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EIHIBIT F
PRAIRIE ISLAND NUCLEAR GENERATING PLANT.
License Amendment Request Dated January 13, 19862
DEMONSTRATION OF THE (DNFORMANG'
OF
PRAIRIE ISLAND UNITS
10
APPENDIX K AND 10CFR50.46
FOR
SMALL BREAK LOCAs'
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W2stingnouse Electric Corporation.
Nuclear Technology Division
Nuclear Safety Department .
Safeguards Engineering and Development
October 1985
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This doceent reports the results of an analysis that was performed todemonstrate tnat Prairie Island, Units I and II, meet the requirements of
Appendix K and 10CFR50.46 for small break LOCA. The analysis incorporatesanticipated plant harmare modifications, i.e. , the new upper reactor internals
package and the tnimble plus removal, as well as increased levels of Fg and
steam generator tube plugging.
II. Methed of Analysis
The analysis was perfccmed using the ]d NOTRUMP and LOCTA computer codes for a
spectra of small break sizes. These codes are incorprated in the approvedWestingnouse ECCS Small Break Evaluation Model ceveloped to cetermine the RCS
response to cesign basis small break LOCAs and to address the NRC concernsexpressec in NUREG-0611, " Generic Evaluation of Feewater Transients and Small
Break Loss-of-Coolant Accidents in Westinghouse-Designed Operating Plants."
The NCIRUMP coc:puter code is a one-dimensional general network code consisting
of a rA2::ber of SCVanced features, including the Calculation of thermalnon-equilibrim in all fluid volmes, flow regime-depencent crif t fluxcalculations with counter-current flooding limitations, mixture lev'el trackinglo61c in multiple-stacked fluid noces, and regime-cepenoent heat transfer
i correlations. NOTRUMP includes the representation of the reactor core asheated control volmes with an associated bubble rise model to permit atransient mixture height calculation. The multinoce capability of the programenables an explicit and cetailed spatial representation of various systemcocpanents. In particular, it enables a proper calculation of the benavior oftne loop seal curing a loss-of-coolant transient.
Claccing ther=al analyses are performed with tne LOCTA-IV (Reference 3) code
whien uses the RC pressure, fuel rod power history, steam flow past themcovered part of the core, and mixture height history from the N07 RUMPhycraulic calculations, as input.
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Table 1 lists important input parameters and initial conditions med in theNOTRUMP analysis. The core power decay and axial power distribution are snownin Figures 1 and 2. For tnese analyns, the SI delivery considers pmp
injection flow which is depicted in Figure 3 as a ftnetion of RCS pressure.This figure represents injection flow from the SI pmps based on performancecurves degraced 5 percent from the design head. The Safety Injection (SI)system was assmed to be delivering to the RCS 25 seconds after the generationof a safety injection signal. The 25-second oelay includes time required for
diesel startup and Icecing of the safety injection pumps onto the emergencybuses. Minimm safeguarcs Emergency Core Cooling Systerr. capability andoperability has, also, been assmed in this analysis.
The nycraulic ana.'.yses are performed with the NOTRUMP code using 102 percent ofthe licensec NSSS core pwer. The core thermal transient analyses areperformed with the LOCTA-IV coce using 102 percent of licensed NSSS core pwer.
Three break size transients were evaluated, 3 inch, 4 inch, and 6 inch. Thesetransients were considered to be terminated when the follming criteria weremet:
1. RCS system pressure had decreased below the accumulator set pint andacetz:ulator flow hac been initiated.
2. The core had been recovered and the core / upper plentra mixture level
was at or above the bottom of the vessel outlet nozzles.
3. The net flow to the RCS was psitive with accumulator and SI fimexceeding the break f1w.
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III. Reste ts and cnne1 usi ons
Of the tnree break sizes evaluated, core mcovery occurred only for the 4-inchbreak case, Figures 5, 7, and 10. Accumulator injection terminates the 3-inchbreak transient; producing a positive slope en the core mixture level curve. Asimilar result occurs for the 6-inch break. The 4-inch break shows two briefperiods of ccre mcovery prior to accumulator 1rdection. During the secondperiod of mcovery a PCT of 1000 F occurs, Figure 8. This value is well belowall Acceptance Criteria limits of 10CFR50.46 and is non-limiting in comparisonto large break analysis results.
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REFERENCES
i 1. Lee, H. , Rupprecht, S. D. , Tauche, W. D. , Schwar , W. R. , " WestinghouseSmall Break ECCS Evaluation Model Using the NOTRUMP Code," WCAP-100% P-1,August 1985.
| 2. Meyer, P. E., "NOTRUMP, A Nodal Transient Small Break and General NetworkCode," WCAP-10074-P-1, August 1985.
3Bordelon, F. M.,8101 (Proprietary), and WCAP-8306 (Non-Proprietary), June
et al. , "LOCIA-IV Program: Loss-of-Coolant TransientAralysis," WCAF-1974.
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TABLE 1
INPJT PAR AMETrR9 flSFB IN THE SMAf f BRCAV ANif YRFR
Parameter 4m11 Brente
Peak Linear Power (kw/ft) 15.03(incluces 1025 factor)
Total Peaking Factor, F 2.50g
Power Shape See Figure 2
Fuel Assembly Array 14x14 0FA
Nominal Cold Les Accynulator 1266Water Volme (ft"/accmulator)
Nominal Colc Leg Aeg/ accumulator)mulator 2000
Tank Volune (ft
! Minimun Colc Leg Accumulator 715Gas Pressure (psia)
Pucped Safety ledection Flow See Figure 3
Steam Generator Initial Pressure (psia) 733.0
Steam Generator Tuoe Plugging Level % 10
Fuel Assemcly Thictle Flugs Removed
Reactor Upper Internals Package New Design
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TABLE 2
SM1? f RRFAY LOCA TIME MFOfffMCF OF EVFRE '
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3 in. Break 4 in. Break 6 in. Break(sec) (sec) (sec)
Start 0.0 0.0 0.0
Reactor Trip 4.5 2.8 17
Top of Core Uncovered WA 183 7 WA
Cold Leg Accumulator Injection 703.0 371.5 162.6
Peax Cad Temperature Occurs WA 297 8 WA
Tcp of Core Covered WA 325.8 WA
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TABLE 3
SMALL BREAK LOCA RESULEFUEL C_ADDIE DATA
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.3 in. Break 4 in. Break 6 in. Break
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Results
Peak Cad Temperature ( F) WA 1000 W/.
Peak Cad Location (ft) WA 12.00 WAt
Local Zr/P 0 Resction (max), (5) WA 0.066 WA2
Local Zr/P 0 Reaction Location (ft) WA 12.00 WA2
Total Zr/H O Reaction (%) <.3 <.3 <.32
; Hot Roc Burst Time (sec) WA WA WA
Hot Rod Burst Location (ft) WA WA WA
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: Figure 1. Core Power After Reactor Trip
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Figure 2. Small Break Power Distribution Assumed for Loca AnalysisJ
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Figure 3. Safety injection Flowrate Versus Pressure
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Figure 5. 3-inch Cold Leg Break Core Mixture Level Versus Time
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Figure 9. 6 Inch Cold Leg Broek RCS Pressure Versus Time
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Figure 10. 6 inch Cold Leg Breen Core Mixture Level Versus Timei
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