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Category:REFERENCE SAFETY ANALYSIS REPORT & AMENDMENTS (RSAR)
MONTHYEARML20042E9171990-04-30030 April 1990 Amend G to C-E SAR Design Certification ML20011D5171989-12-15015 December 1989 Amend F to C-E Std SAR - Design Certification (CESSAR-DC). ML20248C3801989-03-30030 March 1989 App 3.11A, Environ Qualification for Structures & Components, to CESSAR Sys 80+ Std Design ML20247G6661989-03-30030 March 1989 Chapter 1, Introduction & General Plant Description, to CESSAR Sys 80+ Std Design.W/One Oversize Encl ML20247G6781989-03-30030 March 1989 Chapter 2, Site Envelope Characteristics, to CESSAR Sys 80+ Std Design ML20247G7141989-03-30030 March 1989 Chapter 3, Design of Structures,Components,Equipment & Sys, to CESSAR Sys 80+ Std Design ML20247G8511989-03-30030 March 1989 Chapter 4, Reactor, to CESSAR Sys 80+ Std Design ML20247G8621989-03-30030 March 1989 App 4A Sys 80 Reactor Flow Model Test Program, to CESSAR Sys 80+ Std Design ML20247G8681989-03-30030 March 1989 App 4B, Hot Loop Flow Testing of Sys 80 Fuel & Control Element Assembly Components, to CESSAR 80+ Std Design ML20247G9131989-03-30030 March 1989 Chapter 5, RCS & Connected Sys, to CESSAR Sys 80+ Std Design.W/Two Oversize Encls ML20247G9281989-03-30030 March 1989 App 5A, Overpressure Protection for C-E Sys 80 Pwrs, to CESSAR Sys 80+ Std Design ML20247G9831989-03-30030 March 1989 App 5B, Structural Evaluation of Steam Line Break for Steam Generator Internals, to CESSAR Sys 80+ Std Design ML20247G9891989-03-30030 March 1989 App 5C, Structural Evaluation of Feedwater Line Break for Steam Generator Internals, to CESSAR Sys 80+ Std Design ML20247H0331989-03-30030 March 1989 Chapter 6, Esfs, to CESSAR Sys 80+ Std Design.W/One Oversize Encl ML20247H2911989-03-30030 March 1989 Chapter 7, Instrumentation & Controls, to CESSAR Sys 80+ Std Design ML20247H3081989-03-30030 March 1989 Chapter 8, Electric Power, to CESSAR Sys 80+ Std Design ML20247H3361989-03-30030 March 1989 Chapter 10, Steam & Power Conversion Sys, to CESSAR Sys 80+ Std Design.W/One Oversize Encl ML20248C3921989-03-30030 March 1989 App 3.11B, Identification & Location of Mechanical & Electrical Safety-Related Sys Components, to CESSAR Sys 80+ Std Design ML20248B0021989-03-30030 March 1989 App 3A, Discussion of Finite Difference Analysis for Analysis of Pipe Whip, to CESSAR Sys 80+ Std Design ML20247J0591989-03-30030 March 1989 Chapter 18, Human Factors Engineering, to CESSAR Sys 80+ Std Design ML20247H4781989-03-30030 March 1989 Chapter 17, QA Program, to CESSAR Sys 80+ Std Design ML20247H4701989-03-30030 March 1989 Chapter 16, Tech Specs, to CESSAR Sys 80+ Std Design ML20247H4531989-03-30030 March 1989 App 15C, Analysis Methods for Steam Line Breaks, to CESSAR Sys 80+ Std Design ML20247H4431989-03-30030 March 1989 App 15B, Methods for Analysis of Loss of Feedwater Inventory Events, to CESSAR Sys 80+ Sys Design ML20247H4271989-03-30030 March 1989 App 15A, Loss of Primary Coolant Flow Methodology Description, to CESSAR Sys 80+ Std Design ML20247H4171989-03-30030 March 1989 Chapter 15, Accident Analyses, to CESSAR Sys 80+ Std Design ML20247H4031989-03-30030 March 1989 Chapter 14, Initial Test Program, to CESSAR Sys 80+ Std Design ML20247H3971989-03-30030 March 1989 Chapter 13, Conduct of Operators, to CESSAR Sys 80+ Std Design ML20247H3941989-03-30030 March 1989 Chapter 12, Radiation Protection, to CESSAR Sys 80+ Std Desing ML20247H3601989-03-30030 March 1989 App 11A, Core Residence Times, to CESSAR Sys 80+ Std Design ML20247H3531989-03-30030 March 1989 Chapter 11, Radwaste Mgt, to CESSAR Sys 80+ Std Design ML20247H3161989-03-30030 March 1989 Chapter 9, Auxiliary Sys, to CESSAR Sys 80+ Std Design. W/Four Oversize Encls ML20150B8181988-06-30030 June 1988 Amend C to CESSAR-DC ML20151H8191988-04-11011 April 1988 CESSAR-DC Submittal Group B - Revs to Chapters 1,4,5 & 9 ML20236W0531987-09-11011 September 1987 Amend 12 to CESSAR-F ML20054C1001982-03-31031 March 1982 Amend 7 to CESSAR-F ML20039D4701981-11-20020 November 1981 Amend 6 to CESSAR-F ML19350E0871981-06-15015 June 1981 Amend 3 to Chapter 4 of C-E CESSAR-F, Reactor. ML20003C2771981-02-20020 February 1981 Amend 1 to CESSAR-F 1990-04-30
[Table view] Category:TEXT-SAFETY REPORT
MONTHYEARML20210R2131997-05-31031 May 1997 Final Safety Evaluation Report Related to the Certification of the System 80+ Design.Docket No. 52-002.(Asea Brown Boveri-Combustion Engineering) ML20148A8211997-01-31031 January 1997 Abb System 80+ Design Control Document - Volume 1 ML20078Q4311995-02-28028 February 1995 Revs to Sys 80+ Design Control Document ML20080E2051995-01-0505 January 1995 Rev 2 to Technical Support Document for Amend to 10CFR51 Considering Severe Accidents Under NEPA for Plants of Sys 80+ Design ML20076F3301994-10-0707 October 1994 Rev 1 of Technical Support Document for Amends to 10CFR51 Considering Severe Accidents Under NEPA for Plants of Sys 80+ Design ML20069N4091994-06-20020 June 1994 System 80+ Certified Design Material ML20029E1991994-05-0606 May 1994 Technical Support Document for Amends to 10CFR51 Considering Severe Accidents Under NEPA for Plants of Sys 80+ Design. ML20062L8631993-12-31031 December 1993 Certified Design Matl ML20058E9971993-11-15015 November 1993 Amend T to C-E Std SAR - Design Certification. W/31 Oversize Figures ML20062J3551993-10-29029 October 1993 C-E Ssar - Design Certification,Amend S. W/15 Oversize Encls ML20058N1001993-09-23023 September 1993 Rev 2 to Design Alternatives for Sys 80+ Nuclear Power Plant ML20046B3621993-07-15015 July 1993 Session 3.7;Review of SG Tube Rupture Procedure at Borssele Nuclear Power Station. ML20045D3421993-06-30030 June 1993 Rev 1 to Design Alternatives for Sys 80+ Nuclear Power Plant. ML20045C4901993-06-30030 June 1993 Evaluation of Sys 80+ Std Design to Interfacing Sys LOCA Challenges, Special Rept ML20045C6351993-06-15015 June 1993 Amend P to Sys 80+ Cessar - Design Certification. ML20044G7061993-05-19019 May 1993 Common Mode Failure Evaluation for Limiting Fault Events. ML20059F4751993-03-29029 March 1993 Application of Advanced Full Scope Simulators to Severe Accident Precursor Training, Presented at 1993 Simulation Multiconference on 930329-0401 in Washington,Dc ML20044C0061993-03-17017 March 1993 ABB-C-E Sys 80+ Structural Analysis of Nuclear Island & Nuclear Annex Structures. ML20044B9411993-02-23023 February 1993 Rev 0 to Human Factors Evaluation & Allocation of Sys 80+ Functions. ML20012G3351993-02-16016 February 1993 Sys 80+ Advanced LWR PRA-Based Seismic Margin Evaluation. ML20127M4171993-01-15015 January 1993 Control Complex Info Sys Bases for Nuplex 80+ ML20126F6771992-12-0808 December 1992 Review of CE 80+ FMEA & D&Did Analysis, Technical Ltr Rept ML20126J0521992-10-30030 October 1992 Amend K to C-E Std SAR - Design Certification ML20126E6191992-10-30030 October 1992 Amend K to CESSAR - Design Certification. W/50 Oversize Encls ML20012G3361992-09-30030 September 1992 Draft Basis for Seismic Provisions of UCRL-15910. ML20114F5611992-09-30030 September 1992 Evaluation of Defense-in-Depth & Diversity in ABB-C-E Nuplex 80+ Advanced Control Complex for Sys 80+ Std Design ML20104A8501992-09-0202 September 1992 Sys 80+ Design Certification PRA Flood Protection Assessment ML20104A8551992-09-0202 September 1992 Sys 80+ Design Certification Fire Hazard Risk Assessment LD-92-095, Draft Sys 80+ Design Certification Piping Analysis Specification1992-08-31031 August 1992 Draft Sys 80+ Design Certification Piping Analysis Specification ML20101S7281992-07-31031 July 1992 Criteria for Design of Main Control Room & Other Operating Stations for Sys 80+ ML20099D8031992-07-31031 July 1992 Final Sys 80+ Shutdown Risk Evaluation Rept ML20099D8301992-07-25025 July 1992 Draft Sys 80+ Design Certification Distribution Sys Design Guide ML20101G5261992-06-15015 June 1992 Draft Sys 80+ Shutdown Risk Evaluation Rept ML20097A1251992-05-31031 May 1992 Human Factors Engineering Stds,Guidelines & Bases for Nuplex 80+ ML20096F7271992-05-0808 May 1992 Nuplex 80+ Human Factors Design Process Summary ML20095L5041992-04-30030 April 1992 Draft Sys 80+ Shutdown Risk Evaluation Rept, Part 1 ML20095J2321992-04-30030 April 1992 Rev 0 to Design Alternatives for Sys 80+ Nuclear Power Plant ML20095A9601992-04-15015 April 1992 Selection of Control Motion for ABB-C-E Sys 80+ Std Design ML20090K4851992-03-12012 March 1992 QA Program Topical Rept LD-92-031, Marked-up Copy of QA Program Topical Rept1992-03-12012 March 1992 Marked-up Copy of QA Program Topical Rept ML20094E9431992-02-11011 February 1992 LOCA Aspects of C-E Advanced LWR - Sys 80+ ML20079C9641991-06-13013 June 1991 Description of Nuclear QA Program ML20043H2201990-05-18018 May 1990 Seminar on Use of Unusual Event Repts for Improving Nuclear Power Plant Safety. ML20042E9171990-04-30030 April 1990 Amend G to C-E SAR Design Certification ML20106D7341990-01-15015 January 1990 Nuplex 80+ Advanced Control Complex Design Bases ML20096F4761989-12-31031 December 1989 Nuplex 80+ Rev 2 to Verification Analysis Rept ML20011D5171989-12-15015 December 1989 Amend F to C-E Std SAR - Design Certification (CESSAR-DC). ML19324B6831989-10-31031 October 1989 QA Program:Description of Nuclear Power Businesses QA Program, Rev 5 NUREG-1044, Sser Supporting Vendor Responses to Confirmatory Item 1, Shutdown Cooling Sys1989-08-0404 August 1989 Sser Supporting Vendor Responses to Confirmatory Item 1, Shutdown Cooling Sys NUREG-0852, Sser Supporting Vendor Responses to Confirmatory Issue 2, Steam Generator Tube Rupture. Calculated Radiological Consequences of Postulated Steam Generator Tube Rupture Accident Meets 10CFR100.11 Dose Ref Values1989-08-0404 August 1989 Sser Supporting Vendor Responses to Confirmatory Issue 2, Steam Generator Tube Rupture. Calculated Radiological Consequences of Postulated Steam Generator Tube Rupture Accident Meets 10CFR100.11 Dose Ref Values 1997-05-31
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CESSAR 8HWicario.
O APPENDIX SC STRUCTURAL EVALUATION OF FEEDWATER LINE BREAK FOR STEAM GENERATOR INTERNALS O
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,' APPENDIX SC STRUCTURAL EVALUATION OF FEEDWATER LINE BREAK FOR STEAM GENERATOR INTERNALS
. ABSTRACT This report documents the structural adequacy of Combustion Engineering's (C-E's) System 80+ ALWR steam generator internals D to withstand a feedwater line break.
The economizer divider plate, support cylinder, cold leg flow distribution plate and feedwater box are subjected to a hypothetical feedwater line break during 100% power operation.
The resulting stresses in the structures are compared to ASME Boiler and Pressure Vessel Code,Section III allowables to i determine their acceptance. l l
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EFFECTIVE PAGE LISTING APPENDIX 50 Table of Contents Egga Amendaient Abstract D i D 11 D 1RKt East Amendment SC-1 D SC-2 D O- Tables Amendment SC-1 D SC-2 D O
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TABLE OF CONTENTS APPENDIZ 5C Section Subiect Pace No.
1.O INTRODUCTION 5C-1 2.0 ANALYSIS SC-1 2.1 DISCUSSION SC-1 2.1.1 HYDRODYNAMIC ANALYSIS SC-1 2.1.2 STRUCTURAL EVALUATION SC-1 D
2.2 CONCLUSION
S SC-2
3.0 REFERENCES
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LIST OF TABLES APPENDIX SC Table subiect SC-1 Peak Pressure Loads SC-2 Comparison of SYSTEM 80 Margins to Anticipated 0 SYSTEM 80+ AIMR Margins l
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w 1.0 INTRODUCT. ION The hydraulic loadings on the steam generator internals resulting from the rupture of one 14.0 inch I.D. feedwater nozzle are calculated using the CEFLASH computer code to perform the thermohydrodynamic analysis of the accident. The structural analysis of the system 80+ ALWR steam rienerator internal parts which are significantly loaded by the Feedwater Line Break (FLB) D accident, as established by the above CEFLASH analysis, is accomplished by adjusting the stresses calculated for the System 80 steam generator by the differences in pressure loadings hnd size of the parts. The results of these adjustments show that the expected margins of safety for the System 80+ ALWR steam generator are greater than the margins for the System 80 steam generator.
2.0 ANALYSIS 2.1 DISCUSSION 2.1.1 HYDRODYNAMIC ANALYSIS p The hydrodynamic analysis to establish hydraulic pressure loads on the steam generator internals is performed using the CEFLASH computer code. Details of this analysis are given in Reference
- 1. The analysis is done for the 100% power conditions. Pressure l loadings for the FLB accident at 100% power are given in Table SC-1. The basic assumptions for the FLB hydrodynamic analysis are:
A. Rupture of one 14.0 inch feedwater inlet nozzle.
B. A break opening time of .001 seconds based on a mechanistic D analysis of slot ruptures.
C. A Moody critical flow correlation with a discharge coefficient of 1.0.
2.1.2 STRUCTURAL EVALUATION The structural evaluation of the System 80+ ALWR steam generator internals is based on the structural analysis of the System 80 steam generator internals presented in References 2 and 3. The following internal parts are considered to be significantly loaded and are evaluated. !
- 1. Feedwater Box
- 2. Economizer Divider Plate l
- 3. Flow Distribution Plate '
() 4. Support Cylinder Amendment D SC-1 September 30, 1988 )
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The basis of evaluation and comparison is the margin of allowable stress for the System 80 and System 80+ ALWR steam generators.
The margin is calculated as the percentage of remaining allowable j stress, or: {
l g, ,
fAllowable Stress - Calculated Stress 1 X 100 Allowable Stress The allowable stress is the elastic allowable stress as defined The margins for the System 80+
in the ASME Code,Section III.
ALWR steam generator are based on adjustments of the calculated System 80 stresses by the ratios of hydraulic pressure loading and part size. A comparison of the margins is given in Table 5C-2. Materials for the parts of the System 80+ ALWR generator {
are the same as materials for the System 80 generator. !
l 2.2 CONCLU8 IONS The results of the evaluation, which are given in Table SC-2, show that the anticipated margins of the parts for the System 80+
ALWR steam generator are larger than the calculated margins for the System 80 steam generator. The smallest anticipated margin for the System 80+ ALWR generator is 53% for the flow distribution plate. Thus, the feedwater box, economizer divider plate, flow distribution plate, and support cylinder are considered to be adequately designed to withstand a hypothetical 0 Feedwater Line Break. l
3.0 REFERENCES
- 1. Combustion Engineering Calculation, ST-801, Icads for i Feedwater Line Break, July 1988. l
- 2. Systela 00, CESSAR FSAR, Appendix SC, Amendment No. 7, March 31, 1982. ,
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- 3. Combustion Engineering Report No. CENC-1479, Analytical Report for Arizona Public Service Company, Palo Verde Unit No. 3 Steam Generators, August, 1981.
- 4. ASME Boiler and Pressure Vessel Code, Section III for l Nuclear Vessels.
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V TABLE SC-1 PEAK PRESSURE LOADS 100% Power AP Time Location (osi) (sec) Direction Feedwater Box 588 .015 Downward Top of Divider Plate 15.2 .007 Toward Economizer Bottom of Divider Plate 62.0 .007 Toward Economizer Flow Distribution Plate 18.4 .013 Downward D
Shroud Hot Leg 7.4 .055 Tension
-6.5 .148 Compression Shroud cold Leg 10.0 .018 Tension
-21.0 .050 Compression J
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V TABLE 5C-2 COMPARISON OF SYSTEM 80 KARGINS TO ANTICIPATED SYSTEM 80+ ALWR MARGINS Anticipated System 80+
stress Allowable systen 80 ALWR 1
__ Part Catecory Stress Marcin (%) Marcin (%) l Feedwater Box PM+PB 73.5 53.5 65.0 Economizer Divider Plate PM+PB 73.5 43.5 56.0 Economizer Divider D Plate Lug PM+PB 58.7 15.5 83.0 Flow Distribution Plate PM+PB 67.6 43.2 51.0 b Support Cylinder PM+PB I
( j 67.6 84.4 88.0 l
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Volume 6 comausnon)suciassnima