ML091380436

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Meeting Slides, Teleperm Xs Permissions and Operating Modes
ML091380436
Person / Time
Site: Oconee, Indian Point  Duke Energy icon.png
Issue date: 04/15/2009
From:
AREVA NP
To:
Office of Nuclear Reactor Regulation
References
TSC 2007-09, Suppl 16
Download: ML091380436 (59)


Text

TELeEPERM XS Permissions and Operating Modes3/4-1 ii g 7XS Runtime Environment-April 15, 2009 R u n tim e Ei, viro n m e n t (R T,-'-7.)Operating -fo,.,ý;'.Iodes

%oEi--id e ra tin g de Tr- 3ýTXS Runtime Environment-April 15, 2009 Runtime Environment (RTE)Privilege and Permissions for Mode Transitions TXS Runtime Environment-April 15, 2009 3 Permissions for Operating Modes 2 The position of a key switch is connected via a hard wire to a binary input board channel, e.g. of a TELEPERM XS 8430 board The binary input signal of the I/0 board is cyclically read by the input board driver of the I/0 board.TXS Runtime Environment-April 15, 2009 4 Graphic Service Monitor GSM Overview of current I&C state.4";GSM t-P For each CPU: Current operating mode IM Granted permissions B-N'TXS Runtime Environment-April 15, 2009 5 7XS Runtime Environment-April 15, 2009 5 TXS Service Unit -Interaction with TXS CPUs Release of RTE operation modes TXS Runtime Environment-Anril 15. 20096.. ......... ... ...... .. ....... ..ri... .., 2. ..

TXS Service Unit -Interaction With TXS CPUs Two diverse means of access control/I-TXS Runtime Environment-April 15, 2009 7 7XS Runtime Environment-April 15, 2009 7 TXS Application Software Function Diagram (FD) Modules Function Diagram Group (FDG) Modules> Function Diagram (FD) module: " Code resulting from automatic code generation of function diagrams (FDs) being engineered on SPACE engineering tool" Implements the code for the engineered application specific W&C functions" Code consists of calls to Standard Function Block library functions being connected for the specific I&C function> Function Diagram Group (FDG) module: in Code resulting from automatic code generation

  • I Call and data interface to all FD modules running on one CPU with one and the same cycle time IM Max. 2 FDG modules per CPU TXS Runtime Environment-April 15, 2009 8 7XS Runtime Environment-April 15, 2009 8

.Signal Propagation on a Processing Module Call Graph of fdg-compute Function 7XS Runtime Environment-April 15, 2009 9 Run-time of Application Software Linear Structure of FDG Modules Function Diagram Group Module FD Module I I FD Module 2 IFD Module 3 IFDModulen I FDModulen+I Copy signals Copy signals Copy signals Copy signals Copy signals Copy signals Copy Function Diagram Module output siqnals -to destination Function Diagram input signals.FD Module n+I I 7XS Runtime Environment-April 15, 2009 10 7)(S Runtime Environment-April 15, 2009 10 Run-time of Application Software Extract from Function Diagram (FD) Module TXS Runtime Environment-April 15, 2009 11 Run-time of Application Software Computing Time of FDG Module Parts FDG FD FD FD FD FD FDG 1 FD FD FD FD FDG 1 FD FD FD ED U Tcom Tcom FDG modules and FDG module parts:always contain complete FD modules.FD modules are never split into multiple functions.

The distribution of FD modules to FDG parts is based on the FB module computing times.7XS Runtime Environment-April 15, 2009 12 Run-time of Application Software Computing Time of Function Block Modules F FB FB Init Param+ Param Comap ID Name + Comp + Comp COMP 456 457 458 459 460 461 501 502 507 520 1 1 1 1 F~c ~he_j TXS Rwitirne Environment-April 15, 2009 13 TXS Runtime Environment-April 15, 2009 13 FB RTE-INPUT Pictogram RTE-INPUT

-Binary signal transfer V Use: Transferring the 7 binary signals BI1 to B17 whose meaning is predefined in the parameterization mask to the runtime environment, .7XS Runtime Environment-Apr11 15, 2009 14 7XS Runtime Environment-April 15, 2009 14 FB RTEoINPUT Design of Pictogram Layout Eil Edit View Pocument Tools WLindow e ____________

_________________ -- ~ ~ %7 Pictogramme:

f 7XS Runtime Environment-April 15, 2009 15 7XS Runtime Environment-April 15, 2009 15 FB RTE-1-1"PuT Definition of Pictogram in Database jcumant Tut5 vools H~q x K 21 j 36jlO7> f T::Z 2 ,: 2 __ C 9i :V 7XS Runtime Environment-April 15, 2009 16 FB RTE-INPUT 1/0 Ports 1 1.1 Variable Ein -iAusgangssigna le: IJ 7XS Runtime Environment-April 15, 2009 17 FB RTEaINPUT Data Transfer Between FB and RTE SL1ocument

-oois wintrw aeip F-T 12636 F110071 -~ E 1.5 interne Variable: F I Name I rDatentyp IBed eutung-7j1 TXS Runtime Environment-April 15, 2009 18 7XS Runtime Environment-April 15, 2009 18 FB RTE..INPUT-Qfuctogram

-ýEd Viee Dicument Took Wtnd&o& Hel[2 36 F~1O % Li _Anlage 4 zu FANP NGLTS 2002 091 TXS-En1wicklungsdokLumem, Version 2,02: AU-INPUT" .7XS Rntim Envronmnt-Aril 5, 209 1 7XS Runtime Environment-April 15, 2009 19 FB RTE-INPUT Function Block Interface Structure (Header File)7XS Runtime Environment-April 15, 2009 20 FB RTEeiNPUT Function Block Forward Declaration (Header File)7XS Runtime Environment-April 15, 2009 21 TXS Runtime Environment-April 15, 2009 21 FB RTE5INPUT Function Block Source Code (fbS01.c)

(1)7X utm niomnt pi 5 092 7XS Runtime Environment-April 15, 2009 22 FB RTE-INPUT Function Block Source Code (2)23 7XS Runtime Environment-April 15, 2009 FB RTEoINPUT Function Block Source Code (3)TXS Runtime Environment-April 15, 2009 24 F-mf RTEoINPUT Function Block Source Code (4)25 TXS Runtime Environment-April 15, 2009 1)

ý FB RTE-OUTPUT T n=.o : R ,: L i'RTE-OUTPUT-1

-Output of status and fault information Symbol: Menu: Function diagram:~2 Use: Output of status of binary signals and fault information from the. runtime environment to a function diagram in the form 7XS Runtime Environment-April 15, 2009 26.TXS Runtime Environment-April 15, 2009 2&.

FS RTE-OUTPUT K/i 15 wricov4 ýei x L~JI Input / output signals: Signal Direction Type Port Meaning Defaults II I ID I -value Fault status ITest status IJ 27 TXS Runtime Environment-April 15, 2009 FB RTEINPUT I Function: FB RTE-OUTPUT-1 receives fault and status information from the runtime environment thus enabling further processing on function diagrams.The input signals of the function block are assigned to the pieces of information of the runtime environment in the course of linking the entire software for the processing module to the modules of the runtime environment.

If the runtime environment does not return OK, the function block stops executing.

The information is output as sixteen individual binary output signals (501 to BO16) whereby the respective output signal has the value 1 (= TRUE) if the assigned piece of information is output by the runtime environment, otherwise 0 (= FALSE)TXS Runtime Environment-April 15, 2009 28 Data Interface FB- <-4 RTE Data Structures (au.h) (1)29 7XS Runtime Environment-April 15, 2009 Data Interface FB <- RTE Data Structures (2)7XS Runtime Environment-April 15, 2009 30 Data Interface FB e-4 RTE Module locale (static) variables 7XS Runtime Environment-April 15, 2009 31 7XS Runtime Environment-April 15, 2009 31 Data Interface FB <-4. RTE RTE functions (fdgifc.c)

(1)32 7XS Runtime Environment-April 15, 2009 Data Interface RTE functions FB f-4 RT-I TXS Runtime Environment-April 15,2009 33 Data Interface FB <-4 RTE RTE functions (fdgifc.c)

(3)34 7XS Runtime Environment-April 15, 2009 Data inteoface FB u-ti RTE Invocation of RTE functions (4)TXS Runtime Environment-April 15, 2009 35 (Signal Propagation on a Processing Module Call Graph of FDGEOutput Function TXS Runtime Environment-April 15, 2009 36 Signal Propagation on a Processing Module Call Graph: Output Signals to I/O Board 7X utm niomnt pi 5 093 7XS Runtime Environment-April 15, 2009 37 Su"/ RTE Command Interface (Extract)fl'WRITE FDG (E)7"XS Runtime Environment-April 15, 2009 38 SQ RTE Command Interface WRITEFDG (2)/J TXS Runtime Environment-AprU 15, 2009 39 7)(S Runtime Environment-April 15, 2009 39 Cyclic RTE Mode Evaluation RTE MODE Evaluation Function (1)TXS Runtime Environment-April 15, 2009 40 Cyclic RTE Mode Evaluation RTE MODE Evaluation Function (3)7X utm niomnt pi 5 094 TXS Runtime Environment-April 15, 2009 41 Cyclic RTE Mode Evaluation RTE MODE Evaluation Function (4)42 7XS Runtime Environment-April 15, 2009 Cyclic RTE Mode Evaluation RTE MODE Evaluation Function (5)7XS Runtime Environment-April 15, 2009 43-6f CycRic RTE Mode Evaluation RTE MODE Evaluation Function (6)TXS Runtime Environment-April 15, 2009 44 TXS Runtime Environment-April 15, 2009 44 Cyclic RTE Mode Evaluation RTE MODE Evaluation Function (7)7X utm niomn-pi 5 094 7XS Runtime Environment-April 15, 2009 45 Results from the Generic Qualification RTE Qualification Certificate No.: TXS-AU-0902-06 SW Component:

Program Structure of the Runtime Environment, V2.30, 2002-02-25 Kind of Test: Type test analogous to KTA 3503 and in compliance with IEC 880 including evaluation of the test runs performed in a test environment Test Report: "2nd supplement to the technical test report on the type test of the program structure of the Runtime Environment of TELEPERM XS", V 2.00, ISTec GmbH, Garching, September 2002 Test result: The test has passed according to the 2nd supplement of the test report above.7XS Runtime Environment-April 15, 2009 46 Results from the Generic Qualification System Integration Test Certificate No.: TXS-AUST-1006-03 Subiect of test: TELEPERM XS integration test (A UST-Il)SW Component:

Program Structure of the Runtime Environment, V2.30, 2002-02-25 Kind of assessment.

Assessment of the documents and the execution of the integration test in a manner consistent with KTA 3506 and in compliance with IEC 60880 Technical report: ", V 1.00, IS Tec GmbH, Garching and TUV NORD SysTec GmbH & Co. KG, Hamburg, October 2006 7XS Runt/me Environment-April 15, 2009 47 7XS Runtime Environment-April 15, 2009 47 L£s2rec Certificate for the Digital Safety Instrumentation andl Control System TELEPERM XS Certificate number: Subject of test: Test execution:

Kind of assessment:

Technical report: Requirements:

Orderer: Main contractor:

Project management:

Assessment organizations:

Assessment period: Assessment result: Date: Assessors:

TXS-AUST-1006-03 TELEPERM XS integration test (AUST-Il)(For list of documents see appendix 1)AREVA NP GmbH Assessment of the documents and the execution of the integration test in a manner consistent with KTA 3506 and in compliance with lEO 60880"Ergtnzender Technischer Pr0fbericht zum Integrationstest der Hard-und Software:fur TELEPERMXS", V 1.00, ISTec GmbrIH,,Garching, and TOV NORD SysTec GmbH &.Co. KG, Ham'burg, Oktober 2006 see technical report AREVA NP GmbH Institut fOr SiCherheitstechnologie (ISTec) GmbH, Garching Institut fur Sicherheitstechnologie (ISTec) GmbH, Garching Institut fOr Sicherheitstechnologie (ISTec) GmbH, Garching TOV NORD SysTec GmbH & Co. KG, .Hamrburg April 2003 to September 2006 see appendix 3 31. October 2006 see appendix 2.Project management:

..A. Lindner (ISTec)Page 1 of 6 Certificate for the Digital Safety Instrumentation and Control System TELEPERM XS Certificate no.: TXS-AUST-1006-03 Appendix 1: Appendix 2: Documents:

TXS-Testspezifikation, Version 1.00: I ntegrationstest FANP NGLTS/02/157 TXS-TeStbericht, Version 1.00: Integrationstest NGLTS/2003/de10008, Rev. B V1.00 20.08.2004 V1.00 06.04.2006 Assessors:

ISTec M. Baleanu E. Hoffmann Dr. A. Lindner J. Mdrtz H. Miedl TOV NORD SysTec U. .Anders Dr. D. Haake G. Krage E.-U. Mainka Page 2 of 6 SrvNo, Certificate for the Digital Safety Instrumentation and Control System TELEPERM XS Certificate no.: TXS-AUST-1006-03, Appendix 3: Assessment result: The assessment was passed as stated in the technical report. The following system. characteristics are confirmed for: systems that follow the design criteria which were the basis of the system configuration referenced in the test report: 1. The type-tested hardware and software components can be assembled to an operable system if the engineerihngsystem SPACE is used.2. Processing and communication cycle times are not influenced by external process states (measured signals, amount:0ofalarms and monitored information).

3. Mutuallyindependent I&C functions are processed as specified according to their chronological order and their input- signals.4. Mutuallyindependent processing units (in accordance with report KWU NLL5f199611.10c) do not affect each other regarding their operating modes and their time behaviour.

Processing:units Which exchange signals but are otherwise mutually independent have only effect on each others time response within-the limits of the engineered communication functions.

5. Interference on cables with violation of the measuring range and input module failures are detected, marked as signal failures and indicated-.

Signals detected as faulty are processed and indicated by the system components (runtime environment, iO drivers, function blocks) as defined in the specification.

Page 3 of 6 Certificate for the Digital. Safety Instrumentation and Control System TELEPERM XS Certificate no.: TXS-AUST-1006-03 Appendix 3: Assessment result (continued):

6. Transmission failures onTXS Ethernet (Hi) and TXS Profibus (L2) busses are detected, processed and indicated in accordance with the specification.

Single message failures are tolerated by the system. Furthermore, on TXS Ethernet (H1) busses double message failures are tolerated.

Interference caused by a receiving unit on the sending one is impossible.

7. Sending and receiving processing units execute their functions asynchro-nously-if no"expedited messages" are sent via serial bus links, with the exception of voter sub-units monitoring each otheer. Lost, messages are treated like transmission errors. Thus failuresoUf individual sending process-ing units are.always tolerated if signa i.information.

is distributed via redundant trains and special fault propagation ibarrier function blocks are used on the receiving processing modules.8. Single failures0ofactive and passive hardware modules are detected and indicated corresponding to the implemented monitoring rmechanisms (self-monitoring, monitoring of the communication, cabinet annunciation system).Multiple failures are detected and indicated if sufficient resources (for example communicating processing units and communication'processors) are provided.

The cabinet annunciation system is activated according to the specification.

9. Fault propagation barriers are effective provided that no plant-specific fault suppression measures are engineered (for example status correction).

Signal status is changed by the runtime environment as specified, i.e., if required, status is changed to ERROR but never from ERROR or TEST to OK. Page 4 of 6 Certificate for the Digital Safety Instrumentation and Control System TELEPERM XS Certificate no.: TXS-AUST-1006-03 Appendix 3: Assessment result-(continued):

10. The runtime environment behaves in the operating modes start-up., operation, parameterisation, functional test and diagnosis as specified.

It changes between operating modes according to the specificAtion., Permissive signals for operating modes are designed individually according to project requirements and are not dealt with in the integration test.11. The runtime environment can be controlled by means of service commands.Disabling and enabling of service commands are effective as required for the respective operating mode.12. The user software can be loaded from a centralised unit using the network connections.

This function can be deactivated by a hardware switch on the processing modules.13. The system is consisting of several individual computers SVEI and SVE2.When one or more computers'are integrated or eliminated, the:system still behaves as specified.

SVE1:and.SVE2 can be used together at one backplane.

14. Fail-safe behaviour:

Signals marked as faulty (ERROR and/or TEST status)are issued as 0 signals via outpUt modules. Exceptions cause output of 0 signals via output modules and cause shut down or restart. of the,.computers affected.Page 5 of 6 iSTec ThVNOiW Certificate

'for the Digital Safety Instrumentation and Control System TELEPERM XS Certificate no.: TXS-AUST-1006-03 Appendix 3: Assessment result (continued):

15. Thesystem behaviour with respect to I&C functionality is entirely defined by the application software.

The minimum response:times of the system are determined by the cycletimes of the processing modules involved if the processing time of the function diagram / function diagram group modules plus the processing time required for execution for: service commands do not exceed the specified cycle time.Page 6 of 6 srec ID.No. 44.04 LSTec Certificate for the Digital Safety Instrumentation and Control System TELEPERM XS Software Certificate No.: TXS-AU-0902-06 SW Component:

Program Structure of the Runtime Environment, V2.30, dated 25.02.2002 (List of documents, module names and versions as well as CRC sums: see appendices 1 to 4)Manufacturer:

FRAMATOME ANP Kind of Test: Type test analogous to KTA 3503 and in compliance with IEC 880 inclu-ding evaluation of the test runs performed in a test environment.

Test Report: ,2" supplement to the technical test report on the type test of the program structure of the Runtime Environment of TELEPERM XS", V 2.00, ISTec GmbH, Garching, September 2002 Requirments:

See test report Orderer: Bayerisches Staatsministerium fOr Landesentwicklung und Umweltfragen Main Contractor:

Institut fOr Sicherheitstechnologie (ISTec) GmbH, Garching Project Management:

Institut fOr Sicherheitstechnologie (ISTec) GmbH, Garching Test Laboratory:

Institut fOr Sicherheitstechnologie (ISTec) GmbH, Garching Test Period: July to September 2002 Test Result: The test has been pased according to the 2"d supplement of the test report above.Date: 10. September 2002 Assessor:...............

i .. ..........

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

E. Hoffmann M. Baleanu Project Leader: ......-. ' "... './. ...- ....M. Kersken (ISTec)

LSTec 1srec Certificate for the Digital Safety Instrumentation and Control System TELEPERM XS Software Certificate-No.: Appendix 1: TXS-AU-0902-06 Development documents SILT-Lastenheft:

Ablaufumgebung S ILT-Lastenheft:

Ablaufumgebung in der Voter-Ebene SILT-Lastenheft:

Ablaufumgebung im Meldeinterface SILT-Lastenheft:

Ablaufumgebung in den Erfassungsrechnern TXS-Pflichtenheft:

Programmstruktur der Ablaufumgebung TXS-Designunterlage:

Programmstruktur der Ablaufumge-bung TXS-Implementierungsuntedrage:

Programmstruktur der Ab-laufumgebung TXS-Testspezifikation:

Programmstruktur der Ablaufumge-bung TXS-Testbericht:

Programmstruktur der Ablaufumgebung TXS-Testspezifikation:

Zielsystemtest Ablaufumgebung TXS-Testbericht:

Zielsystemtest Ablaufumgebung V 1.04 V 1.03 V 1.01 V.1.01 V 2.30 V 2.30 27.06.2001 27.06.2001 15.12.1995 27.06.2001 31.10.2001 25.02.2002 V 2.30 03.04.2002 V 2.30 05.04.2002 V 2.30 V 2.30 V 2.30 12.04.2002 10.07.2002 29.08.2002 Appendix 2: List of the C source files of the Runtime Environment with status (version no. and latest date in the file header)C-Dateien cyc.c drvifc.c errormsg.c fdgifc.c init.c Version 2.30 2.30 2.30 2.30 2.30 Datum 07.01.2002 19.12.2001 14.02.2002 11.01.2002 14.12.2001 srec srec Certificate for the Digital Safety Instrumentation and Control System TELEPERM XS Software Certificate-No.:

TXS-AU-0902-06 C-file auparams.c input.c mode.c monit.c output.c sync.c system.c trace.c Version 01.05 2.30 2.30 2.30 2.30 2.30 2.30 2.30 Date 25.02.2002 12.02.2002 25.02.2002 25.02.2002 07.01.2002 17.01.2002 25.02.2002 15.02.2002 Appendix 3: List of the Include.status (version no.Include file au.h augen.h auparams.

h au-types.h crcccitt.

h cyc.h drvifc. h errormsg.h fdgifc.h init.h input.h mode.h monit.h and Assembler files of the Runtime Environment with and latest date in the file header)Version 2.30 2.30 1.07 2.30 00.02 2.30 2.30 2.30 2.30 2.30 2.30 2.30 2.30 Date 25.02.2002 11.12.2001 11.12.2001

-11.12.2001 26.06.2001 17.12.2001 19.12.2001 18.12.2001 11.01.2002 13.12.2001 21.12.2001 14.01.2002 15.01.2002 srTec LSTec Certificate for the Digital Safety Instrumentation and Control System TELEPERM XS Software Certificate-No.:

TXS-AU-0902-06 Include file mode.h monit.h output.h sync.h system. h trace.h Assembler file crcccitt.asm Version 2.30 2.30 2.30 2.30 2.30 2.30 Version 0301 Date 14.01.2002 15.01.2002 26.06.2001 11.12.2001 07.02.2002 15.01.2002 Date 01.02.1995 Appendix 4: CRC sums and size in bytes File Version Date au.h augen.h autypes.h auparams.h errormsg.h init.h aupstruc.plk product.sql 02.30 02.30 02.30 01.07 02.30 02.30 02.30 02.30 25.02.2002 11.12.2001 11.12.2001 11.12.2001 18.12.2001 13.12.2001 25.02.2002 25.02.2002 Size (bytes)81601 27672 8147 9796 8822 3424 144277 4715 16bit CRC-sum C5A1 5075 C266 939B 5376 07C7 6D25 9DB4 32bit CRC-sum BB2C3AFD 2CDE9130 5C277C7E F39E175F 5EA8F40A 24C511B02 CBAE7FA9 21F43AD7 VERIFY HARD COPY AGAINST WEB SITE IMMEDIATELY PRIOR TO EACH USE Engineering Directives Manual EDM 130 VENDOR/DUKE MANUAL CERTIFICATION FORM (To be placed inside front cover of manual)Page 1 of 1 1. Station: Oconee Nuclear Station Unit: 1 QA Condition:

2. Title: Oconee Nuclear Station Unit 1 RPS/ESFAS Replacement Project Equipment Qualification Report 3. Duke File Number: OM 201.N--0021.001 Revision No: 3 Distribution Code: OEM-19N 4. Document Type (Check One): MV Vendor Manual Li Duke Manual Manual Type (Check One): -. Instruction Book (I/B) WJ Non-Instruction Book (Non-I/B)5. Vendor: AREVA NP, Inc. For Vendor Manuals Only Vendor Document No: 66-5065212-03
6. Document Transmittal No. 'Date: For DCRM Use Only Manual File Copy (Check One): El Record E Spare El Distribution File Copy Proofed By: Date: 7. Sponsor Team/Sponsor Engineer:

AREVA NP/Gary Wood (or Engineering Service Provider Name PO Number when document revision is prepared by an Engineering Service Provider)Prepared By: Date: Checked By: Date: Approved By: Date: Approved By Owner: 1. " Date: t1/.2 //2¢9o ("N/A", except when document revision is prepared, checked, and approved above by an En'gineering Service Provider)8. Inspections:

Status Codes = (A) Approved, (C) Approved Except as Noted, or (N) Not Approved Catawba Engineering McGuire Engineering Oconee Engineejing NGO Engineering/Other Inspected By Inspected By Inspected By Inspected By Group Status (Itiltip ate) Group Status (hliii Date) Group Status (Initial/Date)

Group Status (Initial/Date)

Elec: BI//r lee: "Elec: \A/ Elec: Mech: Mcch: Mech: _,/ Mech: Civil: Civil Civil: V/ Civil: Otherr ner: Other: V,( Other: 9. Revision

Description:

Vendor Issue of Rev. 3 in support of OD100066 and OD100067.10.VERIFY HARD COPY AGAINST WEB SITE IMMEDIATELY PRIOR TO EACH USE VERIFY HARD COPY AGAINST WEB SITE IMMEDIATELY PRIOR TO EACH USE Engineering Directives Manual VENDOR/DUKE MANUAL CERTIFICATION FORM (To be placed inside front cover of manual)EDM 130 Page 1 of 1 1. Station: Oconee Nuclear Station Unit: 1, 2, & 3 QA Condition:

I 2. Title: Teleperm XS Supplemental Equipment Qualification Summary Test Report 3. Duke File Number: OM 201.N--0021.017 Revision No: 3 Distribution Code: OEM-19N 4. Document Type (Check One): [ Vendor Manual Li Duke Manual.Manual Type (Check One): Li Instruction Book (I/B) [] Non-Instruction Book (Non-I/B)5. Vendor: AREVA, NP, Inc. For Vendor j- Manuals Only Vendor Document No: 66-50158/)3-03

6. Document Transmittal No. Date: For DCRM Use Only Manual File Copy (Check One): E Record I] Spare [E Distribution File Copy Proofed By: Date: 7. Sponsor Team/Sponsor Engineer:

AREVA NP Inc. PO 93336 / Gary D. Grizard (or Engineering Service Provider Name PO Number when document revision is prepared by an Engineering Service Provider)Prepared By: N 1/A Date: Checked By: 'V 14 Date: Approved By: A Date: Approved By Owner: Date: ("N/A", except when document revision is prepared, checked, and approved above by an Engineering Service Provider)8. Inspections:

Status Codes = (A) Approved, (C) Approved Except as Noted, or (N) Not Approved Catawba Engineering McGuire Enoineering Oconee Engineering NOO Engineering/Other s ected By Inspected By Inspected By Inspected By Group Status (Initial/Date)

Group Status (Initial/Date)

Group Status (Initial/Date)

Group Status (Initial/Date)-_ Elec: Elec: Mech: __ Mech: Mech: Meeh: Civil: Civil: Civil: Civil: Other: Other: Other:_Other:

9. Revision

Description:

Vendor Revision Issue per per OD 100066 and OD100067.

Revisions 0, 1 and 2 were not issued to ONS DCRM.10. Material Removed from Manual Material Inserted (Be Specific)(Include page numbers, locations, other identifying information) (Include page numbers, locations, other identifying information)

__a Complete issue of manual (including AREVA NP supplied certification page)VERIFY HARD COPY AGAINST WEB SITE IMMEDIATELY PRIOR TO EACH USE