{{#Wiki_filter:[A..w#0834 Department of Energy Clinch River E$reeder Reactor Plant Project Office PO. Box U Oak Ridge, Tennessee 37830 DocKct No. 50-537 File: 05.10 lune 29,1979 Mr. Domenic B. Dassallo Acting Director Division of Project Management Office of Nuclear Reactor Regulation U. S. Nuclear Regulatory Commission Washington, D. C.

20555  

AMENDMENT NO. 50 TO THE PRELIMINARY SAFETY ANALYSIS REPORT FOR CLINCH RIVER BREEDER REACTOR PLANT The application for a Construction Permit and Class 104(b) Operating 9 License for the Clinch River Breeder Rcactor Plant, docketed April 10, 1975, in NRC Docket No. 50-537, is hereby amended by the submission of Amendment No. 50 to the Preliminary Safety Analysis Report pursuant to 50.34(a) of 10 CFR Part 50.

This Amendment No. 50 includes: an update to Section 9.9.2, " Emergency Plant Service Water System"; an update to Chapter 13, " Conduct of Operations"; and other updates and revisions, as well as a response to NRC's request for additional information contained in a letter dated August 17, 1976.

A Certificate of Service, confirming ser vice of Amendment No. 50 to the PSAR upon designated local public officials and representatives of the EPA, will be filed with your office after service has been mde.

inree signed originals of this letter and 97 copies of this amendment, each with a copy of the submittal letter, are hereby submitted.

Since ly, 4 a~,ond Cop ar l PS:79:161 A ing Assis Directo for Public afety Enclosure'){g]g cc: Service List SUBSCRIBgand SWORN to before me E Standard Distribution this if day of June, 1979.

9 Licensing Distribution A , W&&!, k 0Vlf/-L Not yfPQblic Ccmmission Emp;res May 21,1980 7 13 STAfiDARD DISTRIBUTI0il Mr. R. Balent (2)

Mr. W. W. Dewald, Project Manager (2)

Vice President and General Manager CRBRP Reactor Plant Atomics International Division Westinghouse Electric Corporation Rockwell International Advanced Reactors Division P. O. Box 309 P. O. Box 158 Canoga Park, CA 91304 Madison, PA 15663 Mr. Michael C. Ascher (2)

Project Manager, CRBRP Mr. C. R. Adams (1)

Resident Manager, CRBRP 700 Kinderkamack Road Burns and Roe, Inc.

Oradell, flJ 07649 P. O. Box T

'f!r. Lochlin W. Caffey (2)

Director fir. George G. Glenn, Manager (2)

Clinch River Breeder Reactor Plant Clinch River Project P. O. Box U General Electric Company Oak Ridge, Til 3783)P. O. Box 5020 Sunnyvale, CA 94086 Mr. Dean Armstrong (2)

Acting Project Manager, CRBRP Mr. Hardy B. Adams, Jr. (2)

Stone & Webster Engineering Corp.

Projects Manager, LMFBR Programs 9 P. O. Box 811 Tennessee Valley Authority Oak Ridge, Til 37830 1300 Commerce Union Bank Building Mr. Don E. Erb (1)

Acting Assistant Director for Reactor Projects Division of Reactor Research and Technology U. S. Department of Energy Washington, DC 20545 Mr. Harold H. Hoffman (1)

Site Representative U. S. Department of Energy Westinghouse Electric Corporation Advanced Reactors Division P. O. Box 158 Madison, PA 15663 Mr. J. E. fiolan (2)

Project ifanager, CRBRP

/68 iUu,, s, Westinghouse Electric Corporation Advanced Reactors Division P. O. Box W Oak Ridge, Til 37830 4/19/79 LICEriSIllG DISTRIBUTI0ft fir. Itugh Parris fianager of Power Tennessee Valley Authority 830 Power Building Chattanooga, Til 37401 Mr. R. M. Li ttle Electric Power Research Institute 3412 ilillview Avenue Palo Al to, CA 94303 Dr. Jeffrey 11. Beoido, Manager Analysis and Safety Department Gas Cooled Fast Reactor Program P. O. Box 81608 San Diego, CA 92138 9 ,C ,U.,l \J )'

SERVICE LIST

%Atomic Safety & Licensing Board Anthony Z. Roisman, Esq.

U. S. thclear Regulatory Commisgion flatural Resources Defense Council Washington, D. C.

20555 91715th Street, IN Washington, DC 20036 Atomic Safety & Licensing Board Panel U. S. f'uclear Regulatory Commission Dr. Cadet H. Hand, Jr. , Director Washington, D. C.

20555 Bodega Marine Laboratory University of California S. Wallace Brewer, Judge P. O. Box 247 Office of County Judge Bodega Bay, CA 94923 Roane County Court House Kingston, Yft 37763 Lewis E. Hallace, Esq.

Division of Law Dr. Thomas Cochran Tennessee Valley Authority flatural Resources Defense Council, Inc.

Knoxville, T!i 37902 917 15th Street,fiW 8th Floor Washington, DC 20005 Docketing & Service Station Office of the Secretary

@U. S. fluclear Regulatory Commi.ssion Washington, DC 20555 Counsel for flRC Staf f U. S. fiuclear Regulatory Commission

!!ashington, DC 20555 William B. Hubbard, Esq.

Assistant Attorney General State of Tennessee Office of the Attorney General 422 Supreme Court Building f!ashville, Tf1 37219 Mr. Gustave A. Linenberger Atomic Safety & Licensing Board U. S. f uclear Regulatory Commission Washington, DC 20555 Marshall E. Miller, Esq, Chairman Atomic Safety & Licensing Board U. S. fluclear Regulatory Commission Washington, DC 20555 Luther M. Reed, Esq.

Attorney for the City of Oak Ridge

') 6 p']'G 253 Main Street, East

"" Oak Ridge, Tri 37830 Amendment 50 Clinch River Breeder Reactor Plant Preliminary Safety Analysis Report (Docket No. 50-537)

This fiftieth amendment to the Clinch River Breeder Reactor Plant Preliminary Saiety Analysis Report includes updates to sections describing the Emergency Plant Service Water System and Conduct of Oper-ations, other updates and revisions as well as responses to .*4RC's request for additional information.

Vertical margin lines on the left hand side of the page are used to identify new design information while lines on the right hand side of the page identify question / response information.

NRC Ques. No.011.23 200}!

Transmitted herein is Amendment 50 to the Clinch River Breeder Reactor Plant Preliminary Safety Analysis Report, Docket No.

50-537.Amendment 50 cot.sists of new and replacement pages for the PSAR text and question / response supplement pages.

The following attached sheets list Amendment 50 pages and in-structions for their incorporation into the Preliminary Safety Analysis Report.e n a i .a-Amer.dment 50 Page Replacement Guide RemcVe These Pages In_ sert These Pages Chapter 3 3.8-1, la 3.P-1, la 3.8-3, 3a 3.8-3, 3a 3.8-42 thru 3.8-47a 3.8-42 thru 3.8-47a Chapter 4 4-iib, iic 4-iib, iiba, iic 4-xv, xva 4-xv, xva 4-xvii, xviia, xviii 4-xvii, xviia, xviii 4-xxi, xxia, xxii 4-xxi, xxia, xxii 4.2-95, 95a 4.2-95, 95a 4.2-ll5d, llSe 4.2-ll5d, ll5e 4.2-3280 4.2-328d Chapter 5 (5.4-12 5.4-12 5.6-6a, 7 5.6-6a, /5.6-20, 21 5.6-20, ?i 5.6-34, 34a 5.6-34, 34a Chapter 6 6.2-27d, 27e 6.2-27d, 27e 6.3-lb, 2, 2a, 2b 6.3-2, 2a Chapter 7 7-ix, x 7-ix, x 7.1-17, 18 7.1-17, 18 1.2-77, 78 7.2-77, 78 7.5-7, 8 7.5-7, 8 7.5-15, 16 7.5-15, 16 7.5-26, 27, 27a, 28, 29, 30 7.5-26 thru 7.5-30 7.5-33b, 33c 7.5-33b, 33c, 33d 7.5-34, 35 7.5-34, 35 7.5-42 7.5-42 7.6-3, 3a, 3b, 3c 7.6-3, 3a, 3b, 3c 2bf3 1''A I IJ Remove These Pages Insert These Pages Chapter 9 9.1-13, 14 9.1-13, 14 9.2-3, 3a 9.2-3, 3a 9.2-7, 8, 8a, 8b, 9 9.2-7, 7c, 8, 9, 9a 9.3-12, 13 9.3-12, 13 9.5-3, 4 9.5-3, 4 9.5-7, 8 9.5-7, 8 9.6-65, 66 9.6-65, 66 9.6-84 9.6-84 9.6-87 9.6-87 9.6-92 9.6-92 9.8-1 thru 9.8-6 9.8-1 thru 9.8-6 9.8-7, 7a, 8, 9, 10, 11

: 9. 8-7, 7a , 8, 9, 10, 11 9.8-14, 15 9.8-14, 15 9.9-1 thru 9.9-16 0 91 thru 9.9-16 9.9-18, 19 9.9-18, 19 9.13-11, 12 9.13-11, 12

-9.13-46a Chapter 11 ll-i thru ll-x ll-i thru ll-x

-11.1-24, 25 11.1-24, 25 O.1-11.2-1, 2 11.2-1, 2 11.2-12, 13 11.2-12, 13

: 11. 2- 31 11.2-31 11. 3-1 thru 11.3-6 11.3-1 thru 11.3-6 11.3-9 thru 11.3-12 11.3-9, 10, ll, lla, 12 11.3-15, 16 11.3-15, 16 ll . 3-18a ,18b ,18c ,19, 20, 21 ll.3-18a, 18b, 18c, 19, 20, 21 11.3-24 thru 11.3-33 11.3-24 thru 11.3-33 11.3-36 thru 11.3-39 11.3-36 thru 11.3-39 ll.3-39c, 40, 41, 42 ll.3-39c, 40, 41, 42 11.3-49, 50, 51, 52 11.3-49 11.4-3, 4 11.3-3, 3a, 4 11.4-12, 13 11.4-12, 13 ll.5-6b, 7 ll.5-6b, 7 Chapter 12 12-i thru 12-ix 12-i, ii, iia, iii, thru ix 12.1-37 12.1-37 12.1-65a, 65b, 65c 12.1-65a, 65b, 65c 12.1-78, 79 12.1-78, 79 12.2-16, 17, 18

-12.3-11 thru 12.3-16 12.3-11 thru 12.3-16 268 ii/;B R_emove lhese Pages Insert These Pages Chapter 13 13-i thru 13-vii 13-i, ii, iii, iiia, iv thru vii 13.1-1 thru 13.1-22 13.1-1 thru 13.1-21 13.2-1 thru 13.2-7 13.2-1 thru 13.2-7 13.3-1 thru 13.3-8 13.3-1 thru 13.3-21 13.5-3, 4, 5 13.5-3, 4, 5 13.7-1 thru 5, Sa, 6 thru 10

: 13. 7-1 thru 10,10a ,10b Chapter 15 15.5-20, 21 15.5-20, 21

: 15. 7-11, 12, 13, 13a 15.7-11, 12, 13 Chapter 16 16.2-2 16.2-2 268 1i5 C O Amendment 50 Question / Response Supplement The Question / Response Supplement contains an Amendment 50 tab to be inserted following page Q-i (Amendment 49, April 1979).

Page Q-i (Amendment 50, June 1979) is to follow the Amendment 50 tab.

NRC Ques. No.011.23 (1)

Remove These Pages Insert These Pages Q001.301-1 Q001. 301 -1 Q001.581-8 thru 11 Q001. 581 -8, 9, 10, 10a , 11 Q001. 581 -14, 15 0001.581-14, 14a, 15 Q222.77-1 Q222.77-1 Q310.3-1, 2 Q310.3-1, 2 Q331.20-1 Q331.20-1 Q422.1-1 thru 8 Q422.1-1, 2 Q422.2-1 thru 8 Q422.2-1, 2 Q422.3-1 Q422.3-1 200}}6 D 3.8 DESIGN OF CATEGORY I STRUCTURES 3.8.1 Concrete Containment (Not Applicable) 3.8.2 Steel Containment System 3.8.2.1 Description of the Containment The Containment Vessel is a low leakage, free-standing, all welded steel vessel anchored to the base mat with a steel lined concrete bottom in the form of a vertical right cylinder having an inside diameter of 186 feet and with side walls extending approximately 169 feet from the flat bottom liner at the case to the spring line of the ellipsoidal-45 spherical dome.

The cylindrical shell is embedded in concrete up to the 47 elevation of the operating floor.

On the inside of the Containment Vessel, there is the continuous reinforced concrete wall comprising the peripheral boundary of the internal concrete structure.

Butting against .

the outside face of the steel shell from elevation 733 feet cp tc the 45l elevation of the underside of the operating floor, there is another rein-forced concrete wall of sufficient thickness designed to prevent bucklinc 45lof the steel shell.

Neither of the two concrete walls are considered part of the containment vessel. Alumina-silica insulation is attached 33 to the inside surface of the Containment Vessel from elevation 816 feet to elevation 823 feet.

The insulation is 3 inches thick and has a value of 0.0267 Btu /hr - ft OF.

Its purpose is to limit the shell temperagure 48 at elevation 816 feet during Design Basis Accidents to less than 130 F.

The vessel includes:

its shell, a (" bottom liner plate, one 45 access airlock, one emergency egress airlock, vacuum relief system, one equipment hatch, penetrations, inspection ladders, miscellaneous appur-tenances and attachments.

The configuration of the Containment Building is shown in figures in Section 1.z.

~ ' design lifetime of the contai-39 ment vesc^1 shall be 30 years.

3.8.2.2 Applicable Codes, Standards and Specifications 3.8.2.2.1 Codes The Containment Vessel will be designed, material procured, fabricated, installed and tested in accordance with the requirements of the ASME B&PV Code, Section III, Division 1, 1974 Edition with Addenda through Winter 1974 and Code cases 1713,1714,1809,1682 and 1785 and 50 43 ASME-III, Division 2, 1975 Edition, Subsection cc, for the steel lined concrete containment bottom.

The design shall also meet the requirements of the Class MC Section of RDT Standard E15-2T, " Requirements for Nuclear Components".

2, 0 0 l ,l _,, , 3.8-1 Amend. 50 June 1979 O The quality assurance procedures will be in accordance with RDT Standard F2-2 as well as meeting the requirements of the ASME Code, 1 45 i Section III, divisions 1 an d 2.

@3.8-la Amend. 48 Feb. 1979 Tolerances The Containment Vessel as constructed shall not exceed the tol-erance requirements of NE-4000 of ASME-III for fabrication or erection. The dimensional control procedures shall meet the require-roents of RDT STD F3-15T.

1.11-Instrument Lines Penetrating Primary Reactor Cor,tainment 45 (March 10,1971) 1.12: Instrumentation for Earthquakes (Revision 1, April,1974) 1.15: Testing of Reinforcing Bars for Category 1, Concrete Struc-tures (Revisionl, December 28,1972) 1.19: Nondestructive Examination of Primary Containment Liner Welds (Revision 1, August 11,1972)

Et 1.29: Seismic Design Classification (Revision 2, August 197 6) 1.55: Concrete Placement in Category 1, Structures (June 1973) 1.57: Design Limits and Loading Combinations for Metal Primary 45 Reactor Containment System Components ( June, 1973) 1.60: Design Response Spectra for Seismic Design of Nuclear Power Plants (Revision I . December,1973) 1.61: Damping Values for Seismic Design of Nuclear Power Plants 45 (Oct.1973) 1.63: Electric Penetration Assemblies in Containment Structures for Water-Cooled Nuclear Power Plant: (Oct. 1973)

SC 1.85.Materials Code Case Acceptability - ASME Section Ill m

, , Division 1, 1976

/ D 0 l ,l b, 45 1.92: Combining Modal Responses and Spatial Components in Seismic Response Analysis (Revision 1, Feb., 1976)

Amend. 50 June 197f 3.8-3 O Of the above, Regulatory Guide 1.63 is applicable after the following changes:

1.Deleting " Water-cooled" wherever it appears.

2.Replacing "Aprendix B to 10 CFR Part 50" wherever it appears with "RDT Standard F2-2".

3.Replacing " General Design Criterion 50 of Appendix A to 10 CFR Part 50" wherever it appears with "CRBRP GDC 50".

4.Replacing " loss of coolant accident" with " containment design basis accident".

S.Substituting "(Sunme.1972 Addenda)" following".

..ASME Boiler and Pressure Vessel Code" with ",1974 Edition".

O Amend. 45 July 1978 3.8-3a  

"._...(v-._-_: ,...'1 FI_ED_'79nn ozo i 9 \

, NO. OF PAGES 7 O DUPL!CATE: ALREADY ENTERED INTO SYSTEM UNDER ANO.

/O'lLLEGIBLE:

HARD COPY AT:

O PDR O CF 0 OTHER 268 119 TABLE OF C0flTENTS Continued Page No.34\4. 2. 2.1. 2. 9 Removable Radial Shielding (RRS) 4.2-95a 4.2.2.1.3 Design Loading 4.2-97 44f34 4.2.2.1.3.1. Core Support Structure 4.2-98 4.2.2.1.3.2 opper Internals Structure (UIS) 4.2-101 4 . '' . 2 . 2 Design Description 4.2-105 4.2.2.2.2.1 Reactor Internals Structures 4.2-105 44l4.2.2.2.2.1.1 Core Support Structure

: 4. 2-10S a 4.2.2.2.1.2 Inlet Module 4.2-107a 4.2.2.2.1.3 Bypass Flow Module 4.2-108! 4.2.2.2.2.1.4 Fixed Radial Shield

: 4. 2-108 a 44 4.2.2.2.1.5 Fuel Transfer and Storage Positions 4.2-109 4.2.2.2.1.6 Horizontal Baffle 4.2-109 44l4.2.2.2.1.7 Upper Internal Structure 4.2-111 4.2.2.2.1.8 Core Restraint System 4.2-113 44l4.2.2.2.1.9 Removable Radial Shield 4.2-114 4.2.2.2.1.10 Maintainability 4.2-114 34<4.2.2.2.1.11 Surveillance and In-Service Inspection Surveillance 4.2-114 4.2.2.3 Design Criteria 4.2-114 4.2.2.3.1 Lower Internals Structures (LIS) 4.2-115 4.2.2.3.1.1 Core Support Structure 4.2-115 4.2.2.3.1.2 Lower Inlet Module (LIM),B pass Flow Module (BPFM), 4.2-115 and Core Former Structure CFS) 4.2.2.3.1.3 Horizontal Baffle (HB), Fuel Trans'ar & Storage 4.2-115 Assembly (FT&SA), and Fixed Radial Shield (FRS) 50 4.2.2.3.2 Upper Internals Structure (UIS) 4.2 -l l 5a 268 120 Amend. 50 4-iib June 1979 TABLE OF CONTENTS Continued Page No.4.2.2.3.2.1 Class 1 Appurtenances 4.2-ll5a 4.2.2.3.2.2 Internal Structure 4.2 -ll 5a 4.2.2.3.3 Additional Material Properties 4.2-llSe 4.2.2.3.3.1 Inconel 718 Fatigue Properties 4.2-ll5e 4.2.2.3.3.2 Environmental Effects on Material Properties 4.2-ll5f 50 4.2.2.3.3.2.1 Sodium Effects 4.2-ll5f O} h'b\Amend. 50 June 1979 4-iiba TABLE OF C0flTENTS Continued

.Page No.4.2.2.3.3.2.2 Irradiation Effects 4.2-Il7a 4.2.2.3.3.3 Friction, Ucar, and Self Welding Considerations 4.2-Il7a 4.2.2.4 Evaluation 4.2-ll7c 4.2.2.4.1 Lower Internals Structure Summary 4.2-ll7c 4.2.2.4.1.1 Analysis of Core Support Structure (CSS) 4.2-118 4.2.2.4.1.2 Analysis of Lower Inlet Module (LIM) 4.2-130 4.2.2.4.1.3 Analysis of Bypass Flow Modules 4.2-131 4.2.2.4.1.4 Analysis of the Fixed Radial Shielding 4.2-132 4.2.2.4.1.5 Analysis of the Fuel Transfer and Storage Assembly 4.2-132 4.2.2.4.1.6 Analysis of the Horizontal Baffle 4.2-132 4.2.2.4.1.7 Upper Internal Structure 4.2-132 4.2.2.4.1.7.1 Summary of Results 4.2-132 4.2.2.4.1.7.2 Material Properties 4.2-133 4.2.2.4.1.8 Core Restraint System Analysis 4.2-146 4.2.2.4.1.8.1 Summary of Resul ts 4.2-146 4.2.7.4.1.8.2 Material Properties 4.2-146 4i. l4.2.2.4.1.8.3 Analysis of Assembly Bowing and Duct Dilation 4.2-146a 34 4.2.2.4.1.9 Remo.able Radial Shielding (RRS) 4.2-150 4.2.2.5 Welding and Seizing of Reactor Internal Parts 4 .2 -1 51 4.2.3 Reactivity Control Systems 4.4-151 4.2.3.1 Design Casis J.4-152 n ra ety Design CrH_eria L 2-152 34..4.2.3.1.2 Control Rod System Clearances 4.2-153 4.2.3.1.3 Mechanical Insertion Requirements d.2-153 rg'; 22 4 ?-159b 4.2.3.1.4 Positioning Requirements 4.2.3.1.5 Structural Requirements 4.2-160 4.2.3.1.6 Envi ronmen tal Requi remen ts 4.2-165 4-iic Amend. 44 April 1978 LIST OF FIGURES Continued Figure No.

Page No.50l4.2-46 Core Fonner Structure

: 4. 2-328 d 4.2-47 Limited Free Bow Core Restraint Conc e '.

4.2-329 4.2-48 4.2-330 ylDesign Fatigue Curve for Nickel-Chrcaium Alloy 713 , 4.2-48A Corrosion Rate of Types 304 arid 316 /:ainless 4.2-330a Steel in Flowing Sodium 4.2-483 Corrosion Rate of Inconel 718 in Sodium 4.2-330b 4.2-48C Design Factor for Estimating the Decrease in 4.2-330c Rupture Strength of Type 300 and 316 Stainiess Steel from Surface Interactions with Sodium 4.2-48D Carbon Equilibrium Values for Type 304 and Type 4.2-330d 316 Stainless Steel as a Function of Temperature 4.2-48E Curve for Determining Averace Type 304 and 316 4.2-330e Stainless Steel Interstitial Concentration as a Function of Sodium Exposure Time and Component Thickness 4.?-48F Diffusion Coefficients for Carbon in Type 304 and 4.2-330f Type 316 Stainless Steel 4.2-48G Calculation of Stress-Strain Curves for Type 304 4.2-3300 and 3i6 Stainless Steel 4.2-48" Calculation of Interstitial Gradients in Sodium-4.2-330h Exposed Austenetic St,inless Steel 4.2-48I Effect of Carbon and Ni vogen Concentration on the 4.2-330i Fatigue Strength of Type '16 Stainless Steel at Room Temperature 4.2-48J Rupture Strength Design Allowances for Interstitial 4.2-330j Transfer Effects in Type 304 and Type 316 Stainless Steel 4.2-48K Effect af Carbon Conceneration on the Fatigue 4.2-330k Strenr,th of Type 316 Stainless Steel at 1200 F 44 1 4.2-49 CSS / Reactor Vessel Stress Evaluation Locations 4.2-331 4.2-50 Core Support Structure (CSS) Concept 4.2-332 4.2-51 CSS Geometry Used in Analytical Model 4.2-333') h y'13~L-J t L_ J 4-xv Amend. ';0 June 1979 LIST OF FIGURES Continued O Figure No.

Page No.4.2-52 Minimum Ligament Section in the Core Support Plate 4.2-334 4.2-335 4.2-53 CSS Ligament Models 4.2-54 CSS / Reactor Vessel Axisymmetric Model with Heat 4.2-336 Transfer Boundaries Identified 4.2-337 4.2-55 Comparison of RV-lE and RV-4E Thernal Transients 4.2-338 4.2-56 Displacement Plot for Unit Design t,P's 4.2-57 Displacement Plot for Dead Weight ,oads 4.2-339 4.2-58 Displacement Plot Due to Lateral SSE Loads 4.2-340 4.2-59 Design Fatigue Curve for 304 Stainless Steel 4.2-341 4.2-60 Cone Geometry used in Buckling Analysis 4.2-342 4.2-61 Lower Inlet flodule Wall Structural flodel 4.2-343 4.2-62 Coolant Screen and Header Model 4.2-344 4.2-345 4.2-63 Receptacle Model 4.2-63A One-Eighth BMFM 3-D Finite Element Thermal flolded Geometry 4.2-345a 4.2-638 BPFM Critical Sections in the One-Eighth B?Fri 3-D 44 Finite Element Stress flodule 4.2-345b 4.2-346 4.2-64 Duty Cycle-535 Trips 4.2-347 Creep / Fatigue Damage in Ir.conel 718 (Thickness =

4.2-65 6 inches) RV-IU Transient 4.2-348 Striping Evaluation (200 F Stream-to-Stream t.T) 4.2-66 , , .2bO i i 4-xva Amend. 44 April 1978 LIST OF FIGURES (Continued)

Figure No.

Pa_ge No.4.2-87 Equilibirium Cycle Assembly Two-Dimensional 4.2-369 Temperature and Flux Distributions at Core Midplane 4.2-87a Illustration of Effects of Core Thennal 4.2-369a and Flux Gradients in Radial Blanket Rea (not to scale) 4.2-88 Assembly Bows and Interface Loads at Start of 4.2-370 First Cycle at Operating Temperatures 4.2-89 Assembly Bows and Interface Loads at End of 4.2-371 First Cycle 4.2-90 Assembly Bow and Interface Loads at End of 4.2-372 First Cycle at Refueling Temperature 4.2-91 Assembly Bow and Interface Loads at End of 4.2-373 Second Cycle Operating Temperature 4.2-92 Assembly Bow and Interface Loacs at End of 4.2-374 Second Cycle Refueling Temperature 4.2-92a Bowing Displacements and Reactivity. Change versus 4.2-374a Power to Flow Ratio 4.2-92b Bowing Reactivity versus Power to Flow Ratio for 4.2-374b 44'Various Analysis Assumptions 4.2-93 Control Rod Systems Scram Insertion Pequirements 4.2-375 4.2-93a Calculated Axial Profile of B C Captures in the 4.2-375a 4 34 Secondary Control Assembly 4.2-94 Secondary Control Rod System Scram Insertion 4.2-376 Requi remen t.

4.2-95 Deleteo 4.2-377 4.2-95a Control Rod System Maximum Misalignment Sources 4.2-377a 4.2.95b Control Rod System Maximum Sources for the Reactor 4.2-377b 50 Refueling Condition for the Reactor Operating Condition 4.2.96 Cor. trol Rod System Histogram (5 year) 4.2-373@/-'69') I'I L J J Amend. 50 4-xvil June 1979 l.IST OF FIGURES (Continued)

Figure No.

Page No.4.2-97 Reactor Steady State Thermal Environment 4.2-379 1 4.2-97A Exposure Time Required to Cause Room Temperature Toughness to Fall Below 15 Ft. Lbs.

4.2-379a 4.2-978 Exposure Time Required to Deplete Room Temperature Toughness by One Half 4.2-379b 25 4.2-98 Control Rod Systems - Reactor Elevation 4.2-380 4.2-99 Control Assenhly Positions in Core Layout 4.2-381 44 4.2-100 Primary !!echanical Sub-System 4.2-382 4.2-101 Primary Control Rod System Layout 4.2-383 4.2-102 Primary Control Rod Drive Mechanism 4.2-389 4.2-103 Lower primary CRDM and Driveline Assembly 4.2-390 4.2-104 Primary Control Assembly 4.2-391 268 126@Amend. 50 June 1979 4-xviia LIST OF FIGURES Continuea Figure flo.

Page fio.4.2-105 Secondary Control Rod System Schematic 4.2-392 4.2-106 Secondary Control Assembly (SCA) 4.2-393 4.2-107 Secondary Control Rod Driveline (SCRD) 4.2-394 44l4.2-108 Secondary Control Rod Drive Mechanism (SCRDM) 4.2-395 4.2-109 Diagram of the Control Rnd System flodel Used for 4 . 2- 3 i'8 Evaluation of Retardation Forces due to Lateral flisalienments 4.2-110 Control Assembly Outer Duct Bowing 4.2-399 4.2-111 Primary Control Assembly Duct Bowing 4.2-400 Configurations I 4 2 -Illa Pellet Sweliing and Clad Gap 4.2-400a 34 4.2-Illb Primary Control Rod Axial Burnup Profile t.2-4n0b^ 2-112 Primary Rod Control System Scram Insertion 4.2-401.Distance vs. Tine 4.2-113 Comparison Analysis Tests for FFTF Control 4.2-402 Assembly (flisaligned Conditions) 4.2-114 First Cycle Full Power, Preliminary Primary 4.2-403 Control Rod System Scram Insertion Rates 4.2-115 Equilibrium Cycle, Full Power, Preliminary 4.2-404 Primary Control Systen Scram Insertion Rates 4.2-116 Deleted 4.2-405 4.2-117 Deleted 4.2-406 50 4.2-118 Deleted 4.2-407 4.2-119 Scra"1 of Typical Primary Control Rods-SSE Seismic 4.2-408 Based vs. Normal Conditions 4.2-120 Absorber Assembly Scram Impact Dynamic Model 4.2-409 4.2-121 SCRS Rod Displacement vs. Time 4.2-410 4.2-122 SCRS Scram Reactivity Insertion vs. Time 4.2-411 2 b h/ c ' ,''C Amend. 50 4-xviii June 1979  

, LIST OF FIGURES _ Continued Figure No.

Page No.4.3-30 Criticality of Fuel Assemblies 4.3-119 4 . 3- 31 Schematic of Feedback Effects 4.3-120 4.3-32 Transfer Function for Various Feedback 4.3 ~121 Reactivities 4.3-33 Transfer Functions for Various Feedback 4.3-122 Reactivities 4.3-33a Bowing Reactivity Function for Stability Analysis 4.3-122a 4.3-122b Reactor Power Response to Inherent Reactivity Feedback Following a 2c Step Insertion 4.3-122b 4.3-33c Fuel Assembly Maximum Fuel Temperature Response to Inherent Reactivity Feedbacks Following a 2c Step Insertion 4.3-122c 4.3-33d Fuel Assembly Maximum Cladding Temperature Response to Inherent Reactivity Feedbacks Following a 2c Step Insertion 4.3-122d 4.3-122e Fuel Assembly Maximum Coolant Temperature Response to Inherent Reactivity Feedbacks 44 Following a 2c Step Insertion 4.3-122e 4.3-34 Radial Neutron Flux Distributions 4.3-123 4.3-33 Typical Axial Flux Shape in the Core and Blankets 4.3-124 4.3-36 Calculational Scheme for Analysis of CRBRP 4.3-125 4.3-37 Calculational Scheme for Evaluation of ZPPR 4.3-126 Critical Experiments 4.3-38 ZPPR-3 Calculational Flow Diagram 4.3-127 4.3-39 I in Zones and Central Plate and Pin Cells for 4.3-128 ZPPR-2 4.3-40 Core Layout for ZPPR-3 Phases 1B, 2 and 7 4.3-129 4.3-41 Reference 632 Drawer Sodium Void Confie. ration 4.3-130 for the Modified Phase 3 Core of ZPPR f.s./mbly 3 4.3-42 ZPPR-3 Phase 3, Modi #ied Core, Two-Dimensional 4.3-131 (R,7) Calculation Model 4-x)xP V;p 1 ~, n icv Amend. 44 April 1978  

/LIST OF FIGURES Continued Figure flo.

Page No.4.3-43 ZPPR Assembly 4 Phase 1 Reference Configuration 4.3-132 4.4-1 Typical Fuel Rod Axial Temperature Profile 4.4-54 4.4-2 CRBRP Flow, Pressure Drop, Hydraulic Loads and 4.4-55 Coolant Temperature Distribution for Plant Thermal /

Hydraulic 4.4-3 Inlet Module Core Map, Showing Orificing 4.4-56 Requirements of Reactor Assemblies 50l4.4-3A Lower Core Support Plate Pressure Manifold System 4.4-56a 4.4-4 Modular CSS Assembly: Flow Paths 4.4-57 50l4.4-5 Elevation of Typical Lower Inlet Module 4.4-58@I w/t)oO (_iL Amend. 50 June 1979 4-xxia LIST OF FIGURES Continued Figure flo.

Page No.l20 50 4.4-6 Inlet Module For Bypass Flow 4.4-59 4.4-7 Radial Shield Orificing Flow Path 4.4-60 4.4-8 Upper Internal s Structure Concept Fea <ure 4.4-61 4.4-9 Orificing Scheme and Nominal Flow Rates at 4.4-62 Flant T&H Design Conditions 4.4-10 Equilibrium Fuel Assembly and Radial Blanket 4.4-63 Assembly Management 4.4-11 Flow Maldistribution in the Five Fuel Assembly 4.4-64 Orificing Zones at a Power-to-Flow Ra tio of 1.0 4.4-12 Flow fialdistribution Factors in the Four Radial 4.4-65 Blanket Orificing Zones and the Central Assemblies at a Power to Flow Ratio of 1.00 4.4-13 Flow fialdistribution Factors in the Hot Assembly, 4.4 6C Average Fuel Assemblies, and Average Radial Blanket Assemblies at a Power to Flow Ratio of 1.000 4.4-14 Flow Maldistribution Factors in the Hot Assembly, 4.4-67 Average Fuel Assemblies, and Average Radial Blanket Assemblies at a Power to Flow Ratio of 2.000 4'4~CO 4.4-15 Effect of Buoyancy on Hot T.hannel Enthalpy Rise in the Hot Assembly a: Low Reactor Flow Rates 4.4-69 4.4-16 Graphical Illustration of Seni-Statistical Method 4.4-17 Fuel and Radial Blailket Assemblies Linear 4.4-70 Power Rating at Equilibrium BOL- Conditions 4.4-18 Envelope of Fuel anc' Radial Blanket Assenblies 4.4-71 Linear Power Rating at Equilibriun E0L Conditions 4.4-19 Envelope of Fuel and Radia. Cla. set Assemblies 4.4-72 Mixed Mean Outlet Temperatures for P' ant Thermal Hydraulic Contitions at Equilibrium BOL Amend. 50 June 1979 26g]u 4-xxii r e Bases - The prime objective of this requirement is to assure the functional capability of all core components is preserved.

It is possible to postulate a number of potential failure mechanisms associated with a general condition of duct to duct contact in the active core region. One such failure mechanism is duct brittle fracture under seismic loading. Anc ther would be excessive Afor-mation which could occur due to buildup of large interduct co.itact loads.By not allowinq duct contact to become a general condition, the functional capability of all core components is preserved.

i)Requirement - The design life for the core formers is 30 years for the 75% plant capacity factor.

Bases - This requirement assures that the core fonners will not need to be replaced during the design life of the plant.

The primary incentive for this requirement is economic and operational benefits.

j)Requirement - Design of the core restraint system shall be consistent with annual refueling.

Bases - This requirement provides consistency with established plant operating guidelines, k)Requirenent - The dynamic radial deflection of the inner profile of the Upper Core Former (UCF) shall be less than + 0.100 inch, relative to the LCF centerline during an SSE or OBE event.

For non-seismic events, control rod system alignment requirements 44lare defined by Figures 4.2-95A and B.

The contribution from the core re-straint system and core former clearances and tolerances is limited to less than 0.530 for the control assembly handling socket to reactor vessel centerline.

However, for seismic events, a similar alignment limit was considered not to be applicable, since dynamic analysis is being performad to adequately account for deflections of each component interfacing with the control rod system. Qualita tively, the objective for the core former is to limit seismic deflections to as small as practical, within the various design restrictions.

The 0.100 inch dynamic deflection limit is thus established as a reasonable design objective for such a iarge (150 inch 0.D.) ring.

It should be pointed out 14 Amend. 44 268l}lApril 1978 4.2-95 O that the UCF time vs. deflection history in relation to that for the control rod system and other interfacing components is also an important parameter in the scram analysis, and is not easily factored into a simple deflection requirement.

1)Requirement - The Lower Core Former (LCF) radial deflection relative to the LCF centerline during an SSE or OBE shall be limited to less than

.100 inches.

Bases - The Lower Core Former, interfacing with the above core load pads on the reactor assemblies, performs a geometry control function. To limit the seismic loads on the assemblies and to limit the magnitude of and reactivity insertion during ' seismic event, the LCF deflection must be limited.

If the distance across the core former were significantly reduced due to an elliptical deflection of the ring, the reactor assemblies would be compacted, causing a reactivity insertion and higher loads on the load pads.

By limiting the LCF deflection to less that 0.100, an increase in load pads is avoided since adequate clearances exist between load pads and between the outermost load pad and the Lower Core Former. This is shown in Figures 4.2-84 and 4.2-92.

Preliminary ctre restraint models indicate that cumulative clearance is slightly more than 0.150 in;h2s between the first row blanket assembly load pad and the LCF segment for on-power operation. Therefore, if the LCF deflects up to 0.100 inches, the compaction would primarily affect the shield and outer blanket assemblies and would not be expected to result in a significantly greater seismic reactivity insertion.

There will be a seismic induced core compaction in an orthogonal direction which will occur even with zero LCF deflection. This is discussed in Section 15.2.1.3.The intent of the LCF deflection limit is to prevent an addition-al source of core compaction during a seismic compaction event.

14-n 3 kJ" 50 Amend. 50 U"" 4.2-95a i A" t D-+ti T d D To meet criterion:

D#0 e (7) A cycle limiting criterion is required to verify the applicability of the modified rule.

The effective number of allowable design cycles is: nlD\I n =qD, e g Where n is the total number of significant strain cycles between hold periods.Low amplitude high cycle strain fluctuations (such as normal power fluctuations) need not be considered in n if they are elastic excursions that result in negligible fatigue damage.

(1) The material is austenitic stainless steel Type 304 or 316 solution treated.(2) The structure does not require a Code Stamp under existing Code rules.

(4) Strest rupture test data of the same type of stress concentration with similar geometric proportions tested at prototypic temperatures are used as a basis for modification of the Code Strength.

The test temperature may be higher than the service temperature in order to more closely simulate the actual component lifetime and the stress level.(5) The notched stress rupture data shall be from specimens which are comparably or more severely loaded than the component, i.e., membrane loading of a notched specimen should be more severe than a gradient loading.

(6) The stress rupture test data include data up to 1/60 of the component lifetime at prototypic temperatures or the equivalent when a short-time high temperature combination is used to simulate the desired long-time 49 service environment.

') , _ n-'''dd 4.2-ll5d Amend. 50 June 1979 (7) Subject to the above limitations, the creep damage may be calculated in accordance with F9-4T and Code Case 1592 as modified.

The modi-g fication is to use a peak stress to rupture design curve based upon W the stress to rupture design curve in Code Case 1592 adjusted for the influence of a non-linear stress state caused by the presence of a geometric stress concentration as with the following:

Step 1 - Determine the smooth specimen stress rupture strength curve by tests of the same material at the temperature of interest.Step 2 - Determine the stress rupture strength curve with the presence of the geometric stress concentrations under the same conditions in (1) with specimens of the same heat of material with the same histories.

Analytically determine the peak stress relative to the net stress thus defining the stress rupture strength in terms of " peak stress" vs. time to rupture.Step 3 - Ratio Code Case 1592 stress to rupture design curve by the ratio of Step 1 divided by Step 2.

This must be done for at least 3 points in time with a separation in time of at least two orders of magnitude.

In cases where the strength ratio varies with lifetime, the lesser of the value extrapolated to the component lifetime or the experimental value for the longest duration tests shall be used.

(8) The total creep-fatigue damage is determined by adding to the creep damage and fatigue damage calculated in accordance with T-1411, -1412,-1413, and -1414 of Code Case 1592.

(10) The greater of the damage using the modified rule and the damage using the stress unaltered by the stress concentrations and the Code Case 1592 49 stress to rupture design curve shall be used.

4.2.2.3.3 Additional Material Properties 4.2.2.3.3.1 Inconel 718 Fatigue Properties The Alloy 718 design fatigue curve, Figure 4.2-48, proposed for inclusion in the NSM Handbook as interim data, shall be used until super-ceded.The effects of the fabrication processes and service environment on the structural integrity of the UIS shall be considered.

The effect 41 4.2-ll5e 26[]]] emend.50 dune 1979 VIS ':EYUAY m R R 1 KEY.#~ }/ _t'('/(J y [ G 'T [!ril F q

" ,- 1 NTAL i i UPPER CORE FORMER y f'SUPPORT RING LOWER CORE l'N FIXED h CORE BARREL RADIAL SHIELD Figure 4.2-46.

Core Former Structure Amend. 50 4.2-328d June 1979 268 135 traps are air ccoled, and process the sodium at a flow of 60 gpm. The single trap is sufficient to limit oxygen and hydrogen to a maximum of 2 and 0.2 ppm respectively, and to limit the tritium concentration in the sodium to 0.062 pCi/gm (corresponds to a transport of tritium to the steam generator water of 0.016 Ci/ day).

A more detailed description of the Intermediate SC Sodium Processing System is given in Section 9.3.2.4.

5.4.3 Design Evaluation.

5.4.3.1 Analytical Methods and Data The design of the IHTS is based upon technology attained during the development, design, construction and operation of sodium systems of similar type IHTS hydraulic and fluid volume changes are calculated and based upon sodium thermodynamic data from " Standard FFTF Values for Physical and Thermophysical Properties of Sodium" (Ref. 2)The IHTS sodium pressure losses are calculated using Darcy's formula, the general equation for pressure drop of fluids.

The factors for equivalent lengths of fittings and pipe friction are based upon " Tube Turns," Bulletin TT725 (Ref. 3) and " Friction Factors for Pipe Flow," by L. F. Moody (Ref. 4), respectively.

5.4. 3.1.1 Structural Evaluation Plan (SEP)

-5.4-12 Amend. 50 June 1979@"1 ! r b..)9 AFP Motor Drives These motor drives will be synchronous speed squirrel cage induc-tion motors of 980 horsepower.

These motors will be selected from a 17 vendor's standc.rd line and no special requirements are anticipated.

AFP Turbine Drive This component will be ebtained from an experienced vendor and will be sized to produce 1960 horsepower.

The turbine will be constructed with 17 sufficient quality assurance coverage to assure its reliability during ser-Vice.The auxiliary feedpump turbine is not keot hot for quick start operation.

The drive turbine concept sclected for the Auxiliary Feed eump is based on the capability of thic turbine to withstand severe service con-ditions.This is accomplished by constructing the turbine wheel from a single forging with buckets milled into the forging.

The start-up procedure is similar to thct for the RCIC turbine in a BWR in that it will occur without pre-warming.

25 Pump Integrity The auxiliary feed pumps will be designed to the requirements of ASME B&PV Code, Section III, Class 3.

In addition, the pumps and their i supports will be designed to Seismic Category 1 requirements.

Allowable stress limits are specified in Table 3.9-3 arid pressure limits are speci-fied in Table 3.9-4.

)7 5.6.1.2.3.3 Protected!!aterStoragTan_kJPWSTJ The PW5T holds the protected water to.be supplied to the steam drums in the event of loss of normal f eedwater er normal heat sink.

The size is deteroined by detailed analysis of the heat removal conditions during the first several hours af ter shutdown and by anticipated component leakage rates.

The ' nk will be constructed to the requirements for en ASf1E Section III/ Class 2 vessel and it will operate at low temperature (< 200 F) and low pressure (<l5 17 psig), 268 1R Amend. 47 5.6-6 a Nov. 1973 5.6.1.2.3.4 SGAHRS Piping and Support The SGAHRS riping is described below and is shown in Figure 5.1-5.The SGAHRS piping will be designed in acsordance with the ASME

'Code Section III as specified in Section 5.f. l .l .2.

The material

.49lspecifications are discussed in Section 5.6.1.1.4.

a.PWST Fill l_ine This 3 inch low pressure, low temperature, class 3 carbon steel line runs from the 10 inch alternate water supply line through the motor-driven, normally closed PWST fill valve to the PWST inlet.

b.Protected Water Storage Tank (PWST) to Auxil'ary Feedwater Pump (AFP) Inlet There are three low pressure, low temperature, uninsulated carbon steel lines from the PWST to the three auxillary feedwater pump inlets.

Two of the lines, each of which leads to a half size, motor-driven pump are 6 inches in diameter and the third line to the full size turbine-driven pump is 8 inches.

All three lines contain a manually ooerated, locked open valve and an electrical operated, normally open isolation valve.

These lines are Class 2 from the PWST to the electrically-operated isolation valve 49 land then Class 3 to the pump inlet.

c.Alternate Supply Line to AFWP Inlet The alternate supply line provides the capability for the AFW pumps tc take suction from the condensate storage tank.

A 10 inch carbon steel line runs from the condensate tank junction to the first branch line. An 8 inch branch line 49lpasses through an electrically-operated, ncrmally closed isolaticr valve and tees into the 8 inch turbie pump inlet piping.Two 6-inch branch lines each pass through c.;ctrically-49 operateJ, normally closed isolation valves and then tee into the 6 inch motor-driven pump inlet piping.

The total run of niping is Class 3.

d.Auxiliary Feedwater Pump Discharge to Discharge Header (Inclusive)

The 6 inch carbon steel turbine pump discharge litie leads to a 6 inch discharge header.

This header in turn has three di -

charge points, one to each steam drum feedwater supply loop a 6 inch carbon steel line from each motor dri'len pump feeds into a 6 inch header which also has three discharge points. ona 43 17 to each drum.

Amer.d. 50 June 1979 5.6-7 n 268 1w 5.6.2 Direct Heat Removal Service (DHRS) 5.6.2.1 Design Bases 5.6.2.1.1 Performance Objectives The Reliability Program, discussed in Appendix C, will provide 41 verification that SGAHRS removes residual heat following a reactor shut-down with a high level of reliability.

Hence it is judged that only stcam and feedwater trains backed by SGAHRS are necessary to safely and reliably remove residual heat following shutdown from three loop, full power operation. To enhance the reliability of decay heat removal, the DHRS provides a fourth redundant heat removal path and heat sink.

The impact on overall shutdown heat removal reliability by inclusion of the 41 DHRS is being determined by the Reliability Program described in Appendix C.The DHRS provides this supplementary capability by satisfying the following objectives:

Function to remove reactor decay heat following reactor shutcown a.from three loop rated power operation, assuming loss of all hea*

transfer through the IHX's at the time of reactor trip.

Oncra-tion of three primary pumo pony motors and maximum reactor decay power is assumed.

Under these conditions, the DHRS is desianed to provide sufficient cooling to ensure primary coolant boundary integrity and prevent loss of in-place coolable geometry of the core.To meet this obiective, DHRS components will be sized such that, under these conditions, the average bull p5imary sodium tennera-ture will be limited to aoproximately 1140 F.

Caoability will be provided to pernit remote manual initiation of DHRS from the Control Room.

The overflow and makeup circuit and the snent fuel cooling system will be able to be cross connected in a manner which permits both EVST NaK cooling trains to be used 20 when DHRS is removing full capacity heat load.

Accommodate the thermal transients resulting from normal, upset, b.emergency and faulted plant events in which continued performance of its function is not impaired.

Accommodate floods (Section 3.4), tornadoes (Section 2.3), missiles c.(Section 3.5), and earthquakes (Section 3.7), in which continued performance of its function is not impaired.

d.Function in a manner which will not signiricantly reduce the reliability and availability of the EVST heat removal chain.

263 13?Amend. 43 5.6-20 Oct. 1977 5.6.2.1.2 A_pplicable Code Criteria and Cases The components of the DHRS shall be designed, f abricated, erected, constructed, tested and inspected to the standards of Section III of the ASME Code,1974 edition through the summer 1974 Addenda, Class 1 or 2 as 26 listed in Table 5.6-12.

5.6.2.1.3 Surveillance Requirements The need for surveillance of the DHRS piping and components will 26I be determined as the system design progresses and as the need to monitor austenitic stainless steel is determined by ongoing programs.

If a require-ment is identified, a surveillance program will be designed in accordance with the philosophy of 10 CFR 50, Appendix H.

Material Specifications Stainless steel materials which satisfy the requirements of the ASME Code will be specified for use in the DHRS system, as noted in Table 26 5.6-13.49I.6.2.1.5 Leak Detection Requirements 5 Th< DHRS will be monitored for sodium and NaK leaks and leak 26 indication will be provided in the Control Room by the leak detection system described in Section 7.5.5.

5.6.2.1.6 Instrumentation Requirements DHRS is remote manually activated and controlled from the Control Room.Instrumentation required to monitored the condition of the DHRS consists of thermocouples on the EVST sodium outlet lines (3 loops) and level indicators in the EVST and the Reactor Vessel (RV). These instruments confirm that the sodium levels in the RV remain above the loop outlet nozzles 50 46 and that temperatures remain below design limits.

Other DHRS diagnostic instrumentation is not essential for DHRS operation as the pumps and air blast heat exchanger are being operated at maximum design rates. When the reactor decay heat load has dropped sufficiently, the cooling capacity of the system may manually be reduced by lowering flow-rates or fan speed, or by

-shutting down one o ne of the EVST cooling trains.

.26 Amend. 50 June 1979 5.6-21 268 140 TABLE 5.6-5 SGAHRS VALVE CLASSIFICATION NORMAL OPERATING VALVE ACTIVE / INACTIVE POSITION MODE Alternate AFW Supply Active Open Isolation 44l PWST Fill Inactive Closed Isolation PWST Drain Inactive Closed Isolation PWST Level Indicator Inactive Open Isola tion AFW Pump Inlet (Manual)

Inactive Open Isolation 50 AFW Pumo Inlet (Electrical)

Active Open Isolation Alternate AFW Pump Inlet Active Closed Isolation 26 Pump Recirculation Active Closed Isolation Pump Discharge C/V Active Check Pump Discharge Isolation (Manual)

Inactive Open Isolation AFW Supply Isolation (Manual)

Inactive Open Isolation AFW Supply Control Active Onen Flow Control 50 AFW Supply Isolation (Electrical)

Active Closed Isolation AFW Supply Isolation (Manual)

Inactive Open Isolation AFW Supply C/V Active Check 50 AFW Supply C/V Active Check Steam Drum Vent Control Active Closed Vent, Pressure Control 26 Superheater Vent Control Active Closed Vent, Pressure Control PACC Steam Supply Inactive Open Isolation PACC Steam Supply Bypass Inactive Open Isolation PACC Condensate Return Inactive Open Isolation PACC Noncondensible Vent Active Closed Vent PACC Noncondensible Vent Isolation Inactive Open Isolation Drive Turbine Steam Supply Isolation 50)(Electrical)

Active Closed Isolation 26 Drive Turbine Steam Supply C/V Active Check Drive Turbine Steam Supply Isolation Inactive Open Isolation (Manual)Amend; 50 26,3 1j, une 1979 5.6-34 e , i TABLE 5.6-5 (Cont'd)

NORMAL OPERATING VALVE ACTIVE / INACTIVE POSITION f t0DE __Drive Turbine Steam Supply Pressure Centrol Active Closed Pressure Control Pressure Instrument (Pump In.et)

Inactive Open Isolation Pressure Instrument (Pump Discharge)

Inactive Open Isolation Pressure Instrument (Turbine Inlet)

Inactive Open Isolation 50 26 0.,'2 thi))k ' t '-O 5.6-34a Amend. 50 June 1979

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3.A low leakage enclosure for the main Control Room and its adjoining rooms to provide the capability for keeping a positive air pressure level with~n the enclosure.

4.Two alternate and widely separated air intakes and redundant filter units, to limit the amount of contamination entering the Control Room.

5.Airborne hazard monitors that detect unsafe concent .tions of smoke, toxic chemicals and unsafe radiation levels, annunciate the presence of the hazard and automatically 22 49* ransfer the HVAC system to its accident mou_ of operation.

6.Appropriate fire suppression equipment.

7.Of fice and living accommodations appropriate for long term occupancy.

8.An amply stocked inventory of emergency equipment and supplies.9.Installation of two door vestibules to prevent unfiltered air entering the main Control Room.

49lThe habitability system is also required to permit continuous control room occupancy under accident conditions.

These provisions enable the operators to remain on duty without relief for as long as required.It is, therefore, not necessary to plan on routine shift changes by the control room personnel.

However, if conditions necessitate a change in personnel, this can be accomplished without undue radiation exposure.The calculated radiation exposure for either ingress or egress 49 at 24 hours af ter the accident is less than 1 mrem.

This estimate is based on direct exposure from fission product gases, halogens, volatile solids, fission products, and activated sodium evenly distributed through-out the reactor containment building free volume.

These sources consti-49 tute direct shine dose only.

25 The ingress or egress exposure resulting from the radioactivity (annulus leakage previoualy stated) is approximately 3.50 mrem external exposure (whole body dose).

The internal exposure to the lungs, thyroid, 49 and bone is less than 1.5 mrem, 9 mrem, and 28 mrem, respectively.

Amend. 49 6.3-2 April 1979

?40 1 *r<uO I o s.

The operator ingress or egress is to be made by motor vehicle to a point adjacent to the control building portal.

The car is assumed to travel at an average speed of 15 mph in both directions.

The operator walks between the control building and the motor vehicle at an average rate of 4 mph, and personnel will be equipped with supplied air breathing 25 apparel.49 6.3.1.2 System Design The Control Room Habitability System is designed to provide a safe, comfortable and appropriately equipped location for personnel controlling plant operations during normal times and during accidents.

A concrete enclosure and special sealed doors are important features in this habitability system.

The details of this shielding and 22 the shield wall thicknesses are described in Section 12.1.2.4.

Bases used in the design and analyses are also presented in Section 12.1.2.4.

Factors considered in these design analyses include thermal margin beyc.design basis requirements and the associated activity releases 49 and gamla shine from the containment / confinement.

In addition, other features, such as two widely separated air intal.es are provided to mitigate the consequences of low probability accidents beyond the design 22 basis.Another important feature of the Control Room Habitability System is the HVAC system.

The HVAC system for the Control Room contains two 100: capacity air conditioning units and two 1001 capacity exhaust fans, with one unit each normally operating and the other unit on standby; and two 100? capacity emergency air supply filter units.

Complete details of the system are presented in Section 9.6.1.

A P&ID of the system is also provided and shown in Figure 9.6-1.

This HVAC system contains several aspects that are significant to the Control Room Habit-ability System.

One of these aspects is that this system has full capacity redundancy to assure the capability for controlling the environ-ment af ter any single component or subsystem failure.

A second aspect is the capability to maintain the Control Room at a slightly greater pressure than any of its surroundings at all tines.

A third aspect of interest to the habitability system is the air cleanup units that purify both make-up and recirculated air flows during postulated accidents.

Fach air cleanup unit in the HVAC system contains two banks of HEPA filters and a bank of carbon < arbero.

The filter capability is discussed in Section 9.6.

A fourth aspect is the capability for selecting emergency pressurizing air during accidents from widely separated intakes, one located at the SE Corner of the Control Building roof at approximately elevation 880' and the other at the NE corner of the Steam Generator 4f Building Auxiliary Bay at approximately elevation 858'.

This along with instrumentation provided, allows selection of the cleaner air source during such periods.

Amend. 49 April 1979 6.3-2a 268} i >

LIST OF TABLES TABLE NO.PAGE 7.1-1 Safety Related Instrumentation and 7.1-7 Control Systems 7.1-2 List of Regulatory Guides Applicable 7.1-8 to Safety Related Instrumentation and Control Systems 7.1-3 List of IEEE Standards Applicable to 7.1-9 Safety Related Instrumentation and Control Systems 7.1-4 List of RDT Standards Applicable to 7.1-10 Safety Related Instrumentation and Control Systems 49~*7.1-6 Safety Related Electrical Instrumentation 7.1-13 23 and Control Equipment 7.2-1 Plant Protection Syster. Protective 7.2-18 Functions 7.2-2 PPS Design Basis Fault Events 7.2-19 7.2-3 Essential Performance Requirements for 7.2-23 PPS Instrumentation 7.2-4 thru 40 24 Deleted 7.3-1 Containment Isolation System Design Basis 7.3-5 7.4-1 Sequence of Decay Heat Removal Events 7.4-9 7.5-1 Instrumentation System Function', and 7.5-34 Summary 7.5-2 Reactor and Vessel Instrumentation 7.5-39 44 7.5-3 Sunmation of Sodium / Gas Leak Detection 7.5-40 Methods 34 49 7.5-4 Post Accident Monitoring 7.5-42 7.6-1 Use of Refueling Interlocks 7.6-4 7.9-1 rontrol Rooin Arrangements 7.9-8 26S 7.'''Amend. 50'7-ix''June 1979 LIST OF FIGURES F IG . II,0.

7.2-1 Reactor Shutdown System 7.2-69 I 7.2-2 HTS Coolant Pump Shutdown 7.2-70 , 7.2-2A Typical Prinvry PPS Instrument Channel 7.?-70a 1 Logic Diagram

/.2-2AA f.SS Bypass Functien Block niagran 7.2-70a 15 7.2-2b Primary PPS Logic Diagram 7.2-70b i 7.2-2C Typical Secondary PPS Instrurrent Chanr.el 7.2-7Cc >Logic Diagran i i 7.2-2D Secondary PPS Logic Diagram 7.2-7Cd 'l 44 7.2-3 Typical Primary Subsystem 7.2-71 7.2-4 Typical Secondary Subsystem 7.2-72 7 ' '9- 5 Functional Block Diagrams of the Flux-Delayed 7.2-73 Flux, High Flux, Flux-Pressure, and Reactor Vessel Level Protective Subsystems 7.2-6 Functional Block Diagrams of Primary Pump 7.2-74 Electrics and Primary to Intermediate Speed Ratio Protective Subsystems 7.2-7 Functional Block Diagrams of the IF.X Primary 7.2-75 Outlet Temperature and Steam to Feedwater Flow Mismatch Protective Subsystems 7.2-8 Functional Block Diagrams of the Flux-Total 7.2-76 Flow, Startup Nuclear, Modified Nuclear Rate, and Primary to Intermediate flow Rate Protective Subsystems

'7.2-9 Functional Block Diagrams of the Steam 7.2-77 Drum Level and Loss of Condenser Vacuum Protective Subsystems 7.2-10 Functional Block Diagrams of the Evaporator 7.2-78 Outlet Sodium Temperature and Sodium Water Reaction Protective Subsystems 7.3-1 Containment Isolation System Block Diagram 7.3-6 2b8 lhb Amend. 44 April 1978 7-x N C'as Tatale 7.1-6

(,y Safety Related Electrical Instrumentation And Control Equipment

_Measured Equipment Parameter Purpose Location Temp.Press.Humidity Radiation Chemical Seismic Vibration 39lEVST and 501 Thermocoupl es EVST Outlet Na Safe Shutdown RSB 331, 357 X NA X X X X TBD Temperature Phi 360 Thermocouples OH X N a 0utlet Safe Shutdown RCB 1078 X NA X X X X TB3 47l'Te aperature Pki 4/39lPrimary Sodium None DHRS RCB 103,104 X X NA X X X TBD Makeup Pumps EVST Sodium Pumps None EYST Cooling RSB 357A 360 X NA X X X X TB3]1 EVST NaK Pumps None EVST and Re-RSS 352A, 353A X NA X X X X TBD*and Fid. Panels actor cooling

%EVST A3HX and None EVST and Re-RSS 35ZA, 353A X NA X X X X TB3 Field Panels actor cooling M3keup pump None Reactor CHRS RCB 105A X X NA X X X TBD 39lField Panels Service EVST Sodium Pump None EVST Cooling RSB 352A, 353A X NA X X X X TBD Field Par,els Control Room None DHRS & EVST CB 431 X NA X NA X X TBD Panel cooling con-trol 46 Valve Operators None Various RCB 1078 X X NA X X X TS3 c$2 m 7 II b b k hib. bl b 4 e Q, i (

TABLE 7.1-6 Safety Related Electrical Instrumentation And Control Equipment Sheet 6 cf 9 Measured Equipment Paraneter Purpose Location Temp.Press.Humidity Radiation Chemical Seismic Vibraticn Na R5B Valve Operators None Various 357A, 350 X NA X X X X TED Na K RSB Valve Operatcrs None Various 352A, 353A X NA X X X X TB3 Local Control DHR5 & EVST RSS 311 Panels N ne cooling control Rcs losV X NA x x x x Taa N 46 m co hwl C:~CO" ('i CD EE n ,-1 r.m.,, r vc ,-, c3.~(f' . _~ ~ \

.~\..t~a p.b,a.2 is i'!a.O.,* { i. ;$*-(,-i."' '; d G o (9*a'. s''.i'Q (J/U (,,'. 2 .= L1'j N Sm., D@S 9 9 TO NON-PPS +

BUFFER a-SL , LEVEL DE7ECTOR ELELTRONICS LOOP 'l-SH I'S L b TO NON-PPS +

BUFFER'LEVEL DETECTOR ELECTRONICS t.00 P =2 r/~i.SH SL-TO MON-PPS +

SUFFER-@LEVEL+DETECTuR ELECTRONICS a 100p 3 SH Figure 7.2-9 Functional Block Diagrams of the Steam Drum Level Subsystem.

6678-5@Amend. 47 7.2-77 Nov . 1978 26R 101 10 N0h-PPS e buf ll R fl H:'E i? t.10 P L

-'Ellt'RONifS DIIEClCa-4 LOOP =l U T TO NDH-PPS +

tWI!ER llt'PLP/IURf

~-DfifC10K ElfCIRONICS U t 00P *2 T T O HON-PPS +

6Uf f[ R 1[tvikAIUht

.\'IL(CTFONICS DETEC10R t00P =3;9 EVAPORATOR CUTLET TEMPERATURE BJFf E R TO SWRPRS e (SEE f!G. 7.5-6)

, StHS0R St:Pt hh! Aif k

-[tfCTROFIff SUII E F TO SWRPRS+Op (SEE FIG. 7.5-6)

-$[h:0R^EVAL 0RATOR al J gg--BUFFER 10 h0N-FPS TO SWRS e sut r I r tea , (SEE f IG. 7.5-6)

B'JF T E R 10 NON-PP5

--i ItECIR0hlCS

-[V 20rATOR (?

SODIUM WATER REACTION PROTECTIVE SUBSYSTEM Figure 7.2-10 Functional Block Diagrams of the Evaporator Outlet Sodium Temperature and Sodium Water Reaction Protective Subsystems, 7,7,73..;One Channel of Three is Shown Amend. 50 7.2-76 June 1979 onn 1~'''(_ G I < . -

provide the required time response.

The thermowell is also swaged at the tip.

The thermocouples are spring loaded against the bottom of the well.

Although failures of the wells are not expected, as confirmed by tests and analysis, the head of the thernowell, including the cable penetration, is sealed to pro-vide a secondary boundary for the sodium.

Tests have shown that this system will provide a time response less than 5 seconds.

Flexible mica, polyimide and fiberglass insulated thermocouple extension wires in conduit are used to bring the signals out of the Heat Transport System Cell .

The signals are then routed to the containment mezzanine into reference junctions and signal con-di tioning equipment.

The conditioned signals are transmitted to the control room for the Reactor Shutdown System logic.

Tne Reactor Shutdown System pro-vides buffered signals to the PCS and DH & DS.

Primary _and latermediate Hot and Cold l edegperature The primary and intermediate hot and cold leg temperatures are measured to determine and record operating conditions and to calorimetrically calibrate the pert::anent magnet flowmeters.

The measurement is made by two Dj duplex element resistance temperature detectors (RTDs) per loop, installed in thermowells.

Although failures of the wells are not expected, as con-firmed by tests and analysis, the head of the thermowell, including the cable penetration, is sealed to provide a secondary boundary for the sodium.The signals from the RTDs are routed to signal conditioning equip-ment which converts the resistance variation to a standard signal level for transmission to the DH & D$.

Primary _ and Intermediate Pun;p Discharge Pressure The primary and intermediate puup discharge pressure measurements monitor pump performance and the primary loop / intermediate loop differential The measurements are made by pressure elements installed in the pressure.elevated section of the drain line from the discharge piping of the sodium NaK filled capillaries f rom the pressure elements are connected to pump.pressure transducers which develop electrical s'qals proportional to the These pressure transducers provide a sehadary boundary if the bel-pressure.lows in the pressure elements should fail.

The' and1Noned signal is sup-plied to the DH & DS..I_ntermediate IHX Gutlet Pressure

"'The intermediate IHX outlet pressure measurement is used to 43 monitor the loop and IHX operational performance history.

The measure-43lments c.re made by pressure elements installed in the intermediate loop piping between the IHX and the superheater.

NaK filled capillaries from the pressure elements are connected to pressure tranducers which develop electrical signals proportional to the pressure.

The pressure transJucers provide a secondary boundary if the bellows in the pressure elements should fail. The conditioned signal is supplied to the DH and DS.Abb ib Amend. 49 7.5-7 Apr. 1979 h%%%w I_HX Differential Pressure The primary sodio.a pump discharge pressure and the IHX Interme-diate Loop outlet pressure detectors are used to provide a differential measurement of the IHX Primary / Intermediate pressure difference.

The dif ferential pressure measurement is alarmed to alert the operator for corrective action to assure intermediate to primary differential pressure 50l49 is maintained above the minimum required.

Intermediate Pump Inlet Pressure The intermediate pump inlet pressure measurements provide a signal to onitor pump performance.

Used with the pump outlet pressure, the differential pressure across the puitp is obtained.

In the primary loop, the reactor pressure is used for this surveillance.

The measure-ments are made by pressure elements installed on the piping between the evaporators and the pump inlet.

NaK filled capillaries from the pressure elements are connected to pressure transducers which deveiop electrical signals proportional to the pressure.

The pressure transducers provide a secondary boundary if the bellows in the pressure elements should fail.

Intermediate Expansion Tank Level Two separate level measurement channels are provided; both channels are used for indication in the control room and DH & DS and for alarm. Alarm channels provide a broad range measurement that covers possible high and low levels during plant operation as well as the IHTS 49 fill level . The DH & DS uses measurements for intermediate loop sodium inventory (see also Section 7.5.5).

The level probes are designed to be replaceable.

Evaporator Sodium Outlet Temperature Three thermocouple channels are provided to measure the sodium temperature at the outlet of the evaporators in each loop.

The thermo-couples are placed just af ter the pipes from each evaporater join to form two single lines.

These three signals are conditioned separately and provided to the Reactor Shutdown Systcm logic.

The Reactor Shutdown System in turn provides buffered signals to the DH & DS.

7.5.2.1.2 Sodium Pumps Sodium Level Sodium level is measured in each pump tank.

The signal provides indication and alarm.

The alarm is used to notify the operator cf abnormal operation and allow initiation of action to prevent pump damage.

Tre signal is also provided to the DH & DS where it can be used in calculation of sodium inventory.

Amend. 50 7.5-8 June 1979 268 13, 7.5.4.1 Design Description _

1.Cover Gas Monitoring 34 s subsystem continuously samples the cover gas and determines, through gamma analysis:- the concentration of selected radioactive fission gases to inform the plant operations staff upon 34 each instance of core or blanket pin cladding failure.- the concentration of radioactive fission gases to characterize the failed pins as to burnup and other i n fo rma ti on.

2.Reat. tor Delayed Neutron Monitoring 34 This subsystem continuously monitors for the presence of fission products in the sodium coolant which decay with the emission of neutrons.

A predetermined increase in the neutron signal from the Primary Heat Transport System sodium, above the nonnal background 34 level, is taken as an indication of fuel contact with sodium.

3.Failed Fuel Location Stable (non-radioactive) xenon and krypton isotopes (that aro not fission products) are placed in each fuel and blanket assembly pin.

Each assembly has a unique ratio of isotopes which will be released to the cover gas upon failure of a pin in the assembly.

The FFM subsystems are described in greater detail in the following sections.

A block diagram of the FFM system is provided in Figure 7.5-3.

7.5.4.1.1. Cover Gas Moni toring Subsvo t m The Cover Gas Monitoring Subsystern receives sample gas from the Inert Gas Receiving and Processing System.

The sampling 50 control system is located in a shielded call in the Reactor Service Building.The cover gas passes through a sodium vapor trap and into charcoal delay bed.

3?Amend. 50 ,,/Od,}j,j_June 1979 7.5-15 O The purpose of the delay bed is to increase the concentration of gas (orimarily xenon and krypton) isotopes of interest, and allnw the argon cover gas to pass through without delay, thus enhancing signal-to-signal background ratio.

A fixed-channel analyzer, located in the reactor service building, analyzes the cover gas sample for radioactive xenon and krypton fission products.

If a leak in a fuel pin occurs, an increase in activity will occur.

This indication of a leak will be annunciated by the Plant Annunciator. A mul ti-channel 34 analyzer, including a mini-computer, analyses the signal from the detector to display the entire gamma spectrum, thus providing burnup and other information characterizing the failed fuel pins to supplement the failure location subsystem through correlation with core and blanket history.

: 7. 5. 4.1. 2 Reactor Delayed Neutron Monitoring Subsystem The Reactor Delayed Neutron Monitoring Subsystem includes a Delayed 34 lNeutron Monitor consisting of an assembly of three BF -filled gas proportional 3 neutron detectors, mounted in a shielded moderator assembly adjacent to each of the three Primary Hea t Transport System hot leg pipes.

Coolant sodium transported past the detector assembly, is contin-uously monitored for delayed neutrons emitted by decay of radioactive precursors in the sodium.

The system sonsitivity is dependent on the signal-to-background ratio of the system.

Signal is defined as detected delayed neutrons produced by recoil of precursors from fuel exposed by cladding fail-ure, or from fission of fuel washed out into the sodium through a failure.

S f yrio T s fruiti the three Dr3 detec tors are routed to individual inputs of a preamplifier.

Each input of the preamplifier provides individual electronic discrimination against gamma-caused counts from each detector.

After discrimination, the neutron-caused counts from the three BF3 detectors, 1 per coolant loop, are comcined in a summing circuit, and routed to a local control 34 i panel located in tne Reactor Containment Building.

The local control panel provides controls for remote adjustment of the preamplifier discriminators, a low voltage power supply, a detector-bias high-voltage supply, a comparator for low detector bias voltage alarn and a front panel function switch to select TEST, CALIBRATE or OPERATE modes.

These signals are routed to a panel in the main control room displaying the output on three five decade logarithmic count 34 rate meters and a three pen five decade logarithmic strip chart recorder.

[Amend. 34 7.5-16 Feb.1977 9 7.5.5.3.1 Design Description General Steam or wate. leakage into sodium increases the hydrogen and oxygen concentrate in the sodiim stream. The leak detection is based on measurement of the hydrogen and oxygen concentration in the sodium.

47 0xygen concentration itieasurements in the sodium are complementary to the hydrogen detectors, thus providing a diverse method to ensure early de-tection.To provide a sensitive leak detection capability, the background concentrations of oxygen and hydrogen are maintained as low as practicable.

The hydrogen in the sodium is removed by cold trap precipitation of sodium hydride.Oxygen in the sodium is removed in the same way by sodium oxide precipitation.

The background concentration of hydrogen in the system is normally maintained below 200 ppb through cold trap operation.

Oxygen 50 33l31 13 concentration is maintained at about 2 ppm.

Hydrogen Detectors The measurc,ent of hydrogen in the sodium is performed by allowing the hydrogen to diffuse through a thin walled nickel membrane, and detecting the hydrogen with an ion gauge and an ion pump.

The monitor may operate in a static mode using the ion gauge to monitor ,teady state hydrogen con-centration, since hydrogen content is directly related to the pressure reasured in the chamber.

The monitor may also operate in a dynamic mode, using the ion pump to coastantly pump the chamber since then the hydrogen concentration is directly related to the ion-pump current.

47 34 0xygen Detectors

_Oxygen electro chemical cells are used to continuously monitor in-sodium concentration and consist of a reference oxygen electrode The electrical separated from the sodium by a solid electrolyte.

potential drop between the reference electrode and the sodium measures the in-sodium oxygen concentration.

Amend. 50 n d U' b f D , June 1979 f, 7.5-26 De tec tors _ L oca t io n_

The three steam generation loops utilize identical oxygen-hydro-gen (0-H) detector modules at the following locations (a) On one evaporator outlet piping downstream, f mixing tee.

This leak detection module under normul operation samples sodium that is a combination of sodiun exiting evaporator A and evaporator B.

However, by the use of valves in the sanple line, the leak detection module may be utilized to sample sodium exiting either evcporator A or evaporator B.(b)Superheater vent line.

This leak detection module under all conditions samples only sodium exiting the :uperheater vent line.(c) On one evapoi'ator vent line downstream of evaporator A/B vent line junction, This leak detection module under normal operation saf"ples sodium that is a combination of sodium exiting the evaporator A vent line and evaporator B vent line.

However, by the use of valves in the sample lines, the leak detection module may be utilized to sample sodium exiting either evap-orator A vent line or evaporator B vent line.(d) On one superhea ter outlet piping. This leak detection module under normal oper ation samples sodium that is a combination of sodium exiting both the suoerheater outlets.

However, by the use of valves in the sample lines, the leak detection module may be utilized to sample the sodium exiting each sodium outlet indopendently.

Indication in Control Room M9asurements from the hydrogen and oxygen detectors are monitored by the Data Handling and Display System.

Each channel is limic checked and its trend is limit checked.

Low level, intermediate level and high level alarms and channel failure alarms are also provided to the Plant 4/Annunciator System.

47 lThe leak detector detects two leak signal categories:

1.a strong signal in a single pass, Amend. 47 7.5-27 t;ov. 1978 O-/ O ()k)V ,

@47 2.detection of a gradual concentration increase or decrease throuqh several passes through the sodium.

Figure 7.5-4 illustrates typical first pass hydrogen concentration change as a function of water ! cal rate-A", illustrated, a change in hydrojen concentration of a few ppb would be indicated at the detector for leak rates in the range of 10-4 lb/sec.

Approximately one minute is required for the hydrogen to reach the detector and signal a leak.

Detection capabilitj can be extended to smaller leak sizes through the use of a rate of rise detection system.

Several passes of sodiun through the systen would be required to allow the hydrogen concentration to build up.

The sensitivi ty of this system will allow detection of leaks in the range of 10-b lb/sec. Similarly, Figure 7.5-4A indicates the first pass oxygen 4el47 concentration as a function of water leak rate.

Figure 7.5-5 illustrates the hydrogen concentration change with time for various sizes of leaks.

1 7.5.5.3.2 De_ sign Ana ly_s i_s A Steam Generator Leak Detection System is provided to comply with CRBRP General Design Criteria 4 which calls for provision of 6 leak detection in the Steam Generators.

In order to show how the criterion will be satisfied, a review of leak damage studies is presented with the resulting instrumentation requirements.)g Amend. 4g 2{g;Feb. 1979 7.5-27a Leak Damage Studies Experimental studies have been conducted in tne United States and in Europe over the past ten years which have given a broad base back-ground to the understanding of the behavior of leakage damage effect.

Most of the experimental data taken with 2-1/4 Cr- 1 Mo material have been obtained by injecting water or steam through hole type geometrics at selected target configurations (jet leaks).

In general, results of these studies have indicated that both adjacent tube wastace and self wastage 45l13 are possible damage mechanisms, as described in Reference 1, 3 and 4.

Adjacent tube wastage will occur with the proper leak size and orientation.

For very specific conditions and geometries, some experi-ments have been performed where adjacent tube wastage occurred very rapidly in a localized area.

Relating these specific conditions to CRBRP, adjacent tube wastage could occur which would result in tube failure in a very short period of time, less than one minute.

However, it is not likely that leaks would be optimized as to leak geometry, location and orientation, as those utilized for the experiments.

In the event that this did occur, the steam generator rupture discs provide necessary protection.

Some experiments have noted that some very small leaks have experienced a sudden enlargement after a period o f relatively steady operation as reperted in Reference 1.

The effect of this type of characteristic has been studied by the GE/ANL Steam Generator Systems Development Program and 13 46 is reported in References 3 and 4.

Design Requirements The desian requirements for the Steam Generator Leak Detectors 13 have been selected as described below.

SGS Leak Detection Requirements 47lHydrogen Detectors Oxygen Detectors 50 lSensitivity 6 ppb 24 ppb!23 Range 0.04-2 ppm 0.1-10 ppm Response Time

$30 sec.<30 sec.47 Amend 50 7.5-28 June 1979 268 160 Instrument Sensitivity The wastage rate studies for jet leaks show that leaks below e 10-4 lb/sec persist without major damage for more than one loop transit time.6 Thelooptransittimecanbgcalculated from a 13.49 x 10 lbs/hr flow rate and 4 x 10 lbs sodium 47 inventory in the IHTS loop; the hydrogen generated from the quantity of H 0 leaked in one transit time divided by the 2 total sodium inventory yields an increase of 6.3 ppb in the 50 471 concentration of hydrogen, thus a 6 ppb sensitivity for the hydrogen detectors.

A resolution cf 3 ppb change in the hydrogen background con-e 5(j centration ranging f om 60 - 200 ppb (i.e., a change of 3-4%) under steady-state SG operation is a design goal for the leak detector.

The oxygen detector is as sensitive as the hydrogen detector.

e Taking into account an oxygen background concentration of 1 ppm (with 2 ppm maximum), the sensitivity is 24 ppb.

47 33 13 Instrument Range Detection capability of leaks up to 10~I lb/sec.

e 47 13 Instrument Availability Sodium loop leak detection capability provides continuous e monitoring and indication of the impurity level whenever sodium and water / steam co-exist in the steam generator modules.

13 Amend. 50 O June 1979 qb'3 lDi ,.L 7,5-29  

@13 Operation Requiren,ents t e In order to effect an orderly plant shutdown which minimize plant unavailability, the following operator actions are required.Ald'E L ea k_ Si z_e_.( 1 b/ se c )

Operator Ac tion.

-5 Low<2 x 10 Confirm leak Monitor leak data

-5 Intermediate 2 x 10 to 5 x 10~

Confirm leak Initiate orderly loop Shutdown-3 High>5 x 10 Confirm leak Initiate rapid 47 module blowdown 9 For leakages greater than about 0.1 lb/sec of water, the pressure buildup in the system will occur rapidly, causing the Sodium-Water Reaction Pressure Relief System to be activated (See Section 7.5.6).

7.5.6 Sodium-Water _ Reaction Pressure Relief System (SWRPRS) Instrumen_t_a_ tion and Controls

_DesiE egiy ti on 7.5.6.1 D 7.5.6.1.1 Function The Sodium-Water Reaction Pressure Relief System Instrumentation and Control equipment detects the inception of a large or intermediate sodium-to-water leak in any of the steam generator modules (see Section 5.5.2.6).The following automatic actions in the affected loop are initiated by a large sodium-to-water leak which bursts the steam generator 43 module main rupture discs:

a.Initiation of reactor and main sodium pump trip.

b.Trip of recirculating water pumps.

,, , c.Isolaticn of steam generaur modules water side.

" Amend. 47'7.5-30 9 7.5.7 Centainment Hydrogen Monitoring The objective of Containment Hydrogen Monitoring is to provide indication in the Control Room of the hydrogen concentration in the upper levels of containment.

7.5.7.1 Design Description The hydrogen instrumentation consists of three self-contair ed electro-mechanical cells located near the top of the RCB with signal lines running outside of containment to preamplifiers.

From there, the amplified signal go to the display and alarm panel in the R eactor Cortrol Room so that continuous readout will be provided to the plant operator.7.5.8 Containment Vessel Temperature Monitorina The objective of Containment Vessel Temperat

'e Monitoring is to provide indication in the Control Room of the cor nment vessel temperature.

7.5.8.1 Design Description The temperature instrumentation consists of thermocouples provided for the outside of steel containment vessel.

Signals will be provided to the display and alarm panel in the R eactor Control Room so that continuous readout will be provided to the plant operator.

7.5.9 Containment Pressure Monitoring The objective of the Containment Pressure Monitoring System is to provide indication in the Control Room of the pressure inside the containment above the oeprating floor.

7.5.9.1 Design Description The pressure instrumentation consists of a pressure detector inside the containment vessel.

Signals will be provided to the display 25 and e'irm panel in the Control Room so that continuous readout will be I prov a d to the plant operator.

7.5.10 Post Accident Monitoring Table 7.5-4 provides a listing of those parameters which are monitored to assure the plant is maintained in a safe shutdown status.Equipment to condition, display, and record the instrument 50 signals is provided in the Control Room.

The instruments which serve the Post Accident Monitoring function are included in those discussed 49 in Sections 7.4.1, 7.5.2, 7.5.3, 7.5.8, 7.5.9, and 7.6.3.

The functions of these instruments correspondinq to the parameter of f able 7 5-4 50 are described in the following paragraphs.

m , _Amend. 50 7.5-33b/bb}bs June 1979 The reactor sodium level is monitored to enable the operator to determine whether manual action is necessary to mitigate condition 3 which nay cause low reactor Vessel sodium levels.

The operator may also use the reactor sodium level to deter mine <:onditions in the primary sodium systems such as the volume of primary coolant leakage.

The IHX (Intennediate Heat Exchanger) inlet and outlets temperatures are monitored to verify the heat transfer from P4TS to the IHTS.

These monitors allow the operator to take manual actions r"Jcessary to assura decay r. eat removal from the reactor is maintaire?d within design limits.

Reactor Containment Building pressure and tenperature monitors are provided to follow pressure and temnerature changes due to an accident, and previde confidence that the accident consequences are within the capability of the Containnent Vessel.

Also, these monitors can be used to detect conditions beyond the design basis as discussed in Reference 0 of Sectior 1.6.

The PWST (Protected Water Storage Tank) water level is monitored so the operator is assurcJ of the adequacy of that water supply to remove reactor decay heat for an extended period of time.

In adaition, the level monitor provides indication of the long tenn need ,, refill the PUST or draw auxiliary feedwater from an alternate source.

The Auxiliary r eedwater Flow is monitored to inform the operator of nonnal, abnormal or inadequate flow.

He can take manual actions to provide adequate flow and thas maintain adequate decay heat removal through the steam genera'or systen.

LVST sodium hot leg temperature is monitored tr. enable the operator to make man a l actions during normal, transient, and accident conditions which are necessary to prevent or mitigate the exceeding of 50 Ex-Vessel Storage Tank and stored fuel assembly design limits.

Amend. 50 7.5-33c 268!2 9 References to Section 7 5 1.Ford, J.A.,"A Recent Evaluation of Foreign and Domestic Wastage Data from Sodium Water Reaction Investigation", APDA CTS-73-05, January, 1973.

2.Morejon, J.A., " Sodium-to-Gas Leak Cetection Mockup Tests", N707-TR-520-C04, September 17, 197 L (Atomics International) 3.Greene, D.

A., J. A. Gudahl and J. C. Hunsicker, " Experimental Investigation of Steam Generator Materials by Sodium-Water Reactions, Volume 1, GEAP-14094, January 1976.

4.Gudahl, J. A. and P. M. Magee, "Microleak Wastage Test Results", 46 GEFR-00352, March 1978.

Amend. 50 7.5-33d June 1979 bf3!bb I e I_._, o e g r , S t ,s r.i y P e e s;n al d a d a P eM et t r. p sP ra ie0 nr r l 0 e.1 c , u ui n he ,o c s)e sd c v)a r e.ye i S dt d s ee rt e ce r;gn o .ar D C na ne- c ee tl i g P ar arrn&tt h r ea t c l a e se l r cp pd d (t pe a s r.n y1 y t r yei c t o Se e a a m a1 al nr a rd s w a(id e l a l aie l ue l t pc pi f psn: ap P c rl r F r o n s st5 r i rt ssr c s s s sd u rr ro e re y iy n e ee p un oo c+oi c t c S dl d eyp d t e t s f f t y n ,cn a-a a nn ,l , rr i a oa l a eas mCr o ec ef mT el t p st c si l s u l p l l c p r r y c. i f. i a c a: t ae at)an s o te t a' rs r - r r ni r- c n n y n i f a;x gal gn d r nf nl at r ad p at a. t i e il n i n e l r n l e 5 e r cp l a e l l n 8 F s S(S pc Sa d ie C is l mt i*r F p iie oe ir p tD t ee aS erc eios a vf ,S n vo pc2 nt c rf T I'1 2 3 4 5 H ST ad rl o c ei P FH l n ual P F F p a Scf S rtI Sd*P C ,f j;Y R A f 4 c f P-d r n g U- e X a n S d d d rt h ip A n e e H. e r r r en I t 3 a a ti o ip qs).&D e u N 9" p n.n g in t X i d t t gp s s~u e f f f I ng s i.rm-o o S it 3 a n p ae e d'np e j N a Y y y c r r c t o a e c yl a e c e*." . . . -O" r.L c h l rt e r s m w I u-C t.IE" ao r r d' i t u p p 1 T i i/nt e ,..e 5 N" r.r r i();t d b nt n mo 7 7bo e a r 2 ipl r.-e e-rs e I os e p'p Qm $.m.U r E p t r 7 F e rc t s d.ae r f.t e o p coo p'n n" r e 's it;r ,,.u l '0 a da E M s;g g g np ee rh 93s.L E a S's s c*e e e eee ey) e ic l l tt l r rl l e rr B T Dtn,e $-,, MI;!aa c a nl ee?l l , A S e e d dii d r md T Y s s:ns s s l l dd l i il'a e tp-nu s-e.ih e o oee or ro rh IS S e h -T v C C rr C p P c Ot ,, .O'l{b~h v T N I T s s A d t t Nuh t T s e n n N r t n e.e h'E e a e m r b s m M r.n e r e e le e l a U t a er l e l E t p er C E.R n h pe[f ~k e J cu%th e C mb o nt e e c T om e c aa r r-r S a n Ca s lo o t r u u a N r o h m se)s s I t i ,C s s 0 s F r' pD s s I e e s n 3 s 1 n e e ecR r r r M h.,g I F i- o S F BI P F T RT(P P.t h , iI 5-t--r e r-r e e l e a e r t t td r t u*.C Inne n s n a I *ap: s*-pe e e.ye dt e d r t eP e*d o at l s g*e d r n e g n nl r r.naT n I *aF a t aF aP ie e dl e ee a g n rr ye irt n etr e a yee yeg r t R n a t a P e 3 a t rt r- uu u e a R rt rr rt s m e R en a 3 a rCs aa c r a. i p-id e mit e s ns e id idl r id s tX e r er r e e RP P r I1e reou r ei nH r d w M a u i P er ra i T F rCt P rC:IP P o c S W e , g t e n r t i o i a r p w s/d t n y e.@i ar m n rams e c Tnep t M it o s t rno y x API l-S u e l n Flll 1l0>B$a.m-0 0 g 0 5 N wauA aCb 8 r r;5 5 V [~~ uo F 7[

y , m r l u o o t r-r r id n t o o o o e n p t t s v)o a a a nm c v r r p i r e e r r e e e o a d c o o n n c o ml e n&t t e e e n l ua e a an an gn gn n n r ro ro o o o o m s a i(p e ei ei mi mi i on c o t nt nt at at t it e d s e m o am t p so p n f a ea ea ea ea a a r o u f i a i -a r ee gu gu t u t u u u P r dl rt u m e h c l l sl sl l l e ea y oc-r p rn ma ma a a a a p m a f e o ea av av& v& v v v ee ee e e e e pm t rd l t.f p u t y y p en p d o y r--t a s er ae e u so se se ae ae e e p i y i sp l c p p f c c l c l c c c u n d u pn& r& n& n pn pn n n y yo d ym i m y y yp y-ym isa sa a a- r- p sa , , e a a mim m-d r r a a a ar a r d a at n au d l l n a l p o l l l r l o l o o o o o p pe p ,f p p po pf pf ,f ,f f f s s v S sd S r s s st sr sr S r S r r r n P i n P e i i i a ie ie P e P e e e i iDi P Da F p D D D r Dp Dp P p P p P P D r o)p t p t)-a o t e u r o el p p o l l t h o p t t u c o d ar 1 e uc a l n k ve (l o e a n ed t r r 1 n a a t u ,o e r (o r t oe e o tt m t o)i o wh p l ea u a f r t t n t-t r l r r e o a a o e u u o no d h e t d eh p o t i p r n a e c r is ht a a m e i r u e o L p n t h m r rv a p l o a a o c u o ee e u p n i t v p et a i p t t s n a t n e x rn e d a ad s i v e e ei o v en h a e-n h f s e h a o c r n o e e e wn o r t a D e r r e))e n C r e t i u w a mo t e e ps er m o s t i aj k f t t)ucj ne f um (M e d e n a a as seg i t o ru o 1 e t'e rs a h e ep l e l a)D r t tt T S h h o p l w t m d-" m st se s s r re oh td ea mm t n p p e el ot e ee l e aa e.5 ee e nl p i e r p p l on e t t ee l'om a u u u3 b e lnf us tt n pl t wt r 7 i n n ou g4 Pi I Do P M P P S S(1((I(D(Ss I E q L , B y A 7'-, T s t , t n+n~e e m.e e h e e p 6.,-t l e l e c l l ,a p, 9 E b p b r t p E r P c P e S s i c r i i e i , ,u u e o u o e i c e e r c r t w r c r m u r o u r r i t m sa], f m e u s u u u m l o d o u t s l s t t f t s s e r e h e ir n e e n n i n 5 -,a n e v e v c e' , I r e h e a p a e h r e e r e P L T L T S V V T P V V O V-r on.l.d :

* m---*n e g-e I s n u_-r p l mr f r u n t r o-uu i.u xu it ee r t t e*m i e P e Ei da- e r s a r w a a l P .4-1: e o e: S e l eS t.'n r u o e r n r d o-r p e s l t D I t t s t5 p e t-: s F S;e m r: r as a rm v r;s)r r t u o f-oe e I ee i e idn tT L/u i e a r t C-r*d r ue eP ea a yP t e D a s -rt - T rt r r 1 m.m a h r u a e u w r*m o<aa r l oe id ic a d ew aw p w i M d e po ee ao g:l rt ,'r.er ee e n e.II I sL EC S Pd P?S S S F SF SF EF , ,~at t F. a tl t. i e e vu o ri o u: o e ul tl vl P nn r-s g4 i3 P4 o~,)d r t o t t 't t r o an s a;io?r e r s/d c n nrye(P e-~s G e-a-r m e;t's it ;id e a y t r-;'O* sg NCC C-lm80.aTI L S_e o t*H S S O.3 o 5,_- Ne , 9 9 4 4- -w*wi"m TABLE 7.5-4 POST ACCIDENT MONITORING Parameter Sensor Location

: 1) Reactor Sodium Level RCB 2)IHX Inlet Temperature RCB 3)IHX Outlet Temperature RCB 4) DHRS Cold Leg Temperature RCB 5) RCB Pressure RCB 6) RCB Temperature RCB 7) PWST Level SGB 8) Auxiliary Feedwater Flow SGB 9) Steam Drum Level SGB 10) Steam Drum Pressure SGB 50l11) Deleted 49 12) EVST Outlet Piping Temperature RSB 268 160 Amend. 50$June 1979 Rotating Plug drive system /IVTM grapple position Rotating plug drive system /IVTM hold down sleeve Rotating plug drive system /EVTM position EVST drive motors /EVTM grapple position y 7.6.2.2 Desi_gn Analysis Postulated Reactor Refueling System (RRS) accidents with potentially severe consequences were analyzed in detail to determine requirements for safety interlocks. The techniques employed included safety assurance diagrams, fault trees, mechanical and thermal analyses, and radiological release calcu-lations.fione of the analysis results showed off-site doses exceeding those presented in Section 15.5 or 15.7.

The off-site doses in Section 15.5 and 15.7 resulting from postulated RRS accidents are all well below the 10 CFR 100 guideline exposures without taking credit for interlocks.

It was there-fore concluded that the RRS does not require safety interlocks.

44 7.6.3 Direct Heat Removal Service (DHRS) Instrumentation and Control System 7.6.3.1 Design Description 7.6.3.1.1 Function The DHRS (fluid system and mechanical components as described in Section 5.6, and electrical components as described below) provides a supple-mentary means of removing long term decay heat for tha remote case in which none of the steam generator decay heat removal paths are available.