teste publicação

Preface

Product Overview 1

Commissioning and Diagnostics 2

General Technical Specifications 3

Digital Input Module 4

Digital Output Module 5

Diagnostic Data 6

Dimensioned Drawing 7

Glossary

Index

SIMATIC

Signal Modules for ProcessAutomation

Reference Manual

This manual is part of the documentationpackage with the order number:ET 200M Distributed I/O Device6ES7 153-1AA00-8BA0

Edition 05/2001A5E00085262-02

Copyright © Siemens AG 2001 All rights reserved

The reproduction, transmission or use of this document or itscontents is not permitted without express written authority.Offenders will be liable for damages. All rights, including rightscreated by patent grant or registration of a utility model or design,are reserved.

Siemens AGBereich Automatisierungs- und AntriebstechnikGeschaeftsgebiet Industrie-AutomatisierungssystemePostfach 4848, D- 90327 Nuernberg

Disclaimer of Liability

We have checked the contents of this manual for agreement withthe hardware and software described. Since deviations cannot beprecluded entirely, we cannot guarantee full agreement. However,the data in this manual are reviewed regularly and any necessarycorrections included in subsequent editions. Suggestions forimprovement are welcomed.

©Siemens AG 2001Technical data subject to change.

Siemens Aktiengesellschaft A5E00085262-02

Safety Guidelines

This manual contains notices intended to ensure personal safety, as well as to protect the products and

connected equipment against damage. These notices are highlighted by the symbols shown below and

graded according to severity by the following texts:

!Dangerindicates that death, severe personal injury or substantial property damage will result if properprecautions are not taken.

! Warningindicates that death, severe personal injury or substantial property damage can result if properprecautions are not taken.

! Cautionindicates that minor personal injury can result if proper precautions are not taken.

Notedraws your attention to particularly important information on the product, handling the product, or to aparticular part of the documentation.

Qualified Personnel

Only qualified personnel should be allowed to install and work on this equipment. Qualified persons are

defined as persons who are authorized to commission, to ground and to tag circuits, equipment, and

systems in accordance with established safety practices and standards.

Correct Usage

Note the following:

! WarningThis device and its components may only be used for the applications described in the catalog or the

technical description, and only in connection with devices or components from other manufacturers

which have been approved or recommended by Siemens.

This product can only function correctly and safely if it is transported, stored, set up, and installedcorrectly, and operated and maintained as recommended.

Trademarks

SIMATIC®, SIMATIC HMI® and SIMATIC NET® are registered trademarks of SIEMENS AG.

Third parties using for their own purposes any other names in this document which refer to trademarks might

infringe upon the rights of the trademark owners.

Signal Modules for Process AutomationA5E00085262-02 iii

Preface

Purpose of the Manual

This manual helps you to use the signal modules for process automation. You willfind all the information you require on using the modules in the PCS 7 system.

Contents of the Manual

This manual is aimed at those who want to install and use the modules describedin an ET 200M and in the PCS 7 process control system.

Delivery PackageThis manual is part of the delivery package with the order number6ES7 153-1AA00-8BA0 The delivery consists of the following manuals, which havethe following contents:

Manual

ET 200M Distributed I/OSystem

Reference Manual

S7-300, M7-300Programmable Controllers,Module Specifications

Reference Manual

ET 200M Distributed I/ODevice,Signal Modules for ProcessAutomation

Mechanical configuration General technicalspecifications

Overview of usage in processautomation

Installation and wiring Power supply modules Parameter assignment withSIMATIC PDM

IM 153-x slave interfacemodule

Digital modules Digital input module

Analog modules Digital output module

RS 485 repeater

SIMATIC TOP connect

Electronic Manual

You will, of course, also find the manual in the SIMATIC Manual Collection (ordernumber 6ES7 998-8XC01-8YE0).

Preface

Signal Modules for Process Automationiv A5E00085262-02

Aids to Finding Information

To help you find specific information quickly, the manual contains the followingaids:

• A comprehensive list of contents followed by lists of all figures and tableswhich appear in the manual.

• A heading indicating the contents of each section is provided in the left-handcolumn on each page of each chapter.

• Following the rest of the chapters, you will find a glossary in which importanttechnical terms used in the manual are defined.

• At the end of the manual you will find a detailed index, which makes it easy foryou to find the information you are looking for.

Attributes for Technical Specifications

Some values in the technical specifications are specified with attributes.

These attributes of the values of the technical specifications have the followingmeanings:

Attribute Meaning

Minimum/maximum

A minimum/maximum value represents the limit or operatingvalue guaranteed by SIEMENS. This value must not beviolated during operation within other limits.

Typically The typical value applies under nominal conditions and at anambient temperature of 25 °C. The typical value can beviolated on account of component tolerances.

Approx. The "approx." value is a value that has been rounded up ordown (the weight of a module, for example).

Without attribute Values without an attribute are rated values, not values subjectto tolerance.

Feedback on the DocumentationIn order to be able to offer you and future users the best possible documentation,we would like to ask you to give us some help here. If you have any commentsabout this manual, please fill in the form at the end of the manual and return it tothe address specified there. Please also give your own assessment of the manualthere.

Preface

Signal Modules for Process AutomationA5E00085262-02 v

SIMATIC Training CenterWe offer a range of courses to help get you started with the SIMATIC S7programmable controller. Please contact your local training center or the centraltraining center in Nuremberg, D-90327 Germany.Phone: +49 (911) 895-3200.

Customer Support, Technical SupportAt your service all over the world at any time of the day:

JohnsonCity

Nuremberg

Singapore

SIMATICHotline

Worldwide (Nuremberg)Technical Support

Worldwide (Nuremberg)Technical Support

(FreeContact)

Local time: Mon-Fri 7:00 to 17:00

Phone: +49 (180) 5050 222

Fax: +49 (180) 5050 223

E-mail: [email protected]

GMT: +1:00

(charged service, only possible withSIMATIC Card)Local time: Mon-Fri 0:00 to 24:00

Phone: +49 (911) 895-7777

Fax: +49 (911) 895-7001GMT: +01:00

Europe / Africa (Nuremberg)Authorization

America (Johnson City)Technical Support andAuthorization

Asia / Australia (Singapore)

Technical Support andAuthorization


Phone: +49 (911) 895-7200

Fax: +49 (911) 895-7201


GMT: +1:00


Phone: +1 423 461-2522

Fax: +1 423 461-2289


GMT: -5:00


Phone: +65 740-7000

Fax: +65 740-7001


GMT: +8:00

The languages of the SIMATIC hotlines are generally German and English: on the authorization hotline, French, Italianand Spanish are also spoken.

Preface

Signal Modules for Process Automationvi A5E00085262-02

SIMATIC Customer Support Online ServicesSIMATIC Customer Support offers you a comprehensive range of additionalinformation on the SIMATIC products by means of its online services:

• You can obtain general, up-to-date information:

- On the Internet at http://www.ad.siemens.de/simatic

• Current production information documents and downloads that can be usefulwhen using our products:

- On the Internet at http://www.ad.siemens.de/simatic-cs

- Via the bulletin board system (BBS) in Nuremberg (SIMATIC CustomerSupport Mailbox) on +49 (911) 895-7100.

To access the mailbox, use a modem with up to V.34 (28.8kbps), and set theparameters as follows: 8, N, 1, ANSI. Alternatively, access it using ISDN (x.75,64 kbps).

• You will find a local contact for Automation & in our contact database:

- On the Internet at http://www3.ad.siemens.de/partner/search.asp

http://www.ad.siemens.de/simatic

http://www.ad.siemens.de/simatic-cs

http://www3.ad.siemens.de/partner/search.asp

&RQWHQWV

Signal Modules for Process AutomationA5E00085262-02 vii

&RQWHQWV

3URGXFW2YHUYLHZ

&RPPLVVLRQLQJDQG'LDJQRVWLFV

2.1 Basis on Which Configuration Takes Place ......................................................2-12.2 Configuration .....................................................................................................2-42.3 Parameter Assignment......................................................................................2-62.4 Changing the Parameter Assignment of the Process Control Modules

During Operation ...............................................................................................2-72.5 Diagnostics by Means of the Process Input Image...........................................2-8

*HQHUDO7HFKQLFDO6SHFLILFDWLRQV

'LJLWDO,QSXW0RGXOH

4.1 SM 321; DI 16xNAMUR (6ES7 321-7TH00-0AB0) ...........................................4-14.2 Parameters of the Digital Input Module.............................................................4-64.3 Parameter Descriptions.....................................................................................4-84.3.1 Flutter monitoring...............................................................................................4-84.3.2 Pulse lengthening............................................................................................4-104.3.3 Identification Data............................................................................................4-114.4 Sensor .............................................................................................................4-124.4.1 Connection Rules for Sensors.........................................................................4-124.4.2 Diagnosis Dependent on Sensor.....................................................................4-174.4.3 Terminal Assignment Diagrams ......................................................................4-184.5 Diagnostics of the Digital Input Module...........................................................4-224.5.1 DP Diagnostics/Module Diagnostics ...............................................................4-224.5.2 Diagnosis with a Sensor of the Changeover Contact Type ............................4-24

'LJLWDO2XWSXW0RGXOH

5.1 SM 322; DO 16xDC24V/0,5A (6ES7 322-8BH00-0AB0) ..................................5-15.2 Parameters of the Digital Output Module ..........................................................5-55.3 Diagnostics of the Digital Output Module ..........................................................5-7

'LDJQRVWLF'DWD

'LPHQVLRQHG'UDZLQJ

*ORVVDU\

,QGH[

&RQWHQWV

Signal Modules for Process Automationviii A5E00085262-02

)LJXUHV

1-1 Integration in the Process Control System........................................................1-32-1 Basis on Which Configuration Takes Place ......................................................2-12-2 Digital Input and Value Status Assignment .......................................................2-94-1 Module View and Block Diagram of the SM 321; DI 16 x NAMUR ...................4-24-2 Principle Behind Flutter Monitoring ...................................................................4-94-3 Principle Behind Pulse Lengthening................................................................4-104-4 Connections and Characteristic Quantities of a BERO...................................4-134-5 Connection Example for NAMUR Sensor .......................................................4-184-6 Connection Example for NAMUR Sensor as Changeover Contact ................4-194-7 Connection Example for 10 kΩ/47 kΩ One-Way Contact ...............................4-204-8 Connection Example for 10 kΩ/47 kΩ Changeover Contact...........................4-204-9 Connection Example for One-Way Contact Unconnected..............................4-214-10 Connection Example for Changeover Contact Unconnected .........................4-215-1 Module View and Block Diagram of the SM 322; DO 16xDC24V/0,5A ............5-26-1 Diagnostic Data Record 0 (Bytes 0 to 3)...........................................................6-26-2 Diagnostic Data Record 1 (as of Byte 4) of the Digital Input Module................6-36-3 Diagnostic Data Record 1 (as of Byte 4) of the Digital Output Module .............6-47-1 Dimensioned Drawing of the Signal Modules ...................................................7-1

7DEOHV

4-1 Parameters of the Digital Input Module........................................................4-64-2 Identification Data of the Digital Input Module .............................................4-74-3 Identification Data.......................................................................................4-114-4 Peformance Factors for BEROs and Sensors ...........................................4-144-5 Rules on the Sensor Load..........................................................................4-154-6 Sensor Load Example ................................................................................4-164-7 Diagnosis Dependent on Sensor ...............................................................4-174-8 Diagnostic Message of the Digital Input Module, Causes of Errors and

What to Do .................................................................................................4-225-1 Parameters of the Digital Output Module .....................................................5-55-2 Identification Data of the Digital Output Module...........................................5-65-3 Diagnostic Messages of the Digital Output Module, Causes of Errors

and What to Do ............................................................................................5-7

Signal Modules for Process AutomationA5E00085262-02 1-1

Product Overview 1Introduction

Signal modules for process automation are part of the S7-300 I/O module range,which offers functions in addition to those of “standard“ I/O modules:

• Process-related functions

– Pulse lengthening

– Flutter monitoring

• Enhanced diagnostics

• Provision of identification data

You can make full use of these additional functions in an ET 200M, which is usedin the PCS 7 process control system.

It is not possible to use the modules described in this manual in an S7-300(centralized configuration).

Declaration

The “signal modules for process automation“ are referred to below as “processcontrol modules“.

Product Overview

Signal Modules for Process Automation1-2 A5E00085262-02

Hardware Requirements

You will require the IM 153-2 as of the following version as a DP slave interface:

• IM 153-2 as of 6ES7 153-2AA02-0XB0, Version 07

• IM 153-2 FO as of 6ES7 153-2AB01-0XB0, Version 06

Software Requirements

You will require the following to configure and parameterize the process controlmodules:

• STEP 7 as of V 5.1 SP1 and SIMATIC PDM as of V 5.1

• PCS 7 as of V 5.1 and SIMATIC PDM as of V 5.1

• COM PROFIBUS as of V 3.0 and SIMATIC PDM as of V 5.1

• For use in non-Siemens systems: configuration software for the DP master andSIMATIC PDM as of V 5.1

Product Overview


Integration in Process Control System

PCS 7 is a powerful process control system. With PCS 7 and the process controlmodules, the ET 200M has a direction connection to the process control system.This is also evident from the following:

• Parameterization of the process control modules with SIMATIC PDM (add-onpackage for STEP 7)

• The evaluation and continued processing of the input/output signals is executedusing PCS 7 driver blocks in the DP master CPU.

Configuration withSTEP7

Parameter assignmentwith SIMATIC PDM

Operation and monitoringwith WinCC

Industrial Ethernet

S7-400

PROFIBUS DP

PCS7 ES

PCS7 OS

PCS 7 components

Upper level

Lowest level:actuators, sensors,

field devices

ET 200M

Process control modules

PC

PC

Figure 1-1 Integration in the Process Control System

Reference

You can find more detailed information on the PCS 7 process control system in thePCS 7documentation.


Commissioning and Diagnostics 22.1 Basis on Which Configuration Takes Place

Operating principle of configuration

Parameter assignmentwith SIMATIC PDM

Configuration with STEP 7

Operation and monitoringwith WinCC

Industrial Ethernet

PROFIBUS DP

PC

PCS7 OS

S7-400

Parameters (for net-work configuration,for example)

System visualization

CPU

(1) (2)

Cyclic data exchange:User data of theinputs/outputs andvalue status

!

(1) Acyclic data exchange:Parameters of theprocess control modulesInformation data of theprocess control modules

!

!

(3)

CFC

PCS7 driver

(3)

ET 200M

Process control modules

Acyclic data exchange:Configuration and busparameters for networkconfiguration (for example)Diagnostic interrupts(only with S7, DPV1)

!

!

(2)

Figure 2-1 Basis on Which Configuration Takes Place

Commissioning and Diagnostics


Configuration

This step involves configuring and parameterizing the ET 200M using theprogramming device.

Configuration

You configure the ET 200M with STEP 7 / COM PROFIBUS or with appropriateconfiguration software. At configuration, you only set the basic features of the DPslave (the network parameters, for example).

Parameter Assignment

At parameterization, you set the parameters of the ET 200M and the insertedmodules:

• You parameterize the ET 200M and “standard“ I/O modules with STEP 7.

• You parameterize the process control modules with SIMATIC PDM.

Cyclic Data Transfer Via PROFIBUS DP

Cyclic data transfer takes place between the CPU (S7-400, for example) and theET 200M. The following data is transferred:

• The cyclic user data of the inputs and outputs, including the input value status

• The diagnostic interrupts

This data is prepared in the CPU by the PCS 7 driver and the CFC (ContinuousFunction Chart) for system visualization. This data is then presented on the OS bymeans of WINCC.

The parameters (for network configuration, for example) are also transferredcyclically.

Acyclic Data Transfer Via PROFIBUS DP

Acyclic data transfer takes place between the process control modules of the ET200M and the programming device/PC (SIMATIC PDM). The process controlmodules of the ET 200M are parameterized by means of this acyclic data transfer.Information data is also transferred and displayed in SIMATIC PDM .

• Diagnoses and interrupts

• Data sets (only with S7)



Software Requirements

Configuration SoftwareUsed

Version Notes

STEP 7 and SIMATIC PDM(SIMATIC PDM isembedded in STEP 7HWCONFIG and availableas an add-on package.)

or

PCS 7 (contains amongstothers STEP 7)

STEP 7 as ofVersion 5.1 SP1 SIMATIC PDMas of Version 5.1

PCS 7 as ofVersion 5.1

• Configuration with STEP 7. TheET 200M (IM 153-2* and all themodules that can be used) iscontained in the hardware catalog.

• The SIMATIC PDM is automaticallystarted in HWCONFIG forparameterization.

STEP 7 and SIMATIC PDM(SIMATIC PDM isautonomous and availableas a stand-alone version)

STEP 7 as ofVersion 5.1 SP1 SIMATIC PDMas of Version 5.1

• You require the DDB file for theET 200M (IM 153-2*), and you carryout configuration with STEP 7.

• Parameter assignment withSIMATIC PDM

COM PROFIBUS withSIMATIC PDM (SIMATICPDM is autonomous andavailable as a stand-aloneversion)

COMPROFIBUS asof Version 3.0 SIMATIC PDMas of Version 5.1

• You require the DDB file for theET 200M (IM 153-2*), and you carryout configuration with COMPROFIBUS.


Other configuration softwareand SIMATIC PDM(SIMATIC PDM isautonomous and availableas a stand-alone version)

Configurationsoftware (seemanufacturer) SIMATIC PDMas of Version 5.1

• You require the DDB file, and youcarry out configuration withappropriate configuration software.


* IM 153-2 ab 6ES7 153-2AA02; E07 and IM 153-2 FO as of 6ES7 153-2AB01;E06



2.2 Configuration

Configuration

The table below describes the most important configuration steps:

STEP7 as of Version 5.1 SP1

or

PCS 7 as of Version 5.1

STEP7 as of Version5.1

COM PROFIBUS as of Version3.0/other configuration

software

IM 153-2 as of 6ES7 153-2AA02-0XB0, Version 07

IM 153-2 FO as of 6ES7 2AB01-0XB0, Version 06

Features

• The ET 200M (IM 153-2) iscontained in the STEP 7hardware catalog

• Diagnostic interrupts andtime stamping aresupported

• The ET 200M is integratedas an S7 DP slave

• You require the DDB file of the IM 153-2

• The ET 200M is integrated as a DP standard slave

How toproceed

1. Start SIMATIC Manager.

2. Configure the ET 200M withHWCONFIG.

– Create a new project.

– Drag the modules fromthe hardware catalog tothe configuration table.

3. Save the configuration anddownload it to the DPmaster.

1. Start SIMATICManager.

2. Integrate the DDBfile in HWCONFIG.

3. Configure the ET200M withHWCONFIG.

– Create a newproject.

– Drag themodules from thehardware catalogto theconfigurationtable.

4. Save theconfiguration anddownload it to theDP master.

1. Start COMPROFIBUS/configurationsoftware.

2. Integrate the DDB file in COMPROFIBUS /yourconfiguration software.

3. Configure the ET 200M withCOM PROFIBUS /yourconfiguration software.

4. Save the configuration anddownload it to the DP master.

Reference

You can find additional information on configuration in the STEP 7 / COMPROFIBUS online help system.



DDB File in STEP 7/COM PROFIBUS

The table below describes how to integrate the DDB file in SIMATIC S7 orSIMATIC S5 (COM PROFIBUS).

STEP7 COM PROFIBUS, as of V 3.0

1. Start STEP 7 and select the menucommand Extras / Install New DDB File inthe hardware configurationf.

1. Copy the DDB file from ET 200M (IM 153-2) in the COM PROFIBUS directory:...COMPB3\GSD (default)Copy the Bitmap file in thedirectory:...COMPB3\BITMAPS

2. Select the DDB file to be installed in thefollowing dialog box and confirm with OK.Result: The field device is displayed in thehardware catalog in the PROFIBUS-DPdirectory.

2. Start COM PROFIBUS and select themenu command File / Download DDB File.Result: The ET 200M (IM 153-2) isdisplayed in the hardware catalog duringslave configuration

Downloading the DDB File

You can download the DDB file for the ET 200M (IM 153-2) from the following

• On the Internet at http//www.ad.siemens.de/csi_e/gsd

• Via modem on +49 (911) 73 79 72

http//www.ad.siemens.de/csi_e/gsd



2.3 Parameter Assignment

Parameter Assignment

The following table describes the most important steps in the parameterization ofthe process control modules:

STEP 7 (as of Version 5.1 SP1) with theSIMATIC PDM add-on package (as of

Version 5.1) or PCS 7 as of Version 5.1

SIMATIC PDM as of Version 5.1

IM 153-2 as of 6ES7 153-2AA02-0XB0, Version 07

IM 153-2 FO as of 6ES7 153-2AB01-0XB0, Version 06

Features • You parameterize the process control modules in the ET 200M.

Requirements

SIMATIC PDM is already installed on theprogramming device/PC or PCS 7 ES.

SIMATIC PDM must be a stand-alone version

How toproceed

1. You are still in HWCONFIG. Double-click the first process control module inthe configuration table.Result:SIMATIC PDM is started.

2. Assign the parameters of the processcontrol module with SIMATIC PDM.

3. In HWCONFIG, double-click the nextprocess control module in theconfiguration table.

4. Parameterize the process controlmodule with SIMATIC PDM.

5. Repeat steps 3 and 4 until you haveparameterized all the process controlmodules.

6. Save the parameters or, if you areonline, download the parameters to theprocess control modules.

1. Start SIMATIC PDM.

2. Configure a point-to-point connection tothe ET 200M.

3. Parameterize all the process controlmodules of the ET 200M with SIMATICPDM.

4. Save the parameters or, if you are online,download the parameters to the ET 200M.

Note

You parameterize the IM 153-2 and the “standard“ modules in the usual way inSTEP 7 HWCONFIG.

Reference:

You can find additional information on parameter assignment in the SIMATIC PDMdocumentation.



2.4 Changing the Parameter Assignment of the Process ControlModules During Operation

Changing the Parameter Assignment

The following table describes the most important steps when changing theparameter assignment of the process control modules:

STEP 7 (as of Version 5.1 SP1) with theSIMATIC PDM add-on package (as of

Version 5.1) or PCS7 as of Version 5.1

SIMATIC PDM as of Version 5.1

Features • You can reparameterize the process control modules during operation.

Requirements

SIMATIC PDM is already integrated onthe programming device/PC or PCS 7 ES.

SIMATIC PDM must be a stand-alone version

Procedure 1. Start STEP 7 SIMATIC Manager

2. Open the project in which youconfigured the ET 200M.

3. Double-click the process controlmodule in HWCONFIG in theconfiguration table you want toreparameterizeResult:SIMATIC PDM is started.

4. Download the parameters/identificationdata of the process control module tothe programming device/PC.

5. Change the parameters/identificationdata.

6. Download the parameters/identificationdata to the process control module.

7. Check: Download theparameters/identification data of theprocess control module again to theprogramming device/PC and check thereparameterization.

1. Start SIMATIC PDM.

2. Configure a point-to-point connection tothe ET 200M.

3. Download the parameters/identificationdata of the process control module to theprogramming device/PC.

4. Change the parameters/identificationdata.

5. Download the parameters/identificationdata to the process control module.

6. Check: Download theparameters/identification data of theprocess control module again to theprogramming device/PC and check thereparameterization.

Reference

You can find additional information on parameter assignment in the SIMATIC PDMdocumentation.



2.5 Diagnostics by Means of the Process Input Image

Introduction

In addition to the diagnostic messages by means of LED and module/DPdiagnostics, the module also provides additional information on the validity of eachinput signal – the value status. The value status is stored in the process image likethe input signal.

Value status

The value status is additional binary information on a digital input signal. The valuestatus is entered at the same time as the process signal in the process input imageand provides information on the validity of the input signal. The value status isinfluenced by

• Wire break check

• Flutter monitoring

• Pulse lengthening

• Diagnostics for the changeover contact type of sensor

Meaning of the value status:

• “1“: Signal is valid

• “0“: Signal is invalid



Digital Input and Value Status Assignment

In the process image, each input in the input word IW x of the module is assigned avalue status in the subsequent IW x+1.

Channel 1 input signal

Meaning of value status: 1: signal valid0: signal invalid


EW x

15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0

EW x+1

15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0

Value status for channel 1




Figure 2-2 Digital Input and Value Status Assignment

Evaluation of the Value Status in PCS 7

The value status is evaluated in your CFC program with block FC 277 “CH_DI:Digital Input“. This module undertakes the processing of the digital input value ofS7-300-Digital input modules.

How the value status gets into the block:

1. Link the symbol created with STEP 7 in the symbol table for the digital inputchannel with the VALUE input parameter.

2. Link the status symbol of the value of the digital input channel with theVALUE_QC input parameter

3. Set the PQC = TRUE input parameter

If you use the driver wizard in PCS 7 (as of V 5.1), steps 2 and 3 are executedautomatically by PCS 7.

A Detailed Description

You can find a detailed description of the block and how the input signals areprocessed in the PCS7 documentation.


General Technical Specifications 3Overview

The following general technical specifications correspond to those of the S7-300modules:

• Standards, certificates and approvals

• Electromagnetic compatibility

• Transport and storage conditions

• Mechanical and climatic environmental conditions

• Information on insulation testing, safety class and degree of protection

• Rated voltages

... correspond to those of the S7-300 modules.

Further Reading

You can also refer to the S7-300, M7-300 Programmable Controllers; ModuleSpecifications reference manual.


Digital Input Module 44.1 SM 321; DI 16xNAMUR (6ES7 321-7TH00-0AB0)

Order Number

6ES7 321-7TH00-0AB0

Features

The SM 321; DI 16xNAMUR has the following features:

• 16 inputs

• Connection of a wide variety of sensor types

– NAMUR sensor on the basis of NAMUR worksheet NA 01

• Process control functions

– Pulse lengthening

– Flutter monitoring

• Value status

• Identification Data

• Input nominal voltage DC 24 V

Inrush current

The SM 321; DI 16xNAMUR has an inrush current of 4 A.

We recommend you power the digital input module with its own power supply. Sothat you can make sure that no neighboring modules will be affected when thedigital input module is turned on.

Digital Input Module


Terminal Assignment and Block Diagram

In the figure, NAMUR sensors are connected to the inputs as an example. You canfind out how to connect the other possible sensors in the section on sensors.

Channelnumber

Status displays – greenError displays – red

SFF0

F1

1

F22

F3

31V

F4

4

F5

5

F6

6

F7

7

F12

12

F13

13

F14

14

F15

15 M

L+

2VS1

2VS2

1M

2M

2P8.2

2P18

1M

MUX MUX

2V1V

0F8

F9

9

F1010

F11

112V

9

1VS1

1VS2 1P8.2

1P18

Ba

ckp

lan

eb

us

inte

rfa

ce

mo

du

le

2M

1P18

1P8.2

1M

2P18

2P8.2

2M

Figure 4-1 Module View and Block Diagram of the SM 321; DI 16 x NAMUR



Technical Specifications


Dimensions and Weight

Dimensions W x H x D (mm) 40 x 125 x 120

Weight Approx. 200 g

Data for Specific Module

Number of inputs 16

Occupied address area

• In the process-image input table 4 bytes

Line length

• Unshielded Not permitted

• Shielded Max. 200 m with 8,2 V sensorMax. 400 m with 18 V sensor

Voltages, Currents, Potentials

Rated load voltage L+ 24 VDC

• Reverse polarity protection Yes

Number of inputs that can be addressedsimultaneously

• Horizontal configurationup to 60°C

16

• Vertical configurationup to 40°C

16

Isolation

• Between channels and backplane bus Yes

• Between the channelsIn groups of

Yes8

• Between power supply and sensorpower supply

Yes

Permissible potential difference

• Between the different circuits 75 VDC,60 VAC

Insulation tested with 600 VDC

Current consumption

• From the backplane bus Max. 100 mA

• From the load voltage L+ (no load) typ. 100 mA

Power dissipation of the module typ. 11 W

Status, Interrupts, Diagnostics

Status displays

• Inputs Green LED per channel

• Sensor power supplies (Vs) Green LED per output (Vs)




Interrupts

• Diagnostic Interrupt Parameters can be assigned

Diagnostic functions Parameters can be assigned

• Group error display Red LED (SF)

• Channel error display Red LED per channel (F)

• Diagnostic information readable Possible

Sensor Power Supply Outputs

Number of outputs 4

Output voltage

• Loaded 1VS1: 18 V1VS2: 8,2 V2VS1: 18 V2VS2: 8,2 V

Output current

• Rated value At 18 V: 220 mAAt 8,2 V: 60 mA

• Permitted range

Up to 60 °C At 18 V: 0 bis 110 mAAt 8,2 V: 0 to 60 mA

Up to 40 °C At 18 V: 0 to 220 mAAt 8,2 V: 0 to 60 mA

Additional (redundant) supply Not permitted

Short-circuit protection yes, electronic

Data for Selecting a Sensor

Input voltage

• Rated value 18 V8,2 V

Input current for NAMUR sensor

• At signal “1“ 2.1 to 7 mA

• At signal “0“ 0.35 to 1.2 mA

Input current for 0 kΩ/47 kΩ connectedcontact

• At signal “1“ typ. 10 mA

• At signal “0“ 0.35 to 1.2 mA

Input current for unconnected contact and 3-and 4-wire BEROs

• At signal “1“ typ. 10 mA

• Permitted bias current 0.5 mA

Input delay

• At “0“ to “1“ 2.5 to 3.5 ms

• At “1“ to “0“ 2.5 to 3.5 ms

Input characteristic curve To IEC 1131, type 2

Connection of 2-wire BERO Possible in accordance with NAMUR




Time/frequency

Internal processing time for

• Interrupt and diagnostics processing max. 2 ms (at default setting)

Input delay

• Tolerated switchover time forchangeover diagnostics

300 ms



4.2 Parameters of the Digital Input Module

Overview

The following tables contain:

• all parameters and

• The identification data of the digital input module

Parameter

You set the parameters for each channel in PDM. Entering the sensor type affectsthe channel group. This means that if, for example, you set a “NAMUR sensor“ forchannel 0, PDM then automatically also sets a “NAMUR sensor“ for channel 1, etc.

Table 4-1 Parameters of the Digital Input Module

Parameter Range of Values DefaultSetting

Applicability

Diagnosis

• Enabling: Diagnosticinterrupt

Yes/no No Module

Channel x

Sensor type Channel deactivatedOne-way contact: NAMUR sensorOne-way contact: unconnectedOne-way contact: 10 kΩOne-way contact: 47 kΩChangeover contact: NAMUR sensorChangeover contact: unconnectedChangeover contact: 10 kΩChangeover contact: 47 kΩ

NAMURsensor

Channel group

Group diagnosis Yes/no Yes Channel

Pulse lengthening None; 0,5 s; 1 s; 2 s No Channel

Input signal Contact closed = “HIGH“Contact closed =“LOW“

Contactclosed =“HIGH“

Flutter monitoring Yes/no No Channel

• Monitoring window 0,5 s; 1 s to 100s (can be set in 1 sincrements)

2 s

• Number of signal changes From 2 to 31 5



Group Diagnosis and Value Status

If you deactivate the group diagnosis for a channel, a channel error will not beindicated by the channel error LED and there will be no diagnostic entry. A channelerror will, however, be displayed in the value status.

Identification Data

Table 4-2 Identification Data of the Digital Input Module

Identification Data Range of Values Default Setting Applicability

Device

Manufacturer Read SIEMENS AG Module

Device identification Read 6ES7 321-7TH00-0AB0

Module

Device serial number Read Module

Hardware revision Read Module

Software revision Read

Depends on theversion

Module

Static revision no. Read --- Module

Installation date Read/write (max. 16 characters) --- Module

Operating unit

TAG Read/write (max. 32 characters) --- Module

Description Read/write (max. 32 characters) --- Module

Reference

You can find detailed information on the parameters for pulse lengthening, fluttermonitoring and identification data in the following sections.

See also

Identification Data [→ Page 4-11]



4.3 Parameter Descriptions

4.3.1 Flutter monitoring

Introduction

Flutter monitoring is a process control function for digital input signals. It detectsand reports any unusual signal patterns such as, for example, when an input signalfluctuates too often between “0“ and “1“. The occurrence of such signal patternsindicates that the sensor is faulty or unstable.

Enabling Flutter Monitoring

You enable flutter monitoring by means of the “Diagnosis: Flatter monitoring“ .

Tip: Also enable the diagnostic interrupt at parameter assignment so that, if thereis a flutter error, a diagnostic interrupt is also reported in addition to the diagnosticentry.

Detecting Unusual Signal Patterns

A parameterizable monitoring window is available for each input channel. Themonitoring window is started with the first change of the input signal. If the inputsignal changes more within the monitoring window than the parameterized numberof signal changes, this is recognized as a flutter error. If a flutter error is notdetected within the monitoring window, the monitoring window is started again atthe next signal change.

Reporting a Flutter Error

If a flutter error occurs, the current signal state is entered in the process image andthe value status of the signal is set to “invalid“. In addition, the “flutter error“ isentered as diagnostic information, and an incoming diagnostic interrupt istriggered.

You must evaluate and process the value status and the diagnostic information inthe user program.

Resetting a Flutter Error

If no further fluttering of the input signal is detected during the triple monitoringwindow, the diagnostic entry is removed and an outgoing diagnostic interrupt istriggered. The value status of the current signal in the process image is set to“valid“.



Principle

The following figure illustrates the principle behind flutter monitoring.

Parameter for number of signal changes = 9

Parameter for monitoring window t = x

Processsignal

Module diagnosisIncoming flutter error= report

3 x monitoring window t = 3x

Diagnosis

Module diagnosisOutgoing flutter error= reset

Detect

Figure 4-2 Principle Behind Flutter Monitoring

Reference

You can find out which settings you can make for flutter monitoring in theparameter table and in the SIMATIC PDM online help system.



4.3.2 Pulse lengthening

Introduction

Pulse lengthening is a function for changing a digital input signal. A pulse at adigital input is extended to at least the parameterized length. The input signal willnot be changed if it is longer than the parameterized length.

Principle Behind Pulse Lengthening

The following figure illustrates with examples if and how input pulses are changed.

Pulse is longer than T1and is not changed

Parameter for pulse lengthening = T1

T for 0 1 edge1 ®

Process signal

Processedinput signal

Pulse is shorterthan T and is lengthened1to T1

Short pulses that occurduring pulse lengtheningare ignored.

Process signal

The second pulse, which occursduring pulse lengthening, isdelayed until completion of pulselengthening.

T for 1 0 edge1 ®

Processedinput signal

Figure 4-3 Principle Behind Pulse Lengthening



Note

If you parameterize pulse lengthening for an input channel, this also affects theflutter monitoring enabled for this channel. The “pulse-lengthened “ signal is theinput signal for flutter monitoring. Make sure therefore that the parameters for pulselengthening and flutter monitoring correspond to each other. By selecting theappropriate values for the parameters, you can customize the functions to suit yourprocess as well as possible.

Reference

You can find out which settings you can assign for pulse lengthening in theparameter table and in the SIMATIC PDM online help system.

4.3.3 Identification Data

Identification Data

Table 4-3 Identification Data

Identification Data Description

Manufacturer The name of the manufacturer is storedhere.

Device identification Order number of the module

Device serial number The serial number of the module is storedhere. This makes unique identification of themodule possible.

Hardware revision This indicates the module version. This isincremented when the version and/orfirmware version of the module is/areincremented.

Software revision This indicates the firmware version of themodule. If the firmware version isincremented, then the version (hardwareversion) of the module is incremented aswell.

Static revision no. This gives you information on parameterizedchanges on the module. After each change,the static revision number is incremented.

Installation date The date the module was installed. Enterthe date here. DD.MM.YYYY format

TAG Location of the module. Enter a uniqueidentification for the module here.

Description Free text stored in the module. You canenter additional information on theproperties of the module here.



4.4 Sensor

4.4.1 Connection Rules for Sensors

Introduction

Because of the large number of sensors that can be connected to the digital inputmodule, you must take the sensor load into account at configuration. You will findin this chapter ...

• recommendations on how to connect sensors

• An overview of the sensor-specific load

• A rule for the evaluation of the sensor-specific load

• An example

Sensors Can Be “Combined “

You can connect a wide variety of sensors to the SM 321; DI 16xNAMUR , andthese can also be “combined“.

At parameter assignment, you can specify which sensors are to be connected towhich channel group. The same sensor type is assigned to the channels of achannel group.

Changeover contact

Changeover contacts always occupy two adjacent inputs (for example, 0 and 1 or 2and 3, etc.). Make sure you adhere to the following rule:

• Always connect the normally open contact to the “even“ channel,

• Normally closed contact is always connected to“odd“ channel.

2 Sensor Supplies: 18 V and 8,2 V

The SM 321; DI 16xNAMUR has two different sensor supply voltages. Thefollowing table shows you which sensor to attach to which sensor supply:

18 V 8.2 V

One-way contactt or BERO connected to 10kΩ/47 kΩ

NAMUR sensor or DIN 19234 sensor

Changeover contact or 4-wire BEROconnected to 10 k/Ω47 kΩ

NAMUR sensor changeover contact orsensor DIN 19234 as changeover contact



18 V 8.2 V

One-way contact or 3-wire BEROunconnected

Changeover contact or 4-wire BEROunconnected

Calculating the Performance Factor for the Use of a BERO

We show you below which criteria a BERO should fulfill and how to calculate theperformance factor in order to calculate the sensor load of the digital input module.

Technical Demands Made of the BERO

The following figure illustrates the connections of a BERO and the most importantcharacteristic quantities.

Electronic circuitry(e.g. magneticsensor technology)

(M1)21 (-)

(+)(1P18)10

BERO

Ic

DI16

DI16

T1

A

Ic

10K or 47KW W

DI162

Figure 4-4 Connections and Characteristic Quantities of a BERO

Selection criteria:

• Operating voltage range (BERO terminal (+) and terminal (-)): 15 V to min. 20 V

• Transistor T1 functions as a switch (on/off)

• Protective measures:

– Spurious switch-on pulse suppressed

– Output A short circuit-proof

– Reverse polarity protection

– Wire break protection

– Anti-inductive protection

– Radio telephony protection

• Load capacity (T1) = 150 mA (at TA≤ 85 °C)



Performance Factors for BEROs from the “Low-Voltage Controlgear, Switchgearand Systems“ Catalog

You will find a value in the table below that you can use to calculate the sensorload easily if:

• You use sensors from the “Low-Voltage Controlgear, Switchgear and Systems“NSK catalog from SIEMENS

• IC = 17 mA

You calculate the performance factor as follows: LF = 0,281 + IC x 9,5 = 0,376

Table 4-4 Peformance Factors for BEROs and Sensors

Sensor Performance Factor

NAMUR sensors and sensors that complywith DIN 19234

0.099 x number of sensors

NAMUR sensor as changeover contact or .sensor as changeover contact that complywith DIN 19234

0.099 x number of sensors

One-way contact 10 kΩ/47 kΩ 0.281 x number of sensors

Changeover contact 10 kΩ/47 kΩ 0.281 x number of sensors

One-way contact unconnected 0.281 x number of sensors

3-wire BERO unconnected (0,281 + IC x 9,5) x number of sensors

Changeover contact unconnected 0.281 x number of sensors

4-wire BERO unconnected (0,281 + IC x 9,5) x number of sensors

Constant 1,9



Rules

The following table shows you which conditions you must adhere to. The sensorload on channels 0 to 7 should be approximately the same as the sensor load onchannels 8 to 15.Ensure when wiring the module that the load distribution is as symmetrical aspossible: The sensor load on channels 0 to 7 should be approximately the same asthe sensor load on channels 8 to 15.

Table 4-5 Rules on the Sensor Load

Operation of the Module with theDesired Sensor Connection Possible

at an Ambient Temperature of

Sum of sensorvalues

Channel 0 to 7 orChannel 8 to 15 Max. 60 °C Max. 40 °C

Note

3,7 Yes Yes -

> 3,7 No Yesif the sum is 5,0

Reduce the number of sensors until thesum is 3.7.

5,0 No Yes -



Example

Using the following example of a module’s planned sensor connections, we showyou how the calculation is done.

Table 4-6 Sensor Load Example

Channel

Sensor PerformanceFactor

Evaluation

0 NAMUR sensor 0,099

1 NAMUR sensor 0,099

2

3

NAMUR sensor changeovercontact

0,099

4 One-way contact 10 kΩ 0,281

5 One-way contact unconnected 0,281


7 3-wire BERO unconnected 0.442*

Constant 1,9

Total: 3,482

Desired sensor connection possible forchannels 0 to 7








15 not occupied -

Constant 1,9

Total 4,833

Desired sensor connection possiblewhen the module is used up to amaximum of 40 °C

* LF = 0,281 + 17 mA x 9,5 = 0,442

Evaluation

You should not use the planned sensor connection above as follows:

• Can be used up to a maximum of 40 °C, but

• The sensor load is asymmetrical.

What to do:

• When you use the module up to a maximum of 40°C: Reassign the sensors tothe channels so that the sensor load is as symmetrical as possible.

• When you use the module up to a maximum of 60°C: Use an additional moduleto reduce the sensor load to under the specified factor of 3.5.



4.4.2 Diagnosis Dependent on Sensor

Diagnostic Options

The following table shows you which sensor supplies which diagnosis.

Table 4-7 Diagnosis Dependent on Sensor

Possible withDiagnosis

NAMUR-Compliant

Sensor

One-WayContact

Changeover

Contact

3-WireBERO

4-WireBERO

Interruption of the sensor line or sensorsupply line

X Ifconnected

Ifconnected

Ifconnected

Ifconnected

Break in the bridging resistance X Ifconnected

Ifconnected

Ifconnected

Ifconnected

Short circuit between sensor line(s) andsensor supply line

X - Changeover error atsignalchange

- Changeover error atsignalchange

Load voltage L+ of module missing X X X X X

Flutter of signal sensor X X X X X

Defective sensor (normally openchannel) = changeover contact error

Withchangeovercontact

- X - X

Reference

You can find a detailed description of the module diagnosis in the chapter "Diagnostic Data“



4.4.3 Terminal Assignment Diagrams

Introduction

Below you can find an illustration of how to connect each parameterized sensortype.

Changeover contact

Changeover contacts always occupy two adjacent inputs (for example, 0 and 1 or 2and 3, etc.). Make sure you adhere to the following rule:

• Always connect the normally open contact to the “even“ channel,

• Normally closed contact is always connected to“odd“ channel.

NAMUR sensor or DIN 19234 sensor

As an alternative to the NAMUR sensor, you can also connect a sensor thatcomplies with DIN 19234.

3

11 = 1P8.2

Connection example for channel 0

1VS2

3

1 kW

10 kWor:

11 = 1P8.2

1VS2

Figure 4-5 Connection Example for NAMUR Sensor



NAMUR sensor changeover contact or sensor DIN 19234 as changeover contact

As an alternative to the NAMUR Sensor changeover contact, you can also connecta sensor that complies with DIN 19234 as a changeover contact .

3

Normallyopen

contact

Normallyclosedcontact

5

1VS2

1 kW

11 = 1P8.2

3

510 kW

Connection example for channels 0 and 1

or:Mechanicallylinked

11 = 1P8.2

1VS2

Figure 4-6 Connection Example for NAMUR Sensor as Changeover Contact



One-way contact 10 kΩ/47 kΩ

As an alternative to a 10 kΩ/47 kΩ one-way contact, you can connect a BERO,connected with 10 kΩ/47 kΩ.

1VS1

2

10 = 1P18

R


or

R = 10 k or 47 kW W

+

1VS1

2

1M21

10 = 1P18

BERO

-

R

Figure 4-7 Connection Example for 10 kΩ/47 kΩ One-Way Contact

Changeover contact 10 kΩ/47 kΩ

As an alternative to a 10 kΩ/47 kΩ changeover contact, you can connect a 4-wireBERO, connected with 10 kΩ/47 kΩ.

R=10 kW or 47 kW

10 = 1P18


1VS1

2

4R

10 = 1P181VS1

212

4

1M+

-

R

BERO

or:

Figure 4-8 Connection Example for 10 kΩ/47 kΩ Changeover Contact



One-way contact unconnected

As an alternative to an unconnected one-way contact, you can connect a 3-wireBERO.

2

1VS110 = 1P18

+

1VS1

2

1M21

10 = 1P18

BERO

-


or:

Figure 4-9 Connection Example for One-Way Contact Unconnected

Changeover contact unconnected

As an alternative to an unconnected changeover contact, you can connect a 4-wireBERO.

1VS110 = 1P18

2

4


+

-

10 = 1P181VS1

212

4

1Mor:

BERO

Figure 4-10 Connection Example for Changeover Contact Unconnected



4.5 Diagnostics of the Digital Input Module

4.5.1 DP Diagnostics/Module Diagnostics

In this section, you will find all the diagnostic messages of the digital input module–that can occur in DP diagnoses and STEP 7.

The module reports diagnoses for each channel. A visual indication is given bymeans of the SF LED.

You can activate/deactivate or parameterize the diagnosis by means of the “GroupDiagnosis“ parameter.

Diagnostic Messages, Causes of Errors and What to Do

Table 4-8 Diagnostic Message of the Digital Input Module, Causes of Errors and What to Do

Diagnostic Message

In DP Diagnosis(Channel-Specific

Diagnosis)

In ModuleDiagnosis

Causes of Errors What to Do

Failure of sensor supplyShort circuit (1D) P short circuit(sensor) Short circuit between the sensor line

and the sensor supply line

Eliminate overload/shortcircuit

Interruption of the sensor line(s) orthe sensor supply line

Re-establish theconnection

Break in the bridging resistance Eliminate the interruptionin the bridging resistance

Wire break (6D) Wire break

Defective sensor Replace the sensor

Replace the defectivesensor

Flutter of signal sensor

Reset the flutter monitor

Error (9D) Flutter error

Defective EEPROM Replace the module

Load voltage L+ of module missing Connect load voltage L+Sensor or loadvoltage missing –(17D)

Sensor supplyfailed Defective module-internal sensor

voltageReplace the module

Defective sensor Replace the sensor

Break in the bridging resistance Eliminate the interruptionin the bridging resistance

External error(26D)

Changeovercontact diagnosis

Short circuit in sensor supply andsensor line at changeover signalchange

Eliminate short circuit



Reference

You can find a detailed description of how to evaluate diagnostic information inSTEP 7 in the STEP 7 online help system.



4.5.2 Diagnosis with a Sensor of the Changeover Contact Type

Brief Description

In the case of diagnosis with a sensor of the changeover contact type, the modulemonitors switching between 2 input channels. If after the specified switchover time(see the technical specifications) there is no change in signal on the partnerchannel, the module issues a diagnosis.

Purpose

You can use the diagnosis as follows:

• For a diagnosis of the sensor

• To check that there was definitely a switchover between the normally opencontact and the normally closed contact



Principle

If the digital inputs of a channel group are parameterized as “ changeover contacts“, the module for this channel group carries out a diagnosis for the changeovercontact type of sensor. The tolerated switchover time between the two channels isfixed at 300 ms.

If the check is negative, then:

• The module identifies the value status of the normally open contact channel as “invalid “.

• The module creates a diagnostic entry for the normally open contact channel.

• The module triggers a diagnostic interrupt.

The digital input signal and the value status are only updated for the normally opencontact channel. The digital input signal for the normally closed contact channel isfixed at “zero“, and the value status is set as “invalid“ because this channel is onlysupposed to check the sensor.

Note the following points in the diagnosis for the changeover contact type ofsensor:

• If there is already an error on the normally open contact channel (a wire break,for example), the module no longer carries out a diagnosis for changeovercontact errors.

• The following table lists additional points:

Changeover contact A Negative Check Means

Changeover contact asNAMUR

• Short circuit or

• Wire break

Changeover contactconnected

• Defective sensor or short circuit

It is not possible to distinguish between adefective sensor and a short circuit.

Changeover contactunconnected

Caution: no difference possible between

• Signal “0“ and wire break

• Signal “1“ and short circuit

In addition:

Changeover contact orexternal error (in the case ofDP diagnosis–)

Reference

You can find out how to evaluate the diagnosis in the user program in the STEP 7online help system.


Digital Output Module 55.1 SM 322; DO 16xDC24V/0,5A (6ES7 322-8BH00-0AB0)

Order Number

6ES7 322-8BH00-0AB0

Features

The SM 322; DO 16xDC24V/0,5A has the following properties

• 16 inputs, isolated in groups of 4

• A rated load voltage of 24 VDC

• Parameterizable diagnosis

• Identification data

Use with Rapid Counters

When the 24 V supply voltage is connected via a mechanical contact, the outputsof the SM 322; DO 16xDC24V/0,5A carry the signal for approx. 50 µs “1“-depending on the circuit. You must take this into account if you use the SM 322;DO 16xDC24V/0,5A with rapid counters.

Digital Output Module


Terminal Assignment and Block Diagram

Channelnumber

1M

1L+

2L+

2M

SF

F00

F1

1

F2

2

F3

3

F4

4

F5

5

F6

6

F7

7

F0

0

F11

F2

2

F3

3

F4

4

F5

5

F6

6

F7

7

3M

3L+

4L+

4M

Backpla

ne

bus

inte

rface

module

¬

¬ Channel status (green)Channel error (red)

¬

¬

¬

Status displays – greenError displays – red

Figure 5-1 Module View and Block Diagram of the SM 322; DO 16xDC24V/0,5A

Note

Reverse polarity of the load voltage of the digital output module will also changethe behavior of the output channels: Unconnected channels output instead of“0“ a“1“ and connected channels output “1“ instead of “0“ .The module ignores the parameterized substitute values in each case.



Redundant Output Signals

The output with a series diode can be used for redundant control of an actuator.Redundant control can take place from 2 different modules without an externalcircuit. The two signal modules must have the same reference potential (M).

Note

If the output with a series diode is used, external P short circuits cannot bedetected.



Dimensions and Weight

Dimensions W x H x D (mm) 40 x 125 x 120

Weight Approx. 200 g

Data for Specific Module

Number of outputs 16

Line length

• Unshielded Max. 600 m

• Shielded Max. 1000 m

Voltages, Currents, Potentials

Rated load voltage L+ 24 VDC

• Reverse polarity protection Yes

Total current of the outputs without a seriesdiode (per group)

• Horizontal configurationup to 60°C Max. 2 A

• Vertical configurationup to 40°C Max. 2 A

Total current of the outputs with a seriesdiode (per group)

• Horizontal configurationup to 40°Cup to 60°C

Max. 1,2 AMax. 1 A

• Vertical configurationup to 40°C Max. 1 A

Isolation

• Between channels and backplane bus Yes

• Between the channelsIn groups of

Yes4




Permissible potential difference

• Between the different circuits 75 VDC,60 VAC

Insulation tested with 600 VDC

Current consumption

• From the backplane bus Max. 100 mA

• From load voltage L+ (without load) Max. 40 mA

Power dissipation of the module

• With diode 10 W

• Without diode 3.5 W

Status, Interrupts, Diagnostics

Status display Green LED per channel

Interrupts

• Diagnostic Interrupt Parameters can be assigned

Diagnostic functions Parameters can be assigned

• Group error display Red LED (SF)

• Channel error display Red LED per channel (F)

• Diagnostic information readable Possible

Data for Selecting an Actuator

Output voltage

• At signal “1“ Min. L + (- 0.7 V)

Output current

• At signal “1“Rated valuePermitted range

0,5 A5 mA up to 600 mA

• At signal “0“(residual current)

Max. 0.5 mA

Load resistor range 48 Ω to 4kΩ

Lamp load Max. 5 W

Connecting 2 outputs in parallel

• For redundant triggering of a load Possible for outputs with series diodes

• To increase performance Not possible

Control of a digital input Possible



Switch rate

• With resistive load Max. 100 Hz

• With inductive load, to IEC 947-5-1, DC13

Max. 2 Hz

• With lamp load Max. 10 Hz

Limit (internal) of the inductive circuitinterruption voltage up

typ. L+ (-45 V)

Short-circuit protection of an output yes, electronic

• Response threshold typ. 0,7 A

•

5.2 Parameters of the Digital Output Module

Overview

The following table lists all the parameters of the digital output module.

Note: You set the substitute value behavior inSTEP 7 and the remainingparameters in PDM.

Table 5-1 Parameters of the Digital Output Module

Parameter Range of Values DefaultSetting

Applicability

Set in PDM:

Diagnosis

• Enabling: Diagnosticinterrupt

Yes/no No Module

Diagnosis

• Load voltage L+ missing Yes/no Yes Channel group

• Group diagnosis Yes/no Yes Channel

Set in STEP 7 :

Behavior at CPU-STOP Substitute a value/Keep last value

Substitute avalue

Module

Substitute value 0/1 0 Channel



Identification Data

Table 5-2 Identification Data of the Digital Output Module

Identification Data Range of Values Default Setting Applicability

Device

Manufacturer Read SIEMENS AG Module

Device identification Read 6ES7 322-8BH00-0AB0

Module

Device serial number Read Module

Hardware revision Read Module

Software revision Read

Depends on theversion

Module

Static revision no. Read --- Module

Installation date Read/write (max. 16 characters) --- Module

Operating unit

TAG Read/write (max. 32 characters) --- Module

Description Read/write (max. 32 characters) --- Module

Reference

You can find detailed information on identification data in Section 4.3.3.

See also

Identification Data [→ Page 4-11]



5.3 Diagnostics of the Digital Output Module

In this table, you will find all the diagnostic messages of the digital output modulethat can occur in DP–Diagnosis and module diagnoses STEP 7.

The module reports the diagnoses for each channel. A visual indication is given bythe SF– LED.

You can activate/deactivate and parameterize the diagnosis by means of the“Group Diagnosis““ parameter.

Diagnostic Messages, Causes of Errors and What to Do

Table 5-3 Diagnostic Messages of the Digital Output Module, Causes of Errors and What to Do

Diagnostic Message

In DP Diagnosis(Channel-Specific

Diagnosis)

In ModuleDiagnosis

Causes of Errors What to Do

M short circuit– Short circuit of the output to M(channel group)

Short circuit (1D)

P-Short circuit Short circuit of the output to L+(channel group)

Eliminate short circuit

Output overload Eliminate overloadExcessivetemperature (5D)

Excessivetemperature Short circuit of the output to M Eliminate short circuit

Interruption in the wire betweenthe module and the actuator

Re-establish the connectionWire break (6D) Wire break

Channel unused (open) Disable “wire break diagnosis“for the channel

Error (9D) Fuse failure Defective Module Replace the module

Sensor or loadvoltage missing(17D)

(Load–) supplyvoltage failed

Load voltage L+ of modulemissing

Connect load voltage L+



Behavior at M-Short circuit

If output signal = “1“ the digital output module reports “M-Short circuit“.

If output signal = “0“ the digital output module switches to the safer status and theStatus-LED turns off.

Note: The digital output module reports a P-Short circuit regardless of the signalstatus.

Reference

You can find a detailed description of how to evaluate diagnostic information inSTEP 7 in the STEP 7 online help system.


Diagnostic Data 6In This Chapter

This chapter describes the structure of the diagnostic data in the system data. Youmust be familiar with this structure if you want to evaluate the diagnostic data of thesignal modules in the STEP 7 user program.

In PCS 7 , the CFC diagnostic block carries out the evaluation of the diagnosticdata automatically.

Further Sources

You can find a detailed description of the principle behind the evaluation of thediagnostic data of the signal modules in the user program and a description of theSFCs you can use to do this in the System and Standard Functions referencemanual.

Data Records 0 and 1 of the System Data

The diagnostic data of a module is contained in data records 0 and 1 of the systemdata area.

• Data record 0 contains 4 bytes of diagnostic data, which are the same for allmodules and describe the current status of an S7-300/ET 200M.

• Data record 1 contains:

– 4 bytes of diagnostic data of data record 0 and

– The remaining bytes containing the module-specific diagnostic data

Structure and Contents of the Diagnostic Data

Below you can find descriptions of the structure and contents of the individualbytes of the diagnostic data.

Generally speaking, if an error occurs, the corresponding bit is set to “1“.

Diagnostic Data


Data Record 0 (Bytes 0 to 3)

The assignment of bytes 0 to 3 illustrated in the figure applies to the digital inputand digital output modules.

7 6 5 4 3 2 1 0

Byte 0

Module malfunctionInternal error

External errorChannel error

No external auxiliary supply

0

Parameter assignment missing

7 6 5 4 3 2 1 0

Byte 1

Channel information available

Module class: digital module

0 0 0 1 1 1 1 1

7 6 5 4 3 2 1 0

Byte 2

Internal module supply voltage failed(sensor supply)

Operating mode 0 = RUN; 1 = STOP

0 0 0 0 0 0

7 6 5 4 3 2 1 0

Byte 3

EEPROM memory error

0 0 0 0 0 00

123

0

Figure 6-1 Diagnostic Data Record 0 (Bytes 0 to 3)

Diagnostic Data


Diagnostic Data Record 1 (as of Byte 4) of the Digital Input Module

7 6 5 4 3 2 1 0

Byte 4 70 : Digital input moduleH

7 6 5 4 3 2 1 0

Byte 5 08 : Number of diagnostic bits per channel: 8H

7 6 5 4 3 2 1 0

Byte 6 10 : Number of channels: 16H

7 6 5 4 3 2 1 0

Byte 7

Diagnostic event on channel 0


7 6 5 4 3 2 1 0

Byte 8



7 6 5 4 3 2 1 0

Byte 9

Byte 24

Diagnostic event for channel x

P short circuit (sensor)

Wire break

0

Sensor supply failureFlutter error

Changeover contact diagnosis

0 0

Figure 6-2 Diagnostic Data Record 1 (as of Byte 4) of the Digital Input Module

Diagnostic Data


Diagnostic Data Record 1 (as of Byte 4) of the Digital Output Module

7 6 5 4 3 2 1 0

Byte 4 72 : Digital output moduleH

7 6 5 4 3 2 1 0

Byte 5 08 : Number of diagnostic bits per channel: 8H

7 6 5 4 3 2 1 0

Byte 6 10 : Number of channels: 16H

7 6 5 4 3 2 1 0

Byte 7



7 6 5 4 3 2 1 0

Byte 8



7 6 5 4 3 2 1 0

Byte 9

Byte 25

Diagnostic event for channel x

P short circuit (sensor)M short circuit

Wire break (only when signal = 1)

0

Fuse failure(Load) supply woltage failure

Excessive temperature

Groups of 4 channels have a common power supply. If a power supplyerror occurs, the error bits of all 4 channels are set.

¬

¬

0

Figure 6-3 Diagnostic Data Record 1 (as of Byte 4) of the Digital Output Module


Dimensioned Drawing 7Dimensioned Drawing of the Signal Modules

The figure below shows a dimensioned drawing of the signal modules.

The appearance of the signal modules can vary. However, the specifieddimensions are always the same.

125

12040

130

Figure 7-1 Dimensioned Drawing of the Signal Modules

Additional Dimensioned Drawings

You can find dimensioned drawings of the modules and components of an S7-300and ET 200M in the relevant manuals..


Glossary 8BERO

A position switch that works without any touch or contact being involved. Adistinction is drawn between inductive and capacitive BEROs.

Flutter monitoring

Flutter monitoring is a process control function for digital input signals. It detectsand reports unusual process control signal patterns such as a fluctuation in theinput signal between“0“ and “1“that occurs too often.

Sensor

Sensors are used for the precise detection of digital signals and paths, positions,speeds, revolutions, weights, etc.

Identification Data

Identification data is information stored in a module that supports the user with thefollowing:

• Checking the configuration of a system

• Locating changes to the hardware of a system.

Pulse lengthening

Pulse lengthening is a function for changing a digital input signal. A pulse at adigital input is extended to at least the parameterized length. If the input pulse isalready longer than the parameterized length, it is not changed.

NAMUR

Normenausschuss für Mess- und Regelungstechnik (German standardizationcommittee for measurement and control engineering)

Changeover Contact

Auxiliary switch with only one contact piece that has a closed position for when theswitching device is closed and another closed position for when it is open.

Glossary


Value status

The value status is additional binary information on a digital input signal andprovides information on the validity of the input signal.

Index

Signal Modules for Process AutomationA5E00085262-02 Index-1

Index6ES7 322-8BH00-0AB0 5-1BERO 8-1Changeover contact 8-1

Diagnosis 4-19Changing the Parameter Assignment 2-6Configuration 2-3

Operating principle 2-1Software Requirements 2-2

ConnectionFrom Sensors 4-14

DDB fileintegrate into configuration software 2-4

DDB Filedownload 2-5

DiagnosisRecord 0 and 1 6-1the digital module depend on sensor

4-14with sensor changeover contact 4-19

Diagnostic messagesSM 321 DI 16xNAMUR 4-18SM 322 DO 16xDC24V/0,5A 5-6

Dimensioned DrawingSM 321 DI 16xNAMUR 7-1SM 322 DO 16xDC24V/0,5A 7-1

Flatter monitoring 4-6Hardware Requirements 1-1Identification Data 8-1

SM 321 DI 16xNAMUR 4-5SM 322 DO 16xDC24V/0,5A 5-5

NAMUR 8-1Parameter

Flatter monitoring 4-6Pulse lengthening 4-8SM 321 DI 16xNAMUR 4-4SM 322 DO 16xDC24V/0,5A 5-5

Parameterize 2-5Process Control Modules

Integration in Process Control System1-2

Product Overview 1-1Pulse lengthening 4-8Pulse lengthening 8-1Sensor 8-1

Connect 4-14Diagnostic possibilities 4-14Performance factor 4-12Rules of Connection 4-10

Sensor as Changeover contactDiagnosis 4-19

Signal mudules for process automation 1-1SM 321 DI 16xNAMUR 4-1

Diagnosis depend on sensor 4-14Dimensioned Drawing 7-1Identification Data 4-5module diagnoses 4-18Parameter 4-4Technical Specifications 4-2Terminal Assignment and Block

Diagram 4-1SM 322 DO 16xDC24V/0,5A 5-1

Diagnostic messages 5-6Dimensioned Drawing 7-1Identification Data 5-5Parameter 5-5Technical Data 5-3Terminal Assignment and Block

Diagram 5-1Software Requirements 1-1TAG 4-9Technical data

general 3-1Technical Specifications

SM 321 DI 16xNAMUR 4-2SM 322 DO 16xDC24V/0,5A 5-3

Terminal Assignment and Block DiagramSM 321 DI 16xNAMUR 4-1SM 322 DO 16xDC24V/0,5A 5-1

Value status 2-7, 8-2Evaluation in PCS7 2-8

Date post:	06-Apr-2016
Category:	Documents
Upload:	andre-fabricio
View:	225 times
Download:	0 times

teste publicação

Documents