appendix 2 RO 1-8 10/84EEB-CBL-16 R2 10/84Appendix 1 R2 1-3 10/84EEB-CBL-16.1 RO 7/84Appendix 1 RO 1 7/84Appendix 2 RO 1-7 7/84EEB-CBL-17 RI 10/84Appendix 1 Ri 1 10/84EEB-CBL-18 RO 7 /84Appendix 1 RO 1 7/84Appendix 2 RO 1-2 7/84EEB-CBL-18.1 RO 7/84Appendix 1 RO 1 7/84Appendix 2 RO 1-5 7/84EEB-CBL-18.2 RO 7/84Appendix 1 RO 1 7/84Appendix 2 RO 1-3 7/84EEB-CBL-19 RO 7/84Appendix 1 RO 1 7/84Appendix 2 RO 1-4 7/84EEB-CB-1 RO 7 /84Appendix 1 RO 1 7/84Appendix 2 RO 1 7/84EEB-CON-1 RO 10/84Appendix 1 RO 1 10/84Appendix 2 RO 1-4 10/84EEB-CSC-1 RO 7 /84Appendix 1 RO 1 7/84EEB-HS-1 R2 7 /84Appendix 1 R2 1-2 7/84Appendix 2 RO 1 7/84EEB-JB-1 Ri 7 /84

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Appendix 1 R2 1-2 7/84Appendix 2 RO 1-2 7/84WBNEEB-MTR-i RO 7 /84Appendix 1 RO 1 7/84Appendix 2 RO 1-2 7/84EEB-PEN-1 RO 7/84Appendix 1 RI 1-4 7/84Appendix 2 RO 1-4 7/84EEB-SPL-1 RO 7 /84Appendix 1 Ri 1 7/84Appendix 2 Ri 1 7/84EEB-TB--i RI 7/84Appendix 1 R3 1-3 10/84EEB-XS-1 RI 7/84Appendix 1 R2 1-4 10/84Appendix 2 RI 1-59 7/84Appendix 3 RI 1-12 7/84Appendix 4 RI 1-24 7/84Appendix 5 Ri 1-2 7/84EEB-RLY-1 RI 7/84Appendix A RI 1 7/84WBNEEB-RM-2 RO 7 /84Appendix 1 RO 1 7/84Appendix 2 Ri 1-3 10/84Appendix 3 RO 1-7 7/84EEB-STR-1 RI 7 /84Attachment 1 RO 1 7/84EEB-XS-2 Ri 7 /84Attachment 1 RI 1 7/84EEB-BD-242 RI 10/84Appendix 1 RI 1-2 10/84EEB-PNL-1 RO 7 /84Appendix 1 RI 1-2 10/84EEB-BD-1 RO 7/84Appendix I RI 1-2 10/84EEB-BD-2 RO 7/84Appendix I RI 1-2 10/84EEB-BD-3 RO 7/84Appendix 1 Ri 1-2 10/84EEB-BD-4 RO 7 /84Appendix 1 Ri 1-2 10/84EEB-MC-1 RO 7 /84Appendix 1 Ri 1-2 10/84EEB-MC-2 RO 7 /84Appendix 1 Ri 1-2 10/84EEB-MC-3 RO 7/84Appendix 1 Ri 1-2 10/84EEB-MC-4 RO 7/84Appendix 1 Ri 1-2 10/84EEB-MC-5 RO 7/84

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Appendi~x 1 RI 1-2 10/845.4 MEB EQS Title Page 1 7/84MER EQS Index 1-13 10/84WBN-MEB-30-0001 R2 10/84Appendix 1 R2 1 10/84Appendix 2 R2 1 10/84WBN-MEB-30-0006 R2 10/84Appendix 1 R2 1 10/84WBN-MEB-65-0007 Ri 7/84Appendix 1 RI 1 7/84Appendix 2 Ri 1-40 7/84WBN-MEB-6 5-0008 Ri 7/84Appendix 1 Ri 1 7/84WBN-MEB-6 5-0009 R2 10/84Appendix 1 Ri 1 7/84WBN-MEB-6 5-0010 R2 7/84Appendix 1 RI 1 7/84WBN-MEB-3 0-0011 R2 10/84Appendix 1 Ri 1 7/84Appendix 2 R2 1 10/84WBN-MEB-30-0012 R2 10/84Appendix 1 RI1 7/84Appendix 2 R2 110/84WBN-MEB-30-0013 R2 10/84Appendix 1 R2 110/84WBN-MEB-30-001 5 R2 10/84Appendix 1 RO 17/84Appendix 2 R2 1 10/84WBN-MEB-30-0016 R2 10/84Appendix 1 RI 1-3 7/84Appendix 2 R2 1 10/84WBN-MEB-30-0017 Ri 7/84Appendix 1 Ri 1 7/84WBN-MEB-30-0018 Ri 7/84Appendix 1 Ri .1 7/84WBN-MEB-65--0030 R2 10/84Appendix I RI 1 7/84Appendix 2 R2 1 10/84WBN-MEB-30-003 5 Ri 7/84Appendix I RO 1 7/84Appendix 2 Ri 1 7/84Appendix 3 RO 1-87 7/84Appendix 4 RO 1-2 7/84WBN-MEB-1-0101 Ri 7/84Appendix 1 RI 1 7/84Appendix 2 RI 1-2 7/84WBN-MEB-1i-0107 Ri 7/84Appendix 1 RI 1 7/84Appendix 2 Ri 1-2 7/84WBN-MEB-3-0 111 Ri 7/84

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Appendix 1 Ri 1 7/84Appendix 2 Ri 1-2 7/84WBN-MEB-3-0113 RI 7 /84Appendix 1 RI 1 7/84Appendix 2 RI 1-2 7/84WBN-MEB-3-0114 RI 7/84Appendix 1 Ri 1 7/84Appendix 2 Ri 1-2 7/84WBN-MEB-26-011 5 RI 7/84Appendix 1 Ri 1 7/84Appendix 2 Ri 1-2 7/84WBN-MEB-3 0-0117 R2 10/84Appendix 1 Ri 1 7/84Appendix 2 Ri 1 10/84WBN-MEB-30-01i18 Ri 7/84Appendix 1 Ri 1 7/84Appendix 2 Ri 1 7/84WBN-MEB-30-011 9 R2 10/84Appendix 1 Ri 1 7/84Appendix 2 R2 1 10/84WBN-MEB-30-0121 R2 10/84Appendix 1 R2 1 10/84WBN-MEB-30-0127 Ri 7 /84Appendix 1 Ri 1 7/84Appendix 2 Ri 1 7/84WBN-MEB-65-0130 Ri 7/84Appendix 1 RI 1 7/84Appendix 2 Ri 1 7/84WBN-MEB-6 5-0132 RI .7 /84Appendix 1 Ri 1 7/84Appendix 2 Ri 1 7/84WBN-MEB-67-0134 R2 10/84Appendix 1 RO 1 7/84Appendix 2 R2 1-2 10/84WBN-MEB-67-1i35 R2 10/84Appendix 1 Ri 1 7/84Appendix 2 R2 1-2 10/84WBN-MEB-67-0136 RI 7/84Appendix 1 Ri 1 7/84Appendix 2 RI 1-2 7/84WBN-MEB--67-0137 Ri 7/84Appendix 1 Ri 1 7/84Appendix 2 RI 1-2 7/84WBN-MEB-6 7-0139 Ri 7/84Appendix I Ri 1 7/84Appendix 2 Ri 1-2 7/84WBN-MEB-67-0140 Ri 7 /84Appendix 1 Ri 1 7/84Appendix 2 Ri 1-2 7/84WBN-MEB-7 0-0141 Ri 7/84

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6.2Table 6.2 RO6.3Table 3.11-4, 4A Title PageNEB-Table 3.11-4EEB-Table 3.11-4EEB-Table 3.11-4EEB-Table 3.11-4AMEB-Table 3.11-4Table 3.11-5 Title PageNEB-Table 3.11-5EEB-Table 3.11-5EEB-Table 3.11-5MEB-Table 3.11-5Table 3.11-6 Title PageNEB-Table 3.11-6EEB-Table 3.11-6EEB-Table 3.11-6MEB-Table 3.11-6Table 3.11-7 Title PageNEB-Table 3.11-7EEB-Table 3.11-7EEB-Table 3.11-7MEB-Table 3.11-7MEB-Table 3.11-7

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11-41000101-102(3)

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1-131-5,1000100 1-10111-2,20 13-6,101(2) ,102(2),103(2) ,104(2) ,105(3)

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INSTRUCTION SHEET

The following instructions and checklist provide instructions for insertingthe changes in the Watts Bar Nuclear Plant, Units 1 and 2, IOCFR5O.49 EEEQRsubmitted to NRC in July 1984.

Below are three columns titled Remove, Inpt and Add, respectively. Forall items listed under the columns "Remove" and "Insert," discard the oldsheets and insert the new sheets. Those items under the "Add" column arenew items never before in the report; therefore, these sheets are to beinserted in the appropriate section. In all cases, follow the instructionsunder the columns given.

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INSTRUCTION SHEET

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1OCFR5O.49 EEEQR

INSTRUCTION SHEET

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3.11-7 Sh 201 (R2) EFFECTI.-V -E.DATEI

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WATTS BAR NUCLEAR PLANT - UNITS 1 AND 2

1OCFR5O.49 EEEQR

INSTRUCTION SHEET

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DEO7 :EEEQR.WB

1 .2 SUMMARY OF ELECTRICAL EQUIPMENT QUALIFICATION STATUS

The accompanying Table 1.1 is a listing of electrical equipment beingevaluated for environmental qualification for harsh environment, and thestatus of qualification for each. Available data for unit 2 is included inthis table; however, it is not complete due to the present constructionstatus (fuel load 8/86) of unit 2. Therefore, this data should not beevaluated at this time. Table 1.1 provides the following status andindexing information:

Unit - Unit number, either 0 (common to units 1 and 2), 1 or 2.

Manufacturer/Model No.

Status - I - Devices qualified to lOCFR5O.49 guidelines.

II - Devices judged to be qualified but documentation islacking to prove qualification to lOCFR5O.49 guidelines.

III - Devices which will be requalified by either analysis ortype testing or a combination of these methods.

IV - Devices which will be replaced, shielded or relocated toless harsh environment (to which it is qualified) ratherthan requalified to lOCFR5O.49 guidelines.

For devices which are not covered by the status information above, areference to a note at the end of this table will be made in thiscolumn.

NCR No. -Nonconformance Report (NCR) number for those devices whichdo not have adequate qualification documentation to fullydemonstrate qualification to lOCFR5O.49 requirements. TVA'sDivision of Engineering Design Engineering Procedure 1.26was used in the generation of these NCRs.

EQS No. -Equipment Qualification Sheet (EQS) number for theenvironmental qualification evaluation which has beenperformed for the equipment.

1.2-1 -

L .r.

(IC

WBN TABLE 1.1

SUMMARY OF ELECTRICAL EQUIPMENT-QUALIFICATION STATUS

Unit TVA Tn ~jn, Mnniforturar/MnAol Mn ~t- ~4,,o NCR Mr~ EOS Nc~. Table Reference

1 PT

2 PT

1 FT

2 FT

.1 FT

2 FT

I FSVA.B. D,E, FG,H1,J

2 FSVA, B.D,E, FG,H, J

1 zS

NEB-1-21

NEB-1-21

- 1- 2A Foxboro/EI1GMStyle C S/N 3287045

- 1- 2A Not installed

- 1- 2B Foxboro/EIIGMStyle C SIN 3287046

- 1- 2B Not installed

- 1- 3A ITT Barton 764 (Lot 7)

Not installed

ITT Barton 764 (Lot 7)

Not installed

4A, Gould Allied Control 100

I- 4A, Gould Allied Control 100

1- 5 NAMCO EA1 80

NEB-XX-47

NEB-XX-47

MIEB-1 -0101

MEB-1-0101

EEB0087

DE05:TBL1I .DF

E F ~ ~ .

N 8/1

N 8/1

N 8/1

M 8/0101

* 8/0101

E 8/11

Unit TVA TT) Mý M. - 4ý f- /M A i m q +- +- . NrP mn EOS No

0WBN TABLE 1.1

SUMMARY OF ELECTRICAL-EQUIPMENT QUALIFICATION STATUS

Unit TVA ID No Manufacturer/Model No. NCR No. EOS No.. TAble Rpfprence

1 PCV(LS)

2 PCV(LS)

I PT

PT

PSV

PSV

PSV

PSV

2 FCV(US)

I FCV

2 FSV

- 1- 5 NAMCO EA17011100

- 1- 5 NAMCO EA17011100

- 1- 5 Foxboro/EllGMStyle C S/N 3287047

- 1- 5 Not installed

- 1- 6A ASCO X206-381-3RF

- 1- 6A ASCO S/N 53195D

WPHV202301-IRM

- 1- 6B ASCO X206-381-3RF

- 1- 6B ASCO X206-381-3RFWP11V202301-lRU

- 1- 7 NAMCO EA700

- 1-

- 1-

Target Rock 82AB-001

ASCO HT8300B58RU

DEO 5: TBL1 I . DF

EEB00 87

NEB-1-40

EEBOOO09

N 7/1

N 7/1

E 8/10

MEB-8115

EEB000 9

MEB-8115

E 8/10

EEB8132

EEB0036

EEB0036

E 8/10

E 8/2

Manufacturer/Model No NCR No. EOS No.

WBN TABLE 1.1

SUMMARY OF ELECTRICAL EQUIPMENT-QUALIFICATION STATUS

I1n4

1 TUA TT~ T~T,-~ M,,n.iFsrt,.ror/MnAol Mn NCR Nr~17ý ; f- TUA T7n M Mý 4: f- /M A I m 0 +- t- ý MCR No EOS No Table Reference

FO~ WA~ T~h1 ~ Rpfg~rpncp

1 PT -

2 PT -

1 PT -

2 PT -

1 FT -

2 FT -

1 FT -

2 FT -

I FSV -

A, B, D,E, F, G,H, J

2 FSV -

A, B, D,E,F, G,H,Ji

1 zS -

9A

9A

9B

9B

10OA

10OA

I OB

10OB

I A,

N EB-XX-48

NEB-XX-48

Barton 763 (Lot 7)

Not installed

Barton 763 (Lot 7)

Not installed

Barton 764 (Lot 7)

Not installed

Barton 764 (Lot 7)

Not installed

Gould Allied Control 100TVAOI-0577 SIN 4460

NEB-XX-47

NEB-XX-47

MEB-1 -0101

MEB-1-0 101I- 11A, Gould Allied Control 100TVA01-0577 S/N 4460

1- 12 NAKCO EA1 80 EEB0087

~ ~,'

I ~ - -

DEO5:TBLh11.DF

8/1

8/11

8/1

8/11

4/11

4/1

4/1

4/1

8/0101

M 8/0101

E 8/11

WBN TABLE 1.1

SUMM~ARY OF ELECTRICAL EQUIPMENT QUALIFICATION STATUS

N(~R N~ EOS No17, US *WlL-.t~L T17A. Tn~ 5.* m - -: 4 M A i C oE S NTable Reference

1 PCV(LS)

2 PCV(LS)

1 PT

2 PT

I PSV

2 PSV

Psv

Psv

2 FCVULS)

1 FCV

2 FSV

- 1- 12 NANCOEA1 7011100

- 1- 12 NANCOEA17 011100

- 1- 12 Barton 763 (Lot 7)

- 1- 12 Not installed

- 1- 13A ASCO X206-381-3RF

- 1- 13A ASCO 53195DCat WPHV202301-IRU

- 1- 13B ASCO X206-381-3RF

- 1- 13B ASCO 53195DCat WP11V202302-1RU

- 1- 14 NANCOEA7 00

- 1- 14 Target Rock 82AB-001

- 1- 14 ASCOHT8300B58RU

DEO 5: TBL11 . DF

EEB00 87

MEB-81 15

N EB-XX-48

EEB000 9

MEB-8115

EEB000 9

MEB-8115

EEB0036

EEB8132 EEB0036

177 ~CT VEl

~~&AT~.,934

N 8/1

N 8/1

E 8/10

E 8/10

E 8/10

E 8/2

0WBN TABLE 1.1

~ITMMARY (W P.T.FC.TR TCAT. FOTIT PMF.NT OTTALITFTCATTON STATUS

Unit TVA TTh No~ Si- ~t iii~ NCR No EOS No. Table Reference

1 FCV(LS)

2 FCV(LS)

1 FCV

2 FCV

FCV

FGV

FCV

FCV

- 1- 148 NAMCOEA7 40

- 1- 148 NAMCOEA700

- 1- 15 Limitorque SMB-00

- 1- 15 Reliance M56 712163-2BLimitorque SMB-00 /N254169

- 1- 16 Limitorque SMB-00 S/N254167

- 1- 16 Reliance M456 712163-2BLimitorque SMB-00 S/N254158

- 1- 17 Limitorque SMB-00

- 1- 17 Reliance M456 712163-2BLimitorque SMB-00 S/N 258209

- 1- 17A Fenwal 17323-0

- 1- 17A Fenwal 17323-0

- 1- 17B Fenwal 17323-0

- 1- 17B Fenwal 17323-0

EEB8134

EEB0056

EEB00 56

M4EB-1 -0107

MEB-1-0 107

ME B-i1-0107

EEBOO1 1

EEBOO1 1

EEBOO11

EEBOO1 1

F~i77~T71 VDEO5:TBLl11.DF

E 8/10

E 8/1

M 8/0102

M 8/0102

M4 8/0102

6/1, 8/1

6/1, 8/1

6/1, 8/1

6/1, 8/1

QHMMAPV Qv ELECTRICAL EQUIPMENT

EOS No.Unit TVA ID No Mmnufart-"-/Mndal No Status

0WBN TABLE 1.1

SUMMARY OF ELECTRICAL EQUIPMENT QUALIFICATION STATUS

unit TVA ID No ~- =.~,,aManufacturer/M-del No mrp w v C ?IT ýr ý, I D Cx 0. a e e erence

F CV

FCV

TS

TS

TS

TS

PT

PT

PT

PT

FT

FT

FT

FT

M4EB-1-0107

EEBOO11

EEBOO1 1

EEBOO1 1

EEB0O1 1

NEB-1-20

- 1-

- 1-

- 1-

- 1-

- 1-

- 1-

- 1-

- 1-

- 1-

- 1-

- 1-

- 1-

- 1-

- 1-

18

18

1 8A

1 8A

1 8B

1 8B

20A

20A

20 B

20 B

21A

21A

21B

21 B

DEO 5: TBL11I .DF

Limitorque SMB-00

Reliance 1456Limitorque SMB-00

Fenwal 17323-0

Fenwal 17323-0

Fenwal 17323-0

Fenwal 17323-0

Barton 763 (Lot 7)

Not installed

Barton 763 (Lot 7)

Not installed

Barton 764 (Lot 7)

Not installed

ITT Barton 764 (Lot 7)

Not installed

N EB-XX-47

NEB-XX-47

NEB-1-20

M 8/0102

E 6/1,

E 611,

E 6/1,

E 6/1,

N 8/1

N 8/1

N 8/2

N 8/2

N 4/11

N 4/1

N 4/1

N 4/1

WBN TABLE 1.1

SUMMARY OF ELECTRICAL EQUIPMENT QUALIFICATION STATUS

Unit TVA TTh No ~- 11 ~ NflR Nn FOS No. T~h~ p R~f~r~nce

1 FSV -

A, B, D,E, F, G,H,Ji

2 FSV -

A,B, D,EF, G,HI,J

1 zS -

I PCV -

(LS)

2 PCV -

(LS)

1 PT -

2 PT -

1 PSV -

2 PSV -

1 PSV -

I- 22A, Gould Allied Control 100

1- 22A, Gould Allied Control 100

1- 23

NAMCO EA180

NAMCOEA1 7011100

NAMCOEA17 011100

1- 23 Barton 763 (Lot 7)

1- 23 Not installed

1- 24A ASCO X206-381-3RF

1- 24A ASCOCat. WPHV2O23O1-1RU

1- 24B ASCO X206-381-3RF

MEB-1-0101

MEB-1-01011

EEB0087

EEB00 87

MEB-8115

NEB-XX--48

EEB0009

MEB-8115

EEB0009

E* !F

DEQ5:TBL11 .DF

M 8/Q101

M 8/0101

E 8/11

N 8/2

N 8/2

E 8/10

E 8/10

Unit TVA ID No Manufactu --- IM-,jaI No St. m t- US NCR No EOS No Table Reference

40

Unit TVA ID Nc~

2 PSV - 1- 24B ASCOWPHiV202301-1IRU

2 FCV - 1- 25 NANCOULS) EA700

1 FCV - 1- 25 Target Rock 82AB-001

2 FSV - 1- 25 ASCOUT830OOB58RU

I PT - I- 27A Foxboro/E1IGMStyle C S/N 3287054

2 PT - 1- 27A Not installed

1 PT - 1- 27B Foxboro/EIlGMStyle C S/N 3287055

2 PT - 1- 27B Not installed-

1 FT - 1- 28A Barton 764 (Lot 7)

- 1-

- 1-

- 1-

28BA

28B

28B

~-11~c

Not installed

Barton 764 (Lot 7)

Not installed

DEO5:TBL1I .DF

EF rC-T IV ED AT''EO1CT

0WBN TABLE 1.1

SUMMARY OF ELECTRICAL EQUIPMENT-QUALIFICATION STATUS

0

NCR Nn FOR Nr~

MEB-8115

T~h1 ~

EEB8132

EEB0036

EEB0036

NEB-1 -21

8/10

812

NEB-1 -21

N 8/2

N 8/2

N 8/2

NEB-XX-47

NEB-XX--47

Unit TVA ID No Manufactu --- IM-dal No St- .*-, Q NCR N- EQS Mg Tnhlo R-Faýancg

WBN TABLE 1.1

SUMMARYOFELECTRICAL EQUIPMENT OUALIFTCATION STATUS

unit -TVA ID

1 FSV -

A, BD,E,F, G,H J

2 FSV -

A$ B, D,E$F,G,11,3

I zs -

I PCV -

(LS)

2 PCV -

(US)

I PT -

PT

PSV

PSV

No.

1- 29A,

Manufacturer/Model. No.

Gould Allied Control 100

~I- ~I-.i ~

I

I- 29A, Gould Allied Control 100

1- 30

1- 30

- I-

- 1-

30

31lA

31A

NAMCO EA18O

NAMCOEA70050100

NAMCOEA70050100

Foxboro/EIIGMStyle C S/N 3287056

Not installed

ASCO X206-381-3RF

ASCOWPHV202301-IRU

NCI~ Nn 1I~A~ N~ T~h1 ~

mMEB-1-0101

MEB-1-0101

EEB00 87

EEB00 87

MEB-8115

NEB-1-40

EEB000 9

MEB-8115

Et~~~V

R f~r~nr~

8/0101

M 8/0101

E 8/111

DEO5:TBL11 .DF

N 7/1, 8/2

N 7/1, 8/2

E 8/10

QUALIFICATION STATUS

Q f- +. " . NCR No EOS No Table Reference

WBN TABLE 1.1

SUMMARY OFELECTRICAL EQUIPMENT QUALIFICATION STATUS

Unit TVA ID No ~'I-~~ ~Unit TVA ID No LaLUS 0. LVO "o. lable ReferenceQ mriD m

PSV

PSV

2 FCV(US)

1 FCV

2 FSV

1 FCV(LS)

2 FCV(US)

1 FSV

2 FSV

F SV

FSV

- I- 31B ASCO X206-381-3RF

- 1- 31B ASCOWPHV202301-IRU

- 1- 32 NAMCOEA7 00

- 1- 32 Target Rock 82AB-001

- 1- 32 ASCO

H1T83 00B58RU

- 1- 147 NANCO

EA740

- 1- 147 NAMCO

EA700

- 1- 147 ASCO X206-381-6RVF

- 1- 147 ASCOHT8300B58RU

- 1- 148 ASCO X206-381-6RVF

- 1- 148 ASCOHT830OB58RU

DEO5:TBLI1 .DFrEFFECTIVE

DATEOCT 1J84

EEB000 9

MEB-8115

1~..k1 -~ fl.C

E 8/10

EEB813 2

EEB0036

EEB0036

EEB0056

EEB0056

EEB00O07

EEB0007

EEB0007

EEB000 7

EEB8134

EEB8132

EEB813 2

8/10

8/2

E 8/10

E 8/1

E 8/3

E 8/2

E 8/3

E 8/2

WBN TABLE 1.1

SUMMARY OF ELECTRICAL-EQUIPMENT -QUALIFICATION STATUS

unit TVA ID No. Manufacturpr/Mni~1 1~h-~Man--------*.MýA .wAtau a uA . - - b 1'No. -Table Reference M .

1 FCVULS)

2 FCV(LS)

1 FCV(LS)

2 FCVULS)

1 FSV

2 FSV

I FCV(LS)

2 FCV(LS)

1 FSV

2 FSV

- 1- 148 NANCOEA7 40

- 1- 148 NANCOEA700

- 1- 149 NAMCOEA7 40

- 1- 149 NANCOEA700

- 1- 149 ASCO X206-381-6RVF

- 1- 149 ASCOHT8300B58RU

- 1- 150 NANCOEAl 80

- 1- 150 NANCOEA700

- 1- 150 ASCO X206-381-6RVF

- 1- 150 ASCOHT83 00B58RU

DEO5:TBL1II.DFI c T IVE

E 8/10

E 8/1

E 8/10

E 8/1

E 8/3

EEB8134

EEB8134

EEB8132

EEB8134

EEB8132

EEBOO056

EEB0056

EEBO0056

EEB0O056

EEB0007

EEB0007

EEB00 56

EEB0056

EEB00O07

EEB0007

8/2

8/10

E 8/1

E 8/3

E 8/2

WBN TABLE 1.1

SUMMARY OF ELECTRICAL EQUIPMENT QUALIFICATION STATUS

Unit TVA ID-No.- Manufacturer/Model-No. Status INCR. INo. £tvb ,10. - .----

- 1-

- 1-

- 1-

- 1-

- 1-

- 1-

- 1-

- 1-

EEB813 5

EEB8135

EEB813 5

EEB813 5

EEB007 7

EEB0077

EEB007 7

EEB0077

EEB0077

EEB007 7

EEB0077

EEB007 7

181-A

181-A

182-B

182-B

183-A

183-A

184-B

184-B

FCV

F SV

FCV

FSV

FCV

F SV

FCV

FSV

FCV

FCV

Target Rock 82AB-001

AS CO

HT8300B58RU

Target rock 82AB-001

ASCO

H1T83 00B58RU

Target Rock 82A.B-001

ASCOH1T830OB58RU

Target Rock 82AB-001

ASCOHT83 00B58RU

.Limitorque SB-4

Reliance IMA477 806-G5-UCLimitorque SB-4

Barton 764 (Lot 7)

Barton 764 (Lot 7)

D ATEOCT 1&DEO 5: TBLI .DF

0

)J~

MEB-3-0111

MEB-8115

NEB-3 -4

E 4/9

E 4/4

E 4/9

E 414

E 4/9

E 4/4

E 419

E 4/4

M 8/ 0102- 3- 33

- 3- 33

- 3- 38

- 3- 38

N 4/2

N 4/2

0WBN TABLE 1.1

SUMMARY OF ELECTRICAL EQUIPMENT QUALIFICATION STATUS

Table Reference

LT

LT

LT

LT

LT

LT

FCV

FCV

DE05:TBL11 .DF

NEB-XX-47

NEB-3-4

NEB-XX-47

MEB-3-0111

- 3-

- 3-

- 3-.

- 3-

- 3-

- 3-

- 3-

- 3-

- 3-

- 3-

- 3-

- 3-

- 3-

Barton 764 (Lot 7)

Barton 764 (Lot 2)

Barton 764 (Lot 7)

Not installed

Barton 764 (Lot 7)

Not installed

LimitorqueSB-4

Reliance IMA477 806-G6-UCLimitorque SB-4.

Barton 764 (Lot 7)

Barton 764,(Lot 7)

Barton 764 (Lot 7)

Barton 764 (Lot 2)

Barton 764 (Lot 7)

Not installed

NEB-XX-47

NEB-3-4

NCR No.

MEB- 8115

EOS No.

NEB-3-4

4/2

4/2

4/2

4/2

4/2

4/2

8/ 0102

4/2

4/2

4/2

4/2

4/2

4/2

E; AT EE.4

unit- TVA ID No Man"f-,t- lmýA.l Mn Status

WBN TABLE 1.1

SUMMARY OF ELECTRICAL EQUIPMENT-QUALIFICATION STATUS

TTn~t TUA Tfl Na Mnn,,Pant..rnr/MnAa1 Na NC'R Na Ffl5~ N~ .Table ReferenceHn i t- TUA Tn W M. 4: +- IM-A I w Q f- +. . wrR No EOS No

LT

LT

FCV

FCV

LT

LT

LT

LT

LT

LT

LT

LT

FCV

FCV

NEB-3-4

MEB-3-0111

MEB-8115

- 3-

- 3-

- 3-

- 3-

- 3-

- 3-

- 3-

- 3-

- 3-

- 3-

- 3-

- 3-

- 3-

- 3-

56

56

87

87

93

93

94

94

97

97

98

98

100

100

DE05:TBL1I .DFI~ Z~

Barton '764 (Lot 7)

Not installed

Limitorque SB-4

Reliance IMA477 806-G7-UCLimitorque SB-4

ITT Barton 764 (Lot 7)

ITT Barton 764 (Lot 2)

ITT Barton 764 (Lot 7)

ITT Barton 764 (Lot 2.)

Barton 764 (Lot 7)

Not installed

Barton 764 (Lot 7)

Not installed

Limitorque SB-4

Reliance IMA47 7806-GI-UCLimitorque SB-4

MEB-8115

4/3

4/3

8/0102

NEB-3 -4

NEB-3-4

NEB-XX-47

NEB-XX-47

MEB-3-0111

N 4/3

N 4/3

N 4/3

N 4/3

N 4/3

N 4/3

N 4/3

N 4/3

M 8/0102

WBN TABLE 1.1

QTThfMAPV AV ~TWCTDTCAT. 1~AT1TPM~NT AITAT.T1ITCATTAN ~TAT1T5~

1Tri~t TVA Tfl Nn Moniifort.irar/MnAol Nn f-il g NCR N~ F~AS Nn~. Table Reference

NEB-3-4LT

LT

LT

LT

LT

LT

LT

LT

FCV

FCV

FCV

FCV

MT1R

1M!IR

NEB-3-4

NEB-XX-47

NEB-3-4

- 3-

- 3-

- 3-

- 3-

- 3-

- 3-

- 3-

- 3-

- 3-

- 3-

- 3-

- 3-

- 3-

- 3-

106

106

107

107

110

110

ill

ill

1 16A

1 16A

116 B

116B

11 8A

11 8A

Barton 764 (Lot 7)

Not installed

Barton 764 (Lot 7)

Barton 764 (Lot 7)

Barton 764 (Lot 7)

Not installed

Barton 764 (Lot 7)

Not installed

Limitorque SMB-000

Reliance 720332-XELiinitorque SMB-000

Limitorque SMB-000

Reliance 720332-ZBLimitorque SMB-000

Reliance

Reliance

DEO5:TBL11 .DF EF F!EC T IV EDATE

OCT 19014

MEB-3--0113

M4EB-3-0113

EEB-MTR-1

EEB-MTR-1

4/3

4/3

4/3

4/3

.4/4

4/4

4/4

4/4

7/ 0101

M 7/0101

6/1012

6/ 1012

eTTMMARV nV VTVPTPTrAT. Un"TPMVMT nITAT-IPICATION STATUS

un; f- TUA TTI W- Table Reference

WBN TABLE 1.1

QTflflAADV (~ 1'T vr'rDTCAT RnT1TPM~?.rr ATJATT)?TCATTAN 5~TAT!?~

Thi~ T!ZA Tn ~ NCR Nr~ 1~A5~ Nr~ Table Reference

- 3- 122 FoxboroN-El IDM-411D2

- 3- 122 FoxboroN-ElIDM-HID2

- 3- 122 Fisher Type 546

- 3- 122 MEA 1-19K--2

I PDTA-A

2 PDTA-A

I PM

2 PM

I FCV

2 FCV

EEB0072

EEB0072

EEB8114

Limitorque SMB-000

Reliance 720332-ZBLimitorque SMB-000

Limitorque SMB-O000

Reliance 720332-XELimitorque SMB-O000

Reliance

Reliance

FoxboroN-El lDM-111D2

6/4, 8/9

6/4, 8/9

6/4, 8/6

6/4, 8/6

7 /0101

EEB0023

EEB0023

MEB-3--0113

MEB-3--0113

EEB-MTR- 1

EEB-MTR-l

EEB0072

EEB0072- 3- 132 FoxboroN-El lDM-HID2

M 7/0101

6/1012

6/1012

6/4, 8/9

E 614, 819

DEO5:TBLIl .DF

1 26A

1 26A

126B

126 B

1 28B

12 8B

132

I MTR

2 MTR

1 PDTA- B

2 PDTA- B

- 3-

- 3-

- 3-

- 3-

- 3-

- 3-

- 3-

QTTLOrL DV AV V'rVr'rDTrAT V T 13,MTMlr TIATTVTrATTnW STATUSIU-- X

11 , IMIA Tn M Mý IF #ý /M A I M Q f- f- wrp m^ EOS No Table Reference

Unit TVA ID No.

WBN TABLE 1.1

SUMMARY OF ELECTRICAL EQUIPMENT QUALIFICATION STA.

Manufacturer/Model No. Status - NCR No.

LTUS

EOS Nn. Table ReferencP

1 PM - 3- 132 Fisher Type 546

2 PM - 3- 132 MEA 1-19K-2

1 FCV - 3- 136A Limitorque SMB-000

2 FCV - 3- 136A Reliance 720323-ZBLimitorque SMiB-000

I FCV - 3- 136B Limitorque SMB-O00

2 FCV - 3- 136B Reliance 720323-ZB

Limitorque, SMB-000

I PS - 3- 139A Custom Component604-G

2 PS -3- 139A Custom Component6 04G

I PS - 3- 139B Custom Component6 04G

2 PS - 3- 139B Custom Component6 04G

1 PS - 3- 139D Custom Component6 04G

DEO5:TBLIl .DF

EEB8114

EEB0023

EEB0023

MEB-3-0114

MEB-3-01 14

EEB8115 EEB0016

EEB8115 EEB0016

EEB8115 EEB0016

EEB8115 EEB0016

EEB8115 EEB0016

IVE

D A T E

6/4, 8/6

6/4, 8/6

6/0101

M 6/0101

6/4, 8/6

6/4, 8/6

6/4, 8/6

6/4, 8/6

6/4, 8/6

WBN TABLE,1.1

SUMMARY OFELECTRICAL EQUIPMENTQUALIFICATIONSTATUS

Unit TVA-ID-No. Manufacturer/Model No. Status NCR No. EQSNo. Table Reference

2 PS - 3- 139D Custom Component IV EEB8115 EEB0016 E 6/4, 8/6604G

I PS - 3- 140A ASCO I EEB0016 E 7/3, 8/6SBIIAKR/TGl3A42R

2 PS - 3- 140A ASCO I EEB0016 E 7/3, 8/6SBllAKR/TG13A42R

2 PS - 3- 140B Custom Component IV EEB8144 EEB0050 E 8/26 04G

I PS - 3- 144A Custom Component IV EEB8115 EEB0016 E 6/4, 8/6604G

2 PS - 3- 144A Custom Component IV EEB8115 EEB0016 E 6/4, 8/6604G

I PS - 3- 144B Custom Component IV EEB8115 EEB0016 E 6/4, 8/6604G

2 PS - 3- 144B Custom Component IV EEB8115 EEB0016 E 6/4, 8/66 04G

1 PS - 3- 144D Custom Component IV EEB8115 EEB0016 E 6/4, 8/6604G

2 PS - 3- 144D Custom Component IV EEB8115 EEB0016 E 6/4, 8/66 04G

DEO5:TBLll .DF 18A F DIAT11E

0-SUMMARY OF ELECTRICAL EQUIPMENT-QUALIFICATION STATUS

Unit TVA ID No. . Manufacturer/Model No. Status NCR No. ESN.Table Reference1 LCV - 3- 148 Masoneilan 8012 111 EEB8121 EEB0057 E 6/2, 8/4(Post.)

2 LCV -

(Post.3- 148 Masoneilan 8012

EEB8121

EEB8123

1 LSV -3- 148 ASCO 206-381-3RVU

2 LSV -3- 148 ASCOH1T830OB58RU

1 PS -3- 148 ASCOSBIlAKR/TL1OA32R

2 PS - 3- 148 ASCOSBIIAKR/TLIOA32R

I LT - 3- 148-B Foxboro EI3DM (MCA)

2 LT - 3- 148-B Foxboro E13DM (MCA)

I LM - 3- 148A Masoneilan 8005A

2 LM - 3- 148A Masoneilan 8005A

1 LSV - 3- 148A ASCO 206-381-3RVU

2 LSV - 3- 148A ASCOWPXHV202301I-F

DEO5:TBLI11.DF

EEB0057

EEB002 9

EEB0029

EEB0091

EEB0091

EEB0002

EEB0002

EEB003 8

EEB003 8

EEB0035

E 6/2, 8/4

E 6/6,

E 6/2,

8/14

E /,8/1

E 6/3, 8/1

4/2

4/2

6/1,

6/1,

6/1,

EEB8125 EEB0035

F: ic :v

8/3

8/3

E 6/1, 8/3

0WBN TABLE, 1.1

Unit TVA ID No.

0WBN-TABLE-1.1

SUI*IARY.OF. ELECTRICAL-EQUIPMENT -QUALIFICATIONST)

Manufacturer/Model.No.- Status NCR No.

LTUS

EOS No. Tablep Ra-1 PS - 3- 150A ASCO

SB11AKR/TG13A42R

2 PS - 3- 150A ASCOSB11AKR/TG13A42R

2 FI - 3- 155D Westinghouse VX-252

1 LCV - 3- 156 Masoneilan 8012

(Post.)

2 LCV - 3- 156 Masoneilan 8012(Post.)

1 LSV - 3- 156 ASCO 206-381-3RVU

2 LSV - 3- 156 ASCOHT83 00B58RU

1 PS - 3- 156 ASCOSBIIAKR/TL1OA32R

2 PS - 3- 156 ASCOSBIIAKR/TL1OA32R

I LT - 3- 156-A Foxboro E13DM (MCA)

2 LT - 3- 156-A Foxboro E13GM (MCA)

DEOS:TBLI1 .DF

.IV

III

III

I

IV

I

I

EEB83 06

EEB8121

EEB8121

EEB8123

20VE

EEB0016

EEB0016

EEB00 83

EEB00 57

EEB00 57

EEB0029

EEB0029

EEB0091

EEB0091

EEB0002

EEB000 2

7/3,

7/3,

617,

6/2,

6/2,

6/6,

6/2,

6/3,

6/3,

8/6

8/6

8/13

8/4

8/4

8/14

8/5

811

8/1

E 4/2

E 4/2

0-WBN TABLE,1.1

SUMMA.RY-OF. ELECTRICAL-EQUIýPMENT-QUALIFICATION STATUS

Unit TVA ID NnMauat-- I 0 LaLUS 1vux.1L40. EOS No. Table Reference

1 LM

2 1.2

I LSV

2 LSV

2 Fl

I LCV(Post..

2 LCV -

(Post .

I LSV -

2 LSV -

1 PS -

2 PS -

- 3- 156A

- 3- 156A

- 3- 156A

- 3- 156A

- 3- 163D

-3- 164

-3- 164

-3- 164

*3- 164

*3- 164

*3- 164

Masoneilan 8005

Masoneilan 8005

ASCO 206-381-3RVU

AS COWPXHV202-301-IF

Westinghouse VX-252

Masoneilan 8012

Masoneilan 8012

ASCO 206-381-3RVU

AS COHT83 00B5 8RU

AS COSBl1AKR/TLIOA32R

ASCOSB11AKR/TLlOA32R

DE05:TBL1II.DFE F F F, C -Ti I V E

D ATE

IV

IV

II

III

IV

IV

IV

I

EEB81 25

EEB83 06

EEB81 21

EEB8121

EEB81 23

EEB003 8

EEB003 8

EEB0035

EEB0035

EEBO0083

EEBOO057

EEB00 57

EEB0029

EEB0029

EEBO0091

EEB0091

6/1,

6/1,

6/1,

6/1,

6/7,

6/2,

6/2,

6/6,

6/2,

6/3,

6/3,

8/3

813

8/1

8/3

8/13

8/4

8/4

8/14

8/5

8/1

8/1

9

Unit TVA, Il No. -Manufacturer/ModelNo Status NC o No. o.TbeRfrnce

I LT

2 LT

I LM

2 LM

1 LSV

2 LSV

I LCV`(Post

2 LCV(Post.

1 LSV

2 LSV

1 PS

2 PS

- 3- 164-A Foxboro E13DM (MCA)

- 3-

- 3-

- 3-

- 3-

- 3-

3

164-A

16 4A

16 4A

16 4A

16 4A

3- 171

3- 171

Foxboro E13DM (MCA)

Masoneilan 8005A

Masoneilan 8005A

ASCO 206-381-3RVU

AS CO

WPXHV202-301-IF

Masoneilan 8012

Masoneilan 8012

IV

II

II

I

IV

-3- 171 ASCO 206-381-3RVU

-3- 171 ASCOHT8300B58RU

-3- 171 ASCOSB11AKR/TL1OA32R

-3- 171 ASCOSBI1AKR/TL1OA32R

EEB81 25

EEB81 21

EEB8121

EEB8123

EEB0002

EEB0002

EEB0038

EEB003 8

EEB0035

EEB0035

EEB00 57

EEB0057

EEB0029

EEB0029

EEB0091

EEB0091

412

4/2

6/1,

6/1,

6/1,

6/1,

8/3

8/3

8/1

8/3

DEO5:TBLI11.DF

WBNTABLE.1.1

SUMMARY, OF. ELECTRICA- EQUTTIPMN QAIICTO SAU

E 6/2, 8/4

E 6/2, 8/4

6/6,

6/2,

8/14

8/5

E 6/3, 8/1

E 6/3, 8/1

IWBN-TABLE 1.1

SUMMARYOF, ELECTRICAL .EQUIPMENT. QUALIFICAT.ION STATUS

Unit TVA ID Nn..Unt TA DN e o,- ~ a~aus , -- - NC , No. I ,II ESN.-Table-Reference

Mnn,, fo -,,,.~,. IMA I ~

1 LT - 3- 171-B Foxboro E13DM (MCA)

2 LT - 3- 171-B Foxboro E13DM (MCA)

1 LM - 3- 171A Masoneilan 8005A

2 Lm - 3- 171A Hasoneilan-8005A

I LSV - 3- 171A ASCO 206-381-3RVU

2 LSV - 3- 171A ASCOWPXHV202-301-IF

I LCV - 3- 172 Masoneilan 8012(Post

2 LCV(Post

I LSV

2 LSV

1 LT

2 LT

3

33- 172 Masoneilan 8012

EEB8125

EEB8121

EEB8121

EEB81 23

- 3- 172 ASCO 206-380-3RVU

- 3- 172 ASCO

HT83 00B5 8RU

- 3- 172-A Foxboro E13DM (MCA)

- 3- 172-A Foxboro E13DM (MCA)

EEB0O002

EEB0002

EEB003 8

EEB003 8

EEB0035

EEB003 5

EEB0057

EEB0057

EEB002 9

EEB002 9

EEB0002

EEB0002

4/2

4/2

6/1,

6/1,

6/1,

6/1,

8/3

8/3

8/1

8/3

E 6/2, 8/4

E 6/2, 8/4

6/6,

6/2,

8/14

8/5

E 4/2

E 4/2

DEO5:TBL11 .DF

L I-E T IV ErDATEL OCT 19 84

WBN TABLE,1.J1

SUMMARY. OFELECTRICAL. EQUIPMENT, QUALIFICAT.ION. STATUS

Unit TVA ID Nn..Uni TVA INo ,W- - I .LaLus LJ.4%A, 1.0U. _ _ iw._r~o N iaoie R~eference)~1rD a..

1 LCV -

(Post.)

2 LCV -

(Post.)

1 LSV -

2 LSV -

1 LT -

2 LT -

1 LCV -

(Post.)

2 LCV -

(Post.)

1 LSV

2 LSV -

3- 173 Masoneilan 8012

3- 173

3- 173

3- 173

173-B

173-B

174

3- 174

3- 174

3- 174

- 3-

- 3-

174-B

174-B

Masoneilan 8012

ASCO 206-380-3RVU

ASCOHT83 00B58RU

Foxboro E13DM (MCA)

Foxboro E13DM (MCA)

Masoneilan 8012

Masoneilan 8012

ASCO X206-381-3RVU

ASCO

H{T830OB58RU

Foxboro E13DM (MCA)

Foxboro E13DM (MCA)

I

IV

I

I

III

III

I

IV

I

I

DEO5:TBLII .DF

EEB81 21

EEB81 21

EEB81 23

EEB821 0

EEB8210

EEB813 2

EEBOO057

EEB0057

EEB0029

EEB0029

EEB0002

EEB0002

EEB007 3

EEB0073

EEB0007

EEB0007

E 6/2, 8/4

E 6/2, 8/4

E 6/6, 8/14

E 6/2, 8/5

E 4/2

E 4/2

E 8/9

E 8/9

E 8/3

E 8/2

E 4/2

E 4/2

EEB0002

EEB0002

E FFE CT IV EDATE

O cl

0 WBN. TABLE 1.1

SUMMARY.OF, ELECTRICaJ..EQUIpMENT.QUALIFIC TION STATUS.-

Unit TVA. ID. No.. Manufacturer/Model No. _,--Status NCR, No. EQS No. TbeRfrence

I LCV(Post.)

2 LCV -

(Post.)

3- 175 Masoneilan 8012

3- 175 Masoneilan 8012

EEB8210

EEB821 0

EEB8132

1 LSV - 3- 175 ASCO X206-381-3RVU

2 LSV - 3- 175 ASCOHT8300B58RU

I LT - 3- 175-A Foxboro E13DM (MCA)

2 LT - 3- 175-A Foxboro E13DM (MCA)

1 FCV - 3- 179A Limitorque SMB-000

2 FCV - 3- 179A Reliance 720-323-ZBLimitorque SMB-000

1 FCV - 3- 179B Limitorque SMB-000

2 FCV - 3- 179B Reliance 720-323-ZBLimitorque SMB-000

1 FSV - 3- 185 ASCO206-381 -2F

DEO5:TBL11 .DF

EEB0073

EEB0073

EEB0007

EEB0007

EEB0002

EEB0002

MEB-3-0114

MEB-3 -0114

EEB0020

25 £A TEOCT -:

E 8/9

E 8/9

E 8/3

E 8/3

4/2

4/2

6/ 0101

M 6/0101

E 8/2

WBN-TABLE 1.1

SURMARY.OF. ELECTRICAL. EQUIPMSNT. QUALIFICATION. STATUS

Unit_ TVA, ID, No. Manufacturer/ModelNo. ... Status-, NCRNo. EQS.No.- Table.Reference

2 FSV - 3- 185 ASCO IEEB0020 E 8/2206-381 -2F

1 FSV - 3- 186 ASCO IEEB0020 E 8/2206-381 -2F

2 FSV - 3- 186 ASCO IEEB0020 E 8/2206-381 -2F

1 FSV - 3- 187 ASCO IEEB0020 E 8/2206-381 -2F

2 FSV - 3- 187 ASCO IEEB0020 E 8/2206-381 -2F

1 FSV - 3- 188 ASCO 206-381-2F I EEB0020 E 8/2

2 FSV - 3- 188 ASCO 206-381-2F I EEB0020 E 8/2

1 FSV - 3- 236A ASCO 206-381-2F IEEB0020 E 8/5

2 FSV - 3- 236A ASCO 206-381-2F IEEB0020 E 8/5

1 FSV - 3- 236B ASCO 206-381-2F I EEB0020 E 8/5

2 FSV - 3- 236B ASCO 206-381-2F I EEB0020 E 8/5

1 FSV - 3- 239A ASCO 206-381-2F I EEB0020 E 8/5

DEO5:TBLI1 .DF 26 I

- -.... b~s.

OWBN, TABLE 1. 1

SUI*ARYOF. ELECTRICAL EQUIPMEIT -QUALIFICATION. STATUS

Ilni I- TVA Tfl Mr~

FSV

FSV

FSV

F SV

FSV

FSV

F SV

FSV

FSV

FSV

FSV

FSV

F SV

TS

TS

- 3-

- 3-

- 3-

- 3-

- 3-

- 3-

- 3-

- 3-

- 3-

- 3-

- 3-

- 12-

- 12-

- 12-

- 12-

Un TAI M u , rrl de.,o --- Satus 9I4UP.'NO. J- , QS, o o. , Table..ileerence

23 9A

23 9B

23 9B

242A

242A

242 B

242 B

245A

245A

245B

245 B

79

82

91A

91 B

ASCO 206-381-2F

ASCO 206-381-2F

ASCO 206-381-2F

ASCO 206-381-2F

ASCO 206-381-2F

ASCO 206-381-2F

ASCO 206-381-2F

ASCO 206-381-2F

ASCO 206-381-2F

ASCO 206-381-2F

ASCO 206-381-2F

ASCO 206-380-2RU

ASCO 206-380-2RU

Fenwal 18023-7

Fenwal 18023-7

DEO5:TBL11 .DF27 DATE27

ý ý C~J r j

EEB0020

EEB0020

EEB0020

EEB0020

EEB0020

EEB0020

EEB0020

EEB0020

EEB0020

EEB0020

EEB0020

EEB0049

EEB0049

EEBO0089

EEB0089

E 8/5

E 8/5

E 8/5

E 8/5

E 8/5

E 8/5

E 8/5

E 8/5

E 8/5

E 8/5

E 8/5

E 8/12

N/A

E 8/11

E 8/11

WBN TABLE.14.

SURMMRY OF ELECTRICAL.EOUIPMENTaTJA.IFTCATTInw QrTATTTC

Unit - TVA, ID, No-.-, , Manufac urer/Model No.A t-li~ NflD ~ Dr~c! ).T~.-- - ~ A-aLJJ~J~LeL1(.e

0 TS - 12- 92A Fenval. 18023-7

- 12-

- 12-

- 12-

- 12-

- 12-

- 12-

- 12-

- 12-

- 12-

- 12-

- 12-

- 12-

- 12-

92B

93A

93 B

94A

94B

95A

95B

96A

96 B

97A

97 B

98A

98B

- 12- 99A

Fenwal 18023-7

Fenwal 18023-7

Fenval 18023-7

Fenwal 18023-7

Fenwal 18023-7

Fenwal 18023-7

Fenwal 18023-7

Fenwal 18023-7

Fenwal 18023-7

Fenwal 18023-7

Fenwal 18023-7

Fenwal 18023-7

Fenwal 18023-7

Fenwal 18023-7

DEO5:TBL1I .DF

£) ~

EEB0089

EEB00 89

EEB0022

EEB0022

EEB0022

EEB0022

EEB0022

EEB0022

EEB0022

EEB0022

EEB0022

EEB0022

EEB0022

EEB0022

EEB00 89

E 8/11

E 8/11

E 6/5,

E 6/5,

E 6/2,

E 6/2,

E 6/2,

E 6/2,

E 6/2,

E 6/2,

E 6/2,

E 6/2,

E 6/2,

E 6/2,

E 8/11

8/2

8/2

8/5

8/5

8/5

8/5

8/5

8/5

8/5

8/5

8/5

8/5

mrv m Rnqqt- q f-11 a

OWBN, TABLE, 1. 1

SUMMARY. OF, ELECTRICAL-EQUIPM4ENT. QUALIFICATION, STATUS

0

Unit TVA ID NnUni TVA ID Noo I'---L- .. tatus---,No EQS. No.- Table,fteference

0 TS - 12- 99B Fenwal 18023-7

1 FCV - 26- 240 Limitorque SB-00

2 FCV - 26- 240 Reliance 712127-YCLimitorque SB-00

1 FCV - 26- 241 Limitorque SB-00

2 FCV - 26- 241 Reliance 712127-YCLimitorque SB-00

1 FCV - 26- 242 Limitorque SB-00

2 FCV - 26- 242 Reliance 712127-YCLimitorque SB-00

1 FCV - 26- 243 Limitorque SB-00

2 FCV - 26- 243 Reliance 712127-YCLimitorque SB-00

I FCV - 26- 244 Limitorque SB-00

2 FCV - 26- 244 Reliance 712127-YCLimitorque SB-00

DEO 5: TBLI 1 .DF

EEB00 89

MEB-26-01 15

MEB-26-011 5

MEB-26-011 5

MEB-26-0115

MEB-26-01 15

IL .L ~TIVEI' ý' ~ - -"

8/11

7/ 0105

M 7/0105

M 7/0105

M 7/0105

M 7/0105

WBN TABLE 1,1

SUMMARY OF _ELECTRICAL_ EQUIPMENT. 1U)lIFCAION- STATUS

Unit _TVA ID Np, anacuer/Model No. Sttu NCR No EQS- Np,. 1 Tbe Re f e ren cI FCV - 26- 245

FCV

FCV(US)

FCV(US)

FSV

FSV

FCV(LS)

FCVULS)

FSV

FSV

- 26-

- 30-

- 30-

- 30-

- 30-

- 30-

- 30-

- 30-

- 30-

Limitorque SB-00

Reliance 712127-YCLimitorque SB-00

NAMCO#EA74050100

NAMCO#FtA7405O0O0

AS CO#HTX8316E35E

AS CO#HTX8316E35E

NAMCO#EA74050100

NAMCO#EA74005011

AS COHTX8316E35E

AS COHTX8316E3 5E

MEB-26-011 5

MEB-8115

MEB-8115

MEB-8115

MEB-8115

MEB-30-0118

MEB-30-011 8

MEB-30-0117

MEB-30-0118

MEB-30-0118

MEB-30--0117

I FSV - 30- 7-A ASCO X206-381-3Rr

DEO5:TBLII .DF

EEB0O054

E) rA

M 7/0105

M 7/0101

M 7/0101

M 7/0101

7/0101

7/0101

7/0101

E 5/3

0WBN TABLE.1,1lSUMMARYOFELECTRICAL-EQUIPMENT. QUAL IF ICAT ION STATUS

Unit TVA ID No~.t- V- c .*J Ot . SLUS I4. rl,&K 140, 1ýA- P40ESN. Table Reference

FSV

zS

zS

FSV

FSV

zS

zs

FSV

FSV

zs

zS

FSV

FSV

zs

- 30-

- 30-

- 30-

- 30-

- 30-

- 30-

- 30-

- 30-

- 30-

- 30-

- 30-

- 30-

- 30-

- 30-

DEO5:TBL11 .DF

7-A

7-A

7-A

8-B

8-B

8-B

8-B

9-B

9-B

9-B

9-B

10-A

10-A

10-A

ASCO HV202303-IF

NAMCO EA180

NANCO EA 78050000,EA 78050001

ASCO X206-381-3RF

ASCO HV202303-IF

NAMCO EA740

NAMCO EA7 80,

ASCO X206-381-3RF

ASCO H{V202303-IF

NAMCO EA180

NANCO EA 78050000,EA7 8050001

ASCO X206-381-3RF

ASCO 8002, HV202303-1F

NAMCO EA74050000

MEB-8115

EEB0063

MEB-811 5

EEB0046

MEB-8115

EEB8130

EEB001 8

EEB0059

EEB0054

MEB-8115

EEB0063

MEB-8115

EEB0046

MEB-8115

MEB-30-0121

31 VJ VE

0

E 5/4

E 4/12

E 5/4

E 4/12

M 4/101

Unit .TVA ID No. Manufacturer/Model Np,

2 zs - 30- 10-A NAMCO EA78050000

1 FCV(LS)

2 FCV(LS)

I FSV

2 FSV

I FSV

2 FSV

1 zs

2 zs

St'. t-I usP V j

IV MEB-8115EA7 80500001

- 30- 12-A NAMCO EA74050100

- 30- 12-A NAMCO EA74050100

- 30-

- 30-

- 30-

- 30-

- 30-

- 30-

- 30-

- 30-

- 30-

- 30-

1 2A

1 2A

14-A

14-A

14-A

14-A

15-B

15-B

15-B

15-B

ASCO X206-381-3RF

ASCO HT8316E3-5E

ASCO X206-381-3RF

ASCO 8002, HV202303-IF

NANCO EA180

NANCO EA780500001,EA7 8050000

ASCO X206-381-3RF

ASCO HV202303-IF

NAMCO EA740

NANCO EA780

MEB-30-01 27

MIEB-30-01 27

EEB0054

.Reference

M 5/0101

M 5/0101

E 5/3

MEB-8115

EEB00 54

MEB-8115

EEB0063

E 5/3

E 5/4

MEB-8115

EEB0047

MEB-8115

EEB8130

EEB00l18

EEB0059

E 4/ 10

E 4/1

E 4/3

DEO5:TBL1II.DF32 ~~

7'- ;~

WBN -TABLE- 1 1

SUMMARY OF ELECTRICAL-EQUIPMENT QUALIFICATIONSTATTUS

0SUMMARY-OF ELECTRICAL EOUIPMENT

OUALIFTCATTAWQTT"

Unit TVA ID No. MRflufJ~rtuIrDr/MnA~1 ie~-~ -9. .- ta u - L. I..%j L IQA i 0p . QSN I LLL . - Table Reference

I FCVULS)

2 FCVULS)

1 FSV

2 FSV

1 FCVULS)

2 FCV(US)

I FSV

2 FSV

1 FSV

2 FSV

1 zs

2 zS

- 30- 16-B NAMCO EA180

- 30- 16-B NANCO EA78050000,EA78050001

- 30- 16-B ASCO X206-381-3RF

- 30- 16-B ASCO HV202303-1F

- 30- 17-A NANCO EA180

- 30- 17-A NAMCO EA78050000,EA78050001

- 30- 17-A ASCO X206-381-3RF

- 30- 17-A ASCO HV202303-IF

- 30- 19-B ASCO X206-381-3RF

- 30- 19-B ASCO HV202303-IF

- 30- 19-B NANCO EA180

- 30- 19-B NAMCO EA78050001,EA7 8050000

DEO 5: TBL11I .DF

E F F y

DA E'

0 WBN TABLE 1,1

EEB006 3

MEB-8115

E 5/4

EEB00 54

MEB-8115

EEB00 88

E 5/3

E 4/10

MEB-8115

EEB0047

MEB-81 15

EEB0054

MEB-8115

E 4/10

E 5/3

EEB0063

MEB-81 15

E 5/4

WBN TA&LE 1,1

SUMMARY 0FELECTRICAL -EQUIPMENT QUALIFICATION. STATUS

Unit TVA-ID No. Imanufacturer/M^odel Wo, S u NC NE ES. No, -- TableReference

1 FSV

2 FSV

I zs

2 zs

2 FCOULS)

2 FSV

I FSV

1 zs

I FSV

I zs

1 FCVULS)

2 FCVULS)

I FSV

2 FSV

- 30- 20-A ASCO X206-381-3RF

- 30-

- 30-

- 30-

- 30-

- 30-

- 30-

- 30-

- 30-

- 30-

- 30-

20-A

20-A

20-A

22

22

28

28

29

29

37-B

EEB0047

ASCO HV202303-1F

NAMCO EA740

NAMCO EA780

RB Demospm #C4 JK05

ASCO HT8320A185

ASCO HT8320AI08

NANCO EA180

ASCO HT8320A108

NAMCO EA180

NAMCO EA180

- 30- 37-B NANCO EA78050000,EA780 50001

- 30- 37-B ASCO X206-381-3RF

- 30- 37-B ASCO HV202303-IF

MEB-8115

EEB8130

MEB-8115

MEB-8115

MEB-8115

MEB- 8115

EEB001 8

EEB0059

MEB-30-0001

EEB0067

MEB-30-0001

EEB0067

EEB0063

MEB-8115

EEB0O054

MEB-8115

DEO5TBL1 .DF34 E FF LCT!4

E 4/10

E 4/1

E 4/3

7/0001

7/5

7/ 0001

7/5

5/4

E 5/3

DE05:TBL11.DF

SVUNM-ARY OF ELECTRICA.L EQUIPMENT QUALIFICATION STATUS$

Unit .. TVA ,ID No, Manuf acturer/ Model. No. Status NCR-No. ,-EOS No

1 T - 30- 38-A ReliancelYF882396A1-UC

3 8-A

3 9-B

3 9-B

40-A

40-A

40-A

40-A

42

42

43

Reliance1YF8823 96A4-UC

Reliance1YF8823 96A2-UC

Reliance1YF8823 96A3-UC

ASCO X206-381-3R1F

NAMCO EA740

NAMCO EA780

ASCO HV202303-IF

Foxboro EIIGM

Not installed

Foxboro E11GM

MTR

MTR

MTR

FSV

FCV(LS)

FCV(LS)

FSV

PDT

PDT

PDT

MEB-30-003 5

MEB-30-003 5

MEB-30-003 5

MEB-30-003 5

EEB0047

EEB001 8

EEB0059

- 30-

- 30-

- 30-

- 30-

- 30-

- 30-

- 30-

- 30-

- 30-

- 30-

- 30- 43 Not installed

DEO5:TBL11 .DF

EEB8130

MEB-8115

2 PDT

NEB-30-27

NEB-30-27

M 4/0001

M 4/ 0001

M 4/0001

M 4/0001

E 4/10

E 4/1

E 4/3

N 5/1

N 5/1

N 5/1

N 5/1

I:I . . Table R fav=",-

W5N ALýE 1,1

SUMMARY, OF EýLECTRICALJEQUIPMENT' QUVALIFICATION, STATUS

Unit TVA I& Np.IQ, , . Manufacturer/Model _No. , _Status . I NCR-N.EQ o Table Ref --- e

1 PDT

2 PDT

1 PDT

2 PDT

1 FSV

2 FSV

1 zs

2 zs

L FSV

FSV

zs

* zs

FSV

* FSV

- 30- 44 Foxboro E11GM

- 30-

- 30-

- 30-

- 30-

- 30-

- 30-

- 30-

- 30-

- 30-

- 30-

- 30-

44

45

45

50-B

50-B

50-B

50-B

51-A

51-A

51-A

51 -A

- 30- 52-A

- 30- 52-A

NEB-30-27

NEB-3 0-27

EEB0047

Foxboro Ella!.

Foxboro E11GM

Foxboro EIIGM.

ASCO X206-381-3R1'

ASCO HV202303-IF

NANCO EA740

NAJICO EA780

ASCO X206-381-3RF

ASCO HV202303-IF

NAMCO EA1 80

NAMCO EA78050001,EA7 8050000

ASCO X206-381-3RF

ASCO HV202303-IF

DEO5:TBL1I .DF

MEB-8115

EEB8130

MEB-8115

EEB0018

EEB0059

EEB00 54

EEB0063

MEB-8115

MEB-8115

rEFFECTI]VE0 C T

N 5/1

N 5/1

N 5/1

N 5/1

E 4/10

E 5/4

E 4/10EEB0047

WBN. TABLE, I. I

SUMMRY- OF EýLECTRICAL- EOUIP14ENTOUAL IF ICAT ION STATTIS

Upit --- TVA. ID No, ý Manufacturer/Model No.St 4-uV. I~v vQ, __ LJble-Refernce

I zs - 30- 52-A NANCO EA740

zS

FSV

FSV

zs

zs

.1 FSV

2 FSV

1 FCV(LS)

2 FCV(LS)

I FSV

2 FSV

- 30-

- 30-

- 30-

- 30-

- 30-

- 30-

- 30-

- 30-

5 2-A

53-B

53-B

53-B

53-B

54-A

54-A

54-A

NAMCO EA780

ASCO X206-381-3RF

ASCO HV202303-IF

NANCO EA1 80

NAMCO EA78050001,

EA7 8050000

ASCO X206-381-3RF

ASCO HTX8316E3-5E

NAMCO EA74050100

EEB81 30

MEB-8115

MEB-8115

EEB001 8

EEB0059

EEB00 54

EEB0063

EEB00 54

MEB-8115

MEB-30-01 27

MEB-30-01 27- 30- 54-A NANCO EA74050100

- 30- 56-A

- 30- 56-A

ASCO X206-381-3RF

ASCO HV202303-1F

EEB00 47

MEB-8115

I zs - 30- 56-A NAMCO EA74050000

DEOS:TBL1II.DF

E 5/4

E 5/3

M4 5/0101

M4 5/0101

E 4/10

EEB001 8

37 kfif T VE

E 4/1

. I C . WT

O WBN -TAtLE- 1.1

SUMRMARYý OF ELECTRICAL EQUTITPMENT. QULFCTINLA

Unit, TVA, ID Np Manufacturer modl No- -ttsNCR. No. EQS NoTbeReeec

2 zs - 30- 56-A NAMCO EA780, IV EEB8130 EEB0059 E 4/31 FSV - 30- 57-B ASCO X206-381-3RF' I EEB0054 E 5/3

2 FSV - 30- 57-B ASCO H1V202303-IF IV MEB-8115

I zs - 30- 57-B EAIB I0 EEB0063 E 5/4

2 ZS - 30- 57-B EA78050000, IV MEB-8115EA7 8050001

1 FSV - 30- 58-B ASCO X206-381-3RF I EEB0047 E 4/10

2 FSV - 30- 58-B ASCO HV202303-IF IV NEB-8115

I ZS - 30- 58-B NAMCO EA740 I EEB0059 E 4/10

2 zs - 30- 58-B NAMCO EA780 IV EEB8130 EEB0059 E 4/4

1 FSV - 30- 59-A ASCO X206-381-3RF I EEB0054 E 5/3

2 FSV - 30- 59-A ASCO 11V202303-IF IV MEB-8115

I ZS - 30- 59-A NAMCO EA180 EEB0063 E 5/4

2 zs - 30- 59-A NAMCO EA78050000, IV MEB-8115

.A7 80 50001I FSV - 30- 60 ASCO H1T8320AI08 IV MEB-8115 MEB-30-0001 M 7/0001

DE05:TBL11 .DF 38VE

S WBN., TABLE 1.4

SUMMARY, OF- ELECTRICAL, 9QUJPMENT- QUVALIFICATION, STI

Unit TVA, ID N2 Manufacturer Mpd N p . - Stgtus . , CR, No.90. No,Tal Rerec

1 zs - 30- 60

FCV(LS)

FCV(LS)

FSV

FSV

FCV(US)

FCVULS)

FSV

FSV

FSV

- 30-

- 30-

- 30-

- 30-

- 30-

- 30-

- 30-

- 30-

- 30-

NAMCO EA180

NAMCO#EA74050100

NAMCO#EA74050100

AS COHTX8316E35E

AS CO11TX8316E35E

NAMCO#EA74050100

NAMCO#EA74050100

AS COHTX8316E35E

AS COHTX8316E35E

ASCOHT8320A108

DEO5:TBL11 .DF

MEBO30011

MEB-30-0118

MEB-30-0119

MEB-30-01189

MEB-30-0118

MEB-8115

MEB-8115

MEB-8115 MEB-30-0119

MEB-8115

MEB-8115 MEB-30-0001

EFFrECTIVEDATE

GLCTT

E 7/4

M 7/0101

M 7/0101

M 7/0102

M 7/0101

M 7/0101

M 7/0102

M 7/0001

LTU

.. Table Reference

EEB0067

0WBN, TABLE I,

SUMMRY O ELETRI~l..EATIPMRN. OIAT.TVTr TTA1J. rA1rT.

TVA ID, No.

ZS - 30-- 69

FCO - 30- 109ULS)

FSV -

FSV -

FSV -

FSV -

FSV -

MTR -

Fan MtrA-A

FS -

HTR -

TS -

TS -

TS -

30-

30-

30-

30-

30-

30-

30-

30-

30-

30-

30-

109

134-B

134-B

13 5-A

13 5-A

146A

147

147-A

1 47A

147B

147 D

Manufacturer/Model No

NAMCO EA180

RB Denison #C4 JK05

MIA.' 110,

I

IV

ASCO HT8320A185

Target Rock 77J-001

Target Rock 77J-001

Target Rock 77J-001

Target Rock 77J-001

Reliance #1YF88236 5A2YC

Not Installed

Chromalox TRI-7648

Not Installed

Not Installed

Not Installed

1

2

EEB0067

MEB-30-0004

MEB-30-0005

EEB000 1

EEB0001

EEBOOO1

EEBOOO1

MEB-30-001 7

MEB-30--0006

E 7/4

M 6/0002

M 6/0003

E 4/2

E 4/2

E 5/1

E 5/1

M 7/0005

M 7/0002

rEF F E C T IV E40 G DATEDEO5:TBL1II.DF

vpit

MEB-8115

MEB-8115

MEB-8115

SUMMAAY OF ELECTRTCAT.- EnUIPNM-NT-

0OWBN- TABLE 1. 1

MURT. GUK FEETRICAL -EQUIPMENT'. QUALIFLCATIION. STATUS

Vnit. 1 TVA-. IDý No, M{auufacturer/Npdel. No, Status . ,.-IINCFR- No,EOS No. Table Refe erprt

2 FS - 30- 156

HTR -

TS -

TS -

TS -

FSV -

FSV -

HTrR -

Fan MtrB- B

MTR -

lITR -

TS -

TS -

*30-

*30-

*30-

30-

30-

30-

30-

30-

30-

30-

30-

1 56-B

1 56A

156 B

1 56D

1 57A

157B

157 B

190

191

192

193

I FE - 30- 194

Not Installed

Chromalox TRI-7648

Not Installed

Not Installed

Not Installed

ASCO HT8320A185

ASCO HT8320A185

Reliance #1YF882365A2YC

Baldor #M2334T

Baldor #M2334T

Honeywell T675A

Honeywell T675A

MEB-8115 MEB-3 0-0006 M 7/0002

MEB-8115

MEB- 8115

MEB-30-001 8

MEB-8115

MEB-8115

EEB8315

EEB8315

FCI FR-72-4

MEB-30-0013

MEB-30-0013

EEB00 85

EEB00 85

EEBOO1 5

M 7/0005

M 7/0004

M 7/0004

E 6/5, 8/11

E 6/5, 8/11

E 7/3, 8/1

DEO5:TBLII .DF 41

EFFECTIVE.ýD AT

0 JCT 1984

EOS No. -

WB3N TA13LE, 1,

SUM*"Y. OF-EU.CTRICAL. FQUIPKENT. QUALIFICATION. STATU-S

unit TV ID -o J

4 nf~ue/.oe~ ttsNR o Q o ableReference2 FS - 30- 194 Dwyer 1627-1 IV EEB8152 EEB0015 E 7/3, 8/61 TS - 30- 194 SOR 2O1TA-B125-JJTTX6 I EEB0033 E 7/4, 8/92 TS - 30- 194 Honeywell T675 IV EEB8141 EEB0033 E 7/4, 8/91 FE - 30- 195 FCI FR-72-4 I EEB0015 E 7/3, 8/12 FS - 30- 195 Dw~yer 1627-1 IV EEB8152 EEB0015 E 7/3, 8/61 TS - 30- 195 SOR 2O1TA-B125-JJTTX6 I EEB0033 E 7/4, 8/92 TS - 30- 195 Honeywell T675 IV EEB8141 EEB0033 E 7/4, 8/91 FE - 30- 196 FCI FR-72-4 I EEB0080 E 7/3, 8/122 FE - 30- 196 Dwyer 1627-1 IV EEB8143 EEB0080 E 7/3, 8/11I TS - 30- 196 SOR 2O1TA-B125-JJTTX6 I EEB0033 E 7/5, 8/92 TS - 30- 196 Honeywell T675 IV EEB8141 EEB0033 E 7/5, 8/91 FE - 30- 197 FCI FR-72-4 I EEB0080 E 7/3, 8/122 FE - 30- 197 Dwyer 1627-1 IV EEB8143 EEB0080 E 7/3, 8/111 TS - 30- 197 SOR 2O1TA-B125-JJTTX6 I EEB0033 E 7/5, 8/92 TS - 30- 197 Honeywell T675 IV EEB8141 EEB0033 E 7/5, 8/9

DEO5:TBL1I .DF F F

WAN TABLE. 1,4

SUVMMALRY OF-FLECTRICA EWU IPMNT,. QUALIF ICAT IOR. STATUS

Unit TVA ID Nn~.Un t VA IDNn1,- I. t -& Ey L -, I tau ý. D I G .No? .. . JQS No.-... TableReference,

I TS

I PT

1 PT

1 FCV(LS)

2 FCV(US)

1 FSV

2 FSV

1 FCV(US)

2 FCV(US)

1 FSV

2 FSV

1 FCVULS)

- 30- 214-S

- 30- 310-A

- 30- 311-A

- 31- 305-B

- 31- 305-B

- 31-

- 31-

- 31-

305-B

305-B

306-A

- 31- 306-A

- 31- 306-A

- 31- 306-A

- 31- 308-A

Fenwal 18003-7

Westinghouse 32PAI

Westinghouse 32PAI

NAMCO EA170

NAMCO EA170

ASCO 206-381-2F

ASCO 206-381-2F

NAMCO EA740

NANCO EA170

ASCO X206-381-3RF

AS COWPXHV2O2-300-2F

NAMCO EA740

DEO5:TBL11 .DF 43 FFC V ELA T

...............

EEB841 7

8/11

5/4

5/4

5/3

E 5/3

EEB007 9

EEB00 90

EEBO0090

EEB00 58

EEB0058

EEB0065

EEB0065

EEB0 006

EEB0006

EEB001 9

EEB001 9

EEB0006

5/2

5/2

4/10

EEB8167

EEB8135

E 4/8

4/11

4/2

E 4/10

. I Ma "f. f- -- / A . ?i .

40WBN- 74APLE', 1.4

$LJNMAY-. OF" gLCTRICAL, QUTI [T. QUALIFICATION. STATUS

Unit TVA ID No. Mannf~rtuirg~r/Mn~ic~ 1 ~J,,2ý - , . ýt-a~u . .. mu , ot..,I S. * Lv . INo, -, i,ý. a-jUe Keference

2 FCV - 31- 308-A NAMCO EA170(LS)

1 FSV

2 FSV

I FCVULS)

2 FCV(US)

1 FSV

2 FSV

1 FCV(LS)

2 FCVULS)

I FSV

2 FSV

I FCVULS)

- 31-

- 31-

- 31-

308-A

308-A

309-B

- 31- 309-B

- 31-

- 31-

- 31-

309-B

309-B

326-A

- 31- 326-A

- 31- 326-A

- 31- 326-A

- 31- 327-B

ASCO 206-381-2F

ASCO 208-381-2F

NAMCO EA170

NANCO EA170

ASCO 206-381-2F

ASCO 206-381-2F

NAMCO EA170

NAMCO EA170

ASCO 206-381-2F

ASCO 206-381-2F

NAMCO EA740

DEO5:TBL11 .DF 44

EEB816 7

N/A

N/A

EEB 8417

E 4/8

E 5/3

EEB0006

EEB0065

EEB0065

EEB0058

EEB00 58

EEB0065

EEB006 5

EEB00 58

EEB00 58

EEB0065

EEB0065

EEB00 93

5/3

5/3

5/3EEB8417

N/A E 5/3

5/2

5/2

4/12

W.4N- TABLE, -11

U$uM&Y-. 0F, ELECTRICAL EQUIPMENT ULFCT-NSAU

Unit -TVA, ID. No. Manuf acturer/Mnde1l No, .Statu~s NCR- No,

2 FCV - 31- 327-BULS)

I FSV

2 FSV

1 FCVULS)

2 FCV(US)

I FSV

2 FSV

I FCV(US)

2 FCV(US)

1 FSV

2 FSV

1 FCVULS)

- 31- 327-B

- 31- 327-B

- 31- 329-B

- 31- 329-B

- 31-

- 31-

- 31-

329-B

329-B

330-A

NAMCO EA17011100

ASCO 206-381-3F

ASCO HV200-921-1RF

NAMCO EA740

NAMCQ EA170

ASCO 206-381-2F

ASCO 206-381-2F

NANCO EA170

- 31- 330-A NAMCO EA170

- 31-

- 31-

- 32-

330-A

330-A

80-A

ASCO 206-381-2F

ASCO 206-381-2F

NAMCO EA180

DEO 5: TBL11I .DF 45 F.....I L~

OCT 1984 ~

I

MEB-8115

EOS No~. Tnl,1 R faran

EEB8135

EEB8167

EEB841 7

4/8

4/3

4/10

E 4/8

4/8

4/3

5/3

EEB006 5

EEB001 9

EEB0006

EEB0006

EEB006 5

EEB0065

EEB00 58

EEB00 58

EEB0065

EEB006 5

EEB0051

E 5/3

EOS- Nn -

4

Table ReferenceI FSV - 32- 80A-A ASCO HV206-380-3RU

1 FSV -

2 FSV -

A-A

2 FSV -

B-A

2 FCV -

(US)

1 FSV -

A-B

1 FSV -

B- B

I FCV -

(LS)

2 FSV -

A-B

2 FSV -

B-B

2 FCV -

(LS)

DEO5:TBL11 .DF

32- 80B-A ASCO 206-380-2RU

32-

32-

32-

32-

32-

32-

32-

32-

32-

81

81

81 -A

102

102

102-B

103

103

103-B

ASCO 11V206-380-3RU

ASCO WPHT8262D22

NAMCO EA1 80

ASCO HV206-380-3RU

ASCO 206-380-2RU

NAMCO EAI180

ASCO HV206-380-3RU

ASCO WPHT8262D22

NANCO EA1 80

0 WDN TABLE 1.1

$2UMla~y, OM BECTfICAL. EQUIIPMENT- OUAIIFICATIQN- STATUS

U~ni.t . VA. I1) N9, Ma ufacturer/Mp1no , 'ttu NC"p 0 p

EEB006 5

EEB0044

EEB006 5

EEB0044

EEB0051

EEB0065S

EEB0044

EEB0051

EEB006 5

EEB0044

EEB0051

EEB81 28

EEB81 28

E 5/2

E 5/1

E 5/2

E 5/1

E 5/2

E 5/2

E 5/1

E 5/1

E 5/2

E 5/1

E 5/1

- Table Refprencp

WBN. TABLE. 1, 1

SUMMARY OF' EBLICTRICAL EQUIPMENTOUALIFICATION STATUS

Unit -TVA. ID, No..

I FSV - 32- 110

A-A

1 FSV - 32- 110B-A

I FCV - 32- 110-(US)

2 FSV - 32- 111A- B

2 FSV - 32- 111B-B

2 FCV - 32- 111-ULS)

I FSV - 43- 2-

2 FSV - 43- 2-

1 FSV - 43- 3-

2 FSV - 43- 3-

I FSV - 43- 11-

2 FSV - 43- 11-

.. Manufacturer/Modpl NQ,

ASCO HV206-380-3RU

ASCO 206-380-2RU

A NAMCO EA180

ASCO HV206-3 80 -3RU

ASCO WPHT8262D22

B NANCO EA1 80

A

B

B

AS CO

AS CO

ASCO

AS CO

AS CO

AS CO

0 ~.

EEB8128

206-381-3RF

HV206 -381-3 RVF

206-381 -3RF

HV206-3 81 -3RF

206-381-3RVF

HV206 -381 -2RVF

.ES, No,

EEB006 5

EEB0044

EEB0051

EEB0065

EEB0044

EEBO0051

EEB0020

EEB0020

EEB0065

EEB003 9

EEB0020

EEB0020

DEO5:TBLII .DF

-------------------------------------------------------------------

I-~ I(Jf>i*

.*Table.Refezrence

E 5/2

E 5/1

E 5/1

E 5/2

E 5/1

E 5/1

W13N TABLE 1,4

SUMNAYý OF,, ELECpTRICAL, EQUIPMENT. QUALIFICATION STATUS

Unait: TVA~ ID No.Mauntip/ n~ . X*~------ ... -. "- - '. 4,4'. EV -41 . able Reference

1 FSV

2 FSV

1 FSV

2 FSV

I FSV

2 FSV

I FSV

2 FSV

I FSV

2 FSV

1 FSVD-B

2 FSVD-B

1 FSV

2 FSV

- 43-

- 43-

- 43-

- 43-

- 43-

- 43-

- 43-

- 43-

- 43-

- 43-

- 43-

I12-A

12-A

22-B

22-B

23-A

23-A

34-B

34-B

3 5-A

3 5-A

54

- 43- 54

- 43- 55-A

- 43- 55-A

AS CO

ASCO

ASCO

AS CO

ASCO

AS CO

AS CO

ASCO

ASCO

ASCO

ASCO

206-381-3RF

HV206 -381 -3RF

NP8316 54E

HV206-381--3RVF

206-381-3RF

HV206-381-3RF

206-381-3RF

HV206 -381 -2RVF

HV2O6-381-3RF

HV206 -3 81-3RF

206-381-3RF

ASCO 206-381-3RF

AS CO

AS CO

NP8316 54E

HV206-381-3RF

DEO5TBL1 .DF48 V>:.E,

D AT I.

5/2

5/2

4/7

4/6

5/2

5/2

4/6

4/7

5/3

5/2

4/7

EEB0065

EEB003 9

EEB0020

EEB0020

EEB006 5

EEB003 9

EEB0020

EEBO0020

EEB0039

EEB0039

EEB006 5

EEB0065

EEB003 9

EEB003 9

E 4/7

E 5/3

E 5/3

DE05:TBL11.DF

WBN'. TAJILE,, -19

$UNMIRY, OF-E-LECTRIC", EQUIPMENT'. QUALFICATION., STATUSý

Unit .TVA~ ID No.----~~~~J~U I~' 41. 1ý I i 'ija u . Q -- ý - W - , -L - ,%LTable, Reference

1 FSV - 43- 56D-B

2 FSVD-B

1 FSV

2 FSV

I FSVD-B

2 FSVD-B

I FSV

2 FSV

I FSVD-B

2 FSVD-B

I FSV

- 43-

- 43-

- 43-

- 43-

- 43-

- 43-

- 43-

- 43-

- 43-

56

5 8-A

5 8-A

59

59

61-A

61-A

63

63

ASCO 206-381-3RF

ASCO 206-381-3RF

ASCO NP831654E

ASCO HV206-381-3RF

ASCO 206-381-3RF

ASCO 206-381-3RF

ASCO NP831654E

ASCO HV206-381-3RF

ASCO 206-381-3RF

ASCO 206-381-3RF

.EEBOO39

EEB0039

EEB003 9

EEB003 9

EEB0039

EEB003 9

EEB0039

EEB003 9

EEB003 9

EEB003 9

EEB003 9- 43- 64-A ASCO NP831654E

2 FSV - 43- 64-A ASC HV206-381-3RF

DEO5:TBL~l1.DF

EEB003 9

49 ~~TVi Ed

E 4/8

E 4/8

E 5/3

E 5/3

E 4/8

E 4/8

E 5/3

E 5/3

E 4/8

E 4/8

E 5/3

E 5/3

0SUJMMARY-. OF. ELECTRICAL, 9()IPMgNT- -QUALIF ICAT ION. STATUS

Unit '-TVAL ID No.Manufacturer/Mnds1 M,--,-,- .- ... "'ti %, V A_____ .TIi noeterence,.,M('Dbl Reeec

1 FSV

2 FSV

I FSV

2 FSV

1 H2AN

2 H2AN

1 FSV

2 FSV

I FSV

2 FSV

1 FSV

2 FSV

1 FSV

2 FSV

- 43- 75-B ASCO NP831654E

- 43- 75-B ASCO 206-381-3RF

- 43- 77-A ASCO NP831654E

- 43- 77-A ASCO HV206-381-3Rr

- 43- 200 Comsip K-IIIM

- 43- 200 Comsip K-hIIM

- 43- 201-A ASCO 206-381-3RF

- 43- 201-A ASCO 206-381-3RVF

- 43- 202-A ASCO 206-381-3RF

- 43- 202-A ASCO 206-381-3RVF

- 43- 207-B ASCO 206-381-3Rp

- 43- 207-B ASCO 206-381-3RVF

- 43- 208-B ASCO 206-381-3RF

- 43- 208-B ASCO 206-381-3RVF

50 ' -

rF K C T IVE

SWBN. TABLE-, 1.1

EEB0020

EEB0020

EEB0039

EEB0039

EEB0026

EEB0026

EEB0020

EEB0020

EEB0020

EEB0020

EEB0020

EEB0020

EEB0020

EEB0020

4/7

4/7

5/2

5/2

5/1

5/1

4/6

4/6

4/6

4/6

4/6

4/12

4/6

E 4/12

DE05:TBLII.DF

WBN TABLE 1.1

SUMMARY OF ELECTRICAL EQUIPMENT-QUALIFICATION STATUS

Unit TVA ID No. Manufacture~r/Model No. Status NCR No. EQS No. Table Reference1 H2AN - 43- 210B Comsip K-IIIM I EEB0026 E 5/12 H2AN - 43- 210B Comsip K-IIIM I EEB0026 E 5/11 FSV - 43- 250 Target Rock 82KK-001 I EEBOOO1 E 5/31 FSV - 43- 251 Target Rock 82KK-001 IEEBOOOI

E 4/91 FSV - 43- 268 Target Rock 82KK-004 IEEBOOOI E 5/31 FSV - 43- 287 Target Rock 82KK-002 IEEBOOO1

E 5/31 FSV - 43- 288 Target Rock 82KK-002 IEEB0001

E 4/91 FSV - 43- 307 Target Rock 82KK-002 IEEB0001

E 5/3I FSV - 43- 309 Target Rock 82KK-001 IEEBOOO1

E 5/31 FSV - 43- 310 Target Rock 82KK-001 IEEBOOO1

E 4/91 FSV - 43- 312 Target Rock 82KK-001 IEEBOOO1

E 5/31 FSV - 43- 318 Target Rock 82KK-002 IEEBOOO1

E 5/31 FSV - 43- 319 Target Rock 82KK-002 IEEBOOO1

E 4/91 FSV - 43- 325 Target Rock 82KK-002 IEEBOOOI

E 5/31 FSV - 43- 341 Target Rock 82KK-004 IEEBOOO1

E 5/31 FSV - 43- 342 Target Rock 82KK-004 IEEBOOO1 E 5/3

DE05:TBLI1 .DF r

W3N-. TABL]W I.1

SRUMAY, OF E ECTRIC T, -VSQ 1UVXIN ULFIAINSAU

Unit ... TVA, ID .o -Manufacturer/Mopde No SttsNC o QS- No, . Table -ReferenceI SW - 46- AC Nutherin International/

Model #4641/Transfer Switch

2 SW - 46- AC Nutherin International/Model #4641/Transfer Switch

I SW - 46- DC Nutherin International/Model #4641/Transfer Switch

2 SW - 46- DC Nutherm International/Model #4641/Transfer Switch

I STR - 46- 56A Nuthermi International/Model #4 6 42/Motor Starter

2 STR

I xs

2 XS

2 FCV(US)

2 FSV

1 FCVULS)

EEB-XS-2

EEB-XS-2

EEB-XS-2

EEB-XS-2

EEB-STR-1

EEB-STR-1

EEB-XS-1

EEB-XS-1

- 46- 56A Nutherm International/

Model #4642/Motor Starter

- 46- 57 Electroswitch/Transfer Switch

- 46- 57 Electroswitch/Transfer Switch

- 61- 96 NAMCO EA 17014302,EA 17015302

- 61- 96 ASCO FTX831654

- 61- 97-B NAMCO EA180EEB0051

E 6/1011

E 6/1011

E 6/1011

E 6/1011

E 6/1012

E 6/1012

M 6/1009

M 6/1009

N 8/2

N 8/2

E 4/5

DEO5:TBLII .DF52

lsmN TBlE 1,

$V~MAI-Y- OF, ELECTRICAL, QWIFIMENT, QUALIFICATION. SATUS

Ui..TVA. ID No. .ManufActurpr/Mnd-I1 Nn

2 FCV - 61- 97-B NAMCO EA180ULS)

1 FSV

2 FSV

2 FCV(LS)

2 FSV

1 FCV(US)

2 FCV(LS)

I FSV

2 FSV

I FCVULS)

2 FCVULS)

1 FSV

- 61-

- 61-

- 61-

97-B

97-B

110

- 61- 110

- 61- 122-B

- 61- 122-B

- 61-

- 61-

- 61-

122-B

122-B

192-B

- 61- 192-B

- 61- 192-B

ASCO NP831654E

ASCO NP831654E

NAMCO EA170

ASCO FTX831654

NAMCO EA180

NANCO EA180

ASCO NP831654E

ASCO NP831654E

NANCO EA180

NAI4CO EA1 80

ASCO NP831654E

DEO:TBI1 DF53 V p

IP r~

ti1 at-,, Q wr~ m L, . X7 . .

E 4/5

4/8

4/8

8/2

EEB00 51

EEB0039

EEB0039

EEB0051

EEB0051

EEB003 9

EEB003 9

EEB00 51

EEB0051

EEB003 9

N 8/2

E 4/5

E 4/5

4/8

4/8

4/5

E 4/5

E 4/8

DE05:TBL11.DF

W53N, IADLE.1I,4

SU-MMARY' p(. SUCTRICAL, 9QUIPMET. QUALTFICATION. STV

Unit TVA. 11) No. Manyfacturer/ModlN, tts C oEQS. N~ Table Referenco

2 FSV

1 FCV(LS)

2 FCV(US)

1 FSV

2 FSV

I FCV

2 FCV

1 FCV

2 FCV

1 FCV(US)

2 FCVULS)

- 61- 192-B

- 61-

- 61-

- 61-

- 61-

- 62-

- 62-

- 62-

- 62-

- 62-

194-B

194-B

1 94-B

194-B

61

61

63

63

69

ASCO NP831654E

NAMCO EA180

NAMCO EA1 80

ASCO NP831654E

ASCO NP831654E

Reliance 713114-JZ,Limitorque SB-00

Reliance 713144-EZ,Limitorque SB-00

Reliance 710 741-JZLimitorque SB-00

Reliance 710 741-JZLimitorque SB-00

NANCO EA180

- 62- 69 NAMCO EA17031302

DEO 5: TBL11I .DF

EEB0039

EEB0051

EEB00 51

EEB003 9

EEB0039

NEB-XX-36

E 4/8

E 4/5

E 4/5

E 4/8

E 4/8

N 4/4

N 4/4

N 8/2

N 8/2

E 4/9

N 4/4

NEB-XX-3 7

EEB0068

NEB8118

. -Table Reference

TUS

W51N, TABLE 1, -

SUW4ARY' QU LCR~LBUP4~ QUALIFICATION. STATUS

Unit TVA, ID No. .. .= == 1- 3:-'- .*'-. - . ý V-~jvo 'v410 ., Ev? INO~ *' . .. TableR'eference

1 FSV

2 FSV

I FCV(LS)

2 FCV(LS)

1 FSV

2 FSV

1 FSV

2 FSV

1 FSV

2 FSV

I FSV

2 FSV

I FSV

2 FSV

- 62-

- 62-

- 62-

6 9-A

6 9-A

70

- 62- 70

- 62-

- 62-

- 62-

- 62-

- 62-

- 62-

- 62-

- 62-

- 62-

70O-A

70O-A

7 2-A

7 2-A

73-A

73-A

7 4-A

7 4-A

76

- 62- 76

ASCO NP831654E

ASCO NP831654V

NAMCO EA1 80

NAMCO EA17031302

AS CO

ASCO

AS CO

AS CO

AS CO

AS CO

AS CO

AS CO

AS CO

NP831654E

NP8316 54V

NP831654E

NP8316 54V

NP8316 54E

NP8316 54V

NP8316 54E

NP8316 54V

NP8316 54E

ASCO FT831654

DEO5:TBL11 .DF£ F F ~V EDATL

oCr '(

EEB002 8

EEB002 8

EEB006 8

4/2

4/10

4/9

NEB8118 N 4/4

EEB0020

EEB0020

EEB0028

EEB0028

EEB0028

EEB002 8

EEB0028

EEB0028

EEB001 9

4/7

4/11

4/7

4/10

4/7

4/10

4/7

4/10

4/10

NEB81 27

SU Y.OE -ELUIPVTCAIcA QUIflItENT, IALIJFICATION. STAU

'vJnjt T ID. NoI,* I -anIufacturer/de No st tyr,..

Table Reference1 FCV - 62- 77ULS)

2 FCV - 62- 77(US)

I FSV

2 FSV

1 FCV

2 FCV

I FCV

2 FCV

1 FCV

FCV

FCV

FCV

NAMCO EA17031302

NAMCO EA17031302

- 62- 77 ASCO FT831654

- 62- 77 ASCO FT831654

- 62- 90 Reliance 710-741-JZ

Limitorque SB-00

- 62- 90 Reliance 710 741-EZLimitorque SB-00

- 62- 91 Reliance 710 741-FZLimitorque SB-00

- 62- 91 Reliance 710 741-JZLimitorque SB-00

- 62- 98 Reliance 709551-LZLimitorque SMB-00

- 62-

- 62-

- 62-

Not installed

Limitorque SMB-00

Not installed

DEO5:TBL1II.DF

NEB-XX-1 1

NEB-XX-6NEB8I128

NEB81 28

NEB-XX-37

NEB-XX-3 7

NEB-XX-3 7

N 8/3

N 8/3

N 8/3

N 8/3

N 8/3

N 8/3

N 8/3

N 8/3

N 8/3

N 8/3

N 8/3

N 8/3

N EB-XX-3 7

56

1, ... I I NCR Nq , ., ý. ...S o - - - T-

W5n TýJý 11

SUMMARY. OY. BUCTRIMAI, FGUI.FMNT. OUaT..IICATION-, STATUS

UZI-iit...- TVA~ ID No.MAnuf a ct-i~rMn. m

I MTR - 62- 104

HTR

MIR

MTrR

LCV

LCV

L.CV

LCV

LCV

2 LCV

- 62-

- 62-

- 62-

- 62-

- 62-

- 62-

- 62-

- 62-

104

108

108

132

132

133

133

135

W,, HSDP Style-72F44917

K, HSDP Style-72F44917

ILL HSDP Style-72F44917

K, HSDF Style-7 2F44917

Reliance 710741-JZLimitorque SB-00

Reliance 710741-FZLimitorque SB-00

Reliance 710741-EZLixnitorque SB-00

Not installed

Reliance 710741-JZLimitorque SB-00

- 62- 135 Reliance 434050-JXLimitorque SB-00-10

DEO 5: TBL1 1 . DF 2.KiVETJ~ E98

NEB-XX-3 1

NEB-XX-3 1

NEB-XX-37

NEB-XX-37

N 7/3

N 7/3

N 7/3

N 7/3

N 8/3

N 8/3

N 8/3

N 8/3

N 8/4

N 8/4

NEB-XX-37

WjN,-ALE,1,-

SIJNMARy OF F?.T.FTR.TCAT~ .1~ATTMU w lT. . ~ 'A'~~T6TA.1

Unit TVA ID~ No..1U-U M2 F4WLQ, -4 . .1 tau .. IEE o, . .IIIIS.N ,,... Table Reference

1 LCV

2 LCV

I LT

2 LT

1 LT

2 LT

1 FCV

2 FCV

I FCV

2 FCV

1 FCV

2 FCV

DEO5:TBL11 .DFU~~~ E~iv

NEB-XX-3 7- 62- 136 Reliance 710741-JZ

Limitorque SB-00

- 62- 136 Reliance 710741-JZLimitorque SB-00

- 62- 238 ITT Barton #752

- 62- 238 ITT Barton #752

- 62- 242 ITT Barton #752

- 62- 242 ITT Barton #752

- 63- 1 Reliance #Y271278A1-CZLimitorque #SB-2

- 63- 1 Reliance #Y271266A3-EZ

Limitorque #SB-2

- 63- 3 Limitorque #SMB-OO

- 63- 3 Reliance #709551-LZLimitorque

- 63- 4 Limitorque #SMB-OO

- 63- 4 Reliance #709551-LZLimitorque #SHB-OO

N 8/4

N 8/4

NEB-6 2-26

NEB-6 2-26

N EB-XX-3 7

NEB-XX-3 7

NEB-XX-37

N 7/4

N 7/4

N 7/4

N 7/4

N 7/4

SU4MYOF 91L1NIRICAL, FQUI.MFNT'- QUALIFICATrIQN. STATU.S

Unit. TVA N, IPA t.i er/Mdgl w- tt~ C o ~ S o

1 FCV - 63- 5 Reliance #710741-JZLimitorque #SB-OO

2 FCV - 63- 5 Reliance #708420-HZLimitorque #SB-00

I FCV - 63- 6 Reliance #710741-JZLimitorque SB-00

2 FCV - 63- 6 Reliance #710741-EZLimitorque #SB-OO

1 FCV - 63- 7 Reliance #710741-JZLimitorque #SB-00

2 FCV - 63- 7 Reliance #710741-EZLimitorque #SB-00

L FCV - 63- 8 Reliance #710741-EZLimitorque #SB-OO

FCV - 63- 8 Reliance #710741-JZLimitorque #SB-00

1MTiR - 63- 10 Westinghouse #HSDPStyle-74FI2120

2 MTfR

NEB-XX-3 7

NEB-XX-3 7

NEB-XX-37

NEB-XX-37

N EB-XX-3 1

NEB-XX-31- 63- 10 Westinghouse #HSDP

Style-74F12120

Tab1~ Rpf~rc~n~~

N 7/4

N 7/4

N 7/4

N 7/4

N 7/4

N 7/4

N 7/4,

N 7/4,

N 7/8

N 7/8

DEO5:TBLlII.DF

. . TahIp R-f rance

S1~NW.OF SILCTRICaL SQUIPMEN1 2VALIJFICATIM. STAU

UWt TVA, ID-N. ~ atr/pj o Status .JC ý NQR. S No.v-

1 FCV - 63- 11

2 FCV

1 MTIR

2 MTR

1 FCV

2 FCV

I FCV(LS)

2 FCV

(US)

I FSV

2 FSV

I FCV

Reliance #710741-JZLimitorque #SB-00

- 63- 11 Reliance #710741-JZLimitorque #SB-00

- 63- 15 Westinghouse #HSDPStyle-74F12120

- 63- 15 Westinghouse #HSDPStyle-74F12120

- 63- 22 Reliance #710741-EZLimitorque #SBD-OO

- 63- 22 Reliance #708420-BYLimitorque #SBD-0O

- 63- 23 NAMCO EA170-302

- 63- 23 NANCO EA170-302

- 63- 23 ASCO #FT831654

- 63- 23 Not Installed

- 63- 25 Reliance #710741-EZLimitorque #SBD-OO

DEO5:TBLII .DF

NEB-XX-37

NEB-XX-31

NEB-XX-37

NEX-XX-11I

NEB8128

NEB81 28

NEB-XX-6

NEB-XX-37

[1K7 I V E

* 7.~14e Re f t~tn.

N 714, 8/5

N 7/5, 8/5

N 7/8

N 7/8

N 7/5

N 7/5

N 7/9

N 7/9

N 7/7

N 7/7

N 7/5, 8/5

S1J~~~Q4A1~~QVA O LC CA QUPNOU-IF ICAT Iff STATI!$

Unit TVA TI) NnUn t T A.T W . .. 1t trW... . NCR- No. .. .-. .1 FQ$-No,. ,-,.- Table-,Reference

2 FCV - 63- 25

1 FCV - 63- 26

2 FCV - 63- 26

I FCVULS)

2 FCV(US)

1 FSV

2 FSV

I FCV

2 FCV

I FCV

- 63- 38

- 63- 38

- 63-

- 63-

- 63-

- 63-

- 63-

2 FCV - 63- 40

Reliance #463501-EVLimitorque #SBD-O0

Reliance #710741-JZLimitorque #SBD-O0

Reliance #463501-FVLimitorque #SBD-00

Nainco EA170-302

Nanico EA170-302

ASCO #HT831654

ASCO #FT831654

Limitorque #SBD-0O

Limitorque #SBD-0O

Reliance #710741-EZLimitorque #SBD-O0

Reliance #710741-EZLimitorque #SBD-00

NEB-XX-3 7

NEB-XX-1 1

NEB8128

NEB8128

N 7/5, 8/6

N 7/5, 8/6

N 7/5, 8/6

N 7/9

N 7/9

NEB-XX-6

NEB-XX-3 7

NEB-XX-37

7/7

7/7

7/5,

7/5,

7/5,

8/6

8/6

8/6

N 7/5, 8/6

I--I V-

DEO5:TBL11 .DF

W~ TA~T~ 1.1

StJ~Q1~Y' OF EI~CTMVAL EQUIP~4EIIT QUAbIFICAT~ON STATUS

Unit TVA ID No. Q4- .,.4-.. !~1PD )j.~..Uni .- VA T- o .. .. ra: IXvt!ke1:u . . . 1%x 3,4'V# . RO ±-aDJe - K ej ence

1 FCVULS)

2 FCV(US)

1 FSV

2 FSV

1 FCV(LS)

2 FCVULS)

1 FSV

2 FSV

1 FCV

2 FCV

I FCV

- 63- 41 Namco EA170-302

- 63- 41

- 63-

- 63-

- 63-

Namco EA170-302

ASCO #I{T831654

ASCO #FT831654

Namco EA170-302

- 63- 42 Nainco EA170-302

- 63- 42 ASCO #HT831654

- 63- 42 ASCO #FT831654

- 63- 47 Reliance #710741-JZLimitorque #SB-OO

- 63- 47 Reliance #710741-EZLimitorque #SB-OO

- 63- 48 Reliance #710741-JZLimitorque #SB-OO

DEO5:TBL11 .DF

NEB-XX--11

NEB8128

NEB81 28

NEB-XX-6

N 719

N 7/9

N 7/7

N 7/7

N 7/9

N 7/9

NEB-XX-1 1

NEB8l182

NEB8128

NEB-XX-6

NEB-XX-37

NEB-XX-3 7

N 7/5

N 7/5

SU~4AR OF~~VRICT.~~QUP~N GUT.JIIQAT ION-. STATUS

VJ4i t. .- IVA' 11). No.,,~~'ufacturerTable. Ref. eJC. pr'tpj-

2 FCV

I FCV(LS)

2 FCV(US)

1 FSV

2 FSV

I FCVULS)

2 FCV(LS)

I FSV

2 FSV

I FCV

1 FCVULS)

- 63- 48 Reliance #710741-EZLimitorque #SB-00

- 63- 64 Namco EA170-302

- 63- 64 Nainco EA170-302

- 63-

- 63-

- 63-

ASCO #FT831654

ASCO #FT831654

NAMCO EA180

- 63- 71 NANCO EA180

- 63-

- 63-

- 63-

71-A

71-A

72

- 63- 72

ASCO NP831654E

ASCO NP831654V

Reliance #YF271271A2FZLimitorque #SB-3

NANCO EA1 80

DEO5:TBL11 .DFE F FE~ T IV E

0 C

NEB-XX-1 1

NEB8128

NEB8128

NEB-XX-6

N 7/5

N 7/9

N 7/9

N 7/7

N 7/7

E 4/4

E 4/4

EEB00 51

EEB0051

EEB0020

EEB0020

N EB-XX-3 8

4/2

4/2

8,6 9/11

EEB0061 E 6/3

Kapufacturerlj4odel No. ,

Uniit A. v f o. M1atr~/4~1 o tt~ . NR No. - IQS. No.Tahlpo Rpf ý ncerg~

2 FCV - 63- 72

FCV(US)

FCV

FCVULS)

FCV

FCV(LS)

FCV(US)

FCV(US)

FSV

FSV

FCV

- 63-

- 63-

- 63-

- 63-

- 63-

- 63-

- 63-

- 63-

- 63-

- 63-

Reliance #YF27I27lAIFZLimitorque #SB-3

NANCO EA170

Reliance #YF271265A2GZLimitorque #SB-3

NAMCO EA180

Reliance #YF271265A1GZLimitorque #SB-3

NAMCO EA170

NAMCO EA170-302

NAMCQ EA170-302

ASCO #FTX831654

ASCO #FTX831654

Reliance #X271266A1E2Limitorque SBD-2

DEO5:TBL1l .DF

EEB0058

N EB-XX-3 8

EEB006 1

EEBO0058

NEB-XX--11

NEB8128

NEB81 28

NEB-XX-6

NEB-XX-37

ra -,' 7-

N 8/6, 9/1

E 6/1

N 8/6, 9/1

E 6/3

N 8/6, 9/1

E 6/1

N 7/9

N 7/9

N 7/7

N 7/8

N 7/6

MtNRyW T. Q LY TRCA WIUIPMENT. OUAJJFIVATION.,SAU

Unit TVA Ti) N~Unit TVA, -T Nn .1.. .&,L f..1.. I. t l o.. . .I..IU 4i1W. RO. *' ... IFJ4N .. .Q , e e c

2 FCV - 63- 93 Reliance #Y271278A3GZLimitorque SBD-2

1 FCV - 63- 94

2 FCV - 63- 94

1 FCV - 63- 152

2 FCV - 63- 152

1 FCV - 63- 153

2 FCV

Reliance #Y271266A2EZLimitorque #SBD-2

Limitorque #SBD-2

Reliance #710741-JZ

Limitorque #SB-OO

Reliance #710741-JZLimitorque #SB-OO

Reliance #710741-JZLimitorque #SB-OO

NEB-XX-37

NEB-XX-3 7

NEB-XX-37

- 63- 153 Reliance #710741-jzLimitorque #SB-OO

1 FCV - 63- 156

2 FCV

Reliance #710741-EZLimitorque #SBD-OO

NEB-XX-37

- 63- 156 Reliance #710741-EZLimitorque #SBD-OO

1 FCV - 63- 157 Reliance Frame 215R2 TypedLimitorque SBD-00

N EB-XX-3 7

N 7/6, 8/6

N 716, 8/6

N 7/6

N 7/6

N 7/6

N 7/6

N 7/6

N 7/6

N 7/6

r E'DEO5:TBLII .DF

N 716

W& AL011

$VKK&-Ry.R OF. LCRCLSU1tTQA.FV IO TAU

iii, it TUA Tfl Nn urn. u..----------

2 FCV - 63- 157

1 FCV - 63- 172

2 FCV - 63- 172

1 FCV - 63- 175

2 FCV - 63- 175

1 FCV - 63- 177

2 FCV - 63- 177

- 63- 180

- 63- 180

- 63- 181

- 63- 181

Reliance #710741-JZLimitorque SBD-00

Reliance #Y266345A3KYLimitorque #SB-22

Reliance #Y266345A6KYLimitorque #SB-2

Reliance #709551-LZLimitorque #SMB-O0

Reliance #709551-HZLimitorque #SMB-00

Reliance #710740-EZLimitorque #SB-00

Reliance #710741-LZLimitorque #SB-OO

Barton 764 (Lot 7)

Not installed

Barton 764 (Lot 7)

Not installed

N 7/6

NEB-XX-3 7

NEB-XX-37

NEB-XX-3 7

N 7/6, 8/7

N 7/6, 8/7

N 7/6

N 7/7

N 7/7

N 7/7

NEB-XX-47 4/4

4/4

4/5NEB-XX-47

N 4/5

DEO5:TBL11 .DF

FEE F F- E CT IV EDt

xt ....... i EQ 0 ý , ý .... 21:aj:vloý _ . , '. , J!Y-E, " . *.'. . ý! *.'. LaRýe. EelerfPCe11 i V ý TVA- Tn V ,

~J4~liL

SU~A~Y 0~" ~UT~JCAT.. ~QUIP~NT QUALI~ICATION S~ATUS

Unit TVA ID No.

LT - 63- 182

LT - 63- 182

LT - 63- 183

LT - 63- 183

FCO - 65- 43(LS)

FSV - 65- 8

FSV - 65- 10

TS - 65- 16

HTR - 65- 17-A

MTIR - 65- 23-A

FSV - 65- 24

FS - 65- 25A/B, B/A

FSV - 65- 26

FSV - 65- 27

Barton 764 (Lot 7)

Not installed

Barton 764 (Lot 7)

Not installed

Snaplock #EA75020100

ASCO #HTX8300 B58F

ASCO 8321A2E

Chromalox #106-114426-003

Chromalox #196032951003

Reliance #1YF882366A2 YC

ASCO 8321A2E

FCI 12-64

ASCO #HV202300-1RF

ASCO #11V202300-IRF

DEO 5: TB I .DF

NEB-XX-47

NEB-63-28

MEB-8115

MEB-8115

MEB-8115

MEB-8115

MEB-8115

MEB-6 5-0159

MEB-6 5-0 163

MEB-6 5-0156

MEB-65-0009

MEB-6 5-00 10

MEB-6 5-0007

MEB-6 5-0156

EEB0030

M4EB-8115 MEB-65-0030

MEB-8115 MEB-65-0030

T I~ IVLE

L

4/5

4/5

4/5

4/5

7/ 0105

M 7/0104

*4 7/0104

* 7/0002

* 7/0002

* 7/0002

M 7/0105

E 7/1

7/ 0006

7/ 0006

Unit TVA- ID Nn -0 . . ý . r- r-): I 3-IL = 22 t - LI.Y f .......-2-Lskarp -" -,. .ý . I . W-W. 4140 f , .1, 1, .. I. . .. V-S61, P-0 " ý - 'ý .. .Table., R-r-f erypc e. . I M -nn f t-1, I I . I . . .

0

Unit TVA ID No Mg:f~,,rIMaAai. iJa ..... ,.Q..~.....,P- ~ ~ ~ ~ ~ ~ ~ ~ .r -1. . . =-= x:* im0 . . . A aW ~'. .,,' .. ," ýN ."T b e- e r ic

0 FSV - 65-

o FSV - 65-

2 FSV - 65-

1 FSV - 65-

0 FS - 65-A/B, B/A

o TS - 65-

HTR -

MTR -

FSV -

FS -

A/B, B/A

FSV -

FSV -

FSV -

65-

65-

65-

65-

65-

65-

65-

2 8A

28B

29

30

31

36

37-B

42-B

43

44

45

46

47A

ASCO #HTX8300BS8F

ASCO #HV202300-1RF

ASCO #HV202300-1RF

ASCO 8321A2E

FCI 12-64

Chroma lox#106-114426-003

Chromalox #196032951003

Reliance #1YF882366A1 YC

ASCO 8321A2E

FCI 12-64

ASCO #11V202300-1RF

ASCO #HV202300-1RF

ASCO #11TX8300B58F

0 FSV - 65- 47B ASCO #HTX8300B58F

DEO5:TBL11 .DF

MEB-8115

MEB-8115

MEB-8115

MEB-8115

MEB-8115

MEB-8115

MEB-8115

MEB-81 15

MEB-8115

MEB-6 5-0 163

MEB-6 5-0 163

MEB-6 5-0156

EEB0030

MEB-6 5-0009

MEB-.65-00 10

MEB-6 5-000 8

EEB00 93

EEB003 0

MEB-6 5-013 0

IV MEB-8115 MEB-65-0130

68 E FFE CT IVEDA T

Um"~4YQ', OF" T~.A BEQUI1'"IT' QUIF WATTON', STATU$

0

7/ 010 5

7/0105

7/ 0105

7/11

M 7/0002

7/ 0002

7/ 0002

E 7/1

M 7/0102

M 7/0102

SU~~M~~ F~.SLTRIAL QU1'~~TQUMJ-LFIVATIO lo.STATUS6

Unit. TVA. ID No,Mantfactuar r/mfw I N ... .. .. . ~Ini

2 FSV - 65- 50

1 FSV - 65- 51

1 FSV - 65- 52

1 FSV - 65- 53

0 FS - 65- 55A/B,B/A

PSV -

PSV -

PSV -

Psv -

FCV -

FCV -

FCV

FCV

65-

65-

65-

65-

67-

67-

81-A

81 -A

83-B

83-B

81

81

- 67- 82

- 67- 82

ASCO #HTX8300B58F

ASCO #HTX8300B58F

ASCO 8321A2E

ASCO 8321A2E

PCI 12-64

MEB-8115

MEB-8115

MEB-8115

MEB-8115

MEB-8115

MEB-8115

MEB-8115

MEB-8115

ASCO RT631655

ASCO 11T631655

ASCO 11T631655

ASCO HT631655

Limitorque #SMB-o0

Paramount #085 145 9-429Limitorque #SMB-00

Limitorque #SMB-00

Paramount #0851 459-46 0Limitorque #SM.B-00

MEB-65-0130

MEB-6 5-0156

MEB-6 5-0156

EEB003 0

MEB-6 5-0132

MEB-65-0132

MEB-67-0140

MEB-67-0140

DEO5:TBL11 .DF [EFF:ECTIVEOCT LKI;`04

7/ 0102

7/ 010 5

7/ 010 5

7/1

M 5/0102

M 5/0102

M 7/0102

M 7/0102

~le mtL. LL

8UMMKIA, Of, S~CRC~1,3 EOIPtIUM' I-uMIF-IeAT.If' -ST-ATUEi

Unit. TVA.

1 FCV

2 FCV

MEB-67-0136

MEB-67-0134

MEB-67-0136

- 67- 83-A Limitorque SMB-000

- 67- 83-A Reliance Type PLimitorque SMB-O000

- 67- 87-A Limitorque SMB-000

- 67- 87-A Reliance Type P

Limitorque SMB-000

- 67- 88-B Limitorque SMB-000

- 67- 88-B Reliance Type PLimitorque SMB-000

- 67- 91-A Limitorque SMB-000

- 67- 91-A Reliance Type PLimitorque SMB-O000

- 67- 95-A Limitorque SMB-000

- 67- 95-A Paramount Type WPLimitorque SMB-000

- 67- 96-B Limitorque SMB-000

- 67- 96-B Reliance Type PLimitorque SMB-000

MEB-67-0134

MEB-67-0136

DEO5:TBL1I .DF0 OC T i34

Ifl~ No..

MEB-67-0136

FCV

FCV

FCV

FCV

FCV

FCV

FCV

FCV

1 FCV

2 FCV

M 5/0102

M 4/0101

M 5/0102

M 5/0102

M 4/0101

M 5/0102

ID Nn'ý + I . I I Ma f 4- . I . I...... "ý ýý ýý ý& L 2e J:'LIQ 9 ý.'. OtAtU'p', . .. ., -. VIVR. No.. .. ', '.BQS,ý No-, -, -, -, -.,ý Ta-blg,. R-Pfy-rguýrgg

StH4M WY' OF, 'LUMTRIUA.L 90QUI1'NT, 0tJALFIATIORI. $TATUS

Unit, TVA. ID~ Nn.4. ;; . V v4U .. I aý.$ ' . tv .. e . .W ,-O9... . I% . ab le' Re fer,@n ,e.04...ý-"ý T-. *T1lf wt

1 FCV

2 FCV - 67- 112-A

- 67- 99-B

- 67- 99-B

- 67- 103-B

- 67- 103-B

- 67- 104-A

- 67- 104-A

- 67- 107-B

- 67- 107-B

- 67- 111-B

- 67- 111-B

- 67- 112-A

Limitorque SMB-000

Reliance Type PLimitorque SMB-000

Limitorque SMB-000

Reliance Type PLimitorque SMB-000

Limitorque SMB-000

Reliance Type PLimitorque SMB-000

Limitorque SMB-000

Reliance Type PLimitorque SMB-000

Limitorque SMB-000

Reliance Type PLimitorque SMB-O000

Limitorque SMB-000

Reliance Type PLimitorque SMB-000

DEO5:TBL11 .DFEi CT

DATEOCT

MEB-67-0136

MEB-67-0134

MEB-67-0136

MEB-67-0136

MEB-67-0134

MEB-67-0136

FCV

FCV

FCV

FCV

FCV

FCV

FCV

FCV

1 FCV

M 5/0102

M 4/0101

M 5/0102

M 5/0102

M 4/0101

M 5/0102

HUYLW.Y'._O LC1A FQLUlptgN , IV..Ar.CTnoW. qr.Af

Unit I VA I .D - .. Mauflcturerlmnpdl No., , S, tatvo, ,i , - NCR- No, -, - Q i FO'- 2e. Referonice1 FCV - 67- 123

2 FCV

1 FCV

2 FCV

I FCV

2 FCV

FCV

FCV

FCV

FCV

FCV

FCV

Limitorque #SMB-00MEB-67-0137

MEB-67-0139

-67- 123 Reliance #447021-RBLimitorque #SMB-000

-67- 124 Limitorque #SMB-000

-67- 124 Reliance #447021-RBLimitorque #SMB-000

- 67- 125 Limitorque #SMB-00

- 67- 125 Reliance #447021-RB

Limitorque SMB-000

- 67- 126 Limitorque #SM.B-000

- 67- 126 Reliance #447021-RBLimitorque #SMB-000

- 67- 127 Limitorque #SMB-00

- 67- 127 Reliance #447021-RBLimitorque #SMB-000

- 67- 128 Limitorque #SMB-00

- 67- 128 Limitorque #SMB-000

MEB-67-0137

MEB-67-0139

MEB-6 7-0137

MEB-67-0137

DEO5:TBLI1 .DF L ` kTi V/A T

M 6/0101

M 7/0102

M 6/0101

M 7/0102

M 6/0101

M 6/0101

StJIAWY,. -E I~T~CT QIVIPj4UNT QAFCTON.SAU

1Uni r TVA. Mf N~ Mnrnafnrt.ira'r/MnAnl. Nn ?JI'P. M,~M. f Qý M .'' .......__ __ _ __ _ ~ 4,L

I FCV

2 FCV

1 FCV

2 FCV

1 FCV

2 FCV

FCV

FCV

FCV

FCV

FCV

FCV

- 67- 130-A Limitorque #SM.B-000

- 67- 130-A Reliance Type P

Limitorque SMB-000

- 67- 131-B Limitorque #SMB-000

- 67- 131-B Reliance Type PLimitorque SMB-000

- 67- 133-A Limitorque #SMB-000

- 67- 133-A Reliance Type PLimitorque SMB-000

- 67- 134-B Limitorque #SMB-000

- 67- 134-B Reliance Type P

Limitorque SMB-000

- 67- 138-A Limitorque #SMB-000

- 67- 138-A Reliance Type P

Limitorque SMB-000

- 67- 139-A Limitorque #SMB-000

- 67- 139-A Reliance Type PLimitorque SMB-000

MEB-67-0136

MEB-67-0136

MEB-67-0136

MEB-67 -0136

MEB-67 -0136

MEB-6 7-0136

DEO5:TBLII .DF

M4 5/0102

M 5/0102

M 5/0102

M 5/0102

M 5/0102

M 5/0102

§1~1~XzF ~~CTICALEOUPMET' UALIFICATION, qTATT7Q

Unt .. . TVA, -ID No. Manufa~t,1T/Mn~d~1 N~-r =Z =. -1. "'p LN'I.4' -:-,. ., ,~V,1p le, R feryn

I FCV

2 FCV

MEB-67-0136

MEB-67-0136

- 67- 141-B Limitorque #SME-000

- 67- 141-B Reliance Type PLimitorque SMB-000

- 67- 142-A Limitorque #SMB-000

- 67- 142-A Reliance Type PLimitorque SMB-000

- 67- 146 Limitorque #SMB-00

- 67- 146 Reliance #723515-VCLimitorque #SMB-O0

- 67- 147 Limitorque #SMLB-0O

- 67- 147 Paramount #0851459-422Limitorque #SMB-00

- 67- 151-A Limitorque #SMB-00

- 67- 152-B Limitorque #SMB-0O

- 67- 168 ASCO 206-380-2RU

- 67- 168 ASCO HT8300B58RU

- 67- 170 ASCO 206-380-2RU

DEO5:TBL11 .DF

FCV

FCV

FCV

FCV

FCV

FCV

FCV

FCV

FSV

FSV

F SV

74 EFFECTIVE-V ATE

1. "'

EEB81 23

EEB81 23

MEB-67-0137

MEB-67-0137

MEB-67-0137

MEB-67-0137

EEB0029

EEB0029

EEB0029

M 5/0102

M4 5/0102

M4 6/0101

M4 6/0101

6/ 0101

6/ 0101

6/6, 8/14

6/2, 8/4

6/6, 8/14

$VMWY, OF 9UCTRICAL EQUIPMENT,

WB. N-, TA-13LE 1. -1

0

uni.t TV D No, a~ic e M1 A ~ 1 o. W-N EQ No. _______

2 FSV - 67- 170

- 67- 205

0 FCV - 67- 208

- 67-

- 67-

- 67-

- 67-

- 67- 295-A

- 67- 295-A

- 67- 296-A

- 67- 296-A

- 67- 297-B

0 FCVEEB81 23

EEB81 23

EEB81 23

ASCO HT830OB58RU

Reliance

Limitorque #SMB-O000

Reliance

Limitorque #SMB-000

ASCO HIB8300C58RU

ASCO HB8300C58RU

Limitorque #SMB-00

Paramount #0851 450-37 CLimitorque #SMB-00

Limitorque #5143-000

Reliance Type PLimitorque SMB3-000

Limitorque #5143-000

Reliance Type P

Limitorque SMB-000

Limitorque #SMB-000

EEB0029

MEB-67-0162

MEB-67-016 2

EEB0029

EEB002 9

MEB3-67-0137

MEB3-67-0135

MEB3-67-0135

MEB3-67-0135

E 612, 8/4

M4 6/0101

M4 6/0101

E 6/4, 8/8

E 6/4, 8/8

M4 6/0101

M4 4/0102

M4 4/0102

M4 4/0102

DEO5:TBL11 .DF 75

OCT

* WBN- TAlE%. 1., 1

SIRQ1Y. OF, BUXCI. tJTWIFN'r' QAI'CATIANSAU

MEB-8115

MEB3-8115

MEB-8115

MEB-8115

MEB3-8115

0

FSV

FSV

FCV

FCV

FCV

FCV

FCV

FCV

1 FCV

. 1N AL, ,-SLJMW4AY- OF. 9LCTRIC L -Q ?,Tr QUIFICA TINSAS

Unit. TVA. IDNo, N ctwu-er/Model- No, sat' Retferencqe

- 67- 297-B

- 67- 298-B

- 67- 298-B

2 FCV

1 FCV

2 FCV

2 FSV

2 FSV

1 FSV

2 FSV

I FSV

z FSV

* FSV

* FSV

FSV

FSV

FCV

336

338

350

350

352

352

354

354

356

356

458

Rlianctrqe Type00P

Limitorque #SMB-000

Reliance Type PLimitorque SMB-000

ASCO HB8300C58RU

ASCO HB8300C58RU

ASCO 206-380-2RU

ASCO HB8300C58RU

ASCO 206-380-2RU

ASCO HB8300C58RU

ASCO 206-380-2RU

ASCO HiB8300C58RU

ASCO 206-380.-2RU

ASCO HB8300C58RU

Limitorque #SMB-00

MEB- 8115

MEB-8115

MEB-8115

EEB81 46

EEB8146

EEB81 23

EEB81 23

EEB81 23

EEB8123

MEB-67-0135

EEB0048

EEB0048

EEB002 9

EEB0029

EEB0029

EEB0029

EEB0029

EEB0029

EEB002 9

EEB002 9

MEB-67-0137

M 4/0102

7/1

7/1

7/5, 8/13

7/1, 8/8

7/5, 8/13

7/1, 8/8

7/5, 8/14

7/2, 8/8

7/5, 8/14

7/2, 8/8

6/ 0101

76 v,

- 67-

- 67-

- 67-

- 67-

- 67-

- 67-

- 67-

- 67-

- 67-

- 67-

- 67-

DEO 5: TBLI I . DF

. WPR APL 1

STVA' ~ED~ Np, ~ No, NCR No,'

1 FCV - 67- 478

21

2

1

1

2

1

2

1

2

- 68-

- 68-

- 68-

- 68-

- 68-

- 68-

- 68-

- 68-

- 68-

- 68-

- 68-

- 68-

- 68-

- 68-

2A

2B

2A

2B

1 4A

1 4A

1 4B

1 4B

18

18

24

24

Limitorque #SMB-00

Rd F 21205

Rosemount 176KS

Rosemount 176KF

Rosemount 176KF

Rosemount 176KF

Not installed

Rosemount 176KF

Not installed

Rosemount 176KF

Not installed

Rd F 21205

Not installed

Rd F 21205

Not installed

NEB8123

NEB81 23

MEB-67-0137

NEB-6 8-23

NEB-6 8-24

NEB-6 8-24

NEB-6 8-24

NEB-6 8-24

NEB8123

NEB81 23

NEB81 23

NEB81 23

NEB-6 8-23

NEB-6 8-23

*Installed before fuel load

-- -- -- --DEO5:TBLI11.DF

EO No. 3 t4k

M 6/0101

N 4/8

N 4/8

N 4/8

N 4/8

N 4/8

N 4/8

N 4/8

N 4/8

N 4/8

N 4/8

N 4/8

N 4/8

N 4/8

N 4/8

. EOS- Noý.

al"TQF-Y.O. -LEC2TRICAL, -90UPKE' QIVAT..I JAT IO' S'rArWS,

Unit TVA Tfl Nr~ Mnn,.fort.,rorIMnAA M-~-,-. ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ I I.- ..~,4 ~ . ý T, ,y I4. ~ L pL

1 TE - 68- 25A

1 TE - 68- 25B

2 TE - 68- 25A

2 TE - 68- 25B

1 TE - 68- 37A

1 TE - 68- 37B

2 TE - 68- 37A

2 TE - 68- 37B

*I TE - 68- 41

2 TE - 68- 41

*I TE - 68- 43

2 TE - 68- 43

1 TE - 68- 44A

I TE - 68- 44B

2 TE - 68- 44A

Rosemount 176KF

Rosemount 176KF

Not installed

Not installed

Rosemount 176KF

Rosemount 176KF

Not installed

Not installed

Rd F 21205

Not installed

Rd F 21205

Not installed

Rosemount 176KF

Rosemount 176KF

Not installed

*Installed before fuel load

DE05:TBLI11.DF

NEB81 23 NEB-6 8-24

NEB-6 8-24

NEB-68-24

NEB-6 8-24

N 4/9

N 4/9

N 4/9

N 4/9

N 4/9

N 4/9

N 4/9

N 4/9

N 4/9

N 4/9

N 4/9

N 4/9

N 4/9

N 4/9

N 4/9

NEB8123

NEB81 23

NEB8123

NEB81 23

NEB-6 8-23

NEB-6 8-23

NEB-68-24

NEB-6 8-24

I ~0 WDTNJ- I4

SLThAJRY. ~. 4LCTRCd QWv~inx .QUIJ~CTpN. -A

I TE - 68- 44B Not installed

2

1

2

2

*1

2

2

1

TE

TE

TE

TE

TE

TE

TE

TE

PT

TE

TE

TE

TE

PT

*Installed before fuel load

DEO5:TBLI1 .DF

NEB-6 8-24

NEB-6 8-24

- 68-

- 68-

- 68-

- 68-

- 68-

- 68-

- 68-

- 68-

- 68-

- 68-

- 68-

- 68-

- 68-

- 68-

56A

56 B

56A

56 B

60

60

65

65

66

6 7A

67B

6 7A

67B

68

Rosemount 176KF

Rosemount 176KF

Not installed

Not installed

Rd F 21205

Not installed

Rd F 21205

Not installed

Not installed

Rosemount 176KF

Rosemount 176KF

Not installed

Not installed

Barton 763 (Lot 7)NEB-68-14

79

NEB8123

NEB81 23

NEB81 23

NEB81 23

NEB-6 8-23

NEB-6 8-23

NEB-6 8-43

NEB-6 8-24

N 4/10

N 4/10

N 4/10

N 4/10

N 4/10

N 4/10

N 4/10

N 4/10

N 4/10

N 4/10

N 4/10

N 4/10

N 4/10

N 4/7

w N, ABU- - ll

5UMM~A~y, OF' ELECTRICAL, EQUIPMENTOUALIF*TCA.TTnN *QTATTT~

*

~4anufacturer!Modp1. NA..'Vni~t - ý VA- I11) No,,-

2 PT - 68- 68

1 PT - 68- 69

2 PT - 68- 69

1 TE - 68- 79A

2 TE - 68- 79A

1 TE - 68- 79B

2 TE - 68- 79B

I TE - 68- 83

2 TE - 68- 83

1 FSV - 68- 305

2 FSV - 68- 305

1 FCV - 68- 305(LS)

2 FCV - 68- 305ULS)

Nob,-e~rxz

NEB-6 8-14

NEB-6 8-24

NEB-68-24

Not installed

Barton 763 (Lot 7)

Not installed

Rosemount 176KF

Not installed

Rosemount 176KF

Not installed

Rd F 21025

Not installed

No nameplate

Not installed

NANCO EA170-302

NANCO EA170-302

NEB-6 8-23

NEB-XX-6

NEB-XX-1 1

N 4/7

N 4/7

N 4/7

N 4/10

N 4/10

N 4/10

N 4/10

N 4/11

N 4/11

N 8/9

N 8/9

N 7/9

N 7/9

*Installed before fuel load

DEO5:TBLI11.DF'T VJF

NEB81 23

NEB81 23

fký- q ur r Mo I- No. .0Z Urn.

.. 11 1 c TAN. QT.A.'rTT.Q

* WBN TADLfW1,1

SUKWTR. OF'. IýCTRICAT.~ FQUI'PM-N-T- QUALIFICATIOMi MTVTU

Unit TVA ID Nn- Ynufacturer/MmipTa I.1 FSV

2 FSV

1 FCV(US)

2 FCV(US)

1 FSV

2 FSV

1 TE

2 TE

I LT

2 LT

1 PT

2 PT

1 PT

- 68-

- 68-

- 68-

307

307

308-B

- 68- 308-B

- 68-

- 68-

- 68-

- 68-

- 68-

- 68-

- 68-

- 68-

- 68-

308-B

308-B

319

319

320

320

322

322

323

2 PT - 68- 323

ASCO 206-381-3RF

ASCO #FT8320A19

NANCO EA180

NAMCO EA180

ASCO NP831654E

ASCO NP831654V

RDF 21232

Not installed

Barton 764 (Lot 7)

Barton 764 (Lot 7)

Barton 763 (Lot 2)

Not installed

Barton 763 (Lot 2)

Not intalled

DEO5:TBL11 .DF

81 L I '.

NEB-6 8-3

NEB81 28

EEB0051

EEB0051

EEB0020

EEB0020

NEB-6 8-44

N EB-XX-47

E 4/5

E 4/7

E 4/11

N 4/11

N 4/11

N 4/6

N 4/6

N 4/7

N 4/7

N 4/7

N 4/7

N EB-XX-49

N EB-XX-49

SUN RY ~ I~C uI aL E UW'M N QUI JPI C T IT 'U

V-Pit - VA-. TD. No. -Manufacturer1/4ode1 No

1 TE - 68- 324 RDF 21232

St a tu1S NCR, Nn- F~ ~_______________ -- x '9 Vi~ce

NEB-6 8-44

TE

FCV

FCV

FCV

FCV

PT

PT

XE

XE

XT

XT

PCV

LT

NEB-XX-36

NEB-XX-3 6

- 68- 324 Not installed

- 68- 332 Reliance Type PLimitorque SB-00

- 68- 332 Not Installed

- 68- 333 Reliance Type PLimitorque SB-00

- 68- 333 Limitorque SB-00

- 68- 334 Barton 763 (Lot 2)

- 68- 334 Barton 763 (Lot 2)

- 68- 334 ENDEVCO/2273A

- 68- 334 ENDEVCO/2273A

- 68- 334 TEC/504A

- 68- 334 TEC/504A

- 68- 334 Target Rock 82UJU-001

- 68- 335 Barton 764 (Lot 7)

EEB0074

EEB007 4

EEB0074

EEB0074

EEB0086

N EB-XX-47

N 4/11

N 4/11

N 415

N 4/5

N 4/5

N 4/7

N 4/7

E 419

E 4/9

E 4/9

E 4/9

E 4/12

N 4/6

DEO 5: TBL1 I . DF

NEB-XX-49

WBN- TO~LE, I.

SU1iARY. OF -&LlýCTR~ICAL. EU MENT raTALIIA'I SXA'rUs

I~it TVA, It), Np, ~ tr r/~pe

2 LT - 68- 335 Barton 764 (Lot 7)I

1 LT - 68- 339 Barton 764 (Lot 7)

2 LT - 68- 339 Barton 764 (Lot 7)I

1 PCV - 68- 340A Target Rock 82UU-001I

1 PT - 68- 340 ITT Barton 763 (Lot 2)I

2 PT - 68- 340 ITT Barton 763 (Lot 2)I

I XE - 68- 340A ENDEVCO/2273AI

2 XE - 68- 340A ENDEVCO/2273A I

I XT - 68- 340A TEC/504AI

2 XT - 68- 340A TEC/504AI

L XE - 68- 363 ENDEVCO/2273A

z XE - 68- 363 ENDEVCO/2273AI

XT - 68- 363 TEC/504AI

XT - 68- 363 TEC/504AI

XE - 68- 364 ENDEVCO/2273A T

NCR No. EOS No

NEB-XX-47

EEB00 86

NEB-XX-49

N/A

EEB007 4

EEB0074

EEB0074

EEB007 4

EEB007 4

EEB007 4

EEB0074

EEB007 4

EEB0074

DEO 5: TBL1 I . DF

4

N 4/6

N 4/6

N 4/6

E 4/12

N 4/8

N 4/8

E 4/9

E 4/9

E 4/9

E 4/9

E 4/9

E 4/9

E 4/9

E 4/9

E 4/10

NGR, No EOS N -

SUMNRY ~ SECTICA ~QWMET. UALIFICATION .STAT.US

Uui ~ TVA'ID No, ... '~ act e~ I ~ o~ e N p CR. o. QS. No.T4bJe, Reference2 XE - 68- 364

1 XT - 68- 364

2 XT - 68- 364

1 XE - 68- 365

2 XE - 68- 365

1 XT - 68- 365

2 XT - 68- 365

1 TE - 68- 373

2 TE - 68- 373

1 TE - 68- 376

2 TE - 68- 376

L TE - 68- 377

TE - 68- 377

TE - 68- 378

ENDEVC0/ 2273A

TEC/504A

TEC/504A

ENDEVCO/ 2273A

ENDEVCO/ 2273A

TEd! 504A

TEd! 504A

Minco S8809

Not installed

Minco S8810

Not installed

Minco S8809

Not installed

Minco S8809

2 TE - 68- 378 Not installed

DE05:TBL1II.DF 84

~. I VE

NIA

N/A

NIA

NIA

NIA

NIA

N/A

EEB0074

EEB0074

EEB00 74

EEB0074

EEB007 4

EEB007 4

EEB0074

NEB-6 8-33

E 4/10

E 4/10

E 4/10

E 4/10

E 4/10

E 4/10

E 4/10

N 4/11

N 4/11

N 4/11

N 4/11

N 4/11

N 4/11

N 4/12

N 4/12

NEB-6 8-33

NEB-68-33

NEB-68-33

WBN- TAIBLE, I,

SUNI~1A$Y. 0F ~LCRCLEU LI CATIOM STATUS

Unt VAIJ N. Manufaturer/Mnd.eI.No.Sau NCR, Np EQS, No. -- Table ReferenceI TE - 68- 379 Minco S8809

2 TE - 68- 379 Not installed

I TE - 68- 380 Hinco S8809

2 TE - 68- 380 Not installed

1 TE - 68- 383 Minco S8810

2 TE - 68- 383 Not installed

1 TE - 68- 384 Minco S8809

2 TE - 68- 384 Not installed

L. TE - 68- 385 Minco S8809

2 TE - 68- 385 Not installed

L TE - 68- 386 Minco S8809

TE - 68- 386 Not installed

* TE - 68- 393 Mincc 58809

* TE - 68- 393 Minco S8809

NEB-68-33

NEB-6 8-33

NEB-68-33

NEB-68-33

NEB-6 8-33

NEB-6 8-33

N 4/12

N 4/12

N 4/12

N 4/12

N 4/12

N 4/12

N 4/12

N 4/12

N 4/12

N 4/12

N 4/13

N 4/13

NEB-6 8-33

1 FSV - 68- 394 Target Rock 79AB-001

DE05:TBLII .DF 85

NEB-6 8-43

'TIE

N 4/5

0

Unit -TVA, ID No. .. Manuf acturer/ Model1. No.ý - Status- - NCR, No. -- EQS. No.. - Table Reference

2 FSV - 68- 394

FSV

FSV

FSV

FSV

FSV

FSV

FCV

FCV

FCV

FCV

FCV

FCV

FCV

- 68- 395

- 68- 395

- 68- 396

- 68- 396

- 68- 397

- 68- 397

- 70- 2

- 70- 2

- 70- 3

- 70- 3

- 70-

- 70-

- 70-

Not installed

Target Rock 79AB-001

Not installed

Target Rock 79AB-003

Not installed

Target Rock 79AB-003

Not installed

Limitorque #SMB-OQO

Reliance #447021-RB

Limitorque #SM2B-000

Limitorque #SMB-00

Reliance #447021-RBLimitorque #SMB-000

Limitorque #SME-000

Limitorque #SMB-000

Limitorque #SMB-000

NEB8316

NEB-6 8-43

NEB8316

NEB-6 8-43

NEB8316

NEB-6 8-43

NEB8316

MEB-7 0-0144

MEB-70-0144

MiEB-70-0144

MEB-70-0144

MEB-7 0-0144

DEO5:TBL1II.DF86

0WBN TABLE 1.1

SUMMAR-Y OF ELECTRICAL EQ-UIPMENT' QUALIFICATION STATUS

N 4/5

N 4/6

N 4/6

N 416

N 4/6

N 4/6

N 4/6

M 6/0102

M 6/0102

6/ 0102

6/ 0102

6/ 0102

J:

WBN- TABLE, 1. 1

SUMMAARY* OF ELECTRICAL EQUIPMENT QUALIFICATION STATUS

Unit TVA, ID No. nf~ac'turer~e.N.Sau C o Q o Table Reference0 FCV

1 FCV

2 FCV

2 FCV

2 FCV

2 FCV

MEB-7 0-0144

MEB-7 0-0141

- 70- 12 Limitorque #SMB-O00

- 70- 13 Limitorque #SMB-000

- 70- 14 Reliance #447021-RBLimitorque #SMB-000

- 70- 15 Reliance #447021-RBLimitorque #SMIB-000

- 70- 16 Reliance #447021-RBLimitorque #SMB-000

- 70- 18 Reliance #447021-SBLimitorque #SMiB-000

- 70- 22 Limitarque #SHB-000

- 70- 23 Limitorque #SHB-000

- 70- 23 Reliance #447021-RBLimitorque #SMB-00

- 70- 25 Limitorque #SMB-000

- 70- 26 Limitorque #SMB-OQO

- 70- 27 Limitorque #SME-000

DEO5:TBL11 .DF

F -IiI

K87

- ...~ ~ . -~ I

MEB-7 0-0 141

MEB-7 0-0141

MEB-7 0-0141

MEB-70-0141

MEB-7 0-0141

FCV

FCV

FCV

FCV

FCV

FCV

M 6/0102

M 7/0103

M 7/0103

M 7/0103

M 7/0103

M 7/0103

M 7/0103

WBN TABLE 1-.1I

SUMMARY Of- ELECTRICAL- EQUIPMENT QUALIFICATION STATUS

Unit -TVA. ID~ No-.Ma-----re-I-. -1 w .. ...'W. aLa.us, ý. A "qo............EyS' iNo. - Table Reference

2 FCV - 70- 28 Reliance #447021-RBLimitorque #SMB-000

2 FCV - 70- 29 Reliance #447021-RBLimitorque #SMB-000

0 HTR - 70- 33-B Westinghouse #HSW2,Style - 76F52145

1 FCV - 70- 34 Limitorque #SMB-00

0 MTR - 70- 38-B Westinghouse #HSW2,Style - 76F52145

2 FCV - 70- 39 Paramount #0852459-462Limitorque #SMB-00

0 MTR - 70- 46-A Westinghouse #HSW2,Style - 76F52145

0 MTR - 70- 51-S Westinghouse #HSW2,Style-76F52145

0 MTR - 70- 59-A Westinghouse #HSW2,Style - 76F52145

1 FCV - 70- 64 Limitorque #SMB-00

1 FCV - 70- 74

MEB-81 09

MEB-8109

MEB-8109

MEB-810 9

MEB-810 9

Limitorque #SHB-0O

MEB-7 2-020 4

MEB-7 0-0141

MEB-7 2-020 4

MEB-7 2-0204

MEB-7 2-020 4

MEB-7 2-020 4

MEB-7 0-0141

MEB-70-0141

DEO5:TBL11 .DF88

M 7/0201

7/ 0103

7/ 0201

M 7/0201

M 7/0201

M 7/0201

M 7/0103

M 7/0103

0W-BN' TABLE, 1.1

-SUMMARY OF' ELECTRICAL, EQUIPMENT QUAL-IFICAT ION, 'STATUS

Unit- TVA' ID No.,"aua.re'Mdl Nt,,w1.LI... e Rfeec

I FCV

2 FCV

2 FCV

2 FCV

I FCVULS)

2 FCVULS)

I FCV

2 FCV

1 FCV

- 70- 75 Limitorque #SMB-O000

- 70- 75 Reliance #447021-RBLimitorque #SMB-000

- 70- 76 Paramount #0851459-423Limitorque #SMB-0O

- 70- 78 Paramount #0851459-46ALimitorque #SMB-O0

- 70- 85 Masoneilan 496-2

- 70- 85 Masoneilan 496-2

- 70- 87-B Limitorque #SHB-00

- 70- 87-B Reliance #715047-ZB

Limitorque SMB-00

- 70- 89-B Limitorque #SMB-00

- 70- 89-B Reliance 720332-NFLimitorque SMB-000

- 70- 90 Limitorque #SMB-00

MEB-70-0148

EEB813 9

EEB813 9

EEB006 0

EEB006 0

MEB-7 0-0 142

M 6/0102

E 7/1, 8/10

E 7/1, 8/10

M 4/0102

MEB-811 5

MEB-7 0-0142 M 4/0102

MEB-8115

MEB-70-016 1 M 7/0103

DEO5:TBLI1 .DF89

... Manufacturer]-Model- No,

W-BN- TA-BLE- 1.1

SUMMARY OF ELECTRICAL EQUIPMENT QUALIFICATION STATUS

tinitý TVA- ID No,.,JLBUW 1NQAV No ......V fl . Table Referen-ce

2 FCV -70- 90 Reliance #720332-ZBLimitorque SMB-00

1 FCV -70- 92 Lixaitorque #SMB-O00

2 FCV -70- 92 Reliance #SM.B-000Limitorque #SMB-000

1 FCV - 70- 133 Lim~itorque #SMB-O000

2 FCV - 70- 133 Reliance #720332-ZBLimitorque #SHB-00

1 FCV - 70- 134 Limitorque #SMB-000

2 FCV - 70- 134 Reliance #720332-ZELimitorque #SMB-0O

1 FCV - 70- 140 Limitorque #5143-000

2 FCV - 70- 140 Reliance #720332-ZBLiinitorque #SMB-00

I FCV - 70- 143 Limitorque #SMB-000

2 FCV - 70- 143 Reliance #720332-ZBLimitorque #SMB-00

I FCV - 70- 153 Limitorque #SMB-000

FI -

iii.

DEO5:TBLI1 .DF

MEB3-70-0161

MEB-7 0-0 147

MEB-7 0-0 147

MEB3-70-0161

MEB-70-016 1

MEB-7 0-0141

14 7/0103

M 7/0104

14 7/0104

M 7/0104

14 7/0104

M 7/0103

I M-anufact-- Im-A I. w ....... .

0

Unit- , TVA. ID- No. -- Manufacturer/Mo-del- No.. -' Statu~s, NCR- No .... ES- No. -- -- Table ppiiL FCV

MEB-7 0-1041

MIEB-7 0-0144

- 70- 153 Reliance #447021-RBLimitorque #SMB-000

- 70- 156 Limitorque #SMB-OOO

- 70- 156 Reliance #447021-RBLimitorque #SHB-O00

- 70- 194 Limitorque #SHB-000

- 70- 195 Reliance #447021-RBLim~itorque #SMB-000

- 70- 196 Reliance #4 47021-RB

Limitorque #SMB-000

- 70- 197 Limitorque #SMB-000

- 70- 206 Limitorque #SMB-000

- 70- 207 Limitorque #SMB-000

- 70- 207 Reliance #720332-XCLimitorque #SMB-000

- 70- 208 Limitorque #SMB-000

- 72- 2 Reliance #710787-uZLimitorque #SB-0

DEO5:TBL1II.DF F.. '.~

U

BNTABLE 1.1

SUMMARY OF. ELECT.RIC.AL. EQUTIPMENT-QUAL-IFICA-TIO-N -STATUS

MEB-7 0-0144

MEB-7 0-0148

MEB-7 0-0144

MEB-7 0-0144

NEB-XX-3 7

FCV

FCV

FCV

FCV

2 FCV

0 FCV

0 FCV

1 FCV

2 FCV

FCV

L FCV

M 7/0103

M 6/0102

* 6/0102

* 6/0102

M 6/0102

M 6/0102

N 7/10

W'BN- TABLE, 1.1

SUAR FELTRClEQIPMENT QUALIFICATION- STATUS

Unit -T-VA- -ID No-., .M-anu-fact urer/,Model., No. - Status ..... NCR, No .... EQS, No,.-' ... Table. -Re'ference

FCV

HTR

MTR

FCV

FCV

FT

FT

MTR

MTR

FCV

F CV

- 72-. 2 Reliance #710787-JZ

- 72-

- 72-

- 72-

- 72-

- 72-

- 72-

- 72-

- 72-

- 72-

- 72-

I FT - 72- 34

2 FT - 72- 34

Limitorque #SB-0

Westinghouse IiSW2

Westinghouse HSW2

Liinitorque #SMB-000

Reliance #720329-XBLimitorque #SMB-000

Not installed

Not installed

Westinghouse HSW2

Westinghouse HSW2

Limitorque #SMB-000

Reliance #720329-XBLimitorque #SMB-OQO

Not installed

NEB-XX-3 1

MEB-72-0151

NEB-XX-3 1

MEB-.72-01 51

Not installed

I.'- . . . .

DEO5:TBLIl .DF 92

N 7/10

N 7/10

N 7/10

M 7/0104

N 7/10

N 7/10

M 7/0104

WBN TABLE, 1.1

SUMMARY OF EETIA QIMN ULFCTO.SAU

Unit- TVA. ID Nn-. Mauf-.,acturer/Model. NW-ttu C No. ESN.Tbe ReferenceI FCV - 72- 39 Reliance #710787-LZI

NEB-XX-37 N 7/10Limitorque #SB-02 FCV - 72- 39 Reliance #710787-Jz IN

7/10Limitorque #SB-O1 FCV - 72- 40 Reliance #710741-KZI

NEB-XX-37 N 7/10Limitorque #SB-O02 FCV - 72- 40 Reliance #408420-HZ IN

7/10Limitorque #SB-00

1 FCV - 72- 41 Reliance #710741-KZI NEB-XX-37 N 7/10Limitorque #SB-00

2 FCV - 72- 41 Reliance #710741-EZI N 7/10Limitorque #SB-00

I FCV - 72- 44 Reliance #447285-TB INEB-XX-38 N 9/1Limitorque #SB-0

2 FCV - 72- 44 Reliance #447285-TB IN 9/11Limitarque #SB-0

1 FCV - 72- 45 Reliance #447285-TB INEB-XX-38 N 9/1.Limitorque #SB-0

2 FCV - 72- 45 Reliance #447285-TB IN 9/1Limitorque #SB-0

DEO5:TBLII .DF 93 0 ATE

0W-BN- TABLE, 1.1

SUMMARY- OF ELECTRIC.A.L- EQUIPMENT, QUALIFICATION. STATUS

Un-it. TVA, ID~No.MafaueloelNoSatsNRNo TblReenc

.r %y - /4- J. Reliance Limitorque SB2

2 FCV - 74- 1 Reliance Limitorque SB2

1 FCV - 74- 2 Reliance Lim~itorque SB2

2 FCV - 74- 2 Reliance Limitorque SB2

1 FCV - 74- 3 Reliance #YF271270A2-FZLiinitorque #SB-2

2 FCV - 74- 3 Reliance #YF271264A2-GZLimitorque #SB-2

I FCV - 74- 8 Reliance Limitorque SEI

2 FCV - 74- 8 Reliance Limitorque SB1

1 FCV - 74- 9 Reliance Limitorque SB1

2 FCV - 74- 9 Reliance Limitorque SB1

1 MTR - 74- 10 Westinghouse Model VSW1Style 74F12184, Type LAC

2 MTR - 74- 10 Westinghouse Model VSW1Style 74F12184, Type LAC

1 FCV - 74- 12 Reliance #709551-LZLimitorque #SB-l

NEB-XX-3 6

NEB-XX-3 6

NEB-XX-3 7

NEB-XX-3 6

NEB-XX-3 6

NEB-XX-3 1

NEB841 3 NEB-XX-3 7

N 4/13

N 4/13

N 4/13

N 4/13

N 7/10

N 7/11

N 4/13

N 4/13

N 4/13

N 4/13

N 8/13

N 7/11

N 7/11

* ~ ! E -~DEO 5: TBLl I . DF

0WBN, TABLE, 1,.1

SUMMARY OF- ELEYCTRICAL, EQUIPMENT, QUALIFICATION, STATUS

Unit- TVA, ID~ No.... -Manufacturer/Model. No........ Status- NCR- No. II.EQS, No,.--. ..I....Table-Reference

2 FCV - 74- 12

TE

TE

MTR

2 T

1 FCV

2 FCV

1 FCV

2 FCV

- 74-

- 74-

Reliance #709551-LZLimitorque #SB-1

RDF 21232

Not installed

- 74- 20 Westinghouse Model VSW1Style 70F12184, Type LAC

- 74- 20 Westinghouse Model VSW1Style 74F12184, Type LAC

- 74- 21 Reliance #YF271270A1-FZLiniitorque #SB-2

- 74- 21 Reliance #YF271264-AI-GZLimitorque #SB-2

- 74- 24 Reliance #709551-LZLimitorque #SMB-00

- 74- 24 Reliance #709551-LZLimitorque #SMB-00

- 74- 25 RDF Corp. #21232

- 74- 25 Not installed

rDEO5:TBL11 .DF 95

NEB841 3

8/13

8/13

NEB-7 4-45

NEB-74-31

NEB-XX--37

N 7/11

N 6/2,

N 6/2,

N 7/11

N 7/11

N 7/11

N 7/111

N 7/11

N 7/11

N 6/2,

N 6/2,

NEB8413

NEB8413

NEB-XX-3 7

NEB-7 4-45

0WBN, TABLE- 1.1

Unit.. TVA. IT no....... Manufa-cturer Mode-l' No,. Status .. NCR, No.. ES, No. - 'Table -ReferenceI FCV - 74- 33 Reliance #71O741-RA

NEB-XX-37 N 7/11Limitorque #SB-00

2 FCV

1 FCV

2 FCV

1 FCV

2 FCV

I FCV(US)

2 FCVULS)

1 FSV

2 FSV

1 FSV

2 FSV

- 74- 33 Reliance #710741-RALimitorque #SB-00

- 74- 35 Reliance #710741-RALimitorque #SB-00

- 74- 35 Reliance #710741-RALimitorque #SB-0O

- 74- 40 Limitorque #SB-00

- 74- 40 Limitorque #SB-O0

- 77- 9-B NAMCO EA180

- 77- 9-B NAMCO EA180

- 77-

- 77-

- 77-

- 77-

9-B

9-B

10

10

ASCO NP831654E

ASCO NP831654V

ASCO IFT831654

Not installed

DEO5:TBLI11.DF 96

NEB-XX-3 7

NEB-XX-3 7

EEB0051

EEB0051

EEB003 9

EEB003 9

NEB-XX-6

N 7/11

N 7/11

N 7/11

N 7/11

N 7/11

E 4/5

E 4/5

4/2

4/2

7/12

7/12

NEB81 28

NEB8128

0W-BN, TA-BLE 1.1I

-SUMMARY OF- ELECTRICAL. EQUIPMENT QUALIFICATION- STATUS

Unit. -TVA, TD1 MNo. Manufa~cturer/ odel, No.. ' 'Status, KC-R No. ... E S, No.......Tabble Reference

1 FCV - 77- 16-B NANCO EA180ULS)

2 FCV(US)

I FSV

2 FSV

1 FSV

2 FSV

1 FCV(LS)

2 FCV(LS)

I FSV

2 FSV

I FCV

I FSV

2 FSV

- 77- 16-B NAMCO EA180

- 77-

- 77-

- 77-

- 77-

- 77-

16-B

16-B

17

17

18-B

ASCO NP831654E

ASCO NP831654V

ASCO #FTX831654

Not installed

NAMCO EA1 80

NEB81 28

NEB8128

- 77- 18-B NAMCO EA180

- 77-

- 77-

- 77-

- 77-

18-B

18-B

19

19

ASCO NP831654E

ASCO NP831654V

NAMCO EA170-302

ASCONEB81 28

NEB8128- 77- 19 Not installed

EEB0051

EEB0051

EEB0020

EEB0020

NEB-XX-6

NEB-XX-6

EEB0O051

EEB00 51

EEB0020

EEB0020

NEB-XX-1 1

NEB-XX-6

E 415

E 4/5

4/3

4/9

7/12

7/12

E4/4

E 4/3

E 4/3

E 4/93

N 7/13

N 7/12

DEO5:TBL~lI.DF 97

1i 03

WEBN TABLE, -~.I

SUMMARY OF ELECTRICAL EQUIPMENT QUALIFICATION -STATUS

Unit - TVA-I-D Nn'.Mau ac-- Im- "1. w .. aus 1V..,D.u 1,40. ....................Table-Reference

I FCV

1 FSV

2 FSV

I FCV(US)

2 FCV

(US)

I FSV

2 FSV

0 LT

o LT

0 MTR

0 MTR

o MTR

- 77- 20

- 77- 20

- 77- 20

- 77- 127-B

- 77- 127-B

NAMCO EA170-302

ASCO #FT831654

Not installed

NANCO EA740

NAMCO EA740

- 77- 127-B ASCO X206-381-3RF

- 77- 127-B ASCO WPXHV202-301-IF

- 77- 134 Rosemount 1153DB4

- 77- 135 Rosemnount 1153DB4

- 78- 9 Westinghouse Style-

77C12671, Model-TBDP

- 78- 12 Westinghouse Style-

73C74082, Model-TBDP

- 78- 35 Westinghouse ModelSty le-7 3C740 82/TBDP

DEO5:TBL11 .DFV

TK

NEB81 28

NEB81 28

7/13

7/12

7/12

4/1

E 4/1

EEB813 5

NEB-XX-1 1

NEB-XX-6

EEB001 8

EEB001 8

EEB001 9

EEB001 9

EEB0027

EEB0027

NEB-XX-13

NEB-XX-1 3

NEB-XX-1 3

4/12

4/4

7/4,

7/4,

8/14

8/13

8/13

N 8/14

N 8/14

WEBN TABLE 1.

SMARY OF ELECTRICAL EQUIPMENT QUAL-IFICA-TION. STATUS

Unit T'VA ID~ No.. Mnfcue/oe o ttsNC o Q o al eeec1 FCV - 81- 12 NAMCO EA170-302 I NEB-XX-11 N 7/13(LS)

2 FCVULS)

1 FSV

2 FSV

1 HTR

- 81- 12

-81-

-83-

NAMCO EA170-302

ASCO #FT831654

Not installed

Westinghouse/StortevortModel A

2 HTR - 83- 1 Westinghouse/StortevortModel A

I HTR - 83- 2 Westinghouse/Stortevort

Model A

2 1{TR - 83- 2 Westinghouse/Stortevort

Model A

I FSV - 87- 7-A ASCO NP831654E

2 FSV - 87- 7-A ASCO NP831654V

I FSV - 87- 8-A ASCO NP831654E

2 FSV - 87- 8-A ASCO NP831654V

DEO 5: TBL~l .DF99

NEB8128

NEB8128

NEB-XX-6

NEB-83-1

NEB-83-1

N 7/13

N 8/14

N 8/14

N 4/13

N 4/13

N 4/13

N 4/13

E 4/10

E 4/7

E 4/10

E 4/7

EEB0028

EEB0028

EEB002 8

EEB0028

0W-BN, TA-BLE- -. I

SUMMARY OF ELECTRICAL EQUIPMENTQUAL IF ICAT ION' -STATUS

Unit.. TVA, ID No..Manufacturer/Model No-zS o-T' e eeec

I FCV(US)

2 FCV(US)

1 FSV

2 FSV

1 FCVULS)

2 FCV(LS)

1 FSV

2 FSV

I FCVULS)

2 FCVULS)

I FSV

2 FSV

- 90- 107-A

- 90- 107-A

- 90- 107-A

- 90- 107-A

- 90- 108-B

- 90- 108-B

- 90-

- 90-

- 90-

108-B

108-B

109-B

NAMCO EA170

NAMCO EA170

ASCO X206-381-3RF

ASCO HTX8320A22V

NAMCO EA180

NAMCO EA180

ASCO X206-381-3RF

ASCO HTX8320A22V

NAMCO EA180

- 90- 109-B NANCO EA180

- 90- 109-B

- 90- 109-B

ASCO X206-381-3RF

ASCO HTX8320A22V

DEO5:TBLI11.DF OU'

EEB8417

EEB81 26

EEB00 58

EEB00 58

EEB0037

EEB0037

EEB0051

EEB00 51

EEB001 9

EEB001 9

EEB00 51

EEB00 51

EEB001 9

EEB0019

E 5/2

E 5/2

E 5/2

E 5/2

E 4/11

E 4/4

E 4/4

E 4/5

E 4/5

E 4/5

EEB8135

EEB8135

4/12

414

. MP.D,

0W-BN- TABLE- 1.1I

SUMR-Y, OF ELECTRICAL EQUIPMENT- QUALIFICATION -STATUS

Unit TVA ID- No., Manufac~turer/Mode.1. Noý..ýI. .I Statuls' NCR- No... ,.I. EqS- No. . . ITable Reference

(US)

2 FCV(LS)

1 FSV

2 FSV

I FCVULS)

2 FCVULS)

1 FSV

2 FSV

1 FCVULS)

2 FCVULS)

I FSV

- 90- 110-B NAMCO EA180

- 90- 110-B NA.MCO EA180

- 90- 110-B

- 90- 110-B

- 90- 111-A

ASCO X206-381-3Rp

ASCO HTX8320A22V

NAMCO EA170

EEB8135

EEB8417

- 90- 111-A NAMCO EA170

- 90-

- 90-

- 90-

111-A

111-A

113-A

- 90- 113-A

ASCO X206-381-3RF

ASCO HTX8320A22V

NAMCO EA17045302

NAJICO EA170

EEB81 26

EEB841 7

- 90- 113A ASCO X206-381-3RF

2 FSV - 90- 113A ASCO HTX8320A22VEEB81 26

EEB00 51

EEB00 51

EEBOO1 9

EEB001 9

EEB0058

EEB0058

EEB003 7

EEB003 7

EEB0058

EEB0058

EEB003 7

EEB0037

E 4/5

E 4/5

4/11

4/4

E 5/2

E 5/2

E 5/2

E 5/2

DEO5:TBL1I .DF 101

WBN- TABLE- 1'.1

SUMMARY. OF ELECTRICA . EQUIPMENT QUA-LIF-ICAT-ION -STATUS

Unit -T'VA- IDl No. __---Manufacturer-/Mode-l. No ..........Status. NCR- No.

1 FCV(LS)

2 FCV(LS)

I FSV

2 FSV

I FCVULS)

2 FCV(US)

1 FSV

2 FSV

I FCV(LS)

2 FCVULS)

1 FSV

2 FSV

- 90- 114-B NANCO EA180

- 90- 114-B NAMCO EA180

- 90-

- 90-

- 90-

114-B

114-B

115-B

- 90- 115-B

- 90-

- 90-

- 90-

115-B

11 5-B

116-B

ASCO X206-381-3RF

ASCO HTX8320A22V

NAMCO EA180

EEB8135

NANCO EA180

ASCO X206-381-3RF

ASCO HTX8320A22V

NAMCO EA1 80

- 90- 116-B NANCO EA180

- 90- 116-B ASCO X206-381-3RF

- 90- 116-B ASCO HTX8320A22V

EEB8135

EEB8135

No. Table Reference

EEB0051

EEB00 51

EEB001 9

EEBOO1 9

EEB0051

EEB0051

EEBOOI 9

EEB00l19

EEB0051

EEB0051

EEB001 9

EEBOO1 9

E 4/5

E 4/5

4/11

4/4

4/5

E 4/5

4/11

4/4

4/5

E 4/5

E 4/11

E 4/4

DEO 5: TBLI1 .DF 102:~. *r ~

. . . .-. . . I EQS- No-. - - ... I . . Table Reference

0WBN TABLE 1.1I

-SUMMNARY OY ELECTRICAL- EQUIPMENT QUALIFICATION. STATUS

Un-it- T-VA ID~ No ........ Manuf acturer/Model., No... ... Status .... NCR, No. I.... EQS- No .. .. Table. ReferenceI FCV

(US)

2 FCV

ULS)

I FSV

2 FSV

1 RE

2 RE

I RE

RE

RE

RE

RE

RE

- 90- 117-A NAMCO EA170EEB8417

- 90- 117-A NAMCO EA170

- 90- 117-A

- 90- 117-A

- 90- 271-A

- 90- 271-A

- 90- 272-B

- 90- 272-B

- 90- 273-A

- 90- 273-A

- 90- 274-B

- 90- 274-B

I WTE - 94- 1,2,3 ... 65

ASCO X206-381-3Rp

ASCO HTX8320A22V

General Atomic/RD-23

General Atomic/RD-23

General Atomic/RD-23

General Atoxnic/RD-23

General Atomic/RD-23

General Atomic/RD-23

General Atomic/RD-23

General Atomic/RD-23

Control Pro

EEB81 26

N/A

N/A

N/A

N/A

N/A

N/A

N/A

N/A

NEB841 0

EEB0058

EEB0058

EEB003 7

EEB003 7

EEB-RM-2

EEB-RM- 2

EEB-R}1-2

EEB-RM-2

EBB-RM- 2

EEB-RM-2

EEB-RM- 2

EBB-RM- 2

NEB-94-48

* .. ~. . .

'i'- r'DEO5:TBLI11.DF

E 5/2

B 5/2

B 5/2

B 5/2

E 4/1002

B 4/1002

E 4/1002

E 4/1002

B 4/1002

B 4/1002

B 4/1002

E 4/1002

N 4/14-21

W-BN TA-BLE 1.1I

SUMMA-RY OF ELECTRICA-L EQUIPMENT-QUALIFICATIONW STATUS

Unit .. TV-A ID No.- -, M-anuf acturer/ ModelI No.. Status -NCR- No. .. EQS, No-. - Table Reference

2 WTE - 94- 1,2, Control Pro ii NEB8410 N 4/14/213... .65

1 Cntmt Spray Pmp Baldor #M3710T IV MEB-8115 MEB-30-0011 M 7/0003Bin lA-A Cir Fan Mtr

1 Cntmt Spray Pmp Baldor #M3710T IV MEB-8115 MEB-30-0011 M 7/0003Bin lB-B Cir Fan Mtr

2 Cntmt Spray Pmp Baldor #M3710T IV MEB-8115Bin 2A-A Cir Fan Mtr

2 Cntmt Spray Pmp Baldor #143710T IV MEB-8115Bin 2B-B Cir Fan Mtr

EGTS Bin Cir Baldor #M3611T IV MEB-8115 MEB-30-0016 M 7/0005Fan A-A Mtr

EGTS Bin CirFan B-B Mtr Baldor #M3611T IV MEB-8115 MEB-30-0016 M 7/0005

1 RHR Pmp Bin lA-A Baldor #M3615T IV MEB-8115 MEB-30-0012 M 7/0003Cooler Fan Mtr

1 BIER Pmp Bin lB-B Baldor #M3615T IV MEB-8115 MEB-30-0012 M 7/0003Cooler Fan Mtr

2 BHR Pinp Bin 2A-A Baldor #M3615T IV MEB-8115Cooler Fan Mtr

DE05:TBL1II.DF 104 1H

WBN, TABLE- I.]I

Unit -TVA. IM No ... M-anuf a ct+-r---- N1 Sttu.CRN. EQ-S No,. -Tab le efre9_R~ erence-

Cooler Fan Mtr

1 SIS Pmp Rm CirFans lA-A Mtr

1 Pipe Chs Clr FansIBB Mtr

2 Pipe Chs Cir Fans2A-A Mtr

2 Pipe Clis Clr Fans2B-B Mtr

1 SIS Pmp Rm CirFans lA-A Mtr

1 SIS Pmp Rm CirFans lB-B Mtr

2 SIS Pmp Rm ClrFans 2A-A Mtr

2 SIS Pmp Rm CirFans 2B-B Mtr

I Pipe Chase CirFans lA-A Mtr

Baldor #H3615T

Baldor #H3615T

Baldor #M,3611T

Baldor #M3611T

Baldor #M3611T

Baldor #M3615T

Baldor #14.3615T

Baldor #143615T

Baldor #143615T

Baldor #M3611T

MEB-8115

MEB-8115

MEB-8115

MEB-8115

MEB-8115

MEB-8115

MEB-8115

MEB-8115

MEB-8115

MEB-8115

MEB-30-001 2

MEB-30-0016

MEB-30-001 2

MEB-30--001 2

MEB-30--0016

M 7/0003

* 7/0003

M4 7/0003

M 7/0003

M4 7/0004

DEO5:TBLII .DF

0W-BN- TABLE- 1,.1

SUMMARY Of- ELECTRICAL, EQUIPMENT,. QUAL-IFICAT ION, STATUS

Unit.. TVA, -II No Mua rr/oNo. oStusNRN. No No T....able' ReferenceCentCirs

Chg Pmp RmlA-A Fan Mtr

Cent Chg Pmp RinClrs lB-B Fan Mtr

Cent Chg Pmp RmClrs 2A-A Fan Mtr

Cent Chg Pmp RniClrs 2B-B Fan Mtr

AEW & BA Xfer PmpSpace Clrs A-A

AEW & BA Xfer PmpSpace Clrs B-B

EL 692 Pen kim ClrFan Mtr lA-A

EL 692 Pen Rm ClrFan Mtr lB-B

EL 692 Pen Rm ClrFan Mtr 2A-A

EL 692 Pen Rm CirFan Mtr 2B-B

Baldor #M3611T

Baldor #M3611T

Baldor #M3611T

Baldor #M3611T

Baldor #M2333T

Baldor #M2333T

Baldor #M3611T

Baldor #M3611T

Baldor #M3611T

Baldor #M3611T

MEB-8115

MEB-8115

MEB-8115

MEB-8115

MiEB-8115

MEB-8115

MEB-8115

MEB-8115

MEB-8115

MEB-8115

MEB-30--0016

MEB-30-0016

MEB-30-0016

MEB-30--0016

DEO5:TBLII .DF* '. .- . ~

* U..b.~J ~ I L~

OCT 1131

M 7/0004

* 7/0005

* 7/0004

* 7/0004

0

0WEN- TABLE- 1 .-1

SUMMARY Of- ELECTRICAL EQUIPMENT QUALIFICATION STATUS

Unit TVA, ID) No-. Manuf act urerIMod~ 1 Nn'-auatrrMdelN.. * - I.~ ~ . EL), Ime,, ,,. Table' iteference rDlu

I EL 713 Pent EniCirs lA-A Fan Mtr

1 EL 713 Pent EmClrs lB-B Fan Mtr

2 EL 713 Pent EmCirs 2A-A Fan Mtr

2 EL 713 Pent EmCirs 2B-B Fan Mtr

1 EL 737 Pent EmCirs IA-A Fan Mtr

I EL 737 Pent EmCirs lB-B Fan Mtr

2 EL 737 Pent EmCirs 2A-A Fan Mtr

2 EL 737 Pent EmCirs 2B-B Fan Mtr

CCS Booster &Spent Fuel Pit PmpCir Fan Mtr A-A

CCS Booster &Spent Fuel Pit PmpCir Fan Mtr B-B

DEO5:TBL11 .DF

Baldor #M3611T

Baldor #H3611T

Baldor #M3611T

Baldor #M3611T

Baldor #M3611T

Baldor #M3611T

Baldor #M3611T

Baldor #M3611T

Baldor #M3610T

MEB-8115

MEB-8115

MEB-8115

MEB-8115

MEB-8115

MEB-8115

MEB-8115

MEB-8115

MEB-811 5

MEB-8115Baldor #M3610T

MEB-30-0016

MEB-30-0016

MEB-30-0016

MEB-30-0016

MEB-30-001 5

* 7/0005

* 7/0005

* 7/0005

* 7/0005

* 7/0004

MEB-30-0015 M 7/0004

. MI'JD AT

I 0W-BN -TABLE, 1.1I

SUMMARY OF, ELECTR-ICAL NQ~ETQAIIAIN STAU

Unit -TVA. -ID No.. -- Manuf acturer/ ModelI No.- ---- Status .... NCR. No-- ... EQS- No ..... Table Reference

I Containment SprayPmps No Tag No.lA-A MTR

2 Containment SprayPmps No Tag No.lA-A MTR

1 Containment SprayPmps No Tag No.lB-B MTR

2 Containment SprayPmps No Tag No.IlB- B MTR

Westinghouse MDLHSW2 style

Westinghouse MDLHSW2 style

Westinghouse M4DLHSW2 style

Westinghouse MDLHSW2 style

Cable Call types) Various

Penetrations(all types)

Cable splices

Junction boxes

Terminal Blocks

Conax Modular type

Raychem type WCSF-N

N/A

General Electric typesCR, EB, and CR-151B

None

None

None

None

N one

EEB-CBL-1.0 See EQS Indexthru 19.0(8.4,10.0,11 .0,&14.0)

EEB-PEN--1 4/1000, 5/1000

EEB-SPL-1

EEB-JB-1

EEB-TB--1

See EQS Index

See EQS Index

See EQS Index

DEO5: TBL I. DF1 108k

k 4

UJ;31

NEB-XX-31

NEB-XX-31

NEB-XX-3 1

N 8/11

N 8/11

N 8/11

N 8/11NEB-XX-3 1

W-BN- TABLE- 1.1

SUMM4ARY- OF ELECTRICAL EQUIPMENT- QUALIFICATION. STATUS

Unit. TVA-ID~ No... . Manuf ac turer/ ModelI No.. ,.-., Status. .- NCR- No .. ... No.Handswitches Square D Class 9001, Type K I None EEB-HS-1

Units 1 & 2 Potter & Brumfield/ I None EEB-RLY-1BA & BB relays MDR series

Units 1 & 2 Potter & Brumfield/ I None EEB-RLY-1RI relay MDR series

Units I & 2 Potter & Brumfield/ INone EEB-RLY-1RAS relay MDR series

Units 1 & 2 Potter & Brumfield/ None EEB-RLY-lRBS relay MDR series

Units 1 & 2 Potter & Brumfield/ None EEB-RLY-1SST relay MDR series

Conduit Seal Conax/Type ECSA INone EEB-CSC-1Connectors

Flexible Conduit ServicAir/ SS63 INone EEB-CON-l(Stainless Steel)

DEO5:TBLlI .DF

Table Reference

See EQS Index

E 6/1010

E 6/1010

E 6/1010

E 6/1010

E 6/1010

4/1001 ,6/1000,7/1000

4/1001,5/1001,6/1000,7/1000

'S.,

WBN, TABLE 1.].

SUMMARY- OF ELECTRICAL EQUIPMENT QUALIFICATION- STATUS

Unit TVA ID .No..... Manufacturer/Model No.~ Status- NCR- No.-- EQS- No,. -Table- Ref erence

1 BD-242-1

I BD-242-2

0 DPL-234-Al-SIS

0 DPL-234-Bl/SIS

0 DPL-234-A2/SIS

0 DPL-234-B2/SIS

0 DPL-234-AI/CVC

o DPL-234-Bl/cCV

o DPL-234-A2/cCV

0 DPL-234-B2/cCV

0 DPL-234-A3/CVC

D DPL-234--B3/cCV

) DPL-234-A4/CVC

) DPL-234-B4/CVC

3BD-228-1

El-Tex Ind.

El-Tex Ind.

Thermon Mf g.

Thermon Hf g.

Thermon Hf g.

Thermon Hf g.

Thermon Hf g.

Thermon Hf g.

Thermon Mfg.

Thermon Hf g.

Thermon Mf g.

Thermon Mf g.

Thermon Mf g.

Thermon Mf g.

Arrow-Hart

Co.

Co.

Co.

Co.

Co.

Co.

Co.

Co.

Co.

Co.

Co.

Co.

Non-Class lE(See Note 1)Non-Class lE(See Note 1)Non-Class 1E(See Note 1)Non-Class 1E(See Note 1)Non-Class IE(See Note 1)Non-Class 1E(See Note 1)Non-Class 1E(See Note 1)Non-Class 1E(See Note 1)Non-Class 1E(See Note 1)Non-Class 1E(See Note 1)Non-Class lE(See Note 1)Non-Class lE(See Note 1)Non-Class 1E(See Note 1)Non-Class lB(See Note 1)Non-Class 1E(See Note 1)

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

DEO5:TBL11 .DF

EEB-BD-242

EEB-BD-242

EEB-PNL-l

EEB-PNL-1

EEB-PNL-1

EEB-PNL- 1

EEB-PNL- 1

EEB-PNL-1

EEB-PNL-1

EEB-PNL-1

EEB-PNL-l

EEB-PNL-1

EEB-PNL- 1

EEB-PNL-1

EEB-BD-l

6/1014

6/1014

7/ 1011

7/loll

7/ 1011

7/1011

7/ 1014

6/ 1014

6/ 1014

6/ 1014

6/ 1014

6/1-014

6/ 1014

6/ 1014

6/ 1013

WBN- TABELE- 1 *.1

S LMRY OF' E'LECTRICAL~ EQUIPMENT- _QUALIFICATION. STATUS

Unit, T'A, -ID No-. - Manuf acturer/ Mdel, No,. -Status ...... NCR- No ........... EQ- No,., Table' Reference

0 B 0-22-

o BD-228-3

0 BDC-228-4

o MCC-217-A

0 MCC-216-A

0 MCC-216-B

0 MCC-208--A

Arrow-Hart

Arrow-Hart

Arrow-Hart

I-T-E

I-T-E

I-T-E

I-T-E

I-T-E

Non-Class 1E(See Note 1)Non-Class IE(See Note 1)Non-Class IE(See Note 1)Non-Class IE(See Note 1)Non-Class IE(See Note 1)Non-Class 1E(See Note 1)Non-Class lE(See Note 1)Non-Class IE(See Note 1)

NOTE 1: A status cannot be placed on this equipment as this equipment was not required to be Hwvrprocured to any qualification requirements (e.g., IEEE 323-1971, 1974, NUREG-0588). andowever,TVA has evaluated this equipment and has determined that this equipment will operate ado ofail in any manner detrimental to plant safety. (See Section 2.6)

F -C D TIVE~

DEO5:TBLlII.DF

None

None

None

None

None

None

None

None

EEB-BD-2

EEB-BD-3

EEB-BD-4

EEB-MC-l

EEB-MC-2

EEB-MC-3

EEB-MC-4

EEB-MC-5

E 6/1013

E 6/1013

E 6/1013

E 6/1013

E 6/1013

E 6/1013

E 6/1013

E 6/1013

EFFCT IVE13.0 SERVICE CONDITIONS

Environmental conditions have been established for all areas containing

safety-related equipment exposed to a harsh environment. All DBEs

which could result in a harsh environment per 1OCFR5O.49 are enveloped

by the NUREG-0588 LOCA and HELB environmental conditions contained in

this section. Section 2.0 provides the analysis to support this

conclusion. Temperature, relative humidity, pressure, radiation dose,

area type, chemical spray, and flooding were the parameters considered

for the following operational conditions:

1. Normal conditions resulting from routine plant operation or shutdown

during a design basis day (maximum and minimum) and an average day.

(See special note a.)

2. Abnormal conditions resulting from worst case combinations of extreme

outside tempe~ratures and relative humidities, abnormally high or low

internal space heat loads, and degraded environmental control system

operation. (See special note a.)

3. Loss of Coolant Accident (LOCA) or High Energy Line Break (HELB)

conditions resulting from small, intermediate, or large main steam

line breaks inside containment. (See special note b.)

4. High Energy Line Break conditions outside primary containment

resulting from ruptures and critical cracks in various high energy

lines through-out the auxiliary building and steam valve vaults.

(See special note b.)

3.0-1

5. Tornado Depressurization conditions resulting from a design basis

tornado.

6. Inadvertent Containment Spray Initiation conditions resulting from

accidental operation of the containment spray system.

A summary of the above service conditions is presented in figures 3.0-:1

through -46. Each figure contains a key plan with the subject environ-

mental area highlighted. Directly below the key plan is a tabulation of

values for the different parameters under consideration. Temperature,

pressure, and relative humidity vs. time curves are also provided to

clearly define the effects of various worse case IIELB combinations on the

area. Applicable notes are provided on each figure to explain the data

presented.

All analyses performed to determine the environmental conditions are in

accordance with either TVA quality assurance procedure EP 3.03 or

Westinghouse's internal quality assurance program. ,-

E V

Special Note a. iz2T;

The "normal" maximum design temperature is based on the 99-percentile

meteorological data for the plant vicinity as given in industry-accepted

handbooks such as ASHEAE fundamentals. This data is used in conjunction

with maximum internal heat loads in the space when choosing heating,

ventilating, and air-conditioning (HVAC) equipment. In addition, an

appropriate margin is incorporated into the selection of HVAC equipment

3.0-2

which is used to maintain this normal space design temperature. Since

the normal condition will prevail at least 99 percent of the time, the

abnormal temperature is considered to occur one percent of the time or

less. In arriving at the abnormal conditions, TVA selected outside

temperatures based on actual recorded maximums for the plantsite vicinity

as opposed to the 99-percentile temperature. In addition, selected HVAC

failures such as fan failure, loss of cooling water, or heater failure

were taken into consideration. TVA further stipulates that each "abnormal"

occurrence will have a maximum duration of eight hours. This is based on

the fact that outside extremes will peak and begin to subside during the

day and night such that an extreme condition will exist for no more than

eight hours. To facilitate the expeditious repair of routine HVAC failures,

all spaces which contain safety-related equipment either have a temperature

monitoring and recording system or otherwise will be administratively

monitored once every working shift (eight hours). Additionally, any

continuous excessive condition outside the normal or abnormal range which

could affect the qualified service life will be detected.

Special Note b. EFFECTIVED AT E

OCT 1934High Energy Line Break (HIELB) ___________

Sections 3.1.1.1 and 3.1.2.1 contain material pertinent to HELBs inside

and outside containment. Recent NRC questions on Duke Power Company's

Catawba Nuclear Plant have resulted in a Westinghouse reanalysis of the

main steam line break (MSLB) which includes the effect of the superheated

3.0-3

steam produced when the steam generator tubes uncover. The resultant

superheated blowdown, which has a higher specific energy content than was

considered in previous analyses using only saturated steam, releases more

energy into the pipe break region's atmosphere and thus has the potential

for elevating the atmospheric temperature above that for a saturated

blowdown. In order to assess the impact of the MSLB reanalysis, environ-

mental and heat transfer analyses and safety evaluations were performed

for breaks both inside the containment and in the main steam valve vault

outside containment using preliminary data from the Catawba reanalysis.

The Westinghouse reanalysis of an MSLB inside containment, which included

superheated steam inside the Catawba containment and an ice condenser

drain model, is based upon appropriate conservative assumptions capable

of being justified on a licensing basis. This MSLB reanalysis, which is

generically applicable to WBN, utilized mass and energy release rates

based upon traditional licensing assumptions and an ice condenser model

demonstrated to be conservative by full scale testing. The calculated

peak containment temperature of 324*F is lower than the original WBN

design basis qualification temperature (327*F). Therefore, since no

design basis will be exceeded for an MSLB inside containment, original

class 1E electrical equipment qualification criteria are bounding and

still valid.

As for a MSLB in the valve vault, reanalysis utilizing the Catawba data

predicts a peak environmental temperature of 4460F which exceeds the

temperature used for equipment qualification. As a result, a comprehensive

evaluation of the effects of the increased temperature upon the plant's

3.0-4

capability to achieve controlled hot standby was performed. The evaluation

process consisted of an examination of the effects of the increased

temperature profile upon the environmental qualification of class lE electrical

equipment and a safety evaluation of plant's safe shutdown capability.

The results of this evaluation indicated all class 1E electrical equipment

(with the exception of postaccident monitoring (PAN) instruments) will

perform their required functions before the temperatures rise to levels which

invalidate the environmental qualification of the equipment. Additionally,

it was determined that equipment which could fail when its environmental

qualification temperature is exceeded will fail in a position not adversely

affecting plant safety. The PAM instrumentation which is required to

function during and after the event will be protected from the excessive

valve vault temperature by thermal insulation.

After the Watts Bar specific analyses have been completed and the environ-

mental temperature profiles have been determined all affected sections

will be revised to reflect the results of superheated steam blowdown from

an MSLB.

rEFFECTIVE-OCT 19084

3.0-5

3.1 Areas Affected by a LOCA or HELB

3.1.1 Inside Containment DC A 38E

3.1.1.1 High Energy Line Breaks

The controlling breaks inside containment are a double-ended guillotine

rupture in a pump suction leg of the reactor coolant system (RCS) and

a small slot break in the main steam line. The large LOCA is control-

ling for pressure and long-term temperature response. The small

steam line break produces the most severe short-term temperature

transient. (See special note b in Section 3.0.) Figure 3.0-1 contains

an enveloping curve of the most severe time history of both pressure

and temperature for the upper and lower compartments from a spectrum

of break sizes for both LOCAs and steam line breaks. The containment

pressure and temperature response to the LOCA was evaluated with the

LOTIC computer code using mass and energy releases calculated as

discussed in Westinghouse topical report WCAP-8312A. LOTIC III was

used to evaluate the containment response to main steam line breaks.

3.1.1.2 Chemical Spray

The chemical composition of the containment spray was based on the

following solutions which resulted in the most severe service conditions

are as follows:

3.o-6

1. Ice Condenser: Quantity of ice - 2.55 X 106 ibm boron concentra-

tion - 1800 ppm B added as NA2 B4 07 (sodium tetraborate)

2. Boron Injection Tank: Volume - 900 gallon boron concentration -

20,000-22,500 ppm B in the form of 113B03 (ortho-boric acid)

3. Cold Leg Injection Accumulators: 4 tanks, Volume per tank -1000

ft3 boron concentration - 1,900-2,000 ppm B in the form of H3 B03

4. Upper Head Injection: Volume - 1800 - 1850 ft3, boron concentra-

tion - 1900 - 2,100 ppm B in the form of H3 B03

5. Refueling Water Storage Tank: Volume - 323,400 - 331,400 gal.,

boron concentration - 2,000-2,100 ppm B in the form of H3 B03

6. Reactor Coolant System: Volume - 12,500 ± 100 ft3, boron concen-

tration - 0-2,000 ppm B in the form of (H 3B03 ).

The following assumptions were used in this analysis:

1. Calculations based on minimum quantities (wt or vol) maximum

concentration.

2. All solutions including completely melted ice mix completely.

DATEE0F 1984

3.0-7

3. Density of borated water is equal to that of water.

4. Fission products, corrosion products, etc., will be neglected.

Results - The solutions stated above yield a resulting concentration

of 0.1844 Molar H3B03 (approximately 2,000 ppm boron) and 0.033 M

NaOH. The final pH was empirically determined to be 8.35 at 25'C.

The methodology used above meets the caustic spray solution guide-

lines in SRP section 6.5.2, paragraph II, item e, and reflects the

worse case conditions. These values are being documented per EN DES

EP-3.03.

3.1.1.3 Radiation

The normal operating dose rate and 40-year integrated dose were taken

from FSAR table 3.11-2 (revised by amendment 39). The radiation

exposure inside containment after a design basis LOCA was calculated

based on a release to the containment atmosphere of 100 percent of

the core inventory of noble gas, 25 percent of the core inventory of

iodine, and I percent of the core inventory of solid fission products

(equivalent to TID-14844 releases). Removal of iodine is assumed to

be due to interaction with the ice condenser only. The calculation

of activity in containment after a LOCA is described in FSAR section

15.5. Maximum gamma doses were calculated in the upper compartment,

lower compartment, and ice condenser using a point-kernel-with-buildup

computer code. Doses were integrated to determine equipment exposure

for a one-year period after the accident. There is no unshielded

3.0-8

COC5

equipment in the containment, therefore, beta doses were calculated

only for surfaces using the semi-infinite cloud equation in Regulatory

Guide 1.4.

The calculation of radiation conditions inside containment complies

with paragraph 1.4 of NUREG-0588 except as noted below:

I Paragraph 1.4(3) - The initial distribution of activity was

assumed uniform throughout the containment even though the contain-

ment is broken up into upper compartment, lower compartment, and

E F r ice condenser. The operation of the air return deck fans will

U - result in sufficient mixing so that this assumption is believed

to be valid.

2. Paragraph 1.4(5) - Natural deposition was not considered. Appli-

cable deposition rates are unknown and actions of containment

spray in the upper compartment, and steam condensation in the

lower compartment can be expected to wash the deposited activity

into the sump.

3.1.1.4 Flooding

The maximum water levels given in the table were determined based on

a major non-isolated LOCA which empties the RCS volume. The water

sources are (1) RWST, (2) melted ice, (3) RCS volume, (4) UHI accumu-

lator, and (5) SIS cold leg accumulator. The calculated containment

volumes were reduced by 10 percent to account for components, pipes,

3.0-9

structures, etc. Steady state levels were calculated assuming free

passage of water between the floodable volumes. Surge levels inside

the crane wall were determined based on the fact that water cannot

flow through the crane wall at elevations between 716' and the steady

state level as fast as it is injected.

Using the flood levels calculated, TVA listed all 10 CFR 50.49 equip-

ment which will be submerged. A comprehensive safety evaluation of

the effects of the loss of the submerged equipment upon the plant's

capability to achieve a controlled hot standby condition was performed.

This evaluation resulted in a list of equipment that must operate

and/or not fail during submergence, thus requiring qualification.

Table 3.1 lists this equipment along with the EQSs and a summary of

the resolution providing qualification for submergence.

3.1.2 Outside Containment

3.1.2.1 High Energy Line Breaks

Plant areas outside containment were reviewed to determine areas

where high energy piping was located and could potentially produce

effects that would impact safety-related equipment. The areas affected

by high energy line breaks are the auxiliary building and the main

steam valve vaults.

E-U F 4 IT

3.0-10

E F>

3.1-2.1.1 Auxiliary Building

The high energy lines located in the auxiliary building are:

(1) Auxiliary feedwater pump turbine steam supply (AFWPTSS) -

556*F, 1100 psia, quality - 0.9.

(2) Letdown line - 3001F) 2200 psia.

(3) Auxiliary boiler steam supply (ABSS) - 370*F, 174 psia, quality-

1.0.

Single-ended circumferential ruptures at the fluid conditions

listed above were postulated.

Critical cracks in the residual heat removal (RHIR) system (350 0F,

440 psia) were also postulated.

Mass and energy releases for the steam lines were conservatively

generated using: (1) the Moody critical flow correlation assuming

an fl/D equal to zero for the AFWPTSS, and (2) standard methods for

calculating steam discharges from piping systems for the AIBSS in

each of the environmental areas through which the ABSS passes.

Mass and energy releases for the RHIR line breaks were conservatively

generated using the orifice equation. Choking was not assumed to

occur and the discharge coefficient was conservatively taken to be

unity.

3.0-11

The mass and energy release from the letdown line is limited to

120 gpm maximum by orifices in the line.

For all breaks, the upstream pressure and temperature, and therefore

the mass flow rates, were assumed to remain constant until the

appropriate isolation valves received a close signal. The break

flow was then linearly reduced to zero over the valve closure time.

Isolation times include signal process time, instrument delay time

and valve stroke time.

The steam supply lines isolate automatically on high temperature

in the auxiliary building by temperature switches located in the

immediate vicinity of the lines. The switches used are redundant,

Class 1E, and electrically trained.

Operator action is required to isolate the letdown and ERR lines.

Isolation was assumed to occur 10 minutes after detection equipment

alarms in the main control room. Break detection for ERR breaks is

by safety-grade temperature switches or pressurizer level. Safety-

grade temperature switches or nonsafety-grade component cooling

system low flow provides break detection for the letdown line.

A 26 node model was developed to represent the auxiliary building

and used as input to the COMPARE Mod 1 computer code. The homo-

geneous equilibrium model was chosen and heat sinks were considered.

The surface area and volume of the heat sinks were conservatively

3.0-12

modeled to underpredict the total sink present. The Tagami-Uchida

condensing heat transfer correlation was employed. Figure 3.0-44

shows the auxiliary building with the nodes outlined. Figure 3.0-44,

provides the pipe breaks considered and the nodes where breaks were

assumed to occur.

The pressure and temperature response of each affected area of the

auxiliary building due to each break is documented in reference 1.

HIELB profile figures provide the composite worst pressure and

temperature response by system for each area considering all breaks

of each system described in figure 3.0-44. The pressure and

temperature response of the auxiliary building beyond the analysis

time reflected in the HiELB profile figures is conservatively assumed

to linearly return to ambient in 24 hours. The maximum humidity

level in all areas affected by any HELB is assumed to be 100 percent.

3.1.2.1.2 Main Steam Valve Vaults

The high energy lines in the valve vaults are the main steam lines,

the steam generator blowdown lines, and the main feedwater lines.

Breaks in the main steam line are controlling from an environmental

standpoint due to the large line size and the high energy associated

with the steam.

3.0-13

F F E CIIV EU A T

A spectrum of steam line breaks were evaluated. The South valve

vault evaluations were performed for pipe breaks up to a double-

ended rupture. Due to pipe restraints on the main steam lines

which limit pipe movement, a single-ended steam line rupture was

the largest break considered in the North valve vault. A 0.1

square foot slot was the smallest break considered. Mass and

energy releases were provided by Westinghouse. Break flows were

terminated by isolation of the main steam lines from the unbroken

steam generators and main feedwater based on signals from safety-

related sensors. Auxiliary feedwater to the faulted steam generator

is terminated by operator action 10 minutes after break detection.

For large breaks, the steam valve vaults were modeled using nine

nodes in the South vault and ten nodes for the North. These models

were input into the SPA Rev 2 computer code. SPA is a subcompartment

code using a homogeneous equilibrium model and models two-component,

two-phase flow. Evaluation of superheated steam conditions is also

included in the code. No heat sinks were modeled. Small break

pressure and temperature transients were analyzed using CONTEMPT

LT. Once again, no heat sinks were considered. The valve vaults

at Watts Bar were constructed with large vent paths to the outside

to provide pressure relief in the event of a pipe break. These

paths were included in the models.

The results showed that the large breaks were controlling for both

pressure and temperature in the North valve vault and in the South

valve vault after the first 15 seconds because of the vents provided.

3.0-14

EF~FE C T IVEDAT EýC 118 A 0.6-square-foot slot break produces a short temperature spike

that exceeds the large break temperatures in the South vault. This

spike has been conservatively assumed to last one minute for the

purposes of environmental qualification. Figure 3.0-36 provides

the pressure and temperature response for both the North and South

steam valve vaults. These results represent the conditions in the

node with the most severe environmental conditions which were

applied uniformly to the entire vault.

3.1.2.2 LOCA Impact Outside Containment

3. 1.2.2. 1 Radiation - General spaces

The normal operating radiation environment in the auxiliary building

is shown in figures 3.0-6 through 3.0-42, 3.0-45, and 3.0-46. The

radiation exposure in the general spaces of the auxiliary building

after a design basis LOCA is due to (1) containment sump fluid being

circulated in the RRR, CS, and SI systems, (2) airborne activity in

the auxiliary building, and (3) shine from activity in the contain-

ment. The source terms used for this accident are those suggested

by the NRC for use in responise -to NUREG-0578 and correspond to

TID-14844 releases. Flow diagrams and equipment layouts were

reviewed to determine the flow paths which would be used after an

accident and to determine the volume and 7physical locations of

contaminated fluids in the auxiliary building. The layout of the

shield walls and equipment within the rooms were conservatively

modeled. Source terms were calculated at various times after an

3.0-15

UCI T 984 accident. Dose rates were then calculated at several positions in

the auxiliary building with respect to the contained sources and at

various times after an accident. The locations where dose rates were

calculated were chosen to conservatively calculate the dose rates in

corridors, outside equipment cubicles, in adjacent rooms, and within

the equipment cubicles. These dose rates were then integrated to

determine equipment exposure for a one-year period after the

accident. Airborne activity in the auxiliary building is due to

gaseous leakage from the containment which is processed and

exhausted through HEPA and charcoal filters in the auxiliary

building gas treatment system. The dose rates through the reactor

shield building from activity released into the containment

atmosphere were also calculated (reference TVA's response to

NUREG-0578).

The calculation of radiation conditions outside containment in

auxiliary building general spaces complies with paragraph 1.4 of

NUREG-05 88.

3.1.2.2.2 Radiation - Individually Cooled Rooms

The basis for the radiation exposure in individually cooled rooms

in the auxiliary building is the same as described above for general

spaces at the auxiliary building. The dose rate in a room is due

almost entirely to the activity being circulated through equipment

in that room.

3.0-16

The calculation of radiation conditions outside containment in

auxiliary building individually cooled rooms complies with para-

graph 1.4 of NUREG-0588.

3.1.2.2.3 Environmental Control

Cubicles in areas containing emergency operated safety feature

equipment are ventilated by the building ventilation exhaust duct

system during normal plant operation or when equipment is not

required to operate. Air cooling units, located in each cubicle or

area, will automatically start to provide necessary cooling whenever

the safety feature equipment is operated. Each of these coolers is

designed to limit the maximum ambient air temperature to 110'F, and

is interlocked to operate with the equipment it serves. A thermostat,

located near the return airflow to each cooler, allows the cooler

to remain in operation until the low limit temperature setpoint is

reached. The cooling water control valve and fan are interlocated

to operate together.

Air cooling units are provided for the following equipment and

areas:

1. ROff pumps E C i~2. Safety injection pumps AC T E3. Containment spray pumps

4. Centrifugal charging pumps

5. Reciprocating charging pumps

3.0-17

Unit 1 auxiliary feedwater and component cooling water pumps

Unit 2 auxiliary feedwater and boric acid transfer pumps

Component cooling water booster and spent fuel pit pumps

Pipe chases

El 692 penetration roomsEFFEC hV£El 713 penetration rooms DATEEl 737 penetration rooms VI IJt3 4

Emergency gas treatment assemblies

The above pumps 1 through 5 are each located in a separate room

with cooler, and each room (containing pump and cooler) is provided

with 100 percent redundancy. Pumps and equipment 6 through 13 are

each served by two 100 percent coolers with one on standby.

The safety feature equipment coolers are designed to limit the

maximum ambient temperature to 110*F when supplied with water at

830F.

Annulus

The radiation environment inside the annulus after a LOCA is based

on an estimate of the dose due to shine through the primary contain-

ment steel shell from airborne activity in the primary containment.

The dose due to airborne activity within the annulus was assumed to

be small compared to the shine from containment.

3.0-18

3. 1.2.2.4

The method used to determine annulus peak temperature employed

standard heat transfer relations expressed in finite-difference

form and is considered to be conservative. Heat transfer across

the primary containment shell was modeled dividing the shell into

three regions. The upper region corresponded to that portion of

the unit above a horizontal plane passing through the top of the

crane wall. The lower region corresponded to that position of the

unit below a horizontal plane passing through the bottom deck of

the ice-condenser section. The middle region corresponded to the

ice-condenser portion of the unit. Natural convective heat transfer

was assumed to occur between the primary containment shell and the

annulus air. In addition, radiative heat transfer was modeled

between the containment shell and the shield building walls.

Annulus peak humidity was defined to be 100 percent, although no

source of humidification was identified in the annulus for the

post-LOCA case.

NUJREG-0588 does not provide specific guidance for calculation of

environmental parameters in the annulus.

3.1.2.3 Flooding9 Er1K T '~D AT 2

3.1.2.3.1 Annulus

Flooding in the annulus area was not considered because all high

energy lines are sleeved through the annulus area. Should a HELB

3.0-19

E F~ F E ýC' T V EDATE

J~l occur in the annulus the break flow will discharge into the sleeve

and not into the annulus environmnent. The flow from the sleeve is

designed to discharge into the auxiliary building.

3.1.2.3.2 Auxiliary Building

The largest pipe breaks which could result in the greatest flooding

in the auxiliary building would be for a critical crack to occur in

the RIIR piping during plant shutdown or any of the ERCW inlet

supply headers entering the auxiliary building. If a critical

crack were to occur in the RHll piping, the floodwaters will drain

to the passive sump since all areas containing the RILR piping have

blowout panels in the floor which will dump the water into the

passive sump when the water level reaches a predetermined height.

This design feature will protect all safety-related equipment in

the vicinity of the break from flood damage.

If one of the ERCW inlet supply headers entering the auxiliary

building should develop a critical crack, the maximum flow rate

would be approximately 1,300 gpm. Localized flooding caused by

this break will drain to the passive sump through stairwells and

floor drains before equipment damage can occur. The floodwaters

flowing down through the stairwells will enter the passive sump

through a 3- x 4-foot wide vent. The vent is located directed

above the passive sump which has a capacity of approximately

265,100 gallons. The floodwaters entering the floor and equipment

drains will flow by gravity to the tritiated drain collector tank

3.0-20

E FFE CT IV ED AT E

OCT 19834 and the floor drain collector tank. The capacity of the tritiated

drain collector tank is 24,700 gallons and the floor drain collector

tank is 23,000 gallons. The total capacity of the passive sumnp and

drain collector tanks is approximately 312,800 gallons.

As a consequence of these breaks, the level in the passive sumnp and

drain tanks will eventually increase to the high level setpoints

and high level alarms will be initiated in the main control room.

if the flooding is due to a critical crack in the RIIR piping, the

level in the pressurizer will decrease and alarm in the main control

room. If the flooding is due to a critical crack in the ERCW inlet

supply header, a low ERCW supply header flow alarm will be initiated in

the main control room. Since the ERCW is designed to supply cooling

water to the component cooling water system, the loss of heat sink

to this system will generate several high temperature alarms in the

main control room. From these various indications, the operator

will be able to quickly diagnose which system has ruptured and will

take corrective action to isolate the break. Since the total

capacity of the auxiliary building drain system is large, no appreci-

able flooding will occur and, adequate time is available for the

operator to take corrective action. Damage to safety-related

equipment will also not occur because all safety-related equipment

located in pump rooms and pipe chases are isolated from flooding by

closed doors. Equipment not located within the pump rooms or pipe

chases are protected from spray and where safety-related equipment

cannot be designed to resist spray, shields and barriers are

provided. Flooding of Class 1E shutdown boards and their associated

3.0-21

equipment will not occur because this equipment is located high

above the elevation of either the RHff piping or EROW inlet supply

headers.

Therefore, for the reasons stated above TVA has not identified any

safety-related equipment in the auxiliary building which is required

to be qualified for submergence.

E IF Fk E C T V E

OCT 1964

3.0-22

References

1. Engineering Design Calculation, TI-ANL-94R0, "Environmental Response

of Auxiliary Building to ILELBs," Tennessee Valley Authority.

EFFECTIVEDATE

OCT 19184

3.0-23

Table 3. 1

Submerged Equipment

Resolution

LT-3-38LT-3-42LT-3-5 1LT-3-55LT-3-56LT-3-93LT- 3-94LT-3- 106LT-3-107LT-3- 111LT-3-172LT-3-173LT-3-174LT-3-175TE-68- 1

TE-68-18

TE -68-24

TE-68-41

TE-68-43

TE-68-60

TE-68-65

TE-68-83

PT-68-322RE-90-273RE-90 -274

WBN-NEB- 3-4WBN-NEB- 3-4WBN-NEB- 3-4WBN-NEB- 3-4WBN-NEB-3-4WBN-NEB- 3-4WBN-NEB-3-4WBN-NEB-3-4WBN-NEB- 3-4WBN-NEB- 3-4WBNEEB0002WBNEEB0002WBNEEB0002W'BNEEB0002WBN-NEB- 68-23

WBN-NEB-68 -23

WBN-NEB-68-23

WBN-NEB- 68-23

WBN-NEB-68- 23

WBN-NEB-68 -23

WBN-NEB- 68-23

WBN-NEB-68- 23

WBN-NEB-XX-49WBNEEB-RI- 2WBNEEB-RM-2

RelocateRelocateRelocateRelocateRelocateRelocateRelocateRelocateRelocateRelocateRelocateRelocateRelocate

Replace with devicesubmergence

Replace with devicesubmergence

Replace with devicesubmergence

Replace with devicesubmergence

Replace with devicesubmergence

Replace with devicesubmergence

Replace with devicesubmergence

Replace with deviceSsubmergence

Relocate above floodRelocate above floodRelocate above flood

aboveaboveaboveaboveaboveaboveaboveaboveaboveaboveaboveaboveabove

f loo

f loof loof loof 1004f looi

f loo

f loo

f loof loo(

d leveld leveld leveld leveld1 leveld leveld leveld leveld levelI levelI levelI levelI levelIlevelqualified for

qualified for

qualified for

qualified for

qualified for

qualified for

qualified for

qualified for

levellevellevel

EFECTIVDATE

0-0,T 19984]

ID No. EQS No.

DEO7 :EEEQR.WB

4.3 Required and Demonstrated Accuracy Determination - TVA Methodology

TVA has used two separate methodologies to determine required and demon-strated accuracies for equipment within the scope of lOCFER5O.49, one forBalance of Plant (BOP) equipment and one for Nuclear Steam Supply System(NSSB)' equipment.

BOP Methodology

For BOP, the inaccuracies caused by accident environmental effects werecombined with the normal loop inaccuracies (which included the inaccuraciesof the output devices and any interposing instruments), using a square rootof the sum of the squares method. The result is the total loop inaccuracy.This total inaccuracy was applied to the normal set points for each safetysystem in the most conservative manner in order to evaluate the effect onthe system safety function.

For control applications, it was assumed that instrument function occurredat the extreme limit of the error band on the side that would tax systemperformance the most. The loop accuracy was considered acceptable if thesystem could still perform its safety function. If the system could notperform its intended safety function, the required accuracy was then'specified by the system engineer.

For indicators, the instrument error was evaluated in the adverse directionto determine if the conveyed information would prevent appropriate operatoraction. If the inaccuracies did not prevent prompt operator action orcause ambiguities, then the loop accuracy was considered acceptable. Ifthe inaccuracies had the potential to prompt inappropriate operator actionor cause ambiguities, the required accuracy was then specified by thesystem engineer.

Both the calculation of the total loop inaccuracy and the effect on theability of the system to perform its safety function are documented inTVA's QA calculations.

NSSS Methodologty

For NSSS equipment, Westinghouse Electric Corporation has performed a plantspecific statistical setpoint study and functional requirement documentwhich includes the required accuracies for instrumentation installed atWBN. For the NSSS protection equipment and monitoring equipment, theinaccuracies caused by accident environmental effects were combined withnormal instrumen 't channel inaccuracies and were compared against the WattsBar safety analyses limits and plant trip/actuation setpoints to confirmthat adequate margin exists between the setpoints and safety limits. Theserequired accuracies have been compared against the demonstrated accuraciesas stated in the test report (WCAP) and appear in the 3-11 Tables of thisreport.

4.3-1EF E T VDATE

OCT 1984

EQUIPMENT QUALIFICATION SHEET INDEXNUCLEAR ENGINEERING BRANCH - UNIT 1*

WBN-NEB-68-3l R3WBN-NEB-3-4, R2WBN-NEB-KX-5, 13WBN-NEB-XX-6

WBN-NEB-XX-8, R3WEN-NEB-ZI-il, R33WBN-NEB-XX- 14, 13WBN-NEB-68-23, R3WBN-NEB-.68-24, 13WBN-NEB-62-26, R33WBN-NEB-68-339 12WBN-NEB-XX-37, R3WBN-NEB-XX-38, 13WBN-NEB-68-44t 3.1

WBN-NEB-XX-47, 11WBN-NEB-XK-489 RlWBN-NEB-94-48, Rl

Asco 206-381-3RPBarton 764 (Lot 7)See EQS WBN-EEB-0019; for unit 1 onlyAsco Models Ft-831654, Ht-831654, andFTX831654See EQS WBN-EEB-0068; for unit 1 onlyNamco EA-17-302Barton 763 (Lot 7)Rosemount 176 KSRosemount 176 XFBarton 752Ninco S8809, S8810LimitorqueLimitorque SB-0, SB-3RDF 21232

Barton 764 (LotBarton 763 (LotControl Pro

*Unit 2 EQSa are on file pending further evaluation.

E44289.07

E rFF E C T I VE,DATE0 nýCT 1984

VE

Revision 01 02 03 Unit No. 1~1'" EQS No. WBN-NEB-68-3Preparer/Date George J. Malek 12/01/81 PBN AWL /.'A 4 TVA ID No._____

5/5/83 5T/18/84 AI -FSV-68-307--Reviewer/Date Felecia A. Plesic 12/01/81 RKW DLK ________

5/6/83 5/22/84'g~~.w

WBN EQUIPMENT QUALIFICATION SHEET (EOS)

Manufacturer and Model No. ASCO 206-381-3 31Verification of Table Information (Table 3.11-5)

X Equipment Type - The equipment has been identified as per TVA IDnumber designations (such as MOV, SOy).

X Location - The location has been identified (such as, inside primarycontainment, annulus, individually cooled rooms, general spaces, orarea affected by NILE outside primary containment).

X Component -A unique TVA ID number has been assigned (such as1-FSV-68-308).

X Function - A functional description of the component has been given(such as steam generator blowdown).

X Contract No., Manufacturer, and Model No. -The contract number,manufacturer, and model number have been given.

X Abnormal or Accident Environment -All abnormal or accidentenvironmental conditions -ap-plic-able to this equipment have beenidentified either in tables or by references to figures from tables.K Environment to Which Qualified - The environment to wehich theequipment has been qualified is addressed in either the tables orthe environmental analysis attached.

K Category - A category of a. b, c, or d has been defined for theequipment.

X Operation and Accuracy Required and Demonstrated - The operation andaccuracy required and demonstrated have been defined.

Qualification Status (check if applicable, NA if not)Qualified Life (If equipment is qualified, indicate the qualifiedlife with a numerical entry): 1.years -X Qualification Report and Mdethod- A quialification report and themethod Of qualification has been identified on the Table Input DataSheet (TIDS).

X Environmental Analysis - An environmental analysis has been done,attached to the EQS, and independently reviewed by the responsibleorganization.

N/A. Qualification by Similarity (if applicable) - A justification forqualification by similarity is attached to the EQS considering allthe above factors and referenced to the appropriate tables.

N/A Qualification of Several Exact Components (if applicable) - When anEQS is usdfor more than one item, a list of all exact componentsis given as an appendix with all references to appropriate tableswith justification for qualification considering all the above factors.N/A Interim Qualification (if applicable) - (open item) - Component hasbeen deermined to be qualified only for a limited interim WJoperation, an NCR has been written, and plan of action has been>determined to yield a qualified component. LTerm of Interim Qualification __________________

NCR No.<N/A Unqualiid Compoent - (Open item) - (If applicable) - Component u.A ,.has been determined to be unqualified; the following is attached to LL aC-3.EQS: NCR number, reason for nonqualification, and justification of L..continued operation.

lUNCR No. _________________ E14139.01 I

Preparer/Date: George J. Malek 12/01/81

Reviewer/Date: Felecia A. Plesic 12/01/81 4P1 V

WBN-NEB-68-3, R3Appendix 1, R33Sheet 1 of

This valfe is qualified by type test and analysis as described in ASCO's testreports AQS-21678/TR9 revision A (NEB 820401 201) and AQS-21678/TR, supplement 3(NEB 840328 363). Testing conforms to the requirements of IZEE standard 323-1974. The valve is identified by the manufacturer to be representative of thefamily of valves subjected to qualification tests as described in the abovereports.

This valve is located in the annulus at elevation 723 feet. The environmentalcondition for which this valve must be qualified is:

TemperaturePressureRadiationHumidity

15007 for 24 hoursAtmosphere7 z 107 rads (40-year life plus 100-day accident dose)1001

The valve was qualified for the following environmental conditions:

TemperaturePressureRadiationWear agingSprayThermal aging

3460F for 3 hours (see attachment 1)110 psig for 3 hours (see attachment 1)2 x 108 rads (Accident dose plus aging dose)40,000 cycle.3000 ppm boron, pH 10268*7 for 12 days

Relative humidity was not specifically addressed during the testing. The testchamber was heated and pressurized by injecting steam into the test chamberthroughout the test period. In addition, the chemical spray was re-circulatedin the test chamber throughout the 30-day test period. Therefore, it wasconcluded that relative humidity was simulated throughout the test.

Accelerated thermal aging was used to simulate the thermal aging during avalve's installed life. Arrhenius calculation is the method we used to relatethe accelerated thermal aging from the report to the thermal aging in the actualservice.

Due to the self-heating nature of solenoid valves, the temperature riseassociated with a continuously energized solenoid valve must be accounted for inthe qualified life calculation. There are two areas affected by this heating:(1) the coil sees an increase of 1050C (22107) above ambient and (2) theelastomeric disks see an increase of 450C (8107) above ambient. A separatequalified life wil be calculated for both the coil and the disks.

The following is a list of organic materials and their activation energy valuescontained in the valve:

Ethylene Propylene Terpolymer - .94 eV EFFECTIVE'Magnet-Wire Enamel - Coil - 1.16 eV DATESilicon Varnish - Coil - 1.08 eV OCT 1984Nomex Paper - Coil - 1.54 eVJSilicone Rubber - Coil - 1.59 eV__________ISO-Mica - CoilSilicon-Impregnated Mica Paper - Coil

- 1.00- 1.08

Preparer/Date: George J. Nalek 12/01/81

Reviewer/Date: Felecia A. Plesic 12/01/817011441"

WBN-NEB-68-3p R33Appendix 1, R33Sheet 1 of

By the use of the following modified Arrhenius equation (reference 3):

in (ta/ta) - Q/K (1/Ta - /Ta)

ts = ta e Q/K (1/To 1/Ta)

coils

In Franklin Research Center's "Test Program and Failure Analysis of Class 11Solenoid Valves (NuuEG/GR-3424, F-C5569-3Q9/315)- the solenoid coils were agedat two rates: 150oC for 9.3 days and 131uC for 15.3 days.

therefore:

ta - Accelerated aging - 9.3 daysQlActivation energy (lowest) - 1.0 ey coil

K n Boltzmann's constant - .8617 x 10-4 ev/KTo Normal service temperature - 43.30C 0 110OF + 1050C

- 148.20C - 4210KTa1 Accelerated aging temperature - 1050C + 1500C -255 0C -5280K

Using these values tol - 2480 days a 6.79 yrs.

ta2 -Accelerated aging - 15.3 daysQ -Activation fnergy (lowest) w 1.0 eV coilK - .8617 x 10-" eV`/KTo- 148.20C - 4210K

Ta - 1050C + 1310C - 2360C -509 0K

Using these values t 82- 1796 days - 4.92 yrs

therefore, the total qualified life of the coils is:

t T5 -6.79 + 4.92-11.72 7T 1EC IVDisks (Rest of Valve)EF

t in~das j OCT 1984Ql.94 eVd

K -. 8617 x 10-4 eV/KT- 43 .30c + 450C -88.3 0C -361.2 0K

Ta -131 0C + 450CC 1760C - "490K

Using these values from reference 3 the qualified life of the disks is:

t* 4405.5 days - 12.1 yrs

This valve has a required operability of 5 minutes, then remainint in the safe(closed) position for 100 days. The DBE simulation test profile (attachment 1)included 30 days temperature exposure at 2000? or greater. The requiredpostaccident temperature is 15O for 24 hours and then decreases to 1050!for the next 99 days. The test profile far exceeds the required profile.

Preparer/Datet George J. Malek 12/01/81

Reviewer/Date: Telecia A. Plesic 12/01/81

WBN-NEE-68- 3 , R3Appendix 1, R3Sheet 1 of

it is concluded from the information contained within this report that the valve

is qualified for 11.7 years.

References:

1. ASCO Report AQS 12678/TRI revision A (NEB 820401 201)

2. ASCO Report AQS 21678/TI, supplement 3 (NEB 840328 363)

3. EPRI report NP-1558 - A Review of Equipment Aging Theory and Technology

4. Environment drawing 47E235-445. EN DES Calculation - 0588 cat. and oper. times (NEB 840321 219)

E14139.01

EFFECTIVEDATE

OCT 1384

Revision 01 02 03 Unit No. 1AWL EQS No. WBN-NEB-3-4

Preparer/Date -F. A. Plesic, 5/6/82 6/7/84 ?j/ TVA ID No.DLK See Appenix

Reviewer/Date P. B. Nesbitt, 3/16/83 _6/8/84 /'q_________

WIN EQUIPMENT QUALIFICATION SHEET (EQS)

Manufacturer and Model No. Barton 764, Lot 7Verification of Table Information (Table 3.11-4)

-X Equipment Type - The equipment has been identified as per TVA IDnumber designations (such as MDV, SOy).

-X Location - The location has been identified (such as, inside primarycontainment, annulus, individually cooled rooms, general spaces, orarea affected by HELB outside primary containment).

X Comonet -A unique TVA ID number has been assigned (such as1-FSV-68-'308).

X Function - A functional description of the component has been given(such as steam generator blowdown).

X Contract No., Manufacturer, and Model No. -The contract number,manufacturer, and model number have been given.

X Abnormal or Accident Environment -All abnormal or accidentenvironmental conditions applicable to this equipment have beenidentified either in tables or by references to figures from tables.

X Environment to Which Qualified - The environment to which theequipment has been qualified is addressed in either the tables orthe ennvironmental analysis attached.

X Category - A category of a, b, c, or d has been defined for theequipment.

X Operation and Accuracy Required and Demonstrated - The operation andaccuracy required and demonstrated have been defined.

Qualification Status (check if applicable, NA if not)Qualified Life (If equipment is qualified, indicate the qualifiedlife with a numerical entry): 6 years

X Qualification Report and Method - A qualification report and themethod of qualification has been identified on the Table Input DataSheet (TIDS).

X Environmental Analysis - An environmental analysis has been done,attached to the ZQS, and independently reviewed by the responsibleorganization.

N/A Qualification by Similarity (if applicable) - A justification forqualification by similarity is attached to the EQS considering allthe above factors and referenced to the appropriate tables.

X Qualification of Several Exact Components (if applicable) - When anEQS is used for more than one item, a list of all exact componentsis given as an appendix with all references to appropriate tableswith justification for qualification considering all the above factors.

N/A Interim Qualification (if applicable) - (Open item) - Component hasbeen determined to be qualified only for a limited interim Loperation, an NCR has been written, and plan of action has beendetermined to yield a qualified component.Term of Interim Qualification ___________________

NCR No. __ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _

N/A UnqualifiedComponent - (Open item) - (If applicable) - Component Uhas been determined to be unqualified; the following is attached to "EQS: NCR number, reason for nonqualification, and justification of ýLLNCR No. ________________

E64158 .07

WBN-NEB-3-4, R2Appendix 1, R2Sheet 1 of 1

Cqmponents

LT-3-38LT-3-42LT-3-5 1LT-3-55LT-3-56LT-3-93LT-3-94LT-3-106LT-3-111LT-3- 107

Preparer/Date F. A. Plesic, 5/6/82

Reviewer/Date P. B. Nesbitt, 3/16f/83 'lmli

I z~z

E64158 .07

q/4/?'vl

IEFFECTIVEDATE

OCT 1984

WBN-NEB-3-4, R2Appendix 2Sheet 1 of 3

These transmitters are qualified by Westinghouse test reports UCAP-8687,Supplement 2-EO3A, and WCAP-8587, Supplement I-EQDP-ESE-3A.

These transmitters are located inside containment at elevation 719 feet andare required to meet the following environmental conditions:

Normal

KAccident

Temperature ( 0F)Humidity (Z 2Pressure (lb/in a)Radiation (rads)Chemical Spray (ppm boron)Submergence

120 32780 10014.7 7 26.4 72x10 (40 yrs) 2x10 (100 days)N/A 2000 ph 8.35N/A NO

The transmitters are qualified to the following environmental conditions:

TemperatureHumidityPressureRadiationChemical Spray

- 1001 2

-2500 ppm (boron) ph 10.7

Accelerated thermal aging was used to simulate the thermal aging during thetransmitter's installed life. Arrhenius calculation is the method we usedto relate the accelerated thermal aging from the report to the thermalaging in the actual service.

The following is a list of organic material contained in the transmitterand their activation energy valves:

Preparer/Date F. A. Plesic, 5/6/82 ~~~~."

Reviewer/Date P. B. Nesbitt, 3/16/83 K tlI

E64 158.07

WBN-NEB-3-4, 1.2*1 Appendix 2

Sheet 2 of 3

EPT 0-rings .92 eVTefzel wire insulation .91 eVNylon transistor pads .50 eVSylgard No. 170 potting material 1-.25 eVRed HUT sleeving 1.16 eVEpoxy Laminated

NEMA Graded FR5 board material .96 eVSilicone Oil 550 bellows fluid .92 eVEpoxylete 6203 1.65 eVRTV 102-Silatic .80 eV

4Loctite sensor assembly .77 eV

By the use of the following modified Arrhenius equation (reference 3):

in (ts/ta) - O/K (Ts-lITa)

to ta toeAll( (/Ts -1/Ta)

where: ta -Accelerated aging time -1673 hours0 -Activation energy (lowest) .50 eVK- Boltzman's Constant - *8617x104 eV/KoTs a Normal service temperature - 12001? -320Ta - Accelerated aging temperature - 125 0 C - 398K

Using the above values from the test report into the Arrhenius equation,the normal service time is determined to be:

to - 52229.59 hr or 6 years

At the conclusion of the accelerated thermal aging, leakage through thedifferential pressure unit housings revealed 0-ring failure. Based oninformation from the 0-rings manufacturer, it was determined that the agingtemperature was too high for the amount of time aged. Based on this, theinternal 0-rings were replaced and aged for 350 hours at 125 0c. Thisshowed the internal 0-rings to have a qualified life of 22.4 years.

Based on the test reports, HELB testing simulated a 4-month postaccidentperiod.

Preparer/Date F. A. Plesic, 5/6/82

Reviewer/Date P. B. Nesbitt, 3/16/83 h

E64158.07

JEFFECTIVEJ

WBN-NEB-3-4, R2Appendix 2Sheet 3 of 3

Based on the discussion above, we concluded that these transmitters arequalifieJ ~for 6 years plus at least 100 days accident condition. As partof our qualification maintenance program, the cover 0-rings will bereplaced at 2 years on every time the transmitter cover is removed.

References

WCAP-8687, supplement 2-E03A (NEB 840807 362)1 Rev 2WCAP-8587, Supplement 1-KQDP-ESE-3A (NIB 840807 361), Rev 4EPRI Report NP-1558 - A review of equipment aging theory and technologyEnvironment drawing 471235-42EN DES Calculation - 0588 Cat. and Oper. Times (NIB 840515 225)EN DES Calculation - TI-RPS-48 (NIB 830414 235)ECH 5066 (WE? 840828 546)

Preparer/Date F. A. Plesic, 5/6/82

Reviewer/Date P.B.Nsbit,3/6/83

@.V~I ýo

awh,

E64158.07

EFFECTIVEDATET

OCT 1310"34

I!R

Rev is ion 01 02 03 Unit No. 1PBN AWL EQS No. WBN-NEB-XX-5

.1 ~Preparer/Date George J. Malec,_ 12/1/81 5/9/83 5/18/84 ?/!:4 TVA ID No. ____

RKW DLK FSee Appendix 1Reviewer/Date Pelecia A. Plesic, 12/1/81 5/10/83 5/30/84 ________

WBN EQUIPMENT QUALIFICATION SHEET (EQS)

Manufacturer and Model No. N/AVerification of Table Information (Table N/A)

N/A Equipment Type,- The equipment has been identified as per TVA IDnumber designations (such as MOV, SOy).

N/A Location -The location has been identified (such as, inside primarycontainment, annulus, individually cooled rooms, general spaces, orarea affected by HELD outside primary containment).

X Copnn -A unique TVA ID number has been assigned (such as* 1-FSV-AB-308).

N/A Function - A functional description of the component has been given(such as steam generator blowdown).

N/A Contract No., Manufacturer, and Model No. -The contract number,manufacturer, and model number have been given.

jN/A Abnormal or Accident Environment -All abnormal or accidentenvironmental conditions applicable to this equipment have beenidentified either in tables or by references to figures from tables.

N/A Environment to Which Qualified - The environment to which theequipment has been qualified is addressed in either the tables orthe environmental analysis attached.

N/A Category - A category of a, b, c, or d has been defined for theequipment.

N/A Operation and Accuracy Required and Demonstrated - The operation andaccuracy required -and demonstrated have been defined.

Qualification Status (check if applicable, NA if not)Quýalified Life (If equipment is qualified, indicate the qualifiedlife with a numberical entry): N/A

N/A Qualification Report and Method - A qualification report and themethod of qualification has been identified on the Table Input DataSheet (TIDS).

N/A Environmental Analysis - An environmental analysis has been done,attached to the KQS, and independently revieved by the responsibleorganization.

N/A Qualification by Similarity (if applicable) - A justification forqualification by similarity is attached to the EQS considering allthe above factors and referenced to the appropriate tables.

N/A Qualification of Several Exact Components (if applicable) - When anEQS is used for more than one item, a list of all exact componentsis given as an appendix with all references to appropriate tableswith justification for qualification cons idering all the above factor

N/A Interim Qualification (if applicable) - (Open item) - Component has UJbeen determined to be qualified only for a limited interim>operation, an NCR has been written, and plan of action has been LUJdetermined to yield a qualified component. *9'~Term of Interim Qualification N/ANCR No.: N/A LN/A Unqualified Component - (Open item) -(If applicable) -Component LL i C-'has been determined to be unqualified; the following is attached to uL. CEQS: NCR number, reason for nonqualification, and justification of LUcontinued operation.CNCR No. ______________

E84 139 .01

WBN-NEB-XX-5, R3Appendix 1, R3Sheet 1 of 1

FSV-62-76PSV-68-334APSV-68-334BPSV-68-340AAPSV-68-340AB

Solenoid valve FSV-62-76 has been replaced and will appear on EQS WBN-EEB-0019.

Solenoid valves PSV-68-334A and B and PSV-68-340AA and AD were the pilotsolenoids for the power operated relief valves (PORVs). Due to the new designof the qualified PORVs these valves no longer exist. See NCR WBNNEB8127 CUEB840530 851).

Preparer/Date Felicia A. Plesic 11/23/81 4W ys1

1R3

Reviewer/DateE84139.01

-George J. Halek 12/1/81

EFFECTIVE'DATEOCT 119!3344V

Axg/i

Revision 01PBNPreparer/Date F. A. Plesik,~ 11/23/81 5/11/83

Reviewer/Date G. J. Malek, 12/l/81

02AWL

RKW DLK

03

WIN EQUIPMENT QUALIFICATION SHEET (EQS)

Unit No. 1EQS No. WIN-NEW:U-X-8TVA ID No-. ___

See Appendix 1.

Manufacturer and Model No.Verification of Table Information (Table

X Equipment Type - The equipment has been identified as per TVA IDnumber designations (such as MOV, SOy).

N/A Location - The location has been identified (such as, inside primarycontainment, annulus, individually cooled rooms, general spaces, orarea affected by HELB outside primary containment).

X CoMonent -A unique TVA ID number has been assigned (such asl-FSV-68-:308).

N/A Function - A functional description of the component has been given(such as steam generator blowdown).

N/A Contract No., Manufacturer, and Model No. -The contract number,manufacturer, and model number have been given.N/A Abnormal or Accident Environment -All abnormal or accidentenvironmental conditions applicable to this equipment have beenidentified either in tables or by references to figures from tables.N/A Environment to Which Qualified - The environment to wehich theequipment has been qualified is addressed in either the tables orthe environmental analysis attached.

N/A Category - A category of a, b, c, or d has been defined for theequipment.

N/A Operation and Accuracy Required and Demonstrated - The operation andaccuracy required- -and demonstrated have been defined.

Qualifica-tion Status (check if applicable, NA if not)Q.ualified Life (If equipment is qualified, indicate the qualifiedlife with a nmnmberical entry): -N/AN/A QualificationReport and Method - A qualification report and themethod of qualification has been identified on the Table Input DataSheet (TIMS).

N/A Environmental Analysis - An environmental analysis has been done,attached to the EQS, and independently reviewed by the responsibleorganization.

N/A Qualification by Similarity (if applicable) - A justification forqualification by similarity is attached to the EQS considering allthe above factors and referenced to the appropriate tables.N/A Qualification of Several Exact Components (if applicable) - When anEQS is used for more than one item, a list of all exact componentsis given as an appendix with all references to appropriate tableswith justification for qualification considering all the above factors.N/A- interim Qualification (if applicable) - (Open item) - Component hasbeen determined to be qualified only for a limited interimoperation, an NCR has been written, and plan of action has been LUdetermined to yield a qualified component.>

Term of Interim Qualification __________________

NCR No. IK Unqualified Component - (-Open item) - (if applicable) - Componenthas been determined to be unqualified; the following is attached to LEQS: NCR number, reason for nonqualification, and justification of .continued operation.

LL.NCR NO. WB8118lBILE84139.02

LuA

Iq-

0c,0

I

5/21/84

AIA

WBN-NEB-XX-8, R3.Appendix 1, R33Sheet I of I

Limit Svitch On:

FCV-62-69FCV-62 -70.

Per NCR WBNNEB8118 these limit switches were unqualified for their environment.They are being replaced with qualified limit switches and will appear on EQSWBN-EEB-068.

I

6

I

4

Preparer Date: Felicia A. Plesic, 11/23/81

Reviewer Date: Georite J. !4alek, 12/1/81

E84139.02tia/vi

SEFFECTIVE]DATE

OCT 19 ""4

goý11-117,t61K

Revision 02 03

Preparer/Date Felicia A. Plesic 11/23/81 PEN AWL5/18/83 6/4/8Z

Reviewer/Date Georite J. Malek 12/01/81 RKW DLK5/19/83 6/4/8

WBN EQUIPMENT QUALIFICATION SHEET

Manufacturer and Model No. Namco EA170-302Verification of Table Information (Table 3-11-7, 8

(EQS)

Unit No. 1EQS No. WBN-NEB-XX-11TVA ID No. ____

see Appendix 1

X Equipment Type - The equipment has been identified as per TVA IDnumber designations (such as MOV, SOy).

X Location - The location has been identified (such as, inside primarycontainment, annulus, individually cooled rooms, general spaces, orarea affected by HELD outside primary containment).

X Component -A unique TVA MD number has been assigned (such as1-FSV-68-308).

X Function - A functional description of the component has been given(such as steam generator blovdown).

X Contract No., Manufacturer, and Model No. -The contract number,manufacturer, and model number have been given.

K Abnormal or Accident Environment -All abnormal or accidentenvironmental conditions aippTlicable to this equipment have beenidentified either in tables or by references to figures from tables.

X Environment to Which Qualified - The environment to which theequipment has been qualified is addressed in either the tables orthe environmental analysis attached.

K Category - A category of a, b, c, or d has been defined for theequipment.

K Operation and Accuracy Required and Demonstrated - The operation andaccuracy required and demonstrated have been defined.

Qualification Status (check if applicable, KA if not)

K

K

N/A

K

N/A

N/A

Qualified Life (If equipment is qualified, indicate the qualifiedlife with a numbericul entry): 40 yearsQualification Report and Method - A qualification report and themethod of qualification has been identified on the Table Input DataSheet (TIDS).Environmental Analysis - An environmental analysis has been done,attached to the EQS, and independently reviewed by the responsibleorgani~zation.Qualification by Similarity (if applicable) - A justification forqualification by similarity is attached to t .he EQS considering allthe above factors and referenced to the appropriate tables.Qualification of Several Exact Components (if applicable) - When anEQS is used for more than one item, a list of all exact componentsis given as an appendix with all references to appropriate tableswith justification for qualification considering all the above factors..Interim Qualification (if applicable) - (open item) - Component hasbeen determined to be qualified only for a limited interimoperation, an NCR has been written, and plan of action has been adetermined to yield a qualified component.>Term of Interim Qualification___________________NCR No. LUnqualified Component - (open item) - (If applicable) - Component Ihas been determined to be unqualified; the following is attached to <EQS: NCR number, reason for nonqualification, and justification of LL a -continued operation. L CD)NCR No. ________________E14145.01 U..

uAJ

Revision

Preparer/Date R. D. Darwin, 12/1/81

Reviewer/Date F. A. Plesic, 12/2/81

01 02PBN AWL

5/20/83 6/7/84

03

RKW DLK di5/22/83 6/7/84 &AId~

Unit No. 1EQS No. WBN-NEB-68-14TVA ID No._____

PT-68-68PT-68-69

WBN EQUIPMENT QUALIFICATION SHEET (EQS)

Manufacturer and Model No. Barton 763, Lot 7Verification of Table Information (Table 3.11-4)

X Equipment Type - The equipment has been identified as per TVA IDnumber designations (such as MOV, Soy).

X Location - The location has been identified (such as, inside primarycontainment, annulus, individually cooled rooms, general spaces, orarea affected by HELB outside primary containment).

X Component -A unique TVA ID number has been assigned (such as1-FSV-68-308).

X Function - A functional description of the component has been given(such as steam generator blowdown).

X ContractNo., Manufacturer, and Model No. -The contract number,manufacturer, and model number have been given.

X Abnormal or Accident Environment -All abnormal or accidentenvironmental conditions applicable to this equipment have beenidentified either in tables or by references to figures from tables.

X Environment to Which Qualified - The environment to which theequipment has been qualified is addressed in either the tables orthe environmental analysis attached.

X Category - A category of a, b, c, or d has been defined for theequipment.

X Operation and Accuracy Required and Demonstrated - The operation andaccuracy required and demonstrated have been defined.

Qualification Status (check if applicable, NA if not)Qu!alified Life (If equipment is qualified, indicate the qualifiedlife vith a numerical entry): 6 Us

K Qualification Report and Method - A qualifi cation report and themethod of qualification has been identified on the Table Input DataSheet (TIDS).

K Environmental Analysis - An environmental analysis has been done,attached to the EQS, and independently reviewed by the responsibleorganization.

N/A Qualification by Similarity (if applicable) - A justification forqualification by similarity is attached to the EQS considering allthe above factors and referenced to the appropriate tables.

K Qualification of Several Exact Components '(if applicable) - When anEQS is used for more than one item, a list of all exact componentsis given as an appendix with all references to appropriate tableswith justification for qualification considering all the above factors.

N/A Interim Qualification (if applicable) - (Open item) - Component hasbeen determined to be qualified only for a limited interimoperation, an NCR has been written, and plan of action has been LUdetermined to yield a qualified component.>Term of Interim Qualification__________________ -NCR No. I

N/A Unqualified Component - (Open item) - (If applicable) - Component uhas been determined to be unqualified; the folLowing is attached to UEQS: NCR number, reason for nonqualification, and justification of U_.continued operation. U_.NCR N4o. ______________

LU

CDLU cJ

C).

WBN-NEB-68-14, R.3Appendix 1Sheet 1 of 2

These transmitters are qualified by Westinghouse test reports WCAP-8687,Supplement 2-EOIA, and WCAP-8587, Supplement l-EQDP-ESE-1A.

These transmitters are located inside containment on an instrument rack onelevatiod 716 feet (transmitters are located above flood level) and arerequired to meet the following environmental conditions:

Normal Accident

Temperature (OF)Humidity (M 2Pressure (lb/in a)Radiation (rads)Chemical Spray (ppm boron)Submergence

1208014.7 72x 10N/AN/A

32710026. 4

(40 yrs) 2xi0O (100 days)2000 ph 8.35N/A

The transmitters are qualified to the following environmental conditions:

TemperatureHumidityPressureRadiationChemical Spray

- 420OF- 100% .2- 57 W~in g- 5xl10 rads-2500 ppm (boron) ph 10.7

Accelerated thermal aging was used to simulate the thermal aging during thetransmitter' s installed life. Arrhenius calculation is the method we usedto relate the accelerated thermal aging from the report to the thermalaging in the actual service.

The following is a list of organic material contained in the transmitterand their activation energy valves:

EPTTefselNylonSylgard No. 170Red RUTMEpoxy Laminated

NEMA Graded FRSSilicone Oil 550Epoxylete 6203RTV 102-S ilaticLoctite

0-ringswire insulationtransistor padspotting materialsleeving

board materialbellows fluid

sensor assembly

.92

.91

.501.251.*16

.96

.921.65

.80

.77

Preparer/Date R.D arwin, 1/l/81

Reviewer/Date F. A. Plesic, 12/2/81

E64158 .09f/s u/v

EFFECTIVEDATE

O CCT 1934

AD r1, 4404

WBN-NEB-68-14, R.3Appendix 1Sheet 2 of 2

By the use of the following modified Arrheniua equation (reference 3):

In (ta/ta) - O/K (Ta-i/Ta)

tsa;- ta e #/K (1/Ta -1/Ta)

where: ta -Accelerated aging time - 1673 hours0 Activation energy (lowest) .50 eVK- Boltzman'a Constant - 8617z10ýý eV/KoTs - Normal service temperature a 120O'F - 3220KTa -Accelerated aging temperature - 125 0 C - 3980K

Using the above values from the teat report into the Arrhenius equation,the normal service time is determined to be:

ta - 52229.59 hr or 6 years

At the conclusion of the accelerated thermal aging, leakage through thedifferential pressure unit housings revealed 0-ring failure. Based oninformation from the 0-rings manufacturer, it was determined that the agingtemperature was too high for the amount of time aged. Based on this, theinternal 0-rings were replaced and aged for 350 hours at 1250C. Thisshowed the internal 0-rings to have a qualified life of 22.4 years. It wasdetermined that to maintain this life the cover 0-ring must be replacedeach time the transmitter cover is removed, or every two years; this isbased on the fact that the transmitter was originally tested at 6 weeks at1250C with no failure.

Based on the test reports, HELD testing simulated a 4-mornth postaccident

Based on the discussion above, we concluded that these transmitters arefully qualified for 6 years plus at least 100 days accident condition. Aspart of our qualification maintenance program, the cover 0-rings will bereplaced at 2 years or every time the transmitter cover is removed.

References

1. WCAP-8687, supplement 2-E01A (NEB 840807 359), Rev 22. WCAP-8587, Supplement I-EQDP-ESE-IA (NEB 840807 355), Rev 43. EPRI Report NP-1558 - A review of equipment aging theory and technology4. Environment drawing 47E235-425. EN DES Calculation - 0588 Cat. and Oper. Times (NEB 840515 230)6. EN DES Calculation - TI-RPS-48 (NEB 830414 235)

Preparer/Date R. D. Darwin, 12/1/81

Reviewer/Date F. A. Plesic, 12/2/81E64158.09

!EFFECTIVEDATE

OCT 1984

Revision 01 02 0? Unit No. 1.4 rearr/at P A Pesc,121081 PBN AWL e QS No. WBN-NEB-68-23Reviewer/Date G. J.PMleki, 12/10/81 6110/83 615/84 A1 TVA ID NO.~ ~ r

ReiwrDae G . as,121/1 6/11/83 6/5/84 ___________

WBNl EQUIPMENT QUALIFICATION SHEET (EQS)

Manufacturer and Model No. RdF 21205Verification of Table Information (Table 3.11-4)

X Equipment Type - The equipment has been identified as per TVA TDnumber designations (such as MOV, SOy).

X Location - The location has been identified (such as, inside primarycotinment, annulus, individually cooled rooms, general spaces, orarea affected by RELB outside primary containment).X Coponet -Aunique TVA ID number has been assigned (such as

X Function - A functional description of the component has been given(s steam generator blowdown).

X Contract No., Manufacturer, and Model No. -The contract number,manufacturer, and model number have been given.

X Abnormal or Accident Environment -All abnormal or accidentenvironmental conditions applicable to this equipment have beenidentified either in tables or by references to figures from tables.

I Environment to Which Qualified - The environment to which theequipment has been qualified 'is addressed in either the tables orthe environmental analysis attached.

X Category - A category of a, b, c, or d has been defined for theequipment.

X 22eration and Accuracy Required and Demonstrated - The operation andaccuracy required and demonstrated have been defined.

ualification Status (check if applicable, NA if not)Qualified Life (If equipment is qualified, indicate the qualifiedlife wth a nmrical entry): 40 yea ra

I Qualification Report and Method - A qualification report and themethod of qualification has been identified on the Table Input DataSheet (TIDS).

I_ Environmental Analysis - An environmental analysis has been done,attached to the EQ8, and independently reviewed by the responsibleorganization.

I Qualification by Similarity (if applicable) - A justification forqualification by similarity is attached to the EQS considering allthe above factors and referenced to the appropriate tables.

I Qualification of Several Exac 't Components (if applicable) - When anEQS is used for more than one item, a list of all exact componentsis given as an appendix with all references to appropriate tableswith Justification for qualification considering all the above factors.

_N/A Interim Qualification (if applicable) - (open item) - Component has, ...been determined to be qualified only for a limited interim l4operation, an NCR has been written, and plan of action has beendetermined to yield a qualified component. c* ITerm of Interim Qualification LAcnNCR No. _ _ _ _ _ _ _ _ _ _ _ _ _

N/A Unqualified Component - (Open item) - (If applicable) - Component Lhas been determined to be unqualified; the following is attached to QL .EQS: NCR number, reason for nonqualification, and justification of Ccontinued operation. LLNCR No. _______________

E4428 5.05L-1

A

TE-68- 1TE-68-18TE-68-24TE-68-41TE-68-43TE-68-60TE-68-65TE-68-83

These RTDs are to be installed before fuel load.

Preparer/Date F. A. Plesic, 12/10/81 4al /01121/74

Reviewer/Date G. J. Malek, 12/10/81 ;O/0/A /Of

E44285 .05

EFFECTVD AT]E

nCUTIV

WBN-NEB-68-23, Rev. 3Appendix 1, Rev. 3Sheet 1 of 1

WBN-NEB-68-23, 2.3Appendix 2, 2.3Sheet 1 of 3

Four of these reactor coolant wide-range lTD* are used for postaccidentlei" monitoring (TE-68-1, TE-68-24, TE-68-6O, and TE-68-83). As such, they are

required to operate for 100 days postaccident. The other four wide-rangeRTD9 are used (or on unit 1 will be used) for cold overpressurizationprotection (TE-68-lB, TR-68-4l, TE-68-43, and TE-68-65). As such, theseare required to remain in a failed safe position for 100 days since failurein an unsafe mode might result in an unwanted P0KV opening.

These RTDs are located inside containment at elevation 716 feet. Theenvironmental conditions they are required to function in are:

Normal Accident

Temperature (0F) 120 (max) 327Humidity MZ 80 100

*Pressure (lb/in 2a) 14 7 26 4Radiation (rads) Boron 2~7 (40 years) 2xl0 7 (100 days)Chemical Spray (ppm Boo) N/A 2000 ph 8.35Submergence N/A Yes

The environmental conditions to which the RTDs are qualified to are:

Temperature -420O7 (peak)Humidity - 100% 2Pressure - 75 lb/i gRadiation - 2.47:10 rads (tip); l.22u108 rads (cable)Chemical Spray - 2500 ppm Boron, pH 10.7Submergence - See report below

These RTD. are hermetically sealed units with Flexonics Type 40111 stainlesssteel hydrostatic covering the RTD leads. The hydrostatic hosi is rated

.1from 7007 to 15000F7 at corresponding pressures from 2660 lb/in g (at700p) to 1064 lb/in g (at 150007). These pressure ratings are inaccordance with USA Standard Code for pressure piping and with the ASMEBoiler and Pressure Vessel Code, Section V111. To assure leak tightness ofeach RTD hydrostatic hose covering the RTD leads, helium leak rate testingis performed by the manufacturer on each RTD. The ac ~eptance criteria forthe helium leak rate test is less than lXiO-7 Std. Cm4/S. ASTNStandard E427-71t testing for leaks using the halogen leak detection statesthat, ". . . * ce has shown that, at the same pressures, gas leaks

smaler tan XIO-3 td. Cu3/S will not show visible leakage of aliquid such as water . "Additionally, using the formula from Section7.1.6, of Z427-71, "Correlation of Test-Gas Leakage with Other Gases orLiquids at Different Operating Pressures," it has been determined that for

1. the postulated accident environment the anticipated leakage isinsignificant and well below the acceptance criteria as specified by themanufacturer (see reference 5).

'2Preparer/Date F. A. Plesic, 12/10/81

Reviewer/Date G. J. Malek, 12/10/81E44285. 05

EFFECTIVE* DATE

OCT 1984

WBN-NEB-68-23, R33Appendix 2, 133Sheet 2 of 3

Aging effects simulated by accelerated thermal aging are exclusive Of thosethat result from thermal cycling, normal radiation, and vibration. The RTDdesign contains no aging sensitive materials (materials consist ofstainless steel, platinum wire and magnesium oxide). The organic materialsin the c~ble and cable interface are epoxy (potting mat) and siliconvarnish (cable coating). The silicon varnish is only used as amanufacturing process to prevent the fiberglass insulation of the cablefrom fraying during manufacturing and is not required for operation of theRTD. The epoxy used has an activation energy level of .98 eV.

Westinghouse has performed an analysis that demonstrates that the RThsahead will not increase to the primary coolant temperature of 6500, towhich the probe is exposed. This analysis shows that the air velocity andthe ambient temperature of the area are sufficient to limit the temperatureof the RTD's head to approximately 2000,. This was determined by the useof forced convection heat transfer equation (see reference 6).

Accelerated thermal aging was used to simulate the thermal aging during theRTD's installed life. Arrhenius calculation is the method we used torelate the accelerated thermal aging from the test report to the thermalaging in the actual service.

By the use of the following modified Arrhenius equation:

In (ts/ta) - Q/K (1/Ta - 1/Ta)to- ta e Q/K (1/Ta - 1/Ta)

where: ta - 11 daysQ - .98 eVK - .8617 X 10-4 eVilTo - 200OF - 930C - 3660KTa - 40OOF - 2040C - 4770K

Using these values ts - 15196.4 days - 41.6 years

When these RThs were tested they were sealed with Conax penetrationfittings. To ensure that these RTDs are fully qualified they must besealed with Conax, seals or equal. See reference 4 for the qualification ofthe seals.

To simulate HELB the RThs were tested at 4200, for 1 hour and then thetemperature ramp was decreased to 2500, for 16 days. This simulated theHELB event and poataccident in-containment condition for 100 days.

Based on the temperature and pressure capability of the hydrostatic hose,its stainless steel construction, the conservative helium leak rate testapplied to each lTD and the information documented in the report theselTD's are qualified for 40 years life plus 100 days accident.Additionally, the lTD leads terminate to the field cable above the maximupostaccident flood level thereby precluding a submergence problem with thelTD termination.

Preparer/Date F. A. Plesic, 12/10/81

Reviewer/Date G. J. Halek. 12/10/81 AlIjJVfEE44285.05

J4.A

0.

Reference:

WCAP-8687, Supp. 2-EO6A, Revision 2 (NEB 830829 359)Environmental Drawing 47E235-42EN DES Calculation -0588 Cat. and Open Time (NEKB 840515 230)EQS -WBN-EEB-CSC- 1Memo to NEKB files (later)Westinghouse Cal-note SEC-OSA-1242-CO - On file at Westinghouse.

Preparer/Date F. A. Plesic, 12/10/81 o q"'4'<

Reviewer/Date G. J. Malek, 12/10/81 výAý

E44285.05

DATEGOT 1-1-34

WBN-NEB-68-23, 13Appendix 2, R3Sheet 3 of 3

Revision 01 02 0. Unit No. IPBN AWL W9."~eQSN.wiF F

Preprer/ave P. A. Plesic, 12/10/81 6/1/83 6/5/84 ;Y1'~" TVA ID No. _____

RKW DLK &A See Appendix 1Reviewer/Date G. J. Malek, 12/10/81 6/2/83 6/5/84 014hol __________

WEN EQUIPMENT QUALIFICATION SHEET (EQs)

Manufacturer and Model No. Rosemount 176 KPVerification of Table Information (Table 3.11-4)

X Equipment Type - The equipment has been identified as per TVA IDnumber designations (such as MOV, SOy).

X Location - The location has been identified (such as, inside primarycontainment, annulus, individually cooled rooms, general spaces, orarea affected by HELB outside primary containment).

X Component -A unique TVA ID number has been assigned (such as1-FSV-68-308).

X Function - A functional description of the component has been given(such as steam generator blowdown).

X Contract No., Manufacturer, and Model No. -The contract number,manufacturer, and model number have been given..7 Abnormal or Accident Environment -All abnormal or accidentenvironmental conditions applicable to this equipment have beenidentified either in tables or by references to figures from tables.

X Environment to Which Qualified - The environment to which theequipment has been qualified is addressed in either the tables orthe environmental analysis attached.

X Category - A category of a, bp c, or d has been defined for theequipment.

X Operation and Accuracy Required and Demonstrated - The operation andI accuracy required and demonstrated have been defined.Qualification Status (check if applicable, NA if not)

Qualified Life (If equipment is qualiie, indicate the qualifiedlife with a numerical entry): 5 ears

X Qualification Report and Method - A qual~ification report and themethod of qualification has been identified on the Table Input DataSheet (TIDS).

K Environmental Analysis - An environmental analysis has been done,attached to the EQS, and independently reviewed by the responsibleorganization.

N/A Qualification by Similarity (if applicable) - A justification forqualification by similarity is attached to the EQS considering allthe above factors and referenced to the appropriate tables.

X Qualification of Several Exact Components (if applicable) - When anEQS is used for more than one item, a list of all exact componentsis given as an appendix with all references to appropriate tableswith justification for qualification considering all the above factors.

N/A interim Qualification (if applicable) - (Open item) - Component hasbeen determined to be qualified only for a limited interim LUoperation, an NCR has been written, and plan of action has been>determined to yield a qualified component. LTerm of Interim Qualification -.NCR No.

P__ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _

N/A Unqualified Component - (open item) - (If applicable) - Componenthas been determined to be unqualified; the following is attached to L CEQS: NCR number, reason for nonqualification, and justification of .continued operation. LA.NCR No. ________________

E64 156.06 I

Revision 01 02 03. Uni t No. I and 2PIN AWL J1 "e' EQS No. WBN-NEB-62-26

Preparer/Date Felicia A. Plesik 12/3/81 6/l/83 5/25/84 ')/,1V$ TVA ID No.RIW DLK AWLT-62-!W

Reviewer/Date George A. Malek 12/3/81 6/3/83 5/25 /84'I#5 LT-62-242

WEN EQUIPMENT QUALIFICATION SHEET (EQS)

Manufacturer and Model No. Barton 752Verification of Table Information (Table 3.11-7 and -8)

X Equipment Type - The equipment has been identified as per TVA IDnumber designations (such as MOV, SOy).:

X Location - The location has been identified (such as, inside primarycontainment, annulus, individually cooled rooms, general spaces, orarea affected by HELB outside primary containment).

X _Component -A unique TVA ID number has been assigned (such as1-FSV-68-308).

X Function - A functional description of the component has been given(such as steam generator blowdown).

X Contract No., Manufacturer, and Model No. -The contract number,manufacturer, and model number have been given.

X Abnormal or Accident Environment -All abnormal or accidentenvironmental conditions applicable to this equipment have beenidentified either in tables or by references to figures from tables.

X Environment to Which Qualified - The environment to which theequipment has been qualified is addressed in either the tables orthe environmental analysis attached.

X Category - A category of a, b, c, or d has been defined for theequipment.

X Operation and Accuracy Required and Demonstrated - The operation andaccuracy required and demonstrated have been defined.

Qualification Status (check if applicable, NA if not)Quýalified Life (I-f equipment is qualified, indicate the qualifiedlife with a numerical entry): 40 years

X Qualification Regort and Method - A qualification report and themethod of qualification has beesn identified on the Table Input DataSheet (TIDS).

X Environmental Analysis - An environmental analysis has been done,attached to the EQS, and independently reviewed by the responsibleorganization.

NA Qualification by Similarity (if applicable) - A justification forqualification by similarity is attached to the EQS considering allthe above factors and referenced to the appropriate tables.

X Qualification of Several Exact Components (if applicable) - When anEQS is used for more than one item, a list of all exact componentsis given as an appendix with all references to appropriate tableswith justification for qualification considering all the above factors.

NA Interim Qualification (if applicable) - (Open item) - Component hasbeen determined to be qualified only for a limited interim Loperation, an NCR has been written, and plan of action has been Ldetermined to yield a qualified component.>Term of Interim Qualification ___________________ UJNCR No. J

NA Unqualified Component - (Open item) - (if applicable) - Component Uhas been determined to be unqualified; the following is attached to LUEQS: NCR number, reason for nonqualification, and justification of L L.0Ccontinued operation. LL..NCR No. ________________

E84145.02

WBN-NEB-62-26, Rev 3Appendix 1, Rev 3Sheet 1 of 2

The subject transmitters are qualified based on WCAP 8587 supplement IQualification Data Package, ESE-4, Rev 6, and WC&P 8687, supplement 2 ZQTR-EO4A,Rev 2. The accident conditions to which they are subject are only slightly moresevere than the normal ambient conditions:

Normal Abnormal Accident Qualified

Peak temperature (O 104 110 125 130Peak pressure (lb/in g) ATM ATM ATM ATMPeak humidity M1 80 90 100 95Radiation (rads) 5 x 10 2 (40 yr) N/A 10 4 1 x 10 5

The slightly elevated conditions which result from the DBE are very short term.All ambient conditions have returned to normal by the end of 24 hours. Eachcondition is evaluated separately below.

* Temperature

The accident temperature is only 150? higher than the maximum nonaccidenttemperature of 1100?. This condition only exists for about 3 minutes. Sincethe transmitters are specified to 1300F, the accident transient is consideredinsignificant.

Pressure

Since the pressure transient is so slight (.02 lb/in2a over atmosphere)during accident condition that accident transient is considered insignificant.

Humidity

While the electronics are not hermetically sealed, the humidity transient isshort. The 1001 rh occurs at 0.5 seconds into the accident and it has returnedto normal (801) by 24 hours. The transmitter will be protected from thehumidity by its weatherproof case. Since the transmitter is specified to 951,this transient is also considered insignificant.,

Radiation

The amount of radiation to which the transmitter will be exposed is negligibleand will not have an affect on its ability to operate (see generic positionsection 4.1.3 of EQrR-9O4A and section 2.10.3.1 of ESE-EQDP-4).

Based on the above discussion, these transmitters are judged to be qualified forat least 40 years.

Preparer/Date: Felicia A. Plesik, December 3. 1981

Reviewer/Date: George A. Malek, December 3, 1981+

E84145.02

EFFECTIVEDATE

1h OGT 10034

A

A

'1

WBN-NEB-62-26, Rev 2Appendix 1, Rev 2Sheet 2 of 2

References:

1. EN DES Calculation -0588 Cat, and Oper. Times (NEB 840515 227)

2. Environment Drawing 47E235 - 52, 53

3. IWCAP-8687, Supplement 2 - EQTR-E04A; Barton Differential PressureTransmitter - Qualification Group B, Rev 2 (NEB 840807 358)

4. WCAP-8587, Supplement 1 - EQDP-ESE-4; Differential Pressure Transmitter -Qualification Group B, Rev 6 (NEB 840807 357)

Preparer/Date:

Reviewer/Dat e:

Felicia A. Plesik, December 3, 1981 meý~l-

George A. Malek, December 3, 1981 ~4IMIS.

E84145.02

EFFECTIVEDATE

OCT 13134

Revision 01 02 03 Unit No. 1Prprr/aeAWL JfA ' EQS No. WEBN-NEB--68-733

Peae/aePaulB. Nesbitt 6/13/83 5/29/84 1//1ft9 TVA ID No. _____

Reviewer/Date Ronald K. White 6/14/83 See18 &pedi

WBN EQUIPMENT QUALIFICATION SHEE (EQS)

Manufacturer and Model No. Minco S8809, S8810Verification of Table Information (Table 3.11-4)

X Equipment Type - The equipment has been identified as per TVA IDnumber designations (such as NOV, SOY).

X Location - The location has been identified (such as, inside primarycontainment, annulus, individually cooled rooms, general spaces, orarea affected by HELB outside primary containment).

X Component -A unique TVA ID number has been assigned (such as1-FSV-68-308).

K Function - A functional description of the component has been given(such as steam generator blowdown).

X Contract No., Manufacturer, andModel No. -The contract number,manufacturer, and model number have been given.

X Abnormal or Accident Environment -All abnormal or accidentenvironmental conditions applicable to this equipment have beenidentified either in tables or by references to figures from tables.K Environment to Which Qualified - The environment to which theequipment has been qualified is addressed in either the tables orthe environmental analysis attached.

X Category - A category of a, b, c. or d has been defined for theequipment.

X Operation and Accuracy Required and Demonstrated - The operation andaccuracy required and demonstrated have been defined.

Qualification Status (check if applicable, NA if not)Qualified Life (If equipment is qualified, indicate the qualifiedlife with a numerical entry): 28 years

X Qualification Report and Method - A qualification report and themethod of qualification has been identified on the Table Input DataSheet (TIMS).

X Environmental Analysis - An environmental analysis has been done,attached to the EQS, and independently reviewed by the responsibleorganization.

N/A. Qualification by Similarity (if applicable) - A justification forqualification by similarity is attached to the EQS considering allthe above factors and referenced to the appropriate tables.X Qualification of Several Exact Components (if applicable) - When anEQS is used for more than one item, a list of all exact componentsis given as an appendix with all references to appropriate tableswith justification for qualification cons idering all the above factors.N/A Inei ulfcto (if applicable) - (Open item) - Component hasbeen determined to be qualified only for a limited interimoperation, an NCR has been written, and plan of action has been UJdetermined to yield a qualified component.Term of Interim Qualification___________________

gjNCR No.

has been determined to be unqualified; the following is attached to U<EQS: NCR number, reason for nonqualification, and justification of U..10continued operation. UNCR No. LU_____________E44 150.02 L~

WBN-NEB-68-33, Rev. 2Appendix 1, Rev. 2Sheet 1 of I

This EQS and

CoMponent

TE-68-373

TE-6 8-3 77

TE-68-378

TE-68-379

TE-68-380

TE-68-384

TE-68-385

TE-68-386

TE-68-376TE-68-3 83

its appendices apply

MFRIModeI No.

Minco/S8809

Mincof S8809

Mincof 58809

Minco/S8809

Minco/S8809

Minco/S8809

Mincof 58809

Minco/S8809

Minco/S8810Minco/S8810

to the following components:

Description

Reactor Level Capillary Tube TemperatureCompensation

Reactor LevelCompensation

Reactor LevelCompensation

Reactor LevelCompensation

Reactor LevelCompensationReactor LevelCompensation

Reactor LevelCompensation

Reactor LevelCompensation

Reactor LevelReactor Level

Capillary Tube Temperature

Capillary Tube Temperature

Capillary Tube Temperature

Capillary Tube Temperature

Capillary Tube Temperature

Capillary Tube Temperature

Capil~lary Tube Temperature

Temperature CompensationTempearture Compensation

Preparer/Date Paul B. Nesbitt 6/13/83

Reviewer/Date Ronald K. White 6/14/83

E44150.02

#d izoi-

EFFECTIVEDATE

OCT 1384

WBN-NEB-68-33, R2Appendix 2, R2Sheet I of 3

These lTDs are qualified by type testing as described in Westinghouse'stest reports WCAP-8687 supplement 2-E42A and WCAP-8587, EQDP-ESE-42.

These RTDs are located inside containment and are required to meet the.1 ~followingenvironmental condition:

Normal Accident*Temperature FO) 120 327

Pressure (psia) 14.7 26.4Humaidity MZ 8o 100Chemical Spray (ppm) NA72008 p 8.2) (Boron)Radiation (rads) 2x10 (40 yr) lxlO

The RTDs are qualified for the following environmental condition:

Temperature - 420 F (peak)Pressure - 75 psiaHumidity - 100%Chemical Spray PO~5 (ph 10.7)Radiation - l.6x10 rads

Acceleration thermal aging was used to simulate the thermal aging duringthe RTD's installed life and during an accident condition.

The following is a list of organic materials contained in the lTD and theiractivation energy values:

hypalon - 1.07 eVethylene propylene rubber (EPR) - 1.09 eVepoxy - .97 eV

By use of the following modified Arrhenius equation (reference 5):

ln (ta/ta) - 0/K (1/Ta - 1/Ta)

to- ta E ?'/K (1/Ta - 1/Ta)

where for installed life:

ta Accelerated aging time - 504 hours0 -Activation energy (lowest) - .974zVK -Boltzman's Constant - .8617 z 10 eV/KTo - Normal service temperature - 120OF - 322'0KTa - Accelerated aging temperature - 250OF -393 0K

Preparer/Date Paul B. Nesbitt 6/13/83 Sl~'9 ig/Y

2 Reviewer/Date Ronald K.-White 6/14/83E44150.02

EFFECTIVEDATEIOCT 10

WBN-NEB-68-33, R2A Appendix 2, R2

Sheet 2 of 3

0: Using the above values from the test report into the Arrhenius equation,the normal service time is determined to be:

ts - 278823.8 hours or 31.8 years

The test temperature peaked at 42007 and vas maintained at an average of340OF for about 20 minutes, then gradually reduced to 22507 by 24 hours andmaintained there for 12 more days. Using an activation energy of .88 eVand an integrated temperature of 16507, this demonstrates a 4--monthpostaccident, harsh environment capability (reference 1).

One RTD out of the four exhibited unacceptably low insulation resistanceduring the high energy line break (HELB) simulation. After several testsat the manufacturer's test facility the problem was found to be a faultyweld. This is not a difficult weld to make and the materials are chosen forcompatibility. Since the other three units did not have any faulty welds,this is considered a random failure.

Another anomaly was noticed after the seismic testing. The lead wireinsulation was found to be cracked and brittle in several places. Afterexamination, the cause was concluded to be extensive handling prior to andduring testing. To prove that the damage was not due to thermal aging,radiation and seismic testing, a complete test sequence was performed on adummy RTD and several samples of lead wire. The tests were identical tothe original tests. Care was taken to prevent excessive handling duringthe'test sequence. The results of these tests are contained in appendix Aof reference 1. Although there was some slight discoloration of the leadwire insulation, no cracks were observed and all insulation resistancemeasurements were acceptable. Based on the test results, it was concludedthat the initial damage was not due to the original testing but toexcessive stress during handling prior to and during the testing.

After the discovery of the insulation cracks, during the original testing,* it was decided that the RTDs would be subjected to the BELE simulation withthe cracked portion of the wiring located outside the chamber. The HELEtest was then completed.

Based on the above discussion the subject RTDs are considered to be fullyqualified for 28 years (102 margin) plus four months of postaccident

* conditions).

Preparer/Date Paul B. Nesbitt 6/13/83

MIdReviewer/Date Ronald K. White 6/14/83

E44150. 02

DA7TEOCT 1z;0

Preparer/Date Paul B. Nesbitt 6/13/83

Reviewer/Date Ronald K. White 6/14/83

E44150.02

nEFFECTIVEDATEOCT 18

WBN-NEB-68-33, R2Appendix 2, R2Sheet 3 of 3

References:

I. WCAP-8687, Supp. 2-I42A - "Surface-mounted RTDs" (NEB 831015 353), Rev 0

2. WCAP-8587, EQDP-ESE-42 - RTD. Surface-Mounted (NEB 831015 354), Rev 0

3. Environment Drawing -47E235-42

4. EN DES Calculation -0588 Cat. and Oper. Times (NIB 840515 230)

5. EPRI NP-1558 - "A Review of Equipment Aging Theory and Technology

6. ECN 4398 (wBP 831104 500)

Reviewer/Date F. a. Plesic, 12/2/81

02AWL

5 /30/84

03

RKW DLK6/4/83 6/1/84_PAV

Unit No. 1EQS No. WBN-NEB-XX-37TVA ID No.

See Appendix

I WBN EQUIPMENT QUALIFICATION SHEET (EQS)

Manufacturer and Model No. Limitorgue (see Appendix 1)verification of Table Information (Table 3.11-8

SX Equipment Type - The equipment has been identified as per TVA IDS~number designations (such as NOV, SOy).

X Location - The location has been identified (such as, inside primarycontainment, annulus, individually cooled rooms, general spaces, orarea affected by liSLE outside primary containment).

X CoMonent,-A unique TVA ID number has been assigned (such as1-FSV-68-308).

X Function - A functional description of the component has been given(s-uch as steam generator blowdovo).

X Contract No., Manufacturer, and Model No. -The contract number,manufacturer, and model number have been given.

X Abnormal or Accident Environment -All abnormal or accidentenvironmental conditions applicable to this equipment have beenidentified either in tables or by references to figures from tables.

K Environment to Which Qualified - The environment to which theequipment has been qualified is addressed in either the tables orthe environmental analysis attached.

X Category - A category of a, b, c, or d has been defined for theequipment.

X Operation and Accuracy Required and Demonstrated - The operation andaccuracy required and demonstrated have been defined.

Qualification Status (check if applicable, NA if not)Qualified Life (If equipment is qualified, indicate the qualifiedlife with a numerical entry): 40 years

K Qualification Report and Method - A qualification report and themethod of qualification has been identified on the Table Input DataSheet (TIDS).

X Environmental Analysis - An environmental analysis has been done,attached to the EQS, and independently reviewed by the responsibleorganization.

X Qualification by Similarity (if applicable) - A justification forqualification by similarity is attached to the EQS considering allthe above factors and referenced to the appropriate tables.

X Qualification of Several Exact Components (if applicable) - When anEQS is used for more than one item, a list of all exact componentsis given as an appendix with all references to appropriate tablesvith justification for qualification considering all the above factors.

N/A Interim Qualification (if applicable) - (Open item) - Component hasbeen determined to be qualified only for a limited interimoperation, an NCR has been written, and plan of action has been Ldetermined to yield a qualified component. lTerm of Interim Qualification >____________q_______NCR No. -Ud

N/A Unqualified Component - (open item) - (If applicable) - Component I- I-has been determined to be unqualified; the following is attached to kJEQS: NCR number, reason for nonqualification, and justification of LU Jcontinued operation. LlOC-NCR No. ________________ (D.

E64151 .03 L

Revision 01PBN

Preparer/Date T. W. Sohoene, 11/23/81 6/2/83

WBN-NEB-XX-37, Rev. 3Appendix 1, Rev. 3Sheet 1 of 2

COMPONENT LIST

ManufactUrer: LimitorqueComponents: Valve OperatorsLocation: Outside Containment

Copnn Number Model No.

FCV-62-63 SB-00FCV-62-90 SB-00FCV-62-91 SB-00FCV-62-98 SB0FCV-62-99 SMB-00FCV-63-1 9B-2FCV-63-3 SMB-00FCV-63-4 SMB-00FCV-63-5 53-00FCV-63-6 SB-00FCV-63-7 SB-00FCV-63-8 SB-00FCV-63-11 SB-00FCV-63-22 SBD-00FCV-63-25 SBD-00FCV-63-26 SBD-00FCV-63-39 SBD-00FCV-63-40 SBD-00FCV-63-47 SB-00FCV-63-48 5B-00FCV-63-93 SBD-2FCV-6-94 SBD-2

FCV-63-152 SB-00FCV-63-153 SB-00FCV-63-156 SBD-00FCV-63-157 SBD-2FCV-63-172 SB-2FCV-63-175 SMB-00OFCV-63-177 SB-00FCV-72-2 93-0

Preparer/Date T. W. Shoene, 11/23/82

Reviewer/Date F. A. Plesic, 12/2/81

E64151 .03

EFFECTIVEDATE

OCT 1984

WBN-NEB-XX-37, Rev. 3Appendix 1, Rev. 3Sheet 2 of 2

COMPONENT LIST

Manufac turer: LimitorqueComponents: Valve OperatorsLocationi: Outside Containment

Component Number Model No.

PCV-72-39 SB-OFCV-72-40 SI-O00FCV-72-41 SB-00PCV-74-3 S3-2

1FCV-74-12 K-009

FCV-74-21 S3-2IFCV-74-24 SHB-0OO pFCV-74-33 SB-00FCV-74-35 SB-00LCV-62-132 SB-00LCV-62-133 SB-00LCV-62-135 SB-00LCV- 62-136 SB-00

iThese valve operators have recently been installed and documentation isinadequate for qualification. See NCR WBNNEB8413.

EFFECTIVEDATE

OCT 15134

Preparer/Date T. W,. Shoene, 11/23/82 Il i6Reviewer/Date P. A. Plesic, 12/2/81 0;Y/4jY1

E64151 .03

Revision 01 02 03 Unit No. IPBN AWL 6J44 EQS No. WBN-NE1--3BMPreparerfDate F. A. Plesic 11/23/81 6/6/83 5/30/84 -t1/V1_4 TVA ID No.RKW DLK aSee Appendix 1Reviewer/Date G. T. Malek 12/1/81 -6/8/83 5/31/84 Mg 9 __________

WIN EQUIPMENT QUALIFICATION SHEET (EQS)

Manufacturer and Model No. Limitorgue (See Appendix 1)Verification of Table Information (Table 3.11-8 R)

X_ Euipment Type - The equipment has been identified as per TVA IDnumber designations (such as NOV, SOy).

X Location - The location has been identified (such as, inside primarycontainment, annulus, individually cooled rooms, general spaces, orarea affected by IlELB outside primary containment).

X _Component -A unique TVA ID number has been assigned (such as1-FSV-68-308).

X Function - A functional description of the component has been given(such as steam generator blowdown).

X Contract No., Manufacturer, and Model No. -The contract number,manufacturer, and model number have been given.

X Abnormal or Accident Environment -All abnormal or accidentenvironmental conditions applicable to this equipment have beenidentified either in tables or by references to figures from tables.

X Environment to Which Qu!alified - The environment to which theequipment has been qualified is addressed in either the tables orthe environmental analysis attached.

X Category - A category of a, b. c, or d has been defined for theequipment.

X Operation and Accuracy Required and Demonstrated - The operation andaccuracy required and demonstrated have been defined.

Qualification Status (check if applicable. NA if not)Qualified Life (If equipment is qualified, indicate the qualifiedlife with a numerical entry): 4years

X Qualification Report and Method -A qiualification report and themethod of qualification has been identified on the Table Input DataSheet (TIDS).

X Environmental Analysis - An environmental analysis has been done,attached to the EQS, and independently reviewed by the responsibleorganization.

X Qualification by Similarity (if applicable) - A justification forqualification by similar-ity is attached to the EQS considering allthe above factors and referenced to the appropriate tables.X Qualification of Several Exact Compon ents (if applicable) - When anEQS is used for more than one item, a list of all exact componentsis given as an appendix with all references to appropriate tableswith justification for qualification considering all the above factors.N/A Interim Qualification (if applicable) - (Open item) - Component hasbeen determined to be qualified only for a limited interim LUJoperation, an NCR has been written, and plan of action has been>determined to yield a qualified component. coTerm of Interim Qualification ____________________

N/A Unqualified-Component -(Open item) -Ifapplicable) - Compo-nent Uhas been determined to be unqualified; the following is attached to L.EQS: NCR number, reason for nonqualification, and justification of L- C)continued operation.

NCR No. _______________

E64151 .04

WBN-NEB-XX-38, Rev. 3Appendix 1, Rev. 3Sheet 1 of I

COMPONENT LIST,

Manufactuter: LimitorqueComponents: Valve OperatorsLocation: RER Valve Room (also called Containment Sump Room)

Comeonent No.

FCV-63-72FCV-63-73FCV-72-44FCV-72-45

Model1 No.

SB-3SB-3SB-0SB-0

2I'J

g3

Preparer/Date T. W. Shoene, 11/23/81 qAe9ý*

Reviewer/Date F. A. Plesic, 12/3/81

164151.04

EFFECTIVEDATE

OCT 13304

WBN-MEB-XX-38, Rev 2Appendix 2, Rev 2Sheet I of 2

EQUIPENZr QUALIFICATION

S~ummary

All valve operators listed in appendix 1 are equal to or greater incapability than the valve operators discussed irn EQS WBN-NEB-XX-37(revision 1). Furthermore, the environmental conditions required andlisted below are less severe. Hence, qualification is obtained perWBN-NEB-XX-37.

Identification

These Limitorque valve operators are located in the RHR valve rooms,which are also called the containment sump rooms. These rooms areadjacent to but out of the containment; they are enclosed with noHVAC, and they have a unique accident environment. The operators havebeen field verified, and they have been identified on the properdrawings.

Environmental Conditions

Temperature (OF)Pressure (psia)Relative humidity M%Radiation (rud)Chemical Spray

Normal

110(1)

3 .5 x 10~N/A

Accident

190Atm100 71 x 10~

These valve operators are not really subject to HELD outsidecontainment, in that temperatures does not rise coincident with theoccurrence of high humidity. Nevertheless, the discussion assumes allworst conditions occur simultaneously.

than 1% of life.

Preparer/Date

Reviewer/Date

E~43153.02

T. W. Shoene. November 23. 1981

Felicia A. Plesic. December 3. 11981,~~/A ~

IEFFECTIVEOCT 1984

(1) Effetiv less

IRI

WBN-NEB-XX-38, Reva 2Appendix 2, Rev 2Sheet 2 of 2

Qualification

Qualification discussion is included by reference to EQS WBN IMB-XX-37(revision 0). It should be noted that the manufacturer has verifiedthat report B0003 pertains to FCV-72-44 and -45 and report 600456pertains to FCV-63-72 and -73.

These valves are qualified for 40 years.

Reference

Limitorque Report 30119, "Qualification Type Test Report of Multi-Point Terminal Strips for Use in Limitorque Valve Actuators" (NEB840823 353).

Preparer/Date T. W. Shoene, November 23, 1981 6Y4(Reviewer/Date Felicia A. Plesic, December 3, 1981 101411Y

E43153-02

'EFFECTIVE-D A T EO CJNT 1934

WBN-NEB-68-44, RIAppendix 1, RISheet 1 of 1

These RTDs are qualified by test reports as described in Westinghouse test

following environmental condition:

Normal Accident

Temperature (OF1 120 327Pressure (lb/in a) 14.7 26.4Humnidity M1 80 100Chemical Spray (ppm boron) N/A 2000Radiation (reds) 2x107 12108

The RTDs are qualified for the following environmental condition:

Temperature - 4200?Pressure - 75 lb/in2 g9Humidity - 1001Chemical Spray - 2750 prboron ph 10.7Radiation - l.5x10 rads

The qualified life is greater than 20 years (40 plus years based on actualArhennius calculations based on an ambient temperature of 500C and a500C temperature rise due to the Reactor Coolant System temperature).The qualified life is limited by the expected radiation during 20-yearlife and the Design Based Event.

References

1. WCAP-8587l EQDP-ESE-72. WCAP-86879 Supplement 2-EQTR-EO7A3. Environmental Drawing 47E235-424. EN DES Calculation -0588 Cat, and Oper. Time (NEB 840515 230)5. EQS-WBN-EEB-CSC- 1

Preparer/Date P. B. Nesbitt, 6/26/84

Reviewer/Date R. K. White, 6/16/83e

E44153. 14 1EFFECTIVEk OCT 1984

'I

4

J

02 03 Unit No. 1EQS No. WBN-NEB-XX-47

__________TVA ID No._____See Appendix 1

WIN EQUIPMENT QUALIFICATION SHEET (EQS)

Manufacturer and Model No. Barton 764, Lot 7Verification of Table Information (Table 3.11-4)

X Equipment Type - The equipment has been identified as per TVA IDnumber designations (such as HOV, SOy).

X Location - The location has been identified (such as, inside primarycontainment, annulus, individually cooled rooms, general spaces, orarea affected by HELB outside primary containment).

X_ Copnn -A unique TVA ID number has been assigned (such asl-F&SV-83O8).

X Function - A functional description of the component has been given(such as steam generator blowdown).

X Contract No., Manufacturer, and Model No. -The contract number,manufacturer, and model number have beeon given.

X Abnormal or Accident Environment -All abnormal or accidentenvironmental conditions applicable to this equipment have beenidentified either in tables or by references to figures from tables.

X Environment to Which Qualified - The environment to which theequipment has been qualified is addressed in either the tables orthe environmental analysis attached.

X_ Category - A category of a, b, c, or d has been defined for theequipment.

X_ Operation and AccuracyRequired and Demonstrated - The operation andaccuracy required and demonstrated have been defined.

Qualification Status (check if applicable, NA. if not)Qua!lified Life (If equipment is qualified, indicate the qualifiedlife with a numerical entry): 6 yrs

X _Qualification Report and Method - A qualification report and themethod of qualification has been identified on the Table Input DataSheet (TIDS).

X Environmental Analysis - An environmental analysis has been done,attached to the EQS, and independently reviewed by the responsibleorganization.

N/A Qualification by Similarity (if applicable) - A justification forqualification by similarity is attached to the EQS considering allthe above factors and referenced to the appropriate tables.

X Qualification of Several Exact Components (if applicable) - When anEQS is used for more than one item, a list of all exact componentsis given as an appendix with all references to appropriate tableswith justification for qualification considering all the above factors.

N/A Interim Qualification (if applicable) - (Open item) - Component hasbeen dtermined to be qualified only for a limited interim -operation, an NCR has been written, and plan of action has been LJJdetermined to yield a qualified component.>Term of Interim Qualification___________________NCR No.

N/A Unqualified Component - (Open item) - (if applicable) - Component uhas been determined to be unqualified; the fol~lowing is attached to L"IEQS: NCR number, reason for nonqualification, and justification of Li.continued operat ion.

ILlNCR No. __ _ _ _ __ _ _ _ __ _ _ _ _E64158 .08 I

Revision 01

Preparer/Date Alan W. Lewis 6/7/84 '/j1

Reviewer/Date David L. Kirby 6/7/84 ,,4& ,

C7)

WBN-N'EB-XX-47, RIAppendix 1, RISheet 1 of 1

Ccmponents

FT-1-3AFT- i-s3FT-i-i OAFT-i-WEBFT-1-21A

*FT-1-21BFT-1-28AFT-1-28B

* LT-3-39LT-3-43LT-3-52LT-3-97LT-3-98LT-3-110LT-63-180LT-63-181LT-63-182LT-63-183LT-68-320LT-68-33 5LT-68-339

This is the cambination of EQS's NEB-XX-12 and 15, NEB-68-199 !IEB-63-28,and NEE-3-30.

*This tranfsuitter is located below the flood level but it is not required to Iioperate for the event that produces this flood level.

EFFECTIVEDATE

OCT 1984

Preparer/Date Alan W. Lewis 6/7/84

Reviewer/Date David L. Kirby 6/7/84

E64158.08

3

Normal Accident

Temperature (OF)Humidity (% 2Pressure (lb/in a)Radiation (rads)Chemical Spray (pp. boron)Submergence

1208014.7 72x 10N/AN/A

327100

(4 yu)26.4 7(40 rs)2xl0 (100 days)

2000 ph 8.35N/A

The transmitters are qualified to the following environmental conditions:

TemperatureHumidityPressureRadiationChemical Spray

-42001F

-1002

-57 lý/in2g- xlO rads-2500 ppm, (boron) ph 10.7

Accelerated thermal aging was used to simulate the thermal aging during thetransmitter's installed life. Arrhenius calculation is the method we ugedto relate the accelerated thermal aging from the report to the thermalaging in the actual service.

The following is a list of organic material containedand their activation energy valves:

TefzelNylonSylgard No. 170Red RUTEpoxy Laminated

NINA Graded MRSilicone Oil 550Epoxylete 6203RTV 102-SilaticLoc tite

0-ringswire insulationtransistor padspotting materialsleeving

board materialbellows fluid

sensor assembly

.92.91.50

1.251.*16

.96

.921.65

.80.77

in the transmitter

eVeVeVeVeV I EF:FECTIVjEE,eV 0 DATE

eVOCT 1984Ou

Preparer/Date

Reviewer/Date

Alan W. Levis 617/84

David L. Kirbj 6/7/84

WBN-NEB-XX-47, 30Appendix 2, ROSheet I of 2

These transmitters are qualified by Westinghouse test reports WAP-8687,Supplement 2-EO3A, and UCAP-8587, Supplement 1-EQDP-ESE-3A.

These transmitters are located inside containment on an instrument rack atelevatio&*716 feet (transmitters are above flood level) and are required tomeet the following environmental conditions:

.4*

.4

I.

E64158.08

WBN-YEB-KX-47, RlAppendix 2, RlSheet 2 of 2

By the use of the following modified Arrhenius equation (reference 3):

in (ta/ta) - O/K (Ta-I/Ta)

to mt e'/K (1/Ta -1/Ta)

where: ta Accelerated aging time -1673 hours0 *Activation energy (lowest) .5204eV KK- Boltzman's Constant - .8617xl0 e/KTs - Normal service temperature -120% F - 3220KTa * Accelerated aging temperature - 125 0C - 398'0K

Using the above values from the teat report into the Arrheniua equation,the normal service time is determined to be:

ts- 52229.59 hr or 6 years

At the conclusion of the accelerated thermal aging, leakage through thedifferential pressure unit housings revealed 0-ring failure. Based oninformation from the 0-ring. manufacturer, it was determined that the agingtemperature was too high for the amount of time aged. Based on this, the

* internal 0-rings vere replaced and aged for 350 hours at 1250C. Thisshowed the internal 0-rings to have a qualified life of 22.4 years. It was'determined that to maintain this life the cover 0-ring must be replaced

* each time the transmitterf cover is removed, or every two years; this isbased on the fact that the transmitter was originally tested at 6 weeks at1250C with no failure.

Based on the test reports, HELB testing simulated a 4-month postaccidentperiod.

Eased on the discussion above, we concluded that these transmitters are* fully qualified for 6 years plus at least 100-day accident condition. As* part of our qualification maintenance program, the cover 0-rings will be

replaced at 2 years or every time the transmitter cover is removed.

References

1. WCAP-86879 Supplement 2-EO3A (NIB 840807 362) (Rev 2)2.* WCAP-8587, Supplement l-ZQDP-ESZ-3A (NEB 840807 361) (Rev 4)3. EPRI Report NP-1558 - A review of equipment aging theory and technology4. Environment drawing 47E235-425. EN DES Calculation - 0588 Cat. and Oper. Times (Systems 1, 3, 63, and

4 68)6. EN DES Calculation - TI-RPS-48 (NIB 830414 235)

Preparer/Date Alan W. Lewis 6/7/84 P 14

Reviewer/Date David L. KirbX 6/7/84E64158 .08 I'EFFECTIVE

DATEOCT 1934

Rev is ion 01 02 03 Unit No. 1R~1( ___N.____E-M"-

Preparer/Date Alan W. Lewis 6/7/84 /.d34TVA ID No.2Reviewer/Date David L. Kirby 6/7/84Se

j 'WBN EQUIPMENT QUALIFICATION SHEET (EQS)

Manufacturer and Model No. Barton 763, Lot 7Verification of Table Information (Table 3.11-8)

X Equipment Type - The equipment has been identified as per TVA IDnumber designations (such as MOV, SOy).

X Location - The location has been identified (such as, inside primarycontainment, annulus, individually cooled rooms, general spaces, orarea affected by HELB outside primary containment).

X Component -A unique TVA ID number has been assigned (such asl-FSV-68-308).

X Function -A functional description of the component has been given(such s steam generator blowdown).

X Contract No., Manufacturer, and Model No. -The contract numberpmanufacturer, and model number have been given.

X Abnormal or Accident Environment -All abnormal or accidentenvironmental conditions applicable to this equipment have beenidentified either in tables or by references to figures from tables.

X Environment to Which Qualified - The environment to which theequipment has been qualified is addressed in either the tables orthe environmental analysis attached.

X Caegr - A category of a, b, c, or d has been defined for the

X Operation and Accuracy Required and Demonstrated - The operation and-accuracy required and demonstrated have been defined.

Qualification Status (check if applicable, NA if not)Qualified Life (If equipment in qualified, indicate the qualifiedlife wiha numerical entry): 4.5 yrs

* X Qualification Report and Method - A qualification report and the* method of qualification has been identified on the Table Input Data

Sheet (TIDS).X Environmental Analysis - An environmental analysis has been done,

attached to the XQS, and independently reviewed by the responsibleorganization.

N/A Qualification by Similarity (if applicable) - A justification forqualification by similarity is attached to the EQS considering allthe above factors and referenced to the appropriate tables.

X Qualification of Several Exact Components (if applicable) - When anEQS is used for more than one item, a list of all exact componentsis given as an appendix with all references to appropriate tableswith Justification for qualification considering all the above factors.

N/A Interim Qualification (if applicable) - (Open item) - Component hasbeen determined to be qualified only for a limited interimoperation, an NCR has been written, and plan of action has been Ldetermined to yield a qualified component.>Term of Interim Qualification ___________________ 0)aNCR No. __ _ _ _ _ _ _ _ _ _ _ _ __ _ _ _ _ _ _ _ _ _ _ _ I

N/A Unqualified Component - (Open item) - (If applicable) - Component <has been determined to be unqualified; the following is attached to LU iEQS: NCR number, reason for nonqualificat ion, and justification of ILA.1

CDcontinued operation. U.NCR No. __ _ __ _ _ __ _ J

E64 158.11

WBN-NEB-XX-48, RiAppendix 1, RiSheet 1 of 1

Components

PT-1-9APT-1-9BPT-1 -20APT-1-20BPT- 1-12PT-1-23

This is the combination of EQS's NEB-1-20 and NEB-1-39.

Preparer/Date Alan W. Lewis

Reviewer/Date -David L. Kirby

E64 158.11

6/7/84

6/7/84

WBN-NEB-XX-48, RiAppendix 2, RiSheet 1 of 3

These transmitters areSupplement 2-EOlA, and

qualified by Westinghouse test reports WCAP-8687,WCAP-8587, Supplement 1-EQDP-ESE-1A.

These tranimitters are located outside containment at elevation 729 feetMNR) and are required to meet the following environmental conditions-:

Normal Accident

Temperature ( 0F)Humidity M% 2Pressure (lb/in a)Radiation (rads)Chemical Spray (ppm boron)Submergence

130 446 (Peak)50 100ATM 425.183.5x10 (40 yrs) N/AN/A N/AN/A N/A

The transmitters are qualified to the following environmental conditions:

TemperatureHumidityPressureRadiationChemical Spray

420 0!100% 2

5xl1O rads2500 ppm (boron) ph 10.7

Accelerated thermal aging was used to simulate the thermal aging during thetransmitter's installed life. Arrhenius calculation is the method we usedto relate the accelerated thermal aging from the report to the thermalaging in the actual service.

The following is a list of organic materialand their activation energy valves:

contained in the transmitter

EPTTefzelNylonSylgard No. 170Red HUTMEpoxy LaminatedNEMA Graded FRSSilicone Oil 550Epoxylete 6203RTV 102-SilaticLoctite

0-r ingswire insulationtransistor padspotting materialsleeving

board. materialbellows fluid

sensor assembly

Preparer/Date

Reviewer/Date

E64158.11

Alan W. Lewis 6/7/84

David L. Kirby 6/7/84

.92

.91

.501.251.16

.96.92

1.65.80.77

EFFECTIVE]D AItE

0OCT 193 84

WBN-NEB-XX-48, RlAppendix 2, RiSheet 2 of 3

By the use of the following modified Arrhenius equation (reference 3):

in (ts/ta) - 0/K (Ts-1/Ta)

ts- aO/N (1/Ts -1/Ta) EFFECTIV Ewhere: ta - Accelerated aging time -1673 hours OT 13

0 Activation energy (lowest) .50 4eV 0K- Boltzman's Constant = .8617x10 eV/KTs -Normal service temperature - 130 0F;327 0 K0Ta - Accelerated aging temperature - 125 0C-3980K

Using the above values from the test report into the Arrhenius equation,the normal service time is determined to be:

* ts - 39650.8 hr or 4.5 years

At the conclusion of the accelerated thermal aging, leakage through thedifferential pressure unit housings revealed 0-ring failure. Based oninformation from the 0-rings manufacturer, it was determined that the agingtemperature was too high for the amount of time aged. Based on this, theinternal 0-rings were replaced and aged for 350 hours at 1250c. Thisshowed the internal 0-rings to have a qualified life of 13.5 years. It wasdetermined that to maintain this life the cover 0-ring must be replacedeach time the transmitter cover is removed, or every two years, this isbased on the fact that the transmitter was originally tested at 6 weeks at125 0C with no failure.

Based on the test reports, HELB testing simulated a 4-month postaccidentperiod.

Due to the new information as reported in NCR WBMNB8403 (NEB 840803 851),a new analysis showed that the peak temperature reached 446w'? forapproximately 300 seconds. This peak is above the HELE tested temperature(about 260F) for these transmitters. To protect these transmitters, aninsulated blanket has been designed to enclose the transmitter. Thisblanket is constructed of a teflon-coated fiberglass covering surroundingType E glass fiber insulation. This covering will maintain the temperaturebelow the qualification temperature. A thermal analysis is being done toshow the temperature rise at the transmitter during a main steam linebreak.

Based on the discussion above, we concluded that these transmitters arefully qualified for 4.5 years plus at least 100 days accident condition.As part of our qualification maintenance program, the cover 0-rings will bereplaced at 2 years or every time the transmitter cover is removed.

* ~~Also the flexpak must be placed back around the transmitter any time it is IRremoved.

Preparer/Date Alan W. Lewis 6/7/84

Reviewer/Date Dai L irby/86/~7/84M71E64158.11

WBN-NEB-XX-48, Rl

Appendix 2, RiSheet 3 of 3

References

1. WCAP-8687, Supplement 2-EOlA Rev 2 (NEB 840807 359)2. WCAP-8587, Supplement l-EQDP-ESE-lA Rev 4 (NEB 840807 355)3. EPRI Report NP-1558 - A review of equipment aging theory and technology4. Environment drawing 47E235-765. EN DES Calculation - 0588 Cat. and Oper. Times (NEB 840515 219)

9

0

Preparer/Date

Reviewer/Date

Alan W. Lewis 6/7/84

David L. Kirby 6/7/84 31

E64158.11

E FF E CT IV EDATEj

OCT1 1984

Rev is ion

Preparer/Date Alan W. Lewis 6/8/84

01

Reviewer/Date David L. Kirb~y 6/8/84 ,/,I/g',

02 03 unit NO. . 1&2EQS No.. WBN-NEB-94-48TVA ID No.

See Ap-enTix-

WEN EQUIPMENT QUALIFICATION SHEET (EQS)

Manufactdrer and Model No. Control Pro.Verification of Table Information (Table 3.11-4)

X_ Equipment Type - The equipment has been identified as per TVA IDnumber designations (such as NOV9 SOy).

X Location - The location has been identified (such as, inside primarycontainment, annulus, individually cooled rooms, general spaces, orarea affected by HELB outside primary containment).

X _Component -A unique TVA ID number has been assigned (such as1-FSV-68-308).

X Function - A functional description of the component has been given( ýsuc~has steam generator blowdown).

X Contract No., Manufacturer, and Model No. -The contract number,manufacturer, and model niumber have been given.

X Abnormal or Accident Environment -All abnormal or accidentenvironmental conditions applicable to this equipment have beenidentified either in tables or by references to figures from tables.

X Environment to Which Qualified - The environment to which theequipment has been qualified is addressed in either the tables orthe enviroinmental analysis attached.

X Category - A category of a, b, c, or d has been defined for theequipment.

X Operation and Accuracy Required and Demonstrated - The operation andaccuracy required and demonstrated have been defined.

Qualification Status (check if applicable, NA if not)Qualified Life (If equipment is qualified, indicate the qualifiedlife with a numerical entry): N/

X _Qualification Report and Method - A qualification report and themethod of qualification has been identified on the Table Input DataSheet (TIDS).

X Environmental Analysis - An environmental analysis has been don 'e,attached to the EQS, and independently reviewed by the responsibleorganization.

N/A Qualification by Similarity (if applicable) - A justification forqualification by similarity is attached to th .e EQS considering allthe above factors and referenced to the appropriate tables.

X Qualification of Several Exact Components (if applicable) - When anEQS is used for more than one item, a list of all exact componentsis given as an appendix with all references to appropriate tableswith justification for qualification considering all the above factors.

X Interim Qualification (if applicable) - (open item) - Component hasbeen determined to be qualified only for a limited interimoperation, an NCR has been written, and plan of action has been Ldetermined to yield a qualified component.>Term of Interim Qualification 1st refuelingNCR No.

N/A_ Unqualified Component - (Open item) - (If applicable) - Co~mponenthas been determined to be unqualified; the following is attached toEQS: NCR number, reason for nonqaicton anf justification ofLLcontinued operation. quUalnado 1 LNCR No. _______________

E64160.01

ELi C7)

H-

~~Z1

WBN-NEB-94-48, Rev IAppendix 1, Rev 1Sheet 1 of 29

~1

I4

-i

I.4-4A

'-I

I

Preparer/Date

Reviewer/Date

Component

1-WTE-94- 12-WTE-94- 11-WTE-94-22-WTE- 94-21-WTE-94-32-WTE-94-31-WTE-94-42-WTE-94-41-WTE-94-52-WTE-94-51-WTE-94-62-WTE-94-61-WTE- 94-72-WTE-94- 71-WTE-94-82-WTE-94-81-WTE-94-92-WTE-94-91-WTE-94-102-WTE-94-101-WTE-94-1 12-WTE-94-1 11-WTE-94-122-WTE-94-1 21-WTE-94-132-WTE-94- 131-WTE-94- 142-WTE-94- 141-WTE-94- 152-WTE-94- 151-WTE-94-162-WTE-94- 161-WTE-94-172-WTE-94- 171-WTE-94-182-WTE-94-181-WTE-94-192-WTE-94-191-WTE-94-202-WTE-94-201-WTE-94-212-WTE-94-21I

1-WTE-94-222-WTE-94-221-WTE-94-232-WTE-94-231-WTE-94-242-WTE-94-241-WTE-94-252-WTE-94-251-WTE-94-262-WTE-94-26I-WTE- 94-272-WTE-94-271-WTE-94-282-WTE-94-281-WTE-94-292-WTE-94-291-WTE-94-302-WTE-94-301-WTE-94-312-WTE-94-3 11-WTE-94-322-WTE-94-32I-WTE-94-332-WTE-94-331-WTE-94-342-WTE-94-341-WTE-94-352-WTE-94-35I-WTE-94-362-WTE-94-36I-WTE-94-372-WTE-94-3 71-WTE-94-382-WTE-94-381-WTE-94-392-WTS-94-391-WTE-94-402-WTE-94-401-WTE-94-412-WTE-94--411-WTE-94-422-WTE-94-42

Alan W. Levis 6/8/84

David L. Kirby 6/8/84 ,,/iE64160.01

EFFECTIVEDATE

0 7ka 'D"3

WBN-NEB-94-48, Rev 1Appendix 1, Rev ISheet 2 of 2

Component

1-WTE-94-432-WTE-94-431-WTE-94-442-WTE-94-441-WTE-94-452-WTE-94-451-WTE-94-462-WTE-94-461-WTE-94-472-WTE-94-471-WTE-94-482-WTE-94-48I-WTE-94-492-WTE-94-491-WTE-94-502-WTE-94-5 01-WTE-94-5 12-WTE-94-5 11-WTE-94-5 22-WTE-94-5 21-WTE-94-532-WTE-94-5 3I-WTE-94-54

2-WTE-94-541-WTE-94-552-WTE-94-551-WTE-94-562-WTE-94-561-WTE-94-572-WTE-94-571-WTE-94-582-WTE-94-581-WTE-94-592-WTE-94-591-WTE-94-602-WTE-94-601-WTE-94-612-WTE-94-611-WTE--94-622-WTE-94-621-WTE-94-632-WTE-94-631-WTE-94-642-WTE-94-641-WTE-94-652-WTE-94-65

Attachment 1 contains the justification for interim operation. Thisjustification is contained in Westinghouse letter WAT-D-6168 (NEB 840827624).

Preparer/Date

Reviewer/Date

Alan W. Levis 6/8/84 p'I'

David L. Kirby 6/8/84 o/0I////&

E64160. 01

CDATEOEFCT

L34

1 61

I

Attachment 1

W'BN-NEB-94-48, R1

Watts Bar

Intirim Justification Position for theSeismic and Environmental Qualification of the

Incore Thermocouples, Connectors, Adapters andReference Junction Box(ESE-43 and ESE-44)

I

EFFECTIV ED AT E

G L OT 3,4

OZZ3G/Mi sc/8-84

The Class 1E thermocouples, connectors, and the reference Junction box locatedinside containment form part of a core exit temperature monitoring system tobe qualified for use during and after a design basis LOCA, MSLB or seismicevent. In addition to the accident environment to which components insidecontainment might be subjected, the thermocouple Junctions in the reactorvessel are to be qualified for operation in the event that a LOCA might leadto an inadeqdate core cooling (ICC). The OBE conditions to which thecomponents are to be qualified, therefore, include a 389.97 peak temperature

* I4SLB simulation (the Westinghouse generic profile up to 4207 providesadequate margin for the Watts Bar application) with caustic spray and, for the

*thermocouple measuring junctions, a 2200OF peak temperature inadequately*cooled core simulation (which provide adequate margin over the Watts Bar PCT

of 21717).

The WRO qualification program is presently incomplete. Test sequence steps ofaccelerated thermal aging, normal radiation and seismic simulation have beencompleted on the connectors but a retest is currently being scheduled. Thereference Junction box has been aged, irradiated, and seismically tested but,due to a miscalculation, additional radiation and LOCA testing will berequired. The thermocouple test sequence has been completed. The status ofcompleted testing and the justification for interim operation of the system isprovided below.

* Thermocouples

The thermocouples, including the measuring Junctions and portions of stainlesssteel sheathed cable located inside the vessel, have been subjected to seismic

* and LOCA conditions and demonstrated successful performance during and afterthe dynamic simulations. Accelerated thei'mal aging was not required becausethere are no organic materials in the thermocouple and effects of high(normal) irradiation were considered In developing dynamic test inputs.

The thermocouples have also been subjected to a 22007 peak temperatureinadequately cooled core simulation and maintained standard error limits forspecial Type K thermocouples (± l.1C or + OAS~, whichever is greater) bothduring and after the tests.__________

C [EFFECTIVEI DATE,~

OCT 1984

0223G/mi sc/8-84

Connectors

The thermocouple con nector' assemblies have been subjected to acceleratedthermal aging and Irradiation (gamma and beta) and seismic simulation. Thetest program is being repeated because the radiation test dose was notadequate to simulate the required post accident dose. The test criteria ofthe connectors/adaptors and the mineral insulated cable is that they maintaina continuous signal with no effect on the ac curacy of the system.

* The connector components are made of Ryton R-4, designed to tolerate highradiation exposure. Additionally, the metal outer sheath provides someshielding against exposure. Based on these facts, the additional radiationexposure is not anticipated to cause any changes in the previous successful

2 test results.

A conftidence test of the effects of a LOCA environment on a new LEDO connector* has shown no effect on the accuracy of the thermocouple reading. These

results are considered relevant to the question of performance of agedqualification units because the tendency for moisture to enter the unprotected' :~ connectors is the same for both new and aged samples. No evidence exists tosuggest that the connectors will be more sensitive to LOCA effects. Pendingcompletion of the entire sequence of connector tests, the results of the LOCAtest of new connectors lend confide~nce of successful performance of theinstalled connectors.

Reference Junction Box

The reference Junction box (RJB) has been aged, irradiated and seismicallytested successfully. However, a problem discovered prior to the LOCA test hasaltered the test program. During an external pressurization test it wasdiscovered that the NE14A enclosure was not leak tight and would allow steam toenter the box during the LOCA test. Previous tests had revealed that RTD lead

* wires exposed to a steam environment would result in a substantial drop in the* insulation resistance thus affecting the accuracy of the RTD. An attempt was* made to seal the entire box with a silicone potting compound and perform a

confidence test. If the potting method proved to be successful during the( ~LOCA test a new box was to be modified with the potting and E FE TV

repeated. DAFE TIE I

0223ti/Iiisc/8-84 U i3

* - During the confidence test of the potted box the measured insulation¶ resistance dropped substantially on all three RTO's indicating the potting had

not sealed the box and that the RTD lead wires were being exposed to steam and

caustic spray. However, a review of the data revealed little effect on theaccuracy of the system (approximately 1%). The reference junction box is

expected to maintain the compensated outputs of the incore thermocouples towithin + 2.5% of the actual measured temperature. URD will continue theinvestigation of the apparent independence of insulation resistance and RTDperforinance. Present areas of investigation include the significance of data

acquisition circuit variations and possible electro-chemical effects resultingfrom test measurement voltages in the presence of an electrolyte, such as the

N3 BO3/NaOH caustic spray. Similar results are described by N. J. Selleyin an "Experimnental Approach to Electrochemistry. In conjunction with theinvestigation, the validity of existing IR measurement techniques used inestablishing performance is being evaluated.

The confidence test p~erformed od the potted box tiemonstrateu that theprobability of obtaining a true environmental seal on the box by this methodwas low and was not required for successful system performance. After removal

of the potting material from the qualification test unit, the LOCA test wasrepeate d and followed by a post accident simulation. With the exception ofthe first 20 seconds of the test the errors were again within + 2.5% of actualmeasured temperature. A few rapid spikes occurred during the first 20

seconds, postulated to be due to the rapid influx of steam across the terminal

board.

Upon completion of the test program it was realized that because of theinadequate seal it would not be possible to take credit for Beta-shielding.This lack of shielding increased the required TID for the post accident

simulation. The test dose administered was adequate to simulate the 40 yearnormal operating dose prior to a seismic event. To address the increase in

the required TID the reference junction box will be exposed to additional

radiation and the LOCA simulation repeated.

Because of the inadequate seal, a concern has been raised over long termcorrosion effects and potential hydrogen buildup to volatile levels due to

( containment spray reacting with the internal aluminum structure. however,

* EFFECTWVEDATE

0223G/Misc/8-84 G-~J ', T

confidence and LOCA testing with steam and chemical spray have not shownevidence of chemical residue in the box which is believed to be due to therapid equalization of pressure in the box. Therefore, this is a postulated

WA:: concern not demonstrated to occur during previous qualification testing. In

order to eliminate any potential for this occurrence, a new box is beingdesigned which will effectively seal against the containment atmosphere. All-testing, ihcluding preparation of test reports will be completed on the newdesign by-December 1984..

In the interim, the results of testing to date demonstrate acceptable seismicqualification and short term post-accident environmental operation of the

- existing box desi~gn for Watts Bar application.

02,23G/Hi sc/8-84

WATTS BAR NUCLEAR PLANT

WATTS BAREQS MANUFACTURER/MODEL NO.

WBNEEB0001WBNEEB0002WBNEEB0003WBNEEB0004WBNEEB0005WBNEEB0006WBNEEB0007WBNEEB0008WBNEEB0009WBNEEB00 10

WBNEEBOO 11WBNEEB0012WBNEEB0013WBNEEB0014WBNEEB001 5WBNEEB0016WBNEEB001 7WBNEEB0018WBNEEB0019WBNEEB0020

WBNEEB0021WBNEEB0022WBNEEB0023WBNEEB0024WBNEEB0025WBNEEB0026WBNEEB0027WBNEEB0028WBNEEB0029WBNEEBOO30

WBNEEB0031IWBNEEB0032WBNEEB0033WBNEEB0034WBNEEB0035WBNEEB0036WBNEEB0037WBNEEB0038WBNEEB003 9WBNEEB0040

Target Rock/77J-OO1; 82K1-OO1 ,002,004Foxboro/E 13DM (MCA)

NOT USEDNOT USEDNOT USED

Namco/EA-740ASCO/2063816RVF, 2063813RVU

NOT USEDASCO/2063813RF

Fenwal/17323-0

NOT USED

NOT USEDNOT USEDNOT USED

Fluid Components/FR-72-4ASCO/SB31AKR/Th30A32R, SB11AKR/TG13A42R

NOT USEDNAMCO/EA-740ASCO/X2063813R1, NPX831654EASCO/2063812F, 2063813R1, NP031654E, NP831654V

NOT USEDFenwal/18023-7Fisher/Type 546

NOT USEDNOT USED

Comsip, Inc./K-IIIMlosemount/il 53DB4ASCO/NP83 16 54EASCO/2063813RVU, 2063802RUFluid Components/12-64-3/S

NOT USEDNOT USED

Static-O-Ring/2OlTANOT USED

ASCO/2063813RVUTarget Rock/82AB-001ASCO/X2063813RFMasoneilan/8005AASCO/2063813R1, NP831654E

NOT USED

E EF F2 C TVE-DATEOCT 19i84

04427.17Page 1 of 7 (12)044277.17

WATTS BAR NUCLEAR PLANT (Continued)

WATTS BAREQS

WBNEEB0041WBNEEB0042WBNEEB0043WBNEEBOO044WBNEEBOO045WBNEEB0046WBNEEB0047WBNEEB0048WBNEEB0049WBNEEB00 50

WBNEEB0051WBNEEBOO052WBNEEB00 53WBNEEBO0054WBNEEBOO055WBNEEB0056WBNEEBOO057WBNEEBOO058WBNEEB0059WBNEEB0060

WBNEEB006 1WBNEEB006 2WBNEEB0063WBNEEB0064WBNEEB006 5WBNEEB0066WBNEEB0067WBNEEB0068WBNEEB006 9WBNEEBOO070

WBNEEB007 1WBNEEBOO072WBNEEB0073WBNEEB0074WBNEEB0075WBNEEB0076WBNEEB0077WBNEEB007 8WBNEEB0079WBNEEB0080

MANUFACTURER/MODEL NO.

NOT USEDNOT USEDNOT USED

ASCO/2063802RU, 2063803RUNOT USED

ASCO/X2063813R1ASCO/X2063813Rp

NOT USEDASCO/2063802RU

NOT USED

NAMCO/EA-1 80NOT USEDNOT USED

ASCO/X2063813R1NOT USED

NAMCO/EA740Masoneilan/8012NAMCO/EA-170NAMCO/EA740Masorleilan/496-2

NAMCO/EA-1 80NOT USED

NAMCO/EA1 80NOT USED

ASCO/206-381-3Rp, -3F, -2F,NOT USED

NAMCO/EA1 80NAMCO/EAI 80

NOT USEDNOT USED

NOT USEDFoxboro/NEl IDM-HID2Hasoneilan/8012TEC/504A and ENDEVCO/2273A

NOT USEDNAMCO/EA-170Target Rock/82AB-001

NOT USEDFenwal/18003-7Fluid Components/FR72-4

-3RU; HV206-380-3RU

I: .i1j~.~7~Ij

-

044277.17Page 2 of 7 (R2)

WATTS BAR NUCLEAR PLANT (Continued)

MANUFACTURER/MODEL NO.

WBNEEB00 81WBNEEB0082WBNEEB0083WBNEEB0084WBNEEB0085WBNEEB0086WBNEEB0087WBNEEB0088WBNEEB0089WBNEEB00 90

WBNEEB00 91WBNEEBO0092WBNEEB00 93

NOT USEDNOT USEDNOT USEDNOT USED

Honeywell/T675ATarget Rock/82UU-O01NAMCO/EAl 80NAMCO/EA1 80Fenwal/18023-7Westinghouse! 32PA1

ASCO/SB1 1AKR/TLlOA32RNOT USED

NA24CO/EA740

7.

04427.17Page 3 of 7 (R2)

WATTS BAREQS

T

044277.17

WATTS BAR NUCLEAR PLANT-0588 EQS INDEX

WBN EQS No. Desciption

EEB-CBL-

1.02.0

3.0

3.14.05.06.07.07.17.28.08.18.28.38.48.59.0

10.011.012.013.0

14.015.016.016.117.018.018.118.219.0

Electrical Cable Type

SROAJ (AIW)SROAJ and SROAJ-H(Rockbestos)SROAJ and SROAJ-H(Anaconda)SROAJ (Anaconda)XLPE (Samuel Moore)XLPE (Samuel Moore)XLPE (Anaconda)XLPE (Rockbestos)XLPE (Brand-Rex)MS (Brand-Rex)Triaxial (Raychem)Coaxial (Rockbestos)Coaxial (Raychem)Coaxial (Brand-Rex)Not UsedTriaxial (Brand-Rex)CPJ, CPSJ, and CPJJNot UsedNot UsedEPSJPXJ and PXMJ

Not UsedPJJMsMS (Brand-Rex)Special (ETFE)TriaxialTriaxial (ITT)Triaxial (Brand-Rex)Coaxial

L~

04427 .17Page 4 of 7 (R2)

3.11-4A

3.11-4A

3.11-4A

3.11-4A

3.11-4A3.11-4A3 .11-4A

3.11-4A3.11-4A3.11-4A3.11-4A3.11-4A3.11-4A3.11-4A

3.11-8A

3.11-8A

3.11-8A

3.11-8A

3.11-8A

3.11-8A3.11I-BA3.11 -8A3.11-8A3.11-8A3.1 1-8A3.11-8A

TableSheet No.WBN-EEB

1000

1000,1000A

I1000A, 1001

1000DA10021001,100210021001100110011002100210021003

10021000,1001 ,1002,1003

10041008, 1009 ,1010 ,10111011A "1011B

1005,1006,10071012,1013,1013A1013A10141015101510151016

044277.17

WATTS BAR NUCLEAR PLANT-0588 EQS INDEX

WBN EQS No.

EEB-liS-1

EEB-JB-l

Description

Hand Switches-Square DClass 9001, Type K

Table

3.11-43.11-53.11-6

3.11-7

3.11-8

Junction Boxes 3.11-43.11-53.11-63.11-73.11-8

Sheet No.WBN-EEB

100010001000,10011002,10031004, 10051006,1007,10081000,10011002,1003,1004,1005,1006,1007.1008, 10091000,10011002,10031004, 10051006,10071008,1009,1010,1011,1012,1013,

10001000100010001000,1001,1002,1003,1004,1005,1006,1007,1008,1009,1010,1011,1012, 1013

EEB-PEN-l Electrical PenetrationAssemblies - Conax Modular

3.11-43.11-5

10001000

EFFECT >D ATE

OCT

04427.17Page 5 of 7 (R2)044277.17

WATTS BAR NUCLEAR PLANT-0588 EQS INDEX

WBN EQS No.

EEB-SPL.-l

Description

Heat Shrink Splices -Raychem type WCSF-N

Table

3.11-43.11-53.11-6

3.11-7

3.11-8

EEB-TB-1

EEB-XS-1

EEB-RLY-1

EEB-XS-2

Terminal Blocks

Transfer Switch - ElectroawitchSeries 24

Relay, Rotary- Potter&BrumfieldSeries MDR

Transfer Svitch - NuthermPart No. 4641

3.11-43.11-53 .11-63.11-73.11-8

3.*11-6

3.11-6

3.11-6

Sheet No.WBN-EEB

100010001000 ,1001,1002,10031004,1005,1006,1007,10081000,1001,1002,1003,1004,1005,1006,1007,1008, 10091000,1001,1002,1003,1004,1005,1006,1007,1008,1009,1010,1011,1012,1013

10001000100010001000,1001,1002,1003,1004,1005,1006,1007,1008, 1009,1010,1011,1012, 1013

1009

1010

1011

044277.17Page 6 of 7 (R.2)[- _____K:044277.17

EEB-STR-1

EEM-RM-2

EEB-MTRT-1

EEB-CSC-1

EEB- CON-I

EEB-BD-242*

EEB-PNL-l*

EEB-BD-1 *

EEB-BD-2*

EEB-BD-3*

EEB-BD-4*

EEB-MC-l1*

EEB-MC-2*

EEB-HC-3*

EEB-MC-4*

EEB-MC-5*

Motor Starter - Nutherm.Part No. 4642

Radiation Monitors -General Atomic

Motors - RelianceElectric Company

Conduit Seal Connectors -'Conax Corporation Type ECSA

Staliness Steel FlexibleConduit - Servickir Type SS63

Power Panels - El-Tex, Ind.

Distribution Panels -Thermon Manufacturing Co.

Power Boards - Arrow-Hart

Power Boards - Arrow-Hart

Power Boards - Arrow-Hart

Power Boards - Arrow-Hart

Motor Control Center - I-T-E

Motor Control Center - I-T-E

Motor Control Center - I-T-E

Motor Control Center - I-T-E

Motor Control Center - I-T-E

3.11-6

3.11-4

3.11-6

3.11-43.11-63.11-7

3.11-43.11-63.11-7

3.11-6

3.11-63.11-7

3.11-6

3.11-6

3.11-6

3.11-6

3.11-6

3.11-6

3.11-6

3.11-6

3.11-6

1012

WBN-EEB-1002

1012

100110001000

.100110001000

1014

10141011

1013

1013

1013

1013

1013

1013

1013

1013

1013

*Non-.Class 1E [1OCFR5O.49b(2)]

04427.17Page 7 of 7 CR2)044277.17

Unit NO. , a,,...

JOS NO. WRNE~FlflflMAID No.

See Appendix 1

w NB~~WN MDUIM=? OULTFICA=O 51='Y (EDS)

Manufacturer and Model No. See APne6ndix I'verification of T&Wle Information (Table See Appendix 1

LX w m A - The equipment has been identified as per WVA I numberX designations (such as, KW,, sMV.

LoctX - The location has been identified (such as, inside primarycontainment, annulus, individually cooled roonsp general spaces, or areaaffected by HELB outside primary containmnent)..'X Gm at- A unique TVA ID number has been assigned (such as,, l-FSV-63-308).x F~ntign- A functional description of the component has been given (such as,,steam generator bimuidown).Q nnract No.. Manufacturer, and Model No. - The contract numb~er,, manufacturer,,and model number have been given.

X PAhnormia or Accident Environment - All abnormal or accident environmentalconditions applicable to this equipment have been identified either in tables orby references to figures from tables.X Zvironmet to Which Oualifie - The environment to which the equipment has beenqualified is addressed in either the tables or the enviromemntal analysisattached.

X. -km _A category of a, b,. c,, or dhas been defined for theQ Opration and Accuracy Heqired and DmntrAtod - The operationand accuracy required and demonstrated have been defined.

*Ouailification Status (check if aplicale. H if notQuaifid Lfe(If equipment is qualified, indicate the qualified life with a

Xnumnerical entry): 40XpX Qalification Re~rt andi Hethnd - A qualification report and the method of

qualification has been identified on the Table Input Data Sheet (TIDS).X2. EniomnalAaI - An environmental analysis has been done, attached tothe BDS, adindependently reviewed by the responsible organization.X Qalifcatinn by Similarity (If applicable) - A justification for qualificationby similarity is attached to the EDS considering all the above factors and

referenced to the appropriate tables.X Qualification of Several &Mat CaMnnet (if applicable) - When an MS is usedf or more than one item, a list of all exact c~toqxxts is given as an appendixwith all references to appropriate tables with justification for qualificationconsidering all the above factors.N/Amoterim Oualification (if applicable) -. (open item) - Component has beendetermined to be qualified only for a limited interim operation,, an NM hasbeen written,, and plan of action has been determined to yield a qualifiedcazqxment.Tearm of Interim Qualification_____________________

... jLIA2"fied CaZM=id~ - (Open item) -(If applicable) - Component has beendetermined to be unqualified; the following is attached to EDS: N. flimter,, LUreason for non-qualification, and justification of continued operation. >NM~ LI..

A11L *Due to the extensive changes from Revision 1, revision bars are not used. Fu

Reviewer/Date

Nawwtacturer

Component

Append jr-Rev- -c~

.Target Rock

Solenoid Valves

CanPOne~t UNID FXI0.Tabl V/S het

l-FSV-30-134-u . 77J-001 3.11-4/WBNEEB0OO2

2-FSV-30-134-B 77J-001 3.1 1-4/WBNEEBOOO2

l-FSV-30-135-A 77J-001 3 .1-5/WBNEEBOOO1

2-FSV-30-135-A 77J-001 -3 11-5/wBNEEBoool

1-FSV-43-250 8 = -001 3.11-5/WBNEEB0OO3

I-FSV-43-251 82KK-001 3 .11-4/'WBNEEB000g

I-FSV-43-287 82KK-002 3 .11-5/WBNEEBOOO3

I-FSV-43-288 82KK-002 3.*1 1-4/WBNEEBOOO9

1-FSV-43-307 82KK-002 3 .11-5/WBNEEB0OO3-

I-FSV-43-309 8=1-001 3. 11-5/WBNEEB0003

1-Fsv-43-310 8211-001 3 .11-4/WBNEEB0009

1-FSV-43-312 8 = -001 3.1 1-5/WB NEEB0003

1-FSV-43-318, 8211-002 3 .11-.5/WBNEEB0003

1-FSV-43-319 82KK-002 3 .11-4fWBNEEB0069

1-FSV-43-325 8=1-002 3 .11-5/WBNEEBOOO3

1-FSV-43-341 821-004 3. 1.1-5/WBNEEBOO03

1-FSV-423-342

1-FSV-43-26882KK-004

82KK-004 3. 11-5/WBNEEBOOO3

-~ I

3.11- 5/WBNEEBOOO 3

E.FFECTIVE]DATE

Preparer/Date

Reviewer/Date

1. 1. For solenoid valves:

1-FSV-30-134-B Target Rock Model 77J-001

2. The solenoid valve listed above is located in the Containment lovercompartment. As detailed in EN DES Calculation NEB 840517 222 for theContainment Ventilation System, this valve is required to operate for5 minutes after the start of a LOCA, Main Steam line break or AuxiliaryFeedvater line break and must not fail in a manner detrimental to plantsafety for 100 days thereafter. Additionally, it must operate for 5minutes after an RHR or CVCS line break and must not fail in a mannerdetrimental to plant safety for one month thereafter.

3. This solenoid valve is required to operate in the followingenvironment1 :

Normal Abnormal Accident

Temperature:Pressure:Relative Humidity:Radiation:

Spray/Flooding:

120OFAtm80%2x107 rads(40 yr TID)N/A

130OFAtm100%N/A

N/A

3270F26.4 Pasi100%lx10 8 rads(LOCA)Spray

II. 1. For solenoid valves:

1-FSV-43-250I-FSV-43-287I-FSV-43-3071-FSV-43-309I-FSV-43-3 18l-FSV-43-3251-FSV-43--3411-FSV-43-3421-FSV-30-135A

TargetTargetTargetTargetTargetTargetTargetTargetTarget

RockRockRockRockRockRockRockRockRock

ModelModelModelModelModelModelModelModelModel

82KK-00182KK-00282KK-00282KK-00182KK-00282KK-00282KK-004821K-00477J-001

2. Solenoid valves listed above are located in the Annulus. As detailed inEN DES Calculation NEB 840517 221, the system 43 solenoid valves arerequired to operate for 100 days after the start of a LOCA, Main Steamline break or Auxiliary Feedwater line break, and for 1 month after aCVCS or RUR line break. Per EN DES Calculation NEB 840517 222, valve1-FSV-30-135A is required to operate for 5 minutes after the start of aLOCk, Main Steam line break or Auxiliary Feedwater line break and must notfail in a manner detrimental to plant safety for 100 days thereafter.Additionally, it must operate for 5 minutes after an ERR or CVCS linebreak and must not fail in a manner detrimental to plant safety for 1 monththereafter.

1See WBN Environmental Data Drawing 47E235-42 RI. E F F C TIV

EQS No. IWBNEEB0001Appendix 2 Rev 2Sheet 1 of 5.

Preparer/Date

Reviewer/Date

3. These solenoid valvesenvironment :2

are required to operate in the-following

Normal Abnormal Accident

Temperature:Pressure:Relative Humidity:Radiation:

Spray/Flooding:

110OFAtm( -)80%2x107 rads(40 yr TID)N/A

120OFAtm( -)90%N/A

NIA

150OFAtm( -)100%5x107 rads(LOCA)Spray

111. 1. For solenoid valves:

1-FSV-43-2511-FSV-43-2881-FSV-43-3101-FSV-43-31 9

Target Rock Model 82KK-001Target Rock Model 82KK-002Target Rock Model 82KK-001.Target Rock Model 82KK-002

2. Solenoid valves listed above are located in the Containment lowercompartment. As detailed in EN DES Calculation NEB 840517 221, thesesolenoid valves are required to operate for up to 100 days after thestart of a LOCA, Main Steam line break, or Auxiliary Feedwater linebreak and for 1 month after a CVCS or RUE line break.

3. These solenoid valves are required to operate in the followingenvironment :3

Norma Abnormal Accident

Temperature:Pressure:Relative Humidity:Radiation:

Spray/Flooding:

120OF14.3 psia80%2xl07 rads(40 yr TID)N/A

130OF14.3 psia100%N/A

N/A

3270 F26.4 psia100%1x108 rads

Spray

IV. 1. For solenoid valves:

1-FSV-43-312 Target Rock 82KK-0011-FSV-43-268 Target Rock 82KK-004

2. This solenoid valve is located in the Auxiliary Building (Room 713/A28).As detailed in EN DES Calculation NEB 840517 221', it is required tooperate for up to 100 days after the start of a LOCA and must not failin a manner detrimental to plant safety for I month after a CVCS, RUE,Auxiliary Feedwater, or Auxiliary Boiler line break.

2Per WEN Environmental Data Draving 47E235-M4 RO.3See WBN Environmental Data Drawing 47E235-42.

D - - - , 7D

EQS No. WBNEEB0001Appendix 2 Rev 2Sheet 2 of 5

Preparer/Date

Reviewer/Date 7~LZ9Z-~1MA4i /1~ 9 -AuEQS No. WBNEEBOOO1Appendix 2 Rev 2Sheet -3 of 5..j..

3. This solenoid valve is required to operate in the following environment:4

Temperature:Pressure:Relative Humidity:Radiation:

Spray/Flooding:

Target Rock has testedenvironment:

Temperature:Pressure:Relative Humidity:Radiation:Spray:

1040FAtm.(-80%3.5x105 rads(40 yr TID)NIA

Abnormal

HOO0FAtm()90%N/A

NIA

Accident

208OFN/A100%

41xl04 rads

N/A

their solenoid valves to the following

3855F

66 psig100%1.35x108 radsBoron/Hydrazime

Target Rock Corporation reports 3619 and 3531 qualify the model 82KK-001,002, 003, 004, and Model 77J-001 solenoid valve assemblies by similarityto the model 77CC-001 assembly. Target Rock has tested the model 77CC-001valve to the requirements of IEEE 323-1974, 344-1975, 382-1972, andNUREG-0588. The test criteria and reults are documented in Target RockCorporation Test Report 2375, Rev. G. All qualification tests wereperformed at levels or conditions in excess of known maximum applicationrequirements. Margins were in accordance with those suggested by IEEE 323-1974.

There is no significant82KKR and 77J series andin Test Report 2375 canseries valve assembles.

difference in electrical components between thethe tested model 77CC-00i. The type test documentedtherefore be extended to cover the 82UC and 773

Test valve 77CC-001 was subjected to oequential exposures of pre-agingradiation, aging simulation, resonant frequency, search/seismic simula-.tion and post accident radiation dosage. Functional tests were performedbefore and after each sequence of tests. The valve was cycled once duringeach seismic dwell test point to verify proper operation.

The test valve was exposed to a source of'gamma radiation for an initialminimum dosage of 22.7 megarads.

See 1WBN Environmental Data Drawing 47E235-59, -61.

E [F F V r_,CA

Preparer/Date EQS No. WBNEEBOOO1Appendix 2 Rev 2

Reviewer/Date _________________ Sheet 4 of 5

The test temperature used in the 40-year aging test was 35001 for a periodof 33 days.

The, test valve was cycled 18000 times under load during cycling agingsimulation.

Prior to the seismic test, the valve was exposed .to a .2g resonant frequencysearch over 1-35 Hertz range. (Seismic test input levels were 4.5g). Thevalve was then pressurized with water at 2485 paig and cycled once duringeach dwell point to verify proper valve operation.

The test valve was subjected to a design basis accident test by exposure toa combination of steam and chemical spray for 6 hours (2-three hourtransients). The maximum temperature and pressure were 3850F and 66 psig.The spray solution consisted of 6200 ppm boron in solution with 50 ppm.hydrazine. The pH level was maintained between 8.6 and 10.0.

Following DBA simulation, the valve was subjected to a post-DBA load testby exposure to steam and chemical spray (composition as described above)for 14 days. The temperature/pressure profile was as follows:

Elapsed Time Temperature (OF) Pressure (nsix)

3-8 hrs. 312 -658-42 hrs. 312-290 27.542 hrs.-14 days 290-215 11

Valve operating was verified by position switch indications and bymonitoring flow from the outlet port.

For the post accident radiation exposure test, the valve was exposed toa 112.6 megarad source of gamma, radiation. This resulted in a totaldosage, aging plus accident, of 1.35x108 rads.

The Arrhenius model proves operability for 40 year life at a normaltemperature of 120OF plus operability for over 100 days after the startof an accident. Loss of power and valve failure after this 100-dayperiod will result in the valve assuming the required "~fail-.closed"~position'.

Calculations - Post Accident Life

Calculations are based on the Arrhenius.,equation which states:

[4 T2 - ;)E F F E C-l L2 e I D~

D A1

Preparer/Date 4O,4. ZL 9'YZQS No. WBNEE IB0001SAppendix 2 Rev 2Reviewer/Date Al -' Sheet L5 of 5..

Where

Lj -..Qualified life

L2 ' Accelerated (test) life

El- Worst-case activation energy, eV

K - Boltzmann's constant, 8.617 x 1O-5 eV/OK

T= Qualified temperatures absolute

T2 Elevated (test) temperature, absolute

e - Base of natural logarithms

Calculations for qualified post-accident life for valves located in thecontainment lower compartment (worst case) follow:

L2- 14 days - 3 hrs - 333 hrs. (Report 3619, pag. 15)

El- 0.61 eV

Ti-156.5 0F (temperature profile, WBN environmental data drawings 47E235-42,(1880F @ 3 hrs - 1250F @333 hrs)/2 +O 1250F)

T2- 250OF (Report 3619, pg. 15)

Tj- (156.5-32)/1.8 + 273.15 - 342.30K

T2- (250-32)/1.8 + 273.15 - 394.30K

[ 61 ( LLl-33e8.617xl105 342.3 394.3

- .211.5 days

034150.04

'EFFFChiV~

Preparer/Date

Reviever/Date _________________

ZQS No. WBNEEB0001Appendix 3 Rev 2Sheet I of

The devifts listed below require sealing of the conduit entrance.Qualification of the conduit seals is do*etdi h eeecdEQS.

Component UNID EQS

1-FSV--43- 268

1-FSV-43-312

WEN EEB-CSC-1

WEN EEB-CSC-1

EQS.F

Revision1 ' - .&

Preparer/Dete A'.r4'ek/A'c. 9,198/

q - I - q - unit NO. 1 and 2EDS No. ON__E_0002

MA ID NO.See Appendix 1

ISN MDUTEMMEhI nTMLIic ON E'r(S

Manufactter and Model No. Foxboro Model E13DM (MCA)Verif ication of Table Information (Table See Appendix 1

-X flim =- The equipment has been identified as per TVA MD numberX designations (such as, mv,, s~v) .

X ~to - The location has been identified (such as, inside primarycontainment, annulus, Individually cooled rooms, general spaces, or area

X affected by HELB outside primary containment).X ~p~ - A unique TVA ID numb~er has been assigned (such as,, l-FSV-68-308).X Functio - A functional description of the cqoet has been given (such asp

steam generator blowown).X Contract No.. Manufacturer, and Model No. - The contract nwtdberp manufacturer,

and model number have been given.L Abnormal or Accident Envigonment - All abnormal or accident environmental

conditions applicable to this equipment have been identified either in tables orby references to figures fromi tables.

X* EVmiroMent to Which Qualifie - The environment to which the equipiment has beenqualified is addressed in either the tables or the environmental analysisattached.

x Qg - Acategory of a, b, c,, or dhas been defined for theX Copration and Accuracy Reqired and DeOnstrated - The operation

and accuracy required and demonstrated have been defined.'-

Ouslification Status (check if applicable. NA if not)Ov~ifid Lfe(If equipment is qualified, indicate the qualified life with a

numerical entry): -20 years.... Qualification Report! and Method - A qualification report and the method ofqualification has been identified on the Table Input Data Sheet (TIDS).X ft!irgrig t1a1..Amaysis - Anf environmental analysis has been done, attached to

the BDS#, and independently reviewed by, the responsible organization.._HLA Ouslificaion by Simiarity (If applicable) - A justification for qualification

by similarity is attached to the EDS considering all the above factors andreferenced to the appropriate tables.

X Qualificati-On of Several E=ac Ctmpoets (if applicable) - When an MQS is usedfor more than one item, a list of all exact m netisgvnaanpedxwith all references to appropriate tables with justification for qualificationconsidering all the above factors.

-EL InteriM Q=uIlif ication (If applicable) - (Open item) - Coirqznent has beendetermined to be qualified only for a limited interim operation, an NCR hasbeen written, and plan of action has been determined to yield a qualifiedcmqlcrhent.Term of Interim Qualification ____________________

NM No.N/A i2u1 ifed CaqZM ~ _ (open item) - (If applicable) - Component has been LIU~determined to be unqualified; the following is attached to BQS: NCR number,>reason for, non-qualification, and justification of continued coeration. -

*Due to the extensive changes from Revision 1, revision bars are not used.

C

PreparerIDate JC Q . '?/

Ravi ewer/Date __________

Nanuf wturer

ffS o. WBNEEB0002APPOM df~v a - -Re -"

Foxboro Company

Level Transmitter

*Not yet ~ngtalled.

Compon~ent UUID "Id No.Tbl/ht

l-LT-3-148-B -El3DM (MCA) 3.11-4/VBNEEUOOO2

2-LT-3-148-B* E13DM .(MCA) 3.11-4/WBNEEBOOO2

l-LT-3-156-A E13DM (MCA) 3.11-41WBNEu0O0022-LT-3-156-A E13DH (MCA) 3.11-4/WBNEEnooo2

1-LT-3-164-A E13DH (MCA) 3o11-4/VBNEEBoooa

2-:LT-3-164-A E13DM (MCA) 3.1 1-4/WBNEEnOOO2

l-LT-3-171-B E13DM (MCA) 3.11-4/WBNEE30002

2-LT-3-171-B* E13DM (MCA) 3.11-4/VBNEEBOOOI

l-LT-3-172-A E13DH (MCA) 3.11-4/WBNEEB0002

2-LT-3-172-A E13DH (MCA) 3 .11-41W3NEE300021-LT-3-173-B El3DM*(MCA) 3 .11-4/WBNEEBOOO2

2-LT-3-173-B E13DM (MICA) 3.11-4/WBNEEB0002

l-LT-3-174-B E3M(C)3 .11-4IWBNEEBOOOZ2-LT-3-174-B E13DH (MCA) 3.11-4/VBNEEBOOO2

1-LT-3-175-A E13DH (MCA) 3.11-4/WBNEEB0002

2-LT-3-175-A E13DH (MCA) 3.11-4/VBNEiBOOO

002OO2

LU

LJ-

I -

Preparer/Date EQS No. WBNEEB0002_________________________ Appendix 2 Rev 3

Reiwr/aeSheet 1- of 2

1. Theil-evel transmitters in Appendix 1 are Foxboro Model E13DH (MCA).They are located in the Reactor Building (Containment lowercompartment, floor elev. 716). The actual installed elevation is abovethe postulated maximum flood level. As detailed in EN DES Calculation R.3840515 225, for Main and Auxiliary Feedwater System, they are requiredto operate for 5 days after the start of a LOCA, and RHR, CVCS, MainSteam and Feedwater line breaks.

2. The transmitters are subject to LOCA/HELE conditions. They arerequired to operate in the following enviromments':

Normal Abnormal Accident

Temperature: 120OF 130OF 3270FRelative Humidity: 80% 100% 100%Pressure: 14.7 psia 14.7 psia 26.4 psiaRadiation: I.OXio7 rads N/A 4x106 rads

(20 yr TID) (5 day dose)Spray/Flooding: N/A N/A N/A

3. The manufacturer has tested the transmitters to the followingparameters:

Temperature: 370OFPressure: 75 psigRelative Humidity: 100%Radiation: 1.8X107 rads

4. The test results are documented in the April 26, 1978 (NEB 820204 200),letter No. NS-PLC-5023 to the NRC from Westinghouse ElectricCorporation.

Three Foxboro type El13DM (MCA) level transmitters were irradiated at alevel of 1.8x101 rads (total integrated doese) prior to the

steam/pressure/temperature/chemical spray test. This radiation levelprovides substantial margin over the sum of the 20-year integrateddose and the 5-day accident dose (1.4xl07 rads - refer to EN DESCalculation NEB 830414 235, pg. 11.6). The radiation produced nochange in transmitter output.

The transmitters were then subjected to a steam/pressure/temperature/chemical spray test with total duration of 15 days. In order tosimulate postulated feedline break environmental conditions, a chemical

'See WBN Environmental Data Drawing 47E235-42 1.1 and EN DES CalculationNEB 830414 235, pg. 11.6.

E F"CTI E

Preparer/Date 21 9-VA!J EQS No. WBNEEB0002

#______________ Appendix _2 Rev 3

Reviewer/Date 9l -, Z.. / 7- t%14 Sheet 2 of 2

spriy: -consisting of boric acid and sodium hydroxide was introduced into

the test chamber f or the first 24 hours of the test. The peaktemperature reached (approximately 9 seconds) was 370 0F. Test pressureand relative humidity were 75 psi& and 100%. The temperature was

gradually reduced to 320OF over a period of 16 minutes and heldconstant for 20 minutes. The temperature was further reduced over thenext 24 hours to 22001 (post accident environment) and held constantuntil the end of the test.

A maximum transmitter error of 7% was recorded during the first 90

seconds of the test. A decrease in transmitter error to within a fewpercent of span vas observed as the test conditions were reduced. Allthree transmitters became inoperative during the post accident environ--ment. The first failure occurred at the 5.5 day point which exceedsthe 5-day post accident operating time required for these transmitters.Comparison of the test temperture profile, and the temperature profilegenerated for WBN Containment lover compartment (refer to dwg.47E235-42) reveals that these transmitters were tested to a postaccident temperature level greater than that predicted for theinstalled location. The failures were caused by an open-circuit in thetest resistor circuit located in the transmitter junction box. In thistest, the junction box was exposed to the teat environment; whereas, innormal use the junction box is sealed. Since the resistor is fordevice testing and can be replaced by a short without affecting trans-mitter operation, the above failure mode can be prevented.

Non-metallic components of these transmitters consist of electronicdevices and a viton cover seal gasket. Proper operation of the solid-state circuitry will be maintained by calibration at regular intervals.The viton gasket will be inspected and replaced if found to be worn orcracked. This inspection will occur during every refueling outage as aminimum.

The foregoing shows that the Foxboro model 113DM (MCA) leveltransmitter will operate 'within acceptable accuracy limits for aminimum of 5.5 days 'in an accident environment which envelopes thatapplicable to the installed location in lower containment. Therefore,this equipment is qualified per IEEE 323-1971 for a 20-year life withcalibration, inspection, and maintenance performed at every refuelingoutage as a minimum.

034147.01

EFFEC-TIvc

DAT

Preparer/ Dat O'ted C4jT &Z. q-,t41

RevieverJDate _ N__ =____ /____ 7___Z____q

EQS No. WBNEEB0002Appendix 3 Rev 3Sheet 1 of 1

The devices listed below require sealing of the conduit entrance.Qualification of the conduit seals is docume~nted in the referencedEQS.

Component UNID

1 ,2-LT-3-148-B

1 ,2-LT-3-156-A

I ,2-LT-3-16 4-A

1 ,2-LT-3-17 1-B

1 ,2-LT-3-17 2-A

1 ,2-LT-3-17 3-B

1 ,2-LT-3-17 4-B

1,2-LT-3-17 5-A

WIN

WBN

WBN

WBN

WIN

WIN

WIN

WBN

mE-S-

EEB-CSC-1

EEB-CSC-1

EEB-CSC-1

EEB-CSC-1

EEB-CSC-l

EEB-CSC-1

EEB-CSC-1

EFFECTIVE.!DAT EFJCT 984

un~it NO. 1EDS No. WBNEEB0006MV ID No.

-See Appendix 1

Nanufact(ker and Mo~del No. -- See A21pendix 1Verification Of O&ble Information (Table -- See Append-i-x

x Si~ A - The equipment has been identified as per 7IVA 3:D numberdesignations (such as, 1MT, srYJ.X lati - The location has been identified (such as, inside primarycontaingrentp annulus,, individually cooled roars, general spaces, or areaaffected by HELB outside primary containmnent).X LW =- A unique IVA ID numb~er has been assigned (such as, l-PSV-68-308).X - A functional description of the ccsponet has been given (such as,steami generator bloiedown).X O~rtrc ND.. Manu -fActure-r, and W&Il N. - The contract numb~er#, manufacturer,and model numb~er have been given.X rmaL or Accident- FEviroma~t - All abnormal or accident envirorgentalconitions applicable to this equipment have been identified either in tables orby references to figures from tables.X zavirgmnent to -iich Qualified - The envirornment to which the equipiient has beenqualified is addressed in eithe-r the tables or the envirounmental. analysis

Cae -A category of a,, b,, c, or d has been defined for theX Coration an cuac eured pand fliDnztrated - The operationand accuracy required and demon-strated have been defined.

& Lficaiarj taUS (check if A~licahle. NA if Wot)Omi e jf (If eq~uipmnent is qualif ied,, indicate the qualif ied life with anumerical entry): 31.2 yearsOiw&lficat4 ionR-nrt- And Metho - A qualification report aid the method ofqualification has been identified on the Table Input Data Sheet (TIMS).X ~irA in-iIA~1v An environmental analysis has been done, attached totheZ Ms" and independently reviewed by the responsible organization._LA CualifiCatioll hY SimIAlrity (If applicable) - A justification for qualificationby similarity is attached to the EDS considering all the above factors andreferenced to the appropriate tables.XOualification of Severa xc (if applicable) - Mme an EDS is usedfor more than oneitem, alist ofallexact cmxetsis given as an apnixwith all references to appropriate tables with justification for qualificationc os idering all the above factors.-SA Theim OualificAtion, (If applicable) - (Open item) - omXet has beendetermined to be qualified only for a limited interim operation, an NRhasbeen written, and Plan of action has been determinied to yield a qualifiedcopoent.Term of Interim Qualification_____________________

- ~ f~dCXj~J - (Open item) - (If applicable) - Cmxet bas beedetermined to be unqualified; the following is attached to EDS: M ubrreason for non-qualification, and Justification of continued operatinNM No. __ f

E, F

EDU C T

Preparer/D ate c6•ýŽaJ244 2J-4

Revi ewer/ Date Z15

Manuf act urer

Canponent,

EQS No. WBNEEB0006Appendix TIRv 3Sheet 1=of 1

NAHCO

Limit Svit~h

Model No.Limit Switches on:

1-CV3130-AEA 740 3 .11-4/WBNEEBOOIO

2-FCV-31-306-A EA 170 3.11-4/WBNEEB0008

1-FCV-31-3c)08-A EA 740 3.11-4/WBNEEBOOIO

2T-FCV-31-3UF8-A EA 170 3.11-4/WBNEEBOO08

I-FCV-31-329-B EA 740 3.11-4/WBNEEBoo1o2-FCV-31-32T9--B EA 170 3.11-4/WBNEE~B0008

+

R13

R13

Ccinponent UNID Table/Sheet

Preparer/Date _________________ EQS No. WBNEEBOO06*Appendix 2 Rev 3

Reviewer/Date -- ry Sheet 1 of 7

NANCO has tested the model RA-740 limit switch to the requirements of IEEE Standard323-1974%- The test criteria and results are documented in "Qualification of NANCOControls Limit Switch model EA-740 to IEEE Standards 344 (1975), 323 (1974), and 382(1972)," Revision 1, dated February 22, 1979.

All qualification tests were performed at test levels or conditions in excess ofknown maximum application requirements. These margins are in accordance with themargins suggested in IEEE Standard 323-1974.

Thermal aging calculations in this appendix are based upon the "Arrhenius Equation"shown in equation 1.

K -j T2]EQN.1 Ll L2 e

Where

Ll- Qualified life

L2- Accelerated (test) life

E - Worst case activation energy, eV E FFE~CT-1V EK - Boltzmann's constant, 8.617 x 10- eV/OKDA

Tj- Qualified temperature, absolute

T2- Elevated (test) temperature, absolute

e -Base of natural logarithms

Materials' Potential for Significant Aginit:

In "Estimation of Qualified Life of EA-740 Series Nuclear Switch," February 27,1980, revision, NAMCO identifies a cover gasket containing Nitrile Eutadyne Rubber(NBR) as the material most susceptible to aging. Elsewhere in this EQS, NBR isused as a basis for all calculations determining qualified life.

In the same report, NAMCO states that an ethylene propylene compound (EPa) 0-ring ifused on the level shaft. The NRC has identified EPR as a material having thepotential for significant aging. Noting the greater susceptibility of NBR over EPR,NAMCO concludes:

"As a result of the thermal aging study, the lever shaft 0-ring will not beconsidered a factor in the qualified life estimation."

EPR as used in this limit switch is not a potential for significant aging in theenvirornment in which it is located.

Preparer/ Date ZfA dzký Z4ý/$-Zl-4d/Reviewer/Date

EQS No. WBNEEB0006Appendix 2 Rev 3Sheet 2 of 7...L.

UNIT 1 ONLY

1.The limit switches on Appendix 1 are NAMCO model EA 740. They arelocated in the Incore Instrument room at elevation 716. As detailed inEN DES Calculation NEB 840515 224 for the Air Conditioning System(System 31), these switches must operate for 5 minutes after the startof a LOCA, Main Steam, or Main Feedwater line break and not fail in amanner detrimental to plant safety for 100 days thereafter.Additionally, they must operate for 5 minutes after a line break ineither the Residual Heat Removal or Chemical Volume Control Systems andnot fail in a manner detrimental to plant safety for 1 monththereafter.

2. These switches are subject to LOCA/EELB conditions andthe following environmentl:

Normal Abnormal

must operate in

Accident

Temperature:Pressure:Relative Humidity:Radiation:

Spray/Flooding:

7 50F14.7 psia60%3.5xl05 rads(40 yr TID)N/A

1 20OF14.7 psia90%N/A

N/A

327 OF26.7 psia100%ixiO8 rads(LOCA)N/A

3. The manufacturer has tested the model EU 740 switch to the followingenvironment:

Temperature:Pressure:Relative Humidity:Radiation:

340OF63 puig100%2.04 x 108 rads

4. The manufacturer has thermally aged the UA 740 switch for 235.5 hours at200OF prior to the LOCA test simulation. Therefore, using this informationalong with a value of 0.958 for the activation energy we can calculate thequalified life.

'Per WBN Environmental Data Drawing 47E235-45R0.

-'t'J 9%, zbe- rY

Preparer/Date _______ ____ ___________ EQS No. WBNEEB0006

Reiwr/aeO Appendix 2 Rev 3Revewe/Dte /~i 4 3~i.. ..~6-~/ Sheet 3- of 7

Calculations --Qualified Life

Calculations are based on the Arrhenius equation which states:

Ll L2e [K j T2]

Where

Ll- Qualified life

L2- Accelerated (test) life

E - Worst case activation energy, eV

K - Boltzmann's constant, 8.617 x 10-5 eV/OK

Tj- Qualified temperature, absolute

T2- Elevated (test) temperature, absolute

e - Base of natural logarithms

Calculating the qualified life for the switches located in the IncoreInstrument room using the accelerated aging temperature for the switcheslisted in Appendix 1:

L2- 235.5 hours

Ti -750F -297 0K

T2-200OF 3660K

E - 0.958 eV

Ll- 235.5 e [8:~o5 27 - 36-11,392 days -31.2 years

FF CT rI VEiDATE

DC: 1J3

Preparer/Date ga EQS No. WBNEEB0006MAppendix 2 Rev 3Reviewer/Date 2,2443 Sheet 4 of 7

Calculations - Post-Accident Life

L2- 624-hours

E - 0.958 eV

T2- 200OF - 366 0K

Ti- 1520F - 3400K (temperature profile, WEN Environmental Data drawing 47E235-42;[1900F @ 6x103 sec -115

0F @ 30 days]/2 + 1150F)

I (1... 1) ro0.958 (K T1 T2 L8.617xl0 340 366J

Ll =L 2 e - 624 e- 265 days

This is 265 days equivalent at 152.50F and can be used to satisfy the post-DBElife of 100 days.

The above information shows that the switches are qualified for 31.2 yearsat the maximum normal operating temperature, radiation, humidity, and then forthe HSLB/LOCA conditions and for the post-accident life requirements. Satisfactoryperformance can be expected from the switches in the above environment.

5. Qualification Testing:

a. NAMCO has tested the model EA 740 limit switches to therequirements of IEEE Standard 323-1974 and NUREG-0588. The testcriteria and results are documented in NAMCO Controls Limit Switchmodel EA 740 to IEEE Standards 344 (1975), 323 (1974), and 382(1972) dated February 20, 1978.

All qualification tests were performed at test levels or conditions in excessof known maximum application requirements. These margins are in accordancewith the margins suggested in IEEE Standard 323-1974.

b. Thermal aging: The switches were subjected to an aging temperature of 200 Ffor a test duration of 235.5 hours. They were subjected to 100,000 actuationcycles in order to simulate the normal switching functnions of the unitduring its lifetime. Life at the base temperature of 750F, using theArrhenius equation with an activiation~energy of 0.958 eV, was determined tobe 31.2 years.

c. Radiation: The valves were subjected to cobalt 60 (GANHM) radiation at anexposure rate of less than one megarad per hour. Total integrated dosereceived was 204 megarads.

EFFEcrTIVEDATE /

Preparer/Date ___________ ________ EQS No. WBNEEB0006

A- A 1 Appendix 2 Rev 3Reviewer/Date ~ .Z1C Sheet 5..j. of 7L

d. beismic Simulation/Vibration Endurance: The switches were tested to a single.axis sinusoidal vibration in each of three mutually perpendicular axesparallel to the major dimensions of the switch, in 'accordance with IEEE 382-1974, 323-1974, and 344-1975. The test was performed with the switchesenergized and deenergized. The switches were monitored continuously forcontact opening of 2 milliseconds or greater.

e. LOCA Simulation: The valves vere subjected to a simulated loss-of-coolantaccident (LOCA) by exposure to steam and to chemical spray for 30 days. LOCAsimulation conditions were as follows:

Temperature - Maximum of 340OF for a total period of 3 hours followed by astep decrease to 2500F within 4 days followed by post-DEE conditions of20001 for the remaining 26 days.

Pressure - Maximum of 63 paig for a total period of 4 days fo llowed by a stepdecrease to 10 psig within 2-1/2 hours followed by post-DEE conditions of 10psig for the remaining 26 days.

f. Qualified Life - The solenoid valves have a qualified life of 31.2 years at750F and using a value of 0.958 eV for the activation energy, 2000F for T2and 235.5 hours for L2.

g. The switches are located inside containment where they are subjected tochemical spray.

A chemical solution consisting of boric acid, water, sodium thoiosulfate,and sodium hydroxide was sprayed on the sample at a rate corresponding to0.015 gallons per minute per foot of cross section. The chemical spraysolution pH was maintained between 10 and 11.

The chemical composition of Watts Bar containment spray is:

0.1844 molar H3B03 (200 ppm boron)

0.033 molar NaOH, resulting in a pH of 8.35

The switches successfully completed the LOCA profile test without incurringany operational or corrosion failures. Since the chemical concentration ofcontainment spray is less severe than~ the LOCA profile test concentrations,the switches should not be affected.

E F F E C-_7

Preparer/Date - A t Z)/~2fg QS No. WBNEEB0006Appendix 2 Rev 3Reviewer/Date ~ - -y Sheet 6- of L.

6. In otir..engineering judgment, the manufacturer's LOCA test profile (f igure 1) morethan satisfies the requirements of the actual MSLB/LOCA profile (figure 2). Inaddition, the LOCA test extends out to 722 hours (30 days) at 2060F, which ismore severe an ambience than the latter portions of the actual LOCA curve show.The last 624 hours can be used to demonstrate post-LOCA life capability. Thisperiod at 200OF can be shown to be equivalent to 265 days at 152.50F (seecalculation in 4 above) and, therefore, more than satisfies the 100-daypost-accident requirement.

F F E C I IV EDA T F

Preparer/Date ,KAWReviewer/Date A .z.F

EQS No. WBNEEB0006Appendix 2 Rev 3Sheet 7. of 7

1.The limit switches in Appendix 1 are NAMCO model EA-170. They arelocated in the Reactor Building (in the Containment Instrument Room).They are required to operate for 5 minutes after the start of allaccidents and to not fail in a manner detrimental to plant safety for1 month to 100 days thereafter (depending on which DBA occurs).

2. The limit switches are subject to LOCA and HELB conditions.required to operate in the following enviroaments2 : They are

Normal

Temperature:Pressure:Relative Humidity:Radiation:

Spray/Flooding:

7 5OF14.7 psia60%2x107 rads(40 yr TID)N/A

3270F26.4 psia

Ix108 rads

3*The manufacturer's specifications for the limit switches are:

Temperature:Pressure:Relative Humidity:Radiation:

200OFAtmNone given2.04 x 108 rads

4.These limit switches are not qualified for use in the Containment4 Instrument Room.

5. TVA will replace these devices per IOCFR5O.49 as determined by NCRWBNEEB8I67.

2See SQN/WBN Environmental Data drawing 47E235-48.

DEO6;03416l .02

Preparer/Date/7td-L ./.4 /9.ý-zý$-g 4 I

Reviewer/Date

EQS No. WBNEEB0006Appendix 3 -Rev -3Sheet 1 of I

The devices listed below require sealing of the conduit entrance.Qualificaktion of the conduit seals is documented in the referenced EQS.

Component UNID Q

l-FCV-31-306/ZSl1-FCV-31 -306 /ZS21 -FCV-31 -308 /zSl1-FCV-31-308/ZS21 -FCV-31 -329 /ZSl1 -FCV-31 -329 /ZS2

WBNWBNWBNWBNWBNWBN

EEB-CS C-iEEB-CSC-1EEB-CSC-iEEB-CSC-1EEB-CSC-1EEB-CSC-1

PFC T V EEAI

A T

DEO6 ;034161.02

unitMD. 1 and 2Revisaiona *Sno. WBNEEB U07

VPr~eparer/bate-&) bfa 4.. 6 Pe bAppendix 1

Reiewer/bate _;

Nmaufacturer and pbdel No See Appendix 1Verification of Taple Informt~ion (Table See Appendix 1X Ai2 tTM- The equipment has been identif ied as par WA ID numbe r

Xdesignations (such as, Nov. SM).LQAt±cn - The location has been identified (such as, inside prixy7containment, annulus, Individually cooled roai, general pspces, or area.X affected by IHL outside primary Containment).X Mi~eno - A unique MA ID number has been assigned (such as, l-MS-68-308).X Z~in- A functional description of the cmqxrt has been given (suhr ssteam generator blowdn.).ucasX -,trc N. Manufactrr a9nd Mkodel hb- - The contract number# manufacturer,anmd iel numrber have been given._Abrnnl or Accident Environment -All abnormal or accidient environmentalconditions applicable to this equipment have been identified either in tables orX by references to figures from~ tables.X !~iroz~et t WhCh OUALifi - The environment to which -the -euipment has beenqualified is addressed in either the tables or the envirornental wanlysis

attached.Fequipment. !KX ~ rto an AcayREquired and fl~nr~strated - The operation

-and accuracy required and demonstrated have been defined.qua lficatir tt5ch kifapia . ifn )Di~njjfiadz~iC (If equipment is qualified, indicate the qualif ied life with anumerical entry): 40 yearsQualfictio e ~~~ - A qualification report and the m ethod of Iqualification has been identifie on the Table Input Data Sheet (TMS) -X IvrnnnAl Analni j- An onvironmental analysis has been doae, attached to Lthe_____and____________ rviewe by the responsible organization.-N/A 0uli0 ato 1y F.imilArIty (If applicable) - A justification for cltlficationby similarity is attached to the EDS considering all the above factors andX referenced to the appropriate tables. I p i al) -W m a 0 su e

- Qualificatem, of eer lisx t of (lf e apcial)t frna ~ ueformoretcmitalstoall c tis given as an ap~with all references to appropriate tables. with justification for qualif icationN/A considering all the above factors.2aterin, Ou *fiCAtio (If applicable) - (Opn item) - Cm~ t has beendetermirsed to be qualified only for a limited interim operationr an RM hasbeen written, and plan of action has been determined to yield a qualifiedCompoent.Term of Interim Qualification_____________________

N/A ' - (Op~en item) (If~ applicable) - Czapent has ýbeendetermine ýto be urquzalified; the folloving is attached to EDS: MM nwter,,reason for noon-qualification, and Justification of continued operation.NMN. _ _ _ _ _ _

*Duje to the extensive changes from Revision 0, revision bars are not used.

Preparer/Date •%z ,

Revi ewer/Date______ ______

EQ o WBNEEB0007AppendiX1iVSheet 1 -of 1

Nanuf act urer

Component-

*1~

II,. ~ -)

ASCO

Solenoid Valve

1

±II-Fsv-1-47~

I 2-FSV-1-14-7

IT 1-Fsv-1-14

11 2-FSV-1-14-8

II 2-FSv-1-14-9

I 2-FSV-j-15p

2-LSV-3-17

Model No.

X-206 -381 -6RVF

t T830OB58RUY~2fl~.2D1 ~Dt7u

I --- '--

nli~o3uuBD)aU

X206-381-6-RVF

I RT83 OOB59R-U

i4X2U6-381-6RV -~

HT930OB58RU -

X206-381-3Rt

RT83 00B58RU

X206-381'-3RVU

T80OB58RU

Table/Sheet

3.11-8/WBNEEBcjOO3

3.1 1-8/ WBNEEBO 002

3 .11-8/WBNKEE-oO00

3 .11-8/WBNEU-OO03

3 .11-8/WBNEEBOOOF3

3 .11-8/WBNEEB0003

3 .ll-8/WBNEE-BOO03

3 .11-8/WBNEEB0OO3

3 .11-8/WBNEEB0003

Comiponent UNID

3.11-8/WBNEEB0003

-1

Preparer/Date __________/__47-2__ f________

Reviewer/ Date A' 1 9~gz-jV-EQS No. WBNEEB0007Appendix 2L Rev ISheet 1 of 8

UNIT 1 ONLY

1. For the solenoid valves listed in Appendix 1 under heading I and'II:

UNDNO,l-FSV-1-1471-FSV-1-148I-FSV-1-1491-FSV-1-1 50I-LSV--3-174I-LSV-3-175

MODEL NO,X206-381-6RVFX206-3 81 -6RVFX206-381-6RVFX206-381-6RVFX206-381-3RVUX206-3 81 -3RVU

SouthNorthNorthSouthSouthSouth

LOCATIONValve Room,Valve Room,Valve Room,Valve Room,Valve Room,Valve Room,

As detailed in EN DES Calculations (NEB 840515 219), for the Main SteamSystem and (NEB 840515 225) for the Main and Auxiliary Feedvater andFeedwater Control Systems; these valves are required to operate for five(5) minutes after the start of a Main Steam or Feedwater line break and notfail in a manner detrimental to plant safety for 100 days thereafter,

2a. The solenoid valves located in the North Valve Room are required tooperate in the following environment:1

Normal

Temperature;Pressure:Relative Humidity:Radiation:

Spray/Flooding:

Abnormal

130OFAtm50%3 .5x104 rads(40 yr TID)N/A

1 40OFAtm100%N/A

NIA

Accident

3 25 0F23.17 psia100%N/A

N/A2b. The solenoid valves located in the South Valve Room are required to operate

in the following environment:'

Normal

Temperature:Pressure:Relative Humidity:Radiation:

Spray/Flooding:

Abnormal

130OF14.7 psia,50%3.5xl05 rads(40 yr TID)N/A

140OF14.7 psia100%N/A

N/A

Accident

323 0F25.*18 psia100%N/A

NIA

'Per WIN Environmental Drawing 47E235-76, RO

E~ET IV'E'A TE

Elev.Elev.Elev.Elev.Elev.Elev.

729'729'729'729'729'729'

Preparer/Date 4 A.SýK'i EQS No. WBNEEB0007Appendix 2 Rev 1Reviewer/Date 7•/ .L.A.. .2f'Sheet 2 -of 8

3. ASCO h"s qualified these solenoid valves to the following:

Temperature: 3460 FPressure: 110 psigRelative Humidity: 100%Radiation: 2.0 x 108 rads (See Appendix 3)Spray: 3000 ppm Boron as boric acid in solution with 0.065

molar sodium thiosulfate buffered with sodiumhydioxide, pK 9-11.

4. Qualification Testing:

a. ASCO has tested the 206-381 series solenoid valves to the requirements ofIEEE Standard 323-1974 and NUREG-0588. The test criteria and results aredocumented in ASCO test report AQS21678/TR, Revision A, including supplement3. All qualification and tests were performed at test levels or conditionsin excess of known maximum application requirements.

b. Seven solenoid valve samples representing six generic families of valves,including the 206-381 series, were subjected to sequential exposures ofelevated temperature,; radiation, wear aging, seismic simulation, vibrationendurance, accident radiation, and a 30-day LOCA simulation. Baselinefunctional tests were performed before the start and after each sequence ofthe test exposure with the exception of coil dielectric and insulationresistance measurements which were taken before thermal aging, afteraccident radiation, and after LOCA exposure. The valves were en 'ergized anddeenergized at high and low pressures during the test phases (exceptradiation) and valve leakage monitored.

c. Baseline/Functional Test: Baseline/Functional tests consisted ofmeasurement of coil excitation, seat leakage at high and low pressures,noise test, operational test, and external leakage test before and after allphases of type tests. Measurement of insulation resistance and coildielectric test was performed in the as received condition and aftercompletion of accident radiation and LOCA simulation. Valves were energizedand deenergized and their operation monitored during test (exceptradiation).

d. Thermal aging: The valves were subjected to an aging temperature of 2680Ffor a test duration of 12 days. They, were cycled (deenergized for fiveminutes and then energized) every six hours.

e. Radiation: The valves were subjected to cobalt 60 (GAMMA) radiation at anexposure rate of less than one megarad per hour. Total integrated dosereceived was 50 megarads.

C'F C T I t

Preparer/Dat

Reviewer/Dat

eY &~ EQS No. WBNEEB0007Appendix 2 Rev I

aSheet 3~ of 8

f. 'Wearý-aging: The valves were electrically cycled 40,000 times at maximumpressure differential.

g. Seismic Simulation/Vibration Endurance: The valves vere subjected to acombined SSE and fragility test. The input g. level was 7 g's. The testwas performed with the valves energized and deenergized and with high andlow pressure. The leakage rate was monitored.

h. Accident Radiation: The valves were subjected to cobalt 60 (GAMMA)radiation at an exposure rate of less than one megarad per hour. Valvesreceived an additional accumulated dose of 150 megarads for a totalintegrated dose of 200 megarads received in two stages.

i. LOCA Simulation: The valves were subjected to a simulated loss-of-coolantaccident (LOCA) by exposure to steam and to chemical spray for 30 days.LOCA simulation conditions were as follows:

Temperature - Maximum of 34601 for a total period of six hours followed by astep decrease to 2000F within four days followed by post-DBE conditions of,20001 for the remaining 26 days.

Pressure - Maximum of 110 psig for a total period of six hours followed by astep decrease to 10 psig within four days followed by post-DBE conditions of10 psig for remaining 26 days.

Relative Humidity -All steam environment in excess of 25001; greater than1902 for other conditions.

Chemical Spray - The chemical solution consisted of 3000 ppm boron as boric,acid in solution with 0.064 molar sodium thiosulfate buffered with sodiumhydroxide. The chemical solution pH was maintained between 9.5 and 10.5.

j. Results: One of the valves malfunctioned during thermal aging. The valvedeveloped excessive seat leakage both in the energized and deenergizedstate. This was later determined to be caused by dirt in the valve. Thesource of dirt was the iron pipe used in the cylinder port as piping and anadditional length used to simulate an accumulator.

Other than the above malfunction, the valves sucessfully completed thesequential type tests and the baseline/functional tests.

5. Qual ified Life - The solenoid valves have a qualified life of 40 years at 130OFand 40,000 cycles, providing the maintenance schedule outlined in paragraph 7 isfollowed. Open and close completes one cycle. However, due to the self-heatingnature of solenoid valves, the temperature rise associated with a continuouslyenergized solenoid valve must be accounted for in the qualified lifecalculation. There are two areas affected by this heating: (1) the coil seesan increase of 105*C (221*F) above ambient and (2) the elastomeric discs see anincrease of 45*C (1131F) above ambient. These temperature increase values come

LU

L)

/ZA - ,-1,,4- /, - - - ,

Preparer/Date /t4A" 15; /4%, J•.V4 EQS No. WBNEEB0007- ) ý-- ý 1 7Appendix 2 Rev 1

Reviewer/Date It. 4ZL -u ~ -1&1%- Sheet 4 of 8.

from FranklinýýResearch Center's "Test Program and Failure Analysis of Class IsSolenoid Valves" (NUREG/CR-3424, F-C5569-309/315).

Based on the above information, a separate qualified life must be calculated for boththe coil and the disc. The following qualified life calculations, which are based onthe Arrhenius equation, are for valves to be used at a normal ambient operatingtemperature of 130*F (54.4*C):

Ll -L2e [K T T2]

COILS

In Franklin Research Center's "Test Program and Failure Analysis of Class lESolenoid Valves" (NUREG/CR-3424, F-C5569-309/315), the solenoid coils were aged attwo rates: 1500C (302*F) for 9.3 days (233.2 hours) and 131*C (268*F) for 15.3 days(367.2 hours).

Ll- Qualified life (first aging rate)

L2- Accelerated (test) life - 223.2 hours

E - Activation energy - 1.00 eV

K - Boltzmann's constant - 8.607 x 10-5 eV/PK

Tj- Qualified temperature (ambient + 105C) 159.4*C

T2- Elevated (test) temperature - 1500C + 1050C - 2550C

e - Base of natural logarithms

Ll'- Qualified life (second aging rate)

L2'-s 367.2 hours

E -1.00 eV

K - 8.617 x 10-5 eV/ K

T1'- 54.46C + 1050C -159.4*C

T2'- 131*C + 105*C -236*C

e - Base of natural logarithms

Ll (total) - Total qualified life - Ll Ll' - 5.645 years

EFECIVDATEocu-It

Preparer/Date 4••MAAI

Reviewer/DateAr 8

lueý Z19)J,-ZV EQS No. WBNEEB0007Appendix 2 Rev 1

k Oýa, T S4- Sheet 5. of 8.L..

DISCS

In ASCO test report AQS-21678/TR, supplement 3, the entire valve was aged at 1310C(2680F) for 12 days (288 hours).

Ll- Qualified life

L2- Accelerated (test) life - 288 hours

E - Activation energy - .94 eV

X - Boltzmann' s constant - 8.617 x 10-5 eV/*K

Tl- Qualified temperature - 13001

T2 - Elevated (test) temperature -1310C + 450C -1760C

e - Base of natural logarithms

Ll- 4.845 years

6. Installation - Valves should be installed such that the axis of thein the vertical and upright position.

coil remains

7. Maintenance Requirements - The qualified life depends on the valve being cycledat least every 16-18 months to ensure proper opening and closing. Coils shallbe replaced every 5.645 years and elastomeric components shall be replaced every4.845 years when solenoid valves are subjected to a normal operating ambienttemperature of 130*F. In addition, ASCO recommends that when the solenoidvalves reach 20,000 cycles, ~)at they be rebuilt using the applicable spareparts kit and spare coil kit'

8. Nuclear Regulatory Commission IE Information Notice No. 81-29, EquipmentQualification Notice No. 10 has identified. a pioblem with ASCO solenoid valveswith Viton Dynamic seals. The viton seals will1 adhere to metallic surfaces whenexposed to radiation doses in excess of 20( mdgarads. The environmental area inwhich these valves will be located in is well under this level. In ourengineering judgment, these valves will function satisfactorily in theenvironment in which they will be exposed.

9. Valves are qualified per IEEE Standard 323-1974, IEEE Standard 382-1972, IEEEStandard 344-1975, and applicable portions of NUREG-0588 for the environment inwhich they are required to operate, providing the maintenance schedule inparagraph 7 above is followed. By mathematical analysis, the qualified post-DBEoperating time can be extended to 153 days.

; ASCO Test Report

AQR67368/Rev. 0Appendix C, Page C-2

E F F E C T ~'

AT .

Preparer/Date________________ EQS No. WBNEEB0007

Appendix 2 RevI

Calculations - Post Accident Life

Calculations are based on the Arrhenius equation vhich states:

Ll- L2 e [~

Where

Ll- Qualified life

L2- Accelerated (test) life

El- Worst case activation energy, eV

K -Boltzmann's constant, 8.617 x 10-5 eV/OK

Tj- Qualified temperature, absolute

T2- Elevated (test) temperature, absolute

e - Base of natural logarithms

Calculate qualified post-accident life for the valves located in the North ValveRoom, using the accident temperature profile for the valves listed in Appendix 1:

L2- 29 days (AQS21678/TR Rev. A, figure 2, page 4-21)

El - 0.94 eV (AQR67368, Appendix B, page B-3)

T - 1650F (temperature profile, WBN environmental data drawings 47E235-76, 200OF@ 1 hour - 130OF @ .1 day/2 + 1300F)

T2- 200OF (AQS21678/TR Rev. A, figure 2, page 4-21)

L2 - 29 x 24 -696 hours

L1- .421 year x 365 -153 days

DAT,"

Preparer/Date ŽOa4, ~ -f-IRev iewer/ Date ¶.2 jg

EQS No. WBNEEB0007Appendix 2 Rev 1Sheet 7*. of 8

UN~IT 2 ONLY (Valves previously on WBNERB0036)

I.1. For the solenoid valves on Appendix 1 under heading 1:

2-F SV-1 -1472-FSV-1-1 502-LSV-3-1742-LSV-3-17 5

Located in South Valve Room, Elev. 729'to

The solenoid valves above are required to operate for five minutesafter the start of design-basis accidents and not to fail detrimentalto plant safety for 100 days thereafter.

2. The solenoid valves are subject to EELB conditions. They are requiredto operate in the following environment:1

Normal AccidentTemperature:Pressure:Relative Humidity:Radiation:

Spray/Flooding:

130OFAtm50%1.754103 rads(40 yr TID)N/A

2990F24.4 psia100%Z

441X10 4 rads(LOCA)N/A

3. The manufacturer's specifications for the solenoid valves are:

Temperature:Pressure:Relative Humidity:Radiation:

1040 FAtmNEMA 1 Enclosure4 x 15rads

4. The above information shows that these solenoid valves are notqualified for operation in the required accident environment. TVAwill replace these devices per IOCFR5O.49, as determined by NCRWBNEEB8I32.

'Per SQN/WBN Environmental Data Drawing 47E235-79.

EFFECTIVE,DATEiOCT 03 4

Preparer/ Date z,ý &-7---

Reviewer/Date ,.

Z QS No. WBNEEB0007Appendix 2 Rev _I

JT;'Sheet 8 of 8

UNIT 2 ONLY

II .For the solenoid valves on appendix 1 under heading II:

2-FSV-1-1482-F SV-1 -149

Located in North Valve Room, Elev. 729'of

The solenoid valves above are required to operate for five minutes afterthe start of design-basis accidents and not to fail detrimental to plantsafety for 100 days thereafter.

2. The solenoid valves are subject to BuLB conditions.required to operate in the following envirommenti:

They are required

Normal

Temperature:Pressure:Relative Humidity:Radiation:

Spray/Flooding:

13 OOFAtm50%3-54104 rads(40 yr TID)N/A

Accident

307OF22.9 psia100%IZI0 4 rads

N/A

3. The manufacturer's specifications for the solenoid valves are:

Temperature:Pressure:Relative Humidity:Radiation:

1040 FAtmNEMA 1 enclosure4U105 rads

4. The above information show. that these solenoid valves are notqualified for operation in the required accident environ~ment. TVAwill replace these devices per IOCFR5O.49, as determined by NCRWBNEEB81 32.

'See SQN/WBN Environmiental Data Drawings 47E235-79.

044145.03

Uniit NO. 1MS No. WBNEEB0079

MAI No.See Appendix 1_

Manufactdker and Model No. ASCO X206-381-3RPVerification of Table Information (Table -See Attachynent1

X Ui~ent ZU- The equipmient has been identified as per MA I numberdesignations (such as, icr, s1).

.. Lmatign - 7he location has been identified (such as9, inside prlizarycontainmento, annulus, Individually cooled rooms,, general spaces, or areaaffected by HEL8 outside primary containment).

Xy opn - A unique MA M numb~er has been assigned (such as, l-FSVI-68-3O8).yx mai - A functional description of the ccmponent has been given (such as,

steam generator blowdcorm).X !Qtract ?..Manufacturer, and Model Mao. - The contract numb~er, manufacturer,and model number have been given.X Abnr~oml or Accident Envirgnmnt - All abnormal or accident environmentalconditions applicable to this equipment have been identified either in tables orby references to figures from tables.

-2L &vrnentoW Ichnalifie - The environment to which the equipnent has beenqualified is addressed in either the tables or the environmental analysisattached.

X. QatgMz - A category of a, b, c, or d has been defined for theequipment.

X. Oration and Accura-Cy Reguired and Danutrate - The operationand accuracy required and demonstrated have been defined.

~~~~~~ liainSaus (check i f applicable. M~ if n ItQwl.ijedý .f (If equipmnent is qualifieds, indicate the qualified life with aCaifica 'on-Report And Method - A qualification report and the method ofqualification has been identified on the Table Input Data Sheet (Tm8S).*. Fviozi~tlAnalyais - An environmental analysis has been done, attached to

NAthe BUS, and independently reviewed by the responsible organization.NAOalification by Siallarity (if applicable) - A justification for qualificationby similarity is attached to the SOS considering all the above factors andreferenced to the appropriate tables.X Dual if ication of Several Exact Cawn~j~tI (If applicable) - When an EDS is usedfor more than one item, a list of mall exact corqxnents is given as an appendixwith all references to appropriate tables with justification for qualificationconsidering all1 the above factors.-NA Interim Oualificatign (If applicable) - (Open item) - Carqonent has beendetermined to be qualified only for a limited interim operation, an NCR hasbee written, and plan of action has been determined to yield a qualified

Term of Interim Qualification_____________________

NA I UAiidje - (Open item) - (If applicable) - Component has beendetermined tob unqualified; the following is attached to EDS: NC n~umber,,reason for non-qualification, and justification of continued operation.

*Due to extensive changes from Revision 0, revision bars are not used.

EFFECTIVEDATEf 1I

I

Pre are/D tr .YVEQS No. WBNEEB0009Reviwer/ateAppendix 1 Rev 1Reiee/Dt tiSheet -ITof I

Manuf acturer ASCO

Comiponerit: Solenoid Valve

Component LJNID Model No. Table/Sheet

I 1-PSV-1-13A X206-381-3Ry 3.1 1-8/WBNEEBOOJO

II 1PV--3 206-381-3R.F 3.11-8/WBNEEBOOIO

I l-PSV-1-24A X206-381-3R7 3 .11-8I(WBNEEBOOIO

II I-PSV-1-24B X206-381-3ay 3.11-8/WBNEEBOO1OI 1-PSV-1-31A X206-38*1-31U? 3.1 '-8/WBNEEBO0lO

II 1-PSV-1-31B X2O6-381-31Ry 3 .11-8/WBNEEBOO1O

I l-PSV-1-6A X206-381-3D1? 3 .11-8/WBNEEB0010

II l-PSV-1-6B 1206-381-3Rp 3 .11-8/WBNEEB0010

Preparer/Date z. i&'9J4Reviewer /Date 4?, 4.~~54

EQS No. WBNEEB0009Appendix 2 Rev 1Sheet 1 of 6

ar Te, 4loatd valves in Appendix 1 are ASCO model X206-381-3RF. Theyareloctedin the Auxiliary Building (North and South Steam Valverooks; 729/Al for South and 729/A2 for North). As detailed in EN DESCalculation NEB 840314 220, the devices marked I on Appendix 1 arerequired to operate for 5 minutes and not fail in a manner detrimentalto plant safety for 100 days after breaks in either Main Steam orFeedvater lines. The devices marked II on Appendix I are required tooperate for 100 days after breaks in either Main Steam of Feedwaterlines.

II. The solenoid valves are required to operate in the followingenvironment 1 :

Normal Abnormal Accident

Temperature:.Pressure:Relative Humidity:Radiation:

Spray/Flooding:

13 0OFAtm(-)50%3.5x104 rads (A)3.5x10 5 rads (Al)(40 yr TID)N/A

140OFAtm( -)100%N/A

3 250F25.18 psia100%NIA

NIA N/AIII. ASCO has tested this valve to the following environment:

Temperature:Pressure;Relative Humidity:Radiation:Spray:

346 0F110 psig100%2 x 18rads3000 ppm BORON/pH 9-11

'Per WBN Environmental Data Drawing 47E235-76 RO.

DATE

Preparer/Date ___________________ EQS No. WBNEEB0009

Appendix 2 Rev 1Reviewer/Date OeiLŽ'A aiA... 7 -a 41 Sheet 2 of 6

IV. I. Qu4Lification Testing:

a.- ASCO has tested the 206-380 and 206-381 series solenoid valves to therequirements of IEEE Standard 323-1974 and NUREG-0588. The test criteriaand results are documented in ASCO test report AQS21678/TR, Revision A,including supplement 3. All qualification and tests were performed at testlevels or conditions in excess of known maximum application requirements.These margins are in accordance with the margins suggested by IEEE Standard323-1974.

b. Seven solenoid valve samples representing six generic families of valves,including the 206-380 and 206-381 series, were subjected to sequentialexposures of elevated temperature, radiation, wear aging, seismicsimulation, vibration endurance, accident radiation, and a 30-day LOCAsimulation. Baseline functional tests were performed before the start andafter each sequence of the test exposure with the exception of coildielectric and insulation resistance measurements which were taken beforethermal aging, after accident radiation, and after LOCA exposure. Thevalves were energized and deenergized at high and low pressures during thetest phases (except radiation) and valve leakage monitored.

c. Baseline/Functional Test: Baseline/Functional tests consisted ofmeasurement of coil excitation, seat leakage at high and low pressures,noise test, operational test, and external leakage test before and after allphases of type tests. Measurement of insulation resistance and coildielectric test was performed in the as received condition and aftercompletion of accident radiation and LOCA simulation. Valves were energizedand deenergized and their operation monitored during test-(exceptradiation).

d. Thermal aging: The valves were subjected to an aging temperature of 268OFfor a test duration of 12 days. They were cycled (deenergized for fiveminutes and then energized) every six hours.

e. Radiation: The valves were subjected to cobalt 60 (GAMMA) radiation at anexposure rate of less than one megarad per hour. Total integrated dosereceived was 50 megarads.

f. Wear aging: The valves were electrically cycled 40,000 times at maximumpressure differential.

g. Seismic Simulation/Vibration Endurance: The valves were subjected to acombined SSE and fragility test. The input g. level was 7 g's. The testwas performed with the valves energized and deenergized and with high andlow pressure. The leakage rate was monitored.

E F rjoCTI

Preparer/Date - Z 2a. /0ý_' SY/ EQS No. WBNEEBOOO9

9,2fV Appendix 2 Rev 1Revijewer/Date ~ Ef/ Sheet 3 of 6

hi. Accident Radiation: The valves were subjected to cobalt 60 (GAMMA)Z.adiation at an exposure rate of less than one megarad per hour. Valvesreceived an additional accumulated dose of 150 megarads for a totalintegrated dose of 200 megarads received in tvo stages.

i. LOCA Simulation: The valves were subjected to a simulated loss-of-coolantaccident (LOCA) by exposure to steam and to chemical spray for 30 days.LOCA simulation conditions were as follows:

Temperature - Maximum of 346*F for a total period of six hours followed by astep decrease to 200*F within four days followed by post-DBE conditions of2000F for the remaining 26 days.

Pressure - Maximum of 110 psi& for a total period of six hours followed by astep decrease to 10 psig within four days followed by post-DBE conditions of10 psig for remaining 26 days.

Relative Humidity - All steam environmient in excess of 250*F; greater than90% for other conditions.

Chemical Spray - The chemical solution consisted of 3000.ppm boron as boricacid in solution with 0.064 molar sodium thiosulfate buffered with sodiumhydroxide. The chemical solution pH was maintained between 9.5 and 10.5.

j. Results: One of the valves malfunctioned during thermal aging. The valvedeveloped excessive seat leakage both in the energized and deenergizedstate. This was later determined to be caused by dirt in the valve. Thesource of dirt was the iron pipe used in the cylinder port as piping and anadditional length used to simulate an accumulator.

Other than the above malfunction, the valves suceasfully completed thesequential type tests and the baseline/functional tests.

2. Qualified Life - The solenoid valves have a qualified life of 40 years at 1300Fand 40,000 cycles, providing the mainteannce schedule outlined in paragraph 4 isfollowed. Open and close completes one cycle. However, due to the self-heatingnature of solenoid valves, the temperature rise associated with a continuouslyenergized solenoid valve must be accounted for in the qualified lifecalculation. There are two areas affected by this heating: (1) the coil seesan increase of 105*C (221*F) above ambient and (2) the elastomeric discs see anincrease of 450C (1130F) above ambient. These temperature increase values comefrom Franklin Research Center's "Test Program and Failure Analysis of Class 1ESolenoid Valves" (NUREG/CR-3424, F-C5569-309/315).

Based on the above information, a separate 'qualified life must be calculated for boththe coil and the disc. The following qualified life calculations, which are based onthe Arrhenius equation, are for valves to be used at a normal ambient operatingtemperature of 130OF (54.40C):

EF F E C

Preparer/Dateý- 01W___________ EQS No. WBNEEB0009

.. i Appendix 2 Rev IReviewer/Date 41. -:f..4E-i7 ~ Sheet 4 of 6

L- L2e.[ T _ T2 ]

COILS

In Franklin Research Center's "Test Program and Failure Analysis of Class 1ESolenoid Valves" (NUREG/CR-3424, F-C5569-309/315), the solenoid coils were aged attwo rates: 150*C (3O2*F) for 9.3 days (223.2 hours) and 131*C (268PF) for 15.3 days(367 .2 hours) .

L4 - Qualified life (first aging rate)

L2-Accelerated (test) life - 223.2 hours

E - Activation energy - 1.00 eV

K - Boltzmann's constant - 8.617 x 10-5 eV/*K

Tj- Qualified temperature (ambient + 105*C) - 159.4*C

T2- Elevated (test) temperature -150*C + 105*C -255*C

e - Base of natural logarithms

Ll'- Qualified life (second aging rate)

L2 '- 367.2 hours

E - 1.00 eV

K - 8.617 x 10-5 eV/0K

Til- 54.40C + 1050C = 159.4*C

T2'- 131*C + 105*C - 236*C

e - Base of natural logarithms

Ll (total) -Total qualified life -l + Lj' -5.645 years

F F CIV EAT E1-98

Preparer /Date//%2 AZ #~.S/

Reviewer/Date ~ ~ .2.'EQS No. WBNEEB0009Appendix 2 -Rev 1Sheet --I: of 6

DISCS

In ASCO test report AQS-21678/TR, supplement 3, the entire v alve was aged at 131C.(2680F) for 12 days (288 hours).

Ll- Qualified life

L2-Accelerated (test) life = 288 hours

E - Activation energy - .94 eV

K -Boltzmann's constant - 8.617 x 10-5 eV/OK

T* Qualified temperature - 1300F

T2- Elevated (test) temperature - 1310C + 450C -1760C

e -Base of natural logarithms

Ll- 4.845 years

3. Installation - Valves should be installed such that the axis of thein the vertical and upright position. coil remains

4.Haintenance Requirements - The qualified life depends on the valve being cycledat least every 16-18 months to ensure proper opening and closing. Coils shallbe replaced every 5.645 years, and elastonieric components shall be replacedevery 4.845 years when solenoid valves are subjected to a normal operatingambient temperature of 1300 F. In addition ASCO recommends that when solenoidvalves reach 20,000 cycles, that they be rebuilt using the applicable spareparts kit and spare coil kit.2

5. Valves are qualified per IEEE Standard 323-1974, IEEE Standard 382-1972, IEEEStandard 344-1975, and applicable portions of NUREG-0588 for. the environmient inwhich they are required to operate, providing the maintenance schedule inparagraph 4 above is followed. By mathematical analysis, the qualified post-DBEoperating time can be extended to 153 days.

Calculations - Post Accident Life

Calculations are based on the Arrhenius equation which states:

-l L2 e K T

2ASCO Test ReportAQR67368/Rev. 0Appendix C, Page C-2

T2~

EFFCTIVDATE(JEFF E C T

I 4

Preparer/Date A/~kAA t~ /'9.)~ EQS No. WBNEEB0009Revewr/DteAppendix 2 Rev 1ReviwerDat ~ 2~-'(/ Sheet 6 of 6

Where

Ll- Qualified life

L2- Accelerated (test) life

El- Worst case activation energy, eV

K - Boltzmiann's constant, 8.617 x 10-5 eV/OK

Ti- Qualified temperature, absolute

T2- Elevated (test) temperature, absolute

e - Base of natural logarithms

Calculate qualified post-accident life for valves located in either room usingaccident temperature profile for valves listed in Appendix 1:

L2 29 days (AQS21678/TR Rev. A, figure 2, page 4-21)

El- 0.94 eV (AQR67368, Appendix B, page B-3)

Ti-1650F (temperature profile, WBN envirormental data drawing 47E235-76, 200OF@ 1 hour - 130OF @ 1 day/2 + 1306F

T2- 200OF (AQS21678/TR Rev. A, figure 2, page 4-21)

L2- 29 x 24 - 696 hours

L1- .421 years x 365 -153 days

014139.07

E rC T IVEF ATE

Preparer/Dat KZ\A~ ~fA-9Reviewer/DateZZ /•.g, .~.. -~~

EQS No. WBNEEB009Appendix 3 Rev 1Sheet 1 of 1

The devik~ps listed below require sealing of the conduit entrance.'Qualification of the conduit seals is documented in the referencedEQS.

Component UNID, EQS

1-PSV-1-13B1 -PSV-1 -24B1-PSV-1-31B1 -PSV-1 -6B

WBN-EEB-CSC-11WBN-EEB-CSC-l,WBN-EEB-CSC-1,WBN-EEE-CSM-1,,

WBNWBNWBNWBN

EEB-CON-lEtB-CON-1EEB-CON-lEEB-CON-l

FEF FEECT IVE.) DA TE.

OGT I~S

DEO7 ;014139 .07

iReviewer/ te/ 4u/..9-g'

- is -

Mmnufactwe-r wad Model No. Fenwal model 17323-0Verification of Thble Information (Table -See Agpendix 1

X JWU t a- The equipment has been identified as per MV ID number

IWA M -Theloaso hasV ben detiie (such ass, inside primarycontainments, annulus, individually cooled rooms, general spacess, or areaaffected bY HEM outside primary containment).X nm - A unique TVA ID numb~er has been assigned (such as,, l-FSV-68-308).X IMCUM- A functional description of the c=qment has been given (such as,stemt generator blowdown).

JX Q~nract NU.. Manufacturer, and Hg~,dl No. - The contract numbers, manufacturers,and model number have been given.--Z Ahbrnml or Aceident FExviranunt -All abnormal or accident environmentalconditions applicable to this equipment have been identified either in tables orX by references to figures from~ tables.X nwironmt to 0h11 Pualifieid - The environment to which the equipment has beenqualified is addressed in either the tables or the environme'ntal wanlysisattached..

== - Acategory ofas, b, cl, or dhas been defined for theX XatAeptio and Accuracy Hiquired -and Den~strated -The operation

and accuracy required and demonst~rated have been defined.

00u1lefation Status (check-# i M iUlablp. a if o)agg- f j Lfa(If equipment is qualif ied, indicate the qualified life with an~umerical entry): 4 rQualification Bepot and Itbethd - A qualification report and the method ofqualification has been identified on the Table Input Data Sheet (TIDS).X2 Bm ~a Alzf - An envirozuental analysis has been done, attached tothe EDS, and independently reviewed by the responsible organization.-a uaification by fimla-r~ity (If applicable) - A justification for qualificationby similarity is attached to the EjS considering all the above factors andreferenced to the appropriate tables.X Q lification of Svral Exra ct n (if applicable) - WGhen an SOS is usedfor more than one item, a litof all exact cuoet sgvna napniwith all references to appropriate tables with justification for qualificationc ons idering all the above factors.

-NA kIntraQua if ial-Im (If applicable) - (Opzen item) - a nethsbndetermined to be qualified only for a limited interim operation, an NM hasbeen written, and plan of action has been determined to yield a qualifiedTlerm of Interim Qualification_____________________

NC o.NA. M=lfa mo - (Cpen item) - (If applicable) - Cqoet has beendetermined to be unqualified; the following is attace to BDS: M numbers,reason for non-qualification, and justification of cotinued operation.LEFFECThVECDATE

Of4U 1 1. ":

4

~kit Wio. 1 and 2EQS No. WBNEEBOO11MV ID NO.

See Appendix I

Preparer/Date_ _____EQS No.Appendix 1 Rev3 _Sheet I of

Manuf adturer .. engyi

Cornponen..t TIE~ner~aturg' Svitreh

1.

L.A )

1-TS-1-17A

2-TS-1-17A

1-TS-1-17B

2-TS-1-17B

1-TS-1-18A

2-TS-1-18A

1-TS-1-18B

2-TS-1-18B

Model No.4 1

17323-0

3 .11-8/WBNEEBOOO11 7~2...fla, A 3..LJ.-~IWENEEBDOOI

17323-0

17323-0

17323-0

17 323-0

17323-0

17323-0

Table/Sheet

3 .11-8/WBNEEBOOO1 I3.11~6IwBNEEBooo1 I

3 .11-8/WBNEEB00013-I1-6 /NELEBM 1

3 .11-83/WBNEEB00013.11-6/WBNEEBOOOI3 .11-8/WBNEEBOOO13.11-6/WBNEEBOOOI3 .11-8/WBNEEBOOOI3.11-6/WBNEEBOOOI3 .11-8/WBNEEBOOO13 .11-6/WBNEEBOOO13 .11-8/WBNEEBOOO13 .11-6/WBNEEB0001

Comnponent UNID

J.JLJ-b/WBNEEBnAnl

3.11-8/WBZEEBOOOI

Preparer/Date X__1____________________

Review-er/Date

EQS No. WBNEEBO0llAppendix 2 Rev 3Sheet 1 of .3

1. The-temperature switches in Appendix 1 are Fenval model No. 17323-0.They are located in the Auxiliary Building (692/A6 for unit 1 devicesand 692/A26 for unit 2 devices), in General Space areas. As detailedin EN DES Calculations NEB 840515 219 for the Main Steam System, theseswitches are required to operate for five minutes after the start of aline break in the Auxiliary Feedwater System. They must not fail in amanner detrimental to plant safety for 100 days after the start of aLOCA.

2. The switches are subject to HELB conditions (Volume 5) and are affectedslightly by a LOCA. They are exposed to the following environmentsi:

Abnormal Accident

Temperature:Pressure:Relative Humidity:Radiation:

Spray/Flooding:

104 0 FAtm(-)80%54102 rads(40 years TID)N/A

110OF (Note 2)Atm(-)90% (Note 2)N/A

N/A

211 OF14.46 psia100%IX104 rads(LOCA)

N/A

3. TVA, through testing done by Wyle Laboratories, has qualified theFenwal temperature switches listed in Appendix 1 to the requirementsdelineated in IEEE S 'tandard 323-1974. Test procedures and results aredocumented in Wyle Laboratories Nuclear Environmental QualificationTest Report No. 17509-1 dated May 16, 1983. All qualification testswere performed at test levels or conditions in excess of known maximumapplication requirements. margins were ini accordance with thosesuggested by IEEE Standard 323-1974.

*( yle Laboratories has tested these switches, to the following.environment:

Normal

Temperature:Pressure:Relative Humidity:Radiation:LOCA/HELB:

172.407 (7800)Atmospheric80%N/A(See description below)

Accident

323 Op

7.9 psig (22.3 psia)100%NIA

Notes:

'See WIN Environmental Data Drawings 47E235-69 RI and 47E235-68 RO.

2This abnormal condition could exist for up to 8 hours per excursion andwill occur less than 1% of the plant life (plant life - 40 years).

Preparer/Date 9'1 4unj,Eý t/?.2LWe EQS No. WBNEEBO0llf Appendix 2 Rev. 3

Reviewer/Date A IILdd-l.. -27-, Sheet 2j. of 3 -

The' equipment was subjected to a LOCA/HELB simulation test. Thetransient portion of the test vas repeated twice as required by IEEEStandard 323-1974.

During the first temperature excursion (Margin Ramp), the temperaturerequirement of 3230F was attained in 24 seconds. There was no pressurerequirement during this portion of the accident test.

The second temperature ramp (Main Ramp) was started after the testchamber temperature vas stabilized at 1000F. During this ramp, thetemperature requirement of 3230F in 25 seconds was reached in 24seconds. The pressure requirement of 7.9 psi8 in 3.0 seconds wasreached in approximately 1.5 seconds. Due to the chamber temperaturefalling below 2120F, the chamber pressure was vented to atmospheric atthe 9.5 hour mark of the test. The accident test was ended at the 24hour mark. No post-accident aging was required for these switches.

The Fenwal temperature switch (model 17323-0) was shown to have a 40year qualified life with a 3 -year unattended maintenance period.Additionally, the switch demonstrated a 110 day post-accident lifein accordance with IEEE Standard 323-1974.

The post-LOCA life requirement can be extrapolated from the actualtest using the Arrhenius Equation, which states:

Ll L2 e

where: 77FLl- Qualified life D AC V~L2- Accelerated (test) life ~*4

E - Worst case activation energy, eV oK - Boltzmann's constant, 8.617K10-5 GV/ K ITl- Qualified temperatureT2- Elevated (test) temperature, absolute

e -Base of natural logarithms

Using the portion of the temperature versus time profile (shown inFigure X-1, page No. X-16, of Report No. 17509-1) that extends from24601 at 120 seconds to 14001 at 24 hours, gives 23.97 hours at aT2 Of 19301*. Using a conservative value of 16001 for T2, 11001 forT1 , and 1.69 eV as a conservative value for E, 148.2 days can bederived from the Arrhenius equation. This post-LOCA life of 148.2 daysexceeds the l00-day requirement delineated in paragraph 1 of Appendix2.

*1930p is an average value obtained from the post-transient portion ofthe temperature vs time profile: (246OF + 1400F)/2

Preparer/Date -tl 9M O(Z-

Rev iewejDa teA4 -2-7- TV

EQS No. WBNEEBOO11Appendix 2 Rev 3Sheet 3 of 3

Based on the above test results, these switches are qualified for Class1E operation in the required environments and will remain operationalfor the required 5 minutes post-DBE period.,

014135.03

Cz T

D A TEGu; L

GENERAL ACCIDENT TESTENVELOPE TEMPERATURE PROFILEFOR ALL TEST SPECIMENS

3230F for 10 seconds

323 at 25 seconds

-~ 315 at 30 seconds

246 at 120 seconds

140OF 24 hours

CA

3060 901 12030,

v 8 hours

-1

200

0ý CL"

C> -

wJ0

0

'1 4

1-& .0

00 10 (0 m.

?1 3m .

f ME F-11 t - --I

Unit Mo. 1 and 2Reiion 1 &02* MS NO. WBNER001.5

Prepaer/bte X A/VoSee Appendix 1

WBN ME=U~ N OMUALFICMION SHMM (ES)

Manufacturer and Model No. See, Appendix 1 . j _________

Verification Of Table Information (Table SeeAppndx1_____1____

-. 2L M =Mt MW- The equipment has been identified as per TVA M numberdesignations (such as, MC7J, sM 1. L

x __ tJ - The location has been identified (such ass, inside primarycontainment, annulus, individually cooled roome, general spaceso, or areaaffected by HELB outside primary contairnment).

_2L QUMM=- A unique TVA 3D numb~er has been assigned (such as,, l-FSV-68-308ý.-x Fucin- A functional description of the comiponent has been given (such as,steam generator blowdaiun).

__z Contrac No.. NMnufacturer, and H2&el Na. - The contract nwrberj, manufacturer,,and model number have been given.

SAbnormal or Accident Environmen - All abnormal or accident environmentalconditions applicable to this equipmnent have been identified either in tables orby references to figures fromn tables.

*C Evironment to Which Qualified - The environment to which the equipment has beenqualified is addressed in either the tables or the environmental analysisattached.X Qk= - A category of a, b, c, or dhas been defined for the

x Operation and Accuracy Reqired and pemm~strAted - The operationand accuracy required and demonstrated have been defined.

Qualification Status (check if applicable. NA if not)00iid-of (If equipment is qualified, indicate the qualified life with anumerical entry): 46 years

X ualfcat ion Reprt andi Met1hd - A qualification report and the method ofqualification has ben identified on the Table Input Data Sheet (T=DS).X En~ire1wungtA1....nAJIMI - An environmental analysis has been done, attached toNAthe EQS, and independently reviewed by the responsible organization.NAOualificatiOn by SiMilArity (If applicable) - A justification for qualification

by similarity is attached -to the BDS considering all the above factors andX referenced to the appropriate tables.X Oulification of Several Exact ConConent (If applicable) - When an EDS is used

for more than one item, a list Of all exact components is given as an appendixwith all references to appropriate tables with justification for qualificationNAconsidering all the above factors.N/AInteriM Oualificat -i on (If applicable) - (Open item) - Component has been

determined to be qualified only for a limited interim operation,, an NCR hasbeen written, and plan of action has been determined to yield a qualifiedconqpcment.Term of Interim Qualification_____________________NCRNo.

2LLA IumllifJied urMier - (Open item) - (If applicable) - Caqcnent has beendetermined to be unqualified; the following is attached to EDS: NM number,,reason for non-qualification, and Justification of continued operation.NC No. __ _ _ __ _ _

*Due to the extensive changes from Revision 1, revision bars are not used.

?yrapdrer/UVII~e

Revi ewer/Date

Kanuf acturer Dwyer /Fluid Components, Inc. (FCI)*

Flow Switch Sensor

COMPO" ent UNID

1-FE-30-.194*

2-FS-3O.-l94**

1-FE-30-195*

2-F S-30-195*

FR-72-4

D~wyer (1627-1)

FR-72-4

Dwyer (1627-1)

Tabl e/Sheat

L3.11-7JWBNEEB00o33. 11-8/WBNEEBOOO13. 11-7/WBNEEBOOO33. 11-8/WBNEEB00063. 11-7IWB' NEEBW0033. 11-8/WBNEEB0001

3. 11-7/WBNEEBOOO3

1a

LU

LU

"I No.

Preparer/Date - '1 -Cl

Reviewer/Date

EQS No. VBNEEB0015- -Appendix 2 Rev - -2Sheet - 17- of 4

UNIT 1- ONL~Y

I. The s .ensors listed in Appendix 1 are Fluid Components, Incorporated (FId)Model FR-72-4. FCI has qualified these sensors to the requirementsdelineated in IEEE Standard 323-1974. Test procedures and results aredocumented in FCI report No. 708053 dated 8-28-80.

These sensors are located in the Auxiliary Building at elevation 737, RoomA5. As detailed in EN DES Calculation WIB 840517 222, for the ContainmentVentilation System, these sensors are required to operate for 100 daysafter a LOCA and are required to operate for 1 month after an AuxiliaryBoiler, Auxiliary Feedwater, CVCS, and RER line break.

2Reratinit Environment

The sensors are required to operate in the following enviromment:1

Normal

Temiperature:Pressure:Relative Humidity:Radiation:

Spray/Flooding:

1040FAtm(-)80Z3 .4x104

(40 yr TID)N/A

Abnorma

Atm (-90Z

N/A

NIA

Acc-ident

1920FH/A

IM0rads

N/AThe manufacturer has tested these sensors in the following environment:

Temperature:Pressure:Relative Humidity:Radiation:LOCA/HELB

32 to 340OF43 PSI100%14108 rads(see description below)

lSee WBN Environmental Data Drawings 47Z235-48 RI and 472235-49 RI for DBEEtemperature and pressure profiles.

Preparer/Date 1§ 6C- J> EQS No. WBNEEB0015Appendix 2 Rev 2

Rev iewer/Dat e/_~ItA Z0ý4 ~-tqt Sheet 2 of 4

In order for the equipment to survive a DBE, it was necessary to remotelylocate-tfie electronic portion. of those devices that are exposed totemperatures in excess of 1500F. I-FS-30-194 and 1-FS-30-195 which are theelectronics portion of 1-FE-30-194 and 1-FE-30-195 are located in a mildenvironment. A remotely controlled sensor head can be simulated byseparating the sensor head from the electronics and connecting the tvotogether by cable. This enables testing of the two elements to theenvironment each would encounter.

The sensor was placed in a chamber and the temperature was increased to340OF @100% relative humidity and 43 psig and was maintained for 6 hours.The chamber was then cooled to 30OF for 2 hours and again increased to3400F, 100% rh, and 43 psig for an additional 6 hours. Next, the chambertemperature was lowered to 200OF following the temperature profile curveof Figure 1. At the end of 4 days, the unit xas returned to laboratory.conditions.

The post DBE life requirement can be extrapolated from the 4-day test usingthe Arrhenius Equation which states:

K T 1 T 2Ll- L2 e

Where

Li- Qualified life

L2- Accelerated (test) life

El- Worst case activation energy, eV

K - Boltzmann's constant, 8.617 x 10-5 eV/0K

Tl- Qualified temperature, absolute

T2 Elevated (test) temperature absolute

E - Base of natural logarithms

Ref erence: EPRI, NP-1558, Research Project 890-1, dated September1980.

E Er F C: I` V IED AT E

Preparer/Date

Reviewer/Date ( w

EQS No. WBNEEB0015Appendix 2 Rev 2Sheet 3 of 4

The portion of the temperature versus time profile (shown in Figure 1)that extends from 300OF at 11 hour. to 300OF at 15 hours yields a qualifiedlife of 0003 years using the Airhenius Equation. Then using the portionof the temperature versus time profile that extends from 250OF at 15 hoursto 250OF at 4 days yields a qualified life of 0.209 years. [Note that theactivation energy used, 1.19eV, vas documented by FCI in a letter fromWayne Franz, Nuclear Qualification Specialist, to Ray Shutt of TVA, datedMarch 15, 1984 (EEB 840514 008)). This yieldsa total postaccident life of0.312 years which is in excess of 100 days.

A-zing (Qualified Life)

FCI has thermally aged the sensors for 336 hours at 1000C. The qualifiedlife for these sensors is 46.36 years based on the Arrenius Equation.Note that the activation energy is 1.19eV per information attached toletter from FCI Wayne Franz, Nuclear Qualification Specialist, toRay Shutt of TVA, dated March 15, 1984 (EKE 840514 008).

034145.03

EF~2c'r r~jE F

Preparer/Date C

Reviewer/Date 6// 'Y

EOS No. WBNEEB0015Appendix '2 Rev- 2Sheet 4 o f

UNIT 2 ONLY

ii. 2-FS-30-194 and 2.-FS-30-195

1. These flow switches are Dwyer model 1627-1. They' are located inthe Auxiliary Building (Penetration Rooms - 737/A5 and A9). Theyare required to operate for one month after the atart of variousdesign-basis accidents. Opertion is not required during or aftera LOCA/HELB inside containment..

2. The switches are subject to MELS conditiomv(Volumie 14). They arerequired to operate in the following environment~s2:

Normal

Temperature:Pressure:Relative Humidity:Radiation: Unit 1:

Unit 2:

Spray/Flooding:

10407At.= -80%3.5 x lO3rads(4 years TID)3.5 z l02rads(40 years TID)N/A

3. The manufacturer's specifications for the switches are:

Temperature:Pressure:Relative Humidity:Radiation:

13007AtmNot SpecifiedNot Specified

4. See generic position 4.1.8 for relative humidity. See genericposition 4.1.5 for radiation.

5. Available documentation indicates that these flow switches are notqualified for their temperature environment during certainaccidents.

6. TVA will replace these devices per IOCFR50.49 ,as determined by NCRWBNEEB8l52.

2See SQN/WBN Environmental Data drawing 471235-51.

APND.3

Accident

19507Atz W.100%E/A

N/A

N/A

EQS No. WBNEEB0015Appendix .2 Rev. 2FIGURE 1

TestI Chamber Temperature Profile for Environment Simulation (Combined PWIt/13Wft)

TRANSIENT DURING AND FOLLOWINGA DESIGN &ASIS EVENT

15 min-ShiO0 6

TIREC- *'* .~e Wt* n-n .. - - -

E F F F

- ~

ADDITIONALPEAKTRANSI ENT

31.0

320

300

280

200

11.0

5 min

I

1; 1

Preparer/Date I

Reviewer/Date A / ~ -/Pr2-0ý- 1 6 -Y- io ± -

The devices listed below require sealing of the conduit entrance.Qualification of the conduit seals is documented in the referenced EQS.

Component UNID Q

1-FE-30-1941-FE-30-195

WEN EEB-CSC-1WBN EEB-CSC-1

034145.03

E V F".~vDC

EQS No. WBNEEB0015Appendixii W YvSheet 1- of I

Unit 1b. 1 and 2ZQS No. WBNEEB00167VA IDNo.

See AP~endix 1

[4anufactbjrer .and Mo~del No. Se A end ix 1Verification of ftle Information (Table S-ee AppandIx I

X Bi~t - The equipinet has been identified as per TVA ID numberdesignations (such as,, 9ov, sCW).X2 &CU - The location has been identified (such as,.inside prlimarycontainment, annulus,, individually cooled roams, general spaces,,or areaaffected by HEB outside primary containmrent).X CM - A unique 7VA ID number has been assigned (such as,, l-FSV-68-3O8).X h~tM- A functional description of the cmonent has been given (such as,stemn generator blawdc~wn).X Q~nract -. Umnufacturer. and Model No. - The contract number,, manufacturer,,and model number have been given..X Abnormal or Accident- E1virgmnnt - All abnormal or accident environmentalconditions applicable to this equipment have been identified either in tables orby references to figures from tables.2- ivromant to Which Oualified - The environment to which the equipment has beenqualified is addressed in either the tables or the environmental analysisattached.-x Ct - Acategory of a,, b,, c,, or dhas been defined for the.X~ Opration and -Accura~cy Recired and flemonstralad - The operationand accuracy required and demonstrated have been defined.Oualificatio S ts(c ck if ap~licable. NR if mat)Qifie.zLife (If equipment is qualified, indicate the qualified life with an~umerical entry): 10ye

Y.~ OulfctinRjrt and Methbd A qualification report and the method ofqaiication has been identif ied on the Table Input Data Sheet (TIDS).-X Mvra fa1&~-f - A~n environmental analysis has been dones, attached tothe QSj, and independently reviewed by the responsible organization..NA Oua~lification by Simil~arity (If applicable) - A justification for qualificationby similarity is attached to the EQS considering all the above factors andreferenced to the appropriate tables.X Qmalificatign of Several Exac Lnro~neats (If applicable) - When an EDS is usedfor more than one itun, a list of all exact em~ms is given as an appendixwith all references to appropriate tables with justification for qualificationconsidering all the above factors..NIA Interimn OUA1ifi cat-ion (If applicable) - (open item) - Cqrthsbedetermined to be qualified only for a limited interim operation, an NM hasbeen written,, and plan of action has been determined to yield a qualifiedCOmxnent.

Term of Interim Qualification

NA ~ -(Openitem) -(If applicable) - VM t has ben ''determinhed to be unqualified; the following is attached to ZBOS: MMMreason for non-qualification,, and justification of continued operation.

*Due to the extensive revisions to revision 2, revision bars are not used. //':1

I

Preparer/Date J?. (f~ujO/oI-~

Reviewer/Date A ? 4 1 ~q 0-

EQS No. WBNEEB0016Appendix I Rev -3Sheet 1 of I

Manufacturer Automatic Switch Company (ASCO)

Component Pressure Switch

VolComponent UNID Model No. No. Table/Sheet

3.11-6/WBNEEB0004I 1-PS-3-139A SB31AKR/TD3OA32R 19 3.1l-8/WBNEEBOOO6

3.11-6/WBNEEB0OO42-PS-3-139A SB31AKR/TD3OA32R 9 3.ll-8/WBNEEBOOO6

3.11-6/WBNEEB00041-PS-3-139B SB31AKR/TD3OA32R 19 3.ll-8/WBNEEBOOO6

3. 11-6/WBNEEB0OO42-PS-3-l39B* SB3lAKR/TD3OA32R 9 3.l1-8/MMNEBOOO6

3.1l6147wBNEEB0004I-PS-3-139D SB31AKR/TD3OA32R 19 3.11-8/WBNEEBOOO6

3. 11-6/WBNEEB0OO42-PS-3-139D SB31AKR/TD3OA32R 9 3.1l-8/WBNEEBOOO6

3.11-6/WBNEEB00041-PS-3-144A SB31AKR/TD3OA32R 19 3. 11-8/WBNEEBOOO6

3.11-6/WBNEEB00042-PS-3-144A SB31AKR/TD3OA32R 9 3.11-8/WBNEEB0OO6

3. 11-6/WBNEEBOOO4I-PS-3-144B SB31AKR/TD3OA32R 19 3. 11-8/WBNEEBOOO6

3. 11-6/WBNEEB0OO42-PS-3-144B SB31AKR/TD3OA32R 9 3. 11-8/W'BNEEBOOO6

3.11-6/WBNEEB00041-PS-3-144D SB31AKR/TD3OA32R 19 3.11-8/WBNEEBOOO6

3. 11-6/WBNEEBOOO42-PS-3-144D SB31AKR/TD3OA32R 9 3.11-8/WBNEEBOOO6

3.11-7 /WBNEEB0OO3II 1-PS-3-140A SB11AKR/TG13A42R 14 3.11-8/WBNEEBOOO6

3.11-7/WBNEEB00032-PS-3-14OA* SB11AKR/TG13A42R 14 3.11-8/WBNEEBOO66

3.11-7/WBNEEBOOO3 / ,

1-PS-3-150A SB11AKR/TG13A42R 14 3.11-8/lWBNEEBOOO6

2-PS-3-150A SB11AKR/TG13A42R 14 3.11.-8/wBNEEBOOO)6

*Not yet installed

Reviewer/Date,EQS No. WBNEEB0016Appendix 2Rev 3Sheet 1 Of 8

1.1. The pressure switches in Appendix 1 under heading I areASCO modelS831AKR/TD3OA32R. They are located in the Auxiliary Building (el.713/Al). As detailed in EN DES Calculations (NEB 840907 222) forthe main and Auxiliary Feedwater System, these switches arerequired to operate for 100 days following the start of a LOCA, andfor 1 month following the start of a RHR, CVCS, Auxiliary Boiler,or Auxiliary Feedwat~er Line Break.

2. The switches are subject to HELB condition's (Volumes 9 and 19) andare affected slightly by a LOCA. They are required to operate inthe following environments: (Note 1)

Normal Abnormal Accident

Temperature:

Pressure:Relative Humidity:Radiation:

S pray/Flooding:

1040F

Atm(-)80%5x102 rads(40 years TID)N/A

1100F

Atm(-)90%N/A

N/A

12801 (Volume 9)11801 (Volume 19)Atm100%lxl0 4 rads(LOCA)N/A

3. The manufacturer's specifications for these devices are:

Temperature:Pressure:Relative Humidity:Radiation:

210012.2 psig100%17x106 rads

The above testing is documented in ASCO Qualification ReportAQR-101083, Revision 1, dated June 1, 1984.

4. The worst-case accident for which these devices must operate(auxiliary boiler line break for volume 9 - maximum temperature1280F, RHR line break for volume 19 - maximum temperture 11801).This temperature then decreases in a linear manner for 24 hours,after which it will be 10401 (maximum normal).

Note 1. See WEN Environmental Drawing 47E235-52 RO. r,

Preparer/Date .C .t0/op EQS No. WBNEEB0016Appendix' -2Rev 3Reviewer/Date Sheet 2 of 8

The manufacturer has tested these switches (as shown in Figure 2)Sthe following:

'Design Basis Event (DEE) Phases:

A. Seismic DEE (SSE) Simulation - The units were mounted to theshaker table as described for the vibration aging simulationand were exposed to a single frequency sinusoidal test at 1/3octave frequency interval (17) dwell points between I and 40Hz. The minimum duration at each test frequency was 30seconds. At each test frequency a peak acceleration levelwithin the machine limits was applied. Motion was applied atthe same frequency and acceleration limits in each of threeorthogonal axes separately. Based on this testing, subsequentperformance and physical and pressure boundary integrity are

satisfactory to a minimum of 6g acceleration.

B. Radiation DEE Simulation - 18.7 megarads of gamma radiation ata rate not exceeding 1 megarad per hour to simulate (afterconsideration of margin as suggested in IEEE-323-1974) at least17.0 megarads of accident radiation exposure.

C. Environmental DBE Simulation - The units were installed in achamber and subjected to an exposure of temperature andhumidity for a period simulating a combined loss-of-coolantaccident/high-energy-line-break event and post-event cool-down. The peak ambient temperature of the simulation was 2100Fwith a saturated steam environment. The units were cycled atthe beginning and end of each transient (to demonstrate ther 2 ability to perform a typical safety function) and once dailyC for the remainder of the exposure to demonstrate the ability to

i: operate on demand. The qualified temperature profile4 demonstrated by this simulation (after consideration of marginas suggested in IEEE-323-1974) is shown in Figure 2.

D. Pressurization DEE Test - The units were installed in apressure vessel subjected to an ambient pressure of 2.2 psig of10 minutes followed by 1.1 paig for an additional 10 minutes.All units had a process signal applied but were'not cycled.The qualified pressure profile demonstrated by this simulation(after consideration of margin as suggested in IEEE-323-1974)is shown in Figure 2.

5. To determine a qualified life, ASCO has aged this device as follows(see Figure 1):

Aging Simulation Phases:

A. Thermal Aging Simulation - Aging parameters verie determined byArrhenius calculations to simulate a minimum of 10 years in a

Preparer/Date '. EQS No. WBNEEB0016

Revewe/Dae dAppendix 2 Rev -3Revewr/at Z '~ u i-f2.Sheet 3 of 8

1040F continuous ambient. Refer to Figure 1 for additional.~iinformation regarding service periods for elastomeric

components.

B. Vibration Aging Simulation - Continuous sinusoidal sweeps from5 to 200 to 5 Hz at a rate of 2 octaves per minute, with aminimum peak acceleration level of 0.75g (except at lowfrequencies where the acceleration level was reduced such thatthe displacement did not exceed 0.025" double-amplitude), for aminimum of 90 minutes in each of three orthogonal axes. Thetest units were operated every 15 minutes during this exposure.The units were attached to the shaker table by rigid testfixtures using the standard mounting provisions with the unitsvertical and upright. Flexible hoses on all ports andLiquatite conduit rigidly attached to the shaker table wereused; therefore, the setup did not affect the rigidity or massof the units being tested.

C. Resonance Testing - Accelerometers were attached to the testunits to determine if the units exhibited any resonance.Resonance is defined as a response with a magnitude ofacceleration at least three times as great as the inputacceleration. No resonances were detected between 1 and 35 Hz.

J D. Radiation Aging Simulation - 0.5 megarads of gamma radiation ata rate not exceeding 1 megarad per hour to simulate expected

* non-accident radiation exposure.

E. Wear Aging Simulation - 50,000 operations. Ten percent of thewear aging simulation was conducted concurrently with thethermal aging simulation. Units with the Urethane elastomerwere not partially wear aged concurrently with the thermal

* aging simulation.

F. Seismic Aging (OBE) Simulation - The units were mounted to theshaker table as described for the vibration aging simulationand were exposed to two sinusoidal sweeps from 1 to 100 to 1Hz, with a peak acceleration level (within machine limits) of4g, in each of three orthogonal axes at a rate of not more than1 octave per minute. One sweep in each axis was conductedwith a 20 percent process signal applied and the other with an80 percent process signal applied. These sinusoidal sweeps areconsidered to provide the equiv~alent dynamic effect of 5 OBE's.

1. The switches in Appendix 1 under heading II are ASCO modelSB11AKR/TG13A42R. They are located in the Auxiliary Building(737/A5 for Unit 1, 737/A9 for Unit 2). As detailed in EN DESCalculations (NEB 840907 222) for the Main and Auxiliary Feedwater

Preparer/Date ~*2te7~.s'8

Reviewer/Date________ ______

EQS No. WBNEEB0016Appendix 2 Rev 3Sheet 4 of 8

Sy~stem. These switches are required to not fail in a mannerDVetrimental to plant safety for 100 days after the start of aLOCA, and for 1 month after the start of a RHR, CVCS, AuxiliaryBoiler, or Auxiliary Feedvater line break.

2. The switches are subject to HELE conditions (Volume 14) and areaffected slightly by a LOCA. They are exposed to the followingenvironments (Note 2):

Normal Abnormal Accident

Temperature:Pressure:Relative Humidity:Radiation (Unit 1

devices):(Unit 2 devices):

Spray/Flooding:

10401Atm(-)80%3.5x104 rads(40 years TID)3.5x102 rads(40 years TID)N/A

11001Atm(-)90%W/A

N/A

W/A

*19501Atm100%1x104 rads(LOCA)lxl04 rads(LocA)N/A

3. The manufacturer's specifications for these devices are:

Temperature:Pressure:Relative Humidity:Radiation:

210012.2 psig100%1.7xl07 rads

The above testing is documented in ASCO Qualification ReportAQR-1010839 Revision 1, dated June 1, 1984.

4. The worst-case accident for which these devices must operate (RHRline break) shows a maximum temperature of 19501 after 13.3minutes. This temperature then decreases in a linear manner for 24hours, after which it will be 10401 (maximum normal). Themanufacturer has tested these switches (as shown in Figure 2) tothe following:

Design Basis Event (DBE) Phases:

A.

F K. CaTI

D AT E

Seismic DBE (SSE) Simulation - The units were mounted to theshaker table as described for the vibration aging simulationand were exposed to a single frequency sinusoidal test at 1/3octave frequency interval (17) dwell points between 1 and 40Hz. The minimum duration at each test frequency was 30seconds. At each test frequency with a peak acceleration levelwithin the machine limits the process signal applied was variedfrom 10 percent to 0 percent of maximum range from the

Note 2: See WBN Environmental Drawing 47E235-48 Ri.

Preparer/Date le. &OLd/-J 4Reviewer/DatezfA a~If. '/ X_-pt/

EQS No. WBNEEB0016Appendix 2 Rev -3Sheet 5 of 8

setpoint. At the test frequencies, where functional operationwas unsatisfactory, the peak input acceleration was increasedfrom zero and the g-levels recorded where spurious outputsignals occurred. The values chosen for satisfactoryoperation were a change of output signal (Trip Point) within+3 percent of the setpoint and no contact bounce outside of +5percent of the setpoint. Motion was applied at the samefrequency and acceleration limits in each of the three.orthogonal axes separately. Based on this testing (afterconsideration of margin as suggested in IEEE-323-1974), thefollowing aceptable maximum acceleration levels have beendetermined:

SET AT 30Zni A~,~If~ BMUIR .%

SPD SPI SPD SF1

Vertical Trip Point 5.4 5.4 5.4 5.4Contact Bounce 5.4 5.4 5.4 5.4

Horizontal Trip Point 5.4 5.4 5.4 5.4

Contact Bounce 5.4 5.4 5.4 5.4

SPD - Setpoint DecreasingSP1 - Setpoint increasing

B. Radiation DBE Simulation - 18.7 megarads of gama radiation ata rate not exceeding 1 megarad per hour to simulate (afterconsideration of margin as suggested in IEEE-323-1974) at least17.0 megarads of accident radiation exposure.

C. Environmental DBE Simulation - The units were installed in a.chamber and subjected to an exposure of temperature andhumidity for a period simulating a combined loss-of-coolantaccident/high-energy-line-.break event and post-event cool-down.The peak ambient temperature of the simulation was 210OF with asaturated steam environment. The units were cycled at thebeginning and end of each transient (to demonstrate the ability

- to perform a typical safety function) and once daily for theremainder of the exposure to demonstrate the ability to operateon demand. The qualified tempe~ature profile demonstrated by

iD6~5L~LO n cc-Teuiswr ntle nthis simulation (after consideration of margin as suggested inIEEE-323-1974) is shown in Figure 2.

SET AT 70%

pressure vessel subjected to an ambient pressure of 2.2 psig of10 minutes followed by 1.1 psig for an additional 10 minutes.All units had a process signal applied but were not cycled.

0OCT I'__4

Preparer/Date 5Y,,,,~/o-~8EQS No. WBNEEB0016Appendix 2 Rev 3

5-To determine a qualified life, ASCO has aged these switches to thefo~llowing (see Figure 1):

Aging Simulation Phases:

A. Thermal Aging Simulation - Aging parameters were de termined byArrhenius calculations to simulate a minimum of 10 years in a1040F continuous ambient. Refer to Figure 1 for additionalinformation regarding service periods for elastomericcomponents.

B. Vibration Aging Simulation - Continuous sinusoidal sweeps from5 to 200 to 5 Hz at a rate of 2 octaves per minute, with aminimum peak acceleration level of 0.75g (except at lowfrequencies where the acceleration level was reduced such thatthe displacement did not exceed 0.25" double-amplitude), for aminimum of 90 minutes in each of three orthogonal axes. Thetest units were operated every 15 minutes during this exposure.The units were attached to the shaker table by rigid teatfixtures using the standard mounting provisions with the unitsvertical and upright. Flexible hoses on all ports andLiquatite conduit rigidly attached to the shaker table wereused; therefore, the setup did not affect the rigidity or massof the units being tested.

C. Resonance Testing - Accelerometers were attached to the testunits to determine if the units exhibited any resonance.Resonance is defined as a response with a magnitude ofacceleration at least three times as great as the inputacceleration. No resonances were detected between 1 and 40 Hz.D. Radiation Aging Simulation - 0.5 megarads of gamma radiation atarate not exceeding 1 megarad per hour to simulate expectednon-accident radiation exposure.

EFFECIVE

DT E

E. Wear Aging Simulation - 50,000 operations. Ten percent of thewear aging simulation was conducted concurrently with thethermal aging simulation.

F . Seismic Aging (OBE) Simulation - The units were mounted to theshaker table as described for the vibration aging simulationand were exposed to two sinusoidal sweeps from 1-to 100 to 1Hz, with a peak acceleration lev~el (within machine limits) of4g, in each of three orthogonal axes at a rate of not morethan 1 octave per minute. one sweep in each axis was conductedwith a 20 percent process signal applied and the other with an80 percent process signal applied. These sinusoidal sweeps areconsidered to provide the equivalent dynamic effect of 5 OBEs.III. The above information shows that the devices under heading I willoperate for 100 days following an accident. These devices underheading II will not fail in a manner detrimental to plant safety forthe same time period. This is per the guidelines of NUREG 0588 for aqualified life of 10 years.

0

__I__ __ __ ii

F NOTE:

is

10987

6

5

4

3

2.5

2

1.5

300 C(860 F)

400 C(1040 F)

500 C(1220-)

600C(1400 F)

a(EPDM)

700 C0 580F)

FIGURE 1MAXIMUM SERVICE PERIODS FOR ELASTOMERIC COMPON\ENTS IN ASCO SUFFIX R

PRESSURE SWITCHESBased on accelerated thermal aging at 2100 F ambient temperature and determined by Arrhenius calculations usingactivation energy values of: 0.94 eV for Ethylene Propylene; 1.04 eV for Viton; o.82 eV for Urethane

Pressure Switch Units should be replacedwhenever any of the following levels, simulatedduring qualification testing, are reached:1. Weer Aging -50,000 cycles2. Radiation Aging - 5 x 10s red3. Thermal Aging - The maximumn service

period indicated below 4br the applicationservice ambient temperature. r

I . ~.

, X

Ethy~e a Propyle____ ___ ___ ___ __ _______ ___ Viton __ _ _

200C(680 F) CL 0

1c i tol

0

I

0 01950 F

200

175,

150JKTEMPERATURE

(a F)

125

100

I'

If lIPSIG

HOURS

I,". F~ r

I~ATE

12(0 F

LEGEND

TEMPERATURE

PRESSURE

,-- 1040 F

DAYSTIME

QUALIFI iED AMBIENT TEMPERATURE AND PRESSURE PROFILE

30~

20

PRESSURE(PS IG)

10

0

0mrti Z

0

PCb'

FIGURE 2

Preparer/Date 1ra'L/0-C4

Reviewer/DatexdI,kIý'... zendn---%

EQS No. WBNEEB0016Appendix 3 Rev 3Sheet 1 of 1

The devices listed below require sealing of the conduit entrance.Qualificg#tion of the conduit seals is documented in the referenced EQS.

Co mponent UNID

1 -PS-3-140A1 -PS-3-150A

WEN EEB-CSC-1WEN EEB-CSC-1

E F FECT IV ECDATE

'U" C T 0 41,8

'. -t-- -4r;,ý,

Prearr/ateý69,J,/,, 7T0-

Revini^n J*

WiEN iDUTW~ or ICT 9cri =SH' (MDS)

Manufactiter and Model No. _-NAMCO EA-740verification of Tibe Information (Table See Appendix 1

X Bi TM- The equipmient has been identified as per TVA ID numberdesignations (such as,, NDVT, SMJ.X L~in- The location has been identified (such as, inside primarycontainment,, annulus,, individually cooled rooms, general spaces,, or areaaffected by H=W outside primary containment).

___ M t A unique TVA ID number has been assigned (such as,, l-FSV-68-308).x Aicin- A functional description of the component has been given (such as,steami generator blowown).X~ Contract No.. Manufacturer, and MOdel ko.' - The contract nuiberr manufacturer#and model number have been given.

_jL &=nrmal or Accident Environment - All abnormal or accident envirornmentalconditions applicable to this equipim=nt have been identified either in tables orby references to figures from tables.X anviranmnen to ich Oualified - The environment to which the equipment has beenqualified is addressed in either the tables or the environmental analysisattached.

-.1 Qk= - A category of al, b,, c. or dhas been defined for thex.. Operation an Accuracy Reqired and &eostae - The operationand accuracy required and demonstrated have been defined.

QuaI J tion tatus (check if applicAble. W if DnotQual~ified..Li1fe (If equipet is qualified, indicate the cqualified life with a.numerical entry): Group I - 1.77 years, Group II - 32.31 years, Group III - 3.24 yearsX~ Oualficatian Reprt -and metho - A qualification report and the method ofqualification has been identified on the Table Input Data Sheet (TIDS).X Eni~mna D1Mf - An environmental analysis has been done, attached tothe EQS, adindependently reviewed by the responsible organization..n.LAC lification by Siniilarv (If applicable) - A justification for qualificationbY similarity is attached to the FOS considering all the above factors andreferenced to the appropriate tables.X Oaificatjio of Segveral ExAct Cmi=netm (If applicable) M Wen an MQS is usedfor more than one itemi, a list of all exact cnm t sgvna napniwith all references to appropriate tables with justification for qualificationN/A considering all the above factors.later im nua I If i-Catio (If applicable) - (open item) - Component has beendetermined to be quPalified only for a limited interim operation, an HM hasbeen written,, and plani of action has been determined to yield a qualifiedc'r'onent.Term of Interim Qualification_____________________

N/A ~ ie Cg2MM (Open item) - (If applicable) - Cpm mbedetermined to be wxlualified; the following is attached to FBD: WM nubr,,reason for non-qualifications, and justification of continued operation.

*Due to the extensive changes from Revision 0, revision bars are not used.

Unit No. 1 and 2

See Appendix 1

Preparer/Dat 910. WBNEEB0018Reviewer/Datep Append1& a I Re

LýShoot VManufaCtUrer. NA 0O

Comp"Oent it mi Swich

*L Lover -comPa tment, U - Upper compartment, IR Containment Instrument Room

Component UNID Mlodel goJo. Lobc/S.e

ILS on 1-FCV-30-40-A RA-740 L 3.11-4IWBNEEB0001

ILS on 1-FCV-77-127- EA 740 L

ILS on 2-FCV-77-127- EA 740 L

I1-ZS-30-15-B EA 740 L

[I -ZS-30-20-A EA 740 IR

l-ZS-3E0-50-BA EA 740 L

I -ZS-30-56-A EA 740 LE i

I -ZS-30--8-B EA 740 U 3 .11-4/WBNEEBOOO2

.....................................

CD

Preparer/Date EQS No. WBNEEB0018ZA9ýAppendix 2 Rev 21Reviewer/Date Sheet 1 of 11

NAMCO haq. tested the model EA 740 limit switch to the requirements of IEEEstandard 323-1974. The test criteria and results are documented in "Quali-fication of NAMCO Controls Limit Switch model EA-740 to IEEE Standards 344(1975), 323 (1974), and 382 (1972), "Revision 1, dated February 22, 1979.

All qualification tests were performed at test levels or conditions inexcess of known maximum application requirements. These margins are inaccordance with the margins suggested in IEEE standard 323-1974.

Thermal aging calculations in this Appendix are based upon the "ArrheniusEquation" shown in equation 1.

where

11 - Qualified life

12 - Accelerated (test) life

E - Worst case activation energy, eV

k - Boltzmann's constant, 8.617 x 10-5 eV/OK

T- Qualified temperature, absolute (i iw

T2 Elevated (test) temperature, absolute

e -Base of natural logarithms

Reference: EPRI, NP-1558. Research Project 890-1, dated September 1980.

Materialsa' Potential for Sianificant Azingt:

In "Estimation of Qualified Life of EA 740 Series Nuclear Switch," February27, 1980, revision, NAMCO identifies a cover gasket containing NitrileButadyne Rubber (NBR) as the material most susceptible to aging. Elsewherein this EQS, NBR is used as a basis for all calculations determiningqualified life.

In the same report, NAMCO states that an ethylene propylene compound (EPR)o-ring is used on the level shaft. The NRC has identified EPR as amaterial having the potential for significant aging. Noting the greatersusceptibility of lift over EPR, HAMCO concludes:

"As a result of the thermal aging study, the lever shaft o-ring willnot be considered a factor in the qualified life estimation."

Preparer/Date AZZ.vOl -Z-Q

Reviewer/Date__________________________

EQS No. WBNEEBOO18Appendix 2. Rev 2..Sheet - 2 -of 11

EPR as used in this limit switch is not a potential for significant agingin the environment in which it is located.

I. Sitces esinatd "" i th Loatin Clumn in Avpendix 1.:

1. These switches are KMACO Model EA,-740. They are located in the ReactorBuilding (inside containment, lower compartment). As detailed in ENDES Calculations, NBE 840213 218 and NEB 840314 230 for the ContainmentVentilation and Waste Disposal Systems respectively, these devices arerequired to operate for 5 minutes after the start of a LOCA, Main Steamline break, Feedwater line break, RHR line break, and CVCS line break.Additionally they must not fail in a manner detrimental to plant safetyfor 100 days following a LOCA, Main Steam line break, and Feedwaterline break; for 1 month following a RHR line break and CYCS linebreak.

2. The switches are subject to the HELE/LOCA conditions shown inFigure 2 They are required to operate and/or not fail in the followingenvirornment sl:

ftmi AccidentTemperatur e:Pressure:Relative Humidity:Radiation:

Spray/Flooding:

120OF14.7 psia.8022410 7 rads(40 years TID)N/A

130OF14.7 psia100%NIA

N/A

327 0F26.4 psia100%X1l08 rads

Spray3. The manufacturer has tested the model NA-740 switch to the following:

Temperature:Pressure:Relative Humidity:Radiation:

Normal120OFAtmIOU%

Acc iden=340OF63 psig100%

Total

2.04x108 rads

The required temperature, pressure, relative humidity, and radiationare well within the manufacturer's test data. The LOCA simulationtest profile (Figure 1) exceeds the time-'temperature envelope for theactual LOCA/NSLB, (Figure 2).

4. The manufacturer has thermally aged the FA-740 switch for 235.5 hoursat 200OF prior to the LOCA test simulation.1See WBN Environmental Data Drawing 47E235-42.

E ~ r FI ýA T I

Preparer/Date

ReivrDt

EQS No. WBNEEB0018Appendix 2 Rev 2Sheet 37 of 11

The ¶iialified life for these switches is the thermal aging equivalentprior to the LOCA test. It is calculated below to be approximately1.77 years at the normal operating temperature of 1200F, plus LOCA.

Calculation

12 - 235.5 hoursT2- 200OF - 366.480KTl- 1200F*- 322.040K

E - .958 eV

876 housyers-

E F F ar C T iV .D A

F 0.958 1 -

L8.617xl0S5eV/OK 322.0401t 366.480K

- 1.768 years

5. The switches are located inside containment where they are subject tochemical spray.

A chemical solution consisting of 3000 ppm boron as boric acid insolution with 0.064 molar sodium thiosulfate buffered with sodiumhydroxide to a pH value of 10.5 at 770F was sprayed on the sample at arate corresponding to 0.15 gpm per square foot of area covered by thespray. The chemical spray solution pH was maintained between 10 and11.

The chemical composition of the Watts Bar containment spray is:

0.1844 molar 13103 (2000 ppm boron)

0.033 molar NaOH, resulting in a PH of 8.35

The switches successfully completed the LOCA profile test withoutincurring any operational or corrosion failures. Since the chemicalconcentration of containment spray is less severe than the LOCA profiletest concentrations, the switches should not be affected.

6. In our engineering judgement, the manufacturer's LOCA test profile(Figure 1) more than satisfies the requirements of the actual XSLBILOCAprofile (Figure 2). In addition, the LOCA test extends out to 722hours (30 days) at 2000F, which is more severe an ambience than thelatter portions of the actual LOCA curve show. The last 600 hours,therefore, can be seen to be an accelerated aging period at 200OF whichcan be used to demonstrate post-LOCA life capability. This period at200OF can be shown to be equivalent to over 0.7 years at 152.50 F (seecalculation below) and, therefore, more than satisfies the 100-dayPost-accident requirement.

Preparer/Date

Rev iewer /DateL19

Calculation

12- 600 hoursT2- 2000 F - 366.480 KT* 1520 F - 340.090 K

ZQS No. WENEElO0l8-Appendix 2 Rev .2..Sheet .-4 -of -l11

TA~

(Temperature profile, WIN Environmental Data'drawing 47E235-42; (1900F @6xl03 sec - 1150 F@30 days)/2+1150 F

E 0.958 eV

l= 600 hours- - x 0.958. eV -I I el

L8766 hours/year. L8:.617x1035 eV/0-K 340 .090K 366 .480K

- 0.72 years - 263 days

This is 0.72 years' life equivalent at 152.50 F and can be used to satisfythe post-DBA life of 100 days.

7. The above information shove that the switches are qualified for 1.77years at maximum normal operating temperature, radiation, humidity,and then for MSLB/LOCA conditions and for the poet-accident liferequirement. Satisfactory performance can be expected from theswitches in the above environment.

II. 1-ZS-30-20-A

1. This switch is a NMANO Model ZM-740. It is located in the ReactorBuilding (inside Containment Instrument Room). As detailed in ENI DESCalculation NEB 840213 218, for the Containment Ventilation System,this device is required to operate for 5 minutes after the start ofa LOCA, Main Steam line break, Kill line break, Feedvater line break, andCVCS line break. Additionally it must not fail in a mannerdetrimental to plant safety for a period of 100 days following a LOCA,Main Steam line break and Feedvater line break; 1 month following RHland CVCS line breaks.

2. The switch is subject to the HELB/LOCA conditions shown in Figure 2.It is required to operate and/or to not fail in the followingenvironments 2 :

Normal

Temperature:Pressure:Relative Humidity:

Radiation:

Spray/Flooding:

75 0 F14.7 psia60Z2x107 rads(40 years TID)NIA

120OF14.7 psia90%il/A

N/A

Accident

3270 F26.4 psia100%1x10 8 rads

Spray2See WBN Environmental Data Drawing 47E235-45.

Preparer/Date ',C

Reviewer/Date -Z.41

EQS No. WBNEEB0018Appendix 2 Rev 2Sheet 5 of 11

3. The manufacturer has tested the switches to the following:

Temperature:Pressure:Relative Humidity:Radiation:

Normal120OFAtm100%

Accijdent340OF70 psigIOU%

Total

2.04xl08 rads

The required temperatures pressures relative humidity, and radiationare well within the manufacturerls test date. The LOCA simulationtest profile (Figure 1) exceeds the time-temperature envelope for theactual LOCA/HSLB (Figure 2).

4. The manufacturer has thermally aged the EA 740 svitch for 235.5 hoursat 200OF prior to the LOCA test simulation.

The qualified life for this switch is the thermal aging equivalentprior to the LOCA test. It is calculated below to be approximately32.31 years at the normal operating temperature of 750 F, plus LOCA.

Ca lculat ion

12 -235.5 hoursT2- 200OF -366.48 0K

T -750F 29.00

E - 0.958 eV

llýr 235.5 hours X0.8eV

L8766 hours/year L8.617xl0-5 eV/oK

-32.306 years297 .040K

5,. The switch is located inside containment where it is subject tochemical spray.

A chemical solution consisting of 3000 ppm boron as boric acid insolution with 0.064 molar sodium thiosulfate buffered with sodiumhydroxide to a pH value of 10.5 at 770F was sprayed on the sample at arate corresponding to 0.15 gpm per square foot of area covered by thespray. The chemical spray solution pli was maintained between 10 and11.

The chemical composition of the Watts Bar containment spray is:

0.1844 molar H3B03 (2000 ppm boron)

0.033 molar NaOH, resulting in a pH of 8.35

E FF E i%

DAT

366.480K

PreprerDateW. 1:ý,""-a -/-.AEQS No. WBNEEB00l8

Z 0, ý ý /Appendix 2 Rev 2Reviewer/Date 6Sheet 6 of 11

The -switches successfully completed the LOCA profile test withoutincuriing any operational or corrosion failures. Since the chemicalconcentration of containment spray is less severe than the LOCA profiletest concentrations, the switches should not be affected.

6. In our engineering judgement, the manufacturer's LOCA test profile(Figure 1) more than satisfies the requirements of the actual 14SLB/LOCAprofile (Figure 2). In addition, the LOCA test extends out to 722hours (30 days) at,2000F, which is more severe an ambience than thelatter portions of the actual LOCA curve shows. The last 600 hours,therefore, can be seen to be an accelerated aging period at 200OF whichcan be used to demonstrate post-LOCA life capability. This period at200OF can be shown to be equivalent to over 0.7 years at 152.50 F (seecalculation below) and, therefore, more than satisfies the 100-daypost-accident requirement.

Calculation

12 - 600 hoursT2- 2000 F - 366.480 KTl- 152.50 F - 340.090 K (Temperature profile, WBN Environmental Data

.drawing 47E235-45; WOO0F @6xlO3 sec -1150 F@30 days)/2+1150F

E -0.958 eV

l= 600 hours X0,958 eV 1 ___

L8766 hours/year 8.617x10-5 eV/OK 340.090K 366.480K j-0.72 years -263 days

This is 0.72 years' life equivalent at 152.50 F and can be used to satisfythe post-DBA life of 100 days.

7. The above information shows that the switches are qualified for 1.77years at maximum normal operating temperature, radiation, humidity,and then for MSLB/LOCA conditions and for the post-accident liferequirement. Satisfactory performance can be expected from theswitches in the above environment.

E F F C T IV'ID)ATE

0 0 8

Preparer/Date G

Rev iew er/Date_________________

EQS No. WBNEEB0018Appendix 2. Rev 2-Sheet- -7 - of -11

III. 1-ZS-30-8-B

1. This switch is a NANCO Model EA-740. It is located in the ReactorBuilding (inside containment, upper compartment). As detailed in ENDES Calculation, NEB 840213 218 for the Containment VentilationSystem, this device is required to operate for 5 minutes after thestart of a LOCA, Main Steam line break, ERR line break, Feedvater linebreak, and CVCS line break. Additionally it must not fail in amanner detrimental to plant safety for 100 days following a LOCA,Main Steam line break, and Feedwater line break; 1 month following aERR line break and CVCS line break.

2. The switch is subject to the HELI/LOCA conditions shown in Figure 2.It is required to operate and/or not fail in the followingenvironments3 :

Normal Abnormal Acc id ent

Temp eratur e:Pressure:Relative Humidity:Radiation:

Spray/Flooding:

110OF14.7 psia80%2xl07 rads(40 years TID)N/A

120OF14.7 psia90%N/A

N/A

160OF26.7 psia100%W0i8 rads

Spray

.3. The manufacturer has tested the switch to the following:

Temperature:Pressure:Relative Humidity:Radiation:

Normal

120OFAtm100%

Ac ciden-t

340OF70 psig100%

Total

2.04x108 rads

The required temperature, pressure, relative humidity, and radiationare well within the manufacturer's test data. The LOCA simulationtest profile (Figure 1) exceeds the time-temperature envelope for theactual LOCA/MSLB (Figure 2).

4. The manufacturer has thermally aged the,EA-740 switch for 235.5 hoursat 200OF prior to the LOCA test simulation.

The qualified life for this switch is the thermal aging equivalentprior to the LOCA test. It is calculated below to be approximately3.24 years at the normal operating temperature of 1100F, plus LOCA.

3 See WBN Environmental Data Drawing 47E235-41. - ~~~1

Preparer/Date XC Am ý &-/P,0EQS No. UBNEEB0018Appendix 2 Rev 2

ReieerDte. rSheet 8 of 11

Calculation

12 vs 235.5 hoursT2- 200OF - 366 .480KTl- 110OF - 316.480K

E - 0.958 eV

ll= 235.5 h urs]X F 0.958 1 1 _

8~766 boursiyeaj e [.617xl0-5 eVI0 K 316.480K 366.480K j-3.240 years

5. The switch is located inside containment where it is subject to chemical

spray.

A chemical solution consisting of 3000 ppm boron as boric acid insolution with 0.064 molar sodium thiosulfate buffered with sodiumhydroxide to a pH value of 10.5 at 770F was sprayed on the sample at arate corresponding to 0.15 gpm per square foot of area covered by thespray. The chemical spray solution pH was maintained between 10 and11.

The chemical composition of the Watts Bar containment spray is:

0.1844 molar K3B03 (2000 ppm boron)

0.033 molar NaOR, resulting in a pH of 8.35

The switches successfully completed the LOCA profile test withoutincurring any operational or corrosion failures. Since the chemicalconcentration of containment spray is loes severe than the LOCA profiletest concentrations, the switches should not be affected.

6. In our engineering judgement, the manufacturer's LOCA test profile(Figure 1) more than satisfies the requirements of the actual MSLB/LOCAprofile (Figure 2). In addition, the LOCA test extends out to 722hours (30 days) at 2000F, which is more severe an ambience than thelatter portions of the actual LOCA curve show. The last 600 hours,therefore, can be seen to be an accelerated aging period at 200OF whichcan be used to demonstrate poat-LOCA lif~e capability. This period at200OF can be shown to be equivalent to over 3.8 years at 122.50 F (seecalculation below) and, therefore, more than satisfies the 100-daypost-accident requirement.

Preparer/Date e4 EQS No. WBNEEBOO1BAppendix 2 Rev -2

Revewr/Dte A~li< ý a -VSheet 9 of 11

Caloulat ion

12 -600 hoursT2 2000 F - 366.480 K

T -122.50 F - 323.430 K (Temperature profile, WBll Environmental Datadrawing 47E235-41; (1450F @6xl03 sec -1000 F@30 days)/2+1000F

E -0.958 eV

j 600 hours F 0.958 ev 1 1 ___

e8~766 hours/year L8.617z10-5 eV/Oi 323.430K 366.480K j

- 3.883 years

This is 3.883 years' life equivalent at 122.50 F and can be used to satisfythe post-DBA life of 100 days.

7. The above information shows that the switches are qualified for 3.24years at maximum normal operating temperature, radiation, humidity,and then for MSLB/LOCA conditions and for the post-accident liferequirement. Satisfactory performance can be expected from theswitches in the above environment.

014133.15 --

E F C. T 1, V FD AT EUG~ i524

EOS No. W&=~ 00:IS

APierdiX 1 2 Rev. 2Sheet 10o~fa!

O %

8 c

320-

.-250

200-

1! ...

3. 8 iTime (Hourv)*

73 98 722

Figure I. LOCA Sim~ulation Test Profil~e

S -

E F FECTIVE:LV DAT E~

* I.

a -

120 +

( a

i -- ! i -4--

K

340

EQS No. WBNEEB0018

Appendix 2 Rev. 2

Sheet 11 of 11

CONTAIN MET TE PERATURED DOL)BLE ENDED Pump SUCTION BREAK (LOCA)ANDMOST SEVERE STEPAig.IN BREAKC (MELB) COMBINED

a . ......... g * 5 ,

Figure 2 ,. .

Preparer/Date X. CMAiU.Q -a & -if o

Reviewer/Date/ /s*vr./q 41 tz 6U1f-V(

EQS No. WBNEEB0018Appendix -T -Rev 2Sheet 1 of I

The devi~ces listed below require sealing of the conduit entrance.,Qualification of the conduit seals is documented in the referenced EQS.

Component UNID Q

1 -ZS-30-8-B1 -ZS-30-15-B1 -ZS-30-50-B1 -ZS-30-52-A1-ZS-30-56-A

Limit Switches on:1 ,2-FCV-77-127-B1 -FCV-30-40-A

1-ZS-30-20/1I-ZS-30-20/2

WBNEEB-CSC-lW31NEEB-CSC-IWBNEEB-CSC-lWBNEEB-CSC-1WBNEEB-CSC-1

WBNEEB-CSC-1WBNEEB-CS C-i

WBNEEB-CSC-1WBNEEB-CSC-1

(7 V

014133.15

Unit NO.

TVA 33D No.

1 and 2URJBE-E-BO19

-PPAppprn1.-r 1

Mmnufact(wer .and Model No See Appendix 1Verification of Tiible Information (Table See Appen dix 1

X J~i~t ZU- The equipment has been identified as per WA ID numberdesignations (such as, mv~, 9M~7.X 1M M- The location has been identified (such as,, inside primarycontainment, annulus,, individually cooled roamt, general spaces, or areaaffected toby HELB outside primary containment).X QUM= - A unique 7% ID numb~er has been assigned (such as,, l-FSV-68-308).X bmloJg - A functional description of the component has been given (such as,steami generator blowdon).

-a-* Cmtract No., Manufacturer, 1An Bodel lo. - The contract num~ber#, manufacturer,and model number have been given.*jL Abnorml nr a-cident Environn - All abnormal or accident environmaentalconditions applicable to this equipment have been identified either in tables orby references to figures from tables.X. Evrgymet! to Widh OualifiedW - The environment to which the equipment has beenqualified is addressed in either the tables or the environmental analysis

-.jLCata -Acategory of a,, b,, cr or d has been defined for the-. Operation -and Accu-r~acy Raired anWd Demostrated - The operationand accuracy required and demonstrated have been defined.Oualification Status (check If applicable. ~f not)IQual.±Li..Lfe (If eguipuet is qualified, indicate the qualified life with anumlerical entry): 4.) yrs_X. Qialificat ion Rport and Mt~ A qualification report and the method ofqualification has been identife on the Table Input Data Sheet (TIDS)... X ta na - An environmental analysis has been done, attached tothe MQS, and independently reviewed by the responsible organizatien.-I.NLA Gualification k& Aimilarit-y (if applicable) - A justification for qualificationby similarity is attached to the BQS considering all the above factors andreferenced to the appropriate tables.X Ou.1ifction of Several Exac (if applicable) - When an EDS is Usedfor more than one item, a list of all exact comiponents is given as an appendixwith all references to appropriate tables with justification for qualificationconsidering all the above factors..ILA Interi Ouslification (If applicable) - (Open item) - Conqnent has beendetermined to be qualified only for a limited interim operation, an NaM hasbeen written,, and plan of action has been deteripined to yield a qualifiedcomponent.

Term of Interim Qualification_____________________

N/Aie M (pen i~tem) - (If applicable) - Ccuupnent has beendetermined to be unqualified; the following is attached to EDS: HM number,reason for non-qualification, and justification of continued operation.

E F FE*Due to the extensive changes from Revision ;2, revision bars are not used.'T ~

Preparer/Datr//t 4 ~~/9 es--0s.4

Manuf acturer

Component*.

EQS No. WBNEEB0019Appendix 1. Rev 3Sheet Tof -- I

AS CO

Solenoid Valve

LLU

¶LL--

I

Component UNID Model No. J Table/Sheet

I 1-FSV-90-108-B -X.206-381-3Rp I 3.11-4/WBNEEBOOll

I 2-FSV-90-108-B HTX832OA22V 3 .ll-4/WBNEEBOOO4

I l-FSV-90-1 09-B X206 -3 81-3RF 3.1 l-4/WBNEEBO0l 2

I 2-FSV-90-109-B HTX8320A22V 3 .11-.4/WBNEEBOOO4

I 1-FSV-90-110-B X206-381-3R1 3.11-4/WBNEEBOO11

I____________________ HTX8320A22V 3 .11-4/WBNEEB0OO4

I 1-FSV-90-114-B X.206-381-3Rp 3.1l-4/WBNEEBOO11

I 2-FSV-90-114-B RTX8320A22V 3.11-4/WBNEEB0004

I 1 -FSV-90-1 15-B X206-381 -3RP 3.1 1-4/W IBNEEBOO1 1

I 2-FSV-90-115-B liTX8320A22V 3.l1-4/WBNEEB0004

I 1-FSV-90-116-B X206-381-3Ru 3.11-4/WBNEEBOO11

I 2-FSV-90-116-B -HTX8320A22V 3.11-4 /WBNEEB0004

I 1-FSV-77-127-B X206-381-3RFp 3.11-4/WBNEEBc,012

I 2-FSV-77-127-B WPXRV2O2-301-lF 3.11-4/WBNEEB0OO4

II l-FSV-31-306-A X206-381-3RF 3.11-4/WBNEEBOOll

Ii 2-FSV-31-327-B HV200-921-ljp 3.11-4/WBNEEBOOO3

II 2-FSV-31-306-A IrPXHV202-300o.2p 3.11-4/WBNEEB0OO2

III 1.-FSV-62-76-A NPX831654E 3 .11-4/WBNEEBOO1O

Preparer/Dat _ _ _ _ __ _ _ _ __ _ _ _

Rev iewer/ Date A~/ j~ 94ajEQS No. VBNEEB0019Appendix 2 Rev 3Sheet 1 of 9

I. 1. The solenoid valves listed in Appendix 1 under headings I and IIare ASCO model X-206-381-3Rj* They are located inside Containment,Lover Compartment and the Incore Instrument Room, elevation 716.As detailed in EN DES Calculation NEB 840517 220 for the RadiationMonitoring System and NEB 840515 224 for the Air ConditioningSystem, these valves are required to operate for 5 minutes after thestart of a LOCA, Main Steam line break, or Feedvater line break andnot fail in a manner detrimental to plant safety for 100 days there-after. Additionally, they must operate for 5 minutes after the startof a RHR line break or CVCS line break and not fail in a manner detri-mental to plant safety for 1 month thereafter.

2. The solenoid valves are required to operate in the followingenvironment1 :

Normal

- I

Temperature:

Pressure:

12001 (I)750F (II)14.7 pusi

Abnormal

1300F (I)12001 (II)14.7 psia

Accident

3270 F

26.4 psia (I

26.7 psia (IRelative Humidity:

Radiation:

Spray/Flooding:

80% (1)60% (11)2410 7 rads (1)3.54104 rads (II)(40 year TID)N/A

100% (1)90% (11)

N/A

I.1. The solenoid valves listed in Appendix 1 under heading III is anASCO Model NPX831654E. It is located in the Lover Compartment,elevation 703.1 As detailed in EN DES Calculation NEB 840515 227 for theChemical and Volume Control System, this valve is required to operate for5 minutes after the start of a LOCA, Main Steam line break, or Feedwaterline break and not fail in a manner detrimental to plant safety for 100days thereafter. Additionally, it is required to operate for 5 minutesafter the start of a RHR line break or CVCS line break and not fail in amanner detrimental to plant safety for 1 month thereafter.2. The solenoid valves are required to operate in the same environment asstated in paragraph 2 above for those devices under heading I.

'Per WBN Environmental Data Drawing 47E235-61

100%

1xI08 rads

(LOCA)

Preparer/Date ,EQS No. WBNEEB0019f~P. j ~, Appendix 2 Rev -3

Reviewer/Date .- / A rSheet 2 of L9.

111. 1. ASCO has qualified their solenoid valves under headings I, II, andIII t~o the following:

Temperature: 346OFPressure: 110 psig

Relative Humidity: 100%Radiation: 2.0x108 rads

Spray/Flooding: 3000 ppm, PH 9-11

2. Qualification Testing:

a. ASCO has tested the 206-381 and 8316 series solenoid valves to therequirements of IEEE Standard 323-1974 and NUREG-0588. The testcriteria and results are documented in ASCO test reportAQS21678/TR, Revision A, including supplement 3. All qualificationand tests were performed at test levels or conditions in excess ofknown maximum application requirements.

b. Seven solenoid valve samples representing six generic families of valves,including the 206-381 and 8316 series, were subjected to sequentialexposures of elevated temperature, radiation, wear aging, seismicsimulation, vibration endurance, accident radiation, and a 30-dayLOCA simulation. Baseline functional tests were performed beforethe start and after each sequence of the test exposure with theexception of coil dielectric and insulation resistance measurementswhich were taken before thermal aging, after accident radiation,and after LOCA exposure. The valves were energized and deenergizedat high and low pressures during the test phases (except radiation)and valve leakage monitored.

c. Baseline/Functional Test: Baseline/Functional tests consisted ofmeasurement of coil excitation, seat leakage at high and lowpressures, noise test, operational test, and external leakage testbefore and after all phases of type tests. Measurement ofinsulation resistance and coil dielectric test was performed in theas received condition and after completion of accident radiationand LOCA simulation. Valves were energized and deenergized andtheir operation monitored during test (except radiation).

d. Thermal aging: The valves were subjected to an aging temperatureof 268OF for a test duration of 12 days. They were cycled(deenergized for five minutes and then energized) every six hours.

DTA T"D A

F l':C T 2

GC, "

Preparer/Dat<•A, 94A. 192- EQS No. WBNEEB0019-,Appendix 2 Rev 3Reviewer/Date /T5-Zt. Sheet 3 of j...

e. Radiation: The valves were subjected to cobalt 60 (GAMMA) radiation at anexppsure rate of less than one megarad per hour. Total integrated donereceived was 50 megarads.

f. Wear aging: The valves were electrically cycled 40,000 times at maximumpres sure differential.

g. Seismic Simulation/Vibration Endurance: The valves were subjected to acombined SSE and fragility test. The input g. level was 7 g's. The testwas performed with the valves energized and deenergized and with high andlow pressure. The leakage rate was monitored.

h. Accident Radiation: The valves were subjected to cobalt 60 (GAMMA)radiation at an exposure rate of less than one megarad per hour. Valvesreceived an additional accumulated dose of 150 megarads for a totalintegrated dose of 200 megarads received in two stages.

i. LOCA Simulation: The valves were subjected to a simulated loss-of-coolantaccident (LOCA) by exposure to steam and to chemical spray for 30 days.LOCA simulation conditions were as follows:Temperature - Maximum of 3460F for a total period of six-hours followed bystep decrease to 200OF within four days followed by post-DEE conditions of200OF for the remaining 26 days.

Pressure - Maximum of 110 psig for a total period of six hours followed bystep decrease to 10 psig within four days followed by post-DBE conditions10 psig for remaining 26 days.

Relative Humidity - All steam environment in excess of 250OF; greater than90% for other conditions.

Chemical Spray - The chemical solution consisted of 3000 ppm boron as boricacid in solution with 0.064 molar sodium thiosulfate buffered with sodiumhydroxide. The chemical solution pH was maintained between 9.5 and 10.5.

j. Results: One of the valves malfunctioned during thermal aging. The valvedeveloped excessive seat leakage both in the energized and deenergizedstate. This was later determined to be caused by dirt in the valve. Thesource of dirt was the iron pipe used in the cylinder port as piping and aadditional length used to simulate an accumulator.

Other than the above malfunction, the valves sucessfully completed thesequential type tests and the baseline'/functional tests.

EZEL F F (7 TDA

orIT J

Preparer/Date/__________________ EQS No. WBNEEB0019

Revewe/Dae '-~Appendix 2 Rev 3Reiee/Dt & " n9c= -4 Sheet 4 of 9.

3. Qualified Life - The solenoid valves have a qualified life of 40 yearsat 120F and 40,000 cycles, providing the maintenance schedule outlined inparagraih 5 is followed. Open and close completes one cycle. Hiowever, due.to the self-heating nature of solenoid valves, the temperature riseassociated with a continuously energized solenoid valve must be accountedfor in the qualified life calculation. There are two areas affected by thisheating: (1) the coil sees an increase of 105*C (221*F) above ambient and(2) the elastomeric discs see an increase of 45*C (113*F) above ambient.These .temperature increase values come from Franklin Research Center's "TestProgram and Failure Analysis of Class 1Z Solenoid Valves" (NUREG/CR-3424, F-C5569-309/315).

Based on the above information, a separate qualified life must be calculated forboth the coil and the disc. The following qualified life calculations, whichare based on the Arrhenius equation, are for Valves to be used at a normalambient operating temperature of 120*F (48.9*C):

-l L2e EK T T2

COILS

In Franklin Research Center's "Test Program and Failure Analysis of Class lESolenoid Valves" (NUREG/CR-3424, F-C5569-309/315), the solenoid coils were agedat two rates: 150*C (302*F) for 9.3 days (233.2 hours) and 131*C (268*F) for15.3 days (367.2 hours).

Li- Qualified life (first aging rate)

L2- Accelerated (test) life - 223.2 hours

E - Activation energy - 1.00 eV

K - Boltzmann's constant - 8.617 x 10-5 eV/*K

Tj- Qualified temperature (ambient + 105C) - 153 .9*C

T2- Elevated (test) temperature -1500C + 1050C -2550C

e - Base of natural logarithms

of,

Preparer/Date /.' . Z-ZL:f EQS No. WBNEEB0019Appendix 2 Rev 3

Reviewer/Date 4 qj 42. Sheet 5..~ of 9..L

Ll'- Qualified life (second aging rate)

L2'- 367.2; hours

E - 1.00 eV

K - 8.617 x 10-5 eV/PK

Tl'- 48.90C + 1050C - 153 .90C

T2 1- 1310C + 105 0C - 2360C

e n Base of natural logarithms

Ll (total) -Total qualified life - Ll+ -l 7.973 years

DISCS

In ASCO test report AQS-21678/TR, supplement 3, the entire valve was aged at 131*C(268*F) for 12 days (288 hours).

Ll - Qualified life

L2- Accelerated (test) life -288 hours

E - Activation energy - .94 eV

K - Boltzmann's constant -8.617 x 10-5 eV/*K

Tl- Qualified temperature - 120*F

T2- Elevated (test) temperature - 1310C + 450C - 1760C

e - Base of natural logarithms

Ll-7.56 years

4. Installation - Valves should be installed such that the axis of the coil remainsin the vertical and upright position.

5. Maintenance Requirements - The qualified life depends on the valvebeing cycled at least every 16-18 months to ensure proper opening andclosing. Coils shall be replaced every 7.973 years and elastomericcomponents shall be replaced every 7.56 years when solenoid valves aresubjected to a normal operating ambient temperature of 120*F. Inaddition, ASCO recommends that when the solenoid valves reach 20,000cycles, that they be rebuilt using the applicable spare parts kit and

Preparer/Date ~A 4422~42~V EQS No. WBNEEB0019Appendix 2 Rev 3Reviewer/Date 2=2ý7.S(+ Sheet 6 of

spare coil kit2.-

6. Valves~are qualified per IEEE Standard 323-1974, IEEE Standard382-1972, IEEE Standard 344-1975, and applicable portions of NUREG-0588for the environment in vhich they are required to operate, providing themaintenance schedule in paragraph 5 above is followed. By mathematicalanalysis, the qualified post-DBE operating time can be extended to292 days.

Calculations - Post Accident Life

Calculations are based on the Arrhenius equation which states:

Ll- L2 e T -

Where

1.1 - Qualified life

L.2 - Accelerated (test) life

El Worst case activation energy, eV

K - Boltzmann's constant, 8.617 x 10-5 eV/OK

Tj- Qualified temperature, absolute

T2 - Elevated (test) temperature, absolute

e - Base of natural logarithms

Calculate qualified post-accident life for valves located in the lowerCompartment using the worst case accident temperature profile for thevalves listed in Appendix 1:

L.2 - 29 days - 696 hours (AQS21678/TR, Rev. A, Figure 2, page 4-21)

Ei- 0.94 eV (AQR67368, Appendix B, page B-3)

Tj- 152.50F (temperature profile, WBN environmental data drawings 47E235-42and -45, 190OF @6000 sec - 1150F @30 dayir/2 + 1200F)

T2- 2000F (AQS21678/TR Rev. A, figure 2, page 4-21)

L.2 -29 days x 24 hours/I day -696 hours

ASOTest ReportAQR67368/Rev. 0Appendix C, Page C-2

Preparer/Da tV/2~e~,~ iReviewer/Date -2 fI

Ll 696 e [8.617X10.5 T I T JTj- (152.5-32)/1.8+273.15 -340.1 0K

T2- (200-32)/1.8 + 273.15 -366.5 K

L - 6 96 e I;8.617xlo-5 340.1

EQS No. WBNEEB0019Appendix 2 Rev 3Sheet 7 of ...J.

366.5 J-.7014.9 hours - 292 days

LJ

Preparer/Dat/e. AY EQS No. WBNEEB0019SAppendix 2 Rev 3

Reviewer/Date X2 4 . 'fSheet 8 of

UNIT 2 ONLY

I.1. For the solenoid valves on Appendix 1 under heading I:

2-FSV-90-108-B1 ,2-FSV-90-109-B1 ,2-FSV-90-l10-BI ,2-FSV- 90-114-B1 52-FSV-90-115-B1 ,2-FSV-90-116-B2-FSV-77-127-B1 ,2-FSV- 90-109-B

ASCOASCOASCOASCOASCOASCOASCOASCO

Cat.Cat.Cat.Cat.Cat.Cat.Cat.Cat.

HTX83 20A22VHTX83 20A22VHTX83 20A22VHT483 20A22VHTX83 20A22VHTX83 20A22VIWPXHV2O2-301-IFHTX83 20A22V

The solenoid valves above are located in the lover containmentelevation 716. They are required to operate for 5 minutes after thestart of design-basis accidents and not to fail detrimental to plantsafety for periods of up to 100 days thereafter (depending on whichaccident occurs).

2. The solenoid valves are subject to LOCA/BELB conditions.required to operate in the following environment:3 They are

Accident

Temperature:Pressure:Relative Humidity:Radiation:

Spray/Flooding:

120OF14.7 psia80%24107 rads(40 yr TID)N/A

3270F26.4 psia100%lxl08 rads

Spray only

3. The manufacturer's specifications for the solenoid valves are:

Spec Model1

Temperature:

Pressure:

Relative Humidity:

Radiation:

1040 F200OF1040 FAtmNENA 1 EnclosureNEMA 4 EnclosureNEMA, 4 Enclosure4 zx0 rads7 x 106 rada7 z 106 rads

4. The above information shows that these solenoid valves are not qualified.for operation in the required accident environment. TVA will replacethese devices per 1OCFR50.49, as determined by NCR WBNEEB8135.

3 Per SQN/WBN IEnvironmental Data Drawing 47E235-45.

83 00B588320A22202-301-1

830OB5883 20A22202-301-1830OB588320A22202-301-1

Preparer/Daty<2•L-J4ý4.

Rev iewer/ Date /gc4r4..2'-7(EQS No. WBNEEB0019Appendix 2 Rev 3Sheet 9j of 9.2.

UNIT 2 ONLYII .For the solenoid valves on Appendix 1 under heading II:

2-FSV-3k-306-A2-FSV.-31-327-B

ASCO Cat. No. WPXHV2O2-300-2FASCO Cat. No. RV200-921-lRF

The solenoid valves above are located in the containment instrumentroom, elevation 716. They are required to operate for 5 minutes afterthe start of design-basis accidents and not to fail detrimental toplant safety for period. of up to 100 days thereafter (depending onwhich accident occurs).

2. The solenoid valves are subject to LOCA/HELB conditions.required to operate in the following environment:4

Normal

They are

Accident

Temperature:Pressure:Relative Humidity:Radiation:

Spray/Flooding:

7 5OF

14.7 psia,60%54103 rads(40 yr TID)N/A

3270F26.4 Pasi100%ixio8 rads

NIA3. The manufacturer's specifications for the solenoid valves are:

S~ec Model

Temperature:

Pressure:Relative Humidity:Radiation:

125011 40OFAtmNEMA 1 Enclosure4.5 x 105 rads7 x 106 rads

4. The above information shows that these solenoid valves are not qualifiedfor operation in the required accident environment. TVA will replacethese devices per IOCFR5O.49, as determined by NCR WBNEEE8135.4Per SQN/WBN Environmental Data Drawing 47E235-48.

034147 .07

L:U

200-921-1202-300-2

202-921-1

Uniit No. l and 2R~ev~ison 1~ 2 3* EDS No. WBNEEB0020

12 TVA M No.Preparer/Date 17-) See Appendix 1

Reviewer/bate ~£

14anufact~fir and Model No. -ASCO - See Appendix 1 for model numbersVerification of Tible Information (Table See Appendix 1X Baim u- The equipment has been identified as per MA I numbierdesignations (such as, P)v,, sOY).-X Imtm- The location has been identified (such as, inside primarycontainment, annulus,, individually cooled roons,, general spaces, or area

X affected t-by HELB outside primary containmient).x ow - A unique TVA ID number has been assigned (such as, l-FSV-68-308).x i - A functional description of the comonent has been given (such as,steam generator blowdoiin).-X Conjtract No.. Manufacturer, and Mo~del HQ. - The contract numb~er, manufacturer,and model number haebeen given.-X A1x==ma or A-ccidet Envilom=n - All abnormal or accident environmentalconditions applicable to this equipment have been identified either in tables orX by references to figures from tables.X ~nVircMmet to hich Ouaslifid - The environment to which the equipment has beenqualified is addressed in either the tables or the environmental analysisattached.X Lftteg=r- A category of at b, cp or dhas been defined for theX equlipment.x Opration and Accuray z uiired and Demonstrated - The operationand accuracy required and demonstrated have been defined.

W Oulifica~tionn Status (cak if appliable. NR if not)ife Lf (If equirment is oualifiedo,,indiceate-the qualified life with anumerical entry): 40 yearsX Oul ficat ion Weort and metfrd - A qualification report and the method ofqualification has been identified on the Table Input Data Sheet (TDS).X. Ink n-yi - An environmental analysis has been done, attached tothe BDS, and independently reviewed by the responsible organization.NA Oualification by Similarity (If applicable) - A justification for qualificationby Similarity is attached to the EQS considering all the above factors andXreferenced to the appropriate tables.X UAlifiCAtion of Several ExaCt. &~n (If applicable) - When an EDS is usedfor more than one item,, a list of all exact cmTqonents is given as an appendixwith all references to appropriate tables with justification for qualificationconsidering all the above factors.NA.** Intgrim O ification (If applicable) - (open item) - component has beendetermined to be qualified only for a limited interim operation,, an NM hasbeen written, and plan of action has been determined to yield a qualifiedComoent.

Term of Interim Qualification ___________________

NM NO.NA Ib

-af (Open item) - (If applicable) - Caqxpnent has bedetermined to be unqualified; the following is attached to BDS: NM nl~t~rreason for non-qualif ication, and justification of continued operation.

0 *Due to the extensive changes from Revision 2, revision bars are not used.

Preparer/Dat _________ _____

Revi ewer/DateoeAllz awý. 24ý

EQS No. WBNEEB0020Appendix 1 Rev 3Sheet r-of

Manuf acturer ASC~

Cornponet; Soli

.*Not yet installed

0

enoid Valves

NVR - Worth Valve RoomSVR - South Valve Room

Component UNID Model No. Loc. Table/Sheet

l-FSV-43-2-B 206-381-3RF L 1 3 .11-4/WBNEEBOOO6

2-FSV-43-2-B* liV206-3 81 -3RVF L 3.*11 -4/WBNEEBOOO6

1-FSV-43-11-B 206-381-3"F L 3.ll-4/WBNEEBOOO6

2-FSV-43.1-llB* HV206-381-2RVF L 3 .1l-4/WBNEEBOOO6

1-FSV-43-34-B 206-381-3RF L 3 .11-4/WBNEEB0006

2-FSV-43-34-B* HV206-3 81 -2RVF L 3.*11 -4/WBNEEBOOO7

1-FSV-43-22-B NP831654E L 3.11-4/WBNEEB0OO7

2-FSV-43-22-B* 11V206 -381 -3RVF L 3 .1 1-4/WBNEEBOOO6

1-FSV-43-7 5-B NP8316 54E L 3.11-4/WBNEEBOOO7

2-FSV-43-7 5-B* HV206-3 81 -3RVF L 3 .11 -4/WBNEEBOOO7

1-FSV-43-201-A 206-381-3RF L 3.11-4/WBNEEB00O6

2-FSV-43-201-A* 206-381-3RVF L 3 .11-4/WBNEEBOOO6

1-FSV-43-202-A 206-381 -3R. L 3 .11-4/WBNEEBOOO6

2-FSV-43-202-A* 206-381-3RVF L 3 .11-4/WBNEEBOOO6

2-F SV-43 -20 8-B*

I 1-FSV-62-70-A

2-F SV-6 2-7 O-A*

1-FSV-63-71-A

2-FS-63-71-AjII

206-381 -3RF

206-381-3RvF LI

206-381 -3RF

206-381-3RVF

L NP831654E L JNP83 16 54V

NP83 16 54E

I-

L

Lf

NP831654V

3 .1l-4/WBNEEBO0O6

3 .11-4/WBNEEB0O12

3 .11-4/WBNEEB0006

3 .l1-4/WBNEEB0012

3 .11-4/WBNEEBOOO7

3 .11-4/WBNEEBOO11

3 .11-4/'WBNEEB00O2

3 .11-4/WBNEEBO0O2

H

L - Lower Containment

3.11-4/WBNEEB0006

I

Preparer/Date

Reviewer/Date - 9-2-640a

Manuf acturer ASCO

Componerit .- Solenoid Valves

NVR - North Valve Room*Not yet installed SVR - South Valve Room

Component UNID Model No. Loc.

V l-FSV-68-308-B NP831654E L2-FýSV-68-308-B* NP831654V L

V 1-FV-71BNP364L

F-FSV-77-16-B* NP831654E L

2-FSV-77-18-B* NP831654V L

2-FSV-77-18-B* NP831654E L

V 2-FSV-37-185B NP8-31654V LY

2J -FSV-3-185 206-381-2F SVR

2-FSV-3-185 206-381-2F SYR

1-FSV-3-186 2 06-381-2F NVR

2-FSV-3-186 206-381-2F NVR:

1-FSV--3-187 2 0 6-381-2F ,NVR

2-FSV-3-187 206-381-2FSR

2-Fv-3188 2 06-381-2F SVR

2-FSV-3-188A 2 06-381-2F SVR

2-FSV-3-236A 206-381-2F SVR

2-FSV--3-236A 206-381-2F SVR

I-FSV-3-236B 206-381-2F SVR

' - F S V - 3 - 2 3 6 B2 6 - 8 -2 V

2-FSV-'3-236A 2 06-381-2F SVR

1-FSV-3-239A 2 O638-2 .V

4 2-FSV-3-236B :: 2 O6 -381-2F NVR

EQS No. WBNEEB0020Appendix I Re-v .-3Sheet =of -3

L - Lower Containment

Table/Sheet

3 .11-44/WBNEEB00l1

3 .ll-4/WBNEýEBOOO3

3 .ll-4/WBNEEB0003

3 .11-4/WBNEEB0OO3

3 .1I-4/WBNEEBOOO9

3 .11-8/WBNEEB0OO2

3 .ll-8/WBNEEB0002

3 .11-8/WBNEEBcjoo2

3 .11-8/WBNEEB00O2

3 .l1-8/WBNEEB0002

3 .1l-8/WBNEEBOOO2

3 .ll-8/WBNEEB0OO2

3 .ll-8/WBNEEB0OO2

3 .l1-8/WBNEEB0005

3 .ll-8/WBNEEBOOO5

3 .1l-8/WBNEEBOOO5

3 .I1-8/WBNEEB0005

3 .ll-8/WBNEEB0OO5

3 .ll-8/WBNEEB0OO5

3 .1l-8/WBNEEB0005

3.'l-8/WBN EEB0005

Preparer/Date /A~ ~EQS No. WBNEEB0020Revi ewer/ Date s P Appendi x I-T-Rev

>_ _ _ _ _ _ _ _ _ _ _ _ _ S h e e t f - o f37- %U

WI~~) Manuf acturer AMC

Iý a'poner So________________________Valves__________

L-S-322 CD-812 NVR - North/ValveBRoom

1-FSV--3-242A 206-381-2F SVR 3 .ll-8/WBNEEBOOO52 -FSV-3-242A - 2O6 -381-2F SVR 3 .11-8/WBNEEBOOO5

2-FSV-3-242B 2 06 -381-2F SVR 3 .ll-8/WBNEEBOOO51-FSV-3-245A 206-381-2F SVR 3 .ll-8/WBNEEBOOO5

Preparer/Date'ý? 7 ~•tz/-i-~

Reviewer/Date 7A f- &14"R5EQS No. WBNEEB0020Appendix 2 Revision 3Sheet 1 of ...9j.

UNIT 1 ONLY

I1.The solenoid valves listed in Appendix 1, designated as "L" in thelocation column are ASCO Models 206-381 and NP8316 series. They arelocated in the Lower Compartment at elevation 716 feet. As detailed inEN DES Calculations NEB 840517 221 for the Sampling System, Reading I,NEB 840515 230 for the Reactor Coolant System, Heading V, andNEB 840515 222 for the Waste Disposal System (Heading VI, Appendix 1),these valves are required to operate for 5 minutes and not fail in amanner detrimental to plant safety for 100 days after the start of aLOCA or line breaks in either Main Steam or Feedwater lines. They arealso required to operate for 5 minutes and not fail in a mannerdetrimental to plant safety for 1 month after breaks in either ERR orCVCS lines.

As detailed in EN DES Calculation NEB 840517 221 for the SamplingSystem (Heading II, Appendix 1), these valves are required to operatefor 100 days after the start of a LOCA or after breaks in either MainSteam or Feedwater lines and 1 month after breaks in either ERR or CVCSlines.

As detailed in EN DES Calculation NEB 840517 223 for the SafetyInjection System (Heading IV, Appendix 1), these valves are required tooperate for 5 minutes and not fail in a manner detrimental to plantsafety for 100 days after the start of a L0CA or line breaks in eitherMain Steam or Feedwater lines. As detailed in EN DES Calculation NEB840515 227 for Chemical and Volume Control System (Heading III,Appendix 1), these valves are required to operate for 5 minutes and notfail in a manner detrimental to plant safety for 1 month after a CVCSline break.

2. These solenoid valves are required to operate in theenvironment :1

Normal

Temperature:Pressure:Relative Humidity:Radiation:

Spray/Flooding:

120OFAtm80%2xl0 7 rads(40 years TID)NIA

Abnormal

13 0OF14.7 psia100%N/A

N/A

fol 1lowing

Accident

327 0F26.4 psia100%1x108 rads

Spray only

'Per WBN Environmental Data Drawing 47E235-42R1

024144.02 E F F %C .,'D ATE

Preparer/Dat r 2A4u EQS No. WBNEEB0020Reviwer/ateAppendix 2 Revision -3

ReviwerDat Z 2.A 91?J2 Seet 2 of 19

3. ASCQZ has tested these valve model numbers to the following environment:

Temperature:Pressure:Relative Humidity:Radiation:

Spray:

346OF110 psig100%2x10 7 rads (Viton Seals)2xl08 rads (EPR Seals)3000 ppm Boron/pH 9-11

1.The solenoid valves listed in Appendix 1. designated as "NVR" or "SVR"in the location column, are ASCO Model 206-381-2F. They are located ineither the North Valve Room (NVR) or the South Valve Room (SVR) atelevation 729 feet. As detailed in EN DES Calculation NEB 840515 225f or the Main and Auxiliary Feedwater System (Heading VIII), thesevalves are required to operate for 5 minutes and not fail in a mannerdetrimental to plant safety for 100 days after breaks in either MainSteam or Feedwater lines.

2. These solenoid valves are required to operate in the followingenvironm~ent :2

Normal AccidentAbnormal NVR SVR

Temperature:Pressure:Relative Humidity:Radiation:

Spray/Flooding

130OFAtm50%3.5xl04rads NVR3.5xl05rads SVR(40 years TID)N/A

1 40OFAtm100%N/A

N/A

3250F23.7 psia100%lX10 4rads

N/A

323 0F25.18 psia100%1 xl0 4rads

valve model number to the following environment:

346OF110 psig100%2x1 O8rads3000 ppm Boron/pH 9-11

3. ASCO has tested this

Temperature:Pressure:Relative Humidity:Radiation:Spray:

2Per WBN Environmental Data Drawing 47E235-76, EL

E FA F024144.02

Preparer/Date _ _ _ _ _ _ _ _ _

Reviewer/Date ?- -& 'EQS No. WBNEEB0020Appendix 2 Revision 3Sheet 3 of 19

III 1.Qual~tfication Testing:

a. ASCO has tested the NP8316 and 206-381 series solenoid valves tothe requirements of IEEE Standard 323-1974 and NUREG-0588. Thesecriteria and results are documented in ASCO test reportAQS21678/TR, Revision A, including Supplement 3. Allqualification and tests were performed at test levels orconditions in excess of known maximum application requirements.These margins are in accordance with the margins suggested by IEEEStandard 323-1974,

b. Seven solenoid valve samples representing six generic families ofvalves including the 206-381 and NP 8316 series, were subjected tosequential exposures of elevated temperature, radiation, wearaging, seismic simulation, vibration endurance, accident radiationand a 30 day LOCA simulation, Baseline functional tests wereperformed before the start and after each sequence of the testexposure with the exception of coil dielectric and insulationresistance measurements which were taken before thermal aging,after accident radiation, and after LOCA exposure. The valveswere energized and deenergized at high and low pressures duringthe test phases (except radiation) and valve leakage monitored.c. Baseline/Functional Test: Baseline/Functional tests consisted ofmeasurement of coil excitation, seat leakage at high and lowpressures, noise test, operational test, and external leakage testbefore and after all phases of type tests. Mleasurement ofinsulation resistance and coil dielectric test was performed inthe as received condition and after completion of accidentradiation and LOCA simulation. Valves were energized anddeenergized and their operation monitored during test (exceptradiation).

d. Thermal aging: The valves were subjected to an aging temperatureof 268OF for a test duration of 12 days. They were cycled(deenergized for five minutes and then energized) every 6 hours.e. Radiation: The valves were subjected to cobalt 60 (GAMMA)radiation at an exposure rate of less than one megarad per hour.Total integrated dose received was 50 megarads.f. Wear aging: The valves yore electri:6ally cycled 40,000 timesat maximum pressure differential.

g. Seismic Simulation/Vibration Endurance: The valves were subjectedto a combined SSE and fragility test. The input g. level was7 g's. The test was performed with the valves energized anddeenergized and with high and low pressure. The leakage rate wasmonitored.

024144.02

Preparer/Date /12,rŽ&a 44ZJ c/- r

Reviewer/Date ~~ ~wL~4~~

EQS No. WBNEEB0020Appendix 2 Revision -3Sheet 4 of j1j.

h. &cident Radiation: The valves were subjected to cobalt 60(GiMMA) radiation at an exposure rate of less than one megarad perhour. Valves received an additional accumulated dose of 150megarads for a total integrated dose of 200 megarads received intwo stages.

i. LOCA Simulation: The valves were subjected to a simulatedloss-of-coolant (LOCA) by exposure to steam and to chemical sprayfor 30 days. LOCA simulation conditions were as follows:

Temperature - Maximum of 346OF for a total period of 6 hoursfollowed by a step decrease to 2000F within 4 days followed bypost-DBE conditions of 2000F for the remaining 26 days.

Pressurefollowedpost-DEE

- Maximum of 110 psig for a total period of 6 hoursby a step decrease to 10 psig within 4 days followed byconditions to 10 psig for remaining 26 days.

Relative Humidity - All steam environment in excess of 2500F;greater than 90% for other conditions.

Chemical Spray - The chemical solution consisted of 3000 ppm boronas boric acid in solution with 0.064 molar sodium thiosulfatebuffered with sodium hydroxide. The chemical solution pH wasmaintained between 9.5 and 10.5.

j. Results: One-of the valves malfunctioned during thermal aging.The valve developed excessive seat leakage both in the energizedand deenergized state. This was later determined to be caused bydirt in the valve. The source of dirt was the iron pipe used inthe cylinder port as piping and an additional length used tosimulate an accumulator.

Other than the above malfunction, the valves successfully completedthe sequential type tests and the baseline/functional tests.

2. Qualified Life - The solenoid valves have a qualified life of 40 yearsand 40,000 cycles, providing the maintenance schedule outlined inparagraph 4 is followed. Open and close completes one cycle. However,due to the self-heating nature of solenoid valves, the temperature riseassociated with a continuously energized Polenoid valve must beaccounted for in the qualified life calculation. There are two areasaffected by this heating: (1) the coil sees an increase of 105*C(221*F) above ambient and (2) the elastomeric discs see an increase of45*C (1130F) above ambient. These temperature increase values come fromFranklin Research Center's "Test Program and Failure Analysis of Class1E Solenoid Valves" (NUREG/CR-3424, F-C5569-309/315).

024144.02 C

Preparer/Date $dA

Reviewer /Date '#3c.

EQS No. WBNEEB0020Appendix 2 Revision -3Sheet 5 of 19

Based on ttie above information, a separate qualified life must be calculated for .boththe coil aWh the disc. The following qualified life calculations, which are based onthe Arrhenius equation, are for valves to be used at a normal ambient operatingtemperature of 120*F (48.9*C):

L4 L2e E T (T2J )

COILS

In Franklin Research Center's "Test Program and Failure Analysis of Class 1ESolenoid Valves" (NIJREG/CR-3424, F-C5569-309/315), the solenoid coils were aged attwo rates: 150*C (302*F) for 9.3 days (2-23.2 hours) and 131*C (268*F) for 15.3 days(367.2 hours).

Ll- Qualified life (first aging rate)

L2-Accelerated (test) life - 223.2 hours

E - Activation energy - 1.00 eV

K - Boltzmann's constant - 8.617 x 10-5 eV/*K

Tj- Qualified temperature (ambient + 105*0C - 153.9*C

T2- Elevated (test) temperature -1500C + 1050C -2550C

e - Base of natural logarithms

Li'- Qualified life (second aging rate)

L2 '-. 367.2 hours

E - 1.00 eV

K - 8.617 x 10-5 eV/ K

il'- 48.90C + 105 0C -153.9 0 C

T2 '- 1310C + 105%C 236%C

e -Base of natural logarithms

Ll (total) - Total qualified life - Ll+ L1.1 - 7.973 years

024144.02Uui

Preparer/Date ,/,Lsv ,•/g•A

Reviewer/Date.'O.e ý 9-21,E54___________

EQS No. WBNEEB0020Appendix 2 Revision 3Sheet 6 of J.9L

DISCS 2

In ASCO test report AQS-21678/TR, supplement 3, the entire valve was aged am(268*F) for 12 days (288 hours).

Ll- Qualified life

L2- Accelerated (test) life - 288 hours

E - Activation energy - .94 eV

K - Boltzmann's constant - 8.617 x 10-5 eV/*K

TI Qualified temperature - 120*F

T2 - Elevated (test) temperature - 131% + 450C - 1760C

e -Base of natural logarithms

Ll-7.56 years

For the valves to be used at a normal ambient operating temperature of 130*F(54.4*C), the following qualified life calculations, which are based on theArrhenius equation, apply:

COILS

Ll- Qualified life (first aging rate)

L2-Accelerated (test) life - 223.2 hours

E -Activation energy - 1.60 eV

K - Boltzmann's constant - 8.617 x 10-5 eV/*K

Ti Qualified temperature (ambient + 105*0C - 159.4*C

T2 - Elevated (test) temperature - 150 0C + 1050C - 2550C

e - Base of natural logarithms

024144.02

t 131 0C

D AT 6~E:

Preparer/Date ' ý

Reviewer /Date .41 ý -

EQS No. WBNEEB0020Appendix 2 Revision -3Sheet -7 of 19L2

Llj- Qualified life (second aging rate)

L2'- 367.2 hours

E - 1.00 eV

K - 8.617 x 10-5 eV/OK

T11- 54.40c + 105 0C - 159.4*C

T2 '- 131 0C + 105 0C - 236 0C

e , Base of natural logarithms

Ll (total) - Total qualified life Ll + L1 5.645 years

DISCS

4l - Qualified life

L2 - Accelerated (test) life -288 hours

E - Activation energy = .94 eV

K ' Boltzmann's constant - 8.617 x 10-5 eV/'K

Tl-Qualified temperature -130OF

T2- Elevated (test) temperature - 1310C + 450C - 176*C

e -Base of natural logarithms

Ll 4.845 years

3. Installation - Valves should be installed such that the axis of the coil remainsin the vertical and upright position.

4. Maintenance Requirements - The qualified life depends on the valve being cycledat least every 16-18 months to ensure proper opening and closing. Coilsshall be replaced every 7.973 years and elastomeric components shall bereplaced every 7.56 years when solenoid valves are subjected to a normaloperating ambient temperature of 120*F. Coils shall be replaced every 5.645years and elastomeric components shall be replaced every 4.845 years when thevalves are subjected to a normal operating temperature of 1300F. In addition,ASCO recommends that when the solenoid valves reach 20,000 cycles, that they berebuilt using the applicable spare parts kit and spare coil kit3.3ASCO Test Report AQR67368/Rev. 0, Appendix C page C-2.

024144.02

r iý T "I

Preparer/Date .f4AZ~9 .7-~h EQS No. WBNEEB0020

Reviver/ateAppendix 2 Revision -3Revewr/Dte 4 ~ t~.i~..Sheet -8 of 1

5. Valvem are qualified per IEEE Standard 323-1974, IEEE Standard382-7I..972, IEEE Standard 344-1975 and applicable portions of NUREG-0588for* the environmient in vhich they are required to operate providing themaintenance schedule in paragraph 4 above is followed. Bymathematical analysis, the qualified post -DBE operating time canbe extended to 261 days for Lover Compartment and 137 days for Northand South Valve Rooms.

Calculations - Post Accident Life

Calculations are based on the Arrhenius equation which states:

Where:

El- Lowest Activation Energy

LI-Qualified Life

L2- Accelerated (test) Life

K =Boltzmann's constant, 8.617 x 10-5 eV/OK

Tj- Qualified temperature, absolute

T2- Elevated (test) temperature absolute

e - Base of natural logarithms

Calculate qualified post-accident life for valves located in lowercompartment of containment (worst case accident temperature profile forvalves listed in Appendix 1):

L2- 26 days (AQS21678/TR Rev. A, figure 2, page 4-21)

El- O.94eV (AQR67368, appendix B, page B-3)

Tj- 152.50F (temperature profile, WEN e nviro*Dm'ental data drawing47E235-42, 1900F @ 6 x 103 seconds - 1150F @*30 days/2 + 1150F)

T2- 200OF (AQS21678/TR Rev. A, figure 2, page 4-21)

L2-26 x 24 -624 hours

LI-0.717 years -261 days

024144.02

Preparer/Date ,Aa. EQS No. WBNEEB0020

ReviwerDate e . Appendix 2 Revision -3ReviwerDateA)A ~ ~Sheet, 9. of J.9

CalCUIAt~Dns - PV-t Accident Life

Calculations are based on the Arrhenius equation which states:

4l - L2 e

Where:

El- Lowest Activation Energy

Ll- Qualified Life

L2- Accelerated (test) Life

K - Boltzmann's constant, 8.617 x lO-5eV/OK

Tj- Qualified temperature, absolute

T2- Elevated (test) temperature absolute

e - Base of natural logarithmzs

Calculate qualified post-accident life for valves located in either roomusing accident temperature profile for valves listed in Appendix 1.L2-26 days (AQS21678/TR Rev. A, figure 2, page 4-21)

El- O.94eV (AQR67368, appendix B, page B-3)

Ti- 165OF (temperature profile, WEN environmental data drawing47E235-76, 200OF @ 6 x 0 seconds - 130OF @ 1 day/2 + 130 0F)T2- 200OF (AQS21678/TR Rev. A, figure 2, page 4-21)

L2- 26 x 24 - 624 hours

L* .377 years -137 days

Lj ;

024144.02

Preparer/Date4L /AZa*

Reviewer/Date _z/_E z~-a& I.2 -ftEQS No. WBNEEB0020Appendix 2 Revision 3Sheet -106 Of 19j

- UNIT 2 ONLY

ASCO has tested the 206-381 and NP8316 series solenoid valves to the require-ments of IEEE Standard 323-1974 and HUREG-0588. The test criteria andresults are documented in ASCO test report AQ821678/TR, revision A. Allqualification tests were performed at levels or conditions in excess ofknown maximum application requirements. These margins are in accordancewith the margins as suggested by IEEE Standard 323-1974.

Nuclear Regulatory Commission IE Information Notice No. 81-29, EquipmentQualification Notice No. 10 - has identified a problem with ASCO solenoidvalves with Viton Dynamic seals. The Viton seals will adhere to metallicsurfaces when exposed to radiation doses in excess of 20 megarads.

Thermal aging calculations in this appendix are based upon the "100CRule,"1 equations 1 and 2, which states that life (i.e., test time) ishalved for each 100C increase in temperature.

EQN 1 L -A/(0.5)N

EQN 2 TT -To + iON

where

A - Actual required test time

L - Qualified life at normal ambient operating temperature

N - Number of 100C increments above ambient temperature

To - Qualified temperature, OC

T - Test temperature, OCT

Reference: EPR, NP-1558, Research Project 890-1, dated September 1980.1. Solenoid valves listed in Appendix 1, designated as "L" in locationcolumn:

These solenoid valves are the 206-381 and NP8316 series. These valveshave either ethylene propylene (EPR) or Viton MV seals. The valvesare located inside containment where the maximum normal operatingtemperature is 1200F. These valves are subject to LOCA and MSLBconditions which are shown in figure 2. These valves are required tooperate for 5 minutes after the start of an accident and not to faildetrimental to plant safety for periods of up to 100 days thereafter(depending on which accident occurs).4

4Per EN DES Calculations; NEB 830204 229, NEB 830204 231, NEB 830204 232,NEB 830207 218, and NEB 830207 222.

024144.02II

Preparer/Date L~itA Z /9 zr YEQS No. WBNEEB00204 ý Appendix 2 Revision 3Reviewer/Date ,A 7'24~ Sheet 11 of 19.

Opertting Environment

The valves are required to operate in the following environment:5

Normal Accident

Temperature:Pressure:Relative Humidity:Radiation:

Spray/Flooding:

120OFAtm80%5.0 x 106 rads(10 year TID)N/A

3270 F26.4 psia100%lxl0 8 rads100 days (accident)Spray only

The manufacturer has tested 206-381 and NP8316 series valves to thefollowing environment:

Normal Accident

Temperature:Pressure:Relative Humidity:Radiation:

140OF 346OFAtm 119 psia100% 100%2.0 x 107 rads TID (Viton Seals)*2.0 x 108 rads TID (EPR Seals)

Aging (Qualified Life)

The manufacturer has thermally aged these valves for 12 days at 268OFprior to the LOCA simulation.

The qualified life for these valves is the equivalent of thermal agingprior to the LOCA test which is calculated to be 9.8 years at thenormal operating temperature of 1200F.

5 Per SQN/WBN Environmental Data Drawing 47E235-45 RO.

*Viton seals to be replaced per NCR WBNEEB8147.

r

L.024144.02

Preparer/Date L~2ut z :Reviewer! Date i

Calcula tion

Applying EQN I and EQN 2:

A -12 days - 12 x 24 a 288 hours

To 1200 F - 48.890C

TT -2680 F - 131 .110C

N -(TT - T0)/10 - 8.222

L -A/(0.5)N -288/(0.5) 8.222

L =85992 hours - 85992/8766 - 9.81 years

Non-metallic Materials

EQS No. WBNEEB0020Appendix 2 Revision -3Sheet 12 of 19j.

The materials list of the solenoid valves that have a "Vol in their modelnumber have Viton Dynamic seals. These valves are qualified to aradiaiton dose of 20 megarads. Valves with EPR dynamic seals have beenqualified to 2xl0 8 rads (10-year TID plus 100 days accident), the Vitonseals will be replaced with EPR seals per NCR WBNE.EB8147.

Chemical Spray

These valves are located inside containment where they are subject to achemical spray.

A chemical solution'consisting of 3000 ppm boron as boric acid in solutionwith 0.064 molar sodium thiosulfate buffered with sodium hydroxide to a pHvalue of 10 at room temperature was sprayed on the sample at a ratecorresponding to 0.306 gpm per square foot of area covered by the spray.The chemical spray solution pH was maintained between 9.5 and 10.5. Thespray remained on through the entire phase of the LOCA simulation.

The chemical composition of the Watts Bar containment spray is as follows:

0.2847 molar li3B03 (2000 ppm boron)0.033 molar NaOH, resulting in a pH of 8.2

The solenoid valves did not operate during thle'LOCA test because they werefilled with borated water. This was caused by a faulty installation in thetest chamber. After the test was complete, the coil of the valve was driedout and was found to be within the acceptance criteria. ASCO stated thatif the valve had been properly installed, borated water would not have beeninduced into the valve and would have operated correctly. TVA hasinstalled these valves correctly to prevent this problem.

024144.02 ~.' ~ ~;

[L~ A Y* §7]

Preparer/Date 14 244ZL _/,Reviewer/Date

EQS No. WBNEEB0020Appendix 2 Revision -3Sheet 13 of 19.

Conclusioi~

The required temperature, pressure, radiation, and humidity are veil withinthe manufacturer's data. The LOCA test simulation (figure 1) exceeds thetime-temperature envelope for the actual LOCA/MSLB (figure 2). The valveis qualified for 9.8 years of normal operation and by mathematicalanalysis, the qualified post-DEE operating time can be extended to 263days.

Calculations-Post Accident Life:

Calculations are based on the Arrhenius equation which states:

where Lj Accelerated (test) Life

El- Worst Case Activation Energy, eV

K - Boltzmann's Constant, 8.617 x 10-5 eV/0K

Tj- Qualified temperature, absolute

T2-Elevated (test) temperature, absolute

e - Base of natural logarithms

Calculate qualified post-accident life for valves located in lover compartmentof containment (worst-case accident temperature profile for valves listed inAppendix 1):L2- 26 days (figure 1) - 624 hours

Ei- 0.94 eV (67368, Appendix B. page B-3)

TI - 152.50F (temperature profile, BQN/WBN environmental data drawing47E235-45, 190OF @ 6xl03 sec-1150F 30 days/2 + 1150F)

T2- 200OF (figure 1)

Tj- 152.5-32/1.8+273.15 - 340.10K

T2- 200-32/1.8+273.15 -366.50K

Ll- 6 24e 867l-

Ll- 6318 hours - 263 days

1(340.

E~FQ F"

024144.02

366.5

Rev iever/ Date 4...EQS No. WBNEEB0020Appendix 2 Revision 3Sheet 14L.. of .J9L

2. Solenpid valves listed in Appendix 1, designated as "NVR" or "SVR" inthe l8*tation column:

These solenoid valves are 206-381 series. These valves are locatedoutside containment in either the North Valve Room (NVR) or South ValveRoom (SVR) where the maximum normal operating temperature is 1300F.This area is subject to an HELE and to a LOCA (radiation only). TheHELB temperature profile of this area is shown in figures 3 and 4.These valves are required to operate for five minutes after the startof an accident and to not fail in a manner detrimental to plant safetyfor periods of up to 100 days thereafter (depending on which accidentoccurs) *6

Operating Environment

The valve is required to operate in the following environment:7

Normal Acc ident

NVR

Temperature:Pressure:Relative Humidity:Radiation:

13 0OFAtm50Z.3x103 rads (NVR).6XI04 rads (SVR)(6.7 yrs TID)

2990F24.4 psia100%Ix104 rads

307OF22.9 psia100%1x104 rads

The manufacturer has tested this valve to the following environment:

NormalI Accident

Temperature:Pressure:Relative Humidity:Radiation:

140OFAtm100%5 x 107 rads

346 0F110 psig100%1.5x108 rads

6Per EN DES Calculation NEB 830204 223.

7Per WBN Environmental Data Drawing 47E235-79 30.

024144.02 E

Preparer/Date ____ _____ _________

Reviewer/Date

EQS No. WBNEEB0020Appendix 2 Revision 3Sheet - 1 of 19.

The manuficturer has thermally aged 206-381 valves for 12 days at 268*Ffollowed by the LOCA profile testing shown in figure 1. This thermal aging isequivalent to 6.7 years at 130*F.

Calculation

Applying EQN 1 and EQN 2:

A - 12 days -12x24 - 288 hours

To- 130OF -54.44 0C

TT - 2680 F -131 .11 0 C

N - (TT - T0)/10 - 7.667

L - A/(0.5)N - 2881(0.5)7.667

L = 58531.5 hours - 58531 .5/8766 -6.68 years

From the LOCA test profile (figure 1), it is our engineering judgment that:

- Since the transients of figures 3 and 4 last only 24 hours, the test timebetween 24th and 720th hour can be used to demonstrate post-LOCA lifecapability. Using the I00C rule, those 696 hours (assume conservatively at2000F) are equivalent to 1.2 years at 1300F. This satisfied the post-DBErequirement.

Calculation

Applying EQN 1 and EQN 2:

A -696 hours

To- 130OF - 54.440C

TT - 200OF - 93.330 C

N - (TT - T0)/10 - 3.889

L - AI(0.5)N - 696/(0.5)3.889

L - 10311.3 hours - 10311.3/8766 - 1.2 years

024144.02

E` F F E C TV ED AUT

Preparer/Date /,S2tA gEQS No. WBNEEB0020Revieer/Dte ~Appendix 2 Revision 3

Revewr/at zi7: Sheet 16 of 19I

Materials Potential for Significant Agigg

The material list of 206-381 series valves indicates ethylene propylene rubber(EPR) has been used. EPR is known to have the potential for significant aging.The test report has not indicated any failure of this material during thequalification test.

EPR as used in this solenoid valve is not a potential for significant aging inthe enviroriment in which it is located.

Chemical Spray

These valves are located outside containment so they are not subject to chemicalspray.

Conclusion

The required temperature, pressure, radiation,' and humidity are well within themanufacturer's test data. The LOCA test simulation (figure 1) exceeds thetime-temperature envelope for the actual HELB (figures 3 and 4). The valve isqualified for 6.7 years of normal operation and for 1.2 years following anaccident.

rE

L.. C;024144.02

j- name

0S-i 04

*d 300290/70

o ~CYýCLWithin

* 10 see.hemical 201

Y1 spray to94 be starte

Id

140 Pre-tent Aib ent A REFC I

Target Temnperature/Pressure Profile for simulation of Io~ns-of coolant accident(LOCA) design basis event (DBE) by g team/chemical- spray en~viron~me~ntal exposure.

0 .

i nQ

tj in i-I

#I

0

0.0

EnW

SOW) -

EQS No. WBNEEB0020Appendix 2 Rev. 3Sheet 18 of . 19-R

ft~ NTA..q(~ E~PRMT. DLSLE EDEDPLMP SUCTION BREAK gANDMOST SEVERE STEAI4..J BREAK (WELS) CMG4INEO

lilt

Figure 2

r E F F ? j ; V ? j

EQS No. WBNEEB0020Appendix 2 Rev. 3Sheet 19 of _16

NORTH VALVE VAULT- HELBPRESSURE VS TIKE -TE04PERATUDRE v6 TimE

to~5 aim= -a

Preparer/Date EQS No. WBNEEB0020Appendix-- -Rev 3

Reviewer/Date Z et 1 o

The devrisis listed below require sealing of the conduit entrance.Qualification of the conduit seals is documented in the referencedEQS.

Component UNID

1 ,2-FSV-43-201-A1 ,2-FSV-43-202-A1,2-FSV-43-207-B1, 2-FSV-43-208--B

WEN EEB-CSC-l, WEN EEB-CON-lWEN EEB-CSC-1, WEN EEB-CON-lWEN EEB-CSC-l, WEN EEB-CON-lWEN EEB-CSC-1, WBN EEB-CON-l

024144.02

EFFECTI~f.'IDATC

Revv~rsion , IkUit No. CommoneviOn 1~2* 3 BD MD BEE02Prepaerjbt, z V1 A IDNo.

See Appendix1

Mmnufactfirer and model No. ar.n mtbt-1p 103-7Verification Of *W~e Information (Table See- APendix 1

_Z_ - The equipment has been identified as per TVA Mh numberdesignations (such as, Mv, T)X Z=tM- The location has been identified (such as, inside primarycontainMent, annulus, Individually cooled room,, general spaces, or areaXaffected by JIELB outside primary contaimnent).X 2 9= - A unique WA MD nurber has been assigne-d (s;uch as, l-MS-68-308).MMQU - A functional description of the ampnt has been given (such as,X temu generator blowdcxvn).Kntac N . infactrr and ,- - The contract numberp manufacturer,and moe number have been given.X Abora or .cietFvrn - All abnormal or accident environmiental.citiOns applicable to this equipmet have been identif ied either in tables orX by references to figures fromi tables.... L. virnxentto ~xch Dualife - The environment to which the equipment has beenqualified is addressed in either the tables or the environmental analysisx_X 29 - A category of a,. b, c,, or d has been defined for theX 6qniprat.o and A2uayRourdadD mon ated - The operationand accuracy required and demonstrated have been defined.

Dualfi 111on tatu (ch k faxic ,l.?i nt%migiildle(If equipment is qualified,, indicate the qualified life with anumerical entry) 10 IrsX Qualificaatinmn gb 94. tA and14t+.U - A qualification report and the method ofqualification has been identified on the Table Input Nta Sheet (TnS) .X k Ir tlna~ - An environmental analysis has been done,. attached tothe EDSP and independently reviewed by the responsible organization.N/ .ulfcto byFmiai (If applicable) - A justification for qualificationby similarity is attached to the ZDS considering all the aoefactors andreferenced to the appropriate tables.X QuaIfiatN of CSeve.ral -&act (If applicable) - When an EDS is usedfor more than one item, a list of all ex~act cmr ta is given as an appendixwith all references to appropriate tables with justification for qualificationconsidering all the above factors.N/A elmOaifcto (If applicable) - (Open item) -bxethsbedetermined to be qualified only for a limited interim operation, an UM hasbeen written, and plnof action has been determined to yield a qualified

Term of Interim Qualification -------

_______________

RNM.N/A aAQX~ - (Opn item) - (If applicable) - bxeth budetermined to be uuaified; the following is attached to ED:M abrreao for no-ulificaton, and Justification of continued eperation. i

*Du to the extensive changes from Revision 1, revision bars are not used.

Preparer/Date A.9Reviewer/Date

EQS No. WBNEEB0022Appendix 1 Rev 3Sheet 1 of I

Manufacturer Fenval

Component Temperature Switch

Component UNID Model No. Table/Sheet

3. 1l-6/WBNEEB0OO5-0-TS-12-93A 18023-7 3. 11-8/wBNEEBOOO2

3. 11-6FW7BNEEB0005-0-TS-12-93B 18023-7 3. l1-8/WBNEE.BOOO2

3.1 1-6/WBNE-EBOO02-0-TS-12-94A 18023-7 3. 11-8/WEBqEEB0oo5

3.1 1-6/WNEEB00020-TS-12-94B 18023-7 3. 1l-8/WLNEZBOO05

3.1 1-6/WBNE M 002-0-TS-12-95A 18023-7 3. 11-8/WBNEEE0005

3.1 1-6/WBNEEB00020-TS-12-95B 18023-7 3. 11-8/W33NEEB0O05

3. 11-6/WBNEEB00020-TS-12-96A 18023-7 3. 11-8/WBNEEB0OO5

3.*11 -6/WBAEEBOOOZ-0-TS-12-96B 18023-7 3. 1l-8/wBNEEBOOO5

3. 11-67WBNqEEB00020-TS-12-97A 18023-7 3. 11-8/WBNEEBOOO5

3.1 1-67WBNEEB00020-TS-12-97B 18023-7 3. 11-8/wBNqEEBooo53. 11-6/WBNEEBOOO20-TS-12-98A 18023-7 3.1 1-8/WBNEEBO053. 11-6/WBHER 00020-TS-12-98B 18023-7 3. 11-8/WBNEEBOOO5

TWA2!nflAIAI nj

"Ai'.

0

Preparer/Date

Rev iewer/Date

I.1. For temperature switches:

I;,-2-30-TS-12-93A Fenwal model 18023-7

it

2. These temperature switches are located in the Auxiliary Building (room713/Al). The switches are required to operate for 1 minute after thestart of an Auxiliary Boiler line break, per EN DES CalculationNEB 840314 225.

3. These temperature switches are subject to HELE conditions (Volume 9).They are required to operate in the following environment1 :

Normal Abnormal Accident

Temperature:Pressure:Relative Humidity:Radiation:

Spray/Flooding:

1040 FAtM8025xl02 rads(40 yr TID)N/A

11. 1. For temperature switches:

0-TS-1 2-94A0-TS-12-94B0-TS-12-95A0-TS-12-95B0-TS-12-96A0-TS-12-96B0-TS-12-97A0-TS-12-97B0-TS-12-98A0-TS-12-98B

Fenwal model 18023-7it

of

of

2. These temperature switches are located in the Auxiliary Building (Room 692/Al). The switches are required to operate for 1 minute after the start ofan Auxiliary Boiler line break, per EN DES Calculation NEB 840314 225.

3. The temperature switches are subject to U.IB conditions (volumes 3 and 4).They are required to operate in the following environment:2

'See WBN Environmental Data Drawings 47E235-52 RO, -54 Ri.

2See WBN Environmental Data Drawings 47E235-62 RO, 63 Ri, 64 Ii.J

HOO0FAtm90%N/A

NIA

128OFAtm100%N/A

NIA

Vo lume 4444443333

EQS No. WBNEEB0022Appendix 2 Rev _3Sheet. 1 of 3

Prep'arer/Date

Reviewer/Date A"

Temperature:

Pressure:Relative Humidity:Radiation:

Spray/Flooding:

104 0F HOO0F

Atm80%5xl02 rads(40 yr TID)N/A

1340F(Vol. 3)1230FP(Vol. 4)14.4(-) psia100%N/A

NIA

These Fenval temperature switches were qualified by test per IEEE Standard323-1974. Test procedures and results are documented in Wyle LaboratoriesTest Report No. 17509-1 (TVA contract No. TV-56071A) dated 5/16/83.

All qualification tests were performed at test levels or conditions inexcess of known maximum application requirements. Margins were in accor-dance with those suggested by IEEE Standard 323-1974.

The switches were tested to the following environment:

Normal Abnormal Accident

Temperature:Pressure:Relative Humidity:Radiation:

Spray/Flooding:

104 0FAtm80%3 .5lXlO2rads(40 yr TID)

N/A

1150F

90%

W/A

21 30F**.8 psig**100%lxl04rads(qualificationby analysis)

N/AThe equipment was subjected to an accident simulation test. The transientportion of the test was repeated twice as required by IEEE Standard 323-1974.During the first temperature excursion, the temperature requirement of 3230Fwas attained in 24 seconds with no pressure requirements imposed.

The second temperature ramp was started after the test chamber temperaturewas stabilized at 1000F. During this ramp the temperature requirement of3230F was reached in 24 seconds. The pressure requirement of 7.9 psig in3.0 seconds was reached in approximately 1.5 seconds. Due to the chambertemperature falling below 2120F, the chamber pressure was stabilized toatmospheric at 9.5 hours into the test. The accident test was ended at the24-hour point.

**Subjected to 3230F and 7.9 psig during accident simulation test.

EFFEFCTIVEUDATE

1334 Revision -

P rrepareOD.Cte 4

EQS No. WBNEEB0022Appendix 2 RevSheet 2 of 3

Dal Accident

Preparer/Date EQS No. IWBNEEB0022Appendix 2 Rev 3Reviewer/Date 'e Sheet 3..j.. of 3L

The temperature switch was then aged to simulate 100 days equivalent (plus10% margin) post accident life and functionally tested.

The Fenwal temperature switch (model 10823-7) was shown to have a 10-yearqualified life with a 5-year unattended maintenance period. Additionally,the switch demonstrated a 110-day post accident duration in accordance withIEEE Standard 323-1974.

Based on the above test results, these switches are qualified for Class lEoperation in the required environments and will remain operational for therequired 1 minute post-DBE period.

014143.01

unit 1b 1 and 2Revision 1i 2T3* ft . WBNEEB002]

PreparerAbate #. e'. lýS-141 fIT See Appendix 1

Reviewer/bate

HKM4BN EN 01AUUI M MS

Manufactbrer and Model No MEA/1-19K-2 /Fisher 546verification of T~ble Information (Table See Api~endix I

-2- ~i=B T=- The equipment has been identified as per TVA ID numberdesignations (such ass, Nov. 89M.

-I-~ Uat - The location has been identified (such as, inside primarycontainment, annuluss, individually cooled rooms, general spaces, or areaaffected by HELB outside primary contairment).X Dof~mwt- A unique TVA ID number has been assigned (such ass, l-FSV-68-308).

-I E ti - A functional description of the component has been given (such ass,steami generator blowdowm)._2 Qmtrac No-. MAnufacurer, and NOdel No. - The contract numbers, manufacturers,

and model nu~mber have been given.-2-Abrmal or -Accident =iiroment - All abnormal or accident environmental

conditions applicable to this equipment have been identified either in tables orby references to figures from tables._.x.. Eviromet to W~hich Oualif led - The environment to which the equiprent has beenqualified is addressed in either the tables or the environmental analysis

attached.x Q&M - Acategory of as, b. cs, or dhas been defined for the

x~. Oeration and Accurac ReurdadDmntrated - The operationand accuracy required addemonstrated have been defined.

W Oualifktion satus (check -if a licabe. H&~ if not)Dalif ed it(If equipment is qualified, indicate the qualified life with a

X numerical entry): 9.24 yearsX qalifictign Report and MgetF - A qualification report and the method ofqualification has been identified on the Table Input Data Sheet (TIDS).X . Mnt1 AlYnlB - An envirornmental analysis has been doneo, attached tothe DSs, an independently reviewed by the responsible organization.N/A Cualifiction by Smlarity (If applicable) - A justification for qualification

by similarity is attached to the BOS considering all the above factors andreferenced to the appropriate tables.

X Gualification of Several S=ctt (If applicable) -When an EDS is usedfor more than one items, a list of allexact cm ets is given asan appendixwith all references to appropriate tables with justification for qualificationconsidering all the above factors.

_H.LA Intern OUAlification (If applicable) - (open item) - Component has beendetermined to be qualified only for a limited interim operations, an NM hasbeen writtens, and plan of action has been determin~ed to yield a qualified

Term of Interim Qualification_____________________

N/A J MUfJ.jo eMM~ - (Open item) _ (If applicable) - Caxet has beendetermined to be unqualified; the following is attached to ODS: .M numbers,reason for nion-qualifications, and justification of continued operation.

**Due to the extensive changes from Revision 2, revision bars are not used.

Preparer/Date

Reviewer/Date

EQS No. WBNEEB0023Appendix 1 Rev 3Sheet 1 of I

Manufact~urer HEA**/Fisher*

ComponentE lec tro-liydrauliic Valve Opera tor**/E lec tro-Pnewna ticTransducers*

Component UNID Model No. Table/Sheet

I 1-P-3-12* 5463.1l-6/WBNEEBO004II 2-PM-3-l22** 546K- 3.1l-8/WBNEEB0OO6

3.1 l-6/WBNEEB0OO4

I l-PM-3-l32* 546 3.11-8/k'BNEEB0OO63. ll-6/0BREEB0OO4

11 2-PM-3-132** 1-19KC-2 3.11-8/WBUEEB0006

024283.03

LI~y

Preparer/Date '&J. C. 'y"44.1 ,U/'

Reviewer/Date

EQS No. WBNEEB0023Appendix 2 Rev 3Sheet 17 of -5

UNIT I ONLY

I. 1. The Electro-Pneumatic Transducers listed in Appendix 1 underbeading I are Fisher model 546. They are locted in the AuxiliaryBuilding (room 713/Al, vol. 9).1 A8 detailed in EN DESCalculations (NEB 840515 225) for the Main and Auxiliary Feedwaterand Feedwater Control System, these valves are required to operatefor 100 days after the start of a LOCA and additionally they mustoperte for 30 days after either an Auxiliary Boiler line break,Auxiliary Feedwater line break, CVCS line break, or ERR line break.

2. These transducers are subject to LOCA/HELE conditions and arerequired to operate in the following environment:1

Normal Abnormal Accident

Temperature:Pressure:Relative Humidity:Radiation:

Spray/Flooding:

104 0FAtm80%

5xl02 rads(40 yrs TID)N/A

110 0FAtim90%N/A

N/A

128 0FAtm100%<1xl04 rads(LOCA only)N/A

3. Wyle Laboratories has tested this transducer to the follovingenvironment:

Temperature:Pressure:Relative Humidity:Radiation:

212OFAtm100%1.0X105 rads

4. Wyle Laboratories has thermally aged the model 546 transducer for576 hours at 212OF prior to the LOCA test simulation. Therefore,using this information along with a value of 0.83 for theactivation energy we can calculate the qualified life.

'Per WEN Environmental Data Drawings 47E235-52R0, -54R1.

~-. %~.2 4 2 2 ~,

r I

Jilt; /024283.03

-f of - M Oge. Z /P --'-0 -00

Preparer/Date VZL, C, 91-LReviewer/Date 6. .'"La. /iDS

EQS No. WBNEEB0023Appendix x2RevSheet 2- of -5

Calculations - Qualified Life

Cilculations are based on the Arrhenius equation which states:.

Ll L2 e C I

Where

Ll- Qualified Life

L2- Accelerated (test) life

El - Worst case activation energy, eV

K -Boltzmann's constant, 8.617 x 10-5 eV/OKE <-j Qualified temperature, absolute L

T2- Elevated (test) temperature, absolute

e - Base of natural logarithms

Calculating the qualified life for the transducers located in the

Auxiliary Building Room 713/Al, volume 9:

L2- 576 hours (Test Report No. 17504-1, page 11-2)

T1 - 10407 - 313.150K (temperature profile, WEN environmental datadrawing 47E235-52R0)

T2- 21207 - 373.150K (Test Report No.,17504-1, page 11-2)

El- 0.83 eV (Qualification plan No. 17460-13, Revision C, Table 1,page 28)

Ll - 9.24 years

Calculations - Post-Accident Life

Calculating the qualified post-accident life for the transducerslocated in the Auxiliary Building roo'm 713/Al, volume 9 (the worst-case accident temperature profile vais used for the transducerslisted in Appendix 1):

L2- 14 days (Report No. 17504-1. Figure VIII -1, page No. VIII-12)

E,- 0.83 eV (Qualification Plan No. 17460-13, Revision C, Table 1,page 28)

024283.03

Preparer/Date 2J~ . -I.~.. /i (JY -$7 EQS No. WBNEEB0023Appendix 2 Rev 3

Reviewer/Date M~ C. 4 U't / /0 -,O'* -0y Sheet 3 of 5

-l 1040F 313.150K (temperature profile, WEN environmentaldrawing 47E235-52R0, -54R1)

T2- 1490F - 338.150K (Report No. 17504-1, Figure VIII-1, page No.VIII-12)

Ll- 136.1 days

This is 136.1 days equivalent at 10407 and can be used to satisfythe post-DBE life of 100 days.

The above information shows that the switches are qualified for9.24 years at the maximum normal operating temperature, radiation,humidity, and then for the KSLB/LOCA conditions and for the post-accident life requirements. Satisfactory performance can beexpected from the transducers in the above environment.

5. Qualification Testing

a. Wyle Laboratories has tested the model 546 Electro-PneumaticTransducer to the requirements of IEEE Standard 323-1974 andNUREG-0588. The test criteria and results are documented inWyle test report 17504-1, Revision A. All qualification andtest were performed at test levels or conditions in excess ofknown maximum application requirements. These margins are inaccordance with the margins suggested by IEEE Standard323-1974.

b. Thermal aging: The transducers vere subjected to an agingtemperature of 21207 for a test duration of 576 hours. Threespecimens were cycled 220, 440, and 880 cycles ( 1 cycle isdefined as change in the input signal from 10 mA to 50 mA andback to 10 m&) after the completion of the post-thermal agingprogram to simulate the normal switching functions of the unitduring its lifetime. Life at the base temperature of 10407,using the Arrhenius equation with an activation energy of 0.83

I eV, was determined to be 9.24 years.

4.Radiation: Radiation testing was not required to demonstratethe capability of the transducer to perform its safety functionbecause all the nonmetallic materials in the transducer have adamage threshold level greater than the radiation requirementof 1.15 x 104 rads gammna[5 x 162 rads-normal plus 1.1 x10rads accident (including a 10% conservatism margin)3.

d. Seismic Simulation/Vibration Endurance: The transducers weretested to a single-axis sinusoidal vibration in each of threemutually perpendicular axis parallel to the major dimensions ofthe transducers, in accordance with IEEE 382-1974, 323-1974,and 344-1975. The transducers were subjected to biaxial

024283.03

1'

Preparer/Date V~) . /-Z,.0-aLi ±L~~f

Reviewer/Date

EQS No. WBN~EEB0023Appendix- 2-Rev 3Sheet 4 of 5

(approximately 02.g horizontally and vertically) sine sweeps-*fromlI z to 35 Eztol1flzat asweep rate ofoneoctave perminute. The transducers were also subjected to sine beat teatsconsisting of 10 oscillations per beat, five beats per testfrequency, with a two second pause between beats.

The test was performed with the transducers energized andde-energized. The transducers were monitored continuously forinput signal vs. output pressure.

e. LOCA Simulation: The transducers were subjected to a simulatedloss-of-coolant accident (LOCA) inside an environmental testchamber. The test profile envelops both the HELD and LOCAaccident profiles. LOGA simulation conditions were as follows:

Temperature: - Maximum of 21401 after 47 seconds decreasedlinerarly to 1100F in the next 23 hours and 58 minutes follwedby post-DBE conditions of 1490F for an additional 14 days.

Pressure: - Atm throughout 15 day test.

f. Qualified life - The transducers have a qualified life of 9.24years at 10401 and using a value of 0.83 eV for the activationenergy, 212 F~f or T2 and 576 hours for L2 -

6. in our engineering judgment, Wyle Laboratories' LOCA test profile(Figure VIII-l of Report No. 17504-1, page No. VIII-12) more thansatisfies the requirements of the actual MSLB/LOCA profile (WBNenvironmental data drawing 47E235-54R1). The post-acccident lifewas demonstrated by the 14 days at 14901 period of the accidentprofile. This period can be shown to be equivalent to 136.1 daysat 10401 (see calculation in section 4 above).

024283.03L

jri

,0. Jý. M '-444- / /V -,V -JýO

Preparer/Date2.C.)4 ,./i' 1

Reviewer/Date , . 1'4 //0 -109-(~s

ZQS No. WBIEEB0023Appendix 2 Rev 3Sheet 5 of 5

UNIT 2 ONLY

11. 1. The electrohydraulic valve operators in Appendix 1 are MA model1-19K-2:, They are located in the Auxiliary Building (room 713/Al,Vol. 9)) As detailed in EN MS Calculations (NEB 840515 225) forthe Main and Auxiliary Feedvater and Feedwater Control System,these valves are required to operate for 100 days after the startof a LOCA and additionally they must operate for 30 days aftereither an Auxiliary Boiler line break, Auxiliary Feedvater linebreak, CVCS line break, or iRH line break.

2. The valve operators are required to operate in the followingenvironment.1

Normal Abnormal Accident

Temperature:Pressure:Relative Humidity:Radiation:

Spray/Flooding:

1040?Atm80%

5xl0 2 rads(40 yrs TID)N/A

1100FAtm90%N/A

N/A

1280?Atm100%<IN1l04 rads(LOCA only)N/A

3. The manufacturer's specifications for the valve operators are:

Temperature:Pressure:Relative Humidity:Radiation:

130OFAtmosphericNEHA 4 EnclosureNot Specified

4. See generic position 4.1.2 for radiation. See generic position4.1.3 for relative humidity.

5. The maximum accident temperature to which these operators could beexposed is within the manufacturer's specification for thesedevices. This temperature would be above the abnormal temperature(by 80? or less) for under 24 hours.

6. Since the maximum temperature excursion for these devices is withinthe manufacturer's specified limits and the radiation environmentthat the devices are exposed to is less than 1 x 104 rads; in ourjudgment these devices will operate as required and are therefore.qualified for an interim period. However, due to the lack ofqualification documentation required by NUREG-05889 TVA willreplace these operators as determined by the resolution of NCRWBNEEB8114.

Notes:

1 Per WEN Environmental Data Drawings 479235-52R0, -54R1.E F [C~~

024283.03

Preparer/Date . i)-5 EQS No. WBNEEB0026Appendix 2 Rev 3

Reviewer/Date _________________ Sheet 2- of 4

As seen by the preceeding discussion, the first 5 minutes Of the

accident profile is the only portion of the 30-day profile thatexhibits a significant time rate of change for temperature and,even so, a relatively moderate rate of change. The remainingportion of the profile displays an essentially constant temperaturewith a maximum change in temperature of less than 201? per day. Thusfor purposes of qualification, the accident temperature profile hasbeen divided into 2 portions. The first portion, from accidentinitiation to the 28-hour mark is considered the accident profile.After 28 hours, the conditions are considered to be steady stateambient post accident conditions.

The H2 analyzer was tested at 16501 for 30 days. The first 28 hoursof the test envelopes the first 28 hours of the accident profile,including a 1501 margin. The remaining 692 hours are used in theArrhenius equation below to determine post accident life. Using a

teat temperature of 165O1 for 692 hours and a qualified temperatureof 127.50F ( 15001 + 10501 ) and also using a conservative activation

energy of 0.eV, the qualified post accident li.fe is in excess of 100

days.

Arrhenius equation:

Where

Ll- Quali fied life

L2- Accelerated (test) life

ElmWorst case activation energy, eV

K - Boltzmann's constant, 8.617 x 10-5 eV/OK 1Tl- Qualified temperature, absolute

T2-Elevated (test) temperature, absolute

e - Base of natural logarithms

Reference: EPRI, NP-1558p Research Project 890-I, dated September 1980.

A"ing

Aging consideration will be addressed in the Maintenance and Surveillance

Program for Watts Bar Nuclear Plant.

Reviion 1 1 * 3Unit No. 1and2Reviion-j 3 S No. WBNEEB0026

Preprer/ate/ /I/i j O~f'IDSee Appendix 1

bwB KUI4E=1 OtWRIPIA1=ON SMF7 (MfS)

Nanufactfirer and Yodel No. -Comsip-Delphi, Inc., model K-IIIMVerification of Tible Information (Table --See Appendix 1

M~i9t Z=- The equipment has been identified as per TMA ID num~berdesignations (such ass, MV,, SM??.

x L U - The location has been identified (such ass, inside primarycontainments, annuluss, Individually cooled roomss, general spacess, or areaaffected by HELB outside primary containment).X CCERM=- A unique TVA IM number has been assigned (such ass, l-FSV-68-308).

-IL B~im- A functional description of the component has been given (such as,steam generator blowdown).

*X Cntract N.. Manufacturer. and Model N.-The contract numbers, manufacturers,and model number haebeen given.

x- Ahn0rma or ACCident jvironii~n - All abnormal or accident environmentalcOnditions applicable to this equipment have been identified either in tables orby references to figures from tables.xEironmet to Which Oualife - The environmnent to which the equipment has been

qualified is addressed in either the tables or the environmental analysisattached.x QtaM - Acategory of a, b, c, or dhas been defined for the

-- 90rat ion and Accracy Reiired And Demontrated - The operationand accuracy required and demonstrated have been defined.

OUalifjcation. Status (check if Applicable. NR if Mot)Omliied-ife(If equipment is qualifiedo, indicate the qualified life with anumerical entry): See Appendix 2

-X 01hiaif'ctOUn &Reort and Method - A qualification report and the method ofqualification has been identified on the Table Input Data Sheet (TIDS).Zx.... d ~tal MAnaivS, - An environmental analysis has been done, attached tothe HOSP and independently reviewed by the responsible organization.N/ Oaificatign bySimilarity (if applicable) - A justification for qualificationby similarity is attached to the EDS considering all the above factors andreferenced to the appropriate tables.

X W=100caio 0f SeveralZExct Conpoent (If applicable) - When an EDS is usedfor more than one items, a list of all exact components is given as an appendixwith all references to appropriate tables with justification for qualificationconsidering all the above factors.

_ELA Inerim QUalificatilon (If applicable) - (open item) - Compionent has beendetermined to be qualified only for a limited interim operation, an NCR hasbeen written$, and plan of action has been determined to yield a qualifiedPCIonent.

Term of Interim Qualification ____________________

NCR No.NILA =l~ulif~iedc iMer - (OPen item) - (If applicable) - Cm~t has beendetermined to be unqualified; the following is attached to EDS: MM~ numbers,reason for nont-qualification, and justification of continued operation.

tNCNo. .....

Pre parer/DateR (tA.oLea 1 58

Revi ewer/Date ~IJ-

rlanuf aqturer

Component

*Not Installed

9-

EQS NO. WBNEEB0026Appendi x 1 RevSheetjTofI

'omsip.-De~phi * Incorporated

i Monitor-J

-A

a.

Component UNID Model No. Table/Sheet

1-H2AN-43-20O K-IIIM 3.ll1-5/WBNEEBOO0l

k2-.H2AN-.43..200 .3. 1l-5/WBNEEB0OO1

1-H2AN-43-210 K-IIIM 3. 11-5/WBNEEBQOO1

*2..H2AN-.43..210 3. 11-5/WBNEEBOOO1

5--rf

IR3

1R3

IR3

Preparer/Date (aft45&.V,4 /a-, EQS No. WBNEEB0026S Appendix 2 Rev 3

Reviever/Date See o

1. The hydrogen monitors in Appendix 1 are Comsip-Deiphi, Incorporated,model K-IIIM, and are part of the Watts Bar Nuclear Plant HydrogenDetection System. They are located in the Reactor Building (AnnulusEL 726 and 727). The hydrogen monitors are required to operate for100 days after the start of a LOCA inside containment, Main Steam linebreak, and Feedwater line break. Also they must operate for 1 monthafter ERR, and CVCS line breaks. The above category and operatingtimes are per EN DES Calculation NEB 840321 218, for the sample system.

2. The hydrogen monitors are subject to LOCA/HELB conditions. They arerequired to operate in the following environment:1 F

Normal Abnormal Accident

Temperature: 11001 (I) 120OF (I) 150OF

Relative Humidity: 80% 90% 100%Radiation: 5x105 rads N/A 5x106 rads LL

(40 year TID) -Spray/Flooding: N/A I N/A N/A I

3o Portions of the analyzer system were not qualified to withstand theharsh environment. Those portions have been relocated to a mildenvironment as documented in NCR WBNNEB8122 and ECN 4026. A list ofcomponents remaining in the harsh environment is found in Table 1. Theanalyzer is qualified to IEEE 323-1971 as demonstrated by Comeip '"Ksystems specifications dated September 1981 supplemented by WyleLaboratories Test Report 17502-1.

Radiation

The analyzer was subjected to a radiation exposure of l.Ox107 rads.The system was then subjected to a successful operational checkout.

Accident and Post Accident

The temperature profile of the plant area in which the H2 analyzers arelocated does not exhibit the typically sharp, short durationtemperature excursion normally associate4 with an accident temperatureprofile. In the first 5 minutes following an accident, the temperatureis ramped from 1050F to 1500F which is only a 90F per minute rate ofchange. After 5 minutes the temperature stabilizes at 1500F for thenext 27 hours and 55 minutes, after which, the area cools to 1050F atthe end of 30 days. This yields a temperature decrease of 0.06501 perhour or 1.560F per day.

'See WBN Environmental Data Drawing 47E235-44 RO per environmental data.

Preparer/Date g. cfwý0 10,. - e EQS No. WBNEEB0026

Appendix 2 Rev 3Reviewer/Date ,..A .. te../.g' Sheet 2 of 4

As-seen by the preceeding discussion, the first 5 minutes of the.ac~cident profile is the only portion of the 30-day profile thatexhibits a significant time rate of change for temperature and,even so, a relatively moderate rate of change. The remainingportion of the profile displays an essentially constant temperaturewith a maximum change in temperature of less than 20F per day. Thusfor purposes of qualification, the accident temperature profile hasbeen divided into 2 portions. The first portion, from accidentinitiation to the 28-hour mark is considered the accident profile.After 28 hours, the conditions are considered to be steady stateambient post accident conditions.

The H2 analyzer was tested at 1650F for 30 days. The first 28 hoursof the test envelopes the first 28 hours of the accident profile,including a 1507 margin. The remaining 692 hours are used in theArrhenius equation below to determine post accident life. Using atest temperature of 16507 f or 692 hours and a qualified temperatureof 127.5 0F ( 150OF + 1050F ) and also using a conservative activationenergy of 0.6eV, the qualified post accident life is in excess of 100days.

Arrhenius equation:

Where

Ll- Qualified life

L2-Accelerated (test) life

El Worst case activation energy, eV

K - Boltzmann' s constant, 8.617 x 10-5 eV/OK

TI-Qualified temperature, absolute

T2- Elevated (test) temperature, absolute

e - Base of natural logarithms

Reference: EPRI, NP-15581 Research Project 890-1, dated September 1980.

Aging consideration will be addressed in the Maintenance and SurveillanceProgram for Watts Bar Nuclear Plant.

Preparer/Date . 2pLret o54-

Reviewer/Date4/4u 4 iL-15 2EQS No. WJBNEEB0026Appendix 2 Rev 3Sheet 37- of -4

Summary

Based on the information presented above, the H analyzers are qualified tooperate for 100 days following an accident per juidelines established byIEEE 323-1971.

TABLE 1

I tern Description

1 Entry Exit Valve

2 Moisture Separator

3 Gas.Manifold

4 Air Cooled Heat Exchanger

5 Pressure Indicator

6 Sample Pump

7 H2 Analyzer

8 Flow Orifice

9 Differential Pressure SwitchStatic 0-Ring

10 Check Valve

11 Temperature Switch

12 Temperature Bulb

ED FE C ýD ?A i

Lights

Switch

Terminal Strips

Circuit Breaker

Fittings

Calrod Strip Heaters

13

14

15

16

17

18

Preparer/Date J0

Reviewer/Date A 4

EQS No. WBNEEB0026Appendix 2 Rev 3Sheet 4 of 4

TABLE 1

I tern

19

20

Description

Sample Pump Motor

Trip Switch

Down Stream Regulators

034150.01

[ EF F E C' IV~D A f E0 CT

. I ~Unit No. Como-:/aeRevision -1 2 EDS NO. WREPR.&D2.Z

vj: TVA ID No.

,v 43See Appepndix I

ManufaCt~rer and Model No. ,,,,,,,nt mod -I .1 11 ST) IVerification of ¶~ble Information (Table See Append ixcX &=MtT - The equipment has been identified as per TVA 31) numberdesignations (such as,, mW, sMy).x___m - The location has been identified (such as, inside primarycontainment,, annulus, Individually cooled room~, general spaces, or areaaffected by HULB outside primary containment).X Mt- A unique TVA ID number has been assigned (3uch as, l-FSV-68-308).ZMQ~iM- A functional description of the comonent has been given (such as,steam generator blowdown).X -2aLN..Mnfcuer n o The contract number,, manufacturerl,and model number have been given.X bor2 o ccdn Thvr nma - All abnormal or accident environmentalconditions applicable to this equipment have been identified either in tables orby references to figures fromi tables.~ ~virxn1~ to Wich q aliid - The environment to which the equipment has beenquliffieed iss aaddrroerss~e~d in 'eithler the tables or the envirornmental analysisX agq - Acategory of a, b,, c. or dhas been defined for the

XL. Oprto n cuayRourdadDmntae he operationand accuracy required and demonstrated have been defined.

QM~jjO_" (If equipment is qualified, indicate the qualified life with anumerical entry): io years-. Z-~. Qualif icat irnn R ort- andM-th - A qualification report and the method ofqualification has been identified on the Table Input Data Sheet (TInS).l~n VJ - An environmental analysis has been done, attached tothe EQSr n independently reviewed by the responsible organization.aL~Quaifiatin b B~~lait~(If applicable) - A justification for qualificationby similarity is attached to the EQS considering all the above factors andreferenced to the appropriate tables.j Qulifcaton f SeveralUE atCM"Mant, (If applicable) - W~Ien an BQS is usedfor more than one item, a list of all exact cmoets is given as an appendixwith all references to appropriate tables with justification for qualificationconsidering all the above factors.N/LA Ttrmuaii tin(If applicable) - (open item) - Component has beendetermined to be qualified only for a limited interim operation, an SM hasbeen writtens, and plan of action has been determined to yield a qualifiedcmIxnent.Term of Interim Qualification_____________________

HRNo.S-(Op en it-em-) - (If -applicalee) - t has beenrr-.determined to be unqualified; the following Is attached to EQS: NC ume,reason for non-.qualificatjons, and justification of continued operation.F F

Preparer/Date________ ______

Reviewr/DateZý ý0-u ýZ-jp/

EQS No. WBNEEB0027Appendix. 1 Rev 2Sheet 1 of 1

Manufactxier _Rosemount, Incorporated

Component Level Transmitter

Component UNID Model No. f Table/Sheet

I -. T7711 3.1l7/WBNEBOOO4

* (A

Preparer/Date A

Reviewer/Date ,dI-j'

EQS No. WBNEEB0027Appendix 2 Rev 2Sheet 1 of 3

1. The jevel transmitters in Appendix 1 are Rosemount model 1153DM4. Theyare~located in the Auxiliary Building (Containment Spray Pump Rooms;676ý/MA9,14. As detailed in EN DES Calculations, NEB 840314 230, theyare required to operate for 100 days after the start of a LOCA. Theyare also required to operate for 1 month after breaks in either RHR orCVCS lines outside containment.

2. They are required to operate in the following environments:1

Normal

Temperature:Pressure:Relative Humidity:Radiation:

Spray/Flooding:

104 opAtm( -)80%3.5x102 rads(40 yr TID)

3. The manufacturer's specifications for the transmitters are:

Abnormal

110OFAtm( -)90%N/A

Accident

looFN/AN/AIX107 rads(LOCA)

Temperature:Pressure:Relative Humidity:Radiation:

318OF87.7 psia100%2.2lxl07 rads (TID)

4. Documentation of testing to the requirements Iof IEEE 323-1974 and IEEE344-1975 is provided in Rosemount .'s Qualification Report 108025 andType Test Report 108026. A summary of testing, in testing sequence, isgiven below:

(a) Thermal Ai~ng: Thermal aging was conducted for 1128 hours at 2030F.The Arrhenius Equation was used, with an activation energy of 0.78eV,to determine a qualified life of 10 years at the maximum normaltemperature of 1040F

(b) Seismic Taes~ting: Seismic testing with an input of 7.2 g' s wasperformed. All TRS's were recorded and are included in the testreport.

(c) Accident Simulation Testing: Figure 1 shows the actual test temper-ature curve. The temperature at which the devices must operate ismuch less severe than the test cuzrVe values.

Testing simulated a 2 year post-accident operation, which envelopesthe post-accident operating requirement of 100 days.

'See WBN Environmental Data Drawing 47E235-81wJ.

1A L:

Preparer/Date A

Reviewer/Date /~/> 0

EQS No. WBNEEB0027Appendix 2 Rev 2Sheet 2 of 3

-.Testing simulated a pressure of 73 psig for 10 minutes. Thereinopressure effect due to the LOCA or line breaks after whichteequipment must operate.

(d) Radiation Testing: Radiation aging and abnormal radiation testingwere -ombined n provided a total test dosage of 2.44x107 radsat a maximum dose rate of 1XI06 radu/hour. The test reportverifies qualification for use where any combination of normalradiation and accident radiation is 2.21z107 rads or less. Themaximum radiation exposure for which the devices must operateis IxI07 (40 year TID plus a lOO-day LOCA).5. The temperature, pressure, relative humidity, and radiation environmentsare well within the manufacturer's specifications and test results shownabove.

6. The above information, as documented in Qualification Report 108025 andType Test Report 108026, shows that these transmitters are fully qualifiedper IEEE 323-1974, IEE 344-1975, and NUREG-0588 for required operationin the harsh environments. A qualified life of 10 years was demonstrated.

DEOO ;074144.o3 F ~ v7

Ig!

0

K. ;~I ~

II ~*

(Hog)-13

ov"Zoa

KAO 9PA ýP IR u Q i A T3 P. a m Ir m

a. a

rn0- l

CL 0

0

(age of. 73. Pala)

'EARAwd.of

Preparer/Date lie I.Reviewer/Date,4.Z, 4e5.. 0 iLi'

EQS No. WBNEEB0027Appendix 3 Rev 2Sheet 1 of I

The devices listed below require sealing of the conduit entrance.the condiUit seals is documented in the referenced EQS.

-Component UNIDO-LT-77-134O-LT-77 -135

Qualification of

MB E-S-W4BN EEB-CSC-1

DEOO ;074144 .03

FE F- F

uniit No. 1 and 2ZQS No. WBNFLD0029TVA MD No.

See Appendix 1

Manufactker'rand Model No. See Appendix 1verification of Table Information (Table See Appendix 1

X Madmt LU- The equipnent has been identified as per TVA I numberdesignations (such as, mov, sOT).x IMAUM- The location has been identified (such as, inside primarycontainment, annulus,, individually cooled roms general spaces, or areaaffected by RUB outside primary containment).X QM = -A unique WVA ID number has been assigned (such as, l-FS-68-308).X ZWU - A functional description of the conponkent hjas been given (such as,steam generator blowdown).

Y~ Conrat N.. Manufacturer, And Model o.-The contract number, manufacturer,and model number have been given.-X- AoMMMl Or AC !&=n EnvironM=n - All abnormal or accident environmentalconditions applicable to this equiPnent have been identified either in tables orby references to figures from tables.-.Y Movirmmnm~ag tohich Qualified -*The environment to which the equipment has beenqualified is addressed in either the tables or the environmental analysis

attached.Y f~t = -Acategory of a, b, cl or d has ben defined for the

*. Oeraion and AccuraCy Requijred and DMTontrae - The operationadaccuracy required and -deonstrated have bee defined.Oual if ication Status _(check if' ,Applicable. N#A if not)

Lie(If equipm~nt is qualified, indicate the qualified life with anumnerical entry): --4n y arsx. OMUaliicai &Reort and Method - A qualification report and the method ofqualification has been identified on the Table input Data Shet (TIDS)._2.L . - An environmental analysis has been done,, attached tothe EQS,, and independently reviewed by the responsible organization.N/A Oalifi~tionByimnilarity (If applicable) - A justification for qualificationby similarity is attached to the BDS considering all the above factors andreferenced to the appropriate tables.-.Z Oualificaion of Sqeve3ra Exact (If applicable) - When an EDS is usedfor more than One item, a list Of all exact components is given as an appendixwith all references to appropriate tables with Justification for qualificationconsidering all the above factors.

-EL ThteriMOulificWati (If applicable) - (open item) - Conpoent has beendetermined to be qualified only for a limited interim operation, an NCR hasbeen written,, and plan Of action has been determin~ed to yield a qualifiedllen of Interim Qualification_____________________MM No.

.~L ~-(Open item) - (If applicable) - Cmoethsbedetermin~ed to be unqualified; the followidng is attached to EDS: MM number,,reason for non-qualificationl, and Justification of continued operation.NM[PFE.

*Due to the extensive changes from Revision 2., revision bars are not used. DF E ý 1A

I-J

Preparer/Date('Ža" 45, EQS No. WBNEEB0028Appendix 1 RvTRevi ewer/Date -She 1 o

Manufacturer ASCO

ComponeWt' Solenoid Valve

Preparer/Date .1

Rev iewer/ Date ,;:z~ 4 0 ~ 9-~&EQS No. WBNEEB0028Appendix 2 Rev 3Sheet 1 of 13

.1.The solenoid valves listed in Appendix 1 are ASCO model NP831654E.They axre located inside Containment, in the Lower Compartment atelevation 703, with the exception of 1-FSV-62-69A which is located atelevation 716. As detailed in EN DES Calculation NEB 840411 222 forthe Chemical and Volume Control System, valve number I-FSV-62-69A mustoperate for 5 minutes after a line break in the CVCS and not fail in amanner detrimental to plant safety for 1 month thereafter. Valvenumbers I-FSV-62-72-A, l-FSV-62-73-A, and l-FSV-62-74-A must operatefor 5 minutes and not fail in a manner detrimental to plant safety for100 days thereafter after the start of a LOCA or a line break in theMain Steam or Main Feedwater systems. They must operate for 5 minutesand not fail in a manner detrimental to plant safety for 1 month aftera line break in the Residual Heat Removal or Chemical Volume ControlSystems.

As detailed in EN DES Calculation NEB 840411 220 for the Upper HeadInjection System, valve numbers 1-FSV-87-7 and l-FSV-87-8 must operatefor 5 minutes after the start of a LOCA or a line break in the MainSteam or Main Feedwater systems and not fail in a manner detrimental toplant safety for 100 days thereafter. In the event of a line break inthe Residual Heat Removal or Chemical Volume Control Systems, they mustoperate for 5 minutes after the start of the event and must not fail ina manner detrimental to plant safety for 1 month thereafter.2. These solenoid valves are subject to HELB/LOCA conditions and arerequired to operate in the following environments1 :

Nor-malTemperature:Pressure:Relative Humidity:Radiation:

Spray/Flooding:

3. ASCO has tested these

Temperature:Pressure:Relative Humidity:Radiation:Spray:

1200FAtm80%2x107 rads(40 yr TID)NIA

Abnomali

13OOFAtm100%

N/A

valves to the following environment:

346 0F110 psig100%2xl08 rads3000 ppm BORON/ph 9-11

Ac c Aide nt

327 0F26.4 psia100%1x108 rads

Spray Only

'Per WBN Environmental Data Drawing 47E235-42. E FFEC.TinVE$

OCT ji-3

Preparer/Date -Žd!t 4 / z e5YEQS No.* WBNEEB0028

Revewr/DteAppendix 2 Rev 3___ ___ __ ___ ___ __ ___ __ Sheet 2 - of 13

I.1. Qualification Testing

a. ASCO has tested the NP8316 series solenoid valves to therequirements of IEEE Standard 323-1974 and NUREG-0588. The testcriteria and results are documented in ASCO test reportAQS21678/TR, Revision A. All qualification tests were performed attest levels or conditions in excess of known maximum applicationrequirements. These margins are in accordance with the marginssuggested by IEEE Standard 323-1974.

b. Seven solenoid valve samples representing six generic families ofvalves, including the UP8316 series, were subjected to sequentialexposures of elevated temperature, radiation, wear aging, seismicsimulation, vibration endurance, accident radiation and 30 day LOCAsimulation. Baseline functional tests were performed before thestart and after each sequence of the test exposure with theexception of coil dielectric and insulation resistance measurementswhich were taken before thermal aging and after accident radiationand after LOCA exposure. The valves were energized and deenergizedat high and low pressures during the test phases (except radiation)and leakage monitored.

c. Baseline/Functional: Baseline/functional tests consisted ofmeasurement of coil excitation, seat leakages at high and lowpressures, noise test, operation test, and external leakage testbefore and after all phases of type tests. Measurement ofinsulation resistance and coil dielectric test was performed andLOCA simulation valves were energized and deenergized and theiroperation monitored during testing (except radiation).

d. Thermal aging: The valves were subjected to an aging temperatureof 268*F for a test duration of 12 days. They were cycled (deenergizedfor 5 minutes and then energized) every six hours.

e. Radiation: The valves were subjected to cobalt 60 (gamma)radiation at an exposure rate of less than one megarad per hour.Total integrated dose received vas 50 megarads.

f. Cycle Aging: The valves were electrically cycled 40,000 times atmaximum operating pressure differential.

g. Seismic Simulation/Vibration Endurances: The valves weresubjected to a combined SSE and fragility test. The input'g-levelwas 7 g's. The test was performed with the valves energized anddeenergized and with high and low pressure. The leakage rate wasmonitored.

Preparer/Date /Z44-- f147- -_ EQS No. WBNEEB0028

Appendix 2 Rev 3Reviewer/Date x z?.2E'J Sheet, 3- of 13

h. Accident Radiation: The valves were subjected to cobalt 60(gamma) radiation at an exposure rate of less than 1 megarad perhour. Valves received an additional accumulated dose of 150megarads for a total integrated dose of 200 megarads received intwo stages*

i. LOCA Simulation: The valves were subjected to a simulated loss-of-coolant accident (LOCA) by exposure to steam and chemical sprayfor 30 days. LOCA simulation conditions were as follows:

Temperature - Maximum of 346OF for a total period of 6 hoursfollowed by a step decrease to 200OF followed by post-DBEconditions of 200OF for the remaining 26 days.

Pressure - Maximum of 110 psig for a total period of 6 hoursfollowed by a step decrease to 10 psig within 4 days followed bypost DBE conditions of 10 psig for remaining 26 days.

Relative Humidity - All steam environment in excess of 2500F;greater than 90 percent for other conditions.

Chemical Spray - The chemical solution consisted of 3,000 ppm Boronas boric acid in solution with 0.064 molar sodium thiosulfatebuffered with sodium hydroxide. The chemical solution pH wasmaintained between 9.5 and 10.5.

j. Results: One of the valves malfunctioned during thermal aging.The valve developed excessive seal leakage both in the energizedand deenergized states. This was later determined to be caused bydirt in the valve. The source of dirt was the iron pipe used inthe cylinder port as piping and an additional length used tosimulate an accumulator.

Other than the above malfunction, the valves successfully completedthe sequential type tests and the baseline/functional tests.

2. Qualified Life - The solenoid valves have a qualified life of 40 years at 120*Fand 40,000 cycles, providing the maintenance schedule outlined in paragraph 4 isfollowed. Open and close completes one cycle. However, due to the self-heatingnature of solenoid valves, the temperature rise associated with a continuouslyenergized solenoid valve must be accounted for in the qualified lifecalculation. There are two areas affected by this heating: (1) the coil seesan increase of 105% (221*F) above ambient and (2) the elastomeric-discs see anincrease of 45*C (113*F) above ambient. These temperature increase values comefrom Franklin Research Center's "Test Program and Failure Analysis of Class lESolenoid Valves" (NUREG/CR-3424, F-C5569-309/315).

T

0 r

i

Preparer/Date _______________ QSN.WNEO2

~71Appendix 2 _Rev 3Reviewer/Date /9/1 4 "Sheet 4 of 13

Based on the above information, a separate qualified life must be calculated for both'the coil and the disc. The following qualified life calculations, which are based onthe Arrhenia's equation, are f or valves to be used at a normal ambient operatingtemperature of 120*F (48*.9*C):

LlI -L2e [I K i - T2 3

COILS

In Franklin Research Center's "Test Program and Failure Analysis of Class 1ESolenoid Valves" (NUREG/CR-3424, F-C5569-309/315), the solenoid coils were aged attwo rates: 150*C (302*F) for 9.3 days (223.2 hours) and 131*C (268*F) for 15.3 days(367.2 hours).

Ll- Qualified life (first aging rate)

L2- Accelerated (test) life - 223.2 hours

E - Activation energy - 1.00 eV

K - Boltzmann's constant - 8.617 X 10-5 eV/OK

Tj- Qualified temperature (ambient + 105*0 ) - 153 .9*CT2- Elevated (test) temperature - 150*C + 1050C -255 0C

e - Base of natural logarithms

Ll'u' Qualified life (second aging rate)

L2 '- 367.2 hours

E -1.00 eV

K - 8.617 x 10- eV/OK

Ti'- 48.90C + 1050C - 153 .90C

T2 '- 131VC + 105*C - 2360C

e - Base of natural logarithms

Ll (total) - Total qualified life -l + L1 7.973 years

Preparer/Date(/3/u Z. ~ 9-~ iReviewer/Date 9,2~a.a .. y

DISCS

In ASCO test report AQS-21678/TR, supplement,3,(268*F) for 12 days (288 hours).

EQS No. WBNEEB0028Appendix 2 Rev 3Sheet 5~ of 13

the entire valve was aged at l31*C

Ll- Qualified life

L2- Accelerated (test) life - 288 hours

E = Activation energy - .94 eV

X - Boltzmann's constant - 8.617 x 10-5 eV/-K

Tl- Qualified temperature - 120-F

T2- Elevated (test) temperature - 1310C + 45*C - 1760C

e n Base of natural logarithms

Ll-7.56 years

3. Installation - Valves should be installed such that theIin the vertical and upright position. axis of the coil remains

4. Maintenance Requirements - The qualified life depends on the valve being cycledat least every 16-18 months to ensure proper opening and closing. Coils shallbe replaced every 7.973 years and elastomeric' components shall be replaced every7.56 years when solenoid valves are subjected to a normal operating ambienttemperature of 120*F. In addition, ASCO recommends that when the solenoidvalves reach 20,000 cycles, that they be rebuilt using the applicable spareparts kit and spare coil kit2.

2SOTest Report AQR67368/Rev. 0, Appendix C page C-2.

E F F F,'1~

OCT ~i'

Preparer/Date 1KŽif15P~ ~-2,6 -XV EQS No. WBNEEB0028

Z V Appendix 2 Rev 3Reviewer/Date ~ -7-Z - Sheet 6 of 13

5. Valves are qualified for IEEE Standard 323-1974, IEEE Standard 332-1972, IEEE Standard 344-1975, and applicable portions of NIJREG-0588 forthe environment in which they are required to operate, providing themaintenance schedule in paragraph 4 above is followed. By mathematicalanalysis, the qualified post-DEE operating time can be extended to 263days.

Calculations - Post-Accident Life

Calculations are based on the Arrhenius equation which states:

Ll- L2e [K T T2]Where

L4 - Qualified life

L2- Accelerated (test) life

El - Worst case activation energy, eV

K = Boltzmann's constant, 8.617 x 10-5 eV/OK

Tj- Qualified temperature, absolute

T2 - Elevated (test) temperature, absolute

e -Base of natural logarithms

Calculate qualified post-accident life for valves located in lovercompartment of containment:

L2- 26 days (AQS21678/TR Rev A, figure 2, page 4-21)

El-0.94 eV (AQR67368, Appendix B, page B-3)

Ti-152.50F (temperature profile, SQN/WBN Envirommental Data Drawing47E235-45), 190OF @ 6 x 103 sec -150OF @ 30 days/2 + 1150F)

T2-200OF (AQS21678/TR Rev A, Figure 2, Page 4-21)

L2- 26 x 24 -624 hours

[E F F I: CHVE

Preparer/Dat 7./?AŽ 4 9z 9Reviewer/Date g:?: -?4

Tj- 152.5-32/1.8 + 273.15 - 340.10K

T2- 200-32/1.8 + 273.15 - 366 .50K

-.94 1

Ll=624e L8.617 x 10 340.1

L4 6318 hours - 263 days

EQS No. WBNEEB0028Appendix 2 Rev 3Sheet 7 of 13

366.5J

Preparer/Date LL~~-~

Reviewer/Da te 24. -EQS No. WBNEEB0028Appendix 2 Rev 3Sheet 8- of 13

.1.The solenoid valves listed in Appendix 1 are ASCO model NP831654V.They are located in the lower containment. They are located atelevation 703 with exception of 2-FSV-62-69A, which are located atelevation 716. They are required to operate for 5 minutes after thestart of various design-basis accidents and not to fail in a mannerdetrimental to plant safety for periods of up to 100 days thereafter.*(Depending on which accident occurs.)

2. The solenoid valves are subject to E.ELB/LOCA conditions.required to operate in the following environmental: They are

AccidentTemperature:Pressure:Relative Humidity:Radiation:

Spray/Flooding:

1 20OF14.7 psia80%5.3xl06 rads(10.6 years TID)NIA

327 0F26.4 psia1 00%1x108 rada(LOCA)Subject to both

3.ASCO has tested the solenoid valves to the following environment:

Temperature:Pres sure:Relative Humidity:Radiation:Spray:

346 0F110 psig100z2 x 108 rads3000 ppm Boron/pH 9-11

II .Qualification Testing

a. ASCO has tested the NP8316 series solenoid valves to therequirements of IEEE Standard 323-1974 and NUREG-0588. The testcriteria and results are documented in ASCO test reportAQS21678/TR, Revision A. All qualification tests were performed attest levels or conditions in excess of known maximum applicationrequirements. These margins are in accordance with the marginssuggested by IEEE Standard 323-1974.

*Failures due to flooding are acceptable to plant safety -EN DESCalculation NEB 820505 202. --lPer SQN/WBN Environmental Data Drawing 47E235-45. E

Normal

Preparer/Date 4 i Pa#A 'l EQS No. WBNEEB0028__iwe/a Appendix 2 Rev 3

Revewr/DteL44Z-ý,-4 Sheet 9 of 13

b. Seven solenoid valves samples representing six generic families ofval-ves including the NP8316 series, were subjected to sequentialexposures of elevated temperature, radiation, wear aging, seismicsimulation, vibration endurance, accident radiation and 30 day LOCAsimulation. Baseline functional tests were performed before thestart and after each sequence of the test exposure with theexception of coil dielectric and insulation resistance measurementswhich were taken before thermal aging and after accident radiationand after LOCA exposure. The valves were energized and deenergizedat high and low pressures during the test phases (except radiation)and leakage monitored.

c. Baseline/Functional: Baseline/functional tests consisted ofmeasurement of coil excitation, seat leakages at high and lowpressures, noise test, operation test, and external leakage testbefore and after all phases of type tests. Measurement ofinsulation resistance and coil dielectric test was performed andLOCA simulation valves were energized and deenergized and theiroperation monitored during testing (except radiation).

d. Thermal aging: The valves were subjected to an agingtemperature of 2680F f or a test duration of 12 days. They werecycled (deenergized f or 5 minutes and then energized) every six,hours. Life at a base temperature of 140OF using the 100C rule(Arrhenius Equation) was calculated to be 4.5 years.

e. Radiation: The valves were subjected to cobalt 60 (gamma)radiation at an exposure rate of less than one megarad per hour.Total integrated dose received was 50 megarads.

f. Cycle Aging: The valves were electrically cycled 40,000 times atmaximum operating pressure differential.

g. Seismic Simulation/Vibration Endurances: The valves were subjectedto a combined SSE and fragility test. The input g-level was 7 g's.The test was performed with the valves energized and deenergizedand with high and low pressure. The leakage rate was monitored.

h. Accident Radiation: The valves were subjected to cobalt 60 (gamma)radiation at an exposure rate of less than 1 megarad per hour.Valves received an additional accumulated dose of 150 megarads for.a total integrated dose of 200 megarads received in two stages.

A T:6

Preparer/Date/ ý. / 2 c -J/2.ZI EQS No. WBNEEB0028Reviwer/ateAppendix -2- Rev 3Reviwer/ate~ /~Z--7J~/ Sheet 10 of 13

1.LOCA Simulation: The valve. were subjected to a simulated loss-of-coolant accident (LOCA) by exposure to steam and chemical spray for30.days. LOCA simulation conditions were as follows:

Temperature - Maximum of 34601 for a total period of 6 hoursfollowed by a step decrease to 200OF followed by post-DBEconditions of 200OF for the remaining 26 days.

Pressure - Maximum of 110 psig for a total period of 6 hoursfollowed by a step decrease to 10 puig within 4 days followed bypost DBE conditions of 10 psig for remaining 26 days.

Relative Humidity - All steam environment in excess of 25001;greater than 90 percent for other conditions.

Chemical Spray - The chemical solution consisted of 3,000 ppm Boronas boric acid in solution with 0.064 molar sodium thiosulfatebuffered with sodium hydroxide. The chemical solution pH wasmaintained between 9.5 and 10.5.

j.Results: One of the valves malfunctioned during thermal aging.The valve developed excessive seal leakage both in the energizedand deenergized states. This was leter determined to be caused bydirt in the valve. The source of dirt was the iron pipe used inthe cylinder port as piping and ad additional length used tosimulate an accumulator.

Other than the above malfunction, the valves successfully completed thesequential type tests and the baseline/functional tests.2. Qualified Life - The solenoid valves have a qualified life of,9.8years at 12001 (see following calculations) and 40,000 cycles. Openand close completes one cycle.

Calculations

Thermal aging calculations are based upon the "100C Rule," equationsI and 2, which states the life (i.e., test time) is halved for each100C increase in temperature.

EQN 1 L -A/(0.5)N

ZQN 2 TT To+ 10N

E F:F '~

Preparr/Dat E. ~QS No. WBNEEB0028P r e p r e r D a t Z YA p p e n d i x .2 R e v 3Reviewer/Date Sheet 11- of 13

Where:

A - Aciual Required Test Time

L - Qualified life at normal ambient operating temperatures

N - Number of 100C increments above ambient temperature

To- Qualified Temperature, OC

TT -Test Temperature, OC

Reference: EPR, NP-1558, Research Project 890-1, dated September1980.

Qualified Life-at 120OF

Applying EQN 1 and EQN 2

A -12 days - 12 x 24 - 288 hours

To- 120OF - 120-32/1.8 - 48.890C

TT - 268OF - 268-32/1.8 - 131.110C

N -TT - T0/10 - 131.11 - 48.89/10 - 8.222

L -A/(0.5)N -288/(0.5) 8.222 - 85992 hours

L - 85992/8766 - 9.8 years

3. Installation - Valves should be installed such that the axis of thecoil remains in the vertical and upright position.

4. Maintenance Requirements - The qualified life depends on the valvebeing cycled at least once a month. Coils and elastomeric componentsshall be replaced every 40 years when solenoid valves are subjected toa normal operating ambient temperature of 1200F. In addition, ASCOrecommends that when solenoid valves reach 20,000 cycles, that they berebuilt using the applicable spare parts kit and spare coil kit.2

2ASCO Test ReportAQR67368/Rev. 0Appendix C, Page C-2

..... .. ....

___________________99_ EQS No. WBNEEB0028Prepa er/D te /'~ •k ~ ..4.Appendix 2 Rev 3Reviewer/Date '.Z7 Sheet 12- of 13

5. Nuclear Regulatory Commission IE Information Notice No. 81-29,Equipment Qualification Notice No. 10 has identified a problem withASCO solenoid valves with viton dynamic seals. The viton seals willadhere to metallic surfaces when exposed to radiation doses in excessof 20 megarads. Valves listed in appendix 1 have viton seals. Theviton seals will be replaced with ethylene propylene seals per NCRWBNEEB8147 before fuel loading.

6. Valves are qualified per IEEE Standard 323-1974, IEEE Standard 382-1972, IEEE Standard 344-1975, and applicable portions of NUREG-0588for the environment in which they are required to operate, providingthe maintenance schedule in paragraph 4 above is followed. Bymathematical analysis, the qualified post-DBE operating time can beextended to 263 days.

Calculations - Post Accident Life

Calculations are based on the Arrhenius equation which states:

Ll = L2e [K T - T2 ]

Where

Ll- Qualified life

L2- Accelerated (test) life

El- Worst case activation energy, eV

K - Boltzmann's constant, 8.617 x 10-5 eV/OK

Tj- Qualified temperature, absolute

T2- Elevated (test) temperature, absolute

e Base of natural logarithms

E F F

OC T

Preprer/at -24-CZ EQS No. WBNEEB0028YýAppendix 2 Rev 3Reviewer/Date ZAJý In Sheet 13- of 13

Calculate qualified post-accident life for valves located in lovercompartment of containment:

L2- 26 days (AQS21678/TR Rev. A, Figure 2, page 4-21)

El- 0.94 eV (AQR67368, Appendix B, page B-3).

Ti- 152.50F (tempe rature profile, BQN/WBN Environmental Data Drawing 47E235-45,190OF @ 6 x 103 sec - 150OF @ 30 days/2 + 1150F)

T2-200OF (AQs21678/TR Rev. A, Figure 2, page 4-21)

L2- 26 x 24 - 624 hours

Tl- 152.5-32/1.8 + 273.15 -340.1 0K

T2- 200-32/1.8 + 273.15 -366.50K

.94 1 .... - 1_8.6705 340.1 366.5

Ll 624 eLI

Ll- 6318 hours - 263 days

074144.10

Ow uitj v

Uniit Mt. 1 and 2BQS No. WBNEEB0029TVA M No.

See Appendix 1

DManufact~wer and yo~del No. See Append~ix 1Verification of Table Information (Table See ARnendix

X tTIM- The equipment has been identified as per TVA MD numbterdesignations (such as, Mov, sM r. 4-X Imtion- The location has been identified (such asl, inside primarycontainment, annulus, individually cooled room,~, general spaces,, or areaaffected by HELB outside primary containmient).x 2 m A unique TVA ID numiber has been assigned (such as, l-FSV-68-308).ZMti - A functional description of the comiponent has been given (such as,steam generator blowdown).~ Cntrct No. PMaoufactu rer,& In Hpl D. - The contract number,, manufacturer,,admodel number have been given.X mmoelorAcdn Evrnjnt - All abnormal or accident environmental.conditions applicable to this equipnent have been identified either in tables orXby references to figures fraon tables.X envronmet to hich uaif-ied - The environment to which the equipment has beenqualified is addressed in either the tables or the environmental analysisattached.

.X. equpmeratio an c acy ReqiredadDnntae - The operationand accuracy required and deostrated have been defined.

Quaifid Lfe If pipentig qualified, indicate the qualified life with anumerical entry): 4'0yearsxOaifica~tion Rort and Method - A qualification report and the method ofqualification has been identified on thle Table Input Data Sheet (TIDS).X A I - An environmental analysis has been doneg, attached tothe EXS,, adidpnetly reviewed by the responsible organization.N/A +ulfcto - y Sniar (If applicable) - A justification for qualificationby similarity is attached to the EDS considering all the above factors andreferenced to the appropriate tables.X Oulfcto fSvrlEatCmnns(If applicable) - When an EDS is usedfor more than one item,, a list of all exact compocnents is given as an appendixwith all references to appropriate tables with justification for qualificationccmsidering all the above factors.N/A eimOaifcto (If applicable) - (open item) - Caqrxwmet has beendetermined to be qualified only for a limited interim operation, an NCR hasbeen written, and plan of action has been determined to yield a qualifiedTerm of Interim Qualification_____________________

N/A ~ ~ c& tkjij - (Open item) - (If applicable) - Ccqxonent has beendetermlm to be unqjualified; the following is attached to EDS: NCR number,reao for non-qualification, and justification of continued operation.

E F F E' CT*Due to the extensive changes from Revision ..2, revision bars are not used. -

Preparer/Date4 3za,~ //,/-/0

Revi ewer/D ate .t,927Ay

EQS No. WBNEEB0029Appendix 1 ReSheet I -of -*

Manufacturer ASCO

Component Sole! ioid Valve

Component UNID Model No. Table/Sheet

_______________________________________ ______________________________________ .l -8/r3EB- 1

1-FSV-67-350 206-380-2RU 3 .1--7/WBNEEBOOO5

3.11-87WBNEEBOl3-l -FSV-67-352 206-380-2RU 3 .11-7/WBNEEB0OO5

3.11-81IWNUEEB5014-1-FSV-67-354 206-380-2RU 3 .11-7/WBNEEBOOO5

3 .11-8/W-BN-E-EBO14- -FSV-67-356 206-380-2RU 3 .11-7/WBNEEB0005

3 .l1-8/gENiEEBOU14- -FSV-67-168 206-380-2RU 3 .11-6/WBNEEBOOO6

I-FSV-67-170

1-LSV-3-148

I-LSV-3-1 56

J--A-LSV-3-l 64

IV

IV

IV

IV

IV

IV

VIV

VII

VIII

VIII

VII

Ix

Ix

x

xi

xi

xi

I 206-3 80-2RU

206-381 -3RVU

206-381-3RVU

206-391-3IRVr

I 06-381 -3RV[7

20 -381-3RVU

RB8300C58RU

EB8300C58RU

B830C58RU

BB80 C58RU

3T O5RU

30 B BRU

RTR30lflB8RU-

RT830OB58RU

3.11-3/WBKEEXuu14

-3.11-6/WBWEEB00063 .11-8/WBEBO13 .11-6/WBNEEB00O63 .1l-3/WBNEEBOO3 .11-6/WBNEEB00o6

3.ll-8/WBNEEBOO143.11-6 WBNEEBO143.11-7 T.,TNEEBOOO13 .11-8/WBNEEBOOO83 .11-7/WBNEEBOO0l3 .11-8IWBNEEB0OOB3 .11-7/WBNEEBOOO23 .11-7/WBNEEBo0o83 .11-7/WBNEEBOOO23 .11-8/WBNEEBooo83 .11-6/WBNEEBOOO43 .11-8IWBNEEBOOO83 .11-6/WBNEEB00083 .11-8IWBNEEBOOO83 .11-6/WBNEEBOOO23.*1 1-8/WBNEEB00043.11-76/WBNEEBOOO23.*1 1-6/WBNEEB0004

3.1 1-8/WBNEEB00083.11-6/WBNEEBOOO2

3 .11-8/WBNEEB00053 .11 6/WBNEEBOOO23 .11-8/WBNEEB0OO5

I

1-1-SV--3-172

I-TAV-3-173

2-FSV-67-350

2-FSV-67-352

?-FqV=fi2-354

2-vq3Z--67-356

7-'FqV--67-217

2-F SY-6 7 - 219

2-FSV-67-169_

2 1 9V

2-tSY 3 156-

2-LSV-3-164

1hu 11A- &YmU1 71 - 12

I

VA-

Preparer/Dat ________1__ ;P__2*1___:&

Revi ewer/bate A F 2 -7-E136

Manufacturer AMC

Component. Solex

EQS> No. WBNEEB0029Appendix x1 RevSheet 2 -of T=

ioid Valve

Comiponent UNID Model No. Table/Sheet

3 .11-6/WBNEEBOOO22-LSV-3-171 HT8300B58RU 3 .ll-8/WBNEEBOOO5

3 .11-6/WBNEEBOU0O22-LSV-3-172 HT8300B58RU 3 .1l-8/WBNEEBOOO5

3 .ll-6/WBNEEBOOO22-LSV-3-173 HT8300B58RU 3 .ll-8/WBNEEBOOO5

Preparer/Date ZA,

Reviewer/Date/:ft 4qAA. -% Z-v-j'ViL

EQS No. WBNEEB0029Appendix 2 Rev 3Sheet 1 of 18

UNIT 1 ONLY

1. 1. For solenoid valves:

1-FSV-67-3501-FSV-67-352

ASCO Catalog No. 206-380-2RUASCO Catalog No. 206-380-2RU

2. These solenoid valves are located in the Auxiliary Building (room713/A6). As detailed in EN DES Calculations NEB 840412 219, thesolenoid valves are required to operate for 5 minutes after the startof a LOCA and CVCS, RHR, Auxiliary Feedvater, and Auxiliary Boiler linebreaks and must not fail in a manner detrimental to plant safety for100 days for a LOCA or I month for CVCS, RHR, Auxiliary Feedwater,or Auxiliary Boiler line break.

3. These solenoid valves are subject to LOCA/HELB conditions (Volume 15).They are required to operate in the following environmentl:

Normal Abnormal Accident

Temperature:

Pressure:Relative Humidity:Radiation:

Spray/Flooding:

104 0F

Atm(-)80%1.!5x103 rads(40 yr TID)N/A

110OF

AtmC-)90%N/A

NIA

196 0F1230F (Volume 4)14.4 psia100%lxl0 4 rads (LOCA)

NIA

4. The manufacturer hasenvironment:

tested these solenoid valves to the following

Normal Abnormal Accident

Temperature:Pressure:Relative Humidity:Radiation:Spray/Flooding:

26 80FN/A0-100%50xlO6radsNIA

N/AN/AN/AN/AN/A

346 0F110 psig100%l50xl0 6 radsBoron/NA

1 See WEN Envirorimental Data Drawings 47E235-56 RO and -57 Ri.

E F E T V2

Preparer/Date,ý,L d-& >ŽtaA 2 ,

Rev iewer/ Date ,&l~d g-2Z-7-&ir

EQS No. WBNEEB0029Appendix 2 Rev 3Sheet 2- of 18

UNIT 1 ONLY

11. 1. For solenoid valves:

1-FSV-67-3541-FSV-67-356

ASCO Catalog No. 206-380-2RUASCO Catalog No. 206-380-2RU

2. These solenoid valves are located in the Auxiliary Building (room

737/A5). As detailed in EN DES Calculations NEB 840412 219, the

solenoid valves are required to operate for 5 minutes after the start

of a LOCA and CVCS, RHR, Auxiliary Feedvater, and Auxiliary Boiler line

breaks and must not fail in a manner detrimental to plant safety for

100 days for a LOCA or 1 month for CVCS, RHR, Auxiliary Feedvater,

or Auxiliary Boiler line break.

3. These solenoid valves are subject to LOCA/HELB conditions 2(Volume 14).

They are required to operate in the following environment2 :

Normal Abnormal Accident

Temperature:Pressure:Relative Humidity:Radiation:

Spray/Flooding:

104OFAtm(-)80%3.5xl04 rads(40 yr TID)N/A

110OFAtm(-)90%N/A

192 0F14.4 psia100%IX1O4 rads

N/A

4. The manufacturer hasenvironment:

tested these solenoid valves to the following

Normal Abnormal Accident

Temperature:Pressure:Relative Humidity:Radiation:Spray/Flooding:

26 80FN/A0-100%5OxlO6radsN/A

N/AN/AN/AN/AN/A

346 0F110 psig100%l50xl0 6 radsBoron/NA

2See WIN Enviroanmental Data Drawings 47E235-48 RI and -49 Ri.

Preparer/DateEQS No. WBNEEB0029Appendix 2 Rev 3Sheet 3 of 18

UNIT 1 ONLY

111. 1. For solenoid valves:

1-FSV-67-16 81-FSV-67-170

ASCO Catalog No. 206-380-2RUASCO Catalog No. 206-380-2RU

2. These solenoid valves are located in the Auxiliary Building (room692/Al) general spaces. As detailed in EN DES Calculations NEB 840412219, the solenoid valves are required to operate for 5 minutes afterthe start of a LOCA and CVCS, RIM, Auxiliary Feedwater, and AuxiliaryBoiler line breaks and must not fail in a manner detrimental to plantsafety for 100 days for a LOCA or 1 month for CVCS, RHR, AuxiliaryFeedvater, or Auxiliary Boiler line break.

3. These solenoid valves are subject to LOCA/HELE conditions (Volume 20).They are required to operate in the following envirorment3:

Temperature:

Pressure:Relative Humidity:Radiation:

Spray/Flooding:

Normal

104 0F

Atm(-)80% 2 rd

(40 yr TID)N/A

Abnormal

11 0OF

Atm(-)90%N/A

N/A

Accident

1420 F1230F (Volume 4)14.4 psia100%11x04 rads (LOCA)

N/A

4. The manufacturer hasenvironment:

tested these solenoid valves to the following

Normal Abnormal Accident

Temperature:Pressure:Relative Humidity:Radiation:Spray/Flooding:

26 80FN/A0-100%50xlO6radsNIA

N/AN/AN/AN/ANIA

346 0F110 psig100%l50xl06 radsBoron/NA

3 See WBN Environmental Data Drawings 47E235-62 RO and -65 Ri.

Preparer/Date Xf C-.i,/-z&e-Y

Reviewer/Date ?-z7-JEQS No. WBNEEB0029Appendix 2 Rev 3Sheet 4 of 1

UNIT 1 ONLY

IV. 1. For solenoid valves:

1-LSV-3-1481 -LSV-3-1 56I-LSV-3-1641-LSV-3-17 1

AS COAS COASCOASCO

Catalog No. 206-381-3RVUCatalog No. 206-381-3RVUCatalog No. 206-381-3RVUCatalog No. 206-381-3RVU

2. These solenoid valves are located in the Auxiliary Building (room737/Al). As detailed in EN DES Calculations NEB 840321 220, thesolenoid valves are required to operate 100 days after a LOCA and/orone month after the start of a CVCS, RBR, Auxiliary Feedwater, orAuxiliary Boiler line break.

3. These solenoid valves are subject to LOCA/HELB conditions (Volume 12).They are required to operate in the following environment

4:

Normal Abnormal Accident

Temperature:Pressure:Relative Humidity:Radiation:

Spray/Flooding:

1040 FAtm(-)80%5xl0 2rads(40 yr TID)N/A

110OFAtm(-)90%N/A

N/A

1 29 0F14.4 psia100%lxl04rads (LOCA)

N/A

4. The manufacturer hasenvironment:

tested these solenoid valves to the following

Normal Abnormal Accident

Temperature:Pressure:Relative Humidity:Radiation:

Spray/Flooding:

26 80 FN/A0-100%5OxlO 6rads(40 yr TID)NIA

N/AN/AN/AN/A

N/A

346 0F110 psig100%l50xl06 rads

Boron/NA

4 See WEN Environmental Data Drawings 47E235-46 RO and -47 Ri.

Preparer! Dat e(/•,ZkQ 4 ;6/k

Revijewer/ Date ZZ~ 1 A..7 -- ~

EQS No. WBNEEB0029Appendix 2 Rev 3Sheet 5 of 18

UNIT 1 ONLY

V. 1. For solenoid valves:

1-LSV-3-1721-FSV-3-173

ASCO Catalog No. 206-380-3RVUASCO Catalog No. 206-380-3RVU

2. These solenoid valves are located in the Auxiliary Building (room737/A6) general spaces. As detailed in EN DES Calculations NEB 840321220, these solenoid valves are required to operate for 5 minutes afterthe start of a LOCA and CVCS, RHR, Auxiliary Feedwater, and AuxiliaryBoiler line breaks and must not fail in a manner detrimental to plantsafety for 100 days after a LOCA or 1 month after CVCS, RHR, orAuxiliary Boiler line break.

3. These solenoid valves are subject to LOCA/HELE conditions (Volume 14).They are required to operate in the following environment5:

Normal Abnormal Accident

Temperature:Pressure:Relative Humidity:Radiation:

Spray/Flooding:

1040 FAtm(-)80%lxl06rads(40 yr TID)N/A

110OFAtm(-)90%N/A

NIA

1 92 0F14.4 psia100%lx104 rads (LOCA)

NIA

4. The manufacturer hasenviron~ment:

tested these solenoid valves to the following

Normal Abnormal Accident

Temperature:Pressure:Relative Humidity:Radiation:Spray/Flooding:

26 80FN/A0-100%5OxlO6radsN/A

N/AN/AN/AN/ANIA

346 0F110 psig100%l50xl06 radsBoron/NA

5See WEN Environmental Data Drawings 47E235-80 *Rl and -49 RI1.

* I' *~

Preparer/Date /2ŽIOUA /6ZL /?2Z-5 EQS No. WBNEEB0029Appendix 2 Rev 3

Reviewer/Date Oet& Sheet 6 of 18

VI 1. Qualification Testing:

a. ASCO has tested the 206-380 and 206-381 series solenoid valves to therequirements of IEEE Standard 323-1974 and NUREG-0588. The test criteriaand results are documented in ASCO test report AQS21678/TR, Revision A,including supplement 3. All qualification and tests were performed at testlevels or conditions in excess of known maximum application requirements.These margins are in accordance with the margins suggested by IEEE Standard323-1974.

b. Seven solenoid valve samples representing six generic families of valves,including the 206-380 and 206-381 series, were subjected to sequentialexposures of elevated temperature, radiation, wear aging, seismic

7; simulation, vibration endurance, accident radiation, and a 30-day LOCAsimulation. Baseline functional tests were performed before the start andafter each sequence of the test exposure with the exception of coildielectric and insulation resistance measurements which were taken beforethermal aging, after accident radiation, and after LOCA exposure. Thevalves were energized and deenergized at high and low pressures during thetest phases (except radiation) and valve leakage monitored.

c. Baseline/Functional Test: Baseline/Functional tests consisted ofmeasurement of coil excitation, seat leakage at high and low pressures,noise test, operational test, and external leakage test before and after allphases of type tests. Measurement of insulation resistance and coildielectric test was performed in the as received condition and aftercompletion of accident radiation and LOCA simulation. Valves were energizedand deenergized and their operation monitored during test (exceptradiation).

d. Thermal aging: The valves were subjected to an aging temperature of 2680Ffor a test duration of 12 days. They were cycled (deenergized for fiveminutes and then energized) every six hours.

e. Radiation: The valves were subjected to cobalt 60 (GAMMA) radiation at anexposure rate of less than one megarad per hour. Total integrated dosereceived was 50 megarads.

f. Wear aging: The valves were electrically cycled 40,000 times at maximumpressure differential.

g. Seismic Simulation/Vibration Endurance: The valves were subjected to acombined SSE and fragility test. The input level was 7 g's. The testwas performed with the valves energized and deenergized and with high andlow pressure. The leakage rate was monitored.

h. Accident Radiation: The valves were subjected to cobalt 60 (GAMMA)radiation at an exposure rate of less than one megarad per hour. Valvesreceived an additional accumulated dose of 150 megarads for a totalintegrated dose of 200 megarads received in two stages.

Preparer/Date /2A JZ KI'26-¶ EQS No. WBNEEB0029(Appendix 2 Rev -3

Reviewer/Date ;$/ 2.~92%19C Sheet 7 of 18

i. LOCA Simulation: The valves were subjected to a simulated loss-of-coolantaccident (LOCA) by exposure to steam and to chemical spray for 30 days.LOCA simulation conditions vere as follows:

Temperature - Maximum of 346OF for a total period of six hours followed by astep decrease to 200OF within four days followed by post-DEE conditions of200OF for the remaining 26 days.

Pressure - Maximum of 110 psig for a total period of six hours followed by astep decrease to 10 psig within four days followed by post-DEE conditions of10 psig f or remaining 26 days.

Relative Humidity - All steam environment in excess of 2500F; greater than90% for other conditions.

Chemical Spray - The chemical solution consisted of 3000 ppm boron as boricacid in solution with 0.064 molar sodium thiosulfate buffered with sodiumhydroxide. The chemical solution pH was maintained between 9.5 and 10.5.

j. Results: One of the valves malfunctioned during thermal aging. The valvedeveloped excessive seat leakage both in the energized and deenergizedstate. This was later determined to be caused by dirt in the valve. Thesource of dirt was the iron pipe used in the cylinder port as piping and anadditional length used to simulate an accumulator.

Other than the above malfunction, the valves sucessfully completed thesequential type tests and the baseline/functional tests.

2. Qualified Life - The solenoid valves have a qualified life of 40 years at 104*Fand 40,000 cycles, providing the maintenance schedule outlined in paragraph 4 isfollowed. Open and close completes one cycle. However, due to the self-heatingnature of solenoid valves, the temperature rise associated with a continuouslyenergized solenoid valve must be accounted for in the qualified lifecalculation. There are two areas affected by this heating: (1) the coil seesan increase of 105*C (221*F) above ambient and (2) the elastomeric discs see anincrease of 45*C (1l3*F) above ambient. These temperature increase values comefrom Franklin Research Center's "Test Program and Failure Analysis of Class 1ESolenoid Valves" (NUREG/CR-3424, F-C5569-309/315).

Based on the above information, a separate qualified life must be calculated forboth the coil and the disc. The following quxalified life calculations, whichare based on the Arrhenius equation, are for valves to be used at a normalambient operating temperature of 104*F (40*C):

LI L2e Tj T2J ~

Preparer/Date t/-t 24 /-2~$ EQS No. WBNEEB0029~, Appendix 2 Rev -3

Reviewer/Date 17ze/O"-A--7...~C Sheet 8 of 1,8

COILS

In Franklin Research Center's "Test Program and Failure Analysis of Class 1ESolenoid Valves" (NUREG/CR-3424, F-C5569-309/315), the solenoid coils were aged attwo rates: 150*C (302*F) for 9.3 days (223.2 hours) and 131*C (268*F) for 15.3 days(367.2 hours).

Ll- Qualified life (first aging rate)

L,2 - Accelerated (test) life - 223.2 hours

E - Activation energy - 1.00 eV

K - Boltzmann'sa constant - 8.617 x 10-5 eV/*K

Tj- Qualified temperature (ambient + 105*C) - 145*C

T2- Elevated (test) temperature =1500C + 1050C - 2550C

e - Base of natural logarithms

L1 '- Qualified life (second aging rate)

L2'- 367.2 hours

E -1.00 eV

K - 8.617 x 1i-5 eV/PK

Tl'- 400C + 105*C -145*C

T2 '- 1310C + 105*C -2360C

e - Base of natural logarithms

Ll (total) -Total qualified life -Ll + Ll' -14.217 years

Preparer/Date .ý XeA EQS No. WBNEEB0029Appendix 2 Rev 3

Rev iewer/ Date ZY/. .A' 4 n ?---v Sheet 9 of .18L.

DISCS

In ASCO test report AQS-2l678/TR, supplement 3, the entire valve was aged at 131*C(268*F) for 12 days (288 hours).

Ll- Qualified life

L2-Accelerated (test) life - 288 hours

E - Activation energy - .94 eV

K - Boltzmann'sa constant - 8.617 x 1O-5 eV/*K

Tl-Qualified temperature - 104*F

T2- Elevated (test) temperature - 131 0C + 450C - 1760C

e - Base of natural logarithms

Ll- 15.811 years

3. Installation - Valves should be installed such that the axis of the coil remainsin the vertical and upright position.

4. Maintenance Requirements - The qualified life depends on the valve being cycledat least every 16-18 months to ensure proper opening and closing. Coils shallbe replaced every 14.217 years and elastomeric components shall be replacedevery 15.811 years when solenoid valves are subjected to a normal operatingambient temperature of 104*F. In addition, ASCO recommends that when thesolenoid valves reach 20,000 cyclesa, that they be rebuilt using the applicablespare parts kit and spare coil kit6 .

5. Valves are qualified per IEEE Standard 323-1974, IEEE Standard 382-1972, IEEEStandard 344-1975, and applicable portions of NUREG-0588 for the environment inwhich they are requied to operate, providing the maintenance schedule inparagraph 4 above is followed. By mathematical analysis, the qualified post-DBEoperating time can be extended to 224 days for the valves under Heading 1, 283days for the valves under Heading 11, 1.6 years for the valves under Heading111, 5.32 years for the valves under Heading IV, and 283 days for the valvesunder Heading V.

6ASCO Test Report AQR67368/Rev. 0, Appendix C, Page C-2.

Preparer/Date i/\jtA+. •Z4 2 4 .Reviewer/Date . 4 Z. 27L. Frf

EQS No. WBNEEB0029Appendix 2 Rev 3Sheet 10 of 18

Calculations -Post Accident Life

Calculations are based on the Arrhenius equation which states:

Ll L2 e2

Where

Ll- Qualified life

L2- Accelerated (test) life

El- Worst case activation energy, eV

K - Boltzmann's constant, 8.617 x 10-5 eV/'OK

Ti-Qualified temperature, absolute

T2- Elevated (test) temperature, absolute

e - Base of natural logarithms

The following calculations are for the qualified post-accident life forsolenoid valves listed under Heading I and located in the Auxiliary Building(Room 713/A6):

L2-26 days (AQS21678/TR Rev. A, figure 2, page 4-21) - 624 hours

Ei-0.94 eV (AQR67368, Appendix B, page B-3)

Ti- 155.50F (volume 15 RHR temperature profile, WBN environmental datadrawing 47E235-57, [1960F @625 sec - 115OF @50 sec]/2+1150F).

T2- 200OF (AQS21678/TR Rev. A, figure 2, page 4-21)

Tj- (155.5-32)/1.8+273.15 - 341.76 O~K

T2- (200-32)/1.8+273.15 -366.5 0K

Ll = 6 24 e [.617xlo-5 34.7 366.5 .613 years -224 d~ays

________________o________:21_____ EQS No. WBNEEB0029

ReviwerDate4 IAppendix 2 Rev 183Reviwer/ate 'A . ~ -2-7i$~ Sheet 11 of 1

The following calculations are for the qualified post-accident life forsolenoid valves listed under Heading II and located in the AuxiliaryBuilding (Room 713/A6):

L2 -26 days (AQS21678/TR Rev. A, figure 2, page 4-21) - 624 hours

El- 0.94 eV (AQR67368, Appendix B, page B-3)

Ti- 151OF (volume 14 RHR temperature profile, WBN environmental data

drawing 47E235-49, 11920F @800 sec - 110OF @50 sec]12+1100F).

T2- 200OF (AQS21678/TR Rev. A, figure 2, page 4-21)

Ti- (151-32)/1.8+273.15 -339.26 0K

T2= (200-32)/1.8+273.15 -366 .50K

[.94 ( 1 1____

Lj - 624 e [.1I- 33266.5.766 years - 283 days

The following calculations are for the qualified post-accident life forsolenoid valves listed under Heading III and located in the Auxiliary Building (Room713/A6):

L2- 26 days (AQS21678/TR Rev. A, figure 2, page 4-21) -624 hours

El- 0.94 eV (AQR67368, Appendix B, page B-3)

Ti- 137.50F (volume 20 AFW temperature profile, WBN environmental data

drawing 47E235-65, [1420F @25 sec - 1330F @160 sec]/2+1330F).

T2-200OF (AQS21678/TR Rev. A, figure 2, page 4-21)

Tj- (137 .5-32)/1.8+273.15 - 331.760K

T2- (200-32)/1.8+273.15 -366.50K

.94 ( 1 1____

[8.617x10-5 331.76 366.5 ]Ll -624 e -1.6 years

Preparer/Date 2~J

Rev iewer/ Date

EQS No. WBNEEB0029Appendix 2 Rev -3Sheet 12 of 18

The followi.ng calculations are for the qualified post-accident life forsolenoid valves listed under Heading IV and located in the AuxiliaryBuilding (Room 713/A6):

L2- 26 days (AQS21678/TR Rev. A, figure 2, page 4-21) - 624 hours

El- 0.94 eV (AQR67368, Appendix B, page B-3)

Ti-116.5 0F (volume 12 RHR temperature profile, WEN environmental data

drawing 47E235-47, [1290F @850 sec - 104 0F @50 sec]/2+1040F).

T2- 200OF (AQS21678/TR Rev. A, figure 2, page 4-21)

Ti- (116.5-32)/1.8+273.15 - 320.10K

T2 - (200-32)/1.8+273.15 -366.5 0K

F .94 1 - 1

Ll- 2 eI8.617x10-5 320.76 366.5 5.2yer

The following calculations are for the qualified post-accident life forsolenoid valves listed under Heading V and located in the AuxiliaryBuilding (Room 713/A6):

L2- 26 days (AQS21678/TR Rev. A, figure 2, page 4-21) -624 hours

El-0.94 eV (AQR67368, Appendix B, page B-3)

Ti-151OF (volume 14 RHR temperature profile, WBN environmental datadrawing 47E235-57, [1920F @800 sec - 110OF @50 sec]/2+1100F).

T2-200OF (AQS21678/TR Rev. A, figure 2, page 4-21)

Ti- (151-32)/i1.8+273.15 -339.26 0K

T2- (200-32)/1.8+273.15 -366.50K

.94 ( 1 - 1

-24e 8.617x10-5 339.26 366.5 -. 7 er

-6797.8 hours - 283 days

034143 .07

Preparer /Date/?L EQS No. WBNEEB0029Appendixý 2 "ReV.3

Reviewer/Date , / t ai-9.7.2ISheet J13 of 1

'UNIT 2 ONLY

VII. 1. 4'r 'b-lenoid valves

2-TSV-67-350 ASCO M4odel RB8300C58RU2-FSV-67-352

2. Solenoid valves are located In the Auxiliary Building (713/A6 and A19) In individually cooled rooms. The solenoid valvesare required to operate for five minutes after the start of anaccident and not to fail detrimental to plant safety for periodsof up to 100 days thereafter (depending on which accident occurs).per EN DES Calculation NEB 830204 234.

3. Solenoid valves are subject to LOCA/HELB conditions. They arerequired to operate in the following environment :

Normal Abnormal

Temperature: 104*F 1980FPressure: Atm AtmRelative Humidity: 80%2 100%2Radiation: ill: 1.352 x 10 rads (1 z 10 rads

U2: 3.504 x 10 4 rads(40 years TIh)

Spray/Flooding: N/A N/A

4. The manufacturer's specifications for the solenoid valves are:

Temperature: 240*FPressure: AtMRelative Humidity: NIMA 15 EnclosureRadiation: 4 z 10 rads

5. See generic position 4.1.5 for radiation. See genericposition 4.1.8 for relative humidity.

6. The normal and accident conditions with exception of accidenttemperature, are within the manufacturer's specifications.The solenoid valves during accident conditions could be exposedto temperatures of 198*F which Is such higher than the manufacturer'sspecified maximum ambient temperature of 140*F.

7. The above information indicates that the solenoid valves arenot qualified for their accident environment as required byUtUR.EG-0588. Therefore, TVA will replace these devices per 10CFR5OJO9,as determined by NCR WBNEEB8123.

7 a QN/'-IN Etlrumaintal Data Drawings 47E235-39, -60.

Preparer/Date

Reviewer/Date zfz- 2s?- UNIT 2 ONLY

VIII 1.- For-aglenoid valvesV

2-YOJV67-3542-YSV-67-356

EQS No. WBhNEEB0029Append ix 2 jT?1e~--Sheet 14 of 18.

ASCO Model 3BS300C58RUIt

2. Solenoid valves are located In the Auxiliary Building (737/AS and A9)In individually cooled rooms. The solenoid valves are required tooperate for five minutes after the start of an accident and not to faildetrimental to plant safety for periods of up to 100 days thereafter(depending on which accident occurs), per EN DES CalculationNEB 830204 234.

3. Solenoid valves are subject to LOCA/HELE conditigrns. They arerequired to operate In the following environment :

Normal Accident

Temperature:Pressure:Relative Humidity:Radiation:

Spray/Flooding:

104*FAtm802

Ul: 3.5 X 10 2radsU2: 3.5 z l0 rads

(40 years TID)NI/A

196*FAtm100%2

A1 x 10 ra~ds

N/A

4. The manufacturer's specifications for the solenoid valves are:

Temperature:Pressure:Relative Humidity:Radiation:

140*FAt.IND(A 1 Enclosure4 X lo5rads

5. See generic position 4.1.5 for radiation. See generic position4.1.8 for relative humidity.

6. The normal and accident conditions with exception of accidenttemperature, are within the manufacturer's specifications. Thesolenoid valves during accident conditions could be exposed totemperatures of 196*F which Is such higher than the manufacturer'sspecified maximum ambient temperature of 240*F.

7. The above information Indicates that the solenoid valves are notqualified for their accident environment as required by NUR.EG-0588.Therefore, TVJA will replace these devices per IOCFRL5O.49,asdetermined by NCR WENEEB8123.

Per SOUD Zvirv=enta Data Dravings 47E235-31, -~52.

Prep arer /Datez•

Reviewer/ Date

IX. . For Oplenoid valves

2-FSV-67-2172-TSV-61-*219

EQS No. WBNEEBOO29Appendix 2 Rev. 3Sheet 15. ot -1,

ASCO Model HB830OC58RU

2. Solenoid valves are located in the Auxiliary Building (713 Al)

In individually cooled rooms. The solenoid valves are required tooperate for five minutes after the start of an accident and not tofail detrimental to plant safety for periods of up to 100 daysthereafter (depending on which accident occurs), per EN DES CalculationWEB 830204 234.

3. Solenoid valves are subject to LWcA/ELB conditions. They are requiredto operate In the following environment

9:,

Normal Accident

Temperature:Pressure:Relative Humidity:Radiation:Spray/Flooding:

104*F 213"FAtm Atm

5 10 rads(40 yr TID) -Cl x104zfads

NIA N/A

4. The manufacturer's specifications for the solenoid valves are:

Temperature:Pressure:Relative Humidity:Radiation:

240OFAtMND4A 2l5 Enclosure4 z 10 rads

5. See generic position 4.1.5 for radiation. See generic position4.1.8 for relative humidity.

6. The normal and accident conditions to which the solenoid valves areeaxposed are within the manufacturer's specifications for thesedevices.

7. The above Information shows that the solenoid valves will functionproperly as required and are therefore qualified for an Interim

period. However, due to lack of documentation required by NUR.EG-0588,

TVA will replace these devices per lOCFR50.49 ,as determinedby NCR WBNEE38l23.

9 Per SQN/WBN Environmental Data Drawings 471!235-55, -57. EF

P rep arer/ D a U ,"/,/ , / 21,EQS No. VBNEEBOO29

Reviewer/DateAyni 2Rv7

Shet 16 of 18UNIT 2 ONLY

2. . For solenoid valves

2-?jV-67-1682-FSV-67-270

ASCO Model ITS30OB58RU

2. Solenoid valves are located In the Auxiliary Building (692 Al)general spaces. The solenoid valves are required to operate for

five minutes after the start of an accident and not to fail detrimentalto plant safety for periods of up to 100 days thereafter (depending

on which accident occurs). per EN DES Calculation NEB, 830204 234.

3. Solenoid valves are subject to LOCA/ELE conditions.

required to operate In the following environment19

Normal

They are

Accident

Temperature:Pressure:Relative Humidity:Radiation:Spray/Flooding:

104FP 143*FAtm Atm

5 x 10racis (40 yr TI)C 1 z 10 rads

N/A N/A

4. The manufacturer's specifications for the solenoid valves are:.

Temperature:Pressure:Relative Humidity:Radiation:

125OFAtMNDiA 5 Enclosure4 Xl0 rads .

5. See generic position 4.1.5 for radiation. See generic Position4.1.8 for relative humidity.

6. The normal and accident conditions with exception of accident

temperature, are within the manufacturer's specifications. 'The

solenoid valves during accident conditions could be exposed to

temperatures of 143*F which is much higher than the manufacturer'sspecified maxim= m ibient temperature of 125*F.

7. The above Information Indicates that the solenoid valves are not

qualified for their accident environment as required by NUREG-0588.

Therefore, TVA will replace these devices Tper IOCTR3O .49 9asdetermined by NCR WBNEEB8l23.

1 0 Per SQN/WBN Environmental Data Drawings 47E235-65, -68 for I-PSV-67-168

and -170; 47E235-65, .-67 for 2-TSV-67-168 and .170.

III

Preparer /Date ____________ QS No. WBNEEB0029Appendix 2 Riev. 3

Reviewr/Dat Sheet 17o1 - 18UNIT 2 ONLY

1 ~. Fo~r 'Oplanoid valves

2-Li-3 248 ASCO Model BT8300B58RU2-LSV-3-156 f

2-LSV-3-164 f

2-LSV-3-171

2. Solenoid valves are located In the Auxiliary Building (737 Al)general spaces. The solenoid valves are required to operate forperiods of up to 100 days (depending on vhich accident occurs)after the start of an accident, per EN DES Calculation NEB 830204 234.

3. Solenoi d valves are subject to LOCA/HELB conditions. They arerequired to operate In the following environaentlL.

Normal Accident

Temperature: 104*F 129*FPressure: Atm AtmRelative Humidity: 802 2100%2Radiation: 5 x 0rads 'Cl z l0 rids

(40 years TID)Spray/Flooding: W/A N/A

4. The manufacturer's specifications for the solenoid valves are:

Temperature: 2.251FPressure: AtmRelative Humidity: NEDiA 1 5EnclosureRadiation: 4 x 10 rads

5. See generic position 4.1.5 for radiation. See generic position4.1.8 for relative humidity.

6. The maximum normal operating temperature Is 104*F. During a HELBthe temperature will rise to 129*F within 650 seconds and thendecrease linearly to the maximum normal temperature within 24 hours.The VF temperature rise above the manufacturer's specified maximumabient temperature of l25*F will not affect the operation of the

solenoid valves.

7. The above Information shows that the solenoid valves will funmctionproperly as required and are therefore qualified for an Interimperiod. However, due to lack of documentation required by NUREG-0588,TVA will replaice these devices per loCnsO.49 ,as determined byZCR VINE 8123.-

-

11a SCQfJVBN Environment&al Data Drawings 47E235-49, -50.

Preparer/Date /Ž 1A4.., z-1 -sReviewer/Date e5,4 4. % c).z?-

" ' UNIT 2ONLY

XII. 1. For solenoid valves:

2-LSV-3!1 722-LIV-3-173

EQS No. VBNEEB0029Appendix 2 Rev.Sheet i17of 18

ASCO MIodel ITS300358RD

2. Solenoid valves are located In the Auxiliary Building (737/A6 andAID) general spaces. The solenoid valves are required to operatefor five minutes after the start of an accident and not to faildetrimental to plant safety for periods of up to 100 days thereafter(depending an iihich accident occurs), per EN DES CalculationNEB 830204 234.

3. Solenoid valves are subject to LOCA/ELS conditions. They are requiredto operate in the following environnenJ2:

Normal Accident

Temperature:Pressure:Relative Humidity:Radiation:

Spray/Flooding:

I04*FAt.80%2.5 z 105rads(10 years TID)N/A

1960FAtz1002(1 x l0 rads

N/A

4. The manufacturer 's specifications for the solenoid valves are:

Temperature:Pressure:Relative Humidity:Radiation:

125*FAmuNEHA 1 5Enclosure4 X 10 rads

5. See generic position 4.1.5 for radiation. See generic position4.1.8 for relative humidity.

6. The normal and accident conditions with exception of accidenttemperature, are within the manufacturer's specifications. Thesolenoid valves during accident conditions could be exposed totemperatures of 196"F which Insmuch higher than the manufacturer'sspecified maximum ambient temperature of 125*F.

7. The above :information Indicates that the solenoid valves are notqualified for their accident environment as required by NUR.G-058B.Therefore, TVA will -replace theme devices per 1OCFR50.49 gasdetermined by NCR WBNEEB8l23.

12PrSQN/1W3N Environmental Data Drawings 47E235-83, -52.

F 7:11K, K

I

Preparer/Date . f1^ 1 EQS No. WBNEEB00291, Appendix 3 Rev 3

Reviewer/Date ___-2-4F-Z__________-_ Sheet 1- of 1

The devices listed below require sealing of the conduit entrance.

Qualification of the conduit seals is documented in the referenced EQS.

Component UNID Q

1 -FSV-67 -354 WEN EEB-CSC-l, WBN EEB-CON-1

1 -FSV-67 -356 .WBN EEB-CSC--1, WEN EEB-CON-1

r0,14143,0f7

I-- I Unt No. 1 and 2Reviion 1 2 3 ES No. WBNEEBOO3O

e 44- TVA M No.Preprer/ateSee Appendix 1

Revi~ewerA~ate __

Mmnufactkrer* and moidel No. See Appendix 1Verification of 1*ble Information (Table See Appendix 1

-- Wuipimt Tvce - The equipm~ent has been identified as per TVA Mh numberdesignations (such as,, NOV, SOV).

X- to - The location has been identified (such as, inside primarycontainmient, annulus,, individually cooled rooms,, general spaces, or areaaffected by HELB outside primary containment).

QxX&=t- A unique TVA ID numb~er has been assigned (such as, l-FSV-68-308).- ~ ig A functional description of the component has been given (such as,,

semgenerator blowdown).X Conract No.. Manufacturer. and Model No. - The contract numb~er,, manufacturer,,

and model number have been given.XANorml or Accident FMvironment - All abnormal or accident environmental

conditions applicable to this equipmient have been identified either in tables orby references to figures from tables.

__ Eivironimt to Which qualified - The environment to which the equipmnent has beenqualified is addressed in either the tables or the environmental analysisattached.LXg aLr- Acategory of a,. b,, c,, or dhas been defined for theequipment.

-2L Oeration and Accuracy Heqired and Demornstrated - The operationand accuracy required and demonstrated have been defined.

pualification Status Icheck if a~licable. N& if not)Q~liied ife(If equipment is qualified, indicate the qualified life with a

numerical entry): 1.4-y ars.x Oualification RerIot and Metk~ - A qualification report and the method of

qualification has been identified on the Table Input Data Sheet (TIDS).X nimma A~nalyis - An environmental analysis has been done, attached toXthe EQSP and independently reviewed by the responsible organization.

Oualificatimr by Similarity (if applicable) - A justification for qualificationby similarity is attached to the EQS considering all the above factors andreferenced to the appropriate tables.

-A Qalification of Several Exact Con~ponets (If applicable) - When an EDS is usedfor more than one item,, a list of all exact ccziponents is given as an appehdixwith all references to appropriate tables with justification for qualificationconsidering all the above factors.

1A heriiu Qualif ication (If applicable) - (Open item) - C~omr~onet has beendetermined to be qualified only for a limited interim operation, an NCR hasbeen written,, and plan of action has been determined to yield a qualified

Tftm of Interim Qualification _____________________

NA CRNo.RX0uafl C=Mmtn - (Open item) - (If applicable) - CUzponent has beendetermined to be unqualified; the following is attached to EDS: NM numbT*er,reason for nom-qualif icationj, and justif ication of continued operation.NM No.__ _ _ _

Preparer/Date &Oitd

Revi ewer/Date f/f.

I LIJ

I.

II.

EQS No. WBNEEB0030Appendix 1 Rev 3Sheet 1 Of 1

Fluid Components, Inc. (FCI)

Flow Switch

Manuf acturer

Component

Component UNID Model No. Table/Sheet

I-PDIS-1-17 NA NA

2-PDIS-1-17 NA NA

1-PDIS-1-18 RA NA

2-PDIS-1-18 NA NA

O-FS-65-25A/B, B/A 12-64 3.11-7/WBNEEB0001

O-FS-65-31A/B, B/A 12-64 3.11-7/WBNEEB00O1

O-FS-65-44A/B, B/A 12-64 3.11-7/W'BNEEBOOO1

O-FS-65-55A/B, B/A 12-64 3.11-7/WBNEEB0001

Preparer/Date ;ez &- x, .ed4 EQS No. WBNEEB0030

AAppendix 2 Rev 3Reviewer/Date A 27" he f 2

. 1.,27PDIS-l-17 and 1,2-PDIS-1-18 have been physically removed from the Rsystem per ECNs 3596 (unit 1) and 3604 (unit 2), therefore, there are jRno d§.vices to qualify. -

I. The'switches listed in Appendix I, Heading II, are Fluid Components,Incorporated, (FCI) Model 12-64. FCI has qualified these sensorsto the requirements delineated in IEEE Standard 323-1974. Testprocedures and results are documented in FCI Report No. 708053 dated 8-28-80.

The switches are located in the Auxiliary Building at elevation 757,Room A16. As detailed in EN DES Calculations, NEB 840517 218, for theEmergency Gas Treatment System, these sensors are required to operatefor 100 days after the start of a LOCA.

Operating Environment

These switches are required to operate in the following environment1 :

Normal Abnormal Accident

Temperature: 1040F 110OF HOO0FPressure: Atm N/A AtmRelative Humidity: 80% 90% N/ARadiation: l.0x106 rads N/A 4.2x10 6 TID2

(40 yrs TID)Spray/Flooding N/A N/A N/A

Qualification by Similarity

Two models of FCI switches were used in the qualification tests, Model12-64 and model FR72. Before testing, these models were analyzed todetermine which model would be more severely affected by a particulartest. The weaker model was tested and the results were consideredapplicable to the other model as well. For a detailed summary of thismethodology, see Wyle Laboratories' Test Report No. 708053 dated 8-28-80.

Radiation

The switches were irradiated to 5x106 rads total dose and successfullyoperated after irradiation.

lSee WBN Environmental Data Drawing 47E235-78 RI for DBE temperature andpressure profiles.

2This radiation dose was calculated by the responsible TVA organization forthe specific area in which the devices are located.

Preparer/Date i

Reviewer/Date 7 z4

EQS No. WBNEEB0030Appendix 21 Rev 3....Sheet 2 of 2

Therxial A~in&/DBE and PostDB

The LOCA temperature effect is no more severe than the abnormal temperature

conditions, see WBN Environmental Data Drawing 47E235-78 RI. This being the

case, the thermal aging portion of the qualification test fully envelopes

the LOCA and POST-LOCA temperature conditions, and will be used to establish

POST-LOCA life as well as qualified life.

The flow switches were soaked at 2l2OF (1000C) for 14 days. They are

required to operate for 100 days following a LOCA, therefore, part of the

test duration must be assigned to account for POST-LOCA life. Using the

Arrhenius Equation below and the following parameters:

1) qualified life of 100 days,0

2) qualified temperature of 110 F,3) test temperature of 212 0F, and4) activation energy of 1eV (per FCI letter to TVA dated 6/1/84

[EEB 840608 001]).

9.165 hours of the test must be used to encompass the POST-LOCA requirement.

This leaves 326 .835 hours of the test with which to determine qualifiedlife. The Arrhenius Equation yields a qualified life of 14.435 years,considering 326.835 hours of test life at 212 0 F.

Arrhenius Equation:

el-L2 eKl 2

where:

Ll-Qualified lifeL2- Accelerated (test) life

E - Worst-case activation energyI eVK - Boltzmann' s constant, 8.617 x 10-5 eV/OK

TI-Qualified temperature, absoluteT2- Elevated (test) temperature, absolute

e - Base of natural logarithms

E F F[

Reference: EPRI, NP-1558, Research Project 890-1, dated September 1980.

Summary

Considering the information presented above, these switches are qualified.for applicable parts of NUREG-0588 for the environment they will operate inand are also qualified to operate for 100 days following the start of a LOCA.

034154.01

Unit No. 1land 2Reison1 2* EDS No WBNEEBOO3

Prepa~rer/A~te 14~~See Appendix 1

Reviewer/bate 34).

ME~N EDUITM QUALIcA'O siT (MS)

Manufactfirer' and Ylodel No. SOR, Incorporated, Model 2O1TA-B125-JJTTX6Verification of Tdabe Information (Table See Appendix 1

JL MA~t-Z=- The equipment has been identified as per TVA ID numberdesignations (such as, wvI, Woy.

... LJAt&iU - The location has been identified (such as, inside primarycontainment,, annulus, individually cooled room, general spaces,, or areaaffected by HELB outside primary containment).

x Dp~ - A unique TVA ID number has been assigned (such as, l-FSV-68-308).-a- Lu~tim - A functional description of the comp~onent has been given (such as,

stemo generator blowdon)._Z Q=nract No.. ManufactUrer. and Model No. - The contract number,, manufacturer,,

and model number have been given.-2 Ahborma or Accident Eaviroment - All abnormal or accident environmental

conditions applicable to this equipment have been identified either in tables orby references to figures frorn tables.

--x Bivironmernt to Which Qualified - The environment to which the equipm~ent has beenqualified is addressed in either the tables or the environmental analysisattached.

_y, =e - A category of a, b, c,. or d has been defined for the40 equipment.

2L~. 99eratigo and Accracy Reqired and Demnrgntrated - The operationand accuracy required and demonstrated have been defined.

Oualification Status (check if applicable. M~ if not)Oaified Life (If r1iTernt is qualified, indicate the qualified life with a

X numerical entry): ?asX ~valifiction Reprt And Netltd - A qualification report and the method of

qualification has been identified on the Table Input Data Sheet (TMnS).L.x. Mmr~ a AnLyi - An environmental analysis has been done, attached to

the BUS, and independently reviewed by the responsible organization.ULA ~.ificatian by SinmiALWrt (if applicable) - A justification for qualification

by simiilarity is attached to the EUS considering all the above factors andreferenced to the appropriate tables.

-x Oualification of Several Exact Qzn~onnts (if applicable) - When an !DS is usedfor more than one item, a list of all exact components is given as an appendixw3ith all references to appropriate tables with justification for qualificationConsidering all the above factors.

--n Thtriin Qualification (if applicable) - (Open item) - Component has beendetermined to be qualified only for a limited interim operation, an NCR hasbeen written,. and plan of action has been determined to yield a qualified

21trm of Interim Qualification

N/A DoziWC~~ - (Open item) - (if applicable) - Component has beendeterbined to be urqualified; the following is attached to BDS: NCR number,.rea for non-qualif ication, and justification of continued operation.

*Due to extensive changes from R1, Revision bars are not used. 4

Preparer/Date ~

Reviewer/Date ! 7,2.7--Zc(

EQS No. WBNEEB0033Appendi x-1 T eSheet 1 -of -I

Manufatturer SOR, Incorporated and Honeywell

U.1~Temperature Switch

Com~ponent IJNID Model No. Table/Sheet

3 .1l-8/WBNEEBOOO9I -TS-30-194 2O1TA-B125-JJTTX6 3 .ll-7/WBNEEBOOO4

3 .1l-8/WBNEEB0OO92-TS-30-194 T675A 3 .ll-7/WBNEEBOOO4

3 .11-8/WBNEEBOOO91-TS-30-195 2OLTA-B125-JJTTX6 3 .l1-7/WBNEEBOOO4

3 .ll-8/WBNEEBOOO92-TS-30-195 T675A 3 .ll-7/WBNEEBOOO4

3 .ll-B/WBNEEB0009I -TS-30-196 2OlTA-B125-JJTTX6 3.l1-7/WBNEEBOOO5

3 .1l-8/WBNEEB00O92-TS-30-196 T675A 3 .ll-7/WBNEEBOOO5

3 .11-8/WBNEEB00O9

1-TS-30-197 2O1TA-B125-JJTTX6 3 .ll-7/WBNEEBOOO53 .11-8/WBNEEBOU09

2-TS-30-197 T675A 3 .1l-7/WBNEEBOOO5

Component

Preparer/Date f tws/-1S

Reviewer/Date AZVZAe.. ~2.-~

EQS No. WBNEEB0033Appendix 2 Rev 2Sheet 1 of 5

UNIT 1 ONLY

I. The temperature switches in Appendix 1 listed under heading I are SOR,Inc. 20l-iTA-B125-JJTT6. They are located in the Auxiliary Buildingelevation 737 (Rooms A5 and A9). As detailed in EN DES Calculation NEB840213 218 for the Containment Ventilation System, these switches arerequired to operate 100 days after the start of a LOCA and for one monthafter the start of an RHR, CVCS, Auxiliary Boiler, or Auxiliary Feedwaterline break outside of containment.

The switches are subject to HELB and LOCA conditions (Volume 14).required to operate in the following environmentl:

Normal1 Abnormal

They are

Accident

Temperature:Pressure:Relative Humidity:Radiation:

Spray/Flooding:

104 0FAtm(-)80%3.5x104 rads(40 yr TID)N/A

11 00FAtm( -)90%NIA

192 0FAtm.100%1xI04 rads

NIA

II. The temperature switches in Appendix 1 listed under heading II are SOR,Inc. 2OlTA-B125-JJTTX6. They are located in the Auxiliary Buildingelevation 713 (Rooms A6 and A19). As detailed in EN DES Calculation NEB840213 218 for the Containment Ventilation System, these switches arerequired to operate 100 days after the start of a LOCA and for one monthafter the start of an RER, CVCS, Auxiliary Boiler, or Auxiliary Feedwaterline break outside of containment.

The switches are subject to HULB and LOCA conditionsrequired to operate in the following environment2:

Normal Abnormal

(Volume 15).

Accident

Temperature:Pressure:Relative Humidity:Radiation:

Spray/Flooding:

104 0FAtm(-)80%l.75x103 rads(40 yr TID)NIA

110OFAtm(-)90%N/A

1 92 0FAtm100%lxl0 4 rads

lSee WBN Environmental Data Drawings 47E235-48R1 and -49R.1.

2See WEN Environmental Data Drawings 47E235-56R1 and -57R0.

i FFCJ::

They are

Preparer/Date 4f20aau0-;- EQS No. WBNEEB0033/Appendix 2 Rev -2

Reviewer/Date A.04.u Sheet 2 of 5j

SOR, Int., through testing done by Acton Environmental Testing Corporation(AETC) has qualified the switches covered under headings I and II ofAppendix'l by testing to the requirements delineated in IEEE Standard 323-1974. Test procedures and results are documented in AETC reports 17344-82N-C, Rev. 1 and 18441-83N, Rev, 1, which is an addendum to 17344-82N-D, Rev.1. All qualification tests were performed at test levels or conditions inexcess of known maximum application requirements. Margins were inaccordance with those suggested by IEEE Standard 323-1974.

In section 5.2 of report 18441-83N, Rev. 1, AETC outlines the basis onwhich the results of Class 1E environmental qualification testing of anSOR, Inc., model 12TA-B4-NX-ClA-JJTTX6 pressure switch, previously reportedin AITC test report No. 17344-82N-C, Rev. 1 extend and apply to the model2OITA-B125-JJ temperature switch. The extension of the previous pressureswitch qualification testing is founded on the following facts:

A. The referenced temperature switch utilizes a generically identicalswitch housing.

B. The internal switch mechanism utilizes both materials/componentsidentical to the similar pressure switch.

C. All pertinent, age-sensitive materials have been demonstrated topossess a service life of at least 20 years, within a generic-levelenvironment, i.e.: (1) ambient service temperature of 1600F, (2) aswitch life of 33,000 operations, minimum at 120V ac/5A, resistive(3) a 40-year, plus accident, radiation exposure of 2.2xl08rads/gamma (TID). NOTE: This capability is reduced to 3.3x107

rads/gamma for the temperature sensing bulb, per section 5.1 of AETCreport No. 18441-83N.

D. As evidenced by the manufacturer's data presented in Appendix E, theFreon-12 charge material is not subject to significant thermaldegradation during its expected service life when operated within therated temperature range of model 2OlTA-B125-JJ temperature switch.

E. The switch was thermally aged at two rates which consisted of aninitial 100 hour period at 150*C (3020F) followed by a 177.7 hourperiod at 121.1*C (250*F). The 277.7 hour (total, including 10%margin) aging period yielded a qualified life of 22.3 years at anambient temperature of 150*F.

F. The switch was mechanically aged at 33,000 cycles; each "cycle" beingdefined as normally open contacts of switches making and breaking toconstitute one cycle.

G. Per AETC test report No. 18441-83N, Section 4.0, and per AETC testreport No. 18577-83N, the identical switch mechanism utilized in themodel 201TA-B125-JJ temperature switch was demonstrated to retainoperability during both a simulated 110-day design annacid~n (-DBk>-)and a simulated HELB test. E F F F C.T '

D A~

Preparer/Date i e~$72~i

Reviewer/Date Od414'P- 7 7 S

EQS No. WBNEEB0033Appendix 2 Rev 2Sheet 3 of 5..

The manufacturer has tested these switches in the following environmient:

Normal1

Temperature:Pressure:Relative Humidity:Radiation:

1600FAtm

2.2xl08 rads (totalintegrated dose)

The equipment was subjected to a LOCA/MSLB simulation test. The transientportion of the test was repeated twice as required by IEEE Standard323-1974. The test conditions enveloped the requirements of Figure 1,Appendix 3.

The post-LOCA life requirement can be extrapolatedtest using the Arrhenius Equation, which states:

Ll- L2 e

from the actual 30-day

[l"K T- T2-1

Where

Ll-Qualified life

L2- Accelerated (test) life

E ý Worst case activation energy, eV

YK Boltzmann's constant, 8.617 x 10-5 eV/OK r !7

T- Qualified temperature, absolute

T2 Elevated (test) temperature, absolute

e -Base of natural logarithms

Reference: EPRI, NP-1558, Research Project 890-1, dated September 1980.

Using the portion of the temperature versus time profile (shown in Figure1) that extends from 2600F at 5 days to 260OF at 30 days, gives 25 days ata T2 of 260 0F. Using a conservative value of 110OF (abnormal) for T1 and1.04 eV as a conservative value for E, 193.79 years can be derived from theArrhenius Equation. This post-LOCA life of 193.79 years exceeds the onemonth accident operating requirement.

The qualified life for aging is fully demonstrated under the post-LOCA lifedescribed above and the 193.79 years exceeds the required 4O-year plantlife.

Accident

4300OF80 psig100%

Preparer/Date $

Reviewer/Date 2,7 '~ ?IV/

EQS No. WBNEEB0033Appendix 2 Rev 2Sheet 4 of 5

UNIT 2 ONLY

I. The temlieurature switches in Appendix 1 listed under heading I are Honeywellmodel T675A. They are located in the Auxiliary Building elevation 737(Rooms A5 and A9). As detailed in EN DES Calculation NEB 840213 218 forthe Containment Ventilation System, these switches are required to operate100 days after the start of a LOCA and for one month after the start of anRHR, CVCS, Auxiliary Boiler, or Auxiliary Feedwater line break outside ofcontainment.

The switches are subject to HELB and LOCA conditionsrequired to operate in the following environment':

Normal1 Abnormal

(Volume 14).

Accident

Temperature:Pressure:Relative Humidity:Radiation:

Spray/Flooding:

104 0FAtm(-)80%3.54102 rads(40 yr TID)NIA

110OFAtm(-)90%N/A

NIA

1 92 0FAtM100%1x104 rads

N/A

IL. The temperature switches in Appendix 1 listed under heading II areHoneywell model T675A. They are located in the Auxiliary Buildingelevation 713 (Rooms A6 and A19). As detailed in EN DES Calculation NEB840213 218 for the Containment Ventilation System, these switches arerequired to operate 100 days after the start of a LOCA and for one monthafter the start of an RHR, CVCS, Auxiliary Boiler, or Auxiliary Feedwaterline break outside of containment.

The switches are subject to HELE and LOCA conditionsrequired to operate in the following environment2:

Normal1 Abnormal

(Volume 15).

Accident

Temperature:Pressure:Relative Humidity:Radiation:

Spray/Flooding:

104 0 FAtm(-)80%3.5x104 rads(40 yr TID)NIA

110OFAtm(-)90%N/A

N/A

1920 FAtm100%1x104 rads

N/A

lSee WBN Environmental Data Drawings 47E235-48Ri. and -49R1.2See WBN Environmental Data Drawings 47E235-56R1 and -57R0.

They are

They are

Preparer/Date ~

Reviewer/Date 9.-75(

EQS No. WBNEEB0033Appendix 2 Rev 2Sheet 5 of 5..~...,.

The manufacturer's specifications for the switches are;

Temperatute:Pressure.:Relative Humidity:Radiation:

1250FAtm,Normal plant environmentNot specified

See generic position 4.1.2 for radiation. See generic position 4.1.3 forrelative humidity.

The above information shows that the switches are unqualified for theirtemperature environment during certain accidents.

TVA will replace these switches with qualified devices or will redesign. theinstrument loop to ensure proper system operation, as determined by NCRWBNEEB83 07.

014143 .03

JOT

O

FIGURE 1

REQUIRED LOCA/MSLB ACTUAL TEST VALUES ARE INDICATED BY BRACKETS-~ 1,1

-4

0

'4

-o ~- CDCD <

*0o ~.- 0'

t-I0CD

I'

o 10 40 2 4 10 12 3 S 6 10 40 2 4 1 012 9 1 2 2 42 34 5 ........ 2 Q 3 0LSEC:..- MINUTES -..jitouns...4.SEC:.j MINUTESIf-IIOJs -1 DAYS -TIME

0m 0

I-of ttl

0.1

Revisio i 2 3*liit No. 1 and 2F~eisin 1 2 3 BS No. WBNEEB0035

/Al 31) No.Preparerbate$ c See Appendix 1

Reviewer/bate

PAnufactirer" and Model No. See Appendix 1

Verification of Ti~ble Information (Table See Appendix 1

RWA; t Z=- The equipment has been identified as per TVA ID numberdesignations (such as, PvJ, SCW).

.x L - The location has been identified (such as, inside primarycOntainmenti, annulus, individually cooled roomt, general spaces, or areaaffected by MEL outside primary containmient).

-2x D M - A unique WVA ID number has been assigned (such as, l-PSV-68-308).-Ix ~ i A functional description of the coutmoent has been given (such as,

steam generator blowdon).~ Qmtract No.. Manufacturer. and Mo~del No. - The contract numiber, manufacturer,

and model number have been given.-I Abnormal or Accident Environment - All abnormal or accident environmiental

conitions applicable to this equipment have been identified either in tables orX by references to figures f rom tables.X Owironi~t to Miich uafid-The environment to which the equipment has been

qualified is addressed in either the tables or the environmental analysisX attached._

.±. A Category of a, b, c, or d has been defined for theequipment,

.. IL Cg ration and Agcuracy Reqired aod Demo~nstrated - The operationand accuracy required and demonstrated have been defined.

Qualification Status (check if a~,licable. NA if not)Qualified Life (If equipment is qualified, indicate the qualified life with anumerical entry): 4n ;zears.

X, (Qalif icatiari Reprt and Mgtlr - A qualification report and the method ofqualification has been identified on the Table Input Data Rieet (TIJDS).

-I- Eairomenta A~nalysi - An environmental analysis has been done, attached tothe BDS,, and independently reviewed by the responsible organization.

N/A Q lif ication by SiniilArv (If applicable) - A justification for qualificationIby similarity is attached to the BOS considering all the above factors and

X referenced to the appropriate tables.X QulificAtion Of Several Exact G98Uonets (If applicable) - When an ECIS is used

for more than one item, a list of all exact components is given as an appendixwith all references to appropriate tables with justification for qualification

..ck-sid ing all the above factors.Nj ILiitrim QualificAtion (If applicable) - (open item) - Cca~onent has been

&-termined to be qualified only for a limited interim operation, an NCR hasbeen written, and Plan of action has been determined to yield a qupalif-ied

ftarm of Interim Qualification_____________________

N/A "M itmNo(f.asbeRMuA.U if ~ n (Open ie)-(fapplicable) - Unponent hsbe&vtermined to be urqualif ied; the follow~ing is attached to MS: NCR number,reason for non-qualification, and justification of continued operation.NCR No.______ ___

*Due to the extensive changes from Revision 2, revision bars are not used.

Preparer/Date _____________________

R evi ewer/D ate ,/~ 4eEQS NO. WBNEEB0035Appendix 1 f-Vv-Sheet l-af 1

Manuf acturer ASCO

Comiponent Solenoid Valve

Comiponent IJNID Model No. Table/Sheet

I-LSV-3-148A 206-381-3RVU 3 .11-6/WBNEE-BOO01

3 .I1-8/WBNEEB(UUJ~-2-LSV-3-148A WPXHV202-301-IF 3 .11-6/WBNEEBOOOI

-3 .11-/WBNEEtsU0U±1-LSV-3-156A 206-381-3RVU 3 .11-6/WBNEEBOOOI

3 .11--6/WbNIkdRUUa2-LSV-3-156A WPXHiV2O2-301-lF 3 .11-6/WBNEEBOOO1

1 LSV-3-164A 206-381-3RVU 3.11-6/WBNEEBOOO13 .11-8/WBNEENUM~

2-LSV-3-164A WPXHiV2O2-30 1-lF 3 .11-6/WBNEEBOOO13 .11-8/WBNEEBUUOI-

1-LSV-3-171A 206-381-3RVU 3 .11-6/WBNEEBOOO1-3 .11-8/WBINE~.u

2-LSV-3-171A WPXHV2O2-301-1F 3 .11-6/WBNEEBOOOI

Preparer/Date /KŽ"u./ 1 ý/'2gRev iewer/ Date > -~t

EQS No. WBNEEB0035Appendix 2 Rev 3Sheet 1 of 7

UNIT 1 ONLY

1 1.The polenoid valves in Appendix 1 are ASCO model 206-381-3RVU. Theyare located in the Auxiliary Building (737 Al, Volume 12). As detailedin EN DES Calculation NEB 840515 225 for the Main and Auxiliary Feed-water Systems, these valves are required to operate for 100 days afterthe start of a LOCA. They are also required to operate for 1 monthafter breaks in either Auxiliary Feedwater, Auxiliary Boiler, RHR, orCVCS lines.

I. These valves are required to operate in the following environments:1

Normal1 ,Abnormal Accident

Temperature:Pressure:Relative Humidity:Radiation:

Spray/Flooding:

1040 FAtm(-)80%5x102 rads(40 yr TID)NIA

1 100FAtm(-)90%N/A

N/A

129 0FAtm100%

<Clx1O 4 rads(LOCA)NIA

III. ASCO has tested this valve model number to the following environment:

Temperature:Pressure:Relative Humidity:Radiation:Spray:

346OF110 psig100%2 x 108 rads3000 ppm BORON/pH 9-11

'Per WBN Environmental Data Drawing 47E235-46R0.

I-L.

Preparer/Date //7A av.g4 ;i~d" .,$-z- EQS No. WBNEEB0035.. ~ -~AAppendix 2 Rev 3

Reviewer/Date /~/z4et.. -~ 9 Sheet 2 of 7

UNIT 1 ONLY

IV. 1. Qualifitation Testing:

a. ASCO has tested the 206-381 series solenoid valves to therequirements of IEEE Standard 323-1974 and NUREG-0588. The testcriteria and results are documented in ASCO test report AQS21678/TR,Revision A, including R2 supplement 3. All qualification and testswere performed at test levels or conditions in excess of known maximumapplication requirements. These margins are in accordance with themargins suggested by IEEE Standard 323-1974.

b. Seven solenoid valve samples representing six generic families ofvalves, including the 206-381 series, were subjected to sequentialexposures of elevated temperature, radiation, wear aging, seismicsimulation, vibration endurance, accident radiation, and a 30-day LOCAsimulation. Baseline functional tests were performed before the startand after each sequence of the test exposure with the exception of coildielectric and insulation resistance measurements which were takenbefore thermal aging, after accident radiation, and after LOCAexposure. The valves were energized and deenergized at high and lowpressures during the test phases (except radiation) and valve leakagemonitored.

c. Baseline/Functional Test: Baseline/Functional tests consisted ofmeasurement of coil excitation, seat leakage at high and low pressures,noise test, operational test, and external leakage test before andafter all phases of type tests. Measurement of insulation resistanceand coil dielectric test was performed in the as received condition andafter completion of accident radiation and LOCA simulation. Valveswere energized and deenergized and their operation monitored duringtest (except radiation).

d. Thermal aging: The valves were subjected to an aging temperatureof 268OF for a test duration of 12 days. They were cycled (de-energized for five minutes and then energized) every six hours.

e. Radiation: The valves were subjected to cobalt 60 (GAMMA)radiation at an exposure rate of less than one megarad per hour.Total integrated dose received was 50 megarads.

f. Wear aging: The valves were electrically cycled 40,000 times atmaximum pressure differential.

g. Seismic Simulation/Vibration Endurance: The valves were subjected to acombined SSE and fragility test. The input g. level was 7 g's. Thetest was performed with the valves energized and deenergized and withhigh and low pressure. The leakage rate was monitored.

Preparer/Date Žez tc 1 /92 -'

Reviewer /Date ~ 7 La -~~:s

EQS No. WBNEEB0035Appendix 2 Rev 3Sheet 3 of 7

h. Ac'cident Radiation: The valves were subjected to cobalt 60 (GAMMA)ra&Iiation at an exposure rate of less than one megarad per hour.Valves received an additional accumulated dose of 150 megarads for atotal integrated dose of 200 mnegarads received in two stages.

i. LOCA Simulation: The valves were subjected to acoolant accident (LOCA) by exposure to steam andfor 30 days. LOCA simulation conditions were as

-, I

'LL1 O--~

_I

simulated loss-of-to chemical sprayfollows:

Temperature - Maximum of 346OF for a total period of six hoursfollowed by a step decrease to 200OF within four days followed bypost-DBE conditions of 200OF for the remaining 26 days.

'Pressure - Maximum of 110 psig for a total period of six hours'followed by a step decrease to 10 psig within four days followed bypost-DEE conditions of 10 psig for remaining 26 days.

Relative Humidity - All steam environment in excess of 2500F; greater.than 90% for other conditions.

Chemical Spray - The chemical solution consisted of 3000 ppm boron asboric acid in solution with 0.064 molar sodium thiosulfate bufferedwith sodium hydroxide. The chemical solution pH was maintained.between 9.5 and 10.5.

j. Results: One of the valves malfunctioned during thermal aging.The valve developed excessive seat leakage both in the energized anddeenergized state. This was later determined to be caused by dirt inthe valve. The source of dirt was the iron pipe used in the cylinderport as piping and an additional length used to simulate anaccumulator.

Other than the above malfunction, the valves sucesafully completedthe sequential type tests and the baseline/functional tests.

2. Qualified Life - The solenoid valves have a qualified life of 40 years at 104*Fand 40,000 cycles, providing the maintenance schedule outlined in paragraph 4 isfollowed. Open and close completes one cycle. However, due to the self-heatingnature of solenoid valves, the temperature rise associated with a continuouslyenergized solenoid valve must be accounted for in the qualified lifecalculation. There are two areas affected by this heating: (1) the coil seesan increase of 105'C (221*F) above ambient and (2) the elastomeric discs see anincrease of 45*C (113*F) above ambient. These temperature increase values comefrom Franklin Research Center's "Test Program and Failure Analysis of Class lBSolenoid Valves" (NUREG/CR-3424, F-C5569-309/315).

Based on the above information, a separate qualified life must be calculated for boththe coil and the disc. The following qualified life calculations, which are based onthe Arrhenius equation, are for valves to be used at a normal ambient operatingtemperature of 104*F (40*C):

PreprerDate,/$/\c~A ~EQS No. WBNEEB0035,,Appendix 2_ Rev3

Reviewer/Datey,4 4 O 9-6 ' Sheet 4 .of '7

-l L2e EK i T2

COILS

In Franklin Research Center's "Test Program and Failure Analysis of Class 1ESolenoid Valves" (NUREG/CR-3424, F-C5569-3091315), the solenoid coils were aged attwo rates: 150*C (302*F) for 9.3 days (223.2 hours) and 131*C (268*F) for 15.3 days(367.2 hours).

Ll- Qualified life (first aging rate)

L2- Accelerated (test) life - 223.2 hours

E - Activation energy - 1.00 eV

K M Boltzmann's constant - 8.617 x 10-5 eV/OK

Tj-Qualified temperature (ambient + 105C) - 145*C

T2- Elevated (test) temperature - 150*C + 105*C - 255*C

e - Base of natural logarithms

L1Iin Qualified life (second aging rate)

L2'-n 367.2 hours

E - 1.00 eV

K - 8.617 x 10-5 eV/ K

T1'- 40*C + 105% 1450C

T2 '- 131C + 105*C -236*C

e -Base of natural logarithms

Ll (total) -Total qualified life -Ll + L1' 14.217 years

DISCS

In ASCO test report AQS-21678/TR, supplement 3, the entire valve was aged at 131%(268*F) for 12 days (288 hours).

Ll- Qualified life

L2 Accelerated (test) life -288 hours

E Activation energy .94 eV

PreparerIDate(•4A~M.2 & /92~~ EQS No. WBNEEB0035Appendix 2 Rev 3

Reviewer/Date 2 $# Sheet 5 of 7

K - Boltzmann' s constant - 8.617 x 10-5 eV/*K

Tl- Qualified temperature - 104*F

T2- Elevifted (test) temperature - 131*C + 45*C - 176*C

e - Base of natural logarithms

Ll-15.811 years

3. Installation - Valves should be installed such that the axis of the coilremains in the vertical and upright position.

4. Maintenance Requirements - The qualified life depends on the valve beingcycled at least every 16-18 months to ensure proper opening and closing.Coils shall be replaced every 14.217 years and elastomeric components shallbe replaced every 15.811 years when solenoid valves are subjected to anormal operating ambient temperature of 104*F. In addition, ASCO recommendsthat when the solenoid valves reach 20,000 cycles, that they be rebuiltusing the applicable spare parts kit and spare coil kit2.

5. Nuclear Regulatory Commission IE Information Notice No. 81-29, EquipmentQualification Notice No. 10 has identified a problem with ASCO solenoidvalves having viton dynamic seals. The viton seals will adhere to metallicsurfaces when exposed to radiation doses in excess of 20 megarads. Valveslisted in appendix 1 have viton seals. Since the total radiation exposuredoes not exceed the limit, the valves are qualified for this application.

6. Valves are qualified per IEEE Standard 323-1974, IEEE Standard 382-1972,IEEE Standard 344-1975, and applicable portions of NUREG-0588 for theenvironment in which they are required to operate, providing the maintenanceschedule in paragraph 4 above is followed. By mathematical analysis, thequalified post-DBE operating time can be extended to 4599 days.

Calculations - Post Accident Life

Calculations are based on the Arrhenius equation which states:

Ll -L2e [K (Tl T2]

Where

Ll Qualified life

2ASCO Test ReportAQR67368/Rev. 0Appendix C, Page C-2

T

Preparer/Date ____________Y_____ EQS No. WBNEEB0035

Appendix 2 Rev -2Rev iewer/ Date ZfA, ,,Z ,,Le? Sheet 6 of -7

L2 Accelerated (test) life

El s.Worst case activation energy, eV

K - Boltzmann's constant, 8.617 x 10-5 eV/OK

Tj-Qualified temperature, absolute

T2- Elevated (test) temperature, absolute

e -Base of natural logarithms

Calculate qualified post-accident life for valves located in the AuxiliaryBuilding using accident temperature profile for valves listed in Appendix1:

L2- 29 days (AQS21678/TR Rev. A, figure 2, page 4-21)

Ei 0.94 eV (AQR67368, Appendix B, page B-3)

TI- 1040F (temperature profile, WBN enviroinmental data drawings 47E235-46 RO47E235-46 RO and -47 Rl

T2- 200OF (AQS21678/TR Rev. A, figure 2, page 4-21)

L2- 29 x 24 - 696 hours

L1= 12.6 years x 365 4599 days

Preparer/Date Y'/UtA

Rev iewer/ Date d~ 1f4Ceý,CLEQS No. WBNEEB0035Appendix 2 Rev -3Sheet 7_ of 7

UNIT 2 ONLY

1. The~solenoid valves in Appendix 1 are ASCO model WPXHV2O2-301-lF. They Aslocated in the Auxiliary Building (737A1. General Spaces). The solenoid 'valvesare required to operate for up to 100 days'after the start of design-basisaccidents (depending upon which accident occurs), per EN DES calculationNEB 830204 223.

2. The solenoid valves are subject to LOCA and HELB conditions. They arerequired to operate in the following environmentsl:

Normal Abnormal Accident

Temperature:Pressure:Relative Humidity:Radiation:

Spray/Flooding:

1040FAtm80%5.0 z 102 rads(40 year TID)N/A

110OFAtm

90%

N/A

12901Atm100%.41 x 0rads

N/A

3. The manufacturer's specifications for the solenoid valves are:

Temperature:Pressure:Relative Humidity:Radiation:

1250FAtmNEMA 4 Enclosure7x106 rads

4. See generic position 4.1.5 for radiation.for relative humidity.

See generic position 4.1.8

5. The normal operating temperature is 104*F. During and BELB, the temperaturewill rise to 129*F within 650 seconds and then decrease linearly to the maximumnormal temperature within 24 hours. The VF temperature rise above themanufacturer's specified maximum ambient temperature of 125*F will not effectthe operation of the solenoid valves.

6. The above information shows that the solenoid valves will functionproperly as required and are, therefore, qualified for an interimperiod. However, due to lack of documentation required by NUREG-0588,TVA will replace these valves with qualified devices per IOCFR5O.49 asdetermined by NCR WBNEEB8125.

1Per SQNIWBN Environmiental Data Drawing 47E235-49, -50.

034158.01

L

Unit No. l and2Revision 1 2 13* EDS No, WBNFEBnna7-

Preparer/bate x ~ .lA See Appendix 1_

MN MUIWE1 OtLFI QIN SH=; fffS)

Manufac~irer and ?kodel No AS CO/f or model number see Appendix 1

verification of Table Informiation (Table See ArDlend ix 1

X A~~tTM- The equipment has been identified as per TVA ID numberdesignations (such as, mov, WO 1.

X.. LInALiM - The location has been identified (such as, inside primarycontainment, annulus, individually cooled room, general spaces, or areaaffected by HELB outside primary containmnent).

X =Mft- A unique TIVA MD numb~er has been assigned (such as, i-FSV-68-308).X F~~tiM- A functional description of the component has been given (such as,,steam generator blowown).

X Contract No., Manufacturer. and Model No. - The contract number, manufacturer,and model number have been given.

X &Mnrmal Or Accident EMvronnent - All abnormal or accident environmentalconditions applicable to this equipment have been identified either in tables orby references to figures from tables.

X~ Enyircrmet to Which qualified - The environment to which the equipment has beenqualified is addressed in either the tables or the envirornmental. analysis

* attached.f. atLer - A category of a,, b, co, or d has been defined for theequipmnent.

.. X Coratin and Accuracy REqired and Dmi~ntrated - The operationand accuracy required and demonstrated have been defined.

Dualification Status (check if applicable. NA, if not)QUAlified Life (If equirment is qualified, indicate the qualified life with anumnerical entry): 40years

X OQuAlification Rerport and Method - A qualification report and the method ofqualification has been identified on the Table Input Data Sheet (TIDS).

--L a Envirnmen Al ho iIj - An environmental analysis has been done, attached tothe EDS, and independently reviewed by the responsible organization.

-. Oualification by Similarity (If applicable) - A justification for qualificationby similarity is attached to the EDS considering all the above factors andreferenced to the appropriate tables.

~ Ouaification of Several Exact Canvoneta (if applicable) - When an EOS is usedfor more than one item, a list of all exact comi~onents is given as an appendixwith all references to appropriate tables with justification for qualificationconsidering all the above factors.

N/*A Interim qualification (If applicable) - (open item) - Component has beendetermined to be qualified only for a limited interim operation, an NCR hasbeen written, and plan of action has been determined to yield a qualifiedccuzipnent.Term of Interim (Ojalification_____________________NCR No.

O ..nLA I fual± Co mnt - (Open item) - (If applicable) - Compionent has beendetermined to be unxpualified; the following is attached to BDS: NCR n~umber,,

* ~reason for nion-qualification, and justif ication of continued operation .--.

*Due to the extensive changes from Revision 2, revision bars are not used.

P reparer/Date -/XZ 4 ? A-•4ýR .evi ewer/Date &•/iq4ui.L ~ 2-,5C-/

LiJ

EQS No. WBNEEB0037Appendi x i 7T-R-vSheet 1 of I

AS CO

Solenoid Valve

Component UNID Model No. Table/Sheetf

1-FSV-90-l 07-A X206-381-3Rp 3 .11-5/WBNEEBOOO2

2-FSV-90-107-A HTX8320A22V 3 .1l-5/WBNEEBOOO2

I-FSV-90-11l-A X206-381-3RF -3 .l-5/WBNEEBOOO2

2-FSV-90-11l-A HTX8320A22V 3 .ll-5/WBNEEBOOO2

1-FSV-90-113-A X206-381-3R1 3 .l1-5/WBNEEBOOO2

2-FSV-90-113-A HTX8320A22V 3 .ll-5/WBNEEBOOO2

l-FSV-90-117-A X206-381-3RP 3.ll-5/WBNEEBOOO2

2-FSV-90-117-A liTX8320A22V 3 .ll-5/WBNEEBOOO2

Manuf ae-turer

Coanponont

Preparer/Date a.________________

Rev iewer/ DateA -2/

EQS No. WBNEEB0037Appendix 2 Rev 3Sheet 1 of 7

UNIT 1 ONLY

I.1. Tho solenoid valves in Appendix 1 are ASCO model X206-381-3R1. Theyare located in the Reactor Building (Annulus). As detailed in EN DESCalculation NEB 840413 223 for the Radiation Monitoring System (System90), these valves are required to operate for 5 minutes after the startof a LOCA, or a line break in the Main Steam or Main Feedwater Systemsand they must not fail in a manner detrimental to plant safety for 100days thereafter. In the event of a line break in the Residual HeatRemoval or Chemical Volume Control Systems, they must operate for 5minutes after the start of the event and must not fail in a mannerdetrimental to plant safety for 1 month thereafter.

2. The valves are subject to LOCA/HELE conditions and are required tooperate in the following environmentsl:

Normal Abnormal Accident

Temperature:Pressure:Relative Humidity:Radiation:

Spray/Flooding:

1100FAtm80Z2 x 17rads(40 year TID)N/A

1200FAtm90%NIA

1500?Atm100%5 x 17rads

N/A

3. ASCO has tested these valves to the following environment:

Temperature:Pressure:Relative Humidity:Radiation:Spray:

3460?110 psig100%2 x 108 rads3000 ppm BORON/pH 9-11

'Per WBN Environmental Data Drawing 47E235-44.

F..----j ~

Preparer/Date #,4ka,, EQS No. WBNEEB0037Appendix 2 Rev 3

Reiwr/aeý Sheet 2....L. of 7....

I.1. Qqlification Testing:

a.'.ASCO has tested the 206-380 and 206-381 series solenoid valves to therequirements of IEEE Standard 323-1974 and NUREG-0588. The test criteriaand results are Idocumented in ASCO test report AQS21678/TR, Revision A,including supplement 3. All qualification and tests were performed at testlevels or conditions in excess of known maximum application requirements.These margins are in accordance with the margins suggested by IEEE Standard323-1974.

b. Seven solenoid valve samples representing six generic families of valves,including the 206-380 and 206-381 series, were subjected to sequentialexposures of elevated temperature, radiation, wear aging, seismicsimulation, vibration endurance, accident radiation, and a 30-day LOCAsimulation. Baseline functional tests were performed before the start andafter each sequence of the test exposure with the exception of coildielectric and insulation resistance measurements which were taken beforethermal aging, after accident radiation, and after LOCA exposure. Thevalves were energized and deenergized at high and low pressures during thetest phases (except radiation) and valve leakage monitored.

c. Baseline/Functional Test: Baseline/Functional tests consisted ofmeasurement of coil excitation, seat leakage at high and low pressures,noise test, operational test, and external leakage test before and after allphases of type tests. Measurement of insulation resistance and coildielectric test was performed in the as received condition and aftercompletion of accident radiation and LOCA simulation. Valves were energizedand deenergized and their operation monitored during test (exceptradiation).

d. Thermal aging: The valves were subjected to an aging temperature of 268OFfor a test duration of 12 days. They were cycled (deenergized for fiveminutes and then energized) every six hours.

e. Radiation: The valves were subjected to cobalt 60 (GAMMA) radiation at anexposure rate of less than one megarad per hour. Total integrated dosereceived was 50 megarads.

f. Wear aging: The valves were electrically cycled 40,000 times at maximumpressure differential.

g. Seismic Simulation/Vibration Endurance: The valves were subjected toacombined SSE and fragility test. The input g. level was 7 g's. The testwas performed with the valves energized and deenergized and with high andlow pressure. The leakage rate was monitored.

2-. lz L

Preparer/Date 0. a EQS No. WBNEEB0037S Appendix 2 Rev 3

Reviewer/Date Z4,tSheet 3 of 7

h. Acdfident Radiation: The valves vere subjected to cobalt 60 (GAMMA)radiation at an exposure rate of less than one megarad per hour. Valves-received an additional accumulated dose of 150 megarads for a totalintegrated dose of 200 megarads received in two stages.

i. LOCA Simulation: The valves were subjected to a simulated loss-of-coolantaccident (LOCA) by exposure to steam and to chemical spray for 30 days.LOCA simulation conditions were as follows:

Temperature - Maximum of 3460F for a total period of six hours followed by a

step decrease to 200OF within four days followed by post-DBE conditions of20001 for the remaining 26 days.

Pressure - Maximum of 110 psig for a total period of six hours followed by astep decrease to 10 psig within four days followed by post-DBE conditions of10 psig for remaining 26 days.

Relative Humidity - All steam environment in excess of 2500F; greater than90% for other conditions.

Chemical Spray - The chemical solution consisted of 3000 ppm boron as boricacid in solution with 0.064 molar sodium thiosulfate buffered with sodiumhydroxide. The chemical solution pH was maintained between 9.5 and 10.5.

j. Results: One of the valves malfunctioned during thermal aging. The valvedeveloped excessive seat leakage both in the energized and deenergizedstate. This was later determined to be caused by dirt in the valve. Thesource of dirt was the iron pipe used in the cylinder port as piping and anadditional length used to simulate an accumulator.

Other than the above malfunction, the valves sucessfully completed thesequential type tests and the baseline/functional tests.

2. Qual ified Life - The solenoid valves have a qualified life of 40 years at 110*Fand 40,000 cycles, providing the maintenance schedule outlined in paragraph 4 isfollowed. Open and close completes one cycle. However, due to the self-heatingnature of solenoid valves, the temperature rise associated with a continuouslyenergized solenoid valve must be accounted for in the qualified lifecalculation. There are two areas affected by this heating: (1) the coil seesan increase of 105*C (22l*F) above ambient and (2) the elastomeric discs see anincrease of 45%C (113*F) above ambient. These temperature increase values comefrom Franklin Research Center's "Test Program and Failure Analysis of Class 1ESolenoid Valves" (NUREG/CR-3424, F-C5569-309/315).

Based on the above information, a separate qualified life must be calculated for boththe coil and the disc. The following qualified life calculations, which are based onthe Arrhenius equation, are for valves to be used at a normal ambient operatingtemperature of 11001 (43.30C):

Preparer/Date 4A________________________ EQS No. WBNEEBOO37-

SAppendix 2 Rev 3Reviewer/Date -4 zea "aSheet 4 -of 7

£L - L2 e

COILS

In Franklin Research Center's "Test Program and Failure Analysis of Class lESolenoid Valves" (NUREG/CR-3424, F-C5569-309/315), the solenoid coils were aged attwo rates: 150% (302*F) for 9.3 days (223.2 hours) and 131%c (268*F) for 15.3 days(367.2 hours).

Ll- Qualified life (first aging rate)

L2 - Accelerated (test) life - 223.2 hours

E - Activation energy - 1.00 eV

K - Boltzmann's constant - 8.617 x 10-5 eV/OK

Tj- Qualified temperature (ambient + 1050C) - 1 48 .36C

T2-Elevated (teat) temperature - 150*C + 1050C - 255 0C

e - Base of natural logarithms

Ll'- Qualified life (second aging rate)

L2 '- 367.2 hours

E - 1.00 eV

K - 8.617 x 1O-5 eV/*K

T1'- 43.3% + 105C 14.0

T2 '- 131% + 105*C -236*C

e - Base of natural logarithms

Lj (total) - Total qualified life - Ll+ Li' 11.44 years

DISCS

In ASCO test report AQS-21678/TR, supplement 3, the entire valve was aged at 131*C131*F (268*F) for 12 days (288 hours).

Ll Qualified life

Preparer/Datf" ~-~4{/~ EQS No. WBNEEB0037Appendix 2 Rev 3

Reviewer/Date 9J AL d .24;4~ Sheet 5 -- of 7

L2- Accelerated (test) life - 288 hours

E - Ab.ivation energy - .94 eV

K - Boltzmann' s constant - 8.617 x 1i-5 eV/*K

T1- Qualified temperature - 110*F

T2- Elevated (test) temperature - 1310C + 450C - 1760C

e - Base of natural logarithms

Ll 11 .945 years

3. Installation - Valves should be installed such that the axis of the coil remainsin the vertical and upright position.

4. Maintenance Requirements - The qualified life depends on the valve being cycledat least every 16-18 months to ensure proper opening and closing. Coils shallbe replaced every 11.44 years and elastomeric components shall be replaced every11 .945 years when solenoid valves are subjected to a normal operating ambienttemperature of lO 0*F. In addition, ASCO recommends that when the solenoidvalves reach 20,000 cycles, that they be rebuilt using the applicable spareparts kit and spare coil kit2.

5. Valves are qualified per IEEE Standard 323-1974, IEEE Standard 382-1972, IEEEStandard 344-1975, and applicable portions of NUREG-0588 for the environment inwhich they are required to operate, providing the maintenance schedule inparagraph 4 above is followed. By mathematical analysis, the qualified post-DBEoperating time can be extended to 2.73 years.

Calculations - Post Accident Life

Calculations are based on the Arrhenius equation which states:

Ll- L2e K-T

2ASCO Test ReportAQR67368/Rev. 0Appendix C, Page C-2

Preparer/Date /, ý ,/ ý3-2 -

Reviewer/Datey14&Z4. 4

Ll- Qpalified life

L2- Accelerated (test) life

El--Worst case activation energy, eV

K - Boltzmann's constant, 8.617 x 1i-5 eVI0K

Tj- Qualified temperature, absolute

T2- Elevated (test) temperature, absolute

e - Base of natural logarithms

EQS No. WBNEEB0037Appendix 2 Rev 3Sheet 6 of 7

Calculate qualified post-accident life for valves located in lover compartment(worst-case accident temperature profile for valves listed in Appendix 1):

L2- 26 days (AQS21678/TR Rev. A, figure 2, page 4-21)

Ei- 0.94 eV (AQR67368, Appendix B, page B-3)

Tj- 128OF (temperature profile, WEN environmental data drawing 47E235-44, 150OF@ 3x102 seconds - 1050F @ 2.59xl06 seconds/2 + 1050F

T2- 200OF (AQS21678/rR Rev. A, figure 2, page 4-21)

L2-26 x 24 - 624 hours

Lj- 2.73 years

Preparer/Date

Rev iewer/ Date AY£dG4 A ~2~ ~

EQS No. WBNEEB0037Appendix 2 Rev 3Sheet 7 of 7

UNIT 2 ONLY

1. The solenoid valves in Appendix 1 are ASCO model HTX8320A22V. They arelocated in the Reactor Building (Annulus). They are required tooperate for five minutes after the start of an accident and to not failin a manner detrimental to plant safety for 100 days thereafter(depending on which accident occurs).

2. The solenoid valves are subject to LOCA and HELB conditions. They arerequired to operate in the following environments3 :

Normal Accident

Temperature:Pressure:Relative Humidity:Radiation:

Spray/Flooding:

11 0OFAtm80%5.0 x 106 rads(10 year TID)N/A

150OFAtm100%5.0 x 10 rads

NIA

3. The manufacturer's specifications for the solenoid valves are:

Temperature:Pressure:Relative Humidity:Radiation:

200OFAtmNEMA 4 Enclosure7xl06 rads

4. See generic position 4.1.5 for radiation. See generic position 4.1.8for relative humidity.

5. The normal and accident conditions with exception of accident radiationare within the manufacturer's specifications. Solenoid valves haveviton dynamic seals. ASCO has stated that viton is acceptable forapplications to 20 megarads total dose (including DBE) and that valvescontaining viton dynamic seals may still be considered acceptable upto 200 megarads total dose (including DBE) if they are not required toshift position after exposure to radiation doses in excess of 20megarads. Solenoid valves in appendix 1 are normally energized andmust remain energized for up to five minutes following DBE. For theremaining 100 days valves are deenergized and are not required to shiftposition; therefore, radiation exposure in excess of the manufacturer'sspecification is not considered detrimental to plant safety.

6. The above information shows that the solenoid valves will functionproperly as required and are, therefore, qualified for an interimperiod. However, due to lack of documentation required by NUREG-0588,TVA will replace these valves with qualified devices per lOCFR5O.49 asdetermined by VCR WBNEEB81 26.

3 Per SQN/WBN Environmental Data Drawing 47E235-47. j ~;

014137 .02

UnitNo.1 and 2

Revision 1 2 3* BDS No~ WBN9E-EB0039-

Prepa~r/~I ?CT~~ See Appendix 1

Reviewer/b~ate 5 54 A 1 /

Manufacturer and Model No See Appendix 1

Verification Of TaIble information (Table -See Appendix 1

tTe- The equipment has been identified as per TVA IM numberdesignations (such as, ?WV1, SOVT).

.X TQmtion - The location has been identified (such as, inside primarycontainment, annulus, individually cooled rooms, general spaces,, or areaaffected by HELB outside primary containment).

_2L Qfo~t- A unique TVA MD number has been assigned (such as, l-FSV-68-308).x. Functign - A functional description of the comp~onent has been given (such as,

steam generator blowdown)._L Qmtract No.. Manufacturer, and Model No. - The contract numrber, manufacturer,

and model number have been given.x.. AbnorMal or Accident EnvironMet - All abnormal or accident environmental

conditions applicable to this equipment have been identified either in tables orby references to figures from tables.

Y~ z~virgOnMet to Which Oualified - The environment to which the equipment has been

qualified is addressed in either the tables or the environmental analysis

Sattached.f~teg= - A category of a, b# c, or d has been defined for the

equipment.x. Operation and Accuracy Reqired and Den~ntrated - The operation

and accuracy required and demonstrated have been defined.

flualification Status (check if aplicable. N& if not)

Quaified .Life (If equipment is qualified, indicate the qualified life with anumlerical entry): 40 Years-

X Qualification Reprt and Metho - A qualification report and the method of

qualification has been identified on the Table Input Data Sheet (TIDS).X Envirgnmetal Analysis - An environmental analysis has been done, attached to

the EDS, and independently reviewed by the responsible organization.N/A Ouialification by SiMilarity (If applicable) - A justification for qualification

by similarity is attached to the EDS considering all the above factors andreferenced to the appropriate tables.

X ualification of Several Exact Conugnen (If applicable) - when an EDS is used

f or more than one item, a list of all exact comiponents is given as an appendixwith all references to appropriate tables with justification for qualificationconsidering all the above factors.

N/A Iterim qualificaion (If applicable) - (Open item) - Component has beendetermined to be qualified only for a limited interim operation# an VCR hasbeen written,, and plan of action has been determin~ed to yield a qualifiedcomponent.Term of Interim QualificationNCR~ No.

N A NW i 2uaiLed Cam== - (Open item) - (If applicable) - Czcpionent has been

datermlned to bie unqualified; the following is attached to EDS: NCR number,

W ~reason for non-qualification, and justification of continued operation. __

-- ~ EFFECTIVE*Due to the extensive changes from Revision 2, revision bars are not used. D A TEE

T

D

Preparer/Date_______ ______

Re viewer/ Date A4tLlgAL. ~Z-#

Manuf act urer

Component

EQS No. WBNEEB0039Appendix 1 Rev 3Sheet Fo-Cf 2~

AS CO

Solenoid Valve

*Not vet nRtnhlpd **No identificat~on tn~

ANN - AnnulusU - Upper Containment

ANN

ANN

ANN

ANN

ANN

ANN

ANN

ANN

ANN

ANN

ANN

ANN

ANN

ANN

ANN

U

U

U

U

Component UNID Model No. Table/Sheet

2-FSV-43-3-A* HV206-381-3RF 3.l1-5/WBNEEBOOO2

2-FSV-43-12-A *HV206-381-3RF 3.1 1-5/WBNEEB0OO2

2-FSV-43-23-A* HV206-381-3RF 3.11-5/WBNEEB0OO2

I-FSV-43-35-A ** V206-381-3RF 3.11-5/WBNEEBOOO4

2-FSV-43-35-A * HV206-381-3RF 3.11-5/WBNEEBOOO2

2-FSV-43-77-A * HV206-381-3RF 3.11-5/WBNEEBOOO2

I-FSV-43-77-A NP831654E 3 .11-5/WBNEEBOOO2

1-FSV-43-55-A NP831654E 3 .11-5/WBNEEBOOO3

2-FSV-43-55-A * 11V206-381-3RF 3.l1-5/WBNEEBOOO3

1-FSV-43-58-A NP831654E 3 .11-5/WBNEEBOOO3

2-FSV-43-58-A * HV206-381-3RF 3.1 1-5/WBNEEBOOO3

I-FSV-43-6 1-A NP831654E 3 .11-5/WBNEEBOOO3

2-FSV-43-61-A * HV206-381-3RF 3.11-5/WBNEEBOOO3

1-FSV-43-64-A NP831654E 3 .11-5/WBNEEBOOO3

2-FSV-43-64-A * HV206-381-3RF 3.1 1-5/WBNEEBOOO3

2-FSV-61-97-B NP831654E 3 .11-4/WBNEEBOOOB

2-FSV-61-122-B NP83 1654E 3 .1 1-4/WBNEEBOOO8

2-FSV-r6l-192-B NP831654E 3 .l1-4/WBNEEBOOO8

2-FSV-61-194-B NP831654E 3 .11-4/WBNEEBOOO8

Preparer/Date z

Revi ewer/D ate AEQS No. WBEB03Appendix 1 Rev 3Sheet 2 Of .

Manuf act urer

Component.

ASCO

Solenoid Valve

*Not vet ineta11~d ~No idpntifie~nt~nn tn~

ANN - AnnulusU - Upper Containment7. - T-^.fYv flnn It iaTt

LOC. Component UNID Model No. Table/Sheet

1-FSV-61-97-B NP831654E 3 .l1-4/WBNEEBOOO8

I-FSV-61-122-B NP831654E 3 .11-4/WBNEEBOOO8

l-FSV-61-192-B NP831654E 3 .11-4/WBNEEBOOO8

l-FSV-6 1-194-B NP83 16 54E 3.*1 l-4/WBNEEBOOO8

1-FSV-77-9-B NP831654E 3.ll-4/WBNEEB0OO2

2-FSV-77-9-B NP831654E 3 .1l-4/WBNEEBOOO2

1-FSV-43-56D-B 206-381-3RF 3.1 l-4/WBNEEBOOO8

2-FSV-43-56 D-B * 206-381 -3RF 3 .11 -4/WBNEEBOOOB

l-FSV-43-59D-B 206-381-3RF 3.1 1-4/WBNEEBOOO8

2-FSV-43-59D-B * 206-381-3RF 3.1 1-4/WBNEEB0OO8

1-FSV-43-63D-B * 206-381-3RF 3.11-4/WBNEEB00O8

2-FSV-43-63D-B * 206-381-3RF 3.11-4/WBNEEB0OO8

Preparer/Datex,&

Rev iewer/ Date '0% 8 2HL. - 0 i

EQS No. WBNEEB0039Appendix 2 Rev 3Sheet 1- of 11

I.1. The solenoid valves listed in Appendix 1 under Heading I are ASCOModels liV206-381-3RF and NP831654E. They are located in the Annulus,elevation 723' with the exception of 2-FSV-43-23-A, which is located inthe Annulus at elevation 741'. As detailed in EN DES CalculationNEB 840517 221 for the Sampling System, these valves are required tooperate for 5 minutes and not fail in a manner detrimental to plantsafety for 100 days after the start of a LOCA or line breaks in eitherMain Steam or Feedwater lines. They are also required to operate for5 minutes and not fail in a manner detrimental to plant safety for1 month after breaks in either RHR or CVCS Lines.

2. These solenoid valvesenvironmentl:

are required to operate in the following

Normal Abnormal Accident

Temperature:Pressure:Relative Humidity:Radiation:

Spray/Flooding:

11 0OFAtm80%2 x 107 rads(40 yr TID)N/A

120OFAtm90%N/A

150OFAtm100%5 x 107 rads

3. ASCO has tested these valve model numbers to the following environment:

Temperature:Pressure:Relative Humidity:Radiation:Spray:

346OF110 psig100%2 x 108 rads3000 ppm boron/pH 9-11

'Per WBN Environmental Data Drawing 47E235-44 RO

r ~ ~; V ~V __

Preparer/Date /______A-,. _________

Reviewer/Dated ,2/5'4w-.aiýa7,,..

EQS No. WBNEEB0039Appendix 2 Rev 3Sheet 2 of 11

I.1. The solenoid valves listed in Appendix 1 under Reading II are ASCOModel**IP831654E. They are located in the Upper Compartment atelevation 756'. As detailed in EN DES Calculation NEB 840314 224 forthe Ice Condenser System, these valves are required to operate for 5minutes and not fail in a manner detrimental to plant safety for 100days after the start of a LOCA or breaks in Main Steam or Feedwaterlines. They are also required to operate for 5 minutes and not failin a manner detrimental to plant safety for I month after breaks ineither RHR or CVCS Lines.

2. These solenoid valves are required to operate in the followingenvironment2:

Normal Abnormal Accident

Temperature:Pressure:Relative Humidity:Radiation:

Spray/Flooding:

11 0OF14.7 psia80%3.5 x 14rads(40 yr TID)N/A

120OF14.7 psia90%N/A

NIA

16 0OF26.7 psia100%1 x 108 rads

Spray Only

3. ASCO has tested this valve model number to the following environment:

Temperature:Pressure:Relative Humidity:Radiation:Spray:

346OF110 psig100%2 x 108 rads3000 ppm boron/pH 9-11

2Per WBN Environmental Data Drawing 47E235-41 RO

LA

4?1?14-A4

Preparer/Date . Ž14,U A ,Apt/'ý-Sy8'

Rev iewer/ Date 3 CAe 4 4uL.?Z?-#(

EQS No. WBNEEB0039Appendix 2 Rev 3Sheet 3 of 11

II.1. The solenoid valves listed in Appendix 1 under Heading III are ASCOModels NP831654E and 206-381-3RF. They are located in the LowerCompartment at elevation 716'. As detailed in EN DES Calculation NEB840515 222 for the Waste Disposal System and NEB 840517 221 for theSampling System, these valves are required to operate for 5 minutesand not fail in a manner detrimental to plant safety for 100 daysafter the start of a LOCA or breaks in either Main Steam or Feedwaterlines. They are also required to operate for 5 minutes and not failin a manner detrimental to plant safety for 1 month after breaks ineither RUR or CVCS Lines.

2. These solenoid valvesenvironment3:

are required to operate in the following

Normal1

Temperature:Pressure:Relative Humidity:Radiation:

Spray/Flooding:

120OF14.7 psia80%2 x 10 rads(40 yr TID)NIA

Abnormal

130OF14.7 psia100%N/A

N/A

Accident

3270 F26.4 psia100%1 x 108 rads

Spray Only

3. ASCO has tested these valve model numbers to the following environment:

Temperature:Pressure:Relative Humidity:Radiation:Spray:

346OF110 psig100%2 x 108 rads3000 ppm boron/pH 9-11

3Per WBN Environmental Data Drawing 47E235-42 RI

Preparer/Date Z&eA 119-'~)Y I EQS No. WBNEEB0039Appendix 2 Rev -3

Reviewer/Date A'JZ 9..2-I', Sheet 4 of 11

IV. 1. Qualification Testing:

a. ASCO has tested the NP8316 and 206-381 series solenoid valves to therequirements of IEEE Standard 323-1974 and NUREG-0588. The test criteriaand results are documented in ASCO test report AQS21678/TR, Revision A,including supplement 3. All qualification and tests were performed at testlevels or conditions in excess of known maximum application requirements.These margins are in accordance with the margins suggested by IEEE Standard323-1974.

b. Seven solenoid valve samples representing six generic families of valves,including the 206-381 and NP8316 series, were subjected to sequentialexposures of elevated temperature, radiation againg, wear aging, seismicsimulation, vibration endurance, accident radiation, and a 30-day LOCAsimulation. Baseline functional tests were performed before the start andafter each sequence of the test exposure with the exception of coildielectric and insulation resistance measurements which were taken beforethermal aging, after accident radiation, and after LOCA exposure. Thevalves were energized and deenergized at high and low pressures during thetest phases (except radiation) and leakage monitored.

c. Baseline/Functional Test: Baseline/Functional tests consisted ofmeasurement of coil excitation, seat leakage at high and low pressures,noise test, operational test, and external leakage test before and after allphases of type tests. Measurement of insulation resistance and coildielectric test was performed in the "as received'' condition and aftercompletion of accident radiation and LOCA simulation. Valves were energizedand deenergized and their operation monitored during test (exceptradiation).

d. Thermal aging: The valves were subjected to an aging temperature of 268*Ffor a test duration of 12 days. They were cycled (deenergized for fiveminutes and then energized) every six hours.

e. Radiation: The valves were subjected to cobalt 60 (gamma) radiation at anexposure rate of less than one megarad per hour. Total integrated dosereceived was 50 megarads.

f. Wear aging: The valves were electrically cycled 40,000 times at maximumpressure differential.

Preparer/Date4 Inat~v // o ~Jf r EQS No. WBNEEB0039Appendix 2 Rev 3

Reviewer/Date_______ Sheet 5 of 11

g. Seismic Simulation/Vibration Endurance: The valves were subjected to acombined SSE and fragility test. The input g-level was 7 g's. The testwAs performed with the valves energized and deenergized and with high and-low pressure. The leakage rate was monitored.

h. Accident Radiation: The valves were subjected to cobalt 60 (GAMMA)radiation at an exposure rate of less than 1 megarad per hour. Valvesreceived an additional accumulated dose of 150 megarads for a totalintegrated dose of 200 megarads received in two stages.

i. LOCA Simulation: The valves were subjected to a simulated loss-of-coolantaccident (LOCA) by exposure to steam and to chemical spray for 30 days.LOCA simulation conditions were as follows:

Temperature - Maximum of 346OF for a total period of 6 hours followed by astep decrease to 200OF within 4 days followed by post-DBE conditions of200OF for the remaining 26 days.

Pressure - Maximum of 110 psig for a total period of 6 hours followed by astep decrease to 10 psig within 4 days followed by post-DBE conditions of10 psig for remaining 26 days.

Relative Humidity - All steam environment in excess of 2500F; greater than90% for other conditions.

Chemical Spray - The chemical solution consisted of 3000 ppm Boron as boricacid in solution with 0.064 molar sodium thiosulfate buffered with sodiumhydroxide. The chemical solution pH was maintained between 9.5 and 10.5.

j. Results: One of the valves malfunctioned during thermal aging. The valvedeveloped excessive seat leakage both in the energized and deenergizedstate. This was later determined to be caused by dirt in the valve. Thesource of dirt was the iron pipe used in the cylinder port as piping and anadditional length used to simulate an accumulator.

Other than the above malfunction, the valves sucesafully completed thesequential type tests and the baseline/functional tests.

2. Qualified Life - The solenoid valves have a qualified life of 40 yearsand 40,000 cycles, providing the maintenance schedule outlined in paragraph4 is followed. Open and close completes one cycle. However, due to theself-heating nature of solenoid valves, the temperature rise associatedwith a continuously energized solenoid vklve must be accounted for in thequalified life calculation. There are two areas affected by this heating:(1) the coil sees an increase of 105*C (221*F) above ambient and (2) theelastomeric discs see an increase of 45*C (11lVF) above ambient. Thesetemperature increase values come from Franklin Research Center's "TestProgram and Failure Analysis of Class lE Solenoid Valves" (NUREG/CR-3424, F-C5569-309/315). F-

Preparer/Date AŽV7 ,Z4 Z02-/ EQS No. WBNEEB0039Appendix 2 Rev -3

Reviewer/Date A 7- -F/ Sheet 6 of 11

Based on the above information, a separate qualified life must be calculated for boththe coil and the disc. The following qualified life calculations, which are based onthe Arrhentius equation, are for valves to be used at a normal ambient operatingtemperature of 10*F (43.3*C):

Ll- L2e [K (T1 T2 )

COILS

In Franklin Research Center's "Test Program and Failure Analysis of Class 1ESolenoid Valves" (NUREG/CR-3424, F-C5569-309/315), the solenoid coils were aged attwo rates: 150*C (302*F) for 9.3 days (223.2 hours) and 131*C (268*F) for 15.3 days(367.2 hours).

Ll- Qualified life (first aging rate)

L2- Accelerated (test) life - 223.2 hours

E - Activation energy - 1.00 eV

K - Boltzmann' s constant - 8.617 x 10-5 eV/*K

Tj- Qualified temperature (ambient + 105*0C - 148.3*C

T2- Elevated (test) temperature -1500C + 1050C - 2550C

e - Base of natural logarithms

Ll'= Qualified life (second aging rate)

L2 '- 367.2 hours

E - 1.00 eV

K - 8.617 x 10-5 eV/GK

Ti'- 43.3*C + 105*C -148.30C

T2 '- 131*C + 105*C -236*C

e - Base of natural logarithms

Ll (total) - Total qualified life Ll + L1' -11.44 years

E~ F

Preparer/Date ________________ EQS No. WBNEEB0039

Revevr/DteAppendix 2 Rev 3

Revewr/at YC..~ ~4~i Sheet 7 of 11

DISCS

In ASCO tesit report AQS-21678/TR, supplement 3, the entire valve was aged at 1310C(268'F) for 12 days (288 hours).

Ll- Qualified life

L2- Accelerated (test) life - 288 hours

E - Activation energy - .94 eV

K - Boltzmann' s constant - 8.617 x 1i-5 eV/*K

Ti - Qualified temperature - 110*F

T2- Elevated (test) temperature - 1310C + 450C - 1760C

e - Base of natural logarithms

Ll- 11 .945 years

For the valves to be used at a normal ambient operating temperature of 120*F

(48.9*C), the following qualified life calculations, which are based on the Arrhenius

equation, apply:

COILS

Ll- Qualified life (first aging rate)

L2- Accelerated (test) life - 223.2 hours

E Activation energy - 1.00 eV

K -Boltzmann' s constant - 8.617 x 10-5 eV/*K

Ti Qualified temperature (ambient + 105C) - 153 .9%

T2 Elevated (test) temperature -150% + 1050C - 255*C

e Base of natural logarithms

FL 1

Preparer/Date4- EQS No. WBNEEB0039Appendix 2 Rev 3

Reviewer/Date 92 4?k Sheet 8 of 11.

Ll'o- Qualified life (second aging rate)

L2 '- 367.2 hours

E - 1.00 eV

K - 8.617 x 10-5 eV/ K

T11- 48.9*C + 105*C -153.9*C

T2 '- 131*C + 105*C -236*C

e -Base of natural logarithms

Ll (total) - Total qualified life - Ll+ Ll' 7.973 years

DISCS

In ASCO test report AQS-21678/TR, supplement 3, the(268*F) for 12 days (288 hours).

entire valve was aged at 131*C

Ll- Qualified life

L~2 - Accelerated (test) life -288 hours

E - Activation energy - .94 eV

K - Boltzmann' s constant - 8.617 x 10-5 eV/*K

T1 Qualified temperature -120*F

T2- Elevated (test) temperature - 1310C + 450C - 1760C

e - Base of natural logarithms

Ll= 7.56 years

3. Installation - Valves should be installed such that the axis of the coil remainsin the vertical and upright position.

4. Maintenance Requirements - The qualified life depends on the valve being cycledat least every 16-18 months to ensure proper opening and closing. Coils shallbe replaced every 11.44 years and elastomeric components shall be replaced every11 .945 years when solenoid valves are subjected to a normal operating ambienttemperature of 110*F. Coils shall be replaced every 7.973 years and elastoaieric

Preparer/Date/ - /4ý~ ~9)4

Reviewer/Date 4 4~a ~EQS No. WBNEEB0039Appendix 2 Rev 3Sheet 9. of 11

components shall be replaced every 7.56 years when the valves are subjectedto a normal operating ambient temperature of l20*F. In addition, ASCOrecoxmmends that when the solenoid valves reach 20,000 cycles,ithat they berebuilt using the applicable spare parts kit and spare coil kt 4 .

5. Valves are qualified per IEEE Standard 323-1974, IEEE Standard 382-1972, IEEEStandard 344-1975, and applicable portions of NUREG-0588 for the environment inwhich they are required to operate providing the maintenance schedule inparagraph 4 above is followed. By mathematical analysis, the qualified post-DBEoperating time can be extended to 996 days for the Annulus, 890 days for UpperContainment, and 261 days for Lower Containment.

4ASCO Test Report AQR67368/Rev. 0, Appendix C, Page C-2

EFFECTIVEDATE

OCT-

Preparer/Date ,L 2 AA/ T -f 5 / EQS No. WBNEEB0039

9_ ZýC_ Appendix 2 Rev -3Reviewer/Date /P.V~.4 A.9Z -)iSheet 10 of 11

Calculationis - Post Accident Life

Calculations are based on the Arrhenius equation which states:

ýI T- T2]

Ll L2 e

Where:

El- Lowest Activation Energy

Ll - Qualified life

L2- Accelerated (test) life

K -Boltzmann's constant, 8.617 x 10-5 eV/'OK

Tj-Qualified temperature, absolute

T2- Elevated (test) temperature, absolute

e -Base of natural logarithms

Calculate qualified post-accident life for valves located in the Annulus(worst-case accident temperature profile for valves listed in Appendix 1 underHeading I).

L2- 26 days (AQS21678/TR Rev. A, figure 2, page 4-21)

El-0.94 eV (AQR67368, Appendix B, page B-3)

Ti- 128OF (temperature profile, WBN environmental data drawings 47E235-44,150OF @ 3 x 102 sec - 1050F @ 30 days/2 + 105 0F)

T2-200OF (AQS21678/TR Rev. A, Figure 2, page 4-21)

L2- 26 x 24 - 624 hours

Ll- 2.73 years - 996 days

L VE

Preparer/Date/1ŽAi ~ 9.)'-' EQS No. WBNEEB0039F'Appendix 2 Rev 3

Reviewer/Date /Z(f Z 4-& Sheet 11 of 311

Calculate qualified post-accident life for valves located in the Uppercompartment of containment (worst-case accident temperature profile for valves listedin Appendix 1 under Heading II).

L2 -26 days (AQS21678/TR Rev. A, figure 2, page 4-21)

Ei 0.94 eV (AQR67368, Appendix B, page B-3)

T- 130OF (temperature profile, WEN environmental data drawings 47E235-41,160OF @ 3 x 103 sec - 100OF @ 30 days/2 + 1000F)

T2 200OF (AQS21678/TR Rev. A, Figure 2, page 4-21)

L2 26 x 24 -624 hours

Lj- 2.438 years -890 days

Calculate qualified post-accident life for valves located in the lowercompartment of containment (worst-case accident temperature profile for valves listedin Appendix I under Heading III).

L2- 26 days (AQS21678/TR Rev. A, Figure 2, page 4-21)

Ei-0.94 eV (AQR67368, Appendix B, page B-3)

Ti- 152.50F (temperature profile, WEN environmental data drawings 47E235-45,190OF @ 6 x 103 sec - 115 0F @ 30 days/2 + 115 0F)

T2-200OF (AQS21678/TR Rev. A, Figure 2, page 4-21)

L2- 26 x 24 - 624 hours

L1- .717 years -261 days

044143.10

A

f1~o % 3* ____ Nso. WBNEEB0044

Preparer/bate $c ~ ~ ~ ~See Appendix 1

Reviewer/D~ate 17- -q -g 1 0qYO 116"

'N EUIJE?1 nOMTT-FICATFI S=E (EOS)

Manufactirer and Model No. See Appendix. V

Verification of Table Information (Table See Appendix 1

-IL- The equipmient has been identified as per TVA ID numberdesignations (such as, NOV,, SOV).

X.L Zlaot~im - The location has been identified (such as, inside primarycontainment, annulus, individually cooled rooms, general spaces,, or areaaffected by HELB outside primary contairmient).

X Q Den - A unique TVA MD numrber has been assigned (such as, l-FSV-68-308)...L Functio±n - A functional description of the compjonent has been given (such as,

steam generator blowdowrn).X QmntrAct No.. Manufacturer, and Modiel No. - The contract numiber, manufacturer,

and model numb~er have been given... Abnormal or Accident Enwironmet - All abnormal or accident enviromnental

conditions applicable to this equipmient have been identified either in tables orby references to figures fromi tables.

x EnvircrMet to Which Qualified _ The environment to which the equipment has been

qualified is addressed in either the tables or the environmental analysisattached.

-I- cat - A category of a,, b, c. or d has been defined for theequipment.

_J_. Operation and Accuracy Reqired and Demronstrated - The operationand accuracy required and demonstrated have been defined.

qualification Status (check if arlicable. NA if not)Oualified Life (If eauireoent is qualified, indicate the qualified life with anumierical entry): 40 years

X qualification Report and Metho - A qualification report and the method of

qualification has been identified on the Table Input Data Sheet (TIDS).X Enviromental Analysis - An environmental analysis has been done, attached to

the BOS, and independently reviewed by the responsible organization.N/A iualification by Similarity (if applicable) - A justification for qualification

1by similarity is attached to the EQS considering all the above factors andreferenced to the appropriate tables.

-ýL qalification of Several FxaCt ConMonets (If applicable) - When an EDS is usedf or more than one item, a list of all exact components is given as an appendixwith all references to appropriate tables with justification for qualificationconsidering all the above factors.

N/A interim qualification (If applicable) - (Open item) - Component has beendetermined to'be qualified only for a limited interim operation, an NCR hasbeen written,, and plan of action has been determined to yield a qualifiedcomponent.Term of Interim QualificationNCR No.

N/A R ilfe gM t- (open item) - (If applicable) - Compo~nent has beendetermined to be unqualified; the following is attached to EDS: NCR number,reason for non-qualification, and justification of continued operation

*Due to the Nextensive changes from Revision 2, revision bars are not used.~

Preparer/Date eLe2 -,

Reviewer/Date z2",g ,21-aUJ2 JOY.P

EQS No. _Wgwp&~'AnnAAAppendix 1 RevSheet I Of

Manuf acturer

Component

AS CO

Solenoid Valves

Component UNID Model No. Table/Sheet

l-FSV-32-80B-A 206-380-2Ru 1 -11 i-VINFFRflflfI

2-FSV-32-81 B-A WP11T8262D22 3 A 1-5,WRNF.FRAnfl

l-FSV-32-102B-B 206-380-2RI A-1 1-9.jwR~wyEi~nnnf1

2-FSV-32-103B-B WPHT8262D??'L 31-5,wRNFFyRnnni

l-FSV-32-llOB-A 206-380-3Ru 'Li 1-5,WRNFF.Rnnnfi

2-FSV-32-ll lB-B WPHT8262D22 'Li 1-s/wRNFF.Rflfli

Preparer/Date lle% A" i/'2-4 EQS No. WBNEEB0044Appendix 2 Rev 3

Reviewer/Date O Sheet 1- of 7

UNIT 1 ONLY

I.1. The solenoid valves in Appendix 1 are ASCO model 206-380-2RU and206-380-3RU. They are located in the Reactor Building (Annulus). Asdetailed in EN DES Calculation NEB 840314 222 for the Control AirSystem, these valves are not required to operate after the start of aLOCA or HELB. However, they must not fail in a manner detrimental toplant safety for 100 days after the start of a LOCA or Main Steam orMain Feedwater line break, or for 1 month after a line break in theResidual Heat Removal or Chemical Volume Control Systems.

2. The solenoid valves are subject to LOCA and HELB conditions.They are exposed to the following environments:1

Normal Abnormal Accident

Temperature:Pressure:Relative Humidity:Radiation:

Spray/Flooding:

11 0OFAtm(C-)80%2x107 rads(40 yr TID)NIA

3. ASCO has tested the solenoid valves to the following environment:

Temperature:Pressure:Relative humidity:Radiation:Spray:

346OF110 psig100%2x108 rads3000 ppm Boron/pH 9-11

'See WBN Environmental Data Drawing 47E235-44R0.

- U

1 20OFAtm(-)90%N/A

NIA

150OFAtm(-)100%5xl0 7rads

N/A

Preparer/Date/c/ýA ?ai- EQS No. WBNEEBOO44-Appendix 2. Rev 3

Reviewer/Date 7- 'V Sheet 2 of -7

I.1. Qualification Testing:

a. ASCO has tested the 206-380 and 206-381 series solenoid valves to therequirements of IEEE Standard 323-1974 and KUREG-0588. The test criteriaand results are documented in ASCO test report AQS21678/TR, Revision A,including supplement 3. All qualification tests were performed at test

levels or conditions in excess of known maximum application requirements.These margins are in accordance with the margins suggested by IEEE Standard323-1974.

b. Seven solenoid valve samples representing six generic families of valves,including the 206-380 and 206-381 series, were subjected to sequentialexposures of elevated temperature, radiation, wear aging, seismicsimulation, vibration endurance, accident radiation, and a 30-day LOCAsimulation. Baseline functional tests were performed before the start and

after each sequence of the test exposure with the exception of coildielectric and insulation resistance measurements which were taken beforethermal aging, after accident radiation, and after LOCA exposure. The

valves were energized and deenergized at high and low pressures during the

test phases (except radiation) and valve leakage monitored.

c. Baseline/Functional Test: Baseline/Functional tests consisted ofmeasurement of coil excitation, seat leakage at high and low pressures,noise test, operational test, and external leakage test before and after all

phases of type tests. Measurement of insulation resistance and coil

dielectric test was performed in the as received condition and aftercompletion of accident radiation and LOCA simulation. Valves were energizedand deenergized and their operation monitored during test (exceptradiation).

d. Thermal aging: The valves were subjected to an aging temperature of 268 0F

for a test duration of 12 days. They were cycled (deenergized for fiveminutes and then energized) every six hours.

e. Radiation: The valves were subjected to cobalt 60 (GAMMA) radiation at anexposure rate of less than one megarad per hour. Total integrated dosereceived was 50 megarads.

f. Wear aging: The valves were electrically cycled 40,000 times at maximumpressure differential.

g. Seismic Simulation/Vibration Endurance: The valves were subjected to acombined SSE and fragility test. The input g. level was 7 g's. The testwas performed with the valves energized and deenergized and with high andlow pressure. The leakage rate was monitored.

Preparer/Date/ý M z6 /\ A EQS No. WBNEEB0044Appendix 2 Rev3

Reviewer/Date S/-E/2.d. '-4V Sheet 3 of 7

h. Accident Radiation: The valves were subjected to cobalt 60 (GAMMA)radiation at an exposure rate of less than one megarad per hour. Valvesrtceived an additional accumulated dose of 150 megarads for a total.Integrated dose of 200 megarads received in two stages.

i. LOCA Simulation: The valves were subjected to a simulated loss-of-coolantaccident (LOCA) by exposure to steam and to chemical spray for 30 days.LOCA simulation conditions were as follows:

Temperature - Maximum of 3460F for a total period of six hours followed by astep decrease to 200OF within four days followed by post-DBE conditions of200OF for the remaining 26 days.

Pressure - Maximum of 110 psig for a total period of six hours followed by astep decrease to 10 psig within four days followed by post-DBE conditions of10 psig for remaining 26 days.

Relative Humidity - All steam environment in excess of 2500F; greater than90% for other conditions.

Chemical Spray - The chemical solution consisted of 3000 ppm boron as boricacid in solution with 0.064 molar sodium thiosulfate buffered with sodiumhydroxide. The chemical solution pH was maintained between 9.5 and 10.5.

j. Results: One of the valves malfunctioned during thermal aging. The valvedeveloped excessive seat leakage both in the energized and deenergizedstate. This was later determined to be caused by dirt in the valve. Thesource of dirt was the iron pipe used in the cylinder port as piping and anadditional length used to simulate an accumulator.

Other than the above malfunction, the valves sucessfully completed thesequential type tests and the baseline/functional tests.

2. Qualified Life - The solenoid valves have a qualified life of 40 years at 110*Fand 40,000 cycles, providing the maintenance schedule outlined in paragraph 4 isfollowed. Open and close completes one cycle. However, due to the self-heatingnature of solenoid valves, the temperature rise associated with a continuouslyenergized solenoid valve must be accounted for in the qualified lifecalculation. There are two areas affected by this heating: (1) the coil seesan increase of 105*C (2210F) above ambient and (2) the elastomeric discs see anincrease of 45*C (113*F) above ambient. These temperature increase values comefrom Franklin Research Center's "Test Program and Failure Analysis of Class 1ESolenoid Valves" (NUREG/CR-3424, F-C5569-309/315).

Preparer/Date ZA44 EQS No. WBNEEB0044/Appendix 2 Rev -3

Reviewer/Date /M-,-Z&&~a) Sheet 4 of 7

Based on the above information, a separate qualified life must be calculated forý boththe coil aliiI the disc. The following qualified life calculations, which are based onthe Arrhenius equation, are for valves to be used at a normal ambient operatingtemperature of 110*F (43.3*C):

Ll-L2e [K l T2]

COILS

In Franklin Research Center's "Test Program and Failure Analysis of Class 1ESolenoid Valves" (NUREG/CR-3424, F-C5569-309/315). the solenoid coils were aged attwo rates: 150*C (3020F) for 9.3 days (223.2 hours) and 131*C (268*F) for 15.3 days(367.2 hours).

Ll- Qualified life (first aging rate)

L2 Accelerated (test) life -223.2 hours

E - Activation energy -1.00 eV

K - Boltzmann' s constant - 8.617 x 10-5 eV/*K

Tj-Qualified temperature (ambient +- 105*C) - 148.3*C

T2 - Elevated (test) temperature -1500C + 1050C - 2550C

e - Base of natural logarithms

Li'- Qualified life (second aging rate)

L2 - 367.2 hours

E - 1.00 eV

K -8.617 x 10-5 eV/OK

Ti1 = 43.3*C + 105% - 148.3*C

T2 '- 1310C + 1050C - 236 0C

e - Base of natural logarithms

Ll (total) -Total qualified life -Ll + 1, - 11.44 years

Preparer/DateZ ea4--- I/ EQS No. WBNEEB0044Appendix 2L Rev3

Reviewer/Date 4? 4. D - 7 Sheet 5 of 7

DISCS

In ASCO tebt report AQS-21678/TR, supplement 3, the entire valve was aged at 131*C(268*F) for 12 days (288 hours).

Ll- Qualified life

L2- Accelerated (test) life -288 hours

E - Activation energy - .94 eV

K -Boltzmann' s constant - 8.617 x 10-5 eV/*K

Tl- Qualified temperature - 110*F

T2-Elevated (test) temperature - 1310C + 450C - 1760C

e -Base of natural logarithms

Ll- 11.945 years

3. Installation - Valves should be installed such that the axis of the coil remainsin the vertical and upright position.

4. Maintenance Requirements - The qualified life depends on the valve being cycledat least every 16-18 months to ensure proper opening and closing. Coils shallbe replaced every 11.44 years and elastomeric components shall be replaced every11.945 years when solenoid valves are subjected to a normal operating ambienttemperature of 110*F. In addition, ASCO recommends that when the solenoidvalves reach 20,000 cycles, that they be rebuilt using the applicable spareparts kit and spare coil kit2 .

5. Valves are qualified per IEEE Standard 323-1974, IEEE Standard 382-1972, IEEEStandard 344-1975, and applicable portions of NUREG-0588 for the environment inwhich they are required to operate, providing the maintenance schedule inparagraph 4 above is followed. By mathematical analysis, the qualified post-DEEoperating time can be extended to 2.73 years.

2ASCO Test ReportAQR67368/Rev 0,Appendix C, Page C-2

LO~

Preparer/Date 42,w A '-2•`:fr'9 EQS No. WBNEEB00441ýApni 2 Rev3

Reviewer/Date - 64She of 7

Calculati'ous - Post Accident Life

Calculations are based on the Arrhenius equation which states:

Ll L2 e

Where

Ll-Qualified life

L2- Accelerated (test) life

El- Worst case activation energy, eV

K - Boltzmann's constant, 8.617 x 10-5 eV/OK

T- Qualified temperature, absolute

T2- Elevated (test) temperature, absolute

e - Base of natural logarithms

Calculate qualified post-accident life for valves located in lower compartment(worst-case accident temperature profile for valves listed in Appendix 1):

L2- 26 days (AQS21678/TR Rev. A, figure 2, page 4-21)

Ei- 0.94 eV (AQR67368, Appendix B, page B-3)

T -128OF (temperature profileI WEN enviroinmental data drawings 47E235-44, 150OF@ 3x102 seconds - 1050F @ 2.59x,06 sec/2 + 1050F)

T2-200OF (AQS21678/TR Rev. A, figure 2, page 4-21)

L2- 26 x 24 - 624 hours

L1 - 2.73 years

'd -r-ýZ EQS No. WBNEEB0044Prearr/ate4 Aga gezm Z Appendix 2 Rev 3Reviewer/Date /~..cA. 4 -Sheet 7- of -7

UNIT 2 ONLY

1. The solenoid valves in Appendix 1 are ASCO Model WPHT8262D22. They arelocated in the Reactor Building (Annulus). They are required to notfail in a manner detrimental to plant safety for one month to 100 daysafter the start of an accident (depending on which DBA occurs), per ENDES Calculation NEB 830204 228.

2. The solenoid valves are subject to LOCA and HELB conditions. They areexposed to the following environmxents:3

Normal Accident

Temperature: 110OF 150OFPressure: Atm AtmRelative Humidity: 80% 100%Radiation: 2.xl0 7 rads 5x107 rads

(40 yr TID)Spray/Flooding: N/A N/A

3. The manufacturer's specifications for the solenoid valves are:

Temperature: 176 0FPressure: AtmRelative Humidity: NEHA 6 EnclosureRadiation: 7xl06 rads

4. The temperature, pressure and relative humidity to which the solenoidvalves are exposed are within the manufacturer's specifications. However,the valves would be exposed to a total radiation dose of 7 x 107 radswhich is much higher than the manufacturer's specifications.

5. The above information indicates that the solenoid valves are not qualifiedfor their accident radiation envirornment, as required by NUREG-0588.Therefore, TVA will replace these devices per 1OCFR5O.49, as determinedby NCR WBNEEB8128.

3Per SQN/WBN Environmental Data Drawing 47E235-47.

034145.01

E~ E

EDA T E

Revision 1

Prepaxer/4atej . ý. Q ýz16-9 I -It-

Rvewe r/on -Unit RD. 1JQS RD. WBNEEBOO46TVA IDNo.

See Appendix 1

/ / BN Mt1IP(D1T 0 PFICATrION COMM-=)

Manufacturer and Model No. See Appendix 1

Verification of r~ale Information (Table See Appendix 1

ft. g - Tte equipment has been identified as per WA ID n~umberdesignations (such as, W7J, SM J.

X Lootjign - The location has been identified (such as, inside primarycontainment;, annulus, individually cooled rows9, general spaces, or areaaffected by HELB outside primary contaiunment).

___Q~ n - A unique WVA M number has been assigned (such as, l-F'SV-68-308).X Funtion- A functional description of the component has been given (such as,steam generator blowow).

XL ContrAct No.. Manu acturer. and Model No. - The contract number,, manufacturerl,and model number have been given.

__L Abn~ormal or Accident Environvent - All abnormal or accident envirormentalconditions applicable to this equipment have been identified either in tables or1by references to figures from tables.

-Y Environiment to Which Qualifie - The environment to which the equipment has beenqualified is addressed in either the tables or the environmental analysisattached.

_-L at - A category of a, b,, c, or d has been defined for theequipm~ent.

-Z 9eration and Accuracy Required and Deimonstrated - The operationand accuracy required and demonstrated have been defined.

Oualification Status (check if Aaplicable. NA if not)Quaified~ -ife (If equipmient is qualified, indicate the qualified life with a

Xnumerical entry): 4oyrX uali ication R&port and Mlethod - A qualification report and the method ofXqualification has been identified on the Table Input Data Sheet (TIDS).X &mirmna~ntal Anaygis - An environmental analysis has been done, attached to

the HOS, and independently reviewed by the responsible organization.NA Cialificatioi by Simil~arit (if applicable) - A justification for qualification

by similarity is attached to the EDS considering all the above factors andx referenced to the appropriate tables.

__ ualification of Several Exact Ccxrponets (If applicable) - When an EDS is usedfor more than one item, a list of all exact ccmqxents is given as an appendixwith all references to appropriate tables with justification for qualificationconsidering all the above factors.

N~A Interim Oualification (If applicable) - (Open item) - Component has beendetermined to be qualified only for a limited interim operation, an NCR hasbeen written, and plan of action has been determined to yield a qualifiedCON ~awt.Term of Interim Qua~lification____________________NCR No.

NA Om~fe ~p~ - (Open item) - (If applicable) - Ccmponent has beendetermined to be unqualified; the followiing is attached to HOS: NCR number,reason for non-qualification, and justification of continued operation.

*Due to the extensive changes from Revision 0, revision bars are not used.

Preparer/Dat ____________

Revi ewer/Date A/A~3 4 4~ '-C~

Manuf act urer

Component

EQS No. WBNEEB0046Appendix x1 ReSheet Tl Of I

AS CO

Solenoid Valves

A

________________________________________ _______________________________________ I ________________________________________

4 Component UNID Model No. Table/Sheet

1-FSV-30-8-B X-206-381-3RF 3. ll-4/WBNEEB0012

il-FSV-30-1O-A X-206-381-3RF 3.1l-4/WBNEEB0012

Preparer /Datr/]'2zŽ ' zo k Fgg ~

Reviewer/Date /CPd 4 ~b... -24- 70Ii

EQS No. WBNEEB0046Appendix 2 Rev 1Sheet 1 of 6

I.1. The solenoid valves in Appendix 1 are ASCO model X-206-381-3R.F. Theyare located in the Upper Compartment at elevation 757'. As detailed inEN DES Calculation NEB 840213 218 for the Containment VentilationSystem, these valves are required to operate for 5 minutes and not failin a manner detrimental to plant safety for 100 days after the start ofa LOCA or line breaks in either Main Steam or Feedwater lines. Theyare also required to operate for 5 minutes and not fail in a mannerdetrimental to plant safety for one month after breaks in either RHR orCVCS lines.

2. These solenoid valves are required to operate in the followingenvironmentl:

Normal Abnormal Accident

Temperature:Pressure:Relative Humidity:Radiation:

Spray/Flooding;

11 0OF14.7 psia80%

£.3.5x104 rads(40 yr TID)N/A

120OF14.7 psia90%N/A

160OF26.4 psia100%1x108 rads

Spray only

3. ASCO has tested this valve to the following environment:

Temperature:Pressure:Relative Humidity:Radiation:Spray:

346OF110 psig100%2 x 108 rads3000 ppm BORON/pH 9-11

1 Per WBN Environmental Data Drawing 47E235-41R0.

Preparer/Date/,(/K3ýd44/,/""'-z6-1/,, EQS No. WBNEEB0046

Reviewr/Dat Appendix 2 Rev -1ReieerDae 'Q ~5~2-1, Sheet. 2 of 6

I.1. Qualification Testing:

a. AýSCO has tested the 206-380 and 206-381, series solenoid valves to therequirements of IEEE Standard 323-1974 and NUREG-0588. The test criteriaand results are documented in ASCO test report AQS21678/TR, Revision A,including supplement 3. All qualification and tests were performed at testlevels or conditions in excess of known maximum application requirements.These margins are in accordance with the margins suggested by IEEE.Standard323-1974.

b. Seven solenoid valve samples representing six generic families of valves,including the 206-380 and 206-381 series, were subjected to sequentialexposures of elevated temperature, radiation, wear aging, seismicsimulation, vibration endurance, accident radiation, and a 30-day LOCAsimulation. Baseline functional tests were performed before the start andafter each sequence of the test exposure with the exception of coildielectric and insulation resistance measurements which were taken beforethermal aging, after accident radiation, and after LOCA exposure. Thevalves were energized and deenergized at high and low pressures during thetest phases (except radiation) and valve leakage monitored.

c. Baseline/Functional Test: Baseline/Functional tests consisted ofmeasurement of coil excitation, seat leakage at high and low pressures,noise test, operational test, and external leakage test before and after allphases of type tests. Measurement of insulation resistance and coildielectric test was performed in the as received condition and aftercompletion of accident radiation and LOCA simulation. Valves were energizedand deenergized and their operation monitored during test (exceptradiation).

d. Thermal aging: The valves were subjected to an aging temperature of 268OFfor a test duration of 12 days. They were cycled (deenergized for fiveminutes and then energized) every six hours.

e. Radiation: The valves were subjected to cobalt 60 (GAMMA) radiation at anexposure rate of less than one megarad per hour. Total integrated dosereceived was 50 megarads.

f. Wear aging: The valves were electrically cycled 40,000 times at maximumpressure differential.

g. Seismic Simulation/Vibration Endurance: Th~v valves were subjected to acombined SSE and fragility test. The inpv~t g. level was 7 g'ns. The testwas performed with the v:alves energized and deenergized and with high andlow pre~sure. The le .rate was monitored.

Preparer/Date Z 1?2_7\&2A.fl4QS No. WBNEEB004

Appendix 2 Rev -1Reviewer/Date Sheet 3 of -6

h. Accident Radiation: The valves were subjected to cobalt 60 (GAMMA)radiation at an exposure rate of less than one megarad per hour. Valvesreceived an additional accumulated dose of 150 megarads for a totalintegrated dose of 200 megarads received in two stages.

i. LOCA Simulation: The valves were subjected to a simulated loss-of-coolantaccident (LOCA) by exposure to steam and to chemical spray for 30 days.LOCA simulation conditions were as follows:

Temperature - Maximum of 346OF for a total period of six hours followed by astep decrease to 200OF within four days followed by post-DBE conditions of200OF for the remaining 26 days.

Pressure - Maximum of 110 psig for a total period of six hours followed by astep decrease to 10 psig within four days followed by post-DBE conditions of10 psig for remaining 26 days.

Relative Humidity - All steam environment in excess of 25007; greater than90% for other conditions.

Chemical Spray - The chemical solution consisted of 3000 ppm boron as boricacid in solution with 0.064 molar sodium thiosulfate buffered with sodiumhydroxide. The chemical solution pH was maintained between 9.5 and 10.5.

j. Results: One of the valves malfunctioned during thermal aging. The valvedeveloped excessive seat leakage both in the energized and deenergizedstate. This was later determined to be caused by dirt in the valve. Thesource of dirt was the iron pipe used in the cylinder port as piping and anadditional length used to simulate an accumulator.

Other than the above malfunction, the valves sucessfully completed thesequential type tests and the baseline/functional tests.

2. Qualified Life - The solenoid valves have a qualified life of 40 years at 110*Fand 40,000 cycles, providing the maintenance schedule outlined in paragraph 4 isfollowed. Open and close completes one cycle. However, due to the self-heatingnature of solenoid valves, the temperature rise associated with a continuouslyenergized solenoid valve must be accounted for in the qualified lifecalculation. There are two areas affected by this heating: (1) the coil seesan increase of 105*C (221*F) above ambient and (2) the elastomeric discs see anincrease of 45*C (113*F) above ambient. These temperature increase values comefrom Franklin Research Center's "Test Program and Failure Analysis of Class lESolenoid Valves" (NUREG/CR-3424, F-C5569-369/315).

Based on the above information, a separate qualified life must be calculated for boththe coil and the disc. The following qualified life calculations, which are based onthe Arrhenius equation, are for valves to be used at a normal ambient operatingtemperature of 110*F (43.3*C):

F -4

Preparer/Date /,57-Z -,f EQS No. WBNEEB0046Appendix 2 Rev -

Reviewer/Date A~~& ~ ~Sheet 4 of 6

Ll- L2e ti Tj T2)

COILS

In Franklin Research Center's "Test Program and Failure Analysis of Class lESolenoid Valves" (NUREG/CR-3424, F-C5569-309/315), the Solenoid coils were aged attwo rates: 150*C (302*F) for 9.3 days (223.2 hours) and 131*C (268*F) for 15.3 days

Ll- Qualified life (first aging rate)

L2- Accelerated (test) life - 223.2 hours

E - Activation energy - 1.00 eV

K - Boltzmann' s constant -8.617 x 10-5 eV/*K

Tj- Qualified temperature (ambient + 105*C) - 148.3*C

T2-Elevated (test) temperature - 1500C + 1050C - 2550C

e -Base of natural logarithms

Ll'- Qualified life (second aging rate)

L2'- 367.2 hours

E - 1.00 eV

K - 8.617 x 10-5 eV/"K

Ti'= 43.3*C + 1050C =148.3*C

T2 '- 1310C + 1050C -236*C

e -Base of natural logarithms

Lj (total) - Total qualified life -Ll + Ll' -11.44 years

DA F CTEID A CT E~

Preparer/Date.,/1\S4A. , z•/'-i21-I EQS No. WBNEEB0046tAppendix 2 Rev 1

Reviewer/Datey9Id..g.4A.... Sheet 5 of 6

DISCS

In ASCO test report AQS-21678/TR, supplement 3, the entire valve was aged at 131*C(268*F) for 12 days (288 hours).

Ll - Qualified life

L2 - Accelerated (test) life - 288 hours

E - Activation energy - .94 eV

K - Boltzmann's constant - 8.617 x 1O-5 eV/*K

Tl- Qualified temperature - 110*F

T2- Elevated (test) temperature - 131PC + 450C - 1760C

e - Base of natural logarithms

4l - 11.945,years

3. Installation - Valves should be installed such that the axis of the coil remainsin the vertical and upright position.

4. Maintenance Requirements - The qualified life depends on the valve being cycledat least every 16-18 months to ensure proper opening and closing. Coils shallbe replaced every 11.44 years and elastomeric components shall be replaced every11 .945 years when solenoid valves are subjected to a normal operating ambienttemperature of 1100F. In addition, ASCO recommends that when the solenoidvalves reach 20,000 cycles, that they be rebuilt using the applicable spareparts kit and spare coil kit2 .

5. Valves are qualified per IEEE Standard 323-1974, IEEE Standard 382-1972, IEEEStandard 344-1975, and applicable portions of NUREG-0588 for the environmient inwhich they are required to operate, providing the maintenance schedule inparagraph 4 above is followed. By mathematical analysis, the qualified post-DBEoperating time can be extended to 890 days.

2ASCO Test ReportAQR67368/Rev. 0Appendix C, Page C-2

Preparer/ Date/, 3AaŽ2Al dj•A ,/ý96P 2 EQS No. WBNEEB0046Appendix 2 Rev I

Reviewer/Dateý, L- F a Sheet 6 of 6

Calculations - Post Accident Life

Calculations are based on the Arrhenius equation which states:

[K Tj T 2]Ll- L2 e

Where

Ll- Qualified life

L2- Accelerated (test) life

El- Worst case activation energy, eV

K - Boltzmann's constant, 8.617 x 10-5 eV/OK

Tj-Qualified temperature, absolute

T2 Elevated (test) temperature, absolute

e - Base of natural logarithms

Calculate qualified post-accident life for valves located in upper compartment

(worst-case accident temperature profile for valves listed in Appendix 1):

L2= 26 days (AQS21678/TR Rev. A, figure 2, page 4-21)

El- 0.94 eV (AQR67368, Appendix B, page B-3)

Ti- 130OF (temperature profile, liEN environmiental data drawings 47E235-41, 160OF

@ 3xl0 3 seconds - I000F @ 30 days/2 + 1000F)

T2 - 200OF (AQS21678/TR Rev. A, figure 2, page 4-21)

L2- 26 x 24 - 624 hours

Ll- 2.438 years - 890 days

014143 .02

EFFEECT'IVE

Revision 1*

Prepareri1bat ý- -

Reviewer/bat6 -, z_ - - - •

Unit No. 1_____

BOS No. WRIFlAJ-4-TVA Mh ND.

See Appendix 1

Manufaturer anModel No ASCO Model X206-381-R

Verification of T able Information (Table See Appendix 1

X umtT - The equipmzent has been identified as per WVA ID numberdesignations (such as, NOV,, SMJ).

X Lation - The location has been identified (such as, inside primarycontainment, annulus, individually cooled rooms, general spaces, or areaaffected by HELB outside prlimary contairnment).

--L Ggnmn± - A unique MV ID number has been assigned (such as, l-FSV-68-308)._1_ Functioni - A functional description of the coumponent has been given (such as,

steam generator blcwdown).__ Qmntract No.. ManUfacturer. and Model No. - The contract number, manufacturer,

and model number have been given.__I Abnormal or Accident Environment - All abnormal or accident environmental

conditions applicable to this equipment have been identified either in tables orby references to figures from tables.En. vironment to Mhich Oualifie - The environment to which the equipment has beenqualified is addressed in either the tables or the environmental analysisattached.Cat ~a ~ - Acategory of a,b,c, or dhasbeen defined for theequipment.

*.X Operation and Accuracy Reqired and Dermonstrated - The operationand accuracy required and demonstrated have been defined.

flualificaticri Status (check if A~,licable. NA if not)Qualified Life (If equipment is qualified, indicate the qualified life with anumerical entry) : 0 rp

X OuAlification Report and Mthod - A qualification report and the method ofqualification has been identified on the Table input Data Sheet (TIDS).

X ivironnetal Analysis - An environmental analysis has been done, attached tothe BOS, and independently reviewed by the responsible organization.

NA- Qualification by Similarity (if applicable) - A justification for qualification1by similarity is attached to the BOS considering all the above factors andreferenced to the appropriate tables.

X ujalification of SeVeral Exact Cogrponets (If applicable) - When an BDS is usedfor more than one item, a list of all exact components is given as an appendixwith all references to appropriate tables with justification for qualificationconsidering all the above factors.

-N& Interim qualification (If applicable) - (open item) - Ccxqjxnent has beendetermined to be qualified only for a limited interim operation, an NR~ hasbeen written, and plan of action has been determined to yield a qualifiedconioncent.Term of Interim Qualification_____________________NM ND.

NA D ~ fe Qp= - (Open item) - (If applicable) - Caqmonent has beendetermined to be unqualified; the following is attached to EDS: NCR number,reason for noin-qualification, and justification of continued operation.NCRNo. _ _ _ _ _ _

*Due to extensive changes from Revision 0, revision bars are not used E F 7-

r;-

Preparer/Date. •e , t,-2 /

- ~~Reviewer/Date 'a.9Zi4~

Manuf acturer ASCO

iComponent. Solenoid Valve

EQS No. WBNEEB0047Appendix I Rev 1Sheet 1 -Of..L...

LLJ

Component UNID Model No. Tabl e/Sheet

I l-FSV-30-15-B X206-381-3RF 3.1 1-4/WBNEEBOOIO

I l-FSV-30-40-A X206-381-3RF 3,11-4/WBNEEB0010

I I-FSV-30-50-B X.206-381-3RF 3,11-4/WBNEEBOOIlO

I l-FSV-30-52-A X206-381-3RF 3,11-4/WBNEEB001O

I 1-FSV-30-56-A X206-381-3RF 3.11-4/WBNEEBOOIO

II l-FSV-30-58-B X206-381-3RF 3,11-4/WBNEEB001O

I l-FSV-30-17-A X206-381-3RF 3.11-4/WBNEEB0010

II 1-FSV-30-20-A X206-381-3RF 3.1 1-4/WBNEEB001O

Preparer/Date 4 kh-rý

Reviewer/Date /A.I4~r.- Z-~

EQS No. WBNEEB0047Appendix 2 RevSheet 1 of 6

I. The solen~oid valves in Appendix 1 are ASCO model X20-381-3RF. Thedevices ~iarked I on Appendix 1 are located inside containment, lowercompartment (Elev 716, 720, and 744). The devices marked II onAppendix 1 are located inside containment, lower compartment instrumentroom (Elev 716 and 730). As detailed in EN DES Calculation NEB 840213218, the solenoid valves are required to operate for 5 minutes and notfail in a manner detrimental to plant safety for 100 days after thestart of a LOCA or breaks in either Main Steam or Feedvater lines.They are also required to operate for 5 minutes and not fail in amanner detrimental to plant safety for one month after breaks in eitherRHR or CVCS lines.

II. They are required to operate in the following environment1 :

Normal Abnormal Accident

Temperature:

Pressure:

Relative Humidity:

Radiation:

Spray/Flooding:

120OF (I)75 0 F (II)14.7 psia

80% (1)60% (11)2x107 rads (I)3.5x105 rads (II)(40 yr TID)N/A

130OF (I)120OF (II)14.7 psia

100% (1)90% (II)N/A

N/A

3270 F

26.4 psia (I)26.7 psia (II)100%

1K10 8 rads

(LOCA)

N/A

III. ASCO has tested this valve to the following environment:

Temperature:Pressure:Relative Humidity:Radiation:Spray:

346OF110 psig100%2x10 8 rads3000 ppm. BORON/pH 9-11

'Per WBN Environmental Data Drawings 47E235-42P1 and -45R0.

0*~

D K

V.-;.,

Preparer/Date /4 /i Z/9!VEQS No. WBNEEB0047Appendix 2 Rev 1

Reviewer/Date A le ýSet 2 o

IV. 1. Qualification Testing:

a. ASCO has tested the 206-380 and 206-381 series solenoid valves to the

requirements of IEEE Standard 323-1974 and NUREG-0588. The test criteria

and results are documented in ASCO test report AQS21678/TR, Revision A,

including supplement 3. All qualification and tests were performed at test

levels or conditions in excess of known maximum application requirements.

These margins are in accordance with the margins suggested by IEEE Standard

323-1974.

b. Seven solenoid valve samples representing six generic families of valves,

including the 206-380 and 206-381 series, were subjected to sequential

exposures of elevated temperature, radiation, wear aging, seismic

simulation, vibration endurance, accident radiation, and a 30-day LOCA

simulation. Baseline functional tests were performed before the start and

after each sequence of the test exposure with the exception of coil

dielectric and insulation resistance measurements which were taken before

thermal aging, after accident radiation, and after LOCA exposure. The

valves were energized and deenergized at high and low pressures during the

test phases (except radiation) and valve leakage monitored.

c. Baseline/Functional Test: Baseline/Functional tests consisted of

measurement of coil excitation, seat leakage at high and low pressures,

noise test, operational test, and external leakage test before and after all

phases of type tests. Measurement of insulation resistance and coil

dielectric test was performed in the as received condition and after

completion of accident radiation and LOCA simulation. Valves were energized

and deenergized and their operation monitored during test (except

radiation).

d. Thermal aging: The valves were subjected to an aging temperature of 268OF

for a test duration of 12 days. They were cycled (deenergized for five

minutes and then energized) every six hours.

e. Radiation: The valves were subjected to cobalt 60 (GAMMA) radiation at an

exposure rate of less than one megarad per hour. Total integrated dose

received was 50 megarads.

f. Wear aging: The valves were electrically cycled 40,000 times at maximum

pressure differential.

g. Seismic Simulation/Vibration Endurancel. The valves were subjected to a

combined SSE and fragility test. The input g. level was 7 g's. The test

was performed with the valves energized and deenergized and with high and

low pressure. The leakage rate was monitored.

Preparer/Date ______________ EQS No. WBNEEB0047Appendix 2 Rev 1

Reviewer/Date -00-2. a 2.45 Sheet 3- of 6

h. Accident Radiation: The valves were subjected to cobalt 60 (GAMMA)radiation at an exposure rate of less than one megarad per hour. Valvesreciived an additional accumulated dose of 150 megarads for a totalintegrated dose of 200 megarads received in two stages.

i. LOCA Simulation: The valves were subjected to a simulated loss-of-coolantaccident (LOCA) by exposure to steam and to chemical spray for 30 days.LOCA simulation conditions were as follows:

Temperature - Maximum of 346OF for a total period of six hours followed by astep decrease to 200OF within four days followed by post-DBE conditions of200OF for the remaining 26 days.

Pressure - Maximum of 110 psig for a total period of six hours followed by astep decrease to 10 psig within four days followed by post-DEE conditions of10 psig for remaining 26 days.

Relative Humidity - All steam environment in excess of 2500F; greater than90% for other conditions.

Chemical Spray - The chemical solution consisted of 3000 ppm boron as boricacid in solution with 0.064 molar sodium thiosulfate buffered with sodiumhydroxide. The chemical solution pH was maintained between 9.5 and 10.5.

j. Results: One of the valves malfunctioned during thermal aging. The valvedeveloped excessive seat leakage both in the energized and deenergizedstate. This was later determined to be caused by dirt in the valve. Thesource of dirt was the iron pipe used in the cylinder port as piping and anadditional length used to simulate an accumulator.

Other than the above malfunction, the valves sucessfully completed thesequential type tests and the baseline/functional tests.

5. Qualified Life - The solenoid valves have a qualified life of 40 years at 120*Fand 40,000 cycles, providing the maintenance schedule outlined in paragraph 4 isfollowed. Open and close completes one cycle. However, due to the self-heatingnature of solenoid valves, the temperature rise associated with a continuouslyenergized solenoid valve must be accounted for in the qualified lifecalculation. There are two areas affected by this heating: (1) the coil seesan increase of 105*C (221*F) above ambient and (2) the elastomeric discs see anincrease of 45*C (113*F) above ambient. These temperature increase values comefrom Franklin Research Center's "Test Program and Failure Analysis of Class 1ESolenoid Valves" (NUREG/CR-3424, F-C5569-369/315).

Based on the above information, a separate qualified life must be calculated for boththe coil and the disc. The following qualified life calculations, which are based onthe Arrhenius equation, are for valves to be used at a normal ambient operatingtemperature of 120*F (48.90C): ___

r- ' 7

Preparer/Date - \LA,•T~24•EQS No. WBNEEB0047tý ~Appendix 2 Rev 1

Reviewer/Date /I-r~~p Sheet 4ý of -6

Ll- L2e -j T2 }

COILS

In Franklin Research Center's "Test Program and Failure Analysis of Class lESolenoid Valves" (NUREG/CR-3424, F-C5569-309/315), the solenoid coils were aged attwo rates: 150*C (302*F) for 9.3 days (223.2 hours) and 131*C (268*F) for 15.3 days(367.2 hours).

Ll- Qualified life (first aging rate)

L2- Accelerated (test) life - 223.2 hours

E - Activation energy - 1.00 eV

K - Boltzmann' s constant -8.617 x 10-5 eV/*K

Tj-Qualified temperature (ambient + 105*C) - 153 .9*C

T2- Elevated (test) temperature 1500C + 1050C -2550C

e - Base of natural logarithms

Ll3- Qualified life (second aging rate)

L2'- 367.2 hours

E - 1.00 eV

K -8.617 x 10-5 eV/PK

T1'- 48.90C + 1050C -153 .90C

T2 '- 1310C + 1050C -2360C

e - Base of natural logarithms

Ll (total) - Total qualified life -L 1 + L1 ' -7.973 years

~DA T 1

Preparer/Date IV________A2 ____ EQS No. WBNEEB0047Appendix 2 Rev -1

Reviewer/Date ,4.Lq~#Sm c.i4f Sheet 5 of 6

DISCS

In ASCO test report AQS-21678/TR, supplement 3, the entire valve was aged at 131*C(268 0F) for 12 days (288 hours).

Ll- Qualified life

L2- Accelerated (test) life - 288 hours

E - Activation energy - .94 eV

K - Boltzmann' s constant - 8.617 x 10-5 eV/*K

Tl- Qualified temperature - 120*F

T2-Elevated (test) temperature - 1310C + 45*C - 1760C

e - Base of natural logarithms

Ll-7.56 years

3. Installation - Valves should be installed such that the axis of the coil remainsin the vertical and upright position.

4. Maintenance Requirements - The qualified life depends on the valve being cycledat least every 16-18 months to ensure proper opening and closing. Coils shallbe replaced every 7.973 years and elastomeric components shall be replaced every7.56 years when solenoid valves are subjected to a normal operating ambienttemperature of 120*F. In addition, ASCO recommends that when the solenoidvalves reach 20,000 cycles, that they be rebuilt using the applicable spareparts kit and spare coil kit2.

5. Valves are qualified per IEEE Standard 323-1974, IEEE Standard 382-1972, IEEEStandard 344-1975, and applicable portions of NUREG-0588 for the environmient inwhich they are required to operate, providing the maintenance schedule inparagraph 4 above is followed. By mathematical analysis, the qualified post-DBEoperating time can be extended to 292 days.

2ASCO Test ReportAQR67368/Rev. 0Appendix C, Page C-2

F v.

Preparer/Date -iŽa , / 'grg/ EQS No. WBNEEB0047Appendix 2 Rev 1

Reviewer/Date .~A I~ 4.L. - C / Sheet 6 of 6

Calculatiomis Post Accident Life

Calculations are based on the Arrhenius equation which states:

- ilK Tj T2]

Where

Ll-Qualified life

L.2 - Accelerated (test) life

El - Worst case activation energy, eV

K - Boltzmann's constant, 8.617 x 10-5 eV/OK

Ti-Qualified temperature, absolute

T2- Elevated (test) temperature, absolute

e - Base of natural logarithms

Calculate qualified post-accident life for valves located in lower compartment

(worst-case accident temperature profile for valves listed in Appendix 10)

L.2 - 29 days (AQS21678/TR Rev. A, figure 2, page 4-21)

El- 0.94 eV (AQR67368, Appendix B, page B-3)

Tj- 152.50F (temperature profile, WBN environmental data drawings 47E235-42 and -45,190OF @ 6xlO3seconds - 115 0F @ 30 days/2 + 1150F)

T2-200OF (AQS21678/TR Rev. A, figure 2, page 4-21)

L2- 29 x 24 - 696 hours

Lji- .8 years x 365 -292 days

014142.01

uCV

Uniit No Common

_Revision 1 2 3* EDS No. 'WB-NEEB0049W TVA MD No.

Preparer/Dates ~ ~ See Appendix 1

5. CO Ct#,

Manufactre-r'and Model No. ASCO-Model No. 206-380-2RU

Verification of 1%ble information (Table See Appendix 1

X -fli~et-TM- The equipment has been identified as per TVA ID numberdesignations (such as, Wjr, SJ).

X ..L. i - The location has been identified (such as, *inside primarycontainment, annulus, individually cooled rooms, general spaces, or areaaffected by HELB outside primary containmnent).

X nxu=- A unique TVA ID numb~er has been assigned (such as, l-FSV-68-308).Fucto - A functional description of the comonent has been given (such aspsteam generator blcudcwn).

X Cotract No.. Manufacturer. and Mokdel Ng. - The contract number,, manufacturer,and model number have been given.

XAbnrmoral or Accident Environment - All abnormal or accident environmentalconditions applicable to this equipment have been identified either in tables orby references to figures from tables.

X Environment to Which Oualified - The environment to which the equipment has beenqualified is addressed in either the tables or the environmental analysisattached.

.X.. CatM -A categoryof a,b,,c, or dhas beendefined for the E~. V'sipet .

.X2 CQeration and Accuracy Reqired and Demonstrated - The operation Uand accuracy required and dermnstrated have been defined.

Qulification Status (check if Aglicable. NA. if not)_____Oualified Life (If equipment is qualified, indicate the qualified life with anumnerical entry): 40 years

X Oualificat ion Report and Method - A qualification report and the method ofqualification has been identified on the Table Input Data Sheet (TIDS).

.X EnvironmentalAnalygli - An environmental analysis has been done, attached tothe BDS, and independently reviewed by the responsible organization.

N/A OuL&ificatiori by SiMiJlaity (If applicable) - A justification for qualificationby similarity is attached to the EUS considering all the above factors andreferenced to the appropriate tables.

X QkUalifiation of Several Exact GonM nent (If applicable) - When an EUS is usedfor more than one item, a list of all exact components is given as an appendixwith all references to appropriate tables with justification for qualificationconsidering all the above factors.

N/-A Interim Qualificatign (If ap.plicable) - (Open item) - component has beendetermined to be qualified only for a limited interim operation, an NCR hasbeen written,, and plan of action has been determined to yield a qualifiedccu4 ij nt"Tlerm of Interim Qualification _____________________

NCR No.N/A Urnaiie a~ - (Open item) - (If applicable) - Compo~nent has been

determined to be unqualified; the following is attached to EDS: NCR numbter,,reason for non-qualif ication,, and justification of continued operation.NR No. _ _ _ _ _ _

*Due to the extensive changes from Revision 2, revision bars are not used.

Preparer/Date Z 4A~ -2fAjRevi ewer/ Date ,/~~z.. 4

Manuf acturer

Component

EQS No. WBNEEB0049Appendix 1 -Rev 3Sheet 1-of 1

AS CO

Solenoid Valves

Component UNID Model No. Table/Sheet

3. ll-6/W4BNEEBOO0l0-FSV-12-79 206-380--2RU 3. 1l-8/WENEEBO0l2

0-FSV-12-82 206-380-2RU_____________

Preparer/Date / •k~., '-2 A' EQS No. WBNEEB004941 Appendix 2 Rev 3

Reviewer/Date y•i4-4Lu- z f ( Sheet 1 of 6

I.1. The so'lenoid valves listed in Appendix 1 are ASCO Model 206-380-2RU.They ir~e located in the Auxiliary Building General area. ValveNo. 0-F'SV-12-79 is located at elevation 713. Valve No. 0-FSV-12-82 hasbeen removed from the IE equipment list and is no longer required toperform a safety function. As detailed in EN DES Calculation NEB840314 225 for the Auxiliary Boiler System, valve 0-FSV-12-79 isrequired to operate for 5 minutes after the the start of a LOCA and notfail in a manner detrimental to plant safety for 100 days thereafter.Additionally, it must operate for 5 minutes after either an AuxiliaryBoiler or Auxiliary Feedvater line break and not fail in a mannerdetrimental to plant safety for 1 month thereafter.

2. This valve is subject to LOCA/HELB conditions (Volume 9), and isrequired to operate in the following environmentsl.

Normal

Temperature:Pressure:Relative Humidity:Radiat ion:

Spray/Flooding:

1040FAtm80%5xl02rads(40 years TID)N/A

Abnormal

110OFAtm

90%N/A

Accident

128OFAtm100%

<lxlo4rads

3. ASCO has tested this valve to the following environment:

Temperature:Pressure:Relative Humidity:Radiation:Spray:

346OF110 psig100%2xl0 8 rads3000 ppm Boron/pH 9-11

'Per HBN Environmental Data Drawings 47E235-52, -54.

aI r 1

I -~J ~, ~'. I

Preparer/Date,, r7-s~s EQS No. WBNEEB00491Appendix 2 Rev. 3

Reviewer/Date , EL.9Z P Sheet 2 of -6

1.Qualification Tsig

a. ASICO has tested the 206-380 and 206-381 series solenoid valves tothe requirements of IEEE Standard 323-1974 and NUREG-0588. Thetest criteria and results are documented in ASCO test reportAQS21678/TR, Revision A, including Supplement 3. All qualificationand tests were performed at test levels or conditions in excess ofknown maximum application requirements. These margins are inaccordance with the margins suggested by IEEE Standard 323-1974.

b. Seven solenoid valve samples representing six generic families ofvalves including the 206-380 and 206-381 series, were subjected tosequential exposures of elevated temperature, radiation, wearaging, seismic simulation, vibration endurance, accident radiationand a 30 day LOCA simulation. Baseline functional tests wereperformed before the start and after each sequence of the testexposure with the exception of coil dielectric and insulationresistance measurements which were taken before thermal aging,after accident radiation, and after LOCA exposure. The valves wereenergized and deenergized at high and low pressures during the testphases (except radiation) and valve leakage monitored.

c. Baseline/Functional Test: Baseline/Functional tests consisted ofmeasurement of coil excitation, seat leakage at high and lowpressures, noise test, operational test, and external leakage testbefore and after all phases of type tests. Measurement ofinsulation resistance and coil dielectric test was performed in theas received condition and after completion of accident radiationand LOCA simulation. Valve were energized and deenergized andtheir operation monitored during test (except radiation).

d. Thermal aging: The valves were subjected to an aging temperatureof 268OF for a test duration of 12 days. They were cycled(deenergized for five minutes and then energized) every 6 hours.

e. Radiation: The valves were subjected to cobalt 60 (GAMMA)radiation at an exposure rate of less than one megarad per hour.Total integrated dose received was 50 megarads.

f. Wear aging: The valves were electrically cycled 40,000 times atmaximum pressure differential.

g. Seismic Simulation/Vibration Endurance: The valves were subjectedto a combined SSE and fragility test. The input g. level was 7g'is. The test was performed with the valves energized anddeenergized and with high and low pressure. The leakage rate wasmonitored.

Preparer/Date4 . ?t- 4ý ,ZZ2-I EQS No. WBNEEB0049

Revieer/Dae Z~Appendix 2 Rev. 3

h. Accident Radiation: The valves were subjected to cobalt 60 (GAMMA)radi.~tion at an exposure rate of less than one megarad per hour.Valves received an additional accumulated dose of 150 megarads fora total integrated dose of 200 megarads received in two stages.

i. LOCA Simulation: The valves were subjected to a simulated loss-of-coolant accident (LOCA) by exposure to steam and to chemical sprayfor 30 days. LOCA simulation conditions were as follovs:

Temperature - Maximum of 346OF for a total period of 6 hoursfollowed by a step decrease to 200OF within 4 days followed by post-DBE conditions of 200OF for the remaining 26 days.

Pressure - Maximum of 110 psig for a total period of 6 hoursfollowed by a step decrease to 10 psig within 4 days followed bypost-DBE conditions of 10 psig for remaining 26 days.

Relative Humidity - All steam environmient in excess of 2500 F;greater than 90% for other conditions.

Chemical Spray - The chemical solution consisted of 3000 ppm boronas boric acid in solution with 0.064 molar sodium thiosulfatebuffered with sodium hydroxide. The chemical solution p11 wasmaintained between 9.5 and 10.5.

j. Results: One of the valves malfunctioned during thermal aging.The valve developed excessive seat leakage both in the energizedand deenergized state. This was later determined to be caused bydirt in the valve. The source of dirt was the iron pipe used inthe cylinder port as piping and an additional length used tosimulate an accumulator.

Other than above malfunction, the valves successfully completed thesequential type tests and the baseline/functional tests.

2. Qualified Life - The solenoid valves have a qualified life of 40 years at 104*Fand 40,000 cycles, providing the maintenance schedule outlined in paragraph 4 isfollowed. Open and close completes one cycle. However, due to the self-heatingnature of solenoid valves, the temperature rise associated with a continuouslyenergized solenoid valve must be accounted for in the qualified lifecalculation. There are two areas affected by this heating: (1) the coil seesan increase of 105*C (221*F) above ambient and (2) the elastomeric discs see anincrease of 45*C (113*F) above ambient. These temperature increase values comefrom Franklin Research Center's "Test Program and Failure Analysis of Class lBSolenoid Valves" (NIJREG/CR-3424, F-C5569-309/315).

Preparer/Date / Zd, L./4i.~"-•R QSN.WNEO4/Appendix 2 Rev. 3

Reviewer! Date 7. , a . ?-U. -7V Sheet 4 of 6

Based on tk~e above information, a separate qualified life must be calculated for'boththe coil &ad.-the disc. The following qualified life calculations, which are based onthe Arrheniuis equation, are for valves to be used at a normal ambient operatingtemperature of 104*F (40*C):

Ll- L2e [ T1 T21

COILS

In Franklin Research Center's "Test Program and Failure Analysis of Class 1ESolenoid Valves" (NUREG/CR-3424, F-C5569-309/315), the solenoid coils were aged at

(6.2hustwo rates: 150CC (3OP*F) for 9.3 days (22.3.2 hours) and 131*C (268*F) for 15.3 days

Ll- Qualified life (first aging rate)

L2- Accelerated (test) life - 223.2 hours

E -Activation energy - 1.00 eV

K - Boltzmann's constant - 8.617 x 1O-5 eV/*K

Tj- Qualified temperature (ambient + 105*C) - 1450C

T2- Elevated (test) temperature - 150*C + 1050C - 255*C

e - Base of natural logarithms

Ll'= Qualified life (second aging rate)

L2 '- 367 .2 hours

E -1.00 eV

K - 8.617 x 1i-5 eV/0K

Tj'= 40*C + 105*C -145 0 C

T2'-~ 131*C + 105*C 236*C

e =Base of natural logarithms

Lj (total) -Total qualified life - Ll + Ll' - 14.217 years

K'

I **, 4 J

Preparer/Dateý - A?-4 ,Z~S '

Reviewer/Date ~9~~

EQS No. WBNEEB04-9-Appendix 2 Rev. -3Sheet 5 of 6

DISCS

In ASCO test report AQS-21678/TR, supplement 3, the entire(268*F) for 12 days (288 hours).

Ll-Qualified life

L2- Accelerated (test) life - 288 hours

E - Activation energy - .94 eV

K - Boltzmann' s constant - 8.617 x 10-5 eV/*K

Tl- Qualified temperature - 104*F

T2- Elevated (test) temperature - 131*C + 45 0C - 1760 C

e =Base of natural logarithms

Ll-15.811 years

valve was aged at 131C

3. Installation - Valves should be installed such that the axis of thein the vertical and upright position.

coil remains

4. Maintenance Requirements - The qualified life depends on the valve being cycledat least every 16-18 months to ensure proper opening and closing. Coils shallbe replaced every 14.217 years and elastomeric components shall be replacedevery 15.811 years when solenoid valves are subjected to a normal operatingambient temperature of 104*F. In addition, ASCO recommends that when thesolenoid valves reach 20,000 cycles, that they be rebuilt using the applicablespare parts kit and spare coil kit2.

5. Valves are qualified per IEEE Standard 323-1974, IEEE Standard 382-1972, IEEE Standard 344-1975, and applicable portions of NUREG-0588 forthe envirormient in which they are required to operate, providing themaintenance schedule in paragraph 4 above is followed. By mathematicalanalysis, the qualified post-DBE operating time can be extended to11.325 years.

2iASC0 Test Report AQR67368/Rev 0, Appendix C, Page C-2

vii

Preparer/Date ~ ~ 7 92-/ EQS No. WBNEEB0049Appendix 2 Rev. 3

Reviewer/Date ~ -4i'V Sheet 6 of 6

6. As shown on WBN Environmental Data Drawing 47E235-54, in the event ofan accident the temperature would rise from the normal 1040F to 128OFwithin 20*seconds and return to 1040F within 24 hours. ASCO's LOCASimulation Test (Figure 2, page 4-21, of ASCO test report AQS21678/TR,Rev. A) more than encompasses this requirement in that the temperaturewas maintained at 250OF or higher for 4 days, including one peak wherethe temperature was held at 346OF for 3 hours. Further, the testextended for 26 more days at 2000F, which can be used to satisfy the100 day requirement, as shown below.

Calculations - Post Accident Life

Calculations are based on the Arrhenius equation which states:

Where:

Ll- Qualified LifeL2- Accelerated (test) LifeEl- Worst case activation energy, eV

K - Boltzmann's constant, 8.617 x 10-5 eV/oKTj- Qualified temperature, absoluteT2- Elevated (test) temperature absolute

e - Base of natural logarithms

Calculate qualified post-accident life for valves located in AuxiliaryBuilding (worst case accident temperature profile for valves listed inAppendix 1):

L2- 26 days (AQS21678/TR Rev. A, figure 2, page 4-21)El- 0.94 eV (AQR67368, appendix B, page B-3)Ti- 1040F (temperature profile, SQN/WBN environmental data drawing 47E235-5T2-200OF (AQS21678/TR Rev. A, figure 2, page 4-21)

L2- 26 x 24 -624 hoursLi 11 .325 Years

044139.02

IRevision. 1*1 2131 1

Preparer/Date•, Ce 'A-441po ,s / K f ý

Reiwer/bateg 0f~~r ~~'d 1~

IMN EDUIpmw~ QIZITFTcM'I hJA= (gas)

kihit No. 1 and 2EDS No. WBNEEB0051TIVA MD No.

See Appendix 1

M4anufactfirer and Model No. NAMCO EA-180Verification of Tible Information (Table See Appe~.idix 1

X _ itTY - The equipment has been identified as per TVA ID numberdesignations (such as, NOV,, SOOJ.

X j.L. i - The location has been identified (such as, inside primarycontainment, annulus, individually cooled rocxis, general spaces, or areaaffected by HE outside primary containument).

X D o t- A unique IVA M number has been assigned (such as, l-FSV1-68-3O8).- ucin- j~ Afunctional description of the component has been given (such as#

steam generator blowdon).X Conitract Ng.. ManufaCturer. and Model No. - Th~e contract numbier, manufacturero,

and model numb~er have been given.-x Abnorm~al or Accident govironMen - All abnormal or accident environmental

conditions applicable to this equipment have been identified either in tables orby references to figures from tables.

X EnvirMz~at to Which qualified - The environment to which the equipmnent has beenqualified is addressed in either the tables or the environmental analysisattached.

X te ~a y A category of a,,b, c.or dhasbeen deffle for the

L Doration and Accracy Reqired and Dmerrisrated - The operationand accuracy required and demonstrated have been defined.

Oualiication Status (check if aplicable. M if not)Qualified Life (If equipment is qualified,, indicate the qualified life with anumerical entry): Group I - 8.4 years, Group II - 13.9 years, Group III - 13.9 years

.X ~aification Reprt and Metho - A qualification report and the method ofqualification has been identified on the Table Input Data Sheet (TIDS).

.x Zuro tl ul - An environmental analysis has been done, attached tothe EQS,, and independently reviewed by the responsible organization.

HI uaificatiori by SimilArity (If applicable) - A justification for qualificationby similarity is attached to the BOS considering all the above factors andreferenced to the appropriate tables.

-X Omjaificatiori of Several Exact Conmonets (If applicable) - When an BDS is usedfor more than one item, a list of all exact comp~onents is given as an appendixwith all references to appropriate tables with justification for qualificationconsidering all the above factors.

N/LA Interim Qualification (If applicable) - (open item) - Component has beendetermined to be qualified only for a limited interim operation, an NCR hasbeen written, and plan of action has been determined to yield a qualifiedcomponent.Term of Interim Qualification _____________________

N/A 2Ua if j~S Cgamm - (Open item) -(if applicable) - Coumponent has beendetermined to be unqualified; the followfing is attached to EDS: NCR numberpreason for non-q~ualification, and justification of continued oeainNC No. _ _ _ _ _ *

*Due to the extensive changes from Revision 0, revision bars are not used.

7.]

FreparerlD ate 1 ,4 g

Revi ewer/D ate

Mania? acturer

component

JEqS No. WEN EEB0051Appen~diix 1 Rev 3Sheet I or 2

NAMCO

Limit Switch

*Not yet initalled, "~Lover compartment, U - Upper compartment, Ann - Annulus

Com~ponient UUID Model No. Table/Sheet

Limit Switches on:1

1-FCV468-308-B E180 L 3.11-4/WBNEEBOOO5

2-FCV-68-308-B* L 3* 11-4/WBNEEBOOO5

I-FCV-77-16-B L 3.11-4/WBNEEBOOO5

2-FCV-77-16-B* L 3.11-4/WBNEEBOOO5

I-FCV-90-1108-3 L 391 1-4/WBNEEBOOO5

2-FCV-90-108-B* L 3.11-4/WBNEEBOOO5

I-FCV-90-1O9-B L 3.11-4/WBNEEB0OO5

2-FCV-90-109-B* L 3 .11-4/WBNEEBOOO5

1-FCV-90-110-B L 3.11-4/WBNEEB0005

2-FCV-90-11I0-B* L 3* 11-4/WBNEEBOOO5

1-FCV-90-114-B L 3.11-4/WBNEEB0005

2-FCV-90-114-Be L 3.11-4/WBNEEBOOO5

2-FCV-9O-115-B* L 3.11-4/WBNEEBOOO5

2-FCV-90-116-B* L 3.11-4/WBNEEBOOO5

2-FCV-90-116-B* L 3.11-4/WBNEEBOOO5

1-FCV-32-80-A AN 3.11-5/WBNEEB0001

i-YCV-32-102-B 3.11-5/WBNEEBOOO1

1-FYCV-32-1 10-A 3 .11-5/WBNEE30001

r1-FCV-77-18-B 3.11-4/WBNunooo04

2-FCV-77-18-B L3.11-4IWBNEEB0OO4

Revision

Prepo rcr.,LC cte

rreparerivate C

Reviee/Dt

FQS No. WBNEEB0051Appen~iC Rev=~Sheet 2 brv =

Nanuf acturer

Campnent -

NAMCO

Limit Switches

*Not yet insialled, **iover containment, U - Upper containment, Ann - Annulus

Component UNID NOde No. Table/SheetLimit Svitches on: Loc.**'

1-FCV-63-71-A FA180 L 3.11-4/WBNEEBOOO4

2-FCV-63-71-A* L 3.11-4/WBNEEBOOO4

1-FCV-61-97-B U 3.11-4/WBNEEBOOO5

2-FCV-61-97-B* U 3.11-4/WBNBEBOOO5

I-FCV-61- 122-B U 3.11-4/WBNEEBOOO5

2-C-1-2-*U 3.11-4/WBNEEBOOO5

I-FCV-61-192-B U 3.11-4/WBNEEBOOO5

2-FCV-61.-192-B* U 3.11-4/WBNEEBOOO5

1-FCV-61-194-B U 3.11-4/WBNEEBOOO5

2-FCV-61-194-B* UJ 3.11-4/WBNEEBOOO5

I-FCV-77-9-iB L 3.11-4/WBNEEBOOO5

2-FCV-77-9-B* L 3.11-4/iiBNEEBOOO5

2-FCV-32-81-A* AN3.11-5/WBNEEBOOOI

2-FCV-32-1O3-B* ANN 3.11-51WBNEEBOOO1

2-C-211B ANN 3.11-5/WBNEEBOOO1

Revision 14

Preparer/Dote LEI

Reviewer/Dote

Preparer/Date RC

Rev iew er/Date

KQS No. WBNREEB0051- -

Appendix 2 Revision _-.ýSheet - I of - L.2

MANC0 haif tested the model EU180 limit switch to the requirements of IEEEstandard 323-1971. The test criteria and results are documented in IN&=test report QTR-105, revision 1. All qualification tests were performedat test levels or conditions in excess of known maximum applicationrequirements. These margins are in accordance with the margins suggestedin IEEE Standard 323-1974.

Thermal aging calculations in this appendix are based upon the "ArrheniusEquation" shown in equation 1.

[ (ýL- y)Ll- L2 e

Ll- Qualified life

L2- Accelerated (test) life

E - Worst case activation energy, eV

k - Boltzmann' s constant, 8.617 x 10-5 eV/ 0 K

if~~ ~ E1LLd:

'11 - Qualified temperature, absolute

T12 -Elevated (test) temperature, absolute

e -Base of natural logarithms

Reference: EPRI, NP-1558. Research Project 890-1, dated September 1980.

MANCO has considered the potential for thermal aging of all materials inthe E&180 limit switch. The that report identifies "elastomeric seals" asthe most susceptible parts. No further identification is made of theparts. However, a minimum activation energy of 0.958 eV is stated for theseals. All calculations are based upon an energy of 0.8 eV, which shouldbe sufficiently conservative to cover all elastomeric parts of the switch.

TEST EQUIPMENT PROBLEMS

The caustic storage tank lost solution twice during the LOCA profile test.Approximately one hour and 45 minutes after starting the initial spike to34007. the test was delayed for approximately 2-1/2 hours to replace thecaustic solution, and testing was resumed. Approximately eight hours and35 minutes after starting, the test was shut down approximately 16 hoursbecause of losing solution. The solution was replaced, and testingcontinued. These interruptions occurred during profiles C-D--E and H-J-1-L,respectively, in Figure 1. Revision R3 ___

Neviewer/Dote -

EQN. 1

where

Preparer/Date gv. -Ii- q

Reviewer/Date A4_______________

EQS No. WBNEEBO051-- -Appendix 2- Rev _...Sheet ..27- of -12-

It is our engineering judgment those tvo problems will not change theconclusions found elsewhere in this document regarding the performance tobe expect-ed from this model switch.

1. Limit Svitches Desijtnated- "L". in- the Location Column in- AvPendiz- 1:

1. These switches are NMACO Model EA180. They are located in theReactor Building (inside containment, lover compartment). Asdetailed in EN DES Calculations, NEB 840314 230, NEB 840411 221,WEB 840321 219, and NEB 840413 223, these devices are requiredto operate for 5 minutes after the start of a LOCA, Main Steam linebreak, Feedwater line break, RHR line break, and CVCS line break.Additionally they must not fail in a manner detrimental to plantsafety for 100 days following a LOCk, Main Steam line break, andFeedwater line break; for 1 month following a RHR line break andCVCS line break.

2. The switches are subject to the HELB/LOCk conditions shown inFigure-2. They are required to operate and/or not fail in thefollowing environment 3:1

Normal Abnormal Act id ent

Temperature:Pressure:Relative Humidity:Radiation:

Spray/Flooding:

120OF14.7 psia802x107 rads(40 years TID)NIA

130OF14.7 psia100%N/A

N/A

3270 F26.4 psi&100%,lxO8 rads

Spray

3. The manufacturer has tested the switches to the following.

Temperature:Pressure:Relative Humidity:Radiation:

Normal1200FAtm100%

Actcid ent340OF70 psig100%

2.04x10 8 rads

The LOCA simulation test prof iles (Figure 1) exceeds the time temperatureenvelope for the actual MSLB/LOCA (Figure 2).

14. The manufacturer has thermally aged the UA180 limit switch for400 hours at 1200 C (2480 F) prior to the LOCk test simulation.

The qualified life for these switches is the thermal aging equivalent priorto the LOCA test. It is calculated to be approximately 8.4years at the normal operating temperature of 1200 F, plus LOCk.

IR2lSee WEN Environmental Data Drawing 47E235-42.

Revision ___ _

Prcparer/Dcte

----- --

Preparer/Date 'PCaBQS No. W-BNEEB0051.Appendix -2 Rev 3

Reieer4a Sheet 3 - of

Calcfl~ation

L2- 400 hoursT2 - 120OF - 248OF -393.150K

Tl- 120OF - 322.0401E - 0.8 eV

[.1xo5eVI0K 316.480K 393.19 -

Ll- 400 hours X e( ' 1

- 73560.95 hour. x 1 yr.18766 hours

- 8.392 years

These switches are located inside containment where they are subject tochemical spray.

A chemical solution consisting of 3000 ppm boron as boric acid insolution with 0.064 molar sodium thiosulfate buffered with sodiumhydroxide to a pH value of 10.5 at 770F was sprayed on the sample at arate corresponding to 0.15 gpm. per square foot of area covered by the

spray. The chemical spray solution pH was maintained between 10 and11.

The chemical composition of the Watts Bar containment spray is:

0.1847 molar H3 B03 (2000 ppm boron)

0.033 molar NaQE, resulting in a pH of 8.2

The switches successfully completed the LOCA profile test withoutincurring any operational or corrosion failures. Since the chemicalconcentration of containment spray is less severe than the LOCA profiletest concentrations. the s*itches should not be affected.

5. In our engineering judgement, the manufacturer's LOCA test profile (Figure1) more than satisfies the requirements of the actual MSLB/L0CA profile(Figure 2). In addition, the LOCA test extends out to 722hours (30 days) at 2000F, which is more severe an ambience than thelatter portions of the actual LOCA curve show. The last 600 hours,therefore, can be seen to be an accelerated aging period at 200OF whichcan be used to demonstrate post-LOCA life capability. This period at200OF can be shown to be equivalent to over 2.2 years at 1200 F (seecalculation below) and, therefore, more than satisfies the 100-day

st-accident requirement.

0Revision R3Preparer/Date

Reviewer/Dote~'~

Preparer/Date C~*ý G-// 3QS No. WBNEEB0051- -

Appendix 2 Rev 3..L.Rev iever/DateA , <41^it Sheet 4- of A

Calculation

L2 n 600 hoursT2 - 2000 F - 366.480 KTl- 1200 F - 322.040 K

E - 0.8eV

I[ ' 0 .8 e V - - I * -l- - - * -

8.617xz105 eV/K 322.040 K 366.4801Ll- 600 hours X e

- 2.258 years

This is 2.258 years life equivalent at 1200 F andthe post-DIA life of 100 days at 1200 F.

can be used to satisfy

6. The above information shovs that the switches are qualified for 8.4 yearsat maximum normal operating temperature, radiation, humidity, and then forMSLB/L0CA conditions and for the post-accident life requirement.Satisfactory performance can be expected from the switches in the aboveenviromment.

II. Limit Switches Designated "U" in the Location Column -in AR~endix 1.:

1. These switches are NANCO Model U180O. They are located in theReactor Building (inside containment, upper compartment). Asdetailed in EN DES Calculation, NEB 840314 224, these devicesare required to operate for 5 minutes after the start of a LOCA,Main Steam line break, Feedvater line break, 8111 line break, andCVCS line break. Additionally they must not fail in a mannerdetrimental to plant safety for 100 days following a LOCk,Main Steam line break, and Feedwater line break; for 1 month Rfollowing a ERR line break and CVCS line break.

2. The switches are subject to the HELD/LOCA conditions shown in Figure2. They are required to operate and/or to not fail in the followingenvironments :2

Normal Abnormal Acc id ent

C' eF~mperature:Iressure:

U ý Relative Humidity:Radiation:

Spray/Flooding:

11OOF14.7 psia80%2x107 rads(40 years TmD)

120OF14.7 psia,90%NI/A

160OF26.7 psis,100%ixiOB rads

UA S pra IRevisionl R3 I__

2 See WBN Environmental Data Drawing 4725-1 Iewe: r/Date~j

Preparer/Date X,61 /8

Rev iewer/Date/- 67'AcA~zP/EQS No. WBNBEBOO51- -Appendix 2- Rev W ý -

Sheet 5- o f jj2

3. The manufacturer has tested the switches to the following:

Temperature:Pressure:Relative Humidity:Radiation:

Normal120OFAtm100%

Accident340OF70 psig100%

Total

2.04xl08 rads

The LOCA simulation test profile (Figure 1) exceeds the time-temperature envelope for the actual MSLB/L0CA (Figure 2).

4. The manufacturer has thermally aged the UA180 switch for 400 hoursat 1200 C (2480 F) prior to the LOCk test simulation.

The qualified life for this switch is the thermal aging equivalentprior to the LOCA test. It is calculated below to be approximately13.9 years at the normal operating temperature of 1100 F, plus LOCA.

Calculation

L2- 400 hoursT2 - 120OF - 393.150KT - 110OF - 316.480K

E-0.8 eV

E E F C TJ E

E .. .0.8 eV .. . -- -1.--- -1 - -Ll 48 hors e 8.617x10--eV/oK 316.480 K - 393.1901

- 122018.725 hours x 1 yr./8766 hours

- 13.920 years

These switches are located %inside containment where they are subject tochemiical spray.

A chemical solution consisting of 3000 ppm boron as boric acid insolution with 0.064 molar sodium thiosulfate buffered with sodiumhydroxide to a PH value of 10.5 at 770F was sprayed on the sample at arate corresponding to 0.15 gpm per square foot of area covered by thespray. The chemical spray solution pH was maintained between 10 and11.

The chemical composition of the Watts Bar containment spray is:

0.1847 molar 13103 (2000 ppm boron)

0.033 molar NaOH, resulting in a pH of 8.2Revision R3____

Preparer/Dote

Reviewer/Date

Preparer/Date C

Reviewer/Date/~A4Ql~~//

EQS No. WBNEEB0O51-Appendix 2 Rev 3Sheet -.6 -of iLý2

The switches successfully completed the LOCA profile test withoutincurring any operational or corrosion failures. Since the chemicalconcentration of containment spray is less severe than the LOCA profiletest concentrations, the switches should not be affected.

6. In our engineering judgement, the manufacturer's LOCA test profile (Figure1) more than satisfies the requirements of the actual HSLB/LOCA profile(Figure 2). In addition, the LOCk test extends out to 722hours (30 days) at 2000F, which is more severe an ambience than thelatter portions of the actual LOCA curve show. The last 600 hours,therefore, can be seen to be an accelerated aging period at 200OF whichcan be used to demonstrate post-LOCk life capability. This period at200OF can be shown to be equivalent to over 3.7 years at 1100 F (seecalculation below) and, therefore, more than satisfies the 100-daypost-accident requirement.

Calculatio E F3,EC T IV E

L2- 600 hours AIET2- 2000 F - 366.480 K

Tl- 1100 F - 316.480 K___

E - 0.8eV

E0.8 eV ......81.6117xl0 5 eV/OK

Li- 600 hours X e

( . . .1 -- -316.480K -366.4801K

-3.745 years

This is 3.745 years life equivalent atthe post-DBE life of 100 days.

110 0F and can be used to satisfy

6. The above information shows that the switches are qualified for 13.9 yearsat maximum normal operating temperature, radiation, humidity, and then forMSLB/L0CA conditions and for the post-accident life requirement.Satisfactory performance can be expected from the switches in the aboveenvironment.

Revision___- -

Preporer/ Date

Reviewer/Dote

Preparer/Date

Rev iewer/Date A

IQS No. WBNEEBOO51 ---

Appendix 2. Rev 3ýSheet --7 - of 12L

III. Limit. Switches. Designated "ANN" in- the, Loation Column in A pendix- I-

1. These switches are NA.NCO Model EA180. They are located in theReactor Building (Annulus). As detailed in EN DES Calculation NEB840314 222, these devices are required to operate for 5 minutes-after the start of a LOCA, Main. Steam line break, RER line break,Feedvater line break, and CVCS line break. Additionally they-mustnot fail in a manner detrimental to plant safety for 100 days.following a LOCA, Main Steam line break, and Feedvater line break;I month following a RHI line break and CVCS line break.

2. The switches are subject to the HELB/LOCA conditions shown inFigure 3. They are required to operate and/or not fail in thefollowing environments :3

NoralAbnoma Arccideol

Temperature:Pressure:Relative Humidity:Radiation:

Spray/Flooding:

1100 FAtm(-)80%2xl07 reds(40 years TmD)N/A

120OFAtm(-)90%N/A

1500 714.4 psia100%5xl07 rads

N/A

3. The manufacturer has tested the switches to the following:

Temperature:Pressure:Relative Humidity:Radiation:

Normal1200 FAtm100%

Acc id ent340OF70 psig100%

2.04x108 rads

The LOCA simulation test prof ile (Figure 1) exceeds the time-temperatureenvelope for the actual NSLB/LOCA (Figure 3).

4. The manufacturer has thormally aged the RA 180 switch for 400 hoursat 1200C (2480F) prior to the LOCk test simulation.

The qualified life for these switches is the thermal aging equivalentprior to the LOCA test. It is calculated below to be approximately14 years at the normal operating temperature of 1100 F, plus LOCL.

3 8ee WEN Environmental Data Drawing 47E235-44 P.J

Revision R?3___

PrePoTC- /r ate -3-

Reviewer/DOte -

Preparer/Date -

Rev ievwer/Date

3QS No. WBNEEBOO51-Appendix -2. Rev -3 -Sheet .- 8r of jj ý2

Calculation

L2- 400 hours

T2- 12001 - 248OF - 393.150K

Tl- 11001 - 316.480K

E - 0.8eV

8 .61Wx10'eV/ 0 1Ll- 400 hours X e.

(... 1. -

316.480 K- - - 1- I- __ -

393.150K

- 122018.725 hours x 1 yr./8766 hours

- 13.920 years

These switches are located in the Annulus whereto a chemical spray.

they are not subject

5. In our engineering judgement, the manufacturer's LOCA test profile (Figure1) more than satisfies the requirements of the actual NSLB/LOCA profile(Figure 3). In addition, the LOCA test extends out to 722hours (30 days) at 2000F, which is more severe an ambience than thelatter portions of the actual LOCA curve show. The last 600 hours,therefore, can be seen to be an accelerated aging period at 200OF whichcan be used to demonstrate post-LOCA life capability. This period at20001 can be shown to be equivalent to over 3.7 years at 1100 F (seecalculation below) and, therefore, more than satisfies the 100-daypost-accident requirement.

Calculation

600 hours2000 F - 366.480 K1100 F - 316.480 K

E - 0.8 eV

Ll- 600 hours I

I.I0.86V - - --

8.617xl0ý eV/ 0 K( . .- 1- - -1 - .- -

316.480 K

3.745 years

Viu

Revision 143 _____

Propc -aWJ

366.480 K

Preparer/Date-

levi ever/Dates A ________________A__

EQS No. WBNEEBOO51--Appendix 2- Rev -Sheet. - of -12-

This is 3.745 years life equivalent at 110 OF and can be used to satisfythe post-DIE life of 100 day. at 110 0F.

6. The above information ahows that the switches are qualified for 13.9 yearsat maximum normal operating temperature, radiation, humidity, and then forHSLB/LOCk conditions and for the post-accident life requirement.Satisfactory performance can be expected from the wvitches in the aboveenv ironment.

014133.16

7

:7.

EQS No. WBNEEB0051

Appendix 2Sheet lo of 12-,

Ref: NAMCO test reportNo. QTR-1050 Rev I

340.

320.

240-

S200.

S160-

120

1004

Scale: None

T1 V,

,i~i;j~.

Time - Hours (See Boxes)

ProfileTime(Mrs)

G H 1.0

3K -

K-L 0.167

PrfleLTI-m

M -N 0.25N -P 24.5

P -R 67.0

R -S 0.

*Indetermi nate

FIGURE 1. Profile for Simulated Loss-of-CoolantAccident (LOCA)

Pzvizion 1,R3Frepo er, Pote ý -0

r~c~icwyer/Dote

722

Profile

IC- D

D - EE - F

Ti me(H rs)

3.11.233

2.75

I

EQS No. WBNEEB0051

Appendix 2Sheet,. .9i of 4-

I.

FIGURE 2

I ~ I L.

S Revision 93 1 -'i

------ ZOEPreparer/Dcte

Peviewer/DateEETIýýff- L

EQS No. ~b2KEBQ051

Appendix 2Sheet 12 of -1-2.

DBE Temperature Profile in Annulus

Ref: Harsh Environment Conditions for wBN

Scale: None

0

V

TIME (HOURS)

Revision- - - -

Preparer/Date - - - -

Reviewer/Date ' - - -

FIGURE 3

I -

The deviceýa' listed below require sealing of the conduitQualification of the conduit seals is documented in theEQS.

Component UNID

1,2-FCV-61-97-B (LS)1,2-FCV-61-122-B (LS)1,2-FCV-61-192-B (LS)1,2-FCV-61-194-B (LS)1 ,2-FCV-63-7 1-A (LS)1, 2-FCV-68-3 08-B (LS)1,2-FCV-77-9-B (LS)1,2-FCV-77-16-B (LS)1,2-FCV-77-18-B (LS)11 2-FCV-90-108-B (LS)1,2-FCV-90-109-B (LS)1,2-FCV-90-110-B (LS)1,2-FCV-90-114-B (LS)1,2-FCV-90-115-B (LS)1, 2-FCV-90-116-B (LS)

WBN-EEB-CSC-1WEN-EEB-CSC-1WBN-EEB-CSC-1WBN-EEB--CSC-1WBN-EEB-CSC-1WBN-EEB-CSC-1WBN-EEB-CSC-1WBN-EEB-CSC-1WBN-EEB-CSC-1WBN-EEB-CS C-iWBN-EEB-CSC-lWBN-EEB-CSC-1WBN-EEB-CS C-iWBN-EEB-CSC-1WBN-EEB-CSC-1

EQS.F

Revision q3i___

er,-' c!Eatc

*.c.t~i eer/L'ote

Preparer/Date f .- /

Reviever/Date ZA/EQS No. WBNEEB00 5 1Appendix 3 RevLSheet 1 'of

entrance.referenced

Revison OS No. WRFlEROfDS.

Prep~er/bte/- L ý OSee Appendix 1

manufacturer and Model No. ASCO X206-381-3RFVerification of erable Information (Table See Arnnendix I

X )Wp_ Z - The equipment has been identified as per TVA ID numberdesignations (such as, NWA, SM .

.x.. Lc~ation -~ The location has been identified (such as, inside primarycont~ainment, annulus, individually cooled roomr, general spaces, or area

X affected by HEL outside primary containment).Cauent- A unique IVA ED number has been assigned (such as, l-FSV-68-308).

X Enct.i2 - A functional description of the component has been given (such as,steam~ generator blowon).

XL ContraCt HU. * Manufacturer. and Model fig. - The contract numrber, manufacturer,and umodel number have been given.

X Abnornal or Accident &avironment - All abnormal or accident environmentalconditions applicable to this equipment have been identified either in tables or

X by references to figures from tables.EvironJment to Mhich Oualifie - The environment to which the equipment has beenqualified is addressed in either the tables or the environmental analysis

X attached.-~ eg - A category of a, b, c, or d has been defined for the

equipment.XOperation and Accuracy Required and flen'onstrated - The operation

and accuracy required and demo~nstrated have been defined.

Oualification Status (check if AI~licable, NA~ if not)Qualified Life (If equipment is qualified, indicate the qualified life with a

X numierical entry): 40 yrs.- Qualification Rerirt an Methbd - A qualification report and the method of

X qualification has been identified on the Table Input Data Sheet (TMS).X niwiaa Mayi - An environmental analysis has been done, attached to

the EDS, and independently reviewed by the responsible organization.N/A uiaificatiori by Similarity (if applicable) - A justification for qualification

by similarity is attached to the BUS considering all the above factors andreferenced to the appropriate tables.

X Oualification of Several Exact Ccqnents (If applicable) - When an EDS is usedfor more than one item, a list of all exact oompoents is given as an appendixwith all references to appropriate tables with justification for qualification

N/A considering all the above factors.InteriM OUalification (If applicable) - (Open item) - Ccanpnent has beendetermined to be qualified only for a limited interim operation, an NCR hasbeen written, and pl~an of action has been determined to yield a qualifiedconponent.Term of Interim Qualification ____________________

NE/A NRM.- (Open item) - (If applicable) - Ccmpcrbent has beendetermined to be unqualified; the follow~ing is attached to EUS: NCR number,reason for non-qualification, and justification of continued op'eration.

*Due to the extensive changes from Revision 0, revision bars are not used.

Preparer/Dat _______1___;;_________

Revi ewer/Date //~egAýuL. ?~cI-iyC?-- -- -- - EQS No. f4 5

Sheet j of I.L...

Manuf actiarer

Componert.

ASCO

Solenoid Valve

Component IJNID Model No. Table/Sheet

I-FSV-30-l 9-B X206-381-3RF 311 -5WRNwFERAO3

1-FSV-30-14--A X206-381-3RF ~I19WNF~l'

I-FSV-30-16-B X206-381-3RF 1-WNEffl

l-FSV-30-37-B X206-381-3RF 31~wNEon

1-FSV-30-59-A X206-381-3Rr .3 11-51WENEERMlOp3

l-FSV-30-57-B X206-381-3RF 3.1 1-91WINEERnOOl

I-FSV-30-53-B X206-38l-3Rr -3,11-5 /WBNEERflflA3

1-FSV-30-51-A X206-381-3RF 3-1-51WENEERnOQ3l

1-FSV-30-9-B X206-381-3RjF -1 1-5.1WENEEflAQ001

1-FSV-30-7-A X206-381-3RF' -- 1 1-SIRNFF.Rflflp

I-FSV-30-12A X206-8-3R 3-11-SIWBNEERflppI

1-FSV-30-54A X206-381-31Ry 1-~11-SI/WBNFEROOOI

Preparer! Date 5

Reviewer /Date A • 4~ Z 4EQS No. WBNEEB0054Appendix 2 Rev 1Sheet 1 of 6

I. The sol -eýnoid valves in Appendix I are ASCO Model X206-381-3RF.They are located in the Annulus. As detailed in EN DES CalculationNEB840213 218, the devices are required to operate for 5 minutes andnot fail in a manner detrimental to plant safety for 100 days after thestart of a LOCA or line breaks in either Main Steam or Feedwater lines.They are also required to operate for 5 minutes and not fail in amanner detrimental to plant safety for 1 month after breaks in eitherRHR or CVCS lines.

II. They are required to operate in the following environmient:'

Normal

Temperature:Pressure:Relative Humidity:Radiation:

Spray/Flooding:

11 0OFAtm( -)80%2x107 rads(40 yr TID)NIA

Abnormal

120OFAtm(-)90%N/A

N/A

Accident

150OFAtm(-)100%5x107 rads(LOCA)

N/A

III. ASCO has tested this valve to the following enviromnent:

Temperature:Pressure:Relative Humidity:Radiation:Spray:

346 0F110 psig100%2x108 rads3000 ppm Boron/pH 9-11

IV. 1. Qualification Testing:

a. ASCO has tested the 206-380 and 206-381 series solenoid valvesto the requirements of IEEE Standard 323-1974 and NUREG-0588.The test criteria and results are documented in ASCO TestReport AQS21678/TR, Revision A, including supplement 3. Allqualification and tests were performed at test levels orconditions in excess of known maximum application requirements.These margins are in accordance with the margins suggested byIEEE Standard 323-1974.

1Per WIN Enviromnental Data Drawing 47E235-44R0.

L~

Preparer/Date zK~O4 ~S/½Ct~ EQS No. WBNEEB0054

Reviewer/Dt! Appendix 2 Rev 1Da4e FY__________ Sheet 2- of 6

b*Seven solenoid valve samples representing six generic familiesof valves including the 206-380 and 206-381 series, weresubjected to sequential exposures of elevated temperature,radiation, wear aging, seismic simulation, vibration endurance,accident radiation, and a 30 day LOCA simulation. Baselinefunctional tests were performed before the start and after eachsequence of the test exposure with the exception of coildielectric and insulation resistance measurements which veretaken before thermal aging, after accident radiation, and afterLOCA exposure. The valves were energized and deenergized athigh and low pressures during the test phases (exceptradiation) and valve leakage monitored.

c. Baseline/Functional Test: Baseline/functional tests consistedof measurement of coil excitation, seat leakage at high and lowpressures, noise test, operational test, and external leakagetest before and after all phases of type tests. Measurement ofinsulation resistance and coil dielectric test was performed inthe as-received condition and after completion of accidentradiation and LOCA simulation. Valves were energized anddeenergized and their operation monitored during test (exceptradiation).

d. Thermal Aging: The valves were subjected to an agingtemperature of 268OF for a test duration of 12 days. Theywere cycled (deenergized for 5 minutes and then energized)every 6 hours.

e. Radiation: The valves were subjected to cobalt 60 (GAMMA)radiation at an exposure rate of less than one megarad perhour. Total integrated dose received was 50 megarads.

f. Wear Aging: The valves were electrically cycled 40,000 timesat maximum pressure differential.

g. Seismic Simulation/Vibration Endurance: The valves weresubjected to a combined SSE and fragility test. The inputg level was 7 g's. The test was performed with the valvesenergized and deenergized and with high and low pressure.The leakage rate was monitored.

Preparer/Date /, 2 &U4ý /,1M 1,-'2iIrr? EQS No. WBNEEB0054Appendix 2 Rev 1

Reviewer/Date 4iG vLL ? 4~Sheet 3- of 6

h. 4ccident Radiation: The valves were subjected to cobalt 60(GAMMA) radiation at an exposure rate of less than one megarad-per hour. Valves received an additional accumulated dose of150 megarads for a total integrated dose of 200 megaradsreceived in two stages.

i. LOCA Simulation: The valves were subjected to a simulatedloss-of-coolant accident (LOCA) by exposure to steam and tochemical spray for 30 days. LOCA simulation conditions were asfollows:

Temperature - Maximum of 3460F for a total period of 6 hoursfollowed by a step decrease to 2000F within 4 days followed bypost-DBE conditions of 200OF for the remaining 26 days.

Pressure - Maximum of 110 psig for a total period of 6 hoursfollowed by a step decrease of 10 psig within 4 days followedby post-DBE conditions of 10 psig for remaining 26 days.

Relative Humidity - All steam environment in excess of 2500F;greater than 90% for other conditions.

Chemical Spray - The chemical solution consisted of 3000 ppmboron as boric acid in solution with 0.064 molar sodiumthiosulfate buffered with sodium hydroxide. The chemicalsolution pH was maintained between 9.5 and 10.5.

j. Results: One of the valves malfunctioned during thermal aging.The valve developed excessive seat leakage both in theenergized and deenergized state. This was later determined tobe caused by dirt in the valve. The source of dirt was theiron pipe used in the cylinder port as piping and an additionallength used to simulate an accumulator.

Other than above malfunction, the valves successfully completedthe sequential type tests and the baseline/functional tests.

2. Qualified Life - The solenoid valves have a qualified life of 40 years at 110*Fand 40,000, providing the maintenance schedule outlined in paragraph 4 isfollowed. Open and close completes one cycle. However, due to the self-heatingnature of solenoid valves, the temperature rise associated with a continuouslyenergized solenoid valve must be accounted for in the qualified lifecalculation. There are two areas affected by this heating: (1) the coil seesan increase of 105*C (221*F) above ambient and (2) the elastomeric discs see anincrease of 45*C (113*F) above ambient. These temperature increase values comefrom Franklin Research Center's "Test Program and Failure Analysis of Class 1ESolenoid Valves" (NUREG/CR-3424, F-C5569-309/315).

DI I0 F1

Preparer/Date O- t 2l4 EQS No. WBNEEB0054Appendix 2 Rev 1

Reviewer/Date ~•7 ~ ~ 2. .2fA Sheet 47 of 6

Based on the above information, a separate qualified life must be calculated for boththe coil and ithe disc. The following qualified life calculations, which are based onthe Arrhenius equation, are for valves to be used at a normal ambient operatingtemperature of 110*F (43.3*C):

Lj -L2 e -T T2]

COILS

In Franklin Research Center's "Test Program and Failure Analysis of Class 1ESolenoid Valves" (NUREG/CR-3424, F-C5569-309/315), the solenoid coils were aged attwo rates: 150*C (3OP*F) for 9.3 days (223.2 hours) and 131*C (268*F) for 15.3 days(367 .2 hours) .

L- Qualified life (first aging rate)

L2- Accelerated (test) life -223.2 hours

E - Activation energy - 1.00 eV

K - Boltzmann's constant - 8.617 x 10-5 eV/*K

Tj-Qualified temperature (ambient + 1050C) - 148.30C

T2- Elevated (test) temperature -1500C + 1050C -255*C

e - Base of natural logarithms

Ll'- Qualified life (second aging rate)

L2'-. 367.2 hours

E -1.00 eV

K - 8.617 x 10-5 eV/'K

Ti'= 43.3*C + 105*C - 148.3*C

T2'- 1310C + 105*C - 236 0C

e -Base of natural logarithms

Li (total) -.Total qualified life -Lj + Ll' -11.44 years f L T I-.

Preparer/ Date .•eA t~ /-&~

Reviewer/Date ,,~/Te.ý 1,214-w

DISCS

In ASCO tesZ report AQS-21678/TR, supplement 3,(2680F) for 12 days (288 hours).

Ll- Qualified life

L2- Accelerated (test) life - 288 hours

E - Activation energy - .94 eV

K - Boltzmann's constant -8.617 x 1O-5 eV/*K

Tl- Qualified temperature - 110*F

T2 - Elevated (test) temperature -1310C + 450C - 176 0C

e - Base of natural logarithms

Ll- 11 .945 years

3. Installation - Valves should be installed such thatin the vertical and upright position.

EQS No. WBNEEB0054Appendix 2 Rev -1Sheet 5 of 6

the entire valve was aged at 131*C

the axis of the coil remains

4. Maintenance Requirements - The qualified life depends on the valve being cycledat least every 16-18 months to ensure proper opening and closing. Coils shallbe replaced every 11.44 years and elastomeric components shall be replaced every11 .945 years when solenoid valves are subjected to a normal operating ambienttemperature of 110*F. In addition, ASCO recommends that when the solenoidvalves reach 20,000 cycles,! that they be rebuilt using the applicable spareparts kit and spare coil kit2.

5. Valves are qualified per IEEE Standard 323-1974, IEEE Standa rd382-1972, IEEE Standard 344-1975, and applicable portions of NUREG-0588 for the environment in which they are required to operate,providing the maintenance schedule in paragraph 4 above is followed.By mathematical analysis, the qualified post-DBE operating time canbe extended to 1142 days.

2ASCO Test Report AQR67368, Revision 0,Appendix C, Page C-2

~.' k-' - 2

~) ~ ~

Preparer/Date 1/9*-2 100-h EQS No. WBNEEB0054Appendix 2 Rev IReviewer/Date // Sheet 6 of 6

Calculations -Post-Accident Life

Calculations are based on the Arrhenius equation which states:[( 1 - T2]

Ll- L2 e

Where

Li- Qualified life

L2- Accelerated (test) life

El- Worst case activation energy, eV

K - Boltzmann's constant, 8.617 x 10-5 eV/OK

T1 - Qualified temperature, absolute

T2- Elevated (test) temperature, absolute

e - Base of natural logarithms

Calculate qualified post-accident life for valves located in the Annulususing accident temperature profile for valves listed in Appendix 1:

L2- 29 days (AQS21678/TR Revision A, Figure 2, pages 4-21)

Ei- 0.94 eV (AQR67368), Appendix B, page B-3)

Tj- 127.50F (temperature profile, WBN Environmjental Data Drawing 47E235-44150OF at 28 hrs - 1050F at 30 days/2 + 1050F)

T2- 200OF (AQS21678/TR Revision A, Figure 2, pages 4-21)

L2- 29 x 24 - 696 hours

Ll-3.13 years x 365 - 1142 days

074144.09 1 L

Mmuac(re ndMde- Se!e Appendix 1Verification Of Tikfle Information (Table -See Appendix

Un~it ND. 1 and 2BQS No. WBNEEB0059WA MD No.

See Appendix 1

X WI nT=- 'I¶e equipmenit has been identified as per WvA ID numberdesignations (such as, IUJ, SOil).

.2. loatim - The location has been identified (such as, inside primarycontainment, anniulus,, Individually cooled roomst general spaces,, or areaaffected by HEB outside primary containumrent).

X DmM=- A unique TVA ID numb~er has been assigned (such as, l-FSV-68-308).X Funct~ion - A functional description of the ccuponent has been given (such as,

steam generator blowown).X =tract No.. Manufacturer. and Model No. - The contract number, umnufacturer,

and model number have been given.X Ih~rmal or Accident Environment - All abnormal or accident environmental

-conditions applicable to this equipment have been identified either in tables orby references to figures from tables.

X Environ~me~nt to Which QUAlifie - The environment to which the equipment has beenqualified is addressed in either the tables or the envirormuental analysisattached.X Qt= - A category of a, b,, cl, or d has been defined for theequipment.

X Operatign and Accuracy Heqired and Demonst-rated - The operationand accuracy required and demnorstrated have been defined.

Onalification Status (check if a=licable. IP. if not)9m1ified..Life (If equipment is qualifieds, indicate the qualified life with anumierical entry) : 95 years

X (hiAlificatiori &eprt and Metho~d - A qualification report and the method ofqualification has been identified on the Table input Data Sheet (TIDS).

X Enim tlAlss- An environmental analysis has been done, attached tothe EQS,, and independently reviewed by the responsible organization.

N/ Qlulificat ion by Similarity (If applicable) - A justification for qualification1by similarity is attached to the EDS considering all the above factors andreferenced to the appropriate tables.

X ualification of SeverAl Exact Campmne=t (If applicable) - When an EQS is used- for more than one item#, a list of all exact ccmponen ts i ie sa ~ni

with all references to appropriate tables with justification for qualificationconsidering all the above factors.

2,LA Interin qualifiLcation (If applicable) - (open item) - Caqm~oet has beendetermined to be qualified only for a limited interim operation, an NCR hasbeen written,, and plan of action has been determined to yield a qualified0014"Ient.71em of interim Qualification

iL 2R uaified .MM= - (Open item) - (If applicable) - Ccjoet has beendetermined to be unqualified; the following is attached to HQS: NCR number,reason for non-aualif icationo, and justif ication of continued operation.

NC ND F E C T~ DAT E*Due~~ ~ ~ ~~~~~~~~F to exesv cAne Tro Eeiln1 eiiner r lEU

OCT 1930"4

II

*Due to extensive changes from Revision 1, revision oars are nOL used.

Preparer/Date 'gc. ca4.t4iA-' -Ii-9

- evi owe /D ate/ 4 !a IL I

Kanuf actw

component

or.

EQS No. WBNEEB0059

Appendii- Revi 2Sheet =~or r

NA14CO

Limit Switch

Component UNID Model NO. Tables/Sheet

Limit Switch on:2-FCV-30-40A EA 780 3.11-4/WBNEEBOOO3

2-zS-30-8-B ______________ 3.1 1-4/WBNEEBOOO3

2-ZS-30-.15-B it___________ 3 .11-4/WBNEEBOOO3

2-ZS-30-20-A if___________ 3 .11-4fWBNEEBOOO3

2-ZS.-30-50-B____________ 3 .11-4/WBNEEBOOO3

2-ZS-30-52-A_____________ 3 .11-4/WBNEEBOOO3

2-zS-30-56-A _____________ 3.1 1-4/WBNEEBOOO3

1-ZS-30-58-B EA 740 3.11-4/WBNEEB0O1O

2-ZS-30-58-B EA-780 3.11-4/WBNEEB0OO4

LU

LU.

i

Preparer/Date LCAt w -/. 4

Reviee/a _____________L______

3.QS No. WBNEEB0059- -

Appendix - 2- Rev -L2Sheet - -I- - of 3-3

UNIT, I-ONEM

1. The'limit switches listed in Appendix 1 are NAMCO Model E&740. Theyare located in the Reactor Building (inside Containment, InstrumentRoom). As detailed in EN DES Calculation NEB 840213 218, for theContainment Ventilation System, these devices are required to operatefor 5 minutes after the start of a LOCA, Main Steam line break,Feedvater line break, ERR line break and CVCS line break.Additionally, they are required to not fail in a manner detrimental toplant safety for a period of 100 days following a LOCA, Main Steam linebreak or a Feedwater line break; I month following a RUR or a CVCS line break.

2. The limit switches are subject to LOCk/HELB conditions inside primarycontainment;. They are required to operate in the followingenvironment 1

formal Abnormal1 Accid-ent

Temperature:Pressure:Relative Humidity:Radiation:

Spray/Flooding:

7 50F14.7 psia60%3.5z104 rads(40 years TID)N/A

120OF14.7 psia902N/A

NIA

3270 F26.7 psia100%Ux108 rads

N/A

3. The manufacturer's test (as given in ReportOctober 1, 1981) reflects the following;

QTR-111, Rev. 0, dated

Temperature:Pressure:Humidity:Duration:Spray:

Total Radiation:

DBE Transient340OF80-100 psig100%

Yes

2.04 x 108 rads

fo-st-DBR Aging200OF10 psig100 %33 DaysYes

ISee WIN Environmental Drawing 47E235-45.

r)JT 1334

Preparer/Date G nn ý f6 8 EQS No. WBNEEB0059Appendix 2 Rev. 2

Reviewer/ Date Sheet 2 of 3

4. The-tested DBE curve extends to 340OF for a length of time vhich morethan .encompases the required LOCh environment.The post transient portion of the test curve can be used to satisfy the100 day requirements of section 1. Here the devices vere exposed to200OF for 33 days. Using the Arrhenius equation:

Ll- L2 e

with:

L2 - Accelerated (Test) Life - 33 DaysLl - Qualified Life

e - Ease of Natural LogarithmsE - Worst-Case Activation Energy - .8eVK - Boltzmann's Constant - 8.617 x 10-5 eV/OK

Tj - Absolute Temperature at Qualified Life - 1510F* -339 0KT2 - Absolute Temperature at Accelerated Life - 200OP-3660KLl - 251 Days

This more than satisfies the 100 day requirement of section 1.

*151OF is an average (1880F at 6 x 13sec + 115 0F at 30 days)/2from the post transient portion of the required LOCh curve.

5. The devices were exposed to accelerated aging (400 hrs at 2480F) priorto the DEE Test. From these results we can calculate the qualifiedlife of the device using equation A.

Ll- L2 e

vith L2 -400 HoursT- 750F - 2970KT2 248OF - 3930K

E -. 8 eV

therefore Ll - 95 years

6. Eased upon the above calculations these devices are fully qualifiedper NUR.EG-0588 for the environment in which they will operate.

EFFECTIVE.D ATE

OCT I''6

Preparer/Date X

ReiwrDt1 IF

3QS No. WBNEEB0059Appendix 2 Rev. 2Sheet 3 of 3

UNIT 2 ONLY

1. The limit switches listed in Appendix 1 are NAMCO Model EA-780.They are located in the Reactor Building (inside containment, lovercompartment) except 2-ZS-30-8-B which is located in the uppercompartment. They are required to operate for five minutes afterthe start of all accident. and to not fail in a manner detrimentalto plant safety for period~s of one mouth to 100 days thereafter(depending on which DIA occurs).

2. The limit switches are subject to LOCA and HELB conditions insideprimary containment. They are required to operate in the follovingenvironmenti:

Temperature:

Pressure:Relative Humidity:Radiation:

Spray/Flooding:

Normal

1200F (L)1100F (U)14.7 psia80%2 x l07rads WL5 z 103rads (U)(40 years TID)NA

Accident

3270 F (L)1600F (U)26.4 psia100Z1 x l08 rads

Spray

3. The manufacturer's specifications for the limit switches are:

Temperatur e:Pressure:Relative Humidity:Radiation:

2000FAtm

,Iiaot.'Specified96,t: Specif ied

4. Available documentation indicates that the l~iit 'switches are notqualified for their temperai-ries, pressure,' relawtive humidity, andradiation environiments.

5. TVA will replace these switches with quali'fiieddevices pe~r ,10CFR50.49, as determined by NCR WBNEEB8136'O".

'See SQN/WBN kaviroriment Data Drawings 47E235-44 (U) and 47E235"45 (L)and 47E235--48 WL.

324137 .01

EOCT"F

-I

Preparer/Date . yLitI-(B

Reviewe~r/Date / '?g.4A~~i.'

EQS No. WBNEEB0059Appendi 3 Rev- 2-Sheet 1 of I

The devices listed below require sealing of the conduit entrance.

Qualificsition, of the conduit seals is documented in the referenced EQS.

Component UNID

l-ZS-30-58/1

1-ZS-30-58/2

WBN EEB-CSC-1

WBN EEB-CSC-1

r-ECTIVE:ý

.c 984DEO7 ;B24137.O1

Revision 1 _

Preparer/a~te ~

Reviewer/Date

Uni*it N ____._

HDs No. WBE

See Appendix 1

lIENKM~fME2I RUFcMTg= MSFZ1 (MS)

Nanufactiirpr and Miodel 11o. NAmen vAlRoVerification of Table Information (Table see Appendix 1 1

X M~ tM - The equipment has been Identified as per WA ID numberdeisignations (such as, W7J, SM?!.laoti - The location has been Identified (such as, Inside pdriarycontainments, annuluss, individually cooled rooms, general spacess, or areaaffected by FEU outside primary contairment).

*... DMat - A unique WM ED number has been assigned (such as, 1-PSV-68-308)....* Bmctii - A functional description of Uth component has been given (such ass,

steaml generator blowdcmen).... ~. tra~t No, uatrr WHk o - The contract numibers, manufacturerg,

and model numbier have been given.__2 Abmoi~l or Accident Environment - All abnormal or accident envirorimental

conditions applicable to this equipzment have been identified either in tables orby references to figures from' tables.En~viraMent to Which Qualifie - The envirornment to which the equipment has beenqualified is addressed in ei~thr the tables or the envimsorwtal analysisattached.

.X. Catnggz - A category of a, b. cp or d has been defined for theequipment.

-2... Oeration and Accuracy Reqired and Demo~nstrated - The operation.and accuracy required and demonstrated have been defined.

Dualification Status (check if amlicable. Nik if V~tiQuAl if igd .Li± (If equipment is qualif ieds, indicate the qualified life with anumerical entry): 1.92 y ars

X Qualification Reprt and Nethx - A qualification report and the method ofqualification has been identified on Uth Table Input Data Sheet (TmD).

-.L Mvirgioatal Analysas - An environmental analysis has been done, attached toUth EDS and independently reviewed by Uth responsible organization.

-X,ý Di~alification by Similarity (If applicable) - A justification for qualificationby similarity Is attached to the EDS considering all the above factors andreferenced to the approprilate tables.

Y. Oualificaticn of Several Exact Conponents (If applicable) - lhen an EDS is usedfor more than one itens, a list of all exact components is given as an appendixwith all references to appropriate tables with Justification for qualificationconsidering all the above factors.

NA Interim uliiai (If applicable) - (Open itemi) - Component has beendetermined to be qualified only for a limited interim operations, an NCR hasbeen writtens, and plan of action has been determined to yield a qualified

Terrm of Interim Qualif ication_____________________

N-A M~ulifi le a m - (Open item) - (If applicable) - Capient has beendetermined to be unqualified; the following is attached to NOS: NC~~jnhzterfreason for no-qualifications, and justification of continued operation.NCRNo. _ _ _ _ _ _

*1~

Revision 1

PPreparer/batex ./

-

Re wr /bt I _

Wh~it NO,. ____

MS No. WThNEEBOO6WAID 11.

See Appendix 1-

Manufacturer and Model MD. NAmcn FAignVerification of Table Information (Table see Appendix 1

X v~t j - The equipmient has been Identified as per WA ID numberdesignations (such as, NOV, SMf.l~aotiui - The location has been identified (such aso, inside primiarycontainments, annulus, individually cooled roarss, general spaess, or areaaffected by HMZ outside primary containment).

Y.. Dmj~awt - A unique TA ID numb~er has been assigned (such as, 1-FSV-68-308).-y-.. Pci~ - A functional description of the cai~ment has been given (such as,

steam generator blaownkw).C ontract No.. MaUfacturer. Aad Model No. - The contract number, manufacturers,and model number have been given.

__2 Abrormel or Accident Environment - All abnormal or accident environmentalconditions applicable to this equipmient have been ide ntified either in tables ortyreferences to figures from tables.

, ,frvronment to W~hich Oualifie - The environiment to which the equipment has beenqualified is addressed in either the tables or the environmental analysisattached.

X.. Cat= - A category of as, b, c, or d has been defined for theequipment.

-L.j Opertion And Accuracy Heqired and Demonstrated - The operationand accuracy required and demonstrated have been defined.

Oualificatign Status (check if applicable. Ng. if not)QuAlified Life (If equipment is qualified, indicate the qualified life with anumierical entry): .13.92 Lars

XOualificat ion Rejxrt a M etho~d - A qualification report and the method ofqualification has been identified on the Table Input Data Sheet (TIDE).

-.1L. Covirgomt Anaalysis - An environmental analysis has been done, attached tothe BOS, and independently reviewed by the responsible organization.

_H, CQialificat ion tW Si~niarit (If applicable) - A Justification for qualificationby similarity is attached to the EDS considering all the above factors andreferenced to the appropriate tables.

Y Ckxlificat io of Several Exact Caponent (If applicable) - When an EDS is usedfor more than one items, a list of all exact cmijonets is given as an appndiwith all references to appropriate tables with justification for qualificationconsidering all the above factors.

_ZA InteriM 0ulfcto (if appicable) - (enitem) - Compoent has beendeterie tob ulified only for a limited interim operation, an NCR hasbeen writtens, and plan of action has been determined to yield a qualifiladau~xnent.Term of Interim Qualification_____________________

N ulifled Cassm - (open item) - (If applicable) - Caqxnent has beendetermined to be unqualif ied; the following is attached to EDS: NCR,,~karreason for non-qualifications, and justification of continued %*'ration.

~iE\

Preparer/Date i

Revi ewer/D ate A l.~. 7Z7'

Manuf acturer

Cuniponeflt

EQS No. WBNEEB0063Appendix- I Rev ISheet Tof -

NAMCO

Limit Switch

Component IJNID Model No. Table/Sheet,

Limit Switch on:1-FCV-30-16-B EA18O 3.11-5/WBNEEBOOO4Limit Switch OU:1-FCV-30-37-B EA180 3.11-5/WBNEEB004

1-ZS-30-19-B EA180 3.11-5/WBNEEB0OO4

1-ZS-30-14-A EA.18O 3.11-5/WBNEEBOOO4

1-ZS-30-59-A EA180 3.11 -5/WBNEEBOOO4

1-ZS-30-57 -E EM180 3.1 1-5/WBNEEBOOO4

1-ZS-30-53-B EM180 3.*1 1-5/WBNEEBOOO4

1-ZS-30-51-A EA180 3.11-5/WBNEEB0OO4

1-ZS-30-7-A EA180 3.11-5/WBNEEBOOO4

1 -ZS-30-9-B EM180 301 1-5/WBNEEBOOO4

-LU

Lu

Preparer/Date *)ez&hV2M64.d//-21E.R EQS No. WBNEEB0063Appendix 2L Rev 1

Reviewer/Date 9-2-~.~'..7-& Sheet 1 of 5..

l.ý 'The limit switches listed in Appendix 1 are NAMCO series EA180 and arelocated inside the annulus. As detailed in EN DES CalculationHEB 840213 218, they are required to operate for the first 5 minutesafter the start of a LOCA, ERR line break, CYCS line break, feedwaterline break, and main steam line break. They must not fail in a mannerdetrimental to plant safety for 100 days following a LOCA, main steamline break or feedwater line break and for 1 month following 111R orCVCS line breaks.

2. Operating Environment

The switches are required to operate in the following environment:

Norma AbnrmalAccident

Temperature: 110OF 120OF 150OF (LOCA2)Pressure: Atm(-) Atm(-) Atm(-)Relative Humidity: 80% 90% 100%Radiation: 2.07xl07 rads NA 5x107 rads

3. Qualification

NAMCO tested these switches to the requirements delineated in IEEEStandard 323-1974. Test procedures and results are documented in AMACOqualification test report No. QTR-105, Revision 3 dated August 30,1981. To qualify the switches for conditions in excess of knownapplication requirements, an accident environment simulation test wasperformed with temperatures pressure, moisture, and chemical spray in acycle as shown in Figure 1.

4. Temperature (First 5 Minutes)

The transient portion of the curve in Figure 1 more than encompassesthe initial temperature change for the first 5 minutes after the startof a worst-case LOCA as shown in Figure 2.

lRefer to WBN Environmental Data Drawing No. 47E235-44, Revision 0

2LOCA -Worst case Double Ended Pump Suction break inside primary

containment

A CTE IIDA TiVE

Preparer/Date 2f I EQS No. WBNEEB0063Appendix 2 Rev 1

Reviewer/Date . -7f Sheet 2 of 5

5. ;-TSmyerature (Next 100 Days)

The following calculations are based on the arrhenius equation whichstates:

Ll - L2e [/K .- J

Definitions: EFFECTIVELl- Qualified life DATE

OCT 1980"4L2 - Accelerated (test) life

e - Base of the natural logarithm

E - Worst case activation energy

K - Boltzmann's constant - 8.617 x 10-5 eV/OK

Tl- Absolute temperature at qualified life

T2 - Absolute temperature at accelerated life

The remaining 100 day requirement of section 1 can be extrapolated fromthe long term soak portion of the curve in Figure 1. Here the switcheswere maintained at 200OF for 26 days. Using the hxrhenius equation,an activation energy of 0.8 eV, and an average maximum temperature of130OF from the sloped portion of the curve in Figure 2, the post-accident life is determined to be 1.44 years. This is in excess ofthe 100 day requirement of section 1.

6. Radiation

The switches were subject to a total radiation dose of 2 x 108 radswhich is in excess of the combined normal and accident enviroxnmentalradiation doses of the operating enviromnent.

7. Pressure/Humidity

Pressure and humidity accident conditi.ons are not significantly moresevere than the normal-abnormal operating conditions. These Switcheshave been tested to 80 psig and 100% relative humidity.

Preparer/Date Yez 1. '.~uA

Reviewer/Date.A.&.&4 e 4 A- =~7

EQS No. WBNEEB0063Appendix _.I_. Rev 1Sheet 3 of 5

80:.-Chemical Syrav

The switch was exposed to caustic spray during portions of the DBE asshown in Figure 1. The-spray solution-was prepared and administeredin accordance with IEEE.Stanidard 13 82-1972. After testing, the switchfunctioned properly.

9. Floodinit

All switches are locateid above' ";the,.i maimum .possible flood levele'.

10. Oualified Life

Thermal aging was conducted by :placing the s ;witch in-a chamber withthe temperature maintained at 148OF for 400 hours. By using theArrhenius equation, an activation energyiýof :0.8 eV, and the maximumnormal operating temperatue of 110 0F, t~i~U~alified life i'.1determined to be 13.92 years. It is our engineering judgement thatsatisfactory performance can be expected'.for 13 years and',335 days inthe maximum normal operating environment.-

11. The above information shows that the limit switchesrequired and are fully qualified per NUREG-0588.

074144.11

will function as

EFFECTIVE,DATE__P~2

I yjnz0 > In -T)

0 Lij

24 0 w eval I te

- rema"to

320 4 switgbc osL~ t"d

20 Am.Ibi figure is a graphical ropresa.tatles, of tLb1.Is date Presented se Pa..o. 3-19 of *yindlas S.

NO I I momantary posts of 115ps P51 ressuread 3in 2e*~ * gapoegagug occurred (Nat asalolessmmaay) during so

I ' I Lb. tramaleat perioda. lb.,. posMab.re mractid is36 m Obn videoas"~ raeferncd sm fe 6 el Lb. capon. so

IW~~ft I V4 namical ay git

SeSI

I 40

L~1)0

1.0 *20

~ 11

U10 .6~ f, ' :

It 610 13 Days1Sl

ANML.US TEMPERATURE RESPONSE TO A WORST CASEDOW LE EICED PUMP SUCTION BREAK INSIDE PRIMAff

CONTAINMIENT (LOCA)

Revision LLi>I,

CD 0 rn

1 0

W0Ln,

~VF S ~i@~ m &uSepaSup c

"p. iL a a ii iiil a a I aaiiil I 3 3 iiiiil I 1 I ii1111 I 1 1111111lu I 1 1 11 1 1 .1 111 1 1 11 .11m

Preparer/Date~

Reviewer/Date, o4

'Sm

13

/ SJqVF a =SOS

mom

1042 8 goo a5 Wa 95 a a

Uniit No. 1and 2

FRevision 1 12 3* P S No OWBE E BOO6 5

Preare/~e ~ ~ i 4 See Appendix 1

Reviewer/Date ~

manufactbrwer and Yodel No0. ASCO/For model No. - See Appendix 1

Verification Of TWble Information (Table See Appendix 1

y Ml~ntTjW- The equipment has been identified as per IVA ID num~berdesignations (such as,, PUT, SDV~).

-2L Ia~im1 - The location has been identified (such as#, inside primarycontainments, annulus, individually cooled roomse, general spaces,, or areaaffected by HEL outside primary containment).

... LV== - A unique TA Mh number has been assigned (such as,, l-FSV-68-308)...x.. Functmio - A functional description of the component has been given (such as,

stea generator blowdown).*y Gtract No.. Manufactrer. and Model Ha. - The contract nwrberl manufacturer,

and model number have been given._yx. Ntmrmal or Accident Environment -All abnramal or accident environmental

conditions applicable to this equipment have been identified either in tables orby references to figures from tables.

y Envi rmmet to W~hich DMUaLfe - The environment to which the equipment has beenqualified is addressed in either the tables or the environmental analysis

Sattached.Ca-M -Acteoyo .b c,, or dhas been defined for the IEF E TVequipment. __DATE

and accuracy required and demonstrated have been defined.

Onlification Status (check if aplicable. a ~ if not) __ _ _ _ __ _ _ _ _

nnalifig...Life (If equ ipment is qualified, indicate the qualified life with anumerical entry): 40 years

X Oulification Reprt and metd - A qualification report and the method ofqualification has been identified on the Table Input Data Sheet (TIDS).

X EvirmwiAL~niAlysis - An environmental analysis has been done, attached tothe EUS, and independently reviewed by the responsible organization.

N/A Oulification by Similarity (if applicable) - A justification for qualificationby similarity is attached to the BUS considering all the above factors andreferenced to the appropriate tables.

X ulification of Several Exact Comm~nents (if applicable) - When an EUS is usedfor more than one item, a list of all exact components is given as an appendixwith all references to appropriate tables with justification for qualification

Considering all the above factors.N/A Interim Oualification (If applicable) - (open item) - Cosponent has been

determined to be qualified only for a limited interim operation, an N4CR hasbeen written, and plan of action has been determined to yield a qualifiedcomponent.Term of Interim Qualification

JLL awlfe =n - (Open itemn) - (If applicable) - CaqOnet has been* determined to be unqualified; the following is attached to EDS: NC- numberj,

reason for non-qualification, and justification of continued operation.

*Due to the extensive changes from Revision 2 , revision bars are not used.

Preparer/D at~/2L. ho- 4-&

Revi ewer/Date • vgi..L.9Z4Y

EQS No. WBNEEB006 5

Appendix 1 Rev 3.Sheet 1 of 2

Manuf aqturer

Component

AC Pfl

Rnl.nniA VAlVA

*Niot yet installed

Component UNID Model No. Table/Sheet

I 1-FSV-43-3-A 206-381-3RP 3.11-5/WBNEEBOOO2

1-FSV-43-12-A 206-381-3RF 3 .11-5/WBNEEBOOO2

1 -FSV-43-23-A 206-381 -3RF 3411-5/WBNEEBOOO2

1-FSV-32-80A-A liV206-3 80-3RD 3.1 1-5/WBNEEBOOO2

2-FSV-3 2-81A-A HV206-3 80-3RU 3.1 1-5/WBNEEBOOO2

I-FSV-32-102A-B HV206-380-3RU 3 .11-5/WBNEEBOOO2

2-FSV-32-103A-B HV206-380-3RU * 3 .11-5/WBNEEBO02

1-FSV-32-11OA-A KV206-380-3RU 3 .11-5/WBNEEBOOO2

2-FSV-3 2-11 lA-B HV206-380-3RU * 3.*1 1-5/WBNEEBOOO2

I-FSV-31-305-B 206-381-2F 3 .11-5/WBNEEBOOO2

2-FSV-31-305-B 206-381-2F * 3.11-5/WBNEEB00O2

1-FSV-31-30 9-B 206-381-2F 3 .11-5/WBNEEBOOO3

2-FSV-3 1-30 9-B 206-3 81 -2F 3.1 1-5/WBIIEEB0OO3

I-FSV-3 1-326-A 206-381 -2F 3.1 1-5/WBNEEBOOO2

2-FSV-31-326-A 206-381-2F 3 .11-5/WBNEEBOOO2

1-FSV-31-330-A 206-381-2F 3 .11-5/WBNEEBOOO3

2-FSV-31-330-A 206-381-2F 3 .11-5/WBNEEB0OO3

EI 1-FSV-43-54D-B 206-381 -3RP 3.1 l-4/WBNEEBOOO7

2rFSV-43-54D-B 206-381 -3R7 3.1 1-4/WBNEEBOOO7

A 0 f-f%

Solenoid Valve

Preparer/Date Z/____________

R evi ewer/Date ,A1/7 Iwca.a 12 -

Manuf aqturer

Component

EQS No. WNBO6Appendix 1 Rev 3..a...Sheet 2 of 2

ASCO

Solenoid Valve

Component UNID Model No. Table/Sheet

I11 l-FSV-31-308-A 206-381-2F 3.11-4IWBNEEBOOOS2-FSV-3 1-308-A 206-381 -2F 3.1 l-4/WBNEEBOOO 9l-FSV-31-327-B 206-381-3F 3-11-4/WBNEERDOOO81 -FSV-31 -329-B 206-381-2F 3.*1 1-4/WBNEEBOOO82-FSV-31-3 29-B 20-812 .1 1-4/WBNEER000Q

LIZ

LU

Preparer/Date /~4

Reviewer/Date J•/~? 4 A~''-2~~

EQS No. WBNEEB0065Appendix 2 Rev 3Sheet 1 of 11

L. 1. For the s~lenoid valves on Appendix 1 under heading 1:

1-Fsv-43-3-A1-FSV-43-12-A1-FSV-43-23-A1-FSV-3 2-BOA-A2-FSV -32-81 A-A1-FSV-32-102A-B2-FSV-32-103A-B1-FSV-32-11OA-A2-F SV-3 2-11 lA-B1-FSV-31-305-B2-F SV-3 1-305-B1-FSV-31-309-B2-FSV-3 1-30 9-B1-FSV-31-326-A2-FSV-31-326-A1-F SV-3 1-330-A2-FSV-31-330-A

AnnulusAnnulusAnnu lusAnnulusAnnulusAnnulusAnnulusAnnulusAnnulusAnnulusAnnulusAnnu lusAnnulusAnnulusAnnulusAnnulusAnnulus

ELEVELEVELIVELEVELEVELEVELEVELEVELEVELIVELIVELIVELEVELEVELIVELIVELIV

723723741730716716730725725737737737737737737738738

The solenoid valves listed above are ASCO Models 206-380 and206-381. As detailed in IN DES Calculations NIB 840321 218 for theSampling System (System 43), NIB 840314 222 for the Control Air System(System 32), and NIB 840314 231 for the Air Conditioning System(System 31), these valves are required to operate for 5 minutes afterthe start of a LOCA, Main Steam line break, or Main Feedwater linebreak, and not fail in a manner detrimental to plant safety for 100days thereafter. Additionally, they must operate for 5 minutes after a

line break in the Residual Heat Removal and Chemical Volume ControlSystems and not fail in a manner detrimental to plant safety for 1month thereafter.

2. These solenoid valves are subject to LOCA/HELB conditions and arerequired to operate in the following environments'.

Normal Abnormal Accident

Temperature:Pressure:Relative Humidity:Radiation:

Spray/Flooding:

11 0OFAtm80%2xl07rads(40 years TID)N/A

120OFAtm90%

N/A'

'Per WBN Environmental Data Drawing 47E235-44.

150O0FAtm100%5zl0 7 rads

N/A\EFFECTIVEDATE

UOCT 198 '034

Preparer/Date - a EQS No. WBNEEB0065Appendix 2 Rev 3Sheet -2 of 11

11. 1. For tife solenoid valves on Appendix 1 under heading II:

l-FSV-43-54D--B2-FSV-43-54D-B

Lover ContainmentLower Containment

The solenoid valves listed above are ASCO Model 206-381. As detailedin EN DES Calculation NEB 840321 218 for the Sampling System(System 43), these valves are required to operate for 5 minutes afterthe start of a LOCA, Main Steam line break, or Main Feedvater linebreak, and not fail in a manner detrimental to plant safety for 100days thereafter. Additionally, they must operate for 5 minutes after aline break in the Residual Heat Removal and Chemical Volume ControlSystems and not fail in a manner detrimental to plant safety for 1month thereafter.

2. These solenoid valves are subject to LOCA/HELB conditions and arerequired to operate in the following environments.

Abnormal

Temperature:Pressure:Relative Humidity:Radiation:

Spray/Flooding:

120OFAtm80%2xl07 rads(40 years TID)N/A

130OFAtm100%N/A

Accident

3270 F26.4 psia100%1x108 rads

Spray only

111. 1. For the Solenoid valves on Appendix 1 under heading III:

1-FSV-3 1-308-A2-FSV-31-308-A1-FSV-31-327-B1-FSV-31-329-B2-FSV-31-329-B

Containment Instrument RoomContainiment Instrument RoomContainment Instrument RoomContainment Instrument RoomContainment Instrument Room

The solenoid valves listed above are ASCO Model 206-381. As detailedin EN DES Calculation NEB 840314 231 for the Air Conditioning System(System 31), these valves are required to operate for 5 minutes afterthe start of a LOCA, Main Steam line break, or Main Feedvater linebreak, and not fail in a manner detrimental to plant safety for 100days thereafter. Additionally, they mustf operate for 5 minutes after aline break in the Residual Heat Removal and Chemical Volume ControlSystems, and not fail in a manner detrimental to plant safety for 1month thereafter.

2 Per WBN Environmental Data Drawing 47E235-42.

PDATE'AC ~2

ELEV 716ELEV 716

ELEV 737mEdEV 737ELEV 716KLEV 716ELEV 716

Preparr/Dat

Revijewer/Date &Vr

A%- No. WBNEEB0065heudix 2 Rev 3

Sheet 3 of 1..LZ~2~

2. These solenoid valves are subject to LOCA/RELD conditions and are

requited to operate in the following enviroiuent3.

Normal

Temperature:Pressure:Relative Humidity:Radiation:

Spray/Flooding:

7507

At.6013.5xl04 rads(40 years TID)NIA

120OFAt.901N/A

N/A

Accident

3270126.7 psia1001WOO0 rads

.Spray only

IV. 1. qualification Testing:

a.ASCO has tested the 206-380 and 206-381 series solenoid valves to

the requirements of IEEE Standard 323-1974 and NUREG,-0588. Thetest criteria and results are documented in ASCO test reportAQS21678/TR, Revision A. All qualification and tests were

performed st test levels or conditions in excess of known maximum

application requirements. These margins are in accordance with the

margins suggested by IEEE Standard 323-1974.

b. Seven solenoid valve samples representing six generic families of

valves including the 206-380 and 206-381 series, were subjected to

sequential exposures of elevated temperature, radiation, wear

aging, seismic simulation, vibration endurance, accident radiation

and a 30 day LOCA simulation. Baseline functional tests were

performed before the start and after each sequence of the test

exposure with the exception of coil dielectric and insulation

resistance measurements which were taken before thermal aging,

after accident radiation, and after LOCA exposure. The valves were

energized and deenergized at high and low pressures during the test

phases (except radiation) and valve leakage monitored.

c. Baseline/Functional Test: Baseline/Functional tests consisted of

measurement of coil excitation, seat leakage at high and low

pressures, noise test, operational test, and external leakage test

before and after all phases of type tests. Measurement of

insulation resistance and coil dielectric test was performed in the

as received condition and after comple.tion of accident radiation

and LOCA simulation. Valvwsere energized and deenergized and

their operation monitored during test (except radiation).

d. Thermal aging: The valves were subjected to an aging temperature

of 268*F for a test duration of 12 days. They were cycled

(deenergized for five minutes and then energized) every 6 hours. -

E FFEC L3per WIN Environmental Data Drawing 47E235-45. 1

Abnormal

Preparer/Date /3 \~U ~ 4 '2-' EQS No. WBNEEB0065

Reiee/Dt Appendix 2 Rev 3Re jwe/at L-'dw4a...- Sheet 4 of 11

e. Radiation: The valves vere subjected to cobalt 60 (gamma)radiation at an exposure rate of less than one megarad per hour.Total integrated dose received was 50 megarads.

f. Wear aging: The valves were electrically cycled 40,000 times atmaximum pressure differential.

g. Seismic Simulation/Vibration Endurance: The valves were subjectedto a combined SSE and fragility test. The input g. level was 7g'Is. The test was performed with the valves energized anddeenergized and with high and low pressure. The leakage rate wasmonitored.

h. Accident Radiation: The valve. were subjected to cobalt 60 (gamma)radiation at an exposure rate of less than one megarad per hour.Valves received an additional accumulated dose of 150 megarads fora total integrated dose of 200 megarads received in two stages.

i. LOCA Simulation: The valves were subjected to a simulated loss-of-coolant accident (LOCA) by exposure to steam and to chemical sprayfor 30 days. LOCA simulation conditions were as follows:

Temperature - Maximum of 346*F for a total period of 6 hoursfollowed by a step decrease to 200*F within 4 days followed by post-DBE conditions of 200*F for the remaining 26 days.

Pressure - Maximum of 110 psig for a total period of 6 hoursfollowed by a step decrease of 10 psig within 4 days followed bypost-DBE conditions of 10 psig f or remaining 26 days.

Relative Humidity - All steam environment in excess of 250*F;greater than 90% for other conditions.

Chemical Spray - The chemical solution consisted of 3000 ppm. boronas boric acid in solution with 0.064 molar sodium thiosulfatebuffered with sodium hydroxide. The chemical solution pH wasmaintained between 9.5 and 10.5.

j.Results: One of the valves malfunctioned during thermal aging.The valve developed excessive seat leakage both in the energizedand deenergized state. This was later determined to be caused bydirt in the valve. The source of dirt was the iron pipe used inthe cylinder port as piping and an additional length used tosimulate an accumulator.

Other than above malfunction, the valves successfully completed thesequential type tests and the baseline/functional tests,

E FFV IHV EDAlT E

PreprerDat Zf 2,rA4 EQS No. WBNEEB0065Appendix 2 Rev 3

Reviewer/Date /(1~,(~I. -(fJ Sheet ..L: of 11

2. Qualified Life - The solenoid valves have a qualified life of 40 yearsand 40,000 cycles, providing the maintenance schedule outlined in paragraph4 is providing the maintenance schedule outlined in paragraph 4 isfollowed. Open and close completes one cycle. However, due to the self-heating nature of solenoid valves, the temperature rise associated with acontinuously energized solenoid valve must be accounted for in thequalified life calculation. There are two areas affected by this heating:(1) the coil sees an increase of 105*C (221*F) above ambient and (2) theelastomeric discs see an increase of 45*C (113*F) above ambient. Thesetemperature increase values come from Franklin Research Center's "TestProgram and Failure Analysis of Class IE Solenoid Valves" (NURBG/CR-3424, F-C5569-309/315) .

Based on the above information, a separate qualified life must be calculated for boththe coil and the disc. The following qualified life calculations, which are based onthe Arrhenius equation, are for valves to be used at a normal ambient operatingtemperature of 110*F (43.3*C):

Ll- L2e K-T T2 ]

COILS

In Franklin Research Center's "Test Program and Failure Analysis of Class lESolenoid Valves" (NUREG/CR-3424, F-C5569-309/315), the solenoid coils were aged attwo rates: 150*C (3OP*F) for 9.3 days (223.2 hours) and 131*C (268*F) for 15.3 days(367.2 hours).

Li- Qualified life (first aging rate)

L2- Accelerated (test) life - 223.2 hours

E - Activation energy - 1.00 eV

K - Boltzmann's constant - 8.617 z 10-5 eV/*K

Tj. - Qualified temperature (ambient + 105*C) - 148.3*C

T2- Elevated (test) temperature -1500C + 1050C -2550C

e - Base of natural logarithms

E F V CH E

Preparer /Date /•/~ 4 ~-3P/ EQS No. WBNEEB0065(Appendix 2 Rev 3

Reviewer/Date ,'/.~f6ta. -CSheet 6 of 11

Ll1- Qualified life (second aging rate)

L2 '- 367.2 hours

E - 1.00 eV

K - 8.617 x 10-5 eV/9K

T11- 43.3*C + 105*C -148.3%

T2 1- 131*C + 105*C -236*C

e-Base of natural logarithms

1 ý(total) - Total qualified life - Ll+ L1 11.44 years

DISCS

In ASCO test report AQS-21678/TR, supplement 3, the entire valve was aged at l31PC(268*F) for 12 days (288 hours).

Li-Qualified life

L2- Accelerated (test) life - 288 hours

E - Activation energy - .94 eV

K - Boltzmann's constant - 8.617 x 10-5 eV/PK

Tj- Qualified temperature - 110*F

T2 - Elevated (test) temperature - 1310C + 450C - 1769C

e -Base of natural logarithms

Ll- 11 .945 years

For the valves to be used at a normal ambient operating temperature of 120*F(48.9*C), the following qualified life calculations, which are based on theArrhenius equation, apply:

Preparer/Dat e1 '/Aaa4•22 '-f.V

Rev iever/ Date •~re-- ~.~

EQS No. WBNEEB0065Appendix 2 Rev 3Sheet 7 of 11

COILS

Ll- Qualified life (first aging rate)

L2- Accelerated (test) life - 223.2 hours

E - Activation energy -1.00 eV

K - Boltzmann's constant - 8.617 x 10-5 eV/OK

Tj- Qualified temperature (ambient + 105%) - 153.9*C

T2- Elevated (test) temperature - 150% + 1050C - 2550C

e - Base of natural logarithms

L1"'- Qualified life (second aging rate)

L2 '-' 367.2 hours

E - 1.00 eV

K - 8.617 x 10-5 eV/ K

T11- 48.90c + 1050C - 153 .90C

T2 '- 1310C + 105 0C - 236-C

e - Base of natural logarithms

Ll (total) - Total qualified life - Ll + L11 - 7.973 years

DISCS

In ASCO teat report AQS-21678/TR, supplement 3, the entire valve was aged at 1310C(2680F) for 12 days (288 hours).

Ll- Qualified life

L2- Accelerated (test) life - 288 hours

E -Activation energy -. 94 eV M

K - Boltzmann's constant -8.617 x 10-5 eV/*K AYOCT 193,

Preparer/Date Z1\aAA /9t .h /

Rev iewer/ Date LA~I4.9-Zti

EQS No. WBNEEB0065Appendix 2 -Rev 3Sheet -L:. of 11

T1 - Quallified temperature - 120*F

T2-Elevated (test) temperature - 1310C + 450C - 1760C

e-Base of natural logarithms

1-ý 7.56 years

For the valves to be used at a normal ambient operating temperature of 75*F(23.89C), the following qualified life calculations, which-are based on theArrhenius equation, apply:

COILS

Ll- Qualified life (first aging rate)

L2- Accelerated (test) life - 223.2 hours

E - Activation energy - 1.00 eV

K - Boltzmann's constant - 8.617 x 10-5 eV/*K

Tj- Qualified temperature (ambient + 105*0C - 128.89*C

T2-Elevated (test) temperature - 1504C + 1050C - 2550C

e - Base of natural logarithms

Ll1. Qualified life (second aging rate)

L2'- 367.2 hours

E - 1.00 eV

K - 8.617 x 10-5 eV/-K

Ti'- 23.89% + 1050C a 128.890C

T 2 1- 1310C + 1050C - 2360C

e 0 Base of natural logarithms

Ll (total) - Total qualified life - Ll+ L1 43.22 yearsEFFECTIVE

DATEOCT 1984

Preparer/Date

Reviewer/Date

EQS No. WBNEEB0065Appendix 2 Rev 3..L.Sheet _J of 11

DISCS

In ASCO test report AQS-21678/TR, supplement 3, the entire valve was aged at 1310C

(268*F) for 12 days (288 hours).

Ll- Qualified life

L2 - Accelerated (test) life - 288 hours

E - Activation energy - .94 eV

K - Boltzmann's constant - 8.617 x 1l-5 eV/*K

Tl- Qualified temperature -75*F

T2 - Elevated (test) temperature - 131*C + 450C - 1760C

e - Base of natural logarithms

Ll- 66.353 years

3. Installation - Valves should be installed such that the axis

in the vertical and upright position.

of the coil remains

4. Maintenance Requirements - The qualified life depends on the valve being cycled

at least every 16-18 months to ensure proper opening and closing. Coils shall

be replaced every 11.44 years and elastomeric components shall be replaced every

11 .945 years when solenoid valves are subjected to a normal operating ambient

temperature of 1100F. Coils shall be replaced every 7.973 years and elastomeric

components shall be replaced every 7.56 years when subjected to a normal

operating temperature of 120*F. Valves subjected to a normal operating ambient

temperature of 75*F do not require coils and elastomeric components to be

replaced during the 40-year qualified life. In addition, ASCO recommends that

when the solenoid valves reach 20,000 cycles,' that they be rebuilt using the

applicable spare parts kit and spare coil kit4 .

5. Valves are qualified per IEEE Standard 323-1974, IEEE Standard 382-

1972, IEEE Standard 344-1975, and applicable portions of NUREG-0588 for

the environment in which they are required to operate, providing the

maintenance schedule in paragraph 4 above is followed. By mathematical

analysis, the qualified post-DIE operating time can be extended to

263 days.

4ASCO Test Report AQR67368/Rev 0, Appendix C, Page C-2.

EFFECTIVEDATE

OCT 134

Preparer/ Dat_______________ EQS No. WBNEEB0065

A* Appendix 2 Rev 3Reviewer/Date zz ?.vJ Sheet 10 of 11

Calculations - Post Accident Life

Calculations are based on the Arrhenius equation which states:

Ll- L2 e

Where:

Ll- Qualified Life

L2- Accelerated (test) Life

El- Worst case activation energy, eV

K - Boltzmann's constant, 8.617 x 10-5 eV/OK

Tj- Qualified temperature, absolute

T2 - Elevated (test) temperature absolute

e - Base of natural logarithms

Calculate qualified post-accident life for valves located in lovercompartment (worst case accident temperature profile for valves listed inAppendix 1):

rEFFECTIVEDATEOCT 19`314

Prepare r/Date 44s-P2--~

Rev iewer/ Date ?-2~pEQS No. WBNEEB0065Appendix 2 Rev 3Sheet 11 of 11

- 26 da'ys (AQS21678/TR Rev. A, figure 2, page 4-21)

- 0.94 eV (AQR67368, appendix B, page B-3)

- 152.50F (temperature profile, SQNIWBN environmental data drawing

47E235-45, 190OF @ 6 x 13seconds - 115 0F @ 30 days/2 + 11507)

- 200OF (AQS21678/TR Rev. A, figure 2, page 4-21)

- 26 x 24 -624 hours

- 152.5 - 32/1.8 + 273.15 - 340 .10K

- 200 - 32/1.8 + 273.15 - 366.50K

[8.617 x 10-5 340.1 - 366.5

= 624 e

- 6318 hours - 263 days

044142.01

L E F F E C` ILPTAT E

uniit ft.1EDS No. wN.F~nEE nl79

Preparer/bateW ReiinT D Nb.

-See Appendix 1

Manufacturer and Model Nb. _ Fenwal 18003-7Verification of .Table Information (Table . e AgpendiX 1ftP_ Z - 2h~e spuiiPient has been identified as per TVA n) numb~erdesignations (such as, MV, scnr)

X LaIMUi - The location has been identified (such aso, inside primarycontainment, annulus, Individually cooled rowrs, general spaces, or areaaffected by FmB outside Primary containment).X Q= p"- A unique WA MD number has been assigned (such as, l-PS-68-308)." E~ion- A functional description of the component has been given (such as,steam generator blowdlown)." Contract lb. Manufacturer, and NOde l. The contract number,, manufacturer,and model numb~er have- bee given.- A orial Or-Accident -003ronment - All abnaormal or accident environmentalconditions applicable to this equipmient have been identified either in tables orby references to figures from tables.En Firom~t to, Which Oualif ied - .The environment to which the equipmet has beenqualified is addressed in either the tables or the enviroraental analysisattached.

___ CAUMr - A category of a, b, co, or di has been defined for the

Opeatin ad Ac Gacy Reurdand flemonstrto - The operationand accuracy reqjuired and demonstrated have been defined.

Ouaifca io Sats chek f liabll e.p NA. if not)Q~ajfidr~fr(If equipmient is qualified, indicate the qualified life with anumierical entry): 10 years

- CulifcationReprt and met1~ A qualification report and the method ofqqualification has been identified on the Table Input Data Sheet (Tms).X~~~~ A2i~mftAnAflygin - An environmental amalysis has been done, attached tothe BOS, and independently reviewed by the responsible organization._NA - liication by BIWIAritv (If aP~licable) - A Justification for qualificationbY similarity is attached to the EDS considering all the above factors andNAreferenced to the approprilate tables.- uaalificat-icnof Severa Exact Cumwiner,1 (If applicable) - When an ~ss is used-for more than one itemo, a list of all exact coiponents is given as an appendixwith all references to appropriate tables with Justification for qualificationconsidering all the above factors.ojTtri 1ualificatiM (If applicable) - (Open item) - Conponent has beendetermined to be qualified only for a limited interim opration, an NB: hasbeen written, and Plan of action has been determined to yield a qualifiedemponent.

Term of Interim Qualification _____________________

'I = - (Open item) - (If applicable) - Ccinpnent has beendetrmied o b urualified; the following is attached to a~s: NM number,reason for non-qualification, and Justification of continued operation.NM No. _ _ _ _ _ _

101T

Preparer/Date 9-A

Nanuf acturer

EQS No. WBNEEB0079Appendix 1 Ref!Sheet 17 g r"-

Fenwal

CmpOAet Temnerature Switch

Preparer/Date -I.

Reviewer/Date 40

EQS No. WBNEEB0079Appendix 2 Rev I-Sheet 1 of 2

1.* The temperature switch in Appendix 1 is Fenwal Model 18003-7 and isidentical to Model 18023-7. It is located in the Auxiliary Building(turbine Ariven auxiliary feedwater pump room: 692/A6, volume 5).As detailed in EN IES Calculation NEB 840517 222 for ContainmentVentilation System, it is required to operate for 5 minutes and notfail in a manner detrimental to plant safety for one month after breaksin either Auxiliary Boiler, PER, or CVCS lines.

2. The temperature switch is required to operate in the followingenvironment:1

Normal Abnormal Accident

Temperature:Pres sure:Relative Humidity:Radiation:

Spray/Flooding:

1040FAtm(-)80%5x102 rads(40 yr TID)N /A

11 0OFAtm(-)90%N /A

N/A

1 720FAtm100%

.4,x,04 rads(LOCA)N/A

3. The Fenwal temperature switch was qualified by test per IEEE Standard323-1974. Test procedures and results are documented in WyleLaboratories Test Report No. 17509-1 (TVA contract No. TV-56071A)dated May 16, 1983.

All qualification tests were performed at test levels or conditionsin excess of known maximum application requirements. Margins were inaccordance with those suggested by IEEE Standard 323-1974.

The switch was tested to the following environment:

Normal Abnormal Accident

Temperature:Pressure:Relative Humidity:Radiation:

Spray/F looding:

1 04OFAtm80%3.51x10 2 rads(40 yr TID)

115 0F

90%

2 13 0 F**0.8 psig**

1002W04o rads

(qualification byanalysis)

N/A

**Subjected to 3230F and 7.9 psig during accident simulation test.

The equipment was subjected to an accident si mulation test. Thetransient portion of the test was repeated twice as required by IEEEStandard 323-1974. During the first temperature excursion, thetemperature requirement of 3230F was attained in 24 seconds, with nopressure requirements imposed.

'Per WBN Environmental Data Drawings 47E235-68R0 and -69R1.

Revision

Preparer,'Date_~ --

Reviower/DcleAW

pill

Preparer/Date

Reviewer/Date

EQS No. WBNEEB0079Appendix 2 Rev1Sheet 2of 2

The second temperature ramp was started after the test chambertemperature was stabilized at 1000 F. During this ramp, the temperaturerequirement of 323OF was attained in 24 seconds. The pressure require-of 7.9 paig in 3.0 seconds was reached in approximately 1.5 seconds.Due to the chamber temperatures falling below 212 0 F, the chamberpressure was stabilized to atmospheric at 9.5 hours into the test. Theaccident test was ended at the 24-hour point.

The temperature switch was then aged to simulate 100-day equivalent(plus 10%) post-accident life and functionally tested.

The Fenwal temperature switch (Model 18023-7 which is identical to the18003-7) was shown to have a 10-year qualified life with a 5-yearunattended maintenance period. Additionally, the switch demonstrated a110-day post-accident life in accordance with IEEE Standard 323-1974.

Eased upon the above test results, this switch is qualified for Class1E operation in the required environment as well as the post-accidentrequirements.

074144.07

DT'

MRevisionReviewer/ 'ote II~Iit- M

Preparer/batej /~ ~t

Reviewer/bate M '4> AN/29 /aL

1 * 2 Unit No. 1 and 2EQS No. WBNEEB0085TVA ID No.

0-TS--30-1920-TS-30-193

MNEQUIPMENT OUALIFCfO S17M (Ens)

Manufacturer and Model No. Honeywell T675A _________

Verification of Table Information (Table SLee Appen4WxJ_

.X B~m m- The equipment has been identified as per TVA Ml numb~erdesignations (such as, NOVJ, SOV).

.X Lc~at~ion - The location has been identified (such as, inside primarycontainment, annulus, individually cooled rooms, general spaces, or areaaffected by HELB outside primary containment).

.X -W ~ A unique MA ID number has been assigned (such as, l-FSV-68-308).X Funtio A functional description of the component has been given (such as,

steam generator blowown)..X Contract No.. Manufacturer, and Model No. - The contract number, mianufacturer,

and model number have been given..X Abniormal or Accident Environment - All abnormal or accident environmental

conditions applicable to this equipment have been identified either in tables orby references to figures from tables.

X Environment to Which Oualified - The environment to which the equipmnent has beenqualified is addressed in eithr the tables or the environmental analysisattached.

X ate~r - A category of a, b, c, or dhas been defined for the EFFECTequipment. e A.L.Oeration and Accuracy Beaired and Denrrnstrate - The operationDAT

and accuracy required and demonstrated have been defined.0 V

QualfiedL~Iife (If equipment is qualified, indicate the qualified life with anumerical entry): N/A._RLA Onalification Reprt and method - A qualification report and the method ofqualification has been identified on the Table Input Data Sheet (TIDS).X- Enir~al Anlygir - An environmental analysis has been done, attached to

the EDS, and independently reviewed by the responsible organization.lILA Qualification by similarity (If applicable) - A justification for qualificationby similarity is attached to the EQS considering all the above factors andreferenced to the appropriate tables.

X -Ouplificat ion of Several Exact CoEMoents (If applicable) - When an EQS iis usedf or more than one item, a list of all exact comiponents is given as an appendixwith all references to appropriate tables with justification for qualificationconsidering all the above factors.

X -TIterim Qualification (If applicable) - (Open item) - Component has beendetermined to be qualified only for a limited interim operation, an NCR hasbeen written, and plan of action has been determined to yield a qualifiedcomiponent. SeApniTerm of Interim Qualif ication SeApniNCR No. -WBNEEB8315

lI" nbualif-ied QaMu-onnt - (Open item) - (If applicable) - Ccmponent has beendetermined to be unqualified; the following is attached to ED)S: NCR number,reason for non-qualification, and justification of continued operation.NCRNo. _ _ _ _ _ _

*Due to the extensive changes from revision 0, revision bars are not used.

I VEE.3 ..

I Revision

Dualification Status (chpck if annlirAhla Na Jf

Preparer/Date

Reviewer]Date

Hanufac turer

Component

&QS No. WBNEE BOOB5A&Z- Appendix 1 Rev 2-

z T- -6! Sheet 1 of 1

Honeywell

Temperature Switch

Component UNID Model No. Table/Sheet

3.11-6/WBNEEB00050-TS-30-192 - T675A 3.11- 8/WBNEEBOOll

3.11-6/WBNEEB00050-TS-30-193 T675A 3.11-8/WBNEEBOOll

Preparer/Date

Reviewer/Date ACe. 27 -~ '7'

EQS No. WBNEEB0085Appendix 2 Rev _2_Sheet 1 of 1

1. Temperature switches 0-TS-30-192, -193, are Honeywell model T675A.They~are located in the Auxiliary Building (Room 737/Al). As detailedin EN;DES Calculation (NEB 840213 218) for the Containment VentilationSystem, these switches are required to operate for 100 days after thestart of a LOCA and for one month after the start of a DRft, CVCS,Auxiliary Boiler, or Auxiliary Feedwater line break outside ofcontainment.

2. The switches are subject to HELB and LOCA conditions (Volume 12). Theyare required to operate in the following environments1 :

Normal Abnormal Accident

Temperature:Pressure:Relative Humidity:Radiation:Spray/Flooding:

1 04OFAtm(-)80%5xl0 2 radsN/A

3. The manufacturer has tested these switches to the following environment:

Temperature:Pressure:Relative Humidity:Radiation:

1300F2

AtmNormal plant environmentNot specified

4. See generic position 4.1.2 for radiation. See generic position 4.1.3for relative humidity.

5. The above information shows that the switches will function properly asrequired and are qualified for an interim period. However, due to thelack of sufficient documentation required by NUREG-0588, TVA willreplace these switches with qualified devices as determined by NCRWBNEEB8315.

1Per WEN Environmental Data Drawing 47E235-46R0, -47R1

2Per test data included with Honeywell letter of 8-24-84 (EEB 840828 002).

014135.01

11 0OFAtm( -)90%N/AN/A

1 290FAtm100%

IX10 4

N/A

Revisin I ES ND. WBNEEBO68 7

TVA ID No.PreparrA~teSee Appendix 1

Manufacturer and Model ND. NAMCO EA180

Verification of Table Information (Table See Appendix 1

X Flqnipmt Tj - The equipment has been identified as per TVA ID numb~erdesignations (such as, KW,, W47.

_- a~tim - The location has been identified (such as, inside primarycontainmentl, annulus, individually cooled rooms, general spaces$, or areaaffected by HELB outside primary containmient).

.x eDm±w - A unique MA ID numb~er has been assigned (such as, l-FSUV-68-3O8).Y. Puncti - A functional description of the ccmqvnent has been given (such as,

steam' generator blowdown).G Cutract: No.. Man facturer. and Modiel No. - The contract nurberg manufacturer,and model number have been given._

X NA rl-oiior Accident Envirorsent -All abnormal or accident environmental

coniditions applicable to this equipmient have been identified either in tables orby references to figures fromr tables.

X Envir6[nrrjbt to Which 6uai~fied - The environment to which the equipmnent has beenqualified is addressed in either the tables or the environmental analysisattached.

.. X Ca1te y- Acategory of a,,b, c,, or d.has been defined for the

equipmuent.- Operation an Accuracy Reqired. tnd enxnntrated - The operation

and accuracy req .uired and!.deonsti -a ,tid have been defined.

Doulification Status -(check if-agppicable. NA if notlQumlifie..Iile (If equipzueni is qualified, indicate the qualified life with anumerical entry): 5.147 ..~Lears

__L QUjajficaiori Reprt and Method - A qualification report and the method ofqualification has been identified on the Table Input Data Sheet (TIDS).

_L Endir2gintal Analygi - An environmental analysis has been done, attached tothe BDS, and independently reviewed by the responsible organization.

.JiLA fLuAlification by Similarity (if applicable) - A justification for qualificationby similarity is attached to the ODS considering all the above factors andreferenced to the appropriate tables.X ulification of Several Exact XMC=zxoet (if applicable) - When an MS is usedfor more than one item, a list of all exact cxmý ets is given as an appendixwith all references to appropriate tables with justification for qualificationconsidering all the above factors.

NL/A Interim Qualification (If applicable) - (open item) - Comuponent has beendetermined to be qualified only for a limited interim operationt an NCR hasbeen written, and plan of action has been determined to yield a qualified

oMkAoknt.Term of Interim QualificationNCR No.

N1LA M MAlified r&Me - (Open item) - (If applicable) - Catponent has beendetermined to be unqualified; the following is attached to EQS: NCR number,reason for naon-qualificationj, and justification of continued operation.

EFFe -TIVE0 UT 1984

Preparer/Date

Reyl ewer/Date 15_____fos______

Nanuf acturer

Ccoponent-

EQ No. 'WBNEEBOOB7Appendi x I lev 4Sheet 'r o

NANCO

Limit Switch-

Component IINID Mode No. Table/Sheet

I-ZS-1-12 EAlBO, 3.11-6/WBNEEBOOQ5_____________________3. 11-8/WMB EEBQO11

I-ZS-1-23 UA180 '

I'-ZS-1-30 EA180 R1

I-ZS-1-5 EA180

F->~

FRevisionP reporer/Date --

Preparer/Date.xlzY11 117NReviewer/Datej x ______________________

EQS No. WBNEEB0087Appendix _L_ RevSheet 1 of

1.The litait svitches listed below are NAMO series EA180 and are locatedinsi-de- the North and South Steam Valve roams, Al and A2, at elevation

7 *7,~s'ndicated below:

DAT North SouthOCT k4

1-ZS-1-12 I-ZS-1-301-ZS-1-23 I-ZS-1-5

As-detailed in EN DES Calculation NEB 840515 219, they are required tooperate for 100 days after the start of a Main Steam or Feedwater linebreak.

2. Operating Environment

These devices are required to operate in the following environment:1

Normal Abnormal Accident

Temperature:

Pressure:Relative Humnidity:Radiation:

130OF

Atm(-)50?3.5xl04 rads (North)3.5x105 rads (South)

140OF

Atm(-)100%N/A

3250 F (North)323 0 F (South)Atm,100%1x10 4 rads

3. Qualification

NANCO tested these switches to the requirements delineated in IEEEStandard 323-1974. Test procedures and results are documented in NANCOqualification test report No. QTR*D5, revision 3, dated August 20, 1981.To qualify the switches for conditions in excess of known applicationrequirements, an accident environment simulation test was performed withtemperature, pressure, moisture, and chemical spray in a cycle as shownin Figure 1.

4. Radiation

The switches were subjected to a total radiation dose of 2x108 radswhich is in excess of the combined normal and accident environmentalradiation doses of the operating environment.

5. Temperature

The test curve in Figure 1 more than encompasses the HELE temperatureversus time curves of both the North and South Steam Valve rooms shownin Figures 25 and 26.

The following calculation is based upon the Arrhenius equation whichstates: I

*l L2 e I[XE T - T

Revision IR)I__ __Preparer/Dote

Reviewer/Dote H6.0-zI'Per WEN Environmental Data Drawing No. 47E235-76 RO.

Preparer/Date 4mdc%1 6-9

Reviewer/Date__________________

EQS No. WBNEEB0087Appendix 2 Rev 1Sheet 2. of 5

Definitions:

Ll- Qualified life

L2 - Accelerated (test) life

e - Base of natural logarithms

E - Worst case activation energy

K - Boltzmans constant - 8.617 z 10-5 eV/OK

T1- Absolute temperature at qualified life

T2- Absolute temperature at accelerated life

The 100-day operating requirement of section 1 can be extrapolatedfrom the long-term soak portion of the curve in Figure 1. Here theswitches vere maintained at 200OF for 26 days. Using the Arrheniusequation, an activation energy of 0.8 eV and using an averagetemperature of 151OF from the linear portion of the curves in Figures25 and 26, the post-accident life is determined to be 195 days whichis in excess of the 100-day requirement of section 1.

Pressure/Humidity

These switches have been tested to 70 psig and 100% relative humiditywhich encompasses the worst case HELB pressure and humidity versustime-curves as shown in Figures 25 and 26.

Qualified Life

Thermal aging was conducted by placing the switch in a chamber withthe temperature maintained at 248OF for 400 hours. By using theArrhenius equation, an activation energy of 0.8 eV, and the maximumnormal operating temperature of 1300F, the qualified life isdetermined to be 5.147 years. It is our engineering judgment thatsatisfactory performance can be expected for 5 years at the maximumnormal operating temperature.

The above information shovs that these limit switches will function asrequired and are fully qualified per'NUREG-0588.

[EFFECTIVE,ýD AT E94~

Revi~ion

PLrepGarer/Dote

Reviewer/Dote -

074144.05

EQS No. W~3N EEB0087

Appendix 2 Rev. I

Sheet 3 of 5

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.EQS No. WBN EEB0087Appendix 2. Rev.Sheet 4 of 5

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Preparer/Date

Reviewer/Date

~~4-U4u' 6 QS No. WBNEEBOOB7Appendix 3. Rev .~

_______________________ Sheet 1 of

The devi-tes listed below require sealing of the conduit entrance.Qualifi -cation of the conduit seals is documented in the referencedEQS.

Comp~onent UNID

WBN-EEB-CSC-1

WBN-EEB-CSC-1

WBN-EEB-CSC-1

1-ZS-1-12

1-ZS-1-23

1-ZS-1-30

1-ZS-1-5 WBN-EEB-CSC-1

D, A T .

rEF F7rCTI

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EQS .F

Revision 1~l

Prparer/eate 6-56W1•id7'tWVVVI1

un~it ND.1EDS ND.- _________

OVA EDNoSee Appendix 1

m HEfln!F= oi rICON~ SF= (IDS)

Manufacturer and Yodel MD !NAMCO EA180Verif ication of Table Infommtion (Table See Appendix 1

I Reviewer/bate A/'&ý

X- 7b~e equipuient has been identified as per TVA ID numberdesignations (such as, IMF SCI).

L.. A±tIM - "The location has been identified (such as, insid rmrcontainments annulus,, individually cooled rowls, general spaces, or are

X affected by FOB outside primary containment).Q~mant- A unique VA 33D numb~er has been assigned (such as, l-FSV-68-308).

X £iztion - A functional description of the compnent has been given (such aso,steam generator bla.Idown).

X Qitract No~., MUfacturer. Mod kxe1l No- - 7he contract numbers manufacturersand model numb~er have been given.

X Ahtor~al or Accident 03vironment - All abnormal or accident envirormientalconditions applicable to this equipment have been identified either in tables orby references to figures from tables.

X MnvirMzret to Which Qualified - The environment to which the equipment has beenqualified is addressed in either the tables or the environmental analysisattached.

X ~tM - A category of a, b,, c, or d has been defined for theequipment.

L_ Cora ion and Accur~ay aegired an flemmostrated - The operationand accuracy required and demonstrated have been defined.

flualification Status (check if applcable. NA if not)QulifiedLife (if equipment is qualified, indicate the qualified life with anumerica~l entry): 8.392,yrs.

xL Qjaliicat iomn 4!~r and Method - A qualification report and the method of

qualification has been identified on the Table input Data Sheet (2¶1DS). t

NAthe EDS, and independently reviewied by the responsible organization.N/A nalification bySimilarity (If applicable) - A justification for qualification

by similarity is attached to the MS considering all the above factors andNAreferenced to the appropriate tables.N/M~al if icat ign of Several Exact CoMpnent (If applicable) - When an MS is used

for more than one item, a list of all exact ocmAonIts is given as an appendixwith all references to appropriate tables with Justification for qualification

NAconsidering all the above factors..NAinterim Qualificatio (If applicable) - (open item) - Cuiponent has been

determined to be qualified only for a limited interim operation# an NCR hasbeen written# and plan of action has been determined to yield a qualifiedccxijicent.Term of Interim Qualification

N/A- 2"ualfied Q=== - (Open item) - (If applicable) - Couqjrent has beendetermined to be unqualified; the following is attached to EDS: NCR number,,reason for ron-qualification,, and justification of continued operation.

EFFECTIVifD A

Preparer/Date

Royev!mer/Date______ _______

Manuf acturer

Component_

EQS No. -- WBNEEB0088Appendix 1 Rev ISheet 1-

NAMCO

Limit Switch

Preparer/Date9

Reviever/DatEQS No. WBNEEB0088Appendix 2 Rev ISheet 1 of 5....

1. The limit switch listed in Appendix 1 is a NAMCO series EA180 andis located inside containment in the Lover Compartment:

As detailed in EN DES Calculation NEB 840517 222, it is requiredto operate for 5 minutes after the start of a LOCA, Main Steam linebreak, Feedwater line break, ERR, and CVCS line breaks. It must notfail in a manner detrimental to plant safety for 100 days following aLOCA, Main Steam line break or Feedvater line break, and 1 month for aERR or CVCS line break.

2. Operating Environment

The switch is required to operate in the following environment1 :

Abnormal

Temperature:Pressure:Relative Humidity:Radiation:

1200FAt=M~80%2x107 rads(TID)

130OFAtm(l)1002NIA

Accident

3270 F26.4 psia1002lx1o8 rads

3. Qualification

The manufacturer has tested the switch to the following environment:

Normal (cident)

Temperature:Pressure:Relative Humidity:Radiation:

24801 (3460F)Atm (70 psig)NIA (1002)2.04 x 108 rads

lPer WBN Environmental Data Drawings 47E235-41 RO and -42 R1.

DATE r~evisionOCT 1924

R1

Preparer/Date P

Reviewer/Date -fr

EQS No. WBNEEB0088Appendix 2_L Rev ISheet 2 of 5....

RAMCO tested the switch to the requirements delineated in IEEE Standard32Y-1974. Test procedures and results are documented in hNACO qualificationtest report No. QTR-105, Rev. 3 dated August 20, 1981. To qualify theswitch for conditions in excess of known application requirements, anaccident environment simulation test was performed with temperaturespressure, moisture, and chemical spray in a cycle as shown in Figure 1.

4. Radiation.The switch was subjected to a total radiation dose of 2x108 rads whichis in excess of the combined normal and accident environmental radiationdoses of the operating environment.

6. Temperature.

The test curve in Figure 1 more than encompasses the initial temperaturechange for the first 5 minutes of operation for lower compartment shownin Figure 2.

The following calculation is based on the Arrhenius equation which states:

Ll- L2 e

Definitions:

Ll- Qualified lifeL2 - Accelerated (test) lifee - Base of natural logarithmsE - Worst case activation energyK - Boltzmann's constant - 8.617 x 10-5 eV/OKTl- Absolute temperature at qualified lifeT2- Absolute temperature at accelerated life

The 100-day post accident requirement of section 2 can be extrapolatedfrom the long-term soak portion of the curve in Figure 1. Here, theswitches were maintained at 200OF for 26 days. Using the Arrheniusequation, an activation energy of .8eV and using an average temperatureof 1530F from the linear portion of the lower compartment temperature vs.time curve in Figure 2, the post accident life is determined to be 181days which is in excess of the 100-day requirement of section 1.

6. Pressure/Humidity

The switch has been tested up to 70 psig and 100% relative humidity which

encompasses the worst case pressure and humidity of Section 2.

E F FE CJ I V___________

DATE Rev~sion -934errr/~t6,-

Preparer/Date 7e ES No. WBNEEBOO88.Appendix -2- Rev -L

Reviewer/Date Sheet L..of -L.5

7. Cbemical -Spray

The' switch was exposed to caustic spray during portions of the DBE asshown in Figure 1. The spray solution was prepared and administeredin accordance with IEEE Standard 382-1972. The chemiical spray contentwas more severe than Watts Bar Nuclear Plant's worst case containmentspray.

8. Qualified. Life9

Thermal aging was conducted by placing the switch in a chamber with thetemperature maintained at 248OF for 400 hours. By using the Arrheniusequation, an activation energy of 0.8 eV, and the maximum normaloperating temperature of 1200F, the qualified life is determined to be8.392 years. It is our engineering judgment that satisfactory performancecan be expected for 8 years and 143 days at the maximum normal operatingt emperature.

9. The above information shows that the limit switch will function asrequired and is fully qualified per NURBG-0588.

034147.02

FF CIVE1D AT E.KOT T9,84

Revision ____I__ -

Prepcr:

EQS No. WBNEEB0088Appendix 2 Rev. ___

Sheet 4 of 5

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CONAINDNTTEMERTURED DOUBLE ENDED PUMP SUCTION BREAK (LOCA)ANO'MOST SEVER STERHLINE BREAK (HELD) COMBINED

EQS No. WBNEEB0088Appendix 2 Rev.Sheet 5 of 5

LM

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If WIN~ IEI 6tb1 FICMrC= EZELL= ES

Manufacturer and Widel No. Fenwal Model No. 18023-7Verification of Table Information (Table See Appendix 1

.L- JU mmtM=- The equipment has been Identified as per WA 3CD numberdesignations (such as, NO~, MC7.

Y... ZUat42 -The location has been identified (such as, Inside prizmarycoontairarient, annuluss, Individually cooled roats,, general spaceso, or areaaffected by RUB outside prlimary containment).

X onent - A unique WA ID numb~er has been assigned (such as, l-1%V-68-308).Y. Punction - A functional description of the couponent has been given (such ast

steam generator blca'down).x Qmtract W.. HMnufacturer. And Hoftl No-. - The contract number, manufacturers,

and model number have been given.Y Abrariml or Acciftnt Environme~nt - All abnormal or accident environmental

corditions applicable to this equipmnent have been identified either in tables orby references to figures from tables.

X ?anvirmnnet to bhich Qualifie - The envirornment to which the equipanent Mas beenqualified is addressed in either the tables or the environmental analysisattached.

L.CategMr - A category of as, bs, cs, or d has been defined for theequipment.

X CQeration and Accuracy Reqired and Dersrae he operationand accuracy required and demonstrate have been defined.

Ouslificatign Status -(check if am1icable. M& if 0=1tQuaflifiedLife (If equipment is qualifieds, indicate the qualified life with anumwerical entry): .10 Xas

xL Oualification Report and Metbad - A qualification report and the method ofqualification has been identified on the Table Input Data Sheet (TIDE).

Y.... kivironn~tAl Analysis - An envirornmental analysis has been done, attached tothe BUS, and independently reviewed by the responsible organization.

*.Mi kawl if icat ioni ka Similarity (If applicable) - A justif ication for qualif icationby similarity is attached to the EDS considering all the above factors andreferenced to the approprilate tables.

Y..L Qualification of Several Exact Casmoent (If applicable) -Whetn an ODS Is usedfor more than one items, a list of all exact cmIponents is given as an appedixwith all references to appropriate tables with Justification for qualification

NAconsidering all the above factors.Inteim 0aalIf ication (If applicable) - (open item) - Cajtponent Mas beendetermined to be qualified only for a limited interim operations, an NCR has.been vrittens, and plan of action has been determined to yield a qualif ied

Tvrm of Interim Qualification_____________________NCR MD.

.. ~A~2~a~ifidS ~r~ -(Open item) - (if applicable) - Cai~onent has beendetermined to be unqualif ied; the following is attached to EDS: NM~ number,reaso for nM-qualification, and justification of continued operation.

EFFACTIVE13,E

* OQ1 *3,14

PreparerADatei- LtA9 .

Reviewer/a~te /",-4 ar

I Unit MD. Common (0)MS JID WBNEEBOO89

See Appendix 1-

Rtevt seer/DateEQS NO. WBNEEB0089Appendix-l 1 Rev- 1sheet =orT

Nanufacturer

Component - Temperature Switch

Component DUND Mode NO. Table/Sheet

3. 11-8/VIBNEEB0O110-TS-12-92A 18023-7 3 .11-6/UIBNEEB0006

0-TS-12-92B 18023-

0-TS-12-99A 18023-7 I

0-TS-12-99B 18023-7 '

O0-TS-12-91A 18023-7 3H~~89O-TS -12-191B 18023-7

D 'TOCT

PRevision ct 'R -

rxcviewver,.'Dot -

Lf~$4cA.~ I-91

Epnwa1l

a

T, / 6 -9 -'s -1

Preparer/Date EQS No. WBNEEB0089-- -

Appendix 2- Rev 1..Sheet 1 of- 3

I. The switches listed on Appendix 1, heading I, are located in the AuxiliaryBuilding on Elev 692, Room A14. Per IN DES Calculation NEB 840515 223 forthe Auxiliary Boiler System, they are required to operate for one minutefollowing the start of an Auxiliary Boiler line break. For the purpose ofqualification, it will be assumed the devices must operate for one hour andone minute to satisfy the margin requirement of NURBG 0588.

Operat ing EnvIronment

The switches are required to operate in the following environment:

Normal AbnormalI Accident

Temperature:Pressure:Relative Humidity:Radiation:

Spray/Flooding:

104OFAtm(-)80%I .75xlO3rads(40 years TID)NIA

110OFAtm(-)90ZN/A

N/A

143OF (see note)Atm(+) (see note)100% (see note)

<1x104 rads

N/A -

NOTE: The above normal, abnormal, and accident environmental conditions can befound on WBN Environmental Data Drawing 47 E235-40R1.

IL. The switches listed on Appendix 1, heading IT, are located in the AuxiliaryBuilding on Elev 729, Room A6. Per EN DES Calculation NEB 840515 223 forthe Auxiliary Boiler System, they are required to operate for one minutefollowing the start of an Auxiliary Boiler line break. For the purpose ofqualification, it will be assumed the devices must operate for one hour andone minute to satisfy the margin requirement of NURBG 0588.

Overatius. Envirinunent

The switches are required to operate in the following environment:

Normal Abnormal Accident

Temperature:Pressure:Relative Humidity:Radiation:

Spray/Flooding:

104 0 FAtm(-)80%5xl02rads(40 years TmD)N/A

1100FAtm(-)

90%<lxl04rads

N/A

1250F (see note)Atm(+) (see note)100% (see note)NA

NIA

NOTE: The above normal, abnormal, and accident environmental conditions canbe found on WBN Environmental Data Drawing 47 E235-39R1.

Preparer/Date - 'EQ S No. WBNEDOO089- -/ Appendix -2. Rev-'I

Reviever/Date She 2o -3

III. TVA has qualified the temperature switches listed on Appendix 1 bytepting to the requirements delineated in IEEE Standard 323-1974.Test procedures and results are documented in Wyle Laboratories TestReport No. 17509-1 dated May 16, 1983.

M~int- (Qualified. Life)

The switches were thermally aged for a minimum of 102 hours at a minimumtemperature of 780C (172.40F). Considering a 1040F maximum normaltemperature and an activation energy of 1.69 eV, when the Arrheniusequation below is used, the qualified life of these switches is 10years. However, as delineated in the test report, the maximuunattended maintenance interval is 5 years. These switches have alsobeen cycle aged.

Arrhenius equation:

Ll L2 e

where

11 - Qualified life

12 - Accelerated (test) life

E - Worst case activation energy, OV

k - Boltzmann's constant, 8.617 x 10-5 eV/OK

Tl- Qualified temperature, absolute

T2 - Elevated (test) temperature, absolute

e - Base of natural logarithms

Reference: ERHI, IP-1558. Research Project 890-1, dated September 1980.

Hu~midityv and- Radiat ion

See generic positions 4.1.2 on Radiationi and 4.1.3 on RelativeHumidity.

&T iV EDI A E984e

. - .-- - --- r R / Z I - %C 4S No. WBNEEBOO8-9- - -Revieer/Dae. r-Append ix 2- ReRevie er/D te ~Sheet 3 of -3

Acc-ident-- and- Post- Accid-ent-

Thi equipment was subjected to an accident simulation test. Thetransient part of the test vas repeated twice as required by IEEEStandard 323-1974. During the first temperature excursion, thetemperature requirement of 3230F vas attained in 24 seconds. with nopressure requirements imposed.

The second temperature ramp vas started after the test chambertemperature was stabilized at 1000F. During this ramp, the temperaturerequirement of 3230F was reached in 24 seconds. The pressure require-ment of 7.9 psig in 3.0 seconds was reached in approximately 1.5seconds. Due to the chamber temperature falling below 2120F, thechamber pressure was stabilized to atmospheric at 9.5 hours into thetest. The accident test was ended at the 24-hour point.The temperature switch was then aged to simulate 100 days equivalentpost-accidentdlife and functionally tested.Based on the above test results, these switches are qualified for ClassIE operation in the required environments and will remain operationalfor the required post-DIE period.

064143.08

~ Revision

Prepo. W/Ot- - -

O UIReviewer/Do-te

Preparer/bate "7JC k

ReviewerAbate

Unit NkD. 1 and 2POS No. WNEO9

See Appendix 1

26~ uT.laM ddkunPcATTot gsr IES)

isant~tuer ~Custom Component 604Gverification of 1'1'able Information (Table Sep Appendix 1

X~ The equipment has been identified as per WA ID numberdesignations (such as, KY', SCM?.Ja... ga~t~iM - The location has been identified (such as, inside primiaryoontainment, annulus, individually cooled room,, geneial spaces, or area

X affected by RM[ outside primary containment).Qapmgnt- A unique TVA W numb~er has been assigned (such as, l-FSV-68-308).

iiJnctiuoi - A functional description of the ocmqonent has been given (such as,steam generator blow'6oen).

x Qnrc gMuatueadn&J& - The contract numb~er,, manufacturer,and model nmiber have been given.

_L_ Akrnornal or Accident EDvironvnej. - All abnormal or accident environmentalconditions applicable to this equipiment have been identified either in tables or

X by references to figures from tables.X yirMn~et to Which Qualifie - The environment to which the equipmnent has been

qualified is addressed in either the tables or the envirormental analysisX attached...L atem - Acategory of a, b, c, or dhas been defined for the

equipment.9 Opration an AccuraCy Beqired and Demonstratd- The operationand accuracy required and demonstrated have been defined.

S flualification Status (check if A~licable, Ea if no~t)QuAliiedLife~i (If equipient, is qualified, indicate the qualified life with anumierical entry): IfLI Woas.

X Chialificat ion Report and HattKd - A qualification report and the method ofqualification has been identified on the Table Input Data Sheet (TIDS).

X. EnirML tl alygis - An environmiental analysis has been done, attached tothe EDS, and independently reviewed by the responsible organization.

X Oua~lification by Simlaritv (If applicable) - A justification for qualificationby simi'larity is attached to the EDS considering all the above factors and

X referenced to the appropriate tables.QuChalification of Several Exact Qcxpnets (if applicable) - When an MS is usedf or more than one item, a list of all exact ocqmrwnnts is given as an appendixwith all references to appropriate tables with Justification for qualification

N/A considering all the above factors.In Tterim2 Qualification~ (if applicable) - (Open item) - Component has beendetermined to be qualified only for a limited interim~ operation, an KM~ hasbeen written, and plan of action has been determined to yield a qualified-coczqcxwnt.Term of Interim Chialif ication ____________________

Umm'if ed Qm~t- (Open item) - (If applicable) - Cmponent has beendetermined to be unqualified; the follouing is attached to BOS: NM nwtberpreason for non-qulification, and justification of continued operation.

*Due to the extensive changes from Revision 0, revision bars are not used.

DATEI C Z' 0S~4

Preparer/Date __ __ _ __ __ _

Reviewer/Date '/ IkL. OZYp

Manuf acturer

Component

EQS No.WiEM02..Appendix 1 e vSheet 1 Of 1.

Automatic Switch COMADan

Pressure Switch

Component UNID Model No. Table/Sheet

3 .11-6/WBNEEB0OO31-PS-3-148 SB11AKR/TLlOA32R 3 .11-8/WBNEEBOOO0i

3 .11-6/WBNEEBOOO3.2-PS-3-148 SB1 1AKR/Th1 0A3 2R 3.1 1-8/WBNEEB0001

3 .11-6/WBNEEBOOO3I-PS-3-1 56 SB11AKR/TLlOA32R 3 .11-8/WBNEEBOOOT

3 .11-6/WBNEEBOOO32-PS-3-1 56 SB1 1AKR/TL1 0A3 2R 3.1 1-8/WBNEEBOO0l

3 .11-6/WBNEEB0OO31-PS-3-164 SB11AKR/TLlOA32R 3 .11-8/WBNEEB0001

3 .11-6/WBNEEBOOO32-PS-3-164 SB11AKR/TLlOA32R 3 .11-8/WBNEEB0001

3 .11-6/WBNEEBOOO31-PS-3-17 1 SB~l AKR/ TL1 0321 3 .11 -8/WBNEEB0601

3 .11-6/WBNEEBOOO32-PS-3-17 1 SB1 1AKR/TL 013 2R 3.*11 -8/WBNEEB0OO1

_ _ _ _ _ _ _ _ _ _ _ _

Cm

M2n

G)____ __ __ ___

<n_ _ _ _ _ _ _ _ _ _ _ _ _

_ _ _ _ _ _ _ _ _ _ _ _

Prepare r /Da teA? 0 -z'

Reviewer/Date (/a 2w1. /Ci4

EQS No. WBNEEB0091Appendix 2 Rev ISheet 1 of 5

1. The v*ressure switches listed in Appendix 1. are ASCO Model No.SB11AKR/TLlOA32R. They are located in the Auxiliary Building atelevation 737, room Al. As detailed in EN DES Calculations (NEB 840907222) for the Feedwater System, these switches are required to operatefor 100 days after the start of a LOCA and are required to operate for1 month after the start of a ERR, CVCS, Auxiliary Boiler, or AuxiliaryFeedwater line break.

2. These switches are subject to LOCA/HELB conditions and are required tooperate in the following environment:1

Normal Abnormal Accident

Temperature:Pressure:Relative Humidity:Radiation:

Spray/Flooding:

104 0FAtm(-)80%5x10 2rads(40 years TID)

110OFAtm( -)90%N/A

N/A

1 290 FAtm1 00%1x104 rads(LOCA)N/A

3. The manufacturer has tested these switches in the followingenvironment:

Normal Accident

Temperature:Pressure:Relative Humidity:Radiation:

1040FAtm16 to 24Z0.5x106 rads

21O~F2.2 psig100%17x10 6 rads

This testing is documented in ASCO Qualification Report AQR-101083,Revision 1, dated June 1, 1984. A summary of this testing follows:

Aging Simulation Phases:

A. Thermal Aging Simulation - Aging parameters were determined byArrhenius calculations to simulate a minimum of 10 years in a 104*Fcontinuous ambient. Refer to Figure 1 for additional informationregarding service periods for elastomeric components.

B. Vibration Aging Simulation - Continuous sinusoidal sweeps from 5 to 200to 5 liz at a rate of 2 octaves per minute, with a minimum peakacceleration level of 0.75g (except at low frequencies where theacceleration level was reduced such that the displacement did not

1See WBN Environmental Data Drawing EFFECTIVERO

DATEOCT 1984

Preparer/Date ~ 0-~-& ' EQS No. WBNEEB0091, Appendix 2 Rev 1

Reviewer/Date d /O&it4- Sheet 2 of 5...j.

exceed 0.025" double-amplitude), for a minimum of 90 minutes in each ofthree orthogonal axes. The test units were operated every 15 minutesduring this exposure. The units were attached to the shaker table byrigid test fixtures using the standard mounting provisions with theunits vertical and upright. Flexible hoses on all ports and Liquatiteconduit rigidily attached to the shaker table were used; therefore, thesetup did not affect the rigidity or mass of the units being tested.

C. Resonance Testing - Accelerometers were attached to the test units todetermine if the units exhibited any resonance. Resonance is definedas a response with a magnitude of acceleration at least three times asgreat as the input acceleration. No resonances were detected between 1and 35 Hz.

D. Radiation Aging Simulation - 0.5 megarads of gamma radiation at a ratenot exceeding 1 megarad per hour to simulate expected non-accidentradiation exposure.

E. Wear Aging Simulation - 50,000 operations. Ten percent of the wearaging simulation was conducted concurrently with the thermal agingsimulation. Units with the Urethane elastomer (Ref. TLA, T4 ..A andTN__A) were not partially wear aged concurrently with the thermal agingsimulation.

F. Seismic Aging (OBE) Simulation - The units were mounted to the shakertable as described for the vibration aging simulation and were exposedto two sinusoidal sweeps from 1 to 100 to 1 liz, with a peakacceleration level (within machine limits) of 4g, in each of threeorthogonal axes at a rate of not more than 1 octave per minute. Onesweep in each axis was conducted with a 20% process signal applied andthe other with an 80% process signal applied. These sinusoidal sweepsare considered to provide the equivalent dynamic effect of 5 OBEs.

Design Basis Event (DBE) Phases:

A. Seismic DBE (SSE) Simulation - The units were mounted to the shakertable as described for the vibration aging simulation and were exposedto a single frequency sinusoidal test at 1/3 octave frequency interval(17) dwell points between 1 and 40 Hz. The minimum duration at eachtest frequency was 30 seconds. At each test frequency a peakacceleration level within the machine limits was applied. Motion wasapplied at the same frequency and acceleration limits in each of threeorthogonal axes separately. Based on this testing, subsequentperformance and physical and pressure boundary integrity aresatisfactory to a minimum of 6g acceleration.

OCT i5

Prepar er /Date (i i-6 z- 4'

Reviewer/Date /~ 0'

EQS No. WBNEEB0091Appendix 2 Rev 1Sheet 3 of .....j.

B. Radi&J -ion DBE Simulation - 18.7 megarads of gamma radiation at a ratenot exceeding 1 megarad per hour to simulate (after consideration ofmargin as suggested in IEEE 323-1974) at least 17.0 megarads ofaccident radiation exposure.

C. Environmental DBE Simulation - The units were installed in a chamberand subjected to an exposure of temperature and humidity for a periodsimulating a combined loss-of-coolant, accident/high-energy-line-breakevent and post-event cooldown. The peak ambient temperature 'of thesimulation vas 210*F vith a saturated steam environiment. The unitswere cycled at the beginning and end of each transient (to demonstratethe ability to perform a typical safety function) and once daily forthe remainder of the exposure to demonstrate the ability to operate ondemand. The qualified temperature profile demonstrated by thissimulation (after consideration of margin as suggested in IEEE323-1974) is shown in Figure 2.

D. Pressurization DBE Test - The units were installed in a pressure vesselsubjected to an ambient pressure of 2.2 pig for 10 minutes followed by1.1 psig for an additional 10 minutes. All units had a process signalapplied but were not cycled. The qualified pressure profiledemonstrated by this simulation (after consideration of margin assuggested in IEEE 323-1974) is shown in Figure 2.

The above informationNUREG-0588 guidelinespost-accident life of

shows that these devices are fully qualified tofor a normal service life of ten years and a100 days.

034158.02

~EFFECTIVEýD0 A T E

* £

' [ ______ I ______ I ______ ______

0

15

10987

6

5

4

3

2.5

2

1.5

300 C(860 F)

400C(11040 F)

500 C(I 2r F)

600C(1400 F)

to (EPDM)

700C(1580 F)

FIGURE IMAXIMUM SERVICE PERIODS FOR ELASTOMERIC COMPONENTS IN ASCO SUFFIX R

PRESSURE SWITCHESBased on accelerated thermal aging at 2100 F ambient temperature and determined by Arrhenlus calculations usingactivation energy values of: 0.94 eV for Ethylene Propylene;- 1.04 9V for Viton; o.82 eV for Urethane; 0.91eV for Silicone

lb 0

00

t-d

<0

EFFECTIVEVDATEA;"..*

0:NOTE: Pressure Switch Units should be replaced

whenever any of the following levels, simulatedduring qualification testing, are reached:1 . Wear Aging - 50.000 cycles2. Radiation Aging - 5x I0I rod3. Thermal Aging - The maximum service

period indicated-bekkw for the applicationservice ambient tenrporature.

Uretha

SiliconeEthyle Poye

___ __ _ _ __ __ _ _ __ _____ __ _ _ __ __ Vitonl r ye

200 C(680 F)

0 01950 F

200

175.

2.0 PSIG

150 -Ij-/-TEMPERATURE

(e F)

~7mm(D

0xN

N

-v**1

*00

0

I..

100

/I1.0 PSIG

HOURS

1200 F

LEGEND- TEMPERATURE

PRESSURE

,1040 F

TIME

QUALIFIED AMBIENT TEMPERATURE AND PRESSURE PROFILE

-DATEIOi

I.

0.

3.0

2.0

PRESSURE(PSIG)

1.0

0

(D 10m m

0. 0

0W

<0t

FIGURE 2

pPr~eParer/bate 1

~1.~ ~- ~- U -I I Revision

. BN ~U~Ebuib OIP4LIFiC~roH N (~

Manufacturer and Moe o NAMCO EA740Verification of Ta~le Information (Table --3.ii -4 /wBNEFBOOI 2

XA.im 2uiiZL. - The equipment has been identified as per WVA ID numberdesignations (such as, WDVI SM f.lackima - The location has been identified (such as, inside primrycontainment, annulus, Individually cooled rooms, general spaces, or areaaffected by HELB outside primary containment).

X D~et- A unique WVA ID number has been assigned (such as, l-PSV-68-308).Puct - A functional description of the omponent has been given (such as,steam generator blowon).

_X Qintract No-,. Manufacturer, and Model No-. - The contract number, manufacturer,and model numb~er have been given.

__ Abnormal or Accident En~vironment - All abnormal or accident envirounmentalconditions applicable to this equipment have been identified either in tables orby references to figures fromi tables.

Y Environment to Mhich Oualif ied. - The environment to which the equipment has beenqualified is addressed in either the tables or the environmental analysisattached.

- ae - A category of a, b, cl, or d has been defined for theequipmnent.

.. Operation and Accuracy REqired and DeMgntrAted - The operationand accuracy required and demonstrated haebeen defined.

Oualif icatir Status Pcheckr if awlicable. NA if notOualified.L~ife (if e~ ipen is qualified, indicate the qualified life with anwneria entry): 40 yr..x!.X Ouallificat ion Reprt and Method - A qualification report and the method ofqualification has been identified on the Table Input Data Sheet (TIDS).X k![iQnDB a1-aI AjnI~vg - An environmental analysis has been done, attached tothe EDS, and independently reviewed by the responsible organization.

A.iLA Walification by Similarity (If applicable) - A justification for qualificationby similarity is attached to the BDS considering all the above factors andreferenced to the appropriate tables.I/A Walification of Seve -ral Exact CrmODens (if applicable) - When an BDS is usedfor more than one item, a list of all exact conrionets is given as an appendixwith all references to appropriLate tables with justification for qualificationconsidering all the above factors.

-1LA in erinM Oulificatim~ (If applicable) - (Open item) - Conqonet has beendetermined to be qualified only for a limited interim operation, an NCR hasbeen written, and plan of action has been determined to yield a qualifiedcomponnt.Term of Interim Qualification _____________________

NE/A NM NO.L~Ler - (Open item) - (If applicable) -. Component has beendetermined to be unqualified; the following is attached to EDS: NC number,reason for nor-qualification, and Justif ication of continued operation.

[EFFECTIVE1D1 TOCT _! ~4 /

UkAit Nk,. - 1EDS No. WBNEEB0093TA 1DkN.

1-FCV-31-327-B (LS)

Preparer/Date ~91

Reviever/Date________ ______

EQS No. WBNEEB0093Appendix 1 Rev 0Sheet 1 of 5

1. Thisi-jimit switch is a NAMCO series EA740 and is located in the ReactorBuildfiug Instrument Room at elevation 716.

As detailed in EN DES Calculation NEB 840515 224, for the Air Condi-tioning System, it is required to operate f or the first 5 minutesfollowing a LOCA, Main Steam line break, Auxiliary Feedwater linebreak, ERR, and CVCS accident. Additionally, it must not fail in amanner detrimental to plant safety for 100 days following a LOCA, MainSteam line break, and Auxiliary Feedvater line break, and 1 month aftera RER or CYCS accident.

2. Operating Environment

The switch is required to operate in the following environment:'

Normal Abnormal Accident

Temperature:Pressure:Relative Humidity:Radiation:

Spray:

750F

14.7-14.3 psia60%b3.5xlo4 rads(40 yr. TID)N/A

1200714.7-14.3 psia90%N/A

N/A

3270F26.7 psia100%lx108 rads

NIA

3. Qualification

The manufacturer has tested NAMCO model EA-740 limit switch to thefollowing environment:

Normal (Accident)

Temperature:Pressure:Relative Humidity:Radiation:

12007 (3400F)Atm (75 psig)100%2.04xl08 rads

NAMCO tested the switch to the requirements delineated in IEEE Standard323-1974. Test procedures and results are documented in NMACO QualificationTest Report No. QTR-ll1, Revision 0 dated October 1, 1981. To qualify theswitch for conditions in excess of known application requirements, anaccident simulation test was performed with temperature and pressure asshown in Figure 1.

All qualification tests were performed at test levels or conditions inexcess of known maximum application requirements. These margins are inaccordance with the margins suggested in IEEE Standard 323-1974.

'Per WIN Environmental Data Drawing No. 47E235-45, 10.

EF ~CTI V EDATE

Preparer/Date 2ZZiz~4J698 QS No. WBNEEB0093Appendix 1 ey 0

Reviewer/Date Sheet 2_ of ~

Thermal aging calculations in this Appendix are based upon the"Arrhenius Equation" as follows:

T - T2

L1 L2 e

Definitions:

Ll- Qualified lifeL2 - Accelerated (test) lifeE - Worst case activation energy, eVK - Boltzmann's constant, 8.617x10-5 eV/OKTi- Qualified temperature, absolute

T2 - Elevated (teat) temperature, absolutee - Base of natural logarithms

4. Radiation. The switcb was subjected to a total radiation dose of 2.04x108rads which is in excess of the combined normal and accident environmentalradiation doses of the operating environment.

5. Temperature. The test curves in Figure 1 more than encompass the initialtemperature change for the first 5 minutes of operation for the accidentenvironment shown in Figure 2.

The manufacturer has tested the switch to a temperature (3400F) in excessof the maximum abnormal and accident temperature (3270F).

The 100-day post accident requirement of section 2 can be extrapolatedfrom the long term soak portion of the curve in Figure 1. Here the switcheswere maintained at 2000F for 624 hours. Using the Arrhenius equation, anactivation energy of 0.8eV and an average post-DEE temperature of 1550Ffrom the linear portion of the curve in Figure 2, the post accident lifeis determined to be 166 days which is in excess of the 100-day requirementof section 2.

6. Pressure/Humidity

The switch has been tested up to 75 psig and 100% relative humidity whichencompasses the worst case pressure and humidity of section 2.

Preparer/Date e? r2 i. '99 EQS No. WBNEEB0093Appendiz I,.. Rev 0

Reviewer/Date Zv./-" 7/-ae Sheet z3 of

7. Oualified life. Thermal aging was conducted by placing the switch in achamlier with the temperature maintained at 248OF for 408 hours. By usingthe Arrhenius equation, an activation energy of 0.8 eV, and the maium'normal operating temperature of 750F, the qualified life is determined tobe)40 years. It is our engineering judgment that satisfactory performancecan be expected for 40 years at the maximum normal operating temperature.

The above information shows that the limit switches will function asrequired and are fully qualified per NUREG-0588.

034156.01

G OTI 2i 634

EQS NO. WBNEEB0093Appendix 1 Rev 0Sheet 4 of 5

L- 1 L

LALL~ ~~.. ..J~ ...... **..Ai-i Fr, -6 TO aoto

sit cow.o 1.221... .. .. .: ... . .. ...

-4,I .I

AC%& * I I__________~ ~ ~ ~ ~~~~~I ____________________o______Aden__________

*~III

IiLi

U

pCOWTAINNENT TEHPERRTUREo DOUB3LE YNFDEO PUMP SUCTION BREAK

HOST SEVERE STERHLINE BREAK (HEIDI COMBINED A

u~?~ 2S

1~'

£m0 7

Tr I' V E

U4 A 'a'.

I I I II ititW% - --m.-- -

I I I II iiil I I III tiil I I III iiil I I I I i'itil

zoo-

I's-

IS0O

too

LOM CWMIN01

%lisle"

x

q

W *,an -a aw a AA A AA Ak .0 . .A -

(LOCR 9 -QS NO.. WBNEEB 0093_ppendix 1 -Rev 0heet 5. ..Of 5

Preparer/Date

Reviewer/Date/Y/a4ý

EQS No. WBNEEB0093_S Appendix 2 Rev 0

Sheet 1- of I

The devices listed below require sealing of the conduit entrance.Qualification of the conduit seals is documented in the referenced EQS.

Component UNID S

1 -FCV-31 -327 /ZSl

1-FCV-31-327/ZS2

WEN EEB-CSC-1

WBN EEB-CSC-1

EIF i:E ( - il

[AiT 4

034156.01

7eAdAa-zA-7

- -I 0iL

'I 13 11 EQS No. EEB-CBL-9Llý 0 TVA I D rio: v

~!1 ~7 TAi~b~ I~.J ~Rev 1 -

IrI EQU1H1T QU1ALIFIlCAT) ON SHEET (rQL)

ftanuftactur'er and flodel floun~ber. See Table 3.11-BA, Sheets 1000 and 1001

VerifiCation of Table Information (Table 31-ASheets 1000 and 1)0

X E ulmj'nt T e - The equipment has been identified as per TVA ID number

X Location - The location has been identified (E.G., Inside Primary-"ro-nfal-ivient, Annulus, Individually Cooled Rooms, General Spaices, or.

area affected by IIELB outside prim~ary containment).

'X Component -A unique TVA ID number has been assigned (e.g., l-FSV-65-3O8).X r'unction -A functional description of the component has bee~n given

- {ci.ý. T~uan; Griuerator Blowilown).x C~ont~ract No., MaSnufacturer, and Miode~l No. - The contract r.number,

iiil'at~ur-r, and model number has been given.X All'ioria'l or Accident Environment - A~l abnormal or accident onvironrii:itt.al

- ol, ItosapiaI t ll-eu7n have ken~f identi fie.1 Othewr 'ntables or-by references to figures fromn tables.

X Eniivronmnent to Which Qualified - Tt;e environment to which the equipmen~tTia C EDY51 Fl-iues.idn 'either the tables or the environ.,.entaianalysis attached.

X Cateqoy - A category or a, b, c, or d has bven defined fur the- eý:uipricnt.

X01i~ration ane. Accuracy Reriiirce2 and rk-monstrairdc - The operation and.acuacy reqiuired -Cd~ 11 "&b"~i( ned.

1jual if ication Sttu check: if applicable, NA if not) Qualified 1.ife 40 years R1

X Q ual if ication. R(:port and Ii.thod - A qual if icaion report and the iael~icod~fljJi1Tfiwif~nha -1bei~idct if ieri.INA_ Environrneni.l Antalysis - An environment~al analysis hits beer. dcrir!, a.tt.Cin:cd

to thn i,-ý.:Q:;ý, *aiý,J n'ei',..'~7nd'rktily reviewied by the reýpons;ble org~niziltion.* u:liition ySfi::ihrt:, (If applicablAe) - A justificati':1 for

~uq 1hao I.. IT.i is attachod 1.o the 195. considering ail thliiabuvte fact-ors and refereiiced to the appiropriate t.ables.

XQuealification of Several Exnct Cumvonentr, (If applicable) - When an EQS- WiscTo ~fhno~&TL a i-st oT all exact cown'poneiA.s ar- Fiivcm.

as an iappendix wiithi all refecnxces to appropriate tLables with justifiu..:ti1,:nfor cju,ýliricatioji considerini all the above factors.

N/A Iltetrimi Ot' ilifi r:;ition (If cipplicable) - (QOpeat item) - Comaponcrnt h.- been-36terelirne(Ito he-&jiýiTifiec' oa~y for' j li-nited i!twiteri cpcviation, iti NCR

has hevii v-ri!.;e'a, and plen (of t.iction has been determ~inud to yield a -i

qu~al iic-d comnpa~iint . Ter)) of Interim Quialificat ion >_____-____

N/A 111,q ;,I'if ie (:i~nt:- O; i ten) - (If appi ic~Ai ) - Comyc;Ii-:0. Iros bt,-.r U(Itriiiiie~ i iiuiit aid t)CO cl fllow.ing is attiicl~ud to E05: $

11CR not~iber, rcasoti for' ;lf-p fct a nd ju!ti firj.,tion of cotit i aru 0

HCR NO. U

Prepared by: / 1 tf09/6khs

Reviewed by:

EEB-CBL-9, Rev. IAppendix 1 Rev. ISheet I of 2

CF Family (CPJ. CPJJ. and CPSJ)

The CP famkJly of cables consist of cross-linked polyethylene insulationand polyvinyl-chloride jacketing. All cable of this type was constructed,tested, and accepted for use in accordance with TVA Standard Specification25.016 - Standard Specification f or Cross-linked Polyethylene InsulatedWire and Cable. TVA Standard 25.016 invokes the applicable portions ofIPCEA Standards (such as physical properties, and methods of testing fortensile strength and elongation of the insulation and jacket materials).The TVA Specification included provisions for source inspection of factorytesting and required submittal of certified test reports to assurecompliance with the specification. Cable manufactured since 1971 wascontrolled by a TVA approved QA program.

The following LOCA/SLB tests are representative for the CF family of cableswhich are presently installed.

Wyle Laboratory Test Report 43854-3 dated April 26, 1978, Quali-fication Test on eight cable splice Assemblies (cable assembliescomprised of CPJ cable). (See appendix 2).

Wyle Laboratory Test Report 17513-1 dated January 24, 1984,Containment Accident Test Program on Electrical Cabling andSplices. (See Appendix 2).

The test reports show a baseline functional test was first performed andpassed. Then functional tests were performed and passed after theradiation test, after the temperature aging test, and after the LOCA/SLBtest.

The tests included radiation at 1.13 x 108 rads.

The tests included temperature aging at 1300C for 2576 hours.

The tests included a LOCA/SLE at 3250F, 55 psig, 100 percent humidity.

NOTE: One sample of CPJJ (Plastic wire and cable) received 1.68x1O8rads and temperature aging at 1300C for 5152 hours.

These cables have a qualified lifetime of 40 years based on Arrheniusaging, and are qualified by the above for all HELB areas. Because of theconservatism of these tests including the severity of the mandrel bend anddielectric test in water after the combinedi..OCA/SLB profile, engineeringanalysis concludes that there is sufficient margin to give reasonableassurance of continued operation for more than a year in the post designbasis event environent.

EFET IVE.:DAT AF 1 .DOAT JY

.."A.Rv

Preparer/Date /Ž~~~6~,'//~eReviewer/Date cflnN4/1~

CP Family (CPJ. CPJJ. and CPSJ)

EEB-CBL-9, Rev.Appendix 1 RevSheet 2 of

The tests included cable samples from General Electric, Okonite Company,and Plastic Wire and Cable. This cross section of cable manufacturersrepresented in the tests adequately demonstrated that the CP family ofcables will perform similarly in the given DBE. The variety of vendorsused also proved that successful completion of the test is a function ofthe chemical properties of the insulation and jacketing compound and isnot dependant on the manufacturer. Consistency in the chemical propertieshas been demonstrated by successfully completing the requirements of TVAStandard Specification 25.016. This approach to generic cablequalification follows the general guidelines for type testing as outlinedby IEEE 383-1974.

All cables of the CF family met or exceeded the construction, testing, andacceptance requirements of TVA Standard specification 25.016. In additionrepresentative samples of the CP family of cables supplied to TVA bydifferent manufacturers successfully passed LOCA/SLB testing. In view ofthe above, ye conclude that the results show that the CP family of cablesare generically the same and that regardless of the manufacturer the cableswill perform adequately in a DBE accident.

034279.01

EFFECTIVE

DATE3. OCT 98834

2

Prepared by: _ _ _ _ _ _ _ _ _

Reviewed by: 2IA-~ 1-iFAvoa--60 rI

* EEB-CBL-9Appendix2Sheet I of 10Rev1

QUIALIFICATION TEST RlEPORT

onEIGHT CABLE SPLICE ASSEM3LIFS.

TO bE USED AT

V RO'vf, ISFETRRY NUCLEAR PcI,"-*e PLAN~T

*UNIT 3

VOLUME IOF F

TENNESSEE VALLEY AUTHORITYD)IVIS ION OF POWER PRCODUCTION

804 EDNEY BUILDINGCHATTANOOGA, TENNESSEE 374i01

Wyle shall have no liability for damages of any kind to person orproperty. including special or clons'equential dar.-ages, resultingfrccm Wyle's providing the services covered by this repcrt.

. I

Test R11eporrtREPORT NO0.-

WYLE JOB NO.CUSTOMERP.O0. NO.-

Appendix 2Sheet 2 of 10Rev I

I.385L~- 3

4.3854.

77P8- 147972

PAGE 1 OF - 189~ PAGE REPORT

DATE _ A......pr1 1 26, 1978

SPECIFICATION (S) See* ParnUrph 5.01ý

CUST(Nili<-k

AK1'-"LSS

TELT SRECIMLN

Tennessee Valley Authority Division of Power Production60O4 Ldney BuildingChattanoiqa,_ Tennessee 371101

Coble Splice Assemblies (to be used at Browns Ferry Nuc~lear

Power Plant, Unit 3, Athens, Alabama)________

3.0 MZAIUFACTURERFabricated by TVA

4.0 SUM.MARY*

Ei~ht (8) Cable Splice Assemblies were subjected to a Qualification Test Program toverify their electrical Integrity to perform their lnteneed function during or afterthe environmental tests specified herein. The Cable Splice Assemblies tested are tobe used Inside containment at Unit 3 of Browns Ferry Nuclear Power Plant. A descrip-tion of each Cable Splice Assembly is shown In Paragraph 6.0 of this report.

The te~st programv was performed as specified In Reference 5.1 and In accordance withReference 5.2 to satisfy the requirements for qualifying Class IE electrical equip-ment for use at Browns Ferry Nuclear Power Plant. The following table lists the tests,testing sequence, and test results that comprise the Qualification Test Pr~ogram.

Alabama ProfessionalSTATE OF Al ATPAMAEniergLcns172COIUNTY Dr. MADISON , EniergLcns 172

Wjillam W. Holbrook Is~e" ulysworn.49 ~poses and saysi The ,'efotmat,@r cn Otain'ed in this ýeotot is theS result OfSOm~Oitto and eatiflIov conducted wets an~d is to she best of his knowledge true

fld and. . *'VA t.lrS

______k_____A A Isi

111tav? Public in and f~or tC'nty of Madisohn. State of Alabamai.

My commisaion expires 19

TEST BY _5DSecial Pro lects

PRO*J. ENGI N EAL Z211L..-~~~ iraake r

WYLE 0. A

14"RLr. UIZ. LaVIC

SCIENTIFIC SERVICES AND SYSTEMS GFIOUPHUNTSVILLE. ALABAMA

- , *rra, - -- .1-s - -C. - a *- .S.~. s.-. .~.r..-r .o~ *. - -. *-.n.-t-~.. -- - - ..........-

S1., pollFIG SERVICES AND SYSTEMS GROUP

I..O SUMMARY- (CONTINUED)

iESTS. TESTING SEQUENCE.

-- I

4yl ISpeci menTig No.

1A

IB

2A

20

3A

14A

1,3

5A

Rad ia t ion

Spa re

Spare

X

XX

TemperatureAc i nc3

Accident(LOCA)

Spa re

Spare

X.xXX

Xx

Spa re

Spare

xxxxxX

WIILtI-

2 Appeniix 2IPAGE NO. . sheL.3I of ..t0

I Revi1IREPORT~r. I3~-

AND TEST RESULTS

ComplIiecdwi th

Reaui remrents

X

Spare

-Spare

xxxxXX

Did NotCOm.p I yW ith

Spare

Spare

Note: Test specimens with an "A" suffix are 250 VOC operating splices'.

Test specimens with a "B" suffix are 480 "AC operating splices.

E FTE CT-1V EDATEU. 1C 93A4

I

SLgENTiFIC SE11VIcES AND SYSTEMS GROUP.

EEB-CBL-9

IPAGE N.O. 3 ~1I Rev 1

REPORTHO. 431351.-3(.

SUM~MAR'Y !(CONTINUED).

This-fita) test report contains the following Sections. TheQualification Program was performed in the sequence indicatedb'y the'Section numbers.

Section I

Section I I

Section III

Sectonl IV

Section V

Section VI

Section VII

Section Vill

Section IX

Baseline Functional Tests

Nuclear. Radiation

*Post Radiation Functional Tests

Temperz~ture Ag-ing Test

*Post Temperature Aging Futictional Tests

Actident Test

Post Accident Functional Tests

Dimensional Tests

-Post Test Inspection I FETFFECT IVEDATE

REFERENCES

Conztract Nu.-.b-r 77P8-1-7972. Qualification Testing, £Prowns FerryNuclear Powecr Plant, Tennessee Valley Authority.

Tennessee Valley Authority Test Procedure for Proposed Browns FerryCable Splices.

TEST ITEM ANO0TEST FOUIPMENT DFSrkRIPTION

Test-Iltem Descript ion

Four (4) each of two (2) different types of Cable Splice Assemblies weretested during this test program. Both types were fabricated by TVApersonnel and are to be used inside containment at Browns Ferry NuclearCeneratina Station, Unit 3.

The two types of Cable Splice Assemblies.are described as''follc'ws:

The 480 VAC Cable Splice Aisembly consists of four (4) single cables-of No. 10 CPJ wire, spliced to four (4) single cables of No. 12 VulkeneInsulated wire, spliced to four (4) single cables of No. 10 C?J wire.Five (5) of these assemblies were fab)ricated. Only four (4) were tes-ed.O.ne (1) Assembly was a spare.

The 250 VLC Cable Splice Assembly consists of a seven (7-conductorcable, wire size No. 10, with CPJJ Insu~lation, spliced to seven (7)single conductor cable, wire size No. 10, with CPJJ Insulation.

C .0

6.o

6.1

SCIE NI IF IG SERVICES AND SYSTEMS GORO'JP

LUb-LOL-1Appendix 2

rACE PI. 4 Sheet 5 of lo- --;-Rev 1

REPORT NO.- I3 5 1i

TEST fITEti AND TEST EQUIPMENT DESCRIPTION .(CONTINUED)

Test 1tem Description (Continued)

Five '(5) of these Assemblies w~erc fabricated, Only four (4) were tested'.One Assembly was a spare.

The~test s-plices were butt splices covcred with Raiychemn Heat SfirinkablcSleeving.

All test iteras were fabricated under field conditions by TV/A personnelat growns Ferry Nuclear Power Plant and delivered to Wyle Laboratoriesfor test. The test splices In eacti table-Assembly were wired by Wyloso whe~n loaded all splices were in series. TVA provided the leiadwiresfor each test Item assembly to which Wyle connected a lead arid powersupply.

Test Equipment Description

Test equipment, from sensor to final rceaout device, was selected toprovide the accuracies specified below:

" Chamber Temperature

" Chamb6er Pressure -

* Voltage

" Current

+45 pslg

equipment used for these tests Is shownShcets located In the appendices to thereport.

on Instrumen-tation Equip-appropriate scctions of

EFFECTIVE.DA7TE*

NOCT 1934

S *

K6.0

6.1

TestMen tthis

............. -

[;J*'7 H 'Ii____ I **J ~.*, I I

0j **

[I I I I! Er!A~i~~1 I!i/! i '~'!1VI:

i* a w .f,4 m :&.i. sobiLw et jonf5a 0 ~~.. ~ j.q~ %P

for" 4,.nt, L.~ I. A.%, t4 .i'C W* *

L- f .0to 4--t re~e C . m 'In * A* i.7 . .. r~dl___ ___ ___ ___ ___ ___ ___ __ ___ ___ __ .*. * tim .* .

r 1 !12?!! !H I * IS **I...,.0

'Si

* *1

ob Is 3~ I*CCDflE If?!fA III o of is

ijFl..

EEB-CBL-9Appendix 2Sheet 7 of 10Rev. 1

CONTAINMENT ACCIDENT TEST PROGRAM

ON

ELECTRICAL CABLING AND SPLICES

FOR USE IN

BROWNS FERRY NUCLEAR POWER GENERATING STATION

for

Tennessee Valley Authority400 West Suimilt Hill DriveKnoxville, Tennessee 37902

EFFECTIVE' DAT7EOT I934 1

KLTUKI flU.-

WYLE JOB NO.CUSTOMERP. 0. NO. -

EEB-ICLB-9-Appendix 2Sheet 8 of 10

Test R&'Ibit

17513-

TV-56071A

PAGE i OF 331 -PAGE REPORT

January 24, 1984

SPECIFICATION (S)

WLTP 17460-2, Rev. C

dated January 8, 1984

1.0 CUSTOMER-

ADDRESS-

2.0 TEST SPECIMEN

Tennessee Valley Authority

40West Summit Hill Drive, Knoxville, TN 31902

Electrical cabling and splices, single and multiconductor,

12 through 34 AWG

3.0 MANUFACTURER See Paragraph 6.0

4.0 SUMMARYSeveral generic cabliung types and splices of various manufacture were subject to atest program to evaluate the adequacy of their design to perform their requiredfunctions in Class 1E systems at Browns Ferry Nuclear Power Generating StationUnits 1, 2 and 3. The test items are described in detail in Paragraph 6.0 of thissection.CTI

E

DATE

___________________________________(DN271)

COUNTY OFMADISON -. Engineer Reg. No. 7948Frederirir M-. "4t*.ienn

~- WW WftCmw OW"udsGOWN

PREPARED By ~3"

APPROVED 8BZ LJ

WYLE 0. A.

J~ 'Li f~ib .

LABORATORIES SCIENTIFIC SERVICES & SYSTEMS GROUPHUNTSVILLE. ALABAMA

DATE

depos and saye: TV*he%,W - mm In_______ .i usia" sy MOM:d~y w~r9*fina&ýdist emwin:ed ki imrgo.1s Irw &W* coroinpii

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Page o. vEEB-CBL-9Page o. vAppendix 2Sheet 9 of 10

-Test Report No. 17513-1 Rev. 1

6.0 TEST SPEC1IMEN DESCRIPTION (CONTINUED)

6.1 Contiimujd)

Test-Item No. Specimen Description

1.3 One length (not less than 10 feet) of No. 12 AWG single- conductor, TVA type PXJ Mark WDV-1 cable, containing a

stranded copper conductor (7 strands /0.0305- inch), insulatedby a 0.030-inch thick layer of ethylene propylene rubber.The assembly is covered with a chlorosulfonated polyethylene(0.015-Inch thick) exterior jacket. The cable ismanufactured by the American Insulated Wire Company and isJ rated for 600 Volts, 31 amperes maximum, and a maximumconductor temperature of 900C.

1.4 One length (not less than 10 feet) of No. 12 AWG 3-conductor, TVA Type PXMJ Mark WGC-1 cable, containing 3stranded copper conductors (7 strands/0.0305 inch). Eachconductor is insulated by a 0.030-Inch thick layer of flameretardant crosslinked polyethylene. The assembly is coveredwith a chlorosulfonated polyethylene (0.045-Inch thick)exterior jacket. The cable is manufactured by the EssexGroup and is rated for 600 volts, 31 amperes maximum, and amaximum conductor temperature of 900C.

21.5 One length (not less than 10 feet) of No. 12 AWG singleconductor, TVA type CPJ Mark WDV cable, containing astranded copper conductor (7 strands/0.0305 inch), insulatedby a 0.030-inch thick layer of crosslinked polyethylene.The assembly is covered with a polyvinyl. chloride exteriorjacket. The cable is manufactured by the Okonite Companyand is rated for 600 volts, 31 amperes maximum and a maximumconductor temperature of 900C.

1.6 One length (not less than 10 feet) of No. 12 AWG 2-A conductor, TVA type CPJJ Mark WLB cable, containing strandedcopper conductors (7 strands/O.0305 inch), insulated by a0.030-Inch thick layer of crosslinked polyethylene and a0.015-inch thick layer of polyvinyl chloride. The assembly

.1 is covered with a polyvinyl chloride (0.045-inch) exteriorJacket. The cable is manufactured by Plastic Wire and Cableand is rated for 600 volts. I EFFECTIVE

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EQUflIM1T OtLAUFTCM' SZT (MVS)

Lhit No. 1 and 2EDS Nb. EEB-CBL-1~2TA ID NO.Type EPSJ Cable

Rev. 1

Nanuffactfirex and Model No. See Tabl4Verification of Thble Information (Table 3. 11-8A

e 3.11-BA. sheet 1004sheet 1004

X ji~-M - Th equipment has been identified as per TVA ID nwrberdesignations (such as,, Nov. SOOT.

.***X ZaftjGa i - The location has been identified (such as, inside primarycontainments, annulus,, individually cooled roomsp general spaces, or areaaffected by B.EZ outside primary containment).

X BD== - A unique TVA ID number has been assigned (such as,, l-FSV-68-308).... hfL~tgn - A functional description of the ccmjqont has been given (such ass,

stem generator b1owown).X Q~mract MD.. Manufacturer. And Model No. - The contract number,, manufacturers,

and model number have been given.X Abnormal or Accident Envirozmst - All abnormal or accident environmental

conitions applicable to this equipment have been identified either in tables orby references to figures from tables.

X govironment to WhichD"OUsfietd - The environment to which the equipment has beenqualified is addressed in either the tables or the environmental analysisIattached.X CateM - A category of a,, b. c,, or d has been defined for the

-- 90~ration and Accuracy Beqired and fersrtd- The operationand accuracy required and demonstrated have been defined.

Qualificaticm Status (check if Applicable. RA if not)QulifiedLife (If equipment is qualifiedo, indicate the qualified life with anumerical entry): 40;Par

xChial if icat ion Report and Methbd - A qualif ication report and the method ofqualification has been identif ied on the Table Input Data gmet (TIDS).

-UfL& flii m~taLAlAnalnis - An environmental analysis has been done, attached tothe HDSr and independently reviewed by the responsible organization.Omhilification by Similarit (if applicable) - A justification for qualificationby similarity is attached to the EDS considering all the above factors andreferenced to the appropriate tables.

-- 2hilification of Sevral Exact Ccpm=,net (If applicable) - When an M~S is usedfor more than one itemn, a list of all exact components is given as an appendixwith all references to appropriate tables with justification for qualificationconsidering all the above factors.

-U I oruft*IfWrIWGrgi (If applicable) - (Openitem) - Ccmqnent has beenldetermined to be qualified only for a limited interim operation, an NCR hasbeen written, and plan of action has been determiz)9d to yield a qualifiedcmo~nent. LUTerm of Interim Qualification >_______________________NMNO. I MJJ '-

.aL~~ Q=(jOpn item) - (if applicable) - Comonent has been -.h determined to be unqualified; the following is attached to EDS: NM nmmber, JF reason for non-qualificationo, and justification of continued operation. L

NM No.

'LU

F, I2-/I-41Prepaer/a~te IC, A A, MT-J§4' ff /

Preparer/Date ul a ftozA A e..I I.104S' EEB-CBL-12, Rev. 1Appendix 1 Rev 1

Reviewer/Date At 96 1}11"94 Sheet 1 of 2

EPS Family? UPS, EPSJ. EPSMJ)

The BPS tables consist of ethylene-propylene rubber insulation with achlorosul~ilnated-polyethylene jacket. This cable was constructed, tested,and accepted in accordance with TVA standard specification 25.016 - Flame-Retardant, Cross-Linked Polyethylene-Insulation, Low Voltage Wire and Cableand Ethylene-Propylene Rubber-Insualted, 5-15kV cable prior to January 1980or TVA Standard Specification 25.015 - Ethylene-Propylene Rubber orNonchiorinated, Mineral-Filled, Cross-linked, Polyethylene-Insulated,5-15kV Cable after January 1980. TVA Standards 25.015 and 25.016 invokethe applicable portions of IPCEA Standards S-68-516 and 5-19-81 (such asphysical properties, and methods of testing for tensile strength and elongationof the insulation and jacket materials). The TVA Specification includedprovisions for source inspection of factory testing and required submittalof certified test reports to assure compliance with the specification. Themanufacture of all this cable was controlled by a TVA-approved vendor QAprogram.

The following LOCA/SLI tests are representative of the EPS cables whichare presently installed:

The Okonite Company test report form G-3 dated September 7,1977, "Qualification of Okoguard Ethylene-Propylene RubberInsulation for Nuclear Plant Service." (See Appendix 2).

The Okonite Company test report form G-2 dated May 2, 1977,"Qualification of Okoguard Ethylene-Propylene RubberInsulation for Nuclear Plant Service." (See Appendix 2).

Franklin Research Center Test Report F-C5160-1 dated-may 21,1980, Qualification Tests of Electrical Cables in a SimulatedLos s-of-Coolant Accident (LOCA) Environment )Prepared for Collyer Insulated Wire (See Appendix 2).

The Okonite Company Engineering Report No. 355 dated September 17,1981, "Main Steam Line Break Qualification Test on Okonite,Okonite-FMR, X-0lene-FHR and Okoguard Insulations" (See Appendix2).

The test reports demonstrate that the EPS cables are suitable for Class 1Eservice in nuclear power generating stations in accordance with appropriateguidelines presented in IEEE Standards 323-1974 and 383-1974.

The LOCA/SLB tests included radiation at 2x108 rads for the LOCA tests and5.5xl07 rads for MSLB tests.

The tests included a LOCA at 3460F, 113 psig, 100Z humidity and a MSLB at4550F, 32.psig.

EFFECTIVE.D A' E

Preparer/Date 'u L & ' i.-io*SV EEB-CBL-12, Rev. 1Appendix 1 Rev 1

Reviewer/Date _______-_A0-_/______F! Sheet 2..... of 2.L.

EPS Famfiy (EPS. EPSJ. EPSMJ)

These cables have a qualified lifetime of 40 years based on the hArrheniustechniques and are qualified by the above for all HELB areas. Because ofthe conservatism of these tests including the severity of the mandrel bendand dielectric test after the LOCA and MSLB profiles, engineering analysisconcludes that there is sufficient margin to give reasonable assurance ofcontinued operation for more than a year in the post design basis eventenvironment.

The tests included cable samples from the Okonite Company and CollyerInsulated Wire. The results of these tests adequately demonstrates that EPSJcable manufactured by different vendors in accordance with the same speci-fications will perform similarly in the given DBE and that successfulcompletion of the test is a function of the chemical properties of theinsulation and jacketing compound and is not dependent on the manufacturer.Consistency in the chemical properties has been demonstrated by successfullycompleting the requirements of TVA Standard Specification 25.016 if manu-factured prior to January 1980 or TVA Standard Specification 25.015 ifmanufactured after January 1980. This approach to generic cable qualifi-cation follows the general guidelines for type testing as outlined byIEEE 383-1974.

All EPS cables met or exceeded the construction, testing, and acceptancerequirements of TVA Standard Specification 25.016 or 25.015. In additionrepresentative samples of the EPS family of cables supplied to TVA bydifferent manufacturers successfully passed LOCA/SLE.

In view of the above, we conclude that the results show that the EPSJfamily of cables are generically the same and that regardless of themanufacturer, the cables will perform adequately for a DBE.

034277 .02

EF FECTWIVEDATE

OCT 11114

Prepared by:

STHE Reviewed by:

OKONITECOMPANY

QUALIFICATION OFOKOGUARD ETHYLENE-PROPYLENE

INSULATIONFOR

NUCLEAR PLANT SERVICE (5kV CABLE &

V

The Okonite Company's continuing Research and Development activitiesas a compounder of elastomeric materials has led to an evolutionarydevelopment of Okoguard to its present form as a clean, red dielectric.This evolutionary development has resulted in substantial improvementsin physical strength, lower water absorption rates and higher dielectricstrength over those experienced by the earlier excellent ethylene-propylene Okoguard formulations.

INDEX,

OkoniteForm No.- Title

Qualification of Okoguard Ethylene- Propylene RubberInsulation and Field Splice Materials for NuclearPlant Service

Aging, Radiation and LOCA Testing Okoguard Ethylene-Propylene Rubber Insulated Cables and Field SpliceMaterials for Nuclear Power Generating Stations

Moisture Resistance - Okoguar d Ethylene - PropyleneRubber Insulated Cables

Form G-3 (September 7, 1977)

09

EFFECTIVEDATE.

dOTo 1 10; 34

Post Office Box 340Ramsey. New Jersey 0744B201 -525-0300/Cable: Okonite

EEB-CBL-12Appendix 2Sheet 1 of 10

RUBBER Rev. 1

FIELD SPLICE)

EEB-CBL-12Appendix 2Sheet 2 of 10

-3-. Rev. 1Lossa of -Coolant Accident -SimulationThe unajed and radiated sample and thermally aged and radiated sampleswere then: placed in a autoclave and subjected to the temperature..-pressureprofile forý*simnulation of a LOCA condition as specified in the IEEE Std.No. 323-1974. This profile in shown in Figure II, attached. At the end ofthe 30 day exposure in the autoclave the samples were removed, bent arounda mandrel not greater than 40 times the overall diameter and then subjectedto a final S-minute ac withstand test at 80 volts per mil while immersed intap water at room temperature. The samples were then returned to theautoclave for an additional 100 day post LOCA test and maintained at 212 F.0 pslg, 100%/ relative humidity. At the end of this post LOCA period thesamples were removed, again bent around a mandrel of 40 times the overalldiameter and electrically tested at 80 volts per mil while immnersed in tapwater at room temperature*

Conclusion

The samples of Okoguard 5 kV cable with a field splice' in place unaged andthermally aged to the Arrhenius curve shown in Figure I, were radiated topa total dosage of 200 megarads minimum, and then subjected to a L 'OCA con-dition as shown in Figure U7, all in accordance with IEEE Standard 383 -1974.Throughout the exposure the cables were energized with rated potential andcurrent and insulation resistance measurements taken weekly. At the con-clusion of the LOCA and post LOCA condition the cables were then subjectedto and withstood an 80 V/mil ac proof test.

The satisfactory test results are evidence that the Okoguard insulation anda field splice made from Okoguard T-95 tape and Okonite #35 jacketing tapeare suitable for the designed service in Nuclear Power Generating Plants.

References

(1) IEEE Standard No. 383-1974IEEE Standard for Type Test of Class IE Electric Cables, FieldSplices, and Connections for Nuclear Power Generating Stations,.April 15, 1974

(2). IEEE Standard No. 323-1974IEEE Standard for Qualifying Class LE Equipment for Nuclear Gen-erating Stations, February 28, 1974

(3) IEEE Standard No. 323-A-1975Supplement to the Foreword of IEEE 323-1974IEEE Standard for Qualifying Claus XE Equipmrent for NuclearGenerating S tationsEFFrrT

- _ T TIDOAT E

34G0 F/II3 p@sl/ 0% RWfWNIN 3 TO 5 UK

260DF / 7CWITHIN hI

- 4 DAYSTEMPERATURE IPRES

OF LOSS OF0

FIGURE It CABLE QUALIFICATION TEST PROFILE FOR LIFE &LOCA CONDITIONS

1EASUREMENT; 0 -AC WITHSTAND TEST, SOY/MIL.

STANDARD LOCA STEAM & CHEMICAL jSTEAM a WATEft.,41PRAY'.ecMosURE

335-F/95pdg/ 10% RH I

£ 3I5F/69p /20poOO RH O*RI

& &

pol (4) 12F/26pg/#O% RH

SEC.

-L &

15I

H R6t D A Y S 1 0 0 D A Y Sm

SUR PROFILE FOR SIMULATION IPOST LOCA SIMULATION -0tDOLANT ACCIDENT ITEST 3I

11o t

0 0 1I Il

OTHE.OKONITECOMPANY

QUALIFICATION OF* .OPOGUARD ETHYLENE-PROPYLENE

INSULATIONFOR

NUCLEAR PLANT SERVICE

Post Office Box 340Ramsey, New Jersey 07446201 -825-0300/ Cable: Okcullte

RUBBER

EEB-CBL-12Appendix 2Sheet 4 of 10Rev. 1

The Okonite Company's continuing Research and Developmentactivities as a compounder of elastomeric materials has led toan evolutionary dev~elopment of Okoguard to its present form asa clean, red dielectric. This evolutionary development has re-sulted in substantial improvements in physical strength, lowerwater absorption rates and higher dielectric strength over thoseexperienced by the earlier excellent ethylene- propylene Okoguardformulations..

INDEX

OkoniteForm No. Title

Qualification of Okogua rd Ethylene- PropyleneRubber Insulation for Nuclear Plant Service

Aging, Radiation and LOCA Testing Okog uardEthylene - Propylene Rubber Insulated Cablesfor Nuclear Power Generating Stations

Moisture Resistance - Okoguard Ethylene-Propylene Rubber Insulated Cables

Vertical Tray Flame Test - IEEE Standard #383

Form G-2 (May Z , 1977)supersedes G-1 dtd. 10/5/76)

Appendix 2-2- J~eet 5 of 10

Figure 1 shows the Arrhenius curve for Okoguard insulation compared with that ofButyl insulation. Butyl was first introduced in 1946 and has had extensive use eversince. Examination of some of the original Butyl compounds shows that the mater-ials are still flexible after twenty-five to thirty years of service. Realizing thatOkoguard insIlation is superior to that of Butyl by a factor of approximately six, iti s logical to 4rnticipate a life in excess of a generating station's designed life of40 years. -;-

Extrapolation of the plots to operational temperatures constructed from experigentaldata at high temperatures leads to very considerable errors in terms of life. ýIehave consistently found extrapolation of experimental data to predict designeý HiqUresults in far shorter predicted life than actually experienced by older, well-~Iestablished materials in actual service.U

LU .

Radiation Exposure Test Progtram LL..LLL C1

Samples of single conductor #4/0 AWG, . 175"1 Okoguard insulation, were the zr3llyaged to simulate 40 year design life condition. The aging was performed at 50Cfor three weeks, a point actually above the Arrhenius curve of . 030"1 Okoguard in-sulation shown in Figure I. As pointed out above, use of the Arrhenius technique onthin wall, newer insulations compared with the same analysis on those of well estab-lished insulations which have excellent service records is a reliable method ofdemonstrating the desired 40 year life expectancy.

After aging the heavier wall 0. 175"1 Okoguard insulation to the Arrhenius curve ofFigure I we found the actual percentage elongation for the sample was in excess of85% indicating the compound was still very viable. Using the Arrhenius techniqueson the light wall samples permitted us to show the anticipated 40 year life expectancyby comparison with existing materials. Using the same technique on heavier wallsthat actually will be used in a generating station application at the same temperaturetime period and noting the very high percentage retention of elongation thus reinforcesthis expected life.

Loss of Coolant Accident Simulation

The thermally aged and radiated cables were then placed in an autoclave and subjectedto the tempe rature- pre ssure profile for simulation of a LOCA condition as specifiedin the IEEE Standard No. 323-1974. This profile is shown in Figure II, attached.At the end of the 30 day exposure in the autoclave the samples were removed, bentaround a mandrel not greater than 40 times the overall diameter and then subjectedto a final 5-minute ac withstand test at 80 volts per mil while immersed in tap waterat room temperature. The samples were then returned to the autoclave for an addi-tional 100 day Post-LOCA test and maintained at 212F, 0 psig, 100% relative humid-ity. At the end of this Post-LOCA period the samples were removed, again bentaround a mandrel of 40 times the overall diameter and electrically tested at 80 voltsper mil while immersed in tap water at room' temperature.

Conclusion

The Okoguard samples were thermally aged to the Arrhenius curve shown in Figure Iradiated to a total dosage of 200 megarads minimum, and then subjected to a LOCAcondition as shown in Figure II, all in accordance with IEEE Standard 383-1974.Throughout the exposure the cables were energized with rated potential and currentand insulation resistance measurements taken weekly. At the conclusion of theLOCAand Post-LOCA condition the cables were then subjected to and withstood an 80V/milac proof test.

The satisfactory test results are evidence that Okoguard insulation is suitable for tý.,

0

FIGURE 11 CABLE QUALIFICATION TEST PROFILELOCA CONDITIONS

FOR LIFE a

LEGEND: A WWgLATIOIN RESISTANCE MEASMRMENT ; 0 AC WITHSTAND TEST, 8by/MIL.

I 346OF/113 pol 100m%RNS WIIN3TO SUK STANDARD LOCA STEAM a CHEMICAL *STEAM SWATE .R SIORAYI

WMI 3SPRAY EXOURE

MO /2pS I0%RIn Il,

DAT0c~ z

Imma

CD

EEB-CBL-12Appendix 2Sheet 7 of 10Rev. 1

ELECTRICAL CABLES IN A SIMULATEDLOSS-OF-COOLANT ACCIDENT (LOCA) ENVIRONMENT

FRC FINAL REPORT

F-C5160-1

Prepared for

Collyer Insulated Wire100 Higginson Avenue

Lincoln, Rhode Island 02865

May 21, 1980

lrý?randinResearch CenterA Divsion of The Franklin InstituteThe Benjmin Frankgn Pvkwasy, PNma. PAL 19103 (215) 448- 1000

TIME----*

*Chemical-spray solution consisted of: 0 - Insulation resistance

3000 ppiu boron as boric acid0.064 molar sodium thiosulfate100 ppm hydrazineSufficient sodiws hydroxide to obtainpH - 10.5 @ 770F (250C)

Temperature tolerance a t5 F (30C)Pressure tolerance s t5 lbf/in2 (34 kPa)

A Except during initial temperature/pressure transients.

Figure 4. Temperature/Pressure Profile for Simulation of Loss-of-CoolantAccident (LOCA) Environment

"i El E IIrt 0 n

0

0

Ai~

125

75 1-

100DAYS

Vi

-- ~EEB-M~-12

EF~ECTiVE Appendix 2Sheet 9 of 10U AT C Rev..

STHH OKONITC COMPA.NY O

September 17, 1981

ENGINEERINt REPORT NO. 355

MAIN STEAM LINE BREAK QUALIFICATION TEST ONOKONITE, OKONITE-FMR, X-OLENE-FNMR AND OKOGUARD INSULATIONS

Introduction

A design basis event (DBE) main steam line break test (MSLB) wasperformed on Okonite, Okonite-FMR, X-Olene-FMR, and Okoguard in-sulations. These insulations have previously been qualified fornuclear plant use in prior LOCA tests. The purpose of the MSLBwas to determine if these insulations could maintain an electricalload during such an event. The test profile was based on acustomer's postulated MSLB parameters with margin added. IEEEStandards 383-1974 and 323-1974 were incorporated in the test pro-gram.

As described in this report, qualification testing was performedby Isomedix, Inc. and Approved Engineering Testing Laboratories intwo MSLB tests. These tests are documented in report numbers 558-1021 (September 22, 1980) and 558-1077 (April 8, 1981) and are avail-able for audit at Okonite headquarters.

Conclusion

All four insulations were qualified to the MSLB-DBE describedherein. All samples met the specific performance requirementsestablished prior to testing. These requirements are describedin the body of this report.

Procedure

Qualification to the MSLB-DBE for all four insulations was accom-plished in two tests. Okoguard, Okonite-FMR and X-Olene-FMR weretested in the first MSLB test. Okonite insulation was qualifiedin the second test.

With the exception of sample preparation and thermal aging, thefirst test was performed by Isomedix, Inc. Okonite was respon-sible for sample preparation and aging,. In the second test Okoniteagain performed the sample preparation and thermal aging. Isomedixwas contracted for irradiation services. AETL performed the MSLBand post MSLB tests. For both tests, the reports were written byAETL.

The following samples were selected for testing.Set Description0(A) 5kV, 1/C #6 AWG (7X) bare copper, .020" extruded semicon-,ducting screen, .090" extruded Okoguard EPR, .030"1 extrudedsemiconducting insulation screen, .005" bare copper shield-ing tape: Four samples - fifteen feet (effective).

Reference No. 01-3663-1

0-Y

FIGURE II

REQUIR~ED TEST PROFILE VS. ACTUAL TEST PROFILE

Required Test Profile----Actual Test Profile

1) Spike achieved inS min. 13 secs.

2) 215*F/4.Spsig; transitiontime, 1 hr. 14 min,

3)- Spike achieved 'in2 min. 26 secs. v

4) Plateau extended 3.75 hrs.5) E.O.T.; Total E.T.

267.4 hrs.

(1) 45S5F/32psig (3) 4SSOP/32psig

4' 2650F/32psig

200/.Ssg(2) ,(4 (S)200-F/.Spsig190PF/9psig

EFFECTIEDAT E

C :,

.. 4...280 sec. .,4i. 1 hr. 4. 4.280 Sec. -4 3 lirs. .44259.8 hirs.10.8 days

Timei

.3'a

1<, 0

rt :3

ox I

I-h0-

EQS No. EEB-CBL-13

IVA ID No:

'r/Dat~e ~ ~Rev CJWBIN EQ 1IPH1.FNT QIIAL.1 H CAI ION SHEET (EQS)

tianufacturL'r and Model Number. See Table 3.11-BA, sheets 1008 +krk 1011b

Verification of Tahic Infor-mation (Table _3.11-BA Sheets 1008 +6r'. 1011b

X4Eouip~mcnt Tyne - The eqiuipment has beer: identified as per TVA ID number1~~T~ions~~d.,FIR, SOV, etc.).

X.. Location - The location has been identified (E.G., Inside PrimaryContainmient, Annulus, Individually Cooled Rooms, General Spaces, orarea affected by HELB outside primary containment).

X Compuncnt A uniqutc TVA ID number has been assigned (e.ýg. , l-FSX'-68-308).

x rutiction - A functional description of the component has been given(Tg_.. , S'Lam Generator Blowdown).

X Contriect No. , Flanufiacturer, and M~odcl No. - The contract number,~nufi~tuer, and model n~umber has beptn given.

X Abnormal or Acciden~t Environment - All :ah::o-rip.3 or ac-cident env ironment-al- oniiosaphaDi tochi jeuipi,,._nt have been identified either intables or by references to figures from tables.

X Environment to Which Qualified - The-,, environ.i-Ant to which the. equipmentF:been -,;E W i-41YFi f '1 is adi7Tesd in either the tables or the enviroinriieiitalanalysis attachedU-.

- aegr A catenory of a, b, c, or di has beern defined for- the equiprient.X Cac~pv __ "~~i~TnedX Oww~ation and AccwI.--V yIq~rirerl *rnd Dei-monstrated - The operation and

accuraC y- Tre-cu ;i red -(nd de0mo1s trate.C] haF- T- ' ~

Qualification Status (checkf if applicable, NA if not) Qualified Life4( p

X _Qualificaition Re-port, &nd 1.1-thod - A qualificiation report and the mettiodof I" CL&i icaio * hl011'6S b~w fd-' Qfied1.

NA Environmocntil An~alysis - An rivirornmental anialysils has beeri done, attache-dto the iETS, arid it.. 5n d.r~~ rc'i ewed by the responsibl- orqanizat ion.

X QýUazi ification by Si~riilirit~y (If op-plicable) - A justification forqulT ' ___-- To77Y - iFT, is at.ac~hed to thc EQS ccinsiduririg all the

above factors and re-1'crc::ccd to the appropriate, tables,

Qua~lification of So-vcral Exiact Com~ponen~ts (fanpplcable) - W-hen an EQSis used01 fr nlore than one it;,a list of all exact co:,.rncnts are givenas a:n appendix1) wit-h till reftrC nccus to approrpri!ate tables With jL!StifiCatiCMfor quali~ ication cons idicri rvl all the 0brve fecl-ors.

N/A Interim Qualification (1-1 zipplicaoble) _'(Openi iterm) - Com-iponent, has been)de- ierm in ed t o C_ ciif I rdi o:1, 1 fori a iimi ted i nte r imP o p er at io n, a n N C Rhas been wraitten, and ple'n o~f action has been (Icterm.-ined to yield aqualified crj;:!ione~rit. *rer;ýi of InrtcriM Q:~allification______

N/A Unci~lii ~,n'~n1 (rniiL e) - (If a;lc 1.)-co'npont-n L has be:ý11detotifd to w.~ uip.atl if ied ; 1.:wc f'wllow n'i is. attach:ed lo [r'QS:IHCR num.ber, reason for nc.qaliO ~i; d jiUSti fi CZ Li0en of Con1tilruedopera t ion.NCR No.

I e

P,

R1

KI

Prepared by: L4AA.I.IA-ii/t EEB-CBL-13, Rev. 1Appendix 1 Rev. 2

Reviewed by: teo"tSheet 1 of 2

PX Famili (PX3 and PXMJ)

The P1 fajaily of cables consist of cross-linked polyethylene or ethylenepropylene rubber, and the jacket is chlorosulfonated-polyethylene orchlorinated-polyethylene. All cable of this type was constructed, tested,and accepted for use in accordance with TVA Standard Specification 25.016-Standard Specification for Low-Voltage Wire and Cable with Flame-Retardant,Cross-Linked Polyethylene or Ethylene-Propylene Rubber insulation. TVAStandard Specification 25.016 invokes the applicable portions of IPCEAStandards; such as, physical properties, and methods of testing for tensilestrength and elongation of the insulation and jacketing materials. The TVASpecification included provisions for source inspection of factory testingand required submittal of certified test reports to assure compliance withthe specification. Manufacture of all installed cable was controlled by aTVA approved QA program.

The following LOCA/SLB tests are representative of the P1 family of cableswhich are presently installed.

Franklin Institute Test Report F-C4113 dated May 1975. (Brand-RexCompany) (See Appendix 2).

Rockbestos Company Test Report dated July 19,L7 and revisedNovember 26, 1977 "Qualification of Firewall% III Class 1E ElectricCables (Chemically Cross-linked Insulation) (See Appendix 2).

Franklin Institute Test Report No. F-C5120-1 dated August 19, 1980,(Brand Rex Company) "Qualification Tests of Electrical Cables in aSimulated Steam Line Break (SLB) and Loss-of-Coolant Accident (LOCA)Environment" (See Appendix 2).

Essex Project Report Number PE-53 dated May 7, 1980 "Main Steam LineBreak (MLSB) Test on Aged and Irradiated Cable Specimens." (SeeAppendix 2).

Franklin Institute Test Report F-C4997-1 dated December 1978 "Quali-fication Tests of Electrical Cables in a Simulated Steam-Line-Breakand Loss-of-Coolant-Accident Environment (American Insulated WireCorporation (See Appendix 2).

The Okonite Company Test Report N-i dated July 3, 1978 "Qualificationof Okonite Ethylene-Propylene Rubber Insulation for Nuclear PlantService" (See Appendix 2).

The Okonite Company Test Report FN-2 dated October 28, 1980,"Qualification of Okonite-FHR Flame Retardant Ethylene-PropyleneRubber insulation for Nuclear Plant Service" (See Appendix 2).

r FFr. C T75 1

Prepared by: -- 4EEB-CBL-13, Rev. 1Appendix 1 Rev. 2Reviewed by: &1242 _42 a-)eu Sheet 2 of 2

PX FamiLy (PXJ and PXMJ)

the Okonite Company Engineering Report No. 355 dated September 17,1981j "Main Steam Line Break Qualification Test on Okonite, Okonite-FHR, X-Olene-FMR and Okoguard Insulations" (See Appendix 2).

Franklin Institute Report F-C4836-2 dated January 1978, "QualificationTests of Flame-Guard FR-EP Instrumentation and Control Class lEElectric Cables in a Simulated Steam-Line-Break and Loss-of-CoolantAccident Environment" (Anaconda Company) (See Appendix 2).

The test reports demonstrate that P1.7 and PDLJ cables manufactured to meetthe requirements of TVA Standard Specification 25.016 are suitable forClass 1E service in accordance with appropriate guidelines presented inIEEE Standards 323-1974 and 383-1974.

The tests included radiation at 2x108 rads except the Okonite liSLBEngineering Report 355 included radiation at 55x107 rads.

The tests included a LOCA/SLB at 3460F, ll30psig 100 percent humidityand liSLB's at 4550F, 32 psig (Okonite) and at 440OF (Essex).

These cables have a qualified lifetime of 40 years as determined byArrhenius techniques and are qualified by the above for all HELB areas.Because of the conservatism of these tests including the severity of themandrel bend and dielectric test in water after the combined LOCA/SLBprofile, engineering analysis concludes that there is sufficient marginto give reasonable assurance of continued operation for more than a yearin the post design event environment.

These tests included cable samples from Brand-Rex Company. RockbestosCompany. Essex International, Inc.. American Insulated Wire Corp..

TheOkoit Copay, ndAnacond Cmpany. This cross section of cablemanufacturers represented in the tests adequately demonstrated that thePX family of cables will perform similarly in the given DBE. Thevariety of vendors used also proved that successful completion of the testis a function of the chemical properties of the insulation and jacketingcompound and is not dependent on the manufacturer. Consistency in thechemical properties has been demonstrated by successfully completing therequirements of TVA Standard Specification 25.016. This approach togeneric cable qualification follows the general guidelines for typetesting as outlined by IEEE 383-1974.

All cables of the PX family met or exceeded the construction, testing,and acceptance requirements of TVA Standard Specification 25.016. Inaddition representative samples of the PX family of cables supplied to TVAby different manufacturers successfully passed LOCA/SLB testing. In viewof the above, we conclude that the results show that the PX family ofcables are generically the same and that regardless of the manufacturer,the cables will perform adequately in a DBE accident.

034279.03EF

OT VK4ý

f~ea~r*d .1 Wjj&

IA -

EEB-C3SL- F'!>

5 kett I 'D T

Final ReportF-C4113

QUALIFICATION TESTS OF ELECTRIC CABLESFOR CLASS IlE SERVICE

IN NUCLEAR POWER PLANTS

Prepared for

BRAND-REX COMPAYA PART OFAmnfo INC.

May 1975

THE FRNKLIN INSTITUTE RESEARCH LABOATORIESTa( NFNJAMIN FRANKLIN PARKCWAY - PHILADILPWM IA pgSWSVVANIA 1%103

Report

F__ -

0

Actual Temperature/Pressure Profile for Simulation of LOCA N0 0Figure 4.

0

S.'* tS..

,:' *;.

~ '1I -~

-~1

- -.- . :.

* 4

Y> SI.

'..... 79 e

9UAIFC *.O OF FIEWL I

j i. ',.- WA

J* 7a I..M

'llovisal Nov

LOCA Profile

1401

c:

L~ rn -

4~

m

T I M EDAYS

Jr-

rEb&Cf5L- 13:

QUALWICATION TESTS OF ELECTRICAL CABLES IN ASIMULATED STEAM LINE BREAK (SLB) AND LOSS-OF-COOLANT ACCIDENT (LOCA) ENVIRONMENT

FRC Final ReportF-CS1 20-1

?rapared for

BRAND-REX COMPANYA PART OFA~ZmfOINC.

PHOW 2W 423-777

August 19, 1980

r 191864

lrý? ranflnResearch CenterA Diisin ofTheFrnklin Institute

Tim a3munrm~n* PwPwkouy.Phb..PP& 19 10 m a i) 4a- i000

F-C5120-1 SJke't "To i19

1. SUMMOARY OF SALIENT FACTS ~\2

FTC Project 10D. Report Title:

C5120 QUALIFICATION TESTS OF ?PLECTRICAL CABLES IN A SXIMULATED SWAN

I LINE BREAK (SLB) AND LOSS-OP-CODOLANT ACCIDENT (LOCA) ENVIR0WFWNT

Conducted and Reported by: Conducted for:

Franklin Rseaerch Center grand-Ron CompanyThe Parkway at Twentieth Street industrial and Electronic table DivisionPh iledelphia. PA 19103 Villimantlc. CT 06226

Report Date: Period of Test Program:

August 19, 1980 August through December 1979

Objective:

To demonstrate performance of electrical cables for Class 1t service in nuclear power generatingstations in accordance with guidelinee presented in IEEE Itds 323-1974 and 383-19?4.l

Equipment Teested:

Eighteen electrical cables (four 1/C 016 AWC, two 2/C *2 AWC, six 1/C 012 AWM, three 71C 612 AVG. andthree 1/C #2 AVC) with crosalinked polyethylene (ILPE) insulation and jacketing materials of Rypabonon multiconductor cables. A complete description is provided as Table I herein.

Elements of Prograu:

The specimens were divided into three groups for thermal aging: On@ group of eight specimens Weamaged. a second group of seven specimens was thermally aged for 168 hours (7 days) at 1360C (27707).and the third group of three specimens was thermally aged for 168 hours (7 days) at ISSOC (3170y).All specimens were exposed to 200 Nrd of geema irradiation (air equivalent does) from a cobalt.40 source

a t a rate less than I Ifrd/h end then to a stem/chemical-spray environment simulating a comined astealine break (ELI5) and oses-of-coolant accident (LODCA) and the cooldown following the ILI/LOCA. Thesimulated SLB/LOCA exposure included two rapid rises in temperature/pressure to 36550 (19660I66 Wb/On (455 Rpa). two 10-minute dwell@ at those peak temperatures, followed by decreasing tempera-tures to a final 20-day dwell at 230P (11000/10 Wb/On (69 ka). The total simulated gLI/LDCAduration was 30 days. A chemical solution (6200 pp. boron, S0 p"m hydrauina, sufficient sodium triphee-phate to obtain a pm of I.5. followed by sufficient sodium hydroxide to obtain a pR of 10.0 at Toom tear-peracure) was sprayed on the specimens at the rate of 0.27 spa per square foot (11 L/min per squaremeter). 2 starting at the completion of the 10-minute dwells at 3850? (1960C). The cables were electri-cally energized with ac potentials of 300 and 600 V, and currents of 10. 25. and 120 A ("e appropriate)dur ing the 30-day SLI/LOCA exposure. Fine) tests consisted of a 40X diameter bend teat end a 5-minuteac high-potential-withstand test *t S0 Y per ol) (3150 V/em) of insulation.

sumary of Test Results:

SLBOA Exposue - Fourteen of the 16 specimsns remained energized except for short periods. "ee

FIna tis-Potentia-Withstand Tests - All specimens withstood a high-potential-withatood teat witha e~ak~age&charg-,ting cure -o-&sstan 300 mA. See Reamrks.

Remarks - Failure of four specimens to remain enargised during the gLI/LOCA exposure (too above)wa-s posibly caused by problems with test vessel penetrations . the problems were not considered tobe indicative of the cable performance mar of conditions in a nuclear power ganerating station.

3

Note that all @apeimens withstood a final high-potential-withstand teat.

Ftull sitations are provided in the text.2 "section 4.5 for description of spray area calculation.

3A supplemental letter report is available which discuases thetest methods and the reasons for intermittent cable deemergising.

ll?[ir~:nkdin Research Center1A Wota.n ol The Fis~in kwWa rs

w

6 6ELAPSED TIME WmOn

Actual Temperature and PressureFirst SLB/LOCA Transient-

Profile of

LE5

II

IMh-

? io

41

"IL

to-

79-.

Figure 6.

a

6 aELAPSED TIME (min)

Actual Temperature and Pressure Profileof Second SLB/LOCA Transient

q'j

mope=

0

225r-

I~.2001-

175l-

ISO

125

WEr

So --

Figure 7.

ESSEX GROUP, INC.

POWER CONDUCTOR DIVISION

PROJECT REPORT

1kc-port Nurtbcr : PE-53

Da'atc: May 7, I.D30g.,ttl.teal Itom say part of Lis 0c.wUb31iJ

a6111 ler-ot "m.rcaloo

1[KRCSSEE VALLEY AtUr1:MITY

St SEP 2 3 1980

M AIN STEAM LINT BREAK (MSLB)

Test On Aged And Irradiated Cable Speecirrns

PROlCEDURE:

1'.aufacture and prepare samples of Class lE cableo for atinm, and£wilsequent submittal to Isomedix, Inc. for irradiation and simula-tion of Main Steamt Line.Brealz Tempert.ture and Pressure Profile.'

C07,CLUTSON,:

Specimens of Class 1B EP insulated conductor having successfullywithstood the effects o j heat aging to 40 years at 90C, irradiationto a level of 2.05 x 10~ Rads (C060) and a MSLB temperature andpressure profile according to the requirements of the TVA Specifi-~cation are judged to be fully qualified for service aiccording tothe referenced specifications.

E F FE'C T IVE'

REFERENCE: D-AT EOT 1284A

TVA Specification 25.016 Item 93 Contract 6-825722Isornedix Radiation CertificationEssex Arrhenius Plot (Class lE EP)

SiEQUOYAH

'80'-8.2 73 2 0- 1

Respect fully submitted,

Chief Engineer- - ~-- -w-w~--- -~- -

ý11110ý 1 , I 1 19 1 IM iii'll III M111 - - - _ ___

A ffCeA-X

_S Appef'h 9Z

Tll.-ý'*,E:

U- rJ

r4

"4 T

4co

2..

rr)

A -i

- ~jVrJLa.~gmpg~o.aa

11~IO

ILM~I1~A~fla1.a U&UIU3111

x 1

hIlIiI .18

Qualification, Tests of Electricalin a Simulated Steam-Line-BreaLoss-o f-Cool ant-Acci dent EnvirIFRC Final ReportF-C4997-1

AM PPRO VEDfm Wt&, hC"*109*0 f'""' "~ ON- Of if Oh mj0"t 1.,. Mfl COOMM of

SVALLFY Tyl

M~ AY 20).1980,Prepz'ed for -~~ .Af

American Insulated Wire CorporationPawtucket, Rhode Island

December 1978

77iTV ~'E

U A TE

lrý3rnkfin Research CenterA Division of The Franklin InstituteThe Benjmnrdn Frwnlin Parkway, Phil.. P&. 19 103 (215)4"a- I 00

#7qeks5. 92S3dq?- 2

1 Cables Afpe'iJ*

k and S

IIAPTsviRE- Plfifm 4ý1-ttb

UPPER LIMIT ESTIMATED VESSEL PRESSURE 125FOR TEMPERATURES >4O0OF (USE RIGHT-HAND.SCALE)450- (RECORDER SPAN 00 TO 400*F)

400.04000

IL 350 TEMPERATURE35 dl

0

!;j300 - EPRAUE

2 ~Inn

~20UPPER AND LOWER LIMITS OF -50 CCMEASURED TEMPERATURES

S~MEASURED PRESSURE200- (PLOTTED POINTS CONNECTED

WITH STRAIGHT LINES)

25

~1

0 20 40 60 80 100 120 140 160 1B0 200ELAPSED TIME (SECONDS)

Figure 7. Plot of Temperature and Pressure for First 200 Seconds of S/C Exposure

b7~N

*©0THEOKONITEI COMPANY

Post Office Box 340Ramsey. New Jersey 07446201 -B25-0300/Cablei Okortite

QUALIFICATION OF OKONITE ETHYLENE-PROPYLENE RUBBER INSULATION

FOR NUCLEAR PLANT SERVICE

EES-C& 1

13 of 11

I~j2

The Okonite Company's continuing Research and Development activitiesas a compounder of elastomeric materials has led to an evolutionarydevelopment of Okonite dielectric. This insulation is fully capableof meeting all aging, moisture, radiation and flame test requirementsof IEEE Standard No. 383 and is therefore capable of nuclear plantappl ication.

INDEX

Form No.

(a)

Title

Qualification of Okonite Ethylene-Propylene Rubberfor Nuclear Plant Service

(b) Aging, Radiation and LOCA Testing Okonite Ethylene-Propylene Rubber Insulated Cables for Nuclear PowerGenerating Stations

(c) Moisture Resistance - Okonite Insulated Cables

(d) Vertical Tray Flame Test - IEEE Standard No. 383

r~i777~.TI V ESAT ZE

Form: N-1 (Revised 7/3/78) 6,-, 1.9 0-3

FIGURE 11 CABLE, QUALIFICATION TEST PROFILE FOR LIFE&SLDCA CONDITIONS

LESENO: A ISKIATIO RESISTANCE MEASUmRE :EE 0 AC WITHS ND TEST, SOV/NIL.

Uj\.

34VPF/Is puS/m o% RwmuuI 3 TO 9 UK STANDARD LOCA STEAM G CHEMICAL

SPRAY 0(OURE STEAM 8 WATER. $MRAY

335*F/95pg/ 100% RH

315-F/69pdg/IO% RN

U5F,/Ispolg / 100% of

to60F/ 70 poll (ml.)WITHIN 10 SEC.

212ffIOpil/O0% RH

OF LOSS OFt -~

-I

IA I

~~='~4flm -=

_'Ti

INR TEST AVERAGEONCE PER 2 WVEEKS

TEST

S-

THE.* OKONITECOMPANY

Post Office Box 340Ramsey. New Jersey 07446201 -B25-0300/Cable: Okonite

QUALIFICATION

OF

OKONITE-FMR FLAME RETARDANT ETHYLENE-PROPYLENE

RUBBER INSULATION FOR NUCLEAR PLANT SERVICE

r~e-c0~L-3

Qualification for nuclear plant service has been performed at Okonite onsamples of Okonite-FMR insulated wire. Okonite-FMR is a flame and moistureresistant ethylene propylene rubber which was formulated and compounded byOkonite. This insulation is fully capable of meeting all the aginq, radiation.moisture, and flame test requirements as stipulated In IEEE Standard 383-1974.Based on the test results presented in this report, Okonite-FMR is qualifiedfor nuclear plant applications.

INDEX

TITLE

Ethylene Propylene Rubber

Moisture Resistance

Vertical Tray Flame Test

Form Ft4-2 (10/28/80)

Testing Okonite-FMR

E F F E.- V E

OCG-T E16384

SECTION,

0

eAftt gjvAl.IPICAToJ 'Ts-,VT PROFILL FOOL-6eQoe"j:jiA%- LOCA. lojtý-ý(p

39 9

0 A:r,, 3on-A orway iwrgo ZLIýft-

rn

7tý (A

a-lL FMI4

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vov--Tm4r. df C-Wv6V-r,- I

POOIst'K.XV4b 6 It

JoAft (trf WitM)

ý 0 41

-416MA + VIATem 6?"*( ---

- September 17, 1981

ENIGINEERINd REPORT NO. 355 -bCL1

M!AIN STEAM LINE BREAK QUALIFICATION TEST ON 1OKONITE,.OKONITE-FiMR, X-OLENE-FMR AND OKOGUARD INSULATIONS 2-

Introduction -

A design ba sis event (DBE) main steam line break test (ýMSLB) wasperformed on Okonite, Okonite-FMR, X-Olene-FNMR, and Okoguard in-sulations. These insulations have previously been qualified fornuclear plant use in prior LOCA tests. The purpose of the MSLBwas to determine if these insulations could maintain an electricalload during such an event. The test profile was based on acustomer's postulated MSLB parameters with margin added. IEEEStandards 383-1974 and 323-1974 were incorporated in the test pro-gram.

As described in this report, qualification testing was performedby Isomedix, Inc. and Approved Engineering Testing Laboratories intwo MSLB tests. These tests are documented in report numbers 558-1021 (September 22, 1980) and 558-1077 (April 8, 1981) and are avail-able for audit at Okonite headquarters.

* ~Conclusio n.

All four insulations were qualified to the MSLB-DBE describedherein. All samples met the specific performance requirementsestablished prior to testing. These requirements are describedin the body of this report.

Procedure

Qualification to the MSLB-DBE for all four insulations was accom-plished in two tests. Okogu~rd, Okonite-FMR and X-Olene-FMR weretested in the first MSLB test. Okonite insulation was qualifiedin the second test.

With the exception of sample preparation and thermal aging, thefirst test was performed by Isomedix, Inc. Okonite was respon-sible for sample preparation and aging. In the second test Okoniteagain performed the sample preparation and thermal aging. Isomedixwas contracted for irradiation services. AETL performed the MSLBand post MSLB tests. For both tests, the reports were written byAETL.

The following samples were selected for testing.Set Description U(A) 5kV, I/C 06 AWG (7X) bare copper, .020" extruded semicon-. j,ducting screen, .090" extruded Okoguard EPR, .030"1 extruded ""2

ingitape:cFour samplesionfifteen, feet" (effective).hildsngicond:ctour insulationfscreen .005" barfecopper) hel-.Reference No. 01-3663-1

*

05,

uc

Thbl1 v

4d Its ;DW I I I II I I1I1111

W b * *~J**

~rnIiu~iI

T ~

FIGURE 11____Required Test Profile----Actual Test Profile

1) Spike achieved inS min. 13 secs.

2) 215*F/4.Spsig; transitiontime, 1 hr.-14 min.

3) Spike achieved-bi-2 min. 26 Yecs.'

4) Plateau extended 3.7S hrs.S) E.O.T.; Total E.T.

267.4 hrs.

(3) 4SSOF/3:

'4

'4'4

190*F/9psig5--,

0

Timr

V0 a '6 0ý. I . a %%A 1

11% )%2 3 114 EQS No. EEB-CBL-15

11 TVA I D No:4 4. fy- Z__Type PJJ Cable

WM; ~EQUI PMENT QUA! IAFICATION SHLFf LEQ5Manufacturer and Model Nrni~!ber. See Table 3.11-8A, Sheets 1005, 1006, and 1007

Verific-ation of Table Information (Table 3.11-8A Sheets 1005, 1006, and 1007)

LU ~X EqE9pnent lype - 'fie equjiprment has beern identified as per TVA ID number.deSi'SiX&CTh-To. d., I.OV, SOV, etc.).

I> --CO X ltocation - The location has bken identified (M.., Inside Primary

:ao LCFnT51nmuent, Arnnulos, Individually Cooled Rooms, General Spaces, orarea affected by l1ELB3 outside primary containment).

X Cor~n t -i~ A uniqUe TVA ID number has been assigned (e.g., 1-FS-68-3O8).

LA_ C) X Func!.ion -A functional dec'lc-ption of the component has been given(eg. SiLeaii Generator Bl o--dow~n).

X Con tract N'o., l~antifacturer, and Model No. - The contract number,.manufactu-i r, and model number has been given.

X Abn'Jrnal or Acciftnt Enviromn~ent - All abnorimlal or accident crnvironneritalconi(i 6'Tiý -app]i i Cý [TefluT 11ThiS&Fivi pment haive been i denti fi ed either inltables or by references to figures from tables.

X Environment, to W4hichQualified - The--ý environment to w~hich the equipment- hs ~~ThYI~T~-is addressed -in cither thle tables or the environmiental0 analysis attached.

X L~acioryY A category of a, b, c, or d has been defined for thle eqllipnlcrit.

X Opera-ion and AccurzcyRequirere an~d Demonstrated - Tile operation, and-accu rl 7 -req irccVind demonstFatc laebe dfnd

Ovalificatior, Status (c'herc, -f arppicable, HA if not) Qualified LifeL/~~

X Qualifi.-ation Rc;Pori. end fiathnt1 - A qualification *report, and thle. methodofqual~iUcation h-V-s biiiý id crtjifid

KI X, Env i r~nriental Analysis - An enivironmental analysis has been done, attachedto the Sand ini.dr yreviewecd by the responsible orgaxnization.

NA QAja' i -fioa'Licn b-, Si!.iilarit'/ (It' appliccable) - A. justification for4qFil"If*ic-aUL~-Ii-E)Y S'il ar 1ty is attached to the ErS cons~idering all theaboveo faLctors and refereceicd to the appropriate tables.

X Qualification of Several Exact Compocnents (if applicable) - When an EQS*is ius~for m~ore than one ia list of all exact componenits are qivc-nas art 'tppcnd~ix with all referencces to appropriate tibles With jUStif1rica;tiC.nfor qual ificiitiJun cunsiderin-, all tile i-bove fac~teis.

M/A' Iiterim Qualific;-Lion (faivilic.able)Y (Open item) - Component has beenWjTehijcnedto be qua fied only for a 'limited inter-in: operation, an N'C Rhas keni written, and plan of Oction ),is tceii determirnc(. tc yield aqualified compuncnt. Term of Intcrimi Q,.ali ification ___________

NiAUnqnl i~t. ':ipn~*t-(Op 1ter.) -(If appli1cabl e) - CormporionL has 1, výnde"u ;ii nid Lo 1)(., tinqual ifi .A ; L fi)o(i n is ati aChýd to MQS:WClR r~ui:ibr w, reaison for nc-ilif aio',;:nd justi f i cati on of contin'uod,operantion.

HCR IVO.

Preparer/Date .'6 ( /6v/%/O/'V EEB-CBL-1 5Appendix 1, Rev. 2Reivever/Date ________________ Sheet 1 of 2

Type PJJ Cable

PJJ type;;cabLes consist of a polyethylene insulation and polyvinyl-chloridejacket.. All 'cable-of this type vas constructed, tested, and accepted foruse in accordance with TVA Standard Specification 25.013 - StandardSpecification for Polyethylene - Insulated Wire and Cable. TVA StandardSpecification 25.013 invokes the applicable portions of IPCEA Standards(such as physical properties and methods of testing for tensile strengthand elongation of the insulation and jacket materials). The TVAspecification included provisions of source inspection of factory testingand required submittal of certified test reports to assure compliance viththe specification.

The f ollowing qualification tests are representative for the PJJ cableswhich are presently installed.

Wyle Laboratory Test Report 17503-1 dated January 6, 1984, NuclearEnvironmental Qualification Test Program on Sequoyah Nuclear Power StationControl Equipment and Cables. The test included cable manufactured byPlastic Wire and Cable Corporation. See Appendix 2.

Wyle Laboratory Test Report 17501-1 dated March 12, 1982, NuclearEnvironmental Qualification Test Program on Four Bets of Polyethylene/Polyvinyl-Chloride Insulated Control Cable. The test included cablemanufactured by Plastic Wire and Cable Corporation. See Appendix 2.

Wyle Laboratory Test Report 17508-1 dated November 22, 1982, High EnergyLine Break Test Program on Two Control Equipment/Cable Assembly Test Sets.The test included cables manufactured by Plastic Wire and Cable Corporationand Cerro-Rockbestos. See Appendix 2.

The test reports show a baseline functional test was first performed andpassed. Then functional tests were performed and passed after theradiation test, after the temperature aging test, and after LOCA/SLI test.

The tests include radiation at lx108 rads.

The tests include temperature aging at 110*C for 31 hours, then temperaturewas increased to 120*C for 1019.5 hours. This represents aging equivalentto 4O-year life with an ambient temperature of 120*F. The aging time andtemperatures were based on Arrhenius techniques.

The tests include LOCA/SLB at 330*F, 9.5 PSD7.

The cross section of cable manufacturers represented in these testsadequately demonstrated that PJJ cable will perform similarly in the givenDBE. The variety of vendors used also proved that succcessful completionof of the tests is a function of the chemical properties of the insulation

E F F CTi V E(02T 1..; '4

Preparer/Date A:iA 8

Reivewer/Date 1Oio-f,&EEB-CBL-l15Appendix 1, Rev. 2Sheet 2 of 2

and jacke-ting compound and is not dependent on the manufacturer.Conaiitez~y in the chemical properties has been demonstrated bysuccessfully completing the requirements of TVA Standard Specification25.013. *This approach to generic cable qualification follows the generalguidelines for type testing as outlined by IEEE 383-1974.

All cables of the PJJ family met or exceeded the construction, testing, andacceptance requirements of TVA Standard Specification 25.013. In addition,representative samples of the PJJ family of cables supplied to TVA bydifferent manufac 'turers successfully passed LOCA/SLB testing. In view ofthe above, we concluded that the results show that the PJJ family of cablesare generically the same and that regardless of the manufactuer, the cableswill perform adequately for a DBE.

.3..,

044279.11

.3.

*EEB-CBL-15 NEQ-Appendix 2, Rev. 0

Sheet 1 of 8 &*n~waeo

Test ReportREPORT NO. 7pl

WYE OB NO. 1750:

> . PAGE i OF 299 AE P0n DATE November 22, .1982

Iw SECIFCTO See References

*in Paragraph 5

~re y 3 ~ /Io/Y_ _ _ _ _ _ _ _ _ _

1.0 CUSTOMER Tenese VllyAuthority (TVA)ADDRESS 400 Commerce Avenue, Knoxville, Tennessee 37902

2.0 TEST SPECIMEN Two (2) Control Equipment/Cable Assembl1y Test sets0 -- with Cabling, Splices, Terminal Blocks and Control Devices.

30 MANUFACTURER V

4.0 SUMMARYTwo (2) control Equipm~ent/Cable Assembly Test Sets, described in Paragraph 6.0,were subjected to a High Energy Line Break (HELD) Test Program~ to confirm theadequacy of design to perform their required functions under abnormal conditions,as specified herein.

The test items are for installation in the Browns Perry Nuclear Power Units 1, 2,and 3, Tennessee Valley Authority.

The purpose of the test program was to oubject various generic cable types,splices, terminal blocks, and control devices to various steam temperature andpressure rofiles resulting from HELB as defined for Browns Ferry, Uis1and 3 b

STATE OF ALABAM California Profession Eng. bto=COUNTY OF 14ADIWNt Reg. No. 2635 6"OA1 wW mJames F. Gleason 26ISPEPRDBend ~ys: The t lionmu containd In Ohia pon daM to~ ft rtul of to Aald caZeufIcnuted bet aend is to ft bma of Io knovlap vw am~ oct~j ANOEa

canm for IfoStata of Alabama at brpj.my comwm~iO oap.. _________ 0_ to

CIWFCSERVICES AN SYSTEMS GROUPMKOUTVILLE. ALABAMA

PAGE O. viEEB-CBL-15PAGE O. viAppendix 2, Rev. 0

TEST REPORT NO. 17508=1 Sheet 2 of 8

6.0 TEST SPECIMEN DESCRIPTION (Continued)

Item Description

1.2 * One (1) length (of not less than 10 feet) of No. 14

AWG, 1/C, TVA Type PN, Mark WCA cable (conductor A)#

containing a stranded copper conductor (7 strands/

.0385 inch), insulated by a .030-inch thick layer of

polyethylene. The assembly is jacketed with a nylon

(.004-inch thick) exterior jacket. The cable is rated

for 600 volts, 33 amperesmaiundaaxumc-

ductor temperature of 75*C.

1.3 one (1) length (of not less than 10 feet) of No. 14

AWG, 2-conductor, TVA Type PJJ (conductors B and Co

mark MME cable, containing a stranded copper conductor

(7 strands/.0 2 4 inch), insulated by a polyethylene

(.030-thick)/polyvinyl chloride (.010-inch thick) layer.

The assembly is jacketed with a polyvinyl chloride

(.045-inch thick) exterior jacket. The cable is manu-

factured by the Plastic Wire and Cable Corporation and

is rated for 600 volts, 19 amperes maximum and

a maximum conductor temperature of 750C (40*C ambient

plus 35*C heat rise).

1.4 Cable-splice assembly, consisting of the following:

1.4.1 one (1) length (of not less than 10 feet) of No. 16

AWG, 2-conductor (conductors D and E), Mark WVA cable,

containing a stranded copper conductor (7 strands/

.0192 inch), with a tinned coating. Each conductor is

insulated by a .020-inch thick high density polyethylene

layer. The conductor arrangement consists of a twisted

pair, 2-1/2 inches or less lay, with a shield consist-

ing of .001-inch thick iMylar and a No. 18 AWG tinned

and stranded (7 strands) drain wire. The assembly is

jacketed with a polyvinyl chloride (.050-inch thick)

exterior jacket. The cable is manufactured by Cerro-

Rockbestos and is rated for 600 volts with instrument

current at an ambient temperature of 120*F.

1.4.2 Three (3) Raychem WCSF heat shrink insulated splices,

consisting of the following:

o (2) Raychem NCSF-115-6-N insulated splice, con-

sisting of a crosslinked polyolef2.n sleeve (.08-

E F FECT1VEinch thick) coated with a heat-activated cross-D A T'?".wlinked adhesive (Type N). The sleeve is 6 inches

D0 ATi long and is rated for a maximum of 600 volts.

O~T 1.-V ~900C (continuous operating temperature).

00

n~ C'I 4-4

-...

... ..

-H v-- V.

L)93A

I nq

... ...

_..

~~samum~( to~Sf@ ~UJ.UNJ~m~JOJ.U K 28

EEB-CBL-15Appendix 2, Rev. 0Sheet 4 of 8

NEU#&J 0um 1, -Iftat

Test ReportREPORT NO. 17 501-1

WYLE JOB NO. 17501CUSTOMERT-507-P. 0. NO. _ T-67-

PAGE i OF 143 -PAGE REPORT

DATE March 12, 1982

SPECIFICATION (S) WLTP 17460-21, Rev. B

LO CUSTOMEI

ADDRESS

Tennessee yallay au1thoritvy

AAA t~w,,vi~ Av~v,,i~ KVitWl7ilTh, TN 37902

TEST SPECIMEN .Polyethylene/Polyvinylchloride Insulated Control-Cable

&.0 MANUFACTUIRER Plastic Wire and Cable Corporation

4.0 SUMMARYFour (4) sets (total-of 8 cables) of Polyethylene/Polyvinylchloride InsulatedControl Cable, described in Paragraph 6.0, were subjected to the test programdescribed in Wyle Laboratories' Test Procedure 17460-21, Revision B, and Par&-graph 7.0. It was demonstrated that the specimens possessed sufficient integrityto withstand the required test program and meet the acceptance criteria. TestItem 3.0 experienced a dielectric breakdown during the Post-Radiation MandrelBend Test at 480 VAC (both conductors to ground and conductor to conductor). The

test was performed for information and margin assessment only.

STATE OF ALABAMA Ala. Professional Eng.COUNTY OF MADISON Reg. No.-8256

Flavous R. Johnson- .*b@4 duy WOMdcpom VWd say: The Ikarmatoe scnhind In thie rep@. bw VWmult at =smpI9

w4 to~l ow&m~dWft a 10go oo f hbka~ftde ft W4Wmhin

am rspow

PREPARE BY~ rxýz eo

APPRC ED BY<

WYLE 01. A. W .4 L =:

SCIENTIFIC SERVICES AND SYSTEMS GROUPHUNMSILLE. ALABAMA

r - IAnn Prgnmov- AVA"ue Knoxville TN 37902

R

PAGE NO. iii Appendix 2, Rev. 0Sheet 5 of 8

TEST REPORT NO. 17501-1

O6.0 EQUIPMENT DESCRIPTION

The testing was Performed On TVA Type PJJ Cable, mark letters WHB,p 2/C, No. 14 AWG Control Cable, manufactured by Plastic Wire and CableCorp4?ration and supplied by TVA. The cable is polyethylene insulated(.020" thkc) with a polyvinylchloride jacket (.010" thk), rated at105*C, wrapped around each individual conductor. Both conductors arethen wrapped, as an assembly, by a second polyvinylchioride exteriorjacket (.045" tbk). The cable is rated for 750C maximinn continuousconductor operating temperature.

6.1 Test Specimens

Four (4) sample sets of cable, as described in Paragraph 6.0, wereutilized for the purpose of this test program. Each sample set wasprepared by Wyle Laboratories. Preparation of the cable samples con-sisted of the assembling of 1.5" Unistrut galvanized channel with anoverall length of 8 feet plus two upstanding channel sections (oneat either end of the S-foot section) to form a "U" shaped cable tray.Lengths of cable (approx. 12 feet) were then cut and placed into thechannel and secured with plastic cable ties. Each of the eight (B)channels contained one two-conductor cable. The ends of the cable,approximately 0.5 to 1 inch, were stripped of insulation to facilitatethe necessary test measurements. The cables remained in the traysthroughout the test until the Post-Test Inspection Mandrel Bend Test.

7.0 TEST PROGRAM SEQUENCE

The test program for each sample set was performed in the followingsequence.

7.1 Sample Set 1

" Functional Test EF F EC T71V Eo Accident Radiation Exposure (Item 1.0) DA'o Functional Testo Post Test InspectionOC

7.2 Sample Set 2

o Functional Testo Radiation Aging - 3 Test Specimens (Items 2.0, 3.0, 4.0)o Functional Test Io Thermal Aging - 3 Test Specimens (Items 2.0, 3.0, 4.0)o Functional Test" Accident Radiation Exposure - 3 Test Specimens (Items 2.0,3.0, 4.0)

" Functional Test" Post-Test Inspection

WYLIELABORATORIES

EEB-CBL-15Appendix 2, Rev. 0Sheet 6 of 8

Test ReportREPORT NO.-

WYLE JOB NO.CUSTOMERP. 0. NO. -

17503-i

17503

TV-56071 A

PAGE i OF 529 _PAGE REPORT

DATE January 6, 1984

SPECIFICATION (S) See Paragraph 5.0

LO CUSTOMER-

ADDRESS-

IV TEST SPECIMEN

Tennessee Valley Authority

400 West Summiit Hill Drive, Knoxville, TN 37902

Control equipment consisting of terminal blocks, pushbutton oper-

ators, selector switches and contact blocks and various cables

3.0 MANUFACTURERVarious (see Paragraph 6.0)

4.0 SUMMARY

Four (4) junction boxes, twenty-four (24) terminal block assemblies, ten (10)pushbutton operators, five (5) selector switches, seventy-two (72) contact blocks,fifteen (15) legend plates, and sixteen (16) cables, hereinafter called thespecimens, were subjected to a Nuclear Environmental Qualification Program asspecified in References 5.1, 5.2, and 5.3. The Qualification Program was conductedin accordance with Reference 5.4.

(DN261)

STATE OF ALABAMACOUNTY OF M&DIIUONd

Alabama ProfessionalEngineer Reg. No. 7948

-Frederick M. Sittason __.W"dMOdsosw anW may: TMe WIwotmata alanul in Mbi few boe is * of eswtWWWId ocfiy we and WW to "m be at wes midAd VW W Md in

0* COMAmmli owr.

PREPARED BY il.

on/APPROVED B8IA

LABORATO~IES SCIENTIFIC SERVICES & SYSTEMS GROUPHUNTSVILLE. Al ADAMA

rinm~mimuum.muw~

NEQ

L

Page No. x thbUCBL-IJAppendix 2, Rev. 0

Test Report No. 17503-1 Sheet 7 of 8

S 6.0 TEST SPECIMEN AND TEST EQUIPMENT DESCRIPTIONS (CONINUED)

6.1.1 Control Equipment (Continued)

o Iteons 1.12.2, 2.12.2, 3.12.2, and 4.12.2 - (1) red pushbuttonoperator (CH10250T115); (4) contact blocks," 2-pole, 1 normallyopen and 1 normally closed (CH1O25OT1); and (1) large size legendplate, part 'number 10250Th81.

o Items 1.13, 2.13, 3.13, and 4.13 - Four (4) Cutler-Hammner 10250Type T, oil-tight, three position selector stations, to be panelmounted. Each station consists of the following components: (1)3-position selector switch, part number CH10250T 304; (4) contactblocks (normally open and normally closed, part numberCH10250T48); (1) large size legend plate, part number 10250Th181.

0 Item 4.14 - One (1) Square D. Type K, Class 9001, heavy-duty,oil-tight pushbutton station, to be panel mounted. The stationconsists of the following components:

o Item 4.14.1 - (1) illuminated green pushbutton operator (9001-KIL-IG); (4) normally open contact blocks (KA-2); (4) normallyclosed contact blocks (KA-3); (1) large size legend plate,, partnumber 9001-KN-299.

0 Item 4,14.2 - (1) red pushbutton operator (9001-KR-2R); (4)normally open contact blocks (KA-2); (4) normally closed contactblocks (KA-3); (1) large size legend plate, part number 9001-KN-299.

0 Item 4.15 - One (1) Square D, Type KS, Class 9001, heavy-duty,,oil-tight selector station, to be panel mounted. The stationconsists of the following components: (1) 3-position selectorswitch, Type KS, part number 9001-KS-52FB; (4) normally opencontact blocks (KA-2); (4) normaly closed contact blocks (KA-3);(1) large size legend plate, part number 9001-KN-299.

6.1.2 Cables

o Item 1.2, 2.2, 3.2, and 4.2 - Four (4) No. 14 AWG, 2-conductor,TVA Type PJJ Mark WHB cable, containing a stranded copperconductor (7 strands/O.024 inch), insulated by a polyethylene(0.020u thick)/polyvlnyl chloride (0.0O1 thick) layer. Theassembly is jacketed with a polyvinyl chloride (0.0450 thick)exterior jacket. The cable is manufactured by the Plastic Wireand Cable Corporation and is rated for 600 volts at 19 amperesmaximum, and has a maximum conductor temperature of 750C (400Cambient plus 350C heat rise). EF F C

DATE

WVYLE LADORATORIMNuntavlig Faciity

L64

0

~44

ACTUAL PHASE I HELB TEMPERATURE. ND PRESSURE PROFILES

sec

0 TIME i

FIGURE 1-9

r-- C*" d_ - j -!1

-Ae~ ft A~ TVA I D No:T~ype ms Cable

ILf~k Rev 2

I1:,l.nir~aC11Wrei an !lod!elUiLj _See Table 3.11-8A, S "heets 101Z and 1013, 1013AVeijfice'tfolnof Table Jnform;,tion (Table _3__U-B ieeSh 102 and 1013. 1o1lA

EquimentType- Th eq i,,nnt has bcen identifiecj as per TVA ID nunbeeions~ced. 0 ov, SCIV, etc.).

x i.oc at -1 -n The lIocation has been idrntified (F.G. , Inside Primairy- onJIi';v~iit, AnnUl us, IndivIduai ly Cooled Rowis, General Spaces, orwj area ~fec1ed by 117LB outside priniary contain;i-ec.rt).

> U).Cimpunct - A uniquo TVA ID nIunher has been assigned (e.g. , 1-MS-158-303).- Furi-i on A fu~nct ional drcsc-1 iption of the cm-,poji!_nt _has ber'- ie

L Con t-i Ct 11o , iinUfaCturerl-, an-d Model Ho. -The contract number,man c ~le ~iid modelI Iner has been givyen.

LU XAro o-,.-~dn Envi-ml....icnt - All Tn'm1Or accident einvi1ronirer 21tal(0t("ois cippIi cal?( -LO this, Sc iipment have bien i dcettii Fie,' either int ore by reftercnices, to fic~ures from tables.

X Elli Vonm to 1hc~~ ic -:,:2 envi ronmeint to -,:.hi ch the c-qui pwert-- ~iF~I~ q1TfJ s a c2 LIin either the taýýles or the environfmertal

analysis attached.Y a~c' A cateqmi'y of a, b, c, or d has been <teincd fcr t0-he equip;..ant.X Opraton and ACcuriacv Rroonired 1mrd Dc,_m.onstraltpd -The opDeration mid.

CC1Uy requi rec itrd, der.OuISI tceci 1iv en ~ e

kluajiifation Status~c~' if applicable, NA if not) Qualified Life 10teA - IRsUX ( QIa If~iCF1t io0n R-port and fictho - A q nal if icz;'Jor report and the riethod0"' qj;a iCati on hdb 1rCM I ýotfi ii

X Environmlental Analysis -An ornv'ronmen-tal anal 'vsis ha s b~cen done, attaclhedto tanh7id jl1nc;_ Jh: rttly revieied 1by the respanis ýi cleorqaInization.-- i iCitn iySiiiilar,'(If applica'De), - A j Lst ili cat'lon forq- ju al ii ti~onb S"IPFit is attach-j to the EOOM co1-nsit¾ringn all theabove fa6ctors aiv- rcferounce,: to the apiyvcyv-intc als

X j11q ificotfon el' 17cei-al Fxaýct Co;por,;-t (If Wplioi )-~hen an EOIS U[Cd fur, I1i3Ye Hii(!i one ilc:;iia istfaleat(O~~JLer r las an Oppcndi x with all recfcrences to Zr prrori a e ta~bl tls With julsti 4F ic:;Li C.,for' qt.al ifi cation co;;Sidcrirm~ aBl thc a~boVluf&oNA Ine wi CI ioi(fEj'1 at .(Oplen itn)-Compo-'PiL has been0~dt1i~ t.0 1§-2Y (jilfi- 'd oiyfor a limited in ieririP operationi, an NCIRhas been vir it"o.(", .::rid plin of zc.tion has 1bccl~ a -tori-,ned to yield aqualIif ied cp:o, t. Ter:cm o nter i m Qol- 1 fi ca.t ion

U Ji ncl1a i fjle 'ci C~p: 0 t eI-) (11- a rj) I c Cn:n~ponL ha s b e nIClec~ L ~ 0"! 1111 t .I(Ijýir n. 1i if i ed; t!IC fni 1m I )-,i is atltac!hed to FQS-I ~NCP nui , 1 reason 'c'r lc.r;ci jiý'.~nj iu:[if-icatju'i of contirnaJ2(ope ra nn.o

H~CR io

Prepared by: ___________ ______ EEB-CBL-16

Reviewd by:Appendix 1Reviewe by: 0' (/2S4/'/- Sheet I of 3Revision 2

MS CABLE FAMILY

The MS family of cables consists of flame-retardant, crosslinkedpolyethylene (XLPE) or flame-retardant ethylene propylene rubber (EPR)insulation with clilorosulfonated polyethylene (CSPE) or chlorinatedpolyethylene (CPE) jackets.* For purposes of environmental qualification,these cables are discussed below, grouped by manufacturer:

Anaconda-Continental (contracts 87232, 824447, and 827380)

These cables are EPR-insulated with CPE jackets. The qualification reportthat applies is Franklin Institute Research Laboratories test report No.F-C4836-3, "Qualification Tests of FR-EP/CPE Instrumentation Class 1EElectric Cables in a Simulated Steam-Line-Break and Loss-of-CoolantAccident Environment." As concluded in this test report, the cables arequalified for the following conditions:

a. Temperature: 385*F 1EFFECTjVEb. Pressure: 66 psig D Tc. Radiation: 2xi0 8 rads gamma D Td. Humidity: 100% OCT 'J4e. Chemical Spray: 6200 ppm boron, pH 8.6-10.0f. Qualified Life: 40 years

The above conditions envelope all areas of the plant in which the cablesare located and perform safety-related functions.

Samuel Moore and Company (contracts 821722, 824860, 825651, 825852, 825874,and 826598)

These cables are crosslinked polyolef in (XLPO, generically the same asXLPE) insulated with CSPE jackets. The qualification reports that applyare Isomedix (Component Testing Division) test report dated June 1978,"Qualification Test of Electric Cables Under a Simulated LOCA/DBE bySequential Exposure to Environments of Radiation, Thermal Aging, Steam andChemical-Spray," and Isomedix (Component Testing Division) test reportdated January 1980, "Qualification Test of Electric Cables Under Two MSLBSimulations By Sequential Exposure to Environments of Thermal Aging,Radiation, and Steam." As concluded in these, test reports, the cables arequalified for the following conditions:

*Except for the cable supplied on contract 85947, which is insulated withthermoplastic rubber and jacketed with polyether polyurethane.

Prepared by: 2!dA-04ýReviewed by:

EEB-CBL-16Appendix 1Sheet 2 of 3Revision 2

Temperature: 445*FPressure: 32 p83gRadiation: 2xl10 8 rads gammaHumidity: 100%Chemical Spray: 3000 ppm boron, pH 9.0-11.0Qualified Life: 40 years

The above conditions envelope all areas of the plant in which the cablesare located and perform safety-related functions.

Belden Corporation (contract 85259)

This cable is XLPE insulated with a CPE jacket. The qualification reportthat applies is Isomedix (Component Test Division) test report datedFebruary 1976, "Qualification Test of Electric Cables Under a SimulatedLOCA/DBE by Sequential Exposure to Environments of Radiation, Steam, andChemical-Spray." The test showed that the cable is qualified for thefollowing conditions:

a. Temperature: 346 Fq. Pressure: 113pgc. Radiation: 2x108 rads gammad. Humidity: 100%e. Chemical Spray: 3000 ppm boron, pH 9.0-11.0f. Qualified Life: 40 years

Although no thermal aging was performed on the cable samples prior to thetest, the XJPE was required via TVA's specification to meet certainphysical and electrical requirements for this type material. Since it metor exceeded those requirements, the material can be expected to performadequately in an accident qualification test after thermal aging, as othertests on XLPE insulation has proven. The above conditions envelope allareas of the plant in which the cables are located and perform safety-related functions.

Times Wire and Cable Company (contract 85947)

This cable is insulated with thermoplastic rubber and jacketed withpolyether polyurethane. The test report that applies is Times Hire andCable Companyse test report dated April 14, 1975, "Qualification TestReport for Class 1E Shielded Instrument Cable." The test results showedthat the cable is qualified for the following conditions:

Temperature: 300OFPressure: 25 psigRadiation: 2x108 rads gammaHumidity: 100%Chemical Spray: Boric acid in water, pH 8.5Qualified Life: 40 years

E F F ECT I V Er.0 A

- Ao-rd -r4cOal__ 12, a)wafu

Prepared by:

Reviewed by:g?2 A-0r EEB-CBL-16

Appendix 1Sheet 3 of 3Revision 2

The teste.i conditions envelope all areas of the plant in which the cablesare located and perform safety-related functions. Thermal aging was notperformed prior to the test. However, tensile and elongation measurementstaken on the insulation on other samples of the cable which were thermallyaged (121*C for 168 hours) showed that heataging has little or no effect onthe cable. Because of this fact, thermally aged cables can be expected toperform adequately in the event of an accident.

Rockbestos Company (contracts 823265 and 823577)

These cables are insulated with XLPO and jacketed with CSPE. The testreport that applies is the Rockbestos Company test report dated February 1,1977, "Qualification of FIREWALL III Class lE Electric Cables." Asconcluded in this test report, the cables are qualified for the followingconditions:

a. Temperature: 346 Fb. Pressure: 113 psigc. Radiation: 2x108 rads gammad. Humidity: 100%e. Chemical Spray: 3000 ppm, pH 9-11f. Qualified Life: 40 years (based on preaging at 150*C for 1300 hours)

The above conditions envelope all areas of the plant in which the cablesare located and perform safety-related functions.

DAT

tjF~ ,Ji it-

044278.03

Prepared by: al ~ 2,tC_-/'O 4qI EEB-CBL-17Appendix 1

Reviewed by: ~1L~Sheet 1 of IRevision 1

Special Cable (ETFE Family)

The ETFE family of cables consist of extruded ethylene tetrafluoroethylene(ETFE) fluoropolymer for the insulation material and an overall jacketmaterial composed of either ETFE or polyvinyl chloride (PVC). The specialcables used outside of containment at Watts Ear were furnished to TVA byAnaconda (contract 85838), Carolina Wire (826505), and Teledyne (825280).They are all insulated with TEFZEL, which is the E. I. Dupont Company'stradename for their ETFE fluoropolymer material. To fulfill the require-ments of each contract, the vendors proved by test that the TEFZELinsulation on the cables being supplied met or exceeded specific physicaland electrical requirements of MIL-W-22759/lb(AS). The tests showed thatregardless of the manufacturer, TEFZEL-insulated cables are genericallythe same and can be expected to perform similarly in an accidentenvironment.

TVA has approved test reports on file that demonstrate environmentalqualification for TEFZEL-insulated cables for the following conditions:

a. Temperature: 4500F(l)b. Pressure: 34 ps~il (1)c. Humidity: 100%1(Id. Radiation: 2xl0 8 rads gamma(2)e. Chemical Spray: 3000 ppm boron, pH 9.5-10.5(2)f. Aging to prove a qualified life of 40 years

The worst case accident conditions which the cables could experience intheir installed environments are as follows:

a. Temperature: 220OFEFF C Eb. Pressure: 30 psia D TEc. Humidity: 100%d. Radiation: 1xI08 radse. Chemical Spray: Not Applicable _______

Based on the above, we conclude that the TEFZEL-insulated cables arequalified for use in their service environments for 40 years plus at leasta year in their post-accident environments.

M1 Wyle Laboratories test report No. 46350-1, dated April 10, 1983,"Nuclear Environmental Qualification Test Program on Electrical Cablesfor Carolina Wire and Cable Company."

(2)Okonjite Company test report No. K-0-1, dated September 1, 1979,"Qualification of OKOZEL Insulated Wire and Cable for Nuclear PlantService."U

I Revision

Preparer/bate A9,k £,J / k1~ r _7A VýePyq,1e Metallic Conduit

InterfacEt'p etjnsion for~,ewevirAbate ,'-1I-AS Con ax Conduit Seal

WEN ýDUI~pI OLAFI=A'IN M=~' (M)S) Rev. 0

Manufacturer and Model.-No. Servicair Co. Series SS63Verification of Takble Information (Table 3.11-4. sheet 1001, 3.11-6. sheet) 1000, 3.11-7,

N/A : ý-sheet 1000N/AtT - The equipmient has been identified as per WVA ID number

Xdesignations (such as, WVI, WOY.-L~ation - The location has been identified (such as, inside primary

containment, annulus# individually cooled rooms, general spaces, or areaaffected by HELB outside prinary containment).

N/A QZientz - A unique WA ID number has been assigned (such as, l-FSV-68-308).x. flmckJ.n - A functional description of the omnponent has been given (such as,

steam generator blowdown).X Contract No.. Manufacturer, and Model No. - The contract num~ber, manufacturer,

and model number have been given.... Abnormal or Accident Enviroment - All abnormal or accident environmentalconditions applicable to this equipment have been identified either in tables orby references to figures from tables.X Bavironiment to Which Qualified - The environment to which the equipment has beenqualified is addressed in either the tables or the environmental analysisattached.

X Ca~.tSQM -Acategory ofa,, b,, c, or dhas been defined for the

Ope9riation and Accuracy Equired and Demornstrated - The operationand accuracy required and demonstrated have been defined.

*usLWifcation Status (check if applicable. NA. if not)Q~aalifiejd L~ife (If equipment is qualified,, indicate the qualified life with anumerical entry): -40 years

X Oualification-Report And Method - A qualification report and the method ofqualification has been identified on the Table Input Data Sheet (TIDS).N/A Zoim .anl~f - An environmental analysis has been done, attached tothe EDS, and independently reviewed by the responsible organization.

N/A Oualification by Similarity (if applicable) - A justification for qualificationby similarity is attached to the EDS considering all the above factors andNAreferenced to the appropriate tables.N/Qualification of Several Exact Conanents (If applicable) - When an EDS is used

for more than one item, a list of all exact comiponents is given as an appendixwith all references to appropriate tables with justification for qualification

N/A c ons idering all the above factors.- heriin Oualificatiori (If applicable) - (Open item) - Component has been

determined to be qualified only for a limited interim operation, an NCR hasbeen written, and plan of action has been determined to yield a qualifiedcqenent.Term of Interim Qualification ______________________

NA tNM No.fie Coynponen - (Cpen item) - (If applicable) - Canponent has beendetermined to be unqualified; the following is attached to EDS: NCR number#reason for non-qualification, and justification of continued operation.

Prepared by: U)~ R EB-CON-1VAppendix 1 Rev. 0

Reviewed by: Sheet 1 of 1

Stainles~s Steel Flexible Metallic ConduitServi-Fl~ex (SS63 Series) Type Flexible Conduit Manufactured by Servicair

This stainless steel flexible conduit is used to interface a Class 1EConax Conduit Seal connector vith certain Class 1E ASCO solenoids locatedin harsh environments and subject to a DBA. This Conax connector isnecessary because ASCO solenoid seismic considerations will not allowdirect connection of a Conax connector to a Class lE ASCO solenoid.

This Servicair Co. Series SS63 flexible metallic conduit has a convolutedtubing structure with 300 series corrosion resistant stainless steel (CRES)inner core and with 300 series overbraid. Coupling material is also 300series CRES.

The Servicair Co. Series SS63 flexible conduit and associated couplingshave been qualified in accordance with IEEE 323-1974 for a DBE withtemperatures to 3400F, radiation to lxlOll rads, and relative humidity of100 percent. The 300 series CUBS exhibited no corrosion or degradation forthe tested environment. This Servicair Co. Series SS63 flexible conduithas also been demonstrated, by test, to be capable of withstanding anexternal helium pressure of 250 psig (pressure differential of 242.5 psiabsolute) with no leakage.

The applicable test report and analysis are listed below:

Wyle Laboratories Report No. NES 26303 dated August 18, 1978,"Qualification Report for Series SS63 Flexible Conduit andAssociated Couplings and Support Devices for Servicair Company"

Servicair's Simulated LOCA Pressure Report dated March 4, 1976.

The tests and analyses demonstrated that the Servicair Series SS63 flexibleconduit and couplings will adequately prevent intrusion of moisture intothe Class 1E ASCO solenoids between the Conax connector and the ASCOsolenoid in the worst case WBNP environment of 3270F, 100% relativehumidity, 28 psia, and Ux10 8 rads. This flexible conduit is also notaffected by chemical spray.

034284.04

DAT

rcler"LA 9-1 7 AoeaýVý Isqi!ýNq

-914 962:

*06..Y.E SCRIENTFCSRIE &SS RUREPORT NO. _NES 26303

OUR JOBNO. NES 26303

CONTRACT

YOUR P.O.NO. .15773-1

Servicair Company1841 Flower StreetGlendale, CA 91201

35 - PAGE REPORT

DATE 18 August 1978

QUALIICATION REPORT

.FOR

SERIES SS63 FLEXIBLE CONDUIT

AND

ASSOCIATED COUPLINGS AND SUPPORT DEVICES

FOR

SERVICAIR COMPANY

CEDAJ

STATE OF CALIFORNIACOUNTY OF RIVERSIDE

RaY M. MYrick being duly swam.,deposes and says: That -the information contained in th-is report Is the result ofcomplete and caefully conducted tests and is to thesbeat of his knowledge trueand correct in all to ta.

SIjKSR~,DED andsworn o beforemet..his18 day of August 1,78

Pu li I a rthe C ounty tside , State of California

- nvir,. i Xll9 insiv' L-)"

I.

DEPARTMENT Nuclear Engineering Services

DEPT. MaR. 9i~, £1~ .-

D.- Marsh

TES WInWESS

QUALITY CNRL.Housteau

Appendix 2Rev. 0Sheet 1 of 409'e'j1-e'z0j 6ý 1.

DEyr.mGR. ý;PAýhmroderick

TEST ENGINEER -ýýMrt AAý-,

WML LABORATOWESCIENTIFIC SERVICE AND SYSTEMS GROUP

ADDITIONAL.J'EAK*TRANSIENT

Appendix 2Rev. 0Sheet 2 of 4

OUAUiPICATION PLAN NES 26303

PAGIE NO. 19

TRANSIENT DURING AND FOLLOWdINGA DESIGN BASIS EVENT

320

300

280 -

I-250

200

Sum Shi~sTIME-~

Spray Exposure. Continuously spray vertically downward for first 24 hours with a solution of thefollowing composition at a rate of 0.15 (gallWin)Ift2 (6.1 (mllmin)/M 2 ) of area of the test chamberprojected on to a horizontal plane.

0.064 molar Na2 S2 0 3EF r T VE

NaOH to make a pH of 10.5 at 77rF (about 0.59 percent)* Dissolve chemicals, on a one-liter basis, in the following order: I(1) 600 ml potable water _ _ _ 7

(ni) H3 B03 L-(III) NaOH-(iv) Na12 S2 03(v) Add remainder of water to volume of one liter(vi) Add N&OH to nake a pH of 10.5 at 7 7 F, as required for the Initial spray solution..

If I it Is not practical to reproduce the specified pressure and temperature profiles combined, It Isacceptable during the first four days to follow the temperature profile and allow the pressure to

conform to saturated conditions (100 percent relative humidity). This procedure is justified by thefact that ternperature is the more important parameter and increasing the pressure, (to maintainsaturated conditions) will increase the severity of the test, if anything.-

* ~Spray Exposure. Continuously sryvertically downward with demineralized water at a rate of0.15(galmin)ft 2 6.1 ml /in)1m) of area of the test chamber projected onto a horizontal plane.

-. -_________ igure 7 __

Test Chamber Temperature Profile for Environment Simulation (Combined PW4B WEt)

Appendix 2Rev. 0Sheet 3 of 4

*

,L**- !-.* .I3T~rL*.-' o.i Wi. Frederick

E F FE C T V ED ATE

OQT .'33-;%41;'

*SERVICAIR C:o.!641 rt CWCU GT*9h? CLINC&OLg C.L11 .- too

Knobby Arnold

.cx PE4 F;'A T . 0

REUj 4.iT !6'::

SS63-08

To simulate L.CA pressure buildup to 59.5 Lbs. (PSI)in 20 secondsfrom STP conditions (14.7 Lbs/ eq. ineh)interna2. pressure in conduit.,After reaching 59.5 PSI external condition with internal being monitoredfor signs of rupture or conduit break, :or cracking by sudden rise ininternal pr~essure, allow to stabilize and increase external pressuretp 240 PSI. Read internal pressure and record failure pressure, if it

.-. ccurs.._Rcr wit -comment -as a ~ra nate.

Specimen_.cqnsists of SS63-08 etainlese conduit of 316 CRES core andbraided with 302 CRES wire of .0I0 diameter, 90 76 optical cov-erage.

Internal Px. Outside Px Time after COWNT5

O - ~~0 0 f - i~~

If 5 Sec

/11 lSee

I r4 5 Is see _ __

v I__ _ 305c See_

ft / Z>' 40 Scc

_____ ~ 6 6See _____/4+

IL, ,

lullCI I lul

SFC 3002 3-74

70 ~eo70 Sao _______

op.', ~so Sec ____

iA6C 0NP L E

9 Sec4

lOOaSec _____now or T E S T 44

VA-ds-iT)

*-----y.-- T 1 0. N___- 0

*Ae xe .A s oye* %

March 4, 1976DATE ___

STAMP__Y/1

i

. I ----11hi- -- -

Appendix 2Rev. 0Sheet 4 of 4

.E F F. ,V ED ATI"

CTC " 1' 8'3 4

9.-

I,

Prepared by: >.~2~22~ /c,3S /EBT-Appendix 1 _ ..

Reviewed by: /.0- a.f-2( Sheet 1 of 3 i'Revision 3<1

-Terminal Blocks W

uLJ

The terminal blocks are of the following types: General Electric Companytypes EB-5, EB-25, and CR-151B. They are comprised of single piece molded,phenolic material with washer head binding screws for circuit wireconnections and rated for 30 amps and 600 volts (7500V breakdown voltage).All terminal blocks are mounted in gasketed enclosures that provideadditional isolation from other adverse conditions of the surroundingenvironment. In addition, terminal blocks located inside containment, thenorth and south steam valve rooms, the turbine driven auxiliary feedwaterroom,-the RBR heat exchanger rooms, and the ERR pump rooms have been coatedwith Dow Corning RTV coating to protect them from moisture and corrosion.The enclosures for the terminal blocks in these areas have holes drilled inthem to allow moisture to drain and to prevent the enclosures fromcollapsing in the event of increased pressure during an accident.

The blocks are composed of cellulose-filled phenolic material."l) Forpurposes of conservatism, all these blocks are assumed to be composed ofpaperfilled phenolic material whý'cý is the least radiation resistant typeof wood poduct filled phenolicsý ~ . This material retains at least 50percentffl of its physical properties (elongations, tensile strength,etc.) at gamma radiation doses of Ix108 rads. In addition, a sample of anEB-5 terminal block passed a LOCA qualification test performed by theLimitorque Corporation after a gamma radiation exposure of 204 megarads.(7)

Samples of uncoated CR-151B terminal blocks have passed an environmentalqualification test performed by Wyle Laboratories(3) in the sequenceindicated below:

a. Radiation aging to 2.75x105 rada gamma at a maximum dose rate of1.0x104 rads per hour to simulate a 10-year life.

b. Thermal aging at 110 0C for 1000 hours to simulate a 445-year life.(6)

c. Seismic qualification.

d. Accident qualification at the following conditions: 2400F, 16.4 Pasi,100 percent relative humidity.

Also referenced in the Wyle report was the failure of uncoated CR-151B and10987 terminal blocks at the following conditions:

a. Radiation aging to I .lx106 rads gamma at a maximum dose rate of 1 .0xI04

reds per hour to simulate a 40-year life.

b. Thermal aging at 110 0C for 4000 hours to simulate a 1,780-year lifej6)

EF F ECT WVE EEB-TB-1

I D T ERevision 3c. Seiimic qualification.

d. Accident qualification testing at the following conditions: 3300F,26.8 psia, 100 percent relative humidity.

The failure mode of the blocks was terminal to terminal or terminal to groundbreakdown. This occurrence was caused by extreme corrosion buildup on theterminals during the aging process, which created a conductive path f or shortcircuits when contact with moisture (steam) occurred during the test. Weattribute the buildup of corrosion on the terminals to thermal aging, sincegamma radiation has no effect on metallic materials.

Tests performed by Wyle(4) in September 1982 demonstrated that unaged (anduncorroded) specimens of the EB-25 blocks were capable of passing a similarprofile to the one that the 40-year blocks failed. Since the 445-yearthermally aged specimens, which passed the less extreme profile, exhibitedonly a mild discoloration and not the extreme corrosion seen on the 17 80-year thermally aged blocks, we conclude that the failure mechanism will notbe on the equipment at all during their required 40-year service life, andthey are capable of passing the higher profile.

Also, coated CR-151B terminal bl 9cks have passed an environmental qualification testperformed by Wyle Laboratories(s) in the sequence indicated below:

a. Radiation aging to 5.5xl105 rads gamma at a maximum dose rate of 1.0x104 rads perhour to simulate a 20-year life.

b. Thermal aging at 1100C for 2,000 hours to simulate an 890-year life.(6)

c. Accident qualification testing at the following conditions: 3420F, 29 psia, 100percent relative humidity, and a chemical spray of 2,000 ppm boron.

Based on the above, we conclude that the terminal blocks are qualified forat least 10 years and, as a minimum, for the following accident conditions: 3420F,29 psi:, ixiO8 rads, 100 percent relative humidity, and chemical spray.

(l)Letter dated February 24, 1978, from General Electric Company toD. A. Ross, Jersey Central Power and Light Company.

(2)Radiation data from the Battelle Memorial Institute Radiation EffectsInformation Center Report No. 21, dated September 1, 1961, "The Effectof Nuclear Radiation on Elastomeric and Plastic Components andMaterials," by R. W. King, N. J. Broadway, and S. Palinchak.

(3)Wyle Laboratories Test Report No. 17503-1, dated January 6, 1984,"Nuclear Environmental Qualification Test Program on Sequoyah NuclearPower Station Control Equipment and Cables."1

(4)Wyle Laboratories Test Report No. 17508-1, dated November 22, 1982,"High Energy Line Break (HELB) Test Program on Two (2) Controlh Equipment/Cable Assembly Test Sets."

EEB-TB-1Appendix 1Sheet 3 of 3Revision 3

(5)Wyle Laboratories Test Report No. 17523-l, dated June 20, 1984, "NuclearEnvironmental Qualification Teat Program on Sealants for Class IEDevices and GE Terminal Blocks."

W6 TVA Design Calculation dated Nay 21, 1984 (EEB 840522 921).

(7)Limitorque Corporation Test Report No. B0119, dated July 1, 1982,"Qualification Type Test Report of Multi-Point Terminal Strips for Usein Limitorque Valve Actuators for PWR Service."

Sheet

10001000100010001000, 1001, 1002, 1003, 1004, 1005, 1006, 1007,

1008, 1009, 1010, 1011, 1012, 1013

rE-F IFF T I

*Table

3.11-43.11-53.11-63.11-73.11-8

034122.*02

Prepared by: LI ./ EUB-IS-i

Reviewd by:Appendix 1Reviewe by: ______ A____!2___46&V__ Revision 2

Sheet 1 of 4

Electroikvitch Corporation - Series 24 Instrumentation and Control Switch -Table 3.11-6, Sheet WBN-EEB-1009

1.0 The following documents are referenced:

a. Electrosvitch report No. 2392-2, dated November 6, 1980, "Quali-fication Inspection of Series 24 Instrument and Control Switchesto ESC-STD-1000, Rev. 1." (See Appendix 2)

b. Electrouwitch Technical Publication ESC-STh-l000, Rev. 1 datedFebruary 15, 1978, "General Specifications for Rotary Switchesand Auxiliary Relays f or Utility Applications." (See Appendix 3)

c. Electroawitch Technical Publication 24-1, dated April 1, 1983,"Series 24 Instrument and Control Switches for Power Industry andHeavy Duty Industrial Applications." (See Appendix 4)

d. Watts Bar Nuclear Plant drawings 47E235-62 RO, 475E235-64 11,471235-65 RI, "Environimental Data - Harsh Environment." R

2.0 The Electroiwitch Series 24 selector switch covered herein is aheavy duty, rotary, manually-operated selector switch rated 600V ac,20 amperes, and has 2 maintained positions with a total of 36 contactson 10 decks. The part number of the switch is 24909B-2 and the pistolgrip handle has a part No. 02000-12. The switches are not equippedwith lockout contact relays.

3.0 The switches are installed at columns A2U and A14U, Room Al, elevation692' in the Auxiliary Building. Environmental conditions fordifferent occurrences were obtained from the drawings in reference1.Od above and are as follows:

A. Normal

Parameter Max Min Averaste

Temperature (*F) 104 60 80Relative Humidity (M 80 30 5.5Pressure 'ATM(-)* (ATM(-)* (ATM(-)*

*Slightly negative with respect to atmospheric pressure which is14.4 PSIA..Radiation (Rads) 54102 N/A N/A

IE F .E: C. T V ED ATE

-- EEB-XS-li ~" V E Appendixi1

~AT3 Revision 2DAY E Sheet 2 of4

B. Abnormal

These values occur for up to 8 hours per excursion for less than1% of plant life. The maximum and minimum values could occur as aresult of outside temperature excursions, temporarily greater thandesign heat loads or a degraded environmental control system.

Parameter max Mmi

Temperature OF) 110 90Relative Humidity WZ 90 10

C. Loss of Coolant Accident. (LOCA)Iliuih EnergyV Line Break (HELB)-Break Inside Containment

Parameter maxRadiation (Rads) Less than- 1Iz04

Per note 11 on drawing 47E235-62R0 in reference 1.0d. a value oflx104 rads vill be used for qualification purposes.

D. High Eneray Line Break (HELB) - break Outside Containment-

Temperature (*F) - The maximum temperature profiles are given inFigures 1 and 2 (See Appendix 5). These curves R2vere obtained from drawings 47E2.35-64&1 and47E235-6531 in reference 1.0d. I

Humidity M% - The maximum relative humidity profile is given inFigure 3 (See Appendix 5) and was obtained fromdrawing 47323 5-62R0 in reference 1 .0d.

3. Tornado

Pressure - The tornado depressurization curve is given in Figure 4(See Appendix 5) and was obtained from drawin47323546210 in reference 1.0d.

4.0 The basis for qualification of the switches for the extremes ofenviroinental parameters provided in slection 3.0 is given below.

A. Radiation - Per the general specifications for the switchesprovided in reference l.Ob and the qualification report inreference 1.0a, the equipment has been tested after exposureto IxIO4 rads and passed the functional requirements.

B. Relative Humidity - Per reference 1.0a, the equipment passed therequired functional testing after exposure to 90-95% relativehumidity for 96 hours at a temperature of 40*C. Furthermore, theswitches are housed in EMEA 4 enclosures by TVA for protectionagainst impingement of water.

E~I~A~VEEB-XS-lRevision 2

Sheet 3 of 4

~Figure 3 indicates an exposure to 100% relative humidity for 24hours. The combination of the NEMA 4 enclosure together with theprevious testing after exposure to 90-95Z relative humidity shouldprovide adequate proof of the design to withstand thisenvironment.

C. Pressure - The switches will be operated at about atmosphericpressure except during a tornado when they may be subjected to a 3PSI depressurization per Figure 4. Electroawitch Series 24switches are modular in design and consist of severalsubassemblies or decks of contacts contained within a phenolicmolding. There are no glass components which can crack. Also,all operating surfaces are exposed to the san atmosphericpressure so no differential pressure can result causingmisoperation.

D. Temperature - The following summarizes the temperature extremesto which the switches will be exposed:

Maximum normal temperature - 104*FMaximum abnormal temperature - 110*F

(eight hours per excursion for less than -

1% of plant life)HELB maximum temperature - 142*F decreasing to 1722F in 2.66

minutes per Figure 1

It can be seen from the above temperature ranges that although the 1environment that the switches are in is conscidered harsh, thetemperatures resulting from HIELB are not extreme.

Per reference 1.0b, the switches are rated for continuous duty at550C (1310F).

The switches were aged for 120 hours at 80'C (176*F) and performedsatisfactorily after testing per reference 2.0Ua.

E. Endurance

Per reference 1.0a, the switches performed properly after 10,000operations. Since the switches are for manual operation relatingto the auxiliary feedwater system, the testing after 10,000 cyclesis more than adequate.

5.0 Based on section 4.0 above, the switches are considered qualified forradiation, relative humidity, pressure, and endurance for the 40-yearlife expectancy of the plant.

EEB-XS-1Appendix IRevision Z.Sheet 4 of 4

Regarding the temperature data, it is concluded that the extremes oftemperature environment to which the switch wili be exposed are veillwithin the normal operating range of the switch. Therefore, withrespect to temperature, the switches can be treated as if they were ina mild environment. Furthermore, the switches performed satisfac-torily after exposure to 80*C for 120 hours. Therefore, concerningtemperature, the switches are also considered qualified for the40-year life expectance of the plant.

034122.03

Preparer/Date __,

Reviewer/Date Z .9EQS No. WBNEEB=UM=2-Appendix 2 Rev 1Sheet 1 of .3

1. The rad4iation monitor detector assemblies in Appendix 1 are GeneralAtomitmjodel RD-23. They are located in the Reactor Building (insidecontainment, upper compartment; el.805'-8", and lower compartment;el. 729L6". They are required to operate for 100 days after the start ofa LOCA/MSLB inside containment, per EN DES Calculation NEB 830207 227.

2. The assemblies are subject to LOCA/HELB conditions. They arerequired to operate in the following environments1 :

Normal Accident

Temperature:

Pressure:Relative Humidity:Radiation:

Spray/Flooding:

110OF

14.7 psia80%2 x 107 rads(40 year TID)NIA

160OF (Upper3270F (Lower26. 4psia100%1 x 108 rads

compartment)compartment)

Spray

3. The manufacturer has tested the radiation monitor detector assembliesincluding connector/cable interface to the following:

Temperature:Pressure:Relative Humidity:Radiation:

3550 F91.4 psia100%NA (detector assembly has only inorganic

components)

4. Qualification Testing

a. General Atomic Company has tested these assemblies to therequirements of IEEE 323-1974, IEEE 344-1975 and NUREG-0588.The test criteria and results are documented in General AtomicCompany's Test Report E-254-960, Revision 1. All qualificationtests were performed at test levels in excess of known mA-*muenvironmental requirements. These margins are in accordance withthe margins suggested in IEEE 323-1974.

b. The RD-23 detector has only inorganic components which are notsusceptible to degradation due to thermal or radiation aging. Nothermal aging or radiation exposure testing was performed.

c. The detectors are located inside containment where they are subjectto a chemical spray. A chemical solution of 3000 ppm boron asboric acid in solution with 0.064 molar sodium thiosulfate buffered

'See SQN/WBN Environmental Data Drawing 47E235-44.

I F

r ý7 '~

EQS No. WBNEEB-gm-Appendix 2Sheet 2 of 3

vii sodium hydroxide to a pH value of 10.5 at 770F was sprayed onthe sample. The chemical spray solution pH was maintained between10 and 11.

The chemical composition of the Watts Bar containment spray is:

0.1847 molar H3B03 (2000 ppm boron)0.033 molar Na OH, resulting in a pH of 8.2

Since the chemical concentration of containment spray is less thanthe test concentration, the detectors should not be affected.

d. LOCA simulation consisted of three separate tests as specified inGeneral Atomic's LOCA test procedure 0360-2082. (See Appendix 3 fortemperature/pressure profiles).

5. The General Atomic test results demonstrated a qualification for thesedetectors' use in a diverse variety of specific installations.Forty-year qualification was demonstrated when normal equipmentmaintenance is performed as required. In our engineering judgment, themanufacturer's LOCA test profiles (Appendix 3) more than satisfy therequirements of the actual MSLB/LOCA profile (Figure 1).

6. The above information shows that the detectors are fully qualified perIEEE 323-1974, IEEE 344-1975, and NUREG-0588 for required operation inthese harsh requirements. A qualified life of 40 years wasdemonstrated.

063138.06

E FF EC T IV'EE

EQS No. WBNEEB -RM-2

Appendix 2

Sheet 3 of 3

CONTAINMENT TEM4PERA~TURE, DOLIBLE ENDED PUMP SUCTION BREAK (LbCA)140ST SEVERE STEAMLINE BREAK (HELBI COMBINED

615-

0 1 1 1 ,1 I:i 1 1 1 11111 i i I I 1 1 !1, ! I I 1110 I

5 sea a 5 ISoo a Tile 5 191leato3

Figure 1

E ~ ~ ~ A

I Revision P1Preparer/bate# 9

Revieweribate

NiN FDUIPEH= OIAFICA~TION ir is

Manufacturer and Model No. AC Power Distribution - El-Tex md.. Inc.

Verification-of*Table Information (Table 3.11-6 Sheet 1014

Y.... AWuimwt LU - The equipment has been identified as per TVA ID numberdesignations (such as, NOVJ, SOV).

X LIA~imf - The location has been identified (such as,, inside primarycontainments, annuluss, individually cooled roculs general spaces, or area

-affected by HELB outside primary containmtent).X Cm et- A unique WVA MD number has been assigned (such as, l-FSV-68-308).x Eltion - A functional description of the component has been given (such as,

steam generator blawbu).XL Contract No.. Manufacturer. and Mokdel No. - The contract numrbers, manufacturers,

and model number have been given.X Abnormal or Accident Environment - All abnormal or accident environmental

conditions applicable to this equipuent have been identified either in tables orby references to figures f roml tables.

X Environment to Which QUAlified - The environment to which the equipment has beenqualified is addressed in either the tables or the environmental analysisattached.

-X Categy - Acategory ofas, b. c. or dhas been defined for theequipment.

_Lj. goeration and Accuracy Reqired and Demonstrated - The operationand accuracy required and demonstrated have been defined.

Oualification Status (check if Mplicable. NA if not)Qual.if~iedLife (If equipment is qualifieds, indicate the qualified life with anumerical entry): .aet-Apendix 1

NA OUaliication &Reprt and Met1~ - A qualification report and the method ofqualification has been identified on the Table Input Data Sheet (TIDS).

_1 Enwironmental Analysis - An environmental analysis has been done, attached tothe EDS, and independently reviewed by the responsible organization.

-.& Caification by Similarity (If applicable) - A justification for qualificationby similarity is attached to the EDS considering all the above factors andreferenced to the appropriate tables.

NA Qualification of Several Exact ConIMneta (if applicable) - When an EDS is usedfor more than one items, a list of all exact components is given as an appendixwith all references to appropriate tables with justification for qualificationconsidering all the above factors.

NA Interim qualifiCAtion (If applicable) - (Open item) - C=%p~nent has beendetermined to be qualified only for a limited interim operations, an NCR hasbeen writtens, and plan of action has been determined to yield a qualified

Term of Interim Qualification_____________________

_LA alfe op~ - (Open item) - (If applicable) - CUrponent has beendetermined to be unqualified; the followiing is attached to -'12 vniMdbrreason for non-qualifications, and justification of cooti M T- CT IV E

NMonNo.u 1 .DATE.O 0C)TT 1084

I R I

unlit 140 i ana z~

MS No. EE.BD-242MIDA No.

See Appendix I

.W.-MONSWUNIMM-S

Prepared by:

Reviewed by:~~9-~ . Xdet"9 fc!A r1 -eP-c?

EEB-BD-242Appendix 1, Rev. 1Sheet 1 of 2

APPLICABLE TO PANELS

1 -BD-242-12-BD-242-1

PANELS

The AC power distribution panels have been qualified to 1L seismicrequirements for a 40-year life by El-Tex Ind., Inc.. as documented by aCertificate of Conformance. (See TVA memo from J. L. Parris toF. W. Chandler dated July 13, 1976.)

Environmental qualification was not a requirement imposed on themanufacturer and no qualification tests were performed on the panels. Theonly panel components whose failure could affect associated cabling are thecircuit breakers. Our analysis, which follows, indicates that failure ofthe circuit breakers due to the environment is very unlikely, and if afailure does occur it will not compromise the integrity of the associatedcabling.

The safety function of the circuit breaker is to remove the fault from acable before the cable can catch on fire and jeopardize a safety-relatedcable. Whether the breaker trips and thus interrupts the fault or faultsitself internally and thus moves the fault back from the cable does notmatter. The thermal-magnetic circuit breaker always acts to protect thecircuit under both high and low ambient environments.

Molded case circuit breakers are composed of five main components: moldedcase (frame), operating mechanism, arc extinguishers and contacts, tripelements and terminal connectors. The phenolic molded case encloses theoperating mechanism, arc extinguishers, contacts and trip elements andminimizes exposure to dirt, dust, and moisture. The operating mechanism isa metallic apparatus which is the means for opening and closing thebreaker. The mechanism is spring-loaded which causes the contacts to snapopen (or closed) when the breaker is tripped or manually operated. Thetrip elements serve to unlatch or "trip" the operating mechanism onoccurrence of a prolonged overload or a short circuit. Molded casebreakers are constructed so that the contacts cannot be held closed againsta fault condition ("trip-free operation").

On a breaker equipped with electro-mechanical-. type trip elements, overloadprotection is achieved by the use of a bimetal strip which bends ordeflects when heated by excessive load current, physically causingunlatching of the operating mechanism. Elevated ambient temperaturedecreases the response time. Excessively high ambient temperature cancause degradation of internal insulating materials and affect breakercalibration. However, the design basis accident temperature is on theorder of 150*F, which is well below this threshold. E FFEC~TI~VE

D A T 'E

Prepared by: k2&.&A S' A4-Le.-, 10-f-YY EEB-BD-242

Revewe by: - Appendix 1, Rev. 1/0- rr Sheet 2 of2

Protection against short-circuit current is achieved through the use of anelectro-magnet in series vith the load current. When a short circuitoccurs the~ fault current passing through the breaker causes the magnet toattract the armature which in turn mechanically unlatches the operatingmechanism causing instant opening of the contacts. The magnetic tripelement is set to operate at a current level much lower than that whichwould cause cable damage in the short time before the breaker interrupts.The magnetic trip element is calibrated by varying the size of the air gapwhich proportionally varies the magnetic trip current rating.

The essential components of the tripping mechanism are metallic and thusnonthermally aging. Elevated temperature will not degrade operation of themagnetic trip element as it is sensitive only to fault current.

The phenolic molded case "enclosure" minimizes the effect humidity has onthe internal working parts of the breaker. Elevated levels of ambienthumidity will have very little effect on the breaker when it is carryingload current because the temperature of the air surrounding the breakerwill be higher than the room temperature and the surrounding air will beappreciably dryer than the room air. Even if moisture did condense,magnetic properties are not sensitive to moisture. If severe condensationoccurred, it could cause a phase-to-phase fault and thus trip the mainsource breaker which is located in a mild environment, and even if thesource breaker failed to trip, the fault would be moved away from theI cable. It is extremely unlikely that moisture could cause conductionthrough the open contact and not cause a phase-to-phase or phase-to-groundfault, but if this did occur the arc would instantly evaporate themoisture. Also, the breaker contains no hygroscopic material which wouldbe adversely affected by high humidity.

The radiation effect on the circuit breakers, which is less than IxI04

rads, is considered negligible since there are no known nonmetallicinsulating materials adversely affected by this radiation level. See EPRIReport NP-1558 "Review of Equipment Aging Theory and Technology," Project890-1, Final Report, Figure 7-18.

The breakers do not have voids or areas sealed by diaphragms and are notsusceptible to negative atmospheric pressure.

Therefore, the breakers in panels I-BD-242-1 and 2-BD-242-1 will "failsafe" when exposed to the environmental conditions listed on TVA drawing47E235-46. Absence of effective aging mechanisms assures this capabilityfor the life of the plant.

034270.01

Prepared by: l/ &EEB-BD-1

Appendix 1, Rev. 1Reviewed by: w(0//4 g Sheet 1 of 2

LIGHTING BOARD

(mROW HART)

The lighting board is non-Class IS because it is not required to operateduring a design basis event, but is considered to be associate equipmentbecause the feeder power cables from the lighting board are routed suchthat they share the same raceway with Class IS circuits. Thus failure ofthe lighting board's circuit breakers, protecting these power cables, totrip for a fault could cause damage to a Class IE cable and thus preventClass lB equipment from performing their accident mitigation function.Therefore, to enviroamentally qualify this lighting board it is onlynecessary to address the tripping capability of the molded-case circuitbreakers in the stipulated environmental conditions.

This Auxiliary Building Lighting Board is located in general space onelevation 737 of the Auxiliary Building. The worst-case environmentalconditions are as follows:

Temperature: 127*F after 650 secHumidity: 100%Pressure: drop from 14.3 to 12.3 in 3 sec

2 sec at low pressure and a riseto normal 14.3 in 3 sec

Radiation: <1 x 14rads

The safety function of the circuit breaker is to remove the fault from acable before the cable can catch on fire and jeopardize a safety-relatedcable. Whether the breaker trips and thus interrupts the fault or faultsitself internally and thus moves the fault back from the cable does notmatter. The thermal-magnetic circuit breaker always acts to protect thecircuit under both high and low ambient environments.

Molded-case circuit breakers are composed of five main components: moldedcase (frame), operating mechanism, arc extinguishers and contacts, tripelements and terminal connectors. The phenolic molded case encloses theoperating mechanism, arc extinguishers, contacts and trip elements andminimizes exposure to dirt, dust, and moisture. The operating mechanism isa met 'allic apparatus which is the means for opening and closing thebreaker. The mechanism is spring-loaded which causes the contacts to snapopen (or closed) when the breaker is tripped or manually operated. Thetrip elements serve to unlatch or "trip" the-operating mechanism onoccurrence of a prolonged overload or a short circuit. Molded casebreakers are constructed so that the contacts cannot be held closed againsta fault condition ("trip-free operation").

Prepared by: L0 * V 414- 101ZJ' EEB-BD-1

0 1ý/Appendix 1, Rev. 1Reviewed by: ' ,(/?tt. - Wib-Id. Sheet 2 of 2

On a breaker equipped with electro-mechanical type trip elements, overloadproteotion is achieved by the use of a bimetal strip which bends ordeflects vhen heated by excessive load current, physically causingunlatching of the operating mechanism. Elevated ambient temperaturedecreases the response time. Excessively high ambient temperature cancause degradation of internal insulating materials and affect breakercalibration. However, the design basis accident temperature is well belowthis threshold.

Protection against short-circuit current is achieved through the use of anelectro-magnet in series with the load current. When a short circuitoccurs the fault current passing through the breaker causes the magnet toattract the armature which in turn mechanically unlatches the operatingmechanism causing instant opening of the contacts. The magnetic tripelement is set to operate at a current level much lower than that whichwould cause cable damage in the short time before the breaker interrupts.The magnetic trip element is calibrated by varying the size of the air gapwhich proportionally varies the magnetic trip current rating.

The essential components of the tripping mechanism are metallic and thusnonthermally aging. Elevated temperature will not degrade operation of themagnetic trip element as it is sensitive only to fault current.

The phenolic molded case "enclosure" minimizes the effect humidity has onthe internal working parts of the breaker. Elevated levels of ambienthumidity will have very little effect on the breaker when it is carryingload current because the temperature of the air surrounding the breakerwill be higher than the room temperature and the surrounding air will beappreciably dryer than the room air. Even if moisture did condense,magnetic properties are not sensitive to moisture. If severe condensationoccurred, it could cause a phase-to-phase fault and thus trip the mainsource breaker which is located in a mild environment, and even if thesource breaker failed to trip, the fault would be moved away from thecable. It is extremely unlikely that moisture could cause conductionthrough the open contact and not cause a phase-to-phase or phase-to-groundfault, but if this did occur the arc would instantly evaporate themoisture. Also, the breaker contains no hygroscopic material which wouldbe adversely affected by high humidity.

It has been shown during actual test on motor control centers forHartsville Nuclear Plant that a sudden change of pressure of 3 PSLA had noaffect on molded-case circuit breakers. Radiation levels of 1 x 104 radsare considered negligible. Reference EPRI 9P-1558, Project 890-1, FinalReport, Figure 7-18.

From the above, it is concluded that these lighting boards are qualified toperform their only safety-related function in the worst-case environmentalconditions resulting from an accident. Absence of effective agingmechanisms assures this capability for the life of the plant., E FH\P044279.12-

Prepared by: L A V w- 11E ,4 EB-BD--2

Reviewd by:Appendix 1, Rev. 1Reviewedftde by _____________________ Sheet 1 of 2

LIGHTING BOARD

(ARROW HART)

The lighting board is non-Class 1E because it is not required to operateduring a design basis event, but is considered to be associate equipmentbecause the feeder power cables from the lighting board are routed suchthat they share the same raceway with Class lE circuits. Thus failure ofthe lighting board's circuit breakers, protecting these power cables, totrip for a fault could cause damage to a Class 1E cable and thus preventClass 1E equipment from performing their accident mitigation function.Therefore, to environmentally qualify this lighting board it is onlynecessary to address the tripping capability of the molded-case circuitbreakers in the stipulated environmental conditions.

This Auxiliary Building Lighting Board is located in general space onelevation 737 of the Auxiliary Building. The worst-case environmentalconditions are as follows:

Temperature: 127*F after 650 secHumidity: 100%Pressure: drop from 14.3 to 12.3 in 3 sec

2 sec at low pressure and a riseto normal 14.3 in 3 sec

Radiation: < 1 x 104~ rads

The safety function of the circuit breaker is to remove the fault from acable before the cable can catch on fire and jeopardize a safety-relatedcable. Whether the breaker trips and thus interrupts the fault or faultsitself internally and thus moves the fault back from the cable does notmatter. The thermal-magnetic circuit breaker always acts to protect thecircuit under both high and low ambient environments.

Molded-case circuit breakers are composed of five main components: moldedcase (frame), operating mechanism, arc extinguishers and contacts, tripelements and terminal connectors. The phenolic molded case encloses theoperating mechanism, arc extinguishers, contacts and trip elements andminimizes exposure to dirt, dust, and moisture. The operating mechanism isa metallic apparatus which is the means for opening and closing thebreaker. The mechanism is spring-loaded which causes the contacts to snapopen (or closed) when the breaker is tripped or manually operated. Thetrip elements serve to unlatch or "ti"the operating mechanism onoccurrence of a prolonged overload or a short circuit. Molded casebreakers are constructed so that the contacts cannot be held closed againsta fault condition ("trip-free operation").

Prepared by: __________________________

Reviewd by:Appendix 1, Rev. 1Reiwd y ../,vqLv,/r/-~ Sheet 2 of 2

On a breaker equipped with electro-mechanical type trip elements, overloadprotectio; is achieved by the use of a bimetal strip which bends ordeflect. when heated by excessive load current, physically causingunlatching of the operating mechanism. Elevated ambient temperaturedecreases the response time. Excessively high ambient temperature cancause degradation of internal insulating materials and affect breakercalibration. However, the design basis accident temperature is well belowthis threshold.

Protection against short-circuit current is achieved through the use of anelectro-magnet in series with the load current. When a short circuitoccurs the fault current passing through the breaker causes the magnet toattract the armature which in turn mechanically unlatches the operatingmechanism causing instant opening of the contacts. The magnetic tripelement is set to operate at a current level much lower than that whichwould cause cable damage in the short time before the breaker interrupts.The magnetic trip element is calibrated by varying the size of the air gapwhich proportionally varies the magnetic trip current rating.

The essential components of the tripping mechanism are metallic and thusnonthermally aging. Elevated temperature will not degrade operation of themagnetic trip element as it is sensitive only to fault current.

The phenolic molded case "enclosure" minimizes the effect humidity has onthe internal working parts of the breaker. Elevated levels of ambienthumidity will have very little effect on the breaker when it is carryingload current because the temperature of the air surrounding the breakerwill be higher than the room temperature and the surrounding air will beappreciably dryer than the room air. Even if moisture did condense,magnetic properties are not sensitive to moisture. If severe condensationoccurred, it could cause a phase-to-phase fault and thus trip the mainsource breaker which is located in a mild enviroznment, and even if thesource breaker failed to trip, the fault would be moved away from thecable. It is extremely unlikely that moisture could cause conductionthrough the open contact and not cause a phase-to-phase or phase-to-groundfault, but if this did occur the arc would instantly evaporate themoisture. Also, the breaker contains no hygroscopic material which wouldbe adversely affected by high humidity.

It has been shown during actual test on motor control centers forIla*rtsville Nuclear Plant that a sudden change of pressure of 3 PSIA had noaffect on molded-case circuit breakers. Radiation levels of I x 104 radsare considered negligible. Reference EPRI )iP-1558, Project 890-1, FinalReport, Figure 7-18.

From the above, it is concluded that these lighting boards are qualified toperform their only safety-related function in the worst-case environmentalconditions resulting from an accident. Absence of effective agingmechanisms assures this capability for the life of the plant. E F F E' C,044279.12

Prepared by: ___________________ EB-BD-3

Revieed by ~ ~Appendix 1, Rev. 1Reviewed______by:___Q Sheet 1 of 2

LIGHTING BOARD

(ARROW HART)

The lighting board is non-Class lE because it is not required to operateduring a design basis event, but is considered to be associate equipmentbecause the feeder power cables from the lighting board are routed suchthat they share the same raceway with Class lE circuits. Thus failure ofthe lighting board's circuit breakers, protecting these power cables, totrip for a fault could cause damage to a Class lB cable and thus preventClass IE equipment from performing their accident mitigation function.Therefore, to environmentally qualify this lighting board it is onlynecessary to address the tripping capability of the molded-case circuitbreakers in the stipulated environmental conditions.

This Auxiliary Building Lighting Board is located in general space onelevation 692 of the Auxiliary Building. The worst-case environmentalconditions are as follows:

Temperature: 153*F after 10 secHumidity: 100%Pressure: drop from 14.3 to 12.3 in 3 sec

2 sec at low pressure and a riseto normal 14.3 in 3 sec

Radiation: <1 x 10 rads

The safety function of the circuit breaker is to remove the fault from acable before the cable can catch on fire and jeopardize a safety-relatedcable. Whether the breaker trips and thus interrupts the fault or faultsitself internally and thus moves the fault back from the cable does notmatter. The thermal-magnetic circuit breaker always acts to protect thecircuit under both high and low ambient environiments.

Molded-case circuit breakers are composed of five main components: moldedcase (frame), operating mechanism, arc extinguishers and contacts, tripelements and terminal connectors. The phenolic molded case encloses theoperating mechanism, arc extinguishers, contacts and trip elements andminimizes exposure to dirt, dust, and moisture. The operating mechanism isa metallic apparatus which is the means for opening and closing thebreaker. The mechanism is spring-loaded which causes the contacts to snapopen (or closed) when the breaker is tripped or manually operated. Thetrip elements serve to unlatch or "trip" thi 'operating mechanism onoccurrence of a prolonged overload or a short circuit. Molded casebreakers are constructed so that the contacts cannot be held closed againsta fault condition ("trip-free operation").

DATE

Prepared by: Z Zo EEB-BD-3iL Appendix 1, Rev. 1

Reviewed by: 94~ 4gs. -/0 Mc~e' Sheet 2 of 2

On a breaker equipped vith electro--mechanical type trip elements, overloadProtectionp is achieved by the use of a bimetal strip which bends ordeflects when heated by excessive load current, physically causingunlatchinig of the operating mechanism. Elevated ambient temperaturedecreases the response time. Excessively high ambient temperature cancause degradation of internal insulating materials and affect breakercalibration. However, the design basis accident temperature is well belowthis threshold.

Protection against short-circuit current is achieved through the use of anelectro-magnet in series with the load current. When a short circuitoccurs the fault current passing through the breaker causes the magnet toattract the armature which in turn mechanically unlatcese the operatingmechanism causing instant opening of the contacts. The magnetic tripelement is set to operate at a current level much lower than that whichwould cause cable damage in the short time before the breaker interrupts.The magnetic trip element is calibrated by varying the size of the air gapwhich proportionally varies the magnetic trip current rating.

The essential components of the tripping mechanism are metallic and thusnonthermally aging. Elevated temperature will not degrade operation of themagnetic trip element as it is sensitive only to fault current.

The phenolic molded case "enclosure" minimizes the effect humidity has onthe internal working parts of the breaker. Elevated levels of ambienthumidity will have very little effect on the breaker when it is carryingload current because the temperature of the air surrounding the breakerwill be higher than the room temperature and the surrounding air will beappreciably dryer than the room air. Even if moisture did condense.magnetic properties are not sensitive to moisture. If severe condensationoccurred, it could cause a phase-to-phase fault and thus trip the mainsource breaker which is located in a mild environment, and even if thesource breaker failed to trip, the fault would be moved away from thecable. It is extremely unlikely that moisture could cause conductionthrough the open contact and not cause a phase-to-phase or phase-to-groundfault, but if this did occur the arc would instantly evaporate themoisture. Also, the breaker contains no hygroscopic material which wouldbe adversely affected by high humidity.

It has been shown during actual test on motor control centers forHartsville Nuclear Plant that a sudden change of pressure of 3 PSIA had noaffect on molded-case circuit breakers. Radiation levels of 1 x 104 radsare considered negligible. Reference EPRI ii-1558, Project 890-1, FinalReport, Figure 7-18.

From the above, it is concluded that these lighting boards are qualified toperform their only safety-related function in the worst-case environmientalconditions resulting from an accident. Absence of effective agingmechanisms assures this capability for the life of the plant. E

0"27~~ 9.2 F

Prepared by: LQ,Reviewed by:

C-,0

6 dlzEEB-BD-4Appendix 1, Rev. 1Sheet 1 of 2

LIGHTING BOARD

(mROW HART)

The lighting board is non-Class IS because it is not required to operateduring a design basis event, but is considered to be associate equipmentbecause the feeder power cables from the lighting board are routed suchthat they share the same raceway with Class IE circuits. Thus failure ofthe lighting board's circuit breakers, protecting these power cables, totrip for a fault could cause damage to a Class IE cable and thus preventClass IE equipment from performing their accident mitigation function.Therefore, to environmentally qualify this lighting board it is onlynecessary to address the tripping capability of the molded-case circuitbreakers in the stipulated environmental conditions.

This Auxiliary Building Lighting Board is located in general space onelevation 692 of the Auxiliary Building. The worst-case environmentalconditions are as follows:

Temperature: 1537F after 10 secHumidity: 100%Pressure: drop from 14.3 to 12.3 in 3 sec

2 sec at low pressure and a riseto normal 14.3 in 3 sec

Radiation: < 1 x 14rads

The safety function of the circuit breaker is to remove the fault from acable before the cable can catch on fire and jeopardize a safety-relatedcable. Whether the breaker trips and thus interrupts the fault or faultsitself internally and thus moves the fault back from the cable does notmatter. The thermal-magnetic circuit breaker always acts to protect thecircuit under both high and low ambient environments.

Molded-case circuit breakers are composed of five main components: moldedcase (frame), operating mechanism, arc extinguishers and contacts, tripelements and terminal connectors. The phenolic molded case encloses theoperating mechanism, arc extinguishers, contacts and trip elements andminimizes exposure to dirt, dust, and moisture. The operating mechanism isa metallic apparatus which is the means for opening and closing thebreaker. The mechanism is spring-loaded which causes the contacts to snapopen (or closed) when the breaker is tripped or manually operated. Thetrip elements serve to unlatch or "trip" the operating mechanism onoccurrence of a prolonged overload or a short circuit. Molded casebreakers are constructed so that the contacts cannot be held closed againsta fault condition ("trip-free operation").

EFFECTIVEI DAT EC(~ C5

Prepared by: /1: 5 'EEB-BD-4I I Appendix 1, Rev. 1

Reviewed by: __________________ Sheet 2 of 2

On a breaker equipped with electro-mechanical type trip elements, overloadprotection is achieved by the use of a bimetal strip which bends ordeflects 41hen heated by excessive load current, physically causingunlatching of the operating mechanism. Elevated ambient temperaturedecreases the response time. Excessively high ambient temperature cancause degradation of internal insulating materials and affect breakercalibration. However, the design basis accident temperature is well belowthis threshold.

Protection against short-circuit current is achieved through the use of anelectro-magnet in series with the load current. When a short circuitoccurs the fault current passing through the breaker causes the magnet toattract the armature which in turn mechanically unlatches the operatingmechanism causing instant opening of the contacts. The magnetic tripelement is set to operate at a current level much lower than that whichwould cause cable damage in the short time before the breaker interrupts.The magnetic trip element is calibrated by varying the size of the air gapwhich proportionally varies the magnetic trip current rating.

The essential components of the tripping mechanism are metallic and thusnonthermally aging. Elevated temperature will not degrade operation of themagnetic trip element as it is sensitive only to fault current.

The phenolic molded case "enclosure" minimizes the effect humidity has onthe internal working parts of the breaker. Elevated levels of ambienthumidity will have very little effect on the breaker when it is carryingload current because the temperature of the air surrounding the breakerwill be higher than the room temperature and the surrounding air will beappreciably dryer than the room air. Even if moisture did condense,magnetic properties are not sensitive to moisture. If severe condensationoccurred, it could cause a phase-to-phase fault and thus trip the mainsource breaker which is located in a mild environment, and even if thesource breaker failed to trip, the fault would be moved away from thecable. It is extremely unlikely that moisture could cause conductionthrough the open contact and not cause a phase-to-phase or phase-to-groundfault, but if this did occur the arc would instantly evaporate themoisture. Also, the breaker-contains no hygroscopic material which wouldbe adversely affected by high humidity.

It has been shown during actual test on motor control centers forHartsville Nuclear Plant that a sudden change of pressure of 3 PSIA had noaffect on molded-case circuit breakers. Radiation levels of 1 x 104 radsare considered negligible. Reference EPRI NP-1558., Project 890-1, FinalReport, Figure 7-18.

From the above, it is concluded that these lighting boards are qualified toperform their only safety-related function in the worst-case environmentalconditions resulting from an accident. Absence of effective agingmechanisms assures this capability for the life of the plant. -

044279.12 d

Prepared by: 4,1 ffd EEB-MC-lAppendix 1, Rev. 1

Reviewed by.- ____________________ Sheet 1 of 2

MOTOR CONTROL CENTER

(I-T-E 5600 SERIES)

The motor control center (MCC) is non-Class 1E because it is not requiredto operate during a design basis event, but is considered to be associateequipment because the feeder power cables from the MCCs are routed suchthat they share the same raceway with Class lE circuits. Thus failure ofthe MCC's circuit breakers (both thermal magnetic and magnetic only),protecting their power cables, to trip for a fault could cause damage to aClass lB cable and thus prevent Class lE equipment from performing theiraccident mitigation function. Therefore, to environmentally qualify thisMCC it is only necessary to address the tripping capability of themolded-case circuit breakers in the stipulated environmental conditions.

This Chemical and Volume Control Board is located in general space onelevation 692 of the Auxiliary Building. The worst-case environmentalconditions are as follows:

Temperature: 153'F after 10 secHumidity: 100%Pressure: drop from 14.3 to 12.3 in 3 sec

2 sec at low pressure and a riseto normal 14.3 in 3 sec

Radiation: <1 x 104 rads

The safety function of the circuit breaker is to remove the fault from acable before the cable can catch on fire and jeopardize a safety-relatedcable. Whether the breaker trips and thus interrupts the fault or faultsitself internally and thus moves the fault back from the cable does notmatter. The thermal-,magnetic circuit breaker always acts to protect thecircuit under both high and low ambient environments.

Molded-case circuit breakers are composed of five main components: 'moldedcase (frame), operating mechanism, arc extinguishers and contacts, tripelements and terminal connectors. The phenolic molded case encloses theoperating mechanism, arc extinguishers, contacts and trip elements andminimizes exposure to dirt, dust, and moisture. The operating mechanism isa metallic apparatus which is the means for opening and closing thebreaker. The mechanism is spring-loaded which causes the contacts to snapopen (or closed) when the breaker is1 tripped or manually operated. Thetrip elements serve to unlatch or "trip'" the operating mechanism onoccurrence of a prolonged overload or a short circuit. Molded casebreakers are constructed so that the contacts cannot be held closed againsta fault condition ("trip-free operation").

ATE

Prepared by: _ ___ l l________

Reviewed by:

I ~

~ /0 -/0 -J~d

EEB-NC-iAppendix 1, Rev. 1Sheet 2 of 2

On a breaker equipped with electro-mechanical type trip elements, overloadprotectiox is achieved by the use of a bimetal strip which bends ordeflects when heated by excessive load current, physically causingunlatching of the operating mechanism. Elevated ambient temperaturedecreases the response time. Excessively high ambient temperature cancause degradation of internal insulating materials and affect breakercalibration. However, the design basis accident temperature is veil belowthis threshold.

Protection against short-circuit current is achieved through the use of anelectro-magnet in series with the load current. When a short circuitoccurs the fault current passing through the breaker causes the magnet toattract the armature which in turn mechanically unlatches the operatingmechanism causing instant opening of the contacts. The magnetic tripelement is set to operate at a current level much lower than that whichwould cause cable damage in the short time before the breaker interrupts.The magnetic trip element is calibrated by varying the size of the air gapwhich proportionally varies the magnetic trip current rating.

The essential components of the tripping mechanism are metallic and thusnonthermally aging. Elevated temperature will not degrade operation of themagnetic trip element as it is sensitive only to fault current.

The phenolic molded case "enclosure" minimizes the effect humidity has onthe internal working parts of the breaker. Elevated levels of ambienthumidity will have very little effect on the breaker when it is carryingload current because the temperature of the air surrounding the breakerwill be higher than the room temperature and the surrounding air will beappreciably dryer than the room air. Even if moisture did condense,magnetic properties are not sensitive to moisture. If severe condensationoccurred, it could cause a phase-to-phase fault and thus trip the mainsource breaker which is located in a mild environment, and even if thesource breaker failed to trip, the fault would be moved away from thecable. It is extremely unlikely that moisture could cause conductionthrough the open contact and not cause a phase-to-phase or phase-to-groundfault, but if this did occur the arc would instantly evaporate themoisture. Also, the breaker contains no hygroscopic material which wouldbe adversely affected by high humidity.

It has been shown during actual test on motor control centers forHartsville Nuclear Plant that a sudden change of pressure of 3 PSIA had noaffect of any components used on a motor con~trol center. Radiation levelsof lXlO4rads are considered negligible. Reference EPRI NP-1558, Project890-1, Final Report, Figure 7-18.

From the above, it is concluded that these motor control centers are>qualified'to perform their only safety-related function in the worst-case COenvironmental conditions resulting from an accident. Absence of effectivel _

aging mechanisms assures this capability for the life of the plant.

044279.12 AD

-Prepared by: EEB-MC-2fl ~ f k f''Appendix 1, Rev. 1

Reviewed by:.-~~f Sheet 1 of 2

MOTOR CONTROL CENTER

(I-T-E 5600 SERIES)

The motor control center (MCC) is non-Class 1E because it is not requiredto operate during a design basis event, but is considered to be associateequipment because the feeder power cables from the MCCs are routed suchthat they share the same raceway with Class lE circuits. Thus failure ofthe MCC's circuit breakers (both thermal magnetic and magnetic only),protecting their pover cables, to trip for a fault could cause damage to aClass 1E cable and thus prevent Class 1E equipment from performing theiraccident mitigation function. Therefore, to envirorimaentally qualify thisMCC it is only necessary to address the tripping capability of themolded-case circuit breakers in the stipulated environmental conditions.

This Chemical and Volume Control Board is located in general space onelevation 692 of the Auxiliary Building. The worst-case envirommentalconditions are as follows:

Temperature: 153*F after 10 secHumidity: 100%Pressure: drop from 14.3 to 12.3 in 3 sec

2 sec at low pressure and a riseto normal 14.3 in 3 sec

Radiation: (1 x 104 rads

The safety function of the circuit breaker is to remove the fault from acable before the cable can catch on fire and jeopardize a safety-relatedcable. Whether the breaker trips and thus interrupts the fault or faultsitself internally and thus moves the fault back from the cable does notmatter. The thermal-magnetic circuit breaker always acts to protect thecircuit under both high and low ambient envirorments.

Molded-case circuit breakers are composed of five main components: moldedcase (frame), operating mechanism, arc extinguishers and contacts, tripelements and terminal connectors. The phenolic molded case encloses theoperating mechanism, arc extinguishers, contacts and trip elements andminimizes exposure to dirt, dust, and moisture. The operating mechanism isa metallic apparatus which is the means for opening and closing thebreaker. The mechanism is spring-loaded which causes the contacts to snapopen (or closed) when the breaker is tripped or manually operated. Thetrip elements serve to unlatch or "trip" the '6perating mechanism onoccurrence of a prolonged overload or a short circuit. Molded casebreakers are constructed so that the contacts cannot be held closed againsta fault condition ("trip-free operation").

E F F ~ T~'D A T

'Prepared byy:

Reviewed by: V~ -A7- -r-

EEB-MC-2Appendix 1, Rev. 1Sheet 2 of 2

On a breaker equipped with electra-mechanical type trip elements, overloadproteetio% is achieved by the use of a bimetal strip which bends ordeflects wrhen heated by excessive load current, physically causingunlatching of the operating mechanism. Elevated ambient temperaturedecreases the response time. Excessively high ambient temperature cancause degradation of internal insulating materials and affect breakercalibration. However, the design basis accident temperature is well belowthis threshold.

Protection against short-circuit current is achieved through the use of anelectra-magnet in series with the load current. When a short circuitoccurs the fault current passing through the breaker causes the magnet toattract the armature which in turn mechanically unlatches the operatingmechanism causing instant opening of the contacts. The magnetic tripelement is set to operate at a current level much lower than that vhichwould cause cable damage in the shart time before the breaker interrupts.The magnetic trip element is calibrated by varying the size of the air gapwhich proportionally varies the magnetic trip current rating.

The essential components of the tripping mechanism are metallic and thusnonthermally aging. Elevated temperature will not degrade operation of themagnetic trip element as it is sensitive only to fault current.

The phenolic molded case "~enclosure"t minimizes the effect humidity has onthe internal working parts of the breaker. Elevated levels of ambienthumidity will have very little effect on the breaker when it is carryingload current because the temperature af the air surrounding the breakerwill be higher than the room temperature and the surrounding air will beappreciably dryer than the room air. Even if moisture did condense,magnetic properties are not sensitive to moisture. If severe condensationoccurred, it could cause a phase-ta-phase fault and thus trip the mainsource breaker which is located in a mild environfment, and even if thesource breaker failed to trip, the fault would be moved away from thecable. It is extremely unlikely that moisture could cause conductionthrough the open contact and not cause a phase-ta-phase or phase-ta-groundfault, but if this did occur the arc would instantly evaporate themoisture. Also, the breaker contains no hygroscopic material which wouldbe adversely affected by high humidity.

It has been shown during actual test on motor control centers forHiartsville Nuclear Plant that a sudden change of pressure of 3 PSIA had noaffect of any components used on a motor control center. Radiation levelsof 1llO4 rads are considered negligible. Reference EPRI NP-1558, Project890-1, Final Report, Figure 7-18.

From the above, it is concluded that these motor control centers arequalified-to perform their only safety-related function in the worst-caseenvironmental conditions resulting from an accident. Absence of effectiveaging mechanisms assures this capability for the life of the plant.

044279.12 -~ . 7.17

Prepared by:L 0V04

Reviewed by:,* *.l~ '~

~ (A~EEB-MC-3Appendix 1, Rev. 1Sheet 1 of 2

MOTOR CONTROL CENTER

(I-T-E 5600 SERIES)

The motor control center (MCC) is non-Class lE because it is not requiredto operate during a design basis event, but is considered to be associateequipment because the feeder paver cables from the MCCe are routed suchthat they share the same raceway vith Class 1E circuits. Thus failure ofthe MCC's circuit breakers (both thermal magnetic and magnetic only),protecting their power cables, to trip for a fault could cause damage to aClass 1E cable and thus prevent Class 1E equipment from performing theiraccident mitigation function. Therefore, to environmentally qualify thisMCC it is only necessary to address the tripping capability of themolded-case circuit breakers in the stipulated environmental conditions.

This Fuel and Waste Handling Board is located in general space on elevation713 of the Auxiliary Building. The worst-case environmental conditions areas follows:

Temperature: 1270FHumidity: 10OZPressure: drop from 14.3 to 12.3 in 3 sec

2 sec at low pressure and a riseto normal 14.3 in 3 sec

Radiation: (1 x 104 rads

The safety function of the circuit breaker is to remove the fault from acable before the cable can catch on fire and jeopardize a safety-relatedcable. Whether the breaker trips and thus interrupts the fault or faultsitself internally and thus moves the fault back from the cable does notmatter. The thermal-magnetic circuit breaker always acts to protect thecircuit under both high and low ambient environments.

Molded-case circuit breakers are composed of five main components: moldedcase (frame), operating mechanism, arc extinguishers and contacts, tripelements and terminal connectors. The phenolic molded case encloses theoperating mechanism, arc extinguishers, contacts and trip elements andminimizes exposure to dirt, dust, and moisture. The operating mechanism isa metallic apparatus which is the means f or opening and closing thebreaker. The mechanism is spring-loaded which causes the contacts to snapopen (or closed) when the breaker is trippe4 or manually operated. Thetrip elements serve to unlatch or "trip" the operating mechanism onoccurrence of a prolonged overload or a short circuit. Molded casebreakers are constructed so that the contacts cannot be held closed againsta fault condition ("trip-free operation").

E F~2

711

Prepared by: / IEEB-NC-3A/ Appendix 1, Rev. 1

Reviewed by: y Wtet.44'-46:44 Sheet 2 of 2

On a breaker equipped with electro-mechanical type trip elements, overloadprotectio; is achieved by the use of a bimetal strip which bends ordeflects urhen heated by excessive load current, physically causingunlatching of the operating mechanism. Elevated ambient temperaturedecreases the response time. Excessively high ambient temperature cancause degradation of internal insulating materials and affect breakercalibration. However, the design basis accident temperature is well belowthis threshold.

Protection against short-circuit current is achieved through the use of anelectro-magnet in series with the load current. When a short circuitoccurs the fault current passing through the breaker causes the magnet toattract the armature which in turn mechanically unlatches the operatingmechanism causing instant opening of the contacts. The magnetic tripelement is set to operate at a current level much lower than that whichwould cause cable damage in the short time before the breaker interrupts.The magnetic trip element is calibrated by varying the size of the air gapwhich proportionally varies the magnetic trip current rating.

The essential components of the tripping mechanism are metallic and thusnonthermally aging. Elevated temperature will not degrade operation of themagnetic trip element as it is sensitive only to fault current.

The phenolic molded case "enclosure" minimizes the effect humidity has onthe internal working parts of the breaker. Elevated levels of ambienthumidity will have very little effect on the breaker when it is carryingload current because the temperature of the air surrounding the breakerwill be higher than the room temperature and the surrounding air will beappreciably dryer than the room air. Even if moisture did condense,magnetic properties are not sensitive to moisture. If severe condensationoccurred, it could cause a phase-to-phase fault and thus trip the mainsource breaker which is located in a mild environment, and even if thesource breaker failed to trip, the fault would be moved away from thecable. It is extremely unlikely that moisture could cause conductionthrough the open contact and not cause a phase-to-phase or phase-to-groundfault, but if this did occur the arc would instantly evaporate themoisture. Also, the breaker contains no hygroscopic material which wouldbe adversely affected by high humidity.

It has been shown during actual teat on motor control centers forHartsville Nuclear Plant that a sudden change of pressure of 3 PSIA had noaffect of any'components used on a motor co~trol center. Radiation levelsof lK1O4 rads are considered negligible. Reference EPRI NP-1558, Project890-1, Final Report, Figure 7-18.

From the above, it is concluded that these motor control centers arequalified-to perform their only safety-related function in the worst-caseenvironmental conditions resulting from an accident. Absence of effectiveaging mechanisms assures this capability for the life of the plant.

044279.12 E F F E CT V

Prepared by: -1EEB-M&-f

Reviewed by: 0Appendix 1, Rev. 1

or Sheet 1 of 2

MOTOR CONTROL CENTER

(I-T-E 5600 SERIES)

The motor control center (MCC) is non-Class 1E because it is not requiredto operate during a design basis event, but is considered to be associateequipment because the feeder power cables from the MCCs are routed suchthat they share the same raceway with Class 1E circuits. Thus failure ofthe MCC's circuit breakers (both thermal magnetic and magnetic only),protecting their power cables, to trip for a fault could cause damage to aClass 1E cable and thus prevent Class 1E equipment from performing theiraccident mitigation function. Therefore, to environmentally qualify thisMCC it is only necessary to address the tripping capability of themolded-case circuit breakers in the stipulated environmental conditions.

This Fuel and Waste Handling Board is located in general space on elevation713 of the Auxiliary Building. The worst-case environmental conditions areas follows:

Temperature: 1270FHumidity: 100%Pressure: drop from 14.3 to 12.3 in 3 sec

2 sec at low pressure and a riseto normal 14.3 in 3 sec

Radiation: 4(l x 104 rads

The safety function of the circuit breaker is to remove the fault from acable before the cable can catch on fire and jeopardize a safety-relatedcable. Whether the breaker trips and thus interrupts the fault or faultsitself internally and thus moves the fault back from the cable does notmatter. The thermal-magnetic circuit breaker always acts to protect thecircuit under both high and low ambient environments.

Molded-case circuit breakers are composed of five main components: moldedcase (frame), operating mechanism, arc extinguishers and contacts, tripelements and terminal connectors. The phenolic molded case encloses theoperating mechanism, arc extinguishers, contacts and trip elements andminimizes exposure to dirt, dust, and moisture. The operating mechanism isa metallic apparatus which is the means for opening and closing thebreaker. The mechanism is spring-loaded which causes the contact. to snapopen (or closed) when the breaker is tripped or manually operated. Thetrip elements serve to unlatch or "trip" the'bperating mechanism onoccurrence of a prolonged overload or a short circuit. Molded casebreakers are constructed so that the contacts cannot be held closed againsta fault condition ("trip-free operation").

r E FEAllA

Prepared by: '.0 /9&Z EEB-MC-4

Reviewd by:Appendix 1, Rev. 1Reiwdby C/iw ~L 4 pA Sheet 2 of 2

On a breaker equipped with electro-mechanical type trip elements, overloadprotectio.n is achieved by the use of a bimetal strip which bends ordeflects uýhen heated by excessive load current, physically causingunlatching of the operating mechanism. Elevated ambient temperaturedecreases the response time. Excessively high ambient temperature cancause degradation of internal insulating materials and affect breakercalibration. However, the design basis accident temperature is well belowthis threshold.

Protection against short-circuit current is achieved through the use of anelectro-magnet in series with the load current. When a short circuitoccurs the fault current passing through the breaker causes the magnet toattract the armature which in turn mechanically unlatches the operatingmechanism causing instant opening of the contacts. The magnetic tripelement is set to operate at a current level much lower than that whichwould cause cable damage in the short time before the breaker interrupts.The magnetic trip element is calibrated by varying the size of the air gapwhich proportionally varies the magnetic trip current rating.

The essential components of the tripping mechanism are metallic and thusnonthermally aging. Elevated temperature will not degrade operation of themagnetic trip element as it is sensitive only to fault current.

The phenolic molded case "enclosure" minimizes the effect humidity has onthe internal working parts of the breaker. Elevated levels of ambienthumidity will have very little effect on the breaker when it is carryingload current because the temperature of the air surrounding the breakerwill be higher than the room temperature and the surrounding air will beappreciably dryer than the room air. Even if moisture did condensesmagnetic properties are not sensitive to moisture. If severe condensationoccurred, it could cause a phase-to-phase fault and thus trip the mainsource breaker which is located in a mild enviroznment, and even if thesource breaker failed to trip, the fault would be moved away from thecable. It is extremely unlikely that moisture could cause conductionthrough the open contact and not cause a phase-to-phase or phase-to-groundfault, but if this did occur the arc would instantly evaporate themoisture. Also, the breaker contains no hygroscopic material which wouldbe adversely affected by high humidity.

It has been shown during actual test on motor control centers forHartsville Nuclear Plant that a sudden change of pressure of 3 PSIA had noaffect of any components used on a motor con~trol center. Radiation levelsof lxlO4rads are considered negligible. Reference EPRI NP-1558, Project890-1, Final Report, Figure 7-18.

From the above, it is concluded that these motor control centers arequalified-to perform their only safety-related function in the worst-caseenvironmaental conditions resulting from an accident. Absence of effectiveaging mechanisms assures this capability for the life of the plant.

044279.12 V L

L)T

Prepared by:t 0gIf

Reviewed by:, I

C9 ~;: (LdLE¶.~ /e~ -/0 -~

EEB-MC-5Appendix 1, Rev. 1Sheet 1 of 2

MOTOR CONTROL CENTER

(I-T-E 5600 SERIES)

The motor control center (MCC) is non-Class lE because it is not requiredto operate during a design basis event, but is considered to be associateequipment because the feeder power cables from the MCCs are routed suchthat they share the same raceway with Class lE circuits. Thus failure ofthe MCC's circuit breakers (both thermal magnetic and magnetic only),protecting their power cables, to trip for a fault could cause damage to aClass 1E cable and thus prevent Class 1E equipment from performing theiraccident mitigation function. Therefore, to environmentally qualify thisMCC it is only necessary to address the tripping capability of themolded-case circuit breakers in the stipulated environmental conditions.

This Auxiliary Building Common MCC is located in general space on elevation692 of the Auxiliary Building. The worst-case environmental conditions areas follows:

Temperature: 127*F after 650 secHumidity: 100%Pressure: drop from 14.3 to 12.3 in 3 sec

2 sec at low pressure and a riseto normal 14.3 in 3 sec

Radiation: 4 1 x 10 rads

The safety function of the circuit breaker is to remove the fault from acable before the cable can catch on fire and jeopardize a safety-relatedcable. Whether the breaker trips and thus interrupts the fault or faultsitself internally and thus moves the fault back from the cable does notmatter. The thermal-magnetic circuit breaker always acts to protect thecircuit under both high and low ambient environments.

Molded-case circuit breakers are composed of five main components: moldedcase (frame), operating mechanism, arc extinguishers and contacts, tripelements and terminal connectors. The phenolic molded case encloses theoperating mechanism, arc extinguishers, contacts and trip elements andminimizes exposure to dirt, dust, and moisture. The operating mechanism isa metallic apparatus which is the means for opening and closing thebreaker. The mechanism is spring-loaded which causes the contacts to snapopen (or closed) when the breaker is tripped or manually operated. Thetrip elements serve to unlatch or "trip" the boperating mechanism onoccurrence of a prolonged overload or a short circuit. Molded casebreakers are constructed so that the contacts cannot be held closed againsta fault condition ("trip-free operation").

E F F:ECT IVD A TE

Prepared by: 0.EEZBIO &-MC-5&A~xy e-eo-goAppendix 1, Rev. 1

Reviewed by: L1 C4/Sheet 2 of 2

On a breaker equipped with electro-mechanical type trip elements, overloadprotectioU is achieved by the use of a bimetal strip which bends ordeflects ;hen heated by excessive load current, physically causingunlatching of the operating mechanism. Elevated ambient temperaturedecreases the response time. Excessively high ambient temperature cancause degradation of internal insulating materials and affect breakercalibration. However, the design basis accident temperature is well belowthis threshold.

Protection against short-circuit current is achieved through the use of anelectro-magnet in series with the load current. When a short circuitoccurs the fault current passing through the breaker causes the magnet toattract the armature which in turn mechanically unlatches the operatingmechanism causing instant opening of the contacts. The magnetic tripelement is set to operate at a current level much lower than that whichwould cause cable damage in the short time before the breaker interrupts.The magnetic trip element is calibrated by varying the size of the air gapwhich proportionally varies the magnetic trip current rating.

The essential components of the tripping mechanism are metallic and thusnonthermally aging. Elevated temperature will not degrade operation of themagnetic trip element as it is sensitive only to fault current.

The phenolic molded case "enclosure" minimizes the effect humidity has onthe internal working parts of the breaker. Elevated levels of ambienthumidity will have very little effect on the breaker when it is carryingload current because the temperature of the air surrounding the breakerwill be higher than the room temperature and the surrounding air will beappreciably dryer than the room air. Even if moisture did condense,magnetic properties are not sensitive to moisture. If severe condensationoccurred, it could cause a phase-to-phase fault and thus trip the mainsource breaker which is located in a mild envirooment, and even if thesource breaker failed to trip, the fault would be moved away from thecable. It is extremely unlikely that moisture could cause conductionthrough the open contact and not cause a phase-to-phase or phase-to-groundfault, but if this did occur the arc would instantly evaporate themoisture. Also, the breaker contains no hygroscopic material which wouldbe adversely affected by high humidity.

It has been shown during actual test on motor control centers forHartsville Nuclear Plant that a sudden change of pressure of 3 PSIA had noaffect of any components used on a motor co4trol center. Radiation levelsof lXl04rads are considered negligible. Reference EPRI NP-1558, Project890-1. Final Report, Figure 7-18.

From the above, it is concluded that these motor control centers arequalified-to perform their only safety-related function in the worst-caseenviroimmental conditions resulting from an accident. Absence of effectiveaging mechanisms assures this capability for the life of the plant.

044279.12 E FrF

0sPage 1 of 13

EQUIPMENT QUALIFICATION SHEET (EQS)INDEX

EQS Sheet No./Revision No.

WBN-MEB-30-0001

WBN-MEB-30-0002

Manufacturer

ASCO

NAMCO,

Model No.

HTr8320A108

EA700

rEFFECTIVEI O CCT 1980`4

WBN-MEB-30-0004 R. B. DENISON C4 JK05

Component No.

I-F SV-30-28I-F'SV-30-291-F SV-30-60I-F SV-30-69

1 -ZS-30-31-ZS-30-61 -ZS-30-131-ZS-30-181 -ZS-30-281 -ZS-30-291 -ZS-30-32

1 -ZS-30-33

1 -ZS-30-60I -ZS-30-691 -ZS-30-76I-ZS-30-911 -ZS-30-1 151-ZS-30-1 171-ZS-30-1181-ZS-30-1191 -ZS-30-1 201-ZS-30-121

1-ZS-30-124

1 -ZS-30-1 25

1 -ZS-30-1 28

1-ZS-30-131

1-ZS-30-132

I-FCO-30-129

Table/Sheet No.

3.1l-7/WBN-i4EB-00013. 11-7/WBN-MEB-OOO13. 11-7/WBJN-MEB-OO013. 1l-7/WBN-MEB-OOO1

See EQS WBN-EEB-0066See EQS WBN-EEB-0066See EQS WBN-EEB-0066See EQS WBN-EEB-0066See EQS WBN-EEB-0067See EQS WBN-EEB-0067(Mild Environment Pez

1OCFR5O .49)(Mild Environment Pei

lOCFR5O .49)See EQS WBN-EEB-0067See EQS WBN-EEB--0067See EQS WBN-EEB-0066See EQS WBN-EEB--0066See EQS WBN-EEB-0066See EQS WBN-EEB-0066See EQS WBN-EEB-0066See EQS WBN-EEB-0066See EQS WBN-EEB-0066(Mild Environment Pei

1OCFR5O .49)(Mild Environment Pei

l OCFR50.49)

(Mild Environment Pei1OCFR50.49)

(Mild Environment Pe71OCFR5O.49)

(Mild Environment Pei1OCFR5O.49)

(Mild Environment PeiIOCFR5O .49)

(Mild Environment Pei10CFR50.49)

0EQUIPMENT QUALIFICATION SHEET (EQS)

INDEXPage 2 of 13

EQS Sheet No./Revision No.

WBN-NEB-30-0005

WBN-MEB-30-0006

WBN--MEB-65-0007

WBN-MEB-65 -0008

WBN-MEB-65 -0009

WBN-NEB-65-00 10

WBN-MEB-30-00 11

A 2

Manufacturer

ASCO

CHROMALOX

RELIANCE

RELIANCE

CHROMALOX

CHROMALOX

BALDOR

r~ V E

DATE

Model No.

RT8320&185

TRI-7648 76%~

IYF882366A2-YC

lYF88 2366AI

106-114426-003

196032951003

M371LOT

Component No.

1-F SV-30 -87

1-F SV-30-107

0-FSV-30-122

0-FSV-30-123

1 -F SV-30-129

1-FSV-30-130

1-F SV-30-146A

I-F SV-30-146B

O-HTR-30-156B

0-MTR-65-23A

0-MTR-65 -42 B

0-TS-65 -160-TS-65 -36

0-HTR-65-17A0-HTR-65-37B

I-Contmt Spray PumpKm LA-A Pan Mtr

L-Contmt Spray PumpRm.lB-B Fan Mtr

Table/Sheet No._

(Mild Environment Per1OCFR5O .49)

(Mild Environment Per1OCFR5O .49)

(Mild Environment PerIOCIRSO .49)

(Mild Environment PerIOCFR5O .49)

(Mild Environment PerIOCFR5O .49)

(Mild Environment Per10CFR50 .49)

(Mild Environment PerLOCFR5O .49)

(Mild Environment PerLOCFR5O .49)

3. 1L-7/WBN-MEB-00023. 11-7/WBN-MEB-0002

3. 11-7/WBN-MEB-0002

3.11 -7/WBN-MEB-0002

3. L1-7/WBN-MEB-00023.11-7/WBN-MEB-0002

3.1 l-7/WBN-MEB-0002

3.*11 -7/WBN-MEB-0002

3. 11-7/WBN-MEB-0003

3. 11-7/WBN--MEB-0003

0 00EQUIPMENT QUALIFICATION SHEET (EQS)

INDEX

EQS Sheet No./Revision No. Manufacturer Model No. Component No. Table/Sheet No.

BALDORWBN-MEB-30O001 2

WBN-MB3-30-0013

WBN -MEB-30-00 15

WBN-MEB-30-00 16

BALDOR

BALDOR

BALDOR

M36 15T

M2334T

M361l0T

M361 1T

f EFFECIV E

rE FPLAE :

1 -RHR Pump Em lA-ACooler Van Mtr

1-RHR Pump Em 13-3

Cooler Fan Mtr

1-SIS Pump Em Cir

Fan lA-A Mtr

1-SIS Pump Em Cir

Fan 13-B Mtr

1--MTR-30-19OI-MTR-30-191

O-CCS Bster & SpentFuel, Pit Pump CirFan Mtr A-A

O-CCS later & SpentFuel, Pit Pump ClrFan Mtr B-B

1-Pipe Chase Clr Fans

lA-A Mtr

1-Pipe Chase Clr Fang

13-B Mtr

1-EL 692 Pen Em Clr

Fan Mtr lA-A

1-EL 692 Pen Em Clr

Fan Mtr 13-B

Cent Chg Pump Em

Clr lA-A Fan Mtr

3.*11-7 /WBN-NE3--0003

3. l1-7/WBN-MKB-000 3

3. 11-7/WBN-MEB-0003

3 .11-7IWBN-NEB-000 3

3.11-7/WBN-MEB00043 .11-7/WBN-MEB-0004

3. 11-7/WBN-MEB-0004

3. 11-7/WBN-MEB-000 4

3 .11-7/WBN-MEB-000 4

3 .11-7/WBN-MEB-00 0 4

3 .11-7/WBN-MEB3OOO4

3. 11-7/WBN-MEBOOO04

3 .11-7/WBN-MEB-0OOS

Page 3 of 13

EFFrECTIVE.DATE

0 CT 19,84

EQS Sheet No./Reviaion No.

0EQUIPMENT QUALIFICATION SHEET (EQS)

INDEX

Manufacturer ModelI No. Component No.

-Page 4 of 13

Table/Sheet No.

WBN-MEB-30-O0017

WBN-MEB-30-0018

WBN-MEB-31-0019 ys.

WBN-MEB-31 -0020

WBN-MEB-31 -0025

WBN-MEB-31 -0026

RELIANCE

RELIANCE

GE'

GE

York

Dunham-Bush

IYF882365AIYC

1YF882365A2YC

5K445AK101ZFZ

5KYH9908

HTEI-B2-BBBS

IPCX230-,OQ

Cent Chg Pump EmCir lB-B Fan Mtr

1-EL 713 Pent Rm CirIA-A Fan Mtr

1-EL 713 Pent Em ClrLB-B Fan Mtr

1-EL 737 Pent Em ClrIA-A Fan Mtr

1-EL 737 Pent Em ClrlB-B Fan Mtr

0-EGTS Em CirFan A-A Mtr

0-EGTS Em ClrFan B-B Mtr

0-W1rR-30-146A

0-MTR-30-157B

.0-MCR Chill Pkg A-A

& B-B

0-Shtdh Ed Em A&BChill Pkg A-A & B-B

0-Shtdh Ed Em A&BChill Pkg A-A & B-B

MCR Chill Pkg A-A &B-B

3.*1 1-7/WBN-HEB-0005

3. 1l-7/WBN-NEB-0005

3. 11-7/WBN-MEB-0005

3. 11-7/WBN-MEB-0005

3. 11-7/WBN-MEB-0005

3.11 -7/WBN-MEB-0005

3.*11 -7/WBN-MEB-0005

3. 11-7/WBN-MEB-0005

3 .11-7/WBN-MEB-0005

Mi ld Environment

Per IOCFR50.49

Mild EnvironemntPer IOCFR5O.49

Mild EnvironmentPer LOCFR5O .49

Mild EnvironmentPer 1OCFR50 .49

EFFECTIVEDATEICT 10-8 4

EQS Sheet No./Revision No.

0.EQUIPMENT QUALIFICATION SHEET (EQS)

INDEX

Manufacturer Model No.

- qw

'Page 5 of.13

Component No* Table/Sheet No.

ASCOWBN-NEB-65 -0030

WBN--MEB-30-0035

WBN-NEB-30-0036

WBN-NMEB-30-0037

RELIANCE

RELIANCE

ASCO

HV202300-IRF

1YF882396A-UC

7269THR2

RT8320A108

1-F SV-65 -26I-FSV-65-27

1 -MTR-30-38A2-NTR-30-38A1 -MTR-30-39B2-MTR-30-39B

1 -MTR-30-214

1-F SV-30-3

1-F SV-30-6

I-FSV-30-13

1-F SV-30-18

I-F SV-30-32

I-FSV-30-33

1-F SV-30-76

1-F SV-30-91

1-F SV-30-115

1-F SV-30-117

1-FSV-30-1 18

1-F SV-30-119

I-FSV-30-120

3.11 -7/WBN-MEB-00063.11 -7/WBN-MEB-0006

3 .11-4/WBN-MEB-O0013 * 11 -4/WBN-MEB-OO013.11-4/WBN-MEB-O013. 11-4/WBN-NEB-O01

Mild EnvironmentPer 1OCFR5O .49

Mild Environment PerIOCFRSO .49

Mild Environment PerIOCFR5O .49

Mild Environment Per1OCFR5O .49

Mild Environment Per1OCFR50 .49

Mild Environment Per1OCFR5O .49

Mild Environment PerIOCFR5O .49

Mild Environment 1#erIOCFR5O .49

Mild En vironmint PerlOCFR5O .49

Mild Environment Per1OCFR5O .49

Mild Environment Per10CFR50 .49

Mild Environment Per1OCFR5O .49

Mild Environment Per1OCFR5O.49

Mild Environme~nt Per1OCFR5O .49

T E F 9 TrI V EEDATEOCT 1984

EQS Sheet No./Revision No.

0EQUIPMENT QUALIFICATION SHEET (EQS)

INDEX

Manufacturer Model No. Component No.

I-FSV-30-121

1-F SV-30-124

l-FSV-30-125

1-F SV-30-128

1-FSV-30-131

I-FSV-30-132

Page 6 of 13

Table/Sheet No.

mild EnvironmentIOCFR50 .49

Mild EnvironmentlOCFR5O .49

mild EnvironmentJOCFR5O .49

Mild Environment10CFR.50.49

Mild EnvironmentlOCFR5O .49

Mild Environment1OCFR5O .49

GOULD ALLIED CONTROL 100WBN-MEB-1-0101

WBN-MEB-1 -0102

WBN-MEB-1-0103

LI141TORQUE ' SMB-000

1 ,2-FSV-1-4(A,B,D,EgF,G,H,J)

1 ,2-FSV-1-11(AB,DE,F ,GH,J)

1 ,2-FSV-1-22(A, BDE ,F G, H,3)

1 ,2-FSV-1 -29(A,BD,EFGH,J)

1 ,2-FSV-1-51

1-Limit SwitchesOn PCV-1-12

1-Limit SwitchsOn PCV-1-23

3. l1-8/WBN-MEB-O1O1

3. 11-8/WBN-MBB-O1O1

3 .l1-8/WBN-MEB-O1Ol

3.1 l-8/WBN-MEB-Ol0l

(Mild Environment Per1OCFR5O .49)

See EQS WBN-EEB-0087

Per

Per

Per

Per

Per

Per

E N C-rI V EDATE

OCT 1984

EQS Sheet No./Revision No.

WEN-ýMEB-i -0104

WBN-MEB-1 -0105

WBN-MEB-1-0107

WBN-MEB-1 -0108

WBN-MKB-1 -0110

WBN-MEB-3-01 11

WBN-MBD-3-01 13

WBN-MEB-3-01 14

0EQUIPMENT~ QUALIFICATION SHEET (EQS)

INDEX

Manufacturer

LT.MITORQUE

LIMIT 0RQUE

LIMITORQUE

LIMITORQUE'

Model1 No.

SHB-00

SB-4

SMB-000

SMB-000

Page 7 of 13

Component No.

1 -PSV-1 -13A1I-PSV-1 -13B1I-PSV-1 -24A1 -PSV-1 -24B

1-Limit SwitchesOn PCV-1-30

1I-FCV-1 -15l-FCV-1-161I-FCV-1 -171 -FCV-1 -18

1I-PSV-1 -31lAI-PSV-1-31BI1-PSV-1 -6AI -PSV-1 -6B

1 -PCV-1 -5

1 -FCV-3-331 -FCV-3 -471 -FCV-3-871 -FCV-3-100

1-FCV-3-116AI-FCV-3-116BI-FCV-3-126AI-FCV-3-126B

1-FCV-3-136A1 -FCV-3-136BI-FCV-3-179A1-FCV-3-179B

Table/Sheet No-

See EQS WBN-EEB-0009

See EQS WBN-EEB-0087

3.*1 1-8/WBN-NEB-O 1023 .l1-8/WBN-MEB-01023. 11-8/WBN-MNEB-01023 .11-8/WBN-MEB-0102

See EQS WBN-EEB-0009

See EQS WBN-EEB-0087

3.11 -8/WBN-MEB-01023. 11-8/WBN-MEB-01023. 11-8/WBN-MEB-01023. 11-8/WBN-MEB-0102

3. 11-7/WBN-MEB-O1O13.11-7/WBN-MEB-01013. ll-7/WBN-MEB-O1013 .1l-7/WBN-MEB-0101

3. 1l-6/WBN-MEB-O1013. 1l-6/WBN-MEB-O1O13. 11-6/WBN-MEB-01013. 11-6/WBN-MEB-0101

EQUIPMENT QUALIFICATION SHEET (EQs)INDEX

Page 8 of 13

EQS Sheet No.IRevision. No.

WBN-MEB-26-01 15

WBN-NKB-30-0 117

'WBN-NKB-30-O 118

WBN-4EB-30-O 119

WBN-MEB-30-01 20

WBN-4fEB-30-0 121

WBN-MEB-30-b123

Manufacturer

LIMKITORQUE

ASCO

NAMCO

ASCO

NAMCO

Model No.

SB-00

HTX8316E35E

RA740

HTX8316E35E

EA740

Component No.

1 -FCV-26-240I-FCV-26-241I-FCV-26-2421 -FCV-26-2431 -FCV-26-2144I-FCV-26-245

1-F SV-30-21-F SV-30-5

Limit Switch on.1 ,2-FCV-30-2Limit switch on1 ,2-FCV-30-5Position Switch on19,2-FCV-30-61Position Switch on1 ,2-FCV-30-62

1-FSV-30-611-F SV-30 -62

1-F SV-30-8-B1-FSV-30-10-A

1 -ZS-30-10-A

1-V:SV-30-15-B1-F SV-30-40-A1 -FSV-30-50-B1-F SV-30-5 2-A1 -FSV-30 -56 -A1-F SV-30-5 8-B

I-FEV-30-17-A1-F SV-30-20-A

Table/Sheet No.

3. 11-7/WBN-MEB-0 1053.11 -7/WBN-HEB-0i053. l1-7/WBN-MEB-01053. 11-7/WBN-MEB-01053 .11-7/WBN-MEB-01053 .11-7/WBN-NEB-0105

3. 11-7/WEN-MEB-Ol0l3. 11-7/WBN-MEB-0101

3. 11-7/WBN-MEB-0 101

3. 11-7/WBN-NEB-Ol0l

3. 11-7/WBN-MEB-Ol0l

3. 11-7/WBN-MEB-0101

3. 11-7/WBN-MEB-0 1023.11-7/WBN-MEB-0102

See EQS WBN-REB-0046

3 .11-4/WBN-MEB-0101

See EQS WBN-EEB-0047

E FHFE C T I V E0 T FI.-E

C i ~ *~Or

0EQUIPMENT QUALIFICATION SHEET (EQS)

INDEX

Page 9 of 13

EQS Sheet No./Revision No. Manufacturer Model1 No.

WBN-MEB-30-0 124

WBN-MEB-30 -0125

WBN-MEB-30-0 126

NANCOWBN-MEB-30-0127

WBN-+MB-30-O 128

EA740

EFFECTIVE.,.DALEý

Component No.

1-FSV-30-17-A

1 -FSV-30 -19-BI-FSV-30-14-A1 -FZV-30-16 -BI-FSV-30-37-B1 -FBSV-30-59-AI-FSV-30-57-B1 -FSV-30-53-B

1-FSV-30-51-A1 -FSV-30 -9-B1-F SV-30-7 -A

1 -ZS-30-1 9-B1 -ZS-30-14-ALimit Switch on

1-FCV-30-16-BLimit Switch on

I-FCV-30-37 -B1 -ZS-30-59-A1 -ZS-30-57 -B1 -ZS-30-5 3-B1-ZS-30-51 -A1 -ZS-30-7 -A1 -ZS-30-9-B

Limit Switch on1 ,2-FCV-30-12-A

Limit Switch on1,2-F CV-30 -54-A

1-FCV-30-12A1I-FCV-30 -54A

Table/Sheet No.

See EQS WBN-REB-0088

See EQS WBN-EEB-0058

See EQS WBN-EEB-0063

3. 1l-5/WBN-MEB-O1O1

3. 11-5/ WBN-MEB-Ol0l

See EQS WBN-EEB-0054

WBNME-3-0291 -FCV-31-327-B See EQS WBN-EEB-0093

0

WBN-MB-31-0129

EQUIPMNTIF QUALIFICATION SHEET (EQS)INDEX

Page 10 of 13

EQS Sheet No./Revision No.

WBN-HEB-65-0 130

Manufacturer

ASCO

ASCOWBN-MEB-65-0 132

WBN-MEB-67-0 134

WBN-NEB-67-0 135

WBN-MEB-67 -0136

LIMITORQUE'

LIMITORQIJE

LIMITORQUE

Model No.

HTX8300B58F._

HT631655

SMB-000

SMB-O000

SMB-000

EFFECTIVE-D AT E

0 CT 4

Component No.

0-FSV-65-47A0-FXSV-65-47 B1-FSV-65-51

1 -PSV-65-83-B1-PSV-65-81-A

1-FCV-67-87-A1-FCV-67-95-A1 -FCV-67 -103-B1-FCV-67-111-B

1 -PCV-67-295-A1 -FCV-67-296-A1-FCV-67-297-B1 -FCV-67 -298-B

1-FCV-67 -83-A1 -FCV-67 -88-B1 -FCV-67 -91-A1 -FCV-67-96-B1-FCV-67-99-B1 -FCV-67-104-A1-FCV-67-107-B1-FCV-67-112-A1 -FCV-67 -130-A1-FCV-67-131-B1-FCV-67 -133-A1-FCV-67-134-B1-FCV-67-138-A1-FCV-67 -1 39-A1-FCV-67-141-B1-FCV-67-142-A

Table/Sheet No.

3.*11 -5/WBN-MEB-O 1023 .1l-5/WBN-MEB-01023. 11-5/WBN-mEB--0102

3. l1-5/WBN-MEB-01023.11-5/WBN-MEB-0102

3. 11-4/WBN-MEB-01013.11 -4/WBN-MEB-O 1013.11-4/ WBN-MEB-0 1013.*11 -4/WBN-MEB-0101

3 .11-4/WBN-MEB-01023. 11-4/WBN-NEB-01023. 11-4/WBN-MEB-01023. 11-4/WBN-MEB-0102

3 .11-5/WBN-MEB-01023.11 -5/WBN-MEB-01023. 11-5/WBN-MEB-01023. 11-5/WBN-NEB-01023. 11-5/WBN-MEB-O 1023. 11-5/WBN-MEB-01023. 11-5,'WBN-MEB-01023. 11-5/WBN-MEB-01023. 11-5/WBN-MEB-0 1023.11 -5/WBN-MEB--01023 .11-5/WBN-MEB-01023.11-5/WBN-MEB-01023 .11-5/WBN-MEB-01023.11 -5/WBN-MEB-0 1023. 11-5/WBN-MEB-01023. 11-5/WBN-MEB-0102

EQS Sheet No./Revision No.

00EQUI~PMENT QUALIFICATION SHEET (EQS)

INDEXPage 11 of 13

WBN-MEB-67 -0137

WBN-MEB-67 -0139

WBN-MEB-67-0140

WBN-MEB-70-0141

WBN-MEB-70-0 1421

Manufacturer

LIMITORQUE

LT.MITORQUE

LIMITORQUE'

LIMITORQUE-

LIMITORQUE

Model No.

SMB-00

SHB-000

SHB-000

SMB-000 & 00

SMB-O000SMB-00

Component No.

1-FCV-67-1231-FCV-67-1251 -FCV-67 -127I-FCV-67-128I -F CV-6 7-146

1 -FCV-67 -1471-FCV-67-151-A1-FCV-67-152-B1-FCV-67-2231 -FCV-67 -458I-FCV-67-478

1-FCV-67-124I-FCV-67-126

1 -FCV-67-81I-FCV-67 -82

1 -FCV-70-130-FCV-70-221 -FCV-70-23I-FCV-70-251 -FCV-70-261 -FCV-70-271-FCV-70-341 -FCV-70 -641-FCV-70-74I-FCV-70-153I-FCV-70 -156

1 -FCV-70-89-B1-FCV-70-87-B

Table/Sheet No.

3. 11-6/WBN-MEB-01013. 11-6/WEN-MEB-Ol0l3. 11-6/WBN-MEB-01013 .11-6/WBN-MEB-01O13. 11-6/WBN-MEB--0101

3. 11-6/WEN-MEB-Ol0l3.11-6/ WBN-MEB-0 1013. 11-6/WBN-MEB-01013. 11-6/WBN-MEB-O1013. 11-6/WBN-MEB-01O13 .11-6/WBN-MEB-0101

3. 11-7/WBN-MEB-0 1023. 11-7/WBN-MEB-0102

3. 11-7/WBN-I4EB-01023 .11-7/WBN-MEB-0102

3.11-7/ WBN-MEB-0 1033.11-7/WBN-MEB-01033. 11-7/WBN-MEB-01033. 11-7/WBN-MEB-01033. 11-7/WBN-MEB-01033. 11-7/WBN-MEB-01033. 11-7/WBN-MEB-01033. 11-7/WBN-MEB-01033. 11-7/WBN-MEB-0 1033..11-7/WBN-MEB-0 1033.*1 1-7/WBN-MEB-0 103

3. 11-4/WBN-MEB-01023.*11 -4/WBN-MEB-0 102

0EFFECTIVE

DATEOCT 19:334

EQS Sheet No./Revision No.

WBN-MEB-70-0 144

WBN-NEB-70-0147

WBN-MEB-70-0148

WBN-MEB-72-0151

WBN-MEB-31-0 153

WBN-ME B-3 1-0154

WBN-MEB-65-O 156

0EQUIPMENT QUALIF ICAT ION SHEET (EQS)

INDEX

Manufacturer

LIMITORQUE

LIMITORQUE

LIMITORQUE

LIMITORQJE-

LINCOLN

Lincoln

ASCO

Model No.

SMB-000

SMB-000

SMB-000

SMB-000

284T, TV-2629

254T, 2756

8321A2E

Component No.

1-FCV-70-2I-FCV-70-3I-FCV-70-81 -FCV-70-91 -FCV-70-100-FCV-70-120-FCV-70-1940-FCV-70-197I-FCV-70-2070-FCV-70-208

1-FCV-70-1331-FCV-70 -134

1 -FCV-70-750-FCV-70-206

I-FCV-72-131 -FCV-72-34

0-A/c Circ PumpsA-A and B-B

MCR A/C Cire PumpsA-A and B-B

0-F SV-65-241I-FSV-65 -301-FSV-65-521 -F:SV-65 -531-F SV-65-10

Page 12 of 13

Table/Sheet No.

3. 11-6/WBN-NEB-01023.11-6/WBN-MEB-01023.*1 1-6/WBN-MEB-01023.11 -6/WBN-MEB-0 1023. 11-6/WBN-MEB-01023. 11-6/WBN-NEB-01023. 1l-6/WBN-NEB-01023.11-6/WBN-MEB-01023 .11-6/WBN-MEB-01023 .11 -6/WBN-MEB-0102

3. 11-7/WBN-MEB-0 1043. 11-7/WBN-MEB-0104

3.*1 1-6/ WBN-MEB-O 1023.11 -6/WBN-MEB-0 102

3. 11-7/WBN-MEB-01043.11-7/WBN-MEB-0104

(Mild Environment PerLOCFR5O .49)

(Mild Environment Pet10CFR.50.49)

3. 11-7/WBN-MEB-OlOS3 .11-7/WBN-KEB-01053 .11-7/WBN-MEB-01053.11 -7/WBN-MEB-0 1053. 11-7/WBN-MEB-0104

0-F SV-65-43 See EQS WBN-EEB-0093WBN-MEB-65-0 159 1

[EFFEC TIVEDATE

OCT 19; 3 )4

EQS Sheet No.IRevision No.

WBN-MEB-70-0 161

WBN-MEB-67-0 162

WBN-MEB-65-0 163

WBN-MEB-65-0 164

WBN-MEB-3-020 1

WBN-MEB-3-0202

WBN-MEB-46-0203

WBN-MEB-72-0204

0EQUIPMENT~ QUALIFICATION SHEET (EQS)

INDEX

Manufacturer

LIMITORRQUE

LIMITORQUE

ASCO

ASCO

PALSONS-PEEBLES

TERRY TURBINE

WESTINGHOUSE

Model No.

SMB-000

SMB-000

Hrr 8300 B58K.

HV206 -380

Frame T-400 7J

Component No.

1 -FCV-70-901 -FCV-70-92I-FCV-70-1401 -FCV-70-143

0-FCV-67-2050-F CV-67 -208

I-F SV-65-80-F&V-65-28-A0-F SV-65 -28-1

0-F SV-65-43

Aux PU Pump 1A-A,lB-B, 2A-A,21-B Motors

1 ,2-MTR-3-118D1 ,2-KMT-3-128D

Page 13 of 13

Table/Sheet No.

3. 11-7/WBN-MEB-01033. 11-7/WBN-MEB-01033. 11-7/WBN-MEB-0 1043.*11 -7/WBN-MEB-0 104

3. 11-6/WBN-MEB-0 1013. 11-6/WBN-NEB-O101

3. 11-7/WBN-NEB-0 1043.11 -7/WBN-MEB-01053. l1-7/WBN-MEB-0105

3. 11-7/WBN-MEB-0105

(Mild Environment Per1OCFR5O .49)

See EQS-WBN-EEB-MTR-1See EQS-WBN-EEB-MTR-1

1,2-Aux. PU Turbine (Mild Environment Per1A-S, 2A-S Controls 1OCFR.50.49)

GS-2

HSW2 0-CC S0-CCS0-cCS0-CCS0-CCS

PUMPPumpPumpPumpPump

C-S1AA2AA1 BB211

MotorMotorMotorMotorMotor

3. 11-7/WBN-MEB-02013. 11-7/WBN-MEB-02013. 11-7/WBN-14EB-02013. 11-7/WBN-MEB-02013. 11-7/WBN-MEB-0201

ELD

__ Rev is, cn R1 P, EQS No'. WBN-MEB-30-00O1i

e__ r- a-t TV.A ID No:

K See Appendix Y

1,121 EQUIPMENT QUALIFICATION SHEET (EQS)

M~anufacturcer and Model Number ASCO HT632OffiLO8

Verification .of Table Information (Table See Appencii::- UC

SEquipment Type - The equipment has been identified as per TVA ID number'

designations (e.d., MOV, SOV, etc.). LU s.

A'Location - The location has been identified (E.G., Inside PrimaryContainment, Annulus, Individually Cooled Rooms, Generaal Spaces, or U-

area affected by HELR outside primary containment).

ý Cmpne~nt -A unique TVA ID number has been assigned (e.g., l-FSV-66-3O0h.

X Function -A functional description of the component has been givene.g., Steam Generator Blowdown).

*.Contract No. , Manufacturer, and Model No. - The contract number,manufacturer, and model number has been given.

xzAbnormal or Accident Environment - All abnormal or accident environmentalconditions-applicable to this equipment have been identified either in

tables or by references to figures from tables.

x1Environment to Which Qualified - 7--a environment to which the equipmenthas been qualified is addressed -in either the tables or the enviro-nment-alanaly'sis attached.

SCategory - A category of a, b, c, or d has been defined for the equipment.

SOperation and Accuracy Required and Demonstrated - The operation 311d

accuracy required and demonstrated have been d6efined.

Qualification Status (chec!, if applicable, NA if not) Qualified Life ____

INA Qualification Report and M,?thod - A qualification report and the method

of qualification has 6Wqenffcnified.

NA Environmental Analysis - An environmental analysis has been done, attached,

to the EQS, and ine etyreviewed by the responsithe organization.

NA Qualification by Similaritly (If applicable) - A justif~cation for

-qualification by simiMTr~ty is at tached to the EQS con-sidering all the

above factors and referenced to the appropr'tate tables.

~iQualification of Several Exact Components (If arplicable) - When an EQSis used for more than one item, a list of all exact cc:".oone-ntLs are qiven

as an appendix with all references to appropriate tables with justification

for qualification considering.. all the above factors.

NA_ Interim1 Qualification (If applicable) - (bpen item) - Component has beendecterm-ined to be qualified only for a limited interim operation, an NCRhas been written, and plan of action has been determined to yield a

qualified component. Term of Interim Qualification ___

NCR No.

x Unqualified Component-(Cpen item) - (If applicable) - Component has been

determined' to-be u-nqualified; the flo:i is attached to EOS:

NCR num-,ber, reason for non-qualific-it~in, and justification of continued

N4CR No.. WBNTMEB8115R4

Sheet No. WBN-MEB-30-0001Rev. No. 2Appendix ISheet 1 of 1

Manufacture & Model No.: ASOO BT8320A108

Component: Solenoid Valve

Component No.

1-F SV-30-281-F SV-30 -291-F SV-30-601-FSV-30-69

Table/Sheet Number

3. ll-7/WBN-MEB-OO0l3.11-7/WBN-NEB-OO0l3. ll-7/WBN-MEB-OO0l3.11-7/WBN-MEB-0001

Prepared By:

Reviewed By:

JS. .34

EFFECT!VE

OCT Z-34

V

Sheet No. WBN-NEB-30-0001Rev. No. 2Appendix 2Sheet 1 of 1

The solenoj4 valves are required to operate in the following accidentenvironment:

Temperature:

Pressure:Relative Humidity:Radiation:

1950F (HELl; not to exceed 24 hours) 11OoF(LOCA; 30 days)14.55 psia max100% max40 yr - 1 x 106 rads; Accident -I x 107 rads

The manufacturer's specification for the solenoid valve are as follows:

Temperature:Pressure:Relative Humidity:Radiation:

34 70AtmosphericNEMA 4 Enclosure (Watertight)2 x 108 rads

Westinghouse has performed a safety analysis vhich qualified these valvesfor use in the accident environment associated vith inside containment(3500F, 1 x 10 rads, 1 year total integrated accident dose). Thebasic premise of this qualification is that there is no failure mode whichwould prevent this valve from obtaining and maintaining its safe position.Failure modes evaluated included: loss of air supply, electrical failurein the solenoid, degradation of materials of construction and binding dueto thermal expansion. This analysis is contained in report NS-CE--755(WEB 820401 200).

The above information provides adequate justification for continuedoperation. However, due to the lack of qualification documentation, TVAwill replace these valves with a qualified replacement.

Reference: TVA/WBN Environmental data drawings 47E235-48, -49, and

Prepared By: ______ýI;FA

Reviewed~ By: (~2,

rEFFECTIVE'D JA T0OCCT 1984

I IIUni t No. 1&Rcvision 0 1 I R2 R3 R4 'EQS No. WBN-MEB-30-0006

Dr -. ' .- ~ ~ VA IDNo:

'~' b-HTR-30-147A7-

& evicwer/Date Y'4 0~~17 -HTR-30-156BWBN EQUIPN QUALIFICATION SHEET (EQS) uJz

Manufacturer and Model Number Chromalox Tri-7648, 76" Long L

Verification-of Table Information (Table 3.11-7, sheet WBN-MEB-0002 -I

~*Equipment 'Typej - The equipment has been identified as per TVA ID numberdesignations e.d., MOV, SOy, etc.).

,Y Location - The location has been identified (E.G., Inside Primary ..

Containm int, Annulus, Individually Cooled Rooms, General Spaces, or Larea affected by HELB outside primary containment).L

X Component -A unique TVA ID number has been assigned (e.g., l-FSV-68-308).

x Function -A functional description of the component has been given(e-.g., Steam Generator Blowdown).

,x' Contract No., Manufacturer, and Model No. - The contract number,manufactur, and model ,pumber has been given.

*~Abnormal or Accident Environment - All abnormal or accident environmientalconditions applicable to this equipment have been identified either intables or by references to figures from tables.

SEnvironment to Which Qualified - T;.., environment to which the equipmenthas been qu~alified is addressed in either the tables or the environmentalanalysis attached.

* ( Category - A category of a, b, c, or d has been defined for the equipment.

KOperation and Accuracy Required and Demonstrated - The operation andaccuracy required and demonstrated have been defined.

Qualification Status (cher!k if applicable, NA if not) Qualified Life_____

NA_ Qualification Report and Me~thod - A qualification report and the methodof qualification has be dniid

NA Environmental Analysis - An environmental analysis has been done, attachedto the 'E'1S5 and independently reviewed by the responsible organization.

NA Qualification bySimiairjty (If applicable) - A justification forqualficationby imilarity is attached to the EQS considering all the

above factors and referenced to the appropriate tables.

_J(Qualification of Several Exact Components (If applicable) - When an EQSis used for more than one itemn, a list of all exact components are qivenas an' appendix~with all references to appropriate tables with justifica-ti-on:..:for qualification considering all the above factors.

A44 Interim Qualification (If applicable) - (Open item) - Component has beendetermined to be qualified only for a limited interim operation, an NCRhas been written, and plan of action has been determined to yield aqualified component. Term of Interim Qualification__________

NCR No.

*X UnqualifiedComponent-(Open item) - (If applicable) - Component has beendetermne~id to be unqualified; the following is attached to EQS:NCR number, reason for ncn-qualification, and justification of continuedoperation.

NCR No. WE.)L MrS gj .

Sheet No. WBN4-MEB-30-0006Rev. No. 2Appendix ISheet 1 of 1

The ABGTS heater controlsenvironmental conditions:

Temperature:Pressure:Relative Humidity:Radiation:

The ABCTS heater controlsconditions:

are required to operate in the following

Normal

10407ATM( -)80%1 x 106

Abnormal

11007ATM( -)90%NA

Accident

11007NANAIx104

vere designed to operate in the following

Temperature: 150OFPressure: AtmosphericRelative Humidity: 100%Radiation: Not specified

it is our engineering judgement that the heater controls can continue to

operate. However, the heater controls lack sufficient documentation and

will be replaced, prior to initial criticality.

Reference: TVA/WBN Environmental data drawings 47E235-48 and -49

Prepared by:

Reviewed by:

'I~- c~&-* C41 .k ~•i~94~f

EFFECTIVEDATE

0O01T !98 4

LJS.11

4

4 V.

R 1 so 0 .Ri RZj R3 R4 EQS No. wBN-MEB-65-0009

TVA ID No:

!r IDa te 0.. -TS-65-36 ______

WBN EQUIPMENI IJLFICATION SHEET (EQS) LManufacturer and Model Number Chromalox 106-114426-003>

CoVerification. of Table Information (Table 3.11-7, sheet WBN-MEB-0002 )-LU C-1)

~ quipment ype - The equipment has been identified as per TVA ID numberdeintos~~. MOV, SOV, etc.). LU

X Location - The location has been identified (E.G., Inside Primary J_Containment, Annulus, Individually Cooled Rooms, General Spaces, or U_

area affected by HELB outside primary containment). IL

X1.Component -A unique TVA ID number has been assigned (e.g., l-FSV-68-308).

SFunction -A functional description of the component has been given(e7g, Seam Generator Blowdown).

~.Contract No., M~anufacturer, and Model No. - The contract number,manufacture, and model number has been given.

SAbnormal or Accident Environment - All abnormal or accident environmentalconditions applicable to this equipment have been identified either intables or by references to figures from tables.

Environment to Which Qualified - Tthe environment to which the equipment,has been qualified is addressed in either the tables or the environmentalanalysis attached.

...•category - A category of a, b, c, or d has been defined for the equipment.

....1Operation and Accuracy Required and Demonstrated - The operation andaccuracy required and demonstrated have be-en dce-fined.

Qualification Status (chec%, if applicable, NA if not) Qualified Life_____

NA Qualification Report and Mi.thod - A qualification report and the methodof qualification has iTatfed

NA Environmental Analysis - An environmental analysis has been done, attachedto the E.QS, and independen'tly reviewed by the responsible oi-qanization.

NA Qualification by Similarity (If applicable) - A justification forqualification by similarity is attached to the EQS considering all theabove factors and referenced to the appropriate tables.

.1*Qualification of Several Exact Components (If applicable) - When an EQS -

is used for more than one item, a list of all exact components are qiven .

as an appendix with all references to appropriate tables with justificat.i-on;-:.--for qualification considering all the above factor-s..

_U&Interim Qualification (If applicable) - (Open item) - Component has beendetermined to be qualified only for a limited interim operation, an NCRhas been written, and plan of action has been determined to yield aquali~fied component. term of Interim Qualification __________

NCR No.

SUnqualifiedComponent-(Open item) - (If applicable) - Component has beendetermfined to be unqualified; the following is attached to EQS:NCR number, reason for non-qualification, and justification of continuedoperation.

NCR No. w&3b mEB Bits R4

unit no. 1 & z

IRevision 0 R R2 3 R4EQS No. WBN-IIEB-65-0010

rprer/DI t C b4al 4QTVA ID No:4 C __1O4-iTR-65-37B -

Reviewer/Date 0 -HTR-65-17A -7l

WBN EQUIPMENT QUALIFICATION SHEET (EQS) z

Manufacturer and Model Number Chromalox #196032951003>SL" CO

Verificatiort-of Table Information (Table 3.11-7, sheet WBN-HiEB-0002 Iý- (7

Equpmet Type - The equipment has been identified as per TVA ID numbe-(.deignatons7e.d., MOV, SOy, etc.).L

.ALocation - The location has been identified (E.G., Inside PrimaryContainment, Annulus, Individually Cooled Rooms, General Spaces, or. Uarea affected by HELB outside primary containment).

Component -A unique TVA ID number has been assigned (e.g., l-FSV-68-308).

...A..Function -A functional description of the component has been given*(eg.,S eam Generator Blowdown).

Contract No., Manufacturer, and Model No. - The contract number,manufacture, and model number has been given.

.Ž1.Abnormal or Accident Environment - All abnormal or accident environmentalconditions applicable to this equipment have been identified either intables or by references to figures from tables.

%.Environment to Which Qualified - T;.:e environment to which the equipmenthas been qualified is addressed in either the tables or the environmentalanalysis attached.

..X.Category - A category of a, b, c, or d has been defined for the equipment.

.~.Operation and Accuracy Required and Demonstrated - The operation andaccuracy required and demonstrated have b-een-defined.

Qualification Status (chec!, if applicable, NA if not) Qualified Life_____

NA Qualification Report and M,?thod - A qualification report and the methodof qualification has biiii7Thtinfied.

NA Environmental Analysis - An environmental analysis-has been done, attachedto the EQS, and Ti~T63p~ndently reviewed by the responsible organization.

NA Qualification by Similarity (If applicable) - A justification forqualification by similarity is attached to tHe'&EQScdbnsidering all theabove factors and referenced to the appropriate tables.

A§Qualification of Several Exact Components (If applicable) - When an EQSis used for more than one itemn, a list of all exact components are qiven.as an appendix with all references to appropriate tables with justifica-tion.,:-for qualification considering all the above factors.

SInterim Qualification (If applicable) - (Open item) - Component has beendetermined to be qualified only for a limited interim operation, an NCRhas been written, and plan of action has been determined to yield aquali~fied component. Term of Interim Qualification__________

NCR No. __ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _

_y,. UnqualifiedComponent-(Open item) - (If applicable) - Component has beendeter~mfii~d to be unqualified; the follow.ing is attached to EQS:NCR number, reason for ncn-qualificat-ion, and justification of continuedoperation.

NCR No. W-6 m~ BUS P-4

[Revsion jRI R2

Reviewer/Date iMVývR,7

- p - Va1 1 Sh3liv.

EQS No. -WBN-MEB-30-OO11

TVA I D No:See Appendix I

/

WBN EQUIPMENT QUALIFICATION SHEET (EQS)

Manufacturer and Model Number Baldor M3710T>

Verificatioo. of Table Information (Table See Appendix I UJ

.2.EquipmTen~t~ 'Tye - The equipment has been identified as per TVA ID numberudesignaitions (e.d., MOV, SOy, etc.). L

,YA Location - The location has been identified (E.G., Inside Primary U. C

Containment, Annulus, Individually Cooled Rooms, General Spaces, or U

area affected by HELB outside primary containment). LU

... Ž.Component -A unique TVA ID number has been assigned (e.g., l-FSV-68-30 _

.. Z.Function -A functional description of the component has been given(eTg, Seam Generator Blowdown).

SContract No., Manufacturer, and Model No. - The contract number,manufacture, and model number has been given.

SAbnormal or Accident Environment - All abnormal or accident environmentalconditions applicable to this equipment have been identified either intables or by references to figures from tables..

X1Environment to Which Qualified - Th.e environment to which the equipmenthas been qualified is addressed in either the tables or the environmentalanalysis attached.

.A.category - A category of a, b, c, or d has been defined for the equipment.

JZ, Operation and Accuracy Required and Demonstrated - The operation anid

accuracy required and demonstrated have been defined.

Qualification Status (check, if applicable, NA if not) Qualified Life_____

_NA Qualification Report and Mi.thod -n A qualification report and the methodof qualification has bqen Tdiitified.

NA Environmental Analysis - An environmental analysis has been done, attachedto the E.QS, and indepiiidently reviewed by the responsible organization.

NA Qualification by Similarity (If applicable) -A justification forqulificationbysimilarity is attached to the EQS cbonsidering all the

above factors and referenced to the appropri3te tables.

X*Qualification of Several Exact Components (If applicable) - When an EQSis used for-more than Ione item, a list of all exact components are qivenas anr appendix with all references to appropriate-tables with justificationfor qualification considering all the above~factors.

NA Interim Qualification (If applicable) - ýOpen item) - Component has been- etermined to be qualified only for a limited interim operation, an NCR

has been written, and plan of action has been determined to yield aqualified component. Term of Interim Qualification_______

NCR No.

X Unqualified Component-(Open iten) - (If applicable) - Component has beendetermined to be unqualified; the fcllo,.%inq is attached to EQS:NCR number, reason for non-qualification, and justification of continuedoperation.

NCR No. WBN MEB 8115 R4

Sheet No. WBN-MEB-30-0011Rev. No. 2Appendix 2Sheet 1 of 1

The containment spray pump room cooler fan motors are required to operatein the following accident environment:

Temperature: 1100F max (LOCA - 30 days)Pressure, Relative Humidity: NARadiation: 40 yr - 1 x 101 rads; Accident - 1 x 107 rads

The manufacturer's specifications for the motors are as follows:

Temperature: 1040F

Radiation: Not Specified

TVA has analyzed the materials of subject motors to the above accidentcondition and determined that the motors could continue to operate. It isour engineering judgement that the above motors can continue to operate.However, due to lack of qualification documents, TVA will replace theseitems with qualified and documented motors. TVA Contract 84K5-834550-1 hasbeen awarded to Reliance Electric Company for 1K qualified motors. Thequalified motors will be installed prior to initial criticality.Reference: TVA/WBN Environmental data drawing 47E235-81

Prepared by: & *Reviewed by:__ _ _ _ _ _ _

rEFFECTIVE!GS*1 DA T E1- :

Revision R1 R2 ESN. WBN-MEB-30-0012

'reparer/Date #fx oZ- TVA ID No:

leviewer/Date ýf ee Appendix 11

WBN EQUIPMENT QUALIFICATION SHEET (EQS) ,

Mlanufacturer and Model Number Baldor M3615T

Verificatiog, of Table Informiation (Table See Appendix I U 7

~Eq~uipmet Type - The equipment has been identified as per TVA ID numbe Udesignations (e.d., MOV, SOy, etc.). L

a.Location - The location has been identified (E.G., Inside Primary L_Containment, Annulus, Individually Cooled Rooms, General Spaces, or II"

area affected by HELB outside primary containment). L

SComponent -A unique TVA ID number has been assigned (e.g., l-FSV-68-308).

VFunction -A functional description of the component has been given(e.g., Steam Generator Blowdown).

...1Contract No., Manufacturer, and Model No. - The contract number,manufacturer, and model number has been given.

.2•Abnormal or Accident Environment - All abnormal or accident environmentalconditions applicable to this equipment have been identified either intables or by references to figures from tables.

KEnvironment to Which Qualified - The environment to which the equipmenthas been qualified is addressed in either the tables or the environmentalanalysis attached.

,*l.Category - A category of a, b, c, or d has been defined for the equipment.

.I..Operation and Accuracy Required and Demonstrated - The operation andaccuracy required and demonstrated have been defined.

Qualification Status (check~ if applicable, NA if not) Qualified Life_____

NA Qualification Report and Me3thod - A qualification report and the methodof qualification has bieenf identified.

NA Environmental Analysis - An environmental analysis has been done, attachedto the EEQS, and inde;•e-ndently reviewed by the responsible organization.

NA Qualification bySimilarity (If applicable) - A justification forqualificationby similarity is attached to the EQS considering all theabove factors and referenced to the appropriate tables.

g ualification of Several Exact Components (If aoplicable) - When an EQSis used for more than one iterm, a list of all exact components are given:as an appendix with all references to appropriate tables with justification-. -.for qualification considering all the above factors.

N.A Interim Qualification (If applicable) - (Open item) - Component has been- etermined to be qualified only for a limited interim operation, an NCR

has been written, and plan of action has been determined to yield a -

qualified component. Term of Interim Qualification -

NCR No.

X UnqualifiedComponent-(Open item) - (If applicable) -Component has beende-termirii-d to be unqualified; the following is attached to EQS:NCR number, reason for non-qualificati',n, and justification of continuedoperation.

NCR No. WBN NEB 8115 R4

$beet No. WBN-MEB-30-0012Rev. No. 2Appendix 2Sheet 1 of 1

The RER pump room cooler fan motors and SIS pump room cooler fan motors arerequired to operate in the following accident environment:

Temperature: 110OF nax (LOCA - 30 days)Pressure, Relative Humidity: NARadiation: 1 x 107 rads

The manufacturer's specifications for the motors are as follows:

Temperature: 104OFRadiation: Not Specified

TVA has analyzed the materials of subject motors to the above accidentconditions and determined that the motors could continue to operate. It isour engineering judgement that the above motors can continue to operate.However, due to lack of qualification documents, TVA will replace theseitems with qualified and documented motors. TVA contract 84K5-834550-1 hasbeen awarded to Reliance Electric Company for 11 qualified motors. Thequalified motors will be installed prior to initial criticality.Reference: TVA/WBN Environmental data drawings 471235-74, -75, and -79

Prepared by:

Reviewed by: 1i-K~cU ),

LJS.19 FEFFECT-I V E-DATE

0C 6084

Revsin ~ R2EQSrw-O. WBN-MEB-30-0013

PreprerDat 441 uuý ýýAZ 014 t ZTVA`ID No:k., -MTR-30-190 -

- 1-MTR-30-191WBN EQUIPMENT QULFCATION SHEET (EQSYI)

Manuactrer nd ode Numer aldo M234TLI

Manfacurr ad ode Nube Bado M23>Verificationý_of Table Information (Table 3.11-7, sheet WBN-M4EB-0004 1J-uJ

**y Equipment Type - The equipment has been identified as per TVA ID numberi Lidesignations Te.d., MOV, SOV, etc.). I!

.. Q.Location - The location has been identified (E.G., Inside PrimaryContainment, Annulus, Individually Cooled Rooms, General Spaces, or UL.area affected by HELB outside primary containment). ILU

Component -A unique TVA ID number has been assigned (e.g., l-FSV-68-30h)Function -A functional description of the component has been given(e~g. Steam Generator Blowdown).Contract No., Manufacturer, and Model No. - The contract number,manufacture, and model number has been given.

Abnormal or Accident Environment - All abnormal or accident environmentalconditions applicable to this equipment have been identified either intables or by references to figures from tables.

~.Environment to Which Qualified - Th'-e environment to which the equipmenthas been qualified is addressed in either the tables or the environmentalanalysis attached.

..1Category - A category of a, b, c, or d has been defined for the equipment-..

.. Operation and Accuracy Required and Demonstrated - The operation and'accuracy required and demonstrated have beein de-fined.

Qualification Status (check if applicable, NA if not) Qualified Life_____NA Qualification Report and M-ithod - A qualification report and the method

of qualification has bYi~enR7eWffied.NA Environmental Analysis - An environmental analysis has been done, attached

to the EQS, and inde5Jndently reviewed by the responsible organization.

_NAQua~1ification by Similarity (If applicable).- A~jistification forqualification by similarity is attached to- the'EQS considering all theabove factors and referenced to the appropriate tables.

_*ý§_Qualification of Several Exact Components (If applicable) - When an EQSis used for more than one item, a list of all exact components are givenas an appendix with all references to appropriate-tables with justifica-tion.--for qualification considering all the aboVe factors. ~

!ip. Interim Qualification (If applicable) -'("Open item) - Component has been'determined to be qualified only for a limited interim operation, an NCRhas been writt~en, and plan of action has been determined to yield aqualified component. term of Interim Qualification-

NCR No.

x UnqualifiedComponent-(Open item) - (If applicable) -Component has beendetermine~d to be unqualified; the following is attached to EQS:NCR number, reason for non-qualificatLion, and justification of continuedoperation.

NCR No. WBN MEB 8115 R4

Sheet No. WBN-MEB-30-0013Rev. No. 2Appendix ISheet 1 of 1

The CCS &AFW pump cooler fan motors are required to operate in thefollowing accident enviroment:

Temperature: 1280F max (HELD - not to exceed 24 hours)Pressure: 14.45 paia max (HELD)Relative Humidity: 100% max (EELS - 24 hours max)Radiation: 40 yr - 5 x 102 rads; Accident - (1 x 104 rads (LOCk)

The manufacturer's specifications for the motors are as follows:

Temperature: 1040FRadiation: Not Specified

TVA han analyzed the materials of subject motors to the above accidentconditions and determined that the motors could continue to operate.However, due to lack of qualification documentation, TVA will replace theseitems with qualified and documented motors. TVA Contract 84K.5-834550-2 hasbeen avarded to Louis Allis Division for 11 qualified motors. The qualifiedmotors will be installed prior to initial criticality.Reference: TVA/WBN Environental data drawings 47E235-52, -53i -54,

and -55

Prepared by: A/?Reviewed by:

LJS. 20

- - -Unit No. SC PWLi

-R1 R2 R3 R4 EQS No:' WBN-MEB-30-0015

___ ~ ~TVA ID No:'rI~-ite.A~l1 - .~iLSee Appendix 'I

zr/Date '____i j_________________- WBN EQUIPMENT QUALIFICATION SHEET (EQS)

Manufacturer and Model Number Baldor M3610T

Verification aK Table Information (Table See Appendix I

A'Equipment Type - The equipment has been identified as per TVA ID numberdes ignat io6n s (e. d. , MOV, SOy, etc.).]

ArLocation - The location has been identified (E.G., Inside PrimaryContainment, Annulus, Individually Cooled Rooms, General Spaces, or Iarea affected by HELB outside primary containment). L ?

jQComponent - A unique TVA ID number has been assigned (e.g., l-FSV-68-3O8).7.~jFunction - A functional description of the component has been given

(e~g., Steam Generator Blowdown).*~jContract No., Manufacturer, and Model No. - The contract number,

manufacturer, and model number has been given.

conditions applicable to this equipment have been identified either intables or by references to figures from tables.

SEnvironment to 'Which Qualified - T-.2- environment to %w.hich the equip-menthia-sbeen qUalified is addressed in either the tables or the environmentalanalysis attached.

Category - A category of a, b, c, or d has been defined for the equipment.~QOperation arid Accuracy Required and Demonstrated - The operation .-td

accuracy required and demonstrate have been defined.

_Qualification Status (hc if applicable, NA if not) Qualified Life_____NA Qual-ificatilon Report and fi.ýthnd - A qualification report and the method

of qualification has bver ide-ntified.NA Environr,-ental__Analysis - An environmental analysis has been done, attached

to the EQand in 3_-.ý_-derntly reviewed by the responsible organization.NA Qualifirc.ticin by SiriilariLy (If applicable) - A justification for

qua~l ifi-cPaL~on -by similar~ity is attached to the EQS considering all theabove factors and referenced to the appropriate tables.

9Qualificat-ion of Several- Exact Comp~onents (If applicable) - When an EEQSis used for m~ore than one item, a list of all exact components are qivenas an appendix with all references to appropriate tables with justificationfor qualification considerinri all the above factors.

1NA Interim Qualification (If' applicable) - (Open item) - Component has beendetermined to be qualified only for a limited interim operation, an NCRhas been written, and plan of action has been determined to yield aqualified component. Term of Interim Qualification - ___[

NCR No. Ix UnqualifiedComponent-(open item) - (If applicable) - Component has been

determnicdf to be unqualified; the frll0%winq is attached to EOS:NCR number, reason for ncn-qualification, and justification of continuedoperation.

NCR No. IWB\ MBEB 8115 R4

Sheet No. WBN-MEB-30-0015Rev. No. 2Appendix 2Sheet 1 of 1

The CCS booster and spent fuel pit pump cooler fan motors are required tooperate in the following accident environment:

Temperature: 1290F max (HELBE not to exceed 24 hours)Pressure: 14.45 psia max (HELD)Relative Humidity: 100% (24 hours max)Radiation: 40 yr - 5 x 102 rads; Accident - (1 x 10 rads (LOCA)

The manufacturer's specifications for the motors are as follows:

Temperature: 104OFRadiation: Not specified

TVA has analyzed the materials of subject motors to the above accidentconditions and determined that the motors will continue to operate.However, due to lack of qualification documentation, TVA will replace theseitems with qualified and documented motors. TVA contract 84[5-834550-1 hasbeen awarded to Reliance Electric Company for 1E qualified motors. Thequalified motors will be installed prior to initial criticality.Reference: TVA/WBN Environmental data drawings 47E235-46 and -47

Prepared by:

Reviewed by:

/g~

C F T 1 iVUAT E

0 U f 4

LJS. 23

I-I-I- -. .-. ~p *~ I IRc~v~1nn 0 A RI R2 RI R&

E relparer/Date __1 /411 -., I 1I

U1I 10 I V .,u.

EQS No. WB-ME-30-0016

TVA ID No:

~cv cw r/ at Ov jL' ý1&-L See Appendix I

WBN EQUIPMENT QUALIFICATION SHEET (EQS)

Manufacturer and Model Number Baldor M3611T

Verificatior,.of Table Information (Table See Appendix I r

~•.Equipment Type - The equipment has been identified as per TVA ID number~designations (e.d., MOV, SOy, etc.).

Location - The location has been identified (E.G., Inside Primary IContanm nt, Annulus, Individually Cooled Rooms, General Spaces, or

area affected by HELR outside primar~y containment). LUL

....~Component -A unique TVA ID number has been assigned (e.g., I-FSV-68-3081

SFunction -A functional description of the component has been given(-e.g., Steam Generator Blowdown).

SContract No., Manufacturer, and Model No. - The contract number,manufacture, and model number has been given.

*.A.Abnormal or Accident Environment - All abnormal or accident environmentalconditions applicable to this equipment have been identified either intables or by references to figures from tables.

SEnvironment to Which QUalified - Thýa environment to which the equipmenthas been qualified is addressed in either the tables or the environmentalanalysis attached.

X' Category - A category of a, b, c, or d has been defined for the equipment.

)(Operation and Accuracy Required and Demonstrated - The operation and.accuracy required and demonstrated have been defined.

Qualification Status (chec-? if applicable, NA if not) Qualified Life_____NA Qualification Report and ftithod - A qualification report and the method

of qualification has biiee-n etified.NA Environmental Analysis - An environmental analysis has been done, attached

to the EQS, and indi67Jýndently reviewed by the responsible organization.

NA gu i~fication by Similarity (If applicable) - A'justification forqualification by similarity is attached to- the EQS considering all theabove factors and referenced to the appropriate tables.

_.,Y Qualification of Several Exact Components (If applicable) - When an EQSis used for more than one item, a list of all exact components are qiven

*as an appendix with all references to appropriate tables with justification':-*- - for qualification considering all the above factors.

NA_ Interim Qualification (If applicable) - ('Open item) - Component has been- determined to be qualified only for a limited interim operation, an NCR

has been written, and plan of action has been determined to yield aqualified component. Term of Interim Qualification__________

NCR No.y UqualifiedComponent-(Open iten) - (If applicable) - Component has been

-determne~hd to be unqualified; the frllo%-ing is attached to EQS:NCR number, reason for non-qualificatinn, and justification of continuedoperation.

NCR No. WBNMEB8115R4

Sheet No. WBN-MEB-30-0016

Rev. No. 2Appendix 2Sheet 1 of 1

The vorst case accident environment condition from Appendix I in as

follows: EGTS cooler fan motors and cent chg pump room cooler fan motors:

Temperature: 110OF max (LOCA - 30 days); 1950 max (HELB - not to

exceed 24 hours)Pressure: NA (LOCA); 14.45 psia max (HELB)

Relative Humidity: NA (LOCA); 100% max (HELB - 24 hours max)

Radiation: 40 yr - 1 x 106 rads accident - 1 x 107 rads (LOCA)

The manufacturer' s specifications for the motors are as follows:

Temperature: 104 0FRadiation: Not specified

TVA has analyzed the materials of subject motors to the above accident

conditions. It is our engineering judgment that the above motors can

continue to operate. However, due to lack of qualification documentation,

TVA will replace these items with qualified and documented motors. TVA

contract 84K5-834550-1, -2 has been awarded to Louis Allis Division (-l)

and Reliance Electric Company (-2) for 1E qualified motors. The qualified

motors will be installed prior to initial criticality.

Reference: TVA/WBN Environmental data drawings .47E235-489 -49, -56, -57,

-66, -67, -78, and -79

Prepared by:

Reviewed by: L L

DATELJS.25A^6

.i.ms ioil EQS No'. WBN-MB-B-65-0030

I Pr: ~er/ateTVA I D No:I_______ ~L -See Appendix'i

WBN EQUIPMIENT QUALIFICATION SHEET (EQS),

Manufacturer and Model Number ASCO HV202300-IRF

Verification vf Table Information (Table See Appendix I ) -'-

SEquipmient Type - The equipment has been identified as per TVA ID numberý F-

des-ignations (e.d., MOV, SOy, etc.).

Location - The location has been identified (E.G., Inside PrimaryL.QEContainment, Annulus, Individually Cooled Rooms, General Spaces, orarea affected by HELR outside primary containment).

~jComponen- A unique TVA ID number has been assigned (e.g., I-FSV-68-30~T

2<Function -A functional description of the component has been given(e.g., Steam Genera'tor Blowdown).

A'< Contract No., Manufacturer, and Model No. - The contract number,manufacturer, and model number has been given.

Abnormal or Accident Environment - All abnormal or accident environmentalconditions applicable to this equipment have been identified -either intables or by references to figures from tables.

Environment to Which Qualified - Th:,e environment to which the equipment,asbeen qualified is addressed in either the tables or the environmental

analysis attached.

Categor - A category of a, b, c, or d has been defined for the equipment.

Operation and Accuracy Required and Demonstrated - The operation ond

accuracy required and demonstrated have been defined.

.Qualification Status (kcher_. if applicable, NA if not) Qualified Life_____

N A Qualification Report and M-?thod - A qualification report and the methodof qualification has -bqý'ýnfde-ntified.

NA Environnental Analysis - An environmental analysis has been done, attached-to the EQ'S, and intý7)-ndently reviewed by the responsible organization.

N A Qualification by Sin-*lari~y (If applicable) - A justification forqualification by similarity is attached to the EQS considering all theabove factors and referenced to the appropriate tables.

SQualification of Several Exact Components (If applicable) - When an EQSis used for more than one item, a list of all exact components are ciivenas an- appendix with all references to appropriate tables with justificatioffPfor qualification considering all the above factors.

N A Interim Qualification (If applicable) - (Open item) - Component has beendeterminied to be qualified only for a limited interim operation, an N'CRhas been written, and plan of action has been determined to yield aqualified component. Term of Interim Qualification ___

NCR Nlo.

x UnqualifiedComponent- (Open item) - (If applicable) - Component has beendetermined to be unqUalified; the frllo%,inq is attached to EQS:NCR number, reason for ncn-qualific~ntion, and justification of continuedoperation.NCR No. WBNMEB8115R4

Sheet No. WBN-MEB-65-0030Rev. No. 2Appendix 2Sheet 1 of 1

The solenoid valves were required to operate in the following accidentenvironment:

Temperature: 1100F max (30 days max)Relative Humidity: NAPressure: NARadiation: 40 yr - 1 x 106 rads; Accident - 3 x 107 rads

The manufacturer's specifications for the solenoid valves are as follows:

Temperature: 3470FPressure: AtmosphericRelative Humidity: NEMA 4Radiation: 2 x 108 rads

Westinghouse has performed a safety analysis which qualified these valvesfor use in the accident environment associated with inside containment(3500F, 1 x 108 rads, 1 year total integrated accident dose). Thebasic premise of this qualification is that there is no failure mode whichwould prevent this valve from obtaining and maintaining its safe position.Failure modes evaluated included: loss of air supply, electrical failurein the solenoid, degradation of materials of construction and binding dueto thermal expansion.

This analysis is contained in report NS-CE-755 (NEB 820401 200).

The above information provides adequate justification for continuedoperation. However, due to the lack of qualification documentation TVAwill replace these valves with 1E qualified replacements.

Reference: TVA/WBN Environmental data drawing 47E235-78

Prepared by:

Reviewed by: ________________

LJS.l0

Reiin R1 R2 R3 R4

EQUIP ENT QULIFICATIIN SHEET (R3)

Unit No. 1EQS No. WBN-3FBl.Qr117TVA ID No.

See Appendix 1

Manufacturer and Model No.Verification of Table Information (Ta

Asco HTX 8316E35E

ible 3.11-7 Sheet WBN-MEB-101

x Eqimn p - The equipment has been identified as per TVA ID numberdeinations (such as, MOV, SOy).

" Location - The location has been identified .(such as, inside primaryco'ntainment, annulus, individually cooled rooms, general spaces, or areaaffected by HELB outside primary containment).

x Component -A unique TVA ID number has been assigned (such as, 1-FSV-68-308)." Function -A functional description of the component has been given (such as,

steam generator blowdown).x Contract No., Manufacturer, and Model No. - The contract number, manufacturer,

and model number have been given.x Abnormal or Accident Environment - All abnormal or accident environmental

conditions applicable to this equipment have been identified either in tables orby references to figures from tables.

x Environment to Which Qualified - The environment to which the equipment has been- qualified is addressed in either the tables or the environmental analysisattached..Category - A category of a, b, c, or d has been defined for theequipment.Operation and Accuracy Required and Demonstrated - The operationand accuracy required and demonstrated ha-ve been defined.

Qualification Status (check if applicable, NA if not)Qualified Life (If equipment is qualified, i"ndicate the qualified life with anumerical en-try): ____

X Qualification Repor-t andMethod - A qualification report and the method of- qualificati-on has been identified on the Table Input Data Sheet (TIDS).X Environmental Analysis - An environmental analysis has been done, attached to

NAthe EQS, and independetly reviewed by the responsible organization.NA Qualification by Similarity (If applicable) - A justification for qualification

by similarity is attached to the EQS considering all the above factors andreferenced to the appropriate tables.

X Qualification of Several Exact Components (If applicable) - When an EQS is usedfor more than one item, a list of all exact components is given as an appendixwith all references to appropriate tables with justification for qualification

*considering all the above factors.NA Interim Qualification (If applicable) - (Open item) - Component has been

determined to be qualified only for a limited interim operation, an NCR hasbeen written, and plan of action has been determined to yield a qualifiedcomponent.Term of Interim QualificationNCR No.

X Unqualified Compont - (Opendetermined to be unqualified;reason for non-qualification,NCR No. WBN-MEB-8115 R4

! temtheand

1) - (if applicable) - Component has beenfollowing is attached to EOS: NCR number,Justification of continued operation..

E F M E C T I VODATE I

O CT1

x

x

Sheet No. WBN-IIEB-30-0117Appendix IISheet 1 of 1Revision 2

The solenoid valves are required to operate in the following accidentenvironment:

Temperature 1100 PPressure ATHRelative Humidity 90%Radiation 1 x 106 rads - (40 years); 1 x 10

(accident)

The manufacturer's specification for the solenoid valves is as follows:

Temperature 1400 F'Pressure ATMRelative Humidity NEMA 4 enclosureRadiation 4 x 105 rads

The accident conditions with the exception of radiation are within themanufacturer's specifications. These solenoid valves have viton dynamicseals. Viton is used in a variety of high-temperature applications and hasbeen tested to a radiation environment on the order of 1 x 106 radswithout significant degradation. These valves are the forerunner of thepresently qualified valves per ASCO report AQS 21678/TR, revision A.

Westinghouse has performed a safety analysis which qualified these valvesfor use in the accident environment associated with inside containment(3500F, 1 x 108 rads, 1 year total integrated accident dose). Thebasic premise of this qualification is that there is no failure mode whichwould prevent this valve from obtaining and maintaining its safe position.Failure modes evaluated included: loss of air supply, electrical failurein the solenoid, degradation of materials of construction and binding dueto thermal expansion. This analysis is contained in report NS-CE-755(NEB 820401 200).

Therefore, it is our engineering judgement that these valves can continueto operate. However, due to lack of qualification documents, TVA willreplace these items with qualified and documented valves.

Reference: Drawing 47E235-48 RI

Preparled By/~J Z

Approved By: __ _ _

DEO2;LJS.68

Unit No. 1EQS No. WBN-D.EB-30119[Revision ii R2 TVA ID No.

Preprer/ate Y'7See Appendix I

ýWBEOUIP E'NT QUALIFICATION SHEET (R3)

Manufacturer and Model No. ASCO HTX8316E35EVerification of Table Information (Table 3.11-7 sheet WBN-MEB-0102

Eqimn Type The equipment has been identified as per TVA ID numberdesignations (such as, MOV, SOy).

**Location - The location has been identified (such as, inside primarycontaiinment, annulus, individually cooled rooms, general spaces, or area

Saffected by HELB outside primary containment).Component -A unique TVA ID number has been assigned (such as, 1-FSV-68-308)."Function- A functional description of the component has been given (such as,steam generator blowdown).

S Contract No., Manufacturer, and Model No. - The contract number, manufacturer,and model number have been given.

S Abnormal or Accident Environment - All abnormal or accident environmentalconditions applicable to this equipment have been identified either in tables orby references to figures from tables.

S Environment to Which Qualified - The environment to which the equipment has beenqualified is addressed in eithr the tables or the environmental analysisattached.-

SCategory -A category of a, b, c, or d has been defined for theequipment.

X( Operation and Accuracy Required and Demonstrated - The operationand accuracy required and demonstrated have been defined.

Qualification Status (check if applicable, NA if not)Qualified Life (If equipment is qualified,15indicate the qualified life with anumerical ent-ry): ____X ualification Report and Method - A qualification report and the method ofqualification has been identified on the Table Input Data Sheet (TIDS).K* Environmental Analysis - An environmental analysis has been done, attached tothe EQS, and independently reviewed by the responsible organization.

Jý Qualification by Similgarity (If applicable) - A justification for qualificationby similarity is attached to the EQS considering all the above factors and

X referenced to the appropriate tables.K Qualification of Several Exact Components (If applicable) - When an EQS is usedfor more than one item, a list of all exact components is given as an appendixwith all references to appropriate tables with justification for qualificationconsidering all the above factors.

SInterim Qualification (If applicable) - (Open item) - Component has beendetermined to be qualified only for a limited interim operation, an NCR hasbeen written, and plan of action has been determined to yield a qualifiedcomponent.Term of Interim Qualification

SNCR No.XUnqualified-Component - (Open item) - (If applicable) - Component has been

determined to be unqualified; the following is attaLhed. to EOQS: _NCR number,reason for non-qualification, and justification of :otp~e -ppq-~pNCR No. WJBN-MEB-8115 R4 L. 'k

D ATEGOF, 1984

EQSI

Sheet No. WBN-HEB-30-0119Appendix 11Sheet 1 of 1Revision 2

The solenoid valves are required to operate in the following accidentenvironment:

Temperature: 110 degrees FPressure: ATHRelative Humidity: 90 percentRadiation: 1 x 106 rads - (40 year); 1 x 104 - (accident)

The manufacturer's specification for the solenoid valves is as follows:

Temperature: 140 degrees FPressure: ATMRelative Humidity: Nema 4 enclosuresRadiation: 4 x 105 rads

The accident conditions, with the exception of radiation, are within themanufacturer's specifications. These solenoid valves have viton dynamicseals. Viton is used in a variety of high-temperature applications and hasbeen tested to a radiation environment on the order of 1 x 106 radswithout significant degradation.

Westinghouse has performed a safety analysis which qualified these valvesfor use in the accident environment associated with inside containment(3500F, 1 x 108 rads, 1 year total integrated accident dose). Thebasic premise of this qualification is that there is no failure mode whichwould prevent this valve from obtaining and maintaining its safe position.Failure modes evaluated included: loss of air supply, electrical failurein the solenoid, degradation of materials of construction and binding dueto thermal expansion. This analysis is contained in report NS-CE-755(NEB 820401 200).

Therefore, it is our engineering judgment that these valves can continue tooperate for an interim period. However, due to lack of qualificationdocuments, TVA will replace these items with qualified and documentedvalves.

Reference: Drawing 47E235-56 RO

Prepared by: (ON / vpiReviewed by: .& ~ 9 9 f

DEO2:LJS.64 [EE C T IV E

DATET 1934___

Revision ~U R2 1 R3 R4

Preparer/Date I~ i~Reviewer/Date I?4Ak

Unit No. 1EQS No. MEB-30-.0121TVA ID No.

i-ZS-30-1O-A

/'EQUIPMENT QUALIFICAiION SHEET (R3)

M~ufacturer and Model No. NAMCO - Snaplock Controls ZA74Q:Verificati~on of Table Information (Table 3.11-4 Sheet WBN-MEB-0101

x EquipmentTye - The equipment has been identified as per TVA ID numberdeinations (such as, MOY, SOy).

x Location - The location has been identifiled (such as, inside primarycontainment, annulus, individually cooled rooms, general spaces, or* areaaffected by HELB outside primary containment).

x Component -A unique TVA ID number has been assigned (such as, 1-FSV-68-308).x Funcionth A functional description of the component has been given (such as,

steam generator blowdown).x Contract No., Manufacturer, and Model No. - The contract number, manufacturer,

and model number have been given.x Abnormal or Accident Environment - All abnormal or accident environmental

conditions applicable to this equipment have been identified either in tables orby references to figures from tables.

x Environment to Which Qualified - The environment to which the equipment has beenqualified is addre-ssed in either the tables or the environmental analysisattached.

X Category - A category of a, b, c, or d has been defined for theequipment.

X Operation and Accuracy Required and Demonstrated - The operationand accuracy required and demonstrated have been defined.

Qualification Status (check if applicable INA if not)Q ualified Life (If equipment is qualified,7indicate the qualified life with anumerical entry): 4 Yeils

x Ouallflcation Repor-t and Method - A qualification report and. the method ofqualification has been ide-ntFified on the Table Input Data Sheet (TIDS).NA Environmental Analysis - An environmental analysis has been done, attached tothe EQS, and independently reviewed by the responsible organization.NA Qualification by Similarity (If applicable) - A justification for qualificationby similarity is attached to the EQS considering all the above factors andreferenced to the appropriate tables.

x qualification of Several Exact Components (If applicable) - When an EQS is usedfor more than one 'item, a list of all exact components is given as an appendixwith all references to appropriate tables with justification for qualificationconsidering all the above factors.

NA Interim Qualification (If applicable) - (Open item) - Component has beendetermined to be qualified only for a limited interim operation, an NCR hasbeen written, and plan of action has been determined to yield a qualifiedcomponent.Term of Interim Qualification_______________________NCR No..

NA Unqualified Component - (Ope tem) - (If applicable) - Component has beendetermined to be unqualified; the following is attached to EQS: NCR number,reason for non-qualification, and justification of, ration.NCR No. EFFIECTIVE

DATEEQS J8

Sheet No. WBN-MEB-30-0l21Rev. No. 2Appendix ISheet 1 of I

These switcbies are required to operate in the environment shown on TVAdrawing 47EI35-41 RO, and summnarized below.

Operational Temp. Rel. Pressure 40 year Integrated AceCondition OF Hum. (PSIA) Radiation (LADS) Dose (LADS)

1 Avg. 100 40% ATM(-) NA NAMax. 110 80% 14.7 2 x107 NAMin. 60 30% 14.3 NA NA

2 Max. 120 90% 14.7 NA NAMin. 50 10% 14.3 NA NA

3 160 100% 26.7 NA 1 x108

5 NA NA 12.3 NA NA

Operational Condition Definitions1. Normal2. Abnormal3. LOCA/HELB Inside Primary Containment5. Tornado (Sudden Pressure Drop)

The ACME-Cleveland Development Company tested these switches in theirQualification of Namco Controls Limit Switch Model EA-740 datedFebruary 2, 1979.

To the following levels:

Temperature: 3400 FPressure: 63 psigRelative Humidity: 100% (NEMA 4 Enclosure)Radiation: 2.04 x 108 RADS

Based on the above the switch is qualified for the stated life.

The limit switches on this EQS require sealing of the conduit entrance.

Qualification of the conduit seals is documented in EQS WBN-EEB-CSC-1.

Prepared 'By: ~ ~ "~Reviewed By: _______________

DEO2 :LJS.76

Rev is ion R1I R2 EQS Not. WBN-MEB-67-0134

l~rearerDateTVA ID No:&V. 11, s3See Appendix 1'

VIB11 EQUIPMENT QUALIFICATION SHEET_(EQS)Manufacturer and Model Number Limitorque SMB-O00

Verification R9f Table Information (Table 3.11-4 Sheet !ITBN-MEB-0101 L'.K

...~.Equipme~nt Type - The equipment has been identified as per TVA ID numbeL~~_X eigna~tions (e.d., MOV, SOy, etc.).<

Location - The location has been identified (E.G., Inside PrimaryContainment, Annulus, Individually Cooled Rooms, General Spaces, orarea affected by HELB outside primary containment).

component -A unique TVA ID number has been assigned (e.g., I-FSV-68-308).

Function A functional description ofthe component has been given(e.g., Steam Generator Blowdown).

contract No., Manufacturer, and Model No. -The contract number,manufacture, and model number has been given.

Abnormal or Accident Environment - All abnormal or accident environmentalconditions applicable to this equipment have been identified either intables or by references to figures from tables.-_

~.Environment to Which Qualified - T:-., environment to which the equipmenthas been qualified is addressed in either the tables or the environmentalanalysis attached.

XCategory - A category of a, b, c, or d has been defined for the equipment.

SOperation and Accuracy Required and Demonstrated - The operation andaccuracy required and demonstrated have been defined.

Qualification Status (chec', if applicable, NA if not) Qualified Life

Y. Qualification Report and f1-ithod - A qualification report and the methodof qualification hais bqeiýfMiiiified.

Ž~Environmental Analysis -An environmental analysis has been done, attachedto thle EQS, and iný67,i=ndently reviewed by the responsible organlization.

.!A Qualification by Similarity (If applicable) - A justification forqualification by similarity is attached to th6 EQS considering all theabove factors and referenced to the appropriate tables.

guali~fication of Several Exact Components (If applicable) - When an EQSis usd for more than one item, a list of all exact components are Oivenas air appendix with all references to appropriate tables with justificationfor qualification considering all the abo~ve~factors.

.JA Interim Qualification (If applicable) -(Open item) - Component has beendaetermined to be qualified only for a limited interim operation, an NCRhas been written, and plan of action has been determined to yield aqualified component. Tern of Interim Qualification__________

NCR No.ýJ-Uncjual ifiedComponcent-(Open item) - (If applicable) - Component has been

de-termined to be unqualified; tile following is attached to EQS::NCR nutniber, reason for non-qualificaxtinrn, and justification of continuedoperation.

NCR No. _ _ _ _ _ _ _ _ _ _ _ _ _

Sheet No. WBN-MEB-67-134Rev. No. 2Appendix IISheet 1 of 2

The actuators are required to operate in the environments as shown on TVADrawing 47E235-42, and sutn-arized below:

OperationalCondition

1.AvgMaxMin

Temp. Rel. Pressure 40 TearOF Hum (Psia) Radiation

(Rads)

408030

100%10%

100%

2. MaxMin

NA 100%

ATM14.714.3

14.714.3

26.4

12.4

NA2 x10NA

NA

NA

NA

IntegratedArc. Dose(Rads)

NANANA

NA

NA

I x 108

Operational Condition Definitions1. Normal2. Abnormal3. LOCA/RELI Inside Primary Containment6. Inadvertant Containment Spray Initiation

These actuators are qualifiedis an appendix to Test Report

TempRelative HumidityRadiationPressure

by Limitorque Test Report 600456, whichB0058 to the following environment:

300 OF100%2.04 x 18Rads78 psig

G84161 .04

EF!t~E D ,-A T E '[

T; T

Sheet No. WBN-MEB-67L-1 3 4

Revision 2Appendix 11Sheet 2 of 2

These actuators are above the flood level which would be caused by

activation of the containment spray system. Therefore, they need not be

qualified for flood conditions.

Limitorque has stated that absolute sealing of these actuators against the

ambient conditions is not required for qualification of these components.

Although the LOCA test temperature in 600456 was 3000'?, we feel these

actuators are qualified based on the following:

1. Aging of these actuators took place at 1800C (3560F),

which is in excess of the 32707 peak.

2. Actuators constructed of the same subcomponents were tested

in Limitorque TR 600376A to 3400?. The difference between the

PWR and BWR test reports is in the composition of the spray used.

Water, and not a chemical spray, was used for TR600376A. However,

due to the location of these actuators they will not see a direct

chemical spray. At best these may see some drippage of the spray

solution from the upper compartment. Since the spray is not a

dominant factor, we feel use of the 3400'? temperature is

justified.

TVA has inspected these actuators to verify that the EMO electrical

subcomponents are similar to those tested and approved by Limitorque in

their test reports. As a result of this inspection, we have determined

that T-drains need to be installed in the motor housing. With the

installation of these drains these actuators will be qualified. The T-

drains were installed under work plan WP4571.

Prepared by:__

Reviewed b: 4/ ~

C84161 .05 DAFE TEV

I RevsionR2Preparr/D14I- ~I

EQS No'. WBN-MEB-67-135

TVA ID No:S ee Appendix ..

W__

Qualification Status (chec!: if applicable, NA if not) Qualified Life_____

)(Qualification Report and Ii.?thod - A qualification report and. the method

of qualification heas bien, 7Thified.

Environmental Analysis - An'environmental analysis has been done, attached

to the EQS, and indep~dently reviewed by the responsible organization.

QAua -lification by Similarity (If applicable) - A justification forqtilifcationb imia rity is attached to the EQS considering all the

above factors and referenced to the appropriate tables.

QualiA3fication of Several Exact Components (If applicable) - When an EQSis used for more than one item, a list of all exact components are given

as anf appendix with all references to appropriate-tables with justification

for qualification considering all the above~factors.

ii~ Interim Qualification (If applicable) - (Open item) - Component has been

Udetermined to be qualified only for a limited interim operation, an NCR

has been written, and plan of action has been determined to yield aiqualified component. Term of Interim Qualification _________

NCR No0.

WknqualifiedComponent-(Cpen item) - (If applicable) - Component has been

determfined to be unqualified; the fello'.'ing is attached to EQS:NCR number, reason for non-qualificatin idjutfcto ofntinuedoperation.NCR No. _ _ _ _ _ _ _ _ _ _ _ _ _

(7' brVB /EQUPMENT QAICTONSHEET (EQS)Manufacturer and Miodel Number Limitorgue SMB-000O

Verification of Table Information (Table 3.11-4 Sheet WBN-MEB-0102 LU

A-Equipment ype~ - The equipment has been identified as per TVA ID number ':Zeinations (e.d., MOV, SOy, etc.).

I.Location - The location has been identified (E.G., Inside Primary r

CotainTment, Annulus, Individually Cooled Rooms, General Spaces,.orarea affected by HELB outside primary containment).____

X Copnn - A unique TVA ID number has been assigned (e.g., l-FSV-68-308).

.X_ Function - A functional description of the component has been given

J(e.g.. St eam Generator Blowdown).

Contract No., Manufacturer, and Model No. -The contract number,

manufa-cturer, and model number has been given.

Abnormal or Accident Environment - All abnormal or accident environmentalconditions -applicable to this equipment have been identified either intables or by references to figures from tables.-..,

ŽIEnvironment to Which Qualified - T*he- environment to which the equipmenthas been qualified is addressed in either the tables or the environmentalanalysis attached.

Category - A category of a, b, c, or d has been defined for the equipment.

... Operation and Accuracy Required and Demonstrated - The operation andaccuracy r-equired and demonstrated have been defined.

Reviewer/Date I,) &-il/I

Sheet No. WBN-MEB-67-135Rev. No. 2Appendix IISheet 1 of 2

These actuAtore are required to operate in the environmentsdrawing 476235-41 R0, and sunmmarized below.

as shown on TVA

OperationalCondition

1 Avg.Max.Min.

2 Max.Min.

3

Temp. Rel1. PressureOFHum. (PSIA)

40% ATM80% 14.730% 14.3

90% 14.710% 14.3

100% 26.7

40 yearRadiation (RADS)

Integrated Acc-Dose (R.ADS)

NA2 x10NA

NANA

1 x 108

NA 100% 12.4

Operational Condition Definitions1. Normal2. Abnormal3. LOCA/HELE Inside Primary Containment6. Inadvertent Containment Spray Initiation

These are qualified by Limitorque test report 30003, which is an Appendixto test report B0058, as stated in Limitorque' s letter to TVA datedDecember 11, 1981 (MEB 811215 508), to the following environment.

Temperature:Pressure:Relative Humidity:Radiation:

3000 'F78 psig100%2.04 x 108 RADS

The actuators are located above the steam generators, well above themaximum flood level of 717' due to activation of the containment spraysystem (Ref. dwg. 47W450-29 R4).

Limitorque has estimated the life of class RH insulated motors beyond the30 day LOCA test by use of a linear regression curve, plotting failure lifeagainst temperature exposure in test report 30058. At 160OF the motorinsulation would have an estimated life of 981,131,366 hours, whichencompasses the 100 day operating requirement.,

DE02:LJS.77

Sheet No. WBN-MEB-67-135Rev. No. 2Appendix 11Sheet 2 of 2

The evitch'-material used is a molded phenolic with a temperature index of1500C. With a 600C ambient aging temperature the physical propertiesof this material can be estimated to degrade to 50% of their originalvalues in 3.07 x 107 hours, which is well over the 100 day requirement.

Limitorque has stated that absolute sealing of these actuators against theambient conditions is not required for qualification of these components.

TVA has inspected these actuators to verify that the KilO electricalsubcomponents are similar to these tested and approved by Limitorque intheir test reports.

With the installation ofwill be qualified for 40plan WP4571.

T-drains in the motor housings these actuatorsyears. The T-drains were installed under work

PreparedBy

Reviewed By:7T

0

TABLE 3.11-4 TABLE INPUT DATA SHEET

SHEET NO: WBN-NEB-1* 1 I A ULA LNUNITS 1 AND 2

INSIDE CONTAINMENT

Revision 0 ELI R2 R3 R4

PBN RKW awiPreparer/Date R. Darwin 10-19-81 6-10-83 4-19-84 q/,qjgs

REV AWLReviewer/Date F. A. Plesic 12-15-81 6-11-83 5-5-84 qZ/fYi

CONTRACT NO. ABNL OR OPER OPER ACCUR AC CUR QUAL RPTLOC COMPONENT FUNCTION MFG & )()DEL NO. ACD ENVR ENVIRONMENT TO WHICH QUALIFIED CAT REOT DEMD REQMT DEW) METHODL 1-FT-1-3A SG 1 Main Steam 71C62-54114-1 42 420'F, 57 psig, 109Z rh,2500 ppm A 5 min 4 ma + 10 + 10 WCAP-8587,Supp 2-EQTR

HDR Flow Chan 1 Barton 764 lot 7 Boron,Ph 10.7,5xl0 rads B03A & EQDP-ESE-3L 2-FT-l-3A SG I Main Steam Not Installed 42 A 5min

I1DR Flow Chan 1L 1-FT-l-3B SG I Main Steam 71C62-54114-1 42 420 0F, 75 psig, 10-9% r~h,2500 ppm A 5 min 4 mao + 10 + 10 WCAP-8587,Supp 2-EQTR

HDR Flow Chan 2 Barton 764 lot 7 Boron,Ph 10.7,SxOrd E034 & EQDP-ESE-3L 2-FT-l-3B SG 1 Main Steam Not Installed 42 A 5 min

HDR Flow Chan 2L I-FT-1-10A SG 2 Main Steam 71C62-5411L4-1 42 420'F, 57 psig, 109Z rh, 2500 ppm A 5 min 4 ma + 10 + 10 WCAP-8587,Supp 2-EQTR

HDR Flow Chan 1 Barton 764 lot 7 Borom,Ph 10.7,5z10 rads E03A & EQDP-ESE-3L 2-FT-1I-bA SG 2 Main Steam Not Installed 42 A 5 mini

HDR Flow Chan 1L 1-FT-1-lOB SG 2 Main Steam 71C62-54114-1 42 420uF, 75 psig, 109% rh,2500 ppm A 5 min 4 ma + 10 + 10 WCAP-8587,Supp 2-EQTR

HDR Flow Chan I Barton 764 lot 7 Boron,Ph 10.7.5xlO rads E03A & EQDP-ESE-3L 2-FT-1i-OB SG 2 Main Steam Not Installed 42 A 5 mini

HDR Flow Chan 1L I-FT-1-21A SG 3 Main Steam 71C62-54114-1 42 420 0F, 57 psig, 109Z rh,2500 ppm A 5 mini 4 ma + 10 + 10 WCAP-8587,Supp 2-EQTR

HDR Flow Chan I Barton 764 lot 7 Boron.Ph 10.7.5x1O rads E03A & EQDP-ESE-3L 2-FT-1-21A SG 3 Main.Steam Not Installed 42 A 5min

UDR Flow Chan 1L I-FT-1--21B SC 3 Main Steam 71C62-54114-1 42 420 aF, 57 psig, 109% rh,2500 ppm A 5 mini 4 ma + 10 + 10 WCAP-8587,Supp 2-EQTR

HDR Flow Chan 2 Barton 764 lot 7 BoronPh 10.7,5xl0 rads E03A & EQDP-ESE-3L 2-FT-1-21B SC 3 Main Steam.' Not Installed 42 A 5min

HDR Flow Chan 2'L I-FT-1-28A SC 4 Main Steam 71C62-54114-1 42 420 F, 57 psig, 109% rh,2500 ppm A 5 min 4 ma + 10 + 10 WCAP-8587,Supp 2-EQTR

HDR Flob-Chan I Barton 764 lot 7 Boron,Ph 1O.7#5xlO radsE0A&QD-S3L 2-FT-128A SC 4 Main Steam Not Installed 42 AO3 5 minES

HDR Flow Chan 1L 1-FT-1-28B SG 4 Main Steam 71C62-54114-1 42 420 0F, 57 psig, l09% rh,2500 ppm A 5 mini 4 ma + 10 + 10 WCAP-8587,Supp 2-EQTR

HDR Flow Chan 2 Barton 764 lot 7 Boron.,Ph 10.7,5x10 rads E03A &EQDP-ESE-3

E43159 .02

40

0

TABLE 3.11-4

SHEET NO: WBN-NEB-2

EFF~r TIV~iTABLE INPUT DATA SHEETD A T SWP CLASS 1E EQUIPMENT

WTTS BAR NUCLEAR PLANTUNITS 1 AND 2INSIDE CONTAINMENT

Revision 0

Prenarer/Date R. Darwin 10-19-81 HO

Rl1 R2 R3 R4

P&1- RKW #q d'6-10-83 4-19-84 WyIi/

RKW AWL ige~RO 6-11-83 5-5-84 PhdrY'

LOC COMPONENTCONTRACT NO. ABNL OR

FUNCTION MFG & MODEL NO.- ACD ENVR ENVIRONMENT TO WHICH QUALIFIEDOPER

CAT REONTOPER ACCURDEMO REQMT

AC CUR QUAL RPTDEMO METHOD

L 2-FT-1-28B SG 4 Main Steam Not Installed 42 A 5 minHDR Flow Chan 2

L 1-LT-3-38 Steam Gen No. 1 7IC62-54114-1 42 420"F, 57 psig, 1005 rh, 2500 ppm A 100 4 mo + 15 + 15 WCAP-8587,Supp 2-EQTRLevel XMTR Barton 764 lot 7 Borgn Ph 10.7, 5x10 rads-- days EO3A &ýEQDP-ESE-3

L 2-LT-3-38 Steam Gen No. 1 71C62-54114-1 42 420-F, 57 psig, 100% rh, 2q00 ppm A 100Level XMTB Barton 764 lot 7 Boron Spray, Ph 10.7, 5x10 rads days

L 1-LT-3-39 Steam Gen No. 1 71C62-54114-1 42 420-F, 57 psig, 100% 7rh, 2500 ppm A 100 4 mo + 15 + 15 WCAP-8587,Supp 2-EQTRLevel XMR Barton 764 lot 7 Boron, Ph 10.7, 5x10 rads days E03A & EADP-ESE-3

L 2-LT-3-39 Steam Gen No. 1 71C62-54114-1 42 370-F, 75 psig, 1g0% rh,2750 ppm A 100Level XMTR Barton 764 Lot 2 Borgn,Ph 8.5%5xlO rads days

L I-LT-3-42 Steam Gen No. 1 71C61-54114-1 42 420-F, 57 psig, 100% 7rh, 2500 ppm A 1090 4 io + 15 + 15 WCAP-8587,Supp 2-EQTRLevel XMTR Barton 764 lot 7 Boron, Ph 10.7, 5x10 rads days E03A & EQDP-ESE-3

L 2-LT-3-42 Steam Gen No. 1 Not Installed 42 A 100Level XMR days

L I-LT-3-43 Steam Gen No. I 7IC62-54114-1 42 420-F, 57 psi, 10OZ rh, 2500 ppm A 10 4 mo + 15 + 15 WCAP-8587 ,Supp 2-~EQTRLevel XMTR Barton 764 lot 7 Boron, Ph 10.7, Sxl0 7rads dayos - E03A & EQDP-ESE-3

L 2-LT-3-43 Steam Gen No. 1 Not Installed 42 420-F, 57 psig, 100Z 7 rh, 2500 ppm A 100Level XMTR Boron,' Ph 10.7, 5x10 rads days

L I-LT-3-51 Steam Gen No. 2 71C62-54114-1 42 420-F, 57 psig, 100% 7 rh, 2500 ppm A 100 4 mo + 15 + 15 WCAP-8587,Supp 2-EQTRLevel M~R Barton 764 lot 7 Boron. Ph 10.7, 5x10 rads days E03A & EQDP-ESE-3

L 2-LT-3-51 Steam Gen No. 2 71C62-54114-1 42 420-F, 75 psig, 1003 rh, 2500 ppm A 100Level XMTR Barton 764 lot 7 Boron Ph 10.7, 5xI0 rads dy

L -LT-3-52 Steam Gen No. 2- 71C62-54114-1 42 420-F, 57 psig, lOr,2500 ppm A 10 4 mo + 15 + 15 WCAP-8587,Supp 2-EQTRLevel XMR Barton 764 lot 7 Boron, Ph 10.7, 5xIiO rads. daysEOA&QDE 3

L 2-LT-3-52 Steam Gen No. 2 71C62-54114-1 42 370-F, 75 psig, 1003 rh, 2750 ppm A 100Level .MR Barton 764 lot 7 Boron, Ph 8.5, 5x10 rads,_ days

L I-LT-3-55 Steam Gen No. 2 71C62-54114-1 42 420-F, 57 psig, 100% 7rh, 2500 ppm A 100 4 mo + 15 + 15 WCAP-8587,Supp 2-EQTR

Level XMR Barton 764 lot 7 Boron, Ph 10.7, 5x10 rads days E03A & EQDP-ESE-3L 2-LT-3-55 Steam Gen No. 2 Not Installed 42 A 100

Level XMR days

E43 159.02

Prenarer/Date R. Darwin 10-19-81 RO

Reviewer/Date F. A. Plesic 12-15-81

0

TABLE 3.11-4

SHEET NO: WBN-NEB-3

TABLE INPUT DATA SHEETSWP CLASS 1E EQUIPMENT

WATTS BAR NUCLEAR PLANTUNITS I AND 2

INSIDE CONTAINMENT

Revision 0

Preparer/Date Rt. Darwin 10-19-81 RO

Reviewer/Date F. A. Plesic 12-15-81 RD 6-11-83 5-5-84 qksfjSI

RI R2 R3 R4

pan EKW aw6-10-83 4-19-84 11K/SY

AWL U

CONTRACT NO. ABNL OR OPER OPER ACCUR ACCUR QUAL RPTLOC COMPONENT FUNCTION MFG & MODEL NO. ACD ENVR ENVIRONMENT TO WHI1CH QUALIFIED CAT REQMT DEMO REQMT DEMO METHODL I-LT-3-56 Steam Gen No. 2 71C62-54114-1 42 420-F, 57 psig, 1OXZ7 rh, 2500 ppm A 100 4 no + 15 + 15 WCAP-8587,Supp 2-EQTR

Level XMTR Barton 764 lot 7 Boron, Ph 10.7, ,5x10 rads days E03A & EQDP-ESE-3L 2-LT-3-56 Steam Gen No. 2 Not Installed 42 A 100

Level IO4TR daysL I-LT-3-93 Steam Gen No. 3 71C62-54114-1 42 420 0F, 57 psig, 100% 7rh, 2500 ppm A 100 4 no + 15 + 15 WCAP-8587tSupp 2-EQTR

Level X14TR Barton 764 lot 7 Boron, Ph 10.7, 5x10 rads days E03A &EQDP-ESE-3L 2-LT-3-93 Steam Gen No. 3 71C62-54114-1 42 370-F, 75 psig, 1003 rh, 2750 ppm A 100

Level XMTR Barton 764 Lot 2 Boron, Ph 8.5, 5x10 rads daysL 1-LT-3-94 Steam Gen No. 3 71C62-54114-1 42 420-F, 57 psig, 100% 7rh, 2500 ppm A 100 4 no + 15 + 15 WCAP-8587,Supp 2-EQTR

Level XKTR Barton 764 lot 7 Boron, Ph 10.7, 5x10 rads days E03A & EQDP-ESE-3L 2-LT-3-94 Steam Gen No. 3 71C62-54114-1 42 370-'F, 75 psig, 10OJ rh, 2750 ppm A 100Level XHTR Barton 764 Lot 2 Boron, Ph 8.5, 5x10 rads daysL I-LT-3-97 Steam Gen No. 3 71C62-54114-1 42 420'Fv 57 psig, 100%Z7rh, 2500 ppm A 100 4 mo + 15 + 15 WCAP-8587,Supp 2-EQTR-Level XMTR Barton 764 lot 7 Boron, Ph 10.7, 5x10 reds days E03A & EQDP-ESE-3

L 2-LT-3-97 Steam Gen No. 3 Not Installed 42 A 100Level XMTR daysL -LT-3-98 Steam Gen No. 3 71C62-54114-1 42 420'F, 57 psig, 10OZ 7 rb, 2500 ppm A 100 4 no + 15 + 15 WCAP-8587,Supp 2-EQTR-Level XMTR Barton 764 lot 7 Boron, Ph 10.7, 5xlO rads days E03A & EQDP-ESE-3L 2-LT-3-98 Steam Gen No. 3 Not Installed 42 A 100Level XMTR daysL 1-LT-3-106 'Steam Gen No. 4 71C62-54114-1 42 420 0F, 57 psig, 100%Z7rh, 2500 ppm A 100 4 no + 15 +. 15 WCAP-8587,Supp 2-EQTR-Level XNTR Barton 764 lot 7 Boron, Ph 10.7, SilO rads days E03A & EQDP-ESE-3L 2-LT-3-106 Steam Gen No. 4 Not Installed 42 A 100Level YMIII daysL I-LT-3-107 Steam Gen No. 4 71C62-54114-1 42 420 F, 57 psig, 100% 7rh, 2500 ppm A 100 4 no + 15 + 15 WCAP-8587,Supp 2-EQTR-Level XIMM Barton 764 lot 7 Boron, Ph 10.7, 5x10 rads days E03A & EQDP-ESE-3

L 2-LT-3-107 Steam Gen No. 4 71C62-54114-1 42 420-F, 75 psig, 100% 7 rh, 2500 ppm A 100Level XMTR Barton 764 lot 7 Boron, pH 10.7, SilO reds days_______

*Not Field Verified

E43 159.02

E f7

TABLE 3.11-4

SHEET NO: WBN-NEB-4

E FF EC TABLE INPUT DATA SHET

4*.TFS BAR NUCLEAR PLANTUNITS I AND 2INSIDE CONTAINMENT

Revision 0

Preparer/Date F. A. Plesic 10-21-81

R1 R2 R3 R4

6-10-83 4-19-84 q/,sidjRKW AWL6-11-83 5-5-84,314

-CONTRACT NO. ABNL OR OPER OPER ACCUR AC CUR QUAL RPT

LOC COMPONENT FUNCTION MFG & MODEL NO. ACD ENVR ENVIRONMENT TO WHICH QUALIFIED CAT REQMT DEMO REQMf! DEMO METHOD

L I-LT-3-110 Steam Gen No. 4 71C62-54114-1 42 4V2-0"F, 5-7 psig, 100%Z7rh, 2500 ppm A 100 4 mo + 15 + 15 WCAP-8587,Supp 2"

Level XMTR Barton 764 lot 7 Boron, Ph 10.7, 5x10 reds. days EQTR-E03A & EQDP-ESE-3

L 2-LT-3-110 Steam Gen No. 4 Not Installed 42 A 100

Level XMTR dayL 1-LT-3-111 Steam Gen No. 4 71C62-54114-1 42 4-200F, 57 psig, 100% 7rh, 2500 ppm A 1008 4 mo + 15 + 15 WCAP-8587,Supp 2-EQTR-

Level X4TR Barton 764 lot 7 Boron, Ph 10.7, 5x10 reds days E03A & EQDP-ESE-3L 2-LT-3-111 Steam Gen No. 4 54114-1 42 A 100

Level XMTh days

L 1-FCV-62-61 Seal Flow Ret 71C61-54114-1 42 315-F, go psig, 100% rh,Ph 10.5 B 100 100 NA NA Limit. Rpt B0058

ISO Vlv Reliance Lim SB-00 2.04xl0 rads, 3000 p pm Boron d as days .600456 App. C

*L 2-FCV-62-61 Seal Flow Ret 71C62-54114-1 42 315-F, go psig, 100% rh,Ph 10.5 Bs I00 NA NA

ISO Vlv Reliance Lim SB-00 2.04x10 reds, 3000 ppm Boron daysL 1-LT-63-180 Cntmt Level 71C62-54114-1 42 420-F, 57 psig, lOOZrh, 2590 ppm A 1 wk 4 mo + 15 + 15 WCAP-8687,Supp 2-EQTR-

Min Lvi RHR RecirBarton 764 lot 7 Boron Spray, Ph 10.7, 5x10 reds E03A &Supp 2 E03A

L 2-LT-63-180 Cntmt Level Not Installed 42 A 1lwkMin Lvi RHR Recir

L 2-FCV-62-69 2-FCV-62-69 54114-1 Namco 42 A 5 mini NA NA(LS) Position EA170-302 B 1imo

L 2-FCV-62-70 2-FCV-62-70 54114-1 Nampo 42 A 5-mi NA NA(LS) Position EA170-302 B 1mo

L 2-FSV-62-76 Cntmt Isolation 54114-1 Asco 42 A 5min NA NA

Vlv FT831654 B 100 dys

*Not Field Verified

E43159 .02

0s

Reviewer/Date G J Malek 12-15-81

0

TABLE 3.11-4

SHEET NO: WBN-NEB-5

EALEIFECTTASHESWP CLASS 1K EQUIPMENT

OCI 0 BAR NUCLEAR PLANTUNITS 1 AND 2

INSIDE CONTAINMENT

Revision 0

PReparwer/Date T. A. Schenec HO158

Reviewer/Date F. A. Plesic 12-15-81 RO 6-11-83 5-5-84 .1.4.4

R1 R2 R3 R4

FU10PB HKW 6fr7g6-083 4-19-84 9I/t/0i

RKW AWL 02J(

CONTRACT NO. AB14L OR OPER OPER AC CUR ACCUR QUAL RPTLOC COMPONENT FUNCTION MFG & MODEL NO. ACD ENVR ENVIRONMENT TO WHICH QUALIFIED CAT REQHT DEMO REQ MT DEMO METHODL I-LT-63-181 Cntmt Level 71C62-54114-1 42 420 aF, 57 psig, O0%Z7 rh, 2500 ppm A 1 wk 4 no, + 15 + 15 WCAP-8587,Supp 2-EQTR-Mini Lvi RHR RecirBarton 764 lot 7 Boron, Ph 10.7L, 5xl0 rads E03A & EQDP-ESE-3L 2-LT-63-181 Cntmt Le'vel Not Installed 42 A IlwkMin Lvl RER Recir

L 1-LT-63-m8 Cntmt Level 71C62-54114-1 42 420 0F, 57 psig, 10OZ rh, 2500 ppm A 1 wkt 4 ma + 15 + 15 WCAP-8587,Supp 2-EQTR-Min Lvl RHR RecirBarton 764 lot 7 Boron, Ph 10.7, 5xlO 7rads E03A & EQDP-ESE-3L 2-LT-63-182 Cntmt Level Not Installed 42 A 1iwkMin Lvi HER Recir

L 1-LT-63-183 Cntmt Level 71C62-54114-1 42 420u'F, 57 paig, 100% 7rh, 2500 ppm A I wkt 4 ma + 15 + 15 WCAP-8587,Supp 2-EQTR-Min Lvi HER RecirBarton 764 lot 7 Boron, Ph 10.7, 5x10 rads E03A & EQDP-ESE-3L 2-LT-63-183 Cntmt Level Not Installed 42 A I wkMin Lvl RHR RecirNot Installed

U I-FCV-68-332 RCS Przr Rel 71C62-54114-1, 41 315 0F, 70 psig, 100% gh, 3000 ppn B 100 100 NA NA Lim Rpt B0058Flow Control Reliance Lim SB-00 BoronP 1.5, 2.4x10 rads days days Ap C 600456*U 2-FCV-68-332 RCS Przr Rel 71C62-54114-1 -_ 41 315 -F: 70 pSig, 100% Eh, 3000 ppm B 100 100 NA NA Lti m Rpt B0058Flow Control Reliance Lim AB-00 Boron,Ph 10.5, 2x4xl00 rads days days App C 600456U I-FCV-68-333 RCS Przr Pvr 71C62-54114-19 41 315-F, 70 psigt, 100% rg, 3000 ppm B 100 100 NA NA Lim Rpt B0058Relief Valve Reliance Lim SB-00 Boron,Ph 10.5, 2.04xl0 rads days days App C 600456*U 2-FCV-68-333 RCS Przr Pwr 71C62-54114-1, -41 315-F, 70 psig, 100Z r , 3000 ppm B 100 100 NA NA Lim Rpt B0058Relief Valve Reliance Lim SB-00 Boron,Ph 10.5, 2.04x10 reds days days App C 600456L 1-FSV-68-394 Reac Vessel Head 71C62-54114-1 Tar- 42 420-F, 57 psig, 100% rh8 2500 ppm A 100 1 yr NA NA WCA-8687,Supp 2-H10AVent Iso VIv et Rock 79AB-001 Boron, Ph 10.5, 1.85X10 reds days & EQDP-HE-10A*L 2-FSV-68-394 Heac Vessel Head 7*1C62-54114-l Tar- 42 420-F, 57 psig, 100% rh8 2500 ppm A 100 1 yr NA NA WCAP-8687,Supp 2-HlOAVent Iso Vlv get Rock 79AB-001 Boron, Ph 10.5, 1.85xl0 rads days &EQDP-HE-1OA

*No Field Verified

E43159.02

0

Preparer/Date T. W. Schoene RO

EFFECTIVETABLE3.114 D T ETABLE INPUT DATA SHEETTABLE3.11- DATESWP CLASS IE EQUIPMENT

SHEET NO: WBN-NEB-6 0OCT 19834wTTS BAR NUCLEAR PLANT

UNITS I AND 2INSIDE CONTAINMENT

Revision 0

Prenerer/Date G. 3. Nalek 10-21-81

RI R2 R3 R4

PBN RKW6-10-83 4-19-84

RKWI AWLReviewer/Date F. A. Plesic 12-15-81 RD 6-11-83 5-5-44iý

CONTRACT NO. ABNL OR OPER OPER ACCUR ACCUR QUAL RPTLOC COMPONENT FUNCTION MFG & MODEL NO. ACD ENVR ENVIRONMENT TO WHIiCH QUALIFIED CAT REQMT DEMO REWN DEMO METHODL 1-FSV-68-395 Reac Vessel Head 71C62-54114-1 Tar- 42 420 aF, 57 psig, 100% rh 2500 ppm A 100 1 yr NA NA WCAP-8687,Supp 2-H1OA

Vent Iso Vlv get Rock 79AB-001 Boron,' Ph 10.5, 1.85x10 rads days EQDP-HE-IOAL 2-FSV-68-395 Reac Vessel Head 71C62-54114-1 Tar- 42 420-11, 57 psig, 100% rh8 2500 ppm A 100 1 yr NA NA WCAP-8687,Supp 2-H10A

Vent Iso Vlv get Rock 79AB-001 Boron,' Ph 10.5, 1.85xl0 rads days EQDP-HE-10AL 1-FSV-68-396 Reac Vessel Head 71C62-54114-l Tar- 42 425*F, 70 psig, 100% rh8 2500 ppn A 100 1 yr NA NA WCAP-8687,Supp 2-HiOC

Vent Thrtl Vlv get Rock 79AB3-003 Boron, Ph 10.5, 3.05x10 rads days EQDP-HE-IOC*L 2-FSV-68-396 Reac Vessel Head 71C62-54114-1 Tar- 42 420-F, 70 psig, 100% rh 2500 ppm A l 100 1 yr NA NA WCAP-8687,Supp 2-HIUC

Vent Thrtl Vlv get Rock 79AB3-003 Borgn, Ph 10.5, 3.05x10 rads days EQDP-HE-10CL I-FSV-68-397 Reac Vessel Head 71C62-54114-1 Tar- 42 420-F, 70 psig, 100% rh 8 2500 ppm A 100 1 yr NA NA WCAP-8687,Supp 2-H10C

Vent Thrtl Vlv get Rock 79AB3-003 Boron. Ph 10.5, 3.05x10 rads days EQDP-HE'-IOC*L 2-FSV-68-397 Reac Vessel Head 71C62-54114-1 Tar- 42 420-F, 70 peig, 100% rh 8 2500 ppm A 100 1 yr NA NA WCAP-8687,Supp 2-HiOC

Vent Thrtl Vlv get Rock 79AB-003 Boron. Ph 10.5. 3.05x10 rads-- days EQDP-HE-10CL l-LT-68-320 RCS Przr Level 71C62-54114-1 42 420-F, 57 psig, 100% 7rh, 2500 ppm A 100 4 no + 15 + 15 WCAP-8587,Supp 2-~EQTR-

Barton 764 lot 7 Boron,* Ph 10.7, 5x10 rads days E03A & EQDP-ESE-3L 2-LT-68-320 RCS Przr Level 71C62-54114-1 42 420-F, 57 psig, 100%Z7rh, 2500 ppm A 100 4 no + 15 + 15 WCAP-8'587,Supp 2-EQTR-

Barton 764 lot 7 Boron, Ph 10.7, 5x10 reds days E03A & EQDP-ESE-3Ill I--LT-68-335 RCS Przr Water 71C62-54114-1 45 425"~F" 57 psig, 100%Z7rh, 2500 ppm A 100 4 no + 15 + 15 CAP-8587,Supp 2-EQTR-

Level Barton 764 lot 7 Boron, Ph 10.7, 5x10 reds days E03A & EQDP-ESE-3IIR 2-LT-68-335 RCS Przr Water 71C62-54114-1 45 420-F, 57 psig, 100% 7rh, 2500 ppm A 100 4 no + 15 + 15 WCAP-8587,Supp 2-EQTR-

Level Barton 764 lot 7 Boron, Ph 10.7t 5xlO reds -_- days E03A & EQDP-ESE-3IIR I-LT-68-339 RCS Przr Level 71C62-54114-l 45 420-'F, 57 psig, 100%Z7 rh, 2500 ppm A 100 4 no + 15 + 15 WCAP-8587,Supp 2-EQTR-

-parton 764 lot 7 Boron, Ph 10.7, 5x10 reds days E03A & EQDP-ESE-3IIR 2-LT-68-339 RCS Przr Level '71C62-54114-1 45 420 F, 57 psig, 100 7 rh, 2500 ppm A 100 4 no + 15 + 15 WCAP-8587,Supp 2-EQTR-

Barton 764 lot 7 Boron, Ph 10.7, SilO reds days E03A & EQDP-ESE-3

*Not Field Verified

E43 159.02

0 0

V/709r.Pre arer/Date G. J. Malek 10-21-81

TABLE 3.11-4

SUEE NO: WBN-NEB-7

EFFECTIVED A TE TABLE INPUT DATA SHEET

OCT 1984 SWP CLASS 1K EQUIPMENT

FITTS BAR NUCLEAR PLANTUNITS 1 AND 2INSIDE CONTAINMENT

Revision 0

Preparer/Date G. J. Malek 10-21-81

Reviewer/Date F. A. Plesic 12-15-81

RI R2 R3

PEN RKW

RKW AWL 826e10-11-83 5-584 iový,y

CONTRACT NO. ABNL OR OPER OPER ACCUR ACCUR QUAL RPTLOC COMPONENT FUNCTION MFG & MODEL NO. ACD ENVR ENVIRONMENT TO WHiICH QUALIFIED CAT REQMT DEMO REQNT DEMO METHODL I-PT-68-68 RCS Loop 4 71C62-54114-1 42 420 0F, 57 psig, 100% 7 rh, 2500 ppm A 100 4 mo + 10 + 10 WCAP-8587Hot Leg Press Barton 763 lot 7 Boron, Ph 10.7, 5x10 rads day EQDP-ESE-lAL 2-PT-68-68 RCS Loop 4 Not Installed 42 A 100Hot Leg Press daysL 1-PT-68-69 RCS Wide Rng,Prs 71C62-54114-1 42 420 F, 57 psig, 00% 7 rb, 2500 ppm A 100 4 mo + 10 + 10 WCAP-8587LOop 3 Hot Leg Barton 763 lot 7 Boron, Ph 10.7, 5x10 rads days EQDP-ESEIlAL 2-PT-68-69 CSWide Rng,Prs Not Installed 42 A 100Loop 3 Hot Leg daysL 1-PT-68-322 RCS Przr Press 71C62-54114-1 42 370"'F, 75 qsig, 100% rh, 2750 ppm A 5 mmn 1 hr + 10 +7.2 WCAP-9885

Barton 763 lot 2 Boron, 5x10 rads,Ph 8.5, sod hydrox B 100dayslOOdaysL 2-PT-68-322 RCS Przr Press Not Installed 42 A 5minB 1O0daysL I-PT-68-323 RCS Przr Press 71C62-54114-1 42 370 w , 75 psig, 100 3 rh, 2750 ppm A 5 min 1 hr + 10 +7.2 WCAP-9885

Barton 763 Boron, Ph 8.5, 5x10 reds B 100dayslOOdaysL 2-PT-68-323 RCS Przr Press Not Installed 42 A 5min

aB 100dayshIR I-PT-68-334 RCS Przr Press 71C62-54114-1 45 370 F, 75 psig, 190% rh, 2750 ppm A 5 mim I hr + 10 +7.2 WCAP-9885Barton 763 Boron,ph 8.5.5x10 rads B lO0dayslOOday*IIR 2-PT-68-334 RCS Przr Press 71C62-54114-1 45 370-F, 75 psig, 190Z rh, 2750 ppm A 5 minBarton 763 Boron,ph 8.5,5xl0 rads, B lO0days

*Not Field Verified

E43159.02

0

TABLE 3.11-4 [.t3 F- i EC T V ESHEET NO: WBN-NEB-8 .

TABLE INPUT DATA SHEETSWP CLASS 1E EQUIPMENT

LrTS BAR NUCLEAR PLANTUNITS 1 AND 2

INSIDE CONTAINMENT

Revision 0

Preparer/Date F. A. Plesic NO

Reviewer/Date C. J. Malek 12-15-81 61083 5-5-84 .ahdlA/

RI R2 R3 R4

PBX RKW ~b~5-10-83 4-19-84 /t4

RKW AWL

CONTRACT NO. ABNL OR OPER OPER ACCUR ACCUR QUAL RPTLOC COMPONENT FUNCTION MFG & MODEL NO. ACD ENYR, ENVIRONMENT TO WHICH QUALIFIED CAT REONT DEMO REQMT DEMO METHODIIR I-PT-68-340 RCS Przr Level 71C62-54114-1 45 370 0F, 75 paig, 1003 rh, 2750 ppm A 5 min I hr + 10 +7.2 WCAP-9885Barton 763 lot 2 Boron, Ph 8.5, _5x10 rads B lO10dayalOOday*IIR 2-PT-68-340 RCS Przr Level 71C62-54114-1 45 370-F, 75 psig, 1003 rh, 2750 ppm A 5 mi 1Barton 763 lot 2 Boron, Ph 8.5, SilO rada B 1O0days-L 1 -TE-78-1 RCS Loop 1 71C62-545W(.-1 42 420-F, 75 psig, 100% rh, A 100 4 mo + 8 +.1.2 2F WCAP-8687

-Hot Leg Temp dF2O5'2500 ppm Boron, Ph 10.7 2.47xl& rads days Supp. 2-E06AL 2-TE-683-1 RCS Loop 1 Not Installe 42 A 100Hot Leg Temp ,daysL I-TE-68-2A RCS LP I HL 71C62-54114-1 42 340 F, 66 psig, 1001 rh,lxto rad8 A 5 min 1 hr + 3.45"F + .2uF WCAP-9157RTh Man Temp Rosemunt 176KF Chem Spray 1.13 wt% H3 B0 3 Type Test

L 2-TE-68-2A RCS LP I HL Not Installed 42 A 5 minL I-TE-68 RTD Man TempaaL -E6-2B RCS LP 1 HL 71C62-54114-1 42 340 F, 66 paig, 100% rh,IxIO rads A 5 min 1 hr + 3.45-~F + .2 F WCAP-9157RTD Man Temp Rosemount 176 KF Chem Spray 1.13 wt% H OType Test

L 2-TE-68-2B RCS LP +I HL Not Installed 42 HB3A 5minRTD, Man Tem

L 1-TE-68-14A RCS LP 1 Cold 71C62-54114-1 42 340 0F, 66 psig, 100% rh,lxlO8 rads A 5 min 1 hr + 3.45 0F + .2 0F WCAP-9157Leg RTD Man Rosemount 176 KF Chem Spray 1.13 vt% H 3 BO3 Type TestL 2-TE-68--14A RCS LP 1 Cold Not Installed 42 A 5min

Leg RTD Man0L I-TE-68-14B RCS LP 1 Cold J71C62-54114-1 42 340~'F, 66 psig, 100% rh,lxIO arads A 5 min 1 hr + 3.45'F + .2'F WCAP-9157Leg RTD Man Rosemount 176 KY Chem Spray 1.13 wt% H 3B03 Type TestL 2-TE-68-14B RCS LP 1, gold Not Installed- 42 A min

Leg RTD ManL 1-TE-6818 RCS Loop I Cold 71C62-541,4 41 42 420uF, 75 psig, 100% r,2500 ppm A 100 4 no + 8 a.2uF WCAP-8687L eg Tem Rdf 10 ~ Boron, Ph 10.7 2 ,47x10 rads day Supp. 2-E06AL 2-TE-61F-18 RCS LOoI Cold Not Installed 42 A 100o

Leg Temp i0daysL I-TE-68-24 RCS Loop 2 Hot 71C62-541A4-1 42 420 F, 75 psig, 100% rh a 2500 ppm A 100 4 mo +- + .2"F WCAP-8687Lee Tenp Rdf 21205~- Boron, Ph 10.7, 2.47X10 rada days -Supp. 2-E06AL 2-TE-68-24 RCS Loop 2 Hot Not Installed 42 A 100

Leg Temp days

1These RTD's will be installed before fuel load.

0

TALD31- A Tr V TABLE INPUT DATA SHEETDj T 1:SlP CLASS lE EQUIPMENT

SHEET NO: WBN-=NEB-9 0 0T 1934WATTS BAR NUCLEAR PLANT

UNITS 1 AND 2INSIDE CONTAINMENT

Revision 0

Preparer/Date F. A. Plesic RO

Reviewer/Date G. J. Malek 12-15-81 10 6-11-83 5-584 '.4*1

R1 R2 R3 R4

6 mi KKW

HEW AWL ýeAk

LOC COMPONENTT.

F1flI(~TTflNCONTRACT NO.

MFGI & mnnlW1 unfAPf

Man Temp

ABNL OR

I IiUC62-541'-1

Rosemount 176 KF

D ENV ENVIRONMENT TO W~HICH QUALIFAED CAT42 -340"VF, 66 psig, 100% rh,lxlO- reds A

Chem Spray 1.13 watI H.~BO.L 2-TE-68-25A RCS LP 2 AL Not Installed 42 3A 5 minRTD Man TeF

L I-TE-68-25B RCSLP2 HL 71C62-54114--1 42 340F, 66 psig, 100% rh,lxlO rads A 5 mlin 1 hr + 3.35'F + .26F WCAP-9157RTD Man Temp Rosemount 176 KF Chem Spray 1.13 wt% H3B03 Tyees

L 2-TE-68-25B RCS LP 2 HL Not I-ns-t-aled Typ TeatmiRTD Man Tempa

L I-TE-68-37A RCS Loop 2 Cold 71C62-54114-1 42 340uF, 66 psig, 100% rh,lxl0 rads A 5 min I hr + 3.4iFF -+.2 0 F WCAP-9157Leg RTD Man Rosemount 176 K1 Chem Spray 1.13 wtZ H3 BO3 Type TestL 2-TE-68-37A RCS Loop 2 Cold Not Installed 42 A 5min

LegZ RTD Man a ___L I-TE-68-37B RCS Loop 2 Cold 71C62-54114-1 42 34O0uF, 66 psig, 100% rh,lxlO rads A 5 min I hr + 3.45 F + -20F WCAP-9157

Leg RTD, Man Rosemount 176 KF Chem Spray 1.13 wt% H3 B03 Type TestL 2-TE-68-37B RCS Loop 2 Cold Not Installed 42 A 5min

Leg RTD ManL I-TE-68-41 RCS Loop 2 71C62-5I.11~- 2 40F 5pi,10 h 2500 ppm, A 100 4 mo + 8 +_a.20F WCAP-8687

Cold Leg Temp Rdf 21205 V Boron, Ph 10.7, 2.47x10 reds days Sp.2E6L 2-TE-68-41 RCS Loop 2 Not Installed -42 A 100Cold Leg Temp days_____________

L I-TE-68-43 RC Loop 3 71C62-5411/- 42 40F, 75 psig, 100% rh 8 2500 ppm A 100 4 mo + 8 + .2OF WCAP-8687Hot Leg Temp Rdf 21205 (9Boron, Ph 10.7, .2.47x10 reds days Supp. 2-EO6AL 2-TE-68-43 RC Loop 3 Not Installed 42 A 100Hot LEg Tem days_________________

L I-TE-68-44A RCS LP- HL 71C62-54114-1 42 340 F, 66 psig, 100% rh,lxlO reds A 5 min 1 hr + 3.450 F + .2*F WCAP-9157RTD Man Temip Rosemnount 176 KF Chem Spray 1.13 wt%3H 30 Type Test

L 2-TE-68-44A RCS LP 3 HI Not Installed 42 A 5minRTD Man Tar p)

L 1-TE-68-44B RCS LP 3 H1. 71C62-54114-1 42 T4-00F, 66 psig, 100% rh,lxlO rded A 5 mini 1 hr + 3.450 F + .2C5F WCAP-9157RTD Man Ter~p Rosemount 176 KP Chaem Spray 1.13 wt% H3 B03 Tyees

L 2-TE-68-44B RCS LP 3 HIi Not Installed 42 A 5 minypTsRTD Man Terp

N,,-- Te t

I'These RTD's will be installed before fuel load.

OPER OPER ACCUR ACCURREQMT DEMO REQNT -DEMO5min 1lhr + 3.r+5F + -v'F

QUAL RPTMETHODWCAP-9157L

Reviewer/Date G. J. Malek 12-15-81

0

TABLE 3.11-4 LrT -ABL INUT DATA SHEET

WPCASIE EQUIPMENT7;LAS BAR NUCLEAR PLANT

UNITS 1 AND 2INSIDE CONTAINMENT

Revision 0

PreDarer/Date F. A. Plesitc RO61-3410801--

ReviwerDat G.J. Mlek12-5-8 RO6-11-83 5-5-84 ~4*

11 R2 13 R4PEN RIW q~de

CONTRACT NO. ABNL OR OPER OPER ACCUR ACCUR QUAL RPTLOC COMPONENT FUJNCTION MFG & MODEL NO. ACD ENVR ENVIRONMENT TO WHICH QUALIFIED CAT REQMT DEO HQT DEMO METHODL I-TE-68-56A RCS Loop 3 CL 71C62-54114-1 42 340'F, 66 psig,' 100% rh,lxlO- rads A 5 min D1Eh~r M 45'F + .20'F WCAP-9157RTD Man Rosemount 176 IF Chem Spray 1.13 wt% H3 B0 3 Type TestL 2-TE-68-56A RCS Loop 3 CL Not Installed 42 -A 5min

RTD ManL 1-TE-68--5bB RCS Loop 3 CL 71C62-54114-1 - -4-2 3400'F, 66 psig, 100% rh,lxlOg rads A 5 min 1 hr + 3.45OF + .2"F WCAP-9157RTD Man Rose-ount 176 UF Chem Spray 1.13 wt% H3 B03 Type TestL 2-TE-6F8-56B RCS Loop 3 CL Not Installed 42 A 3 min

RTD ManL I-TE-68-60 RCS Loop 3 71C62-5411J,-1 42 420"F, 75 psig, 100% rk , 2500 ppm A 100 4 mo + 8 ~~2"F WCAP-8687Cold Leg T~eM Rdf 21205LP Boron, Ph 10.7,2.47xlO rads days Supp. 2-EO6AL 2-TE-68-60 RCS Loop 3 Not Installed 42 A 100Cold Leg Temp

daysL I-TE-68-65 RCS Loop 4 71C62-54114J-1 42 420u'F, 75 psig, 100% rk, 2500 ppm A 100 4 mo + 8 + .2'F WCAP-8687Hot Leg Temp Rdf 21205LV Boron. Ph 1O.7,2.47xi0 rads dasSupp. 2-EO6AL -E6-5 RCS Loop 4 Not Installed- 42 A 10Hot Leg Temp

daysaL 1-TE-68-67A RCS LP 4 HL 71C62-54114-l 42 340 F, 66 psig, 100% rh, lxlO 6'rads A 5 min 1 hr + 3.45 F + .20F WCAP-9157RTD, Man Temp Rosemount 176 UF Chem Spray 1.13 wt% H 3B03 Type TestL 2-TE-68-67A RCS LP 4 HL Not Installed 42 A 5min

RTD Man TempL -TE-68-67B RCS LP 4 HL 71C62-54114-1 42 340 F, 66 psig, 100% rh,lxlO rads A 5 min 1 hr + 3.45F + .2 F WCAP-9157RTD Man Temp Rosenount 176 KF Chem Spray 1.13 wt% H3B03 Typ Tes

L 2-TE-68-67B RCS LP 4 HL Not Installed 42 A 5minRTD Man Temip

L I-TE-68-79A RCS LP 4 CL 71C62-54114-1 42 340uF, 66 psig, 100% rh,IxIOo rads A 5 min 1 hr + 3.45OF + .20 F WCAP-9157RTD Man Rosemount 176 UF Chem Spray 1.13 wt% H3 B03 Type TestL 2-TE-68-79A RCS LP 4 CL Not Installed 42 A 5minRTD Man

L I-TE-68-79B RCS Loop 4 CL 71C62-54114-1 42 340 'F, 66 psig, 100% rh,1x108 rads A 5 min 1 hr + 3.45 F + .2 'F WCAP-9157RTD Man Rosemount 176 UF Chem Spray 1.13 wt% H3B03 Type TestL 2-TE-68--79B RCS Lop4C o ntle 2A 5minRTD Man

1These RTD's will be installed before fuel load.

0

R1 R2 R3 R4

0

E F FE CT IVETABLE 3.11-4 JTABLE INPUT DATA SHEETD A ;E SjP CLS 1E EQUIPMENTSHEET NO: WBN-NEB-11 C

WATTS BAR NUCLEAR PLANTUNITS 1 AND 2

INSIDE CONTAINMENT

Revision 0

Preparer/Date P. B. Nesbitt 6-10-83

Revi ewer/Date R. K. White 6-11-83

R1 12 R3 14

11KWR0 4-19-84

AWLRO 5-5-84

CONTRACT NO. ABNL OR OPER OPER AC CUR ACCUR QUAL EPTLOC COMPONENT FUNCTION MFG1 & MODEL NO. ACD ENVR ENVIRONMENT TO WHICH QUALIFIED CAT REQMT DEMO REQmT- DEMO METHODL 1-TE-68-83 RCS Loop 4 CL 71C62-541,W-1 42 420 F, 75 psig, 100% r4, 2500 ppm A 100 4 ma + 8 + a.2'F W-CAP-8687

Temp Rdf 21205 ~ Boron, Ph 10.7,2.47xl0 rads_ days Supp. 2-E06AL 2-TE-68-83 RCS Loop 4 CL Not Installed 42 A 100

Temp adaysaL 1-TE-68-319 RCS Przr Liquid 71C62-54114-1 42 420 F, 75 psig, 100% rh, 2750 ppm A 100 4 ma + 1.2 F + 1. 2F WCAP-8687,

8TepRdF 21232 Boron, pH 10.7, 1.55 x 10 day2 EQDP-ESE-7

L 2-TE-68-319 RCS Przr Liquid Not Installed 42 A 100Temp days

L I-TE-68-324 RCS Przr Vapor 71C62-54114-1 42 420 VF, 75 psig, 100% rh, J750 ppm A 100 4 ma + I .2"F + l.2'F WCAP-8687,.TepRdF 21232 Boron, _PH 10.7, 1.55 x 10 days EQDP-ESE-7

L 2-TE-68-324 RCS Przr Vapor Not Installed 42 A 100Temp Not Installed adaysa

L I-TE-68-373 Reac Level Cap 71C62-54114-1 42 420 F, 75 psig, 100% 8rh,2750 ppm A 100 4 ma + 5 'F + 1 F WCAP-8687,EQDPCS,-4V.?Tube Temp Comp Minco S8809 Boron,Ph 10.7,1.6xl0 rads days Supp 2-E42A

L 2-TE-68-373 Reac Level Cap Not Installed 42 A 100Tube Temp Comp days

L I-TE-68-376 Reac Level Cap 71C62-54114-1 42 420uF, 75 psig, 100% 8rh,2750 ppm A 100 4 ma + 5uF + 1"F WCAP-8687, E4?DP4659#Tube Temp Comp Minco S8810 Boron,Ph lO.7,1.6x10 rads days Supp 2-E42A

L 2-TE-68-376 Reac Level Cap Not Installed 4-2 A 100Tube Temp Comp days

L I-TE-68-377 Reac Level Cap 71C62-54114-1 42 420 VF, 75 psig, 100%Z8 rh,2750 ppm A 100 4 mo + 5'F + 1I'F WCAP-8687, 54ZTube Temp Comp Minco S8809 Boron,Ph l0.7,1.6xl0 rads days Supp 2-E42A

!L 2--TE--68-377 Reac Level Cap Not Installed 42 A 100Tube Temp Camp days

1 "Ik -1These RTD's will be installed before fuel load.

E43159 .02

9" 14"glg #

TABLE 3.11-4 L I E£C T IV E TABLE INPUT DATA SHEETSHET O: BNNEB2D A T E SWP CLASS IR EQUIPMENT

WATTS BAR NUCLEAR PLANITUNITS 1 AND 2

INSIDE CONTAINMENT

Revision 0

Preparer/Date P. B. Nesbitt 6-10-83

Reviewer/Date R. K. White 6-11-83 RO 5-5-84 /O/*'19

R.1 R2 R3 R4RKW 0-

RO 4-19-84 qpfl$4AWL 1.A

CONTRACT NO. ABNL OR OPER OPER ACCUR ACCUR QUAL RPTLOC COMPONENT FUNCTION MFG & MODEL NO. ACD ENVR ENVIRONMENT -TO WHICH QUALIFIED CAT REQMT DEMO RERMT DEMO METHODL I-TE-68-378 Reac Level Cap 71C62-54114-1 42 420"F, 75 psig, lOOZ8 rh,2750 ppm A 100 4 no + 5-F + 1"? WCAP-8687, E4P-4-56-4-Tube Temp Comp Minco S8809 BoronPh 10.7,1 .6xl0 rads days Supp 2-E42AL 2-TE-68-378 Reac Level Cap Not Installed 42 A 100Tube Temp Comp

daysaL 1-TE-6-8-379 Reac Level Cap 71C62-54114-1 42 420 F, 75 psig, 100% 8 rh,2750 ppm A 100 4 no + 5"? + I F WCAP-8687,(4ODR- 6ý6-'d2Tube Temp Comp Minco S8809 Boron,Ph 10.7 ,1 .6xl0 reds days Supp 2-E42AL 2-TE-68-379 Reac Level Cap Not Installed 42 A 100Tube Temp Comp davsL I-TE-68-380 Reac Level Cap 71C62-54114-1 42 420uF, 75 psig, 00%Z8 rh,2750 ppm A 100 4 no + 5"? + I"? WCAP-8687., P4 -EXSE/#Tube Temp Comp Minco S8809 Boron,ph 10.7 LI.6xl0 rads day Supp 2-E42AL 2 -T E- 68-380F -Reac Level Cap Not Installed 42 A 100Tube Temp Comp daysL I-TE-68-383 Reac Level Cap 71C62-54114-1 42 420'F, 75 psig, lOOZ8 rh,2750 ppm A 100 4 ma + 5 F + l"F WCAP-8687, 641JppeE- 46 d 4-Tube Temp Comp Minca S8810 Boron,Ph 1O.7 ,1!6xl0 rads days Supp 2-E42AL 2-TE-68-383 Reac Level Cap Not Installed 42 A 100Tube Temp Comp days aaL 1-TE-68-384 Reac Level Cap 71C62-54114-1 42 420u?, 75 psig, 100% 8 rh,2750 ppm A 100 4 no + 5 F + I F WCAP-8687,E<JvP-f-4s-:--Tube Temp Camp Minco S8809 BoronPh 10. 7 ,1.6xl0 rads days Supp 2-E42AL 2-TE-68-384 Reac Level Cap Not Installed 42 A 100Tube Temp Camp daysL 1-TE-68-385 Reac Level Cap 71C62-54114-1 42 4200"F, 75 psig,9 100Z 8 rh,2750. ppm A 100 4 no + 5"VF + 10F WCAP-8687,~P~4Tube Temp Camp Minco S8809 BoronPh lO. 7 ,I.6xl0 reds days Supp 2-E42AL 2-TE-6-8-385, Reac Level Cap Not Installed 42 A 100Tube Temp Camp) daysE43 159 .02

0

R1 R2 R3 R4

Preparer/Date P. B. Nesbitt 6-10-83

Reviewer/Date R. K. White 6-11-83

r: 7- ETABLE 3.11-4E7 CT

D) A I ESHEET NO: WBN-NEB-13 j4,

TABLE INPUT DATA SHEETSWP CLASS IE EQUIPMENT

WATTS BAR NUCLEAR PLANTUNITS I AND 2

INSIDE CONTAINMENT

Revision 0 111 R2 R3 R4

Preparer/Date F. A. Plesic 10-21-81 RO

Reviewer/Date G. J. Malek 12-15-81 RO

PBN RKW 946-10-83 4-19-84 V0

8KW AWL

CONTRACT NO. ABNL ORLOC COMPONENT FUNCTION MPG & MODEL NO. ACD ENVR ENVIRONMENT TO WHICH QUALIFIEDL I-TE-68-386 Reac Level Cap 54114-1 42 420-F, 75 psig, 100% 8 rh,2750 ppmTube Temp Comp Minco S8809 Boron,Ph 10.7,1.6xl0 radsL 2-TE-68-386 Reac Level -Cap Not Installed 42Tube Temp Como

OPERCAT REQHTA 100

daysA 100

days

DEOPE ACCR ACCUO

'4 1KV 1~~ I' *1~1 V

QUAL RPTM4ETHOD

WCAP-8687, E4OP.ESE-I 4.

Supp 2-E42A

L l-HTR-83-1 H2 Recombiner 54114-1 West. 41 1700-F, 80 pi,100%,Spin WBiGHREEE-02 2500 pp Bopo. Ph 10*L 2-HTR-83--1 112 Recomrbjner 54 114-1,West. 41 170u,8 s, 100%,Spin WBTGHREEE-02250pmBrnPh1

L 1-HTR-83-2 112 Recomrbiner 5 4 ll 4 -1,west. 41 1700-F- 80 psig, 1,00%,Spi WBTGHREEE-01 2500 ppm Boron, Ph 10*L 2-HTR-83-2 112 Recodbiner 5 4 114-l,West. 41 1700 0 F, 80 psig, 100%,Spin WBTGHREEE-01 2500 ppm Boron, Ph 10L 1-FCV-74-1 RHR Isolation 54114-1 Reliance 315-F, 70 psi8 , 100% ri

Valve Lim SB-2 2 .4x10 rads, 3000 ppmL 2-FCV-74-1 RHR Isolation 54114-1 Reli-ance 31.5-F, 70 psi8 , 100% r1-Valve Lim SB-2 2 .4xl10 rads, 3000 ppmL 1-FCV-T4-2 RHR Isolation 54114-1 Reliance 315-F, 70 psi8 , 100% niValve Lim SB-2 2.4x108 rads, 3000 ppmL 2-FCV-7ý4-2 ýRHR isolation 154114-1 Reliance 315 F, 70 psi8 , 100% niValve Lim SB-2 2.4xl108 rads, 3000O ppmL 1-FCV-74-8 RHR isolation 54114-1 Reliance 315-F, 8 70 psi 8 , 1In

-- Bypass Vhlve Lim SB-i 2 .4x10 rads. 30010 ppmL 2-FCV-74-8S RHR Isolation 54114-1 Relia-nce 315 F, 70 psi8 , 100% rh-- Bypass Valve Lim SB-I 2.4x10 rads. 3000 ppmL I -FCV-7 4 -9 -RHR isolation 54114-1 Reliance 315-F, 8 70 psi8 , 100% rh- Bypass Valve Lim SB-i 2.4xl0 rads, 3000 ppmL 2-FCV-74-9 RMR Isolation 54114-1 Reliance 315,7 s 8 10%r

Bypass Valve Lim SB-i 2.x0rd,30pm

*Not Field Verified

E43159.02

82x10- rads A

2xl0O reds A

2.10 reds A

i, Ph 10.5 ABoron B

LPh 10.5 ABoron B

, h10.5 ABoron B, Ph 10.5 ABoron B,Phl10.5 A

Boron BPh 10.5 A

Boron B 1 mo lOOdva600456. Ago. C

100days100days100days100days15 miniI mo15 mmn1mo15 min1 o15 minI mo15 minI mo15 miniI mo15 minI mo15 mmn

100 NAdays100 NAdays100 NAdays100 NAdays1lhr NA100dvs NAIlhr NA100dys NA1lhr NA100dys NA1lhr NA

LOOdys NA

lhr NA

lhr NlO0dys NA1lhr NAlO0dys NAIlhr NA

NA WCAP-7709Test/Arnalysis

NA WCAP-7709Test/Analysis

NA WCAP-7709Test/Analysis

NA WCAP-7709Test/Analysis

NA Limit Rpt B0058,NA 600456, App. cNA Limit Rpt B0058,NA 600456, App. CNA Limit Rpt B0058,NA 600456, App. CNA Limit Rpt B00589NA 600456, App. CNA Limit Rpt B0058,NA 600456, App. CNA Limit Rpt B0058,NA 600456, App. CNA Limit Rpt B0058,NA 600456, App. CNA Limit Rpt B0058,

1 mo 100dva

Revision 0 Rl R2 R3 R4

PrreParer/Date F. A. Plesic 10-21-81 RO

Reviewer/Date G. J. Malek 12-15-81 RO

OPER

4 Mo

ACCUR

+ 5 F

ACCUR

+ 1 F

TABLE 3.11-4

SHEET NO: WBN-NEB-14

TABLE INPUT DATA SHEETSWP CLASS 1% EQUIPMENT

WATTS BAR NUCLEAR PLANTUNITS I AND 2INSIDE CONTAINMENT

Revision 0 R1

0s

Preparer/Date Alan W. Lewis 6-6-84

Reviever/Dste David L. Kirby 6-8-84

CONTRACT NO. ABNL OR OPER OPER ACCUR ACCIJR QUAL RPTLOC COMPONENT, FUNCTION MFG & MODEL NO. ACD ENYR ENVIRONMENT TO WHICH QUALIFIED CAT REQMT DEMO REQMT DEMO METHODL l-MT-94-l' incore Thermo- 54114-1 Control 42 A I O0dys NEB-94-481 Couple ProL 2-wTE-94-1_ Incore Thermo- 54114-1 Control 42 A lO0dys NEB-94-48

1-T-9- ncoupe Sytherm- 541-Ponrl4rA1ods E-L -WrE-94-2 Incore Thermo- 54114-1 Control 42 A 1 O0dys NEB-94-48

L -r-42 Incore Thermo- 54114-1 Control 42 A 1 O0dys NEB-94-481-TE943 couple System ProL -MT-94-3- Incore Thermo- 54114-1 Control 42 A 1 O0dys NEB-94-48

1-WT -944 Ico rp e vThermo 54 1-Ponr l4rAo~y N B 9L 2-E9-- Incore T-hermo- 54114-1 Control 42 A I O0dys NEB-94-482-TE944 1 couple System Pro

L 1-WTE-94-4 Incore Thermo- 54114-1 Control 42 A I O0dys NEB-94-48L 2WE9-- Incore Thermo- 54114-1 Control 42 A lO0dys NEB-94-481WE-4-' oule System ProL I-T-45-!nkco2re Thermo- 54114-1 Control 42 A lO0dys NEB-94-48

----- __couple System ProL 2-WTE-94-6- Incore Thermo- 54114-1 Control 42 A lO0dys NEB-94-481 couple System ProL l-WTE-94-7- Incore Thermo- 54114-1 Control 42 A 1 O0dys NEB-94-48i couple.Seystem ProL 2-WTE-94-6 Incore Thermo- 54114-1 Control 42 A lO0dys NEB-94-48

l-W T -94 8 Icoup e Syth ermo 54 1-Po tr l4roO ~ y E 9L 2-WTE-9 4-7 ýIncore Thermo- 54114-1 Control 42 A lO0dys NEB-94-48couple- System ProL 1-WTE-94ý-9 ncore Thermo- 54114-1 Control 42 A I O0dys NEB-94-48-, couple System Pro

This includes the incore thermocouples, connectors,adpesanrfrncjutinbx.

0

R2 R3 R4

adapters, and reference junction boxes.

TABLE 3.11-4 _ _EFFECTIVE

SHEET NO: WBN-NEB-15 D AT EDOCT 1934

TABLE INPUT DATA SHEETSWP CLASS 1E EQUIPMENT

WATTS BAR NUCLEAR PLANTUNITS 1 AND 2

INSIDE CONTAINMENT

Revision 0 El R2 R3 R4

Preparer/Date Alan W. Lewis 6-8-84 7/y

Reviewer/Date David L. Kirby 6-8-84 9/4r

LOG COMPONENT1L 2-WTE-94-9

L 1-WrE-94-101

L 2-WTE-94-101

L 1-MT-94-111

L 2-WTE-94-11'

L I-MT-94-121

L 2-wTE-94-12'

L I-WTE-94-13 I

L 2-W~rE-94-131

L 1'-WTE-94-14'

L 2-WTE-94-14 i

FUNCTIONIncore Thermo-couple SystemIcore Thermo-cunle Ssgtem

I-ncore Thermo-couple SystemIncorecoupleIncore

coupleMnorecoupleIncore

COEpleIncorecoupleInc orecoupleIncorecoupleIncore

Thermo-SystemThermo-SystemThermo-SystemThermo-SystemThermo-SystemThermo-SystemThermo-SystemThermno-

CONTRACT NO.MFG & MODEL NO.

54114-1 ControlPro54114-1 ControlPro54114-1 ControlPro54114-1 ControlPro54114-1 ControlPro54114-1 ControlPro54114-1 ControlPro54114-1 ControlPro54114-1 ControlPro54114-1 ControlPro54114-1 Control

ABNL ORACD ENVI

42

42

42

42

42

42

42

42

42

42

ENVIRONMENT TO WHICH QUALIFIED CATA

A

A

A

A

A

A

A

A

A

A

OPERREQMT1 00dys

1lO0dys

Il00dys

Il00dys

100dys

lO0dys

IlO0dys

1O0dys

100dys

1O0dys

IlO0dys

OPER ACCUR ACCUR QUAL RPTDENO REQMT DENO METHOD

NEB-94-48

NEB-94-48

NEB-94 -48

NEB-94-48

NEB-94-48

NEB-94-48

NEB-94-48

NEB-94-48

NEB-94-48

NEB-94-48

NEB-94-48L 1-WTE-94-15i incore Thermo- 54114-1 Control 42 A 10udys NEB-94-48

2-rE I-1 couple System ProL 2-TE-9-15'Incore Thermo- 54114-1 Control 42 A 10y E-44

.couple System ProL I-MT-94-16- Incore Thermo- 54114-1 Control 42 A lO0dys NEB-94-481 couple System ProL 2-MT-94-16 Incore Thermo- 54114-1 Control 42 A lO0dys NEB-94-48

1-TE I-1 couple System ProL -r-41'Incore Thermo- 54114-1 Control 42 A 1 O0dys NEB-94-48

1 couple System ProL 2-WTE-94-17 Incore Thermo- 54114-1 Control 42 A lO0dys NEB-94-48

couple System Pro1 This includes the incore thermocouples, connectors, adapters, and reference junction boxes.

F43159.07

0

TABLE 3.11-4 TABLE INPUT DATA SHEET

SHET N* BR-B-1 EFFECTIVE SWP CLASS 1E EQUIPMENT

SHEE NO WB-NE-16D A T E IWATTS BARt NUCLEAR PLANT1-0~4 UNITS 1 AND 2

INSIDE CONTAINMENT

Revision 0 Ri R2 R3 R4

Preparer/Date Alan W. Lewis 6-8-84

Reviewer/Date David L. Kirby 6-8-84

LOC COMPONENTL I-4MT-94-181

L 2-WrE-94-18 i

L 1-WTE-94-19 1

L 2-WTE-94-19'

L 1-Mr-94-20'

L 2-WTE-94-201i

L 1-MT-94-21'

L 2-WTE-94-21'

FUNCTIONIncore Thermo-

Couple SystemEncoe Thermo-

Couple SystemGncoe Thermo-couple SystemIncore Thermo-couple-SystemIncore Thermo-

coupe SystemGncoe Thermo-couple SystemIncore Thermo-couple SystemIncore Thermo-

.nnl S .ýnr

CONTRACT NO.MFG & MODEL NO.54114-1 ControlPro54114-1 Controlpro54114-1 Controlpro54114-1 ControlPro54114-1 ControlPro54114-1 ControlPro54114-1 ControlPro54114-1 ControlP_-

ABNL ORACD ENYR

42ENVIRONMENT TO WHICH QUALIFIED

42 A

42 A

42 A

42 A

42 A

42 A

OPER OPER AC CURREQNT DEMO REQMTlO0dys

1O0dys

lO0dys

100dys

lO0dys

lO0dys

lO0dys

1O0dys

ACCIJR QUAL RPTDEMO METHOD

NEB-94-48

NEB-94-48

NEB-94-48

NEB-94-48

NEB-94-48

NEB-94-48

NEB-94-48

NEB-94-48

L 1-MT-94-22 inc Th~erm-o- 54114-1 Control 42 A lO0dys NEB-94-48

1 couple System ProL 2-MT-94-22' Incore Thermo- 54114-1 Control 42 A 1 Q0dys NIEB-94-48

1 couple System ProL 1-MT-94--23 Mnoe Thermo- 54114-1 Control 42 A lO0dys NEB-94-48

1 couple System ProL 2-WTE-94-23 ;ncoe Thermo- 54114-1 Control 42 A 1O0dys NEB-94-48

I couple System ProL 1-WTE-94-24' Incore Thermo- 54114-1 Control 42 A lO0dys NEB-94-48

1 couple System ProL 2-MT-94-24 incoe Thermo- 54114-1 Control 42 A lO0dys NEB-94-48

1 couple System ProL 1-MT-94-25 7Mcoe Thermo- 54114-1 Control 42 A lO0dys NEB-94-48

I couple System ProL 2-VTE-94-25 Incore Thermo- 54114-1 Control 42 A lO0dys NEB-94-48

1-TE I-2 couple System ProL -r-42'Incore Thermo- 54114-1 Control 42 A 1 O0dys NEB-94-48p1-n

I This includes

E43 159.02

the incore thermocouples, connectors, adapters, and reference junction boxes.

0s

X Lcou le 9 stem Pro

0

TABLE 3.11-4 E FIFEC T I E' TABLE INPUT DATA SHEET

SHEET NO: WBN-NEB-17 D A TE SWP CLASS 1E EQUIPMENT

OCT 1984 WATTS BAR NUCLEAR PLANTUNITS 1 AND 2

INSIDE CONTAINMENT

Revision 0

Preparer/Date Alan W. Lewis 6-8-84

Reviewer/Date David L. Kirby 6-8-84

0s

010-

CONTRACT NO. ABNL OR OPER OPER ACCUR ACCUR QUAL RPT

LOC COMPONM FUNCTION MFG & MODEL NO. ACD ENVR ENVIRONMENT TO WHEICH QUALIFIED CAT REQMT DENO REQMT DEMO METHOD

L 2-lITE-94-26 Incore Thermo- 54114-1 Control 42 A 1 O0dys NEB-94-48

couple System ProL 1-WrE-94-27 1nc;r Thermo- 54114-1 Control 42 A 10y E-44

1 ouple Sysftem roI 2-WrE-94-27 _noeThro 54114-1 Control 42 A 150dys NEBL94-48

L 1WTE94-28'couple System ProA lOdsNB44L 1-M 94-28 Incore Thermo- 54114-1 Control 42 A 10y E-44

1 o copl System ProL 2-Mf'-94-28 Mnor Thermo- 54114-1 Control 42 A lO0dys NEB-94-48

1 cupl System ProL 1-MT-94-29 InoeThermo- 54114-1 Control 42 A 10y E-44

1couple System ProL 2-WTE-94-29' Incore Thermo- 54114-1 Control 42 A 1 O0dys NEB-94-48

i couple System ProL I-lIT-94-30 ;!or Thermo- 54114-1 Control 42 A lO0dys NEB-94-48

1 couple System ProL I-WT'E-94-31 incore Thermo- 54114-1 Control 42 A 1 O0dys NEB-94-48

1 coupl System ProL 2-WITE-94-31 InoeThermo- 54114-1 Control 42 A 10y E-44

1 co!ple System Pro A l~y E-44

L 2-WITE-94-321; Inoe Thermo- 54114-1 Control 42 A lO0dys NEB-94-48

I couple System ProL 2-Mf-94-32 Incore Thermo- 54114-1 Control 42 A 10y E-44

1 couple System ProL 2-WTE-94-32' Incore Thermo- 54114-1 Control 42 A 10y E-44

1 coupl System PrL 1-WrE-94-33 InoeThermo- 54114-1 Control 42 A lO0dys NEBi-94-48

1 couple System ProL 1-MT-94-34 Incore Thermo- 54114-1 Control 42 A lO0dys NEB-94-48

1 couple System ProL 1-WrE-94-34 ;ncore Thermo- 54114-1 Control 42 A 1 O0dys NEB-94-48

couple System Pro

'This includes the incore thermocouples, connectors, adapters, and reference *junction boxes.

E43 159.02

RI R2 R3 R4

TABLE 3.11-4 E FF E TI VSHEET NO: WBN-NEB-18 1) A T 2

'T. J, S4

TABLE INPUT DATA SHEETSWP CLASS 1E EQUIPMENT

WATTS BAR NUCLEAR PLANTUNITS 1 AND) 2

INSIDE CONTAINMENT

Revision 0

Preparer/Date Alan W. Lewis 6-8-84

Reviewer/Date David L. Kirbv 6-8-84

Rl R2 R3 R4

Abg-e

~/I4

LOC COMPONENT i FUNCTIONL 1 -WTE-94-35- Incore Thermo-

2-WTE-94-351

1 -WTE-94-36

2 -MT-94-~361

1 -WTE-94-37

2-WTE-94-371

1 -WTE94-38'

2-WTE-94-38'

1 -WTE-94-39 i

2-WTE-94-39'

1 -WTE-94-40'

2 -WTE-94-40

1 -HT-94 -411

2 -WTE-94-411

1 -WTE-94-42

2 -MT-94-42'

1-WrE94-431i

coupie SystemLcore Thermo-

coupe SystemHncoe Thermo-

cotpe Systemfncoe Thermo-

COuple SystemIncore Thermo-

coupe SystemYn;oe Thermo-couple SystemIncore Thermo-couple SystemIncore Thermo-

coupe SystemHncoe Thermo-couple SystemIncore Thermo-couple SystemIncore Thermo-couple SystemIncore Thermo-

COuple SystemMnore Thermo-

couple SystemHncoe Thermo-couple SystemIncore Thermo-couple SystemIncore Thermo-

couple Systemnc ore Thermo-

CONTRACT NO. ABNL ORMFG & MODEL NO. ACD ENVR

54114-1 Control 42Pro54114-1 Control 42Pro54114-1 Control 42Pro54114-1 Control 42Pro54114-1 Control 42Pro54114-1 Control 42Pro54114-1 Control 42Pro54114-1 Control 42Pro54114-1 Control 42Pro54114-1 Control 42Pro54114-1 Control 42Pro54114-1 Control 42Pro54114-1 Control 42Pro54114-1 Control 42Pro54114-1 Control 42Pro54114-1 Control 42Pro54114-1 Control 42Pro

ENVIRONMENT TO WHICH QUALIFIED CATA

A

A

A

A

A

A

A

A

A

A

A

A

A

A

A

OPER OPER AC CUR AC CUR QUAL RPT1lEQMT DEMO REQMT DEMO METHODI O0dys NEB-94-48

lO0dys NEB-94-48

100dys NEB-94-48

1 O0dys NEB-94-48

1O0dys NEB-94-48

1 O0dys NEB-94-48

lO0dys NEB-94-48

1 O0dys NEB-94-48

I O0dys NEB-94-48

1 O0dys NEB-94 -48

lO0dys NEB5-94-48

1 O0dys NEB-94-48

lO0dys NEB8-94-48

lO0dys 'NEB-94-48

100dys NEB-94-48

1O0dys NEB-94-48

lO0dys NEB-94-48

I This includes the incore thermocouples, connectors,adtes an rfenc jucinbes

I

caunle 9vatem

adapters, and reference junction boxes.

0

TABLE 3.11-4 EFF EC T IVE TABLE INIPUT DATA SHEET

SHEET NO: IIBN-NEB-19 D A T E SlIP CLASS 1E EQUIPM4ENT

G T0 T A WATTS BAR NUJCLEAR PLANTUNITS 1 MND 2

INSIDE CONTAINMENT

Revision 0 RI R2 R3 R4

Preparer/Date Alan N. Lewis 6-8-84

Reviewer/Date David L. Kirby 6-8-84

CONTRACT NO. ABNL OR OPER OPER ACCUR AC CUR QUAL RPT

LOC COMPONENT FUNCTION MFG & MODEL NO. ACD ENVR ENVIRONMENT TO WHICH QUALIFIED CAT REQM DEMO REQMT DEMO METHOD

L 2-WTE-94-43- Incore Thermo- 54114-1 Control 42 A 1 O0dys NEB-94-48

] couple System ProL 1-MT-94-44' Incore Thermo- 54114-1 Control 42 A lO0dys NEB-94-48

; couple System ProL. 2-WTE-94-44 Incoe Thermo- 54114-1 Control 42 A lO0dys NEB-94-48

Icouple System ProL 1-WTE-94-45' Incore Thermo- 54114-1 Control 42 A 1 O0dys NEB-94-48

copeSystem ProL 2-WTE-94-45 InoeThermo- 54114-1 Control- 42 A 1O0dys NEB-94-48

; ouplee System ProL l-MT-94-46 Inor Thermo- 54114-1 Control 42 A 1 O0dys NEB-94-48

l couple System ProL 2-MT-94-46' Incore Thermo- 54114-1 Control 42 A I O0dys NEB-94-48

1t oul System ProL 1-WTE-94-47 InoeThermo- 54114-1 Control 42 A lO0dys NEB-94-48

L 2-MT-94-47 1 opeSystem ProInoeThermo- 54114-1 Control 42 A lO0dys NEB-94-48

1couple System ProL 1-WTE-94-48 Incore Thermo- 54114-1 Control 42 A 1 O0dys NEBr-94-48

1 couple System Pro___L 2-WrE-94-48 Incore Thermo- 54114-1 Control 42 A lO0dys NEB-94-48

1 couple System ProL 1-WTE-94-49 ;ncor Therno- 54114-1 Control 42 A lO0dys NEB:9-4-48

;couple System ProL 2-MT-94-49 Incore Thermo- 54114-1 Control' 42 A 1 O0dys NEB-94 -48

1 couple System ProL 1-WrE-94-50' Incore Thermo- 54114-1 Control' 42 A 1O0dys NEB-94-48

1 couple System ProL 2-MT-94-50 Incr Thermo- 54114-1 Control' 42 A 10y E-44

lcouple System ProL 1-WTE-94-51^ Incore Thermo- 54114-1 Control' 42 A lO0dys NEB-94-48

I couple System ProL 2-WTE-94-51' Incore Thermo- 54114-1 Control 42 A lO0dys NEB-94-48

Couple System Pro

1 This includes the incore thermocouples, connectors, adapters, and reference junction boxes.

0

TABLE 3.11-4 - -EFFECTIVEISHEET NO: WBN-NEB-20 D)A TE

TABLE INPUT DATA SHEETSWP CLASS IE EQUIPMENT

WATTS BAR NUCLEAR PLANTUNITS 1 AND 2

INSIDE CONTAINMENT

Revision 0 Ri R2 R3 R4

-Preparer/Date Alan W. Lewis 6-8-84

Reviewer/Date David L. Kirby 6-8-84 ~Ie4

Isboe2z/i/ 4l J

CONTRACT No.LOC COMPONENT 1 FUNCTION 14FG & MODEL NO.L 1-MT-94-52' Incore Thermo- 54114-1 Control

1 couple System ProL 2-WTE-94-52' Incore Thermo- 54114-1 Control1 couple System ProL 1 -WT-94-53- Incore Thermo- 54114-1 Control

1 couple System ProL 2-MT-94-53 Incore Thermo- 54114-1 Controlcouple System ProL I-MT-94-54' Incore Thermo- 54114-1 Control

1 couple System ProL 2-MT-94-54- Incore The-rmo- 54114-1 ControlI couple System Pro

L 1-WTE-94-55' Incore Thermo- 54114-1 Control.couple System Pro

L 2-MTE-94--55- Incore The'rmo- 54114-1 Control

ABNL ORACD ENVR

42

42

42

42

42

42

42

42

ENVIRONMENT TO WHICH QUALIFIED CATA

A

A

A

A

A

A

OPERREQMTI 00dys

IlOOdys

IlO0dys

1l00dys

Il00dys

1l00dys

I 00dys

couple System ProL 1-WTE-94-60 ~InoeTeo- 5141Cnrl 4A IOdyNE--4L 2-WTE-94-60' Incore Thermo- 54114-1 Control 42 A 1 O0dys NEB-94-48

1-WTE94-6 nco rpe Sythermo 54 1-Po trl4roO~ y E 9L 2-WTE-94-60 Incore Thermo- 54114-1 Control 42 A 1 O0dys NEB-94-481 couple System ProL 1-WTE-94-62' Incore Thermo- 54114-1 Control 42 A 10y E-44

Aopl Sysdy Pro9-2-WTE-V4-62 Incore Therm- 414- Control 42A 1Ody B-441-T-9-3 nor hem- 54114-1 Coto 2A lO0dys EB-94-481couple System ProL 2-WTE-94-63 -incore -Thermo- 54114-1 Control 42 A lO0dys NEB-94-48.couple System Pro

OPER ACCUR ACCUR QUAL RPTDEMO REQMT DEMO METHOD

NE-4-48

NEB-94-48

NEB-94-48

NEB-94-48

NEB-94-48

NEB-94-48

NEB-94-48

LThis includes the incore thermocouples, connectors,

E43159.02

adapters, and reference junction boxes.

Revision 0 RI R2 R3 R4

TABLE 3.11-4 DA ETABLE INPUT DATA SHEETSHET N: WN-EB-1 DA-T E1~ SWP CLASS 1E EQUIPMENT

WATTS BAR NUCLEAR PLANTUNITS 1 AND 2

INSIDE CONTAINMENT

Revision 0 RI R2 R3 R4

Preparer/Date Alan W. Lewis 6-8-84

Reviewer/Date David L. Kirby 6-8-84 •i5

CONTRACT NO. ABNL OR OPER OPER AC CUR ACCUR QUAL RPTLOC COMPONEN FUNCTION MFG & MODEL NO. ACD ENVR ENVIRONMENT TO WHICH QUALIFIED CAT REQMr DEMO REQMT DEMO METHODL l-WTK-94-64, Incore Thermo- 54114-1 Control 42 A 1 O0dys NEB-94-48

2-IT-4-i couple System ProLI2Mc9-6 re Thermo- 54114-1 Control 42 A 1 O0dys NEB-94-48

L~ 1-1945 cule System ProLIncor4-5 e Thermo- 54114-1 Control 42 A 1 O0dys NEB-94-48

icouple System ProL 2-WTr-94-65 Incoe Thermo- 54114-1 Control 42 A 1O0dys NEB-94-48

couple System Pro

1This includes the incore thermocouple, connectors, adapters, and reference junction boxes.

E43159 .02

TABLE INPUT DATA SHEET : io0at R R3 411BKP CLANS is xQUIPIIDIT t. ter/Dat '/ Z'6d/- Lj/ ",-

3* 11-4/WBNEEB00O1l Lvei r,-e r/,DD:,a te - 4- ia~l .4;

LOC COMPONENTCONTRACT NO. ADILL ORt

KNVIEDOMEKJI? TO WHICH MIALIUZKUOP~E OPER, ACCUE

FUCTO MG 6MOE N ADEMRCAT RZONT DENO REM"Y METHODR14

L 1-ZS-30-15-B

IR l-ZS-30-20-A

L Limit Switch on:1-FCV-30-40-A

L 1-ZS-30-50-B

L 1-ZS-30-52-A

L Limit Switch on:l-FCV-77--127-B

L Limit Switch on:2-FCV-77-127-B

L 1-ZS-30-56-A

Lower ComptPurge Poe SW

Incore InstrRm PurgePos SW

VIV Poe SW

Upper CntmtExh Pos SW

Upper CntmtExh Poe SW

Reac BldgSump DiechFlow Control

Lower CntmtExh Porn SW

824495 NANCOEA-740

824495 NAHCoEA-740

824495 NAMCOEA-740

824495 NAMCoEA-740

824495 NAMCOEA-740

820248 NAMCOEA-740

820248 NAMCOEA-740

824495 NAMCOEA-740

Teinp-34007 Humd-IOOZPress-63 PSIG Radn-2.04x10 8 radsSpray - H3 B03 C3000 ppm) pH-10-11

a/b 5 m/** 0.7 yrs1004

Is to is

Acme-Cleveland QualTest Report EA-740,Rev 1, 2/22/79.

is

to I I

IS II II

IS SI II

SI IS II

IS SI IS

IS IS SI

L SI

~11jIS

ACCiJE QUAL RPT

TABLE hIW DATA SHEEr TLiaaR 2_R3 R4

WB3H CLASS 1E RQUIPHUIT eparer/Date k 9/ ~t' -4 - tV

LvievetlDatu le- If-W13.1 l-4/WBNEEB0002

CONTRACT MD. ABUL OR OVER OPEN LcaRn ACCUu QUAL anTKETHOD

LAA. IfLAUNF.IR VU&LE flu.IO *m Ga ur.I NO. £i;u ,.uVa oavanmnawuAV& wsuaun !LM~ =:=C=___________

L 1,2-FSV-30-134-B Cntmt annulus 821270 TargetDP isol vlv Rock 77J-001

42R1 Temp -385OF liwad -100%

Press -66 psig Radn 1.35xlO8 radsSpray -H 3 B03 (62OO .ppm) ph-8.6-l0

a/b 5 m/100d

211.5d N/A N/A Target Rock ReportNos. 2375 and 3531.

U 1-ZS-30-8-B

L 1,2-LT-3-148-B,156-A, 164-A,171-B

L 1,2-LT-3-172-A,-173-B,-174-B,-175-A

L 1-FSV-62-69-A

L 1-FSV-63-71-A

L 1,2-FSV-77-9-B

IR 2-FSV-31-306-A

Upper ComptPurge Pon SW

St. Gen LevelTransformer

824495 NAMCOEA-740

92784FoxboroModel E13DH

41 Temp -340OF Humd -100% to 5 m/Press - 70 psig Radn - 2.04x108 reds 100dSpray - H3B03 (3000 ppm) ph-10-11

42R1 Temp -37007 liumd - 100%Press -75 psig Radn - 1.8xlo 7RaedSpray -1.14% Boric acid 0.17: NaoH

42RI

RC Loop 3Letdown Flow

SIS Check VlvLeak TestI soleation

RCDT PumpDisch VlvFlow Control

Incore InstRM Chill A CWRtool Vlv

827551 ASCONP831654E

527551 ASCONP831654E

82755 1 ASCOZN'831654E

822950 ASCOWPXHV2O2-300-27

a 5d

3.8 yrs Acme-ClevelandQual Test ReportZA-740, Rev 1,2/22/79.

5.5 d '+16.5 +16.5 Westinghouse SensorINWC YNWC Quel Program, dated

4/26/78.

a 5d of +16.5 +16.5YNWC YNWC

42 Temp-346 0 FPress-11O psigSpraY-H3 B03 (3000

42 to

42R1 it

3 Open item - EEB0019

Humd-100ZRadn-2.0x108 redsppm) pH- 9 .5-10 .5

&/b 5 m/100d

263d NIA N/A ASCO Test ReportAQS21678/TR, Rev A.

1 it 261d N/A N/A

to *,

Is go

0

3.11 -4/WBNEEBOOO3

CDNTRACT NO. ABNL ORt

TA1BLE INPUT DATA SuiwRT1R2 3 M

WNWH CLASS 13 EQUIPMENT?2. 6 4', 4

Lviver/Date Y-- __

WUINTDAMM~Mw YE~ UUhf~a flHAiT3WEflOPVR OPER ACCUR ACCUR

MONT DENO

1K 2-FSV-31-327-B

U 2-ZS-30-8-B

L 2-ZS-30-15-B

L I-FSV-77-16-B

L I-FSV-77-18-B

L 2-ZS-30-20-A

L Limit Switch on:2-FCV-30-40-A

L 2-ZS-30-50-B

L 2-ZS-30-52-A

L 2-ZS-30-56-A

Incore inst 822950 ASCORM Chill B CUR HV200921-IRPIsol Vlv

Upper ComptPurge poo SW

Lower ComptPurge poa SW

RCDT to GasAnalyzer FlowSol Vlv

Rcdt to VentHDR FlowControl

Inc ore instrRH PurgePoo SW

Vlv Poe SW

Upper cntmtExh Poe SW

Upper cntmtExh Poe SW

Lower cntmtExh Poo SW

824495 NAMCOEA-780

824495 NAHCOEA-780

827551 ASCONP831654E

827551 ASCONP831654E

824495NAMCO EA-780

824495NAHCO EA-780

824495NAMCO EA-780

824495NAMCO EA-780

824495NAMCO EA-780

3 Open item -. EEBOOI9

44 Open item - EEB0059

a/b 5 m/**100d

of 5m/100d

it of

42RI Temp-3460F Humd-100%Press-11O paig Radn-2.0x10 8 radsSpraY-H3 B03 (3000 ppm) pH-

9 .5 -1 0 .5

42R1 t

"261d M/A N/A ASCO Test ReportAQS21678/TR, Rev A.

"1 $1 i N/A N/A

45& Open item - EEB0059

"34

I I of

LOC ci~

0

QUAL ftPT

LOC MONENT FUNCTION HFG So HODEL NO ACD ENVK WINBUTZInumck" qrn UUTPM TRIED CAT RRONT DENO

of I I

TABLE IMMU IDATA SUMLKsin0R R 3 R

WEW CLAS is equIKN *3rrDto )e 71. d/ .-,--*

3.11 -4/WBNKEE30004

CONTRACT NO. ADUL OR

FUNCTIONY NYC Aai~ flNA!1IK NO Atiy Di' ZMf f

OERg OVER AcCUR ACCUi

Incore instr 824495RN Exh Pos SW NAMCO EA-780

Open itepn - EEB0059

L 2-FSV-1-181-A,* 182-B, 183-A,184-B

L 2-FSV-90-108-B,* 109-B

L 2-FSV-90-l 10-B

L 2-FSV-90-l 14-B, 115-B

L 2-FSV-90-116-B

L 2-FSV-77-127-B

L Limit Switch on:1 ,2-FCV-77-18-B

L Limit Switch on:1,2-FCV-63-71-A

SG B lowdownIsol VI,,Inside cntmt

Cntmt BldgLwr ComptNon-Isol Vi,,

Cntmt BldgLwr ComptMon-Iso 1 Vi,,

Cntmt BldgUp CoinptMon-Isol VI,,

Cntmt BldgUp CompelMon-Isol VI,,

Reac Bldg SumpDisch FlowSol VI,,

RCDT to ventHDR flowcontrol

83577 ASCO11T8300B58RUJ

85629 ASCOHTX8320A22V

85629 ASCOH1TX8320A22V

42 Open item -.EEB0077

61 Open item -EEB0019

85629 ASCOHTX8320A22V

85629 ASCOHTX8320A22V

820248 ASCOWPX-HV202-301-IF

824495 NAIACOEA-180

SIS check Vlv 824495 NAMCOLeak test Isol KA-180

42 Temp-3400 F Pre ss-70 pailHumd-100% Radn-2.O4xlOn radsSpray-H3 B03 (3000 ppm) pH-

1 0-1 1

42 Temp-340O7 Press-70 psigHumd-100% Radn-2.04x10i radaSpray-H3B03 (3O00 ppm) p11-10-lI

,I It

II II

II IS

SI II

IS 55

,S S~

@1 ~ 2.2 yra

a/b 5 m/*2.2 yro100d

NAMCO Teat ReportQTR-1OS, Rev 1.

NAHCO Test ReportQTR-105, Rev. 1.

LOC COMPONENT

L 2-ZS-30-58-Ba/b 5 a/**

100d

QUAL UP?

VE

3.1 l-4/WBNEEBOOO5

C)NT3ACT MD. AMN ORWENKIT __ FUNCTION MIFG & N003L NO. ACD ENVE

TABU INPUT DATA 8833;;?- 23R

"I M etlat V- WeOL4

VMUIDnMMeMF 9fl LMai~!,a IU~ALiWIffhOPER OVE

r'AT *EIY uSif

U Limit Switch on: Inlet Iso Vlv 824495 NA14COl,2-FCV-61-97-B Reactor bldg EA-180

41 Temp-3400 F - Press-70 psi8INumd-100% Radn-2.04x100 radsSpray-H3 B03(3000 ppm) pli-lO-il

a/b 5 m/100d

3.7 yrs N/A NAMCO Teat ReportQTR-105, Rev. I

*U Limit Switch on: outlet Iso Vii,1,2-FCV-61-122-B Reactor Bldg

U Limit Switch on: Glycol Supply 824495 NAMCOl,2-FCV-61-192-B Iso Vlv EA-180

*U Limit Switch on: Glycol Return1 ,2-FCV-61-194-B Iso Vlv

L Limit Switch on: RCDT Pump Disch1, 2-FCV-77-9-B Vlv Flow Control

41 Temp-3400F Press-7 psi IHumd-lOOZ Radn-2.04x100 radsSpraY-H3 B03C3000 ppm) p11-10-il

I I N/A N/A NANCO Test Report

QTR-105, Rev 1.

IS ofo N/A N/A

11 to 2.2 yr. N/4,

L Limit Switch on:1 ,2-FCV-68-308-B

L Limit Switch on:1 ,2-FCV-77-16-B

L Limit Switch on:1, 2-FCV-90-108-B,109-B, 110-B

L Limit SwitchS, 2-FCV-90-1 14-B,115-B, 116-B

RCS flow cntl 824495 NAMCOVlv WDS GA to EA-180Prt

RCDT TD GasAnalyzer flowControl

Cntmt BldgLwr ComptMon 1801 VlV

Cntmt BldgUp ComptMon Isol Vlv

85629 NANCOEA-180

85629 NAMCOEA-180

Is I$14

SI IS

SI SI LI:___42 Temp-3400 P Press-70 psi I

liumd-lOOZ Radn-2.04x100 radsSpray-H3B03 (3000 ppm) pH-I0-11

a/b 5 m/** 2.2 yr.100d

LAMCO Test ReportrrR-105, Rev 1.

I$

so

NAXCO-Test ReportQTR-105, Rev. 1.

W.C COP/ACOIIemit

AORr~u~nubom ~n U~rr Yven EWi

QUAL WpT

it is N/A N/A

MZTHOD

0

TAULE INPUT DATA SUET WZ0 1R 32VUM CIASS 13 SII1HhT to 4Ir

e erDaeZ

1 26 r-II: 0 02

Levee/D:L ~~ ¶

3.11-4/WBNEEB00O6

LOC CawowwrCOWBACT MD. ASUL OR

hIJ3M~T~nN MW2L.-d wnlL M AftDU wUuWflhIamwu tfluhi'fl 151*3 IWWW*tOPF& OPEl

1AP *Wmi ft3E~ flm'~ flu.'"'-- - ----- ------ -- - -. -e mauve eauw.. us .w w.x.ee matS usewa em- =e~n. -

/ACU ACCUR QmA IF?

L 1-757-43-2-B

L I-FSV-43-11-B

L 1-FSV-43-34-B

L 1-FSV-43-201-A,202-A

L I-FSV-43-207-B,208-B

L 2-FSV-43-201-A,202-A

L 2-FSV-43-2-B

L 2-FSV-43-11-B

L 2-FSV-43-22-B

PressurizerGas Cntmt1501 VIV

PressurizerLiq cntmtISO Vlv

Accum Tk HdrCntmt Isol Vlv

LOCA H2 CntmtMonitor 1*01Sol VIV

LOCA 112 CntmtMonitor IsolSol Vlv

PressurizerGas cntmtIsol VIV

PressurizerLiq cntmtIsol Vlv

RCS Hot LegsHdr cntmtIsol Vi,,

85629-2 ASCO206-38 I-3RF

85629-2 ASCO206-381-3RP

42RI Temp -34607 Huad - 100Press -110 psig Radn -2.0:I0

8 radsSpray -131103(3000 ppm)PH - 9.5-10.5

42RI Temp-3460F .Humd-100ZPress-11O psig Radn-2.0z108 radsSpray - H3B03 (3000 ppm) pH-9.5-10.5

a/b 5ma/100d

a/b 5 m/**100d

go m

100d

827551 ASCO206-38 1-3RF

827551 ASCO206-381-3117

87374 ASCO206-381-3RVF

827551 ASCOHV206-38 1-3RVF

827551 ASCOHV206 -38 1-2RVF

827551 ASCO117206-38 1-3RVF

42R1 Temp-3460 F Humd-100%Press-11O psig Radn-2.0x10 8 radsSpray-H3 B0 3 (3000 ppm) pH-9.5-10.5

42RI Open item - EEB0020

42RI Open item - EEB0020

42RI Open item - EEB0020

42Rl Open item - EEB0020

$I so

so S

261d N/A N/A ASCO Test ReportAQS21678/TR, Rev A.

261d N/A N/A ASCO Test Report.AQS21678/TR, Rev A.

to N/A W/A

is N/A N/A

01 N/A

L7

0

0

TABUE INPU DATA SHEET -iigcR 2jqR

VIEW CLASS 13 BQUU"T Dre/atE.NT-V f/

Lewetr/Date A-nn 03.11-4/WBNEEB0007

CONhRACT NO. AnnL OR OVER OVER,.n~w~inn... v~in ni .wt firmn

ACaii ACCURmw.i OEM

MN.U SAIM"UW.N VUNU.ILuU IM~ 4 IUMI no. ALU DEWA 5MVAUIuIM UWAM !LI.&N=&IW & =:= --

QuAL mP

L 2-PS V-43-34-B

L 2-FSV-43-75-B

*L I-FSV-43-22-B

L I-FSV-43-75-B

*L 1-FSV-62-70-A

L I-FSV-62-72-A,73-A,74-A .

L l-FSV-68-308-B

L 2-FSV-87-7-A, 8-A

L 1, 2-FSV-43-54D-B

Accum Tk Hdr 827551 ASCOCatmt Isol Vlv EV-206-381-3RVF

DNSTR ExcessLtdn Hit Exch18o01 VlV

RCS Hot LegsHdr cntat18o1 VlV

DNSTR ExcessLtdn lit Exchtadl VIw

RtC Loop 3Letdown Flow

Regen litExcb LetdownIsol VI,,

RCS Flow CntlVlv Wds GA, toPRT

827551 ASCOliV206-38 1-3RVF

827551 ASCONP83 1654E

827551 ASCONP831654E

827551 ASCONP83 1654E

827751 ASCONP831654E

Test Line Isol 827751 ASCOVlv Flow Cntl NP831654V

Stm Gen Cntmt 828068 ASCOIsol Sol 206-381-3R1

42RI Open item - .EEB0020

42R1 Open item - EEB0020

of go

a/b 5 m/**100d

42R1 Temp -34607 liumd - lOOt 01 5 m/Press -110 paig Radn - 2.01108 wads 100dSpray H leBO3(30OO ppm) pHi-9 .4 -10 .5

@I I I

42RI

42RI Temp -34607. liumd-100%Press -110 psig, Radn . 2.OxlOgradsSpray -H 3 B03 (3000 ppm) pHi-9.5-lO.5

4211 Open item - EEB0028

42R1 Temp-3460F Humd-100%Press-11O paig Radn-2.0x108 radsSpray-H3B03 (3000 ppm) pli-9.5-1O.5

SI IS

6S SI

IS SI

IS II

SI IS

261d N/A NIA ASCO Tlest ReportAQS21678ITR, Rev. A

of /A N/A

is N/A N/A

to N/A N/A

go N/A N/A ASCO Test ReportAQS21678/TR,Rev A.

263d N/A N/A

L

0

0

TAML INPU DATA SHEET ý an0 R R3 4

WW CAWI QU M ever/Date jjA 7 .3.1 1-4/WBNEEB6OO8-

ICOC CopwOBuW

L 1, 2-FSV-43-56D-B,59D-B ,6 3D-B

IR 1,2-7SV-31-308-A

ZR I-FSV-31-327-B,

IR 1,2-FSV-31-329-B

U 1-FSV-6 1-97-B2-FSV-61-97-B

U l-FSV-61-122-B2-FSV-61-122-B

U 1-FSV-61-192-B2-FSV-61-192-B

U 1-7SV-61-194-B2-FSV-61-194-B

ZR Limit Switch on:2-FCV-31-306-A,308-A, 329-B

FUNCTION

St. Gen Cntmt1301 Sol

Incore InstRN Chill ACWS Isol Vlv

Incore InstRm Chill BCUR Isol Vlv

Inlet IsolValve ReactorBldg

Outlet IsolValveReactor Bldg

Glycol SupplyIsol Valve

Gylcol ReturnIsol Valve

Incore Inst RmChill A CURIsol Vlv

CONTRACT NO.MFG 4 MODL MO.

828068 ASCO206-381-3RF

822950ASCO 206-381-2F

822950ASCO 206-381-3F

822950 ASCO206-381-2F

827551 ASCONP831654E

827551 ASCONP831654E

822950 NAHCOEA-1 70

ASIL ORAd

OPKIWDIEM ZKVIEDOMEW TO WHICH WUAIFIED CAT BeW

42RI TemýP-346-7 Huad-1OOX a/b 5 a/**Press-11O paig Radn-2.0x10 8 rads 100dSpraY-H3B03 (3000 ppm) pH-9.5-10.5

45 Temp -34601 Humd - 100% a/b 5 mI**Press -110 psig, Radu - 2.OxlO8 rads 100dSpray -H 3B03 (3000 ppm)PH - 9.5-10.5

45 ofo 5 m/100d

is I I

41R0

41R0

41R0

41RO

of I

45 Open item - EEB0006

OVERIDEMO

263d N/A W/A

263d

QUAL RI?METHOD

ASCO Test ReportAQS21678/TR,Rev. A.

ASCO Test ReportAQS21678/TR, Rev A.

it N/A N/A

It N/A N/A

24438yrs

of

SIL : 41I

0

TAMSL IIWM DATA SMIEff V . t K 3 R

WNvcmisewm *aer/Date - k

OPEl OPEliUVIRMMmuT TO WHICH QUALIFEID CAT RUONT DEMO

U 1,2-XE-68-340A,334, 363, 364,365

U 1,2-XT-68-340A,334, 363, 364,365

L 1-FSV-43-251I-FSV-43-310

L I-FSV-43-2881-FSV-43-319

L Limit Switch on:1-FCV-62-69I-FCV-62-70

L 1-FCV-1-181--A,182-B, 183-A,184-B

L 2-FSV-77-16-B

L 2-FSV-77-18-B

Acoustic VlvPoe Accel

Acoustic VlvPoe ChgConverters

RCPB Isol

827118ENDEVCO 2273A

827118TEC 504A

Target Rock82KK-001

Target Rock82KKC-002

NAMCO EA180

Steam Gen 832045Blwdn Viva Target Rock

82AB-001

RCDT to GasAnalyzer FlowSol Vlv

ASCO 827551NP831654V

RCDT to Vent ASCO 827551HDR Flow Cont NP831654V

42RI Temp -510OF Hund - 100%Press -85 psig Redo - 2.2xlO8 radsSpray H 3B03 (13,000 ppm) PH - 7-7.5

42RI

42R1 Temp-3850 F liumd-1O0lPress-66 psig Radn-1.35%10 8 radaSpray-Boron/Hydraz ine

42R1 Temp-3850 F Humd-lOOXPreaa-66 psig Radn-1.35x10 8 radsSpray-Boron/Hydraz ine

42 Temp-3400 F Humd-lO0lPreas-105 paig Radn-2.04xl08 rads

42 Temp-385 0 F Humd-lO0lPress-66 paig Radn-1.35xl08 radsSpray-6200 ppm Boron/SO ppmHydrazine PH 8.6-10

42 Open item - EEB0020

a 10Od** 116.9d * TEC Report517-TR-03, Rev. 2

"1 100d

a 1O0d 211.5d -N/A Target Rock ReportNos. 3619 & 2375

a 100d 211.5d N/A N/A Target Rock ReportNos. 3619 & 2375

a/b 5 m/I mo

&/b 5 m/100d

a/b 5 m/100d

198d

159.4d N/A

42 Open item - EEB0020 a/b 5 m/100d

N/A NANCO Test ReportNo, QTR-105, Rev. 3

N/A Target Rock ReportNo. 3563

E FFi-F C" V EOC T irE

0

3.1l-4IWBNEpzBOD09

LOC ~UUOM?COUTACT NO. LAlL OR

31IWCIfM NM1 A. uamine am Arn mus11ACCIR ACCUa QMA an?

NETMODRRM" ORTWOLOC CONPONEUr

E F F I VEDATE

cOT 12-I 3oS4*~3 .l1-4/WBNEEBOOIO

LOC COMPONENT FuDI

* Limit switch on:L 1-FCV-30-1 7-A

L 2-FSV-62-69-A

L 2-FSV-62-72-A,* 73-A, 74-A

Limit switch on:IIR 1-FCV-31-306-A,

* 308-A, 329-B

L 1-FSV-30-15-B,40-A, 50-B, 52-A,

* 56-A, 17-A

.III 1-ZS-30-58-B.

L 1-FSV-62-76-A

L I-FSV-87-7-A1 -FSV-8 7-8-A

IIR 1-FSV-30-58-B,20-A

CONTRACT MD. AMONITION IWO & MODEL NO. LCD'LIVE

RC Loop 3Letdown Flow

Regen Ht ExchLetdown 1.01VlV

Incore InstRm Chill ACvr Isol Vlv

Isol VlV

827551NAMCO EAlSO

827551 ASCONP831654V

827551 ASCONP831654V

832128NAHCO EA740

827551 ASCOX206-38 1-3RP

Incore Inatr 832128Pnm Exh Pos Sw NAMCO EA740

Cni!mt Isol &Ldn Isol

Teat LineIsol Vlv FlowControl

Isol VlV

54114 ASCONPX831654E

827551 ASCONP831654E

827551 ASCOX206-38 1-3R7

TANLE INPUT DATA MHET Reisoa

OVER OPER,ENVIRONSMENT TO WHICH OJJAIFIED CAT OT~ DEWD

-41R0& Temp-3400 1 liumd-100%-42R1 Press-70 paig lRadn-2.04x10 8 rada

-42 Open item -EEB0028

-42 Open item - EKB0028

45R0 Temp-34007Press-63 paig

Humd-100%Radn-2.04xI08 rada

-42R1 Temp-346 0 F liund-lOOX-45R0 Presa-11O paig Radn-2x10 8 rads

Spray-3000 ppm Boron/pH 9-11

45R0 Temp-340 0 F Rumd-100%Presa-100 paig Radn-2.04xI0 8 rada

-61 Temp-346 0 F Rumd-100ZPress-11O paig Radn-2x108 radaSpray-3000 ppm Boron/pH 9-11

-42 Temp-346 0 F Humd-IOOZPress-11O paig Radn-2xl08 radaSpray-3000 ppm Boron/pH 9-11

-42RI Temp 34607-45R0 Press-11O paig

Spray-3000 ppm

Humd-1OOZRadn-2x10 8 rada

Boron/pH 9-11

a/b 5 m/100d

a/b 5 m/100d

a/b 5 a/100d

a/b 5 m/100d

a/b 5 m/100d

a/b 5 m/100d

a/b 5 m/100d

a/b 5 m/100d.

a/b 5m/100d

181d

265d

292d

251Id

29 2d

263d

29 2d

ACOIR ACCUI QIIAL an

N/A N/A NANCO Qual TeatReport No. QTR-105,Rev. 3

NAIACO Qual. TeatReport dated 2/20/78

N/A N/A ASCO Test Report No.AQS21678/TR, Rev. A

N/A N/A NAMCO Teat ReportNo. QTR-111, Rev. 0

N/A N/A ASCO Teat Report No.AQS21678/TR, Rev. A.

N/A N/A ASCO Test Report No.AQS21678/TR, Rev. A

N/A N/A ASCO Teat Report No.AQS21678/TR, Rev. A

0

3. 11-4/WBNEEBOO1l

0

TANAE INPUT DATA SU fa1s1n0 1KZ13 R

WSWI CLASS 13 UVIPflNTI? j re/Dt AAA

CONIWTAT NO. ABUL ORt 0111 0111ENVIRONMENT To WHICH OUALIFIRD CAT__UQMT DENO

ACCUR ACCURREONT -DEWG

L 1-FSV-90-108-B,I -FSV-90-1 l0-b~

L I-FSV-90-114-B,115-B, 116-B

1lR 1-FSV-31-306-A

L 2-FSV-63-71-A

L 2-FSV-68-308-B

L 2-FSV-62-70-A

Cntmt BldgLvr CoinptHon-Isol Vlv

Cntmt BldgUpr ComptHon-Isol Vlv

Incore InstRm Chill ACwr Isol Vlv

827551 ASCOX206-38 1-3R1

827551 ASCOX206-38 1-3RF

827551 ASCOX206-38 1-3RP

SIS Check Vlv ASCO 827551Leak Teat Isol NP831654V

RCS Flow Cant ASCO 827551Vlv Uds GA to NP831654VPRT

RC Loop 3 ASCO 827551Ltdn Flow NP831654V

-61 Teamp-3460 F Huad-1OZlPress-11O pug Radn-2x108 redsSpray-3000 ppm Boron/pH 9-11

-61 Temp-346 0 F Humd-100%Press-11O psig Radn-2x108 redsSpray-3000 ppm Boron/pH 9-11

-61 Temp-3460 F Humd-100%

Press-11O psig Radn-2x108 reds

Spray-3000 ppm Boron/pH 9-11

42 Open item - EEB0020

42 Open item - EEB0020

42 Open item - EEB0020

a/b 5 a/100d

a/b 5 m/100d

a/b 5 m/100d

a/b 5 m/100d

a/b 5 m/100d

a/b 5ma/100d

292d

292d

N/A W4A ASCO Test Report No.AQS21678/TR, Rev. A

N/A N/A ASCO Test Report No.AQS21678/TR, Rev. A

2924 N/A N/A ASCO, Teat Report No.AQS21678/TR, Rev. A

QUAL OPT

LOC COMPONENT FUICTION HVG & NOWL NO. ACD'ZNVR

0

TABLE INUT DATA SHUT I

_ _pat ylsina 02 R7 lo2 R3 RWNWe/Dt CLUB Ig opmu3.*1 1-4/WBNEEBOO12

CONTRACT MD. ARUL OR OWES OWES ACCIS ACCISENVIEOMMIENT To WHI1CH OUALI PLED CAT lIONT DENO ILR4W T DEMO

U I-PCV-68-334I -PCV-68-340A

* 334-B, 340-A

*U l-FSV-30-8-BI -FSV-30-10-A

L 2-VSV-43-207-B,208-B

L lFSV-90-l09.B

IIR 1-FSV-77-127-B

IIR Limit Switch on:I-FCV-31-327-B

PressurizerPORV

Upr ComptPurge IsolVlV

LOCA H2 CntmtMonitor IsolSol VlV

Cont Bldg LvrComp Air Montr1301 Vlv

Reactor BldgSump DiscCntmt Isol VIV

Target Rock831934, 82UU-001

ASCO 827551X206-38 1-3R1

87374 ASCO206-38 1-3RVF

827551 ASCOX206-38 1-3RF

827551 ASCOX206-38 1-3RF

IIR Chiller B 832128CWB 1801v Vlv NAI4CO EA 740

41 Temp-385 0 F Press-66 psigHumd-100Z Radn-l .35x1Oe radsSpray-6200 ppm Boron, 50 ppmHydrazine/pli 8.6-10

41R0 Temp-346 0 Fliumd-100%Spray-3000

Press-11O paigRadn-2xl08 rads

ppm Boron/pH 9-11

42RI Open item - EEB0020

61 Temp-346 0 FHumd-100%Spray-3000 ppm

61 Temp-3460 FHumd-100%Spray-3000 ppm

Press-100 psigRadn-2x10 8 rads

Boron/pH 9-11

Press-lao psigRadn-2x10 8 rads

Boron/pH 9-11

4510 Temp-340'OF Press-7 5 pHumd-1O0l Radn-2. 04xO rad

a 100d 182d N/A N/A Target Rock QualReport No. 3543

a/b 5 m/100d

890d ASCO Test Report No.AQS21678/TR, Rev. A

$I of

a/b 5 m/100d

a/b 5 m/1O0d

a/b 5 m/100d

292d

29 2d

166d

N/A N/A ASCO Teat Report No.AQ521678/TR, Rev. A

N/A N/A ASCO Test Report No.AQS21678/TR, Rev. A

N/A N/A NAMCO Test ReportNo. QTR-111, Rev. 0

**a-second; in-minute; d-day; wk-weeks mo-month, yr-year.

DE06;RNB.4

0

LOC CWWOIW!QUAL RIT

LOC COMPONENT FIRWTIOV MG L MODEL NO Arn -RmusI

0

Table No.: 3,11-4Sheet No: WBN-EEB-1001

TABLE INPUT DATA SHEET

wBN CLASS iF EquiPmENT

INSIDE CONTAINMENT

0

R.,, eeer/ Date Ff zCONTRACT NO. ABNL OR Oi'ER OPfR ACCUR ACCUIR QUAL RPT

LUC COMPONENT FUNCTION WG & MODEL NO. ACO ENYR ENVIRONMENT TO WHICH QUALIFIED CAT RE MT DEMO REQMT DEMO - METHOD

U *L2-RE--90-271-A. U Ins Cant 92759 General 7o Temp-5 0 Hud-OO 0ldavs'.1.58 YrE 5O 50OX General Atomic

272-B Post Acd Area Atomic RD-23 Press-91.4 psia Radn-2.1x10 8 rads _______Report E-254-96(

__________Mnn_______ Spray-H3B0_.. (3000 ppm) pH-10-11____ Rev. 1

4t74t23 5-L 1.2-RE-90-273-A. L Ins Cant 74&l I Ii i

274.-B Poet A, AreA _______ ___ ________________

MonL Conduit Seal Seal moisture 836056,836071 T emp - 4300 F8 Press - 70 psig a 1 yr 1 yr CSgee QS EEB-CnnPefrR- in cond,,irq-e ____ Ran_____8 ad

from devices ECSA Spray- H 3B03 /NaOH/Na 2 S20 3 ___ ______

L Stainless Steel ASCO valve to 836772, ServicA-r" Tep-32-70F Pre~ss -e EQ psE1 r 1yr___ O-Flexible CofiduitConax ECSA COMoanv type RiaTnToo% Sprays I o ffce

connector SS63 -uc 0% Sry ntafce

___ ___ _ ___ _ _____ ___ OCT 18

0

TABLE INPUT DATA SHEETSWP CLASS 1E EQUIPMENT

OUTSIDE CONTAINMENTANNULUS UNITS 1 AND 2

Revision 0 RI

PHN

R2 R3 R4

1KW til-dPreparer/Date G. J. Malek 10-21-81 10 6-10-83 4-19-84 &4//V'

RKW AWL 'ge.XReviewer/Date F. A. Plesic 12-15-81 RO 6-11-83 5-5-85 ,ht

CONTRACT NO. AWNL OR OPER OPER ACCUR AC CUR QUAL RPTLOC COMPONENT FUNCTION MFG & MODEL NO. ACD ENVR ENVIRONMENT TO WHICH QUALIFIED CAT REQMT DEMO REQMT DEMO METHOD

ANN I-PDT-30-42 Cntmt Press 54114-1,Foxboro 44 318' 0 90 Psig, 100% rh, A 100 100 * * WCAP-8541Diff Emitter E11GM-HSAA1 2x1 0j rads days days

ANN 2-PDT-30-42 Cmtmit Press Not Installed 44 A 100Diff Emitter days

ANN 1-PDT-30-43 Cntmt Press 54114-1,Foxboro 44 318 05,9 sg 100% rh, A 100 100 * * WCAP-8541Diff Emitter E1MSAI2x10 rads days days

ANN 2-PDT-30-43 Ctmtt Press Not Installed 44 A 100Diff Emitter days

ANN I-PDT-30-44 Cmtmt Press 54114-1,Foxboro 44 318 05,9 s 1001 rh, A 100 100 A- WCAP-8541Diff Emitter E11GM-HSAAI 2x10 rads days days

ANN 2-PDT-30-44 Cntmt Press Not Installed 44 A 100Diff Emitter days

ANN I-PDT-30-45 Cntmt Press 54114-lFoxboro 44 318 0,90si,10rA 10 10 * WCAP-8541Diff Emitter E11GM-HSAAI 2x10 rads days days

ANN 2-PDT-30-45 Cntmt Press Not Installed 44 A 100Diff Emitter days

ANN 1-FSV-68-307 RCS Flow Cnt Vlv 54114,Asco 44 104 0 F. Atm, 5.OxlO'7 rads A 5 min 1 hr NA NA Asco Rpt AQSWDS GA to Rpt 206-381-3RF B 100 days 100 days 21678/TR Supp 3

ANN 2-FSV-68-307 RCS Flow Cnt Vlv Not Installed 44 A 5min NA NAWDS GA to Rpt B 100 days

E43 160.02*Existing equipment cannot attain required accuracy. Relaxing the existing requirements is being reexamined.

TABLE 3.

SHEET No-

0

DiATE7~%CT.VE.uJT ::04

3.11-5/WBNEEBO001

TAXLE INPUT DATA SHEET evsn0R1 2 R3 4

aRPCU 9EU W upare/Date /e3 71.

E iewar/Date 6 ... ./- 'y- al

*LOC COMPONENTANN l,2-H2 AN-43-

200, 210

ANN 1,2-FSV-30-1 35-A

ANN 1-PSV-32-80B-A,102B-B

ANN 1-FSV-32-110B-A

ANN 2-FSV-32-81B-A

ANN 2-FSV-32-103B-B

ANN 2-PSV-32-11IB-B

ANN Limit Switch on:I -FCV-3 2-80-A,102-B, 110-A

ANN Limit Switch on:2-FCV-32-81-A,103-B, 111-B

CONTRACT NO.WIIouq fl- u moom% &. goonflft un

LOCA H2 CntmtMonitor

Cntm~t AnnulusDF taol Vlv

Reactor BldgUnit I TeatSol

Reactor BldgUnit I Non-EssentialCont Air ladl

Reactor BldgUnit 2 TestSol

Reactor BldgUnit 2 Train BIsol

Reactor BldgUnit 2 Non-Essential.Coat Air Isol

RB ControlAir Isol Vlv

RB ControlAir Isol Vlvl

821324Comaip Inc.Model K-IIIM

821270Target Rock77J-001

827551ASCO206-380-2RU

827551ASCO206-380-3RU

822950ASCOWPHT826 2D22

ADUL ORAI'- CMifis

44ROENVI3DUNEKT TO WHICH %!aLIFIED

Temp-1650F Humd-1OOXPress-Atm Radn-lx107 rads

44R0 Temp-3850 FPress-66 paig

Ifumd-100%Radn-l.35x108 rads

44RO Temp-3460F Humd-10OXPress-11O paig Radn-2xl08 rada

44R0

5 Open item - EEB0044

Open item - EEB0044

Open item - EEB0044

822950NAMCO EA-180

44 Temp-34007. Press-70 psiEumd-100% Radn-2.04xl00 radsSpray-H3B03 (3000 ppm) p11-10-11

Olga OPEl

a 100d** 100d

a/b 5 m/100d

ACCUR ACCUR.EI DEWO

-+1.ZH2-(Vol)

211.5d N/A

b 100d 2.73 yra

b 100d 2.73 yra N/A

QIAL RIT

Wyle Labs TestReport No. 17502-1

N/A Target Rock ReportNos. 2375 & 3531.

N/A ASCO Teat Report No.AQS21678/TR, Rev. A

N/A ASCO Teat Report No.AQS21678/TR, Rev. A

b 100d

b 100d

b 100d

a/b 5 m/** 3.8 yra100d

NAMCO TestReport QTR-105,Rev 1.

44 so go of

CAT REnMT DENO

TADLE INPUT DATA SHEEPT rv. i R 3 2

vauP CLASS 11 ZU~uI1NlT Learet/Dte,7-3.*1 1-5/IJBNERBOO02

SLOC COIPNNENTcouTRAC No. AsuL ORt

1NVtf~fl4KN? ?O WlU~R filiAL! 11KBOPEl Oflft ACCUi ACCUR

FUNCTION~~~~~mt Nn OELN C'EV A R rDNANN 1-FSV-90-107-A,

111-A, 113-A,117-A

ANNM 2-FSV-90-107-A,111-A, 113-A,117-A

ANN Limit Switch on:1&2-FCV-90-107-A,111-A, 113-A,117-A

ANN 1-FSV-43-3-A,12-A, 23-A, 35-A

ANN 2-PSV-43-3-A,12-A, 23-A, 35-A

ANN 1-FSV-32-80A-A,102A-B, 1IOA-A;2-FSV-32-81A-A,103A-B, lilA-B

ANN 1-FSV-43-77-A

ANN 2-FSV-43-77-A

ANN I-FSV-31-305-B,326-A;2-FSV-31-305-B,326-A

Cntnt BldgUpper & LowerCoupt Mon-Isol VlV-SOV

827551ASCOX206-38 1-3R?

to 85629ASCOHTX8320A22V

Cntmt BldgLower & UpperCompt Mon-Isol VlV

Cntut tool Vlv

Cntmt Isol Vlv

85629 NMACOEA- 170

85629-2 ASCO206-38 1-31F

827551 ASCOHV2O6-38 1-31?

13 Control Air 822950 ASCOIsol Sol Vlvs HV206-380-3RU

Dnstr Excess 85629-2 ASCOLtdn Htx Isol N831654EVIV

44 Temap-3460FHlumd-100%.Spray-3000

Press-11O psigRadn-2x108 rads

ppm, boron/pH 9-11

44 Open item -EEB0037

44R0 Open item -EEB0058

44 Temp-3460F Humd-100%Press-11O psig Radn-2.0x108 reds

44 t

44 Temp-346 0F Press-11O psigHumd-100% Radn-2.0x108 rods

44 Temp-3460FHumd-100%

Press-11O psigRadn-2.OxlO8 rods

to 827751 ASCOKV206-38 1-3R?

Incore InatRoom ChillA/B CWR isolVlv

822950 ASCO206-381-2?

44 Temp-3460 FHumd-100Z

Press-HO0 psigRadn-2.0x108 rods

a/b 5 =/** 2.73 yrs100d

ASCO Test Report No.AQ921678/TR Rev. A

of It

of o

a/b 5 m/** 263d100d

Is of

of is

a/b 5 m/100d

263d

IS SI

is so

N/A N/A ASCO Test ReportAQS21678/TR, Rev A.

N/A N/A ASCO Test ReportAQS21678/TR, Rev A.

N/A N/A ASCO Test ReportAQS21678/TR, Rev A.

N/A N/A ASCOLTest Report

. . AQS21678/TR, Rev A.

QUAL Ran

0

- ~j-v

3.11-5/WBMNUBO003

TABLE INPUT DATA SlIEST 1 R R3 4

WWN CLASS 11 8QUTfIMTD o4 77 &Z/0 V!SA

ievetDate 4 "f

CONITRACT MD. ASEL OILL.A.,... flflAt I U*Wl

OPEl OPEl*'A~ 01U19 hmW

IAN. Y.AMI'ur.KA ruuKI.IUM MFG G HUJII. Mu. Aplou ENIVE 5lIvUamnut.Ul Ivy WU&& ==.U& * 4 __________

ANN 1-FSV-31-309-B,330-A;

330-A

ANN 2-FSV-43-55-A,58-A, 61-A, 64-A

ANN 1-ISV-43-55-A58-A, 61-A, 64-A

Incore InstRoom ChillA/B Clii ToolVIV

St., GenB lovdownSample ToolVvi

822950 ASCO206-381-2F

827751 ASCOHW206-38 1-3R1

85629-2 ASCONP831654E

44 Temp-3460P Press-hO0 poigRwnd-100Z Radn-2.0x10 8 rado

a/b 5 m/**100d

263d N/A N/A ASCO Test ReportAQS21678/TR, Rev A.

of Is 2.73 yr.

Is so 2.73 yrs N/A

ANN Limit switch on:1, 2-PCV-31-305-B,309-B ,326-A, 330-A

ANN I-FSV-43-250,268,309,*312

ANN l-FSV-43-287,307, 318, 325

ANN l-FSV-43-341,l-FSV-43-342

ANN l-FSV-30-19-B,14-A, 16-B, 37-B,59-A, 57-B, 53-B,51-A, 9-B, 7-A,12-A, 54-A

Incore InstChill A LwrTool Vlv

Isol VIV

Rm 822950 NAXCOUA-170

Target Rock82KK-001

*821C1(.004

Target Rock82KK-002

Target Rock.82KK-004

827551 ASCOX206-381-3RF

44R0 Open item - lEEB 0058

44R0 Temp-3850 F Humd-100%61R0 Press-66 poig Radn-1.35x108 red.

Spray-Boron/Hydraz inc

44R0 Temp-3850 F Hund-lO0lPress-66 poig Radn-1.35x108 radoSpray-Boron/Hydrazime

44R0 Temp-3850'P Humd-100%Preos-66 poig Radn-1.35x10 8 radoSpray-B oron/Hydraz inc

44R0 Temp-346 0 F ' Humd-100%Press-11O paig Radn-2x108 radoSpray-3000 ppm Boron/pH 9-11

11 it

a 100d 211.5d si/A

a 1O0d 211.5d N/A

N/A Target Rock ReportNo.. 3619 & 2375

N/A Target Rock ReportNos. 3619 & 2375

a 1O0d 211.5d N/A N/A Target Rock ReportNos. 3619 & 2375

a/b 5 m/100d

1142d N/A N/A ASCO Teo t Report No.AQS21678/TR, Rev. A!

CURWACCUR qUAL RP?

0

U:E_,j3.11-5/WBNEEB00O4

0

TAMAE INPUT DATA SUZEZ? ~ vsin0R 3R

i v lD ate - '- 71

51

LOC ~OI~NTCIw2=C NO. -Jam OR

FUNCTION WCi A. wUlwV H Arfl iwMunOPER OPER

3UUtS1~IMtM~ Yfl UU1t~U flhlAtIWlUft

ACCUI3 ACCUi.~m DNOia

ANN Limit switch on: Isol Vlv1 -FCV-30-16-B1-PCV-30-37-B

ANN 1-ZS-30-19-B14-A,59-A, 57-B53-B,51-A, 7-A,9-B

k&NN I-PT-3O-31O-AI-PT-30-311-A

kNN 1-FSV-43-35A

Isol Vlv

Cntmt ProsTran~smitter

832128NAMCO EA180

832128NAMCO EA180

Westinghouse32PAI

Cntmt Isol 827551 ASCOVlv HV206-381-3RF

144RO Temp-3400 F Humd-100%Press-SO psig Radn-2xl08 rads

44R0 Temp-3400 F Humd-100%Press-80 psig Radn-2xl08 rads

44R0 Temp-4200 F Huad-lOZlPress-72 psia Radn-6.8kj07 rads

44 Temp-3460 F Humd-100%Press-11O psig Radn-2xlO8 rads

a/b 5 m/1O0d

a/b 5 m/1O0d

1.44 yrs

1.44 yrs

a 100d 865d + 9 psi + 9psi

a/b 5 m/ 2.73 yrs100d

NAMCO Qual Test RptNo. QTR-105, Rev. 3

NANCO Qual Test RptNo. QTR-105, Rev. 3

Westinghouse QualTest Report No.WCAP-8687, Supp.2-EOlB, Rev. 1

ASCO Report No.AQS21678/TR,Rev. A

**s-second; rn-minute; d-day; vk-week; mo-month; yr-year.

DEO6;RNB.5

QUAL RP?

LOC COMPONENT VwwlrDfMwVNw qPn Lmvdu TwIffn METHOD

0

TABLE 3.11--6 E F C i TABLE INPUT DATA SHEETD A TE SWP CLASS 1E EQUIPMENTSHEET NO: WBN-NEB-l OCT 12,3 4

OUTSIDE CONTAINMENTAUXILIARY BUILDING

GENERAL SPACES (GS) UNITS 1 AND 2

Revision 0 Rl

PEN

R2 R3 R4

RKW JWaPreparer/Date R. Darwin 10-19-81 RO 6-10-83 4/19/84'?//,¶k4

RKW AWL kReviewer/Date F. A. Plesic 12-15--81 RO 6-11-83 5/5/84 a

COMPONENT1I-LCV-62-132

2-LCV-62-132

FUNCTIONVCT Outlet IsoVlv Level CntrlVCT Outlet IsoVlv Level Cntrl

CONTRACT NO. ABNL ORMFG & MODEL NO. ACD ENVR71C62-54114-1 56Reliance Lim SB-0071C62-54114-1 56Reliance Lim SB-00

ENVIRONMENT TO WHICH QUALfFIED250'F,25 peig,100% rh,2x10 rads

250uFf25 puig,100% rh,2Xl0 rads

AB

OPER OPERREQMT DEMO5 min IlhrlO0dys 100dys5 min 1 hr100dva lO0dva

ACCUR

REQ1A

N/A

ACCUR,

DN/A

N/A

QUAL RPTMETHOD

Lim Rpt B0058App D B0003Lim Rpt B0058App D B0003

ICR I-LCV-62-133 VCT Outlet Iso 71C62-54114-1 56 250uFp25 paig,100Z rh,2xl10?rade A 5 min 1 hr Lim Rpt B0058Vlv Level Cntrl Reliance Lim SB-00 B 100dys 100dys N/A N/A App D B0003

ICR I-LT-62-238 Boric Acid 54114-1 Barton 52 See Table 3.11-8Tank A Level 752

ICR 2-LT-62-238 Boric Acid 54114-1 Barton 52 See Table 3.11-8Tank B Level 752

ICR l-LT-62-242 Boric Acid 54114-1 Barton 52 See Table 3.11-8Tank C Level 752

ICR 2-LT-62-242 Boric Acid 54114-1 Barton 52 See Table 3.11-8Tank C Level 752

*Not Field Verified

E43 160 .04

LOCICR

*ICR

TABLE 3.11-6 EFFECTIVDATE

SHEET NO: WBN-NEB-2 0OCT 19804JTABLE INPUT DATA SHEETSWP CLASS 1K EQUIPMENT

OUTSIDE CONTAINMENTAUXILIARY BUILDING

GENERAL SPACES (CS) UNITS 1 AND 2

Revision 0 RI R2 R3 R4

PBN RKW &WPreparer/Date F. A. Picnic RO, 6-10-83 4/19/84 loi/54

RKWE AWL aqReviewer/Date G. J. Malek 12-15-81 R0 6-11-83 5/5/84 iobi/rl

CONTRACT NO. ABNL OR OPER OPER ACCUR ACCUR QUAL EPTLOC COMPONENT FUNCTION MFG & MO3DEL NO. ACD ENVR ENVIRONMENT TO WHICH QUALIFIED CAT REQMT DEMO) REQMqT DEND METHODCS 2-LCV-62-133 VCT Outlet Iso Not Installed 56 A 5min

Vlv Level Cntrl 7B 100dys N/A N/ACS 1-FCV-74-33 RHR Ht Exc A 71C62-54114-1 50 250"F,'25 paig,100% rh,2xl07 rads A 100 100 Lim Rpt B0058

Bypass Reliance Lim SB-00 days days N/A N/A App D B0003*GS 2-FCV-74-33 RHR Ht Exc A 71C62-54114-1 50 250'F,25 psig,100Z rh,2Xl0'rads A 100 100 Lim Rpt B0058

Bypass Reliance Lim SB-00 days days N/A N/A App D B0003GS 1-TE-74-14 RHR Pump A-A 71C62-54114-1 50 Refer to Table 3.11-8

Diech Temp RDF 21234CS 2-TE-74-14 EHl Pump A-A Not Installed 50 Refer to Table 3.11-8

Disch TempCS I-TE-74~-25 RHR Pump B-B 71C62-54114-1 50 Refer to Table 3.11-8

Outlet Temp RDF 21232CS 2-TE-74-25 RUR Pump B-B Not Installed 50 Refer to Table 3.11-8

Outlet TempICR 1-FCV-74-33 RHR A Loop 54114-1 Reliance 50 2500F, 25 psig, 100% RH 2X107 A 1 wk 1 wk N/A N/A Lim Rpt B0058

Cross-Tie Vlv Limitoru BBO ADS B lOdys lO0dys App D B0003IC -FCV-74-33 RUR A Loop 54114-F12Rlac 50 250 FT 25 psi8 , 100% RH 2x10 AL k 1w N/A N/A LimRpB05

Cross-tie Vlv Limitorgue 8B-00 RADS B 100dys 100dys App D B0003ICR 0-MTR-78-9 Spent Fuel 54114-1 West. 46 Refer to Table 3.11-8

Pit Pump B-B 77C12671ICR 0-NTR-78-12 Spent Fuel 54114-1 West. 46 Refer to Table 3.11-8

Pit Pump A-A 73C74082ICR 0-MTR-78-35 Spent Fuel 54114-1 West. 46 Refer to Table 3.11-8

Pit Pump C-S 73C74082

*Not Field Verified

E43 160.04

0s

3.ll-6/WBNEEBOOOI

WONTRACT WO. ýWNL OaFUNCTION MFG M ODWL NO. ACD*EMYR

TABLE INPUT DATA SHEET

WNWU CLASS 1E EQUIPMENT

ENVIRONMENT TO WHICH QUALIFIEDOPEl OPER ACCUR ACCUR QUAL UPT

CAT REQIG? DEMO REQET_ _DEMO __METHOD_

5 1-TS-1-17A, -17B,-18A, -18B;2-TS-1-17A, -17B,-18A, -18B

12 2-LSV-3-148A,-156A, -164A,-171lA;

12 1-LM-3-148A,-156A, -164A,-171A2-LH-3-148A,-156A, -164A,-171IA

N/A 0-FSV-12-79

12 I-LSV-3-148k,-156A, -164A,-171A

14 Limit switch on:2-FCV-63-7 22 -FCV-63-73

Steam Flow toAPPT IsolHigh Temp Sv

Stm Gen LviBypass SOT

Stm Gen LviBypass VlvI/P Cony

Aux B ldgStm Isol

86422 Fenwal17323-0

87379 ASCOWPX-HV-202-301-lF

87379Masoneilan8005A

827551ASCO206-380-2RU

Stm Gen Lvi 827551Bypass SOV ASCO

206-381-3RVU

Cntmt Sumpto RHR Pump

824495YAMCOEA-1 70

68& Temp-323 0 F Press-22.3 poia69111 Humd-lO0l Radw-N/A

46RO Open item - BEB0035

46& Temp-133a7 Press-. 55 psig47 liumd-Atm Radn-1.7xl04 rads

52& Temp-346 0 F54 Humd-100%

Spray-3000

46R0& Temp-346 0 F47R.1 Humd-IOOZ

Spray-3000

Press-11O psigRadn-2x108 rads

ppm boron/pH 9-11

Press-11O psigRadn-2x107 rads

ppm boron/pH 9-11

80 Temp-2000 F Press-AtmHumd-100Z Radn-2.04x10 8 rads

a/b 5 m/100d

a 100d

I10d

a 100d 1. 1 yr

a/b 5 m/ 11.325 yrs100d

a 100d 5.9 yrs N/A

a I wk I vk

Wyle Labs TestReport No. 17509-1

Wyle LaboratoriesTest ReportNo. 17506-1.

ASCO Test Report No.AQS21678/TR, Rev. A

N/A ASCO Test Report No.AcS21678/TR, Rev. A

NRApMCDOQ~u~alif/i~cat~ion

7 /24/78

0

LOC COM4PONENT

40

E F F '-C TIV ED ATE'

O CT 19843.11-6/IIMB000OO2

040

TABLE INhPUT DATA SHIRT RZO0 2 R3 4

WIM4P CLASS 1Z E)UIPHENT eparer/Date o 2.AdA~

in-e/Dto /a

LOC cOKPONEN?CONT RACY NO. ABUL OR

rNvIDnimEu? TO W4U~N tUhALtUIKflOVER OVER ACCUR, ACCUR

lEON? DEMO

12 2-LSV-3-148,-156,-164,-171,

14 2-LSV-3-172,-173

3 O-TS-12-97A,-97B,-98A, -983

4 O-TS-12-94A,-94B,-95A,-95B, -96A,-96B

Positioner on:12 1-LCV-3-148,-156,

-164,-171,2-LCV-3-148,-156,-164,-171

14 Positioner on:1-LCV-3-172 ,-1732-LCV-3-172 ,-173

4 2-FSV-67-168 ,-170

Stm GenLevelSGY

Stm GenLevelSOY

AUX B ldgStin LineRuptureTemp SW

AUX BldgStm LineRuptureTemp SW

Stm GenLVL ControlValvePoe itioner

STM GenLVL ControlValvePosit ioner

Centr ChgPup Rm ClrSupply CntlViv SOY

83577 ASCOHT830OB58RU

83577ASCOHT8 300B58 RU

834197Fenwal18023 -7

834197Fenwal18023-7

83577Has one ilan8012

83577 -ADONMasoneilan8912

83577ASCOHT830OB58RU

46R0&47Rl

49R1 &8031

62RO63RI64RI

62R063R164R1

46&47

49&80

62R0&65R.1

Open item -EEB0029

Open item -EEB0029

Temp-323 0 FHumd-100Z

Temp-323 0 Fliumd-100Z

a 100d

a/b 5 m/100d

Presa-7 9 paigRadn-1x10 4 rads

Press-7.9 puigRadn-1x104 rads

Open item-EEBOO57

Open item-EEBOO57

Open item-EEBOO29

a Im 110d

It 1 m 110d

Wyle Labs TeatReport No. 17509-1Dtd 5/16/83

Wyle Labs TeatReport No. 17509-1Dtd 5/16/83

a 1O0d**

a 1O0d

a/b 5 m/100d

QUAL RPTMETHOD

LOC con WENT FUNCTION MFG & MODEL NO ACD ENVR CAT REMT DENOENVIRONMENT TO WHICH MIALIFIED

3.11-6/IIBNEEB00O3

LOC COMPONENT FUNCTION

N/A Limit wvitch on: Cntmt Sump to1-FCV--63-72 RHR Pump A-A

N/A Limit wvitch on: Cntmt Sump to

I-FCV-63-73 RHR Pump B-B

12 I-PS-3-148,-156, SG Lvi Bypass-164,-171 Press Sv2-PS-3-148 ,-156,-164,-171

DAT EGOT li:`34

*COUTUACT NO. ABY ORMFG & MODEL NO. ACD ENVR

824495 77R0NAMCO E.A180

824495 77R0

NAMCO RA180

830616ASCOSBI 1AKR/TLIOA32R

TABLE INPUT DATA SHEET evso0 R R3 4

WWM CLASS 13 EQUFIIHENT

OPEl OPF0 `ACCIZI ACCUR QUAL RPTENVIRONMENT TO WHICH QUALIFIED CAT REQMT DENOM RQT 'EO METHOD

Temp-3400 F liumd-100Z a/b 1 wk/ 5.3 yrs NANCO Test ReportPress-70 psig Radn-2x108 rads 30d No. QTR-105, Rev. 1

Temp-3400

F Humd-100%Press-70 psig Radn-2x108 rads

46R0 Temp-21001? Press-2. 2 psigHumd-100% Radn-17x100

a/b I wk/ 5.3 yrs30d

a 100d 100d

NANCO, Test ReportNo. QTR-105, Rev. 1

ASCO Test ReportNo. AQR 101083Rev. 1, dated 6/1/84

rEF F EC(.T IV TAOLZ INPUDATA SUMIr E7 MWB CL.ASS 19 WQU1PHfIT

OCT 1':, 34

11 R2 ;1 R

3.11-6 /IWBHEKB0004 4.29 4d~'~~s -

t~ne t~mwow~CUT3ACT NO. LIUL OR

1lIW-Y1AU IEwl jL Wbflht bin Amn aHUS wUut3fliaiatw~ Yfl iiiiimn flflAil witSOPVl OflR ACCUR ACCUR

1-PS-3-139A,B ,D-144A,B,D

2-PS-3-139A, B, D

Cond. StorageTank HdrP ress

830616ASCOSB31AKR/TD3OA32R

52RO Temp-2100 FHund-100Z

Prea-2.2 paigRadn-17xl06 rada

a 100d 100d

-144A, B, D

19 1-PI(-3-122,1329 2-PM-3-122,132

19 l&2-PDT-3-122A-A,132A-B

9 2-FSV-67-2172-FSV-67-219

AFW PumpVlv K/HActuator

Aux F, PapaA-A & B-BDiff Preaa

BA Xfr and AuxPu Pap CirV lV

Fisher-Type 546

828973FoxboroN-El IDN-HID2

52R0& Temp-212 07,54R1 Preaa-Atm

52RO55RI54RI

ASCO BB830OC58RU 55&57

Huad-lOOXRadn-Ix105 rada

Temp-3180 F, Huad - 100ZPress - 90 psi, Radn 2.2x108 rada

Open ttem-EEB0O29

a 100d 136d

a Ilmo 43 d

ASCO Test ReportNo. AQR-101083,Rev. 1, dated6/1/84

Wyle Teat Report17504-1, Rev. A

1.0% 1.0% Foxboro Teat Reportspan apan Q9-6005 & Teat

Report No. T3-1097

a/b 5m/100d

0

QUAL 11?HETHOD

Iýi-eioft 0 -

7rerrjDat.,

,4ý. 7ý " I -ev

LOC COMPONENT CAT REnmT DENO RROW DENOwwwlrDfwmwNm wn LUATem irvTvn

E F - I i jVF£A -f-

TABLE INPUT DATA SHEET

WBMP CLASS 13 EQUIRIENTI evision 0 ______

El a~rer/DateY,_4

La viewer/Date

L.OC COMPONENTCONTRACT NO. ABUL OR

FUNCTION MFG & MDODEL NO. ACD ENVI ENVIR~ONMENT TO WHICHR QUALIFIEDOPER OVER

CAT NEON? DEMOACCUR ACCURREOM DENO

N/A 0-TS-30-1920-TS-30-193

NVR 1-ZS-1-12NVR 1-ZS-1-23SVR 1-ZS-1-30SVR I-ZS-1-5

5 I-TS-30-214-S

9 0-TS-12-93A0-TS-12-93B

SEP & ThermalBooster PumpCoolers Fans

Limit Switchon Main StmHdr Press RelValves

AFPT RoomAmbient TempSwitches

Aux BldgSteam LineRupture Prot

824870HoneywellT675A

NAMCOEA180832128

86835Fenwal18003-7

834197Fenwa 118023-7

46R0& 47R11

Open item-EEBOO85

76R0 Temp-3400 F Press-70 p sigHumd-1OOX Radn-2x1 0 rads

68R0 Temp-3230F& 69RI Rumd-100%

Press-7.9 psigRadn-1x104 rads

52RW Temp-3230F Pres-7.9 psig54R1 Huind-lOOX R~adn-lx 0~ rads

a 100d

a 100d 195 days

a/b 5m/ 110 days. +1.70F +1.70 FImo

a 1/in 110 days +207 +20F

NAMCO QualificatinTest Report No.QIR1O5, Rev. 3

Wyle Labs TestReport No. 17509-1Dtd 5/16/83

Wyle Labs TestReport No. 17509-1Dtd 5/16/83

0

3.11-6/WBNEKB0005

R11R2 R

QUAL UP?METHOD

Liewer/Date

3.11-6/WBNEEB0006

E F ;~ *I! 4TABLE VIUPI DATA SHEETI iin0 I R 3 R

Wup CLUB s 1 W1VEIT prrDixs L.'-W

COTRACT MD. ARML ORI ~ t~f3EDflU3~P 3UU1bi~MM3M~ -~ UU?1U LUIAW IWiWfl

OVER OVERrAP 33(3 Mu

ACCUIR ACURn.~D DENO~

22 0-TS-12-92A,22 -92B, -99A,22 -99B

NA 0-TS-12-91A,-91B

14 I-LSV-3-17214 1-LSV-3-173

12 1-LSV-3-148,-156, -164,-171

20 I-FSV-67 -168

20 I-FSV-67 -170

Aux. BlIdg.Steam LineRupture

Aux. Bldg.Steam LineRupture

TD AFWP SGLvi Cant Vlv

Mtr DrivenAFWP SG LviCant Vlv

Centr ChgngPmp RmCooler A SCV

Centr ChgngPinp RmCooler B SCV

Fenwal18023-7

Fenval18023-7

827551 ASCO206 -380 -2RVU

827551 ASCO206-380-2RVU

827551 ASCO206-380-2RU

827551 ASCO206-380-2RU

39R1 Temp-3230F Press-7.9 psig40R1 Humd-See.4.1.3 Radn-See 4.1.2

39R1 Temp-3230 F Press-7.9 psig40RI Huind-See 4.1.3 Radn-See 4.1.2

80R11& Temp-3460F49R1 Humd-lOOX

Spray-3000

46R0& Temp-3460F4711 liumd-100%

Spray-3000

62R0& Temp-3460F6511 Humd-1O0l

Spray-3000

62R0& Temp-3460F65R1 Huad-lOOX

Spray-3000

Press-11O psigRadn-2x107 rads

ppm Boron/pH 9-11

Press-11O psigRadn-2xl07 rads

ppm Boron/pH 9-11

Press-11O psigRadn-2x108 rads

ppm Boron/pH 9-11

Press-11O psigRadn-2x108 rads

ppm Boron/pH 9-11

a 1h/lm

a 1h/in

a/b 5 m/100d

100 days .t2-07 +2-F

100 days +2 0 F

283d

a 100d 5.32 yrs N/A

a/b 5m/100d

a/b 5m/100d

+20 F

Wyle Labs TestReport No. 17509-1Dtd 5/16/83

Wyle Labs TestReport No. 17509-1Dtd 5/16/83

N/A N/A ASCO Test Report No.AQS21678/TR, Rev.A

N/A ASCO Test Report No.AQS21678/TR, Rev.A

1.6 yrs N/A N/A ASCO Test Report No.AQS21678/TR, Rev.A

1.6 yrs N/A N/A ASCO Test Report No.AQS21678/TR, Rev.A

**a-second; rn-minute; d-day; wk-week; mo-month; yr-year.

DEO6 ; NE .6

0 0

QUAL IF?

dw. rVMMMLwwr HETHWw . Mm Oavft IL_ý

0

TABLE 3.11-6

WBN-EEB-

Sh~eet No: 1000

0

TAIILIV' INVuT DATA SIIEET

SWP CLASS 1E EQUIPMENT

OUTSIDE CONTAINMENT - AUXILIARY BUILDINGGENERAL SPACES

LOC- COMPONENTCONTRACT NO. ABNL OR

ACD ENVR ENVIRONJMENTPRwr, control-, Refer to table-TL7-E23is7-I~fU

Electrical cables and signal 3.11-8A P50b52 Refer to table 3.11-8A I ....LX 1..Lxz ___________

circuits for bz1ývarious systeri 8 z ________________

Heat shrink interconn 825348 Raychem ,~Temp - 390 "F,8 Press 6-66-si S r________ safety-relate WCSF-N ____Radn - 2 x 10 8rads aamma 1yr 1______EQ

devices in Spray - 6200 ppm boron E-P1___________ various systeris _____ PH - 10.5 _ __

T e r m i n a l b l o c k s C a b l e t e r m i - G e n e r a l Ite p - 3 r s 6 8 p s a a 1 y _ _ __ _ _ _ _Tm-30 OF Prss-268 sa Iy 1y See EQS EEB-TB-l

nations Electric Types Humd - 100% 8 Spray - N/A______________CR &EB ____Radn- 1 xlo rads________

Handswitches Local control Square D Class 11 Temp -230 0F Press -16.4 psia y 1r yrISee EQS EEB-HS-l

_______________Radn -7x~ln7

ra&~________ _____

Spray - NEMA 4 or 12 enclosure

Cable termina- Tep-6 rs i ee EQSJunction boxes I-inn , hand- , Tep-201 8 Pes-26.4 psiN/A___ Radn - 1 x 10 rads Spray.- N/A _a 1 yr __j yr ___ EB-JB-iConduit seal switch housing 836056,836071 Temp 4300 F Press 70 psig a 1 yr 1 yr See EQS EEB-

-seal moisture Conax type Radn - 2.2x108______________

in cond~uits_ ECSA S~a.-H3BO/N OH/Na2 S 0Co-from devices P_

Stainless Steel ASCO solenoid 836772, ServicAir TemD - 327u es% - 28 psi See EQS EEB-__Flexible Conduit to Conax ECSA Company type ____Radn lxl4 radsurumd- CO1yr y

.connector SS63 Spray -Not affected by

Note: Oper Demo [column has beeb marked to show )ost-DBE gualification time. Qualified life tin deostae 'tib. the ma erialw L& jlSh- TQS appen( ixes.

_ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ D T E _ _ __ _ _

_ _ _ _ _ _ _ _ _ _ _ T H[ C, I ,T~

l Revision 0 ]RI R2 R3 W,PreparerZDate A

7,j,4& /Zhohp/ R;ý,

Reviewer/Date

OPER OPER ACCUR ACCUR QUAL RPTITCTCn rAT ornUT nrun nc UTTn IJWTrW "A

40

Tail1e No 3-11-6Slwet ik . 1014

LOC COUONFNT

0

TABLE INPUT DATA SHEET Rvso lR 3 ROUSIE N CtASS 19 Revisio 49 R/ R2 R3 %

OTIECONTAINMENT - AUXILIARY BUILDING rrDa te A Y /7- R--I' WtGENERAL SPACES Fe..,Dt L_ 71-Y

CONTRACT NO. ABNL ORPNVIBflN?.WNT Tn wiiru nhmni i~irn

OfER OPO'R ACCUR

1-BD-242-1 Radn Monitor 76K(5-87183 47E235- Temp-12 70F Press - 14.4 psia See EQS

O-DPL-234-A1/CVC Heat Trace 77K6-821608 47E2.35-. Temp-,1270 Press -14.3 psia I See EQS90-n.2 -pj-~lisy-. iigt- Pnl rhprion Mfg Cn 92 R ,in_ e~l')ý r:d 43la 1Di~H. .NA. EEB-~lP~t1..

O-DPL-234-A2/CVC________1

IO-DPJ.

O-PL

-234-A3/cCVZ347- B3Lt. /CV

-2 34-A4/CVC

________ __I EFFECTIVE - -

____ I ____ II _________ II ____

40

ACCIJR tQUAL RPT

4725 I T p15 F Press -am 14._ 3__ __ _ __ __I~~A .. 4723 -Tenp153 Press -pm 1431s]III lHumd - 100% . I tIKI

L_ý ____

0

TABLE 3.11-7

SHEET NO: WBN-

TABLE INPUT DATA SHEET

OUTSIDE CONTAINMENT - AUXILIARYBUILDING INDIVIDUALLY

COOLED ROOMS - UNITS 1 AND 2

Revision 0 RI R2 R3 R4

PBN RKW q #APreparer/Date R. Darwin 10-19-81 RO 6-10-83 4/19/84 11(it-4

RKW AWLReviewer/Date F. A. Plesic 12-15-81 RO 6-11-83 5/5/84 q~/'

LOC COMPONENTICR I-PT-l-2A

ICR 2-PT-l-2A

ICR I-PT-1-2B

2-T-I -2B

I-PT-1-5

2-PT-i1-5

1-PT-I1-27A

2-PT-1-27A

I-PT-1 -27B

2-PT-I1-27B

I-PT-I1-30

2 -PT- 1 -30

FUNCTIONSGl Main St.,HDR PressureSGL Main St.HDR PressureSGI Main StmHDR PressureSGl Main StmHDR PressureSGI Main St.HDR PressureSG1 Main St.HDR PressureSG4 Main St.HDR PressSG4 Main St.HDR PressSG4 Main St.HDR PressSG4 Main St.HDR PressSG4 Main St.HDR PressSG4 Main St.

CONTRACT NO.MFG & MODEL NO.54114-1 FoxbooE11GM Style CNot Installed

54114-1 FoxboroE11GM Style CNot Installed

54114-1 FoxboroElIGM Style CNot Installed

54114-1 FoxboroE11GM Style CNot Installed

54114-1 FoxboroElIGM Style CNot Installed

54114-1 FoxboroElIGM Style CNot Installed

ABNL ORACD ENVR56

56

56

56

56

56

56

56

56

56

56

ENVIRONMENT TO WHICQU IIE

Refer to Table 3.11-8

Refer to Table 3.11-8

Refer to Table 3.11-8

Refer to Table 3.11-8

Refer to Table 3.11-8

Refer to Table 3.11-8

Refer to Table 3.11-8

Refer to Table 3.11-8

Refer to Table 3.11-8

Refer to Table 3.11-8

Refer to Table 3.11-8

OPER OPERCAT REQMT DEND

ACCUR ACCUR QUAL RPTREOMY DEMO METHOD

DE03:E33 160.03

0

ICR 2-FCV-61-96 2-FCV-61-96 Not Installed 78 A 5 min N/A N/AB lO0dys

ICR 2-FCV-61-110 2-FCV-61-110 Not Installed 78 A 5 min N/A N/A1O0dys

0

TABLE 3.11-7 E F FECTIV ESHEET NO: WBN-NEB-2 D A T E

6 0T I 3)-: )4

TABLE INPUT DATA SHEETSWP CLASS 1E EQUIPMENT

OUTSIDE CONTAINMENT - AUXILIARYBUILDING INDIVIDUALLY

COOLED ROOMS - UNITS I AND 2

Revision 0

Preparer/Date T. W. Schoene RO

Reviewer/Date F. A. Plesic 12-15-81 RO

R1 R2 R3 R4

P114 KKW AW6-10-83 4/19/84 V/tfjf

RKW AWL &ZK6-11-83 5/5/84 QWg~~

CONTRACT NO. ABNL OR OPER OPER ACCUR ACCUR QUAL RPTLOC COMPONENT FUNCTION N4FG & MODEL NO. ACD ENV ENVIRONMENT TO 1¶ICH QUALIFIED CAT RXQNMT DEMO REQMT DEMO0 METHODICR 2-FSV-61-96 Inlet Iso Vlv 54114-1 ASCO 78 350-F, Atm 1 x 10- RADS A 5 min 1 hr N/A N/A Test/Analysis

Aux Bldg FTX831654 8B lO0dys 100dys NS-CE-755

ICR 2-FSV-61-110 Otlt Iso Vlv 54114-1-ASCO 78 35O0uF, Atm 1 x 10 RADS A 5 min 1 hr N/A N/A Test/AnalysisAux Bldg FTX831654 B lO0dys lO0dys NS-CE-755

ICR 1-FCV-62-63 Seal Flow Ret 54114-1 Reliance Refer to Table 3.11-8Isolation Vlv Limitorgue SB-00

ICR 2-FCV-62-63 Seal Flow Ret 54114-1 Reliance Refer to Table 3.11-8Isolation Vlv Limitorgue SB-00

ICR 1-FCV-62-77 1-FCV-62-77 54114-1 Snaplock 61 248uF, 14.7 psia, 100% RH, WO1 A 100 100 NIA N/A Tat Typ ACME(LS) Position EA17031302 R.ADS days days Clev QTR-107

ICR 2-FCV-62-77 2-FCV-62-77 54114-1 Snanlock 61 248-F. 14.7 nsia. 100% RH. 2xlO~ A 100 100 N/A N/A Tot Type ACNE

IC (LS)-6-9

ICR 1-FCV-62-90

ICR 2-FCV-62-90

ICR 1-FCV-62-91

ICR 2-FCV-62-91

ICR 1-FCV-62-98

ICR 2-FCV-62-98

ICR I-FCV-62-99

Position EA17031302Chrgng Flow 54114-1 RelianceIsolation Vlv Limitorpue SB-00Chrgng Flow RelianceIsolation Vlv Limitorgue SB-00Chrgng Flow 54114-1 RelianceIsolation Vlv Limitorgue SB-00Cbrgng FLow 54114-1 RelianceIsolation Vlv Limitorpue SB-00Chrgng Pmp 54114-1 RelianceIA-A Min Flow Limitorgue SHB-OOCbrgng Pmp Not Installed2A-A Min FlowChrgng Pmp 54114-1 ReliancelA-A Min Flow Limitorgue SHB-OOChrgng Pmp Not Installed

61

61

61

61

61

RefrtoTbl .1-

Refer to Table 3.11-8

Refer to Table 3.11-8

Refer to Table 3.11-8

Refer to Table 3.11-8

Refer to Table 3.11-8

Refer to Table 3.11-8

Refer to Table 3.11-8

days days Clev QTR-107

nlWVn iW~ - .iion. n

2A-A Min Flow

0

TABLE 3.11-7 EFFECTIVESHEET NO: WBN-NEB-3 D AT E

TABLE INPUT DATA SHEETSWP CLASS 1E EQUIPMENT

OUTSIDE CONTAINMENT - AUXILIARYBUILDING INDIVIDUALLY

COOLED ROOMS - UNITS I AND 2

Revision 0 RI R2 R3 R4

PEN RKW &4Preparer/Date R. Darwin 10-19-81 RO 6-10-83 4/19/84 %i

HKW AWLReviewer/Date F. A. Plesic 12-15-81 RO 6-11-83 5/5/84 gaV

CONTRACT NO. ABNL OR OPER OPER ACCUR ACCUR QUAL RPTLOC COMPONENT FUNCTION MFG & MODEL NO. ACD ENVR ENVIRONMENT TO WHICH 9 UALIfIED CT REQMT DEMO REQMT DEMO METHODICR 1-FSV-62-77 Ltdwn Ln leo 54114-1 ASCO 61 350-'F, Atm, Rad 4 x 1 AS A 5 min 5 min N/A N/A Test/Analysis

Vlv Solenoid FT831654 5 10dys 100dys NS-CE-755ICR 2-FSV-62-77 Ltdwn Ln Iso Not Installed 61 350uF, Atn, Red 4 x 10' RADS B 5 min 5 min N/A N/A Test/Analysis

Vlv Solenoid 100dys lO0dys NS-CE-755ICR I-LCV-62-135 Chrtna Pun 54114-1 Reliance 66 Refer to Table 3.11-8

*JUK 2ZIAV-62-i)

ICR 1-LCV-62-136

*ICR 2-LCV-62-136

ICR l-1HrR-62-104

*ICR 2-HTR-62-104

ICR I-MTR-62-108

*ICR 2-MTfR-62-108

Flow RWSTChrgng PmpFlow RWSTChrgng PupFlow RWSTCbrgng PupFlow RWSTCNTFGL ChrgngPmp lB-BCNTFGL ChrgngNmp 2B-BCNTFGL ChrgngPup lA-ACNTFGL Chrgng

Pp2A-A

Limotoqg-e -00O54114-IRelin ce 66Limitorgue SB-00-1054114-1 Reliance 66Limitorgue SB-0054114-1 Reliance 66Limitorgue SB-0054114-1 West. 7972F4491754114-1 West. 7972F4491754114-1 West. 7972F4491754114-1 West. 7972F44917

Refer to Tablfe 3.11-8

Refer to Table 3.11-8

Refer to Table 3.11-8

Refer to Table 3.11-8

Refer to Table 3.11-8

Refer to Table 3.11-8

Refer to Table 3.11-8

*Not Field Verified

DE03:E33 160.03

0

TABLE 3.11-7 -E F FECT IVESHEET NO: WBN-NEB-4 DA T E

CONTRACT NO.

TABLE INPUT DATA SHEETSW? CLASS IB EQUIPMENT

OUTSIDE CONTAINMENT - AUXILIARYBUILDING INDIVIDUALLY

COOLED ROOMS - UNITS 1 AND 2

ABNL OR

Revision 0

0

R1 R2 R3 R4

PEN1 RKW 6I'WPreparer/Date T. W. Schoene RO 6-10-83 4/19/84 4

RKW AWL U~.Reviewer/Date F. A. Plesic 12-15-81 RO 6-11-83 5/5/84 .~V

OPER OPER AC CURLOC COMPONENT FUNCTION MFG & MODEL NO. ACD ENVR ENVIRONMENT TO WHICH QUALIFIER CAT REQ14T DEM) REQMT DEND METHODICR 1-FCV-63--1 RWST ERR Pup 54114-1 Reliance 60 250-F, 25 psig, 100% ER 2 x 10' A 1 wk 1 wk N/A N/A Lim Rpt 30058

Flu Cont Vlv Limitorgue SB-2 RAD B 100dys 100dys App D 30003NrICR 2-FCV-63-1 RWST ERR Pup 54114-1 Reliance 60 250"?, 25 piag, 100% RH 2 x 10 A 1 wk 1 wk N/A N/A Lim Rpt 30058

Flu Cont Vlv Limitorgue SB-2 RADS B 1O0dys 1O0dys App D 30003ICR 1-FCV-63-3 SIS Pupa Rcrc 54114-1 Reliance 60 250-F, 25 psig, 100% RH 2 x 107 A 1 wkt 1 wk N/A N/A Lim Rpt 30058

Flu Coat Vlv Limitorgue SMB-00 RADS B 100dys 100dys App D 30003~ICR 2-FCV-63-3 SIS Pups Rcrc 54114-1 Reliance 60 250uF, 25 psig, 100% RH 2 x 10' A 1 wk 1 wk N/A N/A Lim Rpt 30058Flu Coat Vlv Limitorgue SMB-00 R.ADS 7 B 100dys 100dys pDB03u5~F 259pDOO

ICR 1-FCV-63-4

*ICR 2-FCV-63-4

ICR 1-FCV-63-5

*ICR 2-FCV-63-5

ICR 1-FCV-63-6

*ICR 2-FCV-63-6

ICR 1-FCV-63-7

SIS Pwp A-ARWST VlySIS Pup A-ARWST VlvRWST SIS PupFlu Cont VlvRWST SIS PinpFlw Cont VlvSIS Pup Inlet-CYCS Clip PupSIS Pup InletCVCS Clip PmpSIS Pup Inlet

54114-1 RelianceLimitorgue SMB-0054114-1 RelianceLimitorgue SMB-0054114-1 RelianceLimitorgue SB-0054114-1 RelianceLimitorgue SB-0054114-1 RelianceLimitorgue SB-0054114-1 RelianceLimitorgue SB-0054114-1 Reliance

79

60

60

60

60

25ADS 2

RADS

250AD 2

RADS250 0 F, 25RADS

RADS

25uF 25i

ps ig,

ps ig,

psi5 ,

ps ig,

psig,

ps ig,

1100% RH,2x10100% RH, 2 x 10'

100% ER, 2 x 10O7

100% RH, 2 x 1

100% RH, 2 x 10'9

100% RH, 2 x 10~

100% RH, 2 x 107

AB

BAB

Ilwk 1lwk100dys lO0dysIluk 1lwk100dys 1O0dysIlwk IlwklO0dys lO0dysIlwk 1lwklO0dys lO0dys1 wk Ilwk1O0dys 100dysIlwk lwklO0dys 100dysIlwk Ilwk

aAA. NfA.. A.e. Ti aAAx*ICR 2-FCV-63-7 SIS Pmp Inlet 54114-1 Reliance 60 2500F, 25 psi5 100% RH, 2 x 10' A 1 wk 1 wk N/A N/A Lim Rpt B0058CVCS Clip Pmp Limitorgue SB-00 RADS B lO0dys 100dys App D B0003

ICR 1-FCV-63-8 ERR HIXA to 54114-1 Reliance 60 Refer to Table 3.11-8CVCS Clip Pmp Limitorgue SB-00

*ICR 2-FCV-63-8 ERR HTXA to 54114-1 Reliance 60 Refer to Table 3.11-8CVCS Clip Pmp Limitorgue SB-00

ICR I-FCV-63-11 ERR HTXB to 54114-1 Reliance 61 Refer to Table 3.11-8

N/A

NIA

N/A

N/A

N/A

N/A

N/A

N/A

N/A

N/A

Lim Rpt 30058App D B0003Lim Rpt 30058App D B0003Lim Rpt B0058App D 30003Lim Ept 30058App D B0003Lim Rpt 30058App D 30003Lim Rpt 30058App D 30003Lim Rpt 30058

Limitoraue SB--OO

*Not Field Verified

DE03:E33 160.03

SIB Pu,

ACCUR QUAL RPT

I

TABLE 3.11-7 EFFECTIVElSHEET NO: WBN-NEB 5 D AT E

TABLE INPUT DATA SHEETSWP CLASS lE EQUIPMENT

OUTSIDE CONTAINMENT - AUXILIARYBUILDING INDIVIDUALLY

COOLED ROOMS - UNITS I AND 2

Preparer/Date T.

Reviewer/Date F.

Revision 0 RI

PENW. Schoene RO 6-10-83

RKWA. Plesic 12-15-81 RO 6-11-83

0

CONTRACT NO. ABNL OR OPER OPER ACCUR I ACCUR 2 QUAL RPTLOC COMPONENT FUNCTION MFG & MODEL NO.* ACD ENVR ENVIRONMENT TO WHICH QUALIFIED CAT REQMT DEMO REQMT DEMO METHOD

*ICRt 2-FCV-63-11 RHR HTXB to 54114-1 Reliance 61 See Table 3.11-8SIB Pup Limitorgue SB-00

ICR 1-FCV-63-22 SIB Pmp Cold 54114-1 Reliance 61 250'FE, 25 psig, 100% RH, 2 x 10 A 1 wkc 1 wkc N/A N/A Lim Rpt B0058Leg Injj Limitorgue SBD-00 RADS 100dys 100dys App D B0003

*ICR 2-FCV-63-22 SIB Pup Cold 54114-1 Reliance 61 250'F, 25 psig, 100% RH, 2 x 1O0 A I wkc 1 vk N/A N/A Lim Rpt B0058Leg Ini Limitorgue SBD-00 RADS 100dys 100dys App D B0003

ICR I-FCV-63-25 SISB Em Injj 54114-1 Reliance 61 Refer to Table 3.11-8Tic Shtof Vlv Limitorgue SBD-00

*ICR 2-FCV-63-25 SIS Emn Inj 54114-1 Reliance 61 Refer to Table 3.11-8Tic Shtof Vlv Limitorgue SBD-00

ICR 1-FCV-63-26 SISB Em Inj 54114-1 Reliance 61 Refer to Table 3.11-8Tic Sbtof Vlv Limitorgue SBD-00

*ICR 2-FCV-63-26 515 Emn Inj 54114-1 Reliance 61 Refer to Table 3.11-8Tic Sbtof Vlv Limitorciue SBD-00

ICR 1-FCV-63-39 SISB Em Inj 54114-1 Reliance 61 Refer to Table 3.11-8Tic Shtof Vlv Limitorgue SBD-00

*ICR 2-FCV-63-39 SIS Emn Inj 54114-1 Reliance 61 Refer to Table 3.11-8Tic Shtof Vlv Limitorgue SBD-00

ICR 1-FCV-63-40 SIB Brn Inj 54114-1 Reliance 61 Refer to Table 3.11-8Tic Shtof Vlv Limitorgue SBD-00

*ICR 2-FCV-63-40 SIB Bin Inj 54114-1 Reliance 61 Refer to Table 3.11-8Tic Shtof Vlv Limitorgue SBD-00

ICR 1-FCV-63-47 SIB Pmp A-A 54114-1 Reliance 79 250'F, 25 psig, 100% RH, 2xl0' B 100 100 N/A N/A Lim Rpt B0058Inlet Vlv Limitorciue SB-00 BADS ?days days App D B0003

*ICR 2-FCV-63-47 SIS Pmp A-A 54114-1 Reliance 79 250-F, 25 psig, 100% RH, 2xio B 100 100 N/A N/A Lim Rpt B0058Inlet Vlv Limitorgue SB-00 RADS ?days days App D B0003

ICR 1-FCV-63-48 SIB Pmp B-B 54114-1 Reliance 79 250'F, 25 psig, 100% RH, 2x10 B 100 100 N/A N/A Lim Rpt B0058Inlet Vlv Limitorciue SB-00 RADS days days App D B0003

*ICR 2-FCV-63-4.8 515 Pmp B-B 54114-1 Reliance 79 250oF, 25 psig, 100% RH, 2x10' B 100 100 N/A N/A Lim Rpt B0058Inlet Vlv Limitorgue SB-O0 RADS days days App D B0003

*Not Field Verified

0

R2 R3 R4

RKW4/19/84 1*4AWL 1

5/5/84

DE01:E13160.01

TABLE 3.11-7 'EFFECTIVESHEET NO: WBN-NEB-6 D AT E

OCT 'T

TABLE INPUT DATA SHEETSWP CLASS 1E EQUIPMENT

OUTSIDE CONTAINMENT - AUXILIARYBUILDING INDIVIDUALLY

COOLED ROOMS - UNITS 1 AND 2

Revision 0 Ri R2 R3 R4

PBN RKW J14ePreparer/Date T. W. Schoene RO 6-10-83 4/19/84 5'.i

RKW AWL 1"Reviewer/Date F. A. Plesic 12-15-81 RO 6-11-83 5/5/84 Id'

CONTRACT NO. ABNL OR OPER OPER ACCUR ACCUR QUAL RPTLOC COMPONENT FUNCTION MPG & N)DEL NO. ACD ENVR ENVIRONMENT TO WHICH QUALIFIED CAT REQMT DEMO REQMT DENO) METHODICR 1-FCV-63-93 ERR RCS 2&3 54114-1 Reliance 61 Refer to Table 3.11-8

Flow Cant Vlv Limitorgue SBD-2*ICR 2-FCV-63-93 ERR RCS 2&3 54114-1 Reliance 61 Refer to Table 3.11-8

Flow Cant Vlv Limitorqgue BD-2ICR I-FCV-63-94 ERR RCS 1&4 5414- Reince 61 Refer to Table 3.11-8

Flow Cant Vlv Limitorgue SBD-2*ICR 2-FCV-63-94 ERR RCS 1&4 54114-1 Reliance 61 Refer to Table 3.11-8

Flow Cant Vlv Limitorgue SBD-2 7ICR I-FCV-63-152 SIS Pmp A-A 54114-1 Reliance 61 250uF, 25 psig, 100% ER, 2x10 A 100 100 N/A N/A Lim Rpt B0058

Flow Cant Vlv Limitorgue SB-00 BADS 7days days App D B0003*ICR 2-FCV-63-152 SIS Pap A-A 54114-1 Reliance 61 250'F, 25 psig, 100% ER, 2x10' A 100 100 N/A N/A Lim Rpt B0058

Flow Cant Vlv Limitorgue SB-00 RADS 7days days App D 30003ICR 1-FCV-63-153 SIS Pap 3-B 54114-1 Reliance 61 250~'F, 25 psig, 100% ER, 2x10 A 100 100 N/A N/A Lim Rpt B0058

Flow Cant Vlv Limitorgue SB-00 RADS 7days days App D B0003*ICR 2-FCV-63-153 SIS Pap 3-3 54114-1 Reliance 61 250'F, 25 puig, 100% RH, 2x10 7 A 100 100 N/A N/A Lim Rpt B0058

Flow Cant Vlv Limitorgue, SB-00 RADS days days App D B0003ICR 1-FCV-63-156 SIS Pap RCS 54114-1 Reliance 61 250'F, 25 psig, 100% ER, 2xl0 7 A 1 wk 1 wk N/A N/A Lim Rpt B0058

LP 1&0 HL Limitargue SBD-00 RADS ? lO0dys lO0dys App D 30003*ICR 2-FCV-63-156 SIS Pap RCS 54114-1 Reliance 61 250-'F, 25 psig, 100% ER, 2x10 A 1 wk 1 wk N/A N/A Lim Rpt B0058

LP 103 HL Limitorgue SBD-00 RADS 7 O0dys lO0dys App D 30003ICR 1-FCV-63-157 SIS Pap RCS 54114-1 Reliance 61 250'F, 25 psig, 100% ER, 2X107 A 1 wk 1 wk N/A N/A Lim Rpt B0058

LP 2&4 HL Limitorgue SBD-2 RADS 1O0dys 1O0dys App D B0003*ICR 2-FCV-63-157 SIS Pap RCS 54114-1 Reliance 61 250'F, 25 psig, 100% ER, 2xl10' A 1 wk 1 wk N/A N/A Lim Rpt 30058

LP 2&4 HL Limitorgue SBD-00 RADS 1O0dys lO0dys App D 30003ICR I-FCV-63-172 ERR RCS 1&3 54114-1 Reliance 61 Refer to Table 3.11-8

Flow Iso Vlv Limitorgue S3-2*ICR 2-FCV-63-172 ERR RCS 1&3 54114-1 Reliance 61 Refer to Table 3.11-8

Flow Iso Vlv Limitorgue 93-2ICR 1-FCV-63-175 SIS Pap B-B 54114-1 Reliance 79 250"F, 25 psig, 100% ER, 2xil07 A 1 wk 1 wk N/A N/A Lim Rpt 30058

RUST Sht Vlv Limitorgue SMB-00 RADS B lO0dys lO0dys App D 30003

*Unit 2 has not been field verified

DE03:E33 160.03

0

0

TABLE 3.11-7 EFFECTIVESHEET NO: WBN-NEB-6 D AT E

Ujf OCT i 4

TABLE INPUT DATA SHETSliP CLASS 1E EQUIPMENT

OUTSIDE CONTAINMENT - AUXILIARYBUILDING INDIVIDUALLY

COOLED ROOMS - UNITS 1 AND 2

Revision 0

Preparer/Date T. W. Schoene RO

Reviewer/Date F. A. Plesic 12-15-81 RO

0

CONTRACT NO. ABNL OR OPER OPER ACCUR ACCUR QUAL EPT

LOC COMPONENT FUNCTION MFG & MODEL NO. ACD ENVR ENVIRONMENT TO WHICH QUALIFIED CAT REQMT DEMO REQMT DENO METHODU

ICR I-FCV-63-93 ERR RCS 2&3 54114-1 Reliance 61 Refer to Table 3.11-8Flow Cont Vlv Limitorgue SBD-2

*ICR 2-FCV-63-93 ERR RCS 263 54114-1 Reliance 61 Refer to Table 3.11-8Flow Cont Vlv Limitor2 B-

Flow ant lv Li itorue SB D-2*ICR I-FCV-63-94 ERR RCS 1&4 5411- Rliance 61 Refer to Table 3.11-8

Flow Cont Vlv Limitorgue SBD-2*ICR 2-FCV-63-942 SIB PCp A-A 54114-1 Reliance 61 Re0fer 25 psil, 3101-E,8 1 7 A 10 10 N/ / i p 05

Flow Cant Vlv Limitorcgue SBD-O0RD2as dy p 00*ICR 1-FCV-63-152 SIS Pup A-A 54114-1 Reliance 61 250 F, 25 psig, 100% ER, Wx10 A 100 100 N/A N/A Lim Rpt 30058

Flow Cont Vlv Limitorgue SB-00 BADS days days App D B0003*ICR 2-FCV-63-152 SIS Pup A-A 54114-1 Reliance 61 2500'F, 25 psig, 100% ER, 2x10' A 100 100 N/A N/A Lim Rpt B0058

Flow Cant Vlv Limitorgue SB-00 EADS days days App D 30003

*ICR I-FCV-63-153 SIS Pmp B-B 54114-1 Reliance 61 250~'F, 25 psig, 100% ER, 2X10O A 100 100 N/A N/A Lim Rpt B0058

Flow Cont Vlv Limitorpue SB-00 RADS days days Akpp D B0003

*ICR 2-FCV-63-153 SIS Pinp RCS 54114-1 Reliance 61 250"'F, 25 psig, 100Z ER, 2x107 A 100k 100k N/A N/A Lim Rpt B0058

FlPw 13t EL LimItorgH SB-O0 EADS Odays Odays App D B0003

*ICR I-FCV-63-156 SIS Pup RCS 5411-1 Reliance 61 250'F, 25 psig, 100% ER, 2510O A 1 wk 1 wk N/A N/A Lim Rpt B0058

LP 103 HL Limitorgue SBD-00 RADS lO0dys 1O0dys App D B0003

*ICR 21-FCV-63-157 SIB Pmp RCS 54114-1 Reliance 61 250'Fg 25 psig, 100% ER, 2x107 A 1 wk 1 wk N/A N/A Lim Rpt B0058

LP 214 HL Linitorgue SBD-00 EADS 1O0dys lO0dys App D B0003

*ICR 1-FCV-63-157 SIS Pup RCS 54114-1 Reliance 61 250-F, 25 psig, 100% ER, 2x107 A 1 wk 1 wk N/A N/A Lim Rpt B0058LP 2&4 HL Limitorgue SBD-O0 RADS lO0dys lO0dys App D 30003

*ICR 2-FCV-63-157 ERRPm RCS13 54114-1 Reliance 61 Re0Fer to Table 311-8H xo k Iwk NA NA Li 05

FLow Is4 HL Limitorgue SBD-002D 0ds10y R 00

*ICR I-FCV-63-172 RRR RCS 1&0 54114-1 Reliance 61 Refer to Table 3.11-8.

Flow Iso Vlv Limitorgue S3-2

ICR 1-FCV-63-175 SIS Pup B-B 54114-1 Reliance 79 250'F, 25 psig, 100% ER, 2x10o A I wk 1 wk N/A N/A Lim Rpt B0058

RIEST Sht Vlv Limitorgue SMB-00 RADS B lO0dys 100dys App D B0003

*Unit 2 has not been field verified

DEO3:E33 160.03

Ri R2 R3 R4

6-10-83 4/19/84 & ,ERKW AWL ',a

6-11-83 5/5/84 ;1,40'f

TABLE 3.11-7 F E TVSHEET NO: WBN-NEB-8 D)A TEi

r)~ 2-

TABLE INPUT DATA SHEETSWP CLASS IE EQUIPMENT

OUTSIDE CONTAINMENT - AUXILIARYBUILDING INDIVIDUALLY

COOLED ROOMS - UNITS I AND 2

Revision 0 RI R2 R3 R4

PEM RKW oqdPreparer/Date G. J. Malek 10-21-81 RO 6-10-83 4/19/842(M&fg

RKW AWL XReviewer/Date F. A. Plesic 12-15-81 RO 6-11-83 5/5/84 ii4r4

CONTRACT NO. ABNL OR OPER OPER- ACCUR ACCUR QUAL RPTLOC COMPONENT FUNCTION HFG & MODEL NO. ACD ENVR ENVIRONMENT TO WHICH QUALIFIED CAT REQNT DEMO REQMT DEMO METHOD

*ICR 2-FSV-63-84. SIS Chk Vlv Not Installed 61 A 5minLk Tat Iso ! 1O0dys

ICR I-MTR-63-10 'SIS Pmnp lA-A 54114-1 West. 79 11OuF, 1 Atm, 100% RN, WO1 R ADS A 100 100 N/A N/A Test/Analysis74FI2120 a8days days WCAP 8754

*ICR 2-MTR-63-10 SIS Pmnp 2A-A 54114-1 West. 79 110 F, I Atm, 100% RH, 2x10 RADS A 100 100 N/A N/A Test/Analysis74F12120 days days WCAP 8754

ICR 1-MTR-63-15 SIB Pmnp lB-B 54114-1 West. 79 11O"F, 1 Atm, 100% RH, 2x10 RADS A 100 100 N/A N/A Test/Analysis74FI2120 0 days days WCAP 8754

*ICR 2-MTR-63-15 SIS Pmnp 2B-B 54114-1 West. 79 1lOuF, 1 Atm, 100% RE, Wx1 RADS A 100 lOOr N/A N/A Test/Analysis74FI2120 0Sdays days WCAP 8754

ICR 1-FSV-68-305 RCS Flow Cont 54114-1 61 350 F, Atm, 100% RH, 4x10 RADS A 5 min 1 hr N/A N/A Test/AnalysisVlv No Nameplate B 100dys 100dys NS-CE-755

*ICR 2-FSV-68-305 WDS N2 Man to Not Installed 61 A 5minPrt B lO0dys

*Not field verified

DE03:E33 160.03

0

- TABLE INPUT DATA SHEETt F F LE TI V SWP CLASS 1E EQUIPMENT

DATE OUTSIDE CONTAINMENT - AUXILIARYOCT 1984 BUILDING INDIVIDUALLY

COOLED ROOMS - UNITS 1 AND 2

Revision 0 RI R2 R3 R4

RKW 4JWPreparer/Date P. B. Nesbitt 6-10-83 4/19/84 911*4i4

Reviewer/Date R. K. White 6-11-83 5/5/84 ?,I,&e

CONTRACT NO. ABNL OR OPER OPER ACCUR ACCIIR QUAL RPT

LOC COMPONENT FUNCTION MPG & MODEL NO. ACD, ENVR ENVIRONMENT TO WHICH QUALIFIED CAT REQMT DEMO REQMT DEWM METHOD

ICR 1-FCV-63-23 1-FCV-63-23 54114-1 Snaplock 61 248-1, 14.7 Pasa, 100% rh, A 100 100 NA NA Tat Typ ACHE

(LS) Position EA17031302 2x10 rods days dayxs Clev QTR-107

ICR 2-FCV-63-23 2-FCV-63-23 54114-1 Snaplock 61 248-1, 14.7 psia, 100% rh, A 100 100 N/A N/A Tat Typ ACME

(LS) Position EA17031302 2x12 rads day da8 Clv QTR-107

ICR I-FCV-63-38a 1-FCV-63-38 54114-1 Snaplock 61 248-1 14.7 psi~a, 100 ýO rh, A 10 100I M N[A- N/A Tst Typ ACNE

(LS) Position EA17031302 2x10 rads days days Cley QTR-107

ICR 2-FCV-63-38 2-FCV-63-38 54114-1 Snaplock 61 248-g, 14.7 poia, 100% rh, A 100 100 N/A N/A Tat Typ ACME

(LS) Position EA17031302 WO1 rads days days Clev QTR-107

ICR I-FCV-63-41 I-FCV-63-41 54114-1 Snaplock 61 248 - ' 14.7 Pasi, 100% rb, A 100 100 N/A N/A Tat Typ ACNE

(LS) Position EA17031302 2x12 rads doay day~s Clay QTR-107

ICR 2-FCV-63-41 2-FCV-63-41 54114-1 Snaplock 61 248- , 14.7 psia, 100% rh, A 1010 100 N/A N/A Tat Typ ACME

(LS) Position EA17031302 2x10 rads days days Clay QTR-107

ICR 1-FCV-63-42 I-FCV-63-42 54114-1 Snaplock 61 248-1, 14.7 psia, 100Z rh, A 100 100 N/A N/A Tat Typ ACME

(LS) Position EA17031302 2x10 rads days days Cle'J QTR-107

ICR 2-FCV-63-42 2-FCV-63-42 54114-1 Snaplock 61 248-1, 14.7 Pasi, 100% rh, A 100 100 N/A NIA Tjt Ty ACHE

(LS) Position RA17031302 2x100 roads days days C ev 6TR107

ICR 1-FCV-63-64 1-FCV-63-64 54114-1 Snaplock- 61 248-1, 14.7 psia, 100% rh, A 100 100 N/A N/A Tot Typ ACME

(LS) Position EA17031302 2x10 rads days days Clay QTR-107

ICR 2-FCV-63-64 2-FCV-63-64 54114-1 Snaplock 61 248-1, 14.7 psia, 100% rh, A 100 100 NA N/A Tst Typ ACME

(LS) Position EA17031302 2x10 rods days days Clay QTR-107

ICR I-FCV-63-84 1-FCV-63-84 54114-1 Snaplock 61 248-1, 14.7 psia, 100% rh, A 100 100 N/A N/A Tat Typ ACME

(LS) Position EA17031302 2x10 rads days days Cley OTR-107

ICR 2-FCV-63-84 2-FCV-63-84 54114-1 Snaplock 61 248-, 147 isi, 100% rh, A 100 100 N/A N/A Tst Typ ACME

(LS) Position EA17031302 WxO rods days days Clev QTR-107

ICR 1-FCV-68-305 1-FCV-68-305 54114-1 Snaplock -61 248-1, 14.7 Pasi, 100% rh, A 100 100 NA N/A Tst Typ ACME

(LS) Position EA17031302 2xlO rads days days Clev QTR-107

ICR 2-FCV-68-305 2-FCV-68-305 54114-1 Snaplock 61 248'j, 14.7 Pasi, 100% rh, A 100 100 N/A N/A Tot Typ ACME

(LS) Position EA17031302 WxO rads days days Clev QTR-107

*Not field verified

DEO3 :E33160 .03

0

TABLE

SHEET

0s

TABLE 3.11-7 EFF CTIV - TABLE INPUT DATA SHEET-- E F E T ISWP CLASS 1E EQUIPM1ENT

SHE OOWNNE-0 DT E1~3 OUTSIDE CONTAINMENT - AUXILIARY0 1" 1 4BUILDING INDIVIDUALLY

COOLED ROOMS - UNITS 1 AND 2

CONTRACT NO. ABNL OR

Revision 0 R1 R2 R3 R4

- P311 1KWPreparer/Date T. W. Schoene RO- 6-10-83 4/19/84

RKW AWL ýdReviewer/Date F. A. Plesic 12-15-81 RO 6-11-83 5/5/84 A/h/b'l

OPER OPER .ACCUR, ACCUR QUAL RPT

LOC COMPONENTICR 1-FCV-72-2

*ICR 2-FCV-72-2

ICR 1-FCV-72-39

*ICR 2-FCV-72-39

ICR I-FCV-72--40

*ICR 2-FCV-72-40

ICR I-FCV-72-41

*ICR 2-FCV-72-41

ICR I-MTR-72-10

*ICR 2-MTR-72-1O

ICR 1-MTR-72-27

*ICR 2-zrrR-72-27

ICR 1-FCV-74-3

FUNCTION MFG & MODEL NO. ACCmtmt Spray 54114-1 RelianceHdr B Iso Vlv Limitorgue SB-0Cntmt Spray 54114-1 RelianceHdr B Iso Vlv Limitorgue SB-OCntmt Spray 54114-1 RelianceHdr A Iso Vlv Limitorgue SB-0Cntmt Spray 54114-1 RelianceHdr A Iso Vlv Limitorgue SB-ORER Spray HDR 54114-1 RelianceA Iso Vlv Limitorgue SB-00RHR Spray HDR 54114-1 RelianceA Iso Vlv Limitorgue SB-00RHR Spray HDR 54114-1 RelianceB, ISO Vlv Limitorgue SB-00

RHR Spray HDR 54114-1 RelianceB Iso Vlv Limitorgue SB-00Cntmt Spray 54114-1 West MdlPump lA-A Mtr HSW2 Styl 76F52608Cntmt Spray 54114-1 West Ndl,Pump IA-A Mtr HSW2 Styl 76F52608Cntmt Spray 54114-1 West MdlPump lB-B Mtr HW2 !tyl 76§F52608Cntmt Spray 54114-1 West MdlPump 13-B Mtr HSW2 Styl 76F52608

1) ENVR ENVIRONMENT TO WHICH QUALIFI1 CAT REQMT DEMO REQMT DENO METHOD48 250'-F, 25 psig, 100% RH, 2x10ý A 5 min 1 hr N/A N/A Limi apt 30058

RADS :7 B 30dys3Odys Ap D B0003

48

48

61

61

61

61

81

81

81

81

BADS

RADS250 0F,RADS

20F,BADS

250"F,RADS

BADS

BADS

110 OF,RBADS

RADS

25 psig, 100% RH, 2X10'

25 psig, 100% RH, 7X10 ?

25 psig, 100% RH, 2X10O

25 puig, 100% RE, 2xl0'

25 psig, 100% RH, 2x10 7

25 psig 100% RH, 2x10 7

25 psig, 100Z RH, 2x107?

1 Atm, 100% RH, 2xl108

I Atm 100 RH,2xf0

1 Atm, 100% RH, 2x10

1 Atm, 100% RH, 2xl00

A

A

A

A

A

A

5 min30 dy

30 dye5 mint30 dys30days30days30days30days30days30days30

days30

1 hr N/A

lh0 4/A

lhr N/A30 dys

30 N/A

30 N/Adays30 N/Adays30 N/A

30a N/

30 N/Adays30 N/A

30 N/Adays

N1/A

N/A

N/A

N/A

N/A

N/A

N/A

N/A

N/A

N/A

N/A

Lim Kpt BUU58App D 30003Lim Rpt 30058App D B0003Lim Rpt B0058App D B0003Lim Rpt B0058App D 30003Limi Rpt B0058App D B0003Limi apt B0058App D B0003Lim Rpt B0058

Test/AnalysisWCAP 8754Test/AnalysisWCAP 8754Test/AnalysisWCAP 8754Tesi:/Anafys.isWCAP 8754

RHR Pump A-A 54114-1 Reliance 74 250'F, 25 psig, 100% RH, 2xl10' A 1 wk 1 wk N/A N/A Lim Rpt B0058Flw Cntrl Vlv Limitorciue SB-2 BADS B 100dys lO0dys -App D B0003

*Not Field Verified

DE03:E33 160.03

RADS da a da a

TABLE 3.11-7

EFFECTIVESHEET NO: WBN-NEB-11 D AT E

0 , 4

TABLE INPUT DATA SHEETSWP CLASS 1E EQUIP1MENT

OUTSIDE CONTAINMENT - AUXILIARYBUILDING INDIVIDUALLY

COOLED ROOMS - UNITS 1 AND 2

PBN R1CW V~Preparer/Date T. W. Schoeme RO 6-10-83 4/19/84 2~4/e

RICW AWL sailReviewer/Date F. A. Plesic RO 12-15-81 6-11-83 5/5/84 ylkfI9~

CONTRACT NO. ABNL OR OPER OPER ACCUR ACCUR QUAL RPT

LOC COMPONENT FUNCTION MFG & MODEL NO. ACD ENVR ENVIRONMENT TO WHICH QUALIFI&D CAT REQMT DEMO REQMT DEMOJ METHOID

*ICR 2-FCV-74-3 ERR Pump A-A 54114-1 Reliance 74 255 F, '25 psig, 100% ER, 2x10' A 1 wk 1 wk N/A N/A Lim Rpt B0058Fly Cmtrl Vlv Limitorgue SB-2 RAflS i B 1O0dys lO0dys App D B0003

ICR I-FCV-74-12 RHR Pumep A-A 54114-1 Reliance 58 250"F, 25 psig, 100% ER, 2x10 A N/A N/A Lim Rpt B0058

Min Flow Vlv Limitorjue SB-i RADS 1O0dys lO0dys App D 30003

*ICR 2-FCV-74-12 ERR Pump A-A 54114-1 Reliance 58 250'F, 25 psig, 100% ER, Wx10 7 A N/A N/A Lim Rpt B0058

Min Flow Vlv Limitorgue SB-i RADS A lO0dys 100dys App D 30003

ICR I-FCV-74-21 HER Pump 3-3 54114-1 Reliance 74 300u.F, 70 psig, 100% ER, 2.04x10- A 1 wk I wk N/A N/A Lim Rpt 30058Min Flow Vlv Limitorpue SB-2 RADS AB 1O0dys laodys App C 600456

*ICR 2-FCV-74-21 REX Pump B-B 54114-1 Reliance 74 300'F, 70 psig, 100% ER, 2.04x10- A 1 vk 1 wk N/A N/A Lim Rpt 30058

Min Flow Vlv Limitorgue SB-2 RADS B lO0dys lO0dys App C 600456

ICR I-FCV-74-24 HER Pump B-B 54114-1 Reliance 58 250'F, 25 psig, 100% ER, 2xl6 A N/A N/A Lim Rpt 30058

Min Flow Vlv Limitorgue SNB-00 RADS 7 1O0dys lO0dys App D 30003

*ICR 2-FCV-74-24 REX Pump B-3 54114-1 Reliance 58 250'F, 25 psig, 100% ER 2x10 A N/A N/A Lim Rpt 30058Min Flow Vlv Limitorgue SMB-00 RADJS ?lO0dys lO0dys App D 30003

ICR 1-FCV-74-35 RHR Hit Exch 54114-1 Reliance 50 250"F, 25 psig, 100% ER WO1 A 1 wk 1 wk N/A N/A Lim Rpt 30058

B Bypass Limitorgue SB-00 RADS B 1O0dys 100dys App D 30003

*ICR 2-FCV-74-35 RHR Hit Exch 54114-1 Reliance 50 250'F, 25 psig, 100% ER Wx10' A 1 wk 1 wk N/A N/A Lim Rpt 30058B Bypass Limitorgue SB-00 RADS a B 100dys lO0dys App D 30003

ICR 1-MTR-74-10

*ICR 2-MTR-74-10

ICR I-MTR-74-20

*ICR 2-MTR-74-20

ICR 1-FCV-72-40

ICR 2-FCV-72-40

ICR 1-FCV-72-41

lA-A 54114-1 West ModelV5Wl Style 74F12184

lA-A 54114-1 West ModelV5Wl Style 74FI2184

13-B 54114-1 West ModelV5W1 Style 74F12184

13-B 54114-1 West ModelV5W1 Style 74F1218454114-1 Reliance

Vlv Limitorgue SB-0054114-1 Reliance

Vlv Lirnitorizue SB-0054114-1 Reliance

74

74

74

50

50

R.ADS

RADS100F,

RADS

RADS250uF,RADS

2500F,

1 At=, 100% RH, WO1

1 Atm, 100% RH, 2xl10a

1 Atm, 100% RH, 2xli08

1 Atm, 100% ER, WxO 8

25 psig, 100% RH WO1?

25 psig, 100% ER Wx10'

25 psig, 100% RH Wz10

A

A

A

A

A

100days100days100days100days1 wklO0dys1 wk100dysI wk1 nAfl

100days100

dayIs100days100days1 wk100dys1 wklO0dys1 wki nAA.

N/A N/A

)IIA U/A

.. 5. ast.run LI/A

N/A

N/A

ri/A El/A

El/A

N/lA

~,. .. I.ruin ruts'.

WCAP 8754Test/AnalysisWCAP 8754Test/AnalysisWCAP 8754Test/AnalysisWCAP 8754Lim Rpt B0058App D B0003Lim Rpt B0058App D B0003Lim Rpt B0058

RHR Pump

RM Pump

ERR Pump

RHR Pump

RHRE SprayIso lat ionRHR SprayIsolationRHR Spra3Isolation Vlv L~imitorgue SB-uu 7" .- '. -

ICR 2-FCV-72-41 ERR Spray 54114-1 Reliance 50 250'F, 25 psig, 100% ER WO1 A 1 wk 1 wk N/A N/A Lim Rpt B0058

Isolation Vlv Limitorgue SB-00 RADS- lO0dys 100dys App D B0003*Not Field Verified

RI R2 R3 R4Revision 0

N/A

N/A

ro / AL

"/A

NiA

N/A

min

0

TABLE 3.11-7 E.FF.ECTIVESHEET NO: WBN-NEB-12 D A TE

TABLE INPUT DATA SHEETSWP CLASS 11 EQUIPMENT

OUTSIDE CONTAINMENT - AUXILIARYBUILDING INDIVIDUALLY

COOLED ROOMS - UNITS 1 AND 2

Revision 0

0

RI R2 R3 R4

PTN RiCH jPreparer/Date G. 3. Malek 10-21-81 RO 6-10-83 4/19/84 ?i~

RiCH AWLReviewer/Date F. A. Plesic 12-15-81 R0 6-11-83 5/5/84 06

CONTRACT NO. ABEL OR OPER OPER .AC CUR ACCUR QUAL RPTLOC COMPONENT FUNCTION MFG & MODEL NO. ACD ENVR ENVIRONMENT TO WHICH QUa.IFIED CAT REQMT DEN) !XQNT DEMO METHODICR 1-FSV-77-10 Rcdt Pump Die 54114-1 Asco 61 350-F, Atm, 100% RH, 4x10- RADS A 5 mini 1 hr Nj/A N/A Analysis

71w Sol Vlv FT831654 B 1O0dys 1O0dys NS-CE-755ICR 2-FSV-77-10 Rcdt Pump Die Not Installed 61 A 5 mini N/A N/A

Fly Sol Vi B 100dysICR 1-FSV-77-17 Rcdt to GA 54114-1 Asco 61 Refer to Table 3.11-8.

Flow Cntrl FTX831654ICR 2-FSV-77'-17 Rcdt to GA Not Installed 61

Flow CntrlICR 1-FSV-77-19 Rcdt to Vent 54114-1 Asco 61 35O0uF, Atm, 100% RH, 4xl0' BADS A 5 mini 1 hr N/A N/A Analysis

Hdr Fly Cntrl FTX831654 B 12Pds a 10dys NS-CE-755IC 2SV7719Rcdt to Vent Not Installed 61 A 5 mIniNA /

Hdr F1w Cntrl SB 100dysICR I-FSV-77-20 Rcdt N2 Spply 54114-1 Asco 61 350'F, Atm, 100% RH, 4x10 RADS A 5 mini 1 hr N/A N/A Analysis

Flow Cntrl FT831654 B lO0dys 100dys NS-CE-755ICR 2-FSV-77-20 Rcdt N2 Spply Not Installed 61 A 5 mini N/A N/A

Flow Cntrl B lO0dys

DE03:E33160.03

0

TABLE 3.11-7 - TABLE INPUT DATA SHEETE F F'--C 11V E SWP CLASS 1E EQUIPMENT

SHEE N~ IIU-UE-13D AT E OUTSIDE CONTAINMENT - AUXILIARYCT 1-134 BUILDING INDIVIDUALLY

COOLED ROOMS - UNITS 1 AND 2

Revision 0 RI R2 R3 R4

PBN REW 169Preparer/Date F. A. Plesic RO 6-10-83 4/19/84 1114(ff

RKW AWL 2Reviewer/Date G. J. Malek 12-15-81 RO 6-11-83 5/5/84 fbc/g'!

CONTRACT NO. ABNL OR OPER OPER ACCUR ACCUR QUAL RPTLOC COMPONENT FUNCTION MPG & MODEL NO. ACD ENVR ENVIRONMENT TO WHICH QUa4IFIED CAT REQMT DENO REQ14T DEMO METHODICR 1-FSV-81-12 PW RCS Press 54114-1 Asco 61 350-F, Atm, 100% RH, 4xl&- RADS A 5 min I hr N/A N/A Analysis

Relf Tnk FT831654 B 100dys lO0dys NS-CE-755ICR 2-FSV-81-12 PW RCS Press Not Installed 61 A 5 min N/A N/A

Reif Tnk B l~yICR 1-FCV-77-19 1-FCV-77-19 54114-1 Snaplock 61 248'F, 14.7 psia, 100% EN, A 51 mm~ 1 hr N/A N/A Tot Typ ACME

(IS) Position EA170-302 B lO0dys lO0dys Clew QTR-107*ICR 2-FCV-77-19 2-FCV-77-19 54114-1 Sneplock 61 2480F, 14.7 psia, 100% RH, A 5 min 1 hr N/A N/A Tst Typ ACME

- (LS) Position EA170-302 B 100dys 100dys Clev QTR-107ICR l-FCV-77-20 1-FCV-77-20 54114-1 Snaplock 61 2480F, 14.7 psia, 100% EN, A 5 min 1 hr N/A N/A Tot Typ ACME

(Is) Position EA170-302 B 100ds a 02y Clew QTR-107*IR -FV-7-02-FCV-77-20 54114-1 Snaplock 61 248'F, 14.7 psia, 100% EN, A 5 mO 1hn/ /A TtTpAM

(LS) Position EA170-302 B lOdys 1O0dys Clew QTR-107

ICR 1-FCV-81-12 1-FCV-81-12 54114-1 Snaplock 61 2480 F, 14.7 psia, 100% EN, A 5 min 1 hr N/A N/A Tot Typ ACME(LS) Position EA170-302 B lO0dys lO0dys Clev QTR-107

*ICR 2-FCV-81-12 2-FCV-81-12 54114-1 Snaplock 61 248~'F, 14.7 psia, 100% EN, A 5 min 1 hr N/A N/A Tst Typ ACME

(1.5) Position EA170-302 B 100dys 100dys Clew QTRI107*Not Field Ve-r~iied

DE03:E33160.03

0s

3.1 1-7/WBNEEBWOOO

LOC COMPONENT FUNCTION

N/A O-FS-65-25A/B,B/A EGTS Fan-31A/B,B/A So Decay-44A/B,B/A Cool Vlv-55A/B,B/A Intlk

N/A 2-FSV-67-336,-338 Egt RoomCir A/B

17 Limit Switch on:I ,2-FCV-70-85

Excess LtdnirrX OutletVlv Position

CONrRACT NO. ABNL, OltMFG 4 MODEL NO. ACD ENVE

829301 78R1FCI 12-64

83577 20ASCO11B8300C58RU

83577 61ROMasoneilan496-2

0

TABLE INPUT DATA SHEET

15BNP CLASS 11 EQUIPPHENT

ENVIRONMENT TO WHICH QUALIVI

Temp-212 0 F Radn-5x10 6 reds

Open iteur-EEB0048

Open item-EEBOO6O

OPEl OPEl ACCUR ACCUR QUAL RPTED CAT REQIIT DENO_ REQMT DEMO METHOD

a 100d 100d + 3fps 3fps Wyle Labs TestReport No. 708053dated 8-28-80

a/b 5m/1O0d**

go m

40

3.11-7/WBMEEBOOO2

LOC COMPONENT

15 2-FSV-67-350,352

14 2-FSV-67--354

14 2-FSV-67-356

FUNCTION

PenetrationKm Cir ContVlv - SOV

Penn KmCir Vlv

Penn KmCir Vlv

CONTRACT NO. ABk4L ORMPG & MODEL NO. ACD ENVE

83577 56R0ASCO 57RIHB8300C58RU

83577 48R2ASCO 49ELIRB830OC58RU

83577 48R2ASCO 49ER1HB8300C58RU

TABLE INPUT DATA SHEET

WMIP CLASS 19 EFI)UXHENT

ENVIRONMENT TO WHICH QUALMFI

Open iteur-EEBOO29

open itear-BEB0029

OPEU OPEl ACCUR ACCUR QUAL RPTED CAT REqKT DEMO RMT DMMETHOD

a/b 5m/1O0d

Open itemr-EEBOO29

0

0

3.11-7/WBNEEBO0O3

'v., -

CONTRACT NO. ABNL ORV1IWeWrmm bIWfl A. WUWI No~ A1~n HUWD

0

TABLE INPU1T DATA SHEET 2vlo0RI 2; 3 R4

WDNP CLASS 1E EQUtPHENT g4

e arerl A 1e.o.-

tUUtDflMHVNf TO UIITCH ONALIUIRDOPER OPER

CAT REORT DENOACCURREONT

ACCUR.DENO

QUAL IPTMETHOD

14 I-PS-3-140A,150A Aux Fw Pipe2-PS-3-140A,150A Break

Detection

14 2-FS-30-1942-FS-30-195

14 1-FE-30-1941-FE-30 -195

15 1-FE-30-1961 -FE-30-197

15 2-FE-30-1962-FE-30 -197

Pen Rm ClsFan A-A orB-B FlowControl Sw

Pen Rm CiaFan A-A orB-B PlowControl Sw

Pen Em CirsFan Flow Sw

Pen Em CirsFan Flow Sw

830616ASCOSB11AKR/TG13A42R

821197Dwyer 1627-1

FCI FR-72-4

834252PCI FR-72-4

821197Dwyer 1627-1

-48RI Temp-2100 F Preae-2.2 psig

-49RL1 Humd-IOOZ Radn-1.7x10 7- rada

48RI49RI

Open itear-EEBOO15

48R.1 Temp-3400 F Presa-4 3 pi4981 Rumd-100% Radn-lx 1 0 d rad a

56R0 Temp-340OF Preaa-43 3pa57RI Humd-100Z Radn-1x10~ rada

59 Open item-EEBOO8O

b 100d 100d ASCO Report No.AQR-101083, Rev. 1dated 6/1/84

I 1 mo

a 100d .312 yra- ±L3fps±t3fps

a 100d .312 yra

t3fps PCI Report No.t3fps 708053 dated 8/28/80

PCI Report No.708053 dated 8/28/80

a 100d

0

:1W ~4PflUtNTI tv. COMPONEL"r ENVIRONMENT TO WHICH WALIFIED

0s

3.11-7 /WBNEEBOOO4I

TABLE INPUT DATA SHEET -WIMP~[R CAS1 Rvision 0- ______ RI 2 13 R4

re arer/Date . 7

FvieverlDate y~Z h 8'

LOC COMPONENTCONTRACT NO. AIM!. OR OPER OPER ACCUR ACCUR

.PlM DENO

N/A 0-LT-77-1340-LT-77-135

14 1,2-TS-30-1941, 2-TS-30-195

N/A 1-ZS-30-60,-69

Passive SumpAux BldgLevel Tx

Pen Rm Cirs,Ely 737, FanA-A; Fan B-B

828967-2Rosemount1153DB4

833871SOR201TA-B125-JJTTX6

Limit Switches 832128on Interim NAMCO EA 180ABSCE Isol Vlv

81R0 Temp - 318 FHumd - 100%

-48R1 Temp - 430OF49R1 Humd - 100%

Press.- 87.7 psiaRadn - 2.21xlO 7rads

Press - 80 psigRadn - 2.2xl08 rads TID

-48R1 Temp-3460 F Press-7 0 psi I-78RI Humd-100Z Radn-2. 04x100 rads

ff it 2 yrs Temp Effi-1.88Z Rosemount Reportsspan, Rad Effm 108025 and 108026.1.5% span

a 100d 193.79yr t-50FL5 OF

a/b 5 min/ 3.89 yrs100d

t50 F Acton Environ. Testt5"F Corp. Reports 17344

82N-C, Rev. 1 &18441-83N, Rev. 1

NAMCO Test ReportNo. QrR 105, Rev.dated 8-20-81.

0

QUAL RF?

FUNCTION NFG & MODEL NO ACD EMVR METHODENVIRnmurm-P Tn UUTPU 19TWn rA*P 9V DENO

3.11-7/WBNEEBOOO5

CONTRACT NK). ARML ORFUNCTION MIFG 4 MODEL NO. ACD ENVE

TABLE INPUT DATA SHEET

WIN? CLASS 11 EQUIPHENTRevision 0 _______ RI 2 A3 R4

,T a a r,,rDa :t e o- - -1

OPER OPElID

ACCUR ACCUR QUAL IPTVA- 2W nLLNI Danh" n~R~ wvvwnnTH

15 1, 2-TS-30-196I ,2-TS-30-197

14 1-zs-30-28,-29

15 l-FSV-67 -350I-FSV-67 -352

14 1-FSV-67 -3541 -FSV-67 -356

Pen Rm Cirs,Ely 713, FanA-A; Fan B-B

Limit Switcheson InterimABSCE Isola-tion Valve

833871SOR201TA-B125-JJTTX6

832128NANCOEA180

Pen Rm 827551 ASCOCoaler SCV 206-380-2RU

Pen Em 827551 ASCOCooler SCV 206-380-ZRU

-56R1 Temp-430O7 Presa-80 paig-57R0 Humd-100Z Radn-2.2xl08 rada

-48R1 & Temp-3460F-7881 Humd-100%

56R0& Temp-346 0 F57R1 Humd-100%

Spray-3000

48R1& Temp-346 0 F49R1 Humd-100%

Spray-3000

Preaa-70 psi&Radn-2.04x1O5 rad a

Preas-ilO psigRadn-2x108 rads

ppm Boron/pH 9-11

Preas-ilO paigRadn-2x10 8 rads

ppm Boron/pH 9-11

a 100d 193.79yr ±507

t5Oy

a/b 5 m/100d

a/b 5 m/100d

a/b 5 m/100d

3.89 yrs N/A

224d

283d

t507 Acton Environ. Testi5O7 Corp. Reports 17344

82N-C, Rev. 1 &18441-83N, Rev. 1

N/A NAMCO Teat ReportNo. QTR 105, Rev.Dtd. 8-20-81

N/A N/A ASCO Test Report NoAQs21678/TR, Rev. A

N/A N/A ASCO Test Report NoAQS21678/TR, Rev. A

**s-aecond; rn-minute; d-day; vk-week; mo-month; yr-year.

DE06;RNB.7

LOC COMPONENTENVIRONMENT TO WHICH OUALIVIED

0

TABLE 3.11-7

';Ioc--- No:-

SC COMI ONENT

WBN-EEB-1000

0

TA I.i .U I NPUT' DATA SHEEU T

SWP CIASS 1E EQUIPMENTr

OUTSIDE CONTAINMENT - AUXILIARY BUILDINGINVIDIVIDUAL COOLED ROOMS

CONTRACT NO.FUNCTION MFG & MODEL NO.

Pwr, con~trol, Refer to table

ABNL ORACO ENVi4q1E2?Zý

4.9NL58cablelandsiona 1 311-8

ENVIRONMENT TO WHICH DUALIFFED

Revicwer/DnLabN

OPER OPER ACCUR ACCUR QUAL RTREONT DEMO REQMT DEMO METHO-)

-variouPresst'6Heat ýn ink Interconn 825348 Raychem ~g Temp - 390-F '8 Pes- 66psg See EQS__splices ____ .--safetyw-welate~ WCSF-N _____ Radn_- 2 x 10 rads gamma a 1yr I.Y - SPrLIdevices in Spray - 6200 ppm boron

Ivarious systeis ____PH - 10.5 ___ ____

__Junction boxes Cable termi- N/A Temp -260 0 C Press -26.4 DSia al 1 yr .I v. See EQS EEB-Bnation, hand- Radn - lxlO~rads Spray-: N/A

-- switch housing I____________

__Terminal blocks Cable termi- General Electric 1 Temp -330 0 F Press -26.8 psia.- a 1 yr Ij. __ See EQS EEB-T-.nation Types CR & EB Humd - 100% 8 Spray - N/A 1v

___________Radn - 1 xlo rads I______ ___ _______

- aiidswitchp-s~ Local control Square D Class ____Temip - 2300F Press -16.4 psio.. I vr- I rSee EOS EEB-HS-l9001 Humd --NEMA 4 or 12 enclosure

_____________SDrav NEMA 4 or 12 enclosure I___

'Conduit Seal Seal Moisture 836056,836071 Temp__ Ra00 F Press radsgSe Q EB-. _______________Rdo22xcras_________ in conduits a IyeTm 3~F rs 0pi yr yr SeESEBfrom devices ECSA Spray - H3 B0 3 /NsaI/Na 2 S2 0 3

PB - 10.0 1___ ________Stainless Steel ASCO solenoid 836772, ServicA r " Temp 3270 F Press-.28psia bj 1 yr i yr See EQS EEB-Flexible Conduit to Conax ZCSA Coin any type Rndn- - xQ rads Ilumd - 100% _______CON-i

connector SS63 Spray - Not affected by

- ~tLDoer~ Dam~ column as been~ mrked to-B qulfcton time. Oualified life tm( demons ;rte b a 1 esi~lo

EQS appen ixes. -

U ", At

+ -j -- ) I -j ",7Q -7Q C-^ 0

RI

0

ISheet No. WBN-MEB-000O1

LOC COMPONENTCONTRACT NO. ENYR DWG

FUNCTION MFG &. MODEL No. 47E235-

TABLE INPUT DATA SHEET

SWP CLASS 1E EQUIPMENT

TABLE 3.11-7

ENVIRONMENT TO WHICH QUALI

IRevision 0 1 ~ Rl' p2IR3

Preparer/Date 416-~ 7

OPER OPER ACCUR ACCUR QUAL RPT

FIED CAT REQMT DEMO REQ~r DEMO METHOD

737 1-FSV-30-28,29 INTERIM AE CE 820963A5 ISOLATION LV ASCO HT8320AI08 48

757 I-FSV-30-60,69A16

INTERIM AB CE 820963ISOLATION rLV ASCO HT8320A108 78

OPEN ITEM

OPEN ITEM

5 min/A/B 100

Days

5 min/A/B 100

Days

NA NA NA

NA NA NA

EFFECTIVE-DATEJOCT 1964i

0

Sheet No. WBN-MEB-O002

LOC COMPONENT FUNCTrION_CONTRACT NO. ENVR DWG

MFG & MODEL NO. 47E235-

TABLE INPUT DATA SHEET0 l*R IR3 4

SWP CLASS 1E EQUIPMENT

TABLE 3.11- 7

OPER OPER ACCUR ACCUR QUAL RPTENVIRONMENT TO WITCH OUALIFTED1 CAT REOMT DEMO REONMT DEMO METHOD

O-HTR-30-147A

0-HTR-30-1 56 B

0-MTR-65 -23A

0-MTR-65-42B

O-TS -65-16,36

O-HTR-65-37B,17A

AB GAS TRI,,TSYS HUMIDI'!YHTR

AB GAS TRT ITSYS HUMIDITYHTR

EGTS FANMOTOR

EGTS FANMOTOR

EGTS TRAINREL HUMIDI "Y.HTR CONT

ECTS HUMID TYHTR

83116CHROMALOXTRI-7648 76"LONG

831163CHROMALOXTRI-7648 76"LONG

83246RELIANCE

lYF88-2366A2-YC

83246RELIANCE

1IYF882366AI

83175CHROMALOX106-114426-003

83175CHROMALOX196032951003

OPEN ITEM

OPEN ITEM

HARSH

HARSH

OPEN ITEM

OPEN ITEM

100Days

100Days

100Days

100Days

100Days

100Days

RELIANCE

ELECTRIC CO.REPORT NUC-9

RELIANCEELECTRIC CO.REPORT NUC-9

[E EFFECT IVEDATE '

TABLE INPUT DATA `11EEIT

SWP CLASS 1E EQUIPMENT

TABLE 3.11-7S'heet No. W*BN-MEB-201

E-r COMPONENT FUNCTION

CONTRACT NO. ENVR DWGflh¶fl#I filiAl YCflVfl f'A~'

MFG & MODEL NO. 47E235- ENVI~RONMENT4 TO WHICH QUALIFIED i

OPER OPER ACCUR ACCUR QUAL RPTowni~r DEMO REOMT DEMO METHOD

ICR CCS PUMP C-3MOTOR

ICR CCS PUMP MOTOR1AA

ICR CCS PUMP MOTOR2AA

ICR CCS PUMP MOTORI BB

ICR CCS PUMP MOTOR2BB

83173 HSW2WESTINGHOUSE

83173 HSW2WESTINGHOUSE

83173 HSW2

83173 HSW2WESTINGHOUSE

83173 HSW2

WESTINGHOUSE

52 HARSH

52 HARSH

52 HARSH

52 HARSH

52 HARSH

A 100Days

A 100Days

A 100Days

A 100Days

-A 100Days

NA NA NA WESTINGHOUSEWCAP 8754RI

NA NA NA WESTINGHOUSEWCAP 8754R.1

NA NA NA WESTINGHOUSEwcAp 8754RI

NA NA NA WESTINGHOUSEWCAP 8754R1

NA NA NA WESTINGHOUSEWCAP 8754RI

EFFECTIVED A T E

0

TABLE INPUT DATA SHEETSWP CLASS IE EQUIPMENT

OUTSIDE CONTAINMENT - SUBJECTTO HELB UNITS I AND 2

Revision 0

PBN RKW 1AWPreparer/Date R. Darwin 10-19-81 RO 6-10-83 4-19-84 ?/,'dh4

RKW AWLReviewer/Date F. A. Plesic 12-15-81 RO 6-11-83 5-5-84

CONTRACT NO. ABNL OR OPER OPER ACCUR ACCUR QUAL RPTLOC COMPONENT FUNCTION MFG & MO)DEL NO.* ACD EIIVR ENVIRONMENT TO 'WHICH QUALIFIED CAT REQMT DEMO~ REQMT DENO) METHODICR 1-PT-l-2A SGI Main Stm 54114-1 Foxboro 56 318-F f8 90 psig, 100% rb A 100 100 + 14 + 10 WCAP 8541

HDR Pressure E11CM Style C 2 x 10 rads days days TestICR 2-PT-1-2A SCI Main Stm Not Installed 56 A 100

HDR Pressure .0daysICR 1-PT-12B SGI Main Stm 54114-1 Foxboro 56 318 F18 90 psig, 100% rh A 100 100 + 14 + 10 WCAP 8541

HDR Pressure E11GM Style C 2 x 1 0 rads days days TestICR 2-PT-1-2B SG1 Main Stm Not Installed 56 A 100

HDR Pressure daysICR 1-PT-1-5 SG1 Main Stm 54114-1 Foxboro 56 318-F, 890 psig, 100% rh A 100 100 + 14 + 10 WCAP 8541

HDR Pressure E11GM Style C 2 x 10 rads days days TestICR 2-PT-1-5 SGI Main Stm Not Installed 56 A 100

HDR Pressure daysNVR 1-PT-1-9A SG2 Main Stm 54114-1 Barton 76 420'F, 57 psig, 100% rý, 2500 ppm A 100 4 mo + 10 + 10 WCAP-8587,Supp 2-EQTR-

HDR Press 763 Lot 7 Boron, Ph 10.7, 5 x 10 rads days EO1A & EQDP-ESE-lANVR 2-PT-i-9A SG2 Main Stm Not Installed 76 A 100

HDR Press dayslIVR 1-PT-1-9B SG2 Main Stm 54114-1 Barton 76 420'F, 57 psig, 100% r~p, 2500 ppm A 100 4 mo + 10 + 10 WCAP-8587,Supp 2-EQTR-

HDR Press 763 Lot 7 Boron, Ph 10.7, 5 x 10 rads days E01A & EQDP-ESE-IANVR 2-PT-1-9B SG2 Main Stn Not Installed 76 A 100

HDR Press adayslIVR 1-PT-1-12 SG2 Main Stm 54114-1 Barton 21 420 F, 57 psig, 100% rip, 2500 ppm A 100 4 mw + 10 + 10 WCAP-8587,Supp 2-EQTR-

HDR Press 763 Lot 7 Boron, Ph_10.7, 5 x 10 rads days EOIA & EQDP-ESE-IANVR 2-PT-1-12 SG2 Main Stm Not Installed 21 A 100

HDR Press daysNVR I-PT-1-20A SG3 Main Stm 54114-1 Barton 76 420'F, 57 psig, 100% rlp, 2500 ppm A 100 4 mo + 10 + 10 WCAP-8587,Supp 2-EQTR-

IIDR Press 763 Lot 7 Boron, Ph 10.7, 5 x 10 rads dasEOIA & EQDP-ESE-1ANVR 2-PT-1-20A SG3-Main Stm Not Installed 76 A 100y

HDR Press dayA

DE06:E33160.01

SHEET NO:

TABLE Rl R2 R3 R4

TABLE 3.11-8 -EFF E %-rTIVESHEET NO: WBN-NEB-2 D A T -E

0

TABLE INPUT DATA SHEETSWP CLASS 1E EQUIPMENT

OUTSIDE CONTAINMENT - SUBJECTTO HELB UNITS I AND 2

Reviion0 R R2W 031

Preparer/Date T. W. Schoene RO 6-10-83 4-19-84 $/IV~~RKW AWL

Reviewer/Date F. A. Plesic 12-15-81 RO 6-11-83 5-5-84

CONTRACT NO. AJBNL OR OPER OPER AtCUR ACCUR QUAL RPTLOC COMPONENT FUNCTION MFG & MODEL NO. ACD ENVR ENVIRONMENT TO WHICH QUALIFIED CAT REQMT DEMO REQMT DEMO METHODNVR I-PT-1-20B SG3 Main Stm 54114-1 Barton 76 425 F, '57 psig, 100% r9, 2500 ppm A 100 4 mo + 10 + 10 WCAP-8587,Supp 2-EQTR-HDR Press 763 -Lot 7 Boron, Ph 10.7, 5 x 10 rads days E01A & EQDP-ESE-1ANVR 2-PT-1-20B SG3 Main Stm Not Installed 76 A 100HDR Press daysNVR I-PT-1-23 SG3 Main Stm 54114-1 Barton 21 42&'F, 57 psig, 100% r9, 2500 ppm A 100 4 mo + 10 + 10 WCAP-8587,Supp 2-EQTR-HDR Press 763 Lot 7 Boron, Ph 10.7, 5 x 10 rads dasE01A & EQDP-ESE-lANVR 2-PT-1-23 SG3 Main Stm NotIsald 2 A 100HDR Press daysICR I-PT-1-27A 504 Main Stm 54114-1 Foxboro 56 318-'F18 90 psig, 100Z rh A 100 100 + 14 + 10 WCAP-8541HDR Press ElIGM Style C 2 x 1 0 rads days daysICR. 2-PT-1-27A SG4 Main Stm Not installed 56 A 100HDR Press daysICR 1-PT-1-27B SG4 Main Stm 54114-1 Foxboro 56 318'F ' 90 psig, 100% rh A 100 100 + 14 + 10 WCAP-8541HDR Press EIIOM Style C 2 x 108 rads days daysICR 2-PT-1-27B SG4 Main Stm Not Installed 56 A 100HDR Press days

ICR I-PT-1-30 SG4 Main Stm 54114-1 Foxboro 56 318-F, 90 psig, 100% rh A 100 100 + 14 + 10 WCAP-8541HDR Press ElMSyeC2 x 10 8rads d as d ays Type TestICR 2-PT-1-30 n~ SGP Main Stm Not Intale 56 A 100HDR Press daysICR 2-FCV-61-96 2-FCV-61-96 Not Installed 14 A 5min NA NA(LS) Position B 100dysICR 2-FCV-61-110 2-FCV-61-110 Not Installed 20 A 5min NA NA(LS) Position

8B 5 m4dysICR 2-FSV-61-96 Inlet Iso Vlv 54114-1 ASCO 20 35",Atm I x 10 inS 5m 1 hr NA NA AnalysisAux Bldg FTX831654 -8B lO0dys 1O0dys NS-CE-755ICR 2-FSV-61-110 Otlt Iso Vlv 54114-1 ASCD 20 350vF, Atm 1 x 10 RADS A 5 min 1 hr NA NA AalysisAux Bldg FTX831654 7 B 100dys lO0dys NS-CE-755ICR 1-FCV-62-63 Seal Flow Ret 54114-1 Reliance 61 250'F 25 psig, 100% RH, 2 x 10 A 100 100 NA NA Lim Rpt 80058Isolation Vlv Limitorcue SB-00 RADS days days App D B0003ICR 2-FCV-62-63 Seal Flow -Ret 54114-1 Reliance 61 250'~F 25 psig, 100% RH, 2 x 1-04 A 100 100 NA NA Lim Rpt 80058Isolation Vlv Limitorgue SB-00 RADS days days App P B0003

DEO6:E33160.01

Revision 0 RI R2 R3 R4

400

TABLE

SHEETRevision 0 RI R2 R3 R4

Preparer/Date F. A. Plesic

Reviewer/Date G. 3. Malek 12-15-81

PBN6-10 -83

RKW

HO 6-11-B3 5-5-84 ,i~at'/AWL 0

CONTRACT NO. ABNL OR OPER OPER ACCUR- ACCUR QUAL RPTLOC COMPONENT FUNCTION MFG & MODEL NO. ACD ENVR ENVIRONMENT TO WHICH QUALIFIED CAT REQMT DEMO REQMT DEMO METHODICR 1-FCV-62-77 I-FCV-62-77 54114-1 Snplock 61 2480F, 147 psia , 100% RH, 2 x 10' A 5 mini 1 hr NA NA Acme Test(LS) Position EAI 70-,302 BADS - - lO0dvs 1 o0iy.. QTRI07*ýICR 2-FCV-62-77 -2-FCV-62-77 54114-1 Snplock 61 248vF, 147 psia, 100% RH, 2 x 10' A 5 mini 1 hr NA NA Acme Test(LS) Position EA170 -302 RADS - B 100dys 100dys QTR107ICR 1-FCV-6'2-90 -Cbrgng Flow 54114-1 Reliance 61 156"YF-, 25 psig, 100% RH, 2 x 107 A 5 mini 1 hr NA NA Lim Rpt B0058Isolation Vlv Limitorgue SB-00 RADS B 100dvs lO0dys App D B0003*ICR 2-FCV-62-90 Chrgng Flow 54114-1 Reliance 61 2500 F, 25 psig 100% RK, 2 x 101 A 5 min 1 hr NA NA Lim Rpt B0058Isolation Vlv Limitorgue SB-00 P.ADS - B 1O0dys lO0dys App D B0003ICR I-FCV-62-91 Chrgng Flow 54114-1 Reliance 61 250'F, 25 psig, 100% RH, 2 x 10' A 5 min 1 hr NA NA Lim Rpt B0058Isolation Vlv LimitorguLe S00RADS B lq~ds lO0dys App D B0003*ICRK Z-FCV-62-91 Chrgug FLow 54114-1 Reliance 61 250'F, 25 psig, 100% RH, 2 x 10~ A 5 m 1 hr NA NA Lim Rpt B0058Isolation Vlv Limitorgue SB-00 RADS B lO0dys 100dys App D B0003ICR 1-FCV-62-98 Chrgng Pmp 54114-1 Reliance 61 2500F, 25 psig, 100% RH, 2 x TO' A 100 100 NA NA Lim Rpt B0058l A-A Hin Flow Limitorgue SMB-00 RADS days days App D B0003ICR 2-FCV-62-98 Chrgng Pmp Not Installed 61 A 100 NA NA2A-A Him Flow

0?days 0 NA NB05ICR I-FCV-62-99 Chrgng Pmp 54114-1 Reliance 61 250'F, 25 psig, 100% RH, 2 x I0 A 100B 10 N NA Lim RptB05lA-A Hinm Flow Limitorgue SMB-00 BADS days days App D B0003ICR Z-FCV-62-99 Chrgng Pmp Not Installed 61 A 100 NA NA2A-A Him Flow

daysICR 1-FSV-62-77 Ltdwn Ln Iso 54114-1 ASCO 61 350-F, Atm, Red 4 x '10 RADS A 5 min 1 hr NA NA AnalysisVlv Solenoid FT831654 5B 1O0dys 100dys NS-CE-755*kICR 2-FSV-62-77 -Ltdwn Ln Iso 54114-1 ASCO 61 350 F, Atm, Red 4 x 10' RADS A 5 min I hr NA NA AnalysisVlv Solenoid FT831654 B 100dys 1O0dys NS-CE-755GS 1-LCV-62-132 VCT Otlt Iso 54114-1 Reliance 14 250uF 25 psig, 100% RH, 2x '10 A 5 min 1 hr NA NA Lim Rpt B0058Vlv Lyl Ctrl Limitorgue SB-00 RAD B 1O0dys 1O0dys App D B0003*GS 2-LCV-6 2-132 -VCT O~tt Iso 54114-1 Reliance 14 250 0F 25 psig, 100% RH, 2 x 10 A 5 min 1 hr NA NA Lim Rpt B0058Vlv Lvl Ctrl Limitorgu RB0 ADS B lOds lO00dys App D B0003GS 1-LCV-6271ii VCT Otlt Iso 54114 Relianc 14 250OF 25 psig, 100% RR, 2 x 10 RA 5 m 1 hr NA NA Lim Rpt B0058Vlv Lvl Ctrl Limitorgue SB-00 RADS B 1O0dys lO0dys, App D B0003GS 2-LCV-62-133 VCT OttIso Not Installed 14A *WA A

1u'Juys*Not Field Verified

DEO6 :E33160.01

TABLE INPUT DATA SHEETSWP CLASS IE EQUIPMENT

OUTSIDE CONTAINMENT - SUBJECTTO HELB UNITS 1 AND 2

Rpvistion 0 Rl R2 R3 R4

Preparer/Date F. A. Plesic

Reviewer/Date G. J. Malek 12-15-81

m nVlv Lvl Ctrl

RO 6-11-83

0

TABLE INPUT DATA SHEETSWP CLASS 1E EQUIPMENT

OUTSIDE CONTAINMENT - SUBJECT *Preparer/DateTO HELD UNITS 1 AND 2

Reviewer/Date

Revision 0 RI

PENT. W. Schoene RO 6-10-83

RKWF. A. Plesic 12-15-81 RO 6-11-83

R2 R3 R4

AWL jg

5-5-84 qh'k'I

LOC COMPONENTICR 1-LCV-62-135

*ICR 2-LCV-62-135

ICR 1-LCV-62-136

*ICR 2-LCV-62-136

ICR 1-LT-62-2-38

*ICR 2-LT-62-238

ICR 1-LT-62-242

*ICR 2-LT-62-242

ICR 1-MTR-62:-104

*ICR 2-MTR-62-104

ICR 1-MTR-62-108

*ICR 2-MfTR-62-108

CONTRACT NO.FUNCTION MFG & MODEL NO.

Chrgng PmpFlow RWSTChrgng PupFlow RWSTCbrgng PupFlow RWSTChrgng PupFlow RWSTEric Acd TnkA LevelEric Acd TnkB LevelEric Acd TnkC LevelEric Acd TnkC LevelCNTFGL ChrgngPmp lB-BCNTFGL CbrgngPup 2B-BCNTFGL Chrgng

Pu lA-ACNTGL Chrgng

Pup 2A-A

54114-1 RelianceLimitorgue SB-0054114-1 RelianceLimitorgue SB-0O-54114-1 RelianceLimitorgue SB-0054114-1 RelianceLimitorgue SB-0054114-1 Earton75254114-1 Barton75254114-1 Barton75254114-1 Barton75254114-1 West.7 2F449 1754114-1 west.72F4491754114-1 west.72F4491754114-1 west.

ABNL ORACD ENV ENVIRONMENT TO WHICH QUALIFIEg

66 25U F '25 psig, 100% RH, 2 x 10'RADS

966 250~'F 25 paig, 100% RH, 2 x 107

-10 RADS66 250"F 25 psig, 100% RH, 2 x 10 7

RADS66 250OF 25 psig, 100% RH, 2 x 107

RADS552 130uF, 14.7 psig, 95% RH, 1x10' rad

52 1300F, 14.7 paig, 95% RH,1x10 5 rad

352 1300F, 14.7 psig, 95% RH,lxlO red

52 1300F, 14.7 psig, 95% RH,lxlO Sred

20 110"F, 1 Atm, 100% RH, 2 x 10~RADS

20 110'F, 1 Atm, 100% RH, 2 x 10~RADS

20 110'F, 1 Atm, 100% RH2 x 10~RADS8

20 110'F, 1 Atm, 1600%RH 2 x 1o0

ABABABAB

A

A

A

OPER

I wkI 00dysI wk100dys1 wk1 O0dys1 wkI OOdys100days100100s

100

100s

100

100

OPER ACCUR.

DEMO NAQ

1lwk NA

1lwk NA

Ilwk NA

100d+1

100dy1

100 +1Idays100 +1I

100 NAI

100 NA

100 NA

ACCUR QUAL RPTDEMO METHODNA Limitorque RPT B0058

App D B0003NA Limitorque RPT B0058

App D B0003NA Limitorque RPT B0058

App D B0003NA Limitorque RIT B0058

App D B0003* 1 WCAP 8687, Supp 2-

EQTR-E04A, EQDP-ESE-4* 1 WCAP 8687, Supp 2-

EQTR-E04A, EQDP-ESE-4* 1 WCAP 8687, Supp 2-

EQTR-E04A, EQDP-ESE-4* 1 WCAP 8687, Supp 2-

QT-E04A, EQDP-ESE-4NA Tes/Analysis

WCAP 8754NA Test/Analysis

WCAP 8754NA Test/Analysis

WCAP 8754NA Test/Analysis

WCAP 8754

*Not Field Verified

DE06:E33 160.01

TABLE 3.

SHEET NO:

.1y.. ays..

A 100 100 NAdays days

TABLE 3.11-8

MHEET NO: WBN-NEB-5 -EFFECTIVEDATE

0CT 4

TABLE INPUT DATA SHEETSlIP CLASS 1E EQUIPMENT

OUTSIDE CONTAINMENT - SUBJECTTO HELB UNITS 1 MID 2

PEN RKW V

Preparer/Date T. W. Schoene RO 6-10-83 4-19-841/Ift#1RKW AWL ,t0

Reviewer/Date F. A. Plesic 12-15-81 RO 6-11-83 5-5-84 q?/Itl

CONTRACT NO. ABNL OR OPER OPER ACCUR ACCUR QUAL lIFT

LOC COMPONENT FUNCTION MFG & MO)DEL NO.* ACD ENVR ENVIRONMENT TO WHICH QUALIFIED: CAT REQKT DE1M) REQMT DE1N) METHOD

ICR I-FCV-63-8 RHR HTXA to 54114-1 Reliance 61 2550F, 25 psig, 100% RH, 2 x 10' A 1 wk 1 wk NA NA Lim Rpt B0058

CVCS Cha Pmp Limitorgue SB-00 LADS B 100dy a 10dys App D B0003

*ICR 2-FCV-63-8 RUR HTXA to 54114-1 Reliance 61 250 Fp 25 psig, 100% RE, 2 x 10' A I wk 1 wk NA NA Lim Rpt B0058

CVCS Che Pmp Limitorgue SB-00 RADS - B 100dys 100dys App D B0003

ICR I-FCV-63-11 RHR HTXE to 54114-1 Reliance 61 250'F, 25 psig, 100% RH, 2 x 10' A 1 wk 1 wk NA NA Lim Rpt B0058

SSPp Limitorque SB-00 LADS - B 100dys 1O dys App D B0003

*ICR 2-FCV-63-11 RHR WIBt 41- Rlac 1 20,2 sg 0 _0% RH, 2 i-00' A 1 wk 1 wk NA NA Lim Rpt B0058

ICR. 1-FCV-63-25 SIS Emn Inj 54114-1 Reliance 61 256-F, 25 psig, 100% RH, 2 x 10' A 5 in 5 min NA NA Lim Rpt B0058

Tic Shtof Vlv Limitorgue SBD-O00 BADS B 100dys 100dys _ _ _App D B0003

*Not Field Verified

DE06:E33160.01

Rl R2 R3 R4Revision 0

0

TABLE 3.11-8 E F F P T TI V e TABLE INPUT DATA SHEET

SHEET NO: WBN-NEB-6 D AT E SWP CLASS 1E EQUIPMENT

O ' J K.-A OUTSIDE CONTAINMENT - SUBJECTTO HELB UNITS I AND 2

Revision 0

Preparer/Date

Reviewer/Date

RI R2 R3 R4

PENT. W. Schoene RO 6-10-83

RKWF. A. Plesic 12-15-81 RO 6-11-83

RKW &&

AWL5-5-84 9/kG/f 4

CONTRACT NO. ABNL OR OPER OPER ACCUR- ACCUR QUAL RPTLOC COMPONENT FUNCTION MFG & MODEL NO. ACD ENVR ENVIRONMENT TO WHICH QUALIFIED, CAT REQKT DEMO REQMT DEMO METHOD*ICR 2-FCV-63-25 SIS Brm Inj 54114-1 Reliance 61 255 F, '25 psig, 100% RH, 2 x 10' A 5 min 1 hr NA NA Lim Rpt B0058Tk Shtof Vlv Limitorgue SBD-00 RADS ? B lO0dys 1O0dys App D B0003ICR I-FCV--63-26 SIS Brm Inj 54114-1 Reliance 61 250uF, 25 psig, 100% RH, 2 x 10 A 5 min 1 hr NA NA Lim Rpt B0058Tk Shtof Vlv Limitorgue SBD-00 RADS B lOdys 100dys App D B0003IC2FC-3-26 SIS Bin Inj 54114-1 Reliance 61 250'F, 25 psig, 100% RH, 2 x 1 7 An m 1 hr NA NA Lim Rpt B0058Tk Shtof Vlv Limitorgue SBD-00 RADS ? B 1O0dys 100dys App D B0003

ICR I-FCV-63-39 SIS Bin Inj 54114-1 Reliance 61 250uF, 25 psig, 100% RH, 2 x 107 A 5 min 1 hr NA NA Lim Rpt B0058Tk Shtof Vlv Limitorgue SBD-00 RADS B 1O0dys 100dys App D B0003*ICR 2-FCV-63-39 SIS Emn Inj 54114-1 Reliance 61 250 uF, 25 psig, 100% RH, 2 x 10 7 A 5 min 1 hr NA NA Lim Rpt B0058Tk Shtof Vlv Limitorgue SBD-00 RADS 7 B 1O0dys lO0dys App D B0003ICR 1-FCV-63-40 SIS Bin In~j 54114-1 Reliance 61 250"F, 25 psig, 100% RH, 2 x 107 A 5 min 1 hr NA NA Lim Rpt B0058

Tk Shtof Vlv Limitorgue SBD-00 RADS 7 B 100dys 1O0dys App D B0003*ICR 2-FCV-63-40 SIS Emn Inj 54114-1 Reliance 61 250'F, 25 psig, 100% RH, 2 x 107 A 5 min 1 hr NA NA Lim Rpt B0058Tk Shtof Vlv Limitorgue SBD-00 RADS 0 B 1O0dys lO0dys App D B0003ICR 1-FCV-63-72 Cntmt Sumnp to 54114-1 Reliance 77 300uF, 10 psig, 100% rh,2x10 rads A 1 wk 1 irk NA NA Lim Rpt B0058

RHR Pump A-A Limitoru BD3 6 B 100dys 1O0dys App C 600456*ICR 2-FCV-63-72 Cntmt Sump to 54114-11Reliane -77 3O0UF, 10 psig,100% rh,2x100 rads A 1 irk I wrk NA NA Lim Rpt B0058RHR Pump A-A Limitorgue SBD-3 0 B lO0dys 100dys App C 600456

ICR 1-FCV-63-73 Cntmt Sump to 54114-1 Reliance 77 300uF, 10 paig,100% rh,2x10 rads A 1 wrk I wrk NA NA Lim Rpt B0058RHR Pump B-B Limitorgue SBD-3 a B 100dys lO0dys App C 600456*ICR 2-FCV-63-73 Cntmt Sump to 54114-1 Reliance 77 300uF, 10 paig,100% rh,2x100 reds A I irk I irk NA NA Lim Rpt B0058RHR Pump B-B jLimitorpue SBD-3 B lO0dys lO0dys App C 600456ICR 1-FCV-63-93 RHR RCS 23 54114-1 Reliance 61 250'uF, 25 paig, 100% RH, 2 x 10O7 A I wk I wrk NA NA Lim Rpt B0058Flow Cont Vlv Limitorgue SBD-2 RADS 7 B lO0dys lO0dys App D B0003*ICR 2-FCV-63-93 RHR RCW 2&3 54114-1 Reliance 61 2500 F, 25 psig, 100% RH, 2 x 107 A 1 irk 1 irk NA NA Lim Rpt B0058Flow Cont Vlv Limitorgue SBD-2 RADS ? B 1O0dys lO0dys App D B0003ICR 1-FCV-63-94 RHR RCS 164 54114-1 Reliance 61 250'F, 25 paig, 1001 RH, 2 x 1 A I irk 1 irk NA NA Lim Rpt B0058Flow Cont Vlv Limitorpue SBD-2 RADS B lO0dys lO0dys App D B0003

*Not Field Verified

DE06:E33160.01

0

0

TABLE 3.11-8 EFFECTIVESHEET NO: WBN-NEB-7 Ai T EL; i iý'34

TABLE INPUT DATA SHEETSliP CLASS 1E EQUIPMENT

OUTSIDE CONTAINMENT - SUBJECTTO HELB UNITS 1 AND 2 Reviewer/Date

Reviever/Date F. A. Plesic 12-15-81 RO 6-11-83

Ravision 0 El R2 R3 R4

PBNT. W. Schoene RO 6-10-83

RKV

R EV Ofw t

AWL

CONTRACT No. ABNL OR OPER OPER AC .CUR ACCUR QUAL RPTLOC COMPONENT FUNCTION MFG & MO)DEL NO. ACD ENVR ENVIRONMENT TO WHICH QUALIFIED CT REONT DEMO REQKfT DEMO) METHOD*ICR 2-FCV-63-94 RHR RCS 1&4 54114-1 Reliance 61 250 aF, 25 paig, 100% RH, 2 x 10 SAL 1 wk 1 wk NA NA Lim Rpt B0003Flow Cont Vlv Limitorgue SBD-2 RADS B lO0dys lO0dys Ap~p D B0003ICR I-FCV-63-172 RHR RCS 1&3 54114-1 Reliance 61 300-'F, 70 -ig 100% RH A 1 wk 1 wk NA NA Lim Rpt 80058Flow Iso Vlv Limitorgue SB-2 2.04 x 10 RADS B 100dys 100dys- App C 600456*ICR 2-FCV-63-172 ERR RCS 1&3 54114-1 Reliance 61 300- x 7 0O8Pai9, 100% RH A I wk 1 wk NA NA Lim Rpt 80058Flow Iso Vlv Limitorgue SB-2 2.04 x 10 RADS B lO0dys 100dys App C 600456

*Not Field Verified

DE06:E33160.01

0

Preparer/Date

Revision 0 R1 R2 R3 R4

0

TABLE INPUT DATA SHEETSWP CLASS 1E EQUIPMENT

OUTSIDE CONTAINMENT - SUBJECTTO HELB UNITS 1 AND 2

Revision 0

Preparer/Date G. J. Malek 10-21-81 RO

Reviewer/Date F. A. Plesic 12-15-81 RO

RI R2 R3 R4

PEN RKW &9-

RRW AWL 81Y

6-11-83 5-5-84 .4.114

LOC COMPONENTICR I-FSV-68-305

CONTRACT NO.FUNCTION MFG & MO)DEL NO.

RCS Flow Cont 54114-1

ABNL ORACD ENVR ENVIRONMENT TO WHICH QMAIFIED

61 3?0 F, Atm, 100% RB, 4x1 0 RADS

OPERCAT REQMTA 5min

OPER ACCUR,DEMO REQMT5 min NA

AC CUR QUAL RPTDEND METHODNA Test/Analysis

Dl oNm aeluy IUUUYO 1UIJUE5 V5IICR 2-FSV-68-305 WDS N2 Man to 54114-1 Not 61 3ý0 F, Atm, 1002 RH, 4-xO RADS A 5 min 5 min NA NA Test/AnalysisPrt Installed B 100dys lO0dys NS-CE-755

DE06:E33 160.01

TABLE 3.1

SHEET NO:

0s

TABLE 3.11-8

SHUETNO: WBN-NEB-13 EFFECTIVEDATE2T %.

TABLE INPUT DATA SHEETSWP CLASS 1E EQUIPMENT

OUTSIDE CONTAINMENT - SUBJECTTO HELB UNITS I AND 2

0

Revision 0

Preparer/Date T. W.

Revewe/Dae F A.Plesic 12-15-81 RO 6-11-83

RI R2 R3 R4k'm4

Schoene RO 6-10-83RKW

KKW qjhc4-19-84 ?,//Y/

AWL f:/

5-5-84 ib.v~,'

LOC COMPONENT FUNCTIONGS 1-TE-74-14 RHR Pump A-A

Disch Temp

CONTRACT NO.MFG & MO3DEL NO.54114-1 RDF

ABNL OR--- NUNwn CATTfl~vq 'inM DEOhnnDEOnETOOPER ACUNACR UL P50 w.,in"W 7CA. I~ A BM IM RQT D13 MTO

OPER

-0 *,S g,LUUA. rn,L.:ýJXXu

GS 2-TE-74-14 RHlE Pump A-A 54114-1 Not 50 A 100uDisch Temp Installed dyGS 1-TE-74-25 RHR Pump B-B 54114-1 RDF Corp 50 420"OF,75 psig,100% rh,1.55x10 A 100 100 1.20F 1.2'F WCAP 8587Outlet Temp 21232 rads,2750 ppm,Boron SprayqPh 10.7 days days EQDP-ESE-7GS 2-TE-74-25 RHlE Pump B-B 54114-1 11DF Corp 50 A 100Outlet Temp, 21232 daysICR 1-FSV-77-17 Rcdt to GA 54114-1 Asco 61 350-F, Atm, 100% RH, 4 x 10 5 RADS A 5 mini 1 hr NA NA AnalysisFlow Cntrl FTX831654 B lO01dys 100dysN NS-CE-755ICR 2-FSV-77-17 Rcdt to GA 54114-1 -Asco 61 A 5mm nA NAFlow Cntrl Not Installed B 100dys

A 100

DEO6:E33160.01

OPER

100

ACCUR

1.2'F

ACCUR QUAL RPT

1.2-F WCAP 8587

WWVT0nWwVwm ý

Rl R2 R3 R4

Reviewer/Date F. A.

TABLE 3.11-8 TABLE INPUT DATA SHEET Revision 0 RI R2 R3 R4-E FF EC TI VE~-1 SWP CLASS 1E EQUIPMENT____________________SHEENO:WBN-EB_1

PEN RKWSHETN: B-BD4VA T E JOUTSIDE CONTAINMENT - SUBJECT Preparer/Date T. W. Schoene 10-21-81 RO 6-10-83 4-19-84M4fTO HELE UNITS 1 AND 2 RKW AWL 8I

Reviewer/Date F. A. Plesic 12-15-81 RO 6-11-83 5-5-84 Me/j

CONTRACT NO. ABNL OR OPER OPER ACCUR' ACCUR QUAL RPTLOC COMPONENT FUNCTION MFG & MODEL NO. ACD ENVR ENVIRONMENT TO WHICH QUALIFIED CAT REQMT DEMO REQNT DEMO METHODICR I-FSV-77-20 Rcdt N2 Spply 54114-1 Asco 61 350 0 F, Atm, 80% RH, 4 x WO~ RADS A 5 min 1 hr NA NA Test/Analysis

Flow Cntrl ET831654 B 100dys 100dys NS-CE-755ICR 2-FSV-77-20 Rcdt N2 Spply Not Installed 61 A 5min NA NAFlow Cntrl B 100dysICR 0-MTR-78-9 Spent Fuel 54114-1 West. 46 See EQS NEB-XX-.13 for A 100 NA NA See EQS NEB-XX-13Pit Pmp B-B 77CI2671 Qualification Environment days

ICR 0-MTR-78-12 Spent Fuel 54114-1 West. 46 See EQS NEBXX-13 for A 100 NA NA See EQS NEB-XX-13Pit Pump A-A 73C74082 Oujalifftcation Environment daysICR O-MTR-78-35 Spent Fuel 54114-1 West. 46 See EQS NEBXX,1~.3 for A 100 NA NA See EQS NEB-XX-13Pit Pump C-S 73C74082 Qualification Environment -days

ICR 1-_FSV-81-12 PW RCS Press 54114-1 Asco 61 350-F, Atm, 100% RH, 4 xý 10 5 RADS A 5 min 1 hr NA NA AnalysisRelf Tnlc FT831654 B lO0dys lO0dys NS-CE-755*ICR 2-FSV-81-12 PW RCS Press 54114-1 Not 61 350 0 F, Atm, 100% RH, 4 x 10-' RADS A 5 min 1 hr NA NA AnalysisReif Tnk Installed B lO0dys 100dys NS-CE-755

*Not Field Verified

DE06:E33160.01

3. 11-8/WBNggR0001

TABLE INPUT DATA SHU ~ viin lE22T2

WINW CLASS 11 EQUIPtIENT aerat

viewer/Date A41 - -;

couTRAcT No. ASnn 01~UIT~~MVM~m JUIIZflI~ ID Wl A- RUV4 DENO~ ~ Efl.... ~~~ ~ ~ ~ ~ ~ ~ ~ ~ ~ F-w flfl DENO bwnn w ... a.. .. 9..f9. M .' d Ws - r. - --

OPER OVER ACCUR ACCUR

5 1-TS-1-17A,-17B,-18A,-18B

2-TS-1-17A,-17B,-18A, -188

15 I-FE-30-194I-FE-30-195

..12 1-LSV-3-148A,-156A, -164A,-171IA

MV Limit Switch on:2-FCV-1-148,-149

SVR Limit Switch on:2-FCV-1-147 ,-150

12 1-PS-3-148,-156,-164, -1712-PS-3--148,-156,-164, -171

Steam Flowto AFPT1.01 HighTemp, SW

Pen Ebm Cl.Fan A-A orB-B FlowControl Sw

Stm Gen LviBypass SOV

SG WarmingVlv LimitSW

SG WarmingVIV LimitSW

SG LviBypass PressSW

86422Fenwal17323-0

Fluid Comp,Inc. (FCI)FR-72-4

827551ASCO206-381 -3Rvu

83577NamcoEA700

83577Namc oEA700

830616ASCO51.1 AKR/TLIOA32R

68R0 &. Temp-3230F Press-22.3 psia69RI Humd-100% Radn - N/A

48Rl& Temp-3400F Press 43 psi49Rl Humd-l00% Rad xlIO rsds

46R06 Temp-3460F Press-11O psig47RI Iiumd-100Z Radn-2x10 7 .rads

Spray-3000 ppm boron/pH 9-11

76R0 Open item-EEBOO56

76R0 Open item-EEB0O56

46R0 Temp-21001? Press-2.2 sigHumd-100% Radn-17x1O9 rads

a/b 5m/100d

110 d +50F +50F Wyle Labs Test-140F -140 F Report No. 17509-1

a 100d .312 yr. +3fps

a 100d 5.9 yr.

+3fps. FCI Report No.- 708053 Dtd 8/28/80

ASCO Test ReportNo. AQS21678/TR,Rev. A

a/b 5m/100d

of of

a 100d 100d ASCO Test ReportNo. AQR-101083,Rev. 1, dated 6/1/84

0

W"L IF?

0

:3.11-8/WBNEEB0OO2

CONTRACT NO. hURL 01O

TABLE INPUT DATA SHZRT

WSWP CLASS 19EQUWIPMENITE

ENVIRONMENT TO WHICH QUALIFIEDOPEl OVER AGGUR ACCUR

SVR 2-FSV-1-7 ,-14,-25 ,-32

SVR 2-FSV-1-150

SVR 2-FSV-1-147

NVR 2 -FSV-1 -148 ,-149

SVR I -FSV-3-185 ,-1882-FSV-3-185 ,-188

NVR 1-FSV-3-186,-1872-FSV-3-186 ,-187

Stm GenB lowdown HdrFlow Soy

Stm, GenWarming Soy

Stm GenWarmingSoy

Stm GenWarmingSow

SG Hain 7WCheck VlvBypass Soy

SG Main FWCheck VlvBypass Soy

83577ASCOHT830OB58RU

83577 ASCOHiT8300B58 RU

83577ASCOHT8 300B58 RU

83577ASCO1fl8300B58RU

822950ASCO206-381 -2F

822950ASCO206-381-2F

76R0 Open item-EEBOO36

76R0 Open itear-EEB0007

76R0 Open item-EEBOOO7

76R0 Open item-EEBOOO7

76R0 Temperature: 3460FPress: 110 psigRel. Humidity: 100%Radiation: 2x108 rads

76R0 Temperature: 34607 Press:11O psigRel. Humidity: 100%Radiation: 2x108 rads

a/b 5m/100d

to It

It is

of of

a/b 5m/100d

N/A N/A

N/A N/A

N/A N/A

137d N/A N/A ASCO Test ReportAQS21678/TR,Rev A

to to o N/A N/A

SVR 2-LSV-3-174

9 0-TS-12-93A0-TS-12 -93B

SCI Level 83577 ASCOSol Vlv 11T8300B58RU

Aux B ldgSteam lineRupture Prot

834197Fenval18023-7

76R0 Open item-EEBOOO7

52106 Temp-323 0F54R1 Humd-100Z

a/b 5m/100d**

Press-7.9 psigR~adn-lx104 rads

N/A N/A

a I. 110d + 207 + 20F Wyle Labs TestReport No. 17509-1Dtd 5/16/83

LOC COMPONENTQUAL IF?

CAT REQN? DENO RVAWT . DENO METHODFUNCTION MFG 4 MODEL NO ACD'ENVR

3.1 1-8/WBtIEEBOOO3

-- ----o, - TABLE INPUT DATA MET813n I 2R3R

WMIP CLSS1 EUIPEN eOarer/Daa 4t 27. L"1e/0 -f'-

vL~vier/Date . /--2

.LOC lThDflWWP

SYR, 2-LSV-3-175

12 2-LSV-3-148A,-156A,-164A,

-171lA

I-LN-3-14aA,-156A,-164A,-17 1A2-LM-3-148A,-156A,-164A,

-171lA

CONTRACT NO. ABML ORtWIIPulMwrn MDfP IL MnflTi IM Ad~ftUU

SG4 Level 83577 ASCOSol Vlv RT830OB58RU

St. GenLvi BypassSoy

St. GenLvi BypassVlv 1/P cony

87379ASCOWPXRV202-301-IF

87379Masoneilan8005A

WMUDflMWMP YE~ UUTI!Il flIIALTPIED

76RO Open item E EB0007

46RO & Open item-EEBOO3547RI

46R0 & Temp - 133 0F47RI Humd - At,

Press. -.55 psigRadn - i.72ci0 4 rads

OPRa Ovis

fVMVMCAT RIONT DENO lO? Dl) HTO

a/b 5m/100d

a 100d

ACCUR ACCUR QUAL RPT

N/A NIA

N/A NIA

a 100d 1.1 yr Wyle LaboratoriesReport No. 17506-1.

.SVR 1-LSV-3-174,-175

SVR 1-FSV-1-150,-147

NVR I-FSV-1-148,-149

SG Level SolVIV

St. GenWarming Soy

Stm GenWarming Soy

827551ASCOX206-381-3RVU

827551ASCOX206-38 1-6RVF

82755 1ASCOX206-38 l-6RVF

76R0 Temp, - 346 0FHumd - 100%Spray - 3000

76RO

Press. -110 psigRadn - 2x1O8 rads

ppm Boron/pH 9-11

76RO

a/b 5m/100d

a/b 5m/100d

a/b 5m/100d

153d

15 3D

15 3d

ASCO Test ReportAQS21678/TR, Rev. A

TABLE INPUT DATA SHEET R

W N Wa j o 0L S I t 2IP E N 1 3 a r r1 4 -

Io ar rDta - Y3.1 1-8IWBNEEB0004

Lac COMPONENT12 Positioner on:

1-LCV-3-148, -156,-164,-171

* 2-LCV-3-148,-156,* -164,-171

FUNCTIONStm Gen LviControl ValvePosi tioner

CONTRACT NO. AbNL ORMFG 4 MODEL NO. LCD'ENVE83577 46&Masoneilan 8012 47

wwuwonumagmY 9m RUITfPA (tETRIED CAT Rt(Off DEMO URONT MTOpen iteam-EEBOO57

OPEl OPEl

a 100d

14 Positioner on: Stm Gen Lvi 83577-ADON1-LCV-3-172,-173 Control Valve Masoneilan 8012

2-LCV-3-172,-173 Positioner

20 2-FSV-67-168,-170 Centr Chg Pup 83577 ASCOEm Clr Supply ITT8300B58RUContl Vlv Soy

49& Open item-EEBOO5780

62R0 Open item-EEB0029& 65R1

fcu AccuR QUAL IF?

a lO0d**

a/b 5m/100d

0

3.*1 l-8/WBNEEBOOOS

LOC _COMPONENT FUN(CONTRACT NO. AMIM! OR

ITION MF HG & MODEL NO. ACD EMVE

TARLE INPUT DATA SHEET

VDNP CLASS 11 EQUIPHENT

ENVIRONMIENT TO WHICH QUALMFI

FRevi aio0 a 01 1 2 R 3 34

e arer/Dateie7 0L~ - V-9-/ Z

vicver/D.teAZ7~s76 ~ a.q ... g~

OPEl OPEl

ED CAT KB (JMT DEMO REZUKI DEMO METHOD

R ACCUR QUA!. RPT

12 2-LSV-3-148,-156, Stm Gen Level 83577 ASCO-164,-171 Soy HT8300B58RU

14 2-LSV-3-172,-173

3 O-TS-12-97A,-97B,-98A, -983

4 0-TS-12-94A,-94B,-95A, -953, -96A,-96B

SVR i-FSV-3-236A,-2363, -245A ,-245B2-FSV-3-236A,-2363, 245A, -2453

Aux Bldg StiaLine RuptureTemp Sw

Aux Bldg StmLine RuptureTemp Sv

834197 Fenval18023-7

834197 Fenwai18023-7

Upper Tap Main 822950FW Sg Isol Vlv ASCOSoy 206-381-2F

46 RO Open itecr-EEB0029&47 Ri

80 RI&49 Ri

62R0,63R1,&64RI

62R0,63Rl,&64R1

Temp-3230 1 Press-7.9 psigliund-1O0l Radn-1x10 4 rads

Temp-3230F Press-7.9 psigHumd-100% Radn-INlO' rads

76RO Temperature-3460F; Press-11O psigRelative Humidity-IOOZ;Radiation-2xl08 rads

a 100 d

a/b 5m/100d

a lm* 110 days + 201

a lm 110 days + 201

a/b 5m/100d

137d -N/A

" 201 Wyle Labe TestReport No. 17509-1Dtd 5/16/83

" 201 Wyle Labs TestReport No. 17509-1Dtd 5/16/83

N/A ASCO Test ReportAQS21678/TR,Rev A.

NVR i-FSV-3-239A, -2393,-242A, -24232-FS V-3-239A, -239B,-242A, -2423

76RO $I is ofN/A N/A

3.1l-8/WBNEEB0006enT -,

CONTRACT NO. ADUL, ORCION MFG_4 NODEL NO. ACD'ENVI

TABLE INPUT DATA SHEET

WMIP CLASS 1z EQUIPtEWT

ENVIRONMENT TO WHICHe OALMEDK ~ um ~ 3w nw VUf

OPER OPER ACCIJI ACCUR QUAL RP?

I-PS-3-l3gA,B,D-144A,B,D2-PS-3-139A,B,D-144A,B, D

Cond StorageTank RdrPress

14 l-PS-3-140A,l5oA, Aux Fe Pipe2 -PS-3-140A, ISCA BreakDetection

*19 I-P14-3-122,132, AFW Pump VlV9 2-PMf-3-122,132 E/H Actuator

.14 2-PS-30-194 Pen Rm Cla2-FS-30-195 Fan A-A or

B-B FlowControl Sv

830616 ASCOSB3lAKR/TD3OA32R

830616 ASCOSB1IAKR/TG13A42R

Fisher-Type 546

821197 Dwyer1627-1

52R0 Temp-2100r Press-2.2 p8ugHumd-lOOZ Radn-17xl0 6 rads

52R0 & Temp-21207 Press-Atm54R1 Humd-100% Radn-lxl05 rads

51 Open item - EEB0015

a 100d l00d

b 100d 100d

a 100d 136d

ASCO Test ReportNo. AQR-101083,Rev. I dated6/1/84.

ASCO :rest ReportNo. AQR-101083Rev. 1 dated6/1/84

Wyle Test Report17504-1, Rev. A

a I Mo.

LOC COMPONENT

0

3. 11-8/WBNEEB0OO7

LOC COMPONENT FUNl

0

CONTRACT NO. ARML ORICION -MPG 4 MODEL NO. ACD'SKYE

TABLE INPUT DATA SlIEST avsn0al R R3 4WWI CLASS 13 EQUIRT tEN

OPER OVER ACCUR ACCUR QUAL RPTENVIRONMEENT TO WHICHI QUALIFIED CAT REONT DENO REORT DEWO METHOD

THIS PAGE INTENTIONALLY LEFT BLANK

0s

TABLE INPUT DATA SHEET

wi3U cLAss LE EQUIPMEfNT

3.1 1-8/WBNEEBOOO8

LOC COMONVOENT

15 2-FSV-67-350,352

14 2-FSV-67-354

9 2-FSV-67-2172-FSV-67-219

14 2-FSV--67-356

FUNCTION

PenetrationRm Cir Cantvlv SovPenn Em Cirvlv

BA Xfr andFw Pmp Clrvlv

Penn ha Cirvlv

CONTRACT NO. A- FG So ODEL NO. AC

83577 ASCOHB8300C58RUJ

Aux

w-L OR~D'EIVR

56R057RI

48R249RI

5557

ENVIRONMENT TO UHICH QUALIZII

Open item -. EEBOO29

Open item - EEB0029

vieerjoate h'. e. 46 4 d-,v ls

OPEl OnER ACCUR ACCUR QUAL UP?ED CAT REQNT DEMO REQMT DEMfO METHOD

a/b 5m/100d

a/b 5m/

100d

&49Rl

0

F-. , *;..I\.

3.1 l-8/WBNEEBOOO9

LOC COM4PONENT FUNiCONTRrACT NO. ADUL OR

0

TABLE INPUTr DATA SHEET Fvso 1 B 3 R

WBNP CLASS i I ftfEQ IPET

vieve/Date ~ .ow

- - ~mw* aSwmn& V .. 4 asuiLIDwUa&%U iUL !E 5DM& I.A& u&!LI5 IrwJ 5aAFI MD,. M.ETHOD

OPEN OPEN ACCla ACCUR QIJAL RPT

19 1&2-PDT-3--122A-A,132A-B

Aux Fw PmpsA-A & B-BDiff Press

828973 FoxboroN-El lDM-H1D2 54RIPrss9 psi; Radn-2.2xlO rad

&55R1

a Imo 43d 1.0% 1'.0% Foxboro Test Reportspan span Q9-6005 & Test

Report No. T3-1097.

14 1,2-TS-30-1941 ,2-TS-30-195

15 l,2-TS-30-1g61 ,2-TS-30-197

Positioners on:SVR l,2-LCV-3-174

I ,2-LCV-3-175

Pen Rn ClrsEly 737, FanA-A; Fan B-B

Pvn Em CirsEly 713, FanA-A; Fan B-B

SG 1 and 4Level ControlValve

833871 48R1SOR & 49R1120 lTA-B1 25-JJTTX6

Temp-4300 F Press-80 psigliumd-lOOX Radn-2.2xl0 8 rads TID

56R1&-57R0

83577Hasonei lan8012

a 100d 193.79yrs

+ 50 F + 50F

+ 50F + 50F

Action Environ. TestCorp-.Reports 17344-82N-C,Rev. I& 18441-83N, Rev. I

of

76 Open item - EEB0073

0

E) 51 I -

3.1 1-8/WBNEEBOOIO

TABLE INPUT DATA SHEET iso0 R R3 4

WB3NP CLASS 13 BQUT.PttDT

vepaer/Date/C 4 a

LOC COMPONENTCONTRACT NO). ABUL OR

FUNCTION NNC L MOlDEL bHO AEf WuunOPER OPER

ENVIRONMIENT TO WdHICHl QUALIFIED CAT_ REQMT DENOACCUR ACCUREEQMT DENO

NVR I-PSV-1-13A,-13B, -24A,-24B

SVR I-ECV-1-7,-14,-25, -32

Limit Switch on:SVR 1-FCV-1-147,NVR 148, -149SVR *1-FCV..1-.15O

SVR 1-PSV-1-31A,-31B, -6A, -6B

Mauin SteamHeader Pres

Steam Gen.Blowdovn Viva

SG Loop 1-SC Loop 4Warming Vivs

Main SteamHeader Pree

827551ASCOX206-381-3R1

832045Target Rock82AB-001

832128NAMCOEA 740 *EA180

827551ASCOX206-381I-3RF

76RO Temp-3460 F Press-11O psigHumd-100% Redn-2x108 radsSpray-3000 ppm Boron/pH 9-11

76R0 Temp-385 0 F Press-66 peigHumd-100Z Radn-1.35x10 8 redsSpray-6200 ppm Boron/SO ppmHydrazine PH 8.6-10

76R0 Temp-3400 7 Press-lOS psigHumd-100% Radn-2.04x108 reds

76R0 Temp-346 0 FHumd-100%Spray-3000

Press-11O psigRadn-2x10 8 reds

ppm boron/pH 9-11

a/b 5m/100d

a/b 5m/100d

a/b 5m/100d

153 d

197 d

N/A N/A ASCO Teat ReportAQS21678/TR, Rev. A

Target Rock ReportNo. 3563

525.6 d N/A

a/b 5m/ 153 d100d

N/A NAMCO Test ReportNo. QTR-111, Rev. 0

*NAMCO Test ReportNo. QTR-105, Rev. 3

ASCO Test ReportAQS21678/TR, Rev. A

QUAL 3??METHOD

TABLE INPUT DATA SHEET u.i 0R1 2 R3 411BHP CLASS IE EQUIFIIEN

w~evet/Dat

CONTRACT NO. ABUL OR OPEI OPElENVIRONMENT TO WHICH QUALIFIED CATREQMT DENO

A4CCUR ACUR*3~ ftEbUi

QUAL UP?MwwIIrn~

-- - -C-.-

N/A 0-TS-30-1920-TS-30-193

NVR 1-ZS-1-12NVR 1-ZS-1-23SVR l-ZS-1-30SVR 1-ZS-1-5

5 l-TS-30-214-S

22 0-TS-l2-92A,-92B, -99A,-99B

15 2-FE-30-1962-FE-30-197

N/A O-TS-12-91A,-91B

SFP & ThermalBooster PumpCoolers Fans

Limit Sw onMain Stm HdrPress RelVivs

AFPT RoomAmbient TempSwitches

Aux. Bldg.Steam LineRupture

Pen Rm ClrsFan Flow Sw

Aux BldgSteam LineRupture

824870HoneywellT675A

NANCOEA180832128

86835Fenwal18003-7

Fenwal18023-7

821197Dwyer1627-1

Fenwa 118023-7

46RW& 47RI

Open item-EEBOO85

76R0 Temp-3400 F Press-70psiHumd-100% Radn-2x1 0g ragds

68R0 Temp-323 0 F Press-7.9 psig&-69R1 Humd-100% Radn-1x10 4 rads

40R1 Temp-323 0 F Press-7.9 psigliumd-See 4.1.3 Radn-See 4.1.2

59 Open item-EEBOO80

39R1 Temp-3230F Press-7.9 psigHumd-See 4.1.3 Radn-See 4.1.2

a 100d

a 100d 195 d

a/b 5m/lmo

a lh/Im

a 100d

a lh/In

NAZ4CO QualificationTest Report No.QTR105, Rev. 3

110 d +1.70F +1.70F Wyle Labs TestReport No. 17509-1Dtd 5/16/83

100 d + 20F +201 Wyle Labs TestReport No. 17509-1Dtd 5/16/83

100d + 201 + 201 Wyle Labs TestReport No. 17509-1Dtd 5/16/83

nj;?' ~

ILOC COMPONENTFUNCTION MFG & MODEL NO Arn vwuR

3.11-8/WBNEEBOOII

0

z, 47

L W *;:-3.11-8/WBNEEB0012

TABLE INPUT DATA SHEEPT [. o i R 3 R

WIMP CLASS 13 WQUIPHIET

wiovrf/DateAC, ft-

LOC COIIPONRwrCONTRACT NO. ASUL OR

FUNCION~~l imvr JL WUtW? IMn Aft.OP It OVER ACCUIL ACCUi QUAL RP?

-mw - S * W"VaVWamunnms AW mumonI ImuabaI.&Uu %.A& 5&IFUA II~W 5L~ AIEI UWIuuU

*N/A 0-FSV-12-79

15 I-FE-30-1961-FE-30-197

Aux BldgStm I801

Pen m CMrsFan Flow Sw

827551ASCO206 -380-2RU

834252FCIFR- 72-4

52& Temp-3460 F54 Humd-100%

Spray-3000 p

56R0, Temp-3400 F47RI liwnd-100%

Press-11O psigRadn-2xl08 rads

pm boron/pH 9-11

Press-43 gRadn-lxlOgsra*d.

a/b 5m/ 11.325 yrsl0O~d

a 100d .312 yrs

ASCO Test Report No.AQS21678/TR, Rev. A

FCI Report No.708053 Dtd 8/28/80

S

3.11 -8/WENEE BOO 13CONTRACT MD. BUlL OR

TABLE INPUT DATA SHE~RTFvsn0 2 R3 4

IIDIP CLASS 13 EQUIPMIENT *ae/aeA7

Lviewer/Date -ý

OPEE OPERwtMwonwUMWM W% uuYI'u flhai tIn PAW nwfMY hEIf

ACCUR ACCUaDC ý nhuIU

QUAL UPT

N/A O-LT-77-134O-LT-77-135

1-FSV-67-350I-FSV-67-352

Passive SumpAux BldgLevel Tx

828967-2RoseountI 153DB4

Pen Rm 827551 ASCOCooler SCV 206-380-2RU

81R0 Temp - 31809 Press.-_87.7 psiaHumd - 100% Radn -2.2lx107 rads

56R0& Temp-346 0 F57RI Huind-100%

Spray-3000

Press-ilO psigRadn-2xl08 rads

ppm Boron/pH 9-11

is Is .2 yrs Temp Effect - 1.88%span, Rad Effect =1.5% span.

a/b 5m/ 224d100d

N/A N/A

Rosemount Reports108025 and 108026.

ASCO, Test Report No.AQS21678/TR, Rev. A

FUNCTION NFC 4 MODEL NO. ACD EKVR MEMOLOC COMPONENT

E F F 6.;I V ED-A TE

TABLE INPUT DATA SHEET fvgo i R 3 RWNWeio 0IS 11 EQI2EN 13 11

viewer/Date /'~

CONTRACT NO. AME OR OVER OVERFUNCTIONlwu MFG 4UP MODELYI~f NOY ACanDWflnw' wRf

1-FSV-67-3541-FSV.-67-356

I -LS V-3-1 72I-LSV-3-173

1-LSV-3-148,-156, -164,-171

1-FSV-67-168

I-FSV-67-170

Pen Rm 827551 ASCOCooler SCV 206-381-2RU

TD AFWP SGLvi Coat Vlv

Mtr DrivenAFUP SG LvlCoat VI,,

Centr ChgngPap RMCooler A SCV

Ceatr ChgagPmp RmCooler B SCV

827551 ASCO206-380-2RVU

827551 ASCO206-380-2RVU

827551 ASCO206-380--2RU

827551 ASCO206 -380-2RU

48R2& Temp-346 0 F49R1 Humd-100Z

Spray-3000

Press-lb0 psigRadn7-2x107 reds

ppm Boron/pH 9-11

80R1& Temnp-346 0 F Press-11O psig49RI Huad-100Z Radn-2x10 7 reds

Spray-3000 ppm Boron/pH 9-11

46R0& Temp-3460 F Press-lID psig47R1 Huad-100% Rada-2x107 reds

Spray-3000 ppm Boron/pH 9-11

62 & Temp-346 0 F Press-11O psig65R1 Huad-lO0l Radn-2x10 8 reds

Spray-3000 ppm Boron/pH 9-11

62 & Temp-346 0 F Press-lb0 psig65R1 Humd-100Z Radn-2x10 8 reds

Spray-3000 ppm Boron/pH 9-11

a/b 5m/d 283d N/A N/A ASCO Test Report No.AQS21678/TR, Rev. A

a/b 5m/d100d

28 3d

a 100d 5.32 yrs

a/b 5m/100d

a/b 5m/100d

1.6 yrs N/A

1.6 yrs N/A

ASCO Test Report No.AQS21678/TR, Rev. A

ASCO Test Report No.AQS21678/TR, Rev. A

N/A ASCO Test Report No.AQS21678/TR, Rev. A

N/A ASCO Test Report No.AQS21678/TR, Rev. A

**s-second; rn-minute; d-day; wk-week;ý*mo-mot;y-erDE06;RjIB.8mot;y-er

LOC -COMPONENT

ACCU ACCU1 QUAL RPT

3.11-8/WBNEEB0014

0

WBN-EEB-

Sheeot No:. 1000

LOC C09PONEPITCONTRACT NO.

FUNCTIOlN MFG, &. Mnrl in

TABLE 3.11-8ATABiLE INIPUT D)ATA SHEET

WBNP CLASS 1E EQUIPMENTELECTRICAL CABLES OUTSIDE

CONTAINMENT SUBJECT TO HELS

ABNL OR CPJ CABLES

IRevlIsin 0 Ri 11 R3 R~4

Pr rerZ1Datc 4-

OPER OPE~t ACCUR ACCUR QUAL RPT-. 47E2______&__ 1 --- 1 Lil -*** V,~U 1 1111`[I16-1 !JURI~F1ED WAI Kttj~l9 ULLMU -REOMi UUT'DEM METHODU

NA O 806-) Power 85069-2 Tinl4q,, p-325OF Press - 55 psiq 1- y 11y Se-e EQS.A Tyr ~EB-CBL-9.O

etdlU1t & La Huma - iuUm UnefliSpray- N/IA

WOE (85069-2)1

1WOG (85069-2) it__ __ _ _ _ __ _ _ _ _ _ _ __ _ _ _ _ _ _ __ _ _ _ _ _ _ _

1W0H (85069-2) it it of It ItWON (85069-2) ItIt 11 itI

WDOK (85069-2) It

WON (85069-2) ItI It It Is H t I

WOO (85069-2) to

WOO (824873) _________Bin 86150-2Plastic wire

___________& Cable

WOE (823131)

IWOE (822768) SQN 54762-1General Can Ie

WDK (85124)SQN 824164 AM.WOK (825124) Insulated Wire ____

WOK (822607) BFN ____EFFECTIVE U U

_LDWOO (82260ý7) BFN A___ F It___ it__ to__ __

__W~O (823751) ________BF 54180-2 ____It It___ It__ ____________

lbenerai Cable I

40

WBN-EEB-

Shee No: 1001

COM1PONE NT

WDO (825801)

WDQ(TR830291)

WDQT- 30 1WDQ(TR830291)

WOGG(TR823 751)

FUNCTION

[Power

CONTRACT NO.MFG & MIODEL NO.

ISQN 54762-1, 1

TABLE 3.11-8ATABLEr INPUT DATA SHEET

WBNP CLASS 1E EQUIPMENTELECTRICAL CABLES OUTSIDE

CONTAINMENT SUBJECT TO HELB

AI3NL OR CP] CABLESACD ENVR ENVIRONMENT TO

a 4 Temp - 325DF- I - - I- res;q -75228-1, Plastic Humd - 100% Chem Spr

0 'ER OPtR ACCUR ACCUR QUAL RPTWHICH QUALIFIED CAT REQMT DEMO - REQMT -DEMO METHOD

55 psig

ay - N/A J 1 ~ * --4

See EQSEEB-CBL.-9.0

1 ~Raw - 6-9"" r-afi I4 I I

SQN54762-1Rnme r~-j

1 I-I I I I L

I I I-f + I I

!SQN75228-1 Plasttr I -IWire &

W~~reH SoCal1SQN83874-2 .4Rome Cabole ____I___________________

___ ___I________

1BF54180-21se[Ieral us, 2e ______

PAWDP(TR825551) BIN 86150-2Sxprus Wire So ____

Cable

£fl11A(I 1 mark ~ ~jr with r ~inI-Letd pnlypthy~lon -akf nua thioinsul tion.

- - ____ ____ ____ ___ _____

I 1 11

ZRE235-

j 1 - I -

11

0

WBN-EEB-Shevt No: 1002

LOC COMIPONENTCONTRACT NO.

FUNCTIOlN MFG~ &. mnnsI mf

TABLIE W ~AAIX-9EETWBNP CLASS 1E EQUIPMENT

ELECTRICAL CABLES OUTSIDECONTAINMENT SUBJECT TO HELB

ABNlL OR CPJJ CABLESL rVXUIIE1 v Wilfl, !IUtAL~rIW CATRI KUMT DEMO 'RE(QMT DEMO METHODI L7EZ:!6j See EQSfol WLC (85069-2) Power & Cntro1- 85069-2.Plastic 4tL. TeD 2 0F Press -- 55 psig j 1 EEBCBLy.

Wire & Cable +1,.- ?~3 Humd - 100% Chem Spray -N/A

____(8%6 Radn - 6.qxj07 ,rgad

WN 806-2) .1 1 " 1

WLO (8506-9-2) ofI

- M (809-T Poe 85069-2, Tria-ngi '

___________ Conduit & Cable __________________

Power & ContrcT - Is

WLB (BZM1e8) SQN 85333, Essex TIIIS I

________________ Wire & Cable __________________

WLU (13se2T - IWM 62t'j ower D T ~-___

T~~~~~~~ ~ ~~~~~~~ ALI T -wr&LnrI-F~~jPatj~ II I

Rei~n0 Ri R2 R3 R4

PrDrrIateg it-l ý0 21ERviewcr/Date /Zf-J/ i-SIl

QUAL RPTOPER OPIR ACCUR ACCUR

WBN-EEB-

Sheet No: 1003_______

LOC CO'IPONFNT

TABLE 3.11-8ATABLE INPUT DATA SHEET

WBNP CLASS 1E EQUIPMENTELECTRICAL CABLES OUTSIDECONTAINMENT SUBJECT TO HELD

C.PSJ andABNL OR CPJJ CABLESAm ui ~~,l~~r~ -

______ -Rev-isilon 0 RI R2 _R3 V,4

Re viewer/Date ft.-7f "P 1-Z IOPER OfIER ACCUR ACCUR

* -.-. ~... ,.'. ~ .. gWu LS"MZ cS"VIUý1rUIrc IU Wilil I4UIALUILU CATI DEJI JMO RELJMT DEMO METHODPower and 7Z5 Tm Z- rs 5pi e

V WH(832) Cnrl SN7281Humd - 100% 7 Chem Spray - N/A aj 1 yr 1___ 4 EEB-CBL-9. 0&isi wir C Cýbl Radn - 6.9 x 10 rads

WLJ (823022) It 15 5

WLK (823022) St'

WLS (823751) BF 54180-2 Genera 1tLaD ie

WGB(TR822525) Control BF 83483 Plastic 11I )'Wire and Cable

-7- WMj (UZ44gi-17 Power 824443-1, irie ~.___________Okonite Company ____

WGM(TR823751) Control BF'54180-2I_________________ General CableEF CT V

___________Wire & Cable AT

W'4o5ON' 86506-3, Cyp, us'

Wire & Cable

- ~ j (fV -nflr)--U L Ip -LUISULuLu- ca~blev wI h IaJ cur u the s;peiled nSumber f US p ep. b! lylt-5i U ctr fSfI1tgi.uJndu1-LL WI ...

___________ross-linked polyethylene Insulation and a polyvi~nyl -chloride jacte: over tie ins~ultion) c vered with a

NOTE: CPSJ (TVA Kark Number): ;ame as above exc pt with in overall shield;

CONTRACT NO.FIImrTTnm mr- t. F~nnci

QUAL RPT

0s

WBN-EEB-

Sheet No: 1004

CO-MPONENT FUNCTION

WNB (87365) Power

WNB-l (827750)

TABLE 3.11-8ATABLE INPUT DATA SHEET

WBNP CLASS 1E EQUIPMENT

ELECTRICAL CABLES OUTSIDECONTAINMENT SUBJECT TO HELB

CONTRACT NO.MFG & MODEL NO.

UIJbb,Anaconda

ABNL 0~ACOEN~

LW aL*1 - inn-/ rkII -t~~-- 1:~ 10 1 R"-k. .. yra . I r ~

IREPSJ CABLES

ENVRONENTTOWHICH nUALIFTIlCTRAM lM flATfDI riaThmn - 185-F Press - bb I 'j '~U 4LILL

Revision 0 Ri R2 R3 R4.

Prepgrerlt'ate ~1~L4~,,, .% A~

Reviewer/Dlate ( ~ . 4

OPER OPER ACCUR ACCUR QUAL RPT

a~uII - L x 10 PPM boron, pH

8 6-10 0I8Z/5U, [he t ii-- ''I

Okonite CnmnRnv irnip - .,'o Ir Press - in psiq

See E(QSEEB-CBL-12.0

- __ I_ ti-lmd - 100% Chfem Sipray -N/IWB- 9213-)822173-3, Collye- RCLCvlWNB-1 (822173-3) Ins. Wire______________________________

WNB-l (825471) Anaconda

WNB- (82337)8Z/,331, AnacondaWNB- (82337)Ericsson

WNC-i (827337)i I

I_ Note: EPSJ (TVA Ma-rk Number): Sinqie-conductot, high-v itaqe cable with extruded strand shiel( , ethyleni -propylene rubber insulationor flame retardint, nonc lorinated, mineral-filled, cross-linke( olyethy ene insulation, with extruded

irfsulation shield, with,' etallic electrostatic shielding, and 1hlorosu fonated-polyethylene jacket or

clorinated poly thylene akt

_(82)Pbanad 824L43 and 827750, T~ern -ý8%

See,?, -B,1.2.NHA WNC-1 82770) Power p kni ____ eS5s , a -EBCL-2.

Company Ra4.'^ - zx 106rc~d-.

_________~~~~~~ F_____ F__ E i~ i

Okonite Comnan

U 2

WBN-EEB-Sheet No: 1005

LOc COM~PONENTCONTRACT NO. ABNL OR

LE 3.11-8AINPUT DATA SHEET

ASS lE EQUIPMENTICAL CABLES OUTSIDE PeWMENT SUBJECT TO HELBPr

PJJ CABLES Revi

flJVTvRflMMNT Tfl UUifr U l KTCTrfl

FRevision 0 Ri R2 IR3 R4

arer/Datef p. L -i

ewer /Date az' ,

OP'4R OP&orn- nru

ACCUR ACCUR QUAL RPT_______________ - -- - . -. . . . . . !4~c %A If ul.44 ULi4 nLIYjF ULIIU MEr I I1UUWFB(806-1 Cntol 85069-1, PlasticI4F-2-3-5- Temp - 153vF Press - rl/A See EQS

NA __________ (85069-1_Contro Wire & Cable q~~4 Humd - 100% Chem Spray - 1/ 0 r 1y E-B-54

i.-~S3 Rad - 1 x 108 rads

-- WFD (fl85069-1) 444 444

WFD (85069-1) W

WFG (85069-1) __________________________

WFH (85069-1) 4

WGB (85069-1) ______ ___

WGC (85069-1) _______ __ ___

WGD (85069-1) ______ ___

WGE (85069-1)44_ __

WGG (85069-1)-

WGH (85069-1) "

WGM (85069-1) 444

WHB (85069-1) 4

WHC (85069-1) 4 4- -4

WHO ( 85069-1) 4

WHETIO (806-1 &4 MOE NOY ACD EN

WHG (85069-1)

0

WBN-FEESheet No: 1006

LOC COMPONENT

TABLE 3.11-8ATABLE INPUT DATA SHEET

B- WBNP CLASS 1E EQUIPMENT

ELECTRICAL CABLES OUTSIDECONTAINMENT SUBJECT TO HELB

CONTRACT NO. A8NL OR PIJJ CABLESFIINrTTflN mrm L. MLIWIr unf Krn ruu rulnur7?lutli

R~evision 0JJ R1 R2 3

Prerarer/D 7ý

Reviewerf Date ?

OPER OftR ACCUR ACCUR QUAL RPT____________ * ...-... .~.,---- ". ~t-~ Lt1I L-I~w1,I1UQrILl IV jnnpf !JIURLiritu LAJI IKL14MI ULPIU kLIJMII DEMO METHOD

Coto 7P23! .I-em1P - 'DP-' rreuSS -N/ N/ .1yr r See `EQSCotrl _________'4 4,W Humd - 100% r~hem Spray -/Aa 1y.1r. _______EEB-CBL-15. 0

A48S~ Kadn jx 1139 raag II

_____________47E235- Tenp.-1530

Press NIA____________________44,46,thiuHumd - 100% Chem Spray -NIA I

WGG (823272) Sqp__ 83 Radn 1x108 rads

823128, AmericaiI I I II

WI4R (sR2-412g) IF______ Insulated Wire 2.r2Z.. IF___ IF_____IF

WHL (821238) -as_____ N52ire & 'able to 9

WHL (822435) SQN 75228-1 Pla tic__________ Wire & Cable ttI I I

WFR (sRi 1sn) ____________ Ca ___L____

WFC (86150) toit i

WFD (86150) to to 11ii I IF oil

WFG (86150) 1. IF IF It I IF I.

WFH (86150) IF IF t I ItoI

WGB (86150) IF 11i i ti

WGC (86150) EI EF F. 7 IF

WGO (86150) IF I Ft IF IF 1. to

WGE (86150) It 1. IF II F it II

WGG (86150) IF IFIiit i IF I

WGH (86150) ItIt IF itIt iiIt

WOK (86150) IIHIF i i IF I

WGM ( 86i150) 11 i. IIiiI

0

WBN-EEB-Sheet No: 1007

CONTRACT NO.r"Fi~rrinM r

____________ COMPONENTi mVIUL fUI - MO W M EL W

Control 8615U, CyprushNAJWHB (86150)

TABLE 3.11-8ATABLE INPUT DATA SHEET

WBNP CLASS 1E EQUIPMENT

ELECTRICAL CABLES OUTSIDE Pre

CONTAINMENT SUBJECT TO HELB Rv

ABNL OR PJJ CABLES Rv

ACO ENYR ENVIRONMENT TO WHICH QUALIFIED47EZ3(- j.Temp. - 1530F Press - N/AtadL IL IC...A lrW n~

___ Revision 0 Ri R2 R3 R4

arer ateP.I jV-AX\ 7~

OPER dPER ACCUR ACCURCAT REQMT DEMO REOMT DEMO

-1.I 1 1 1 -1Tii _ Sp u~~n1 ray - N/Aa1ylj1 r

I I WHC (R6l~n) '44.-. 183 Radn -Ixi'ras

QUAL RPTMETHOD

See-EQ SýEB-CBL-15.O0

T WHO (86150) I Ii t i II

-WHE (86150) III I

WHG (86150) iIIa ai '

WHH (86150) II

WHJ (86150)_I I

WHL (827004) Plastic Wire & ___ _____________

WHM (823750) II , I i

__WHM (85069-1) a85069-1, PlasticIJji- and rlahlp' I II

Note: PJJ (TVA N rk Number): M itiple-conductoy cable with a core of the specified number of typý Pi sinjle condictors ___

(Oingie conductor with p01 ethylene insulation and a poyoinyl-chlo ide jace ove the____________sulation) covere with a polyvinyl-chloride outer jacket. ___ ______ _______

0

[DC CflNPIINFNTI

.1

0

WBN-EEB-Sheet No: 1008

bC COMPONENTCONTRACT NO.

FIINrT~nm WrV L. mnni tin

TABLE 3.11-8ATABLE. INrtJT DATA SHEET

WRNP CLASS 1E EQUIPMENT

ELECTRICAL CABLES OUTSIDECONTAINMENT SUBJECT TO HELS

ABNL OR PXJ CABLES

-- ,. ~HH~sg~*,.. %WlH Lilvf% ERIK14MlUIVI~~ 1U WHIMil qAIJUI41L CAR1 KUMI DEMO 'REQMT DEMO METHODN Pwr 827292, Americarq7a5 Tem-p - 36J Press- -113pi rseEEBCB-1________82792)_owe Insulated Wire 44,qO, Humd- 100 % ChmSry-300pm I Ir Lyiz EEB-CBL-13.Corporation A-4 82, Radn - 2 x 10 rads boron, pH 8-11

WOE- 1 (827292) UH gH H

24965, AmericanWOO-i (824965) Hg nsuiated Wire gHH

H g

Corporation

24164, Am-eri canIWOO-i (824164) HgInsulated Wire g gH H gH

I orporation

WOE-i (824164) H rH g H gH

WD- 846,824164,823412-1 HH g HWOK-i (824164, ~Amprig-an Tnig-; _________+ 234TZ--U atied Wire Corp

WON-i (82-4164,823412-1 )

H

WOE-i (825275) _________ ____ ____________________

WOO-i (823412-1 823412-1,82217--r822~173-2) H American Insui-H

Hg g

ated Wire Corp

WOH-i (823412-i,8221 73-2)

g H

WDP-182508-2)825668-2, Americin

CorpF 5

__ __ _ __ _ COMPONENT

I -tRevislon 0. Rt R2 R31fR4i]Prc a re r J1) a t ei4.f t 4 / - /f P o~

Re viewer/Date 2- / .jI-OIVrR OPER ACCUR ACCUR QUAL RPT

WBN-EEB-Sheet No: 1009Q

LOC CO IPOrIIENT

TABLE 3.11-8ATABLE INPUT DATA SHEET

W3NP CLASS 1E E~QUIPMENT

ELECTRICAL CABLES OUTSIDECONTAINMENT SUBJECT TO HELB

CONTRACT NO. AENL OR PXJ CABLES

PIN)TOnMMPNT

Re .viewer/Date U

OPER _ 12,$- ACCR/ ACURQUA

Tn UUTriI "2AI irirn-~UCTO MF & MOE NO A. ...DV .JElVt L.

41 =2 f Temp - .4L44,ql- Humd - 100%

+k~-. 83 1 RadnPress - 113 psig

Chem Spray - 30ODDo- 2 x 10- rads boron, pH 8-11

CAT REQ.'4T DEMO 'REQMT DEMO METHOD___

~aj yr Jyr I f ____EEB-CBI--13.O

WDP-1 (824749) ' POW~eR 824749, The V tV t I

I Okonite Company

WDP-1(82169-3)821609-3, CyprusWDP-1 (821609-3) Wire & Cable It It tI

WDD-1 (TR835573) HTN835342-1 ,, , ,- (831425, 84847) knt o ___________________ ____________________

- ~ _ L _ _ WOH-1ltp Co. ,,~_ _ _ _ __ _ _ _

WD,- TR319

WD- T851)HTN827928 tVWDD- (TR3511) ___________ Okonite Co. ____ ___________________ ________ ________

WOE-i (827749) 827749 Amer______________ ___________ Insulated tqiýr _____________________

WDE-1(TR831136) "HTN825342-1 '

WDH- 1(TR83 1136) kntCo

825668-2 Americai14JfO(825668-2) Insulated Wire

824443 Thee WDO(824443) ___ _____Okonite Company t t V t

NOTE: PXJ (TVA 4rk Number): Single-conductor wire or zable with flame retardant, cross-linke polye+h lene insulation, or flanretardant,Prhy1ppgiiprnpV1. rubber ins &ion. and a nahlorooaf nated ys.nackePtinaover the insulat on.

0

WBN-EEB-Sheect No: 1010

TABLE 3.11-8ATABLE TNI'UT DATA SHUET

WBNP CLASS IL EQUIPMENT

ELECTRICAL CABLES OUTSIDECONTAINMENT SUBJECT TO HELB

-Revis-lon 0 RI R2 4~A~

Reviewer/Date_ Q;7 4- - p,~f'$LOC C0-IPONENT FIINCTI AM

6URIII.AUS KU. IAVNL UR FAMkJ LUOLC.3 OPERv~~N Aff f ~ lrn n rtlnall~rIS LUlt 'II,~- OPrR ACCIJR ACCUR QUAL RPT___________ IfVInvViILI'l IvF fll g,1 UIAL1IFLU LwiI RE.LQ[I DELMO l{QMT DEMO ME~THOD

N WFA-4 (824749) Control 824749, The ~41 E2 ml- - 346 F Press, 113 ps_ 1 yr 1 ee EQWCB-1.Ukonite C-omp-any j, 1-uMa - LUU7. 8nr -11 pray -3800--Ii

(82479Y it Radn -2 x 108 rads boron, pH 8-171

WFB-1 (821609-dI) Control - ±-r-- -yr______(AIW)

a_______________

WFB-1 (822401) 822401, Afflerlcan_____________ __________ Insulated Wire

Corporation

WI-C-I (8ZZ4UI) - ~__wbbI-I ý8zzwI) -

WFH-S- (8Z444i-I) 824443-1, Irie-- - ___________

- - ~L.C2A1J. ____________Okonite Company 0

WGB-1 (824443-1) u sasIa ta

827292, Ame ic I It at If

WHB-1 (827292) Control 827292, Americar i lyr 1lyr

________________ Corporation- _ _ ________

WI-D-i (827292) I I- 2, tI

__WGB-1 (825848) _______ 825848. America 'r,

______________ __________Corporation 1

0

40

WBN-EEB-Shee't No: 1011

LOC COMPONENT

TABLE 3.11-8ATABLE INPUT DATA SHEET

* `PfTR ICALCONTAINMENT

CONTRACT NO.

1E EQUIPMENT

CABLES OUTSIDESUBJECT TO HELB,

ABU3L OR PXMJ CABLESFUNCTION MFG L MOOP Nfl ACfl FNVR

IRevision 0 RI R 3 pi

Pro Dae/Dtg

Reviewer/Dnate

FNVTR0t~MFNT TA WHICH AhlAl IFTFfl CATOfPER OPERIvF0MT DEMOl

ACCUR ACCURD )FfMT flFmn

QUAL RPTWNWTunn

NUWHD-1 (825848) iiq7EZýS- 11It 11 Siee EQS

____________ I EB-CBL-13.0

WHB-1 (822173-1) Control 822173-1, The *"2 Temp - 3460F Press - 113 psig a 1 yr 1 yr I

ROL~k mpto Co- -- Humd - IOU% Chem Spray - 3O~00ppri_______ Radn - 2x108 rads boron, pH 8-11

________

WHH-1 (822173-1) '

1WHB- 1 (823412-1) 823412-1, American " "U

Insulated W~ireCorporation____

WHD-1 (823412-1) 11 II" aa

WHB-1 (825668-2) 825668-2, American to 1 it I

Insulated Wire___________________________Corporation _________

IWHE-1 (824965) Control 824965, American ____Temp - 346 F Press - 113 psig a 1 yr 1 yr ____

Ins-uratFedWire iuma - IUU76 Chem Spray -3UOU ppmCorporation iRadn - 2x1O8 rads boron, pH 8-11____ ___

WHG-1 (824965) It it so to.1.

WHH-1 (824965) 11 of 1, It a1 a1 Is 13

__WHE-1 (826112) 1________ 8LN 820013, Esse -, -- 1a1

WM 8243-) Power and international Z,WM 844-) Control 824443-1, The

Note* -PXMJ (IVA aknumber): fultlple-:cbndiitof- 'ae T fi tna core ot the spec I ied num0-re-df~ -f, f s in I e fo najc. cto6rs qn-T-ec nauctor wi-tnf lame-retardant, cross-linked polyethylene insulation, or f lame-retardant.' ethyl ene-propyl en rubber i nsul1at ion) coy ?red wi t Ia chi1oro-sulfonated -polyethylene 0a clorinatea-pol yethiyle-ne outer jacket.

OPEN OPEK ACCURACCUR

0

Table No.: 3611-SASheet No: WBN-EEB-1OI1A

TABLE 3.11.8A

TABLE. INPUT DATA SHIEET

WBNl CLASS 1E. EQUIPHENTElectrical Cables outside

Containment Subject to HELBPXMJ Cables

COTRC NO I9uL l. Ifl.ULNI ORiwiin UNIU JAIILJ ClRUIDM EPT DMVHI~n Awn C an*.. *.

0 RviR2 R3 0

PrepreriDate 2 6%9 4•e4•iReviewer/Date

N/T1- ýR353 HTN825342-2 47E235-1 Temp 3460. F Press 11 8s T Seq(TR 1 ,830cco, Control American 44_ 46 -lp, ~y3OOppm lA 1 yr-I i

iInsulated Wire thr9u 63 aon- 2lX'. rads boron, PH 8-11

(jUAL APTMETH1OD

CBL-13.0

(TR835584)WHE- 1 (TR832560)____________________

WHH-1 (TR834847) . .

WHJ-l (TR836007) *''. .

WHL-1 (TR830504) '.

WHM4-l (TR835573) "". . 9

WFB-1 (TR832405) """..

WGB-1 (TR833893) ". .

WGH-I (TR835713) "". . ,

RBN 828714 ,WGB-1 (TR833893) "AIW .

WGB-1 (TR835584) PBN 827928Okonite Co.

WF- (883)828633 Anaconda 9 ,9 9 ,WFB- (8863) ___________ Erickson__ __________________

WGD-i (828633)

WFB-l (TR833890) BLN820013 , , - - -.....

(TR83i5653) ESSEX Group ,~ .

WFB-1 (TR835279) ,, LN 824597 it'...'_________________Amer Insulated __ ___'. *I

Wire Corp.

WB-1.(TR829649) BLN 824279-1 ---------- -- - ------8264Brand-Rex Co._____________________________

11B1(R8 8 PBNg825342-2 *- - _ _____(TR833893) _______AW ____ __________________

[LOC COMPOlNENT

TRRIM971

Table No.: 3_____1-8A __

Sh~eet No: -WBN-EEB-1011B

LOC COI4PflNFNT

TABLE 3.11.8ATAB3LE INPUT DATA SHEET

WEN CLASS IF. EQUIMHENT

Electrical Cables Outside rpe/DContainment Subject to HELB R ~wrD

CONTRACT NO. ABNL OR PXMJ CablesriUrT~nw Wtr- L. MflleI an Arr uo ~ i~nurr*ng9.~.

R~~~m I 7 2 7 3m71

OPER OPER ACCUR ACCUR QIJAL RPT_________ *~.*~. 1Uv L"IIn LU"YIfU~h1c"E IV HIIII.11 uuMnLIrIE CAI K'RIIM UUIIJ REKTI~ DEMOi iETIIIU

WGB-1 (TR834521)1 Control YN 829Z Ame 47E235- emg ? 482 F Pres - 13 osig a1 1 yr I1 yr See EQSNI ______ Insulatea Wire 444 und - %~ Chem Spra 00p ______ EEB-CBL-1-1. 0

WHB-l(TR833352) Corp- thru 83 Radn -2xl00

rads, boron~ PH 8-11(TR834521) to"

828824 Amer-WGD-1(828824) "Tng,91nf-pd W1. rp '9

Corporation

WHC-2(TR828 9 35) I 4 Ng821l2-"2

Continental99 9999

WHE-2(TR830044) "' 99 99

WHJ-2(TR828935) i

IrWHC-2(TR835584) ifHTN824853______________Brand-Rex Co. ___

FE F F L TiV E_ ___________

_____~J A UAE I

0

I Rpulatnea 0

WBN-EEB-Sheet No: 1012

LOC COMPONENTCONTRACT NO

TABILE ~~TfARI 4A7%XAEET

WBNP CLASS 1E EQUIPMENT

ELECTRICAL CABLES OUTSIDE PrenOTIMN UJC OHL

CONTINMET SBJEC TO ELBRev iABUL OR MS CABLES

Nn arn r4JID rmwIIDnPmkqmy TALUUAla rn

[Revision 0 R1 R2 % R~LII4

ewe r/DlateOPER OPER ACCUR ACCUR QUAL RPT

NX WVA (827380) Sina 827380 q4,qL, Temp -385 F Press - 66 osig a1 yr 1 yr ECK1.Vn-aco-n a- 93 l Humd - IUU% Chem Spray -620OT-iii --

I V 8730 t Radn - 2x108 rads boron, pH 8-11 -I

___________Wire & Cable ____

WVA (5259 8529, BldenTemp - 346uI1 Press - 113 psig I tt f- - VR L~59) ____________8525, Beden ______ lumd - 100%m Chem Spray - 3000 ppm ________ ________

Corporati-on Radn - 2x10' r ads

WVC (85259) ~ F 1

W EU (85259) "t'*o "

WV!: (85259) - -5 r -n---

WVA (8/ZJZ) 8/LUZ, Anacond T~~emp - 385' F 66b-u p~.Lg "5 1

_________(Continental) Humd - 100% ~ Chem Spray - 6200 ppmitaun - 2L.IU raub Dnorn, pml 8

.6

-tO.3

___ ____________

WVB (87232) ,II II I

WVC (87232) it i It to 1

jWVK (87232) to , to if

WVC (824447) Signal 824447, Anaconda It D L: 1y 1y __

Wire and Lable- II LWVB (824447) _______1

WVO (824447) II 1I55 55I

0

WBN-EEB-Sheet No.. 1013

TARI.E TM&t~ TIA10AEET

WBNP CLASS 1E EQUIPMENT

ELECTRICAL CABLES OUTSIDECONTAINMENT SUBJECT TO HELB

0

_-___Revision 0 Rt R3I

1'reoarer/Dat. e .41A'1 #12f IN P1 gj

Reviewer/Date VC/CONTRACT NO. ABUL OR Ms CABLES

PIInrTTnPm Mcn 0- Unn~ r~r, UVLI~ urLr~ MlA.UrM IALLUK LqUiL Kir* ~ 99 UCfL flU. MULF C[4YI Lf4VIlUNMNJTi1 TO WHICH~ QUARLIFIED CAT REQMT DEMO *REQMT DEMO METHOD

q7 E-Z ---- See E S.Nk WVK -(824447') it "q 141 it11i t EEB -C LS-16.0WVA+Y. (85581w&A Temp - 445~'F Press - 32 psig

WV 8S5,825852. 825874. 1!-um - l00%t Chem Spray - 3000 ppm "'825874) Samuel Moore Radn _- 21!10 - Boron, pH 9.0-11.0

WVB (825852) 825852, Samuel to o IsII-moore & Company ____________________

WVA (821722') "821722. Samuel It It t IstMoore & Company

WYC (821722) '821722, Samuel It i it it 'I

Moore & Company ____________________

-- WVC (823577) It 823577. The Temp - 346 0 F Press - 113 psigHumd - 100%m " Chem Spray - 3000 ppm""

WV 257Rockbe~tos Co. Radn - 2xl10 0I Boron, pH 9.0-11.0

W4VA (823257) 8235,Te"IWVAt82 5R82265kbeso Co. ____

Roc-betosCo.Temp - 300 0F Press - 25 psigWV 5Q94Z) 85947. Times Wir? " Humd 102Z~ Chem Spray - Boric "

and Cable Radn 2;1;8 Acid in water,pH 8.5

WVL (8258T74) "825874, Samuel Temp -445 0I k. Press - 32 pS1rg - , itMoore & Co. ____Humd -100% Chem Spray - 3000 ppm ____ ___

-- WVA (826598') "BLN 826598 Eaton 1 Radn -2x10 I Boron, pH1 9.0-11.0 t 1E F FE CTIVEWVA(TR833327) 'HTN825651 Eaton " "" "

WVC-1(TR835348) 'HN280Samuel t,4-____________HTN824860____

Moore-

Nt MS (TVA MakNumber): Multi-conductor insulated signal cable (not paired) with shield and ceall1 jac .et; fi ~irt at,rrnqS-linkpd P2ytyln.. ltn or ~j flam mtran ethylene-propyl~ne rubber insUaltioneclrs poyt lenor chlorinated-polyethylene jacket.

CO~4P0NFNT

0

Table No.: 3-11-8ASheet No: WBN-EEB-1013A

TABLE 3.11.8A

TAI3LF. INPUT DATA SHEET

WEN CLASS I1. EQUIPMENTElectrical Cables OutisdeContainment Subject to HELB

MS Cables-

0

Preparer/Date h->e," 19 'Ya ~PRevieiier/IOate.

LOC COMPONENTCONTRACT NO. ABNL OR

vflEnnUflMFT Tn utiorea ftaltrimn £ATOPER OPER

(T830)PN202 47E235- Temp 440Q0 F Pressl113 psi9 a 1 yr 1 yr See EQSNI WVA(TR83 5 8 4 ) Signal Rrnnd-1Rpx 444 RýA 9W1fl r q~ pý 6200t)= ____EB-CBL-16. 1thru 83 PH 8.5-10.0

14VC(TR835573) Signal

1,VE(TR835573)

WVA (TR835304) PBN 825419 Temp 3460 F Press 113 psi9(19835406) -1ralad-Rpy Radn 2x10 8 -Spray

310

00pnm--

PH 10-10.5

WVE(TR835111) ________ ____

________EFFECTJ-E-

_ _ _ _ _ _ _ _ _ _ _ _ _ _D .A T E_ _

FUNTIO [jG & -4DE -O -C NV

ACCUR ACCUR QUAL RPT

0

0

WBN-EEB-Shieet No: 1014

COAPONFr4T Ft INt'T TAM

0

TABLE 3.11-8ATABLE INPUT DATA SHEETR4

-WBNP CLASS IF EQUIPMENT -son0R1 R2 R3 RELECTRICAL CABLES OUTSIDE vr rrIae.

CONTAINMENT SUBJECT TO HELB Re .viewer/DateO~.i

CONTRACT NOýPEQW fffE/ETFE AND ETFE/PVC CABLES 'R' "'AC CCR QLRTVS" "IJ~LU. MUU rjivi tYLtKur1MENT TO WHICH QUALIFIED CAT REQMT DEMO ftEQMT DEMO METHOD

t4Ak WWK( 8 2 52 80 ) ~Signal 825280,Teeye7r Imp 45F PesSe Q________________,4i _______ eeye Tm 5 rs -32 nsig a1 yr 1 yrSeEQTTMV~~o~~ 111 C Irm C S55 Rner npra -u P F - -- ____EEB-CBL-17, 0T______ lRamdn- 2x108 rads boron, p)H'1- 9.5

WWK (826505)' 826505, Carolina "I t I

VO-(85838) 85838, A11dr~uriddi' ~ ~Wire and Cable

-Note. Sp ei a!5iil Cabl-,. f~ FEI'FE and Er, v-f* k 1U.bý,t WWK).- z~ . 3,252890 .a.,c &2675) - Mutpl;l-C M trs insulation,,.x-~ia j~d~t -miteri9 -a indovrrupeaLk-

ETFE fluor polymer.

Contract 8i838 - Multiple conductor signal cables, nsulation and coaxial jacket material ?xtruded ETFE flioropolyner, ove all jacket

C O P N N r. y ¶ - +" + o -. a ._ _ _ _ _ _ _ _ _ _

0

WBN-EEB-Shevt No: 1015

LOC C0~1PflNFNTCONTRACT NO.

FU~trTynN Wrf L mflDFi tin

TABLE 3.11-8AITABLE INPUT DATA SHEET

WBNP CLASS 1E EQUIPMENT -

ELECTRICAL-CABLES OUTSIDE _________ atCONTAINMENT SUBJECT TO HELB PRe vewr/DtLent -;

ABNL OR TRIAXIAL CABLE 01)ERarn FMiwo ruttionfitmrwr Trn tuirru "fiM VrTrfl CATD K4AT

Fiiflfl Dinn~4 0 1IR 3 R

OPERflImA

ACCUR ACCUR QUAL RPT1117 T ncun ucTu~n

I RI I R2 I R3 I R4l

NN T 814) Sga 821043 Raychem ±4Y ITm - 3570F Press > >70 psig 1 yr 1 y See EQ1WTK(TR835201) 11 83 nii 3% C~n~ru 00~i E-B-8

Radn - 2X108 rads boron, pH 9.5-11.0 it I I

WTU(TR830292) SQN84595 00% Chem Spa See.-&" EEBCL-S

WT(329 *832289 . Temp -385q F Press 113 psig See EQSBrand-Rex -Rldn - 9,,1A

8 ra'id/Sorv2onnm a 1 yr- 1 yr _______EEB-CBL-18.2

E F

Nut: TV !GAiUl .ýBbie (+VA-tMe.kNo. WTU). +.; + t±a to RG-l1/u witoi cross-linked polyetly ene for primary insulation and nner and outer

-O COMPONENTs __________________________ _ _ _ __ _ _ ___

Jar-ketsL

0

WBN-EEB-Sheet- No: 1016

TABLE T i I1AkASEFT

WBNP CLASS 1E EQUIPMENTELECTRICAL CABLES OUTSIDE

CONTAINMENT SUBJECT TO HELB

I -Revistion 0 R1 R...........J.L2 R3 R4

Preparer/flate xj / -/-T

Rev iewer/~a tew~j -/-

LOC COA'PONFNTCONTRACT NO. .ABNL OR COAXIAL CABLE . fPER OPER

FUNCTION MFG &. MODEL NOV ACD ENVR rNvWANPJNT Tn UWJ('1 fl~ai TFTyf rT DrnMT flrmfACCUR ACCIJRDcnmTr nFmfl

47EZ35- Sr y ee EQSMAI WTK (826045), Signal 826045, 828797 444q& Temp -340bF Press - 104 psig 1 r y EB-CBL-19828797) Rockbestos Co. H"8 UMd - 100 Chir Spray -T 0 jOpm -? Zee EQS

____________ ______Radn -2xj08 RadsD (f I9.-l. EEB-CBL-19

tAWTK (826080) Sga 826080 Raychem Temp- 3570F Press -. pp 70 ________

liuma - UUX Chlem 70ra -sl 3000_ ___________

______________ Radn -2x108 rads boron, pH 9.5-11.0 _ _ ______ _______

Note: Coax Cable, RG59B/U (TVA lark Number WTK): Flame-ratardant, cross-linked polyethylene insi1 tion, Aith flane-retar ant, crcss-linkedpolyetnyleie jaMET-.

rQUAL RPT

TABLE 3.11-9EF CTVSWEET NO: WBN-NEB-1 D AT E

OCT 13,84

TABLE INPUT DATA SHEETSWP CLASS 1E EQUIPMENT

OUTSIDE CONTAINMENTSUBJECT TO LOCA

INSIDE CONTAINMENT

Revision 0 Ri R2 R3 R4

PBN RKlE WAPreparer/Date R. Darwin 10-19-81 RO 6-10-83 4/19/84 jl1/5s4

RKWE AWL 1Reviewer/Date F. A. Plesic 12-15-81 RO 6-11-83 5/5/84 gkýjw'I

LOC COMPONENT1 l-FCV-63-72

*1 2-FCV-63-72

I I-FCV-63-73

*1 2-FCV-63-73

1 l-FCV-72-44

*1 2-FCV-72-44

1 l-FCV-72-45

*1 2-FCV-72--45

FUNCTIONCntmt Bump toRER Pump A-ACmtmt Bump toRHR Pump A-ACntmt Sump toRRR Pump 3-BCnmtt Bump toRHR Pump 3-BCntmt Sump toHDR Flow Cnt VlaCmtmt Bump toHDR Flow Cnt VliCnmnt Sump toHDR Flow Cnt Vl'Cntnt Sump to

CONTRACT NO. ABNL ORMFG & MODEL NO. ACD ENVR71C62-54114-1 77Reliance Lim S3-371C62-54114-1 77Reliance jim SB-371C62-54114-1 77Reliance Lim SB-371C62-54114-1 77Reliance Lim S3-371C62-54114-1 22

v Reliance jim 93-071C62-54114-1 22

v Reliance jim SB-O71062-54114-1 22

v Reliance Lim SB-071C62-54114-1 22

ENVIRONMENT TO WHICH QUALIFI&D CAT3OO0'F97O paig, 1001 rh92.04x10 reds A

30O'uF,70 paig,1001 rh,2.04x10 rads A

a B300"F,70 psig, 1001 rh,2.04xlO rads A

0 8 B300 F,70 paig,100% rh,2.04x10 reds A

250ý'F,25 psig, 1001 rh,2x10 reds A

250 F,25 psig,100% rh,2x10 reds A

7 B250uF,25 psig, 1001 rh,2x10 reds A

B

OPER OPER ACCURREQMT DEMO REOMT1 wk 1lwk N/A

1O0dys 100dys1lwk 1lwk N/A100dys 100dysIlwk 1Iwk N/A100dys 10 dys1lwk Ilwk N/A3O0dys 30 dye1 wk 1lwk N/A

30dys 30 dys1lwk Ilwk N/A

30dys 30 dye

ACCURDENDN/A

N/A

N/A

N/A

N/A

N/A

N/A

N/A

QUAL RPTMETHOD

Lim Rpt B0058App C 600456Lim Rpt B0058App C 600456Lim Rpt B0058App C 600456Lim Rpt B0058App C 600456Lim Rpt B0058App D 30003Lim Rpt B0058App D 30003Lim Rpt 30058App D B0003Lim Rpt 30058Ann D B0003

*Not Field Verified

E43 160 .03

HDR Flow Cnt Vlv Reliance Lim SB-O