Text

Clinch River Breeder Reactor Plant Fuel Assembly Structural Analysis in Support of Final Design Review.
	ML19331D327
Person / Time
Site:	Clinch River
Issue date:	01/31/1978
From:	Bitner J, Prevenslik T, Sane A; WESTINGHOUSE ELECTRIC COMPANY, DIV OF CBS CORP.
To:	;
Shared Package
ML19331D323	List: ML19331D322; ML19331D327;
References
	CRBRP-ARD-0204, CRBRP-ARD-204, NUDOCS 8009020017
	Download: ML19331D327 (389)
	v • d • e

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CRBRP-ARD-0204 ,

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U Clinch River

~ Breeder Reactor Plant FUEL ASSEMBLY STRUCTURAL ANALYSIS IN SUPPORT OF THE FINAL DESIGN REVIEW JANU ARY,1978

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Prepared for the United States Department of Energy under contracts DE-ACIS-76CLO2395 and EW-76-C-15-0003.

Any Further Distribution by any Holder of this Document or of the Data Therein to Third Parties Representing Foreign Interest, Foreign Govern-ments, Foreign Companies and Foreign Subsidi-aries or Foreign Divisions of U.S. Companies Should be Coorinated with the Director, Division of Reactor Research and Technology, United States Department of Energy.

i" W Westinghouse Electlic Corporation i -- ADVANCED REACTORS OlVISION

.s ic7th:.: 80X 158 l 0.

M ADISO N. PENNSY1.V ANI A 15663 i

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C l INFORMATION CONCERNING USE OF THIS DOCUMENT PRELIMINARY DOCUMENT This document contains information of a preliminary nature prepared in the course of work for the U.S. Department of Energy. This information is subject to correction or modification upon the collection and evaluation of additional data.

NOTICE This document was prepared as an account of work sponsored by the United States Government. Neither the U.S. Department of Energy, nor any of their employees, nor any of their contractors, subcontractor 0, or their employees, makes any warranty, express or impiled, or assumes any legal liability or responsibility for the accuracy, completeness or usefulness of any information, apparatus, product or process disclosed, or represents that its use would not infringe privately owned rights.

1 WESTINGHOUSE ELECTRIC CORPORATION ADVANCED REACTORS DIVISION BOX 158 MADISON, PENNSYLVANIA 15663 L,,

CRBRP-ARD-0204 k

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4 CRBRP FUEL ASSEMBLY STRUCTURAL ANALYSIS IN SUPPORT OF THE FINAL DESIGN REVIEW January 1978 Prepared by: ' h \) t um' T. V. Prevenslik

Contributors: A. D. Sane D. V. Swenson M. A. Todd y /? , *) ,

Approved by: '

N ))Mr.v J. L. Bitner, Manager Structural Analysis l

WESTINGHOUSE ELECTRIC CORPORATION Advanced Reactors Division l P.O. Box 158 Madison, Pennsylvania 15663 iO w

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TABLE OF CONTENTS

' A' pag l.0 INTRODUCTION . . . . . . . . . . . . . . . . . . . . . . . . 1 g, 1.1 Purpose . . . . . . . . . ., . . . . . . . . . . . . . . . 1 g 1.2 Scope . . . . . . . . . . . . . . . . . . . . . . . . . . 1 1.3 Applicability . . . . . . . . . . . . . . . . . . . . . . 1 1.4 Summary . . . . . . . . . . . . . . . . . . . . . . . . . 2

2.0 DESCRIPTION

AND APPROACH . . . . . . . . . . . . . . . . . . . 3 2.1 Shield Block ...................... 6 2.2 CMP Hex Duct ...................... 6 2.3 ACLP Hex Duct . . . . . . . . . . . . . . . . . . . . . . 7 2.4 TLP Outlet Nozzle . . . . . . . . . . . . . . . . . . . . 8 2.5 Attachment Assembly . . . . . . . . . . . . . . . . . . . 8 2.6 O ri fi ce P l a te . . . . . . . . . . . . . . . . . . . . . . 9 3.0 CRITERIA . . . . . . . . . . . . . . . . . . . . . . . . . . . 10 3.1 Background and Rationale ................ 13 3.1.1 ASME Section III Code .............. 13 3.1.2 Code Case 1592 . . . . . . . . . . . . . . . . . . 14 3.1.3 RDT Draft Criteria for Breeder Reactor Core Components . . . . . . . . . . . . . . . . . . . . 15 :

. 3.1.4 CRBRP F/A Core Components. . . . . . . . . . . . . 17 3.1.4.1 Crack Initiation ............ 19 3.1.4.1.1 Local Ductile Rupture. . . . . 19 l e 3.1.4.1.2 Creep-Fatigue Damage . . . . . 21 3.1.4.2 Excessive Deformations ......... 23 3.2 Appl i ca ti on . . . . . . . . . . . . . . . . . . . . . . . 24 1 3.2.1 Crack Ini tiation . . . . . . . . . . . . . . . . . 25 3.2.1.1 Local Ductile Rupture . . . . . . . . . . 25 3.2.1.2 Creep-Fatigue Damage .......... 26 :

3.2.2 Excessive Deformation .............. 28 l 4.0 SHIELD BLOCK ANALYSIS AND EVALUATION . . . . . . . . . . . . . 29 4.1 Loading Analysis. . . . . . . . . . . . . . . . . . . . . 29 4.1.1 Mechanical . . . . . . . . . . . . . . . . . . . . 29 4.1.2 Thermal ..................... 30 4.1.2.1 Model and Geometry ........... 34

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4.1.2.2 P roperti es . . . . . . . . . . . . . . .

36 4.1.2.3 Boundary Conditions and Wetted Surfaces. 36 , s, 4.1.2.4 Heat Generation Rates ......... 38 38 4.1.2.5 Analysis and Results . . . . . . . . . .

45 4.1.3 Wo rs t Ca s e Du ty Cycl e . . . . . . . . . . . . . .

4.2 Structural Analysis. . . . . . . . . . . . . . . . . . . 47 4.2.1 Model, Geometry, and Boundary Conditions .... 47 4.2.2 Properties ................... 49 4.2.2.1 Linear . . . . . ............ 50 4.2.2.2 Non-linear . . . . . . . . . . . . . . . 50 4.2.2.2.1 Stress-Strain Curves .... 50 4.2.2.2.2 Thermal Creep Equations . . . 53 4.2.3 Worst Case Duty Cycle Response ......... 53 4.2.3.1 Constraints and Reference Temperature Selections . . . . . . . . . . . . . . . 54 4.2.3.2 Analysis and Results . . . . . . . . . . 56 4.2.3.2.1 Time Independent ...... 56 4.2.3.2.2 Time Dependent ....... 63 4.3 Structural Evaluation. . . . .............. 66 4.3.1 Crack Initiation ................ 67 4.3.1.1 Local Ductile Rupture ......... 67 4.3.1.1.1 Allowable Uniaxial Strains . 67 4.3.1.1.1.1 Uniform Elongation 68

+

4.3.1.1.1.2 Fracture . . . . 68 4.3.1.1.2 Comparison with Criterion . . 69 4.3.1.2 Creep-Fatigue Damage . . . . . . . . . . 70 4.3.1.2.1 Allowable Limits ...... 70 4.3.1.2.1.1 Fatigue Life . . 71 4.3.1.2.1.2 Creep-Rupture Time 75 4.3.1.2.2 Comparison with Criterion . . 79 4.3.2 Excessive Deformation ............. 80 4.3.2.1 Peak Plus Accumulated Defonnations . . . 80 4.3.2.2 Residual Deformations ......... 81 4.3.3 S unina ry . . . . . . . . . . . . . . . . . . . . . 81

4

5.0 CMP HEX DUCT ANALYSIS AND EVALUATION . . . . . . . . . . . . . 83 4 5.1 Loading Analysis. . . . . . . . . . . . . . . . . . . . . 83 g 5.1.1 Mechanical . . . . . . . . . . . . . . . . . . . . 83 g 5.1.1.1 Beam Bending .............. 84 5.1.2 Thermal. . . . . . . . . . . . . . . . . . . . . . 87 5.1.2.1 Model and Geometry ........... 92 5.1.2.2 Properties ............... 94 5.1.2.3 Boundary Conditions and Wetted Surfaces . 94 5.1.2.4 Heat Generation Rates . . . . . . . . . . 96 5.1.2.5 Analysis and Results .......... 97 5.1.3 Worst Case Duty Cycle .............. 102 5.2 Structural Analysis . . . . . . . . . . . . . . . . . . . 104 5.2.1 Model, Geometry and Boundary Conditions ..... 104 5.2.2 Properties . . . . . . . . . . . . . . . . . . . . 106 5.2.2.1 Linear ................. 106 5.2.2.2 Non-linear ............... 106 5.2.2.2.1 Stress-Strain Curves . . . . . 106 5.2.2.2.2 Thermal Creep Equations ... 108 5.2.3 Worst Case Duty Cycle Response . . . . . . . . . . 109 a 5.2.3.1 Constraints and Reference Tempcrature Selections. . . . . . . . . . . . . . . . 109 5.2.3.2 Analysis and Results .......... 110

.- 5.2.3.2.1 Time Independent . . . . . . . 111 5 2.3.2.2 Time Dependent . . . . . . . . 115 5.3 Structural Evaluations. . . . . . . . . . . . . . . . . . 116 5.3.1 Crack Initiation . . . . . . . . . . . . . . . . . 117 5.3.1.1 Local Ductile Rupture . . . . . . . . . . 117 5.3.1.1.1 Allowable Uniaxial Strains . . 118 5.3.1.1.1.1 Unifonn Elongation 118 5.3.1.1.1.2 Fracture .... 119 5.3.1.1.2 Comparison with Criterion .. 119 5.3.1.2 Creep-Fatigue Damage .......... 120 5.3.1.2.1 Allowable Limits . . . . . . . 120 5.3.1.2.1.1 Fatigue Life .. 121 i

0 5.3.1.2.1.2 Craep Rupture Time 125 5.3.1.2.2 Comparison and Criterion . . . 128

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5.3.2 Excessive Deformation . . . . . . . . . . . . . . . 129 b

5.3.2.1 Peak Plus Accumulated Deformations . . . . 129 5.3.2.2 Residual Deformations .......... 130 g 5.3.3 Summary . . . . . . . . . . . . . . . . . . . . . . 130 ,

6.0 ACLP HEX DUCT ANALYSIS AND EVALUATION . . . . . . . . . . . . . 131 6.1 Loading Analysis . . . . . . . . . . . . . . . . . . . . . 131 6.1.1 Mechanical .................... 131 6.1.1.1 Beam Bending . . . . . . . . . . . . . . . 132 6.1.1.2 Local Contact .............. 135 6.1.1.2.1 OBE and SSE Seismic . . . . . . 136 6.1.1.2.2 Steady State and Transient Core Restraint ........ 141 6.1.2 Thermal . . . . . . . . . . . . . . . . . . . . . . 147 6.1.2.1 Model and Geometry . . . . . . . . . . . . 154 6.1.2.2 Properties . . . . . . . . . . . . . . . . 156 6.1.2.3 Boundary Conditions and Wetted Surfaces . 156 6.1.2.4 Heat Generation Rates. . . . . . . . . . . 158 6.1.2.5 Analysis and Results . . . . . . . . . . . 159 6.1.3 Wo rs t Ca s e Du ty Cyc l e . . . . . . . . . . . . . . . 164 6.2 Structural Analysis ................... 167 .

6.2.1 Model, Geometry and Boundary Conditions . . . . . . 167 6.2.2 Properties .................... 169 6.2.2.1 Linear . . . . . . . . . . . . . . . . . . 169 +

6.2.2.2 Non-Linear . . . . . . . . . . . . . . . . 169 6.2.2.2.1 Stress Strain Curves ..... 169 6.2.2.2.2 Thermal Creep Equations . . . . 174 6.2.2.2.3 Irradiation Creep and Swelling Equati ons . . . . . . . . . . . 177 6.2.3 Worst Case Duty Cycle Response .......... 178 6.2.3.1 Constraints and Reference Temperature Selection ................ 178 6.2.3.2 Analysis and Results . . . . . . . . . . . 179 6.2.3.2.1 First Cycle - Tine Independent 179 6.2.3.2.2 First Cycle - Time Dependent 185 6.2.3.2.3 Second Cycle - Time Independent 189 6.2.3.2.4 Second Cycle - Time Dependent 192

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6.3 Structural Evaluation . . . . . . . . . . . . . . . . . . . 195 6.3.1 Crack Ini tiation . . . . . . . . . . . . . . . . . . 195 or 6.3.1.1 Local Ductile Rupture . . . . . . . . . . . 195 0 6.3.1.1.1 Allowable Uniaxial Strains . . . 196 6.3.1.1.2 Comparison with Criterion ... 196 6.3.1.2 Creep-Fatigue Damage ........... 199 6.3.1.2.1 Allowable Limits . . . . . . . . 199 6.3.1.2.2 Comparison with Criterion ... 202 6.3.2 Excessive Deformation ............... 204 6.3.2.1 Peak Plus Accumulated Deformations .... 2 04 6.3.2.2 Residual Deformations . . . . . . . . . . . 205 6.3.3 Summary . . . . . . . . . . . ........... 206 7.0 TLP OUTLET N0ZZLE ANALYSIS AND EVALUATION. . . . . . . . . . . . 207 7.1 Loading Analysis ..................... 207 7.1.1 Mechanical . . . . . . . . . . . . . . . . . . . . . 207 7.1.2 Thermal ...................... 208 7.1.2.1 Model and Geometry ............ 21 3 7.1.2.2 Properties. . . . . . . . . . . . . . . . . 215 j 7.1.2.3 Boundary Conditions and Wetted Surfaces . . 215 7.1.2.4 Heat Generation Rates . . . . . . . . . . . 217 7.1.2.5 Analysis and Results ........... 218 7.1.3 Worst Case Duty Cycle .. . . . . . . . . . . . . . . 223 e

7.2 Structural Analysis . .................. 224 7.2.1 Model, Geometry, and Boundary Conditions . . . . . . 224 7.2.2 Properties . . . . . . . . . . . . . . . . . . . . . 226 7.2.2.1 Linear .................. 226 7.2.2.2 Non-Linear ................ 226 7.2.2.2.1 Stress-Strain Curves . . . . . . 226 l l

7.2.2.2.2 Thermal Creep Equations .... 227 7.2.3 Worst Case Duty Cycle Response . . . . . . . . . . . 230 7.2.3.1 Constraints and Reference Temperature Selection ................ 230 7.2.3.2 Analysis and Results ........... 232 7.2.3.2.1 Tine Independent . . . . . . . . 233 7.2.3.2.2 Time Dependent . . . . . . . . . 239

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243 7.3 Structural Evaluation . . . . . . . . . . . . . . . . .

243 7.3.1 Crack Ini tiation . . . . . . . . . . . . . . . .

Local Ductile Rupture . . . . . . . . . 243 ,,

, 7.3.1.1 7.3.1.1.1 Allowable Uniaxial Strains . 244 e

7. 3.1.1. 2 Comparison with Criterion. . 244

7. 3.1. 2 Creep-Fatigue Damage. . . . . . . . . . 245

7. 3.1. 2.1 Allowable Limits . . . . . . 245 7.3.1.2.2. Comparison with Criterion. . 248 249 7.3.2 Excessive Deformation. . . . . . . . . . . . . .

249

7.3.2.1 Peak Plus Accumulated Deformations. . .

250 7.3.2.2 Residual Deformation. . . . . . . . . .

7.3.3 Summary. . . . . . . . . . . . . . . . . . . . . 25G 252 8.0 ATTACHMENT ASSEMBLY ANALYSIS AND EVALUATION. . . . . . . . .

8.1 Loading Analysis. . . . . . . . . . . . . . . . . . . .

252 252 8.1.1 Mechanical . . . . . . . . . . . . . . . . . . .

253 8.1.1.1 Deadweight. . . . . . . . . . . . . . .

8.1.1.2 Pressure Drop . . . . . . . . . . . . . '256 259 8.1.1. 3 Seismic . . . . . . . . . . . . . . . .

8.1.1.3.1 Horizontal . . . . . . . . . 261 8.1.1. 3. 2 Vertical . . . . . . . . . . 264 8.1.1. 4 S umma ry . . . . . . . . . . . . . . . . 266 268 8.1.2 Thermal. . . . . . . . . . . . . . . . . . . . . m 8.1.2.1 Dimensional Extent and Finite Element Detail. . . . . . . . . . . . 269 8.1.2.2 Thermal Analysis. . . . . . . . . . . . 273 8.1.2.2.1 Model, Boundary Conditions, and Wetted Surfaces. . . . 273 8.1.2.2.2 Properties . . . . . . . . . 275 8.1.2.2.3 Res ul ts . . . . . . . . . . . 275 l

8.1.2.3 Structural Analysis . . . . . . . . . . 276 l

8.1.2.3.1 Model and Boundary Conditions 276 l

i 8.1.2.3.2 Properties . . . . . . . . . 278 8.1.2.3.3 Results. . . . . . . . . . 278 8.1.2.4 Conclusions . . . . . . . . . . . . . . 280 l

8.1. 3 Wo rs t Ca s e Du ty Cycl e . . . . . . . . . . . . . . 281 ,

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8.2 Structural Analysis . . . . . . . . . . . . . . . . . . 285 i 8.2.1 Model and Geometry . . . . . . . . . . . . . . . 285 8.2.2 Boundary Conditions and Loading Application. . . 287 8.2.3 Properties . . . . . . . . . . . . . . . . . . . 289 o

8.2.3.1 Linear. . . . . . . . . . . . . . . . . 289 8.2.3.2 Non-Linear. . . . . . . . . . . . . . . 289

8.2.3.2.1 Stress-Strain Curves . . . . 289 8.2.3.2.2 Thermal Creep Equasions. . . 291 8.2.4 Worst Case Duty Cycle Response . . . . . . . . . 291 8.2.4.1 Analysis and Results. . . . . . . . . . 292 8.3 Structural Evaluation . . . . . . . . . . . . . . . . . 301 8.3.1 Crack Ini tiation . . . . . . . . . . . . . . . . 301 8.3.1.1 Local Ductile Rupture . . . . . . . . . 301 8.3.1.1.1 Allowable Uniaxial Strains . 302 8.3.1.1.2 Comparison with Criterion. . 302

8. 3.1. 2 Creep Fatigue Damage. . . . . . . . . . 303

8. 3.1. 2.1 Allowable Limits . . . . . . 304 8.3.1.2.2 Comparison with Criterion. . 304 8.3.2 Excessive Defonaation. . . . . . . . . . . . . . 305

. 8.3.2.1 Peak Plus Accumulated Deformation . . . 305 8.3.2.2 Residual Deformations . . . . . . . . . 306 8.3.3 S umma ry . . . . . . . . . . . . . . . . . . . . . 307 o 9.0 0FFICE PLATE ANALYSIS AND EVALUATION . . . . . . . . . . . . 309 l 9.1 Loading Analysis. . . . . . . . . . . . . . . . . . . . 309 9.1.1 Mechanical . . . . . . . . . . . . . . . . . . . 309 9.1.2 Thermal. . . . . . . . . . . . . . . . . . . . . 312 9.1.3 Worst Case Duty Cycle . . . . . . . . . . . . . . 315 l

! 9.2 Structural Analysis . . . . . . . . . . . . . . . . . . 316 l

9.2.1 Model and Geometry . . . . . . . . . . . . . . . 31 6 j 318 1 9.2.2 Properties . . . . . . . . . . . . . . . . . . .

! 9.2.2.1 Linear. . . . . . . . . . . . . . . . . 31 8 l 9.2.2.2 Non-Linear. . . . . . . . . . . . . . . 318 9.2.2.2.1 Stress-Strain Curves . . . . 31 8 9.2.2.2.2 Thermal Creep Equations. . . 31 9 o

l

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9.2.3 Elastic Response . . . . . . . . . . . . . . . . 321 ,

321 9.2.3.1 Pressure Drop . . . . . . . . . . . . .

9.2.3.1.1 Model and Boundary Conditions 321 9.2.3.1.2 Analysis and Results . . . . 323 .

9.2.3.2 Radial Interferance . . . . . . . . . . 325 9.2.3.2.1 Model and Boundary Conditions 325 9.2.3.2.2 Analysis and Results . . . . 327 9.2. 3.3 Conclusions . . . . . . . . . . . . . . 327 9.2.4 Worst Case Duty Cycle Response . . . . . . . . . 329 9.2.4.1 First Cycle - Time Independent. . . . . 329 9.2.4.2 First Cycle - Time Dependent. . . . . . 333 9.2.4.3 Second Cycle - Time Independent . . . . 333 9.2.4.4 Second Cycle - Time Dependent . . . . . 334 9.3 Structural Evaluation . . . . . . . . . . . . . . . . . 337 9.3.1 Crack Ini tiation . . . . . . . . . . . . . . . . 337 9.3.1.1 Local Ductile Rupture . . . . . . . . . 338 9.3.1.1.1 Allowable Uniaxial Strains . 338

9. 3.1.1. 2 Comparison with Criterion. . 338

9. 3.1. 2 Creep-Fatigue Damage. . . . . . . . . . 340 9.3.1.2.1 Allowable Limits . . . . . . 340 9.3.1.2.2 Comparison with Criterion. . 341 9.3.2 Excessive Deformation. . . . . . . . . . . . . . 342 9.3.2.1 Peak Plus Accumulated Deformations. . . 342 9.3.2.2 desidual Deformations . . . . . . . . . 343 9.3.3 Summary. . . . . . . . . . . . . . . . . . . . . 343

10.0 REFERENCES

. . . . . . . . . . . . . . . . . . . . . . . . . 345 11.0 AC KNOWLEDGEMENTS . . . . . . . . . . . . . . . . . . . . . . 349 l APPENDIX A - DAMAGE PROCESSOR . . . . . . . . . . . . . . . . . . . A-1 t

1

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l

i LIST OF TABLES i

1.0-1 F/A Margin of Safety Summary . . . . . . . . . . . . . . . . . 2 3.0-1 CRBRP F/A Inelastic Criteria and Limits. . . . . . . . . . . . 12 -

l 4.1-1 Worst Case F/A Shield Block Duty Cycle ANSYS Input Data ... 39 4.2-1 F/A Shield Block True Minimum Mean of BOL and E0L Stress-Strain Data SA-316-SS. . . . . . . . . . . . . . . . . . . . . 53 4.2-2 F/A Shield Block Reference Temperatures ........... SS 4.2-3 F/A Shield Block Time Independent Analysis Sumary Initial Steady State Conditions ................... 57 l

4.2-4 F/A Shield Block Time Independent Analysis Sunnary E-4a Transient and Return to Final Steady State Conditions .... 58 4.2-5 F/A Shield Block Time Dependent Analysis Sumary 10-day Hold-Time and Unloading ................... 63 4.3-1 F/A Shield Block Fractional Reduction Rupture Strength SA-316-SS.............................. 76 4.3-2 F/A Shield Block Structural Evaluation Sunnary . . . . . . . . 82 5.1-1 F/A CMP Hex Duct OBE and SSE Seismic, and Core Restraint Bending Moments, Stresses, and Strains . . . . . . . . . . . . 86 5.1-2 Worst Case F/A CMP Hex Duct Duty Cycle ANSYS Input Data ... 97 5.2-1 F/A CMP Hex Duct Minim, n Yield and Proportional Elastic Limit Stress First Core 20% CW-316-SS . . . . . . . . . . . 107 5.2-2 F/A CMP Hex Duct Reference Temperatures . . . . . . . . . . 110 5.2-3 F/A CMP Hex Duct Time Independent Analysis Suxary Initial Steady State, E-16 Transient, and Final Steady State . . . . 111 5.3-1 F/A CMP Hex Duct Structural Evaluation Sumary . . . . . . . 130 f

6.1-1 F/A ACLB Hex Duct OBE and SSE Seismic and Core Restraint Bending Moments , Stresses, and Strains . . . . . . . . . . . 134 6.1-2 F/A ACLP Hex Duct Average 19 90 Sector Loads . . . . . . . 140 6.1-3 F/A ACLP Hex Duct Average Steady State Core Restraint 90*

Sector Loa ds . . . . . . . . . . . . . . . . . . . . . . . . 145 ;

6.1-4 Worst Case F/A ACLP Hex Duct Duty Cycle ANSYS Input Data . . 159 6.2-1 F/A ACLP Hex Duct True Minimum Mean of 80L and E0L Stress-Strain Data . . . . . . . . . . . . . . . . . . . . . . . . 172 6.2-2 F/A ACLP Hex Duct Reference Temperatures . . . . . . . . . . 178 6.2-3 F/A ACLP Hex Duct First Cycle Time Independent Analysis Sumary Initial Steady State, E-16 Transient / Mechanical Loads, and Final Steady State . . . . . . . . . . . . . . . 18 0 o

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l l - . . . . - , - - -

6.2-4 F/A ACLP Hex Duct First Cycle Time Dependent Analysis

Sumary 10-day Hold-Time and Unloading . . . . . . . . . . . 185 6.2-5 F/A ACLP Hex Duct Second Cycle Time Independent Analysis Sumary Initial Steady State, E-16 Transient, and Final Steady State . . . . . . . . . . . . . . . . . . . . . . . . 189 ,

6.2-6 F/A ACLP Hex Duct Second Cycle Time Dependent Analysis Sumary 10-day Hold-Time and Unloading . . . . . . . . . . . 192 6.3-1 F/A ACLP Hex Duct Structural Evaluation Sumary ...... 206 7.1-1 Worst Case F/A Outlet Nozzle Duty Cycle ANSYS Input Data . . 218 7.2-1 F/A Outlet Nozzle True Minimum BOL and E0L Stress Strain Data SA-316-SS . . . . . . . . . . . . . . . . . . . . . . . 227 7.2-2 F/A Outlet Nozzle Reference Temperatures . . . . . . . . . . 232 7.2-3 F/A Outlet Nozzle Time Independent Analysis Sumary Initial Steady State, E-16 Transient, and Final Steady State . . . . 234 7.2-4 F/A Outlet Nozzle Time Dependent Analysis Sumary 10-day Hold-Time and Unloading .................. 239 7.3-1 F/A Outlet Nozzle Structural Evaluation Sumary ...... 251 8.1-1 F/A Attachment Assembly Support Bar, Deadwei9ht Distribution by Rows. . . . . . . . . . . . . . . 255 8.1-2 F/A Attachment Assembly Support Bar, Pressure Drop Di s tri bu ti on by Rows . . . . . . . . . . . . . . . . . . . . 259 8.1-3 F/A Attachment Assembly, Horizontal OBE and SSE Seismic Load, Distribution by Rows . . . . . . . . . . . . . 263 .

8.1-4 F/A Attachment Assembly Support Bar, Vertical OBE and SSE Seismic Loads, Distribution by Rows. . . . . . . . . . . 266 8.1-5 F/A Attachment Assembly Support Bar, Mechanical Load ,

S uma ry , D i s tri buti o n by Rows . . . . . . . . . . . . . . . . 267 8.1-6 F/A Attachment Assembly Support Bar, E-4a Transient, Ansys Input Data . . . . . . . . . . . . . . . . . . . . . . 275 8.2-1 F/A Attachment Assembly Support Bar, First Duty Cycle, Time Independent and Dependent Analysis Sumary. . . . . . . 293 8.3-1 F/A Attachment Assembly Support Bar, Structural Eval u a ti on S uma ry . . . . . . . . . . . . . . . . . . . . . 308 9.1-1 F/A Orifice Plate, Average Steady State Pressure Drops . . . 31 0 9.2-1 F/A Orifice Plate, True Minimum BOL and E0L Stress-Strain Da ta , SA- 316-S S . . . . . . . . . . . . . . . . . . . . . . . 319 9.2-2 F/A Orifice Plate, First Cycle-Time Independent An a l y s i s Suma ry . . . . . . . . . . . . . . . . . . . . . . 330 9.2-3 F/A Orifice Plate, Second Cycle-Time Independent An a ly s i s S uma ry . . . . . . . . . . . . . . . . . . . . . . 333 ,

9.3-1 F/A Orifice Plate, Structural Evaluation Sumary . . . . . . 344

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i i 1

A.1 Damage Processor Typical Output for One Element. . . . . . . A-4

A.2 Damage Processor Maximum Damage Factors Typical Output . . . A-6 !

A.3 Damage Processor Source Deck Listing . . . . . . . . . . . . A-7 4

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r LIST OF FIGURES 4

2.0-1 CRBRP Core Arrangement Sector A Designation Scheme . . . ..

CRBRP F/A Design Layout Drawing. . . . . . . . . . . . . . . . 5 2.0-2 Combined Creep-Damage Factor . . . . . . . . . . . . . . . . . 21 3.1 -1 ,

............... 32 4.1-1 F/A Shield Block E-4a Transient F/A Shield Block Worst Case Duty Cycle . . . . . . . . . . . . 33 4.1-2 4.1-3 F/A Shield Block Thermal Model Dimensional Extent and Finite 35 Element Detail . . . . . . . . . . . . . . . . . . . . . . . .

F/A Shield Block Boundary Conditions :nd Wetted Surfaces . . . 37 4.1-4 4.1-5 F/A Shield Block E-4a Transient Load Steps . . . . . . . . . . 40 4.1-6 F/A Shield Block E-4a Transient Temperature Difference vs.

Cumulative Iteration . . . . . . . . . . . . . . . . . . . . . 42 4.1-7 F/A Shield Block E-4a Transient Cumulative Iterations 2 and 43 36 Temperature Distributions . . . . . . . . . . . . . . . . .

4.1-8 F/A Shield Block E-4a Transient Cumulative Interation 63 Tempe ra tu re D i s tri bu ti on . . . . . . . . . . . . . . . . . . . 44 4.2-1 F/A Shield Block Structural Model, geometry, and Boundary Conditions . . . . . . . . . . . . . . . . . . . . . . . . . . 48 4.2-2 F/A Shield Block SA-316SS Stress-Strain Curves Minimum Mean of BOL and E0L . . . . . . . . . . . . . . . . . . . . . . . . 52 4.2-3 F/A Shield Block Initial and Final Steady State Time Independent Equivalent Stress ................ 60 .

4.2-4 F/A Shield Block Cumulative Iteration 36 and 63 Time Independent Equivalent Stress ................ 61 4.2-5 F/A Shield Block Non-Uniform Deformation Time Independent .. 62 4.2-6 F/A Shield Block Non-Uniform Deformation Time Dependent ... 65 4.3-1 F/A Shield Blogk SA-316-SS Fatigue Life E0L Fluence (E>0.1 Mev, 4t = 0.31 x 10c2 n/cm2) Temperature m 800 F ......... 74 4.3-2 F/A Shield Block SA-316-SS greep gupture Time E0L Fluence ...

(E>0.1 Mev, 4t = 0.31 x 102 n/cm ) Temperature s 800 F 78 5.1-1 F/A CMP Hex Duct E-16 Transient. . . . . ........... 90 5.1-2 F/A CMP Hex Duct Worst Case Duty Cycle . . . . . . . . . . . . 91 5.1-3 F/A CMP Hex Duct Thermal Model Dimensional Extent and Finite Element Detail. . . . . . . . . . . . . . . . . . . . . 93 5.1-4 F/A CMP Hex Duct Boundary Conditions and Wetted Surfaces . . . 95 5.1-5 F/A CMP Hex Duct E-16 Transient Load Steps . . . . . . . . . . 98 5.1-6 F/A CMP Hex Duct E-16 Transient Temperature Difference vs.

Cumu l a ti ve I te ra t i on . . . . . . . . . . . . . . . . . . . . 100 9

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4 5.1-7 F/A CMP Hex Duct E-16 Transient Cumulative Iterations 2 and 27 Temperature Distributions . . . . . . . . . . . . . . 101 5.2-1 F/A CMP Hex Duct Structural Model, Geometry, and Boundar Conditions . . . . . . . . . . . . . . . . . . . . . . .y . . 105 5.2-2 F/A CMP Hex Duct Steady State and Cumulative Iteration 27 Equivalent Stress Time Independent . . . . . . . . . . . . . 113 5.2-3 F/A CMo Hex Duct Steady State and Cumulative Iteration 27 Non-Vaiform Deformations Time Independent . . . . . . . . . 114 j 5.3-1 F/A CMP Hex Duct First Core 20% CW-316-SS Fatigue Life . . . 124 5.3-2 F/A CMP Hex Duct First Core 20% CW-316-SS Creep Rutpure Time 127 6.1-1 F/A ACLP Hex Duct PCM Ig Static Load Locations . . . . . . . 138 6.1-2 F/A ACLP Hex Duct Method of Selecting Statis lg Loads . . . 139 l 6.1-3 F/A ACLP Hex Duct CRM Core Restraint Load Locations . . . . 143 6.1-4 F/A ACLP Hex Duct Method of Selecting Core Restrain loads . 144 6.1-5 F/A ACLP Hex Duct E-16 Transient . . . . . . . . . . . . . . 150 6.1-6 F/A ACLP Hex Duct E-16 Transient Largest Sustained S.S. Temp. 152 6.1-7 F/A ACLP Hex Duct Worst Case Duty Cycle . . . . . . . . . . 153 6.1-8 F/A ACLP Hex Duct Dimensional Extent and Finite Element Detail 155 6.1-9 F/A ACLP Hex Duct Boundary Conditions and Wetted Surfaces . 157 6.1-10 F/A ACLP Hex Duct E-16 Transient Largest Sustained S.S.

Temperatures Load Steps. . . . . . . . . . . . . . . . . . . 160 6.1-11 F/A ACLP Hex Duct E-16 Transient Temperature Difference vs.

Cumul a ti ve I te ra ti on . . . . . . . . . . . . . . . . . . . . 162

, 6.1-12 F/A ACLP Hex Duct E-16 Transient Cumulative Iteration 2 and i 32 Temperature Distributions . . . . . . . . . . . . . . . . 163 1 6.2-1 F/A ACLP Hex Duct Structural Model, Geometry, and Boundar i Conditions . . . . . . . . . . . . . . . . . . . . . . . y . . 168 6.2-2 F/A ACLP Hex Duct First Core 20% CW-316-SS Stress-Strain Curves Minimum Mean of BOL and E0L at 1000 F . . . . . . . . 17 3 6.2-3 F/A ACLP Hex Duct First Cycle Time Independent Initial Steady State Equivalent Stress and Peak Non-Uniform Deformation . . . . . . . . . . . . . . . . . . . . . . . . 182 6.2-4 F/A ACLP Hex Duct First Cycle Time Independent Core Restraint and SSE Loads with Cumulative Iteration 32 Temperature Distribution Equivalent Stress and Peak Non-Uniform Deformation ........................183

! 6.2-5 F/A ACLP Hex Duct First Cycle - Time Independent Final Steady State Equivalent Stress and Peak Non-Uniform Defomation . . 184 l

1

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6.2-6 F/A ACLP Hex Duct First Cycle - Time Dependent Final Steady State Equivalent Stress and Non-Uniform Deformation . . . . . 187 .

6.2-7 F/A ACLP Hex Duct First Cycle - Time Dependent Unloading for Residuals Equivalent Stress and Non-Uniform Deformation . 188 6.2-8 F/A ACLP Hex Dutt Second Cycle - Time Independent Cumulative

Iteration 32 Temperature Distribution Equivalent Stress and Peak Non-Uniform Deformation . . . . . . . . . . . . . . . . 190 6.2-9 F/A ACLP Hex Duct Second Cycle - Time Independent Final Steady State Equivalent Stress and Non-Jniform Deformation . 191 6.2-10 F/A ACLP Hex Duct Second Cycle Tire Dependent Final Steady State Equivalent Stress and Non-Uniform Deformation . . . . . 193 6.2-11 F/A ACLP Hex Duct Second Cycle - Time Dependent Unloading for Residuals Equivalent Stress and Non-Uniform Deformation . 194 6.3-1 F/A ACLP Hex Duct First Core 20% CW-316-SS Fatigue Life . . . 200 6.3-2 F/A ACLP Hex Duct First Core 20% CW-316-SS Creep Rupture Time 201 7.1-1 F/A Outlet Nozzle E-16 Transient. . . ............ 211 7.1-2 F/A Outlet Nozzle Worst Case Duty Cycle . . . . . . . . . . . 212 7.1-3 F/A Outlet Nozzle Thermal Model Dimensional Element and Fini te El ement Detail . . . . . . . . . . . . . . . . . . . . 214 7.1-4 F/A Outlet Nozzle Boundary Conditions and Wetted Surfaces . . 216 7.1-5 F/A Outlet Nozzle E-16 Transient Load Steps . . . . . . . . . 219 i 7.i-6 F/A Outlet Nozzle E-16 Transient Temperature Difference vs . Cumul ati ve ::terations . . . . . . . . . . . . . . . . . . 221 .

7.1-7 F/A Outlet Nozz~.e E-16 Transient Cumulative Iteration 3, 16, and 31 Temperature Distributions ............ 222 7.2-1 F/A Outlet Nozzle Structural Model, Georetry, and Boundary

Conditions . . . . . . . . . . . . . . ........... 225 7.2-2 F/A Outlet Nozzle SA-316-SS True Minimum BOL and EOL Stress-Strain Curves . ....... ............ 228 7.2-3 F/A Outlet Nozzle Solution SA-316-SS Secondary Creep Rate at 1000 F and 1200*F ......... ........... 231 7.2-4 "'A Outlet Nozzle Initial and Final Steady State Equivalent Stress Time Independent . . . ................ 236 7.2-5 F/A Outlet Nczzle E-16 Transient Cumulative Iteration 31 Equivalent Stress Time Independent ............. 237 7.2-6 F/A Outlet Nozzle Initial Steady State and E-16 Transient Cumulative Iteration 31 Non-Uniform Deformation Time Independent . . . . . . . . . ................ 2 38 7.2-7 F/A Outlet Nozzle Final Steady State Equivalent Stress and Non-Uniform Deformation Time Dependent ........... 241

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l l

l 9 7.2-8 F/A Outlet Nozzle Residual Deformation . . . . . . . . . . . 242 l

7.3-1 F/A Outlet Nozzle SA-316-SS FatigNe Life E0L Fluence (E>0.1 Mev, 4t = 0.31 x 1022 n/cm ) Temperature

1250 F . 246 o 7.3-2 F/A Outlet Nozzle Creep RuDture Time E0L Fluence (E>0.1 Mev, 4t = 0.07 x 1022 n/cm2) Temperature s 11000F . . 247 8.1-1 F/A Attachment Assembly, Deadweight Load Distribution. . . . 254 8.1-2 F/A Attachment Assembly, Pressure Drop Load Distribution . . 258 8.1-3 F/A Attachment Assembly, Seismic Load Distribution . . . . . 260 8.1-4 F/A Attachment Assembly Support Bar, Thermal Load Model, Dimensional Extent and Finite Element Detail . . . . . . . . 270 8.1-5 F/A Attachment Assembly Support Bar, Thermal Load Model, Heat Transfer Boundary Conditions and Wetted Surfaces. . . . 274 8.1-6 F/A Attachment Assembly Support Bar, Thermal Load Model, Structural Boundary Conditions . . . . . . . . . . . . . . . 277 8.1-7 F/A Attachment Assembly Support Bar, E-4a Thermal Loads, Relative Displacements . . . . . . . . . . . . . . . . . . . 279 8.2-1 F/A Attachment Assembly Support Bar, Dimensional Extent and Finite Element Detail. . . . . . . . . . . . . . . . . . 286 8.2-2 F/A Attachment Assembly Support Bar, Boundary Conditions and Load Applications. . . . . . . . . . . . . . . . . . . . 288 8.2-3 F/A Attachment Asserably Support Bar, First Cycle - Time ,

Independent Initial Steady State, Deadweight + Pressure l Drop, Equivalent Stress Deformations . . . . . . . . . . . . 295 8.2-4 F/A Attachment Assembly Support Bar, First Cycle - Time )

Independent, First SSE Seismic Loading, Pressure Drop + i Up Vertical + Left Horizontal, Equivalent Stress and D e fo rma t i on s . . . . . . . . . . . . . . . . . . . . . . . . 296 8.2-5 F/A Attachment Assembly Support Bar, First Cycle - Time Independent, Second SSE Seismic Loading, Deadweight +

Down Vertical + Right Horizontal, Equivalent Stress and De fo rma t i o n s . . . . . . . . . . . . . . . . . . . . . . . . 297 8.2-6 F/A Attachment Assembly Support Bar, First Cycle - Time Independent, First E-4a Thermal Loading, Deadweight +

Inward Base Motion, Equivalent Stress and Deformations . . . 298 8.2-7 F/A Attachment Assembly Support Bar, First Cycle - Time Independent, Second E-4a Thermal Loading, Deadweight + l Outward Base Motion, Equivalent Stress and Deformations. . . 299 l 8.2-8 F/A Ai.tachment Assembly Support Bar, First Cycle - Time Independent, Final Steady State, Deadweight + Pressure Drop, Equivalent Stress and Deformations . . . . . . . . . ... 300

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9.2-1 F/A Orifice Plate, Dimensional Extent and Finite

Elemental Detail. . . . . . . . . . . . . . . . . . . . . . . 317 9.2-2 F/A Orifice Plate, SA-316SS, True Minimum BOL and EOL Stress - Strsin Curves. . . . . . . . . . . . . . . . . . . . 320

=

9.2-3 F/A Orifice Plate, Pressure Drop Structural Model . . . . . . 322 9.2-4 F/A Orifice Plate, Pressure Drop Elastic Response, Equivalent Stress and Perpendicular Displacements . . . . . . 324 9.2-5 F/A Orifice Plate, Radial Interference Structural Model . . . 326 9.2-6 F/A Orifice Plate, Radial Interference Elastic Response, Equivalent Stress and In-Plane Deformations . . . . . . . . . 328 9.2-7 F/A Orifice Plate, First Cycle - Time Independency, Peak E-4a Radial Interference, Equivalent Stress and Ncn-Uniform Deformation . . . . . . . . . . . . . . . . . . . 331 9.2-8 F/A Orifice Plate, First Cycle - Time Independent, Final Steady State, Equivalent Stress and Non-Uniform De fo rma t i o n . . . . . . . . . . . . . . . . . . . . . . . . . 332 9.2-9 F/A Orifice Plate, Second Cycle - Time Independent, Peak E-4a Radial Interference, Equivalent Stress and Non-Uniform Deformation . . . . . . . . . . . . . . . . . . . 335 9.2-10 F/A Orifice Plat , Second Cycle - Time Independent, Final Steady Stuce, Equivalent Stress and Non-Uniform Deformation . . . . . . . . . . . . . . . . . . . . . . . . . 336 A-1 Damage Assessment Flow Chart. . . . . . . . . . . . . . . . . A-3 I

e

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l t

1.0 INTRODUCTION

i o The Clinch River Breeder Reactor Plant (CRBRP) core is comprised of Control (C/A), Fuel (F/A), Blanket (B/A), and Removable Radial Shield (RRS/A)

I assemblies arranged in a hexagonal pattern within the core barrel. The i o core assemblies are exposed to nuclear irradiation at elevated temperature l in direct contact with liquid sodium and are subjected to mechanical and l thermal loads. Owing to the severity of the environment and loadings over the replacement schedules planned for the C/A, F/A, B/A, and RRS/A, it is important that attendant structural damage does not impair the intended function of the core components in the overall CRBRP system.

l 1.1 Purpose l The purpose of this report is to present a structural evaluation of the CRBRP F/A in support of the Final Design Review so as to assure that structural damage does not impair intended F/A function in the CRBRP j system in accordance with the requirements of the Equipment Specification for the First Core Fuel Assembly [1].

1.2 Scope i

The scope of the Structural avaluation is applicable to all F/A in the CRBRP core and all F/A components, excluding the fuel rods. The scope of F/A structural evaluation was reduced by evaluating only worst case F/A locations. Further, only worst case F/A regions were evaluated, which included the shield block, Core Mid-Plane (CMP) hex duct, Above Core Load Plane (ACLP) hex duct, Top Load Plane (TLP) outlet nozzle, attachment assembly, and orifice plate. Other F/A locations and component regions were

bracketed within the worst case approach.

1.3 Applicabili ty Prior F/A structural evaluations in support of Preliminary Design Reviews l were applicable to the homogeneous CRBRP core arrangement and respective thermal and nuclear performance. The F/A structural evaluation presented in this report is based on June 1977 thermal and nuclear performance of the

. CRBRP Heterogeneous core over the first and second cycles of l9 and 200 full power-days respectively, for a total of 328 full-power days.

1

1.4 Sumary The F/A structural evaluaticn was perfo med in accordance with the criteria identified in the First Core Fuel Asserbly Equiprent Specification [1] which assure t.... he intended function of the F/A in the CRERP core is not impaired over the first and second reactor cycles comprising a total of 328 full power days. The F/A criteria protect against the crack '

initiation failure modes of local ductile rupture and co-bined creep-fatigue darage. In addition, the excessive defomation failure codes of peak plus at u ulated and residual defomation are crotected against by the '

F/A criteria. The F/A structural evaluation based on the June 1977 loads and currently available raterials data showed that the F/A design con-prising the shield block, TLP outlet nozzle, CMP and ACLP hex ducts, attachrent assembly, and orifice plate are not expected to experience crack initiatien and excessive defor ation failure over the first and second reactor cycles. A sumary of the cargins of safety for the F/A regions structurally evaluated is presented in Table 1.0-1.

TABLE 1.0-1 F/A PAR 3IN OF SAFETY SUWARY F/A I Fargin of Safety

I Pegion I Crack Initiation i Excessive Defomation Local Combined Peak plus Residual Ductile Creep- Acc culated Rupture Fatigue Darage ; -

Shield i Block 2.80 61.62 4.75 ,

2.13 C??

Hex Duct 12.76 191.3 37.4 CO

+ACLP I

! !!ex Duct 10.49 91.6S 4.65 1.58 L !

[TLP 1.56

' Outlet 0.37 0.29 3.0 Nozzle Attachrent S2.33 925,925 10.11 N nsserbly

' Orifice I

4.03 291,544 0.43 1.52 Plate j

"argin of Safety = Ailce ble Value ,) ~

Calculated Value

2.0 DESCRIPTION

AND APPROACH

, The heterogeneous core plan places F/A adjacent to C/A, B/A, or other F/.'.

A total of 156 F/A,15 C/A, 208 B/A, 306 RRS/A and 6 assemblies which can be either F/A or B/A are provided. The full 360 plan view arrangement is

, subdivided into 60 sectors designated by A, B, C, D, E, and F. The core map for Sector A including the individual assembly designation scheme is presented in Figure 2.0-1.

The F/A structural evaluation presented in this report addresses the shield block, CMP and ACLP hex ducts, TLP outlet nozzle, attachment assembly and orifice plate. The F/A design at all locations in the core is identical in tenns of materials of construction, dimensions, and tolerances. The F/A design layout is presented in Figure 2.0-2.

The F/A structural evaluation approach adopted for the shield block, CMP and ACLP hex ducts, TLP outlet nozzle, attachment assembly, and orifice plate was to construct analytical models for the respective F/A regions in relation to prominent design features and loading conditions which would provide worst case structural damage. The ANSYS Computer Program [2]

was used extensively in the analytical approach adopted for the F/A structural evaluation. In the following, the F/A regions selected for structural evaluation are described in terms of prominent design features and worst case loadings from which the ANSYS analytical models were formulated.

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2.1 Shield Block 3 ihe F/A shield block, located between the hex duct and inlet nozzle, functions to limit the irradiation of the core support plate. The shield block is a near solid SA-316-SS hexagonal bar with nominal flat-to-flat dimensions of 4.695 in. x 12 in, long. In order to permit sodium to pass o

, from the inlet nozzle through the F/A, the shield block is provided with a pactern of 7 flow holes, nominally 0.75 in. diameter, comprising a ,

centrtl hole and 6 symetrically spaced holes on a nominal 2.750 in. dia- I l meter circle. The shield block region is identified adjacent to Section E-12 in the F/A design layout presented in Figure 2.0-2. '

The shield block region represents the worst case location far structural l damage for the F/A inlet hardware. Thermal loads caused by steady state and inlet sodium transients control ' structural damage as mecnanical core re traint and seismic loads are relatively insignificant throughout the inlet nozzle region. The thermal loads cause tne worst damage in the shield block because the inlet sodium transients in the flow hole passages are restrained by the relatively thick-walled nield block body. Other prominent F/A inlet locations include the nozzle, nozzle to shield block weld, and hex duct to shiel' block weld. However, the latter locations are relatively thin-walled with welds on exterior .eraces exposed to the stagnant sodium interstice and not to the inlet sodium transients. As such,thestructuraldam$gecau'sedbythermalloadsintheF/Ainlethard-ware would be worst case in the shield block, or alternately the structural damages of the F/A inlet nozz.le, and nozzle and hex duct to shield block welds is considered to be conservatively bounded by the structural damage of the shield block.

2.2 CMP Hex Duct The F/A CMP hex duct is the region of the hex duct body at the core mid-plane. The CMP hex duct is constructed from 20%-CW-316 SS with nominal outside dimensions of 4.575 in, flat to flat x 0.120 in, wall thickness.

The CMP hex duct construction is identical to the hex duct body above and below the ACLP as depicted in Section E-16 of the F/A design layout presented in Figure 2.0-2.

~

The CMP hex duct region represents the worst case location for structural damage in the F/A hex duct body above and below the ACLP. The CMP region is exposed to the worst case fluence levels over the life of the F/A. As such, the available ductility of the F/A hex duct material which can be safely exhausted during thermal and mechanical loadings in damage evalua- T tions is a worst case minimum at the CMP.

2.3 ACLP Hex Duct The F/A ACLP hex duct is the thickened region of the hex duct body at the above core load plane which functions to transfer inter-duct loads between adjacent assemblies to the ACLP core former. The ACLP hex duct is con-structed from 20%-CW-316-SS with nominal outside dimensions of 4.745 in, flat to flat x 0.205 in, wall thickness over a 4 in. axial extent. Minimum ACLP wall thickness is 0.190 in. The ACLP hex duct construction as de-picted by Section E-14 of the F/A design layout is presented in Figure 2.0-2.

The ACLP hex duct region represents the worst case location for structural damage of the F/A under lateral mechanical core restraint and seismic inter-duct loadings as a hollow thin walled construction is required to accommodate the fuel rod bundle. Other F/A location which transfer lateral mechanical ~

loads are the inlet and TLP outlet nozzles, however, these locations are not critical as relatively thick walled construction is permitted. The failure mode of interest at the ACLP hex duct is duct crushing initiated by insta- .

bility or rupture related to the ductility at fluence and temperature.

i 2.4 TLP Outlet Nozzle l The F/A TLP outlet nozzle, located at the top of the F/A, ft.nctions to channel the sodium coolant into the outlet plenum while providing lateral support of adjacent assemblies in transfering lateral mechanical core restraint and l seismic loads to the TLP core former. The TLP outlet nozzle is constructed from SA-316-SS with nominal outside hex dimensions of 4.745 in. flat to flat. The outside nozzle surface at one end is provided with a shoulder to accommodate the hex duct weld while the other end is formed to permit handling during installation and removal. The inside nozzle surface is l

4

generally circular with the exception of a fluted region which prevents fuel rod and bundle damage in the event that a RB/A is inadvertantly inserted in an occupied F/A position. The TLP outlet nozzle region is identified e in Section E-16 of the F/A design layout presented in Figure 2.0-2.

The TLP outlet nc zle region constitutes the worst case location for structural damage in the F/A outlet nozzle hardware. Thermal loads caused by steady state and outlet sodium transients control structural damage.

Mechanical core restraint and seismic loads are not significant in con-tributing to structural damage as the outlet nozzle is of relatively thick walled construction. Thermal loads are significant because the thick walled nozzle construction restrains the expansion of the inside nozzle surfaces under outlet sodium transients. The other prominent TLP outlet nozzle location 'is the nozzle to hex duct weld. However, the weld is located on the extericr surface exposed to stagnant sodium interstice temperatures and not to outlet sodium transients. As such, the structural damage caused by thermal loads in the F/A outlet hardware is worst case in the outlet nozzle, or alternately the structural damage of the hex duct to outlet nozzle weld is considered to be conservatively bounded by the structural o damage or the F/A TLP outlet nozzle.

2.5 Attachment Assembly The F/A attachment assembly, located adjacent to the hex duct to shield block weld, functions to support the bottom of the fuel rod assembly in both vertical and horizontal directions. The attachment assembli comprises, )

in combination, a pair of U-Shaped SA-316-SS support bars welded at their :

free ends to recesses formed in the supporting shield block, a total of l 17 thin SA-316-SS attachment rails supported in lateral grooves cut in I

each of the support bars, and a pair of Inconel 713 locking bars which, when inserted into mating holes formed in the support bars secure the fuel

! rod assembly by the attachment rails to the shield block. The attachment assembly with prominent design features is identified adjacent to and including Section E-12 in the F/A desisn layout illustrated in Figure 2.0-1.

l

-S- ,

a 1

1 The attachment assembly represents the worst case F/A location for ,

localized structural damage as the grooves machined in the support bars to accommodate the many attachment rails inherently act as stress risers.

In addition, welds are provided to secure the base of the support bar ,

legs to the top of the shield block. The latter are of interest as the welds have reduced ductility relative to the parent material. Mechanical loads acting on the support bars include deadweight and vertical OBE and SSE seismic while thermal loads comprise expansion differences caused by the response lag of the shield block relative to the support bars during inlet sodium transients.

2.6 Orifice Plate The F/A orifice plate assembly, situated bet >een the inlet nozzle and shield block, functions to passively throttle the inlet sodium flow. The orifice plate is comprised of a set of SA-316-SS perforated circular plates, nominally 1/4 in. thick, and spacers identified adjacent to and including Section F-4 in the F/A design layout illustrated in Figure 2.0-2.

The orifice assembly as comprised of thin perforated plates represents the .

worst case F/A location for structural damage under steady state and transient pressures induced by inlet sodium flow. In addition, thermal loads caused by the thermal lag of adjacent shield block response in .

relation to exhausting the diametral clearances in relation to radial constraints at the orifice plate periphes; rcquire investigation.

_g.

L

i

( 3.0 CRITERIA I

1

, In order to assure that CRBRP functional requirements are not impaired by i structural damage during the first and second reactor cycles, the F/A Equipment Specification [1] includes both elastic and inelastic l . structural criteria from which the F/A design can be evaluated in relation to acceptability.

Fundamental in both F/A elastic and inelastic structural criteria is the use of excessive defonnation as the measure of structural damage from which judgements on the impairment of F/A functional requirements and design acceptability are made. Two measures of excessive deformation are con-sidered. The first are the peak plus accumulated deformations that occur between BOL and E0L which are related to operational F/A functional require-ments. The second are the E0L residual deformations related to the l dimensional tolerances specified on the design drawings which were con-sidered necessary for B0L F/A functional requirements. For the F/A elastic 1

criteria, limits on excessive peak plus accumulated and residual deformation which assure F/A Functional requirements are not explicitly specified.

The structural criteria based on elastic analyses protect against gross deformation, tensile instability, stress rupture, excessive strain (greater than 1%) and ratchetting by limiting the values of primary and secondary stresses either to elastic domain or to a fraction of ultimate strength or rupture strength. These criteria, in general, are highly

\

conservative and preclude the need for any strain or inelastic calculations. l I

In the case of F/A inelastic criteria, excessive deformation limits are specified because inelastic deformations may be large in relation to opera-tional and dimensional F/A functional requirements.

The F/A elastic and inelastic criteria also protect against crack initiation and elastic / plastic / creep instability failures that may occur before excessive deformation limits are exceeded. The modes of crack initiation failure which are protected against include both local ductile rupture and combined creep-fatigue damage. The F/A elastic criteria protect against crack initiation and elastic instability failures by imposing l

O

limits placed on elastically calculated stresses. For the F/A inelastic criteria, strain limits protect against crack initiation failures while '

large deformation analysis is required to assure that elastic / plastic /

creep instability failures do not occur.

The CRBRP F/A structural criteria selected for the F/A regions evaluated in this report are the inelastic structural criteria presented in the F/A Equipment Specification [1]. Accordingly, the intent of the structural evaluation of the F/A regions is to establish that crack initiation and elastic / plastic / creep instability failures do not occur before limits on excessive deformation are exceeded.

In the following subsections, the specific CRBRP F/A inelastic criteria i are described *.. terms of background and rationale for selecting design limits, and a description of the application of the inelastic criteria for the F/A regions evaluated is presented. A summary of the CRBRP F/A inelastic criteria is given in Table 3.0-1.

O I

L 9

i i

l TABLE 3.0-1 CDCRP F/A II:!. ASTIC CRITTPIA AND LIMITS Type of

Failure Mode Criteria Limit F/A Region Crack FDR = Man of man principal 0.3 sf I"f i y gjg Initiation Local e (c ,,, ,,,,c,,,j) TF k cu Ductile where.

Rupture

<f = True Min. Fracture Strain cu = True Min. Uniform Elongation TF = Tr'tantality Factor TF = .7 (sy + e2 * '3)

[(og-c y )2,{,,,,3)2,{,3 ,i/

.,. ,,. 3 = Princi,ai st, esses t

' man principal = Masinun Principal Strain (Peak + Accumulated)

Creep e 7/3 OC+0#

FCFD = a/b = Minima of I AM Fatigue e De + 7/3 Dg 1.0 ~

DC Limit l g s j _

- Daa9e 4

. 0.0 f 1.0 a

where.

DC = Creep Carage Factor C =

D g ,

. tr i tr = kupture Time Based on Equivalent Stress cr Man. Positive Principal '

Stress D = Fatigue Damage Factor D

= y i l

n = No. of Cycles .

Ng = A11cwable No. of Cyctes Based on range of equivalent or Man.

l Principal Strain Encessive Feak + p.g 0.082 in. ACLP Deformation Accurulated 6 < PADL Hex Duct TLP Lt.e re. 0.020 in. Outlet

" ##I' PADL = Peak + Accumulated Non-Uniform Defomation Limit. 0.010 in. CMP Escluding Irradiation lies Net Creep and Swelling g, g ,,, gg

, Wr; I N Residual 5 ~< RDL ACLP 0.010 in. Hex Duct TLP 0.020 in. Outlet whe re. Mozzle RDL

Residual Nondnifom Defomation CMP Limit. Excluding Irradiation 0.010 in. MenDwt Creep and Swelling g33 0.005 ir,. Cthers

3.1 Background and Rationale The structural criteria,which assure the functional requirements of the ,

F/A in the CRBRP system over the first and second reactor cycles is not impaired, requires special considerations of nuclear fluer.ce at elevated temperature in a liquid sodium environment. Established struc- i tural criteria for Class 1 nuclear components such as the ASME Section III Code [3] and Code Case 1592 [4] do not cover the combined effects of irradiation and elevated temperature, nor reflect the defonnation limits necessary to assure the functional requirements of the F/A in the CRBR system. The proposed Structural Design Criteria for Breeder Reactor Core Components [5] provide guidelines to cover the combined effects of irradiation at elevated temperature, but recognize that specific structural criteria in terms of deformation limits which assure the functional require-ments of a core component can only be specified by the Owner on a case-by-case basis.

The inelastic criteria established for the CRBRP F/A are in large part extensions of the proposed Breeder Reactor Core Components Design Criteria

[5] except as modified to accommodate the specific functional requirements of the shield block, CMP and ACLP hex ducts, TLP outlet nozzle, attachment .

assembly, and orifice plate designs. In the following, the ASME Section III Code, Code Case 1592, and Proposed Breeder Reactor Core Components Criteria in relation to respective scope and applicability are first presented to ,

form a background from which the rationale for the specific criteria identified in the F/A Equipment Specification [1] are iAntified.

f l

3.1.1 ASME Section III Code The ASME Section III Code stress limits and design rules of Subsection NB are applicable to Class I nuclear components not exposed to nuclear fluence and operating at temperatures (< 800 F) where creep and relaxation effects are negligible for typical materials of construction. Accordingly, the NB rules only protect against time-independent failure modes summarized ,

as follows:

l , e Crack initiation caused by ductile rupture from short term loadings,

, o Crack initiation caused by fatigue under short term loading, and e Elastic / lastic instability causing gross distortion or incremental collapse under short term loading.

The ASME Section III Code Subsection NB rules are not directly applicable to the structural evaluation of the CRBRP F/A because generally the materials are irradiated and temperatures are in excess of 800 F where time dependent creep effects may occur. In addition, the NB stress limits do not reflect the deformation limits necessary in assuring that the specific CRBR F/A functional requirements are satisfied.

3.1.2 Code Case 1592 The Code Case 1592 design rules are applicable to Class I nuclear components exposed to elevated temperature (> 800 F) where creep and relaxation effects are significant and irradiation effects on materials of construction are negligible. Code Case 1592 rules are formulated to include ASME Section III code stress limits and design rules to protect against time-

. independent failure modes with additional criteria provided to protect against time-dependent failure modes. A summary of the failure modes protected against with Code Case 1592 rules is as follows:

o Crack initiation caused by ductile rupture from combined short and long term loadings, o Crack initiation caused by creep-fatigue interaction under combined short and long term loadings, o Elastic &lastic/ creep instability causing gross distortion or incremental collapse under short and long term loading, and

b A

3 e Loss of function due to excessive deformation under short ,

I and long term loadings. -

The Coje Case 1592 rules are only applicable to the CRBR F/A when the r

, effects of nuclear irradiation on the materials of construction are '

insignificant. For unirradiated regions of the F/A, the Code Case 1592 rules protect against time-dependent failure modes while time-independent failure modes are protected against by the NB stress limits of the ASME Section III Code. However, Code Case 1592 rules do not provide guidance in protecting against time-dependent and tine-independent failure modes i of F/A regions where the effects of material irradiation are significant.

Further, Code Case 1592 rules only identifj excessive deformation as a l "

l potential failure mode with specific limits which would assure CRBR F/A functional requirements to be specified by the Owner.

i 3.1.3 RDT Draft Criteria for Breeder Reactor Core Components [5] '

! The RDT Draft Criteria for Breeder Reactor Core Components are applicable to nuclear core components exposed to low (< 800*F) or elevated (> 800 F) temperatures and fluence levels where the effects of material irradiation are rignificant. The RDT draft rules are prescribed for Class A, B, and ,

! C Breeder Reactor core components instead of the rules for Class I nuclear components presented in the ASME Section III Core and Code Case 1592. [

i Classification of a Breeder Reactor Core Component depends on the level of .

assured structural integrity required to satisfy the reliability and f functional requirements of the total reactor system during specified Normal, I

Upset Emergency, and Faulted Events. Core components are classified as A, B, and C for decreasing levels of structural integrity designated t.s very high, high, and moderate respectively. The RDT draft rules protect against the same time-dependent and time-independent failure modes as Code Case 1592 and provide guidance for including the effects of irradia- ;

tion on material properties. In addition, the RDT draft rules provide guidance for protecting against unstable crack propagation in materials ,

highly embrittled by irradiation. A suniary of the failure modes protected against by RDT draft rules is as follows.

i l

l .

h L --.

o Crack initiation caused by ductile rupture from combined short and long term loading, o Crack initiation caused by creep-fatigue interaction under t

combined short and long term loading, o Elastic / plastic / creep instability causing cross distortion or incremental collapse under short and long term loading, e Loss of reliability and function due to excessive deformation under short and long term loading, and e Propagation of pre-existing cracks.

The RDT draft rules are generally apolicable to the CRBR F/A as the effects of irradiation at elevated temperature are expected in the reactor core. The proposed RDT draft rules are mandatory in protecting against crack initiation, elastic / plastic / creep instability, and loss of function due to excessive deformai. ion in all CRBRP components identified as Class A, !

B, and C. However, protection against crack propagation in RDT rules is proposed as mandatory only for CRBR core components identified as Class A j by the Owner. For example, the RDT draft suggests that the CRBR C/A would be considered a Class A component because reliability and functional requirements are important during SSE while the F/A and RB/A of less importance would be Class B components and the RRS/A of even less importance classified as Class C. With regard to methods of structural evaluation, the RDT draft rules permit inelastic analysis prior to or following elastic analysis with separate limits and design margins pre-sented for the structural evaluation method selected.

In this arrangement, the RDT Draft Criteria for Breeder Reactor Core Components provides general guidance in the classification and structural evaluation of the CRBR F/A which is not provided by ASME Section III and Code Case 1592 rules. Further, the RDT draft rules provide specific criteria which c

would be appli' cable for the CRBR F/A to protect against crack initiation, l

elastic / plastic / creep instability, and crack propagation, but permit the Owner to specify alternate criteria which are rationally defensible. With ~

regard to loss of function due to excessive deformation, the RDT rules recognize that general governing criteria can not be fonnulated for a core component and, for the CRBR F/A,would permit specific deformation i limits relevant to its particular reliability and function to ba specified by the Owner.

3.1.4 CRBRP F/A Core Component The CRBRP F/A core component criteria and limits were formulated in accordance with the general rules and guidance provided in the RDT Draft for Breeder Reactor Core Components except as modified to include additional safeguards and to more properly reflect the F/A functional requirements of the Owner as identified in the Equipment Specification [1].

In accordance with the RDT draft rules and guidelines, the CRBR F/A was con-sidered as a Class B Breeder Reactor core component which requires a high level of assured structural integrity in protecting against crack initiation, elastic / plastic / creep instability, and excessive deformation so as to satisfy reliability and functional requirements during Normal, Upset, i Emergency, and Faulted conditions specified for the reactor core. The '

protection against the propagation of pre-existing cracks, which is a mandatory requirement for Class A Breeder Reactor compor.ents,was not considered .

necessary or important for the CRBRP F/A in relation to the functional requirements of the total reactor system as a whole. A summary of the failure modes protected against by the CRBRP F/A core component criteria at the shield block, CMP and ACLP hex duct, TLP outlet nozzle, attachment assembly, and orifice plates are as follows.

e Crack initiation caused by ductile rupture from combined short and long term loading, i

e Crack initiation caused by creep-fatigue interaction under combined short and long term loading, 9

e Elastic / plastic / creep instability causing gross distortion or incremental collapse under short and long term loading, and e Loss of reliability and function due to excessive deformations under short and long term loading.

In the formulation ni specific CRBRP F/A Structural design criteria, the fundamental difference between RDT draft rules for Breeder Reactor Core Components was that crack initiation and elastic / plastic / creep instability failure modes are only of significance if the loss of function expressed in terms of excessive deformation limits are not exceeded. Alternately, crack initiation and elastic / plastic / creep instability failure modes which occur at deformations which exceed the defonnation limits necessary to assure function for the specific F/A region evaluated are not relevant.

Accordingly, the CRBRP F/A inelastic structural criteria were formulated on the basis of assuring that crack initiation and elastic / plastic / creep instability failure modes would not occur before deformation associated with functional limits are exceeded. However, no explicit criteria to protect against elastic / plastic / creep instability are formulated. Instead,

, the protection against elastic / plastic / creep instability was to require the method of analysis that would implicitly indicate the instabilities with attendant deformations limited by the excessive deformation limits.

. The protection against elastic / plastic / creep instability failure modes prior to exceeding deformation limits was assured by requiring large deformation non-linear analysis for F/A regions subjected to mechanical loads which are energy unbounded and load controlled. Conversely, F/A regions with thermal loads which are energy bounded and deformation controlled, non-linear small deformation analysis is required. In this arrangement, the structural integrity of the CRBRP F/A regims reduces to assuring that crack initiation failure moda would not occur before limits on excessive deformation failure modes were exceeded.

In the following, the specific CRBRP F/A inelastic structural criteria as formulated to protect against crack initiation and excessive deformation

~

failure modes are deccribed and summarized.

l

3.1.4.1 Crack Initiation The CRBRP F/A criteria to protect against crack initiation are based on .

the rationale developed for protecting against local ductile rupture and creep-fatigue interaction in the ROT Draft for Breeder Reactor core components [5] except as modified to provide additional safeguards. De- ,

scriptions or the local ductile rupture and creep-fatigue criteria are as follows.

3.1.4.1.1 Local Ductile Rupture In the RDT Draft for Breeder Reactor Core Components [5], the local ductile rupture criterion as a protection against crack initiation limits the local maximum peak plus accumulated principal strain (cmaxprincipal}

to a safe fraction (0.3) of the true uniaxial fracture strain (cf) corrected for the triaxiality fractor (TF) of the stress state according to the relation:

' max principal 1 0 cf One difficulty in the implementation of the proposed local ductile rupture criterion is that reduction in area measurements in irradiated tensile ,

specimens,which are related to the true strain at fracture, are difficult to obtain in practice. In addition, tensile tests of irradiated EBR-II ducts [10] indicate that true fracture strains based on initial and final ,

reduction of area measurements significantly exceeded total elongation.

I Accordingly, local ductile rupture criteria based on true fracture strain may not provide adequate protection against crack initiation in irradiated materials even if reduction in area measurements could be accurately obtained, i

In order to provide an additional safeguard in protecting against local ductile rupture in irradiated materials, an additional criterion based on true uniform elongation (cu) corrected for the triaxiality factor of the stress state was adopted for the CRBRP F/A. As the true uniform elongation (cu) was observed in the irradiated EBR-II tensile tests [10] to be

{

l .

i L

significantly lower than the reported fracture strains (cf), additional conservatism in selecting a safe fraction (<1) was not considered necessary.

The additional criterion formulated:

5

max principal 1h With the understanding that the difficulty in the implementation of a local ductile rupture criterion based on true fracture strain is one of lack of data and may not be a deficiency in the criteria itself, the lucel ductile rupture criterion selected for the LRE?P F/A considered the minimum of true uniform elongation or fracture strair correlations in the design limit.

e 0.3 cf, min

max principal 1 Minimum of: TF e cu, min TV In order to facilitate the CRBRP F/A structural evaluation, it was found convenient to express the local ductile rupture criterion in a dimensionless form through a ductile rupture fractor (FDA) e (*maxprincipal)TF

. FDR = Maximum of , 0.3 cf, min '

l

' (* max principal) TF '

u, min l

Where, FDR 11 for acceptability l V"E (a) + 2+ 3)

[(ej- 2) +I 2- 3) +I 3 - "1)

= Maximum 1* "2* 3 Principal Stresses

- TF = 1, for TF < 1

-20

i 6

3.1.4.1.2 Creep-Fatigue _ Damage .

The RDT Draft for Breeder Reactor Core Components [5] identifies creep-fatigue damage as a neans of protecting against crack initiation. The '

C total damage (D) consists of the sum of the themal creep (D ) and ,

I fatigue damage (D ) factors which rust be less than a design margin (s).

c I f D = D + D <3 j

For Nomal and Upset, and Emergency events, the RDT Draf t guidelines recoceend a unity design cargin (s = 1). On the other hand, the Code Can 1592 criterion is more conservative in protecting against creep-fatigue damage and therefore was selected for the F/A structural criteria.

In order to express the calculated cochined creep-fatigue darage as a fraction of the Code Case 1592 darage limit, the concept of a coebined creep-fatigue darage factor (FCFD) was introduced and is illustrated in Figure 3.1-1.

1.0 ,

\ RDT Draft

Recomendation Code Case Creep 1592 Danage ! \

Factor N c j y (D ) '

0.3 '

Damage Limit a # l /' Calculated

, /,,- ,

0. 0' N

0.0 0.3 1.0 1 Fatigue Darage Factor (D# )

Figure 3.1-1 Corbined Creep-Darage Factor

i

- .=. _ - _ . __. .. . - _ - .

l The combined creep-fatigue damage factor (FCFD) in terms of distances a and b, which are derived from calculated creep and fatigue damage factors and the geometry of the bi-linear limits of acceptability,is given according to the relation:

J e 7/3 Dc+DI I' FCFD = a/b = Minimum of .Dc3D)

In the creep damage evaluations of the ' . regions, the creep damage c

factor (D ) was based on the stress relaxation during time-dependent loading according to the relation:

l I

D C

= dt J tr o

l where, tc = Duration of Loading t

r

= Rupture time as function of stress (c) and temperature (T) ,

o = Maximum equivalent or positive principal stress

, whichever provided a minimum rupture time (t )

r In the fatigue damage evaluations of the F/A regions, the fatigue damage

, (Df ) for n cycles was based on the fatigue life (Nf ) for the time-independent strain range within a single cycle according to the relation:

N D =

i=1 where, :

I N = Fatigue life based on maximum Von Mises f

Equivalent or Principal Strain Range, whichever produced a minimum number of cycles to failure.

3.1.4.2 Excessive Deformations The RDT Draft Criteria for Breeder Reactor Core Components [5] recomends that ~

deformation limits for functional requirements be identified in the Owner Equipment Specifications and include elastic, plastic, themal creep, and irradiation creep and swelling. ,

The CRBRP F/A defomation limits identified in the Equipment Specification

[1] were formulated in terms of peak plus accumulated, and residual deforma-tions which would not exceed functional requirements. The fundamental difference with those recommended by RDT draft guidelines was that the F/A functional limits formulated apply only to elastic, plastic, and themal creep deformations during the total number of loading cy:les. The F/A functional limits do not apply to irradiation creep and swelling deforma-tions because the latter were already included in the deformation limits specified for the F/A regions on a case by case basis.

In formulating the CRBR F/A deformation limits applicable to elastic, plastic, and themal creep defomations, a change in dimensions caused by a uniform thermal expansion were not considered to impair functional requirements. Accordingly, the dimensions and tolerances of F/A hardware as specified on the design drawings at room temperature provide a convenient -

reference from which to assess dimensional changes caused by loadings at elevated temperature. In this arrangement, only dimensional changes caused by non-uniform thermal expansion at elevated temperature were considered to impair F/A functional requirements.

The specification of residual deformation limits for the F/A regions on a case-by-case basis was relatively direct. Dimensional changes were not permitted to exceed the tolerances on the design drawings. For the F/A shield block, CMP and ACLP hex ducts, TLP outlet nozzle, attachment assembly, and orifice plates, the residual deformation limits (RDL) were taken from the dimensional tolerances given in the F/A Design Layout Drawing presented in Figure 2.0-2.

i With regard to the peak plus accumulated deformations, the basis for specifying the limits required an assessment of whether the F/A regions were load or deformation controlled. Only the ACLP hex duct region was considered load controlled because of OBE and SSE Seismic, and Core Restraint loads. Other F/A regions including the shield block, TLP outlet nozzle, CMP hex duct, attachment assembly and orifice plate were considered pritarily deformation controlled. The peak plus accumulated deformation limits (PADL) for the derarmation controlled F/A regions were specified to not exceed the dimensional tolerances on the design drawing, or conservatively not exceed the respective residual deformation limit (RDL). For the ACLP hex duct region which is primarily load controlled, the PADL was determined from l interaction analysis of the F/A rod bundle and hex duct under irradiation creep and swelling and directed to establishing the maximum ACLP hex duct deflection which could be accommodated without loacing the fuel rods. The l ACLP hex duct PADL was found to nearly approximate the clearance between the wire wrap and inside duct surface plus one wire diameter with a value of 0.082 in.

3.2 Application

In the application of the F/A inelastic criteria to the structural evalua-tion r f the F/A regions, the number and characteristics of a worst case mechanical and thermal loading duty cycle was established so as to umbrella all Upset, Emergency, and Faulted Events identified in the F/A Equipment Specification [1]. The Normal events which produce little, if any, structural damage were neglected. The characteristics of the worst case duty cycle were established to include worst combinations of time independent and dependent mechanical and thermal loads, while the number of worst case duty cycles were taken as the number of worst case Upset, Emergency, and Faulted Events. The advantage of the worst case duty cycle approach in the structural evaluation of the F/A regions was that the inelastic analysis was performed on a single cycle of loading, instead of performing l separate analyses for the number and characteristics of individual Upset, Emergency, and Faulted events. A description of a typical F/A region worst case duty cycle, and the number and distribution over the first and second reactor cycles is as follows.

l - _ . . _ - _ . -- - _ . - _ . _ _ _ _ _ _ _

i A typical worst case duty cycle for a F/A region was assumed to be ;

initiated by time independent short term mechanical and thennal loads followed by time dependent long term mechanical and thermal loads. The time independent loads were characterized by initial steady state tempera-l ture distributions followed by the brief thermal transient and the return to final steady state temperature distributions. Mechanical core restraint and OBE and SSE seismic loads of significance were also included as time in-dependent loads. The time dependent loads were the steady state temperature j distributions and mechanical core restraint loads which were maintained for a representative hold-time. Thereafter, the worst case duty cycle was I assumed to repeat successively throughout the first and second cycles.

I l I With regard to the number of the worst case duty cycles over the first and second reactor cycles, a total of 40 were found to typify the F/A regions evaluated. Of the total, 20 were considered to occur during the first reactor cycle of 128 FPD and 20 during second reactor cycle of i 200 FPD. Accordingly, the representative hold-time in i single worst case duty cycle was conservatively based on 20 occurrences over the second !

! reactor cycle of 200 FPD, for a 10 day hold-time. In this arrangement, j a total of 40 worst case duty cycles with a 10 day hold-time per duty

cycle corresponds to 400 FPD which is slightly greater and more conservative -

i than the 328 FPD specified for the first and second reactor cycles.

i j 3.2.1 Crack Initiation 3.2.1.1 Local Ductile Rupture l The structural evaluations of the CRBRP F/A regions in relation to the local ductile rupture criterion were made using minimum values of true l

uniaxial uniform elongation (c u , min) and fracture strain (cf. min) at local metal temperature and E0L fluence. The maximum principal strain (cmax principal) was computed from E0L peak plus accumulated time-independent and dependent strain components after a total of N worst case duty cycles.

The peak plus accumulated E0L strain components (c A) were taken from BOL A

peak (c])andaccumulated(cg g ) during the first worst case duty cycle as follows. .

P+A P N-1 A

ij " I' ij) + )

(* ij)K !

l

I For the first BOL duty cycle, the EOL strain components are given by the relation.

P A (c A)E0L =

(cj3 ) BOL + (N-1) (c$3 ) BOL As the method of computing maximum principal strains (cmax principal) neglects shake down effects for time-independent loadings and relaxation of stresses during time-dpendent loading for the (N-1) worst case ioading cycles following the first cycle, the CRBRP F/A structural evaluations of local ductile rupture are conservative.

3.2.1.2 Creeo-Fatigue Damage i

In the creep damage evaluations of the F/A regions, the creep damage C

factor (D ) for a total of N worst case duty cycles was based on the relation.

N c = c

. D D g K=1 For the first BOL Duty Cycle, the E0L Creep Damage:

e =

c D N ho r where, t c= Duration of one worst case duty cycle.

tp = Rupture time For the creep damage evaluation of a single worst case duty cycle, the minimum rupture time (tr ) was taken from experimental data [8,12] on l

pressurized tubes in a biaxial stress state (c) at temperature (T) and E0L fluence ($t). Minimum rupture time (t ) rwas based on 2 standard l

deviations below the average experimental data. The time dependent stress l

(c) was taken as the maximum equivalent or positive principal stress, whichever produced the greatest creep damage in a single worst case duty cycle.

l . L

In the fatigue da age evaluations of the F/A regions, the fatigue daraga (DI ) for a total of N worst case duty cycles was based on the relaticn.

~

f N f D = 0.

E K=1

(

For the first SOL duty cycle, the ECL fatigue danage:

f N O =

7'f i Where N f = Fatigue Life ,

l t

I The fatigue life (Nf ) cata for irradiated F/A raterials are not currently available. The fatigue life (Nf) for the raxirr.m strain range (ar) within the worst case duty cycle of irradiated F/A raterials was develcped froc ,

the Mansen Universal Slopes Method [7] co renly used for unirradiated raterials. The effects of irradiation were ircluded by applying corrections to the elastic and plastic strain ranges at EOL fluence (et) and peak j netal tercerature (T). For conservatisn, the fatigue life (N )f developed j for irradiated raterials was reduced in accordance witn the 2 on strain range and 20 en cycles (2-20 rule) recomended in tne RDT Draft CoreCoconents[5). Sircly stated, the 2-20 rule recuires : .at tne fatigue ,

life (N f) relation be reduced by a factor of 2 cn strain (ic) or 20 en fatigue life (N ), which ever orovides a =inirun fatigue life.

f .

In the calculation of the raxirun strain ran;e (ac), the strain coccenents ,

(cgj) during the tire-independent portions of the worst case duty cycle were screened to obtain extrue values (c'g). The range bedeen the f strain ccmonents (acg) at any point in the duty cycle and the extrce values were cercuted according to the relation: f 1*ij 'fj ~ ' ij l

The equivalent arrd raxiru: principal strain range were co outed fro: the strain cocconent ranges (acg) at each point in the worst case duty cycle. l The tire-independent strain range (ac) was taken as the Yon Mises ecuivalent !

or taxiru2 principal strain range, whichever previded the smallest -

j fatigue life (N )f over a single warst case daty cycle. !

l i

3.2.2 Exct he Deformation The evaluation of the F/A regions for compliance with the PADL and RDL, in relation to the worst case duty cycle- "3s made in a manner similar to that used for the peak plus accumulated strains in the local ductile rupture evaluation. The E0L peak plus accumulated time-independent and P

dependent deformations (6 +A) after a total of N worst case duty cycles was based on the peak defonnation (6P) and accumulated (A6ss) defonnation between initial and final steady state conditions at BOL.

I ^

6 P+A = 6P+ "f K=1 6

For the first BOL Duty Cycle, the E0L Peak plus accumulated deformation:

l P (6+A , (3 )P BOL + (N-1) (a6") BOL Similarly, the E0L residual deformation (6R) after N worst case duty cycles based in the difference in residual defonnation (6 ) between initial and I final dimensions at BOL was taken as:

. y R = R 6 6 X

K=1

, For the first BOL duty cycle, the E0L regional deformation:

i R R (6 ) E0L = N(6 ) BOL For satisfactory compliance of the F/A region in relation to excessive deformation, P

(6+A)E0L 1 PADL R

(6 )E0L 1 4

4.0 SHfELD BLOCK ANALYSES AND EVALUAT10N In the F/A shield block analysis and evaluation, a loading analysis was rade that considered rechanical seismic and core restraint, and themal steady stste and transient loaos i.1 establishing the nu iber and characteristics of a worst case duty cycle that umbrellas all expected duty cycles for the shield block regio 1 in the first and second reactor cycles. Next, an inelast!c structural analysis of the shield block region was made for a single worst case BOL duty cycle to calculate the strains and dimensional changes from whicn EOL values were approxirated. Finally, a structural evaluation of EOL strains and dimensional changes in relation to criteria which protect against crack initiation and excessive defonation was made.

A sumary of the loading, structural analysis and structural evaluation is presented as follows.

4.1 Loading Analysis The F/A shield block loading analysis was directed to establishing the number and characteristics of a worst case duty cycle that u-brellas both the number and characteristics of Upset, Emergency, and Faulted Events specified over the first and second reactor cycles. The number and characteristics of these events are specified in the Equipcent Specification [1].

It is important to note that the worst case F/A shield block duty cycle is, in itself, hypothetical, but pemits a conservative structural evaluation -

to be perfomed on a :, ingle duty cycle instead of on each of the individual events specified. In the following, the F/A shield block mechanical and l themal loads are assessed individually and in relation to each other prior to establishing the worst case duty cycle which was used in stnJctural evaluation.

4.1.1 Mechanical

> The F/A shield block mechanical loads of any significance in relation to subsequent structural evaluations are deadweight and internal pressure as

^

l

. l

OBE and SSE seismic and core restraint loads are relatively insignificant.

Hcwever, in relation to thermal steady state and transient loads, even the deadweight and internal pressure loads are insignificant. Accordingly, the mechanical loads were neglected in establishing the worst case F/A shield block duty cycle for the first and second reactor cycles.

4.1.2 Thermal The F/A shield block thermal loads include the steady state and transient temperature distributions that occur during the Upset, Emergency, and Faulted Events over the first and second reactor cycles. In the definition of F/A shield block transients, the sodium temperatures at the reactor vessel inlet were conservatively assumed to be applied directly to the F/A j inlets without the mitigating effects of mixing that would normally occur in the inlet plenum. As such, the transients are inherently worst case at all F/A locations in the core. Further, the description of F/A transient duty cycles was based on a worst case umbrella approach for the Upset, Emergency, and Faulted Transients. Over the first and second reactor cycles comprising 328 FPD, a total of 39 Upset transients umbrel'aed by the worst of U-2b, U-lla, U-16, or U-21b were specified. Similarly, tt.e

- worst of the E-4a, E-7, or E-15 was specified to umbrella the Emergency Events, while the worst F-1 or F-2 was identified to umbrella the Faulted Events.

In order to reduce the number of the specified F/A event duty cycles to a single worst case duty cycle, the Upset, Emergency, and Faulted transients were assessed by comparing the sodium temperature in terms of maximum value, rate of temperature change, and range. With regard to initial sodium temperatures, all transients were considered to be initiated at 750 F. The worst case Upset Transient was found to be the U-18 with a maximum down ramp of 2 F/second over a 420 F range. For the Emergency Transients, the E-4a was found to be the worst case with a down ramp of 2*F/second over 180 F range followed by an up ramp of 2.2 F/second over a range of 420*F.

The maximum sodium temperatures reached in the U-18 and E-4a transient were 750 and 995 F respectively.

With regard to Faulted Transients, the F-1 was found to be practically indistinguishable from the Upset Il-lb transient which itself was unbrellaed by the U-18. The Faulted F-2 transient was found to have a maximum sodium temperature of 1230*F which is the highest for all F/A shield block transients, but is slow acting at a maximum rate of temperature a

change of 0.02*F/second. As temperature differences developed in the F/A shield block would be negligible for very slow acting transients, the F-2 Further, the transient was considered less severe than the U-18 and E-4a.

E-4a was considered more severe than the U-18 because the reversal in '

rate of temperature change through the transient would develop greater temperature differences and attendant structural damage. In this arrange- ,

t ment, the Emergency E-4a transient was selected as 51 worst case umbrella to all of the Upset, Emergency, and Faulted transi 3nts for the F/A shield block. The E-4a transient is illustrated in Figure 4.1-1.

The selection of the Emergency E-4a transient as the worst case F/A shield block transient is, in itself, not sufficient to establish the worst case F/A duty cycie. The thermal conditions following the E-4a transient and subsequent hold-times at steady state conditions are also required. The thermal conditions selected following the E-4a transient were a 2 hour2.314815e-5 days 5.555556e-4 hours 3.306878e-6 weeks 7.61e-7 months soak at 600 F, a 20 F/ hour heat-up rate for 2 hours2.314815e-5 days 5.555556e-4 hours 3.306878e-6 weeks 7.61e-7 months , and a 5.5 F/ minute .

heat-up rate to the steady state sodium temperature of 750*F. Thereafter, a 10 day hold-time at steady state temperatures was selected. The 10 day hold-time corresponds to 40 worst case E-4a distributed over 400 FPD .

which is slightly greater than the 328 FPD designated for first and second reactor cycles. The worst case F/A shield block duty cycle is illustrated in Figure 4.1-2.

4

The worst case F/A shield block duty cycle in terms of the E-4a transient

followed by thermal conditions which return the F/A shield block region to steady state conditions followed by a 10 day hold-time prior to the j initiation of the successive E-4a transient may be sufficient to establish the worst case F/A duty cycle, but is not sufficiently specific to define the corresponding temperature distributions necessary for detailed structural analysis.

I

=- - _ . - .

1000 -

l i .

Figure 4.1-1 950 -

F/A Shield Block E-4a Transient

~

Joo .

850 -

I v

2 800 -

5 /

- K _ /

5 W

750 5

E e .

700 -

650 -

\

. 600 -

' I - I i I . l , l , g 0 400 800 1200 1600 2000 2400 Time (Seconds)

i Figure 4.1-2 F/A Shield Block Worst Case Duty Cycle 1000 -

,n i i l ',

i Sodium f 1, Temp I t

(*F) l {

l l I

I <

, s L,

y 750 - --- - - --

/ _

Hold Time _

s-'

s

\

%/

\

(10 Days) \ ,el i

i I i 640 -- - - - - - - - - - - -

4 -*

lli 1

em 20 Min. 's E-4a Transient . 2 Hr. Soak 2 Hr.

(2400 Seconds) (600 F) i e I t I f I a l I Time (Seconds)

. , t e e

In the fo' lowing, the F/A shield block thermal model and geometry, boundary conditions and wetted surfaces, heat generation rates, and thennal analysis and results are described from which conclusions on the detailed

! temperature distributions in relation to subsequent structural analysis are presented.

4.1.2.1 Model and Geometry The F/A shield block thermal mode; was formulated in the ANSYS finite element program. The ANSYS program has compatibility between thermal und structural elements which permits thermal solutions of temperature distributions to be used directly in subsequent structural analysis.

The F/A shield block region selected for analysis corresponds to a 2 dimensional slice of a symmetrical 30* sector taken through the 7 hole pattern provided for inlet sodium flow. The 30 symmetrical sector is justified as coolant flow in all 7 passages is uniform and heat generation rates are nearly uniform. The corresponding shield block geometry provides the greatest constraint for thermal expansions and represents the worst case location for structural damage for the F/A inlet hardware. The F/A shield block thennal model illustrating the dimensional extent and finite element detail of the 2 dimensional 30 sector geometry is presented in Figure 4.1-3.

The F/A shield b hck thermal model as formulated with the ANSYS program included 276 linear temperature (STIF 35) elements arranged in a mesh of 277 node points. A fine mesh was selected at the wetted surfaces dirhetly l

exposed to the rapid sodium transients so the thermal skin effect would be included in subsequent structural analysis. A coarse mesh was selected at exterior surfaces exposed to stagnant sodium where skin effects are negligible.

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)

l a

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4

1 4.1.2.2 Properties The F/A shield block is constructed from SA-316-SS. The material proper-ties necessary to derive both steady state and transient temperatures are the thermal conductivity (K), specific heat (C), and density (p). The ;

SA-316-SS properties expressed in terms of polynomials in temperature )

(T s F) were taken from the NSM Handbook [6] and are summarized as follows.

I Thermal Conductivity (K s BTU /in-sec- F) I l

K = (0.187 E-3) + (0.107E-7)*T Specific Heat (C s BTU /LB- F) 1 2

C = (0.102) + (0.104 E-3)

T - (.152E-6)*T l

3 4

+ (0.1007E-9)*T - (0.256E-13)

T 1

Density (o s LB/in 3) p = 0.2885 - (0.839E-5)

T

, 4.1.2.3 Boundary Conditions and Wetted Surfaces J The F/A shield block boundary conditions and wetted surfaces selected for analysis are illustrated in Figure 4.1-4.

1 The boundary conditions for the F/A shield block thermal analysis consisted of adiabatic conditions along the lateral surfaces of the 30 sector and along the exterior surface adjacent to the stagnant sodium.

l Along the lateral surfaces of the 30 sector, the boundary conditions l simulate the symmetry in the unifonn temperature and flow through the l 7 inlet sodium passages. For the exterior surface adjacent to the stagnant sodium, an adiabatic surface simulates the symmetry of temperature between adjacent shield blocks.

a

T

/

,/ j Adiabatic -

. ' Adiabatic Lateral Surface j/ . Exterior

'/ Surface

/

Wetted Surface Nodes /

271 + 277 / -

im i -

6' AY e 4 -

/

k N ' '

Wetted d Surface Nodes f' js 1 e 37 w Node 237

' i

>X / r

'- Node 1 Adiabatic '

Lateral Surface Figure 4.1-4 F/A Shield Block Boundary Conditions and Wetted Surfaces

, e e e _ e a

i The sodium temperatures in the thermal analysis were assumed to be directly coupled to the wetted surface nodes of the portions of the flow passages included in the 30' sector of the F/A shield block. As such, thermal skin l effects are conservative because the mitigating effects of a heat transfer film coefficient were neglected. The flow passage surface nodes coupled directly to the sodium temperatures were Nodes 1 through 37, increments of 1; and 271 through 277, increments of 1.

4.1.2.4 Heat Generation Rates During steady state operation, the F/A shield block is exposed to nuclear heating which was considered to collapse immediately following the initiation of the Upset, Emergency, and Faulted Transients. The nuclear heating rate per unit volume is maximum at the upper portion of the F/A shield block and decreases toward the inlet nozzle. In order to obtain a conservative estimate of temperature distributions for subsequent struc-tural analysis, the maximum nuclear heating rate per unit volume (0.0295 3

BTU /in -sec) was assumed throughout the 30 sector of the F/A shield block material. The heat generation was taken to collapse from maximum to zero in 230 millseconds at 1.2 seconds into the E-a l

4.1.2.5 Analysis and Results

, The ANSYS thermal analysis of the F/A shield block was arranged to provide detailed temperature distributions over the total worst case duty cycle.

A total of 21 load steps were selected at prominent sodium temperature and heat generation conditions. Sodium temperatures were imposed at the l wetted surface nodes and heat generation rates applied to each finite element. The first 17 load steps were taken for steady state conditions and the E-4a trcnsient to 2400 seconds. Load Steps 1 and 2 represent steady state thermal conditions under 750 F sodium temperatures and maximum heat generation rate. Load Steps 3 and 4 provide the continua-tion and collapse of the heat generation rate. Load Steps 5 through 17 correspond to prominent E-4a sodium temperatures to 600 F. The 600'F soak corresponds to Load Step 18. The 20 F/ hour and 5.5*F/ minute heat-a up rates were represented by Load Steps 19 and 20. The steady state

sodium temperatures and heat generation rate for the 10 day hold-time corresponded to Load Step 21. Prominent Load Steps in the E-4a transient are illustrated in Figure 4.1-5 and numerical values for the total worst case F/A shield block duty cycle are summarized in Table 4.1-1.

Table 4.1-1 Worst Case F/A Shield Block Duty Cycle ANSYS Input Data i

3 Load ! Time l Temp Heat Gener.

Step l (SEC) ( F) (BTU /SEC-IN3 )

1 0.0 750 0.0295 2 0.0 750 0.0295 3 1.2 750 0.0295 4 l.43.' 750 0.0 5 20. 750 0.0 6 80. t 710 j 0.0 7 '

200.I675 +

0.0 8 260. 586 I 0.0 .

9 400. 915 0.0 10 760. 1000 0.0 11 880. 975 0.0 12 1000 800 0.0 13 1140 745 0.0

14 1260 l745 0.0 15 1520 i 820 0.0 16 1750 735 .0 17 2400 600 0.0 18 9600 600 0.0 19 16800 640 0.00787 20 18000 750 0.00295 21 882000 750 0.00295

l i

1000 -

@ i

/

\@ '

Figure 4.1-5 90 -

~

F/A Shield Block ;

/ E-4a Transient Load Steps

\ ,

@< l

\

900 -

(

\

850 - l

\

I , !

m 15' !

t I I / !

e 800 2a2 h I

- /

_@ @ @ l \ /

E @ l \

. 750 @ l 37 it i l li l I

~

T l \

700 -

i 650 -

, 600 -

L7/

il,

, i r , i i , i i

! 0 400 800 1200 1600 2000 2400 Tirne (Seconds)

The ANSYS solution of the worst case F/A shield block duty cycle was obtained in 124 cumulative ite;ations using a steady state and transient ,

convergence criteria of 1 and 5 F respectively. The temperature distribu-tions at each cumulative iteration were saved on ANSYS Tape 4 for recall in subsequent structural analysis. In order to determine the cumulative -

iterations of interest in structural analysis, maximum and minimum through the wall temperature differences are most important in relation to structural damage. The F/A shield block temperature differences were based on the through-the-wall temperatures at Nodes 1 and 237 depicted in Figure 4.1-4. A plot of tt2 temperature difference between Nodes 237 and 1, that is, aT =

T 237 - Tj , in terms of cumulative iteration in the solution run is illustrated in Figure 4.1-6.

A review of the through the wall temperature difference shows that the

maximum and minimum values occur at cumulative iterations 36 and 63 respectively, with a temperature difference range of 290'F. In the thermal solution run, cumulative iterations 36 and 63 correspond to the E-4a tran-sient at 260 and 760 seconds as illustrated in Figure 4.1-1. The steady state temperature distributions at the start of the E-4a transient, and beginning and end of the 10 day .sid-time correspond to cumulative

~

iterations 4, 80, arid 124. Cumulative iteration 23 represents the first positive maximum after the initial steady state conditions. Plots of the temperature distributions at cumulative iterations 2, 36, and 63 are -

, illustrated in Figures 4.1-7 through -8 respectively.

4 l

l l

f !

N

n o

i t

7' n o

a4 r8 e *ita0 t r r8

= I e t

d*

y a

e*

h* I en vo ii t tt S aa

l r 0 ue I

7 mt uI C

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g f j

n0 I a9 R2 0

3 : 6 6

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0 4

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o 3 t 2 a r _

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. o I i

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0 v 6 r 3 i 3

e t t k a n I c t l o 6 o n u i

. - l e m t 1 B i u a s C r 4 d n e l a s t 0 e e r V I

2 r i T u h e _

g S a c i 4 n F A - e

/ E r F e e

t f

f a i t D S

x y id e r

I d u _

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T A 'l 0

0 0

5 o 0 0 0 5 0 5 1 - 1 1 e

c

.n pe)

. mrF ee Tf(

f i

D

e Initial and Final Steady State (Cumulative Iteration 2)

- 826*F 750 F Cumulative Iteration 36 N

w l < 1 i j 790 F 615*F Figure 4.1-7 F/A Shield Block E-4a Transient Cumulative Iterations 2 and 36 Temperature Distributions ,

I l

l l

l

\

l l

\

l :

1 . \ a \ \f"'

800*F

\*

l l

Figure 4.1-8 F/A Shield Block i

E-4a Transient Cumulative Iteration 63 l Temperature Distribution l

l l

4.1.3 Worst Case Duty Cycle The conclusions based on the F/A shield block loading analysis in relation ,

to establishing the worst case duty cycle with reconnendations made for subsequent structural analysis were as follows. ,

e Mechanical loads comprising OBE and SSE seismic, core

' restraint, internal pressure, and dead weight were considered negligible in establishing the worst case F/A shield block duty cycle, o Thernal loads comprising the E-4a transient in combination with thermal conditions in returning to steady state and the hold-time prior to the initiation of the next E-4a transient were considered most important in establishing the worst case F/A shield block duty cycle.

The recommendations for the specific F/A shield block loading in relation to the worst case duty cycle were based solely on time independent and dependent thermal loadings. In the specification of temperatures in the ANSYS structural analysi', the uniform temperature is a constant tempera- .

ture distribution throughout while the reference temperature is the basis for deriving the thermal expansion relative to a uniform temperature or a temperature distribution corresponding to a cumulative iteration in the .

thermal solution run. The following worst case F/A loading cycle sequence simplified from the maximum temperature difference versus cumulative iteration plot (Figure 4.1-6) was recommended to be repeated 40 times so as to provide to upper bound to the 39 Normal and .pset Events and worst Emergency or Faulted Event.

Time Inda7endent e Select a uniform temperature equal to the reference temperature at cumulative iteration 23. Load to the cumulative iteration

. 23 temperature distribution and unload to uniform temperature.

e Select a uniform temperature equal to the reference temperature at cumulative iteration 36. Load to the cumulative iteration 36 temperature distribution and unload to uniform temperature, e Select a uniform temperature equal "to the reference temperature at cumulative iteration 63. Load to the cumulative iteration 63 temperature distribution and unload to uniform temperature.

e Select a uniform temperature equal to the reference temperature at cumulative iteration 80. Load to the cumulative iteration 80 temperature distribution and unload to uniform temperature.

Time Dependent e

. Select a uniform temperature equal to the reference temperature at cumulative iteration 124. Load to the cumulative iteration 124 temperature distribution and hold for 10 days.

S

4.2 Structural Analysis The F/A shield block structural Analysis was directed to deriving the stresses, strains, and dimensional changes which occur during the worst case duty cycle from which subsequent structural evaluations were '

made. In the following, the F/A shield block structural model, geometry, and boundary conditions are described. Next, linear and non-linear material properties including the effects of irradiation on stress-strain curves and the basis for neglecting thermal creep are presented. The selection of a reference temperature for thermal expansions in relation to the axial constraints on the region selected for analysis is described.

Finally, the time independent and time dependent inelastic analysis and results for the F/A shield block are presented in preparation for sub-sequent structural evaluation.

4.2.1 Model, Geometry, and Boundary Conditions The F/A shield block structural model was formulated in the ANSYS finite element program compatible with the prior thermal analysis. As such, the dimensional extent of the 30 sector and finite element mesh in both structural and thermal models were identical. In formulating the F/A shield block structural model, the ANSYS constant strain (STIF 2) element was used to replace the linear temperature element (STIF 35) used in the thermal model.

The boundary conditions along the lateral surfaces of the 30* sector,in the manner of the conventional roller support were taken to have zero normally disposed displacement, but free to move radially. Along the surface parallel to the Global X - axis, the UY displacements were set equal to zero at Nodes 1, 37, 38, 74, 75, 111, 112, 148, 149, 185, 186, 204, 205, 223, 224, 234, 242, 249, 256, 263, 270, and 277. For the inclined surface-the UY displacements, after a 30 rotation to obtain normally disposed directions, were set equal to zero at Nodes 228 through 232, 237 through 239, and 243, 250, 257, 264 and 271. The F/A shield block structural model is illustrated in Figure 4.2-1.

m

Roller Supports UY=0.0 Node Points 1, 37, 38, 74, 75, 111, 112, 148, 149, 185, 186, 204, 205, 223, 224, 234, 242, 249, 256, 263, 370, 277 hY , 5b EL. 98 EL. 90 X

UY=0.0 Node Points 228 + 232, 237 + 239, 243, 250 Figure 4.2-1 F/A Shield Block Structural Model, Geouetry, And Boundary Conditions

4.2.2 Properties The F/A shield block as constructed from SA-316-SS and initially unirradiated 22 2 at BOL is irradiated to a fluence (E > 0.1 Mev) of 0.31 x 10 n/cm at E0L. Operational temperatures range from 400 to 1000*F. The , linear and ,

non-lir ear properties of SA-316-SS under fluence and temperature selected

! in the F/A shield block structural analysis are described as follows.

4.2.2.1 Linear The linear SA-316-SS material properties are the Young's modulus (E),

Poisson's ratio (u), and the coefficient of thermal expansion (a). The linear material properties are relatively insensitive to fluence, but are functions of temperature. The corresponding linear properties as polynomial functions of temperature (T s F) were taken from the NSM Handbook [6] and are sumarized as follows.

Young's Modulus (E s PSI)

E = (2.834E7) - (2.88E3)*T .

- (3.69) x T2 + (7.71 E-4)*T3 Poisson's Ratio (v) .

u = 0.262 + (4.26E- 5)*T Coefficient of Thermal Expansion (a s 1/ F) a= (10.08E-6) + (0.ll7E-8) *T In order to reduce the non-linearity of the material properties with j temperature in the ANSYS structural analysis, constant properties which provide conservative results were selected instead of the polynomial i relations. The use of constant properties permits the use of the initial f

stiffness matrix as computation time associated with reformulating the stiffness matrix for varying temperature distribution is eliminated.

In the F/A shield block structural analysis, the values of Young's modulus (24.06 x 106 psi) and Poisson's ratio (0.2966) were taken as the 800 F values for SA-316-SS. The 800 F temperature is the approximate mean of the F/A shield block during the worst case duty cycle. The value for the SA-316-SS coefficient of thermal expansion (11.25 x 10-6/ F) was taken at 1000 F. The selection of maximum coefficient of thermal expansion provides a worst case estimate of attendant damaging strains over the range of temperatures in the worst case duty cycle.

4.2.2.2 Non-Linear The non-linear SA-316-SS material property behavior required for the F/A shield block are the constitutive relations for stress and strain and thermal creep. The constitutive relations including the effects of fluence and tempera-ture with attendant simplifications made in the F/A shield block structural analysis are described in the following.

4.2.2.2.1 Stress-Strain Curves The SA-316-SS stress-strain curves as a function of temperature and fluence are given the NSM Handbook [6] in terms of true average values. A review of the data shows that the effect of fluence is to increase the stress at a given level of strain. As such, irradiated stress-strain curves for SA-316-SS exhibit a time dependent hardening through embrittlement from B0L to E0L. For the F/A shield block, the E0L fluence (E >0.1 Mev) based on June, 1977 data is 0.31 x 1022n/cm .

2 Simplifications made in the F/A structural analysis for the time dependent effects of fluence on stress-stt ;in curves as well as the consideration of minimum instead of average properties are discussed as follows.

O

!b

~

For ne initially unirradiated F/A shield :Icck a: 51, :*,e SA-316-55 stress-strain curve is a riniru and increases during cceraticcal life .

reacning a raxirun at ECt. In order to derive a re:resentative ineiastic response with the structural analysis Of the F/A shield blect fer the worst case duty cycle, a rean stress-strain cune based ne tire average ,

values of rinin;- EOL and raxirun EOL stress-s* rain cunes was selected for the structural ar,alysis. Tne use of tre tire averaged rean stress -

strain curves is c:qsistent wita :ne tire average: 10 worst case F/A duty cycles distributed unifornly over the 325 FrD Sedeen E.1 and ECt. 'di ta rean stress-strain curves, the 50L fatigue dam;e is underestfratec while ne 50L creep car. age is everes*inted. Conversely, :~e rean stress-strain a;proacn everestira:es EOL fatigue da age wnile t*.e EOL creep carage is underesti ated. A:::rcic;1y, the F/A shield :!::k stru:: ural analysis based on rean tire averaged stress-strain curves wa; considered to describe the overall inelastic resocnse to tre unifem distribution of the 10 worst case daty cycles witbout any significant less in accura:y.

'ditn regard to tne scatter of SA-316-55 stress-strain data at fluence and te cerature, trae rinin;- ins:ead of true average or typical values were selected. Minim Yalues ;rOViCe c *,servative inellstic res;Cnse as the wcrst case F/A shield block duty cycle as descrited by the relatively -

sicw acting t*,erral transients wnich are basically static loadirr;s. Tne true ninins stress-strain curves were ccnstrue:ed by taking 9M of the true average stress values given :ne h5M Fando ci [6].

In order to illustrate tre :/A shield block analysis a: rca:n, :*e SA-316-55 stress-strain cune as ne rean of tr.e 50L ard ECL stress-strain curves

., .ry.....

. , a <-

~ ~r - j n j n .. m .>. *.,=. s ..= ". .e r .= . :mW., .: '. s . e c..a . . *. *. .d 4. . . r. i. ~g -a.

. 4.7-2.

Tne correscending stress-strain curve cata at 500, 9~0, and ICCFF are

resentec in Table 4.2-1. The true ninine ezn stress-strain cune data fer SA-316-55 at SCW F was als used fcr F/A s .ield block te cerata es less :han ECW :. Stress-s:cain curve data at i .:emediate terperatures e<rw 3. + w~- e s e i so.

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1 Table 4.2-1 F/A Shield Block True Minimum Mean of BOL and EOL Stress-Strain Data SA-316-SS

! Temp I E Stress (PSI) at Total Strain 6

'(*F) (10 P5I) 0.000748!0.003068 0.00728 ! 0.011382 0.0518 i

17997 26600 31200 33800 47200 800 ,

24.06 ,

17997 ; 25100 29400 32600 46400 i 900 24.06 24.06 17997 26900 32400 34400 g 47000 1000 3 4.2.2.2.2 Thermal Creep Equations The unirradiated SA-316-SS thennal creep-time constitutive relations as a function of stress and temperature are given in the NSH Handbook [6].

The thermal creep constitutive relations for irradiated SA-316-SS are not identified as the effects of irradiation are included in the irradiation creep equations.

22 2 For the F/A shield block, the E0L fluence is 0.31 x 10 n/cm with thermal .

creep occuring at a steady state temperature cf approximately 750"F over the 10 day hold time of the worst case duty cycle. As the E0L fluence is relatively low and steady state temperatures are below 800*F, thermal ,

creep over the worst case F/A shield block duty cycle was considered negligible. Accordingly, a study of the thermal creep constitutive relation for SA-316-SS in relation to the F/A shield block analysis with simplifica-tion similar to those made for the SA-316-SS stress-strain curves were not performed.

4.2.3 Worst Case Duty Cycle Response i

The structural response of the F/A shield block to the worst case duty cycle loading required the selection of reference temperatures compatible a

with the temperature distributions at the worst case through the wall temperature difference and axial constraints prior to deriving time . \

independent and dependent solutions. A description of the analysis and solutions which are required in subsequent structural evaluations is as follows.

4.2.3.1 Constraints and Reference Temperature Selection i

The F/A shield block structural model corresponds to a 30 sector of a lateral slice taken along the length of the shield block. Axial cons-traints normal to the 2 dimensional representation of the 30 sector closely simulate a plane strain condition as the length of the shield block is significantly greater than the corresponding cross-section dimensions. Accordingly, the F/A shield block was considered to be in plane strain condition for the purposes of analysis.

In a plane strain analysis under thermal loading, the ANSYS program calculates mechanical stresses induced by thermal strains (cTH) which are dependent on the coefficient of thermal expansion (a), temperature distribution (T), and reference temperature (TR ) according the relation c

TH = a ( -TR ).

As the plane strain condition requires that the total net force (F n) along the length vanish, the nomal mechanical stresses (og) induced by the thermal strains (cTH) when integrated over the area (A) must also vanish. In this arrangement, the selection of a reference temperature (TR ) depends on the temperature distribution (T) throughout

. the plane section.

The selection of a reference temperature (TR ) that provides a net force (Fn ) across the plane section that vanishes is approximated with classical elasticity theory even though the nomal (o,) stresses may be beyond the proportional elastic limit of the material. The linear elastic approxi-mation was considered acceptable as a first approximation to assuring a plane strain condition. For the case where the Young's modulus (E) and coefficient of thermal expansion (a) are constant, the reference tempera-ture (TR) in a plane strain finite element model is related to the nomal stress distribution o, (x, y) for an arbitrarily selected reference temperature (Tg ) as follows.

n T

R = T, AEa 9 jf "z (x, y) A j Where, n = No. of Finite Elements Ai = Area of Individual Finite Elements A = Total Plane Area n

A = I Aj i=1 In order to facilitate the computation of reference temperatures for the F/A shield block structural analysis, ANSYS elastic solutions for the normal stress distribution o, (x, y) at an arbitrary reference temperature (Tg ) were obtained for each of the temperature distributions corresponding to the reconinended cumulative iterations in the thermal analysis solution run. ANSYS tape 12 data containing the normal stress distribution and finite element geometry were catalogued for recall by a reference temperature post processor. The F/A shield block reference temperatures (T R ) at the recocinended cumulative iterations for the worst case duty cycle are sununarized in Table 4.2-2. .

Table 4.2-2 F/A Shield Block .

Reference Temperatures i

Temperature Reference Distribution Temperature (cumulative iteration) ,

(T R s F) 4 f 788.8 23 -

635.4 36 821.4 63 860.7 ,

80 805.3 l 124 788.8

4.2.3.2 Analysis and Results The ANSYS inelastic analysis of the F/A shield block structural model

, under the worst case duty cycle was arrangedin time-independent plastic analysis associated with the short term E-4a transient followed by time-dependent creep analysis corresponding to steady state temperatures over the 10-day hold-time. The time independent and dependent analysis pro-vide the structural response from which evaluations of crack initiation in tenns of local ductile rupture and creep fatigue damage are made. With regard to dimensional changes which can exceed functional limits, the peak plus accumulated and residual deformation response during and following the worst case F/A duty cy* are required.

In order to obtain the desired results i 4 an efficient manner, the ANSYS restart option was used to provide the 1 > ding sequence within, between and after the time independent and time dependent solutions. As elastic /

plastic / creep instability would not be expected for the F/A shield block under the deformation-controlled thermal loadings, the ANSYS small strain-small deformation option was used in the inciastic r.ialysis.

A description of the time independent and dependent analysis e id results is as follows.

4.2.3.2.1 Time Independent The time independent ANSYS analysis of the F/A shield B~ock was directed to deriving the peak + accumulated strains and deform.tions associated with following the path dependent thermal loadings fron. initial steady )

l state conditions through the E-4a transient followed by the return to final l steady state conditions, but excluding the 10-day hold-time. The time independent loadings were considered as static loadings applied at zero time.

A total of 3 load steps were used to detennine the F/A shield block structural response to the initial steady state temperature distribution. For the E-4a transient and the return to final steady state temperature distributions, a total fo 24 sequential load steps in combination with the ANSYS restart

option were used to obtain the path dependent structur al response.

Sumnaries of the F/A shield block time independent structural analysis procedures for the initial steady state conditions and E-4a transient fol-lowed by the returr. to final steady state conditions in terms of Load Steps, iterations, temperature distributions, reference temperatures, and descriptions are presented in Tables 4.2-3 and -4 respectively.

Table 4.2-3 F/A Shield Block Time Independent Analysis Summary Initial Steady State Conditions Temperature Reference Load Iterations Distribution Temperature Descriotion Steps ( F) ('F) 1 1 788.8 788.8 Initial Steady State ~

2 12 Cum. Iter. 4 (Time = 0.0 sec.)

3 3 Cum. Iter. 4 e

~

Table 4.2-4 F/A Shield Block Time Independent Analysis Summary E-4a Transient and Return to Final Steady State Conditions Load Step Iterations Temperature Reference Description Distribution Temperature

( F) (F) .-_

First E-4a Loading 636.4 1 1 636.4 2 14 Cum. Iter. 23 and(Time Unloading

= 0.0 )

3 5 636.4 Second E-4a Loaa-4 1 821.4 ing and Unloading 5 26 Cum. Iter. 36 821.4 ( me = 60 sec.)

6 5 Cum. Iter. 36 7 1 Cum. Iter. 36 8 26 821.4 9 5 821.4 10 1 860.7 860.7 Third E-4a Loading 11 4 860.7 and Unloading 12 18 Cum. Iter. 63 (Time = 760 sec.)

13 8 Cum. Iter. 63 14 1 Cum. Iter. 63 15 13 860.7 16 1 860.7 _

17 1 805.3 l 805.3 Fourth E-4a Load-18 5 Cum. Iter. 80 ing and Unloading 19 3 Cum. Iter. 80 (Time = 9600 sec.)

20 5 805.3 21 1 805.3 22 1 788.8 788.8 Final Steady State 23 10 Cum. Iter.123 (Time = 882000 sec.)

24 1 Cum. Iter.123

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f 12,653 PSI Figure 4.2-3 F/A Shield Block

- Initial and Final Steady State Time Independent Equivalent Stress Cumulative Iteration 36 -

w

\\ 23,870 PSI

,/

Cumulative Iteration 63

\

l s- % .

20,396 PSI A/

e Figure 4.2-4 F/A Shield Block Cumulative Iteration 36 and 63 l Time Independent Equivalent Stress ,

!nitial Steady State l .

M F 0.00035 in.

Cumulative Iteration 36 h

l .,

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Figure 4.2-5 '

F/A Shield Block

. Non-Uniform Deformations Time Independent

4.2.3.2.2 Time Dependent .

The F/A shield block time dependent ANSYS analysis was directed to deriv-ing the residual strains and defomations associated with the 10-day hold-time following the final time independent steady state conditions.

The time dependent analysis was perfomed in 2 Load Steps using an i

ANSYS restart from load step 24 of the time independent analysis for the final steady state conditions , represented by cumulative iteration 23 temperature distributions, and maintained for 10 days or 240 hours0.00278 days 0.0667 hours 3.968254e-4 weeks 9.132e-5 months .

As thermal creep was considered negligible and not included in the creep analysis, a redistribution of final steady state stresses by relaxation would not occur. Nevertheless, the final steady state structural response, although constant with time, is still required for subsequent evaluations of creep damage. An additional ANSYS restart from Load Step 26 in 2 Load Steps was performed to unload the F/A shield block to a unifom temperature so as to obtain residual deformations. A sunnary of the F/A shield block time dependent structural analysis pro-cedure for the 10-day hold-time and unloading to a unifom temperature is presented in Table 4.2-5.

Table 4.2-5 F/A Shield Block Time Dependent Analysis Sumary ,

10-Day Hold-Time and Unloading Load Iterations Temperature Reference Description Steps Distribution Temperature

( F) ( F) 25 l Cum. It. 23 788.8 10-Day Hold-Time 26 1 Cum. It. 23 27 1 788.8 788.8 Unloading for 28 1 788.8 Residual Deforma-tions.

i The F/A shield block structural response to the time dependent loading was identical to the response found at the final steady state conditions of the time independent loading as thermal creep ingly, the time dependent maximum equivalent stress and peak non-uniform defonmations for the worst case duty cycle are identical to the time independent values illustrated in Figures 4.2-3 through -5.

With regard to the non-uniform deformations of the F/A shield block, the final steady state and residual values were found to be 0.00035 and 0.00004 in respectively, and are illustrated for Figure 4.2-6.

I l

9

=

Final Steady State N

l '.

_g 6 0.00035 in.

Residual \

N l '.

s..

d E 0.00004 in.

FIGURE 4.2-6 F/A Shield Block Non-Uniform Defomations Tine Dependent P

4.3 Structural Evaluation The F/A shield block structural evaluation was arranged to provide a com-l parison of the structural response for the 40 worst case duty cycles in l

, relation to criteria which protect against crack initiation and excessive deformation failure modes and thereby assure reliability and function over the first and second reactor cycles.

The procedure for performing the F/A shield block structural evaluations of peak plus accumulated and residual deformations in relation to defoma-tion limits was relatively direct as the inelastic deformations are known from the ANSYS displacement solutions. However, for comparisons of the stress and strain response with crack initiation failure mode criteria, l the structural evaluation procedure is not direct because a detailed examination of local multiaxial stress and strain behavior in relation to uniaxial tensile and biaxial pressurized tube data is required prior to

! evaluating the local ductile rupture and combined creep-fatigue factors.

Further, the F/A shield block model includes a large number of finite elements which must be screened to determine the worst location for crack initiation. Accordingly, an important consideration in perfoming a thorough structural evaluation of crack initiation is a means of crocess-ing the stress and strain response into a format that perrits a ready comparison with allowable limits. In this arrangement, a special l purpose damage processor was written to access the stress and strain response data written on ANSYS Tape 10 for each converged time-independent and dependent solution throughout the worst case F/A shield block duty cycle. From supplied uniaxial or biaxial materials data and crack initiation failure mode correlations, the damage processor examines the local stress and strain response of each element in the l F/A shield block throughout the worst case duty cycle and identifies l the element with the maximum local ductile rupture and combined creep damage factors. A description, flow chart, and listing of the damage processor is presented in Appendix A.

I L J

In the following, the F/A shield block structural evaluation of crack initiation, including allowable materials data and failure mode correla-tions with results for local ductile rupture and combined creep-fatigue damage, are presented. Next, the structural evaluation of F/A shield block defonnations in n' elation to allowable limits is presented.

Finally, the F/A shield block structural evaluation of crack initiation and excessive deformation failure modes is sumarized.

4.3.1 Crack Initiation i The F/A shield block structural evaluation of crack initiation in rela-tion to local ductile rupture and combined creep-fatigue damage criteria over the 40 worst case duty cycles is presented in the following sub-sections.

4.3.1.1 Local Ductile Rupture The local ductile rupture criterion in protecting against crack initiation requires that the local ductile rupture factor (FDR) be less than unity at any point in the F/A shield block.

F = Maximum of 03 DR f, min >

(

g

' I* max principal) TF j S

u, min In the following, the allowable uniaxial strains used in the F/A shield block structural evaluation and comparison of results with the local ductile rupture factor criterion are presented.

4.3.1.1.1 Allowable Uniaxial Strains The F/A shield block as constructed from SA-316-SS is unirradiated at 22 2 80L. The E0L fluence (E>0.1 Mev) is 0.31 x 10 n/cm . In addition, the F/A shield bicek temperatures range from 400 to 1000*F. The true minimum uniaxial uniform elongation (cu, min) and fracture (cf, min) strains for unirradiated and irradiated SA-316-SS as a function of temperature used .

in the F/A shield block structural evaluation are described as follows.

4.3.1.1.1.1 Uniform Elongation The true irradiated uniaxial SA-316-SS uniform elongation (cu, min.) used in the F/A shield block structural evaluation were based on the minimum correlations of irradiated engineering uniform elongation (Eu, min) recom-mended in the trial applications of the RDT Draft for Breeder Core Components [20-28].

The minimum engineering uniform elongation (Eu, min) ver the temperature range 700 to 1100 F as a function of fluence (E>0.1 Mev, where (4t) is in units of 10 21 N/ cm2 ) is given by the relations.

21 E

u, min = 0.22, for (4t) < 10 21 l 21 I c u, min = 0.22 ( t ), f r (4t) > 10_

In order to obtain true minimum irradiated uniform elongation ('u, min) strains for the evaluation of the local ductile rupture factor (FDR) I" the F/A shield block, the following relation was used.

'u, min

I" (I + u, min) 4.3.1.1.1.2 Fracture The true uniaxial irradiated SA-316-SS fracture strains (cf, min) used in the F/A shield block structural evaluation were taken directly from the minimum correlations for true fracture strain recommended in the trial applications of the RDT Draft for Breeder Reactor Core Components [5]. .

I The true minimum irradiated fractre strain (cf, min) ver the temperature range 800 to 1400 F as a function of fluence (E>0.1 Mev, where (4t) is

- in units of 10 22 n/cm2 ) and temperature (Tm F) is given by the relations.

l

S f, min " *f for (4t) < (4t). .

_1 '(4t)'N S

f, min -*f .(4t)., for (4t) > (4t).

where, I for 800 < T 5 1000 cf = 0.45 1000 I for 1000 < T < M00 cf = 0.45 ,1000 (4t). = 1.4 1000 r 800 < T 5 1000 (4t).= -1 or 1000 < T < M 00 1000 n=-1.7+h00 4.3.1.1.2 Comparison with Criterion The F/A shield block structural evaluation in relation to the worst case location for local ductile rupture was made by screening each of the finite '

elements over the 40 worst case duty cycles with the damage processor. The maximum local ductile rupture factor (FOR) max for the F/A shield block was found to occur at element 90, identified in Figure 4.2-1. .

The peak BOL strain components occurred at the cumulctive iteration 63 temperature distribution in the E-4a transient where the local metal temperature was 802 F. Accumulated BOL strain components were based on the difference between final and initial time independent steady state condition in the worst case duty cycle. The EOL maximum principal strain for the peak BOL and accumulated BOL strain components over l

40 worst case F/A duty cycles was 0.00952 in/in, The triaxiality i

factor for the local stress state was 2.1 while the true minimum irradiated uniform elongation and fracture strains at E0L fluence I 22 2 (E>0.1 Mev, (4t) = 0.31 x 10 n/cm ) were 0.076 and 0.972 respectively.

i In this arrangement, the maximum local ductile rupture factor (FDP) max for the F/A shield block was found to be controlled by the uniform elonga-tion with a value;

~

(FDR) max = 0.263 As (FDR) max = 0.263 < l.0, the F/A shield block is not expected to experience crack initiation over the 40 worst case duty cycles based on the local ductile rupture criterion.

4.3.1.2 Creep-Fatigue Damage The creep-fatigue damage criterion in protecting against crack initiation requires that the combined creep-fatigue damage factor (FCF9) be less than unity at each point in the F/A shield block.

c+D F

CFD

= a/b = Minimum of {e7/3D eDc + 7/3 D 1 In the following, the allowable limits for fatigue life and creep rupture times used in the F/A shield block structural evaluation and a comparison of the results with the combined creep-fatigue damage criterion are pre-sented.

4. 3.1. 2.1 Allowable Limits The F/A shield block as constructed from SA-316-SS is irradiated to an 22 2 E0L fluence (E>0.1 Mev) of 0.31 x 10 n/cm . In addition, the F/A shield block temperatures range from 400 to 1000*F with the wetted sodium surfaces subjected to oxidation as well as interstitial transfer of carbon and oxygen. The fatigue life and time to rupture data for SA-316-SS including the effects of fluence, temperature, interstitial transfer, and surface oxidation used in the F/A shield block structural evaluation are described as follows.

4.3.1.2.1.1 Fatirse Life Currently, fatigue idfe c:rrelatiens are rot available fcr irradiated SA-316-55 as a function of fluence and teecerature. A:::rdingly, the Manson U .iversal 51cpes Method [7] was used to develcp f atigue life .

correlaticas fr:m mich the fatiya damage fa::Or (D') for ite F/A shield block over the 20 wors case duty cy:les was derived.

In the Mansen Universal Sicpes Method, the sl tes of elastic a-d plastic strain lines expressed in ters::s of strain range versus nacer of cycles en a full logarithcic plo are assured to te the same for all mtedals.

As a;;olied to .nirradiated SA-315-55, the :Otal strain ran;e (Lc) is dependent on the ninigun unirradiated true fracture strain (c,.,,J), average unirradiated engireering ultirate strengtn (Su,u), Yecng's Modulus (E),

and cycles to failure (N,) by :ne relation:

0.5 -

+ s.: Su,u % ,0.12 Ec = cf,,.,h-0.6

a. ; .

In order : include 16e effects of irradiation in the fatiFA life relatice for SA-315-SS, reduction fa::crs for 04 elastic (F,) and plastic (Fp ) '

strain ran;es were used in atterdance with :ne guidelires of t% EST Draft for 5reeder Reactor Ccre C:ccccents [5].

- 0.5 e , ,, N

-0.5 +

s.: r Su,u % ,0.12 Lc = r p ... a. e .

E ie.e re , t = ,5u ,I )Le e

t Su,u F = ('f,I) 1 P

c , ,,

c,..I = True Minitun Irradiated Fra::;re Strain S, y = Average Irradiated Engireerin; Ultir. ate Strert;;h k , k: = Ex:erirental Cecstants i ,

-71

l l

Without available material data, the elastic reduction factor (F e) and plastic reduction factor exponent (kj ) were taken as unity. Accordingly the fatigue life relation developed for irradiated SA-316-SS was:

Ac=c

-04 g -0.6 + -0.12 f,7cf f 3. 5 S_ N f

The development of the irradiated SA-316-SS fatigue 1ife relation requires the trae minimum irradiated and unirradiated fracture strains (cf,y and ;f, ),

average unirradiated engineering ultimate strength (Su,u), and Young's Modulus (E).

e The true minimum irradiated and unirradiated fracture strains (cf,7 and cf,u) as a function of temperature and fluence are given in Section 4.3.1.1.2.

e The average unirradiated engineering ultimate strength (Su,u) was taken as 125% of the minimum values given in the NSM Handbook [6].

Su,u = 100220 - (161.42)*T+(0.368)*T2 3 4

- (0.325E-3)*T +(0.863E-7)*T where, Su,u % psi ,

T s *F .

e Young's Modulus (E) as a function of temperature is given in Section 4.2.2.1 The irradiated SA-316-SS fatigue life relation as developed from the Manson universal slopes method and corrected for the effects of irradiation is strictly applicable only to uniaxial stress states. In order to apply the fatigue life relation to the F/A shield block, reductions in fatigue life which reflect the multiaxial stress and strain state are required. The RDT Draft Criteria for Breeder Reactor Core Components [5] recomends that equivalent strain be used for the strain range in fatigue evaluations of multiaxial stress and strain states. Another means of accounting for multiaxial effects

on fatigue life is to use the range on naximum principal strain. fn the F/A shield block fatigue evaluation, the fatigue life based on equivalent -

or maximua principal strain, whichever produced the minicxn fatigue life was adopted in order to provide an additional safeguard against fatigue failure. ,

An additional consideration is that the Manson Universal Slopes Method is strictly applicable only to the rean fatigue life of a material and does not account for the scatter in experimental data. 15e RDT Draft Criteria for Breeder Reactor Core Cocponents [5] recomends that the 2-20 rule be used to account for the minioun fatigue life due to scatter of data about the mean. The 2-20 rule was adopted for the fatigue life correlations of irradiated SA-316-SS in the F/A snield block structural evaluation of fatigue life. Simp!y stated, the 2-20 rule requires that the multiaxial fatigue life be taken as the uniaxial fatigue life reduced by a factor of 2 on strain range or a factor of 20 on life, whichever is minicum. The 2-20 rule as applied to the untaxial fatigue life relation developed for irradiated SA-316-SS using the Manson Universal Slopes Method for the F/A shield block E0L fluence (E>0.1 Mev, :t = 0.31 x 10 22 n/cm ) at 800*F 2

is presented in Figure 4.3-1.

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d ebeu ns.ts - S 4.3.1 21.2 Creep-Rupture Time Currently, rupture time correlations are available for unirradiated and irradiated SA-316-SS based on pressurized thin walled tubes in a biaxial stress state [8]. As such, the available biaxial rupture time data with

reductions for interstitial transfer and surface oxidation are sufficient c '

for the evaluation of the creep damage factor (D ) for the F/A shield block over the 40 worst case duty cycle.

The creep-rupture time data [8] for unirradiated and irradiated SA-316-SS is presented in terms of the Larson-Miller Parameter (LMP). The minimum unirradiated and irradiated LMP, designated as (LMP)u and (LMP)g, taken as 2 standard deviations below average data, as a function of stress 22 2 (o S ksi) and fluence (E>0.1 Mev, where (4t) is in units of 10 n/cm) are:

(LMP)u = 48.91 - 5.27 Log 10 o - 2.995 (Log 10 ")

(LMP); = 52.024 - 13.353 Log 10 -1.311 Log 10(4t)

To obtain the minimum rupture time (tp s HRS) at a temperature (Ts *R x 10-3) ,

for either unirradiated or irradiated SA-316-SS, (LMP)u = (LMP)g = T (20 + Log 10rt)

Reductions in rupture timer(t ) to account for interstitial transfer of carbon and nitrogen for SA-316-SS were found to be neglible. However, surface oxidation of SA-316-SS at wetted sodium surfaces is known to moderately affect rupture strength. The percent decrease in rupture strength for SA-316-SS from surface i: teraction with sodium as a function of temperature is identified in the CRBRP Core Former E-Spec [9] and summarized as a fractional reduction (FR) over a 800 to 1300*F temperature range in Table 4.3-1.

TABLE 4.3-1 F/A SHIELD BLOCK FRACTIONAL REDUCTION RUPTURE STRENGTH

. SA-316-SS Fractional Temp.

Reduction ( F)

(FR) 1.0 800 1.0 900 0.97 1000 034 1100 0.91 1200 0.88 1300 In order to include reduction in rupture strength for both unirradiated and irradiated SA-316-SS due to sodium effects in F/A shield block evalua-

- tions of creep damage, the inelastically calculated maximum stress intensities or principal stresses (a) were increased by the reciprocal of the fractional reduction (FR) prior to evaluating the minimum rupture times (tr).

o = o/FR In sumary, the minimum rupture time (t p) for unirradiated SA-316-SS including reductions in rupture strength due to sodium effects used in creep damage evaluations of the F/A shield block are as follows.

t, =

10 exp [(LMP)u, min-20]

T o

.i where, I

~

(LMP)u, min =48.91-5.27 Log 10(FF)-2.995(Log 10Tff) I Similarly, for irradiated SA-316-SS, .

t =10exp[ I, min-20]

r where, 1

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l n/cm ) at 800*F are illustrated in Figure 4.3-2.

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4.3.1.2.2 Carparison with Criterion The F/A shield block structural evaluation in relation to the worst case location for cortined creep-f atigue darage was rade by screening each of tne finite eierents over the 40 worst case duty cycles with the da age processor. The raxiram comoined creep-fatigue da age f actor (FCFD) rax for the F/A shield block was found to occur at eierent 98 as identified in Figure 4.2-1.

The fatigue darage factor (D ) was found to be 0.0159 for 40 worst case duty cycles. The equivalent strain range was found to be critical and occurred between cu"JlatiVe iteration 35 and 63 temerature distributions during the E-aa transient with a value of 0.0041 in/in. The peak retal tercerature over the fatigue cycle was 911 F. The fatigue life for the equivalent strain range was 2505 cycles based on the E0L fluence (E>0.1 Fev, (4t) = 0.31 x 10 22 n/cr ).

C -6 for the 40 worst The creep damage factor (D ) was found to be 0.668 x 10 case duty cycles. The principal stress was found to be critical with a value of 12,579 psi corresponding to the steady state te perature condi-

~

tions at the beginning of the 10 day hold tire. For the EOL fluence (E>0.1 Mev, (;t) = 0.31 x 10 22 n/cr.2) at a retal te perature of 752*F, the 10 rinirum rupture tire was 1.43 x 10 hours .

In this arrangerent, the raxirun cc-tined creep-fatigue darage factor (FCFD) rax for tne F/A shield block was found to be do-inated by fatigue da age while creep da age was negligible.

= 0.0:59 (FCFD)7,x As (FCFO) rax = 0.0159 < l.0, tne F/A shield block is not expected to experience crack initiation over the 40 worst case duty cycles based on the creep-fatigue carage criterion.

4

. 4.3.2 Excessive Defomation The F/A shield block structural evaluation of peak plus accumulated, and

~

residual deformations in relation to functional limits over the 40 worst case duty cycles is presented in the following subsections.

4.3.2.1 Peak Plus Accumulated Deformations The peak plus accumulated deformation criterion in protecting against excessive peak defomations requires that peak plus accumulated deformations (6P+A) be less than the peak plus accumulated deformation limit (PADL).

P 6 +A 1 PADL Thepeakdeformation(5 ) of the F/A shield block during the worst case duty cycle at BOL was found to occur in the flow passage holes at the cumulative iteration 63 temperature distribution of the E-4a transient with a value of 0.00086 in. The initial time independent and final time dependent steady state non-uniform deformations were both found to be 0.00035 in. Accordingly, the accumulated deformation (a6ss)

- between the initial and final steady state conditions for one duty cycle at BOL was 0.0 in. For 40 worst case duty cycles, the E0L peak + accumulated (6P+A) deformation.

(6P+A)E0L = (6 )BOL + (N-1) (a6ss)BOL (6P+A)E0L = 0.00087 + 39 (0.0)

(c )E0L = 0.00087 in.

For the F/A shield block, the peak plus accumulated deformation limit (PADL),

PADL = 0.005 in.

A As 6 1 PADL, the F/A shield block is not expected to experience excessive peak deformation during the 40 worst case duty cycles.

4.3.2.2 Residual Deformations ,

The residual deformation limit in protecting against excessive residual defonnations requires that the residual deformation (6 ) be less than the residual deformation limit (RDL).

R 6 3RDL The residual deformation (6 ) between initial and final uniform conditions for one worst case duty cycle at BOL was found to be 0.00004 in. For 40 duty cycles, the residual deformation (6 ) at E0L is R R (6 )E0L = N(6 )BOL R = 0.0016 in.

For the F/A shield block, the residual deformation limit (RDL) is RDL = 0.005 in.

R As 6 1 RDL, the F/A shield block is not expected to experience excessive residual deformation during the 40 worst case duty cycles. ,

4.3.3 Summary The F/A shield block was found to satisfy the crack initiation and -

excessive defonnaticn criteria for a total of 43 worst case duty cycles.

A sunnary of the F/A shield block structural eval.uation is presented in Table 4.3-2.

TABLE 4.3-2 F/A SHIELD BLOCK STRUCTURAL EVALUATION

SUMMARY

Allowable Calculated Margin of Safety

Criteria Value Value Crack Ductile Initiation Rupture 1 0.263 2.80 Factor Combined Creep-Fatigue 1 0.0159 61.62 ,

Damage Factor Excessive Peak +

Deforma- Accumulated 0.005 in. .0.00087 4.75 tion Residual 0.005 in. 0.0016 in 2.13

Margin of Safety = Allowable Value Calculated Value _)

9 5.0 CMP HEX DUCT ANALYSIS AND EVALUATION

~

In the F/A CMP hax duct analysis and evaluation, a loading analysis was made that considered mechanical seismic and core restraint, and thermal steady state and transient loads in order to establish the number and '

characteristics of a worst case duty cycle that umbrellas all expected y duty cycles for the CMP hex duct in the first and second reactor ,

cycles. Next, an inelast c# structural analysis of the CMP hex duct was made for a single worst case BOL duty cycle from which E0L values were approximated. Finally, a structural evaluation of E0L strains and dimensional changes in relation to criteria which protect against crack initiation and excessive defomation was made. A sunnary of the loading and structural analysis, and structural evaluation is presented as follows.

5.1 Loading Analysis The F/A CMP hex duct loading analysis was directed to establishing the number and characteristics of a worst case duty cycle that umbrellas both the number and characteristics of the Upset, Energency, and Faulted Events specified over the first and second reactor cycles. The number and characteristics of these events are specified in tie Equip-ment Specificat:en [1].

It is important to note that the worst case F/A CMP hex duct duty cycle is, in itself, hypothetical, but permits a conservative structural evaluation to be perforced on a single duty cycle instead of on each of the individual events specified. In the follcling, the F/A CMP hex duct nechanical and themal loads are assessed individually and in relation to each other prior to establishing the worst case duty cycle used in the structural evaluation.

5.1.1 Mechanical The F/A CMP hex duct mechanical loads of significance in relation to subsequent structural evaluations are the beam type bending loads induced by OBE and SSE seismic, and core restraint. Deadweight and internal pressure loadings are relatively insignificant. -

Other mechanical loads postulated for the F/A CMP hex duct assume that the effects of irradiation creep and swelling are sufficient to exhaust the nominal clearances between adjacent hex ducts at the CMP so as to permit local inter-duct contact during OBE and SSE seismic events and due to core restraint under steady state operation. However, the potential for CMP inter-duct contact under seismic and core restraint loadings was assessed and found not to occur for the E0L fluence (E>0.1), (4t)= 9.29 x 22 2 10 N/cm ) identified for the F/A CMP.

Accordingly, mechanical loads for the worst case F/A CMP hex duct duty cycle considered only the beam type bending loads induced by 0BE and SSE seismic, and core restraint as local inter-duct contact loads do not occur and deadweight and internal pressure loads are relatively insignificant.

5.1.1.1 Beam Bending In order to perfonn a structural evaluation of the F/A CMP hex duct, the maximum bending stresses and strains under lateral OBE and SSE seismic, and core restraint sre required. The OBE and SSE seismic bending moments (M) were taken as the static l-g moment (Ms) amplified by the respective acceleration (a) of the core barrel, while the core restraint moment (Mcr) corresponding to steady state operation was taken directly.

a

" 0BE E"s 0BE "SSE b"s] a SSE M

cr "cr With regard to core restraint behavior during the Upset, Emergency, and Faulted thennal transients, the temperatures of the F/A and adjacent C/A, RB/A and RRS/A hex ducts were assumed to follow the overall core temperatures, but the temperature differences across the F/A which cause t

I o

l i

transient the core restraint bending moments were not assumed to change ,

from steady state values. Alternately, the steady state temperature

difference across the F/A hex duct cross-section at any point along its length was assumed to be the same during the thermal transients . !

' even though overall temperatures increased or decreased according to j the characteristics of the transients. In this arrangement, the transient bending moments (MTR) were assumed equal to the steady state core

, restraint moments (MCR}*

NTR " "CR For the F/A CMP hex duct the cross-section modulus (1) and Young's Modulus (E), the maximum bending stresses (c) and strains (c) are given by the following relations:

o = M/I and c = c/E 3

Numerically, the F/A CMP hex duct section modulus (Z) is 2.250 in . The Young's Modulus (E) for the F/A CMP hex duct constructed from first core 20% CW-316-SS a.1d operating at a steady state temperature of 900 F is 23.31 x 106 psi. The F/A CMP hex duct maximum stresses (e) and -

[

l strains (c) under OBE and SSE seismic, core restraint and transient i bending moments are summarized in Table 5.1-1. l t

I I

I J

i 9

I 3

1 o

s e v . e- t

~

l i

1 l TABLE 5.1-1

! F/A CMP HEX DUCT OBE AND SSE SEISMIC, AND CORE RESTRAINT '

BENDING M0MENTS, STRESSES, AND STRAINS Max. Max.

Core Barrel Bending Bending Bending Loading Acceleration Moment Stress Strain (a) (M S in-lb) (o S PSI) (c s in/in)

, Static Dynamic

, co i OBE 1.57 1351 2121 943 4.05E-5 Seismic i

SSE 2.2 1351 2972 1321 5.67E-5 Core Restraint N/A 26213 N/A 11650 5.00E-4 Transients N/A 26213 N/A 11650 b.00E-4 L

l

3.l.2 s he rral The F/A CMP hax da:t therral loads are the steady state and transient -

tercerature distributicns that occur during the U: set, Erergency, ard Faulted Events over the first and second reactor cycles. The steady state F/A CMP hex duct inside retal te cerature distributiens throughcut .

Sector A of the core at EO: 1, E00 1, 500 2, and ECC 2 and tre U; set, Erergency, and Faulted Transients defined in terns of tire-deperdent scale factors applied to the steady state inside retal te-ceratures were consicered. In this arrangement, the FfA CMP hex cu:: therral loads in terns et inside retal terceratures asse:iate, wito zus e , tc v. 1, .20. 2 ,

and EOC 2 steady state as well as U: set, Energen:y, and Faulted Transients were identified at any F/A locatico in the core.

In crder to proceed with a structural evaluation of the F/A C.V? hex duct, it was desirable for tne sake cf sircticity to consider Only the worst case therrai leading. Accordingly, all F/A Iccated in Sector A cf the core were assessec in relaticn tc the raxi ;- inside retal wall tercerature difference bet sen a F/A and adjacent C/A cr RE/A. The raxirc steady inside retal wall tercerature difference was fcund : eccur atF/AAf2 adacenttoC/Ak.7 1during DO: 1 witn a value of 126:F. It is

~

ir;crtant to note that at EOC 1, 500 2, and EOC 2, the res;ective in-ide netal teeperature differences were found to de:rease frec ECC 1 values.

As such, the ECC 1 raxirur steady state inside retal ter:erature difference of 125 F te: ween a F/A and adjacent C/A was clearly worst case for all F/A CMP aex ducts in tr.e core over the first and seccnd reactor cycles.

With regard to F/A and adjacent C/A CWP nex duct therral transients, the Equip ent 5:ecification [1] using an -crella 2;;rcach identified tne n; cer of U: set, Erergency, and Faulted transients ever the first and se:Ond rea:: cycles as 1/15 of tre n -ter s:e:ified for 30 years rounced to the next whole nu cer. C<er tre first anc se:Ord reactor cycles co crising a totai c' 225 FF0, a ::tal of 39 U; set Transients umbrellaed by the vorst of U-2b cr C5E were s ecified. Similarly, the

l 4

worst of the E-16, 60c Step, or U-2b during OBE were specified to umbrella the Emergency Transients while the SSE was identified to umbrella the Faulted Transients.

In the derivation of the F/A and adjacent C/A inside metal temperature transients for the Upset, Emergency, and Faulted transients, the upper and lower bounds for the Upset U-2b and OBE events and the Emergency 60c step event were considered. The upper bounds were based on quickest flow decay and maximum decay heat while the lower bounds were based on slowest flow decay and minimum decay heat. Further, the SSE Faulted Transient was found to be umbrellaed by the Emergency E-16 transient. The

Upset transients comprising the upper and lower bound U-2b and OBE, and j the Emergency Transients including the upper and lower bound 60c step, 7

E-16, and U-2b during 0BE were identified from current data.

In order to reduce the number of F/A CMP hex duct transients which

] umbrella the Upset and Emergency Transients to a single worst case transient, the individual transients were assessed for severity in subsequent structural evaluations by comparing the inside metal wall '

. temperatures in tems of maximum value, rate of temperature change, and i range. With regard to steady state conditions, all transients were initiated with F/A and C/A inside metal wall temperatures of 874 and 748'F

= which provide the worst case temperature difference of 126'F. For the Upset Transients at the F/A CMP hex duct inside metal surface, the upper and lower bound U-2b transients were assessed as slightly more severe in terms of maximum temperature with maximum rate and range of temperature indistinguishable from the upper and lower bound OBE transient.

However, the adjacent C/A inside metal temperature transients for the lower bound U-2b were observed to more closely follow the F/A metal transient than in the case of the upper bound U-2b. Owing to the thermal ;

lag in the thin walled F/A CMP hex duct, temperature differences thrcugh the wall, which are important in structural evaluations, are slightly more severe in the lower bound U-2b transient than the upper bound ounterpart.

With regard to the Emergency Transients, the E-16 transient in terms of

. -8S-

P j

maximum value, rate of temperature change, and range was found to be clearly more severe than the upper and lower bound 60d step, and the U-2b _

i during OBE transients. Further, the E-16 was also considered more severe than the lower bound U-2b transient. In this arrangement, the Emergency .

E-16 transient was selected as the worst case Jmbrella to all of the .

r Upset, Emergency, and Faulted transients for the F/A CMP hex duct and is illustrated in Figure 5.1-1.

The selection of the Emergency E-16 transient as the worst case F/A CMP hex duct transient is, in itself, not sufficient to establish the worst ,

case F/A CMP hex duct duty cycle. Thermal conditions following the E-16 j transient and subsequent hold-times at steady state conditions are alos required. The thermal conditions selected consisted of a cool-down to I

600*F in 1 hour1.157407e-5 days 2.777778e-4 hours 1.653439e-6 weeks 3.805e-7 months from the F/A and C/A inside metal wall temperature at ,

L

450 seconds into the E-16 transient, followed by a 1 hour1.157407e-5 days 2.777778e-4 hours 1.653439e-6 weeks 3.805e-7 months heat-up to l I initial steady state F/A and C/A temperatures. Thereafter, a 10 day

! hold-time at steady state temperatures was P.ssumed. The 10 day hold time l

corresponds to 40 worst case E-16 transients uniformly distributed over 400 FPD which is slightly greater than the 328 FPD specified for the l first and second reactor cycles. The worst case F/A CMP hex duct duty '

l cycle is presented in Figure 5.1-2. l The worst case F/A CMP hex duct duty cycle in terms of inside metal -

temperatures at initial steady state, followed by the E-16 transient,

]

thermal conditions in returning to initial steady condition, and 10 day :

hold-time are not sufficiently detailed for subsequent structural evalua-tion. i s the following, the F/A CMP hex duct thermal model and geometry, boundary conditions and wetted sodium surfaces, heat generation rates, and tnermal analysis and results are described from which conclusions on detailed temperature distributions used in subsequent structural analysis are presented.

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5.1.2.1 Model and Geometry l The F/A CMP hex duct model was formulated in the ANSYS finite element I

program. The ANSYS program was selected because of the compatibility i

between thermal and structural elements which permits thermal solutions of temperature distri'uutions to be used directly in subsequent structural analysis.

The F/A CMP hex duct region selected for analysis corresponds to a 2 dimensional 90 sector of the full CMP cross-section. As the worst case F/A CMP steady state and transient temperatures include adjacent C/A inside metal wall temperatures, an effective film coefficient was used to simulate the thermal resistance of the C/A wall. The effective C/A film coefficient (h) was taken as the thermal conductivity (K) divided by the wall thickness (L) according to the relation, b = K/L. The effective film coefficient of the sodium in the CMP interstice gap in relation to the CMP hex duct itself was not found to be significant. The F/A CMP hex duct thermal model illustrating the dimensional extent and finite element detail is presented in Figure 5.1-3.

The F/A CMP hex duct 90 sector thermal model as formulated in the ANSYS program included a total of 354 linear temperature (STIF 35) elements in a mesh of 406 node points. A relatively fine mesh was selected in the corner adjacent to the global X-axis so as to include the thermal skin response to the thermal transients. Otherwise, a relatively coarse mesh was used throughout the 90 sector of the CMP cross-section.

I D

i

RB/A h

0.120 Sodium Interstice U-n

(

\

0.16 R C/A 4.575 Flat to Flat C/A CMP Wall Simulated -

By Effective F/A Film Coefficient (h)

\,

Figure 5.1-3

[1 F/A CMP Hex Duct Thermal Model Dimensional Extent and Finite Element Detail L

. _ _ . . - - . _ - - . = - .-

5.1.2.2 Properties The F/A CMP hex duct is constructed from first core 20% CW-316-SS. The thermal conductivity (K), specific heat (C), and density (p) of 20% CW-316-SS

. are known to not significantly differ from SA-316-SS values. Accordingly, the first core 20% 316-SS properties used in the F/A CMP hex duct thermal analysis were identical to the SA-316-SS properties identified for the F/A shield block described in Section 4.1.2.2.

5.1.2.3 Boundary Conditions and Wetted Surfaces The F/A CHP hex duct boundary conditions and wetted surfaces selected in the thermal analysis are illustrated in Figure 5.1-4.

Boundary conditions for the thermal analysis consisted of adiabatic conditions along the lateral surfaces coincident with the Global X and Y axes of the 90 sector model. In simulating the thermal resistance of the C/A CMP hex duct wall, the effective film coefficient (h=0.00164 BTU /in2 -sec 'F) was based on a thermal conductivity (K=0.000197 BTU /in-sec- F) and wall thickness (L=0.12 in). The effective film coefficient (h) was specified at the free surfaces of all elements forming the exterior of the F/A CMP hex duct which included elements 10 through 58, increments of 12; 254 through 262, increments of 8; and 266 through 354, increments of 4.

The wetted interior F/A CMP surfaces were assumed to respond immediately to the inside me'st wall temperatures of the worst case F/A CMP duty cycle.

Local variations in wetted interior surface temperatures were neglected.

Instead, all F/A CMP hex duct interior surface node temperatures were globally coupled to each other and included Nodes 1 through 61, increments of 12; 73 through 280, increments of 9; and 287 through 402, increments of 5.

With regard to the wetted interior C/A CMP surfaces which are exposed to inside metal wall temperatures, local temperature variations were also neglected and a global variation assumed in the form of a Bulk Temperature.

The bulk temperatures were specified in accordance with C/A inside metal C/A Bulk Temperature d

~

l } } I I I I If

/

f - 4 C/A & RB/A Effective Film Coefficients Elements

' Adiabatic 10 + 58, inc. cf 12 Surface 254 + 262, inc. of 8 266 + 354, inc. of 4 L

e--- h = 0. 00164 Interior emperature Wetted Surface Nodes 1 + 61, inc. of 12 73 + 280, inc. of 9 287 + 402, inc. of 5 f-Node Node 1 /9 -

W$5?hN$

Adiabatic Surface Figure 5.1-4 F/A CMP Hex Duct Boundary Conditions and Wetted Surfaces .

~

Surface temperature variations of the worst case F/A CMP hex duty cycle and applied to the F/A through the effective C/A wall fi.1m coefficients.

5.1.2.4 Heat Generation Rates During steady state operation, the F/A CMP hex auct is exposed to nuclear heating. The expected maximum and average CMP heating rates were 58 and 45 watts /cc respectively~. The steady state F/A CMP metal temperatures include the average heating rate over the core region. Accordingly, only the difference between the maximum and average heating rates of 3

13 watts /cc or 0.20 BTU /in -sec should be considered in the derivation of detailed CMP hex duct temperatures.

For the F/A CMP hex duct exposed to a heat generation rate (Q) with thermal conductivity (K) and wall dimension (L), the temperature difference (AT) is given by:

= 2 AT QL /2K AT = 3 0.20 BTU /in -sec) (0.12 in)2 2(2.87 x 10-4 BTU /in-sec- F)

AT = 5.01 F For the F/A CMP hex duct, the steady state temperature difference (ATss) caused by sodium flow was 126"F. As aT < < ATss, the steady state tempera-ture is insignificant, and heat generation rates were neglected in the thermal analysis 5.1.2.5 Analysis and Results The ANSYS ther-al analysis of the F/A C"? hex duct was arranged to Oro-vide detailed ter:erature distridutiens ever the :::al wcrst case duty cycle. A total of 10 lead ste:s were selected at Orceiren: F/A and C/A inside retal surface te ceratures. Tre firs: 7 Load Steps c.aracterized the initial steady state ccnditiens and ne E-16 transient to '50 seccnds.

Load Steps 1 and 2 re:resen; initial steacy state centiticns while Lead Steps 3 thrcug 7 ccrres;cnd :: :ne E-15 trar.sier,:. Lea:! Ste? 5 ccrres:ce.ds to the I haur cc-cl-dear. to 600'F. The return to fir.al steady state temeratures witn :ne i h:ur heat-up .as acco clished in Load Stes 9. The final steady state te ceratures rele fcr 10 days .ere cdtained in Load Step 10. Pronirent Lead Stecs ir, :ne E-16 transient are illustrated in Figure 5.1-5 and nu erical values fer ce full .orst case F/A C"? hex duct duty cycle are presented in Ta:1e 5.1-2.

t a,

1.--

W:5T CASE F/A CM :"EI DJ'T DJTT CYCLE ANSYS I W T CATA

> . ~

l ,

+

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The ANSYS solution of the worst case F/A CMP hex duct duty cycle was obtained in 47 cumulative iterations using a static and transient convergence -

criteria of 1 and 5*F, respectively. The temperature distributions at each cumulative iteration were saved on ANSYS Tape 4 for recall in subsequent structural analysis. In order to determine the cumulative iterations of interest in structural analysis, maximum and minimum through the wall temperature differences are most important in relation to structural damage.

The F/A CMP hex duct temperature differences based on the through-the-wall temperatures at nodes 1 and 9 depicted in Figure 5.1-4 are illustrated in Figure 6.1-6.

A review of the through-the-wall temperature differences shows that the maximum and minimum values occur at cumulative iterations 27 and 37 respectively, with a range of 95*F. In the thermal solution run, cumula-tive iteration corresponds to the E-16 transient Figure 5.1-1. The initial steady state condition corresponds to cumulative iteration 2 with a temperature difference of 80*F. Plots of the temperature distribu-tions throughout the F/A CMP hex duct thermal model at cumulative iterations 2 and 27 are presented in Figure 5.1-7.

1 O

l i

)

1 Cumulative Iteration 27 100 -

H 80 -

.S.

S.S.

o' RCumulative ,

Iteration 60 m 41 7

~ Maximum 8 Range g -

(95'F) g 40 t

E "

e 5

%s.

g 20 -

Pu r

Cumulative Iteration 14 0 - I ' I i 1 L i - "i 10 20 30 40 50 Cumulative Iteration Cumulative Iteration 37

-20 -

2 Figure 5.1-6

. F/A CMP Hex Duct E-16 Transient Temperature Difference vs. Cumulative Iteration

-100-

r -a.,m a!ns%!n . -

Cumulative Iteration 2 ,

f 04 F 874 F '

- =: ; _

Cumulative Iteration 27 N .

Figure 5.1-7 F/A CMP Hex Duct l E-16 Transient Cumulative Iterations 2 and 27 Temperature Distributions

-1 01-

l 5.1.3 Worst Case Duty Cycle The conclusions based on the F/A CMP hex duct loading analysis in relation to establishing the worst case duty cycle with recommendations for subsequent structural analysis were as follows.

e Mechanical loads comprising OtsE and SSE beam bending, internal pressure, and deadweight were considered insignificant. Local inter-duct contact loads are non-existent. Only beam bending loads caused by core restraint under steady state operation were considered to be of significance in establishing the worst case F/A CMP hex duct duty cycle.

e Thermal loads associated with the E-16 transient in combination with the thermal conditions in returning to steady state and the hold-time prior to the initiation of the next E-16 transient were considered most important in establishing the worst case F/A CMP hex duct duty cycle.

The recommendations for the specific F/A CMP hex duct loading in relation

- to the worst case duty cycle were arranged into combined mechanical and thermal time independent and dependent loadings. The following sequence for the worst case F/A CMP hex duct cycle was recommended to be repeated

. 39 times so as provide an upper bound to the 39 specified Upset events, and the worst Emergency or Faulted event.

Time Independent 4 Select a uniform temperature equal to the reference temperature at cumulative iteration 2. Load to the cumulative iteration 2 temperature distribution and apply the steady state core restraint bending moment. Unload to uniform temperature.

O Select a uniform temperature equal to the reference temperature at cumulative iteration 27. Load to the cumulative iteration 27 temp-erature distribution and apply the transient bending moment. Un-

- load to unifonn temperature.

-102-l

O Select a uniform temperature equal to the reference temperature at cumulative iteration 2. Load to the cumulative iteration 2 temperature distribution and apply the steady state core restraint bending moment. ,

Time Dependent 0 Hold the cumulative iteration 2 temperature distribution in com-bination with the steady state core restraint bending moment for 10 days.

O i

i i

-103-i

___ - -=

5.2 Structural Analysis The F/A CMP hex duct structural analysis was directed to deriving the stresses, strains and dimensional changes which occur during the worst case duty cycle from which structural evaluations were made. In the following, the F/A CMP hex duct structural model, geometry, and boundary conditions are described. Next, linear and non-linear material properties including the effects of irradiation on stress-strain curves and simplifications made in the themal creep equations are presented.

Further, reference temperature selection for themal expansions in relation to axial constraints is described. Finally, the time inde-pendent and dependent inelastic analysis and results for the F/A CMP hex duct are presented in preparation for subsequent structural evaluation.

5.2.1 Model, Geometry and Boundary Conditions The F/A CMP hex duct model was formulated in the ANSYS finite element program so as to be compatible with the temperature distributions of the themal model. The F/A CMP geometry was taken to be identical i to that used for the thermal analysis, except that the film coefficients simulating the C/A CMP wall thermal resistance were deleted.

In formulating the F/A CMP hex duct structural model, the ANSYS constant strain (STIF 2) structural element was used to replace the linear temperature (STIF 35) thermal element. The boundary conditions along the lateral surfaces of the 90 sector coincident with the global X and Y axes, in the manner of the conventional roller support, were taken j to have zero nomally disposed displacements, but free to move laterally.

! Along the surface conincident with the global X axis, the UY displace-ments at nodes 1 through 9 were set equal to zero. For the surface coincident with the global Y axis, the UX displacements at nodes 402 through 406 were set equal to zero. The F/A CMP hex duct structural

, model is illustrated in Figure 5.2-1.

-104-

l f

.t i .

l A

V

/N Element

- Roller Supports

( UX402 + 406 = 0.0)

Roller Supports El ent (UY jg = 0. 0)

Element -

JNT w

//// //

Figure 5.2-1 F/A CMP Hex Duct Structural Model, Geometry, and Boundary Conditions

-105- .

5.2.2 Properties 2

The F/A CMP hex duct as constructed from first core 20% CW-316-SS and initially unirradiated at BOL is irradiated to a fluence (E > 0.1 Mev,

. (4t) = 9.29 x N/CM ) at EOL. The linear and non-linear properties of first core 20% CW-316-SS under fluence and temperature with simplifications used in the F/A CMP hex duct analysis are desc ibed as follows.

5.2.2.1 Linear The linear 20% CW-316-SS properties including the Young's Modulus (E), Poisson's ratio (u), and coefficient of thermal expansion (u) are known to not significantly differ from SA-316-SS values. Accordingly, the first core 20% CW-316-SS properties used in the F/A CMP hex structural analysis were identical to the SA-316-SS properties 2

identified for the F/A shield block described in Section 4.2.2.1.

5.2.2.2 Non-Linear The non-linear first core 20% CW-316-SS material property

( . behavior required in the F/A CMP hex duct structural analysis are the time independent stress-strain curves and the time dependent thermal creep equations.

5.2.2.2.1 Stress-Strain Curves Currently, stress-strain properties of first core 20 percent CW-316-SS are not extensively known as prior experimental effort has been primarily directed to N-Lot steel. The available stress-strain

properties of first core steel [11] are limited to fluence (E > 0.1 Mev) to 3 x 1022 N/Oi 2over a temperature range from 1000 to 1200 F. As 22 2 the CMP hex duct E0L fluence (E > 0.1 Mev) is 9.29 x 10 N/CH , the l available data requires extrapolation in order to obtain first core l 20% CW-316-SS stress-strain data for use in the F/A CMP hex duct analysis.

I

-106-i

In the F/A CMP hex duct analysis, the first core 20% CW-316-SS -

stress-strain data of importance are the proportional elastic limit stresses as time independent mechanical and thermal loadings are relatively low and elastic analysis was justified. .

The available first core 20% CW-316-SS true minimum proportional elastic limit stress ( PEL) was taken as 86 percent of the minimum engineering yield stress ( Y, MIN}

t

= 0.86 Y, MIN PEL The minimum engineering yield stress (oy s KSI) data identified in Reference [11] was fit to a polynomial in temperature (T S F x 10-2) according to the relation:

2 cy, MIN = 60.596 - 0.817

T - 0.0601

T Numerical values of the true minimum proportional elastic limit stress (oPEL) as a function of temperature are summarized in Table 5.2-1.

Table 5.2-1 F/A CMP Hex Duct Minimum Yield and Proportional Elastic Limit Stress ,

First Core 20% CW-316-SS Temp oy, MIN o PEL

( F1 (KSI) (KSI) 800 50.21 43.18 850 49.31 42.41 900 48.37 41.60 950 47.41 40.77 1000 45.42 39.06

-107-

, 5.2.2.2.2 Thermal Creep Equations The steady state F/A CMP hex duct temperatures cover the temperature range of 800 to 875'F. Calculations for these conditions with the unirradiated 20% CW-316-SS thermal creep equations for thermal creep of N-lot (interim NSMH equations [12]) and first core [24] lots indicate that thermal creep was negligible. Accordingly, thermal creep during time dependent mechanical and thermal loadings was neglected for the F/A CMD hex duct.

M

~

-108-

5.2.3 Worst Case Duty Cycle Response The structural response of the F/A CMP hex duct to the worst case duty cycle loading comprised of combined mechanical and thermal loadings required an analytical approach different from that used for the F/A ~

shield block and outlet nozzle where thermal loadings alone formed the basis for the respective duty cycles. The structural response associated with the time independent and time dependent thermal loadings were derived independently of the mechanical loading respor.se and combined by super-position. Superposition of thermal and mechanical structural response, in terms of stresses and strains, was justified because the F/A CMP hex duct remained linear elastic throughout the worst case duty cycles. The 4

superposition of mechanical stresses and strains is described in the F/A CMP hex duct structural evaluation. In the following, the analysis and thermal structural response solutions for the F/A CMP hex duct are presenthd.

t 5.2.3.1 Constraints and Reference Temperature Selection The F/A CMP hex duct corresponds to a 90 sector of a lateral slice taken through the length of the hex du',t at CMP. For through the wall thermal loadings, axial constraints normal to the 2 dimensional 90 sector closely simulate a plane strain condition as the length of the hex duct is significantly greater than corresponding cross-sectional dimensions.

Accordingly, the F/A CMP hex duct was considered to be in a plane strain condition for the purposes of deriving the structural response to thermal loadings.

The method of selecting a reference temperature in relation to an arbitrary temperature distribution imposed on an ANSYS plane strain model was described for the F/A shield block in Section 4.2.3.1. Using the same method for the F/A CMP hex duct, the r2ference temperatures for the cecommended cumulative iterations in the worst case duty cycle are su marized in Table 5.2-2.

-109-

l TABLE 5.2-2 F/A CMP Hex Duct

. REFERENCE TEMPERATURES Temperature Reference ,

Distribution Temperature (Cum. Iter.) ( F) 2 836.6 27 872.5 5.2.3.2 Analysis and Results The ANSYS elastic analysis of the F/A CMP hex duct structural model under the worst case thermal duty cycle was arranged into a time independent analysis of the short term E-16 transient followed by a time dependent analysis at steady state temperatures over the 10 day hold-time. In order to obtain the thermal structural response in an efficient manner, the ANSYS restart option was used to follow the loading sequence within,

between, and after the time independent and dependent loadings. As elastic or creep instability would not be expected for the F/A CMP hex duct under the deformation controlled thermal loadings, the ANSYS small-strain small deformation option was used in the elastic analysis. Descriptions of the time independent and dependent analysis and results are as follows.

e

-110-

5.2.3.2.1 Time Independent The time independent ANSYS analysis of the F/A CMP hex duct was directed to deriving the peak elastic strains and deformations associated with the thermal loadings from initial steady state through the E-16 transient followed by a return to final steady state, but excluding the 10 day hold-time. The time independent loadings were considered as static loads applied at zero time. A total of 8 secuential ANSYS Load Steps in combination with the restart option were used to obtain the time independent structural response of the F/A CMP hex duct, a summary of which is presented in Table 5.2-3.

TABLE 5.2-3 F/A CMP HEX DUCT TIME INDEPENDENT ANALYSIS

SUMMARY

INITIAL STEADY STATE, E-16 TRANSIENT, AND FINAL STEADY STATE Temperature Reference Load Iterations Distribution Temperature Description Step ( F) ( F) -

1 1 836.6 836.6 Initial 2 1 Cum. Iter. 2 836.6 Steady State 3 1 836.6 836.6 (0.0 SEC.)

4 1 872.5 872.5 E-16 ;

Transient 5 1 Cum. Iter. 27 872.5 (100 SEC.)

6 1 872.5 872.5 7 1 836.6 836.6 Final 8 1 Cum. Iter. 2 836.6 Steady State (7650 SEC.)

-111-

l l

The F/A CMP hex duct structural response to the time independent loadings l in terns of elastic stresses and strains were saved on ANSYS Tape 10 for subsequent recall in structural evaluations. The initial and final time o

independent steady state maximum equivalent stress was found to be 13,128 psi. During the E-16 transient, the maximum equivalent stress at cumula-tive iteration 27 was 17,179 psi. The peak non-uniform deformation was found to occur at cumulative iteration 27 with a value of 0.00026 in.,

while the maximum initial and final steady state non-uniform deformations were 0.00017 in. Computer plots of time independent equivalent stress and deformations are presented in Figures 5.2-2 and -3.

I b

l

. -112-

l l

\ ~

l i

~

l Initial and Final l Steady State l

l l

13,128 PSI i

Cumulative Iteration r 27 l

i I

17,179 PSI ::

Figure 5.2-2 F/A CMP Hex Duct Steady State and Cumulative Iteration 27 .

Equivalent Stress .

Time Independent -

l

-113-

-*-=w-,----, , - . ,-. _ _ _ _

- U 0.00017 in. 5 1 :

9 __

_ _ _ _ _...;- \\

\

Initial and Final \~

Steady State

\

\ ,

E 0.00026 in. 5 I t ;_______...,

\

- \ ,

\

. Cumulative g\

Iteration \s 37

\g

\

Figure 5.2-3 F/A CMP Hex Duct Steady State and Cumult.tive Iteration 27 Non-Uniform Deformations

~

Time Independent i

-114-

. _ _ __, _ _ __ _ =_ _ __

1 1

1 5.2.3.2.2 Time Dependent l

The time dependent ANSYS analysis of the F/A CMP hex duct was directed to deriving the final time dependent steady state structural response associated with the 10 day hold-time at final time independent steady state conditions. ,

I The time dependent analysis was performed with Load Step 9 using an ANSYS restart from Load Step 8 of the time independent analysis at the cumulative i iteration 2 temperature distribution and maintained for 10 days or 240 hours0.00278 days 0.0667 hours 3.968254e-4 weeks 9.132e-5 months .

As thermal creep was neglected in the time dependent analysis, a redistribution of the time independent stresses would not occur. Accordingly, only one iteration at a creep time step of 240 hours0.00278 days 0.0667 hours 3.968254e-4 weeks 9.132e-5 months was used in Load Step 9.

The F/A CMP hex duct structural response for the time dependent loading .

l was identical to the time independent final steady state response as thermal creep was neglected. Accordingly, the final time dependent steady state maximum equivalent stress and non-uniform deformations are identical to the final time dependent values illustrated in Figures 5.2-2 and -3.

With regard to the residual non-uniform deformations of the F/A CMP hex i

duct, none would occur because the F/A CMP hex duct remains linear elastic over the worst case duty cycle.

1 l .

i t

l i

l

-115-

--- - ew.. - -- - - , - - - - .~, - -

5.3 Structural Evaluations The F/A CMP hex duct structural evaluation was arranged to provide a comparison of the structural response for thL 39 worst case duty cycles

- in relation to criteria which protect against crack initiation and excessive deformation failure modes and thereby assure F/A CMP hex duct function over the first and second reactor cycles.

The procedure for performing the F/A CMP hex duct structural evaluations in relation to crack initiation and excessive deformation criteria was identical to that used for.the F/A shield block theml stresses and strains presented in Section 4.3, except as modified to superpose the time independent transient and time dependent core restraint mechanical bending stresses and strains. A linear superposition of the thermal and mechanical bending stresses and strains i; justified, as combined stresses are less than the proportional elastic limit stresses identified for first core 20% CW-316-SS in Table 5.2-1.

In order to perform a true superposition of mechanical bending stresses and strains with the thermal stresses and strains in the 90 sector of the F/A CMP hex duct, a linear variation of mechanical bending stress and strain about the neutral axis of the CMP hex duct would be sumed algebraically with the local thermal stresses and strains. However, a true superposition was not made. Instead, a simpler, yet conservative, approach was adopted which consisted of superposing the peak outer fiber mechanical bending stresses and strains uniformly over the full cross-section of the F/A CMP hex duct 90 sector. In essence, the. full F/A CMP hex duct cross-section was placed in a uniaxial stras and strain state equal to the peak outer fiber bending values. By using both positive and negative peak outer fiber bending values, the true super-position of mechanical and thermal stresses and strains was conservatively bracketed between tensile and compressive values. The peak bending stresses and strains for the mechanical transient and core restraint

-4 bending moments used in the superposition were 11,650 psi and 5 x 10 in/in

as identified in Table 5.1-1.

-116-

The superposition of peak outer fiber rechanical and therral stresses and strains was cade in conjunction the structural evaluation of crack ,

initiation fat' .e nodes using the darage processor. Local ductile rupture and crbined creep-fatigue darage factors were computed for each element in the F/A CMP hex duct model for 3 sets of mechanical bending ,

-4 in/in),

strt ' strain values, that is, (+ 11,650 PSI, + 5 x 10

(- 11.6d0 PS1, - 5 x 10 -4 in/in), and (O PSI, 0 in/in). Of these sets of mechanical bending stresses and strains, the worst combination with the local ther al stress and strain state in terms of raximum local ductile rupture and combined creep-fatigue danage factors were used in cocparison with allowable limits.

A sumary of the F/A CMP hex duct structural evaluation and sumary of results is presented as follows.

5.3.1 Crack Initiation The F/A CMP hex duct structural evaluation of crack initiation in relation to local ductile rupture and combined creep-fatigue damage criteria over the 39 worst case duty cycles is presented in the folicwing subsections.

5.3.1.1 Local Ductile Ruoture The local ductile rupture criterion in protecting against crack initiation requires that the ductile rupture factor (FDP) be less than unity at .

each point in the F/A CMP hex duct.

r

' ('rax principal) TF F

U

DR L

'f, nin. +

(' (Crax princioal) TF

'u, min.

-11 7-

In the following, the allowable uniaxial strains used in the F/A CMP hex duct structural evaluation and comparison of results with the local ductile rupture factor criterion are presented.

5.3.1.1.1 Allowable Uniaxial Strains The F/A CMP hex duct as constructed from first core 20% CW-316-SS is unirradiated at BOL. The E0L fluence (E>0.1 Mev) is 9.29 x 1022 N/cm2 ,

In addition, the F/A CMP hex duct temperatures range from 600 to 1000 F.

The true minimum uniaxial uniform elongation (cu, min) and fracture (cf, m'n) strains for unirradiated and irradiated first core 20% CW-316-SS as a function of fluence and temperature used in the F/A CMP hex duct structural evaluation are described as follows.

5.3.1.1.1.1 Uniform Elongation Currently, uniform elongation data [11] for first core 20% CW-316-SS is limited to a fluence (E>0.1 Mev, (4t) = 3 x 10 22 N/cm2 ) and a tempera-ture range of 1000 to 1200 F. In order to apply the available first core

, 20% CW-316-SS data to the F/A CMP fluence and temperatures, extrapolations were made. Specifically, the minimum engineering uniform elongation (c u, min s in/in) data was fit to a polynomial in temperature (T S 10-2op)

. according to the relation:

2 3 c u, min = 0.128 + 0.0108 *T + 0.000938

T - 0.00018

T The true minimum uniform elongation (cu, min) used in the F/A CMP hex duct structural evaluation in terms of the minimum engineering uniform elongation (cu, min) were taken as:

'u, min " b (I

u, min) e

-118-l

5.3.1.1.1.2 Fracture

^

Uniaxial fracture strain data for first core 20% CW-316-SS is currently not available for use in the F/A CMP hex duct structural ysluation.

Accordingly, the true uniaxial fracture strain based on unirradiated and .

irradiated SA-304-SS and SA-316-SS recomended by General Electric for 20% CW-316-SS in the trial applications of the RDT Draft for Breeder Reactor Core Components [15-23] identified for the F/A shield block ii Section 4.3.1.1.1 were also used in the structural evaluation of F/A CMP hex duct.

5. 3.1.1. 2 Comparison with Criterion The F/A CMP hex duct structural evaluation in relation to the worst case location for local ductile rupture was made by screening each of the finite elements over the 39 worst case duty cycles with the damage processor.

Individual structural evaluations were made for the 3 sets of bending stresses and strains in order to obtain the worst case superposition.

The maximum F/A CMP hex duct local ductile rupture factor (FDR)maxwas found to occur for the case of tensile superposition at element 10 as identified in Figure 5.2-1.

The peak BOL strain components occurred at the cumulative iteration 27 temperature distribution in the E-16 transient where the local metal '

temperature was 827 F. Accumulated BOL strain components were based on the difference between final time dependent and initial time independent steady state conditions. The E0L maximum principal strain for the peak BOL and accumulated BOL strain components over the 39 worst case F/A CMP hex duct duty cycles was 0.00099 in/in. The triaxiality factor for the local stress state was 1.692. The true minimum irradiated unifonn elongation and fracture strains at E0L fluence (E>0.1 Mev, (4t) = 9.29 22 2 x 10 N/cm ) were 0.166 and 0.0768 in/in respectively.

-119-

4 I

In this arrangement, the maximum local ductile rupture factor (FDR) max for the F/A CMP hex duct was found to be controlled by the fracture strain with a value, (FDR) max = 0.0727 i

As (FDR) max < l.0, the F/A CMP hex duct is not expected to experience i crack initiation over the 39 worst case duty cycles based on the local ductile rupture criterion.

i 5.3.1.2 Creep-Fatigue Damage The creep-fatigue damaca criterion in protecting against crack initiation requires that the combined creep fatigue damage factor (FCFD) be less than unity at each point in the F/A CMP hex duct.

i.7/3Dc+DIh F

CFD

= a/b = Minimum of eDc + 7/3 DIf In the following, the allowable limits for fatigue life and creep-rupture times used in the F/A CMP hex duct structural evaluation and a comparison of results with the combined creep-fatigue damage factor criterion are presented.

~

5.3.1.2.1 Allowable Limits The F/A CMP hext duct as constructed from first core 20% CW-316-SS is 22 2 irradiated to an E0L fluence (E>0.1 Mev) of 9.29 x 10 n/cm . In addition, l the F/A CMP hex duct temperatures range from 600 to 1000 F with the j wetted sodium surfaces subjected to oxidation as well as interstitial ,

transfer of carbon and oxygen. The fatigue life and time to rupture data for first core 20% CW-316-SS including the effects of fluence, temperature, interstitial transfer, and surface oxidation used in the F/A CMP hex duct structural evaluation are described as follows. l l

l

-120-l

5. 3.1.2 .1.1 Fatique Life Currently, fatigue life correlations are not available for irradiated first core 20% CW-316-SS as a function of fluence and temperature.

l Accordingly, the Manson Universal Slopes Method [7] was used to develop ~

I fatigue life correlations from which the fatigue damage factor (D ) for the F/A CMP hex duct over the 39 worst case duty cycles was derived.

In the Manson Universal Slopes Method, the slopes of elastic and plastic strain lines expressed in terms of strain range versus number of cycles on a full logarithmic plot are assumed to be the same for all materials.

As applied to unirradiated 20% CW-316-SS, the total strain range (ac) is dependent on the minimum unirradiated true fracture strain (cf,u), average unirradiated engineering ultimate strength (Su, u), Young's Modulus (E),

and cycles to failure (Nf ) by the relation:

ac = c0.6 N-0.6 +

0.12

,9 f 3.5 Su,u N'f In order to inc!ade the effects of irradiation in the fatigue life relation for SA-316-SS, reduction factors for the elastic (F,) and plastic (Fp )

strain ranges were used in accordance with the guidelines of the RDT Draft for Breeder Reactor Core Components [5].

ac = Fp c N

-0.6 + 3.5 F Su,u N -0.12 .

i f e f E

Where, F,=(h')k 2 F

P

= "f'I I C

f,u l

l cf,7 = True Minimum Irradiated Fracture Strain S

u,!

= Average Irradiated Engineering Ultimate Strength k,k2 = Experimental Constants i

-121-4 e- ,- w . ~ - - c - . - - - - - - - - - - - - - - - - - , - - -- - - - - - ,, - --

l i

i Without available material data, the elastic and plastic exponents (k),

k2) were taken as unity. Accordingly the fatigue life relaxation developed !

for irradiated SA-316-SS was:

-0.4 Ac = c f,I c f,u N

-0.6 + 3.5 Su,I N -0.12 f I E

The development of the irradiated first core 20% CW-316-SS fatigue life relation required the true minimum irradiated and unirradiated fracture strains (cf, y and cf,u), average irradiated engineering ultimate strength (Su, I), and Young's Modulus (e) e The true minimum irradiated and unirradiated fracture strains (cf,7 and cf,u) as a function of temperature and fluence are given in Section 4.3.1.1.2.

e The average irradiated engineering ultimate strength (Su,1) was based on the available first core 20% CW-316-SS data [11]. A polynomial fit to the available data was made for the average engineering ultimate (Su, I s KSI) as a function of temperature (T s F x 10-2),

2 Su,I = 78.92 + 3.68

T - 0.47

T

- e Young's Modulus (E) as a function of temperature is given in Section 4.2.2.1 The irradiated first core 20% CW-316-SS fatigue life relation as developed from the Manson universal slopes method and corrected for the effects of irradiation is strictly applicable only to uniaxial stress states. In order to apply the fatigue life relation to the F/A CMP hex duct, reductions in fatigue life which reflect the multiaxial stress and strain state are required. The RDT Draft for Breeder Reactor Core Components [5] recommends that equivalent strain be used for the strain range in fatigue evaluations of multiaxial stress and strain states. Another means of accounting for

-122-

multiaxial effects on fatigue life is to use the range on maximum principal strain. In the F/A CMP hex duct fatigue evaluation, the fatigue life based on equivalent or maximum principal strain, whichever produced the ,

minimum fatigue life was adopted in order to provide an additional safeguard against fatigue failure.

An additional consideration is that the Manson Universal Slopes Method is strictly applicable only to the mean fatigue life of a material and does not account for the scatter in experimental data. The RDT Draft for Breeder Reactor Core Components [5] recommends that the 2-20 rule be used to account for the minimum fatigue life due to scatter of data about the mean. The 2-20 rule was adopted for the fatigue life correlations of irradiated first l

core 20% CW-316-SS in the F/A CMP hex duct structural evaluation of fatigue life. Simply stated, the 2-20 rule requires that the multiaxial fatigue life be taken as the uniaxial fatigue life reduced by a factor of 2 on strain range or a factor of 20 on life, whichever is minimum. The 2-20 rule as applied to the uniaxial fatigue life relation developed for irradiated first core 20% CW-316-SS using the Manson Universal Slopes Method for the 22 2 F/A CMP hex duct E0L fluence (E>0.1 Mev, $t = 9.29 x 10 n/cm ) at 900*F is presented in Figure 5.3-1.

e e

-123-

3_ 4 - -

4.__i __.

T - l !

eeumsee.

Nm D

g5 ~

3

. 3 sg -

5 3 l.~5

. _ , , . . , 3 -

, , a . u.._4- w p +

d E r'rtttr i I.__7 -- h- h. -

2x s e a r- g t k r

e

-a g e g

n e

s -: - e a* {

S t - *p 3 -

r ~

3 C e t

C 8

w .

O s ._

w ee e

i t ~1 1 a5 m Od

- w IE .

I ss .

-3 2

___]

h-

~"

I 9 ;

3 m

g 8

- -C o sa b2 t:

25 --,

b

~~.

m.= h

.e emum emuuuu e

8

-_1

-i i

-q 3

.,.e --e-m

gm e- e b-p%

9 N ,

-124-

5.3.1.2.1.2 Creep Rupture Time Currently, creep-rupture time correlations are not available for irradiated first core 20% CW-316-SS. However, creep rupture time correlations have ,

been developed [12] for irradiated N-lot 20% CW-316-SS based on thin walled 22 pressurized tubes irradiated to fluences (E>0.1 Mev), from 0.21 to 0.90 x 10 n/cm over a temperature range of 1000 to 1400 F. Owing to the lack of ,

irradiated first core steel creep rupture data and correlations, the N-lot 20% CW-316-SS creep rupture correlaticas were used in the evaluation of creep damage factor (Dc ) for the F/A CMP hex duct over the 39 worst case duty cycles.

The creep rupture time correlations for irradiated N-lot 20% CW-316-SS given in [12] are presented in terms of the mean Larson-Miller Parameter (LMP).

A logarithmic bilinear correlation between LMP and maximum principal stress (asksi) was developed in terms of temperature (Ts R) and time (trsHrs). The transition stress ( xsksi) is given by:

o x

= 69.405e[-4.85 xT 10-4 ]

The a-LMP correlations are given by:

LMP = 64292 - 7762 in (a), o >,ox LMP - 44270 + 2.295T - 3040 in (a), o < o x .

No specific fluence term appears in the correlation. It was found that a difference existed between irradiated and unirradiated data, but that a change in fluence had no detectable effect on the correlation.

The mean rupture time (tr) is given by the relation: -

tr = 10 exp [lMP - 20]

T

-125-

E In order to correct for the spread in the experimental creep rupture-time data for N-lot 20% CW-316-SS, the minimum irradiated creep rupture times, based on 1.926 standard deviations belcw the mean on the LMP, were used in the F/A CMP hex duct structural evaluations of creep damage. The o mean and minimum rupture times at the F/A CMP hex duct fluence

[E > 0.1 Mew, (4t) = 9.29 x 10 22 n/cm ] and 900 F as a function of maximum principal stress (a) are illustrated in Figure 5.3-2 1

W e

-126-

0

' 1 9

j

)

m c '

/

n 2

2 0

1 s x

s

- 9 F 6 2 I 1 E "0 9 C 3 M 9 0 I 0 2 U - I 9 1

- D H T =

3 C t

s

. X E 5 E t R 4 E l

l 0 U ( R E 2 T U e R P LP T u U M U v A l G C RR M e R E a I 0 V F A C P P

/ E 1 M n F T E . E a S R 0 T e

R C > M I E F (

E C

N E 8 l

t L

8 0 1

F L

O E

)

s r

u o

lf

(

R t

7 1 0 1

d .

nv ue oD D

rd et wS o

L2 6

8 0 1

e 0

- - - ~ - 0 l

0 5 0 5 5 0 3 2 2 1

)

O~ t L. iC

i 5.3.1.2.2 Comparison and Criterion ;

- The F/A CMP hex duct structural evaluation in relation to the worst case location for combined creep-fatigue damage was made by screening i each of the finite elements over the 39 worst case duty cycles with the

= damage processor. Individual structural evaluations were made for the 3 l

sets of bending strerses and strains in order to obtain the worst case

! superposition. The maximum F/A CMP hex duct combined creep-fatigue damage factor (FCFD) max was found to occur for the case of compressive super-position at Element 1 as identified in Figure 5.2-1.

]

The fatigue damage factor (DI) was found to be 0.657 x10 -6 for the 39 worst case duty cycles. The equivalent strain range was found to be critical and occurred between cumulative iteration 27 and a uniform temperature distribution during the E-16 transient with a value of 0.00065 in/in. The peak local metal temperature during the E-16 transient was 918 F. The fatigue life for the equivalent strain range was 59.3 x 10 6cycles based on the E0L fluence (E>0.1 Mev, (4t) = 9.29 x 10 22 n/cm ),

2 c

The creep damage factor (D ) was found to be 0.00515 for the 39 wnrst case duty cycles. The equivalent stress was found to be critical with a ,

value of 21,387 psi corresponding to the steady state operation at the beginning of the 10 day hold-time. For the E0L fluence (E>0.1 Mev, (4t)=

9.29 x 10 22 n/cm ) at a metal temperature of 872 F, the minimum rupture 2

time was 1.82 x 106 hours0.00123 days 0.0294 hours 1.752645e-4 weeks 4.0333e-5 months .

In this arrangement, the maximum combined creep-fatigue damage factor (FCFD) max for the F/A CMP hex duct was found to dominated by creep damage l while fatigue damage was negligible.

(FCFD) max = 0.0052 l As (FCFD) max < l.0, the F/A CMP hex duct is not expected to experience crack initiation over the 39 worst case duty cycles based on the creep-fatigue damage criterion.

l

j. -128-i

o . .s . 2 u cessive vetor - ation .

Tne F/A CwP tex duct stru : ural evaluation of peak - accrclated, and .

residual defor aticns in relatten to functi:nal licits is presented in the following subsections.

5.3.2.1 Feak Plus A::u ulated Cefer ati:ns The peak plus accrulated defor aticn criterien in ;rciecting against excessive defor ation rec; ires (na peak plus accu ulated defor aticcs (d' u.,.')

be less than the ;eak plus a:Crulated deferratice linit (FAF ).

,F+A _ , _ ,

rm ine peak defor aticn (!' ) cf tne F/A C"? nex duct during the wors: case duty cycle at EOL as fc.nd to c: cur at tre trulative iteration 27 te cerature cistrit;; ion with a value of 0.0'426 in. As the F/A CMD h e r.

dact re ained linear elastic, the initial tire ir.de:endent are final ti e ce;endent steady state defer ati:n were identical with a value cf 0.00017 in. A:ccrdin ly, ite accrulated defor-atien (.tiss) gg ,egn initial ar.d firal steacj state canditicns crer cne duty cycle a*. ECL was 0.0 in. For 39 worst case duty cycles, the ECL peak plus accrulated .

de f e r-a ti on ,

m = i-I on rg_js e.

/ , , s s 3, 7, .

s- J q r .

ras. .,s .

(<E~As 1

. _m. .

= n . m.s--. -u . :n i n . n i, s -

A

( ! ' 4 "9) 7,y

= 0.0%26 in.

For ne F/A C": r:e t cac , e ceak clus accrulated cefer atice lirit (Fa't.)

FAIL = 0.010 in.

As i' < FAOL, tre F/A CFP *.ex du : is not errected c esperience excessi.e : eat def n ati:n crer the 39 wcrst case du y cycles.

9 JD%

k

5.3.2.2 Residual Deformations

, The residual deformation limit in protecting against excessive residual deformation requires that the residual deformation (6R ) be less than the residual deformation limit (RDL).

R 6 1 RDL R

The residual deformation (6 ) between initial and final uniform conditions for the F/A CMP hex duct are identically zero because the defonnations are R

linear elastic. Accordingly, 6 1 RDL and the F/A CMP hex duct inherently satisfies excessive residual deformation limits.

1 .

i 5.3.3 Suninary The F/A CMP hex duct was found to satisfy the crack initiation and excessive deformation criteria for a total of 39 worst case duty cycles.

A summary of the F/A CMP hex duct structural evaluation is presented in Table 5.3-1.

TABLE 5.3-1

!, F/A CMP HEX DUCT STRUCTURAL EVALUATION

SUMMARY

~

Allowable Calculated Margin

Criteria Value Value of Safety Crack Ductile Initiation Rupture 1 0.0727 12.76 Factor Combined Creep-Fatigue 1 0.0052 191.3

, Damage Factor Excessive Peak Plus 0.00026 in Deformation Accumulated 0.010 in. 37.4 Residual 0.010 in. O in. =

Margin of Safety = Allowable Value _j Calculated Value

-130-

6.0 ACLP HEX _ DUCT ANALYSIS AND EVALUATION In the F/A ACLP hex duct analysis and evaluation, a loading analysis was ,

made that considered mechanical seismic and core restraint, and thermal steady state and transient loads in order to establish the number and u

characteristics of a worst case duty cycle that umbrellas all expected .

duty cycles for the ACLP hex duct in the first and second reactor cycles. Next, an inelastic structural analysis of the ACLP hex duct was made for a single worst case BOL duty cycle from which E0L values were approximated. Finally, a structural e' uation of E0L strains and I dimensional changes in relation to critt.ria which protect against crack initiation and excessive deformation was made. A summary of the loading and structural analysis, and structural evaluation is presented as follows.

6.1 Loading Analysis I

l The F/A ACLP hex duct loading analysis was directed to establishing the number and characteristic: of a worst case duty cycle that umbrellas both the number and characteristics of the Upset, Emergency, and Faulted I

Events specified over the first and second reactor cycles. The number and characteristics of these events are specified in the Equipment Specification [1]. .

It is important to note that the worst case F/A ACLP hex duct duty cycle i is, in itself, hypothetical, but permits a conservative structural evalua- ,

tion to be performed on a single duty cycle instead on each of the individual events specified. In the following, the F/A ACLP hex duct mechanical and thermal loads are assessed individually and in relation 4

to each other prior to establishing the worst case duty cycle used in the structural evaluation.

6.1.1 Mechanical The F/A ACLP hex duct mechanical loads of significance in relation to subsequent structural evaluations are the beam type bending and local contact loads induced by OBE and SSE seismic, and core restraint.

Deadweight and internal pressure loadings are relatively insignificant. ~

-131-

_.,---.--...,-e.- _ . - . _ _ _ _ _ _ _ _ _ _ _ _ _ _ ____r, . _ _ , _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _

i l

6.1.1.1 Beam Bending

In order to perform a structural evaluation of the F/A ACLP hex duct, the maximum bending stresses and strains under lateral OBE and SSE seismic, and core restraint are required. The OBE and SSE seismic bending moments (M) are given in terms of the static 1-g moment (M ) amplified by the s

respective acceleration (a) of the core barrel, and the core restraint moments (MCR) corresponding to steady state operation are given directly.

i 1

M =

OBE [Ms l "0BE

" a '

"SSE E"s] SSE "CR "CR ,

With regard to core restraint behavior during the Upset, Emergency, and

, Faulted thermal transients, the temperatures of the F/A and adjacent l C/A, RB/A and RRS/A hex ducts were assumed to follow the overall core temperatures, but the temperature differences across the F/A which cause the beam bending moments are not expected to change significantl" from steady state values. Accordingly, the core restraint bending moments during the transients were not assumed to change from steady state values.

. Alternately, the steady state temperature differences across the F/A hex duct cross-section at any point along its length was assumed to be the same during the thermal transients even though overall temperatures l increased or decreased according to the characteristics of the transients.

In this arrangement, the transient bending moments (MTR) were assumed equal to the steady state core restraint moments (MCR)

"TR "CR

-132-

In order to determine the raxinen ACLP bending stresses and strains, the ACLP bending recents were screened for each F/A. The raxiru ACL? core '

0 restraint (MCP) and transient (K7p,)norentswerefoundtooccuratF/AA$ O with a value of 43,E60 in-lb. The raxirun 1-g static tending rorent (Ms )'

aoplicable to all F/A, was found to be 2600 in-lb. ,

For the F/A ACLP hex duct the cross-section ncdulus (E) and Young's 9cdalus (E), the naxirut tending stresses (:) and strains (c) are given by the fcilowing relations:

= M/I and c = :/E 3

Surerically, the F/A ACLF hex duct section ocdalus (I) is 3.92; 3 , 7ne Young's Modulus (E) for the ACLP nex duct as constructed from 20: CW-315-SS a

and operating at a steady tercerature of 10CO F is 22.54 x 10~ psi. The F/A ACLP hex duct naxiru stresses (:) and strains (c) under 03E and SSE seismic, core restraint and transient bending re ents are sunnarized in Table 6.1-1.

o O

-133-

TABLE 6.1-1 F/A ACLP HEX DUCT OBE AND SSE SEISMIC, AND CORE RESTRAINT BENDING M0MENTS, STRESSES, AND STRAINS Max. Max.

Core Barrel Bending Bending Bending Loading Acceleration Moment Stress Strain (a) (M s in-lb) (o s PSI) (c s in/in)

Static Dynamic OBE 1.57 2600 4082 1039 4.61E-5 Seismic SSE 2.2 2600 5720 1456 6.46E-5 Core Restraint N/A 48860 N/A 12436 5.52E-4

? Transients N/A 48860 N/A 12436 5.52E-4

6.1.1.2 Local Contact The F/A ACLP local contact loads are the inter-duct loads that occur at the corners and faces of a F/A ACLP load pad und~,c lateral OBE and SSE seismic excitation, or are induced by the core restraint system during steady state and transient thermal operation.

An important consideration in the structural evaluation of the F/A ACLP is whether the local inter-duct loads are load or deformation controlled, or some combination tnereof. However, the local inter-duct behavior of the F/A ACLP hex ducts in relation to whether the structural response due to lateral seismic and core restraint is load or deformation controlled is not fully understood at this tine. Currently, the local ACLP inter-duct loads are thought to be load controlled only when the attendant deforrutions are less than the gaps that exist between adjacent assemblies.

The rost conron example of a load controlled condition occurs when a F/A ACLP hex duct experiences compressive 2 face loading from adjacent ducts across 2 opposing flats, but the outwardly disposed deformations at the unloaded corners are not sufficient to exhaust the gaps and initiate contact with the adjacent ACLP hex ducts. Once the unloaded corners .

contact the respective adjacent ACLP hex ducts, the 2 face loading of the duct under consideration becomes defernation controlled. By the same argument, the ACLP hex ducts which were applying the 2 face loads .

to the duct under consideration are also undergoing deforration and load redistribution. Alternately, the 2 face loads applied to the ACLP hex duct are themselves deformation controlled and in a strict sense are not load contro!1ed.

In a pure deformation controlled CRBR core with a rigid core former ring and core barrel, the local inter-duct ACLP hex duct loads approach a pure hydrostatic loading with a uniform deforration pattern throughout the ACLP cross-section. In actuality, a small amount of load controlled behavior characterized by 2 face loading and non-uniforn cross-section deformations would occur because of nominal gap variations, temperature differences,

-135-

core former ring and core barrel flexibilities and exterior ACLP hex duct

, dimensional tolerances. However, system analysis of actual CRBR core behavior under lateral seismic and steady state or transient thermal operation with the detail necessary to assure displacement compatibility at the contact surfaces of each ACLP hex duct within the flexibility of the core formers and barrel is beyond current state-of-the-art analytical procedures. Current analytical procedures only approximate true displace-ment compatibility between CRBR core assemblies in order to obtain practical solutions. As such, systems analysis of CRBRP seismic and core restraint response provide conservative loads for ACLP duct structural evaluations which, neglect the mitigating effects of actual deformation controlled core behavior.

In the following, the F/A local contact ACLP hex duct seismic loads during OBE and SSE, and induced by core restraint during steady state and transient thermal conditions are described. Also, conservatisms in the local contact F/A ACLP hex duct loads to be used in the structural evaluation are cited.

6.1.1.2.1 OBE and SSE Seismic The F/A local contact ACLP hex duct loads are based on the Planar Core Model (PCM) presented in the Core Inter-Duct Analysis Document [13].

The PCM used to derive the F/A ACLP hex duct local contact loads under lateral OBE and SSE seismic excitation was based on a 2 dimensional 180 sector of the CRBR core at the ACLP. A lateral lg acceleration was imposed on the 2 dimensional 180 sector of the CRBR core at the ACLP with a portion of the ful . weight of each F/A, RB/A, C/A, and RRS/A lumped at the corners of the respective ACLP cross-sections. Owing to the detail of the PCM, a true simulation of ini.er-duct contact using non-linear gap elements at each of the 12 possible contact points for each core assembly was not practical. Instead, a semi-linear analytical approach consisting of interposing linear springs between each pair of contact points was

~

adopted. As the linear springs permit tensile loads to be developed, a manual iterative procedure was used to obtain a compression only solution. In

-136-

J essence, the inter-duct loads were inspected after each linear solution and, if found to be tensile, the spring stiffness was reduced until the '

majority of inter-duct loads were compressive. In this arrangement, the local F/A ACLP loads derived by the PCM are considered conservative for the following reasons. ,

o The PCM considered full load transfer of the ACLP region to the ACLP core former. However, the bending action of individual i or groups of core assemblies would actually transfer a portion of the ACLP load to the TLF outlet nozzle and core support i plate. Accordingly, PCM local contact loads for the F/A ACLP hex ducts under lateral 1-g static acceleration are larger in magnitude from what would be expected in the CRBR core.

4 e The PCM simulated compression only local contact through linear springs which were reduced in stiffness to provide mininal tensile loads. However, the duct corners were permitted to overlap each

other in the process. Accordingly, true displacement compatibility j consistent with the deformation controlled loading of the F/A ACLP hex ducts and adjacent ACLP hex ducts which would tend to produce hydrostatic loading was not obtained. As such, the PCM local contact loads for the F/A ACLP hex duct under lateral 1-9 static acceleration include 2 face loads larger in magnitude from what i

would be expected in the CRBR core.

In order to establish the worst case F/A ACLP hex duct local contact OBE and SSE seismic loads, F/A locations in a 60* sector of the core were identified for structural evaluation as illustrated in Figure 6.1-1.

l e

-137-I

-- eyv-- u v w -- . - - - - - - m -.,- + , - re- --- _ _ - - - _- - - - . - - - - . + - - - - - - - - _ _

Figure 6.1-1 A

F/A ACLP Hex Duct p PCM 1g Static Load Location p 10 3 11 A

12 01 02 03

[ \/\ \

A A] Ah Afl3

/\b 08 09 10 g li g l2 A A 4 01 02 03 04 05 Worse F/A ACLP

[\/\/\

A 07 A

08 A

09

^10 A 11 3 12 06 02 03 04 os Hex Duct Locations --w 01 l ::: \f f k 06 4

07 4

08 4

09 g 10 A ll 07 4

A / Ig Acceleration 10 12 A

05 01 1

4 A

06 02 A

07 03 th A Jg 04 08 l 6

g 09 05 A

06 g li 07 A

08 >

,/h \ \/ /\b

\ e e l e ie le y e e e ^s

/\ / y 5 08 09 10 h lI 2 07 A A

01 E A 04 i A

05 T

' A 06 04 t A

05 i A 06 A

07 A

08 A

09 10 01 02 ! 03

\ \

[ 02 j 03 1 04 W A

05 4'06 A 07 A AC8 A 09

{ A 10 09 A

II 10 A

l2 11 A A 06 07 08

01. r 02 i .A03 $ 04 05

                                                        %/A MYh                                                   \                                 \
      ,<         h\                   k

t 1 The method of selecting the worst case F/A ACLP hex duct local contact seismic loads for structural evaluation was directed to establishing a , ! set of static 1 g loads for a 90 sector of the ACLP hex duct cross-section which are representative of the 12 loads on each of the 6 F/A locations. In essence, a set of 3 loads (F), F2 , and F3 ) in a 90 sector . of the ACLP hex duct cross-section were selected to represent the 12 loads (W)),W12' N21' N22' 'N61' N62) n each of the F/A ACLP hex ducts. The load designation scheme is illustrated in Fiaure 6.1-2. 1 l W 12 N 11 F) N W 62 1 F 21 , . _ _ 2 W 22

                                                 /                                             W
                                                                                          \ / 61       ,'                 l
                                                                                                                                            \             F 3
                                                \                                              W 52                                          /

t W32 #h Oy 4 61 3 W W)4 42 Figure 6.1-2 F/A ACLP Hex Duct Method of Selecting Static 19 Loads . The values of the representative static 19 loads on the 90 sector ACLP ] hex sector of each F/A were derived from the following method of averaging. 4 i F = j W)) + W12 + N41 + N42 4 F

2 N21 + N32
N51 + N62

, 4 3 N22 + N31 + N52 + N61 4 , A summary of the static 19 loads (F), 2F , F3 ) for each of the 6 F/A - l locations is given in Table 6.1-2. i 1 -139-l

_ TABLE 6.1-2 F/A ACLP HEX DUCT AVERAGE 19 90 SECTOR LOADS t { F/A ! Average 90 Sector Loads (LBS)

               ' Location
               ,                  j               ;                ,
                                                  '   F     ,  F F)            g 3

A 2278 1313 ' 2080 l A 2670 238 1643 ! i A 2658 345 1930 t 07 A , 2515 835 2150 l 3 , 07 A 2993 1223 2155 6 I i A 2768 568 2105 l l 1 The average static 1g loads in the 90 sector of a F/A ACLP hex duct cross-section represent a symmetrical set of loads with attendent structural dan. age which is an approximation to the damage that would occur for the actual non-symmetrical set of loads over the 360 sector of the F/A ACLP hex duct cross-section. However, the disadvantage with the average lg 90 sector load is that individual structural evaluations would be required for each of the 6 F/A ACLP hex duct locations because a simple assessment of the worst case loading is not possible. Consequently, the individual F/A loads (F), F2, F 3) were, in turn, averaged for the 6 F/A locations so as to simplify structural evaluations, ar.d yet also provide a reasonable set of 90 sector F/A ACLP hex duct loads. The average lg F/A loads (F)) , (F 2) av , and (F 3) av used in %e UA W hex duct ; structural evaluation were obtained by averaging the F/A loads (F), F2 ' < F3 ) in Table 6.1-2. I (Fj )av = 2647 LBS (F2)av = 754 LBS (F3)av = 2010 LBS

                                          -140-

t i f i In order to detennine the dynamic OBE and S',E seismic F/A ACLP hex duct

loads (FDYN), the static ig loads (F s) were increased by the dynamic accelerations (a) of the core barrel.

F DYN, OBE

[Fs ] a 0BE F DYN, SSE

[Fs ] a SSE

                                                                                         = 1.57 g), the worst case F/A ACLP For the OBE seismic acceleration (a0BE i                             hex duct loads are:

j (F)av,OBE

                                                           =  4156 LBS.

l (F2)av, OBE

                                                           =  1184 LBS.

(F3)av, OBE = 3156 LBS. Similarly, for the SSE seismic acceleration (aSSE = 2.2 g). l (Fj )av, SSE = 5823 LBS. (F)av,SSE=1658LBS. 2 . ! -(F3)av, SSE = 4422 LBS. 6.1.1. 2. 2 Steady State and Transient Core Restraint I The F/A local contact ACLP hex duct loads are based on the 2 dimensional Core Restraint Model (CRM). The F/A ACLP hex duct local contact core restraint loads under steady state , reactor operation were derived using a 2 dimensional CRM which incorporates f j simplified 3 dimensional assembly interaction effects. The CRM is based i on a string of F/A, C/A, RB/A, and RRS/A assemblies extending from the I center of the core to the ACLP and TLP core former rings. Assemblies were simulated using 2 dimensional beams with gap elements at the inlet . nozzle, ACLP, and TLP to represent contact with the inlet module and adjacent assemblies. Each assembly in the model is assigned the stiffness and interaction characteristics of a hexagonal ring of assemblies. .

                                                                                       -141-t
  = - wc..-,+7.,ww__.~,,m.,,

J i

   . Owing to the simplicity of the CRM, a true simulation of non-linear inter-duct contact consisting of gap and stiffness simulation at each of the 12 possible contact points on each core assembly ACLP and TLP location was not obtained. Nevertneless, a reasonable approxiration of F/A ACLP hex duct load to be used for structural evaluation were obtained for the following reasons.

e The CRM local contact F/A ACLP nex duct loads were based a 1.4 uncertainty on the steady state temperatures. Acco rdingly, the 40% increase in terperature difference across the cross-sections of the core assemblies in the string of core asserblies produces larger F/A ACLP hex duct loads than would be expected in the CRBR core, even if true displacement compatibility were obtained. e The CRM local contact F/A ACLP hex duct load; were based on a uniforn gap distriubtion of 0.010 in, where as the nominal CRSR gap at operating conditions is 0.015 in. Accordingly, the F/A ACLP hex duct local contact loads during steady ; tate CRER tnerral operation as constrained by the ACLP and TLP core forners and derived by the CRM are higher than would be excected in the actual CRBR core. In order to establish the worst case F/A ACLP hex duct local contact core restraint loads,4 F/A locations in a 30' sector of the core were identified for structural evaluation as illustrated in Figure 6.1-3.

                                           -142-

2" U e s m E , i n a e 8 a W 2 22 O= = 7 --

       's !                                                                                  \ ~'              -

e e

                                             / _,_/-
                                                        /us\'/-_/
                                                        \    '   /.     =s
                                                                            \ ~~~                            . .
              -                  /                           =,                       e
                                         => \,

e

                       ,   =s                         ~                  om h   -               ss -
                                                   ~
                                                                        ~'
                /. u \ ' / =s '/ ea        <                   <
            =>N,                        j    sa\ ~

~~na/ -'/ , , s8 -~~
~~~ -e '~~
~~x- a s \,,=- -~~
~~/==\='a.u \ < / sa \; ' / sa \~~
~~o on/~~
\ ss a s,\Ss v < // sgg> ==t \
~~5 < // as #==y, s s ';-w~~
~~</ Q_ mm ~ -f sa/ ~~~
s
~ 'p. I \ k y 'I! \ 'e //~83 s \ =a s h- 85=
~~ay// --~~
\\t . \.e y d"j / 'aa '/"\\ sa ~ /// ==f ss 9 N sf ,/ sa '\ v</ \4a5 .,/wrw, w sf sy =< ;s , sa e . \/~s~s'Lm a - )
~~l '(e ,~~
~~/f,~ h 85 =~~
~~ga yv/7 w aa ._~~
~~< < \~~
~~A g U - - a j a,5 ) : :. r 3g =-~~
/
~~YC ll odo 2<a~~
~~\ .~ J'/ . -143-~~
The method of selecting the F/A with the worst casa ACLP hex duct local contact steady state core restraint loads for structural evaluation was directed to establishing a set of loads for a 90 sector of the ACLP hex duct corss-section which are representative of the 2 face loads at each of the 6 faces in each of the 4 F/A locations. Alternately, a set of 3 loads (Fj , F 2, and F )3 in a 90* sector of the ACLP cross-section were selected to represent the 6 sets of 2 face loads (W), . . , W ) on each 6 of the F/A ACLP hex ducts. The load designation scheme is illustrated in Figure 6.1-4. i Wj F) U I U p2 F N '
~~2 6~~
\
~~l Ng 3 (. ( 1 gy j%y '~~
/
~~W \ / 5 / t 3 --->~~
~~. W 4~~
r . Figure 6.1-4 j F/A ACLP Hex Duct Method of Selecting Core Restraint Loads The values of the cora restraint loads on the 90 sector of each F/A were derived by the following metlad of averaging. I
=
~~F) Wj+W4 4 F~~
~~2 N2+N3+N5+N6 8~~
F
~~3 2+N3+N5+N6 8~~
~~, -144-r2. m-, ..w.- , . - . - - . -~~
A :umary of the steady state core restraint loads (F), F2 , F3 ) for each of the 4 F/A locations is given in Table 6.1-3. . TABLE 6.1-3 F/A ACLP HEX DUCT AVEPAGE STEADY STATE CORE RESTRAINT 90' SECTOR LOADS I Average 90 Sector Loads (LBS) F/A '
~~, Location - .~~
~~F F F) 9 2 3 432 298 l 293 i A~~
~~= f g f 210 230 230 !~~
A l A 0 122 ! 122 A 0 42 42 m . The average steady state core restraint loads in the 90* sector of a F/A ACLP hex duct cross-secticn represent a symetrical set of losis with attendant structural damage is an approxiration to the damage that would occur over the 360 sector of the F/A ACLP hex duct cross-section. Unlike the local contact seist.ic loads, the worst case core restraint loads were selected by sirole inspection of the individual loads at the 4 F/A locations given in Table 6.1-3. The F/A location A steady state core restraint loads were selected as worst case in F/A ACLP hex duct structural evaluations. F j
~~= 432 LSS F = 298 LB5 2~~
~~F = 293 LBS 3 .~~
~~-145-~~
~~.-. - . . -_-..- - - ._ -_= -~~
The worst case F/A ACLP hex duct local contact core restraint loads apply i only to steady state thermal performance of the CRBR core. With regard to transient CRBR core restraint behavior during Upset, Emergency, and Faulted thermal transients, the temperatures of the core assemblies change locally over the brief duration of the transients. In relation to the global temperature change of the full CRBRP core as constrained by the ACLP and TLP core formers, significant difference in local contact ACLP j hex duct contact loads from that would occur during steady state behavior is not expected. Accordingly, the ACLP hex duct local contact loads (FTR) during the transient behavior of the CRBR core were assumed to be identical to the steady state loads (Fss) for the purposes of structural evaluation. i F = F TR ss 4 e i t i 4 e
~~-146- ,.-r - , -- , - - , . -~~
6.1.2 Therral The F/A ACLP hex duct therral loads are the steady state and transient , terperature distributions that occur during the Upset, Erergency, and Faulted Events over the first and second reactor cycles. The steady state F/A ACLP hex duct inside retal ter;:erature distributions throughout , Sector A of the core at BOC 1, EOC 1, EOC 2, and EOC 2 and the Upset, Erergency, and Faulted Transients defined in ter s of tire-dependen'. scale factors applied to the steady state inside retal tegeratures we e considered. In this arrangerent, the F/A ACLP hex duct therral loads in terns of inside retal temperatures associated with E0C 1, EOC 1, EOC 2, and EOC 2 steady state as well as Upset, Erergency, and Faulted Transients were identified at any F/A Iccation in the core. In order to proceed with a structural evaluation of the F/A ACLP hex doct, it was desirable for the sakt of simplicity to consider only the worst case then al loading. Arc:-dingly, all F/A located in Sector A of the core were assessed in r<.lation to the raximu inside retal wall te perature difference between a F/A and adjacent C/A or RB/A. The raxirun steady state inside retal wall temperature difference was found to occ' r at F/A 0 A adjacent to RS/A A 0 during BOC 1 with a value of 219'F. It is 0
irrortant to note that at EOC 1, BOC 2, and E0C 2, the respective inside retal terperature differences were found to decrease from BOC 1 values with an average terTerature difference over the first and second reactor cycles of 152 F. A greater raintained steady state inside etal wall ter;erature dif ference over the first and second reactor cycles is observed for F/A A adjacent to C/A A0 or the latter, a raximun te~perature difference of 217*F is seen to occur at EOC 1 while the average tegerature over the first and second reactor cycles is 200'F. Accordingly, 07 07 the F/A A 02 adj cent to C/A A 01 with a respective average inside retal surface terperature dif ference of 200'F was considered as worst case for steady state tercerature distributions in subsecuently F/A ACLP hex duct structural evaluations.
~~-147-~~
With regard to F/A and adjacent C/A ACLP hex duct thermal transients, the Equipment Specification [1] using an umbrella approach identified the number of Upset, Emergency, and Faulted transients over the first and second reactor cycles as 1/15 of the number specified for 30 years rounded to the next whole number. Over the first and second reactor cycles comprising a total of 328 FPD, a total of 39 Upset Transients umbrellaed by the worst of U-2b or OBE were specified. Similary, the worst of the E-16, 60c Step, or U-2b during 0BE were specified to umbrella the Emergency Transients while the SSE was identified to umbrella the Faulted Transients. In the derivation of the F/A and adjacent C/A inside metal temperature transients for the Upset, Emergency, and Faulted transients, the upper and lower bounds for the Upset U-2b and OBE events and the Emergency 60c step event were identified from June,1977 data. The upper bounds were based on quickest flow decay and maximum decay heat while the lower bounds were based on slowest flow decay and minimum decay heat. Further, the SSE Faulted Transient was found to be umbrellaed by the Emergency E-16 transient. The Upset transients comprising the upper and lower bound U-2b and OBE, and the Emergency Transients including the upper and lower o bound 60C step, E-16, and U-2b during OBE are identified. e
~~-148-~~
In order to reduce the number of F/A ACLP hex duct transients which umbrella the Upset, and Emergency Transients to a single worst case transient, the individual transients were assessed for severity in sub- , sequent structural evaluations by comparing the inside metal wall tempera-tures in terms of maximum value, rate of temperature change, and range. 08 steady state temperature In the assessment, the F/A A 09 adjacent to RB/A A . difference of 219 F with F/A and RB/A inside metal surface temperatures of 1056 and 837 F were used. For the Upset Transients at the F/A ACLP hex duct inside metal surface, the upper and lower bound U-2b transients with maximum rate and range of temperature indistinguishable from the upper and lower bound OBE transient. However, the adjacent RB/A inside metal temperature transients for the lower bound U-2b were observed to more closely follow the F/A metal transient than in the case of the upper boend U-2b. Owing to the thermal lag in the thin walled F/A ACLP hex duct, temperature differences through the wall, which are important in structural evaluations, are slightly more severe in the lower bound U-2b transient than the upper bound counterpart. With regard to the Emergency Transients, the E-16 transient in terms of naximum value, rate of temperature change, and range was found to be clearly more severe than the upper and lower bound 60c step, and the U-2b during 0BE transients. Further, the E-16 was also considered more severe than the lower bound ' U-2b transient. In this arrangement, the Emergency E-16 transient was considered to umbrella all Upset, Emergency, and Faulted transients for the F/A ACLP hex duct and is illustrated in Figure 6.1-5. , e
~~-149-~~
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~~- E-16 Transient 1150 - N Largest Sustained S.S. Temperature i~~
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The worst case F/A ACLP hex duct duty cycle in terms of inside metal tempera-
, tures at initial steady state, followed by the E-16 transient, thermal conditions in returning to initial steady condition, and 10 day hold-time are not sufficiently detailed for subsequent structural evaluation. In o the following, the F/A ACLP hex duct thermal model and geometry, boundary conditions and wetted sodium surfaces, heat generation rates, and thermal analysis and results are described from which conclusions on detailed temperature distributions used in subsequent structural analysis are presented.
6.1.2.1 Model and Geometry The F/A ACLP hex duct model was fomulated in the ANSYS finite element program. The ANSYS program was selected because of the compatibility between thermal and structural elements which permits thermal solutions of temperature distributions to be used directly in subsequent structural analysis. The F/A ACLP hex duct region selected for analysis corresponds to a 2 dimensional 90 sector of the full ACLP cross-section. As the worst case o F/A ACLP steady state and transient temperatures include adjacent C/A inside metal wall temperatures, an effective film coefficient was used to simulate the thermal resistance of the C/A wall. The effective C/A film , coefficient (h) was taken as the thermal conductivity (K) divided by the wall thickness (L) according to the relation, h = K/L. The effective film coefficient of the sodium in the ACLP interstice gap in relation to the ACLP hex duct itself was not found to be significant. The F/A ACLP hex duct thermal model illustrating the dimensional extent and finite element detail is presented in Figure 6.1-8. The F/A ACLP hex duct 90 sector thermal model as formulated in the ANSYS program included a total of 294 linear temperature (STIF 35) elements in a mesh of 341 node points. A relatively fine mesh was selected in the corner adjacent to the global X-axis so as to include the thermal skin response to the thermal transients. Otherwise, a relatively coarse mesh was used throughout the 90 sector of the ACLP cross-section.
~~-154-~~
~~Nominal --- - Operating ' Gap e (0.015in) RB/A a h i 0.190 Sodium Interstice IL .~~
~~., \~~
~~n N : . : .~ T~~
~~
0.16 R C/A 4.745 Flat to Flat C/A ACLP , Wall Simulated By Effective F/A Film fficient 1
\,
~~l 9 Figure 6.1-8 F/A ACLP Hex Duct Dimensional Extent and Finite Element Detail~~
~~-155-~~
6.1.2.2 Properties The F/A ACLP hex duct is constructed from first core 20% CW-316-SS. The thermal conductivity (K), specific heat (C), and density (c) of 20% CW-316-SS are known to not significantly differ from SA-316-SS values. O Accordingly, the first core 20% 316-5S properties used in the F/A ACLP hex duct thermal analysis were identical to the SA-316-SS properties identified for the F/A shield block described in Section 4.1.2.2. 6.1.2.3 Boundary Conditions and Wetted Surfaces The F/A ACLP hex duct boundary conditions and wetted surfaces selected in the thermal analysis are illustrated in Figure 6.1-9. Boundary conditions for the thermal analysis consisted of adiabatic conditions along the lateral surfaces coincident with the Global X and Y axes of the 90 sector model. In simulating the thermal resistance of the C/A ACLP hex duct wall, the ef fective film coefficient (h=0.00104 BTU /in2-sec- F) was based on a thermal conductivity (K=0.000197 BTU /in-sec- F) and wall thickness (L=0.190 in). The effective film coefficient (h) was specified at the free surfaces of all elements forming the exterior of the F/A ACLP O hex duct which included elements 8 through 40, increments of 8; 49 through 153, increments of 8; element 163; elements 169 through 223, increments of 6, and 230 through 296, increments of 6. C The wetted interior F/A ACLP surfaces were assumed to response imediately to the inside metal wall temperatures of the worst case F/A ACLP duty cycle. Local variations in wetted interior surface temperatures were neglected. Instead, all F/A ACLP hex duct interior surface node temperatures were globally coupled to each other and included Nodes 1 through 172, increments of 9; and 181 through 35, increments of 7. With regard to the wetted interior C/A ACLP surfaces which are exposed to inside metal wall temperatures, local temperature variations were also neglected and a global variation assumed in the form of a bulk temperature. The bulk temperatures were specified in accordance with C/A inside metal o
~~-156-~~
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surface temperature variations of the worst case F/A ACLP hex duct cycle ( and applied to the F/A through the effective C/A wall film coefficients. 6.1.2.4 Heat Generation Rates During steady state operation, the F/A ACLP hex duct is exposed to nuclear heating. The maximum heating rate per unit volume was relatively uniform 3 with a value of 1.919 watts /cc or 0.0295 BTU /in -sec. For the F/A ACLP hex duct exposed to a heat generation rate (Q) with thermal conductivity (K) and wall dimension (L), the temperature difference (AT) is given by:
~~= 2 AT QL /2K 3~~
AT = (0.0295 BTU /in -sec) (0.205 in)2 2(2.87 x 10-4 BTU /in-sec*F) AT = 2.16 F For the F/A ACLP hex duct, t se steady state temperature difference (aTss) caused by sodium flow was 200 F. As AT < < ATss, the steady state tempera-o ture is insignificant, an heat generation rates were neglected in the thermal analysis. ed
~~-158-~~
1 6.1.2.5 Analysis and Results The ANSYS thermal analysis of the F/A ACLP hex duct wa; arranged to pro-vide detailed temperature distributions over the total worst case duty cycle. A total of 10 load steps were selected at prominent F/A and C/A inside metal surface temperatures. The first 7 Load Steps characterized ,
~~! the initial steady state conditions and the E-16 transient to 450 seconds.~~
~~Load Steps 1 and 2 represent initial steady state conditions while Load~~
Steps 3 through 7 correspond to the E-16 transient. Load Step 8 corresponds to the 1 hour cool-down to 600*F. The return to final steady state temperatures with the 1 hour heat-up was accomplished in Load Step 9. The final steady state temperatures held for 10 days were obtained in Load Step 10. Prominent Load Steps in the E-16 transient are illustrated in Figure 6.1-10 and numerical values for the full worst case F/A ACLP hex duct duty cycle are presented in Table 6.1-4 i TABLE 6.1-4 WORST CASE F/A ACLP HEX DUCT DUTY CYCLE ANSYS INPUT DATA Temp ( F)
Loau Time Step (Sec) F/A C/A 1 0.0 1000 800 2 0.0 1000 800 - 3 2.0 1010 805 4 12.5 820 735 5 90 1155 845 6 175 00 800 . 7 450 'j 11 0 755 8 4050 v00 600 , 9 7650 1000 800 10 900000 1000 800
~~b. _ _ . _ _. ._ _ _ . _ . . --___..__....._ .._ ._ _~~
~~-159-~~
~~] i _. _ . . _ - - . , . . . _ _ . , , - . . - _ . _ , _ _ _ _ _ _ _ . . . ___~ _ _ -~~
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t s e g r 0 a , 0 L 3 0 i 5 2 y l y b l m b s e m 0 ) s e 0 s s s 2 d A s n A o l c e e F u l o r
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0 0 1 0 0 0 0 5 0 2 0 0 0 0 1 1 I 0 9 8 7 1 1 T i 1 g?
The ANSYS solution of the worst case F/A ACLP hex duct duty cycle was obtained in 74 cumulative iterations using a static and transient con- ' vergence criteria of 1 and 5'F respectively. The temperature distributions at each cumulative iteration were saved on ANSYS Tape 4 for recall in sub-sequent structural analysis. In order to determine the cumulative , iterations of interest in structural analysis, maximum and minimum through the wall temperature differences are most important in relation to structural damage. The F/A ACLP hex duct temperature differences were based on the through-the-wall temperatures at nodes 1 and 9 depicted in Figure 6.1-9. A plot of the F/A ACLP hex duct temperature differences is presented in s Figure 6.1-11. ; A review of the through-the-wall temperature differences shows that the maximum and minimum values occur at cumulative iterations 32 and 61 respectively, with a range of 174 F. In the thermal solution run, cumula-tive iteration 32 corresponds to the E-16 transient at 90 seconds as illustrated in Figure 6.1-6. The initial steady state condition corresponds to cumulative iteration 2 with a tenperature difference of Il0*F. Plots of the temperature distributions throughout the F/A ACLP hex duct therral model at cumulative iterations 2 and 32 are presented in Figure 6.1-12. e t i
~~-1 61- I h~~
l I
1 O O i l 200
~~- Cumulative 180 . Iteration 32 h~~
160 . 140 . u S.S. 5 - Cumulative 5 120 _ Iteration L 2 3*3 N Et ga 100 _ Maximum 3m m Range { ', 80 . 174 F 5D s - 60 40 . 20 . Cumulative Iteratior. 47 I I
~~. t . . . 1 0 . , , . . . . . . ,~~
~~0 10 20 30 40 50 60 70 80 90 100 Cumulative Iteration Figure 6.1-11 F/A ACLP Hex Duct E-16 Transient Temperature Difference vs. Cumulative Iteration~~
~~~ -162-J~~
~~y Cum. Iter. 2~~
~~-w ., - n- .~~
~~i. 4 y~~
~~c 1000'F + c 890 F a m ww .1 ,~.s k1 Cum. Iter. 32 , 6 v. e 1155 F~~
Figure 6.1-12 F/A ACLP Hex Duct

E-16 Transient Cumulative Iteration 2 and 3" Temoerature Distributions
~~-163-~~
I
~~; 6.1.3 Worst Case Duty Cycle 2 #~~
The conclusions based on the F/A ACLP hex duct loading analysis in relation to establishing the worst case duty cycle with recommendations for subsequent j structural analysis were as follows. i O
(
l e Mechanical loads comprising OBE and SSE beam bending, internal pressure, and deadweight were considered insignificant. Steady state and transient beam bending moments were considered negligible relative to local contact loads and SSE loads are more severe I than OBE local contact loads. Only local contact loads caused by core restraint under steady state and transient operation, and 3 during SSE seismic events were considered to be of significance in establishing the worst case F/A ACLP hex duct duty cycle. i e Thermal and mechanical core restraint loads associated with the E-16 transient in combination with the thermal conditions in returning to steady state and the hold-time prior to the initiation of the next E-16 transient were considered most important in , establishing the worst case F/A ACLP hex duct duty cycle. In order to provide a copastent basis for combining the local contact i steady state and transient core restraint and SSE seismic loads with the
~~, E-16 steady state and transient thermal loads, a 90 sector of the ACLP ;~~
cross -section was selected. The local ACLP hex duct contact loads were j conservatively assumed to be load controlled even though attendant deformations I may mitigate actual structural response due the restraint of adjacent ACLP hex ducts. ! The recommendations for the specific F/A ACLP hex duct loading were to apply a first and second worst case duty cycle of time independent and dependent loading. The first worst case duty cycle comprising successive SSE seismic loads applied at peak E-16 transinet temperatures and core I restraint loads was to be applied only once. The second worst case duty cycle comprising the E-16 transient temperatures and core restraint loads, L L
~~-164-i~~
l but excluding additional SSE loads, was considered to be repeated 38 times. In this arrangement, the recommended number and characteristics of the first 5 l and second worst case F/A ACLP hex duct duty cycles provide an upper bound to the 39 specified Upset events and the worst Emergency or Faulted event.
First Cycle - Time Independent (One Application) e Select a uniform temperature equal to the reference temperature at cumulative iteration 2. Load to the cumulative iteration 2 temperature

distribution and apply the steady state core restraint local contact loads. Unload to uniform temperature.
i i e Select a uniform temperature equal to the reference temperature at , cumulative iteration 32. Load to the cumulative iteration 32 temperature distribution and apply the transient core restraint local contact loads. j Apply successive SSE seismic local contact loads until shakedown is observed. Unload to uniform temperature, l o Select a uniform temperature equal to the reference temperature at cumulative iteration 2. Load to the cumulative iteration 2 temperature distribution and apply the steady state core restraint local contact r loads. First Cycle - Time Dependent (One Application) , e Hold the cumulative iteration 2 temperature distribution in combination l j with the 2 face steady state core restraint local contact loads for 10 days. I l l Second Cycle - Time Independent (Repeat 38 times) e Select a uniform temperature equal to the reference temperature at j cumulative iteration 2. Load to the cumulative iteration 2 temperature ', distribution and apply the steady state core restraint local contact I loads. Unload to uniform temperature. l
~~-165-l =~~
d I
i e Select a uniform temperature equal to the reference temperature a'. cumulative iteration 32. Load to the cumulative iteration 32 temperature distribution and apply the transient core restraint local contact loads. Unload to uniform temperature. o Select a uniform temperature equal to the reference temperature at cumulative iteration 2. Load to the cumulative iteration 2 temperature distribution and apply the steady state core restraint local contact loads Second Cycle - Time Dependent (Repeat 38 times) e Hold the cumulative iteration 2 temperature distribution in combination with the 2 face steady state core restraint local contact loads for 10 days. 9 e i O i
~~-166-i i~~
6.2 Structural Analysis o Tb_ F/A ACLP hex duct structural analysis was directed to deriving the stresses and strains, and dimensional changes which occur during the first and second worst case duty cycles from which structural evaluations were made. In the following, the F/A ACLP hex duct structural model, geometry, and boundary conditions are described. Next, linear and non-linear material properties including the effects of irradiation on stress-strain curves and simplification made in the thermal creep equations are presented. Further, reference temperature selection for thermal expansions in relation to axial constraints is described. Finally, the first and second worst case duty cycle time independent and dependent inelastic analysis and results for the F/A ACLP hex duct are presented in preparation for subsequent structural evaluation. 6.2.1 Model, Geometry and Boundary Conditions The F/A ACLP hex duct nodel was formulated in the ANSYS finite element program so as to be compatible with the terperature distributions of the thermal model . The F/A ACLP geometry was taken to be identical to that used for the thermal analysis, except that the film coefficients simulating the C/A ACLP wall thermal resistance were deleted. . in formulating the F/A ACLP hex duct structural model, the ANSYS constant strain (STIF 2) structural element was used to replace the linear tenperature , (STIF 35) thermal element. The boundary conditions along the lateral surfaces of the 90 sector coincident with the global X and Y axies, in the manner of the conventional roller support, were taken to have zero normally disposed displacements. Coincident with the global X axis, the UY displacements at nodes 1 through 9 were set equal to zero. For the surface coincident with the global Y axis, the UX displacements at nodes 335 through 341 were set corners of the ACLP hex duct cross-section. With the 90' sector of the ACLP formulated in a plane strain condition, the local contact loads (F), F 2, F )3 were expressed in terms of a load / length basis by dividing each load by the 4 in. ACLP pad length. The F/A ACLP hex duct structural model is illustrated in Figure 6.2-1.
~~-167-~~
~~i jk~~
~~F 1~~
~~i U~~
~~d. ,~~
~~' I F~~
~~- 2~~
~~-Roller Supports~~
~~( UX335 + 341 = 0.0) F Roller Supports Element 59 3 . 3 (UY jg 0.0) N / Element k;~~
~~\ 1 7 , , , n ,-~~
~~Element 8 FIGURE 6.2-1 a F/A ACLP Hex Duct Structural Model, Geometry, and Boundary Conditions~~
~~-168-~~
6.2.2 Properties The F/A ACLP hex duct as constructed from first core 20 percent CW-316-SS ' 2 is initially unirradiated to a fluence (E > 0.1 Mev, (4t) = 0.59 x N/CM ) at E0L. The linear and non-linear properties of first core 20% CW-316-SS 4 under fluence and temperature with simolifications used in the F/A ACLP , hex duct analysis are described as follows. 6.2.2.1 Linear The linear 20% CW-316-SS properties including the Young's Modulus (E), Poisson's ratio (v), and coefficient of thermal expansion (a) are known ! to not significantly differ from SA-316-SS values. Accordingly, the first core 20% CW-316-SS properties used in the F/A ACLP hex structural analysis l were identical to the SA-316-SS properties identified for the F/A shield block described in Section 4.2.2.1. 6.2.2.2 Non-Linear The non-linear first core 20% CW-316-SS material property behavior required in the F/A ACLP hex duct structural analysis are the time independent stress-strain curves and the time dependent thennal creep , equations, and irradiation creep and swelling equations. 6.2.2.2.1 Stress Strain Curves Currently, stress-strain properties of irradiated first core 20% CW-316-SS are not extensively knwn as prior experimental effort has been primarily directed to N-Lot steel. The available stress-strain properties of first 22 2 core steel [11] are limited to fluence (E > o.1 Mev) of 3 x 10 N/CM over a temperature range from 1000 to 1200 F. As the ACLP hex duct E0L fluence 22 2 (E > 0.1 Mev) is 0.59 x 10 N/CM , the available data requires extrapolation in order to obtain irradiated first core 20% CW-316-SS sress-strain data for use in the F/A ACLP hex duct analysis. With regard to unirradiated first core 20% CW-316-SS stress-strain data, unirradiated N-Lot data is representative and was taken for the F/A ACLP hex duct analysis. .
~~-169-i~~
In constructing the F/A ACLP hex duct stress-strain @ich are compatible with the worst case duty cycles uniformly distributed over the first and second reactor cycles, a mean of true minimum BOL and the minimum E0L stress-strain values was taken. Minimum properties were selected to provide conservative inelastic stress and strain response because mechanical and thermal ACLP hex duct loads were assumed to be applied slowly in an essentially static manner. For elastic BOL and E0L response of the F/A ACLP hex duct, the Young's Modulus for unirradiated and irradiated first core 20% CW-316-SS was taken to be identical to the Young's Modulus for un-irradiated SA-316-SS as described for the F/A shield block in Section 4.2.2.1. In the following, the unirradiated and irradiated stress-strain data used in the F/A ACLP hex duct analysis are identified, t The average unirradiated engineering stress-strain aat.a Tcr N Int W CW-316-SS used to represent unirradiated first core steel in the inelastic response of the F/A ACLP hex duct is given in the NSM Handbook-[6]. Minimum unirradiated engineering N-Lot stress strain data was taken as 80% : of average values. The minimum engineering unirradiated proportional elastic limit stress (6PEL,u), yield stress (5Y,u), ultimate stress 4 (5u,u), and uniform elongation strain (Eu,u), where stress and strain is in units of KSI and in/in regectively, in terms of temperature (T S 'F) is given according to the relations. PEL,u = 0.80 "Y,u , 3 = 76.89 - 0.10*T + (1,208E-3)*T2 - (0.817E-5)*T3 + (3.04E-8)*T4 Y,u 8 [
~~- (6.75E-ll)*T5 + (0.931E-13)*T6 - (7.99E-17)*T7 + (4.14E-20)*T ;~~
10
~~- (1.lSE-23)*T9 + (1.42E-27)*T 2 4 B~~
~~u,u = 97.62 - (0.812E-1)*T + (6.67E-4)*T - (2.69E-6)*T3 + (4.98E-9)*T 6~~
~~- (4.58E-12)*T5 + (2.04E-15)*T - (3.46E-19)*T i~~
~~s I~~
~~-176-l l~~
~~1 i 4 Eu ,u = 0.104 + (4.81E-4)oT - (7.0E-6)oT2 + (4.33E-8)oT3 - (1.49E-10)oT 5 7 9~~
~~+ (3.0E-13)*T - (3.64E-16)*T6 + (2.70E-19)*T - (1.19E-22)*T8 + (2.89E-26)*T .~~
10
~~! + (2.95E-30)*T The minimum irradiated engineering stress-strain data for first core <~~
20% CW-316-SS used for the F/A ACLP hex duct at ECL fluence (E>0.1 Mev, 22 2 (4t) = 0.59 x 10 n/cm ) were taken from the available first core data [11]. The minimum irradiated engineering proportional elastic limit stress (5 p ,y), yield stress (5y,y), ultimate stress (au,1),and
~~! uniform elongation (Eu,I) in terms of temperature (T s F x 10-2) are as follows. ! PEL,I = 0.86 B y,;~~
~~2 5 f,y~~
~~= 60.596-0.817*T-0.0601*T 2~~
~~Gu,I = 78.92+3.68*T-0.47*T 2 3 E u,I~~
= 0.128+0.0108*T+0.000938*T -0.00018*T I In order to obtain true minimum stress-strain data from minimum engineering data for unirradiated BOL and irradiated E0L conditions of the F/A ACLP hex duct, the following relations between true stress and strain (o,c) and engineering stress and strain (5, E) were used. "PEL,u PEL,u u,u (I + u,u) u,u "PEL,I PEL,1 u,I (I + u,I) 0u,I y = - c u,u I" (I + u,u) '
~~Y,u Y,u o = 5 Y, I 'u,I I" (I + u,1) Y,I e~~
~~-171-3 - - - . - , _ _ . , ~ . . , . . _ . _ ,~~
o The mean of true minimum unirradiated BOL and true minimum irradiated E0L stress-strain for the F/A ACLP hex duct over a temperature rnage of 800 g to 1200 F are summarized in Table 6.2-1. TABLE 6.2-1 F/A ACLP HEX DUCT TRUE MINIMUM MEAN OF BOL AND E0L STRESS-STRAIN DATA l Temp. Young's Stress (PSI) at Total Strain (in/in) ( F) Modulus - --" 6 0.00178 0.00378 0.01 0.04 0.08
~~; (PSIX10 )~~
800 24.06 42830 55390 56900 62700 68500 900 23.31 41490 53940 55360 ; 60790 66220 1000 22.53 40100 51920 53290 58500 63800 1100 21.72 38660 48470 49810 54960 60100 1200 20.89 37180 43300 44650 49830 {55000 e 3 In order to illustrate the approach adopted to represent the mean of true minimum unirradiated B0L and irradiated E0L stress-strain data for the F/A ACLP hex duct during the worst case duty cycles, the respective l average, mininium, and mean stress-strain curves for first core 20% CW-316-SS at 1000 F are presented in Figure 6.2-2. I i -172-
~~- -, w m, g -,r- , ,e,,, . -,- - - - + , - - . -,,,--.s -~- ---~~
e :- y
1 i Average BOL Unirradiated Minimum BOL Unirradiated Minimum of Mean of E0L and BOL Average E0L Inadated 90000 Minimum EOL Irradiated 80000 - i . i 7 70000 - E . b -
~~, co - -~~
~~U' 60000 -~~
~~~ ,_ -'~~,
~~50000 -~/ . , .l .~. I/.~~
~~,'/~~
40000 f i . i . . i . . . . . . 0 .005 .010 .015 .020 .025 .030 .035 .040 .045 .050
~
c (Strain) FIGURE 6.E-2 F/A ACLP HEX DUCT FIRST CORE 20% CW-316-SS STRESS-STRAIN CURVES MINIMUM MEAN OF BOL AND E0L AT 1000'F e .
6.2.2.2.2 Thermal Creep Equations The thermal creep equations for irradiated and unirradiated first core 20% CW-316-SS are currently being developed and have not been placed into an approved form for use in the F/A ACLP hex duct analysis. However, thermal creep equations for unirradiated N-Lot 20% CW-316-SS are identified as the interim NSM Handbook relations [12] are available which tends to approximate first core steel thermal creep. Accordingly, the N-Lot 20% CW-316-SS thermal creep equations were used in the F/A ACLP hex duct analysis. The thermal creep equations for N-Lot 20% CW-316-SS are expressed in tems of a hoop strain (cc) and stress (c) as the experimental data was based on pressurized thin walled tubes. In applying the pressurized thin walled tube data to multiaxial stress states in the F/A ACLP hex duct, equivalent stress ( e) and strain (c )e were used according to the relations: e
=
and ce= 2_ cc 2 73 The thermal creep equations for hoop strain (c ) and strain rate (k) from the pressurized thin walled tube data is presented in both integrated and rate form. cc = Ao cosh-I (1 + rt) + Pc" t* + Qa" t dc l c= Acr + m Pc" t - + 2.5 Qa" t .5 dt 2 t2
\[2rt+r In applying the thermal creep equations to the worst case F/A ACLP hex duct duty cycle, the relaxation of thermal stresses occurs during the 10 day hold time. As the duty cycles are assumed to be successively repeated, it was desirable for the sake of conservatism to neglect the primary creep and only consider secondary creep. I s aver, the form of the thermal creep equations used to represent the pressurized thin walled -174-
tube data does not permit a separation of primary and secondary creep. Accordingly, both primary and secondary thermal creep were considered to A occur simultaneously in successive duty cycles. The approach is considered only slightly non-conservative as thermal creep was not expected to be significant at the steady state operational temperature of 1000 F. A , summary of the fi-Lot thermal creep equation for hoop strain (cc m %) nd stress (c m PSI), time (t s HRS), and temperature (T s K) are presented as follows. 3
~~-8.94451 4.331_4_x 10 T~~
~~in A = or q 1.07471 x 10~~
-1.3748 - I whichever yields the smaller v61ue of in A -2.99573 inr= or l.0114 x 109 - 3.70757 x 10 II 26 425.0 291.069 - 2 3 1 T T T whichever yields the larger value of in r 6.3 for T s 922.039*K (1200'F) n= or -124.593 + 0.283804T - 1.539 x 10- T ,
for T > 922.039 K (1200*F) 0.533 for T s 922.039 m= or ~5 f 44.5365 - 0.0954482 T + 5.17593 x 10 T' i for T > 922.039"K (1200 F)
~~-175-~~
8.965 x 10 35.3606 for T < 810.928 F (1000 F) - l In P = ' i er 12 1.35198 x 107 + 1.17285 x 1010 - 3.39674 x 10 5131.26 2 3 T T T for 1033.15"K (1400*F) 3 T z 810.928'K (1000*F) 5 8
~~-453.917 + 5.91409 x 10 - 2.39794px 10 T T l~~
~~for T < 810.928 K (1000*F) inQ= or~~
~~- 89.2335 for 866.483 K (1100*F) 3 T 3 810.928 K (1000*F) ,or 8 . 9 91 x 10 6 9.52226 x 10 1179.06 - .~~
~~T T 4 for 1033.15 K (1400 F1 : T t 866.483 K (1100'F) s 4~~
~~-176-a~~
i 6.2.2.2.3 Irradiation Creep and Swelling Equations The irradiation creep and swelling equations for first core 20% CW-316-SS . are currently being developed and have not been ;;%ced into an approved l fann for use in the F/A ACLP hex duct analysis. However, irradiation ' a : creep and swelling equations for N-Lot 20% CW-316-SS are available which l tend to approximate first core steel irradiation creep and swelling i behavior and were used in the F/A ACLP hex duct analysis. The irradiation creep equations for N-Lot 20% CW-316-SS include both deviatoric and dilational effects. The equivalent deviatoric creep strain (c s in/in) is related to the equivalent stress (i s psi) according to 1, the relation: f 7/7 = A [1-e-f/b] + cf + 0 S g 4 where; A[1-e-I/D] = Primary creep term i
~~cf = Secondary creep tenn~~
; DS g = Swelling Tenn In the worst case F/A ACLP hex duct duty cycle, the relaxation of thermal ,
i stresses by irradiation creep occurs during the 10 day hold-time. However, ') the ACLP hex duct region is exposed to an insignificant E0L fluence (E>0.1 Mev, (et) = 0.59 x 10 22 n/cm ) and little, if any, stress relaxation 2 j due to irradiation creep and swelling would be expected. In order to simplify the time dependent analysis as well as providing slightly con-servative creep damage results, irradiation creep and swelling were neglected. The effects on time dependent elastic / plastic / creep instability
~~and functional limits which would be enhanced by including irradiation~~
~~! creep and swelling were not considered significant. i~~
~~-177-i~~
6.2.3 Worst Case Duty Cycle Response The structural response of the F/A ACLP hex duct to the first and second worst case duty cycles required the selection of reference temperatures compatible with the temperature distributions at the worst case through the wall temperature differences and axial constraints prior to deriving the time independent and dependent solutions. A description of the analysis and solutions which are required in subsequent structural evaluation is as follows. 6.2.3.1 Constraints and Reference Temperature Selection The F/A ACLP hex duct structural model corresponds to a 90 sector of a lateral slice taken through the length of the ACLP cross-section. Axial constraints normal to the 2 dimensional 90 sector reasonably simulate a plane strain condition as the length of the ACLP is comparable to the corresponding cross-sectional dimensions. Accordingly, the F/A ACLP hex duct was considered to be in a plane strain condition for the purposes of analysis. The method of selecting a reference temperature in relation to an arbitrary temperature distribution imposed in an ANSYS plane strain model was described for the F/A shield block in Section 4.2.3.1. Using the same method for the F/A ACLP hex duct, the reference temperatures for the recommended cumulative
~~- iterations in the worst case duty cycle are summarized in Table 6.2-2.~~
TABLE 6.2-2 F/A ACLP Hex Duct Reference Temperatures Tempera ture I Reference l Distribution Temperature (Cum. Iter.) (TR' I) 2 948.4 32 1072.7
~~-178-0~~
~~- . _ - = - . . _ _ . - . ._ . .- - .__ -. . .-~~
6.2.3.2 Analysis and Results The ANSYS inelastic analysis of the first and second worst case duty cycles < was arranged in time independent and dependent loadings. The first worst case duty cycle time independent loads included the initial steady state thermal and steady state core restraint loads, the E-16 transient thermal and transient core restraint load, 2 successive peak SSE loads at maximum E-16 transient thermal and transient core restraint loads, and a return to i final steady state thermal and core restraint loads. A 10 day hold-time under steady state thermal and core restraint loads comprised the time dependent loads of the first worst case duty cycle. The second worst case duty cycle time independent loads were identical to those of the first duty cycle except that the SSE loads were not repeated. The time dependent loads for the second worst case duty cycle were identical to those of the first duty cycle. In order to follow the path dependent ACLP hex duct structural response to the first and second worst case duty cycles, the ANSYS restart option was i used. In addition, the ANSYS small strain-large deformation option was used in the event that the deformations associated with the mechanical core restraint and SSE seismic loads were sufficient to initiate the collapse of , the F/A ACLP hex duct due to elastic / plastic / creep instability. i
~~6.2.3.2.1 First Cycle - Time Independent ,~~
The F/A ACLP hex duct structural response to the time independent loadings of the first worst case duty cycle was obtained in 20 sequential ANSYS load i steps in combination with the restart option. The first cycle time independent i loadings were considered as static loadings applied at zero time. A summary of the time independent thermal and mechanical loadings for the first cycle
~~time independent analysis is presented in Table 6.2-3.~~
~~k t~~
~~-179-~~
~~TABLE 6.2-3 o F/A ACLP HEX DUCT FIRST CYCLE TIME INDEPENDENT ANALYSIS~~
~~SUMMARY~~
INITIAL STEADY STATE, E-16 TRANSIENT / MECHANICAL LOADS, AND FINAL STEADY STATE e I' Load Iterations Temperature I Reference I Mechanical l Description 1 Step Distribution Temperature! Loads , ( F) ( F) I (F), F2 , F3) 1 1 948.4 948.4 None Initial Steady State 2 1 Cum. Iter. 2 948.4 None I (0.0 sec) : 3 1 Cum. Iter. 2 948.4 CR 4 1 948.4 948.4 l CR ! 5 1 1072.7 1072.7 CR ' E-16 Transient f 6 1 Cum. Iter. 32 1072.7 ! CR (90sec) ! j 7 1 Cum. Iter. 32 1072.7 l CR E-16 Transient i 8 5 Cum. Iter. 32 1072.7 CR + 0.5 SSE (90 sec) First Cycle of
~~9 9 Cum. Iter. 32 1072.7 CR + 1.0 SSE SSE Loads i~~
10 1 Cum. Iter. 32 1072.7 lCR+0.5SSE i 11 1 Cum. Iter. 32 1072.7 ! CR i E-16 Transient 12 1 Cum. Iter. 32 1072.7 ! CR (90 sec) 13 1 Cum. Iter. 32 1072.7 CR + 0.5 SSE Second Cycle of SSE Loads i 14 2 Cum. Iter. 32 1072.7 CR + 1.0 SSE 15 1 Cum. Iter. 32 1072.7 .CR + 0.5 SSE 16 1 Cum. Iter. 32 1072.7 CR l 17 1 Cum. Iter. 32 1072.7 : CR E-16 Transient I
1 18 1 1072.7 1072.7 ! CR (4050sec) i 19 1 948.4 948.4 CR , Final Steady State 20 1 Cum. Iter. 2 948.4 CR (7650 sec) l
~~-180-o~~
The F/A ACLP hex duct structural response to the first cycle tine independent loadings was obtained with a plastic convergence ratio of 0.01. The detailed - stress-strain response at each of the converged solutions was saved on ANSYS Tape 10 for subsequent recall in structural evaluations. The initial and final first cycle time independent steady state maximum equivalent stresses were found to be 24,038 and 20,082 psi respectively. During the E-16 transient, the maximum equivalent stresses at the cumulative iteration 32 temperature distribution with the first peak SSE loads was 46,168 psi. The peak non-uniform deformation was found to be 0.01256 in at cumulative iteration 32. The initial and final steady state non-uniform deformations were 0.00187 and 0.00245 in, respectively. Computer plots of equivalent stress and peak non-uniform deformation are presented in Figures 6.2-3 through -5. 1 1 l l e l 1 -181-
~
1 l
l 1 < l l i 1 24,038 psi % l f_ ,- - ._ -_.... _ _ _ - --* : 's j g T- - - - - - _ _ ...., ', 0.00187 in. 's ' i s s ! \
)
~~l, , l l y\ N l~~
\ l \ \ \ \
} i 1 i j i FIGURE 6.2-3 l F/A ACLP HEX DUCT I FIRST CYCLE - TIME INDEPENDENT 4 INITIAL STEADY STATE EQUIVALENT STRESS AND PEAK NON-UNIFORM DEFORMATION
~~-182-i .~~
l 3
46,163 psi -
~~.1 _ _.- - - - - - - ,~~
~~p s, s - - - - N~~
\
~~O.01256 in. \ -~~
\ - \ \ \ \ \ \ \ .
t.. . . FIGURE 6.2-4 F/A ACLP HEX DUCT FIRST CYCLE - TIME INDEPENDENT CORE RESTRAINT AND SSE LOADS WITH CUMULATIVE ITERATION 32 TEMPERATURE DISTRIBUTION EQUIVALENT STRESS AND PEAK NON-UNIFORM DEFORMATION .
~~-183-~~
~~I e l l 1~~
~~-20,082 psi ? 5-----.., z.-~~
~~4 -~~
- - - -__., s ,- , s 0.00245 in. s \
x\
\ \ \ \ \ . 't . .
~~FIGURE 6.2-5 F/A ACLP HEX DUCT FIRST CYCLE - TIME INDEPENDENT FINAL STEADY STATE EQUIVALENT STRESS AND PEAK NON-UNIFORM DEFORMATION e~~
~~-184-~~
6.2.3.2.2 First Cycle - Time Dependent The F/A ACLP hex duct structural response to the tire dependent loadings of , the first worst case duty cycle was obtained in load steps 21 through 23 with an ANSYS restart from load step 20 of the first cycle time independent analysis. A creep tine step of 5 hours was used initially to follow the primary creep and increased to a 10 hour time step for the remainder of the 10 day hold time. Subsequent ANSYS restarts were nade for load steps 24 through 26 to obtain the residual deformations af ter the first worst case duty cycle. A sumnary of the first cycle time dependent nechanical and therral loadings is presented in Table 6.2-4 TABLE 6.2-4 F/A ACLP HEX DUCT FIRST CYCLE TIME DEPENDENT ANALYSIS SUSNARY 10 DAY HOLD-TIME AND UNLOADING
'L'o a d Iter. Time Temperature Reference Mechanical Description Step (Hrs.) Distribution Temperature Loads ; (*F) -
~~(*F) (F), F2 , F3) _ _ _ _ __a__ ___ _ _ 4 21 1 0.0 Cum. Iter. 2 948.4 CR~~
- 10 Day 22 6 i 30 Cum. Iter. 2 943.4 CR Hold-Time 23 21 240 Cum. Iter. 2 948.4 CR 24 1 240 Cum. Iter. 2 948.4 CR Unicading -
25 1 240 948.4 948.4 None For Residual f Deformations 26 3 240 94S.4 948.4 None The F/A ACLP hex duct structural response to the first cycle time dependent loading was obtained with a creep convergence ratio of 0.25. The detailed l stress-strain response was saved on A' ai3 Tape 10 for subsequent recall in structural evaluations. The F/A ACLP hex duct structural response at the end of the 10 day hold-time, designated as the tine dependent final steady state condition, was not found to significantly differ from the tire independent final steady state response because of negligible relaxation
~~-185-~~
of stresses and deformations under primary and secondary thermal creep. The maximum equivalent stre'ss and peak non-uniform deformation in the F/A ACLP hex duct at the first cycle time dependent final steady state condition were found to be 17,915 psi and 0.00267 in. as illustrated in Figure 6.2-6. With regard to the residual stresses and deformations of the F/A ACLP hex i duct, maximum values of 18,605 psi and 0.00055 in, were found for the first worst case duty cycle as illustrated in Figure 6.2-7. 't 4 9 D I
~~-186- I i~~
~~i i 4 I i l l~~
~~- 17,915 psi I~~
~~L ;________, ( f y'y - - _ _ _ __.., 's, s~~
~~,f ,~~
~~s \ l~~
~~'N O.00267 in. \~~
g
\
i
\ \ '
~~g\ \~~
~~\ \~~
i.. . . FIGURE 6.2-6 F/A ACLP HEX DUCT FIRST CYCLE - TIME DEPENDENT FINAL STEADY STATE t i EQUIVALENT STRESS AND NON-UNIFORM DEFORMATION
~~-187-l - -- -- a,--, - - - . . - ,.. _ __ _ _,_~~
4
~~' l l~~
~~l l i 1 l 18,605 psi - .. , 1 .- - - - __~~
'y y : ,'s - -...., r \ ' \
l
' O.00055 in. \ g \ \ \ \ \ \ \ \ \ .
~~i FIGURE 6.2-7 1,, F/A ACLP HEX DUCT FIRST CYCLE - TIME DEPENDENT UNLOADING FOR RESIDUALS EQUIVALENT STRESS AND NON-UNIFORM DEFORMATION~~
~~-188-A~~
~~l l 6.2.3.2.3 Second Cycle - Time Independent The F/A ACLP hex duct structural response to the time independent loadings ,,~~
) of the second worst case duty cycle was obtained in load steps 27 through 30 with an ANSYS restart from load step 26 of the first cycle time dependent j analysis. The second cycle time independent loadings were considered as .
~~static loadings applied at 240 hours. A summary of the time independent thermal and mechanical loadings for the second cycle time independent analysis~~
~~; is presented in Table 6.2-5.~~
1 i TABLE 6.2-5 I F/A ACLP HEX DUCT j SECOND CYCLE TIME INDEPENDENT ANALYSIS
~~SUMMARY~~
~~INITIAL STEADY STATE, E-16 TRANSIENT, AND FINAL STEADY STATE 1~~
i
'I.oa d Iter. Tem %rature Reference Mechanical Description Step Distribution Temperature Loads j
( F) (*F) (F), F2 , F3) 27 1 1072.4 1072.4 CR l E-16 28 3 1072.4 1072.4 CR Transient i . _ _ _ _ _ . . . _ . . . _ . . _ . . . _ _ _ _ _ . . . . _ _ _ _ . _ .. . (90_ s e.c ) .
; 29 1 Cum. Iter. 32 1072.4 CR Loading and 30 1 1072.4 1072.4 CR Unloading ,
I. The F/A ACLP hex duct structural response to the second cycle time independent loadings was obtained with a plastic convergence ratio of 0.01 and saved on ! ANSYS Tape 10 for subsequent recall in structural evaluations. During the l E-16 transient, the maximum equivalent stress was found to occur at the cumulative iteration 32 temperature distribtuion with a value of 27,063 psi. , The maximum equivalent stress at the final steady state condition was found f to be 17,908 psi. The peak non-uniform deformations at the cumulative iteration 32 temperature distribution and final steady state condition were l found to be 0.00273 and 0.00267 in respectively. Computer plots of equivalent I stress and peak non-uniform deformation are presented in Figures 6.2-8 and -9.
~~-189-i.~~
~~. L...~..... . . y \ ,.\ \,~~
s
~~\\ \~~
~~s\g~~
\\\ \, \\ \ - - 27,063 psi \ \ -f a
~~3- - - - - ____ , [O.00273in.~~
~~'s \~~
g
~
9
~~\ \~~
~~g\ \~~
~~\g \ .~~
g
~~' l. . .~~
~~FIGURE 6.2-8 F/A ACLP HEX DUCT SECOND CYCLE-TIME INDEPENDENT CUMULATIVE ITERATION 32 TEMPERATURE DISTRIBUTION~~
~~, EQUIVALENT STRESS AND PEAK NON-UNIFORM DEFORMATION l -190- ;~~
l i t ;
r"--*'-~~'--~'~N. e s.
~~t. . .. a... . . . . . . . - . . . , .~~
*:l \, .
~~s, s~~
~~-s x.\ \ s \ \~~
~~s h g~~
,.... \. . 4 .\. \' \ \\ 17,908 psi . \
~~hb a [-----.-_._....,s, ,~~
- 's / s \ s O.00267 in. \
n.
~. \ \ \ . \ \ \ \ .
~~S.* *.~~
~~.\ .,~~
~~s . . i...~~
~~. FIGURE 6.2-9 ~~~
~~F/A ACLP HEX DUCT SECOND CYCLE-TIME INDEPENDENT FINAL STEADY STATE EQUIVALENT STRESS AND NON-UNIFORM DEFORMATION~~
~~-1 91 -~~
6.2.3.2.4 Second Cycle - Time Dependent The F/A ACLP hex duct structural response to the time dependent loadings of the second worst case duty cycle was obtained in load steps 31 through 34 with an AflSYS restart from load step 30 the second cycle time independent analysis. A creep time step of 10 hours was maintained throughout the 10 day hold-time. A subsequent AfiSYS restart was made from load step 34 to obtain the residual deformations after the second worst case duty cycle. A summary of the second cycle time dependent mechanical and thermal loadings is presented in Table 6.2-6. TABLE 6.2-6 F/A ACLP HEX DUCT SECOND CYCLE TIME DEPEtlDENT AtlALYSIS
~~SUMMARY~~
l l_0 DAY HOLD TIME AND UNLOADING (Load t Iter., Time Temperature ' Reference : Mechanical Description Step (Hrs.) Distribution : Temperature i Loads ' ( F) ( F) '(F), F2 , F3) 31 1 240 948.4 948.4 CR iInitiate and 32 3 240 948.4 948.4 CR l hold for
, 33 1 240 Cum. Iter. 2 948.4 CR i ten days 34 24 480 Cum. Iter. 2 948.4 CR 35 1 480 948.4 948.4 None Unloading for Residual . Deformations The F/A ACLP hex duct structural response to the second cycle time dependent loading was obtained with a creep convergence ratio of 0.25 with the stress-strain response saved on ANSYS Tape 10 for subsequent recall in structural ,
evaluations. The maximum equivalent stress and peak non-unifom deformation in the F/A ACLP hex duct at the second cycle time dependent final steady state condition were found to be 17,498 psi and 0.00272 in. as illustrated in Figure 6.2-10. i With regard to the residual stresses and deformations of the F/A ACLP hex duct, maximum values of 18,786 psi and 0.00083 in. were found for the second duty cycle as illustrated in Figure 6.2-11.
~~-192-L~~
m e .c. - e-~c. - %'*
~~l_ .. . . . , ,-a . . t. . w i..~~
~~\ s s .. \ \~~
~~T \~~
, s \ \ \\ \, 17,498 psi y
~~b J ._ - - - - - _ _ _ _ j j~~
~~,/ 'A - ------___.-.., s, x 's %~~
~~i s s~~
~~\ \~~
~~0.0027E in. \~~
~~\ \~~
g\
\ \ \ \ - - i s
~~l.. FIGURE 6.2-10 F/A ACLP HEX DUCT SECOND CYCLE-TIME DEPENDENT FINAL STEADY STATE~~
~~- l EQUIVALENT STRESS AND NON-UNIFORM DEFORMATION -193-~~
~~r.i: : . :2W~ u _ ...... . . . : . . . .r. s~~
, S,A, ',\ o A.' %\x \. N 18,786 psi # . . . ,, N, s \ \ \
~~0.00083 in. s s \-~~
~~\ \~~
N
\ \ \ \ . \ ., \.. .
~~FIGURE 6.2-11 F/A ACLP HEX DUCT SECOND CYCLE-TIME DEPENDENT UNLOADING FOR RESIDUALS EQUIVALENT STRESS AND NON-UNIFORM DEFORMATION~~
~~-194-i~~
~~< J~~
~~..- ..r.. .s..s.. .., ,1 :..... l...i. .-. ..~~
Tre F/A *:L: cex du:: stru: ural evaluation was arranged to cr0 vide a cc aris n of :"e stra : ural res;:nse for ne 39 worst case duty cycles in relati:n :: criteria anicn Or:te:: agair.s: Orack initiatien and excessive Oef:r aticn fail;re c:es and :nereby assure F/A A LF r.ex du:: cver the
~~'. i r s *. = e. .d s a. . w- . '. r a. .= . . s r . , .- l a. s .~~
Tne ;rc;edure for perferring :te F/: CL tex 0;;; structural evaluation *
~~.1 . se. , r a_ .- e. rc. - . .. . ,..o . . . s a. . s. e. . .. e. . . a_ . -~~
~~s n t a. ; .s 8lo.rt ,~~
~~..% ir r -..~~
~~m v..3a.. . no.~.~ 3 e a ""*" i r. . . .>*.~~
~~~ *.e..a. s *. r .* . . ". r .a 'i e. a. s , ^,*. s e #. .- r. *..* a_ #. i r s '. = .r. .d 3a. . .- a~ .d w. r. s *. v .= s a. . . ,~~
cyc,es "ad ic te Dine . Tne cc-bination was race cy considering one of tre first caty cycles and 35 of the se::nd c;;y cycles so as to obtain A - .a. s s- r i .- *. i caa ." #. F,/ A
.... a. r. a. . u i r. a. s. . . .,1 . . r.e. a :. a .6r s *. .- =.> a. d u *.,~ . .y" . l a. s . *CL: str;;: ural evaluation is presented as folicas.
~~6.3.1 Crack Initiation~~
~~-CLr rex d;ct stru: ural evaluatice,-o . cra:.( initiation in relation .ne . r n.~~
c 10:a1 du: tile r;;;ure and cc cir.ed cree -fatigue da age criteria over tne 39 aces: case d;;y cycles is : resented in the folicwing subse::icns. 5.3.1.1 L: al D;;;ile Ru::ure Tne 10:31 ca: ile ru: ure criterien for protecting agains: trati initiation
~~r. a. . s. i ra. s *. r .= *. * .* = . .~ ~. .- . i. l a. r". s a. " ra. '..=-. .s r s.pg, It i "a. 'aa s s *.n. -a n .e. . i *.f-~~
~~. .=~~
~~a. .= . u^~~
~~..a. :t* =e~~
~~r. :. +aA .a.,-.~~
~~- t .s in.. in .. ., . s...~~
~~9 f : 4-. 'l~~
~~' Fax OrinC1:al)'~~
~~V.J Eg .. f pp V ., 3. j ., .s . v. s~ln~~
~~.~ r --~~
~~0 . . tr (c~Idx crinC1:3l e~~
~~'u, min qe -ir:-~~
w
In the following, the allowable uniaxial strains used in the F/A ACLP hex duct structural evaluation and comparison of results with the local ductile rupture factor criterion are presented. 6.3.1.1.1 Allowable Uniaxial Strains The F/A ACLP hex duct as constructed from first core 20% CW-316-SS is unirradiated at BOL. The E0L fluence (E>0.1 Mev) based on June 1977 data is 0.59 x 10 22 n/cm2 . In addition, the F/A ACLP hex duct temperatures range from 700 to 1150 F. The true uniaxial uniform elongation (cu, min) for irradiated first core 20% CW-316-SS used for the F/A ACLP hex duct was identical to that used for the CMP hex duct presented in Section 5.3.1.1.1.1. The fracture strain (cf min) f r unirradiated and irradiated first core 20% CW-316-SS used in the F/A ACLP hex duct struc-tural evaluation was taken from recommendations in the trial applications of the RDT Draft Criteria for Breeder Reactor Core Components [15-23] and is identical to that taken for the F/A shield block structural evaluation presented in Section 4.3.i.1.1. 6.3.1.1.2 Comparison with Criterion The F/A ACLP hex duct structural evaluation in relation to local ductile rupture considered the first duty cycle to occur only once while the second duty cycle was repeated 38 times. In determining the maximum principal strain for comparison with the local ductile rupture criterion, the peak strain components were taken from the combined mechanical and thermal loads in the first duty cycle while accumulated strain components were taken from the 29 repeated second duty cycles. The peak and accumulated strain components were computed separately for the first and second duty cycles using the damage processor and combined by hand to determine the ductile rupture factor (FDR) for the 39 worst case duty cycles. In the F/A ACLP hex duct, the maximum local ductile rupture factor (FDR) max during the 39 worst case duty cycles was found to occur at element 1, as identified in Figure 6.2-1.
~~-196-~~
~~= _ - .-. - . _ _ _ = _ . . ,- .. = . - . .-- _ _.~~
~~1 I For the first duty cycle at BOL, the peak strain components occurred under~~
~~- I ! the combined core restraint and SSE seismic mechanical loads, and the thermal loads corresponding to the cumulative iteration 3? temperature distribution f~~
of the E-16 transient. The local stress stats was found to have a triaxiality factor of -2.075 but was taken as unity for conservatism in the structural evaluation. For the local metal temperature of 1146 F, the> true minimum
~~; irradiated uniform elongation and fracture strains at E0L 'luence (E>0.1 Mev, L~~
~~22 2 (4t) = 0.59 x 10 n/cm ) were 0.100 and 0.134 in/in respectively. The peak~~
~~BOLstraincomponents(c(j)BOLwere:~~
~~P = '~~
, c xx 0.002757 (c * 'Yy -0.003618 )BOL < ' P y
xy
~~= 0.000612 'c z = -0.000832 In the second duty cycle at BOL, the accumulated strain components occur i~~
between initial time independent and final time dependent steady state condi tions . The local stress states were found to have negative triaxiality l factors, but were both taken as unity in combining the strain components. J j The difference between final and initial steady state, strain components (acfj)atBOLwere:
~~= 0.0000190 '~~
~~acfx "~~
~~= -0.0000100~~
) *
~~/ ac^YY '~~
~~(^'Aij )BOL I ay ^y= 0.0000020 A ac zz~~
~~= 0.0 i~~
~~! After a total of N= 39 worst case duty cycles, the peak plus accumulated strain components (c A) at EOL were: l P (cjj+A)EOL~~
~~I'Pij )BOL + (N-l)(^CA ij )BOL i~~
s
-197- - - - - - - - - - - . -_. _ __ _ _ _ . - - - . - _ . _ . _ _ . _ . _ - - - , - - - . _ . - - . . _ _ - , , , , . - , .- - . , , - - , , - , e--
~~'c PA = 0.003479i A " lc = -0.003998~~
~~('P+A}EOL ij L NA I y xy~~
= 0.000688 'c A = -0.000832 The EOL maxima. principal strain (cmax principal) based on the E0L peak plus accumulated strain components was:
~~c max principal = 0.00349 in/in Accordingly, the maximum local ductile rupture factor (FDR) max was found to be controlled by the fracture strain with a value;~~
=
(FDR) max 0.087 As (FDR) max < l.0, the F/A ACLP hex duct is not expected to experience . crack initiation over the 39 worst case duty cycles based on the local ductile rupture criterion. l i l
~~. -198-l l~~
( )
4 6.3.1.2 Creep-Fatigue Damags The creep-fatigue damage criterion in protecting against crack initiation requires that the combined creep-fatigue damage factor (FCFD) be less than unity at each point in the F/A ACLP hex duct.
~~. 7/3 Dc+DI il F = a/b = Minimum of CFD eO c+7/30)~~
In the following, the allowable limits for fatigue life and creep-rupture times used in the F/A ACI.P hex duct structural evaluation and a comparison of the results with the combined creep-fatigue damage factor criterion I are presented. 6.3.1.2.1 Allowable Limits The F/A ACLP hex duct as constructed from first core 20% CW-316-SS is unirradiated at BOL. The E0L fluence (E>0.1 Mev) based on June 1977 22 2 data is 0.59 x 10 n/cm . In addition, the F/A ACLP hex duct temperatures range from 700 to 1150 F. The fatigue life and creep rupture time relations used in the F/A ACLP hex duct structural evaluation were identical to those used in the F/A CMP hex duct structural evaluation presented in Section 5.3.1.1.1. The fatigue life and creep rupture time relations representative of F/A ACLP hex duct peak and steady state metal temperature at EOL fluence are illustrated in Figures 6.3-1 and -2 respectively. 4
~~-199-~~
~~l$ C~~
/
c Ee f E g 3$ O r ws og 7 6 7 y. _' r A* 9 : e ~a , o e 1 ,, U2 y g : 8 2 C ~~ o W E ++ / C~~
~~@ 1 %4 D +~~
~~O >- w W ec LaJ CL N CL E O~~
~~% J D~~
~~D E D U W E > b-O aC E C atC~~
~~- O CL E E A <C U W W N W e CL L F- E = E M U C W E A F- - W LA.~~
~~W U~~
~~Z W D C d = 0 L " J O W n Y 1. 3 O 1 9 9~~
~~~ ! t C>~~
~~3D OO 8 CO 04 3D o JN i l c~~
~~- O "~~~
~~l 1 l l ! m~~
~~' ' I I i e o '~~
~~f m m~~
~
~~e M R 3 O (tsx) o _201-~~
~~6. 3.1.2 . 2 Coccarison with Criterion The F/A ACLP hex duct structural evaluation in relation to the cc-bined creep-fatigue darage was based on the first duty cycle applied only ence s~~
while 3S of the second < duty cycles were considered. The creep and fatigue C darage factors (D , D') were corputed separately for the first and second duty cycles with the darage processor and cc-bired by hand to cbtain the l total corbined creep-fatigue darage factor (FCFD) for the 39 worst case duty cycles. In the F/A ACLP hex duct, the raxiru coctired creep-fatigue da-age factor (FCFD)rax during the 39 worst case duty cycles was found to occur at ele ent 59, as identified in Figure 6.2-1. f The fatigue da age factor (D j ) for the first duty cycle was found to be 0.0000154 while the fatigue darage factor (D2f ) or 33 of the second duty cycles was 0.0000186. Tre peak retal tercerature in both the first and second duty cycles was ll34 F corresponding to the E-16 transient cu ulative iteration 32 te perature distribution. Tne raxinc principal and equivalent strain ranges were found tc be critical in the first and second duty cycles respecti vely. For the first duty cycle, the raxiru : principal strain range was found to occur between the first ceak SSE load application and a uniforn te cerature distribution with a value of 0.00147 in/in. In the second duty
cycle, the raxiru equivalent strain range occurred between a unifom j terperature and the E-16 transient cu ulative iteration 32 te cerature dis-l tribution with a value of 0.000SS2 in/in. Based on the F/A ACLP hex duct 2
E0L fluence (E>0.1 Mev, (:t) = 0.59 x 10"" n/cn ), the fatigue cycles to failure for the raximm strain ranges of the first and second duty cycles 6 6 were 0.65 x 10 and 2.04 x 10 . Accordingly, the total fatigue da age
~~' i factor (D') in tems of the first cycle fatigue da age factor (D ) cortined I~~
~~f with the fatigue darage factor (D c) for the 38 second duty cycles. l 4 4 f 0 = Dj+Dj D = 0.0000154~~
0.0000186

e 1 D' = 0.0000340 l l
l
~~-202-~~
c The creep damage factor (D ) for the first duty cycle was found to be 0.000946 while the creep damage factor (Dl) for 38 of the second duty cycles was 0.0242. The steady state local metal temperature in both first and second duty cycles was 938 F. The maximum equivalent stress was found to be critical in both first and second duty cycles. In the first duty cycle with a duration of 240 hours, the initial and final time dependent maximum equivalent stresses were 17,059 and 14,177 psi. For the 38 second duty cycles with a duration of 9120 hours, the initial and final time dependent maximum principal stresses were 14,148 and 13,618 psi. Based on the F/A ACLP 22 2 hex duct EOL fnuence (E>0.1 Mev, (4t) = 0.59 x 10 n/cm),themeanminimum rupture times for the maximum equivalent stresses during the first and 6 6 second duty cycles were 0.254 x 10 and 0.377 x 10 hours . Accordingly, the c total creep damage factor (D ) in terms of the first cycle creep damage c factor (D)combinedwiththecreepdamagefactor(Dl)forthe38second duty cycles was c O = D c+Dj c = 0.000946 + 0.0242 D c D = 0.0251 9 In this arrangement, the maximum combined creep-fatigue damage factor (FCFD) max for the F/A ACLP hex duct is given by the realtion: d l i e 3 Dc+9f
~~= = Min mum of ?~~
~~(FCFD} max ' e DC + h D'~~
= 0.0108 (FCFD) max As (FCFD) max < 1.0, the F/A ACLP tex duct is not expected to experience crack initiation over the 39 worst case duty cycles based on the creep-fatigue damage criterion. -203-t -g.
6.3.2 Excessive Deformation The F/A ACLP hex duct structural evaluation of peak plus accumulated, and residual deformations in relation to functional limits over the 39 worst case duty cycles is presented in the following subsections. 6.3.2.1 Peak Plus Accumulated Deformations The peak plus accumulated deformation criterion in protecting against excessive deformations requires that peak plus accumulated deformations (6P+A) be less than the peak plus accumulated deformation limit (PADL). 4 P 6 +A < PADL The F/A ACLP hex duct peak BOL deformation (6 ) was 0.01256 in and occurred during the combined core restraint and SSE seismic mechanical loads and the thermal loads associated with the cumulative iteration 32 temperature distribution of the E-16 transient of the first duty cycle. A The accumulated BOL deformation (6 ) was based on the initial time independent and final time dependent steady state conditions of the second duty cycle. For the initial and final deformation values of 0.00267 and O.00272 in., the accumulated steady state deformation (A655) in the second duty cycle at BOL was 0.00005 in. For the 39 worst case F/A ACLP hex duct duty cycles, the E0L peak plus accumulated deformation (6P+A) is given by the relation P (3 ) E0L = (6 ) BOL + (N-1) (A6ss) BOL P (6 +A) E0L = 0.0126 + (38) (0.00005) P (6 +A) E0L = 0.0145 For the F/A ACLP hex duct, the peak plus accumulated deformation limit (PADL)is PADL = 0.082 in.
~~-204-~~
~~- _ . - - - - =. - .- . - - _ _ _ _- _ - . - - . .~~
i As 6P+A < PADL, the F/A ACLP hex duct is not expected to experience l ~ excessive peak deformation over the 39 worst case duty cycles. 6.3.2.2 Residual Deformations e > The residual deformation limit in protecting against excessive defomation , R ! requires that the residual deformation (6 ) be less than the residual deformation limit (RDL). ! 6R < RCL 1 R The F/A ACLP hex duct residual BOL deformations (6 ) after the first and second duty cycles were found to be 0.00055 and 0.00083 in. respectively. R Accordingly, the change in residual eformations (a6 ) in successive second duty cycles would be 0.00028 in. For the 39 worst case F/A ACLP hex duct l duty cycles, the E0L residual deformation is given by the relation. R R R (6 ) E0L = (6 ) + (N-1)(a6 ) R (6 ) E0L = 0.00055+38(0.00028) i R (6 ) EOL = 0.011 in. For the F/A ACLP hex duct, the residual deformation limit (RDL) across the # flats is 0.010 in. However, the RDL for a single hex duct flat is 0.005 in. As (6R) E0L > 0.005 in. , the F/A ACLP hex duct residual deformation at E0L approximated from the response of the first and second duty cycles at BOL is not acceptable. Accordingly, the response to a third duty cycle was derived using the same procedure identified for the second duty cycle. The F/A ACLP hex duct residual BOL deformation after the third duty cycle was 0.00086 in. For the 39 worst case F/A ACLP hex duct duty cycles, the E0L residual deforma-tion estimated from the second and third duty cycles at BOL is given by the relation.
~~205 I !~~
{
~~. . , _ _ , .- -._. .-...______..___= __ ._~~
~~R (6 ) E0L = 0.00083 + 37 (0.00086 - 0.00083) i~~
~~R (6 ) E0L = 0.00194 in.~~
As 6R< RDL, the F/A ACLP hex duct is not expected to experience excessive o residual deformation over the 39 worst case duty cycles. 6.3.3 Sumary The F/A ACLP hex duct was found to satisfy the er - k initiation and excessive l deformation criteria. A summary of the F/A ACLP ..ex duct structural evaluation is presented in Table 6.3-1. TABLE 6.3-1 F/A ACLP HEX DUCT STRUCTURAL EVALUATION SUfMARY l 1 Allowable Calculated Margin of Criteria Value Value Safety
l Crack Ductile 1 0.087 10.49

Initiation Rupture Factor Combined 1 0.0108 91.59
~~, Creep-Fatigue Damage Factor~~
! Excessive Peak + 0.082 in 0.'0145 4.65 Deformation Accumulated i Residual 0.005 in 0.00194 1.58 1
~~Margin of Safety = Allowable Value _)~~
~~. Calculated Value 206~~
~~... ..r~~
~~.1.,. m. _ 1.. .-- ,g . . 4 . .g ,, .._s . s h..: .. ..g...-....,g ... .?o , * .. = a. * /1. p.;.~~
.-. ...'.a.. .. is. * * - . 33 :e 1., 3 i 3 .s a .
~~4. , .3 '. ..3*i"., . . .1 3 -- .s .* i *.~~
~~3 -.3.,t.3-s~~
. -s . .3 *. c a. . q~ n . 3 .* 3..* **:.S. .p. . * -3.. .+ - ** ** e-a.. t .- * * .-3 * ...
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a. .re. . .
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e
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t
v. 3. e. 3 .- *. s. e..g5*.+-> . . ~ -~~~2.<<** + .5 .< . , t
., ; t. >. s.. .. . ,*.2 . ....g. ** .. . . . *a. . 4. . *.2 . es. .
~~3... zc.~~
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I '"
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g .g .e. g =. mw . . g3.3 *G...
~~5 Tc* " . * .~~
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5
~~g e e s. 4. <~~
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~~rs.~~
a. .* . - . s. .t...* 3, *

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A.
**. 3 g r+ e.t *. * .3.;2 * ..*.q ~ * , a. , **3* y. og.6 3g *g.***-
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~~a..;~~
~~.,g.- . w. . . **g p. .eg > 3 3 .m~~
~~g .p .**. e. . .. ) . * *. a ...,~~
gg* .qg eas.ma.g 3.,*
. ~ .3.,,*.g* . . w.-e 3 m .e . ..- .. . *- 2 . 6..*q .. z. ...e .iiig.. . . 6pe .
~~e.. s. - e i e .z *. 3**. .z. :. . ,= e s. .t .= *..* * .,4 s.'s a. .t . *' s..- s...%e.% e.~~
~~3 e,.4 m, .3 e .g...~~
.
~~g..e ., q a. . = *.)~~
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*a **2 .. ( .* . ?. *. g*t - *.
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SSE seismic, and core restraint are relatively insignificant. However.
- in relation to thermal steady state and transient loads, even internal pressure loads are insignificant. Accordingly, mechanical loads were neglected in establishing the worst case F/A outlet nozzle duty cycle for the first and second reactor cycles.
7.1.2 Thermal The F/A outlet nozzle thermal loads are the steady state and transient temperature distributions that occur during the Upset, Emercency, and Faulted events over the first and second reactor cycles. The steady state F/A outlet nozzle inside metal temperature distributions throuchout Sector A of the core at B0C 1. E0C 1, BOC 2, and EOC 2 and the Upset, Emergency, and Faulted transients defined in terms of time-dependent scale factors applied to the steady state inside metal temperatures were considered. In this arrangement, the F/A outlet nozzle thermal loads in terms of inside metal temperatures associated with BOC 1 E0C 1, B0C 2, and E0C 2 steady state conditions as well as during Upset, Emergency and Faulted transients were identified at any F/A location in the core.
In order to proceed with a structural evaluation of the F/A outlet nozzle, it was desirable for the sake of simplicity to consider only the worst case thernal loading. Accordingly, all F/A located in Sector A of the o core were assessed in relation to the maximum inside metal wall temoerature difference between & F/A and adjacent C/A or R8/A. The maximun steady state inside metal wall temperature difference was found tooccuratF/AA!adjacenttoRB/AA during BOC 1 with a value of 214*F. It is important to note that at EOC 1, BOC 2 and E0C 2, the respective inside metal temperature differences were found to decrease from BOC 1 values. As such, the BOC 1 maximun steady state inside retal temperature difference of 214*F between a F/A and adjacent RB/A was clearly worst case for all F/A outlet nozzles in the core over the first and second reactor cycles.
~~208~~
~~. .. _ . _ . _= _ _ _ - - . _ - - . - - - _ -~~
I With regard to F/A and adjacent RB/A outlet nozzle thern'al transients, the Equipment Specification [1] using an umbrella approach identified the number of Normal Upset, Emergency, and Faulted transients over the first - 4 and second reactor cycles as 1/15 of the number specified for 30 years rounded to the next whole number. Over the first and second reactor
cycles comprising a total of 328 FPD, a total of 39 Upset transient events f umbrellaed by the worst of U-2b or OBE were specified. Similarly, the worst of the E-16, 60c Step, or U-2b during OBE were specified to umbrella i the Emergency Transients whilc the SSE was identified to umbrella the Faulted Transients.
4 ! In the derivation of the F/A and adjacent RB/A inside metal temperature l transients for the Upset, Emergency, and Faulted events, the identified i upper and lower bounds for the Upset U-2b and OBE events and the 1 Emergency 60c step event. The upper bounds were based on quickest flow decay and maximum decay heat while the lower bounds were based on slowest i flow decay and minimum decay heat. Further, the SSE Faulted Transient was found to be umbrellaed by the Emergency E-16 transient. The Upset l transients comprising the upper and lower bound U-2b and OBE, and the ! Emergency Transients including the upper and lower bound 60c step, E-16, and U-2b during OBE are based on June 1977 loads. , i In order to reduce the number of F/A outlet nozzle transients which , i umbrella the Upset and Emergency Transients to a single worst
! case transient, the individual transients were assessed for severity in subsequent structural evaluations by comparing the inside metal wall temperatures in terms of maximum value, rate of temperature change, and j range. With regard to steady state conditions, all transients were initiated with F/A and RB/A inside metal wall temperatures of 1076 and
! 862*F which provide the worst case temperature difference of 214*F. For the Upset transients at the F/A outlet nozzle inside metal surface, the upper and lower bound U-2b transients were assessed as slightly more severe in terms of maximum temperature with maximum rate i and range of temperature indistinguishabla from the upper and lower bound L
~~-209-~~
OBE transient. However, the adjacent RB/A inside metal temperature transients for the lower bound U-2b were observed to more closely follow the F/A metal transient than in the case of the upper bound U-2b. Owing to the thermal lag in the thick walled F/A outlet noz:le, temperature
~~, differences through the wall, which are important in structural evaluations, l~~
are more severe in the lower bound U-2b transient than the upper bound counterpart. With regard to the Emergency transients, the E-16 transient in terms of maximum value, rate of temperature change, and range was found to be clearly more severe than the upper and lower bound 60c step, and the U-2b during 0BE transients. Further, the E-16 was also considered I more severe than the lower bound U-2b transient. In this arrangement, the , l Emergency E-16 transient was selected as the worst case umbrella to all ( the Upset, Emergency, and Faulted transients for the F/A outlet nozzle and is illustrated in Figure 7.1-1. 1 The selection of the Emergency E-16 transient as the worst case F/A out-let nozzle transient is, in itself, not sufficient to establish the worst case F/A outlet nozzle duty cycle. Thermal conditions following the E-16 transient and subsequent hold-times at steady state conditions are also required. The thermal conditions selected consisted of a cool-down l to 600 F in 1 hour from the F/A and RB/A inside metal wall temperature at 450 seconds into the E-16 transient, followed by a 1 hour heat-up to initial steady state F/A and RB/A temperatures. Thereafter, a 10 day hold-time at steady state temperatures was assumed. The 10 day hold time corresponds to 40 worst case E-16 transients unifonnly distributed over 400 FPD which is slightly greater than the 328 FPD specified for the first and second reactor cycles. The worst case F/A outlet nozzle duty cycle is presented in Figure 7.1-2. The worst case F/A outlet nozzle duty cycle in terms of inside metal temperatures at initial steady state, followed by the E-16 transient, thermal conditions in returning to initial steady condition, and 10 day hold-time are not sufficiently detailed for subsequent structural evalua-tion. In the following, the F/A outlet :ozzle thermal model and geometry, l 1 ! -210-
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700 i Time 1 Hour 1 Hour 10 Day
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Cool-Down ~ Heat-Up Hold Time Fiqure 7.1-2 F/A Outlet Nozzle Worst Case Duty Cycle '
l l i: l f boundary conditions and wetted sodium surfaces, heat generation rates, , and themal analysis and results are described from which conclusions on detailed temperature distributions used in subsequent structural analysis l are presented, . 7.1.2.1 Hodel and Geccetrv_ t
~~! The F/A outlet nozzle nodel was formulated in the A'iSYS finite element program. The ANSYS program has cocpatibility between therral and~~
{ structcral elements which permits thermal solutions of ter;;erature j 4 distritutions to be used directly in sesequent structural analysis. The F/A outlet nozzle region selected for analysis corresponds to a !- l 2 dimensional slice of a symetrical 30* sector taken through the fluted ! pattern provided to protect the fuel rods from inadvertant placement of RB/A. As the worst case F/2 stlet nozzle duty cycle includes adjacent , j RB/A inside metal wal) te'eperatures, a flat slab simulation of the RB/A j was also included in the thamal codel. The 30* syretrical sector is
~~justified as outlet sodium flow and heat generation rates are uniform.~~
The F/A outlet nozzle thermal rodel illustrating the dirensional extent i and finite element detail is presented in Figure 7.1-3. -t [ j f L l s 1 2 , e
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The F/A outlet nozzle thermal model as formulated in the ANSYS program included a total of 149 linear temperature (STIF 35) elements in a mesh of 366 node points. The F/A outlet nozzle was modeled with 113 elements - while the simulation of the adjacent RB/A as a flat slab was modeled with 36 elements. The F/A and RB/A elements were assigned different element types in the thermal model so that the RB/A elements a could be deleted in the structural analysis solutions. A relatively fine mesh was selected at the wetted sodium surfaces of the F/A outlet nozzle so as to include the thermal skin response to the thermal transients. 7.1.2.2 Properties The F/A and adjacent RB/A outlet nozzles are both constructed from SA-316-SS. The thermal conductivity (K), specific heat (c), and density (p) properties used in the thermal analysis were identical to those used for the F/A shield block as presented in Section 4.1.2.2. 7.1.2.3 Boundary Conditions and Wetted Surfaces The F/A and adjacent RB/A boundary conditions and wetted surfaces selected in the thermal analysis are illustrated in Figure 7.1-4. Boundary conditions for the thermal analysis consisted of adiabatic conditions along the lateral surfaces of the 30 F/A outlet nozzle and the flat slab simulation of the RB/A outlet nozzle. Conductive conditions a were assumed at the sodium interstice between the exterior surfaces of the F/A and RB/A. Owing to the relatively high thermal conductivity (Ks) of sodium in combination with the small interstice gap (G), the effective film coefficient (h = Ks/G) is high. Accordingly, the node points along the F/A and RB/A exterior surfaces were locally coupled to each other in the thermal analysis. The F/A node 13 was coupled to the RB/A node 300, and so forth along the sodium interstice as follows.
~~-215-s~~
. + , * . . RB/A Metal Temperature Nodes / Adiabatic (306 - 366, inc.10) [ Lateral Surface / I l Sodium Inter-face Nodes f [ 13 + 133,inc. 20 g ,i 300 + 360, inc.101 '
~~/ \~~
~~i 1~~
~~,. # N.~~
~~hY F/A Metal Temperature / Nodes ' 1 ~241, inc. 20) i { (241 - 244 Jg f~~
~~. Adiabatic - Node 1 - Node 13 Lateral Surface Figure 7.1-4 F/A Outlet Nozzle Boundary Conditions and Wetted Surfaces~~
~~' 13 = 300 '~~
33 = 310 53 = 320 - F/A RB/A 4 73 = 330 > 93 = 340 113 = 350 . s133 = 360 s The wetted interior surfaces of the F/A and RB/A were assumed to respond immediately to the respective inside metal wall temperatures of the worst case F/A outlet nozzle duty cycle. Local variations in wetted interior surface temperatures were neglected. Instead, all F/A outlet nozzle interior surface node point temperatures were globally coupled to each other and included nodes 1 through 241, in increments of 20; and 241 through 244. Similarly, the interior surface node point temperatures for the flat slab simulation of the RB/A were globally coupled to each other at node points 306 through 366 in increments of 10. 7.1.2.4 Heat Generation Rates During steady state operation the F/A outlet nozzle is exposed to nuclear heating. Based on June 1977 Data, the maximum heating rate /per unit - volume is relatively uniform with a value of 0.038 watts /cc or 3 0.00059 BTU /in -sec. For the F/A outlet nozzle exposed to a heat generation rate (Q) with thermal conductivity (K) and wall dimension (L), the tempera- < ture difference (AT) is given by: AT = QL2 /2K (0.00059 BTU /in3 -sec) (2.33 in)2 AT = 2(2.87 x 10-4 BTU /in-sec- F) AT = 5.88 F For the F/A outlet nozzle, the steady state temperature difference (ATss) caused by sodium flow was 214 F. As AT a Tss, the effect of heat generation rate ',n the steady state temperature distribution is
~
~~small and heat generation rates were neglected in the themal analysis.~~
~~-217-~~
i 7.1.2.5 Analysis and Results The ANSYS thermal analysis of the F/A outlet nozzle was arranged to pro-vide detailed temperature distributions over the total worst case duty cycle. A total of 10 load steps were selected at prominent F/A and RB/A
~~inside metal surface temperatures. The first 7 load steps 'haracterized the initial steady state conditions and the E-16 transient to 450 seconds.~~
Load Steps 1 and 2 represent initial steady state conditions while Loads Steps 3 through 7 correspond to the E-16 transient. Load Step 8 corresponds to the 1 hour cool-down to 600 F. The return to final steady state tempera-tures with the 1 hour heat-up was accomplished in Load Step 9. The final steady state temperatures held for 10 days were obtained in Load Step 10. I Prominent load steps in the E-16 transient are illustrated in Figure 7.1-5 and numerical values for the full worst case F/A outlet nozzle duty cycle are presented in Table 7.1-1. TABLE 7.1-1 WORST CASE F/A OUTLET N0ZZLE DUTY CYCLE ANSYS INPUT DATA Temp. ( F) Load Step Time (Sec.) F/A RB/A 1 0.0 1076 862 2 0.0 1076 862 3 2 1085 865 i 4 12.5 885 780 5 90 1250 925 6 175 1100 860 , 7 450 1000 810
~~8 4050 600 600~~
~~, 9 7650 1076 862 4 10 900000 1076 862 i~~
~~, -218-~~
~~L i-Figure 7.1-5 f~~
~~1200 - 's' F/A Outlet Nozzle s~~
~~E-16 Transient Load Steps I l100 -~~
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w \' C' "' ~% ~ _ y f,1000 -' I Fuel Assembly t \ B t
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~~.M.~~
g 700 $ 0 50 100 150 200 250 300 350 400 450 Time (Seconds) e * $
The ANSYS solution of the worst case F/A outlet nozzle duty cycle was obtained in 79 cumulative iterations using a static and transient con-vergence criteria of 1 and 5 F respectively. The temperature distributions at each cumulative iteration were saved on ANSYS Tape 4 for recall in , subsequent structural analysis. In order to determine the cumulative iterations of interest in structural analysis, maximum and minimum through the wall temperature differences are most important in relation to structural damage. The F/A outlet nozzle temperature differences were based on the through-the-wall temperatures at nodes 1 and 13 depicted in Figure 7.1-4. A plot of the temperature difference between nodes 13 and 1, that is, AT = T13 - T), in terms of cumulative iterations is presented in Figure 7.1-6. A review of the through-the-wall temperature differences shows that the maximum and minimum values occur at cumulative iterations 16 and 31 respectively, with a range of 383 F. In the thermal solution run, cumula-tive iterations 16 and 31 correspond to the E-16 transient at 12.5 and 90 seconds as illustrated in Figure 7.1-1. The initial steady state condition corresponds to cumulative iteration 3 with a temperature difference of 135 F. Plots of the temperature distribution throughout the F/A outlet nozzle thermal model at cumulative iterations 3,16, and 31 are presented in Figure 7.1-7. 6
~~-220-4~~
~~340 -~~
~~,-Cumulative f teration 31 320 300 -~~
~~280 - 260 240 _ Maximum Range (383*F) 220 C~~
~~% ~~~
~~200~~
~
180 J-8 160 - 5 ,-S.S. S 140 f ,,-S.S. 120 - 5 \ 100 - t 5 80 - n 1 60 1 f l ! 40 - f I 20 - 0 I "* " #
~~10 2 30 40 50 6L 70 80 Iteration~~
~~-20 -~~
I
~~,-Cumulative Iteration 16 -40 -~~
~~{ {M.~~
~~-60 Figure 7.1-6 F/A Outlet Nozzle E-16 Transient Temperature Difference vs. Cumulative Iterations -221-~~
~~rumulative Iteration 3 e 1076*F - N~~
~~\ \ - 862'F \ \~~
~~Cumulative Iteration 16 I~~
~~- 780 F l em '~~
~~885cF / , e' t~~
~~. Cumulative Iteration 31 1250 F / 903 F \~~
~~Figure 7.1-7 + F/A Outlet Nozzle E-16 Transient Cumulative Iteration 3,16, and 31 Temperature Distributions a~~
~~-222-~~
7.1.3 Worst Case Duty Cycle The conclusions based on the F/A outlet nozzle loading analysis in , relation to establishing the worst case duty cycle were as follows: 8 Mechanical loads comprising 0BE and SSE seismic, core restraint internal pressure, and dead weight are unimportant in establishing the worst case F/A outlet nozzle duty cycle. I e Thermal loads comprising temperature distributions associated with steady state, the E-16 transient, return to steady state, and the hold-time prior to the initiation of the next E-16 transient were considered most important in establishing the worst case F/A outlet nozzle duty cycle. i The recomendations for the specific F/A outlet nozzle loading in relation ! to the worst case duty cycle were based solely on time independent and dependent thermal loadings. The following sequence for the worst case F/A outlet nozzle duty cycle was recommended to be repeated t 39 times so as to provide an upper bound to the 39 Upset events, and the Emergency or Faulted event. Time Independent 4 Select a uniform temperature equal to the reference temperature at cumulative iteration 3. Load sequentially to cumulative iteration .i 3 and 6 temperature distributions. Unload to uniform temperature. 9 Select a uniform temperature equal to the reference temperature at cumulative iteration 16. Load to the cumulative iteration 16 temperature distribution and unload to unifonn temperature. I 8 Select a uniform temperature equal to the reference temperature f at cumulative iteration 31. Load to the cumulative iteration 31 temperature distribution and unload to uniform temperature. 4 Select a unifonn temperature equal to the reference temperature j at cumulative iteration 3. Load to the cumulative iteration 3 temperature distribution. Time _ Dependent O Hold the cumulative iteration 3 temperature distribution for 10 days.
~~-223- . , - - , - - , - ~ , , ,~~
~~7.E Structural Analysis~~
. The F/A outlet nozzle structural analysis was directed to deriving the stresses, strains, and dimensional changes which occur during the worst case duty cycle from which subsequent structural evaluations were . made. In the following, the F/A outlet nozzle structural model, geometry, and boundary conditions are described. Next, linear and non-linear material properties including the effects of irradiation on stress-strain curves and simplifications made in the thermal creep equations are presented.
Further, reference temperature selection for thermal expansions in relation te axisl constraints is described. Finally, the time independent and dependent inelastic analysis and results for the F/A outlet nozzle are presented in preparation for subsequent structural evaluation. 7.2.1 Model, Geometry, and Boundary Conditions The F/A outlet nozzle structural model was formulated in the ANSYS finite element program so as to be compatible with the temperature distributions of the thermal model. The F/A outlet nozzle geometry was taken to be identical to that used for the thermal analysis, except that the slab simulating the R8/A was deleted. In formulating the F/A outlet nozzle model, the ANSYS constant strain (STIF 2) structural element was used to replace the linear temperature
. (STIF 35) thermal element. The boundary conditions along the lateral sur-faces of the 30 sector, in the manner of the conventional roller support, were taken to have zero normally disposed displacements, but free to move t;dially. Along the surface parallel to the global X-Axis, the UY displacements at Nodes 1 through 13 were set equal to zero. For the inclined surface, the UY displacements, after a 30 rotation to obtain normally disposed directions, were set equal to zero at Nodes 130, 131, !
132,133,149,150,166,167,168, 205 , 224 and 244. The F/A outlet nozzle structural model is illustrated in Figure 7.2-1. 1 1 l = l
~~-224-l l~~
~~j ( , s~~
~~- - Roller Supports Nodes~~
~~( ; /130 thru 133 ) f 149 thru 150 !~~
~~\ 166 thru 168 205~~
~~( 224~~
~~\ 244 / -/ ~~~
b
\
gY 0 Element 137 30 , e i y Element 19' d Figure 7.2-1 F/A Outlet Nozzle Structural Model, Geometry and Boundary Conditions .
~~-225-1 - . - - - - - . - - - . - - . - - - . ~ c - . -. - -,~~
7.2.2 Properties The F/A outlet nozzle as constructed from SA-316-SS and initially unirradiated at BOL is irradiated to a fluence (E>0.1 Mev, (4t) = 0.07 x 10 22 N/cm2 ) at E0L. The linear and non-linear prooerties of SA-316-SS under fluence and temperature used in the F/A outlet nozzle structural analysis are I described as follows. ~' 7.2.2.1 Linear The linear SA-316-SS material properties are the Young's Modulus (E) , Poisson's ratio (u), and coefficient of thermal expansion (a). Simplifica-
~~; tions of the properties in terms of constant conservative values over the 700 to 1250 F range of operational temperature used in the F/A shield~~
! block structural analysis, were not made in the F/A outlet nozzle. Instead, - the material properties as a function of temperature were used directly as identified in Section 4.2.2.1. 7.2.2.2 Non-Linear The non-linear SA-316-SS material property behavior required in the F/A outlet nozzle structural analysis are the time independent stress-strain, I and the dependent thermal creep constitutive relations. The constitutive relations with attendant simplifications used in the F/A outlet nozzle are as follows. 7.2.2.2.1 Stress-Strain Curves The true average stress-strain curves for SA-316-SS given in the NSM Handbook [16] were reviewed in relation to the F/A outlet nozzle E0L fluence (E>0.1 Mev, (4t) = 0.07 x 10 22 N/cm2 ) and the operational tempera-ture range from 700 to 1250 F. Temperature effects were found to be significant, but the effect of irradiation at E0L fluence relative to i unirradiated BOL values was found to be insignificant. Accordingly, the true average E0L and BOL stress-strain curves for SA-316-SS were considered identical to each other for the F/A outlet nozzle.
~~-226-e 7~~
In the F/A outlet nozzle structural analysis, true minimum BOL and E0L stress-strain curves are required because the thermal loads which occur . during the worst case duty cycle are slow acting and are basically i statically applied. The true minimum BOL and E0L stress-strain curves i as a function of temperature,taken as 90% of the true values given in the , NSM Handbook [6],are illustrated in Figure 7.2-2 with corresponding numerical values sumarized in Table 7.2-1. TABLE 7.2-1 F/A OUTLET N0ZZLE TRUE MINIMUM BOL AND E0L STRESS-STRAIN DATA SA-316-SS Temp. E Stress (KSI) at Total Strain I ( F) (106 PSI) .0005617 .002 .006 .010 .050 800 24.06 13514. 17100 21240. 23490. 34740. 925 23.12 12985. 16086 19395 21211 34443 1050 22.13 12429. 15511 18236 19756 32971 1175 21.10 11851 15131 17499 18858 30048 1300 20.03 11250 15030 16920 18360 26280 i 7.?.2.2.2 Thermal Creep Equations . The thermal creep equations for unirradiated SA-316-SS as a function of stress and temperature are identified in the NSM Handbook [6]. Thermal j creep equations for irradiated SA-316-SS are not identified as the com-bined irradiation-thermal creep effects are included in the irradiation creep equations. d In relation to the F/A outlet nozzle with an E0L fluence (E>0.1 Mev, 22 2 l (4t) = 0.07 x 10 N/cm ) operating over a steady state temperature range I of 950 to 1075 F, the effects of irradiation on thennal creep were con-l sidered insignificant, with temperature alone controlling creep rate. As such, the unirradiated SA-316-SS thermal creep equations as a function f -227-
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of temperature were selected to simulate the time dependent relaxation of stresses in the F/A outlet nozzle analysis. . A review of the unirradiated SA-316-SS thennal creep equations given in the NSM Handbook [6] was made for the purposes of simplification. Over , a temperature range of 800 to 1000"F, which is a reasonable approximation to the actual steady state F/A outlet nozzle temperatures, the thermal creep equation is given by: c = cl + *t (I - g-rt) , ,m t where, c = Total Strain e = Loading Strain l
= Primary Creep-Strain et (I-8. t) c = Secondary Creep Strain mt In order to simplify the thermal creep equation, the primary creep strain was neglected. Accordingly, stress relaxation during the time dependent 10 day hold time would be minimum, with subsequent structural evaluations ~
of creep damage conservative. Although structural evaluations of accumulated deformation would be non-conservative, the degree of non-conservatism was not considered significant. Expressing the secondary creep strai: in terms of the secondary creep strain rate (csc), the thermal creep equation for SA-316-SS used in the F/A outlet nozzle time dependent analysis was: sc = A [ Sinh c
~~]"e - **"'E = in/in-Hour o = Stress (PSI)~~
~~T = Absolute Temperature ( R)~~
~~-229- .~~
~~The numerical values of the secondary creep constraints used in the F/A outlet nozzle time dependent analysis are identified as follows. 10 A = 5.6229 x 10 / Hour~~
~~= , 8 2.015 x 10-4/ PSI n = 4.6 =~~
Q 67000 cal /mol R = 1.10389 cal /mol- R Thus, 4.6 e -60694 Sinh (4.38X10-5,) sc = (5.6229X1010) c The secondary thermal creep rate used in the F/A outlet nozzle time independent analysis as a function of stress and temperature are illustrated in Figure 7.2-3. 7.2.3 Worst Case Duty Cycle Response The structural response of the F/A outlet nozzle to the worst case duty cycle loading required the selection of reference temperatures compatible with the temperature distributions at the worst case through the wall temperature differences and axial constraints prior to deriving the time independent and dependent solutions. A description of the analysis and solutions which are required in subsequent structural evaluation is as follows. 7.2.3.1 Constraints and Reference Temperature Selection The F/A outlet nozzle structural model corresponds to a 30 sector of a lateral slice taken through the length of the outlet nozzle. Axial constraints normal to the 2 dimensional 30 sector closely simulate a plane strain condition as the length of the outlet nozzle is significantly greater than corresponding cross-sectional dimensions. Accordingly, the F/A outlet nozzle was considered to be in a plane strain condition for the purposes of analysis.
~~-230-o~~
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~~'0 0~~
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~~F l~~
~~z S 0 3 z - 0~~
~~- o 6 0 2 N 1 1 ~~~
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0
. - . ~ - . - - - _ - _ _. - 1 - 0 5 0 5 0 5 0 5 4 3 3 2 2 1 1 O ,Ebm v
e l
The method of selecting a reference temperature in relation to an arbitrary temperature distribution imposed in an ANSYS plane strain model was described for the F/A shield block in Section 4.2.3.1. Using the same method as for the F/A outlet nozzle, the reference temperatures for the recommenced cumulative iterations in the worst case duty cycle are summarized in Table 7.2-2. TABLE 7.2-2 F/A OUTLET N0ZZLE REFERENCE TEMPERATURES Temperature , Reference Distribution ! Temperature (Cum. Iter.) (T R s F) 3 1003.5 6 1003.5 16 977.2 31 1030.7 J 7.2.3.2 Analysis and Results The ANSYS inelastic analysis of the F/A outlet nozzle structural model under the worst case duty cycle was arranged in time-independent plastic analysis associated with the short term E-16 transient followed by time-dependent creep analysis corresponding to steady state temperatures over the 10 day hold-time. The time independent and dependent analysis pro-vide the structural response from which evaluations of crack initiation in terms of local ductile rupture and creep-fatigue damage are made. With regard to dimensional changes that can exceed functional limits, the peak + accumulated deformations during the duty cycle and the residual deformations following the duty cycle are required.
~~-232-4~~
In order to obtain the desired results in an efficient manner, the ANSYS restart option was used to follow the loading sequence within, between . and after the time independent and dependent loadings. As elastic / plastic / creep instability would not be expected for the F/A outlet nozzle I under the deformation controlled thermal loadings, the ANSYS small strain- , small deformation option was used in the inelastic analysis. A description of the time independent and dependent analysis and results is as follows. 7.2.3.2.1 Time Independent The time independent ANSYS analysis of the F/A outlet nozzle was directed to deriving the peak plus accumulated strains and deformations associated with following the path dependent thermal loadings from initial steady state through the E-16 transient followed by the return to final steady state, but excluding the 10 day hold-time. The time independent loadings were considered as static loadings applied at zero time. A total of 18 sequential ANSYS load steps in combination with the restart option were used to obtain the time independent structural response of the F/A outlet nozzle. A summary of the F/A time independent analysis procedure is presented in Table 7.2-3. I i b t
~~-233-~~
~~TABLE 7.2-3~~
~~, F/A OUTLET N0ZZLE TIME INDEPENDENT ANALYSIS~~
~~SUMMARY~~
INITIAL STEADY STATE, E-16 TRANSIENT, AND FINAL STEADY STATE e Load Iterations Temperature Reference Step Distribution Temperature Description (F) ( F) 1 25 Cum. Iter. 3 1003.5 Initial Stead 2 4 Cum. Iter. 3 1003.5 Time =y0.0State Sec. 3 5 Cum. Iter. 6 1003.5 1st E-16 Transient Loading 4 12 1003.5 1003.5 and Unloading i 5 1003.5 Time = 2.0 Sec. 7 1003.5 , 6 1 977.3 977.3 2nd E-16 7 28 Cum. Iter. 16 977.3 Transient loading and Unloading 8 6 Cum. Iter. 16 977.3 Time = 9.5 Sec. 9 28 977.3 977.3 10 5 977.3 977.3
11 1 1030.7 1030.7 3rd E-16 Transient Loading 12 68 Cum. Iter. 31 1030.7 and Unloading 13 6 Cum. Iter. 31 1030.7 Time = 90 Sec.
. 14 68 1030.7 1030.7 15 11 1030.7 1030.7 I 16 25 1003.5 1003.5 l 17 1 Cum. Iter. 3 1003.5 Ste State f 18 3 Cum. Iter. 3 ,
~~1003.5 , Time = 900000 Sec. 8~~
~~-234-6~~
The F/A outlet nozzle structural response to the time independent loadings was obtained with a plastic convergence ratio of 0.01. The detailed - stress-strain response at each of the converged solutions was saved on ANSYS Tape 10 for subsequent recall in structural evaluations. The initial and final time independent steady state maximum equivalent stresses were
~~i found to be 14,900 and 13,157 psi respectively. During the E-16 transient, the maximum equivalent stress was 16,846 psi at cumulative iteration 31.~~
The peak non-uniform deformation was found to be 0.00149 in. at cumulative iteration 31. The initial steady state non-uniform deformation was 0.00041 in. Computer plots of time independent equivalent stress and 1 peak non-unifom deformation are presented in Figures 7.2-4 through -6. e t e a i i I
~~-235-~~
. e i I
I
~
~~Initial Steady State e~~
~~\ , 14,900 psi---+ i -~~
~~t i . l Final Steady State g~~
~~' '\ '. \~~
13,157 psi i 1 i - , -___.._..\._._ \_ - l-Figure 7.2-4 F/A Outlet Nozzle > Initial and Final Steady State ;- Equivalent Stress
~~-4 Time Independent -236- 1~~
/
~~e i~~
~~\ ,g \ \ \~~
~~I 16,846 psi~~
> I \\ \ \ \
~~l 4 i Figure 7.2-5 F/A Outlet Nozzle E-16 Transient Cumulative Iteration 31 i Equivalent Stress Time Independent a j~~
~~-237-1 4~~
~~~ . Initial Steady State C \~~
~~0.00041 in. A [, 2~~
~~. . _ _ \ 's \~~
~~s \~~
\ , \ \ \ ! \ l \- Cumulative ' \x Iteration 31 \
~~O.00149 in. s.__ , '\ s'y~~
~~, \~~
~~s \ , s l~~
~~'N- \ ,~~
~~i _a _ _~~
\\
Figure 7.2-6 F/A Outlet Nozzle Initial Steady State and E-16 Transient Cumulative Iteration 31 Non-Uniform Deformation a Time Independent 4 -238-
7.2.3.2.2 Tire Dependent The time dependent AASYS analysis cf the F/A outlet ner:le was cirected . to deriving the residual strains and cefernaticcs associated with the 10 day hold-tire follewing the final tire dependent steady state conditien. The tire dependent analysis was perforred in 3 icad steps . using an ANSYS restart frc.n Load Ste, IS of the tire inderendent analysis corresponding to tne curulative iteraticn 3 te cerature distribution. Load Steps 19 and 20 were used to stabilize One tire inde;-endent final steady state condition. The tire dependent relaxatien of stress in relation to secondary therral creep rate was obtained in lead ste: 21. A total of 24 iterations at a 10 hour creep tire step were used to ebtain the time dependent solution over the 10 day or 240 hour hold-tire. A subsequent ANSYS restart for 2 lead steps was rade in unicading the F/A outlet no::le to a uniforn temperature so as to cbtain the residual deforration after one worst case duty cycle. A sg7 ary cf the F/A cutlet no::le tire dependent analysis crecedure for the 10 day hold-tire and unloading to a unifere tercerature is presented in Table 7.2 4 is:L-t ,e.,.-,
"~
p,f , OUTL~i 'w' 't _n t . - , TIME DEPENDENT ANtLYSIS SLT.GY 10 DAY HOLD-TIME AN3 UNLCA31NG i j l Te cerature l Refe rence ; t Descri;;ien l Lead ; Iterations , Distribution i Terce rature l lr Step ! (#F) ; ('F) i
~~, < 4 1003.5 i 10 dav~~
~~I 19 1 1 , Cun. Iter. 3 i 4 . -~~
( 4 ) i i 20 ,l 3 ; Cue. Iter. 3 ; 1D03.5 : Bold-Tire l i ; , i i l ' ' 1 21 l 2a Cur. Iter. 3 1033.5 '. !, T' . l 22 ! 1 ! 1003.5 } 1003.5 Unicsading j
~~?3 I ~1 I "ral ~ ' R t 1 09'~#':~ I 0" #5id"3I I j~~
~~l l t j referratiens :~~
~~-239-~~
l The F/A outlet nozzle structural response to the time depenaent loading was obtained with a creep convergence ratio of 0.25. The detailed stress-strain response was saved on ANSYS Tape 10 for subsequent recall in structural evaluations. The F/A outlet nozzle structural response at the
, end of the 10 day hold-time, designated as the time dependent final steady state condition, was not found to significantly differ from the time independent final steady state response because of negligible relaxation of stresses and deformations under the secondary thermal creep rate. The maximum equivalent stress and peak non-uniform deformation in the F/A outlet nozzle at the time dependent final steady state condition were found to be 13,058 psi and 0.00049 in. as illustrated in Figure 7.2-7.
~~With regard to the residual deformations of the F/A outlet nozzle, a maximum value of 0.00018 in, was found over the worst case duty cycle as illustrated in Figure 7.2-8. a 3~~
~~-240-1 !4 -, . - - ---.-..,,m-- --- .w- -- - , , , . , - - -~~
i
~~\ .~~
~~N A% s( s 13,058 psi - i. +~~
~}
3\
\
~~0.00049 in..~~
~~, ~\~~
~~s s \ s I~~
~~\s\_.~~
Figure 7.2-7 l F/A Outlet Nozzle Final Steady State Equivalent Stress and Non-Uniform Deformation , ! Time Dependent l
~~-241- .~~
i
~~\ \ \~~
C
\
~~0.00018 in.s~~
~~' \ \ '\s_ \\~~
~~s. s~~
\
N
~~\ \~~
i
\k
_t
\
~~Figure 7.2-8 F/A Outlet Nozzle Residual Defomation b~~
~~-242-~~
7.3 _ Structural Evaluation The F/A outlet nozzle structural evaluation was arranged to provide a , comparison of the structural response for the 39 worst case duty cycles in relation to criteria which protect against crack initiation and excessive deformation failure modes and thereby assure F/A outlet nozzle function , over the first and second reactor cycles. 1 The procedure for performing the F/A outlet nozzle structural evaluations ^ in relation to crack initiation and excessive deformation criteria was f identical to that for the F/A shield block presented in Section 4.3. The damage processor was used to screen the F/A outlet nozzle elements for the worst location for the ductile rupture and combined creep-fatigue factors over the 39 worst case duty cycles while attendant deformations were com-pared with peak + accumulated and residual defonnation limits. A
~~description of the F/A outlet nozzle structural evaluation and suninary of results is presented as follows.~~
7.3.1 Crack Initiation The F/A outlet nozzle structural evaluation of crack initiation in relation to local ductile rupture and combined creep-fatigue damage . criteria over the 39 worst case duty cycles is presented in the following subsections. 7.3.1.1 Local Ductile Rupture The local ductile rupture criterion in protecting against crack initiation requires that the ductile rupture factor (FDR) be less than unity at each
~~! point in the F/A outlet nozzle. #' (' max principal) TFi F =~~
~~Mad mum of ( 9, min > f DR 5~~
' (' max principal) TF 'u, min l -243-I
~~.- - - . _ _ _ _ - _ _ - - = -~~
~~1 In the following, the allowable untaxial strains used in the F/A outlet~~
~~- nozzle structural evaluation and comparison of results with the local ductile rupture factor criterion are presented.~~
~~i i~~
7.3.1.1.1 Allowable Uniaxial Strains The F/A outlet nozzle as constructed from SA-316-SS is unirradiated at 22 2 BOL. The E0L fluence (E>0.1 Mev) is 0.07x10 n/cm . In addition, the F/A outlet nozzle temperatures range from 700 to 1250*F. The true uniaxial uniform elongation (cu, min) and fracture (cf. min) f0" unirradiated and irradiated SA-316-SS used in the F/A outlet nozzle structural evaluation were taken from the recommendations in the trail j applications of the RDT Draft for Breeder Reactor Core Components [15-23] I and are identical to those taken for the F/A shield block structural !
1
~~evaluation presented in Section 4.3.1.1.1.~~
~~1 I 7.3.1.1.2 Comparison with Criterion~~
The F/A outlet nozzle structural evaluation in relation to the worst case location for local ductile rupture was made by screening each of the finite elements over the 39 worst case duty cycles with the damage processor.
~~The maximum local ductile rupture factor (FDR) max f r the F/A outlet i nozzle was found to occur at element 127, as identified in Figure 7.2-1.~~
The peak BOL strain components occurred at the cumulative iteration 31 temperature distribution in the E-16 transient where the local metal l temperature was 1242 F. Accumulated BOL strain components were based on the difference between final time dependent steady state conditions and initial time independent steady state conditions in the worst case i cycle. The EOL maximum principal strain for the peak BOL and accumulat

l BOL strain components over 39 worst case F/A outlet nozzle duty cycles was 0.03 in/in. The triaxiality factor for the local stress state was
~~-1.868, but was taken as unity for conservatism in the structural evalua-tion. The true minimum irradiated uniform elongation and fracture strains~~
~~, at E0L fluence (E>0.1 Mev, (4t) = 0.07 x 10 2 N/cm 2~~
~~) were 0.227 and 0.137 in/in i . respectively.~~
4 -244-s
1 In this arrangement, the maximum local ductile rupture (FDR) for the F/A outlet nozzle was found to be controlled by the fracture strain with . a value: (FDR) max = 0.732 , As (FDR) max < l.0, the F/A outlet nozzle is not expected to experience crack initiation over the 39 worst case duty cycles based on the local
~~> ductile rupture criterion.~~
7.3.1.2 Creep-Fatigue Damage The creep-fatigue damage criterion in protecting against crack initiation requires that the combined creep-fatigue damage factor (FCFD) be less than unity at each point in the F/A outlet nozzle. c+D h F CFD
~~= a/b = Minimum.Oc+7/3D) of ( . 7/3 D 1~~
In the following, the allowable limits for fatigue life and creep-rupture times used in the F/A outlet nozzle structural evaluation and a comparison - of the results with the combined creep-fatigue damage factor criterion l are presented. J e
7. 3.1. 2.1 Allowable Limits The F/A outlet nozzle as constructed from SA-316-SS is unirradiated at 22 2 BOL. The E0L fluence (E>0.1 Mev) is 0.07 x 10 N/cm . In addition, the F/A outlet nozzle temperatures range from 700 to 1250*F. The fatigue life and creep rupture time relations used in the F/A outlet nozzle structural evaluation were identical to those used in the F/A shield block structural evaluation presented in Section 4.3.1.1.1. The fatigue life and creep rupture time relations representative of F/A outlet nozzle peak and steady state metal temperatures at E0L fluence are illustrated in Figures 7.3-1 ,
~~and -2 respectively.~~
~~. r -245-e e~~
r o a + o . 1.:o . . . .-
~~;_'._ ...._- - - . . : . __ _ ; . :__.-_..._.!.--_. w. . - . . . ' .. .- -- _ :~~
~~L. . . i~~
..3 .. __ . . . . _ _ . . . ..--.1 . . a .- - ..
~~2 . 4 , , Fig.re 7.3 1~~
~~' I~~
~~_,.__.-_-__._., .__,i_,. ii F/A Cutlet ?'Ozzle .. _ . . _ . _ . . . . . _~~
! i l 'I___ $A-31f.-55 l- . i i
~~i.1.!~~ i Fcti a life~~
. < .i ' . 1 i. 1 EDL Fluence (f >0.1 ? ev , e t=0.0 7 x 1022 ,je,2}
~~C.1 ' ' * . i # ~~^ ~~ Tererature s IMO*r~~
4
. [.. ! --.* , -_a. . . . _ _ _. .- -. - _ -, ss a . +' " F4ctor cf Iwo f, Strain Rech.ctico I! '
[ j' - N / , . 4 g x / ,
~~'t. .~~
8 \ N \ 'i l Universa'l Slopes i N Correlation j 4
~~. ! i~~
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~~l j'~~
' i ;1 Design Fatf 2We Life .
~~l 3~~
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,;51 _. _ . _ . . _ ._._ ; 4 . . - , y_ a, [ ; {j' { , , , ,. p --y -- . ; 3 '
101 102 103 106 105 W Cycles to Failure
I i
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~~. 247- ;~~
b
~~% g.-9 , g- ...-.----- m - p-p-m,- - , -_ - - . - y~~
~~7.3.1.2.2 Comparison with Criterion~~
. The F/A outlet nozzle structural evaluation in relation to the worst case location for combined creep-fatigue damage was made by screening each of the finite elements over the 39 worst case duty cycles with the damage e
processor. The maximum combined creep-fatigue damage factor (FCFD) max for the F/A outlet nozzle was found to occur at element 19, as identified in Figure 7.2-1. The fatigue damage factor (DI ) was found to be 0.547 for 39 worst case duty cycles. The equivalent strain range was found to be critical and occurred between cumulative iteration 16 and 31 temperature distributions during the E-16 transient with a value of 0.0075 in/in. The peak metal temperature over the fatigue cycle was 1237"F. The fatigue life for the equivalent strain range was 71 cycles based on the E0L fluence (E>0.1 Mev, 22 2 (4t) = 0.07 x iO N/cm ), c The creep damage factor (D ) was found to be 0.0966 for the 39 worst case duty cycles. The equivalent stress was found to be critical in the determination of minimum rupture times. As stress relaxation was negligible, the equivalent stress of 13,166 PSI at the beginning of the 10 day hold-time controlled the creep-damage. The mean minimum rupture time for E0L , fluence (E>0.1 Mev, ($t) = 0.07 x 1022 N/cm2 ) at a metal temperature of 1073 F was 9.69 x 10 I hours. In this arrangement, the maximum combined creep-fatigue damage factor (FCFO) max for the F/A outlet nozzle was dominated by fatigue damage while creep damage was small . (FCFD) max = 0.773 As (FCFD) max = 0.773 < 1.0, the F/A outlet nozzle is not expected to experience crack initiation over the 39 worst case duty cycles based on the creep-fatigue damage criterion. l 248 ~.
J l 7.3.2 Excessive Deformation The F/A outlet nozzle structural evaluation of peak plus accumulated, and . i residual deformations in relation to functional ifmits over the 39 worst case duty cycles is presented in the following subsections. 4 7.3.2.1 Peak + Accumulated Deformations 4 The peak plus accumulated deformation criterion in protecting against excessive deformations requires that peak plus accumulated defonnations (6 A)beless than the peak plus accumulated deformation limit (PADL). 6 P+A < PADL P The peak deformation (6 ) of the F/A outi . nozzle during the worst case duty cycle at BOL was found to occur at the fluted surface at the cumulative iteration 31 temperature distribution of the E-16 transient with a value of 0.00149 in. The initial time independent and final time dependent steady state non-uniform deformations were found to be 0.00041 and 0.00049 in, respectively. Accordingly, the accumulated deformation l (60) between initial time independent and final time dependent steady state conditions for one duty cycle at BOL was 0.00009 in. For 39 worst , P case duty cycles, the peak plus accumulated (6 +A) deformation at E0L is l (6P+A) E0L = (6 ) BOL + (N-1) (t.6ss) BOL (6 A) EOL = 0.00149 + (38) (0.00009) i (SP+A) E0L = 0.0049 in. For the F/A outlet nozzle, the peak plus accumulated deformation limit l (PADL)is PADL = 0.020 in. 249
l As 6P +A < PADL, the F/A outlet nozzle is not expected to experience
~~. excessive peak deformation over the 39 worst case duty cycles.~~
7.3.2.2 Residual Deformations The residual deformation limit in protecting against excessive deformation requires that the residual deformation (6 ) be less than the residual deformation limit (RDL). 6 < RDL 0 The accumulated deformation (6 ) between the initial and final uniform conditions for one worst case duty cycle at BOL was found to be 0.000180 in. For 39 duty cycles, the residual deformation (6 ) at EOL. R A (6 ) EOL = N (6 ) BOL (6 ) E0L = 0.007 in. For the F/A outlet nozzle, the residual deformation limit (RDL)
~~, RDL = 0.020 in.~~
R As 6 < RDL, the F/A outlet nozzle is not expected to be experience excessive residual deformation over the 39 worst case duty cycles. 7.3.3 Summary The F/A outlet nozzle was found to satisfy the crack initiation and excessive deformation criteria. A summary of the F/A outlet nozzle structural evaluation is presented in Table 7.3-1. e 250
~~~ ,~~
~~TABLE 7.3-1 F/A OUTLET N0ZZLE , STRUCTURAL EVALUATION~~
~~SUMMARY~~
~~Allowable Calculated Margin of Criteria Value Value Safety~~
Crack Ductile 1 0.732 0.37 Initiation Rupture Factor Combined 1 0.773 0.29 Creep-Fatigue Damage Factor Excessive Peak + 0.020 in 0.005 3.0 Deformation Accumulated Residual 0.020.in 0.007 1.86

Margin of Safety = Allowable Value -j Calculated Value 251
8.0 ATTACHMENT ASSEMBLY Af4ALYSIS Afl0 EVALUATION In the F/A attachment assembly analysis and evaluation, a loading analysis was made that considered mechanical seismic, pressure and deadweight loads, and thermal steady state and transient loads in establishing the number and characteristics of a worst case duty cycle that umbrellas all expected duty cycles for the attachment assembly in the first and second reactor cycles. flext, an inelastic structural analysis of the attachment was made for a single worst case BOL duty cycle to calculate the strains and dimensional cFanges from which E0L values were approximated. Finally, a structural evaluation of E0L strains and dimensional changes was made in relation to criteria which protect against crack initiation and excessive deformation. A sumary of the loadirg and structural analysis and structural evaluation is presented as follows. 8.1 Loading Analysis The F/A attachment assembly loading analysis was directed to establishing the number and characteristics of a worst case duty cycle that umbrellas both the number and characteristics of Upset, Emergency, and Faulted Events specified over the first and second reactor cycles. The number and characteristics of these events are specified in the Equiprent Specification [1]. It is important to note that the worst case F/A attachment assembly duty cycle is, in itself, hypothetical, but permits a conservative structural evaluation to be performed on a single duty cycle instead on each of the individual events specified. In the following, the F/A attachment assembly mechanical and thermal loads are assessed individually and in relation to each other prior to establishing the worst case duty cycle which was used in structural evaluation. ) 8.1.1 Mechanical The F/A attachment assembly mechanical loads of significance in relation to subsequent structural evaluations are due to deadweight, flow pressure drop, 1 and seismic excitation. A description of the mechanical loads is presented l in the following subsections. s
~~-252-~~
8.1.1.1 Deadweight The F/A attachment assembly supports the deadweight of the fuel rod , bundle. The total deadweight (FDW)T f the rod bundle including a total number (MT ) f 217 rods is: a (FDW)T = 235 LBS. Neglecting the buoyancy effects of rod bundle immersed in sodium and assuming the total deadweight (FDW)T equally distributed between both support bars, the deadweight (FDW) suspended by a single support bar, F DW = (FDW)T 2 J F DW
~~= 117.5 LBS.~~
l Alternately, the deadweight (fDW) of a single rod, in terms of the j deadweight (F DW) and total number T(N ) of rods, is as follows. I = F DW DW (NT /2) - f = 1.083 LBS. DW
~
With regard to the distribution of the deadweight load (FDW) along the single support bar, a trapezoidal distribution consistent with the distribution of the rods in the hexagonal F/A duct was assumed. The hexagonal distribution of F/A rods supported by a symmetrical half of a single support bar is illustrated in Figure 8.1-1. s
~~-253- ,~~
~~i Row 1 z c Row 9 [ ,~~
~~..V/ Fy'd . \ \ k 0;; . , ' g ~~~
~~c l'l\ TTTT T Rod Bundle l[ i) Tb i' & I Y I le lei~~
~~. M i} .'yjf; id g _f__A7.R,esgj3f Support Bar /~~
~~(FDW)1 J , (FDW}i V (FDW}i l u o , m , t~~
~~, y yyp j ,~~
~~i t Weld~~
~~/ \ /~~
~~Figure 8.1-1 F/A Attachment Assembly Deadweight Load Distribution s~~
~~-254-~~
)
In the F/A rod bundle plan view, the number of rods varies over nin2 rows, designated by a row 1 through 9 notation. Thedeadweight(FDW)i row distribution in terms of the number (Ng ) of rods in a row and the single . rodweight(fDW) was taken according to the relation. N (FDW)i i DW' I " I' 9' The trapezoidal row distribution of deadweight loads (FDWI ifor the number (N j ) of rods in each of the 9 rows is sumarized in Table 8.1-1. TABLE 8.1-1 F/A ATTACHMENT ASSEMBLY SUPPORT BAR DEADWEIGHT DISTRIBUTION BY R0WS Row Number Row Load of (FDW)i s LBS. Rods ;
~~. (N9 ) l . _ _. _ ____ w - - . - . -~~
7- , 1 8.5 9.206 2 8.0 8.664 3 7.5 - 8.123 , i 4 7.0 7.581 5 6.5 7.040 6 6.0 , 6.498 ~ 7 5.5 5.957 8 5.0 5.415 - 9 4.5 4.874
~~-255- ,~~
~~- . _ . =_-~~
~~l 8.1.1.2 Pressure Drop~~
= The F/A attachment assembly secures the rod bundle to the shield block during steady state sodium flow. Consideration was given to steady state pressure drop across the tube bundle for the CRBRP core flow zones. For 6 the five CRBRP core flow zones, designated as flow zones 1 through 5, the total nominal pressure drops across the tube bundles are 42.66, 40.41, 37.37, 34.98, and 32.12 psi, respectively. Of these, the worst case steady state pressure drop (ap)ss occurs in flow zone 1. Including the additional pressure drop of 1.09 psi for the rod bundle inlet and outlet, the total worst case steady state pressure drop (Ap)ss' (Ap)ss = 43.75 PSI In obtaining the total load (F )T p acting on both support bars caused by the upward steady state sodium flow, it was decided that the full cross-sectional area (A) should be used for the worst case pressure drop (Ap)ss' (Fp)T = A (Ap)ss The area (A) based on the F/A hex duct inside surface flat-to-flat Dimensions of 4.320 in is 16.16 in2 . Accordingly, the total upward worst case pressure drop force (Fp )T acting on both support bars, 2
~~(Fp )T = (16.16 in ) (43.75 PSI) (Fp)T = 707 LBS. 4~~
~~-256-~~
~~Neglecting the offective pressure drop force applied to the inside i~~
~~surface of the F/A hex duct, and assuming the full pressure drop force~~
, F(p )T is equally distributed between both support bars, the worst case ; - pressure drop load (F,) supported by a single support bar, Fp = (F p)T l 2
~~l Fp = 353.5 LBS. Alternately, the pressure drop load p(f ) for a single rod, in tems of the total load (F ) and number of rods (N T~~
~~), is given by the relation. [~~
l p f = F p _P_ N T f = 353.5 p (217/2) L f = 3.258 LBS. p , With regard to the distribution of pressure drop load (Fp ) along the single
~~support bar, a trapezoidal distribution proportional to the number of rods in a row was assumed, in the manner described for the distribution of deadweight, as illustrated in Figure 8.1-2.~~
~~- i -257-~~
~~Row I Ll , l< Dow 9~~
~~.v .yui u,. :+ ~, \'}y'p'25'dO';~~
~~1 U ,~~
)QT',N flJ '. .PAOh s L. -p>23.+g. ; r....s ,0,\ ,'{ns * .
~~Rod Bundle~~
~~.{"T T'9 T ' /~~
l
/
~~I l :~~
~~, l. : . . ,~~
~~l:9y i, i J ! ) t,-J q-- Y # #1 kj 'g t h ;;r. i l L~~
~~.P #~~
~~g 70~~
"~
c< . Support f Bar af[ t I (i 7 9 (FP )I / ~- (F P)1.
~~/ (F )~~
~~Qrry~~
~~, .1 ==_.. _.. . -._~~
f
~~'. s I~~
~~T 'a'el d~~
/
~~m a Ficure 8.1-2 F/A Attachment Asserbly Pressure Droo load Distribution~~
~~-253-~~
The pressure drop load (F p )9 row distribution in terms of tha number (N9 ) of rods in a row and the single rod pressure drop load (f )p was taken according to the relation. (Fp), = N9 e f , j = 1, 9 p J The trapezoidal row distribution of pressure drop loads (F p )j for the number of rods in each of the 9 rows is sumarized in Table 8.1-2. TABLE 8.1-2 F/A ATTACHMENT ASSEMBLY SUPPORT BAR PRESSURE DROP DISTRIBUTION BY R0WS i Row Number Row Load j of ! (FP)9 s LBS Rods l (NI) __ l 1 8.5 ! 27.693 2 8.0 26.064 l 3 7.5 24.435 j 4 7.0 22.806 l < 5 6.5 21.177 i 6 6.0 19.548 i 7 5.5 17.919 ! I 8 ! 5.0 16.290 . 9 ! 4.5 14.661 8.1.1.3 Seismic The F/A attachment assembly experiences both horizontal and vertical dynamic loads during the OBE and SSE seismic events. The horizontal and vertical seismic loads applied to a single support are illustrated in Figure 8.1-3.
~~-259-~~
~~I Row 1 L~~
~~Row 9 h ..~~
~~. /sN i .~~
~~s .'o ,~~
\
ff);N e .c q l Rod T T'T'T T Bundie 8 V, OBE n a H, OBE or c ;- or a V, SSE y ,
)Y j'J Th ~,;l fp , a H, SSE 3 I J et q[jt1nfe . A g ' FPc?.?t a, :;f@f Support r - ~~ '- '-
~~[ Bar (~~
~~\ , ,~~
~~f (FV,0BE)1 r (FV,SSE)1 l~~
~~% ~ - -.1 (FV,0BE)9 r (FH,SSE)9 I~~
~~hih r'r u o y n,,~~
~~~yp ~ ~ ~ ~~~
~~(FH,0BE)1 r (FH,SSE)1 ( H,0BE)9 or (FH,SSE)9 - t h,.' Weld~~
/
A
/
l
~~- Figure 8.1-3 F/A Attachment Assembly Seismic Load Distribution ~~~
T
~~-260-~~
8.1.1.3.1 Horizontal . The OBE and SSE horizontal accelerations in the N-S and E-W direction at the ACLP, TLP, and CSP elevations were considered. As the se rod bundle is disposed along a significant portion of the elevational i extent between the TLP and CSP, the horizontal OBE and SSE accelerations (a ) applied to the rod bundle were taken to be the average of the N-S or H E-W accelerations at the ACLP, TLP and CSP locations. a H, OBE = 1.629 a H, SSE = 2.269 In the definition of the OBE and SSE loads transferred horizontally to the support bars, the weight , the rod bundle was assumed to be simply supported at the top of the rod bundle and at the support bars. Accordingly, the lateral support of the rod assembly by the F/A hex duct at points inter-mediate to the top of the rod bundle and the support bars was conservatively neglected. Thus, the static 19 horizontal load (FH,5) of the rods supported by a single support bar, in the manner of a simply supported beam, was taken as half of the corresponding deadweight load (FDW)* , F H,5
~~=F DW -~~
~~2 Expressing the total OBE dynamic horizoMal load (FH,0BE) applied to a single bar in terms of the static l-g joad (FH,5) and acceleration (a0BE)' F~~
~~H,0BE H,S] aH,0BE or F H,0BE DW] aH,0BE 2~~
F'
~~-251-~~
Similarly, for the SSE dynamic horizontal load (FH, SSE), H, SSE H,S]aH,SSE F = F a 3 ii, SSE DW With regard to the row distribution of the horizontal OBE load (FH,0BE)i and SSE load (Fli,SSE)1 along the length of the single support bar, a trapezoidal distribution consistent with the number (Nj ) of reds in a row and the weight (fDW) of a single rod was assumed as described in Section 8.1.1.1. (FDW)i "i 'IDW' i " I' 9 Thus, (FH,0BE)i "i 'I DW a H,0BE 2 and, (FH,SSE)i
~~N I a i DW H,SSE 2~~
~~, The trapezoidal row distribution of horizontal 0BE and SSE seismic loads (FH,0BE) and (r.H,SSE) f r the number of rods in each of the 9 rows is summarized ir Table 8.1-3. D~~
~~-262-~~
~~.l 4~~
~~TABLE 8.1-3 F/A liTTACHMENT ASSEMBLY HORIZONTAL OBE AND SSE SEISMIC LOAD~~
]
DISTRIBUTION BY R0WS Number Row Load (LBS) I of Row Rods , y p (Nj ) t H. OBE H, SSE l 1 8.5 ; 7.456 10.402 l r 2 8.0 7.018 9.790 1 3 7.5 . 6.579 9.178 4 7.0 I 6.141 8.567 i
~~; 5 6.5 8 5.702 , 7.955 6 6.0 .~~
5.263 7.343 7 5.5 ; 4.825 6.731 i 8 5.0 4.386 6.119 9 4.5 3.948 ! 5.507 I 9
~~-263-~~
I i 8.1.1.3.2 Vertical 1 The OBE and SSE vertical accelerations at the ACLP, TLP, and CSP elevations were considered. As the rod bundle is disposed along i a significant portion of the elevational extent between the TLP and CSP, the vertical OBE and SSE accelerations (ay ) applied to the rod bundle were taken to be the average of the accelerations at the ACLP, TLP, and CSP locations. a v, OBE
~~= 1 0.61g l~~
~~a =~~
~~v. SSE 1 0.969 In the definition of the OBE and SSE loads transferred vertically to the support bars, the full weight of the rod bundle was assumed to be suspended~~
; by the support bars. Accordingly, the static 1 g vertical load (Fv.s) I l the rods supported by a single support bar was taken as the corresponding l deadweight (FDW)* = F v,s DW A distinction was made as to whether the vertical acceleration was upward or downward. ^
l For upward OBE acceleration (av, OBE), the downward load (Fv, OBE, D) acting on a single support bar is increased over the static 19 vertical load (Fv,s)* F " V, OBE, D b V,S (av, OBE
I)
.a or, F " l V, OBE, D EfDW](av, OBE + I) Similarly, for upward SSE accelerat, ion, F =
~~V, SSE, D [FDW] (av, SSE + I)~~
; -264-i ,,,._,_,.m. - _ , , - . . _ . - , _ = _ . - . _ . _ --, - , -m _m..--r ,....-,.._-,__,___-.<_.,..---_-,-r. ~ , - - - . . . . -_
~~With downward OBE acceleration (aV, OBE) the upward load (FV, OBE, U I ' acting on a single support bar is proportional to the difference between actual and 1g accelerations.~~
=
~~F V, OBE, U [Fy,3][aV,OBE~I) or, F V, OBE, U = [FDW][aV,OBE~Il Similarly, for downward SSE acceleration,~~
=
F V, SSE, U [FDW][aV,SSE~I3 With regard to the row distribution of the vertical OBE loads (FV,OBE,U)i and (FV, OBE, D)i, and vertical SSE loads (FV, SSE, Ul iand (FV,SSE,D)i along the length of the single support bar, a trapezoidal distribution consistent with the number (N4 ) of rods in a row and the weight (fDW) r a single rod was assumed as described in Section 8.1.1.1.
=
~~(FDW)f Ng *fDW' I " I' 9 e Thus, (FV,OBE,D)1~~
* # (aV, OBE
I) b"i DW (FV,SSE,D)i E"i IDW] (aV, SSE

I) -
~~and, (FV,OBE,U)1~~
=
~~[Ng *f0W][aV,OEE~I3 (FV,SSE,U)1~~
=
[N4 *fDW][aV,SSE~Il The trapezoidal row distribution of vertical OBE and SSE seismic loads (FV, OBE) and (FV, SSE) in the upward and downward directions for the number of rods in each of the 9 rows is summarized in Table 8.1-4. t k f
~~-265-0' * ~ v ~~~
TABLE 8.1-4 - F/A ATTACHMENT ASSEMBLY SUPPORT BAR g VERTICAL OBE AND SSE SEISMIC LOADS DISTRIBUTION BY R0WS Row Row Load (LBS) !
~~~ '~~
Rods i I"i) F V, OBE, D F V, OBE, U F V, SSE, D lFV, SSE, U 1 8.5 14.821 -3.590 18.043 . -0.368 2 : 8.0 13.949 -3.379 , 16.981 '
-0.346 3 7.5 13.077 -3.168 l 15.920 -0.325 4 7.0 12.205 -2.957 14.859 -0.303 5 6.5 11.334 -2.745 13.797 ; -0.282 6 . 6.0 10.462 -2.534 12.736 -0.260 7 5.5 9.590 -2.323 11.675 -0.238 8 5.0 8.718 -2.112 10.613 -0.217 , 9l 4.5 7.846 -1 .901 9.552 , -0.195 b_ l
~~A negative upward load is equivalent to positive downward load.~~
~~8.1.1.4 Sumary The F/A attachment assembly mechanical deadweight, pressure drop, and horizontal / vertical 0BE and SSE seismic loads distributed by rows is sumarized in Table 8.1-5. .a~~
~~-266-~~
~~TABL'E 8.1-5 F/A ATTACHMENT ASSEMBLY SUPPORT SAR MECHANICAL LOAD~~
~~SUMMARY~~
~~DISTRIBUTION BY ROL'S Row Loads (L85)~~
~
Row Deadweight Pressure Drop Horizontal Seismic Vertical Seismic (FDW)i (Fp ), {p H,0BEl i (FV,0BE.D)t (FV,0BE.U}i. (FV,SSE,DI t (FV,SSE U iI' (FH.SSE}i 7.456 10.402 14.821 -3.590 18.043 -0.368 1 9.206 27.693 7.018 9.790 13.949 -3.379 16.981 -0.346 2 8.664 26.064 6.579- 9.178 13.077 -3.168 15.920 -0.325 3 8.123 24.435
.8.567 12.205 -2.957 14.859 -0.303 g 4 7.581 22.806 6.141 -2.745 13.797 -0.282 y 5 7.040 21.177 5.702 7.955 11.334 5.263 7.343 10.462 -2.534 12.736 -0.260 6 6.498 19.548 6.731 9.590 -2.323 11.675 -0.238 7 5.957 17.919 4.825 6.119 8.718 -2.112 10.'613 -0.217 8 5.415 16.290 4.386 3.948 5.507 7.846 -1.901 9.552 -0.195 9 4.874 14.661 ,
I
~~A negative upward load is equivalent to a positive downward load.~~
b
8.1.2 Thermal The F/A attachment assembly thermal loads are the steady state and tran-sient temperature distriubtions that occur during the Upset, Emergency, and Faulted events over the first and second reactor cycles. In the
, definition of the F/A attachment assembly temperature distributions, the sodium temperatures at the reactor vessel inlet were conservatively assumed to be applied directly to the F/A attachment assembly without the mitigating effects of mixing that would normally occur in the inlet plenum. The approach adopted for the F/A attachment assembly transient thermal response is consistent with that taken for the F/A shield block.
Accordingly, the selection of the E-4a transient as the umbrella to all Upset, Emergency, and Faulted transients for the F/A attachment assembly invoked the same rationale used for the F/A shield block. Further, the number and characteristics of the worst case F/A attachment assembly duty cycle are the same as that used for the F/A shield block. The F/A shield block E-4a transient and worst case duty cycle taken for the F/A attach-ment assembly are presented in Figures 4.1-1 and -2, respectively. A derivation of the detailed F/A attachment assembly temperature distri-butions during the worst case thermal duty cycle, in the manner described for the F/A shield block, was not made. Instead, the F/A attachment assembly was assumed to instantaneously follow the reactor vessel inlet sodium temperatures while the F/A shield block was considered to lag because of its thermal inertia. Specifically, the base of the support bar legs welded to the shield block lag the response of the attachment assembly. At steady state, the differential thermal expansion across the support bar and the base of the support bar legs is small. During the E-4a transient, however, differential thermal expansion characterized by relative motion of the support bar relative the base of the support legs occurs because of the thermal lag in the shield block. o
~~-268-~~
_ _ _ - _ _ _ _ _ . _ - - _ - _ ~ . - _ _ _ _ -_ _-_ ._- - _ .. _ _ _ . . _ _ _ _ _ _ i i l ! In order to define the F/A attachment assembly support bar E-4a thermal ' loads in tems of relative base motion, an ANSYS themal and structural , analysis was performed for a portion of the shield block adjacent to the ! base of the support bar legs. Descriptions of the dimensional extent and ' ! finite element detail of the shield block region selected for analysis, thermal and structural analysis and results, and conclusions on the E-4a thermal loads in terms of relative motions of the support bar leg base are presented in the following subsections. 8.1.2.1 Dimensional Extent and Finite Element Detail The F/A shield block region selected to derive the relative motions of the support bar leg base during the E-4a transient was a 2 dimensional l axisymetric clyindrical section which approximates the outer periphery of the shield block directly below the base of the support bar legs. The inner periphery of the cylindrical section was taken tangent to the six , hole pattern provided for sodium flow, while the outer periphery was selected to be tangent to the hex corners of the shield block. The i dimensional extent of the axisymmetric cylindrical section in relation j to the geometry of the shield block, in combination with the finite '
~~! element detail along the elevation extent of the cylindrical section, is illustrated in Figure 8.1-4.~~
It is important to note that the 2 dimensional axisymmetric cylindrical f section only approximates the actual thermal and structural response of i the F/A shield block adjacent to the support bar legs during the E-4a ' transient. The actual response is more 3 dimensional than 2 dimensional 4 axisymmetric. However, the 2 dimensional axisymetric thermal and i structural response was considered representative of the 3 dimensional response for the following reasons. . With regard to thermal response, the 2 dimensional axisymetric sector approximates the 3 dimensional response because the shield block region inside the inner cylinder periphery, containing the seven hole pattern of sodium flow passages, responds more rapidly to the sodium transients , I
~~-269-~~
~~0.15 N1.75 ~~~
~~. . . _ . . - g . . -~~
~~O 15 re tion~~
~~) .._.~~
~~c 4.32 =~~
~~. L . . ,a I~~
~~L T~~
~~..+ - R3 3.0 $N' ,~~
~~14JIl Yj( C, 7 .L. - T~~ 4 y , n _ _ - Figure 8.1 4 J F Attachment Assently Support 8ar Thermal load Model Dimensional Extent and finite Element Detail~~
~~-270-~~
than the region exterior to the inner cylinder periphery. As such, the 3 l dimensional thermal response of the shield block region between the , interior and exterior peripheries of the cylindrical section can reasonably be approximated by applying the sodium transients directly to the 2 dimensional axisymmetric surface formed by the inner periphery of the ; cylindrical section. In terms of structural response, the 2 dimensional axisymmetric sector provides a conservative estimate of 3 dimensional support bar base motion. l With the shield block region inside the inner cylinder periphery responding rapidly to the sodium transients, attendent expansions or contractions act to force the shield block region between the interior and exterior peripheries outward and inward, respectively. As the support bar response is considered to respond instantaneously to the sodium transients, the 3 dimensional support bar base motion relative to the support bar would be diminished by the near in-phase expansions and contractions of the inner shield block region. Accordingly, the 2 dimensional axisymetric sector, which neglects the inner shield block region, would provide an upper bound on motions of the support bar relative to the support bar leg base. The dimensional extent of the axisymmetric section taken to approximate the outer periphery of the shield block was a cylinder with inside radius and wall thickness of 1.75 and 0.75 in., respectively. With regard to the length of the cylindrical section, a minimum length is de-sirable for finite element idealization. The minimum length was selected on the basis that edge effects associated with structural constraints at the lower end of the cylinder would not significantly modify the outward or inward motion of the top of the cylinder where the support bar legs are considered to be attached.
~~-271-~~
From the classical theory of cylindrical shells [14], the local effects of shear and moment are known to diminish rapidly from the point of application. For a cylinder of radius (a), wall thickness (t), and Poisson's ratio (p), the distance (x) at which local effects are attenuated by approximately 95% is given by the relation
~~= - 3 X~~
~~3(1-v2 ) I a2 t 2 Numerically, a = 2.13 in, t = 0.75 in. p = 0.3 Thus, 3~~
* =
X 2 I 3(1 .3 ) (2.13)2 (0.75)2 4 X = 2.95 in., Say X = 3.0 in. With regard to a finite element mesh for the 2 dimensional axisymmetric sector, a total of 90 ANSYS axisymmetric elements in a relatively uniform mesh of 136 node points was selected for the thermal and structural response analysis of the F/A support bar base motion. ll l l c g a
~~-272-I~~
1 8.1.2.2 Thermal Analysis The thermal response of the 2 dimensional axisymmetric sector of the F/A , shield block during the E-4a transient was derived with the heat transfer option of the ANSYS program. Descriptions of the model boundary conditions, wetted sodium surfaces, properties, and results are as follows. 7 8.1.2.2.1 Model, Boundary Conditions, and Wetted Surfaces The 2 dimensional axisymetric thermal model of the F/A shield block in-cluding a simple representation of the support bar and boundary conditions and wetted sodium surfaces is. illustrated in Figure 8.1-5. The F/A shield block was modeled with 90 linear temperature (STIF 35) elements formulated in a condition of axisymmetry. Adiabatic conditions were selected for the bottom lateral surface and the surface forming the exterior periphery. At the top lateral surface and the surface forming the interior periphery, wetted surface conditions were taken with E-4a sodium transient temperatures directly applied to the respective surface nodes. At the top surface, the nodes 16 through 136 were coupled directly to the sodium temperature. Similarly, the interior surface nodes 1 through 16 were coupled to the sodium temperature. ,
~
The F/A support bar was modeled with a single conducting bar (STIF 32) element arranged radially from the line of axisyninetry to a point above . the top surface of the cylinder representing the F/A shield block. Even though the support bar was assumed to respond instantaneously to the sodium temperature transients, the simple thennal representation permits relative displacemants between the shield block and support bar to be conveniently obtained in subsequent derivations of structural response. The support bar node 156 was directly coupled to the sodium temperature and placed directly above the shield block node 96.
~~-273-~~
1 o l Support Bar Simuiation 3 Conducting Bar Element l Node 157 Node 156 l (STIF32) Node 96 Wetted Surface Nodes 1 + 16 / 36 + 136, inc. of 20 ) 156
/
~~Shield Block Simulation Axisymmetric Elements (STIF 35)~~
\
e / tAdiabatic Surfaces 1 Figure 8.1-5 F/A Attachment Assembly Support Bar Thermal Load Model Heat Transfer Boundary Conditions and Wetted Surfaces A
~~-274-l~~
8.1.2.2.2 Properties l The F/A shield block is constructed from SA-316-SS. The thermal conductivity * (K), specific heat (C), and density (p) as a function of temperature (T) f given in Section 4.1.2.2 were used for the 2 dimensional axisymmetric model of the F/A shield block. t The F/A support bar is also constructed from SA-316-SS. The respective thermal conductivity (K) and specific heat (C) as a function of tempera- l ture (T) were taken to be identical to those specified for the F/A shield block. However, the density (p) was selected to be arbitrarily small in order to obtain a near instantaneous response of the F/A support bar to the E-4a transient. 8.1.2.2.3 Results The F/A shield block and support bar thermal response to the first 2400 seconds of the E-4a transient was derived with 14 ANSYS load steps. The sodium temperatures were directly coupled to the end of the support bar, and to the top and inside surfaces of the shield block. Heat generation rates were neglected. Prominent features of the E-4a transient are generally the same as those illustrated for the F/A shield block in , Figure 4.1-5. A summary of the ANSYS input data is presented in Table 8.1-6. TABLE 8.1-6 , F/A ATTACHMENT ASSEMBLY SUPPORT BAR E-4a TRANSIENT ANSYS INPUT DATA Load Time Temp. Step (Sec) ( F) 1 0.0 750 2 20 750 3 80 710 4 200 675 5 260 586 6 400 915 7 760 1000 8 880 975 ' 9 1000 800 10 1140 745 11 1260 745 12 1520 820 735 $ 13 1750 14 2400 600
~~-275-~~
r The ANSYS solution of the E-4a thermal response was obtained in 90 cumula-o tive iterations using steady state and transient convergence criteria or 1 and 5 F, respectively. The temperature distributions in the support bar and shield block at each cumulative iteration were saved on ANSYS 3 Tape 4 for subsequent structural response analysis. Unlike the study of through the wall temperature differences used in structural evaluations of other F/A regions presented in this report, the temperature distributions in the F/A support bar and shield block are not of themselves significant. Accordingly, plots of temperature differences or distributions were not made. Instead, the temperature distributions at each of the 90 cumulative iterations were recommended for the derivation of relative support bar and shield block structural response motions. 8.1.2.3 Structural Analysis The structural response of the 2 dimensional axisymmetric model of the F/A shield block during the E-4a transient was derived with the static analysis opition of the ANSYS program. Descriptions of the model boundary conditions, properties, and results are as follows. P 8.1.2.3.1 Model and Boundary Conditions The 2 dimensional axisymmetric structural model of the F/A shield block
~~. including a simple representation of the support bar and boundary conditions is illustrated in Figure 8.1-6.~~
The F/A shield block was modeled with 90 constant strain (STIF 2) elements formulated in a condition of axisymmetry. In order to permit rigid body radial motion during uniform thermal expansions or contractions, roller supports were simulated by specifying the UY displacements to be zero along the bottcm surface of the cylindrical surface at nodes 1 through 121, increments of 20.
~~-276-~~
e Support Bar Simulation Spar Element Node 157 Node 156 (STIF 1) 1 g M M Node 96 l Shield Block Simulation Axisymetric Elements (STIF 2)
\
ll x C - . . . Roller Supports O / UY = 0.0 Nodes 1 + 121 Inc. of 20 Figure 8.1-6, F/A Attachment Assembly Support Bar Thermal Load Model Structural Boundary Conditions
~~-277- ;~~
The F/A support bar was modaled with a single spar (STIF 1) element arranged to be radially disposed from the line of axisymmetry to a point 6 above the top surface of the cylinder as formulated in the thermal model. The UX displacement of Node 157 was specified to be zero, t 8.1.2.3.2 Properties The F/A shield block and support bar are both constructed from SA-316-SS. The Young's modulus (E), Poisson's ratio (u), and coefficient of thermal expansion (a) for SA-316-SS as a function of temperature (T) are presented in Section 4.2.2.1. In the F/A support bar and shield block structural response, constant material properties at 1000 F were selected. Constant material properties with temperature permits the initial stiffness matrix to be used in structural response derivations of successive temperature distributions. The values taken for both support bar and shield block were: E = 22.53 x 106 psi a = 11.25 x 10 -6 jop , u = 0.305 8.1.2.3.3 Results , The F/A shield block and support bar structural response to the first 2400 seconds of the E-4a transient was derived with 88 ANSYS load steps using the temperature distributions saved on Tape 4 at each of the cumula-tive iterations in the thermal solution run. The structural response assumed that the shield block remained linear elastic during the E-4a thermal loading as the effect of local inelastic behavior at the wetted sodium surfaces would not be expected to significantly alter the overall deformation pattern. With regard to E-4a thermal loads for the F/A support bar, the lateral deformation of the top surface of the shield block relative to the end s
~~-278-~~
of the support bar are of importance. A plot of the UX displacement of the shield block node 96 relative to the UX displacement of the support bar node 156 over the 2400 second duration of the E-4a transient is pre- y sented in Figure 8.1-7. Maximum P Outward Displacement (0.000159 in @ 416.59 sec) 0.0001 ] 1
~~\ \ a 0.0 A -~~
~~v y v 8 ,~~
, I 5 / 3 E -0.0001 !
~~s' 2 ' 2 E~~
~~-0.0002 5~~
~~I 3~~
~~-0.0003 0 480 950 14 .0 liszo 44 JO Time (sec)~~
~~Maximum Inward Displacement (0.000258 in 0 278.67 sec) Figure 8.1-7 F/A Attachment Assembly Support Bar E-4a Thermal Loads Relative Displac_ements~~
~~-279-~~
A review of the relative deformation plot shows a maximum inward displace-9 ment of the base of the support bar legs of 0.000258 in. at 278.67 seconds into the E-4a transient. The maximum outward displacement of the base of the support bar legs is seen to occur at 416.59 seconds with a value of O.000159 in. At steady state, the relative displacement is zero as would be expected. The F/A support bar and block temperatures at the maximum inward and outward displacments were found to be 586 and 1000 F, respec-tively. 8.1.2.4 Conclusions The cor.clusions based on the analysis of the F/A attachment assembly support bar thermal loading were that the inward and outward lateral deformations of the support bar leg base during the E-4a transient are of most significance in establishing the worst case duty cycle. - During the E-4a transient, the F/A attachment assembly support bar thermal loads consist of lateral inward deformation [(6 )TR, L inward] and outward deformation [(6L )TR, outward] applied to the base of the support bar legs. (6L)TR, inward
~~= 0.000258 in.~~
~~(6L)TR, outward~~
~~= 0.000159 in.~~
With regard to the F/A attachment assembly support bar thermal loads during steady state conditions, the lateral deforma tion (6L)ss of the support bar leg base relative to the support bar was neglected.
~~= 0.0 (6L)ss s~~
0
~~-280-3~~
8.1.3 Worst Case Duty Cycle The conclusions based on the F/A attachment assembly support bar loading analysis in relation to recommendations for the worst case duty cycle are as follows. r e Mechanical loads comprising deadweight, pressure drop, and OBE and SSE seismic were considered important in establishing a worst case F/A attachment assembly duty cycle. SSE seismic loads were taken to conservatively bound the OBE loads. e Thermal loads corresponding to lateral inward and outward deformations of the support bar leg base during the E-4a transient were considered important in establishing the worst case F/A attachment assembly duty cycle. In order to establish the sequence of duty cycle loading, a worst case combination of SSE seismic loads was selected based on an assessment of the mechanical loads summarized in Table 8.1-5. The mechanical load assessment was based on load combinations which would maximize ductile rupture and fatigue damage at the base of the support bar leg. The support bar leg base location was selected because it is representative of the weld used to join the support bar legs to the shield block. Creep damage was neglected in the load assessment as steady state - temperatures are 750 F. The weld attachment location is identified in Figures 8.1-1 through -3. U r 4
~~-281-~~
I i t j With regard to steady state mechanical loads, the upward pressure drop l loads are significantly higher than the downward deadweight loads and, as such, tensile strains develop in the weld at the outside surface of the support leg. Considering a SSE load combination consisting of upward l vertical and left horizontal components at steady state conditions, the tensile strains would increase above steady state values. Conversely, l a SSE load combination of downward vertical and right horizontal would provide the maximum compressive strains in the weld. Accordingly, the maximum fatigue damage under SSE loads would occur in the weld region for the strain range between upward vertical /left horizontal and down vertical /right horizontal. Further, maximum ductile rupture would occur at peak tensile strain corresponding to upward vertical /left horizontal in combination with steady state upward pressure drop and downward l deadweight. Other combinations of SSE seismic loads were considered less damaging. The recommendations for the F/A attachment assembly support bar loading were directed to formulating a number of worst case duty cycles that would conservatively bound the 39 specified Upset events and the worst Emergency of Faulted event. A first and second duty cycle of time independent and
dependent loading was selected. The first duty cycle, including successive applications of SSE seismic loading at steady state temperatures in combination steady state deadweight and pressure drop mechanical loads and
<m thermal E-4a lateral deformation loads, followed by a 10 day hold-time, was considered to be applied only once. The second duty cycle comprising the steady state and E-4a transient mechanical and thermal loads followed by the 10 day hold-time, but excluding the SSE seismic loads, was con-sidered to be repeated 38 times. The first and second cycle loading sequence is described as follows. l l l t I
~~-282-~~
I First Cycle - Time Independent (One Application) e Apply the initial steady state upward pressure drop and downward , deadweight loads at the steady state temperature of 750 F. e At the steady state temperature of 750 F, first apply the upward , vertical and left horizontal SSE seismic loads in combination with the upward pressure load. Next, apply downward vertical and right horizontal SSE seismic loads in the absence of pressure drop loads. Repeat the loading sequence until shakedown is observed. e With deadweight acting downwar/, apply and then remove the inward lateral deformation of the support bar leg base during the E-4a transient at a temperature of 150 F. e Maintaining the deadweight, apply and then remove the outward lateral deformation of the support bar leg base during the E-4a transient at a temperature of 1000 F. e Apply the final steady state upward pressure drop and downward deadweight loads at 750 F. < First Cycle-Time Dependent (One Application) e Maintain the upward pressure drop and downward deadweight loads , over a 10 day hold-time at the steady state temperature of 750 F. W G
~~-283-~~
~~Second Cycle-Time Independent (Repeat 38 Times) 6 e Maintain the pressure drop and deadweight loads at 750 F. e With deadweight acting downward, apply and then remove the~~
~~, inward lateral deformation of the support leg base during the E-4a transient at a temperature of 750 F.~~
.l e Maintaining the deadweight, apply and then remove the outward lateral deformation of the support bar leg base during the E-4a transients at a temperature of 1000 F. e Apply the final steady state upward pressure drop and downward deadweight loads at 750 F. Second Cycle-Time Dependent (Repeat 38 Times) e Maintain the upward pressure drop and downward deadweight loads over a 10 day hold-time at the steady state temperature of 750 F. I J J e
~~-284-~~
s j 8.2 Structural Analysis The F/A attachment assembly structural analysis was directed to deriving 9 the stresses, strains, and dimensional changes which occur during the first and second worst case duty cycles from which structural evaluations were made. In the following, the F/A attachment assembly support bar structural model, , geometry, and boundary conditions are described. Next, linear and non- 1
~~> linear material properties including the effects of irradiation on stress-strain curves and the basis for neglecting thermal creep are presented.~~
Finally, the time independent and dependent inelastic analysis and results for the first and second F/A attachment assembly duty cycles are presented in preparation for subsequent structural evaluation. I
8.2.1 Model and Geometry The F/A attachment assembly support bar structural model was formulated in the ANSYS finite element program. A total of 424 constant strain (STIF 2) elements formulated in a condition of plane stress with a unit thickness and arranged in mesh of 489 node points were selected to model
~~! the support bar.~~
l The F/A attachment assembly support bar region selected for analysis , included the full lateral extent of a single support including the length of the support legs above the surface of the shield block, but excluded the regions adjacent to the saw cuts provided for the attachment rails ~ as preliminary analysis showed the effects of the local stress risers to be small. A full structural model was selected because of the non-syaretry in the support bar deformations during horizontal SSE seismic loadings. However, only one support leg, adjacent to the shield block surface, was i modeled in fine d >. tail in order to assure a proper resolution of stress and strain response which was taken to be representative of the attachment weld. Otherwise, the structural model was relatively coarse with the mesh size i selected so that nodes would be provided at the locations of the attachment ! rails where the rod bundle row loads occur. The F/A attachment assembly l support bar structural model illustrating the dimensional extent and finite element detail is presented in Figure 8.2-1. i ! -285-i l
r a B t r o p p u S 4
*4 / - ?- / -
~~a, il.l,, :I~~
I
~~,~ s l.18 18l l.~~
~~e f ' I~~
/ - ' ,11 , , l I ol I / .l. l .l . l 1 l .ll,, . lis - / ' . l . l a
s
~~/ .l. l. s l i~~
~~X- / l i a t~~
. l , l l ::l r e . , l = a D B - ,k c t
~~r t n e al. . fl o l o o p m e Yl . M S p u l E d y t e i/~~
. l l a l 1 5 . l ll e - l i 6 2 b n 2 h '~ m i S 8 e F 4 s e . .
~~l l e s d~~
. . : r A n u a , i F
~~g t n e t n~~
, m e .. l, I::lI h t / c a E x /W t
~~t l A a~~
. l,, ill o A o / i F s n
e
. l l ,11 l a I ,. m l 0 2 , i D
~~ill,~~
~~. , lsil l l \~~
0
/
~~il llisl \ -~~
,
~~fK l~~
~~r ,~~
~~, Il: I I ,N > . ;\ =~~
~~iI. . s s _~~
~~- V ,~~
~~3 0 , 1 2~~
~~, ' 9 ,~~
a 1 a 3 m 6 , 2 hp
9 8.2.2 Boundary Conditions and Loading Application The F/A attachment assembly support bar boundary conditions and loading application are illustrated in Figure 8.2-2. The F/A design layout drawing, included in this report as Figure 2.0-2, identifies the attachment of each support bar leg base to the shield block to be a weld located at the exterior surface of the shield block. Welds are not provided at the interfaces between the remaining sides of each support bar leg and the shield block. The boundary conditions selected for the support bar analysis consisted of fixed conditions along the side of the support bar leg adjacent to the weld provided. As the support bar is modeled in a condition of plane stress, the assumed boundary conditions are in effect totally fixed, which corresponds to fully welded support base to shield block attachment. Even though a full weld is not currently identified on the F/A design drawing, it was assumed for the purposes of analysis that a full weld would be provided prior to fabrication. The fixed boundary conditions were simulated by specifying zero UX and UY displacements at Nodes 1 through 7, and 447 through 489. With regard to load application, mechanical row loads from the tube bundle , comprising deadweight, pressure drop, and SSE seismic were assumed to be locally applied at the roots of the saw cuts, while the E-4a thernal loads were imposed by specifying lateral displacements at the weld attachments. , The mechanical load application points as related to the tube bundle row l through 9 designation scheme considered the center row 1 as Node 223. Row 2 nodes were 209 and 237 to the lef t and right of center, and so forth, for the remaining seven rows. The thermal E-4a loads were specified as equal and opposite UX displacements of Nodes 1 through 7, and 477 through 489 respectively. O e
~~-287-~~
.
6- o c Mechanical Load Points Row Nodes p1 p8 y1 y6 p5 y4 p3 {l p y2_ Jgp{g Q Q .yA pg 1 223 2 209,23) .
3 195.251 1 4 181,265 /
~~, 5 167,279 g ro 6 7~~
~~153,293 139,307 N, \ \/~~
/
~~e 8 132,314 s 9 125,321~~
\ f % ~ ._:ps -C pigt+- pe4i ed.e4 Therr.41 Thermal d Load Points Load Points , < . ,
~~(UX) (UX) X hm, iis~~
~~, , , , , , ,,, ._._.-------n------ - - -~~
Fixed Conditions I bFixedConditions (UX = UY = 0.0) (UX = UY = 0.0) Nodes 1 + 7 Nodes 477 + 489 Figure 8.2-2 F/A ATTACPMENT ASSEMBLY SUPPORT BAR Boundary Conditions and Load Applications
8.2.3 Properties The F/A attachment assembly support bar, located at the top of the shield , block, constructed from SA-316-SS and initially unirradiated at BOL is 22 2 irradiated to a E0L fluence -(E>0.1 Mev, (4t) = 0.31 x 10 N/cm ). Doerational temoeratures rance from 750 to 1000*F. The linear and non-linear properties of SA-316-SS at fluence and temperature selected for the F/A attachment assembly support bar analysis are as follows:
~~8. 2. 3.1 Linear The linear SA-316-SS material properties are the Young's modulus (E),~~
Poisson's ratio (u), and coefficient of therral expansions (a). The material properties as a function of temperature (T s *F) used in the F/A attachment assembly support bar analysis were identical to those identified for the F/A shield block presented in Section 4.2.2.1. 8.2.3.2 Non-Linear The non-linear SA-316-SS material properties required for the F/A attach-ment assembly support bar structural analysis are time independent stress- ' strain, and the time dependent thermal creep constitutive relations. The constitutive relations with attendant singlifications used for the F/A attachment assembly support bar analysis are as follows. a 8.2.3.2.1 Stress-Strain Curves The SA-316-SS stress-strain data given in the NSM Handbook [6] as a function of temperature and fluence are in terms of true average values. As the June 1977 data identifies the E0L fluence (E>0.1 Mev, (ct) = 0.31 x 1022 2 N/cm ) for the F/A shield block in the vicinity of the attachment assembly support bar, the stress at a given strain increases from BOL to E0L because of time dependent hardening through irradiation embrittlement. In the F/A shield block analysis, a mean of true minimum BOL and EOL stress-strain values was taken to represent the stress-strain curve for s t
~~-289-~~
the duty cycles uniformly distributed over the first and second g reactor cycles. The approach was justified as the F/A shield block was essentially deformation controlled under the E-4a thermal loading. However, j in the F/A attachment assembly support bar, mechanical SSE seismic loads l
, in addition to the E-4a thermal loading occur in the first duty cycle while E-4a thermal loadings alone occur in the 38 second duty cycles. Accord-ingly, the approach adopted for the F/A attachment assembly support bar was to take. unirradiated stress-strain data for the first duty cycle at BOL, while the mean of BOL and EOL stress strain data was used for the second duty cycle. In both first and second duty cycles, true minimum stress-strain values over the support bar operational temperature range from 750 to 1000 F were taken because of the essentially static characteristic of the mechanical and thermal loadings.
The SA-316-SS true minimum BOL stress-strain curve and data used for the F/A attachment assembly support bar in the first duty cycle analysis were identical to those used in the F/A orifice plate analysis as presented in Section 9.2.2.2.1. With regard to the mean of the true minimum BOL and E0L stress-strain curve and data used in the second duty cycles, the values were taken to be identical to those used in the F/A shield block analysis described in Section 4.2.2.2.1. 6 s
~~-290-~~
8.2.3.2.2 Thermal Creep Equations The unirradiated SA-316-SS thermal creep-time constitutive relations as a function of stress and temperature are given in the NSM Handbook [6]. The themal creep constitutive relations for irradiated SA-316-SS are not identified as the effects of irradiated are included in the irradiation creep equations. For the F/A attachment assembly support bar, thermal creep occurs at the steady state temperature of 750 F over the 10 day hold-times in the first and second duty cycles. The F/A attachment assembly support bar E0L fluence (E>0.1 Mev)is 0.31 x 22 2 10 N/cm . As the E0L fluence is relatively low and steady state temperatures are below 800 F, thermal creep during both first and second F/A attachment assembly support bar duty cycles was neglected. 8.2.4 Worst Case Duty Cycle Response The structural response of the F/A attachment assembly support bar to the first and second worst case duty cycles was given a preliminary review in order to establish the severity of the mechanical ar' thermal loadings. The preliminary review showed that the stress, stri n, and deformation a response of the F/A support bar would remain linear elastic during the more severe first duty cycle. Accordingly, the recommended single first duty cycle followed by 38 of the second duty cycles was rejected in favor of applying 39 of the first duty cycles. The approach must be viewed as conservative as the SSE seismic loads are repeated in each of the 39 first duty cycles. a e
~~-291-~~
Even though the preliminary review indicated that the F/A attachment assembly support bar structural response would remain linear elastic, the true minimum BOL stress-strain curves for SA-316-SS at 750 and 1000 F were retained in the ANSYS analysis. In addition, the ANSYS small strain-large deformation option was used in the event that the mechanical SSE seismic loads were sufficient to initiate the collapse of the F/A attachment assembly support bar due to elastic / plastic / creep instability. In the following, the ANSYS analysis of the first cycle time independent and dependent loading are presented. As the F/A attachment assembly support bar was modeled in a condition of plane stress, a consideration of reference temperatures and axial constraints as presented for other F/A regions modeled in a plane strain condition and presented in this report was not required. 8.2.4.1 Analysis and Results The ANSYS analysis of the F/A attachment assembly support bar for the i time independent and dependent loadings of the first worst case duty cycle, including unloading for residual deformations, was obtained in a single solution run comprising 15 load steps. The time independent loading were applied at zero time, while the time dependent loading was applied over the 10 day hold-time. Thereafter, the F/A attachment assembly support bar was unloaded for residual deformations. A summary of the first cycle time independent and dependent analysis for the F/A attachment assembly support bar is presented in Table 8.2-1. I i l l
~~-292-l i~~
i
1 l I I TABLE 8.2-1 i F/A ATTACHMENT ASSEMBLY SUPPORT BAR I FIRST DUTY CYCLE TIME INDEPENDENT AND DEPENDENT ANALYSIS
~~SUMMARY~~
a
~~, Load Time Temp. Description Step Iter.~~
(HRS) j ( F) , l -- 1 1 0.0 750 Initial Steady State ! 2 3 . (FDW + pF ) ; 3 1 O.0 l 750 First Seismic Loading l 4 3 ! (Fp +FSSE, U + FSSE,Left) 5 1 f 0.0 750 l Second Seismic Loading) 6 3 , (FSSE, D + FSSE, Right 7 1 0.0 750 First E-4a Loadin 8 3 (FDW + OL, Inward 9 1 0.0 1000 Second E-4a Loading 10 3 (FDW + O L , Outward) 11 1 0.0
~~750 Final Steady State 12 3 (FDW + pF )~~
13 , 1 240 i 750 10 Day Hold-Time (FDW + pF ) 14 1 240 750 Unloading for Residuals 15 3 (No Load) , e
~~-293-~~
~~The F/A attachment assembly support bar structural response to the first cycle of time independent and dependent loadings was saved on ANSYS~~
~
Tape 10 for recall in subsequent structural evaluations. The time independent response in terms of computer plots of equivalent stress and deformations at initial steady state, first and second SSE seismic loadings, first and second E-4a thermal loadings, and final steady state are presented in Figures 8.2-3 through -8, respectively. The time independent initial steady state maximum equivalent stress and deformations during deadweight plus pressure drop mechanical loadings were found to be 2829 psi and 0.000269 in. As the structural response remained linear elastic, the time independent final steady state maximum equivalent stress and deformations under deadweight plus pressure drop mechanical loads were identical to the respective initial steady state values. For the first application of SSE seismic loads, consisting of up vertical and left horizontal, the maximum equivalent stress and deforma-tions were 8992 psi and 0.00045 in. With the second application of SSE seismic loads comprised of down vertical and right horizontal, the maximum equivalent stress and deformations were 7612 psi and 0.00041 in. For the E4-a thermal loads of lateral inward and outward support bar base deformations, the maximum equivalent stresses were 4314 and 1290 psi, respectively.
With regard to the structural response over the 10 day hold-time, the time dependent final steady state maximum equivalent stress and deforma-tion are identical to the time independent final steady state response as relaxation of stresses due to thermal creep was neglected. Further, residual deformations following the removal of all loads after the 10 day hold-time were identically zero as the structural response remained linear elastic. As such, computer plots of equivalent stress and deformations for the time dependent response and unloading for residual deformations are not presented, j
e
~~-294-~~
~~= } Ww "JJ c- -~~
~~7 . 2829 psi - 0.000070 in. 7 0.000269 in.~~
~~.d.h.~~
~~l\ V^ . ' y~~
~~-____________g___________--~~
(
~~; p_________________________,,~~
~~I i :~~
l ; : , Figure 8.2-3 F/A Attachment Assembly Support Bar First Cycle - Time Independent Initial Steady State Deadweight + Pressure Drop Equivalent Stress and Deformations S
~~-295-~~
~~QM J <~~
~~. ~ ,~~
~~P[- ND . [( 1( c~~
/
~~Lu,J~~
~~} 4 -8992 psi 0.00045 in, 0.00045 in.~~
f
~~. t i / + =j p ----------_-__3_____________m_ _~~
~~l l I I e i~~
~~( i :~~
I p I O Figure 8.2-4 F/A Attachment Asse.nbly Support Bar First Cycle - Time Independent First SSE Seismic Loading Pressure Drop & + Vertical + Left Horizontal l Equivalent Stress and Defomations b
~~-296-~~
~~k j ' c >~~
~~\ r N ^ b ]r )~~
~~g - 7612 psi 0 000413 in. 0.000266 in.~~
/
7
~~.= = - _ _ _ _ _ _ _ _ _ _ _ _1 h~~
~~l I I I~~
~~I il l l l l .~~
l l l l l l l l l l I Figure 8.2-5 I F/A Attachment Assembly Support Bar First Cycle - Time Independent Second SSE Seismic Loading Deadweight + Down Vertical + Right Horizontal Equivalent Stress and Deformations l 4
~~-297-~~
~~N s .. I - 4314 psi i I~~
~~.000054 in l l~~
1 l Ah l l l - ____________ ; I i : l l l l l l l l
~~. l. l ! : . 1~~
~~.... l ! l~~
~~= --~~
. -0.000258 in. Figure 8.2-6 F/A Attachment Assembly Support Bar First Cycle - Time Independent First E-4a Thermal Loading Deadweight + Inward Base Motion Equivalent Stress and Defonnations 3
~~-298-~~
~~[#- I I 1290 psi 0.000217 in.~~
~~----_----_-J .-_---_---__~~
~~l n I ; l .--------------------------... ,~~
~~l l A..;~~
~~i 1ll~~
~~> g~~
~~0. 000159 in.~~
~~Figure 8.2-7 F/A Attachment Assembly Support Bar First Cycle - Time Independent Second E-4a Thermal Loading Deadweight + 0utward Base Motion Equivalent Stress and Deformations~~
~~-299-~~
~~ww my c- -m~~
~~/% Y n W- m3 n /s ' i 1~~
~~2. t 2829 psi \~~
~~d $1 y 7 000269 0 in.~~
~~/ j~~
~~_____________g __ _ ___ ____ __ __ __ _ g~~
I
~~, f_ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ q,i :~~
~~q f l l I o l Figure 8.2-8 F/A Attachment Assembly Support Bar First Cycle - Time Independent Final Steady State Deadweight + Pressure Drop Equivalent Stress and Deformations 3~~
~~-300-~~
8.3 Structural Evaluation The F/A attachment assembly support bar structural evaluation was arranged I to provide a comparison of structural response for the 39 worst case duty cycles in relation to criteria which protect against crack initiation and a excessive deformation failure modes and thereby assure F/A attachment as-sembly support bar function over the first and second reactor cycles. The procedure for performing the F/A attachment assembly support bar evalu-ation of crack initiation failure modes considered only the response to the first duty cycle in estimating the response of the 39 worst case duty cycles. The approach is conservative for creep-fatigue damage evaluations as the strain range is controlled by SSE seismic loads which occur only in the first duty cycle. Otherwise, the ductile rupture and deformation evaluations are representative as the response remained linear elastic. A description of the F/A attachment assembly support bar structural evaluation is as follows. t 8.3.1 Crack Initiation The F/A attachment assembly support bar structural evaluation of crack initiation in relation to local ductile rupture and combined creep-fatigue - damage criteria over the 39 worst case duty cycles is presented in the following subsections.
~~, =~~
l 8.3.1.1 Local Ductile Rupture The local ductile rupture criterion for protecting against crack initiation requires that the ductile rupture factor (FDR) be less than unity at each point in the F/A attachment assembly support bar.
~~I* max principal) TF 0.3 cf, min F = Maximum of q f DR~~
~~' (' max principal) TF 'u, min I~~
4
~~-301-I~~
In the following, the allowable uniaxial strains used in the F/A attachment assembly support bar structural evaluation and comparison of results with the local ductile rupture factor criterion are presented. 8.3.1.1.1 Allowable Uniaxial Strains The F/A attachment assembly support bar as constructed from SA-316-SS is unirradiated at BOL. The EOL fluence (E>0.1 Mev) is 0.31 x 10 22 n/cm2 . In addition, the F/A attacnnent asser.bly support bar temceratures range from 750 to 1000*F. The true uniaxial uniforn elongation (cu, min) and fracture (cf, nin) for unirradiated and irradiated SA-316-SS used in the F/A attachment assembly support bar structural , evaluation were taken from the recommendations in the trial { applications of the RDT Draf t for Breeder Reactor Core Components [15-23] and are identical to those taken for the F/A shield block structural evaluation presented in Section 4.3.1.1.1. i With regard to the allowable uniaxial strains of the weld material at the base of the support bar legs, true minimum uniform elongation and fracture strain data in irradiated weld naterials is currently not available. Accordingly, the Code Case 1592 [a] oosition on reductions in carent raterial ductility for weld regions was adopted. Both true ninimun uniforn elongation and fracture strains of irradiated SA-316-SS were reduced by 505 to obtain the allowable weld strains (tw) used in the structural evaluation of the F/A attachment assenbly succort bar welds. (cw)f, nin = 0.5 cf, nin (cw)u, nin = 0.5 cu, nin 8.3.1.1.2 Corparison with Criterion i 1 l Tne F/A attachr.ent asserbly succort bar structural evaluation in relation j to the worst case '.ocation for local ductile ructure was rade by screening l each of the finite eierents over the 39 worst case duty cycles with the l
~~-302-l 4 -- - -, ,,,,,,,---.,.,,,w, - , - - . , - - - - - - - - - , , - . , - - -~~
~~-. .- _ _ _ _ _ - -. . . _ __ _ .. ~ _ , _ _ -~~
damage processor. The maximum local ductile rupture factor (FDR) maxfor the F/A orifice plate was found to occur at element 375, located in the , support bar leg base weld and identified in Figure 8.2-2. The peak BOL strain :omponents occurred at the first SSE seismic loading , in combination with upward pressure drop and deadweight loads where the local metal temperature was 750 F. The accumulated BOL strain components were identically zero as the structural response between the initial time independent and final time dependent steady state of the first duty cycle remained linear elastic. The E0L maximum principal strain was 0.000373 in/in at a triaxiality factor of 1.233. The true minimum irradiated uniform elongation and fracture strains in the support leg base weld region, taken as 50% of the respective SA-316-SS parent material, were 0.038 and 0.491 in/in,respectively. In this arrangement, the maximum local ductile rupture (FDR) for the F/A attachment assembly support bar was controlled by the uniform elongation 4 strain of the weld material with a value: (FDR) max = 0.012 . As (FDR) max < l.0, the F/A attachment assembly support bar is not expected to experience crack initiation over the 39 worst case duty cycles based on . i the local ductile rupture criterion. i 8.3.1.2 Creep-Fatigue Damage The crcep-fatigue damage criterion in protecting against crack initiation requires that the combined creep-fatigue damage factor (FCFD) be less than unity at each point in the F/A attachment assembly support bar. I
~~= Min, of <~~
~~e fDc+D ' FCFD = a/b - Dc+73 D f s 4~~
~~-303-~~
~~In the following, the allowable limits for fatigue life and creep-rupture times used in the F/A attachment assembly support bar structural evaluation~~
~
and a comparison cf the results with the combined creep-fatigue damage factor criterion are presented. 8.3.1.2.1 Allowable Limits The F/A attachment assembly support bar as constructed from SA-316-SS is s 22 2 unirradiated at BOL. The E0L fluence (E>0.1 Mev) is 0.31 x 10 N/cm , In addition, the F/A attachment assembly support bar temperatures range from 750 to 1000*F. The fatigue life and creep rupture time relations used in the F/A attachment assembly support bar structural evaluation were identical to those used in the F/A shield block structural evaluation presented in Section 4.3.1.1.1. The fatigue life and creep rupture time relations representative of F/A attachment assembly support bar peak and steady state metal temperatures at E0L fluence are illustrated in Figure 4.3-1 and -2 respectively. With regard to the allowable fatigue life and creep rupture times of the weld material at the base of the support bar legs, irradiated creep-fatigue data of weld regions is not currently available. Accordingly, the Code Case 1592 [4] position that the fatigue life and creep rupture times of weld regions be taken as the respective values of the parent material was adopted for the F/A attachment assembly support bar welds. 8.3.1.2.2 Ccmparison with Criterion The F/A attachment assembly support bar structural evaluation in relation to the worst case location for combined creep-fatigue damage was made by screening each of the finite elements over the 39 worst case duty cycles wi i the Jamage processor. The maximta combined creep-fatigue damage factor (l'CFD) max for the F/A attachment assembly support bar was found to occur at element 375, located in the support bar base weld and identified l in Figure 8.2-2. l e 9
~~-304-~~
The fatigue damage factor (D ) was found to be 0.108 x 10-5 for ?, worst case duty cycles. The principal strain range was found to be critical . and occurred between the first and secono SSE seismic loadings with a value of 0.000696 in/in. The peak metal temperature over the fatigue i' cycle was 750 F. The fatigue life for the equivalent strain range was . 22 2 36.1 x 106 cycles based on the E0L fluence (E>0.1 Mev, (4t) = 0.31 x 10 n/cm ), The creep damage factor (D c ) was found to be 0.47 x 10-12 for the 39 worst case duty cycles. The principal stress was found to be critical with a value of 2,956 psi corresponding to the steady state temperature conditions at the beginning of the 10 day hold time. For the E0L fluence (E>0.1 Mev, 22 2 (4t) = 0.31 x 10 n/cm ) at a metal temperature of 750*F, the minimum rupture time was 20.98 x 10 15 , In this arrangement, the maximum combined creep-fatigue damage factor (FCFD) max for the F/A attachment assembly support bar was found to be dominated by fatigue damage while creep damage was negligible. (FCFD) max = 0.108 x 10-5 As (FCFD) max <l.0, the F/A attachment assembly supprt bar is not expected to experience crack initiation over the 39 worst case duty cycles based on the creep-fatigue damage criterion. , 8.3.2 Excessive Defomation The F/A attachment assembly support bar structural evaluation of peak plus accumulated, and residual deformations in relation to functional limits over the 39 worst case duty cycles is presented in the following subsections. 8.3.2.1 Peak Plus Accumulated Defomation The peak plus accumulated deformation criterion in protecting against excessive peak defomations requires that peak plus accumulated defonnations (6P+A) be less than the peak plus accumulated deformation limit (PADL). P 6 +A < PADL
~~-305-~~
l i P The F/A attachment assembly support bar peak defonnation (6 ) during the first duty cycle occurred at the first SSE seismic loading with a value of l~ 0.00045 in. The accumulated deformation ( a 685) between the initial time independent and final time dependent steady state conditions was identical fy zero as the structural response remained linear elastic throughout the first l duty cycle. For the 39 worst case duty cycles, the E0L peak plus accumulated (6P+A) deformation is given by the relation. P P (6 +A) = (6 )BOL + (N-1) (a 6ss)BOL P (6 +A)E0L = 0.00045 + 38(0.0) P (6 +A)E0L = 0.00045 in. For the F/A attachment assembly support bar, the specified peak plus P accumulated deformation limit (PADL) is 0.005 in. As 6 +A < PADL, the F/A attachment assembly support bar is not expected to experience failure by excessive deformation during the 39 worst case duty cycles. l
~~8.3.2.2 Recidual Deformations The residual deformation limit in protecting against excessive residual l deformations requires that the residual deformation (6R ) be less than the~~
~
residual deformation limit (RDL). l 6R< RDL R The F/A attachment assembly support bar residual deformation (6 ) after the l first duty cycle at BOL was identically zero as the structural response remained linear elastic. Accordingly, the E0L residual deformation (6 R) E0L after 39 worst case duty cycles, R R (6 ) E0L = N(6 )BOL R (6 ) ECL = 39 (0.0) R
~~. (6 ) EOL = 0.0 = -306-l~~
For the F/A attachment assembly support bar, the specified residual deformation limit (RDL) is 0.005 in. As SR < RDL, the F/A attachment , assembly support bar is not expected to experience excessive residual deformation during the 39 worst case duty cycles. 8.3.3 Sumnery The F/A attachment assembly support bar was found to satisfy the crack initiation and excessive deformation criteria for a total of 39 worst case duty cycles. A summary of the F/A attachment assembly support bar structural evaluation is presented in Table 8.3-1. e 9
~~-307-~~
~~TABLE 8'.3-_1 F/A ATTACHMENT ASSEMBLY SUPPORT BAR STRUCTURAL EVALUATI0tt~~
~~SUMMARY~~
~~. Allowable Calculated Margin of Safety~~
~~Criteria Value Value r~~
Crack Ductile Initiation Rupture 1 0.012 82.33 Factor Combined Creep-Fatigue -5 925,925 1 0.108X10 Damage Factor Excessive Peak + Deforma- Accumulated 0.005 in. 0.00045 10.11 tion _, Residual 0.005 in 0.0 cc = $
~~Mar i9 n of Safety = Allowable Value .)~~
~~Calculated Value l l l~~
~~-308-l I ,w,---- -, m., - ,~~
)
i 9.0 ORIFICE PLATE ANALYSIS AND EVALUATION In the F/A orifice plate analysis and evaluation, a loading analysis was ,
' made that considered mechanical pressure drop, and thennal steady state and transient loads in establishing the number and characteristics of a j worst case duty cycle that umbrellas all expected duty cycles for the .
~~orifice plate region in the first and second reactor cycles. Next, an inelastic structural analysis of the orifice plate region was made for~~
~~a single worst case BOL duty cycle to calculate the strains and dimensional i~~
changes from which EOL values were approximated. Finally, a structural i evaluation of E0L strains and dimensional changes was made in relation to criteria which protect against crack initiation and excessive deformation. l A sununary of the loading, structural analysis, and structural evaluation is presented as follows. l 9.1 Loading Analysis ; The F/A orifice plate loading analysis was directed to establishing the i number and characteristics of a worst case duty cycle that umbrellas both the number and characteristics of Upset, Emergency, and Faulted Events specified over the first and second reactor cycles. The number and < characteristics of these events are specified in the Equipment Specifica- , t i tion [1]. 1 It is important to note that the worst case F/A orifice plate duty cycle is, , in itself, hypothetical, but pemits a conservative structural evaluation
~~to be performed on a single duty cycle instead on each of the individual~~
! events specified. In the following, the F/A orifice plate mechanical and thermal loads are assessed individually and in relation to each other prior to establishing the worst case duty cycle which was used in structural evaluation. l r 9.1.1 Mechanical The F/A orifice plate mechanical load of any significance in relation to subsequent structural evaluations is the pressure drop under sodium flow, as deadweight and OBE/SSE seismic and core restraint loads are relatively . I insignificant. i
~~= i~~
! -309-
l In order to establish the worst case F/A orifice plate pressure drop loading, the CRBRP core was reviewed in relation to flow zones, the number
~~, of orifice plates in each F/A of a particular flow zone, and the total pressure drop across the full number of orifice plates in a F/A of a flow l zone, e~~
For the CRBRP core design, a total of five flow zones, designated as flow zones 1 through 5, are provided. The F/A in flow zones 1 and 2 contain 2 orifice plates. In flow zone 3, each F/A is provided with 3 orifice plates. Each F/A in flow zones 4 and 5 include 4 orifice plates. With regard to the F/A orifice plate pressure drop under steady state flow conditions, consideration was given to the total pressure drop across the full number of orifice plates in a F/A according to the flow zone. For the flow zones 1 through 5, the total pressure drops were 26.75, 29.84, ; 33.94, 37.58, and 41.63 psi, respectively. I The average steady state pressure drop (a p),y was calculated from the total pressure drop (a p) TOT and the number (N) of orifice plate using the relation. ' * = (Ap)T0T (Ap)av g A summary of the average steady state pressure drop for the number of F/A orifice plates in the CRBR core flow zones is presented in Table 9.1-1. TABLE 9.1-1 F/A ORIFICE PLATE AVERAGE STEADY STATE PRESSURE DROPS Flow Total Pressure Number of Average Pressure Zone Drop Orifice Plates Drop l (PSI) (PSI) ( l 26.75 2 13.38 29.84 14.90 2 2
~~3 33.94 3 11.31 l~~
~~4 37.58 4 9.39 5 41.63 4 10.41~~
~~-31 0-~~
1
)
A review of the average F/A orifice plate pressure drops shows that the worst case steady state loading occurs in flow zone 2 containing 2 orifice ' plates where the average pressure drop is 14.90 psi. However, the actual 1 pressure distribution over a series arrangement of orifice plate is not uniform, but is greater for the leading orifice plate. An estimate of the ' actual pressure drop in the leading orifice plates is 50% greater than the average pressure drop. Accordingly, the worst case F/A orifice plate steady state pressure drop (ap)ss was taken according to the relation.
=
~~(Ap)ss 1.5 (ap)av (ap)ss = 1.5 (14.9 psi) i (Ap)ss~~
~~= 22.35 psi.~~
t With regard to the variation in pressure drop across the F/A orifice plates , l during the Upset, Emergency, and Faulted Transients, sodium flows at steady state conditions iecrease to 7.5% of nominal conditions inanediately after the transients aid initiated and return to 100% of nocinal conditions upon the return to steady state conditions. Accordingly, the maximum F/A
)'
orifice plate pressure drop occurs during steady state flow conditions while the pressure drop during the transients are negligible. For the , purposes of the F/A orifice plate structural evaluation, the transient pressure drop (ap)TR was taken to be zero. i . 1 0.0 (ap)TR i
~~E 311- '~~
~~9.1.2 Thermal~~
. The F/A orifice plate thermal loads are the steady state and transient temperature distributions that occur during the Upset, Emergency, and Faulted Events over the first and second reactor cycles. In the
definition of the F/A orifice plate temperature distributions, the sodium temperatures at the reactor vessel inlet were conservatively assumed to be applied directly to the F/A orifice plate without the mitigating effects of mixing that would normally occur in the inlet plenum. The approach adopted for the F/A orifice plate transient themal response is consistent with that taken for the F/A shield block. Accordingly, the selection of the E-4a transient as the umbrella to all Upset, Emergency, and Faulted transients for the F/A orifice plate invoked the same rationale used for the F/A shield block. Further, the number and characteristics of the worst case F/A orifice plate duty cycle are the same as that used for the F/A shield block. The F/A shield block E-4a transient and worst case duty cycle taken for the F/A orifice plate are presented in Figures 4.1-1 and -2, respectively.
A derivation of the detailed F/A orifice plate temperature distributions during the worst case thermal duty cycle, in the manner described for the l l F/A shield block, was not made. Instead, the F/A orifice plate was assumed ! to instantaneously follow the reactor vessel inlet sodium temperatures while the mating F/A inlet nozzle housing was considered to lag the F/A orifice
~
plate response because of its thermal inertia. The thermal response assumption is conservative in relation to the subsequent structural evaluation of the F/A orifice plate under thermal loads. For the F/A orifice plate responding instantaneously to the sodium temperatures, the radial gap between the periphery of the orifice plate and the inlet nozzle housing are closed and interfere to a greater amount than if the themal inertia of the orifice plate were considered. 1 i
~~-312-i~~
In order to define the F/A orifice plate thermal loads induced by in-plane radial interference, the temperature difference (IT) between the orifice . plate or sodium and the inlet nozzle housing during the E-4a transient is required. An estimate of the temperature difference (IT) is to use the
~~-T ,~~
plot of the temperature difference (AT) between Nodes 1 and 237, AT = T237 j , in the F/A shield block thermal model during the E-4a transient as illustrated in Figure 4.1-6. IT = AT . The estimate of the temperature difference (IT) is conservative because the F/A shield block region is thick-walled with greater thermal inertia than the relatively thin-walled inlet nozzle mating housing. A review of the F/A shield block temperature difference (AT) plot shows both positive and negative values during the E-4a transient. As applied to the F/A orifice, positive temperature differences tend to open the gap at the orifice plate periphery while negative values cause the gap to close and cause interference. With regard to structurally damaging in-plane thermal loads, only the negative temperature differences which place the orifice plate in in-plane compression due to radial interference are of significance. Positive temperature differences do not place the orifice plate in in-plane tension because the orifice plate is free to slide inward on the locating pins. The maximum negative temperature difference (IT max
~~for the F/A orifice plate is:~~
~~(IT) max = 170 F i 9 W~~
~~-313-~~
~~In order to establish the maximum amount of radial interference (6r ) at the outer orifice plate periphery during the E-4a transient the following relation was used.~~
=
, (6r)TR a R, (IT) max - 0 Where, a = Coefficient of thermal expansion (1/*F) R, = Nominal outer radius (in) G = Nominal gap (in) Numerically, the F/A orifice plate nominal outer, radius (R,) and gap (G) are 1.87 and 0.0025 in. respectively. For the F/A orifice plate constructed from SA-316-SS, the coefficient of thennal expansion (a) as a function of temperature (T s F) is given in the F/A shield block analysis described in Section 4.2.2.1. During the E-4a transient, the peak F/A orifice plate temperature is 1000 F. The corresponding coefficient of thermal expansion (a)is11.25x10-6*F. / Accordingly, the worst case F/A orifice plate E-4a transient radial interference (6 )TR r taken for the thermal loads. (6r)TR
=
~~(11.25 x 10-6/ F) (1.87) (170)-0.0025 (d r)TR~~
~~= 0.00108 in.~~
~~With regard to the F/A orifice plate thennal loads during steady state conditions, the radial interference (6 ) rdoes not exist and was neglected in the structural evaluation.~~
~~= 0.0 (67)ss l~~
l
~~-314-l~~
~~9.1.3 Worst Case Duty Cycle The conclusions based on the F/A orifice plate loading analysis in relation to recommendations for the worst case duty cycle are as follows.~~
+
e Mechanical loads comprising OBE and SSE seismic, and core restraint, internal pressure, and deadweight are negligible. Only the steady state pressure drop is of relative significance in establishing the worst case F/A orifice plate duty cycle. e Thermal loads corresponding to in-plane radial interference at the outer orifice plate periphery during the E-4a transient was considered most important in establishing the worst case l F/A orifice plate duty cycle. The recocmendations for the F/A orifice plate loading were to apply a single worst case duty cycle of the time independent mechanical loads combined with time dependent thermal loads. The worst case duty cycle was recommended to be repeated 39 times so as to umbrella the 39 Upset and worst Emergency or Faulted events specified for the F/A orifice plate. The single cycle loading sequence is as follows. . Time Independent e Apply the worst case pressure drop at the initial steady state . temperature of 750 F. e Reduce the pressure drop to zero at the start of the E-4a transient while maintaining the 750 F steady state temperature. e With the pressure drop removed, apply the worst case radial interference at the peak E-4a transient temperature of 1000*F. e Remove the radial interference and apply the worst case pressure drop at the final steady state temperature of 750*F. lime Dependent e Maintain the worst case pressure drop over a 10 day hold-time at the 750 F steady state temperature. .
~~-315- --m_ -- _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ . _ _ _ _ - . _ .-__ - - - - . _ . . - - - _ - - - - - - - _- - .~~
~~- -.a - >.w - - - - - - m- :L-. a 2 -Aa,-_a-_- s4_ - J .- -, ------4.,, .ma ---h -~~
~~_ .._,J_S 3, 9.2 Structural Analysis~~
, The F/A orifice plate structural analysis was directed to deriving the stresses, strains, and dimensional changes which occur during the worst case duty cycle from which structural evaluations were made. In the . following, the F/A orifice plate structural model and geometry are described.
l Next, linear and nonlinear material properties including the effects of l irradiation on stress-strain curves and the basis for neglecting thermal l j creep are presented. Elastic an? lysis is presented to establish that I mechanical pressure drop loading is neglible in relation to thermal loading induced by radial interference at the orifice plate periphery. Finally, the time independent and dependent inelastic analysis and results for the worst case F/A orifice plate duty, cycle are presented in preparation for subsequent structural evaluation. 9.2.1 Model and Geometry l The F/A orifice plate structural model was formulated in the ANSYS finite l l element program. In the pressure drop analysis, the triangular plate l (STIF 13) and quadrilateral plate (STIF 63) elements were used to derive the out-of-plane bending stresses and strains. For the analysis of in-l . plane response to radial interference loadings, the constant strain (STIF 2) element in a condition of plane stress with a constant thickness was used. In both the pressure drop and inplane response ANSYS analysis, the geometry and finite element mesh were identical in deriving the structural response. The F/A orifice plate region selected for analy:is corresponds to a symmetrical 30* sector taken through the 6 hole flow pattern. The 30* I symetrical sector is justified as pressure drop and radial interference loadings are essentially uniform. The F/A orifice plate structural model l illustrating the dimensional extent and finite element detail of the 30* l sector is presented in Figure 9.2-1. l 316-i
c cg : L (7,koG>>N
~~] ~~~
~~w\ O) .~~
~~\ ~~~
~~N >i~~
~~-317-~~
9.2.2 Properties The F/A orifice plate as constructed from SA-316-SS and initially unirradiated at BOL is irradiated to a fluence (E>0.1 Mev, (?t) = 0.0066 x 102? n/cm2 ) at E0L. Operational temperatures range from 750 to 1000 F. The linear and non-linear properties of SA-316-SS at fluence and temperature selected for the F/A orifice plate analysis are described as follows. I 9.2.2.1 Linear 1 The linear SA-316-SS material properties are the Young's modulus (E), Poisson's ratio (u), and coefficient of thermal expansion (a). The material properties as a function of temperature (T s F) used in the F/A orifice plate structural analysis were identical to those identified for the F/A shield block presented in Section 4.2.2.1. 9.2.2.2 Non-Linear The non-linear SA-316-SS material property behavior required in the F/A orifice plate structural analysis are the time independent stress-strain, and the time dependent therual creep constitutive relations. The con- . stitutive relations with. attendant simplifications used in the F/A orifice plate analysis are as follows. 9.2.2.2.1 Stress-Strain Curves The true average stress-strain curves for SA-316-SS given in the NSM
~
Handbook [6] were reviewed in relation to the F/A orifice plate E0L fluence (E>0.1 Mev, (ct) = 0.0066 x 10 22 N/cm2 ) and the operational temperature range from 750 to 1000 F. Temperature effects were found to be significant, but the effect of irradiation at EOL fluence relative to unirradiated BOL values was found to be insignificant. Accordingly, the true average E0L and 80L stress-strain curves for SA-316-SS were considered identical to each other for the F/A orifice plate. e e
~~-318-~~
i In the F/A orifice plate structural analysis, true minimum BOL and E0L ' stress-strain curves sre required because the mechanical and themal loads i which occur during the worst case duty cycle are slow acting and are basically statically applied. The true minimum BOL and EOL stress-strain curves
i as a function of temperature, taken as 90% of the true values given in the l NSM Handbook [6], are illustrated in Figure 9.2-2 with corresponding l
numerical values summarized in Table 9.2-1. I TABLE 9.2-1 ; r F/A ORIFICE PLATE i TRUE MINIMUM BOL AND EOL STRESS-STRAIN DATA SA-316-SS i F Temp Stress (PSI) at Total Strain E 0.00049 0.00249 0.0105 0.0205 0.0505 ( F) (106 PSI) 12,370 17,100 23,490 26,100 34,740 J 750 24.77 11,250 15,750 20,250 24,930 33,750 1000 22.53 I 9.2.2.2.2 Tliermal Crecp Equations The unirradiated SA-316-SS thermal creep-time constitutive relations as a function of stress and temperature are given in the NSM Handbook [6].
~~The thermal creep constitutive relations for irradiated SA-316-SS are not identified as the effects of irradiation are included in the irradiation creep equations.~~
22 2 For the F/A orifice plate, the EOL fluence is 0.0066 x 10 n/cm with thermal creep occuring at a steady state temperature of approximately 750*F I over the 10 day hold time of the worst case duty cycle. As the E0L fluence is relatively low and steady state temperatures are below 800'F themal creep over the worst case F/A orifice plate duty c1cle was neglected. f l I l ' l l ! -319- ' l
e 0
~~'5 0~~
~~o 5~~
~~' 4 0~~
0
~~' 4 0~~
5
~~' 3 0~~
F 0 0 0 0 ' 3 1 0 s e v r ) u n C 5 i n 2 a i 0 r e a t r f S t * ( S 0 '
~~- 5 c s 7 s 0 e 2 e r '~~
~~0 t t o 2 a S~~
~~- l 2 P S L '~~
~~S 0 9 e 6 E c 1 e r i f 3 d n 5 1 u i A a 0 g r S i O L F O A B '~~
/
~~F m u 0 i m ' 1 n 0 i M e u r T 5 0~~
~~' 0 - . - - - - . - ' - 0 ,~~
0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 5 0 5 0 5 0 . 1 4 3 3 2 2 1 a 7*[e o LY
9.2.3 Elastic Response The F/A orifice plate elastic structural response to the pressure drop and radial interference loading was obtained in order to determine their relative importance in the worst case duty cycle. The ANSYS analysis and results are described as follows. 9.2.3.1 Pressure Drop 9.2.3.1.1 Model and Boundary Conditions The ANSYS elastic structural response of the F/A orifice plate to pressure drop loading was obtained using the geometry and finite element mesh identified in Figure 9.2-1. The F/A orifice plate structural model for pressure drop analysis included 9 elastic triangular (STIF 13) and 59 elastic quadrilateral (STIF 63) flat plate elements arranged in a finite element mesh of 252 node points. The F/A orifice plate pressure drop structural model illustrating the boundary conditions is presented in Figure 9.2-3. Simply supported boundary conditions were simulated at the outer periphery of the 30 sector by specifying the UZ displacements, normal to X-Y plane, to be zero at nodes 113 through 119. The boundary conditions along the lateral surfaces of the 30 sector were selected to maintain the symmetry - of the deformations under the pressure drop loading. Along the lateral surface coincident with the Global X-Axis, the UY displacements and ROTX rotations were set equal to zero at Nodes 1, 2, 5, 201 through 204, 249 through 252,106, and 113. For the lateral surface inclined to the Global X-Axis, the UY displacements and ROTX rotations, after a -30 rotation to obtain normally disposed directions, were set equal to zero at Nodes 1, 4, 7, 8, 216, 220, 224, 9, 11, 14, 105, 112 and 119. O
~~-321-~~
~~r-- Symetry Conditions (UY = ROTX = 0.0)~~
~~Nodes (1, 2, 5, 201 thru 204, 249 thru 252,106,113)~~
~~O X Simple Supports (UZ=0.0) I Nodes~~
~~/ (113 thru 119)~~
~~I. - Element~~
~~\ ! 18 . Y -~~
~~oooooeoc oooooooooooooooooooooo e // // // /l// / / / / // / / / / / / / / / / // / / / / /~~
~~-Node 1 Symmetry Conditions (UY = ROTX = 0.0)~~
~~Nodes (1, 4, 7, 8, 216, 220, 224, 9,11,14,105,112, and 119) Figure 9.2-3 F/A Orifice Plate Pressure Drop Structural Model s l~~
~~-322-1~~
b i 9.2.3.1.2 Analysis and Results j , The F/A orifice plate elastic response to the pressure drop loading was obtained in a single ANSYS solution run. The orifice plate minimum thickness of 0.240 in was taken in the analysis. The steady state , pressure drop (Ap)ss of 22.35 psi was applied to the lateral face of each element. The SA-316-SS material properties of Young's modulus (E) and , l Poisson's ratio (u) were taken at 750*F. I The F/A orifice plate maximum equivalent stress was found to be 2284 psi. The maximum 'JZ displacement was 0.00075 in. The maximum equivalent stress and UZ displacement occurred at element 18 and node point 1 as identified in Figure 9.2-3. < The elastic structural response of the F/A orifice plate under the steady state pressure drop shows that the maximum equivalent stress is well below the SA-316-SS proportional elastic limit stress of 12,370 psi at 750*F. Plots of maximum equivalent stress and perpendicular UZ dispicacement contours are presented in Figure 9.2-4. i e t i { 4 I b ! t i 1
~~-323-~~
~~i i e 1 l 1 o 1~~
> I 1 ! 2284 PSI , 1 i /
~~l [~~
,/
~~IL' . 4 l l t I l 0.r, in i i 7 e,;0.00075 in.~~
\\ ' \, ,
~~N .~~
%~ . ! I Fiaure 9.2-4 F/A Orifico Plate Pressure Drop Elastic Response "~ouivalent Stress and Perpendicular Displacements s * -324-
9.2.3.2 Rad _ial Irterference 9.2.3.2.1 Model and Boundary Conditions i The ANSYS elastic structural response of the F/A orifice plate to radial interference loading was obtained using the geometry ..d finite element mesh identified in Figure 9.2-1. The F/A orifice plate structural model for radial interference analysis included 68 constant strain (STIF 2) elements formulated in a condition of plane stress with a constant thickness and arranged in a finite element mesh of 252 node points. The F/A orifice plate radial interference structural model illustrating the boundary conditions is presented in Figure 9.2-5. ~ The radial interference (6r) deformations at the outer periphery of the
~~30* sector were specified as the in-plane UX displacements af ter rotating the local coordinates of the node points on the periphery to obtain~~
{ radially disposed directions. For node points 113 through 119, arranged counter-clockwise from the Global X-axis, the rotations of the local coordinates were 0 to 30 , in increments of -5*. The boundary conditions along the lateral surfaces of the 30 sector were selected to maintain the , syynetry of the deformatiors under radial interference loading. Along the lateral surface coincident with the Global X-Axis, the UY displace-ments were set equal to zero at Nodes 1, 2, 5, 201 through 204, 249 , through 252, 106 and 113. For the lateral surface inclined to the Global X-Axis, the UY uisplacements, after a -30 rotation 'o obtain normally disposed directions, were set equal to zero at Nodes 1, 4, 7, 8, 216, 220, 224, 9,11,14,105,112, and 119. t
~~-325 ~ .~ . . - .. _ - --~~
~~o O -- Symetry Conditions (UY = 0.0) Nodes (1, 2, 5, 201 thru 204, 249 thru 252, 106, 113) X~~
- Radial , y Displacements i .. UX Nodes (113 thru 119) 1 Element 7 21 ./
~~Y oooooooo oooooooooooooooooooooo'~~
~~~ ///////// A/////// /// /// ////// /// -Symetry Conditions (UY = 0.0) f! odes (1, 4, 7, 8, 216, 220, 224, 9,11,14,105,112 and 119)~~
~~Figure 9.2-5 F/A ORIFICE PLATE RADIAL INTERFERENCE STRUCTURAL MODEL l~~
~~-326-~~
9.2 .3 . 2. 2 Analysis and Results The F/A orifice plate elastic response to the radial interference loading was obtained in a single ANSYS solution run. The orifice plate minimum thickness of 0.240 in, was taken in the analysis. The radial interference (6r) at the maximum E-4a transient value of 0.00108 in, was applied to the outer orifice plate periphery. Velues of Young's modulus (E) and Poisson's ratio (p) material properties were taken at 1000 F. The elastically calculated F/A orifice plate maximum equivalent stress was fnund to be 28,383 psi. The maximum equivalent stress and attendant in-plane deformation occur at element 21 and outer periphery Nodes 113 through 119 as identified in Figure 9.2-5. The elastic structural response of the F/A orifice plate under the maximum E-4a radial interference shows that the maximum elastically calculated equivalent stress is well beyond the SA-316-SS proportional elastic limit stress of 11,250 psi at 1000 F. Plots of the maximum equivalent stress and in-plane displacements are presented in Figure 9.2-6. 9.2.3.3 Conclusions . The conclusions based on the elastic analysis of the F/A orifice plate under pressure drop and radial interference loading are as follows. e Pressure drop loadings produce stresses within the F/A orifice plate which are well below the proportional elastic limit. e Radial interference loadings cause elastically stresses within the F/A orifice plate which are well above the proportional elastic limit. e Only radial interference loadings are of significance in the worst case F/A orifice plate duty cycle. Pressure drop loadings can be neglected without a significant loss of accuracy in overall structural response. , r
~~-327-~~
~~Q O . l n 1~~
- 28,383 psi 'x / 1 J yi / m - --- 0.00108 i n. /
Ab
~~\ ' \ \~~
~~l \ i~~
~~\ \ /~~
~~N / j FIGURE 9.2-6 F/A ORIFICE PLATE RADIAL INTERFERENCE ELASTIC RESPONSE EQUIVALENT STRESS AND IN-PLANE DEFORfiATIONS l~~
~~-328-~~
9.2.4 Worst Case Duty Cycle Response a The F/A orifice plate structural response to the worst case duty cycle included only the thermal loads caused by radial interference as the mechanical loads caused by pressure drop were shown to be negligible. Further, the response to both first and second duty cycles was used to approximate the response to the 39 worst case duty cycles. The first cycle was considered to be applied once, while the second cycle was repeated 38 times. The F/A orifice plate structural response to the time independent and dependent loadings of the first cycle provides the basis from which evaluations of crack initiation in terms of local ductile rupture and creep-fatigue damage are made. For the evaluation of peak plus accumulated and residual deformation over the 39 worst case duty cycles in relation to deformation limits, the response of both first and second duty cycles were used. In order to obtain the first and second cycle response in an efficient manner, the ANSYS restart option was used to provide the loading sequence within, between and after the time independent and time dependent solutions. As elastic / plastic / creep instability would not be expected for the F/A orifice plate under the deformation controlled radial interference loadings, . the ANSYS small strain-small deformation option was used in the inelastic analysis. Descriptions of the first and second cycle time independent and dependent analysis and results are as follows. , 9.2.4.1 First Cycle-Time Independent The first cycle time independent ANSYS analysis of the F/A orifice plate was directed to deriving the peak plus accumulated strains and deformations associated with following the path dependent radial interference loadings from initial steady state conditions through the E-4a transient followed by the return to final steady state conditions, but excludirig i.he 10-day hold-time. The time independent loadings were considered as static loadings applied at zero time. A total of 5 load steps were used to derive the first cycle-time independent F/A orifice plate response from initial to final steady state conditions as sumarized in Table 9.2-2. , a
~~-329-~~
~~l l TABLE 9.2-2 l F/A ORIFICE PLATE FIRST CYCLE-TIME INDEPENDENT ANALYSIS~~
~~SUMMARY~~
~~Load Iterations Temperature Radial Description Steps Distribution Deformation (F) (or~~
IU) 1 1 750 None Initial Steady State 2 1 1000 None Peak E-4a Loading 3 12 1000 0.00108 and Unloading 4 1 1000 None 1
5 1 750 None Final Steady State The F/A orifice plate structural response to the first cycle time independent loading was obtained with a plastic convergence ratio of 0.01. The detailed stress, strain response at each of the converged solutions was saved on ANSYS Tape 10 for subsequent recall in structural evaluations. The initial and final time independent maximum equivalent stresses were zero and 3449 psi. During the E-4a transient, the maximum equivalent stress and non-a uniform deformation at the maximum radial interference were found to be 14,305 psi and 0.0011 in. The initial and final time independent steady state non-uniform deformations were zero and 0.0004662 in. Computer plots l of first cycle time independent peak and final steady state response are j presented in Figures 9.2-7 and -8. l 8 s -330-
+
~~i V i/ 14,105 psi - . P e 411 ; i AY h jj)))f 0.0011 in.~~
,/
7
~~'\ \ \~~
~~l i \~~
~~/ - 1 I~~
~~I fjspre_9,2 7 Q6_ Orifice plate First Cvcle - Tir:e Independency Peak E-4a_gadial.Jnterference Iduivalent Stress and f!on-l!niform Defomation i , s~~
~~-331-~~
~~e O e l i ! ! '~~
~~- 3,449 psi ,~~
~~Y [ \\ p~~
- 0.0004662 in. /:. '. \ \ \ \
~~I \~~
' \ / .- / 1 - t i
Figure 9.2-8 F/A Orifice Plate First Cycle - Time Independent Final Steady State Equivalent Stress and tion-Unifom Defomation e s -332-
9.2.4.2 Firs; Cycle-Time Dependent The first cycle time dependent ANSYS analysis of the F/A orifice plate ' was directed to deriving the final steady state strains and defonnations associated with the 10 day hold-time. As thennal creep was neglected , for the F/A orifice plate, the final time dependent steady state response was identical to the time independent final steady state response. Never-theless, a time dependent solution was still derived in order to initialize the second duty cycle. The first cycle time dependent solution was obtained in load step 6 for 1 iteration over the 240 hour hold-time with an ANSYS restart from load step 5 of the first cycle time independent
analysis, 9.2.4.3 Second Cycle-Time Independent The second cycle time independent ANSYS analysis of the F/A orifice plate was directed to deriving the peak and final steady state response associated with the second application of the radial interference loading at 240 hours. Using an ANSYS restart from load step 6 of the first cycle time dependent solution, a total of 3 additional load steps were used to derive the second cycle time independent response as summarized in 4 Table 9.2-3.
~~TABLE 9.2-3~~
?
~~F/A ORIFICE PLATE SECOND CYCLE-TIME INDEPENDENT ANALYSIS~~
~~SUMMARY~~
~~load Iterations i Temperature Radial Description Steps Distribution Deformation ( F) (6r~~
~~I"*)~~
7 1 750 None Initial Steady State 8 12 1000 0.00108 Peak E-4a Loading 9 1 750 None Final Steady-State . >
~~-333-~~
During tha E-4a transient, th] maximum cquivalcnt stress and peak non-uniform deformation was found to be 14,799 psi and 0.0011 in. The final m steady state maximum equivalent stress and peak non-uniform deformation ')* were 3055 psi and 0.0004748 in. Corresponding computer plots are presented in Figures 9.2-9 and -10. C 9.2.4.4 Second Cycle-Time Dependent The second cycle time dependent ANSYS analysis of the F/A orifice plate was obtained in load step 10 for 1 iteration at 480 hours using a restart from load step 9 of the second cycle time independent analysis. As thermal creep was neglected, the time dependent stress and deformation response was identical to the second cycle time independent final steady state response. l I J -334
F -_
/
~~D 14.799 psi , v1h W r~~
nnk /b d .,0.0011 in. ,# \ \ .A \ \ - \ 'l \ / - } / /
~~f __ I Figure 9.2-9 F/A Orifice Plate ' Second Cycle - Time Independent Peak E-4a Radial Interference Equivalent Stress and Non-Unifonn Defomation ,~~
~~-335-~~
~~\ \ \ ! \ \ .-- 3,055 ps i N~~
~~f N~~
~~\ / N ,, 0.00'M718 in.~~
~~( A,y\ \~~
~~\ \~~
~~i \~~
' \ / * / I - 1 I
~~Figure 9.2-10 F/A Orifice Plate Second Cycle - Time Independent Final Steady State Ec.sivalent Stress and Non-Uniforn Defomation u~~
~~-336-~~
~~. . - _ - = _ . - . . . . - .-~~
1 I i 9.3 Structural Evaluation , The F/A orifice plate structural evaluation was arranged to provide a ,
comparison of the structural response for the 39 worst case duty cycles in relation to criteria which protect against crack initiation and 3 excessive deformation failure modes and thereby assure F/A orifice plate function in the first and second reactor cycles.
The procedure for performing the F/A orifice plate evaluation of crack I initiation failure modes considered only the response to the first duty cycle in estimating the response of the 39 worst case duty cycles. The approach is renresentative for creep fatigue damage evaluations as strain range and residual stresses do nct change appreciably during successive duty cycles. However, the ductile rupture evaluation based on the first duty cycle is conservative because the difference in strain components between initial and final steady state conditions are reduced significantly in successive duty cycles. Nevertheless, only the first duty cycle response was used because the local ductile rupture criterion could be satisfied f even though the evaluation was conser,ative. For evaluations of peak 4 plus accumulated and residual deformations, the conservatism in using the , first duty cycle alone could not be invoked and still establish acceptability. Accordingly, both first and second duty cycle deformation response were used in establishing the F/A orifice plate acceptability in relation to j excessive deformation. A description of the F/A orifice plate structural evaluation is presented as follows. l 9.3.1 Crack Initiation The F/A orifice plate structural evaluation of crack initiation in l relation to local ductile rupture and combined creep-fatigue damage ! criteria over the 39 worst case duty cycles is presented in the following subsections. i 4 9 l a r k
~~-337-~~
9.3.1.1 Local Ductile Rupture The local ductile rupture criterion for protecting against crack initiation ,) requires that the ductile rupture factor (FDR) be less than unity at each point in the F/A orifice plate. 4 I' I' max principal) TF F = Maximum of 0.3 cf, min I DR (' (" max principal) TF
~~'u , min In the following, the allowable uniaxial strains used in the F/A orifice plate structural evaluation and comparison of results with the local ductile rupture factor criterion are presented.~~
9.3.~1.1.1 Allowable Uniaxial Strains The F/A orifice plate as constructed from SA-316-SS is unirradiated at 22 2 BOL. The E0L fluence (E>0.1 Mev) is 0.0066 x 10 n/cm . In addition, the F/A outlet nozzle temperatures range from 750 to 1000*F. The true uniaxial uniform elongation ( u, min) and fracture (c t , min) for unirradiated and irradiated SA-316-SS used in the F/A orifice plate structural evaluation were taken from the recommendations in the trail applications of the RDT Draft for Breeder Reactor Core Components [15-23] and are identical to those taken for the F/A shield block structural evaluation presented in Section 4.3.1.1.1. I 9.3.1.1.2 Comparison with Criterion The F/A orifice plate structural evaluation in relation to the worst case location for local ductile rupture was made by screening each of the finite elements over the 39 worst case duty cycles with the damage processor. The maximum local ductile rupture factor (FDR) max for the F/A orifice plate was found to occur at element 21, as identified in Figure 9.2-5. 4
~~-338-~~
The peak BOL strain components occurred at the maximum radial interference in the E-4a transient where the local metal temperature was 1000 F. Accumulated BOL strain components were based on the difference between b final time dependent steady state conditions and initial time independent stead state conditions in the first duty cycle. The E0L maximum principal strain for the peak BOL and accumulated BOL strain components ove- 39 worst case F/A orifice plate duty cycles was 0.027 in/in. The triaxiality factor for the local stress state was -1.244, but was taken as unity for conservatism in the structural evaluation. The true minimum irradiated unifonn elongation and fracture strains at E0L fluence (E>0.1 Mev, (4t) = 22 2 0.0066 x 10 N/cm ) were 0.223 and 0.450 in/in respectively. In this arrangement, the maximum local ductile rupture (FDR) for the F/A orifice plate was controlled by the fracture strain with a value. (FOR) .ax = 0.199 . As (FDR) max < l.0, the F/A orifice plate is not expected to experience crack initiation over the 39 worst case duty cycles based on the local ductile rupture criterion. ,,
~~\. -339-~~
9.3.1.2 Creep-Fatigue Damage The creep-fatigue damage criterion in protecting against crack initiation requires that the combined creep-fatigue damage factor (FCFD) be less than unity at each point in the F/A orifice plate. e F = hDc+D CFD /b = Minimum of \ 7 0f e D c+7 In the following, the allowable limits for fatigue life and creep-rupture times used in the F/A orifice plate structural evaluation and a comparison of the results with the combined creep-fatigue damage factor criterion are presented. 9.3.1.2.1 Allowable Limits The F/A orifice plate as constructed from SA-316-SS is unirradiated at 22 2 BOL. The EOL fluence (E>0.1 Mev) is 0.0066 > 10 N/cm . In addition, the F/A orifice plate temperatures range from 750 to 1000 F. The fatique life and creep rupture time relations used in the F/A orifice plate structural evaluation were identical to those used in the F/A shield block structural l evaluation presented in Section 4.3.1.1.1 The fatigue life and creep l rupture time relations representative of F/A orifice plate peak and steady l state metal ten'peratures at E0L fluence are illustrated in Figure 4.3-1 & l - 2, respectively. </ -340-
9.3.1.2.2 Comparison with Criterion The F/A orifice plate structural evaluation in relation to the worst case location for combined creep-fatigue damage was made by screening each of the finite elements over the 39 worst case duty cycles with the damage processor. The maximum combined creep-fatigue damage factor (FCFD)
~~for the F/A orifice plate was found to occur at element 21 as identified in Figure 9.2-5.~~
~~-5 I~~
The fatigue damage factor (D ) was found to be 0.343 x 10 for 39 worst case duty cycles. The principal strain range was found to be critical and occurred between the final steady state and maximum radial interference during the E-4a transient with a value of 0.00077 in/in. The peak metal temperature over the fatigue cycle was 1000 F. The faigue lite for the 6 equivalent strain range was 11.4 x 10 cycles based on the E0L fluence 22 2 (E>0.1 Mev, (:t) = 0.0066 x 10 n/cm ). The creep damage factor c(D ) was found to be 0.12 x 10 " for the 39 worst case duty cycles. The equivalent stress was found to be critical with a value of 3,348 psi corresponding to the steady state temperature conditions at the beginning of the 10 day hold time. For the E0L fluence (E>0.1 Mev, 22 2 (ct) = 0.0066 x 10 n/cm ) at a metal temperature of 750 F, the minimum rupture time was 7.61 x 10 15 , In this arrar.gement, the maximum combined creep-fatigue dar-age factor (FCFD) max for the F/A orifice plate was found to be dominated by fatigue damage while creep damage was negligible.
~~-5 (FCFD) max = 0.343 x 10 As (FCFD) ax < l.0, the F/A orifice plate is not expected to experience crack initiation over the 39 worst case duty cycles based on the creep-fatigue damage criterion.~~
Se
~~-341-~~
9.3.2 Excessive Deformation The F/A orifice plate structural evaluation of peak plus accumulated, and v) residual deformations in relation to functional limits over the 39 worst case duty cycles is presented in the following subsections. 6 9.3.2.1 Peak Plus Accumulated Deformations The peak plus accumulated deformation criterion in protecting against excessive peak defonnations requires that peak plus accumulated deformations 1 (6P+A) be less than the peak plus accumulated deformation limit (PADL). I P 6 +A < PADL I The peak defonnation P(6 ) of the F/A orifice plate during the first duty cycle of radial interference loading occurs at the orifice holes with a value of 0.0011 in. In the second duty cycle, the initial time independent and the final time dependent steady state deformations were 0.0004662 and 0.0004748 in. Accordingly, the accumulated deformation (i 6ss) between the initial and final steady state conditions of the second duty cycle at BOL was 0.0000086 in. For 39 worst case duty cycles, the E0L peak plus accum-ulated (6 P+A) deformation is given by the relation. p (6 )E0L = (6 )BOL + (N-1) (A6" )BOL P (6 +A)E0L = 0.0011 + 38 (0.0000086) (6P+A)E0L = 0.0014 in. For the F/A orifice plate, the specified nominal peak plus accumulated deformation limit (PADL) is 0.005 in. However, the tolerance on the orifice holes of 0.002 in is more restrictive and was used as the PADL. PADL = 0.002 in. As 6P+A < PADL, the F/A orifice plate is not expected to experience
~~' excessive peak deformation during the 39 worst case duty cycles. .I -342-~~
9.3.2.2 Residual Deformations The residual deformation limit in protecting against excessive residual R deformations requires that the residual deformation (6 ) be less than the residual deformation limit (RDL). 6R < RDL The residual deformation (6 ) at the F/A orifice plate holes after the i first duty cycle at BOL was 0.0004662 in. After the second duty cycle at BOL, the residual deformation (62R ) was 0.0004748 in. Accordingly, the E0L residual deformation (6R ) EOL after 39 worst case duty cycles is given by the relation. R (6 )EOL =(6f)BOL+(N-1)(6f-6f)BOL R (6 )E0L = 0.0004662 + (38) (0.0000086) R (6 )E0L = 0.000793 in. For the F/A orifice plate, the specified nominal residual deformation limit (RDL) is 0.005 in. However, the tolerance of the orifice holes of 0.002 in. is more restrictive and was used as the RDL. RDL = 0.002 in. As 6R < RDL, the F/A orifice plate is not expected to experience excessive residual deformation during the 39 worst case duty cycles. 9.3.3 Summary The F/A orifice plate was found to satisfy the crack initiation and excessive deformation criteria for a total of 39 worst case duty cycles. A summary of the F/A orifice plate structural evaluation is presented in Table 9.3-1. J e-
~~-343-~~
~~TABLE 9.3-1~~
~~-7 , F/A ORFICE PLAIE f STRUCTURAL EVALUATION~~
~~SUMMARY~~
~~I Allowable Calculated Margin of Safety~~
Criteria Value Value Crack Ductile Initiation Rupture 1 0.199 4.03 Factor Combined Creep-Fatigue 1 0.343X10-5 291,544 Damage Factor Excessive Peak +
~~Deforma- Accumulated 0.002 in. 0.0014 0.43 tion i Residual 0.002 in 0.000793 1.52 i~~
~~Margin of Safety = Allowable Value~~
~~-I Calculated Value ) -344-~~
~~10.0 REFERENCES~~
r (1) E-953015, Revision 9, CRBRP Equipment Specification, First Core Fuel Assembly, Westinghouse Electric Corporation, Advanced Reactors Division, November 1977. (2) G. J. DeSalvo and J. A. Swanson, ANSYS - Engineering Analysis User's Manual, Swanson Analysis Systems, Inc., Elizabeth, PA., 1975. (3) ASME Boiler and Pressure Vessel Code, Section III, Division 1 - Subsection NB, " Class 1 Components," Rules for Construction of Nuclear Power Plant Components, American Society of Mechanical Engineers, New York, 1977. (4) ASME Boiler and Pressure Vessel Code Case N-47 (1592-10), " Components in Elevated Temperature Service, Section III, Division A," in
~~" Nuclear Components," American Society of Mechanical Engineers, New York, 1977.~~
(5) Draft RDT Design Guideline / Criteria for FBR Core Ccmponents, Vol. I, Structural Design Criteria, June 1976. . (6) " Nuclear Systems Materials Handbook," TID-26666, Hanford Engineering Development Laboratory, Richland, Washington , (7) S. S. Manson, " Fatigue: A Complex Subject-Some Simple Approximations", Exp. Me:h. 5, pp 193-226 (1965). (8) "0xide Fuel Element Development", Quarterly Progress Report for Period Ending September 30, 1974," January 1975. (Availability: US DOE Technical Information Center). (9) E953019, CRBRP, Core Former Equipment Specificatico, Appendix B, Environmental Effects on Material Properties. i 4
~~-345-~~
(10) H. D. Garkisch, et.al. , " Clinch River Breeder Reactor Plant, v) Irradiated EBR-II Duct Crushing Tests and Analysis," CRBRP-ARD-0164, April 1977. (Availability: US DOE Technical Information Center). (11) D. R. Duncan, M. M. Paxton and J. L. Straalsund, "Postirradiation Tensile Properties of an FTR Fuel Duct Produced from FTR Core 1-2 Steel" in " Cladding and Structural Materials. Semi-Annual Progress Report, July 1975 to January 1976", HEDL-TME-76-13, pp 181-182, April 1976. (12) D. C. Jacobs, "CRBRP, the Development and Application of a Cumulative Mechanical Damage Function for Fuel Pin Failure Analysis in i.ihBR Systems," CRBRP-ARD-Oll5, May 1976. (Availability: US DOE Technical Information Center). (13) "CRBRP Core Inter-Duct Force Analyses for Unit Gravitational Loading," Westinghouse Electric Corporation, WARD-D-0208, Advanced Reactors Division, January 1978. ( 14) S. Timoshenko, Theory of Plates and Shells, McGraw-Hill, New York, 1940. (15) T. T. Claudson, " Irradiation Effects on Reactor Structural Materials: Quarterly Progress Report, February, March, April 1973." HEDL-TME-73-47, May 1973. (Availability: US DOE Technical Information Center). 1 (16) T. T. Claudson, " Quarterly Progress Report Irradiation Effects on l Reactor Structural Materials - August, September, October,1972," HEDL-TME-72-144, December 1972. (17) T. T. Claudson, " Quarterly Progress Report Irradiation Effects on Reactor Structural Materials - May, June, July 1972," HEDL-TME-72-105, August 1972.
~~-346-~~
,)
(18) T. T. Claudson, " Irradiation Effects on Reactor Structural Materials Quarterly Progress Report, February-April,1972," HEDL-TME-72-64, June 1972. (19) T. T. Claudson, " Irradiation Effects on Reactor Structural Materials Quarterly Progress Report, August-October 1970," WHAN-FR-40-1, January 1971. (20) R. Carlander, S. D. Harkness and F. L. Yaggee, " Fast-Neutron Effects or Type-304 Stainless Steel" Nucl . Appl. & Tech. 7, pp. 67-75 (1969). (21) H. J. Busboom and R. R. Asamoto, " Evaluation of Physical and Mechanical Properties of Type-304 Stainless Steel After Irradiation 22 to 3.9 x 10 n/cm 2 Total Fluence" GEAP-13571, February 1970. (22) T. Lauritzen, A Withop and G. P. Ferguson, " Mechanical Properties Evaluation of Austenitic Stainless Steels Irradiated in EBR-II," GEAP-10066, July 1969. (23) L. D. Blackburn, A. L. WARD and J. M. Steichen, " Ductility of Irradiated Type 304 and 316 Stainless Steels," Presented at the International Conferences on Radiation Effects in Breeder Reactor ' Structural Materials, Scottsdale, Arizona, June 1977. (24) E. R. Gilbert and L. D. Blackburn, " Creep Deformation of 20 Percent Cold Worked Type 316 Stainless Steel", Trans. ASME 99, p.168 (1977). I 4
~~-347-P~~
') 11.0 ACKNOWLEDGMENTS The objective of the F/A structural evaluation presented in this document was to provide an analytical assessment of the functional adequacy of the F/A in the CRBRP core over the first and second reactor cycles. The scope of effort associated with accomplishing this objective was significant and required the contributions of many individuals in the areas of criteria formulation, development of analytical methods, and the implementation of the criteria and analytical methods in the structural evaluations. Acknowledgments of individuals most directly involved in accomplishing the objective of this document are as follows. In the area of F/A criteria development, the guidance provided by J. L. Bitner, B. A. Bishop, H. D. Garkisch, V. J. Sazawal, and A. F. Snow of W-ARD was greatly appreciated. In addition, the guidlines provided by the National Working Group on FBR code components critera under the direction of R. G. Sim, Chairman, and the General Electric FBR Department members, in particular, was appreciated.
" With regard to the development analytical methods, recognition is given to the Swanson Analysis System personnel who provided guidance on the use of the ANSYS code. In the area of implementing an automated precedure for - assessing crack initiation failure modes, special acknowledgment is given to M. A. Todd of W-ARD for developing the damage processor.
In the area of implementing the criteria through analytical methods, special recognition is given to A. D. Sane and M. A. Todd of W-ARD for their invaluable assistance in completing the structural evaluations within schedular constraints.
~~% 1 -348-~~
APPENDIX A DAMAGE PROCESSOR 9 Since the CRBRP First-Core Fuel Assembly is designed for a service life of two years and is subjected to various thermal transients and mechanical loads during this period, there exists a possibility of crack initiation at one or more critical locations during the two-year period. The identified mechanisms of crack initiation for the Fuel Assembly are local accumulation of creep-fatigue damage and local accumulation of inelastic strain (ratchetting). Criteria have been established to limit creep-fatigue damage and local strain accumulation to safe levels. Because the applica-tion of these criteria requires careful screening of the stress-strain history for the Fuel Assembly, with extensive calculation involved, the crack initiation assessment crocedure was automated, a damage processor being prepared for use on the W-NES CDC 7600 computer system. This appendix describes the damage processor and illustrates the results obtained from its use. The sequence of calculations and comparisons comprising a damage assessment are illustrated in the Damage Assessment Flow Chart, Figure A-1. As may - be seen from the figure, the damage assessment procedure consists of two steps, stress analysis and damage calculation. The stress analysis, which is described elsewhere, supplies the stress-strain history for one duty , cycle. This history then becomes the input to the damage processor. The stress-strain history supplied to the processor is not a complete time history. For purposes of calculating strain range for fatigue, only peak values are needed and are supplied. Creep calculations require a detailed stress-time history only if relaxation is occurring with time. In practice, the stress-:: train history used by the damage processor is an edited one. Since the processor was written to make use of data generated by the ANSYS finite element computer program, it was possible to edit and combine the permanent files containing the stress-strain histories for the Fuel Assembly by means of a file combination option available with ANSYS. A-1 )
The damage processor functions by calculating stress and strain para-meters identified in the criteria as critical, calculating the damage jf factors associated with these parameters and screening the values obtained to determine peak damage factors and critical locations. The processor A then prints an element-by-element list of the stress and strain para-meters, damage factors and stress-strain-temperature-time data for the particular element, followed by a list of the peak damage factors and the numbers of the critical elements. Typical output data from the damage processor are reproduced in Tables A.1 and A.2. A listing of the damage processor source deck is in Table A.3. Since it was intended to use the processor to supplement several analyses, involving different materials, the computer code was written so that necessary materials data would be obtained from separate subprograms. This arrangement allowed quick conversion when different materials were involved. Separate materials data packages, containing the necessary sub-programs, were written for solution annealed and 20% cold-worked 316 stain-less steels. Source deck listings for these two data packages are shown in Tables A.4 and A.5, respectively. l l 4 A-2 , . l l l
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TABLE A.1 DAMAGE PROCESSOR ,. TYPICAL OUTPUT FOR ONE ELEMENT a DAMAGE ASSESSMENT FOR CRep FIRST-CORE FUEL ASSEMBLY SHIELD BLOCr DAMAGE AMD STRAIN LIMIT ASSESSMENT FOR ELEMENT 98 FATIGUE DAMAGE CREEP DAMAGE E W IVALENT STRAIN IS CRITICAL PRINCIPAL STRESS IS CRITICAL SEYwfEM LOAD STEPS 3 AND 4 PEAK STRESS = .12579E+05 PSI EQUIVALENT STRAIN RANGE = .4117E-02 PEAK TEMPERt.TURE = 751.5 DEG. F.
*EAK TEMPERATUerE = 911.2 DEG. F. MEAN RtsPTURE TIME = .1437E+11 HRS.
FATIr4)E LIFE = .250$E+04 CYCLES HOLD TIME PER CYCLE = 240.0 HRS. DAMAGE PER CYCLE = .39915E-03 DAMAGE PER CYCLE = .16707E-07 3Amar,E FOR 40 CYCLES = .15966E-01 DAMAGE FOR 40 CYCLES = .66827E-06 ACCUMULATED STRAIN LIMITS DUCTILE RUPTURE GARKISCH QUANTITY CRITERION CRITERION CRITIC AL LOAD STEP 4 4 mas! MUM PWsNCIPAL STRAIN .9454E-02 9454E-02 Talax! ALITY FACTOR 2.099 2.099 MFTAL TEMPERATURE 802.4 802.4 rpACTURE DUCTILITY 9723E+00 tavIroom EtoesGATION 7644E-01 , l rew rNFD rpFFP-FATIGUF DAMAGE FACTOR PEP CYCLE = .39918E-03
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~~, 4p ,+<. ,~~
1 a L v
t) TABLE A.1 (continued) A DAMAGE ASSESSMENT FOR CR8R FIRST-CORE FUEL ASSEMBLY SHIELD BLOCK l STRESS AND STRAIN COMPONENTS FOR ELEMENT 96 LOAD TIME / TEMP STRESS / STRAIN COMPONENTS STEP XX yy xy 22 1 0.00 191440E+05 .254403E+04 .5R2659E+04 161040E+05 751.51 .606958E-03 .391966E-03 .701344E-03 423985E-03 2 0.00 .203789E+05 .275099E+04 .618585E+04 174530E+05 588.11 .785838E-03 648861E-03 .100713E-02 .549186E-03 3 0.00 .252448E+05 366867E+04 758769E+04 .213185E+05 911.23 .164730E-02 181938E-02 .243819E-02 .102138E-02 4 0.00 .213205E+05 .310456E+04 .639498E+04 175705E+05 802.43 109082E-02 .104301E-02 .148965E-02 .662240E-03 5 0.00 .163975E+05 .193850E+04 .507721E+04 .142120E+05 819.43 .706591E-04 .318679E-03 .165246E-03 .160974E-03 6 0.00 14780E+05 163143E+04 .347145E+04 918887E+04 751.51 755441E-03 .802412E-03 .108663E-02 423985E-03
- 7 0.00 114780E+05 163143E+04 .347145 E +04 918887E+04 751.51 755441E-03 .802412E-03 .108663E-02 423985EH13 a /4t i.t W e 114780E+05 163143E*04 .347145E+04 918897F+o4 151.51 755441F-03 802412E-03 .108A63E-H2 421995E-H1 4
~~A-5~~
~~.4, )~~
TABLE A.2 .r DAMAGE PROCESSOR MAXIMUM DAMAGE FACTORS TYPICAL OUTPUT i DAMAGE ASSESSMENT FOP rgep FIpgT-CORE FUEL AS$f*P Y SHgr! - MAXIMUM DAMAGE FACTORS AND LOCATIONS MAXIMUM FATIGUE DAMAGE FACTOR IS .15966E-01 AT ELEMENT 96 i MAXIMUM CREEP DAMAGE FACTOR IS .11442E-04 AT ELEMEgT 1N i= MA*! MUM COMBINED CREEP-FATIGUE DAMAGE FACTOR IS .15967E-01 AT ELE *ENT PAXIMUM DUCTILE RUPTURE FACTOR IS .69172E-01 AT EL EMEN F' A MAy[ MUM CApr!SCH FACTOR IS .26383E+to AT ELEMENT .h ?
=
! A-6 ... I
TABLE A.3 DAMAGE PROCESSOR c,00RCE DECK LISTING q , f5AiAAX TOTDE(INPHT,T APE 91NPitT,at TNif,7 APF A-rdif Ft ri,7 M r l'y
~~'frrrrrrrrrrrrrrrrrrrerCCrrrrrrrrrrrrrrrCrrrrrrrrrrrreerrer ea r to r ea. .~~
r

c trr r r rrrtCtrCrCC ctrCtrCtrCCCCCCf rC CcCCCo.r.r.rr tr.rrr r r rr.r r err.r r e e r r < < < < < < *

r e
~~-*'* rFNFRAf INFARMATION our r~~
~~( < r THE TOTDMC PROCRAM EVAlliATES COMP!NED CR :P-FATIrUE DAMArE IN ArrrGr ANr5~~
~~r witw THE PROVISIONS OF ASME r0DE CASE N-*? (1592-10) AND PEA < PRINrIPAI~~
~~( CTRAIN IN ACCORDANCE WITH THE DUCTILE RtlPTURE r>ITERION OF THE r,sAFT regr~~
IAMPONENT' CRITERION FOR l! QUID METAL FAST BREEDFR REACTOR $. Ter s .-5 AH r r FilNCTION! e' READING A PERMANENT FILE CONTAINING THE SiaESS ANh SIGAIN *
r. r3MPONENTS CENERATED BY A FINITE ELFMENT ANALYSIS, CALCULATING THE r APPROPRIATE STRESS, 51 RAIN AND DAMAGE QUANTITIES, AND SCREEN!Nr Ter ya .fr r C r,GTAINED TO DETFFMINE THE WORST-CASE LOCATIONS AND VALHES.
r r r id!S */FRSION nr TOTDMG 15 r0MPATIGLF w!TH THE ANSYS FINITF El.F. VENT PG*#Gav r ;M Y , ANr> W!t t FRODUCE roRRECT RFSlalTS ONIY FOR A MODEt f oNS TRe :CTfr FROV
~
f T HF AN9YS ST!F2 PL ANE Ft. EMENT. r r r - rer.rrrrrCrrrrCrCrrctrCCCCCerCrerrrecrCCCrrrCCCrCCCCCCCCCCCCCertretrCrrr*rce- r* r
r

c i MATFRI A' PG PERTY Parv.ArE s' r -
r r e r (A f rR! At PSo,FRT!fS FAR THIS YFRC.!AN AF TATDMG Muti Ef SHPPt IFS S* TH8 s*FE IN A cli9 PRO 6S AM par./ AGF , THE Per*ArE Mils 1 CONTA!N FotfR FliNet! *N r " -r.r s c. i nvc At Fat : 0wS, O 8 1 T iet I F (DFt FP,TErP,Fi lis.Nr ) -- (AIrte!ATES SES]CN F A t t ellt !!FE (FTesIt) AC A FliNrT['.N OF STRAIN RANCE (DFlEP), TFMPFKevosr fTrvP) AN r. !RRA[!ATIAN Fi lif NCf ( re tIENC) .
~~', e - P']v( C if v 4, T F yr , Fi siF Nr,r. N F ) -- C ai tlil AT[C r E C]rN RtIPT!iC F 1:vr~~
~~( ;; .r ' ! v . Ae A Fs:NrYJrA 0F ciuf;C (CICMA), if MPEG AtliRF ( T ivJ ' ,~~
*.-n. .. tie- s issNrF 'r erNr: ANF. A re hr l' f Nr f C' AC Avf T r G ri, - e, . .. . 's r , r i r u- -- r o r- a'r: s : s t vi .- scar 7 r 'i . ' t *. .. .. r- - .c . . g . , . rse 'e er 4 trve Av- .c.' -
O.oFhrE (FLUENC). ' r 4 Et 'tN ! F (TEMP,FLHENC) -- C AL(Ut A T E S MIN I mum HN I Fof M F e ^N< A f .'t h *
' e (ELUNIF) AS A FUNCTION OF TEMPERATURE (TEMP) AND IRRADIAT!?N '
~~r FUlfNCE (FtllENC). ' r~~
~~r a l~~
i 4 A-7 l zNh
TABLE A.3 (continued) ((' r e r r rC Cr r r C crc'C tr rCCCCrtCrrCCCCCCr.CCCCrCCCCCr tCCCrCCCCCCCCCt Ctr CC C rrr.r c r .r er r < 't 6 r e r ** *' INPUT D AT A REQti!REMENTS **na r r r r e I NPeli TO THIS ppar, RAM (ON$!STS of A RERMANENT FILE CONTAINING THE FINIT[ r r FIFM(NT 50l HTION DAT A SFTS AND A DAT A DECK OF TWO OR MORE C ARDS CONT AIN]Nr- r
~~' INTfrFR AND REAl VARIAetES DFSrR!e!NG THE MODEL AND SOLUTION DATA.~~
r C r C r r FMF PfAMANfNT F!tE MH$7 et AN ANSYS STRESS FILE (T APE 10) WRITTEN DURING A r STATJr OR NON-lINFAR TRANS!fNT DYNAM!r S0ttlTION RUN, WITH A POST-PROCESSINC C l e e Ar'T I AN OTHFG THAN PO$f? $PfCIFIID. THIS FILE MUST BE ATTACHED AS TAPE 10 C trw THE TATDM6 rAHPuTAT]ON. THF roNTENTS OF TAPE 10 MUST BE AS FOLLOWS. 1 f C
~~< 1 THF FIRST DATA Sif MusT DFSrRIBE THE INITI AL STE ADY STATE OF THE C e MADEt OR THE STEADT STATE AT THE BEGINfJING OF A NEW DUTY CYCLE.~~
~~r r~~
/. THIS TATA Sff MI'ST PF IMFFDIATFtT FOLLOWED ET TWO OR MORE DATA C r 'FTt DisrR!alNC THF r ATICHE $FQUFNrE OF THE DUTY CYCLE. r e
~~t. TwF FATIr.DE $FQhfNrf DATA $FTS MUST BE F0tt0WED IMMEDI ATFLY ey C~~
f TWO AR MACf DATA %fft OfCiR]P!Nr. TH[ CREEP-RFLAXATION Sf30ENCE r r oF fpp be tT y rsf r f, C f 4 THf IA$7 rRffP-AftAIAT!rN DATA SET ]$ ASSIBMED TO BE THF END-OF- r f rTrt F STF 4ht-C T ATE C'ee HT ION DAT A SFT FOR THF MoDFt . r r A f]t F #AFv offRAT!'N wAv DF Nff6fD TA ArHIFVf THIC ORDF R !Ns* AF DATA (ETc. r a f r Te. A f Yat hwr !wPt If!TI y TRfAT$ THF CDs itT !nN AC !F rRFFF ANh (AT!rhF &as e r 41!% 'F8AGAffiT. TMF t!N!TF Fl[MFNT ANAtTCit CHrt re f AF PFAf6&NF6 IN R vara rsNt!<TfNT v!Tw tw'r AtruvF-Y !
~~N ,~~
4
~~.: **. tr. # ge*-se e * ,- . s ,.; g r e A; f. erse, rrt ?nsst- a s;~t a, -~~
~~er. t~~
rse t. *at et, ist , ey*
e
~~!c pi y N A ,~~
ITS FONTINTC W!t t RF WRITTfN A' m' A e " AH > : ' rA&b A !% THf T!TlF CARit. fEARACTFR% AT THF HEAh 0F EA(H PACE OF PRINTOl'.T. r rARD P CONTAINS INTEGER AND REAL DATA, RFAD AS F6tt0WS. I
~~r cot ttMNS V ARI apt f DEFINITION '~~
r 1- 6 NFTG NO. OF FATIGUE DATA SETS ON TAPE 10 (!NTFCFri C 7-12 NCRP NO. OF CREEP DATA SETS ON TAPE 10.(INTErrp) e r 13-18 NEL NO. OF ELEMENTS IN MODEL (INTEGER) e C 19-24 NPR NO. OF ACTIVE ELEMENTS TO BE ASSESSED f!NTErFG, ' C 25-30 NCYC NO. OF DUTY CYCLES CONSTITUTING THE SERVIrE IIFF ' C (INTEGER) 't ' C 31-42 FLNC IRRADIATION FLUENCE AT END OF DUTv CYCLE IN UN!?! C- 1.E+22 NEUTRONS /CM2. (REAL) <- r 43-54 PCRP CONFIDENCE FACTOR FOR STRESS-RUPTURE CAtr.ui.AT!cN '
~~' (DIFFERENCE BETWEEN NOMINAL AND DESIGN RUPTURE C~~
r STRENGTH EXPRESSED IN STANDARD DEVIATIONS) (RE Ai ) ; r Cast r r CARD C IS OPTIONAL, TO BE INCLUDED ONLY IF NPR IS SMALLER THAN NEL. r r C, WHICH MAY BE REPEATED AS NECESSARY, CONTAINS THE NtiMBERS OF THE ACT!vE'-F r l ELEMENTS IN ASCFNDING ORDER. A TOTAL OF NPR NUMeERS MUST BE PROVIDED. " C FOGMAT FOR EACH CARD !$ 13!6. r I i ! A-8 v-
TABLE A.3
~~'k T' ./ (Continued)~~
~~O Crr rf C rt C crc C C CCCf r.C CC CC C CCCC Cerc e rC C Cr.rC crc C C C C C C CCtrCr.Crrr t t C err re,r.r r r. r~~
~~r r -~~
i C ! C C >>' PROC. RAM OUTPUT **e r r r - r r onTPtlY FOR EACH ACTIVE EL EMENT CONSISTS OF A LISTING OF rpIT!r Ai. Sv-recre, r ST&AINS AND ! TRAIN PANfES Al.ONA WITH ASSOCIATED TEMPERAfslREC AND T!vFC, r ANfe A t.! STING OF CREEP, F ATICIIE AND Dtir.T ILE RUPTt'AE F ArTAFS. S? cec' AN-t CTGAIN roFPONENTS AT EACH toAfi STEP AFE LISTED FOG EArH F'FMFNT. v-r ee-r pare OF OUTPtif rONT AINS THE MAFIMUM DAMACE AND Rt'PTI'AC r Ar nae r ,; - r M A E' AND THEIR t0 CATIONS. t
*rr**:t errer*rrCrrrrrrrrrrCCrrrer.rerrrrererrr*rtrererc*rrer r r.
~~e:< re *rrr.rrrrrrrrrrr. rrre errrrrrer er errrrrrer rtrerer:rc< .<-~~
~~,. . gas sett - s,.r ar. t a 3 c~~
s t.ct t* ' *
,s- * * * *1 r EFa' c.rgs+. r,AfA' . fan r c. ,v)) Nr c, Nr F P,NEl. ,NF'P,NC yr, F? Nr,F'r PO e t r r t '. v UAt t;E ? f NFF 2 net i IF (NPR .EG. 0) NPP 2 net i
~~a C NO. or DATA SETS NSETS = NFTG + NCRP + 1 I C ( At rip. ATE POINTERS FOR DYN AMIC STAP AGE LtI6 x 1 LEPS = LSIG + 4eNSETSeNPF ! LTEM~~
~~LEPS + GrNSETS NPR l LTIM a LTEM + NSETS>NPR l - LNLI : LTIM + NSETS IDMG z LNI.! + NPR L AST = LDMG + 2eNrsP r, CFT SCM TO MINIMUM LENGTH N a LOCF(A(1))~~
LENGTH = L AST + N + 2 CALL RFLS(LENGTH) l C FROCRAM EXECUTION T AKES PL ACE IN SU6POUTINES FIRST AND SECOND. l C toepoVTINE FIRST PEADS TAPE 10 AND STORES THE DATA IN AppAv5. l rALL FIRST (A(LSIC),A(LEPS),A(LTEM),AfLTIM),A(LNLI),NSETS,NE' ,Nrc, l 1 NFTG,NCPP,NCYC,Fl.NC) - C CUPPallTINE SErOND PFpFOPMS A(t DAMACE CAICUtATIONS AND yp!TEc a r ti s. T c ** C nelT Ptif . C At t SECOND (A(LSIC),AttEPS),A(! TEM),AO TIP),AD N !),Ao t'** , Nerve i , net ,NPP,NFTG,NrGP,Nr_Yr,r Nr,PrGP) r &i . Fr!T
~~, / r*AVAT (W Aile) ,d r ** s','M T l5Id,2%i'/,f) rNe I~~
~~A-9 1 t j~~
~~' 1 l~~
l
TABLE A.3 (continued) FitPRal' TINE F IRtf (516MA,EP??N,TFMP,11Mf,NI!?f,N'F1',Nr , sis,Nr' , 1 NrRP,NCYC,Fthr) r Tott strepotTINE READS AND STORES THE DA1A ON TAFE1D DIMENSION W(34),1W(34),5 !6MA(4,N$F TS,NPP),EP$1 N(4,Nf f ,Nf 6 s , 1 TEMP (NSETS,NPR),T!ME(NSETS),NLIST(NPP) W EQUIVALENCE (IW(1)$)(1)) COMMON / TITLE / HEAD ( IF (NPR.LT.NEL) READ (5,98) (NLIST(!),I:1,NPP) VRITE (6,96) (HEAD (!),I:1,8)
~~? WRITE (6,94) NS ET S ,N F T G,NC F P, Nr. Y C , f L Nr. ,NPP , Afl CALL READST (IW,10)~~
~~Nx ? fO4 !=1,NSETS CAL' READER (!W,N) TIME (1) = WC1)~~
~~v. = 1 00 4 IEL*1,NEL CALL READER (IW,N) r stoeE ONtf THE DATA FROM THE ACTIVE ELEMENTS IF ((NPR .LT. NEL) .AND. (NllST(P) .NE. IEt)) 60 TA 4 TEMP (I,K) = W(10)~~
~~DO 3 J r 1 s. r PECHANICAL S1 AIN 2 EL ASTIR + PL ASTIC + OF!r.IN SH!rt + rpEFp . gyr, :sc = EP$tN(),1,K)~~
V(10+J) + W(14+J)

Vf1@

i) + W(??*.')

V(445 3 SirMAfj,I,K) z W(6+J)
~~S!6MA(4,I,r) : W(4) FPSLN(3,1,K)~~
~~EPSLN(3,I,K) - V(34)~~
V=K+1 4 CONTINtlF E E Tif9N - 34 rA& MAT (////16#,'THr ditty Cyre.E It DFFINrD ET ,13,' soAh 'TFcc, is' 1ri t.sh).9 THF INITI AL CTE ADY C T AT E,a / /15v,!?, tc Ar. St rPt err!A:s>
~~?HF raft'lif SErllENrF, a ANS*,]3, toad $TrPS DFr!NIN.' Tw[ (Crr.~~
~~re, t, - t r es iF Nr f . THit DAP. AGE AstFSSMrNT le rop ,13,- tr ru mit. . 4 T,sE rNr.-AF-i lr F: / /1 Ar, sr Ac t riteFNir Fos Turs rey m NFN* ;c ,~~
~~<rA t, r~~
~~77 NFittf oNc /r> ? f r cf . o.1 q v) . si1Aw, rAvacr acecceers-ar egr rk;ytrr for r for , t c, r e r vr o.i t 's t ,.r . -r~~
~~,'4, p 5 .* , '~~
4 ' fluitfsfi#t,4Ah,*
~~se i~4 d% ' 1 % [J .~~
=
A-10 m
i TABLE A.3
~~., (continued)~~
(UPdoUf !NF SFrnNn (t:6MA,F PS N, T F MP, r !xF ,Ni r. r ,s.w ,u s e. ,se , . . ,e 1 NFf6,NrRP,Nrvr,fiNr,FfsP) . f Iwlt %UP40tif !NF PERFORMS At t D AMArF C At fin AY ]r,Ne 1 DIMENSION E'StN(4,NSETS,NPR LOL FTG(2)I(,Pi TIME (NSFrRP(4),S TM),Nt !$7tr.MA(4,Ne (NPR I,r.Me tFe,New is,NF3,r k),s f.c,f kP f N' F f",*d b e , COMMON / TITt.E /HE AD(8) DAT A LBl CRP/8HPRINCIPA,PHL STRFSC, AHSTRFCC I,4HN T. N'I f v t, 1 L DL F TC /10HT QUIVM ENT,1flHP6 f Nr. I P Al / iFEN s NSETS - NCRP IFST = IFEN - NrTG + 1 IFEN1 = IFEN - 1 ICST IFEN + 1 r INITIAL!lE PEAv. t.AMAGF VAtOFS AND lOCAtloN T AT S FATDAM = 0.0 CRPDAM = 0.0 IvihAM
~~O.0 RtIPhtlC s O.O HANCAR = 0.0 IELFAT =0 IELrRp e IELTOT =0 IELRUP = fe IEt. GAR = 0~~
~~. rat rest ATE DAMArE FnR ALL ArTIVf F8FMENT!~~
~~00 60 N21,NPR IFt = N IF INPR .L T . NEl. ) IEL : N!ICT(N) l r F Af f r.IIE DAMACE T At fits ATION 11 CYMTN : 1.E50 FPFTc 0,0 IFfC r ()~~
#FTC 40 t FTT a t' TFTd : 16.16 *-ArrN at . F AT J(teF r yre rt Tr r ] Nr> P.i.$ r f AM Ar t y' SidA!N 4 AVI , f-n 14 ftIFCT,IFFN1 *e1 ; . 1 'in 14 e-fr1,[FFN r.r. 1' *1,L 1s g r- i s s - r : t N r s ,1, N ) - ria s . ,u,'1 * **r .* t s * '.*e ' T 416 r 1C n. * ? > r t as G 9 % i .t: r'1 . tr .r.is s. ' .. e EP/ AR$(0C ..R)
EP3 : ARS(EP(43) EPPR = AMAR1(EP1,EP2,EP3) r r At (tJt ATE EQUIVALENT STR AIN R AN6F EPEQ = SQRT(3.aRR$*2 + (OC-EP(4)):<-?)/1.5 C PIrv. LARGER OF Two STRAIN RANCES BIG = EPEQ L=1 IF (elG .GE. EPPR) GO TO 13 O!G = EPPR L=2 l 13 TIJ = AMAX1(TEMP (I,N) , TEMP (),N)) C DESIGN FATICUE LIFE COMES FROM FTCLIF FilNCTION CTIJ = FTGLIF(BIG,TIJ,FLNr) IF (CTMIN .LE. CTIJ) 60 TO 14
~~r IF THIS IS WORST CASE SO FAR, RESET F AT!riiE LIFE, STRAIN R ANrE ANf Pr!N'Faf.~~
CTMIN = CYIJ FPFTG = SIG l IrTG = I JFTG = J ~ l O i A-11 1 4 l T
TABLE A.3 .i (continued) LFTG z L 3 TFTG = tis 14 CONTINUE C CA'.CLLATE FATIGUE DAMAGE (PER CYCLE ANh TOTAL) FOR THIS ElEM:NT. FDPC
1. / CYMIN FDLFTM = FDPC

FLOAT (NCYC)
IF (F ATDAM .GE. FDL FTM) G0 TO 21 C IF THIS ELEMENT IS WORST SO F AR, RESET PEAK DAMAGE VAulF AND tor ATION TE?. FATDAM 3 FDLFTM IFLFAT = IEL C rRFEP DAMAGE CALCULATION r INITIAlilE STRESSES AND MEAN RHPTURE T'ME P1 HIS! = 0.0 HISM 3 0.0 TrkP s O.h Do 22 I:! CST,NCFTS nr : 0.5 ( C i r,M A ( 1,1, N )
~~CIGMA(2,I N))~~
~~pp + SGWT (0.25 (S IrM A(1,1,N)~~
I6M A (5, I,N) ) ; ' 2 + C !i.V A ,i,h' c rAsrotAf( Pp[Nr[PAi NA A V At CTGFSCFe ANfi CFifrf 1. AC r i t i V Al .is C1 - APS(Ar + RR) c/ - AAC f 0f - PP) c4 An t f 0 f (P A f 4, f ,Ni l A.Ay1rC1,t/,*'s r..g ,,t, gree n a. g g 's..'ne'.As f ? f F' HISM : AMAX1(HISM,$M) r (At(pgATF PR]NC[ pat $TRESC DIFF(R(NrFC ANfi SFlFri 1 AsrF',? 'A'**f S1 : OC

RR - SIGMA (4,I,N)
~~S2 = RR~~
RR S3

ABS ($1 - $2) ,
~~S1 = ABS ($1) SI = AMAX1(S1,S2,53) e SAvf HIGHEST STRESS INTENSITY HISI~~
AMAX1 (HISI,$I)

C CAVE HIGHEST TEMPERATURE TIJ = TEMP (I,N)
~~TCRP = AMAX1 (TIJ, TrRP ) C DAMAGE RATE IS INVERSE OF RUPTURE TIME, OSTAINED FROM RUPTIM FuNrTIAN DMG(1,I-IFEN)~~
~~1 / RUPTIM ( $1, TI), FLNC, PCRP )~~
22 DMG(2,I-IFEN) 2 1. / RUPTIM ( SM, TIJ, FLNC, PCRP ) DGI 0.0 ~ DGM = 0.0 r INTEGRATE DAMAGE RATE BY TRA EIOIDAL PLRE TO 00TAIN DAMAGE DO 23 I:2,NCRP DELT = TIME (IFEN*I) - TIP ,* (I FEN +1-1) IF (DELT .LE. 0.0) 60 TO -'O DGI DGI + 0.5 2 DELT
~~DMG(1,1) + DMG(1,1-1 ) )~~
~~23 DGM = DGM + 0.5~~
~~DEL T * (DMc(2,1) + DMG(2,1-1))~~
~~C S(IEri HIGHER OF TWO DAMAGE VALUES AND SET TAG. CDPC~~
DGM L=1 STRESS

HISM IF ( DGM .GE. DGI ) GO TO 24 STRFSS

HIS!
~~L*3 CDPC = DGI r4 TH0t b~~
~~TIME (NSFTS) - TIME (ICST)~~
~~TOPP = THot D / CDPr CDt F TP = Cf0C Ft0AT(NrTC)~~
~~, IF f r RPD A.v. ; G E . C f.t. F t re) Go To 11 r *f THIS It Wr.RCT F1(M[NT Cr FAR, C A$ f, AVA(F V As pf Avs RfC[t e3*,~~
I R C fi AM 'f t F TM IFi rsf- - Iri A-12 y i
7
~~. TABLE A.3 (continued)~~
~~L c !Nrt. tr.yArF r At rip AY }.-N~~
~~' ? *e A ' r Je rstRAr+iATFr. i tNrag , te i t .:; f ri pr r. m * * , . .~~
~~t- -~~
* - n. t ratt, r.A:. r raai c ec ;A, ..r Aren. r .r >- a n- -
~~5 ** < 1 e ri r s ftr* s satoatteseetan r 'frir . r- e~~
) , *tettteeteatta f*
F ?e 1111 1 TNFTM F 0A1(N(vrl T r.f r IF (TATDAM .rE , Trit F TM) (A f4 41 TAfDAM z foiFTM IELT07 = IFL r DUCT!tE RUPTtlRE FACTOR r C AL COL ATE STR AIN INCREMENT FOR NrY( Dtif f rvfl EC 41 00 42 K 1,4 42 EP(K) = (EP?tN(K,NSETS,N) - EPS1N'r,1,N)) Fi r'AfrNrvr - 9, C INITIALIFE PEAK VAltiE AND TAGS EPMFR = 0.0 IEPFR = 0 EPFRAC = 0.0 TRFACF = 1.0 RUPFAC = 0.0 TMPRUP = 0.0 EFELNG = 0.0 EPMr! = 0.0 IEPPI = 0 TRFACI = 1.0 cARFAC = 0.n
'MPtNG = 0.0 r FrREFN ALL LOAD STEPS FOR HICHEST RUPTilRE FACTOR AND CARVIErr rAPTOs DO 44 !=1,NSETS C rAl.CULATE SUM OF PRINCIPAL STRESSES AND EQUIVALENT STRESS SM 2 SIGM4(1 * .S!CMA(2,I,N) + SIGMA (4,I N)
~~SI S QR T (0.5 *I,N)( ( S I GM A ( 1,1, N ,5 -S I CF A ($2,1rF I ,AN (.',1,N~~
~~) ) - a Jh ?* 6 1+(SIGMA (1,1,N)-SIGMA (4,1,N))*c2*(SIGMA (2,],N)-SICM4(4,I,N1)2 ?){~~
~~C ( AL CLR ATE TRI AXI ALITY FACTOR. TF IS AlvAYS TAvEN TO FE At i EA'? ' . ' . TF 1~~
~~IF (Si .NE. 0.0) TF 2 SM / Si r rAtrlH. ATE MAXIMhM PRjNC[PA( STRAIN EPr EPSI N(1,1,N) + EP(1)~~
~~FPY = EPSLNf2,I,N) + EP(2) Cry : EPSLNf3,I,N) + EP(3) FPI~~
EP$1N(4,!,N)

EP(4) car - II.S ( EFF

EPY )
~~& - 0.5 sert s ( ( Err - Er) '? + ryv ?) .~~
~~EP! - nr~~
~~Rp rrr - AMArt ( EPI, EPl )~~
~~v ' .' - T E vF-( I , N )~~
~~' A r .4 ; % t c Ar ipRr r.vir T fi [T y rgo*FPFylN ri sNr T I AN~~
~~r. '~~
~~fi f tN T[: 61 N' ; avr ve r v r r .' . ti .; r r A c e e~~
~~.< '.eet r r.c. .~~
~~4- s u s su, '. .* C OSTAIN UNIFORM ELONGATION FROM ELUNIF FUNCTION EPINS = ELUNIF (TIJ,FLNC) C CALCULATE GARKISCM FACTOR~~
~~AMAx1(TF FHG = AMAX1(EPI,0.0)IF (RUPFAC .GE./DAF EPINS~~
~~) GO TO 43 ,1.0)~~
C IF WORST CONDITION, RESET VALUES AND TAGS EPMFR = EPI IEPFR = I EPFRAC = EPLIM TRFACF = TF RUPFAC = DRF TMPRUP = T!J 43 IF (GARFAC .GE. FHG) GO TO 44 4 A-13
r m TABLE A.3 (continued) EPMPI = EP! j IEPPI = I EPELNG = EPINS TRFACI = TF GARFAC = FHG TMPLNG = TIJ 44 CONTINUE , C IF WORST LOCATION, RESET VALUES AND TAGS IF (HANGAR .GE. GARFAC) GO TO 45 HANGAR = GARFAC IELGAR = IEL ' 45 IF (RUPDUC .GE. RUPFAC) CO TO 51 RUPDUC = RUPFAC IELRUP = IEL C PRINT CALCULATED DAMAGE FACTORS ETC. 51 WRITE (6,96) (HEAD (I),1=1,8I LRITE (6,101) IEL LBLCRP(L),LBLCRP(L+1),IFTG,JFTG, STRESS, 1 WRITE (6,102) LBLFTG(LFTS)fFTG,TRUP,CYMIN,THOLD,FDPC,CDPC,NCYC, LBLFTG(LFTG),EPFTG,T;RP, 2 FDLFTM NCYC,CDLFTM WRITE (6',103) IEPFR,IEPPI,EPMrR,EPMPI,TRFACF,TRFACI,TMPRUP,TMPLNG, 1 CPFRAC,EPELNG WRITE (6,104) TDPC,NC1C,TDLFTM,RUPFAC,GARFAC C Pe!NT STRESSES AND STRA!NS WRITE (6,96) (HEAR (!),I=1,6) dRITE (6 130) IEL DO 60 !=I NSET'; t ) rFMP(I,N), WRITE (6,I31) I,T!ME(!),(SIGMA (J I 1 (FP$lN(.9,1,N),D1,4$ ,N),n ,4 , w rrNilunF e r+;NT we ost.rA y Damar,F rArtop$ ann inrATInNC, WRITE (6,9ti) (HEAD (I),I=1,8) WRITE (6,111) F AT D AM,I EL F AT ,C RPD AM, I E L C RP, T O T D AM, I L L TOT , RUPDUC , 1 IELRUP, HANGAR,IELGAR RETURN C ERROR MESSAGE FOR ZERO OR NEGATIVE TIME INLREMENT. 70 WRITE (6 120) (TIME (J),J=IC$T,NSETS) 95 FORMAT (THO,16X 8A10) 96 FORMAT (1H1////I6X,8A10) 101 FORMAT (///31X,* DAMAGE AND STRAIN LIMIT ASSESSMENT FOR ELEMENT *,
1 I4) 102 FORMAT (/26X,* FATIGUE DAMAGE *,33X,* CREEP DAMAGEv//16X A10,* STRAIN 1 IS CRITIC AL*,17X,2 A8,* IS CRITIC AL*/16X,*BETWEEN LOAb STEPS *,13,*
~~2 AND*,13 18X,* PEAK STRESS **,E11.5~~
PSI /16X,A10

STRAIN RANGE =
~~3*,E10.6,$1X~~
~~PEAK TEMPERATURF =*,'Ff.1,* DEG. F.*/I6X,* PEAK TEMPERA 1 EAN RUPTURE TIME =*,E10.6,* HRS.*/~~
~~4TURE=*,F7.i,*DEG.F.*6.3X, 516X~~
~~FATIGUE LIFE =*,E1 4 -~~
~~6F7.$* HRS.*/16X,*DAMAGEP(* CYCLES R CYCLE =*,E15.5 17X *,15X*HOLDTIMEPERCYCLE=*k~~
~~DAMAGE PER CYCL 7=*,EI1.5/16X,*DAMAGEFOR*,I4,* CYCLES =*,E1I.5,i2X,*DAMAGEFOR*,I4 8,* CYCLES =*,E11.5)~~
*ACCtmutATED STRAIN LIMITS *//56X
~~DUCTILE RUPTURE *,~~
~~103112X,*GARKISCH+/ FORMAT ( / / / 43X ,37X,~~
QU ANT IT Y * ,14X ,

CR IT ER ION *,14 X,

C R I T ER ION * / /2 7X 2,* CRITICAL LOAD STEP *,2123/21X,*MAXIPUM PRINCIPAL STRAIN *,2r23,4/

METAL TEMPERATURE *,2F23.1/27X 321X,*TRIAXIALITY FACTOR *,2F23.3/28X, FORM ELONGATION *,23X,E23.4) 4,* FRACTURE DUCTILITY *,E23.4/27X,* UNI 104 FORMAT (////29X,*COPEINED CREEP-FATIGUE DAMAGE FACTOR PER CYCLE **
1,E '.1. 5 / /24 X Cope!NED CREEP-FATIGUE DAMAGE FACTOR FOR*,14,* CYCLES 2=*,E11.5//$*31,*DUCTILERUPTUREFACTOR=*,E11.5//60X,*GARKISCHFAC 3T0R =*,E11.5) 110 FORMAT (///38X,*P'AXIMM DAMAGE FACTORS AND LOCATIONS *///27X
MAXIM 14//28X,*MkXIMUM 10M FATIGUE DAMAGE FACTOR IS* E 2CREEPDAMAGEFACTORIS*,E11.$,11.5,*ATELEMENT*$9X,*MAXIMUMCOMBI

AT ELEMENT *,14//
E11.5,* AT ELEMENT *,I4//26X,*M 3NEDCREEP-FAT!GUEDAMAGEFACTORIS*II.5,*ATELEMENT*,14//30X,* 44XIMUM DUCTILE RUPTUNE FACTOR IS*,E man SIMUM GARKISCH FACTOR IS*,E11.5,* AT ELEMENT *,14) iM FORMAT f//13X,* INPUT DATA ERROR--CREEP ttME STEP IS NEGAT!vF--CAtr itRATION TERMINATED--CREEP TIMES ARE*//16E (8F10.2)) 1 E ropwAT (//343,* STRESS AND STPAIN COMPONENIS FOR FLEMENT*,14///16r, 1 i ^Ah TIME / TEMP *,22N,* STRESS / STRAIN COMPONENTS 6/16X,* STEP ,2tX, trrr ,isv,*vy*,14r e f+,14r,*I?+)
**1 roovat e r 1 Ar ,; t, r h ./ ,4 F 16.6 /19 7, F 1 ? .2,4F 16.6, ,
ers n A-14 r
t A
~~;. TAB:.E A.3 (Cont) i . 'J t $UER007INE READER (Lt ,N)~~
DIMENSION Lt (1),NBt.0CE f 68 8') DAT4 NT,r.LK$ 17,Nr.0Lv,N INEt.M,N F6( r /1f8,6tV ,H,fs,1/ W4-NC9tr GO TO 10 ENTRT READ 57 NT=IAES(N) NINPLK:0 NFELKal NCBLK*O VtK51Za6CO 4 RETURN 10 IF ((MM+2).LE. NINBLK) GO TO 12 IF ((NBLOCK(MM).LT.0) .AND. (MM GT.0)) GO 70 14 IF (NFBLK .GT. 01 RFWIND NT . READ (NT) IN,14,13(NOLOCK(I),I:1,1X) 3r (EOF (NT)) 14 N -1 RETU#N
~~13 NFBLKa -1 t~~
~~NihPLK IN MM = 0 1? MM z MM + 1 N = NBLOCv,(MM) e f$ 11 } s 1,N MM = MM + 1 k' 11 LL(!) : N9L0er(MM) MM = MM + 1 N(SLP r MM FFTues F Nf' I 4 A-15~~
~~.N s4 W- ,,wy.--m -- ,,-,-~~
q J TABLE A.4 MATERIAL DATA PACKAGE FOR SA 316 SS SOURCE DECK LISTING , FUNCTION FTGLIF (DELEP, TEMP, FLUENf) *
]
~~C FTGLIF ~~ "TES DESIGN FATIGUE LIFE FOR SA316*.$, USING UNIVERSAt $(OPFS C CORRELATION -aD 2-20 REDUCTION AULE' C C DEFINITION OF TERMS~~
?
~~C DELEP = STRAIN RANGE (INPUT )~~
C TEMP = METAL TEMPERATURE IN DEG. F. (INPUT) C FLUENC = FAST FLUENCE IN E22 N/CM2 (INPUT) C FTGLIF = FATIGUE LIFE IN CTCLES (OUTPUT) C C FLWCTION EPFMIN (TEMP,FLUENC) IS EATERNAL TO THIS PROGRAM AND MUST BE SUPPLIED C AS A PART Of 'HE MATERIAL PROPERTY PACKAGE
~~C C ,~~
C ' C CALCULATE TRUF FRACTURE STRAINS FOR IRRADIATED AND UNIRRADIATED MATERIAC. EPFI = EPFMIN (TEMP,FLUENC) EPFU = EPFMIN (TEhp,0.0) C COEFFICIENT FOR PLASTIC STRAIN TERM - A= (EPFU**(-0.4))
~~EPFI C FOR TEMPERATURES LESS THAN 800 F, USE 800 F DATA.~~
~~T = AMAX1(TEMP,000.) E = 28336690. - T * (2882.211 + Ta(3.697849 .0007709188*T) ') U=( ( (.8634445E-07*T .3247471E-03)ai + .3678569 ) *T 1 - 161.4171 )~~
~~T + 100220.3 -~~
~~C COEFFICIENT FOR ELASTIC STRAIN TERM 8 = 3.5~~
~~U / E C SET MINIMUM STRAIN VALUE TO AVOID OSTAINING INFINITE FATIGUE LIFE.~~
~~Y = AMAX1(DELEP,5.E-04)~~
~~C DEFINE COEFFICIENTS FOR NEWTCN EXTRAPOLATION METHOD.~~
0 = Y/9 9 R = 5.*A/B C CALCULATE INITIAL VALUE OF XI. XI = 0 * ( 0.8 + 0.2/(R*c2*4 + 1.) ) C CAtClfLATE Dr. , 1 Dr = 0.2
~~x! + (0.8+x! - 0)/(Rexlse4 + 1.)~~
C (ALCULATE NEW VALUE OF x!. y1 = y1 - Dr C TEST FOR CONVERGENCE. IF ( A95(Dx/YI) .GE. 1.E-04 ) GO TO 1 rasrietATE FATICHE LIFE F0p t!FE FArTOR OF 20. Ft1 = n.t6 + XI**(-8.3 333333333 353) r #srFAT 4EWTON Extp APOL ATION FOR STRAIN FACTOR OF 2. s v.y
v Q=Q+Q

x) = 0 * ( 0.8 + 0.2/(R*Q**4 + 1.))

2 Dx = 0.2 * *J + (0.8*XJ - Q)/(R'XJa*4 - 1
~~. XJ = XJ - DX IF ( ABS (0x/xJ) .GE. 1.E-04 ) 60 TO 2 ' rt? = NJa*(-8.3333333333333)~~
C SELECT SMALLER VALUE OF FATIGUE LIFE AS OUTPUT Vf UE. FTGLIF = AMIN 1(FL1,FL2) RETURN END i >
/
~~A-16~~
~~TABLE A.4 s (continued)~~
FUNCTION EPFMIN(T,F) r I C EPFMIN CALCULATFS MINIMUM FRACTURE DurTILITY Fr.R cA316Ci Fpec An Evr p e a-C CORRELATION DEVLLOPED BT GE C C DEFINITION OF TERMS C T = TEMPERATURE IN DEG F C F IRRADIATION FLUENCE IN 1.E22 N/(M2 C EPFMIN a MINIMUM FRACTURC DUCTILITY C C DIVIDE TEMPERATURE B' 1000 TT = T * .001 C FOR TEMPERATURES LESS THAN 800 F, USE 860 F DATA TT a AMAX1(TT,.8) C rALCOLATE THRESHHOLD FLUENCE FOR REDUCTIO
~~OF Dutitt!Tv F0 = 1.4 - TT IF (T .GT. 12CO.) F0 = TT - 1.0 r CAlrtt ATE MINIMUM DUCTILITY FOR UNIRRADIATED MATERIAL EF0 m 45 / (SQRT(TT) * (TTao3))~~
~~IF ( T .GT. 1000.) EPO~~
~~EP0/(TT**2)~~
~~IF (F .LE. FO) GOTO1 . r IF FtHENCE EXCEED 3 THRESH 90LD rs.uCNCE, APPLY FOf fit ;TY G E f>ur ? !~~
~~N rar;~~
~~!! - TT ' 7 l EPO z EPO * ((F/F0)*all) 1 EFFMIN 2 EPO RE7UAN Fett.~~
FUNCTION RUPTIM(SIGMA, TEMP,FLUENC, CONF) r ' I r RDPT!M CatCI'LATES DESIGN RUPTURE TIME FOR SA3165t, USINr AN EMP!E l r M F:1 6 C to EXPERIMENTAL DATA FROM HEDL.
~~r. DEFINITION OF TERMS (7 r TEMP--METAL TEMPERATUnE IN DEG. F.~~
r SIGMA--CRITICAL STRESS IN PS! r FLUENC*-F- UENCE IN 1.E*22 NEUTRONS /CM2 C CONF--CONFIDENCE FACTOR ON RUPTURE TIME r r r' rAirUtATE 57PENGTH REDUCTION FACTOR FOR SODIUM EXPOSURE ALPHA = 1270. - 0.3* TEMP AL PHA n AMIN 1(ALPHA,1000.) r C Ai rDt. A1E AU6 MENT ED STRESS INCLUDING SOD!l>M EXPOSURE Fai. sOR Sz AM Ax 1 ( $ 16M A,1000. ) / AL PH A C FOR TEMPERATURES LESS THAN 800 F, USE 800 F DATA T
~~AMAt1(TEMP,6CO.)~~
~~BETA = At0G10(S) r FIRST CALCULATE LARSON-MILLER PARAMETER FOR UNIRRADIATEh MATERIAL 01~~
~~49950. -(520.* CONF + EETA*(5270. + 2795.seETA)) ,~~
IF (FLUENC .GT. 0.) GO TO 1 l r If FtHENCE IS ZERO, USE UN!RRADIATFD DATA FOR RUPTURE TIME l 02 Y Q1 ' r,n ' 2 r IF Ft OE_ .c IS CREATER THAN lERO CALCUL ATE (MP USING IRR ADI ATED ^^T A , 1 47 8 54(84. -(990.* CONF +1$353.'GETA
1111.c At on10(FLUENr )) l

ntF SMAttFR VAIVE Of LMP TO CALCD'. RTE RUPTilRE T!ME l J 'I * -20

A.'t!N1 (ul , J2 ) / ( T

460.) l AnVit" s 10 'll as?ncu I F Nf* a I I
~~a l i A-17 '~~
,3
7-s TABLE A.4 (continued) FUNCTION Et.liN!F (TEMP,rLUENC) f C ELUN!F C A'. CLt ATES MINIMUM TRUE L'Nf f ORN ELONGATION FOR SA316SS, U$jNC A C CORREL AT ION DEVELOPE ( 87 CE. f-C DEFINITION OF TERMS - C TEMP = TEMPERATURE IN DEG F C FLUENC = IRRADIATION FLUENCE (FAST) IN 1.E22 N/CM2 f Et,UN I F r MINIMUM TRUE UNIFORM ELONGATION C r FOR TEMPER ATURES LESS THAN 800 F, USE 8CC F DAT A T = AMAX1(TEMP,600.) - f CA'. cot. ATE ENr.INEERING UNIFORM ELONGATION FOR UNIRRADIATED Ma:E R ! st , ,nc INc C P0tTNOMjAL CORRELATION FOR BAR STOCK FROM NSM HAND 000K. EU = ((t((((((.6172085E-29*T .6840613E-25)*T+.2987206E-21)'T - - 1 .694287E-18)*T+.960199E-15)aT .8284638E-12)eT+.45249?EH 4.T 2 1554308E-6612T+.3283548E-04)*T .004073204)37 + .4965563 r IF FLUENCE IS ABOVE THRESHOLD VALUE OF 0.1, APPLY IRRADIATION 'CORREf.t:.A. IF (FLUENC .LE. 0.1) 60 TO 1 EH = El' / (10.
~~FLUENC) r r At rett A TE TRUE STR AIN VALUE FROM enc!NEERINf. STR AIN Y A' UF..~~
*1 FLONIF - AI,0C(1 + (U) ,
RFThaN d r N *: S h b i A-18 , (
TABLE A.5 MATERIAL DATA PACKAGE FOR CW-316-SS $ SOURCE DECK LISTING f FUNCTION FTGLIF (DELEP, TEMP, FLUENC) C FTGLIF CALCULATES DESIGN FATIGUE LIFE FOR CW316SS, VSING UNIVERSAL SLOPES C CORRELATION AND 2-20 REDUCTION RULE C C DEFINITION OF TERHS C DELEP = STRAIN RANGE (IhPUT ) C TEMP = METAL TEMPERATURE IN DEG. F. (INPUT) C FLUENC = FAST FLUENCE IN E22 N/CH2 (INPUT) C FTCLIF = FATIGUE LIFE IN CYCLES (OUTPUT) C C FLNCTICN EPFMIN (T E v.?,F LL U4 C ) IS EXTERNAL TO THIS FPCGRAM AND MUST DE SUPPLIED C AS A N RT CF Tf! UATERIAL FSOPERTY PACKAGE C C C C C#LCULATE Tr:UE FRACTURE STP.LIh5 FOR IRRADIATED AhD LNIRRADIATED MATESIAL. EPFI = EPFl:IN (T EVP, FLUE!!C ) Eifu e EPFMIN (1 E MP,0,0 ) C COEFFICIENT FCR PLASTIC STRAIN TERM A = (EPFU** (-0. A ))
~~EPFI C FOR TEMPERATURES LESS THAN EOO F, USE B00 F DATA.~~
~~T = AMAX1 (TEMP,800.) E = 2 9336690. - T * (2882.211 + T*(3.697849 .0007/09188*T) ) U = 78918. + T * (36.854 .047012~~
T)
~~C COEFFICIENT FOR ELASTIC STRAIN TERM B = 3.5~~
~~U / E C TET MINIMUM STRAIN VALUE TO AVOID 00TAINING INFINITE FATIGUE LIFE.~~
~~Y = A KAX1 (D EL EP,5.E-04 ) C DEFINE COEFFICIENTS FOR NEWTON EXTRAPOLATION METHOD. he Q = Y/8 R = 5.**/0~~
~~' (? C CALCULATE INITIAL VALUE OF XI.~~
~~XI = 0 * ( 0.8 + 0.2 / (R *Q * *4 + 1.) ) C CALCULATE DX. 1 DX = 0.2~~
~~XI + (0.8 XI - Q)/ (R*XI**4 + 1.)~~
~~~ C CALCUL ATE NEW VALUE OF XI. XI = XI - DX C TEST FOR CONVE.lCENCE. IF ( ABS (DX/X;) .GE. 1.E-04 ) GO TO 1 CALCULATE FATIGUE LIFE FOR LIFE FACTOR OF 20. FL1 = 0.05~~
~~31**(-8.3333333333333)~~
~~C REPEAT NEWTON EXTAAPOLATION FOR STRAIN FACTOR OF 2. Y s Y+Y 0eo+o XJ = 0 * ( 0.8 + 0.2/(R*0**i. + 1. )) 2 DX : 0.?~~
~~XJ + (0.5eXJ - C)/ (2 *XJ ** 4 + 1.)~~
XJ = XJ - DX IF ( AUS CCX/XJ) .CE. 1.E-C4 ) 00 T0 2 FL2 = /J **(-3.3333333333333) C SELECT E.~. ALLER VALUE OF F ATICUE LIFE AS CUTPUT VALUE. FTGLIF = An!N1(FL1,FL2) RETUk4 END + A-19 s (1
I TABLE A.5 (continued) jf FUNCTION RUPTIM (SGPRNC,TF,FLNC,0UMMY) g REAL LMP F DIMENS ION AHAT (2 ),XB A R (2 ),$ IGX (2 ), CORREL (2 ), A (4 ),8 (4 ),C (4), 1 XB R (4 ) ,X S IG (4 ) ,N (4 ) ,S T D E R R (4 ),C OR (4 ),T ST AT (4 ) ,T OL F C T (4 ), 1 AX (2 ),8X (2 ),XBR2 (4 ),X51G2 (4 ),COR2 (4 ) DATA ( A (J ),J =1,4 ) / S ee26.0,35 5 99.0,64292.0,442 70.0 1 / ,(B (J ),J =1,4 )/0.0,6.9413,0.0,2.294 7 2 / , (C (J ),J S1,4 ) /-6135.8,-263 7.0,-7 762.1,-3040.0 3 / , (XBR (J ),J =1,4 )/0.0,1760.0,0.0,1823.6 4 / ,(XBR2 (J ),J =1,4 )/3.6200,2.8154,3.9666,2.3714 5 / (XSIG(J ),J s1,4 )/0.0,92.195,0.0,48.105 6 / ,(XS'G2 (J ),J =1,4)/0.38416,0.23989,0.24960,0.37468 7 / ,(N (J ),J =1,4 )/ 85,10,3 7,11 8 / ,(STDE RR (J ) ,J =1,4 )/300.84,199.2 8,469.89,308.97 1 / ,(COR (J ),J =1,4 ) / 4 *1.0/ ,(COR2 (J ),J =1,4)/ 4 *1.0
~~7. / .(TST AT (J ),J =1,4 )/1.989,2.026,2.032,2.306 6 / , ( A X (K ),K =1,2 )/ 763.959,69.405 S / , t9 X (K ),K =1,2 )/-1.9839E-03,-4.8595 E-04 /~~
C C THIS COP'PUTES TIME TO RUPTURE (HR) FOR 20 PCT CW 316 C HODEL *
~~LMP= A +0 *T R +C *LN (S IG)~~
C $1G=NAA PRINCIPAL CTRESS (<SI) OR STRESS INTENSITY (KSI) C TR= TEMP (DEC R) C TRANSITION GIVEN BY ** SIGT=AX*EXP(BX/TR) C POST TRANSITION IF SIG.LT.SIGT (BRITTLE RUPTURE) C J z1 FOR UN-IAR, PRE-TRANSITION C Js2 FOR UN-!RR, POST-TRANSITION C J=3 FOR IRR, PRE-TRANSITION C J=4 FOR IRR, POST-TRANSITION C ENTEPED WITH**** C TF=T[MPERATURE IN DEG. F. C SGPRNCrEAX PRINCIPAL STRESS OR STRESS INTENSITY (PSI) C ICO = 1 FOR UN-IRR,No SODIUM C =2 FOR IRR.,No SODIUM as C 83 FOR UN-IRR,IN SODIUM C =4 FOR IRR., IN SODIUM y' C RETURN $ **** C RUPTIMrLOWER VALUE RUPTURE TIME FOR 2-STD.DEVI AT10N CONFIDENCE BAND C GET TEMP (DEG R) AND STRESS (KSI) TR=TF+4to.0 - SIG = SGPRNC
~~0.001 S IG = AMAX1 ($ 1G,1.0)~~
~~C SELECT CONSTANTS ICOND = 3 IF ( FLNC .GT. 0.0s ICOND = 4 J 81 K =1 I F (ICOND .E Q .2.0R . ICOND .EQ .4 )J r3 IF(ICOND.EQ.2.OR.!COND.EQ.4)K=2 S IGT = A X (K )~~
~~E XP (B X (K ) *T R )~~
~~IF (S IG.LT .S IGT )J rJ +1 LMP = A (J ) + (B (J ) - ALOG10 (4.0))* TR + C (J )~~
~~ALOG(SIG)~~
XHAT(1)=TR Xe A R (1 ) =XB R (J ) S IGX (1 ) =X S IG sJ ) COR R EL (1 )=COR (J ) XHA T (2 ) = ALOG (S IG) XB A R (2 )= XB R2 (J ) S IGX (2 ) =XS IG2 (J ) C OR REL (2 ) =COR2 (J ) CFACT = CNFLIM (2,N (J ),XHA T ,XB A R ,51GX ,$T DE RR (J ), CORREL ,TST AT (J )) RUPTIM = E X P ( ALOG (10. ) * ((LMP - CFACT)/TR - 20.)) RETURN END I
~
A-20 ',
TABLE A.5 (continued)
~~- s]~~
G FUNCTION EPFMIN(T,F) C C EPFMIN CALCULATES MINIMUM FRACTURE DUCTILITY FOR CW316SS FROM AN EMPIRICAL C CORRELATION DFVELOPED BY GE C C DEFINITION OF TERMS C T = TEMPERATURE IN DEG F C F = IRRADIATION FLUENCE IN 1.E22 N/CM2 C EPFMIN = MINIMUM FRACTURE DUCTILITY C C DIVIDE TEMPERATURE BY 1000 l TT = T * .001 C FOR TEMPERATURES LESS THAN 800 F, USE 800 F DATA TT = AMAX1 CTT,.8) C CALCULATE THRESHHOLD FLUENCE FOR REDUCTION OF DUCTILITY F0 = 1.4 - TT IF (T .GT. 1200.) F0 = TT - 1.0 C CALCULATE MINIMUM DUCTILITY FOR UNIRRADIATED MATERIAL EPO = .45 / (SQRT(TT) * (TT * *3 ) ) IF ( T .GT . 1000. ) EPO = EP0/ (TT**2) IF (F .LE. FO) GOTO1 C IF FLUENCE EXCEEDS THRESHHOLD FLUENCE, APPLY DUCTILITY REDUCTION FACTOR ZZ = TT - 1.7 EPO = EPO * ((F/FO)**ZZ) 1 EPFMIN = EPO RETURN END h l l () FUNCT5ONELUNIF (T EMP,FLUENC ) - C ELUNIF CALCULATES MINIMUM TRUE UNIFORM ELONGATION FOR CW31625, USING A C CORRELATION DEVELOPED BY HEDL FOR FIRST-CORE STEEL. 1 ( 1 C C DEFINITION OF TERMS ' l C TEMP = TEMPERATURE IN DFG F , C FLUENC = IRRADIATIOP FLUENCE (FAST) IN 1.E22 N/CM2 C ELUNIF MINIMUM TRUE UNIFORM ELONGATION 1 C C FOR TEMPERATURES LESS THAN B00 F, USE 800 F DATA T = AMAX1(TEMP,800.) C C ALCUL ATE ENGINEERING UNIFORM ELONGATION, USING POLYNOMI AL CORRELATION EU = .12854 + T * (.00010857 + T * (.93846E-07 .17995E-00*T) ) I C CALCULATE TRUE STRAIN VALUE FROM ENGINEERING STRAIN VALUE. 1 ELUNIF = ALOG(1. + EU) RETURN END l l b ~* A-21 l j) l l l
TABLE A.5 ' (continued) r-V FUNCTION CNFLIM (M ,N ,XHAT ,x8 A R ,S IGX ,$ E E ,C OR R EL ,T S T AT ) DIMENSION XHAT (M),xBAR(M),5 IGX (M), CORREL (M) C THIS COMPUTES CONFIDENCE BAND AND TOLERENCE BAND ABOUT MULTI-LINEAR C REGRESSION EQUATION C ENTERED WITH FOLLOWING VARIABLES ** C MrNUMBER OF INDEPENDANT VARIABLES IN MODEL C NzNUMBER OF DATA POINTS USED IN 00TAINING MODEL C XHAT(1)=VALUE OF I-TH INDEPENDANT VARIABLE (TRANSFORMED IF APPLICABLE) C TO BE USED IP CALCULATION, !=1,2,3,...,M C XeAR(1)rMEAN VALUE G. 1-TH INDEPENDANT VARDBLE (FROM MELO) C SIGX(I)=STD DEVIATION ABOUT EACH INDEPENDANT VARIABLE (FROM MELS) C SEE= STANDARD ERROR IN ESTIMATE OF DEPENDANT VARIABLE (FROM MELB) C CORREL (1)= CORRELATION COEF FOR 1-TH IND. VARIABLE (FROM MELS) C TSTAT= DESIRED T STATISTIC TO BE USED IN CALC OF CONF LIMIT C TOLFCT: DESIRED TOLERANCE FACTOR USED IN CALC OF TOL. LIMIT C THE FOLLOWING IS RETURNED *** C CNFLIM:2- STD. DEV. CONFIDENCE BAND ABOUT DEPENDENT VARIABLE C SUM =0.0 00 10000 !=1,M,1 T E RM1 =1.00 +50 RT (1.0-CORR EL (1) * *2 ) TE RM2 = (xB AR (I )-xHAT (1 )) * *2 T E RM3 = FLOAT (N ) *S IGX (I ) * *2 IF (TERM 3.EQ.0.0)GO TO 10000 SUM r$UM +TE RM1 *T E RM2/ TE RM3 10000 CONTIl4UE CNFLIP = ABS (TSTAT
SEE

SQRT(SUM + 1.0/ FLOAT (N)))

RETURN END J
~~.4 A-22 ( \~~
~~_}}~~

ML19331D327

Contents

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2.0 DESCRIPTION

10.0 REFERENCES

1.0 INTRODUCTION

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SUMMARY

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ML19331D327

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2.0 DESCRIPTION

10.0 REFERENCES

1.0 INTRODUCTION

2.0 DESCRIPTION

SUMMARY

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