INDEX A 1 and A 2 values, radioactive material packaging, 348, 350, 351 Q-system for calculation of, 345, 350, 353, 356 Abrasion, of pressure equipment, 153 AC. See Alternating current. Accelerated intergranular corrosion test, French codes, 249, 253 Acceptance criteria, of age management program, 58 Access door, in pressure equipment, 152 Accident sequence analysis, 93 Accreditation, of Canadian organizations developing standards, 160 Accredited standards-developing organizations (SDOs), 160 Acetylene gas, compressed, 260 ACI. See American Concrete Institute. Acoustic circuit analyses, 6 Acoustic emission, 254 CODAP future specifications, 208 ACR ® . See Advanced CANDU ® Reactor. ACRS. See Advisory Committee on Reactor Safeguards. Active component failure rate, 96 Active power plant structures/components, surveillance and maintenance programs, 31 ACVG. See Alternating current voltage gradient method. Addenda to the Code 1972 Addenda to Section III, Appendix G, 44 1983 Addenda to Section XI, 116 1988 Addenda to Section XI, 7, 118 1994 Addenda (2004 Edition as revision), 296, 298, 299 1999 Addenda, 271, 307, 666, 667 2001 Addenda, 298, 668, 673 2002 Addenda to Section XI, 118, 119, 121, Section XI, Appendix C, 19–20, 21, 22, 118, 126 2003 Addenda, 668 Adjustment factor (Ke factor), 273. See also Ke factor. AD Merkblätter code, 316, 329, 330 Administrative Procedure Act of 1946 (APA), 338, 594 AD 2000, 139, 553, 554, 555, 557, 561, Advanced CANDU ® Reactor (ACR ® ), 188 Advisory Committee for Energy, Nuclear and Industrial Safety Subcommittee, 259 Advisory Committee on Reactor Safeguards (ACRS), 505 Advanced Notice of Proposed Rulemaking, 350 Advantica (formerly BG Technology), 400 AE. See Aging effect. AEA. See Atomic Energy Act. AEC. See U.S. Atomic Energy Agency. Aerospace Material Specifications, materials standards, 163 A 0 factor, 275 AFCEN. See French association for design, construction and inservice inspection rules for nuclear island components. AFCEN Quality Manual, 197 AFIAP. See Association Française de Ingenieurs en Appareils à Pression. AFNOR. See French Standardization Organization. AGA. See American Gas Association. Aging fitness-for-service rules (Japan), 276 indicators, 58 managing the effects of, 35 pressure equipment conformance, 142 preventative action, 35 Aging degradation, 58–59 Aging effect (AE), 58–59 environmental, 38 Aging management, of pressurized water reactor (PWR) vessel internals, 57–60 Aging management program (AMP), 21, 30–31, 33–35, 39, 41, 58–59 audits, 33–34, 36–37 during extended operation, 38 elements, 35, 57 environmental aging effect and, 41 GALL Report and, 33–34 license renewal and, 32 plant-specific, 37–38, 57 Aging management review (AMR), 30–35, 38, 41, 57 Aging management strategies, 59–60 AI. See Authorized Inspector. AIA. See Authorized Inspection Agencies. Air environments austenitic stainless steels fatigue crack growth rate, 21 ferritic steels fatigue crack growth rate, 21 Air conditioning, Japanese codes, 261 Air Conditioning and Refrigeration Institute, cooling equipment standards, 163 Additional page numbers with information about individual ASME Specifications (SA and SB numbers) can be found under the headings “American Society of Mechanical Engineers Ferrous Material Specifications” and “American Society of Mechanical Engineers Nonferrous Material Specifications.” Referrals to Code Paragraphs and Sections can be located by their alphabetical code (NA, NB, etc.).
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INDEX
A1 and A2 values, radioactive material packaging, 348, 350, 351Q-system for calculation of, 345, 350, 353, 356
Abrasion, of pressure equipment, 153AC. See Alternating current.Accelerated intergranular corrosion test, French codes, 249, 253Acceptance criteria, of age management program, 58Access door, in pressure equipment, 152Accident sequence analysis, 93Accreditation, of Canadian organizations developing standards, 160Accredited standards-developing organizations (SDOs), 160Acetylene gas, compressed, 260ACI. See American Concrete Institute.Acoustic circuit analyses, 6Acoustic emission, 254
CODAP future specifications, 208ACR®. See Advanced CANDU® Reactor.ACRS. See Advisory Committee on Reactor Safeguards.Active component failure rate, 96Active power plant structures/components, surveillance and
maintenance programs, 31ACVG. See Alternating current voltage gradient method.Addenda to the Code
1972 Addenda to Section III, Appendix G, 441983 Addenda to Section XI, 1161988 Addenda to Section XI, 7, 1181994 Addenda (2004 Edition as revision), 296, 298, 2991999 Addenda, 271, 307, 666, 6672001 Addenda, 298, 668, 6732002 Addenda to Section XI, 118, 119, 121,
Adjustment factor (Ke factor), 273. See also Ke factor.AD Merkblätter code, 316, 329, 330Administrative Procedure Act of 1946 (APA), 338, 594AD 2000, 139, 553, 554, 555, 557, 561,Advanced CANDU® Reactor (ACR®), 188Advisory Committee for Energy, Nuclear and Industrial Safety
Subcommittee, 259Advisory Committee on Reactor Safeguards (ACRS), 505Advanced Notice of Proposed Rulemaking, 350Advantica (formerly BG Technology), 400
AE. See Aging effect. AEA. See Atomic Energy Act.AEC. See U.S. Atomic Energy Agency.Aerospace Material Specifications, materials standards, 163A0 factor, 275AFCEN. See French association for design, construction and
inservice inspection rules for nuclear island components.AFCEN Quality Manual, 197AFIAP. See Association Française de Ingenieurs en Appareils à
Pression.AFNOR. See French Standardization Organization.AGA. See American Gas Association.Aging
Air conditioning, Japanese codes, 261Air Conditioning and Refrigeration Institute, cooling equipment
standards, 163
Additional page numbers with information about individual ASME Specifications (SA and SB numbers) can be found under the headings“American Society of Mechanical Engineers Ferrous Material Specifications” and “American Society of Mechanical EngineersNonferrous Material Specifications.” Referrals to Code Paragraphs and Sections can be located by their alphabetical code (NA, NB, etc.).
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688 • Index
Air transport, of radioactive materials, 347, 352, 353AISC. See American Institute for Steel Construction. ALARA. See As Low as Reasonably Achievable.ALARP. See As Low As is Reasonably Practical region.Allowable flaw depth, 9, 118Allowable pressure
Seismic and External Events Standard, 104Subcommittee 28, 107
American Nuclear Society (ANS) Standards, specific types 53.1 (Nuclear Safety Criteria for the Design of Modular Helium
Cooled Reactor Plants), 10958.21, 110, 112
American Petroleum Institute (API), 162American Petroleum Institute (API) Pressure Vessel Inspection Code
standards, specific typesAPI 530, 162, 170, 188API 579, 121API 1104 (Acceptance Standards of Production Welds), 400API 1160 (Managing System Integrity for Hazardous Liquid
Pipelines), 377, 380American Society for Nondestructive Testing (ASNT), 148, 264,
ASNT TC 1A (Personnel Approval), 148Master Curve test method, 43materials for pressure equipment construction, 147steels, toughness conformance, 147
American Society for Testing and Materials (ASTM) SpecialTechnical Publication (STP)
Temperature Shift in Reactor Vessel Materials), 54–55, 61E 900-87 (Standard Guide for Predicting Neutron Radiation
Damage to Reactor Vessel Materials), 54, 61
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COMPANION GUIDE TO THE ASME BOILER & PRESSURE VESSEL CODE • 689
E 1921, 53E 1921-97, 61
American Society of Mechanical Engineers (ASME), 162, 163Class 1 ferritic piping, flaw evaluation procedures, 118Code cases, 103, 104, 106, 107, 108nameplate, removal of, 366safety factor, 149specifications, for steel, 149Subcommittee VIII, 208Subcommittee XII, Transport Tanks, 357
American Society of Mechanical Engineers Board on Nuclear Codesand Standards (BNCS), 103, 107, 109, 189
Code cases, 109–110, 112Committee on Nuclear Risk Management (CNRM), 90, 108environmental fatigue effects and, 21Independent Decision-Making Panels, 110non-mandatory appendices, revising risk-informed, 228, 358Nuclear Air and Gas Treatment Equipment Committee, 107Nuclear Codes and Standards (NS&S) Task Team, 107, 108, 109,
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690 • Index
American Society of Mechanical Engineers (ASME) InnovativeTechnologies Institute, 110
American Society of Mechanical Engineers (ASME) NonferrousMaterial Specifications (SB specifications), SB-166,19
American Society of Mechanical Engineers (ASME) Operations andMaintenance Code for Nuclear Power Plants (O&M Code)
Appendix II (Check Valve Condition Monitoring Program), 105Code cases, 109Inservice Inspection (ISI) code, 108Inservice Testing (IST) code, 103, 109OMN-Code 1995 Edition-1996 Addenda, 105OMN-1, 105OMN-3 (Risk Categorization), 103, 104, 105, 106, 112OMN-4 (Treatment of Check Valves), 103–106, 112OMN-4 White Paper, 105, 112OMN-7 (Treatment of Pumps), 103–106, 112OMN-10 (Snubbers), 103–106, 112OMN-11 (Treatment of Motor-Operated Valves), 103–106, 112OMN-12 (Treatment of Pneumatic and Hydraulic Valves),
American Society of Mechanical Engineers (ASME) Pressure VesselResearch Council (PVRC) Workshop on the EnvironmentalEffects on Fatigue Performance, 20
American Society of Mechanical Engineers (ASME) Research TaskForce on risk-Based Inservice Testing Guidelines, CRTD-Vol.40-2, 103, 108
American Society of Mechanical Engineers PVHO-1 (SafetyStandard for Pressure Vessels for Human Occupancy), 169,188
American Society of Mechanical Engineers (ASME) SectionSubgroup on Range, 124
American Society of Mechanical Engineers (ASME) website(www.asme.org), 107
American Society of Mechanical Engineers (ASME) Working Groupon Check Valves, 103
American Society of Mechanical Engineers (ASME) Working Groupon Codes Strategy, 258
American Society of Mechanical Engineers (ASME) Working Groupon Motor-Operated Valve, 103
American Society of Mechanical Engineers (ASME) Working Groupon Pumps, 103
American Society of Mechanical Engineers (ASME) Working GroupPressure (WGP), Standing Committee, 131
guideline for PED, 144American Welding Society (AWS), 163AMP. See Aging management program,AMR. See Aging management review.Anhydrous ammonia service, pressure vessels, 170ANI. See Authorized Nuclear Inspector.ANII. See Authorized Nuclear Inservice Inspector.Annex Z, 147, 149, 193Annulus spacers, 164ANS. See American Nuclear Society.ANSI. See American National Standards Institute.Anticipated transients without scram (ATWS), 31, 42APA. See Administrative Procedure Act.API. See American Petroleum Institute.Appliances burning gaseous fuels, New Approach Directive, 145Approval of Type B Quantity and Fissile Material Packagings,
341–342, 344Architectural Institute of Japan, stress analysis of concrete structures,
288–289Argonne National Laboratory, 21–23, 86Arkansas Nuclear One, Unit 2 nuclear power plant, 97Arrhenius equation, 76Asada, Yasuhide, 112, 257, 276, 292Asbestos removal, 428, 431As Low As is Reasonably Achievable (ALARA), 440, 447, 450, 462,
463, 471As Low As is Reasonably Practical (ALARP) region, 385ASME. See American Society of Mechanical Engineers.Asme Code at Paks Npp, Hungary 589ASNT. See American Society for Nondestructive Testing.Asphalt enamel coatings, for pipeline systems, 409, 412–413Assemblies, in Pressure Equipment Directive, 130, 151, 153, 155Assembly, definition, 218Association Française de Ingenieurs en Appareils à Pression
(AFIAP), 255ASTM. See American Society for Testing and Materials.Atomic Energy Act of 1954 (AEA), 29, 338, 341, 343, 591, 594, 625,
627, 633, 655–659, 662–663, 665, 677 Atomic Energy Control Board, Ottawa, Canada, 188Atomic Energy of Canada Limited, 187Atomic Industrial Forum, 89Attachment weld, 13, 72, 367
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COMPANION GUIDE TO THE ASME BOILER & PRESSURE VESSEL CODE • 691
ATWS. See Anticipated transients without scram.Audits, age management program/review (AMP/AMR), 34, 36–39Austenitic-ferritic stainless steels
for industrial piping, French codes, 142, 191, 553, 554for pressure equipment, French codes, 252, 253for pressure vessels, French codes, 205, 208for pressure vessels, Japanese codes, 263, 264
Austenitic stainless steelsfor calandria material, 163chloride attack susceptibility, 63for containment vessels, 348for containment vessels for radioactive materials, 345, 346for cryogenic portable tanks, 367dissimilar metal welds, 19, 72environmental fatigue effects, 21, 28fatigue crack growth rate in air environments, 5, 21fatigue crack growth rate in water environment, 4–6, 9, 21–22, 24,
of cylinders, 116–117of supports, PD 5500 (U.K.), 319
Bending rupture energy, in pressure equipment, 157Bending stresses, 46, 116
of containment vessels for radioactive materials, 345French codes, 191, 193, 196, 253, 653nuclear power plant piping, 296, 299nuclear pressure vessels, PD 5500 (U.K.), 324
Bending stress intensity factor, 46Bend test
French codes, 253pressure vessel, Japanese codes, 263–264
Bettis Atomic Power LaboratoryWAPD-BT-16, 85WAPD-TM-944, 85
B factor, 251BG Technology. See Advantica, British gas.Bidirectional exercise test, 105Biofouling, 33Blowoff systems, 169Blowoff vessels, 169BMI. See Bottom-mounted instrument nozzle.BNCS. See American Society of Mechanical Engineers (ASME)
Board on Nuclear Codes and Standards.BNQ. See Bureau de normalization du Québec.Boilers. See also Pressure vessels.
Canadian non-nuclear standards, 162Canadian standards, 160–163, 168failure modes, French codes, 198, 218French codes, 191, 193, 196, 253, inservice inspection, Canadian, 181–187in scope of PED, 130–131
Boiling water reactor (BWR)vs. CANDU® design, 163control rod drive stub tube cracking, 12feedwater nozzle, 8–10, 12ferritic stainless steel fatigue crack growth, 22fitness-for-service code (Japanese), 280inclusion criteria (Level A) for high-safety significant (HSS)
snubbers, 106
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57, 59, 63weld overlay, 1weld overlay repairs of dissimilar metal welds at nozzles, 81
Boiling water reactor (BWR) environmentaustenitic stainless steel, fatigue crack growth rate in, 21–22ferritic steels, SCC growth rate relationship, 23
Boiling water reactor/2 (BWR/2) material, 12–16Boiling water reactor/2 (BWR/2) plant, shroud support geometry, 14Boiling water reactor/3 (BWR/3) material, 15–16Boiling water reactor/4 (BWR/4) material, 15–16Boiling water reactor/5 (BWR/5) material, 15–16Boiling water reactor/6 (BWR/6) material, 15–16Boiling Water Reactor (BWR) Owners Group
analysis, 16flaw evaluation guidelines, 22objectives, 15pipe cracking in boiling water reactors, 17Topical Report, 15–16, 26, 41
for crack growth due to IASCC, 60for loss of toughness due to irradiation, 60
Bounding crack growth evaluation, 24Bounding curve, 53Bounding locations, in fatigue monitoring program, 37BPTCS. See American Society of Mechanical Engineers (ASME)Board on Pressure Technology Codes and Standards.Branch Technical Position RSB 5-2, 45, 60Brazing
1113 (water-tubesteam generating plant), 311, 314, 3161500 (fusion-welded pressure vessels for general purposes), 309,
314, 3301501, 310–3111501-224-490A or 490B, 3101501-304-S61, 3111503, 3111515, 309, 314–315, 3301560, 3162790 (shell boiler of welded construction), 3113915 (steel vessels for primary circuits of nuclear reactors), 315
Boiling water reactor (BWR) (continued)
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COMPANION GUIDE TO THE ASME BOILER & PRESSURE VESSEL CODE • 693
4504, 3164975 (prestressed concrete pressure vessels for nuclear
engineering), 3114994 (vessels and tanks in reinforced plastics), 3115169 (fusion-welded steel air receivers), 3115500 (unfired fusion-welded pressure vessels), 309, 311, 321, 324,
330–3317005 (carbon steel vessels for use in vapor compression
refrigeration systems), 311EN 286 (simple unfired pressure vessels designed to contain air or
Buckling strain, theoretical, for a perfectly circular cylinder, 314–315Bugey 3 nuclear power plant, 69Bulk low specific activity materials, 347Bureau de normalization du Québec (BNQ), 160Bureau of Explosives (Association of American Railroads) permits
for radioactive materials packages, 340Burnishing, to reduce potential PWSCC, 82Bursting
Assembly), 164–165Figure 48.6 (Schematic Overview of CANDU® Online Refueling
System), 176Table 48.1 (CSA B 51 Standard: Classification of Pipe Fittings), 169Table 48.2 (CSA N285.5 and N287.7 Interfaces-Requirements for
Inspection and Testing of Containment System Components),172, 174, 176
Canadian Boiler and Pressure Vessel Standards, specific typesA series (Construction Materials), 163B series (Tolerance Specifications and Pressure Boundary
Standards), 163B51-03, Part 2, 170B51-03, Part 3, 170C series (Electrical Codes and Standards), 163G series (Structural Steel Specification), 163S Series (Construction and Structural Specifications), 163W series (Welding Specifications), 163Z series (Quality Assurance Programs), 163CAN/CSA-B51 (Boilers, Pressure Vessels, and Pressure piping),
162, 168, 172subcommittees for, 168
CAN/CSA-B51-03 (Pressure Vessel Design and Construction),159, 162, 168, 172
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694 • Index
CAN/CSA-B149.1 (Natural Gas and Propane Installation Code),162, 170
CAN/CSA-B 149.2 (Propane Storage and Handling Code), 162,169–170,
CAN/CSA-B 149.5 (Installation Code for Propane Fuel Systemsand Tanks on Highway Vehicles), 162
CAN/CSA-N287.7-96 (Periodic Inspection of ContainmentComponents, Concrete and Structural), 159
CAN/CSA-N288 (Environmental Radiation Protection), 163CAN/CSA-N289 (Seismic Qualification of CANDU® Nuclear
Power Plant Structures and Systems), 159, 163, 171, 179CAN/CSA-N289.1 (General Requirements for Identification and
Qualification), 179CAN/CSA-N289.2 (Ground Motion Determination), 179CAN/CSA-N289.3 (Design Procedures), 179CAN/CSA-N289.4 (Testing Procedures), 179CAN/CSA-N289.5 (Instrumentation, Inspection, and Records), 179CAN/CSA-N290 (Safety and Safety-Related Systems), 163CAN/CSA-N291 (Safety-Related Structures), 163CAN/CSA-N292 (Waste Management), 163CAN/CSA-N293 (Fire Protection), 163CAN/CSA-N294 (Decommissioning), 163CAN/CSA-Z180.1 (Compressed Breathing Air and Systems), 162,
170CAN/CSA-Z299 (Canadian Quality Control Program), 168CAN/CSA-Z305.1 (Nonflammable Medical Gas Piping Systems),
162, 170CAN/CSA-Z305.3 (Pressure Regulators, Gauges, and Flow-Metering
Devices for Medical Gases), 170CAN/CSA-Z662 (Oil and Gas Pipeline Systems), 162, 170, 403,
405–406Appendix N, 376–377
CAN/CSA-Z662-03 (Oil and Gas Pipeline Systems), 159, 170–171Appendix K, 400
Canadian Boiler and Pressure Vessel Standards, specific types (continued)
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COMPANION GUIDE TO THE ASME BOILER & PRESSURE VESSEL CODE • 695
CAN3-Z305.4 (Qualification Requirements for Agencies TestingNonflammable Gas Piping Systems), 170
CAN/ULC-S603.1 (Galvanic Corrosion Protection Systems forUnderground Steel Tanks), 169, 189
NRCC 38726 (National Building Code of Canada), 179, 189NRCC 38727 (National Fire Code of Canada), 189
Canadian Standards Association (CSA), 160annexes, nonmandatory and mandatory, 162boiler and pressure vessel standards development, 161CSA-SDP-2.1-99, 188CSA-SDP-2.2-98, 188format and structure of standards, 161–162headquarters address, to obtain standards, 168non-nuclear boiler, pressure vessel, and piping design and
construction standards, 168–171nuclear boiler and pressure vessel design and construction
standards, 171–181nuclear boiler and pressure vessel inservice inspection standards,
Web site and headquarters address, 160Canadian Transportation Safety Board, 372CANTEACH Web site, 166, 189Capacity certification test report, 173Carbides, 16–17
PWSCC and density of, 68Carbon, alloy presence and PWSCC, 67Carbon-manganese steels
fast breeder reactor material, 251for industrial piping, French codes, 223–224for pressure equipment, French codes, 201–202, 236–237for pressure equipment PD 5500 (U.K.), 311–312
Carbon steelsboiling water reactor piping, 16for containment vessels for radioactive materials, 346dissimilar metal welds, 63environmental fatigue effects, 21fatigue life in high-temperature reactor water, 21for industrial piping, French codes, 223–224J estimation, 114–115
Carlsbad, New Mexico pipeline incident, 371, 374Carrier, 337Cask code, Japanese codes, 289–290Cask design
for Type B radioactive materials, 348Casks, shipping, for radioactive materials, 340, 343–345, 347CASS. See Cast austenitic stainless steel.Cast austenitic stainless steel (CASS)
irradiation embrittlement in, 59thermal aging embrittlement in, 59
284Cast steel, in pressure equipment, 157Categorization of components strategy, 59Category 0, 131, 133, 134Category I, 131, 133–136, 138, 143, 147, 153Category II, 131–138, 140, 143, 147, 152, 154Category III, 133–138, 140, 142-143, 147, 152, 154Category IV, 133–138, 140, 142–143, 145, 152, 154Cathodic protection
for pipeline system assessment, 391–394for pipeline systems, 413, 410–411, 412–414for pipeline systems, calculation of resistance values, 413–414for pipeline systems, monitoring of, 415–416
CAVS. See Crack arrest/advance verification system.CCDP. See Core damage probability.CCV. See Concrete containment vessels.CDA. See Copper Development Association.CDF. See Core damage frequency.CE. See Combustion Engineering.CEA. See Commissariat à l’Energie Atomique.CEDM. See Control element drive mechanism.CEGB. See British Central Electricity Generating Board.CEN (European Standardization Body for Mechanical Equipment),
144, 150represented in Working Group Pressure Standing Committee, 144standard, 324
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696 • Index
CERCLA. See Comprehensive Environmental Response,Compensation, and Liability Act.
Certificate of Authorization (ASME), 169Certificate of Compliance (CoC), 350–355Certificate of Conformity, 136, 144, 156Certification, CANDU® nuclear power plants, 174Certified Individual (CI), 365–366CFER Technology, 384, 385CFR. See United States Nuclear Regulatory Commission (USNRC)
Code of Federal Regulation.CGR. See Crack growth rate.CGSB. See Canadian General Standards Board.Change-in-risk evaluation, 96Charpy energy curve, 125Charpy KV tests, pressure equipment, French codes, 235Charpy V-notch (CVN) absorbed energy, 118Charpy V-notch (CVN) impact test, 54
carbon steels, PD 5500 (U.K.), 312fracture toughness transition due to temperature, 50monitoring changes in fracture toughness, 45of pressurized water reactor vessel materials, 44surveillance data, 50–51transport tanks, 359–360
Chemical attack, of pressure equipment, 153Chemical plants, 110, 168Chemical resistance, pressure equipment conformance, 143Chemical testing, 248Chemical Volume and Control System (CVCS), risk-informed safety
significance, 100Chinese Daya Bay 1 and 2 contract, 193–194Chinese nuclear power plants, 193–194, 293Chloride-induced stress corrosion cracking, 63–64Chromium, solution heat treatment (SHT) and, 17Chromium alloys, for use in PWR vessels, 63–64Chromium carbide, 66
boundary deposition in PWHT, 63Chromium concentration, susceptibility to PWSCC and, 66–67Chromium-molybdenum steels
fast breeder reactor material, 251for industrial piping, French codes, 222–223for pressure equipment, French codes, 201–203,
236–237, 241Chromium-molybdenum-vanadium steels
for industrial piping, French codes, 222for pressure equipment, French codes, 201–203, 236–237, 251
Chromium steels, for pressure equipment, Japanese codes, 287CI. See Certified Individual.Circumferential cracks (flaws), 4, 15, 18, 49, 69–70, 118–120
in boiling water reactor (BWR), 74crack growth predictions for, 76–77on control rod drive mechanism (CRDM) nozzles, 69flaw size for nozzle failure, 79nondestructive testing to determine, 73in plate material, 15in PWR RPV CRDM nozzles, 74–75, 77–78in PWR RPV inlet/outlet nozzles, 74
tensile strength causes, 67in top head nozzles, 72–73
alloy 65, 66, 69alloys 82/182 crack detection, 70alloys 82/182 used for, 65corrosion-resistant, 17stainless steel, on inside of pressurized water reactor vessel top
head, 74stress corrosion cracking initiation, 25
Class 1 components, 174ASME Code requirement development, 103austenitic stainless steel piping, 26BWR intervals, 1design control provisions, 102as high-safety significant (HSS), 100–101piping, flaws and continuing service, 18piping, RI-ISI requirements, 94–97piping, Section XI inspections, 94piping, structural factors, 118reactor coolant pressure boundary structures, systems, and
Class 3 componentsASME Code requirement development, 103austenitic stainless steel piping, 26high-safety significance, 101piping, RI-ISI requirements, 94–97piping, structural factors, 118reactor coolant system, SSC function of removing heat from
support system, 99transport tanks, 366–367
Class CC (concrete containment) components, 99Class MC (metal containment) components, 99Cleanliness, French codes, 253Cleanup cost, crude oil pipeline break, 371CLERP. See Conditional large early release probability.Cleavage crack, from local brittle zone, 52Clock Spring(tm) repair, 404–405Closure plugs, 174CNRM. See American Society of Mechanical Engineers (ASME)
Committee on Nuclear Risk Management (CNRM).CNSC. See Canadian Nuclear Safety Commission.Coal tar enamel coatings, for pipeline systems, 409–413Coatings, 143, 409–413
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COMPANION GUIDE TO THE ASME BOILER & PRESSURE VESSEL CODE • 697
CoC. See Certificate of Compliance.CODAP. See Code de Construction des Appareils à Pression.Code. See American Society of Mechanical Engineers Boiler and
on environmental fatigue effects, 21evaluation and repair of stainless steel pipe cracking, 21French codes, 197proposed, environmentally assisted fatigue crack growth in a BWR
environment, 22risk-informed, 90
Code Cases, specific typesN-47, 193N-XXX (Alternative Acceptance Criteria and Evaluation
CODETI. See Code de construction de Tuyauteries Industrielles.Code of Federal Regulations (CFR). See United States Nuclear
Regulatory Commission (USNRC) Code of FederalRegulations (CFR).
Code of Record of ASME Section III (Nuclear Vessels), design risk-informed safety classification, 108
Code stamped devices, on Code Stamped Transport Tanks, 359Code year, 174COG. See CANDU® Owners Group.Cold leg temperatures, 67, 83Cold springing stress, 18Cold work, and Alloy 60 susceptibility to PWSCC, 68Collapse, 403
by limit load, 113of radioactive material packaging, 340–341
Collars, 131Combination impact group assessment, 95Combined tension and bending, of cylinders, 115–116Combustion Engineering (CE)-designed PWR plant, 64–66Combustion Engineering (CE) Marking, 129–131, 133–134, 136,
138, 141, 143, 149Commercial grade classification, 98Commissariat à l’Energie Atomique (CEA), 193, 195Committee of Enquiry into the Pressure Vessel Industry (U.K.), 309
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698 • Index
Competent Authority, regulation of hazardous material transportation,334
Conformity assessment procedures, 129–131, 133, 135–137sboilers, French codes, 224, 253industrial piping, French codes, 142, 191, 554manufacturer responsibility, 138–140, 144, 168
Conical shells, 312–313EN 13445 vs. PD 5500 (U.K.), 328–330
Consequence assessment, ranking, 328Conservation integrals, 328Conservation of Air and Water Environment (CONCAWE), 372Constant amplitude stress, pressure vessels, PD 5500 (U.K.), 320Construction
boilers, French codes, 222industrial piping, French codes, 142, 191, 553–554nuclear boiler and pressure vessels, Canadian standards, 168, 171,
253, 337, 655, 679Construction code, 101
alternatives, 102fracture toughness requirement, 102technical requirements of replacement, 102
Construction materials, Canadian standards, 163Construction of spent nuclear fuel storage, 268–269, 345Construction products, New Approach Directive, 145
345Coordinated Research Project (CRP) of IAEA, 352Copper
content, probability of vessel failure and, 55content, upper shelf life and, 15for pressure equipment, Japanese codes, 258–259for pressure equipment, PD 5500 (U.K.), 311transition fracture toughness temperature shift, 54
Copper-64, 363Copper-67, 363
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COMPANION GUIDE TO THE ASME BOILER & PRESSURE VESSEL CODE • 699
Copper alloysfor pressure equipment, Japanese codes, 258for pressure equipment, PD 5500 (U.K.), 311Copper Development Association (CDA), 162
Core damageassessing risk of, 84reducing risk, 83
Core damage frequency (CDF), 8component high-safety significance and, 100estimating, 99Level 1 PRA analysis for, 96probabilistic risk-assessment (PRA) Standard, 111ranking according to contribution to, 90
Core damage probability (CCDP), 100, 525Core flow, 6
predicted crack lengths for, 6Core meltdown
initiators, 89from loss of coolant accident, 89operator error, 89from transients, 89
certificate of compliance holders, for recordkeeping and reportingregulations, 354
of Davis Besse RPV head wastage, 84of decommissioning a nuclear facility, 439, 590, 661of NRC to monitor certificate holders and applicants, 354pipeline corrosion damage, 399pipeline system assessment methods, 386, 395-396
pipeline system breaks, 372reporting minimal changes vs. preparing license amendments, 387
COVAP. See Code de construction des générateurs de VAPeur.Covers, 131Crack. See also Flaws.
hydrogen water chemistry for, 17stress improvement remedies for, 17through-wall circumferential in pipe, 115–117
Crack arrest, 53, 69, 245Crack arrest/advance verification system (CAVS), 24Crack detection, in boiling water reactors, Japanese codes, 278Crack driving force J, 115, 122–123Crack growth, 115–116
attachment weld to vessel material, 13BWR evaluations, 6changes in pH and, 68due to cyclic loading, 33, 647due to irradiation-assisted stress corrosion cracking
(IASCC), 60due to SCC, 5, 22dynamic, 52–53environmentally-assisted, 22, 28in feedwater nozzle, 8-9fracture mechanics analysis, 24hydrogen concentration, 67–68lithium concentration, 68predicting, 84, 126, 397, 450PWSCC in alloy 600 in PWRs, 69, 79vessel-to-shroud support weld, 14welding residual stress contributing to, 77–78
cracks, 70in BWR jet pumps, 4BWR stainless steel intervals, 2–3in BWR water environment, 2–3effect of hydrogen on PWSCC, 80effect of lithium on, 82effect of temperature reduction on, 82effect of zinc on PWSCC, 83irradiation and, 1monitoring, 24and plant monitoring, 20prediction model, 22probability of PWSCC on alloy 600 in PWRs, 86reduction in, 23
Crackingfrom aging, 57-58causing pipeline incidents, 373detecting effects of, due to aging, 59
Crack initiation, 9, 20, 25, 33, 55, 67–68, 113, 303compared to P-T limits for normal cooldown transient, 55in feedwater nozzles, 9irradiation embrittlement and, 59and primary water stress corrosion cracking, 63, 86-87, 94, 684P-T limit and deterministic analysis of conditional vessel failure,
56rate in alloy 82/182 PWSCC in butt welds, 70residual stresses and, 67steam-dryer-support-bracket, 14
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due to fatigue in low alloy and stainless steels, 69dynamic loading and, 51fatigue, 4to through-wall, 73
Crack stability, 44, 74, 122, 123Crack tip
plastic deformation, 66strain rate, 22-23
Crack tip opening displacement (CTOD), 113–114, 400Crack tip stress intensity factor, 44Crack tip temperature, 124Creep, 139, 152, 157, 159, 186, 448Creep design, pressure vessels, EN 13445, 324Creep regimes
French codes, 252Japanese codes, 275
Creep ruptureboilers, French codes, 212industrial piping, French codes, 198pressure vessels, 188
Creep rupture strength, industrial piping, French codes,213, 220Creep rupture stress, French codes, 312Creep-strain laws, French codes, 251Crevice corrosion, age evaluation, 33Crevice corrosion cracking, 17Critical flaw size, 59
feedwater nozzle, 9Criticality safety, 342, 350, 351, 353, 447Criticality Safety Index (CSI), 350, 351, 353Critical stress, ferritic steels at lower shelf, 113, 374Critical zones, of pressure equipment, 152CRC. See Corrosion-resistant cladding.CRD. See Control rod drive.CRDM. See Control rod drive mechanism.CRN. See Canadian Registration Numbers.CRP. See Coordinated Research Project.Crush test, 350, 353
for Type B radioactive materials packaging, 345–350, 447, 478,681
Cryogenic Cargo Tanks, 358Cryogenic portable tanks, 358, 361, 364, 367Cryogenic temperatures, fusion reactors, Japanese codes, 293CSA. See Canadian Standards Association.CSA Info Update, 158CSI. See Criticality Safety Index.CTOD. See Crack tip opening displacement.CUF. See Cumulative usage factor.Cumulative usage factor (CUF), 20, 34, 180, 306Curies, 342–344Current licensing basis (CLB), 32–33, 35, 39
Cushion tanks, Canadian standards, 169–170CVCS. See Chemical Volume and Control System.CVN. See Charpy V-notch upper-shelf energy (USE).CVN. See Charpy V-notch energy.CWA. See Clean Water Act.Cyclic bending stress, 14Cyclic events, design specifications and fatigue, 20
PD 5500 vs. EN 13445, 327as pressure equipment, PD 5500 (U.K.), 299, 300
D&D. See Decontamination and decommissioning.Dampers, 169Damping constant, 295, 300Dangerous goods, definition, 357Data analysis, 93Davis Bacon Act (DBA), 202, 222, 326, 488, 494, 528Davi-Besse nuclear power plant
costs of RPV head wastage, 84cross-section through reactor vessel head, 75top head boric acid corrosion, 69–70, 73–76
Daya Bay nuclear power plant, China, 193–194, 255DBA. See Davis Bacon Act.DBA. See Design by analysis.DBE, 32DBF. See Design by formula.DC. See Direct current.DCRC. See Design and Construction Rules Committee.DCVG. See Direct current voltage gradient method.DE. See Designated equipment.Deactivation (or Transition) Plan, for decommissioning, 425Dead weight loading, 67Declaration of Conformity, 311Decommissioning, definition, 661Decommissioning of nuclear facilities, 656, 661
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COMPANION GUIDE TO THE ASME BOILER & PRESSURE VESSEL CODE • 701
content, thermal aging embrittlement and, 59requirements in weld reinforcement, 18
Demands for Information, 392Demolition, of nonradioactive structures, 479Dents, in pipeline systems, assessment, 396–397Department of Public Safety, New Brunswick, Canada, 168Department of Trade and Industry (DTI) (U.K.), 309Department of Transportation Act, 338–343Design
boilers, French codes, 217, 222-224, 225Canadian oil and gas pipeline systems, 170CANDU® nuclear power plants, 172–174, 176CANDU® nuclear power plants, seismic qualification, 179criteria for the facility, 33expansion bellows, 208explicit safety factor of PWR reactor vessels, 43EN 13445, 324–329fast breeder reactors, French codes, 250French pressure equipment, 191–192, 208industrial piping, French codes, 209, 226nuclear boiler and pressure vessels, Canadian standards, 168, 171,
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702 • Index
Design fatigue analysis, 35Design fatigue usage factor, 35Design pressure, 314, 316–317, 325Design of indian pressurized heavy water reactor components 316Design specification, 20
use for dismantling planning, Design stress, 314, 315
ferritic piping, 119PD 5500 vs. EN 13445, 327
Design stress intensityof containment vessels for radioactive materials, pressure equipment, Japanese codes, 286–287
Design temperature, 325Design tensile strength, pressure equipment, Japanese codes, 287Design tensile stress, pressure equipment, Japanese codes, 286–287Design transients, 35Design yield strength, pressure equipment, Japanese codes, 286–287Destructive examination
Det Norske Veritas (DnV), 400DnV RP-F101 method, 400
Deuterium ingress, zirconium alloys, 159DFM. See Deterministic fracture mechanics.DIAL. See Differential Absorption LIDAR.Differential Absorption LIDAR (DIAL), 417Differential thermal expansion
allowable stresses for reactor vessel components/structures, 67clad-base metal, 51
Diffusion treatment, French codes, 248Dimensionless parameter h1, 115DIN standards, 259Direct assessment, pipeline systems, 376–377, 385, 393Direct current (DC) potential technology, 24Direct current voltage gradient (DCVG) method, for pipeline system
assessment, 395Directive (97/23/CE). See Pressure Equipment Directive.Direct use of spent pressurized water reactor fuel in CANDU®
butt weld inspection requirements for, 72examination methods, 72inspection of, 81, 83MSIP applied to PWR vessel nozzle, 83weld overlays,
Distribution pipeline, DMW. See Dissimilar metal weld.DN. See Nominal diameter.DnV. See Det Norske Veritas.
DOC. See Decommissioning Operations Contractor.Documentation
justification of solutions adopted for ESRs, 147material certification of pressure equipment, 143
DOD. See United States Department of Defense.DOE. See United States Department of Energy.DOE/OCRWM. See United States Department of Energy, Office of
Civilian Radioactive Waste Management.Donnell’s formula for cylindrical shells, 262–263DOT. See United States Department of Transportation.Double containment rule
for plutonium, 344for plutonium, proposed rule elimination (1997), 349–352for plutonium, rule elimination (1998), 349–350for plutonium vitrified high level waste, elimination (1998 final
rule), 349–350DP. See Decommissioning Plan.DPFAD. See Deformation plasticity failure assessment diagram.DTF. See Decommissioning trust fund.DTI. See Department of Trade and Industry.Dual-purpose packages, 354–355Ductile cast iron, for metal casks, Japanese codes, 289Ductile collapse, 113Ductile crack extension, 122–123, 124–125Ductile fracture, of pressurized water reactor vessels, 48Ductile overload, 113Ductile tearing, 125–126Ductility
of pressure equipment, 143, 156temperature and, 50
Dugdale elastic plastic strip yield model, 398DUPIC. See Direct use of spent pressurized water reactor fuel in
CANDU®.Dupont, E.I., Savannah River Plant, 425Dye penetrant testing, 72Dynamic/arrest fracture toughness, crack propagation and, 51Dynamic crack, 53Dynamic crush test, 353. See also Crush test.
of Type B radioactive material packages, 342, 345, 355Dynamic loads
crack propagation and, 51of transport tanks, 357–359, 365, 366, 368
Dynamic load test, bend of pipe, 297
EA. See Environmental Assessment.EAF. See Environmentally assisted fatigue evaluation.EAM. See European Approval of Materials.Earthquake(s)
Earthquake loads, public health risk, 14, 90EC. See European Commission.Economic and Social Council of the United Nations, 333ECP. See Electrochemical corrosion potential.Eddy current inspection/examination, CANDU® nuclear power plant
components, 177French codes, 252as surface examination, 72of wetted surface of each J-groove weld and RPV head penetration
nozzle, 72zirconium alloy components, 170–171
EDF. See Electricit È de France.
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COMPANION GUIDE TO THE ASME BOILER & PRESSURE VESSEL CODE • 703
EDM. See Electrodischarge machining.EDYs. See Effective degradation years.Effective crack size, 113Effective degradation Years (EDYs), 72“Effective” fatigue life correction factor, 37Effective flaw depth, 120Effective full-power years (EFPY), 72Effective stress intensity factor, 120Efficiency diagram method, 236, 237EFPY. See Effective full-power years.EFR. See European Fast Reactor studies.EGIG. See European Gas Pipeline Incident Data Group.EJMA (Expansion Joint Manufacturers Association, Inc.) Standard,
Elastic stress analysismethods for design analysis of concrete containment vessels, 287–288nuclear pressure vessels, PD 5500 (U.K.), 309
Elastic stress intensity factor for an effective crack size, 115Elastomer degradation, age evaluation, 33Elastoplastic analysis, French pressure equipment, 243, 251Electrical codes and standards, Canadian standards, 163Electrical equipment, New Approach Directive, 145Electrical equipment, nuclear power plant, environmental
qualifications, 31, 34Electric Power Research Institute (EPRI), 22
categorizing systems and components for inservice inspection (ISI)programs, 100
conditions causing high boric acid corrosion, 74, 75evaluation of draft radiation embrittlement trend equations, 54NPV economic modeling software developed, 84pipe cracking in BWRs, 17piping reliability study, 294primary water stress corrosion cracking causal testing, 68probable rate of corrosion of low-alloy steel by boric acid, 74researching effect of zinc on crack growth, 80risk-informed inservice testing, pilot program for snubbers, 100testing mechanical remedial measures for PWSCC of alloy 600
nozzles, 83weld overlay repair studies, 18white paper (Reactor Vessel Integrity Requirements for Levels A
and B conditions), 46Electric Power Research Institute (EPRI) Boric Acid Corrosion
Guidebook, 74Electric Power Research Institute (EPRI) Ductile Fracture Handbook, 48Electric Power Research Institute (EPRI)/General Electric (GE)
project, 21, 22, 24Electric Power Research Institute (EPRI) J estimation scheme, 114Electric Power Research Institute (EPRI) Materials Reliability
Program (MRP)
Reactor Internals Issue Task Group (RI-ITG), 57, 59Electric Power Research Institute (EPRI) Nondestructive (NDE)
Center, 72Electric Power Research Institute (EPRI) Piping and Fitting
Reliability Program (PFDRP), 295, 296, 298Electric Power Research Institute (EPRI) Pressurized Water Reactor
(PWR) Primary Water Chemistry Guidelines, 82Electric Power Research Institute (EPRI) Reports, 115
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measure for PWSCC, 83Electroless nickel plating, as remedial measure for PWSCC, 83Electrolytic plating, French codes, 253Electromagnetic compatibility, New Approach Directive, 145Electro mechanical nickel brush plating, as remedial measure for
PWSCC, 83Electroslag, 15–16Elevated temperatures
boilers, French codes, 237concrete containment vessels, 287conformance of pressure equipment, 148fast breeder reactors, French codes, 250Japanese fast breeder reactor, 275pressure equipment conformance, 143–144, 149
Elongation after rupture, in pressure equipment, 157, 311Embrittlement, 50–51, 57Embrittlement trend curve prediction, 43, 54–55Emergency/faulted conditions, structural factor, 118Emergency Operating Procedures (EOP), 100Emergency responders, 352EN. See Euro Norm.Enbridge Pipeline, 388End fittings, 164–165, 174, 177Energy release rate, 114Energy Resource and Development Agency (ERDA), 334Enhanced immersion test, 323Enquiry Case, 311Envelope defect, 245Environmental effects
causing PWSCC, 66–68, 77–78concrete casks, Japanese codes, 290concrete containment vessels, Japanese codes, 287on fatigue life, 39fuel-handling equipment, CANDU® nuclear power plants, 176on high-CUF components, 37to initiate PWSCC in PWR, 76Japanese codes, 276pipeline systems, 372–374of reactor coolant on components, 34–35, 37seismic design, Japanese codes, 290, 294–296, 298water and fatigue of pressure vessels, 212
Environmentally assisted fatigue (EAF) evaluation, 35, 37Environmental Standard Review Plan, 31EOP. See Emergency Operating Procedure.EPA. See United States Environmental Protection Agency.EPFM. See Elastic-plastic fracture mechanics.EPR studies (project), 23, 193, 228, 245, 247
ETC-M (Paper 2488), 253EPRG. See European Pipeline Research Group.EPRI. See Electric Power Research Institute.EPU. See Extended power uprate.Equivalency recommendation, 393Equivalent flat-bottom hole criteria, 249
Equivalent margin, review summary, 16Equivalent margin analysis, 15–16ERDA. See Energy Resource and Development Agency.Erosion
of pressure equipment, 153provision for, 102
Erosion/corrosion, fuel channel feeder pipes, 183ES&H. See Environment, safety, and health.ESRs. See Essential safety requirements.Essential safety requirements (ESRs), 129–130, 142–144, 147
556, 558Annexes B and C, 326Annex G, 329, 330Annex J, 329
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COMPANION GUIDE TO THE ASME BOILER & PRESSURE VESSEL CODE • 705
Annex K, 329Annex Z, 325
EN 13445-2, 326EN 13445-3, 208, 312, 326EN 13480 (European Harmonized Standard for Piping), 142, 209,
556EN 15614-1 (Procedure Testing for Steels), 148EN 29001, 253EN 45004, 138, 570EN 45012, 138EN ISO 3452-2 (Testing of Penetrant Materials), 249EN ISO 6506 1-2-3, 249EN ISO 6507 1-2-3 test, 249EN ISO 6508 1-2-3, 249EN ISO 9000, 136, 137, 228, 253, 538EN ISO 9001, 554, 555EN ISO 9606-4, 248EN NF 287-1, 248, 554, 555EN NF 288-1, 554, 555EN NF 288-3, 212, 222EN NF 10028-2 (Pressure Vessel Steels), 236NF EN 1591, 216NF EN 9606-4, 248
European Approval of Materials (EAM), 139, 142–144, 148, 310European Parliament and Council, 131, 563European Network for Inspection Qualification (ENIQ)519, 520, 524,
536, 593chairing Working Group Pressure Standing Committee, 144Guiding Principles issued by, 142Web site, 130
European Commission (EC) Declaration of Conformity, 133, 144European Commission (EC) Design Examination Certificate, 136,
137European Commission (EC) Type Examination Certificate, 136, 557European Commission (EC) unit verification, 136European consortium of gas pipeline companies (GERG), 417European Court, legal authority for implementing PED Guidelines,
144European Data Sheet, 310EU 6th Framework Programmes, 582European Fast Reactor (EFR) studies, 193European Federations, represented in Working Group Pressure
Standing Committee, 144European Gas Pipeline Incident Data Group (EGIG), 372European Pipeline Research Group (EPRG), 397European Union (EU), 129–131, 133, 138, 148, 149, 310, 545, 553
New Approach concept, 129Examination categories, specific types
B-A (Vessel Welds), 6, 96–98B-D (Full Penetration Welded Nozzles in Vessels), 10, 11, 673B-F (Pressure-Retaining Dissimilar Metal Welds in Vessel
Nozzles), 72, 96–98, 572, 573B-J (Pressure-Retaining Welds in Piping), 94–98, 573B-N-1 (Interior of Reactor Vessel), 72B-N-2 (Core Support Structures), 1B-N-3 (Removable Core Support Structures), 60B-O (Control Rod Housing Welds), 72B-P (Pressure Retaining Components), 72, 98C-F-1, 96, 97, 98C-F-2, 96, 97, 98
Executive Summary of the Reactor Safety Study, 89Expansion bellows
EN 13445 standard, 329French code design rules, 206–208
Expansion joints, 131, 216, 226, 262–264, 267Explosive atmospheres, equipment and protective systems, New
Approach Directive, 146Explosives for civil uses, New Approach Directive, 145Extended operation
existing nuclear facilities, 679age management programs (AMPs) and, 58, 59license renewal application for, 29, 57standards to evaluate programs, 41
Extended power uprate (EPU), 6External events, 91, 104
probabilistic risk assessment for treatment of, 105
FabricationCANDU® nuclear power plants, 174failure due to defects in, 102industrial piping, French codes, 228–229inspections, Canadian standards, 169pressure equipment, EN 13445, 330pressure vessels, French codes, 206–208shipping containers for radioactive materials, 347transport tanks, 358, 365
FAC. See Flow-assisted corrosion.Factor MF, 122FAD. See Failure assessment program.Failure analysis, 69, 96, 264, 265Failure Assessment Diagram Procedure, 121Failure Assessment Program (FAD), two-criteria (CEGB), 117Failure modes
pipeline systems, 374pressure vessels, PD 5500 (U.K.) (EN 13445), 326
Fatigue crack growth, 24in boiling water reactor jet pumps, 4–5vessel-to-shroud support weld, 14
Fatigue crack growth analysisevaluation methods, 5–6reference curves: austenitic stainless steels in air environment, 21reference curves: austenitic stainless steels in water environment,
21–22
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706 • Index
reference curves: ferritic stainless steels in air environment, 22reference curves: ferritic stainless steels in water environment, 22
FAVOR Code, pressurized thermal shock events, 56FBE. See Fusion bonded epoxy coatings.FBR. See Fast breeder reactor.Federal Aviation Act of 1958, 339Federal Aviation Administration, 339Federal Aviation Agency, 336–337Federal Aviation Regulations, 339Federal Highway Agency, corrosion costs and effects study in U.S.,
407Federal Register. See United States Nuclear Regulatory Commission
(USNRC) Federal Register(FR).Feedwater nozzle, 8–9, 11–12, 24Feedwater System (FWS), 99Ferrite content, French tests for, 249Ferritic-austenitic stainless steels, for industrial piping, French codes,
203Fiber-optic sensors, 417
50 ft.-lb. regulatory requirements, 121Fillet weld, 322Filling stations, Canadian standards, 168Film/rupture model, 23Film thickness measurement, coatings and liners of CANDU®
nuclear power plant components, 186Filters, in scope of PED, 131Final assessment/inspection, of pressure equipment, 154Final safety analysis report (FSAR), 30, 32–33, 58–59, 539Financial planning, for decommissioning, Fine-grained steels
allowable membrane stress, 144for industrial piping, French codes, 212
in pressure equipment, 157for pressure equipment, French codes, 223–224
Fired-heater pressure coils, 168, 170Fired or otherwise heated equipment, categorization, 134Fired pressure vessels, 157Firetube boilers, French codes, 217, 222, 236. See also COVAP.Fissile Classes, 336–338Fissile Class I, 338Fissile Class II, 336, 337Fissile Class III, 336, 337Fissile material, 335–338, 341,–342, 344, 347, 349–350, 352–354, 356Fissile-to-nonfissile mass ratio, 354Fitness-for-service code (Japanese Nuclear Safety), 276–281Fitness-for-service demonstrations, of pressurized water reactor
vessel internals, 59FIV. See Flow-induced vibration.Ferritic steels
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COMPANION GUIDE TO THE ASME BOILER & PRESSURE VESSEL CODE • 707
reactor vessel lower closure, use of alloy 600, 63–66welded to alloy 600 nozzle, 65, 72, 82, 83
Flapper wheel surface polishing, as remedial measure for PWSCC,83
Flaring test, French codes, 249Flat ends, EN 13445 standard, 329Flat plates and covers, for pressure equipment, PD 5500 (U.K.), 317Flattening test, French codes, 249Flaw (crack)
Flux welds, failure mechanism, 118FMP. See Fatigue monitoring program.Folias factor M (MT), 396, 398, 401, 402“For a Use of Nuclear Energy in 21st Century of Japan”, 257Foreign national competent authority, 342, 343
Forge welding, 365Forgings, European standards, 236Form NIS-2 (Owner’s Report for Repair/Replacement Activity), 102,
541, 543Forms, sample, Canadian standards (Annex D), 163Form X, 311FR. See United States Nuclear Regulatory Commission (USNRC)
Federal Register.Fracture, as pipeline failure mode, 374Fracture design analysis, based on J integral, 114Fracture design handbook, 114Fracture mechanics analysis, 8, 9, 55, 400, 592, 646
for crack growth due to IASCC, 60flaw tolerance evaluation, 9for loss of toughness due to irradiation, 60plant-specific, 9of pressurized water reactor vessels, 45
determining median, 53of ferritic steel, 53, 348French codes, restrictions, 230irradiation and, 1–3, 45, 57, 59, 60in light-water reactors, 45lower bound curves, 52–54Master Curve approach, 43, 53, 581, 583monitoring changes in, 45of nuclear pressure vessel steels, 114pressure vessels, Japanese codes, 281protection against pressurized thermal shocks, 33reduction in, due to aging, 57static loading and, 51temperature dependent, 50testing, 53transition temperature, 44, 53
Fracture toughness curve index, 44Fracture toughness curves, referenced, 50–53Framatome-ANP, 677Framatome-EDF teams, 194Freeze plugging, 405French association of design, construction, and inservice inspection
rules for nuclear island components (AFCEN), 191, 193–197,246
working groups, 197French codes dealing with pressure equipment, 191
Annex FA 1 (Permissible welded joints), 205design, 193Figure 49.1 (CODAP Committee Structures), 192Figure 49.2 (Initial Pragmatic Approach for Establishing RCC-M),
193Figure 49.3 (Organization of French Nuclear Codes), 194Figure 49.4 (AFCEN Structure), 195Figure 49.5 (Structure of Subsections of RCC-M and Relations
among Sections), 196Figure 49.6 (Hazard Category Determination of a Vessel
Containing Dangerous Gas), 199Figure 49.7 (Hazard Category Determination for Piping
Containing a Dangerous Gas), 218Figure 49.8 (Installation of Expansion Joints (Extracted from
Annex C3.A3)), 226
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244Table 49.44 (Correspondence among RCC-M B 3200, B 3500, and
B 3600 Criteria), 246Table 49.45 (RCC-MR Technical Appendices), 250Table 49.46 (RSE-M Appendices), 252testing and inspection, 216
French Association of Pump Manufacturers, 246French-German ETC-M rule, 253French 1984 Order on Quality, 253French Pressure Vessel Regulation, 254French Safety Authority, 193
French Standardization Organization (AFNOR-Association Françaisede Normalisation), 192
AFNOR/SNCT Codes, 195French Standard Series NF E 32-100, 217French transposing regulations, Decree 99-1046, 222FSAR. See Final safety analysis report.Fuel bundle design, 163Fuel channels, 174Fuel cladding, 164Fuel deposit, reduction in, 83Fuel fabrication plants, 343Fuel reprocessing, 343Full penetration welds, 52Functionality analysis, as aging management strategy, 60Fuse holder, age management program (AMP), 39Fusion bonded epoxy (FBE) coatings, for pipeline systems, 410Fussell-Vesely (FV), 106FV. See Fussell-Vesely.FWS. See Feedwater System.
Gadolinium-159, 475GALL Report. See Generic Aging Lessons Learned Report.Galvanic corrosion
age evaluation, 33as pipeline failure mode, 374pressure equipment conformance, 143
GAO. See Government Accounting Office reports.Gas, in sense of PED, 133Gas distribution systems, Canadian standards, 171Gaskets, 131Gas pipeline systems, 170Gas Research Institute (GRI), 395Gas tungsten arc welding (GTAW), 18Gas Utility Industry Law, 258Gathering system, definition, 372
French codes dealing with pressure equipment (continued)
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COMPANION GUIDE TO THE ASME BOILER & PRESSURE VESSEL CODE • 709
GE. See General Electric.GEIS. See Generic Environmental Impact Statement.General corrosion, as pipeline failure mode, 407General Electric (GE), 27
Pipeline Solutions, 388General Electric (GE) Reports
Generic Environmental Impact Statement (GEIS) for LicenseRenewal of Nuclear Plants, 31
Geographic information systems (GIS), database, 379Geometry (deformation, caliper or band pigs), for pipeline system
assessment, 391Geotechnical issues, causing pipeline incidents, 373GERG. See European consortium of gas pipeline companies.German KTA provisions, 193Girth weld, 17, 49GIS. See Geographic information systems. GL. See United States
Nuclear Regulatory Commission (USNRC) Generic Letter.Glass, structural factors, 125Gouges, in pipeline systems, assessment, 396–397Grain size, French codes, 249Grandfather clauses, radioactive material packaging, 340
for special form radioactive material encapsulation, 340TS-R-1 provisions, 349–353, 355
GRI. See Gas Research Institute.Grinding, for removal of surface flaws, 80Ground storage vessels, compressed natural gas, Canadian standards,
168, 170Group 1 gas, 133Group 2 gas, 133Group VII transport group, 340GTAW. See Gas tungsten arc welding.Guidance Documents, 333Guiding Principles, 142Half-pipe coils, 318Hanford and West Valley, 434Hardness testing
CANDU® nuclear power plant components, 181French codes, 253
Harmonized European Product Standard, 139Harmonized standards, 129, 137–142, 147, 150
Annex Z, 147definition, 150
Hazard analysis, 140Hazard categories
boilers, French codes, 208, 212, 217, 222–224industrial piping, French codes, 191
Hazard classes, transport tanks, 358Hazard identification, 138Hazardous material, 340
disposal of, 438Hazardous Materials Regulations of the Department of
French codes, 253of pressure equipment, 138, 141of pressure vessels, Japanese codes, 257–261, 263
Heatup/cooldown limit curves, for pressurized water reactors, 43, 49–51High alloy steels, 360, 365
for pressure vessels, Japanese codes, 259High consequence areas (HCAs), of pipeline rupture, 375High consequence assessment, 100High cycle fatigue, 6, 245High-fatigue lines, limiting welds, 38High-level requirements (HLR), PRA Standards, 93
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710 • Index
High-level waste (HLW) borosilicate glass, 349, 356High-level waste (HLW) containing plutonium, 349, 355–356High Level Waste (HLW) Packages, 355High-pressure cylinders, for on-board storage of natural gas fuel for
automobiles, Canadian standards, 168High-pressure gases, definition, Japanese codes, 260High-Pressure Gas Safety Law (HPGSL), 258, 260High Pressure Institute of Japan, 271High-pressure polyethylene units, reactors for, 261High-safety significant (HSS) components, 90, 96High-strength steels, for pressure equipment, PD 5500 (U.K.), 312High temperature gas-cooled reactors (HTGR), 505–506High-yield strength steels, 224HLR. See High-level requirements.HLW. See High-level waste.HMR. See United States Hazardous Materials Regulations.HMTA. See Hazardous Material Transportation Act of 1990.Holiday, pipeline systems, 395Homeland security, risk-informed methods for protection, 89Homeland Security Act of 2002, 420Hoop stress, 67, 315, 402
pipeline systems, 413Hopper diagram, 324Hot cell test, 60Hot cracks, as PWSCC initiators, 67Hot isostatic pressing unit, 261Hot-leg nozzle, weld overlay repair, 81Hot-leg pipe, 69Hot leg welds, 72Hot-water boilers, 156
New Approach Directive, 144Hot-water generators, 156Hot-water tanks, Canadian standards, 169HP. See Health physics.HPGSL. See High-Pressure Gas Safety Law. HRC test, 249HSA. See Historical Site Assessment.HSS. See High-safety significant segments.HSW. See Heat-sink welding.HTGR. See High temperature gas-cooled reactor.Human factors, 104Human reliability analysis, 93Hungary’s sole Nuclear Power Plant 589Hungarian Atomic Energy Authority (HAEA).589Hungarian regulatory rules 590–591HV 10 for welds test, 249HV test, 249HWC. See Hydrogen water chemistries. H/X. See Hydrogen to fissile
material atomic ratio.Hybrid containment vessels, Japanese codes, 288Hydraulic pressure test
crack growth rate and concentration, 67–68pressurized water reactor primary coolant concentration, 85refrigerated, hazard class, 358use in dissimilar metal weld overlays, 19
Hydrogen cyanide, liquefied, 260Hydrogen-induced cracking, 140Hydrogen to fissile material atomic ratio (H/X), 335Hydrogen water chemistries (HWC), 3, 17Hydropneumatic tanks, Canadian standards, 169Hydrostatic pressure, PWR test limits, 45, 103, 155
CANDU® nuclear power plant components, 184in pressure equipment, 157pressure vessels, Japanese codes, 263
Hydrostatic testing, 45, See also Hydro testing.detecting PWSCC, 69pipeline systems, 376, 393transport tanks, 366
Hypothetical accident conditions, radioactive material incidents, 336,338, 341
Hypothetical Accident Condition test, 339nHysteresis tests, piping, Japanese codes, 296
IAEA. See International Atomic Energy Agency.IASCC. See Irradiation-assisted stress corrosion cracking.IATA. See International Air Transport Association.ICAO. See International Civil Aviation Organization.ICC. See Interstate Commerce Commission.ICDA. See Internal corrosion direct assessment.ICI. See Incore instrument nozzle.ICRP. See International Commission on Radiological Protection.ID. See Inside diameter examination.Idaho National Engineering Laboratory (INEL) Oversight Program,
506IDCOR. See Industry Degraded Core Rulemaking program.Identification, for Canadian standards, for pressure
equipment, 169IDP. See Integrated decision-making panel.IEC. See International Electrotechnical Commission.IEC. See International Energy Consultants, Inc.IEEE. See Institute of Electrical and Electronics Engineers.IGSCC. See Intergranular stress corrosion cracking.Inhibitors, for pipeline systems, 416IHSI. See Induction heating stress improvement.ILI. See In-line inspection.Immersion tests, of radioactive material packaging, 416Immersion-type electrically heated boilers, 156IMP. See Integrity management plan.Impact limiters, 345Impact resistance, pressure equipment conformance, 141–142Impact strength, pressure equipment conformance, 149 Impact testing, 144
French codes, 253pressure vessels, Canadian standards, 169pressure vessels, Japanese codes, 263–264, 266radioactive material packaging, 292, 350–356transport tanks, 365
Imperfection, RCC-MR code, 251Inaugural inspection, CANDU® nuclear power plant components, 182INCO. See International Nickel Corporation.Inconel alloys, 17, 63, 85. See also Nickel alloys, specific types;
Nickel-chromium alloys; Weld metals, specific types.Incore instrument (ICI) nozzles, 65
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COMPANION GUIDE TO THE ASME BOILER & PRESSURE VESSEL CODE • 711
Incremental collapseboilers, French codes, 222industrial piping, French codes, 209pressure vessels, 200
Indirect assessment, pipeline systems, 380, 386 Indian phwr 635Industrial code in korea:korea electric power industry code (kepic)
674Individual plant examination (IPE), for severe accident
as remedial measure for IGSCC in boiling water reactors, 83Industrial hazards, Japanese codes and standards
preventing, 259Industrial piping
buried, French codes, 216, 228design, French codes, 213, 216, 221–222failure modes, 212French codes (CODETI), 197–198, 212, 218, 220materials, French codes, 216, 222nominal design stress, French codes, 213, 221risk assessment, French codes, 212in scope of PED, 147
Industrial Safety and Health Law, 267Industry Degraded Core Rulemaking (IDCOR) program, 89INEL. See Idaho National Engineering Laboratory. INGAA. See Interstate Natural Gas Association.Initiating event impact group assessment, 95Inlet/outlet nozzles
primary water stress corrosion cracking in, 79projected repair weld cracking, 81
In-line inspection (ILI), of pipeline systems, 374, 378, 387, 401Inside diameter (ID) examination, of boiling water reactors, 7Inservice inspection (ISI), 110
access problems, 7as aging management strategy, 60of boiling water reactor jet pump, 10CANDU® nuclear power plants, 171code, 108and crack growth rate monitoring, 24French codes, 253French pressure equipment, 252Frequency/coverage, 59implementation, 95Japanese codes, 257–259nuclear boiler and pressure vessels, Canadian, 181as part of age management program (AMP), 57of piping, 108plant-specific, risk-informed decision-making, 103, 106of pressure-retaining RPV shell welds, 6–7, 9of pressurized water reactor nozzles, 10primary water stress corrosion cracking detection, 79probabilistic risk assessment, 111of reactor pressure vessel axial shell welds, 8of reactor pressure vessel nozzles, 11of reactor pressure vessel-to-shroud support plate weld, 13for reactor vessel nozzles, 11risk-informed (RI-IST), 90–92, 94–96, 98–112of small bore piping, 39transport tanks, 358–359, 366, 368
Inservice Inspection Rules for Mechanical Components of PWRNuclear Islands (RSE-M), 254–255
Inspectionof boilers, French codes, 217, 222–224of boiling water reactors, 10Canadian requirements, 170effects on probability of crack growth leakage to failure, 79French codes, 253improved capability by using weld overlay repair, 81industrial piping, French codes, 191nuclear boilers and pressure vessels, Canadian, 181of nuclear reactor vessels, 86PD 5500 (U.K.), 319pressure equipment, EN 13445, 331pressure vessels, French codes, 205transport tanks, 365–366
Inspection frequencyfeedwater nozzle, 9future Section XI changes, 94
Inspection interval, 13, 96alternate inspection frequency, 11CANDU® nuclear power plants, 184–185for feedwater nozzle/sparger, 10for high susceptibility plants, 73for low susceptibility plants, 73for moderate susceptibility plants, 73and probability of leakage from a top-head nozzle, 79–80socket welds, 95
boiling water reactor issue, 10initiation and propagation, 17, 66inservice (ISI) inspection program for, 94piping, cracking conditions, 16–18piping, remedial measures, 17, 82
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712 • Index
repair/replacement/mitigation of, 17stainless steel for resistance to, 4stub tube, 12weld overlay repair, 18, 81
349–353, 355–35610CFR71 (1988 proposed changes), 347–348guidance documents, 42labeling system for radioactive materials, 339no double-containment requirement, 355revision cycle of two years, 355Safety Series No. 6 (‘Regulations for the Safe Transport of
Radioactive Materials’), 338, 350, 352–353, 356Safety Series No. 6 (Cross Index to Present and Proposed
Regulations), 338 Appendix II, 543 Appendix I, 180 TS-G-1.1 (Advisory Material for the Regulations for the Safe
Transport of Radioactive Material), 338, 341TS-R-1 (ST-1) standard, 349, 350–353, 355–356Appendix A, 351
International Atomic Energy Agency certificate, 342 International Civil Aviation Organization (ICAO), 353International Conference on Nuclear Engineering (8th), Proceedings,
ICONE-8, 26International Congress on Advances in Nuclear Power Plants,
Proceedings, ICAPP03, 25International Electrotechnical Commission (IEC), Canadian
participation, 160International Energy Consultants, Inc. (IEC), 349International Nickel Corporation (INCO), 63International Organization for Standardization (ISO), 162
Canadian participation, 160special form radioactive materials, 335
International Organization for Standardization (ISO) Registrar, 160, 162
International Organization for Standardization (ISO) standards, specific types
7195 (Packaging of Uranium Hexafluoride for Transport), 3519000 (Quality Assurance Rules of French Codes), 228, 9001 (Quality Control Program), 16911439: 2000 (Gas Cylinders—High-Pressure Cylinders for
On-Board Storage of Natural Gas for Automobiles), 17017020, 138/DIS 2694 (International Pressure Vessel Standard), 309, 312
International System of Units (SI), 350–351International Thermo-Nuclear Experimental Reactor (ITER) Code, 269
Committee, 269project, 269
International Trade and Industry Ministerial Ordinance 51 (MITI MO 51), 270
International Trade and Industry Ministerial Ordinance 123 (MITIMO 123), 271–272
International Trade and Industry Ministry, Notification 501, 272–273 Interstate Commerce Commission (ICC), 334–338, 340–341
Interstate Commerce Commission (ICC) Regulations, 338Interstate Natural Gas Association (INGAA), 420 Iodine-131, 437Iodine-133, 478IPA. See Integrated plant assessment. IPE. See Individual plant examination. IPEEE. See Individual plant examination of external events.Iron castings, for pressure equipment, French codes, 252Irradiated fatigue curves, 174Irradiated metals, risk of piping failure and, 124Irradiated steels, 5, 44–45, 50Irradiation, 1–3
loss of toughness due to, 60personnel exposure, 13shift in nil ductility, reference temperature due to, 51
Irradiation-assisted stress corrosion cracking (IASCC, 1, 57, 59Irradiation embrittlement, 15, 45, 126as aging mechanism, 57Irradiation-enhanced stress relaxation, as aging mechanism, 59Irradiation-induced void swelling, as aging mechanism, 59Irwin plastic zone correction, 113ISG. See Instrument selection guide. ISG. See Interim staff guidance. ISI. See Inservice inspection. ISMS. See Integrated safety management system.ISO. See International Organization for Standardization.IST. See Inservice testing. ITER. See International Thermo-Nuclear Experimental Reactor.
Jacketed vessels, as pressure equipment, PD 5500 (U.K.), 318 JAERI. See Japan Atomic Energy Research Institute. James A. Fitzpatrick nuclear power plant, 97Japan Atomic Energy Research Institute (IAERI), 291Japan Electrical Association (JEA), 294
Technical Guidelines for Seismic Design of Nuclear Power Plant,294
Supplement (1984), 294–295Japan Electrical Association Code (JEAC 4205-2000), 294Japan Electrotechnical Standards and Codes Committee (JESC), 271Japanese boiler and pressure vessel codes and standards, 259
class 1 components, flaw evaluation, 246class 2 components, 247class 3 components, 247Figure 50.1 (Laws/JIS under the Mandatory Laws [Pressure Vessel
Standards]), 266Figure 50.2 (Organization of JSME Committee on Power
Generation Facilities Codes), 269Figure 50.3 (JSME Design and Construction Code Structure), 273Figure 50.4 (Plastic Analysis Results for Nuclear Power Plant
Components), 274Figure 50.5 (JSME Fitness-for-Service Code Structure), 276Figure 50.6 (Flow Chart of Rules on Inspection and Flaw
Evaluation), 277 Figure 50.7 (Flow Chart to Determine the Extent of Ultrasonic Test
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COMPANION GUIDE TO THE ASME BOILER & PRESSURE VESSEL CODE • 713
Figure 50.8 (Extent of Examination and Inspection Period,Determination of), 279
Figure 50.10 (Flow of Flaw Evaluation), 280 Figure 50.11 (Flaw Evaluation Procedure for Ferritic Vessel), 282 Figure 50.12 (Fracture Evaluation Method Selection for Pipe), 283Figure 50.13 (Relation Between Design/Construction Codes and
Welding Codes), 284Figure 50.14 (Test Apparatus Sketches [Testing of Bend in Pipe]), 297 nuclear power plant components, 268 nuclear-specific material specifications, 286 seismic design codes, 290Table 50.1 (Suggested Codes), 258 Table 50.2 (Publication of JIS on Construction of Pressure Vessel),
267 Table 50.3 (Publication of JSME Committee on Power Generation
Facility Codes), 270 Table 50.4 (Comparison Between MO 51 and JSME Code on
Power Boilers), 271 Table 50.5 (Comparison Between MO 123 and JSME Code on
Power Boilers), 272 Table 50.6 (Ultrasonic Examination in the JSME FFS Code), 278Table 50.7 (Loads Posed on Concrete Portions), 288 Table 50.8 (Classification of Major ITER Components), 293 Table 50.9 (ITER Metallic Components, Requirements and
Technical Rules), 294 Table 50.10 (Technical Guidelines for a Seismic Design of Nuclear
Power Plant Allowable Stress of Piping), 296 Table 50.11 (Philosophy for the Future Revision of the Piping
G 3106-1999, 262, 264 G 3114-1998, 264G 3115-2000, 264G 3126-2000, 264 Z 3014 (Radiographic Testing and Classification of Steel Welds),
263–264Z 3801-1997 (Qualification Procedure for Manual Welding
Technique), 263–264Z 3805-1997 (Welding Technique of Titanium), 264 Z 3811-2000 (Welding Technique of Aluminum and Aluminum
Alloys), 264Z 3821-2001 (Welding Technique of Stainless Steel), 264 Z 3841-1997 (Semiautomatic Welding Procedure), 264
Japan Maintenance Standard, 22–23Japan Power Engineering and Inspection Cooperation (JAPEIC),
fitness-for-service code, 280Japan Society of Mechanical Engineers (JSME), 258
code and rule endorsement by government, 258Codes Committee, 258Committee on Power Generation Facilities Codes, 268–269Concrete Containment Vessel Code, 287 Design and Construction Rules, 268–270, 272–273 Guideline on the Approval of new Materials (Nuclear Materials
Code), 286Nuclear Materials Code Appendix 1, 286 Power Generation Facility Codes, 268–270, 272, 276 Rules on Concrete Casks, Canister Transfer Machines, Canister
Transport Casks for Nuclear Fuel, 289–290 Rules on Concrete Containment Vessels for Nuclear Power Plants,
287 Rules on Construction of Nuclear Power Plant Components, 286 “Rules on Design and Construction for Nuclear Power Plants”,
268, 270, 272 Rules on Design and Construction for Thermal Power Generation
Facilities, 286 Rules on Fitness-for-Service for Nuclear Power Plants (2000), 268Rules on Materials for Nuclear Use, 287 Rules on Metal Casks, 289 Rules on Nuclear Design and Construction, 269 Rules on Nuclear Power Generation Facilities, 268 Rules on Thermal Power Generation Facilities, 268, 270, 286 Rules on Transportation/Storage Packaging for Spent Nuclear
Fuel, 269Subcommittee on Fusion Power Generation Facilities, 268 Subcommittee on Fusion Reactors, 291–292 Subcommittee on Nuclear Codes, 276 Subcommittee on Nuclear Power Generation Facilities, 268, 276 Subcommittee on Thermal Power Generation Facilities (SC-TP),
268–269Subgroup on Environmental Fatigue, 275 Subgroup on Materials (SG-M), 270 Subgroup on Structures Design (SG-SD), 270 Subgroup on Welding (SG-W), 270
thermal and nuclear plant component codes, 268Welding Technical Standard, 281–282
Japan Society of Nondestructive Inspection, 267Japan Standard Association, 268JAPEIC. See Japan Power Engineering and Inspection Cooperation. J applied, evaluation procedure for calculation, 122J-controlled crack growth, 115JEA. See Japan Electrical Association.JEAC. See Japan Electrical Association Code.
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714 • Index
JESC. See Japan Electric Standards Committee.Jet pump, 4
boiling water reactor internals, 10 J-groove welds, 65
materials for pressure equipment, 212Joining procedures qualifications, of pressure equipment, 140 Joint coefficients, 139
French codes, 253in pressure equipment, 157
Joint efficiency, pressure vessels, Japanese codes, 262Joint efficiency factor, 312Joints
for boilers, testing, French codes, 224bolted flanged, PD 5500 (U.K.), 316brazed, 140French codes, 253lattice tube-to-calandria tubesheet, 175mechanical, French codes, 248oil and gas pipeline systems, Canadian, 170permanent, 140in pressure equipment, 157pressure vessels, French codes, 205pressure vessels, Japanese codes, 263soldered, for air piping, 170welded joint coefficient, industrial piping, French codes, 222welded, PD 5500 (U.K.), 318
Joint tensile test, pressure vessels, Japanese codes, 264 JR curve, 115J-R curve, 15J-R curve Crack Driving Force Diagram Procedure, 123 J-R curve test, 122JSME. See Japan Society of Mechanical Engineers. J-T. See J-Integral/Tearing Modulus Procedure.
KI, stress intensity factor, 46KIA, reference fracture toughness curve, 53. See also KIR reference
Ke501 factor in Notification 274KeA0, 275Kellogg Company method, 264KHK. See Koatsu Gas Hoan Kyokai.Koatsu Gas Hoan Kyokai (KHK), 260Korean nuclear power plants, surveillance programs, 229Korean regulatory system and codes of nuclear boiler and pressure
vessels 655Korean Ulchin 9–10 project, 193
allowable release limit in a hypothetical accident, 336
Labeling, of pressure equipment, 141Labeling system, for radioactive materials packages, 340Labor cost, of decommissioning a nuclear facility, 460Lamellar iron castings, for pressure equipment, French codes, 252Lame’s equations, 312Large-diameter butt welds, 77Large early release, definition, 91Large early release frequency (LERF), 8
Large quantity, 335“Large quantity”, of licensed material, definition, 335 Large quantity shipments, radioactive materials, 345Laser cladding, 83Laser weld repair, 83Last-pass heat sink welding (LPHSW), 17LBB. See Leak-before-break analysis. LCM. See Life cycle
management. LDM. See Low Dispersible Material.Lead-201, allowable release limit in a hypothetical accident, 348 Lead shielding, 345 Leakage, 9
boiling water reactor stub tube cracking, 12boric acid, 69bottom-head nozzles PWSCC crack in, 70from control rod drive housing, 26from CRDM nozzle PWSCC, 87radioactive soil and water remediation, 486probabilistic analysis to determine PWSCC behavior in alloys
600/82/182, 70top head, from flange gaskets, 73
Leak-before-break (LBB) analysis, 9of CANDU® nuclear power plants, 170fast breeder reactors, French codes, 250French pressure equipment, 252fusion reactors, 292
Leak testing (LT), 45of boiling water reactor components, 45of CANDU® nuclear power plants, 185French codes, 253pressure vessels, Japanese codes, 263of pressurized water reactor components, 263risk-informed initiatives, 45as Section XI provision, 45
Leak tightness, 329of radioactive material packaging, 356
Leckie/Penny calculation, 320 Leckie/Penny formulation, 316 LEFM. See Linear-elastic fracture mechanics. LEFM/EPFM. See Linear-elastic fracture mechanics/elastic plastic
fracture mechanics analysis.
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COMPANION GUIDE TO THE ASME BOILER & PRESSURE VESSEL CODE • 715
LER. See Licensee event report. LERF. See Large early release frequency. Level 1 Probabilistic Risk Assessment (PRA), 89 Level 2 Probabilistic Risk Assessment (PRA), 91 Level 3 Probabilistic Risk Assessment (PRA), 110Level of confidence, maximum, 148Levels A, B, C, D. See Service Level A, Service Level B, Service
Level C, Service Level D.LFRD. See Load and Resistance Factor Design methodology. License applications, 336 Licensee event reports (LERs), 30, 32 License-exempt contractors, 342License renewal
age management program and, 58–59aging effects, 57environmental review, 29, 31guidance documents, 29, 40–41requirements, 31TLAA identification/update, 31–32, 34, 35, 38, 41
License renewal application (LRA), 29–35, 37–38, 41, 57aging management program, 30–32, 35, 58aging management review (AMR), 30–32, 57Appendix A (Final Safety Analysis Report Supplement), 32Appendix B (Aging Management Programs and Activities), 32final safety analysis report (FSAR), supplement, 38guide for, 41requirements list, 31reviewing process, 39–40safety assessments for, 30scoping and screening methodology, 31–33Section 2.0 (Identifying Structures/Components Subject to Aging
transfer of responsibilities from DOT to AEC, 341Licensing restrictions, plutonium air transport, 352LIDAR. See Light Detection and Ranging. Life cycle management (LCM) approach, 84Lifting and tiedown device requirements, radioactive materials,
336Lifting attachments, radioactive materials, 338Lifting eyes, 329–330Lifts, New Approach Directive, 147Ligament, evaluation with multiple indications, 3Ligament efficiency factor, 316Light Detection And Ranging (LIDAR), 417Light-water reactor (LWR), 104–105
construction, French codes, 253environment effects on fatigue crack growth rate, 21–22fitness-for-service code, 264monitoring changes in fracture toughness, 45piping systems, flaw evaluation, ferritic piping, 118–119use of alloy 600 base metal, 63
Light-water reactor (LWR) nuclear power plant
inservice testing (IST), 104–105Japanese codes, 257–259PRA Standard for, 90–92, 95, 97RI-IST of check valves, 105
118–119, 124assessing flaws effects on nuclear components, 113evaluation, 124methodology, 114predicting conditions for brittle failure, 55pressure vessels, Japanese codes, 257technique, 113
Linear elastic fracture mechanics/elastic plastic fracture mechanics(LEFM/EPFM) analysis, of irradiated stainless steel fracturetoughness, 3
Linearized stress method, 46–47Line loads, EN 13445 standard, 329–330Liners, 153Ling Ao nuclear power plant, China, 255Ling Ao 1 and 2 contract, 193Linings, 143
pressure vessels, PD 5500 (U.K.), 311Liquefied gases, 170, 260 Liquid, in sense of PED, 138Liquid-injection system (LISS) nozzles, 177Liquid natural gas systems, 159, 168
Canadian standards, 168Liquid penetrant test (PT)/examination, 400
CANDU® nuclear power plant components, 159, 163–167, 171
of feedwater nozzle/sparger, 10French codes, 196, 253pressure vessels, Japanese codes, 257, 264transport tanks, 366for vessel-to-shroud support weld cracking, 13zirconium alloy components, 176–177
Liquids rule, 376LISS. See Liquid-injection system nozzles. Lithium, 68, 82LLS. See Low level solid radioactive material. LLW. See Low level waste. LMFBR reactors, 193Load
pressure vessels, EN 13445 (PD 5500, U.K.), 309–310stress on welds, PD 5500 (U.K.), 309
Load and resistance factor design (LRFD)for concrete components, 108Level 2 analysis, 91methodology, 400reliability based, for piping, 108, 112use for nuclear service concrete components, 108with risk-informed safety classification, 108
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Load capacity ratings, 53Load category system, Japanese codes, 288Load line displacement, 115Load per unit thickness, 115LOCA. See Loss of coolant accident. Local brittle zones, 52Localized corrosion, piping failure, 96Log-normal distributions, in predicting initiation of PWSCC in
PWRs, 76Log-normal model, 76 Log secant model, 398 Longitudinal flaw sizes, piping, 118Longitudinal upper-shelf energy (USE), 15Longitudinal welds, 48Long-lived structures/components, 31–32, 41 Loss of alternating current power, 33Loss of coolant accident (LOCA), 80, 89, 172
Loss of material, from aging, 57Lost production, 84Low-alloy steel, 69
boric acid wastage, 74, 84butt welding, 65–66, 69for containment vessels for radioactive materials, 269corrosion rate by high temperature borated water onto a hot
surface, 74dissimilar metal welds, 19, 72fatigue effects, 13, 21, 69for pressure equipment, French codes, 234for pressure equipment, PD 5500 (U.K.), 311, 325for pressure vessels, Japanese codes, 263–264for reactor coolant piping, 66repair/replacement/mitigation for IGSCC in, 17SCC initiated in cladding, 24for transport tanks, 358, 366weld cracking, 13
Low upper shelf energy (USE) evaluation, 15, 26, 121, 128 Low upper-shelf toughness, 121, 124–126Low voltage directive, 138, 141Low water cut-off, 169LPHSW. See Last-pass heat sink welding. LPSCC. See Low potential stress corrosion cracking. LRA. See License renewal application. LRFD. See Load and resistance factor design. LRG. See License renewal guidance. LSA. See Low specific activity material. LSS. See Low-safety-significance. LT. See Leak testing.LTOP. See Low-temperature overpressure. LTP. See License Termination Plan. LWR. See Light-water reactor.
Machiningfor removal of surface flaws, 81of repair surface for nondestructive examination (NDE), 94
Magnesium-molybdenum-chromium-nickel steels, for industrialpiping, French codes, 223
Magnesium-molybdenum steelsfor industrial piping, French codes, 223, 224for pressure equipment, French codes, 129, 130, 131, 133–141,
Magnetic flux leakage (MFL), 387–388Magnetic particle examination, 248, 263
CANDU® nuclear power plant components, 181French codes, 253pressure vessels, Japanese codes, 263transport tanks, 366
Maintenance, 90Maintenance pigging, 390 Management Board, French codes, 191 Manganese-nickel-molybdenum steels, for pressure equipment,
French codes, 129 Manhole, sizing minimum, 169 Manufacturer. See also Certificate of Conformity.
accreditation by ASME for meeting PED requirements, 149achieving overall level of safety, 138application to Notified Body, 152assembly of pressure equipment, 131conformity assessment categories in PED, 310conformity assessment modules without QA, 136conformity assessment modules with QA, 136conformity assessment of pressure vessels, French codes, 320conformity assessment procedures for pressure equipment, 154data report detailing inspections, for Canadian regulating authority,
181defining testing type and extent, pressure vessels, French codes, 253drawing up technical documentation, 137industrial piping, testing and inspection, French codes, 142, 223inspection of boilers, French codes, 260, 253material specifications of pressure equipment, 141
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COMPANION GUIDE TO THE ASME BOILER & PRESSURE VESSEL CODE • 717
New Approach principles for pressure equipment, 147non-nuclear-specific equipment, French codes, 230PED requirements, 148pressure equipment manufacturing procedures, final assessment,
marking, labeling, and operating instructions, 154product quality assurance, 137responsibility for design manufacture and conformity assessment,
pressure equipment, 144self certification, 136testing definition and extent, boilers, French codes, 224
Manufacturers Standardization Society of the Valves and FittingIndustry (MSS), 162,
MAOP. See Maximum allowable operating pressure. Marine Self Defense Force, 260 Market surveillance, 144 MARSSIM. See Multi-Agency Radioactive Site Survey and
Investigation Manual. Martensitic stainless steel
for containment vessels for radioactive materials, 346for end fitting material, 642for fuel channel end fittings, 177for industrial piping, French codes, 191for pressure equipment, French codes, 212
Master Curve reference fracture toughness, 44, 53Material certification, 143Material fatigue, primary water stress corrosion cracking, 63Material flow stress, 118. See also Stresses.Material manufacturer, of pressure equipment, 139, 153Material reference fracture toughness, 43Material Reliability Program (MRP) (EPRI sponsored), 57
MRP-86 Materials
for boilers, French codes, 224, 253for construction, PED vs. ASME code, 147industrial piping, French codes, 191, 253PD 5500 (U.K.), 311for pressure equipment, 156pressure equipment, Japanese codes, 259for pressure equipment, PD 5500 (U.K.), 264, 311for pressure vessels, French codes, 191, 201transport tanks, 365
Material specifications, of pressure equipment, 141 Material surveillance program, monitoring changes in fracture
toughness, 45Material Tables and Allowable Stress Tables (Japanese codes), 275Material transition temperature, 53MAWP. See Maximum Allowable Working Pressure. Maximum
allowable bending stress, of pressure vessels, Japanese codes, 262
Maximum allowable buckling stress, of pressure vessels, Japanese codes, 262
Maximum allowable longitudinal compressive stress, pressurevessels, Japanese codes, 262
Maximum allowable longitudinal stress, of pressure vessels, Japanese codes, 257
Maximum allowable operating pressure (MAOP), 397 Maximum allowable tensile stress, pressure vessels, Japanese codes, 263 Maximum Allowable Working Pressure (MAWP), 368
of transport tanks, 366Maximum elastic stress, nozzle reinforcement, 316 Maximum membrane stress, 139Maximum normal operating pressure (MNOP), 488
Maximum shear stress theory, 320 Maximum transport index, 351 MC. See Metal containment vessels, MDMT. See Minimum Design Metal Temperature. Mean fracture toughness curve, 53 Measured material toughness, 44 Measuring instruments, New Approach Directive, 147 Mechanical stress improvement (MSIP), 17
as remedial measure for IGSCC in boiling water reactors, 83as remedial measure for PWSCC in PWRs, 76
Mechanical testing, 283Medium consequence assessment, 99Medium voltage underground cable testing, 39Membrane stress, 46–49. See also Stresses.
environmental impact on nuclear power plant components, 42Metallography, crack detection by, 13Metallurgical analysis, 14Metal cracks, Japanese codes, 258, 259Metal containment (MC) vessels, Japanese codes, 288Metal structure examination, French codes, 249Methane, detection near pipeline systems, 417Methyl-bromide, liquefied, 260METI. See Ministry of Economy, Trade and Industry.Metrication Policy, 351MF factor, 124Mm factor. See Membrane stress intensity factor.MFL. See Magnetic flux leakage.MIC. See Microbial influenced corrosion.Microbial influenced corrosion (MIC), as pipeline failure mode, 408Microcleavage pop-in, 53Midland reactor pressure vessel, 61Milliroentgen per hour or equivalent, 337Miner’s Rule, 320 Mine Safety Law, 260 Minimum Design metal Temperature (MDMT), transport tanks, 360Minimum holding temperatures, Japanese codes, 263Minimum holding time, Japanese codes, 263Ministerial Council on Economic Measures (Japan), 266 Ministry of Economy, Trade and Industry (METI), 258
Notification 97Notification 408 (Technical Standards on Structure for Concrete
Reactor Containment), 287Notification 97, 147, 258, 162, 187, 260, 261, 266Ordinance 258Ordinance 270 (Technical Standards for Nuclear Power
Ministry of Education, Culture, Sports, Science and Technology,fusion reactor safety, Japanese codes, 292
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718 • Index
Mitigation programs, effects of aging and, 58MITI MO 51. See International Trade and Industry Ministerial
Ordinance 270. MITI MO 123. See International Trade and Industry Ministerial
Ordinance 272.Mitigation programs, effects of aging and, 58, 59Mixed waste, classification of, 519 Mixers, 141MNOP. See Maximum normal operating pressure. Model PAT-1 package, 334Modulus of elasticity, of containment vessels for radioactive
materials, 363Molybdenum-250, 236, 351 Molybdenum stainless steel casting grades, for French pressure
equipment, 236 Molybdenum steels
for industrial piping, French codes, 191for pressure equipment, French codes, 212, 222
Moment loading, 320Monitoring, of age management program, 34 Monitoring devices, for pressure equipment, 153 Motor-operated valves (MOV), esting requirements for HSS and
LSS, 105MOU. See Memorandum of Understanding. MOV. See Motor-operated valves. MRP. See Material reliability program. MSIP. See Mechanical stress improvement process.MSS. See Manufacturers Standardization Society of the Valves and
Fitting Industry.Multi-Agency Radioactive Site Survey and Investigation Manual
(MARSSIM), 431Multiple flaw indications, 3–4. See also Flaws.
N4 studies, 245N289 Technical Committee (TC), 180Nameplate, 169, 366NASA. See national Aeronautics and Space Administration.National Accreditation Body, 138National Aeronautics and Space Administration (NASA), predicting
effect of small component failures, 89National Association of Corrosion Engineers Standards,
National Board Inspection Code, 366National Board Inspection Code (ANSI/NB-23), 366National Board of Boiler and Pressure Vessel Inspectors (Canada),
162National Board of Boiler and Pressure Vessel Inspectors in the United
States, 168National Board Owner/User “R” Certificate of Authorization, 366National Board “R” Stamp, 366–367National Building Code (Canada), 163, 179, 189National Energy Board (NEB) (Canada), 374, 376National Energy Board, Canada’s Safety and Performance Indicators,
annual report, 372National Energy Board Act (Canada), 420National Environmental Policy Act (NEPA), 31National Fire Code (Canada), 163, 189National Fire Protection Association (NFPA), 162National Fire Protection Association Fire Code, 163National Regulations, 129–130National Standards of Canada, 160–161
Natural gas fuel, high-pressure storage cylinders, automotive,Canadian storage, 168
Natural gas liquids, 170NB. See Notified Bodies.NCT. See Normal conditions of transport.NDE. See Nondestructive evaluation/testing.NDT. See Nil-ductility temperature.NDTT. See Nil-ductility transition temperature.NEB. See National Energy Board (Canada).NEI. See Nuclear Energy Institute.NEPA. See National Environmental Policy Act; National
Environmental Protection Act.Net positive suction head (NPSH), 45, 50Net present value (NPV) cost, 84–85Net present value (NPV) economic modeling software, 84Net-section collapse, 84
pressure vessels, Japanese codes, 281of PWR vessel materials, 50, 55
Neutron fluence, 59New Approach concept, 129New Approach Directives, 138, 144–145New Approach to Technical Harmonization and Standards, 129
fundamental principles, 129New/one-time inspections, detecting aging effects, 58NFPA. See National Fire Protection Association.NG18 surface flaw equation, 396Nickel
66, 68–69, 76–78alloy 600, properties, 63alloy 600, properties compared to austenitic stainless steel, 63alloy 600, related weld materials, 63–64alloy 600, repair processes for PWSCC, 80–82alloy 690 (NC 30 Fe), 64, 67, 84, 236alloy 690, for pressure equipment, Japanese codes, 287alloy 690, resistance to PWSCC, 67alloy 800, 64, 250SB-166, 16
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COMPANION GUIDE TO THE ASME BOILER & PRESSURE VESSEL CODE • 719
Nickel-base alloysfor fast breeder reactor material, 251irradiation embrittlement, 59for pressure equipment, French codes, 242
Nickel-chromium-iron alloyschromium content and PWSCC, 66for containment vessels for radioactive materials, 346fatigue curve, 14intergranular stress corrosion cracking, 1
Nickel-chromium-iron alloys, specific typesalloy 52, 19–20alloy 82, 19–20. See also Weld metals, specific types.alloy 182, 12–15, 17, 19, 26, 28. See also Weld metals, specific types.alloy 600, 12, 15, 19–20, 23, 28, 39, 63–66, 68–69, 71–72, 76–80,
236. See also Nickel alloys, specific types.Nickel-chromium-molybdenum steels, for pressure equipment,
French codes, 242Nickel-chromium steels, for pressure equipment, French codes, 242Nickel steels, for pressure vessels, Japanese codes, 262, 286Nil ductility reference temperature, 44, 48–51, 53, 55Nil-ductility reference temperature index, 43–44Nil-ductility temperature (NDT), steel containers for radioactive
materials, 346Nil-ductility transition temperature (NDTT), 50Niobium, alloy presence and PWSCC, 67Niobium alloys, UNS R60901, for pressure tube material, 164NISA. See Nuclear and Industrial Safety Agency.Nitric acid, 436Nitrogen, addition to stainless steel for structural strength, 1NKK, 388Nobel metal, addition to mitigate cracking, 3Nominal design strength, of pressure equipment, PD 5500 (U.K.), 312Nominal design stress
boilers, French codes, 222, 234industrial piping, French codes, 212, 221
Nominal diameter (DN), 132, 134Nominal pipe size (NPS), 4, 72NON. See Notices of Nonconformance.Non-alloy quenched-tempered steels, for industrial piping, French
codes, 223Non-alloy steels
for industrial piping, French codes, 221, 223for pressure equipment, French codes, 203–204, 234–235
Nonaustenitic stainless steelsfor pressure equipment, EN 13445, 327for pressure equipment, French codes, 203–206, 224, 234
Non-austenitic steels, for industrial piping, French codes, 212, 216,223
of alloys 600/82/182 locations, 71boilers, French codes, 224, 240of BWR nozzles and their welds, 11of crack depth, 3to detect vessel flaws, 55of effects of fatigue on nuclear power plant components, 38French codes, 240, 253–254frequent, to prevent boric acid corrosion, 84future Section XI changes, 94industrial piping, French codes, 223, 231–232information in technical documentation, 137
joints, 139–140, 152, 154–155, 157personnel, 137–138mechanical components, French codes, 252of piping segments, 100personnel approval in PED, 147personnel qualification and certification, French codes, 248of pressure vessels, French codes, 205, 213pressure vessels, Japanese codes, 264–267, 281reference flaw size, 44, 56requirements, 102of RPV nozzles, 71, 72selection, 95transport tanks, 358, 364–366of weld replacement repair, 82welds, EN 13445, 326–327zirconium alloy components, CANDU® nuclear power plants, 176
for pressure equipment, Japanese codes, 262–263for pressure equipment, PD 5500 (U.K.), 311, 324for pressure vessels, French codes, 203–205for transport tanks, 365
Non-Linde 80, 16Non-nuclear boilers, Canadian standards, 168Non-nuclear pressure vessels, Canadian standards, 168Non safety related (NSR) classification, low-safety significance
(LSS), 100Non-stainless alloy steels, for industrial piping, French codes, 212,
214, 221Non-stainless steels
for pressure equipment, French codes, 224, 234for pressure vessels, French codes, 201–204
Notified Bodies (NB), 129–131, 133, 136–139, 146, 149appraisal of material for boilers, French codes, 212approval of design procedures of pressure equipment, 139–140,
144, 148, 152conformity assessment of boilers, French codes, 224, 241conformity assessment of pressure vessels, French codes, 208,
214–216conformity assessment procedure, industrial piping, French codes,
212experimental design approval of pressure equipment, 139–140,
142, 147, 156identification number, 136–137, 141lists, and their scope of approval, 138monitoring by, 136–137represented in Working Group Pressure Standing Committee, 144Web site providing lists and scope of approval, 138
Normal Conditions of Transport, 337–338of containment vessels for radioactive materials, 346–347
Normal form, 343of radionuclides, Type A package limits, 334
Normal operation/upset conditions (Levels A/B conditions), 14structural factors, 118
North Anna Unit 2 nuclear power plant, 74–75NOV. See Notices of Violation.Novatome, 193–194
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720 • Index
Novetech, N 14–3, 61Nozzles, 68, 131, 320
alloy 600 use in PWR vessels, 65bottom-mounted instrument, 63, 65control-element drive mechanism, 65control rod drive mechanism, 63, 65cracking, 8–10, 22, 74de-gas line, 65dissimilar metal weld overlay, 19effect of temperature on PWSCC, 82ejection danger, 74, 77–78, 82examination methods, 9–12, 71–72head vent, 65improved thermal sleeve design, 11incore instrument (ICI), 65inlet/outlet, 63–64, 66, 74, 78J-groove welds for, 65liquid-injection shutdown system, 175mechanical remedial measures for PWSCC, 82–83predicting time to PWSCC, 84probabilities of leakage and failure, 79reinforcing, PD 5500 (U.K.), 314–316repair/replacement, 80–82residual stresses and crack initiation, 67stainless steel, SCC in BWRs, 64subsequent leakage following repair, 82thermocouple, 65top-head, 63, 84water-jet conditioning, 84
Nozzle to safe end socket welds, examination methods, 72Nozzle-to-safe end butt welds, surface method
examinations, 72NPS. See Nominal pipe size.NPSH. See Net positive suction head, 45NPV. See Net present value.NQA. See American Society of Mechanical Engineers (ASME)
BNCS Nuclear Quality Assurance Committee.NRC. See United States Nuclear Regulatory Commission.NRMCC. See American Society of Mechanical Engineers (ASME)
Nuclear Risk Management Coordinating Committee.NSC, 79NSNRC, installation of LTOP systems, 49NSR. See Non safety related classification.NSSC. See Canadian Standards Association, Nuclear Strategic
Steering Committee.NTD ASI Code for VVER Reactor Components, 577Nuclear and Industrial Safety Agency (NISA), 258–259Nuclear regulatory organizations, 655Nuclear boilers and pressure vessels, inservice inspection, Canadian,
181–187Nuclear cranes, 107, 109, 112–113Nuclear energy, history, 29–30Nuclear Energy Institute (NEI), 110
31–32, 41–42Section 3.0 (Identify the SSCs Within the Scope of License
Renewal and Their Intended Function), 32
Section 4.1 (Identification of Structures and ComponentsSubject to an Aging Management Review and IntendedFunctions), 32–33
USNRC endorsement, 33Nuclear industry, risk-informed codes and standards, 107Nuclear power plants (NPPs), 433Nuclear Power Engineering Corporation (NUPEC), 295–297Nuclear power plant
aging research, NRC, 29–30detection of age effects in, 58extended operation period, 29–31license renewal, 40, 58maintenance program, 30–31onsite NRC inspectors, 30outage extension, 63plant shutdown, 63, 69, 83, 99–100, 104–106, 112–114, 165seismic design guidelines, Japanese codes, 290–300
Nuclear Power Plant Components (ASME BPV Code Section III)age management program (AMP), 33–37age management review (AMR), 33–35flaw evaluation during inservice inspection, 113–128indications evaluated from inservice inspection, 113–128metal fatigue, 34–35passive/long-lived structures/components, 32repair/replacement, 37–38time-limited aging analysis, 31
Nuclear power plants in Spain, 567, 570NUPEC. See Nuclear Power Engineering Corporation.NWC conditions, boiling water reactor crack growth rate,
23–24NWPA. See Nuclear Waste Policy Act of 1982.NYSEARCH group of the North East Gas Association, 417
Oak Ridge National Laboratory (ORNL), 506finite element stress analyses, 48ORNL/NRC/LTR-93/15, 61ORNL/NRC/LTR-93/33, Revision 1, finite element analysis for
inside surface flaws, 61ORNL/NRC/LTR-94/26, 61
testing for microcleavage pop-ins, 53updated FAVOR code, 56
Obrigheim steam generators, U-bend cracking, 68Oconee Unit 2 nuclear power plant, 73Office of pipeline Safety (OPS), 373–376
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COMPANION GUIDE TO THE ASME BOILER & PRESSURE VESSEL CODE • 721
Office of the Federal Register, 26, 42Official Journal of the European Communities, 138, 142, 146, 148, 310
97/23/EC, 130Offshore steel pipelines, Canadian standards, 171Oilfield steam distribution pipelines, Canadian standards, 171Oil pipeline systems, 170–171Oil spill, 528Oil Refineries and Petrochemical Plants, 565On-power refueling, 165Onshore Piping Regulations (OPR) (Canada), 376Operability, requirements for LTOP protection and, 50Operating condition stress/fabrication residual stress leading to
PWSCC, 67Operating heatup and cooldown limit curves, 49–51Operating instructions, 148
of pressure equipment, 141, 155Operating pressure, use in predicting crack growth rate, 77Operating temperature
effect in predicting crack growth rate, 77, 79PWSCC in pressurized water reactors, 79–80, 83
Operating timecorrections for predicting time to PWSCC, 83and probability of nozzle cracking/leakage in RPV head, 79
Operational insights, for component safety categorization, 104OPR. See Onshore Piping Regulations.OPS. See Office of Pipeline Safety.Order on Life Cycle Asset Management, U.S. Department of Energy,
485ORNL. See Oak Ridge National Laboratory.OSHA. See Occupational Safety and Health Administration.Overlay weld metal, 17–18Overpressure protection, French codes, 249Overpressure Protection Devices, Canadian standards, 168Overpressure Protection Report, 15, 172
CANDU® nuclear power plants, 172“An Overview of R6 Revision 4”, 121, 128Owner/Licensee
CANDU® nuclear power plants, 172, 174repair program, 103
PAA. See Price Anderson Indemnification Act.PACE. See Petroleum Association for the Conservation of the
Canadian Environment.Paris law crack growth model, 401Partial penetration nozzles, examination method, 72Partial penetration welds, 67
for BMI nozzles, 73for control rod drive mechanism nozzles, 73
Particular Material Appraisal (PMA), 137, 142–143, 146, 310Part wall defect, 310Passivation, 23Passive power plant structures/components, 41
aging management, 31, 57identification, 31–32
PAT. See Plutonium Air Transport package.PCCV. See Prestressed concrete containments vessels.PD 5500. See Published document (PD) 5500.PDD-63. See Presidential Decision Directive 63.Peak stress, 125–126
Petroleum Association for the Conservation of the CanadianEnvironment (PACE), 162
Petroleum gas, liquefied, 170, 260Petroleum plants, fired-heater pressure coils, 168PFM. See Probabilistic fracture mechanics.PGE. See Portland General Electric Company.pH
crack growth rate and changes in, 68of PWR primary coolant, 82
Phased array ultrasound, 388Phosphorus
alloy presence and PWSCC, 67causing hot cracks, 67
PHTS. See Primary heat transport system.PHWR. See Pressurized heavy water reactor.Physical testing, 248Physicochemical testing, 248Pigging, 386Pipe fittings, Canadian standards, 168–169Pipeline security, 371–410Pipeline systems, 371–410. See also Piping.
2000), 371Figure 54.2 (Natural Gas System Network), 372Figure 54.3 (Pipeline Construction [by decade]), 373Figure 54.4 (Causes of Pipeline Incidents on U.S. Pipelines in
2000), 373Figure 54.5 (Buckling, Gouging and Denting, Corrosion), 374
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722 • Index
Figure 54.6 (Frequency of Occurrence of Various Threats to GasPipelines), 375
Figure 54.7 (Integrity Management Process Flow Diagrams[ASMEB31.8S]), 377
Figure 54.8 (API 1160 Managing System Integrity for HazardousLiquid Pipelines), 377
Figure 54.9 (Simplified Risk Hierarchy), 381Figure 54.10 (Example of Relative Ratings of Potential Threats),
382Figure 54.11 (Risk Matrix), 383Figure 54.12 (Risk Assessment and Mitigation Process Template),
383Figure 54.13 (Calculating the Failure Probability from a Limit
State Analysis), 384Figure 54.14 (Simple Event Tree to Predict Ignition Probability
Following Rupture), 384Figure 54.15 (Possible Scenarios Following a Gas Pipeline
Rupture), 385Figure 54.16 (ALARP Figure), 385Figure 54.17 (Effect of Three Integrity Strategies on Risk
Reduction), 386Figure 54.18 (Hydrotest Aftermath for Driving Out SCC), 386Figure 54.19 (Defect Assessment Curve), 387Figure 54.20 (Magnetic Flux Leakage), 387Figure 54.21 (Ultrasonic Tool in a Liquid Batch), 388Figure 54.22 (Four-Step Direct Assessment Process), 389Figure 54.23 (Part Wall [A] and Through Wall [B] Defects), 389Figure 54.24 ([a]Dimensions of a Longitudinal and [b]a
Circumferential Through Wall Crack Defect), 394Figure 54.25 (Dents Under Pressure), 396Figure 54.26 (Method of Determining Longitudinal Extent of
Localized Corrosion and Interaction Distances), 396Figure 54.27 (Determination of Nondimensional Variable B), 397Figure 54.28 (Simplified and Detailed RSTRENG Profiles), 398Figure 54.29 (Profile of Corrosion Depth Along the “River
Bottom” Path), 399Figure 54.30 (Remaining Strength Assessment Representation of
Metal Loss), 399Figure 54.31 (Type A and Type B Sleeves), 400Figure 54.32 (A Composite Wrap Repairs), 402Figure 54.33 (Clock Spring(tm) repair), 403Figure 54.34 (Stopple(tm) Bypass Repair Method), 404Figure 54.35 (Schematic Showing a Differential Corrosion Cell on
a Pipeline Surface), 404Figure 54.36 (Factors Affecting Corrosion), 405Figure 54.37 (Timeline of Coating Development), 407Figure 54.38 (Special Purpose Multilayer Coatings), 409Figure 54.39 (Cause of Pipeline Coating Breakdown in Australian
Pipelines), 409Figure 54.40 (Vertical Anode Arrangement), 410Figure 54.41 (Helicopter-Borne LIDAR Used for Surface
Topography and Leak Detection), 410Figure 54.42 (Buried Fiberoptic Detection Device), 415Figure 54.43 (Synthetic Aperture Radar Scanning Swaths from
Orbiting Satellites), 417Figure 54.44 (Vandalized Attack on the Alyeska Pipeline Causing
Millions of Dollars of Environmental Damage), 418Figure 54.45 (Gas Pipeline System Dependencies Source Argonne
national Laboratories), 419hydro testing, 376, 386–392inhibitors for protection, 409, 416
integrity assessment methods, 386–395integrity management plans, 375–378line marking and locating, 416liquid hydrocarbon, 372long-term repairs to pressure boundary piping, 19magnetic flux leakage for assessment, 387–389natural gas, 372pressure boundary risk, 19, 96probability of segment failure, 96ranking process, 95regulations, 374–377remote sensing of encroachment, 417–418remote sensing of leaks, 416–417repair, 402–406right of way patrols, 416risk assessment of failures, 376, 378–384risk-informed-inservice inspection (RI-ISI) process, 95risk mitigation, 384–386safety, 372–374security management programs, 418–420Table 54.2 (Fatality Rate by Mode, 2000), 373Table 54.3 (Major Threats to Transmission Pipelines ASME
B31.8S), 377Table 54.4 (Index Methods for Rating Annual Probability of
Occurrence), 382Table 54.5 (Matching Risk Severity with Level of Response), 383Table 54.6 (Defect Detection Capability of Various Inspection
Tools), 388–389Table 54.7 (Attributes of Various Pipe Protection Methods),
390–393Table 54.8 (Methods for Assessing Corrosion), 401Table 54.9 (Codes and Standards for Making Repairs, Gas
Pipelines and Oil Pipelines), 403Table 54.10 (Permissibility of Corrosion Repair Technique), 405Table 54.11 (Permissibility of Crack Repair Technique), 406Table 54.12 (Permissibility of Mechanical Damage Repair
Technique), 406Table 54.13 (Pipeline Corrosion Prevention), 408Table 54.14 (Galvanic Series of Common Commercial Metals and
Alloys in Brine [approx. 25°C]), 408Table 54.15 (Advantages and Disadvantages of Pipeline Coatings),
412Table 54.16 (Classification of Pipeline Coating Tests), 413–414third party damage awareness and control, 416–418ultrasonic testing, 388–389, 391, 394, 400
Pipeline Research Council International (PRCI), 395pipeline repair manual, for gas pipeline repairs, 403pipeline repair manual, oil pipeline repairs, 403
Pipeline Safety Improvement Act of 2002, 374, 419Pipeline transportation, advantages and purposes, 371–372Pipe rupture, circumferential cracking and, 74Pipe steel
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COMPANION GUIDE TO THE ASME BOILER & PRESSURE VESSEL CODE • 723
Piping and Fitting Dynamic Reliability Program, 294Piping element tests, Japanese codes, 297Piping seismic evaluation methodology, Japanese codes, 269Pitting corrosion
age evaluation, 33as pipeline failure mode, 390–391, 395, 405–408
Plane strain, in elastic component of J, 115Plane stress, in elastic component of J, 115Plant expert panel, 95, 104–106Plant overall safety, 53Plastic collapse, 116–118, 387Plastic deformation, 113, 198
industrial piping, French codes, 212prevention, French codes, 243
Plastic instabilityboilers, French codes, 222bursting, pressure vessels, 198industrial piping, French codes, 209
Plasticity theory, 323Plastic load line displacement, 115Plastic pipelines, Canadian standards, 171Plastic strain correction factor (Ke), 245
French codes, 247Plastic zone size, 47–48, 113, 122Plastic zone size correction, 113Plate-and-shell theory, 317Plates
center-cracked, loaded to failure, 113–114construction materials, 149European standards, 236J-R curve parameters, 124for pressure equipment, Japanese codes, 263
final rule), 349–354, 349packaging of fissile material, 341sea transport, 352shipment and quality assurance, 343–348solid exemptions from double containment requirements,
344–345vitrified high level waste (1997 proposed rule), 349–352
Plutonium isotopes, 337Plutonium nitrate, 342–347Plutonium oxide, 343PMA. See Particular Material Appraisal.Pneumatic testing, 141
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724 • Index
pressure vessels, Japanese codes, 262of welded components, 12, 17, 19
Power boilers, Japanese codes, 271Power Generation Facilities Codes Committee, 258Power uprate and license renewal, 685PRA. See Probabilistic risk assessment/analysis.PRA Standard. See American Society of Mechanical Engineers
Probabilistic Risk Assessment (PRA) Standard.PRCI. See Pipeline Research Council International.PRDs. See Pressure relief devices.Precipitation-hardened austenitic steels, fast breeder reactor material,
251Precipitation hardening alloys, in pressure equipment, 157Precracked specimen tests loaded to failure, 44Predicted instability load, 116–117, 125Predicted time to crack initiation, 84Predictive model, in determining PWR component performance, 60Preheating, requirements of welds, 19Preliminary Safety Analysis (PSA) Applications Guide, 96, 106Preload, 57, 59Preservice examination, 103Presidential Commission, to investigate Three Mile Island, 89Presidential Decision Directive 63 (PDD-63), 420Pressure
of cylindrical shell, 313–314designing for fluctuations in, 20–21low upper-shelf energy evaluation, 122maximum allowable (PS), 132, 134
209, 217, 271Article 10 (Conformity Assessment), 131, 135, 198, 209, 217Article 11 (European Approval for Materials), 131, 142, 156Article 12 (Notified Bodies), 131, 554, 557, 663Article 13 (Recognized Third-Party Organizations), 154, 272Article 14 (User Inspectorates), 271, 272Article 15 (CE Marking), 155Article 16 (Unduly Affixed CE Marking), 272Article 17 (Appropriate Measures), 272Article 18 (Decisions Entailing Refusal or Restriction), 272Article 19 (Repeal), 272Article 20 (Transposition and Transitional Provisions), 131, 272Article 21 (Addressees of the Directive), 272articles, 272category A, 201category B, 201category C, 201category D, 201category Ex (Exceptional), 201classification of pressure equipment, 131comparisons with ASME Code, 147conformity assessment categories (I to IV), 310conformity assessment modules, 131, 135, 136, 310conformity assessment procedures, 129, 130, 131, 133, 135, 136,
137, 156, 198, 209, 212, 217, 222, 310definition, 146development of, 324and EN 13445, 129Figure 47.1 (PED Flow chart), 131, 132Figure 47.2 (Hazard Categories for a Vessel Containing a
Dangerous Gas), 134Figure 47.3 (Determination of Hazard Category for a Piping
Containing a Dangerous Gas), 134, 135final assessment and proof test, 141flow chart, 120, 277, 278, 380, 570,591Fluid Group 1, 310Fluid Group 2, 310vs. French codes, 191, 193, 196, 253, 653guidelines, 144hazard categories, 133, 134, 138, 198, 209, 212, 217, 218, 220,
627industrial piping, 142, 191, 553, 554industrial piping risk assessment, 219link with COVAP, 217link with codes and standards, 192, 193material specifications, 141, 143, 148, 163, 177, 188New Approach Directives, 129, 131, 138, 144, 145, 147Notified Bodies, 129, 137, 138, 142, 310objectives and requirements, 130vs. published document (PD 5500 (U.K.)), 309, 531vs. RCC-M, 248risk assessment of pressure vessels, 320scope, equipment covered, and exclusions, 137technical documentation, 136Table 47.4 (Selection of Conformity Assessment Procedures), 136
Post-weld heat treatment (PWHT) (continued)
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COMPANION GUIDE TO THE ASME BOILER & PRESSURE VESSEL CODE • 725
Table 47.5 (List of New Approach Directives (as of January2005)), 144, 145, 146
Table 47.6 (European System vs. U.S. System PressureEquipment), 148–149
Web site, 130Pressure Equipment Regulations 1999, 309, 330Pressure excursions, 45Pressure Equipment Directive (PED) 97/23/EC, 547, 553, 561, 563Pressure gauges, in scope of PED, 129, 148, 191, 259, 308Pressure hazard level, 131, 133Pressure limiting devices, in pressure equipment, 141, 157Pressure load, 44, 47, 49Pressure piping, Canadian standards, 162, 168, 170, 288, 422Pressure regulations, in scope of PED, 626, 628, 633Pressure relief devices (PRD), 169, 192, 357, 358,, 368, 370, 666,
677Canadian standards, 160
Pressure stress intensity factor, 47, 49Pressure Systems Safety Regulations 2000, 310Pressure-temperature (P-T), rate of temperature change affecting, 49Pressure-temperature (P-T) limit, 49Pressure-temperature (P-T) limit curves, 49
in CANDU® design, 163environmental fatigue effects, 21–22“feed and bleed” items, safety significance of, 95flaw effect on integrity of nuclear components, 43–50, 53, 55French codes, 226hydrogen concentration in primary coolant, 82inclusion criteria (Level A) for (HSS) high-safety significant
snubbers, 106large-diameter pipe weld repair, 81lithium concentration and pH of primary coolant, 82LTOP for brittle fracture protection, 43, 49nozzle cracking, 10operating cycle, 74passive structural components, 57pressure-temperature heatup and cooldown curves, 43, 45–49primary water stress corrosion cracking and, 69, 73, 78primary coolant water chemistry, 67, 78reactor coolant water chemistry changes, 67, 80risk-informed process, 98top-head nozzles, repairs, 81–82zinc added to coolant, 82
Pressurized Water Reactor (PWR) Owner’s Group, aging mechanism study programs effects, 57
Pressurized water reactor plantpersonnel radiation exposure, 53plant safety, 53use of alloy 600 base metal, 63
Pressurized water reactor (PWR) vessel(s)absence of inner surface flaws, 51–52alloy 600 applications, 63–66beltline material, 44–45, 49beltline region, brittle failure at, 43, 55beltline weld, 48degradation predictions of PWSCC, 76–79embrittlement, 50failure/fracture, 43–44Figure 44.1 (Locations with Alloys 600/82/182 Materials in
Typical PWR Vessel), 63–64inspection methods of PWSCC and requirements, 71–72integrity analysis, 50, 54–55primary water stress corrosion cracking (PWSCC), 63, 66–68primary water stress corrosion cracking of alloy 600 material,
operating experience, 68–71probability of failure as a function of pressure temperature, 55remedial measures of PWSCC, 80–81repairs of PWSCC, 79–82safety considerations of PWSCC, 73–74strategic planning for PWSCC, 83–84surveillance program, 50top head insulation, 74, 75toughness level of plates, 50
Pressurized water reactor (PWR) vessel internalsaging management of, 57–60aging management strategies, 59–60aging mechanisms, 57enhanced visual (VT) examinations, 60irradiation-assisted stress corrosion cracking, 59irradiation embrittlement, 59stress corrosion cracking, 59stress relaxation, 59structure/component, loss of material due to aging, 58support, in event of structural failure, 66
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726 • Index
thermal aging embrittlement, 59void swelling, 59
Pressurizer heater sleeve, 84–85use of alloy 600, 63, 68
Pressurizer welds, 73Prestressed concrete containment vessels (PCCV), Japanese codes,
287Primary bending stress, 18, 118–119, 121. See also Stresses. of
containment vessels for radioactive materials, 346–347transport tanks, 362
Primary bending stress intensity, 272Primary coolant system
of alloys 600/82/182 in PWR plants, 63–82as axial, 67causes: environmental, 66–68causes: material susceptibility, 66–67causes: tensile stresses, 66–67conditions of PWSCC susceptibility, 68crack arrest, 69crack growth, 67crack growth behavior in alloy 600, 79cracking issue in pressurized water reactors, 74crack initiation, 67, 76, 79description, 66inspection methods/requirements to identify, 71–72predicting time to crack initiation, 76, 84in PWR RPV inlet/outlet nozzles, 74remedial measures, 82–84repair of RPV alloy 600 components, 80resistant materials, 84small cracks, 73susceptibility of alloys 81/182, 66
Principal (CODAP), 207Principal, for boilers, French codes, 224Probabilistic EPFM, 126Probabilistic failure mechanics (PFM), 94Probabilistic fracture mechanics (PFM) analysis, 7, 55, 79
as alternative for assessing margins in Appendix G method, 56code, VIPER, 11for inspection exemption, 6predicting PWSCC on Alloy 600/82/182 in PWRs, 76, 79
Probabilistic risk assessment analysis (PRA), 33applications, piping systems, 95to assess risk of leaks, 84background, 89capability category I, 92–93
capability category II, 92–93capability category III, 92–93codes and standards guiding, 102–103, 106–107component ranking, plant specific, 104to determine allocation of resources, 89to determine inservice activities, 89, 94, 107–108to determine risk importance, 89impact, 92Level 1, 106Level 2, 106Level 3, 106limitations, 100piping system examinations, 96–97plant-specific to determine safety significance of SSCs, 99ranking measures, 104RI-IST and, 104shutdown, 104, 106, 114for valves, 115
Probabilistic Risk Assessment (PRA) Standard. See AmericanSociety of Mechanical Engineers Probabilistic RiskAssessment Standard.
Production from a well, measurement of, 372Production weld test coupons, 248Product verification, 135–136Proof test, 141, 148
for cast iron boilers, 169pipe fittings, 169of pressure equipment, 154–155transport tanks, 366
Property damage, from pipeline incidents, 371–374PS. See Pressure, maximum allowable.PSA. See Preliminary safety analysis.PSAR. See Preliminary Safety Analysis Report.PSDAR. See Post-Shutdown Decommissioning Activities Report.PT. See Liquid penetrant examination.PT. See Penetrant testing.P-T. See Pressure-temperature.PTS. See Pressurized thermal shock.Public Law 104, 358Public Law 104–113 (National Technology Transfer and
309–314Annex A, 317, 320, 323–324Annex B, 313Annex C, 319–325, 330Annex D, 325Annex G, 319–320, 324, 329–330Annex G.2, 320Annex G2.5, 315Annex K, 312Annex M, 313–314Annex Z, 310Appendix F, 316bolted flanged joints, 316–317design, 312, 316–317design for fatigue, 320–321Enquiry case 5500/116, 329Enquiry case 5500/122, 330Enquiry case 5500/126, 318Enquiry case 5500/128, 318Enquiry case 5500/130, 329
Pressurized water reactor (PWR) vessel internals (continued)
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COMPANION GUIDE TO THE ASME BOILER & PRESSURE VESSEL CODE • 727
Enquiry case 5500/133 (Rectangular, Narrow-Faced and Full-Faced Flanges), 317
Figure 51.1 (Values of Coefficient _ for Cone/Cylinder Intersectionwithout Knuckle), 313
Figure 51.2 (Buckling Forms for Stiffener Cylindrical Shells),313–314
Figure 51.3 (Theoretical Buckling Strain e as a Function of ShellLength, Radius, and Thickness), 314–315
321Figure 51.9 (Fatigue Design Curves from Annex C of PD 5500),
321–322Figure 51.10 (Annex A Stress Categories and Limits of Stress
Intensity-Hopper Diagram), 324Figure 51.11 (Dished End Thicknesses Compared for 2:1
Ellipsoidal Form), 328Figure 51.12 (Dished End Thicknesses Compared for 10%
Torispherical Form), 328Figure 51.13 (Dished End Thicknesses for 6% Torispherical Form
Compared), 328flat plates and covers, 317Form X, 311inspection, 319jacketed vessels, 318loads, local, 319–320materials, 311–312nozzle reinforcing, 314–316sections and appendices, 311shells under external pressure, 313–316shells under internal pressure, 312–313supports, 319Table 51.1 (Comparison of the Bases of ASME and PD 5500
Published Document (PD) 6439 (Stress Calculation Methods forLocal Loads and Attachments of Pressure Vessels), 313
Published Document (PD) 6497 (Stresses in Horizontal CylindricalPressure Vessels), 311, 319, 330
Published Document (PD) 6550 (Supplement to BS 5500), 311, 313,324, 330–331
PUC. See Public Utility Commission.Pumps
cavitation, 45group A, 105group B (standby), 105high-safety significant (HSS) category, 105low-safety significant (LSS) category, 104, 108OMN-Code testing program, 105Risk-informed IST application, 103seal, 50
Pump sizing, French codes, 246–247Puncture/tearing test, 336
Pure water stress corrosion cracking. See Primary water stresscorrosion cracking (PWSCC).
PVE/Pressure Vessels, 309PVE/1, Pressure Vessels (technical committee), 309PVE/1/15 Design Methods, 309PVRC. See Pressure Vessel Research Council.PVRUF reactor pressure vessel, 52PWHT. See Postweld heat treatment.PWR. See Pressurized water reactor.PWSCC. See Primary water stress corrosion cracking.Pyrophoric liquids, 340
QA. See Quality assurance.QAPP. See Quality Assurance Program Plan.QC. See Quality control specialists.QI. See Qualified Inspectors.QIO. See Qualified Inspection Organization.Qualification of welders, oil and gas pipeline systems, Canadian, 170Qualified Inspectors (QI), 366Qualified Inspection Organizations (QIO), 366Qualification of NDT for ISI, 568Quality assurance (QA), 135–136, 144
focusing in CDF-vulnerable components, 90French codes, 229, 233–234, 241pipe fittings, 169plutonium shipments, 343–345of pressure equipment, 156pressure vessels, Japanese codes, 268radioactive material packagings, 343–344, 345
Quality assurance program, 101Canadian standards, 163CANDU® nuclear power plants, 171, 173, 177–178radioactive material packaging, 349–350
Quality Assurance Program (Z series), 162Quality Assurance Requirements for Transport Packages, 1978
effective rule, 345Quality control
licensee of fissile material shipments, 338spent fuel storage containers and transportation casks, 452
Quality Control Program, Canadian standards, 168–169Quality Control Program Manufacturers of Fittings, Canadian
standards, 168Quality Management Systems (CAN/CSA-ISO-9001-00), 162Quantitative risk analysis, of pipeline failure possibility, 382Quenched and tempered non-alloy steels, for pressure vessels, French
codes, 223–224Quenched and tempered steels
for industrial piping, French codes, 224for pressure equipment, French codes, 223
Radial/shear stress, concrete containment vessels, 288Radial shrinkage, in weld repairs, 18Radiation damage, on pressurized water reactor vessel materials, 43Radiation embrittlement, 43, 54, 125Radiation exposure, 339
employees, 53Japanese codes, 292–294Off-site, 30
Radiation shielding, 335Radiation unit, 337Radioactive materials, responsibility for cleaning up spills, 340Radioactive release, risk assessment of, 90
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728 • Index
Radiographic inspectionCanadian standards, 171CANDU® nuclear power plant components, 184, 185, 187French codes, 240, 249pressure vessels, Japanese codes, 264–265welds in calandria assemblies, Canadian, 175zirconium alloy components, 176–177
Radiography, 400Radiological exposure hazard models, 292Radiological impacts, fusion reactors, Japanese codes, 292–294Radiotoxicity of isotope, 436Radium, shipments of, 342RAI. See Request for additional information.Ramberg-Osgood curve, 114Ramberg-Osgood model, 121Ramberg-Osgood parameters, 119Ramberg-Osgood stress-strain equation, 121RAMSES committee, 193Random (sample) testing, joint coefficients allowed, 139Ratcheting
nuclear pressure vessels, PD 5500 (U.K.), 323prevention, French codes, 243, 251thermal, in cylindrical containment vessels, 345
Ratcheting fatigue, 299–300low-cycle, 299–300piping failure during earthquakes, Japanese codes, 295seismic shakedown, Japan, 295–296
RAW. See Risk achievement worth.RCC-C. See Design and Construction Rules for Fuel Assemblies of
Nuclear Power Plants.RCC-E. See Design and Construction Rules for Electrical Equipment
of Nuclear Islands.RCC-G. See Design and Construction Rules for Civil Works of PWR
Nuclear Islands.RCC-I. See Design and Construction Rules for Fire Protection.RCC-M. See Design and Construction Rules for Mechanical
Components of PWR Nuclear Islands.RCC-MR. See Design and Construction Rules for Mechanical
Components of FBR Nuclear Islands.RCC-P. See Design and Construction Rules for System Design,
French Codes.RCCV. See Reinforced concrete containments vessels.RCRA. See Resource Conservation and Recovery Act.RCS. See Reactor coolant system.Reactivity control units, CANDU® nuclear power plants, 175Reactor building, 165–166Reactor coolant
environmental impact on components, 34–35, 37temperature, LTOP setpoint and, 50
Reactor coolant system (RCS)aging mechanisms, 57levels of corrosion products in, 63metal fatigue, 21piping, 31pressure boundary, integrity, 30, 98–99, 104primary coolant system cracks/leaks, 63PWSCC occurrences, 68
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COMPANION GUIDE TO THE ASME BOILER & PRESSURE VESSEL CODE • 729
of pipe segment risk evaluation, 95Risk-informed (RI) analysis, 90
applications, 103capability of PRA to support application, 91–94decommissioning of nuclear facilities, 425future plans for, 107–110HSS classification and, 100IST application, 103preservice, 103repair/replacement requirements, 97, 101, 108risk category and, 97safety classification, 98–100, 103, 108security applications, 89, 110standard for use of PRA, 90–93in testing mechanical equipment, 103
Risk-informed (RI) decision-making, PRA Standard application, 91Risk-informed (RI) fracture mechanics evaluations, 126Risk-informed-inservice inspection (RI-ISI), 95, 96, 100
Risk studies, 90–91RMA. See Rubber Manufacturers Association.Roll expansion repair, 12–13Role of regulatory authority, 83Roll peening, to reduce potential PWSCC, 59Root cause determination, 35, 59
of component aging, 35RPV. See Reactor pressure vessel.R ratio, 5
environmentally assisted fatigue crack growth in BWRenvironment, 22
RRM, risk-informed, 109RSE-M. See Inservice Inspection Rules for Mechanical Components
of PWR Nuclear Islands.R-6 methodology, 114, 121“R” Stamp, 366–367RSTRENG, 376, 399–400RTNDT brittle to ductile transition temperature determination,
French codes, 249RTPO, 148
approval of joining procedure qualifications, 140approval of NDE examiners, 148
Rubber Manufacturers Association (RMA), 162Rubber Manufacturers Association standards, RMA IP-2, 170Rules on Design and Construction for Nuclear Power Plants, 275Rules on Fitness-for-Service for Nuclear Power Plants
(Japan, 2000), 275Rules on Thermal Power Generation Facilities, 259Rupture, 83–84
of radioactive material packaging, 352–353, 354Rupture disks, 359Russian Regulation and Codes in Nuclear Power, 601
different classes of packages of special nuclear material, 334emergency response plans of pipeline companies, 421identifying concerns using PRA, 89Japanese codes and standards, 259plant overall, 53RCC-M French codes, 228–229, 249risk from boric acid corrosion, 74
Safety accessories, 134in scope of PED, 130–131, 139, 153–154
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Safety systemseffects of aging on, 58low-safety significance of, 100
Safety valves, 141French codes, 249repair guidelines, Canadian standards, 168
Sample package, 336Sample size, 58Sampling, as inspection method, 58SAR. See Safety analysis report.SAR. See Synthetic aperture radar imaging.SARA. See Superfund Amendment and Reauthorization Act.Satellites-optical systems, 418
surveillance of pipeline systems, 418–419SAW. See Submerged arc welding.SBC. See Systems-Based Code.SCADA. See Supervisory Control and Data Acquisition.Scale model testing, 6SCC. See Standards Council of Canada.SCC. See Stress corrosion cracking.SCO. See Surface contaminated object.Scoping methodology, 41
SCV. See Steel containment vessels.SDO. See Standards-developing organizations.SDWA. See Safe Drinking Water Act.SE. See Safety evaluation.
Secondary bending stress, 118–119. See also Stresses.Secondary stresses, 124–125
in containment vessels for radioactive materials, 346membrane, French codes, 251–252nuclear power plants, Japanese codes, 294–295nuclear pressure vessels, PD 5500 (U.K.), 324
Section I (Power Boilers), 147, 169–170, 188, 258–259, 364vs. COVAP (French Boiler Code), 224vs. Japanese codes, 268–270
Section II (Materials), 267, 286Appendix 1, 287Appendix 2, 287Appendix 5, 287vs. French codes, 230vs. Japanese codes, 268–269, 286–287Part A (Materials: Ferrous Material Specifications), 169, 188PartB (Materials: Nonferrous Material Specifications), 169, 188Part C (Materials: Specification for Welding Rods, Electrodes and
Filler Materials), 169, 188Part D (Materials: Properties), 169, 188, 275, 359, 362–363Table U, 311vs. PD 5500 (U.K.), 311
Section III (Power Piping Codes), 118, 124, 193Addenda, 295allowable stresses for reactor vessel components, 67for Canadian nuclear construction standards, 159Class 1 systems, 1, 6, 346Class 2 systems, 108Class 3 systems, 108, 293, 295Code cases, 108developing reliability-based load and resistance factor design
methods for piping, 107fatigue design curves, 21Figure 42.1 (Audit of AMPs Consistent with the GALL Report),
36Figure 42.2 (Audit of Plant-Specific AMPs), 37Figure 42.3 (AMP Review Process, Consistent with GALL
Report), 38Figure 42.4 (AMR Review Process, Consistent with Precedent), 39Figure 42.5 (Interim Staff Guidance Process Flow Chart), 40–41Figure 43.8 (Charpy V-Notch Surveillance Data Showing RTNDT
Shift Due to Irradiation), 50–51Figure 44.1 (Locations with Alloys 600/82/182 Materials in PWR
Vessel), 64Figure 44.2 (Typical Control Rod Drive Mechanism (CRDM)
Hydrogen Concentration), 67–68Figure 44.7 (Effects of Hydrogen Concentration on PWSCC
Initiation and Growth), 68Figure 44.8 (Typical Small Volume of Leakage from CRDM
Nozzle), 69, 71vs. French codes, 226, 229, 236–237, 246–247intergranular stress corrosion cracking, 1vs. Japanese codes, 272–273, 275, 284joint design with American Concrete Institute, 400material fracture toughness requirements, 348nuclear requirements, 102pressure-retaining components, 20
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COMPANION GUIDE TO THE ASME BOILER & PRESSURE VESSEL CODE • 731
pressurized water reactor vessel design requirements, 43service-induced degradation in BWR vessels, internals, and
pressure boundary piping, 24Table 42.1 (Consistent with GALL Report Classification), 33–34Table 42.2 (Elements of an Aging Management Program), 35Table 44.1 (Factors on Crack Initiation and Growth Time at
Section III, Division 1 (Rules for Construction of Nuclear PowerPlant Components), 34, 42, 171–173, 188, 194, 259
Appendix I, 358Appendix III, 45Appendix XIII, 237Appendix XIV, 237Appendix A, 37Appendix B, 173Appendix C, 173Appendix G (Protection Against Nonductile Failure), 43–46, 60,
vs. EN 13445, 327fatigue design procedure, 20Figure 19.2 (Fatigue Design Curve for Ni-Cr-Fe), 14maximum postulated defect, related to allowable surface
Section III, Division 3 (Containment Systems for TransportPackaging), 174
adoption by USNRC, 354, 353vs. Japanese codes, 268–269
Section III, Division 4, vs. Japanese codes, 291Section IV (Heating Boilers), 169Section V (Nondestructive Examination), 169, 177,
183, 188vs. Japanese codes, 270
Section VIII, 138–139, 317canister design requirements for radioactive materials,
349vs. Japanese codes, 270nuclear requirements, 102pressurized water reactor vessel design requirements, 43
Section VIII, Division 1 (Rules for Construction of Pressure Vessels),147, 169–170, 258–259, 347, 360, 364
compared to CODAP rules (French codes), 208vs. EN 13445, 328–329vs. Japanese codes, 259, 272production tests, 264Subsection A (General Requirements for All Methods of
Construction and All Materials), 151Part UD, 359Part UG, 359–360
Section VIII, Division 1, Subsection CPart UCS (Requirements for Pressure Vessels Constructed of
Carbon and Low-Alloy Steels)Table UCS-23, 262–263UCS-56, 365UCS-85, 262
Part UHA (Requirements for Pressure Vessels Constructed ofHigh-Alloy Steel)
Table UHA-23, 262–263Part UHX, 208
UHX-12, 208
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732 • Index
Part UNF (Requirements for Pressure Vessels Constructed ofNonferrous Materials)
Class 2 componentshigh-safety significance items, 95piping, 98systems, 108
Class 3 componentshigh-safety significance items, 95piping, 89, 98systems, 108
Code Cases, 94–106, 108, 109code requirements for safety relation, 95conditional consequence of failure, 93Figure 41.1 (Overview of BWR Pressure Vessel and Internal
Components), 1–2Figure 41.2 (BWR Core Shroud Weld Designations), 3Figure 41.3 (A Distributed Ligament Length Example), 3Figure 41.4 (Typical Geometry of a BWR Jet Pump), 5Figure 41.5 (Sample of Stress Time History at Cracked Location),
5, 9Figure 41.6 (Crack Lengths for Core Flow Levels), 6Figure 41.7 (BWR Steam Dryer Assembly), 7Figure 41.8 (Steam Dryer Damage), 8Figure 41.9 (Feedwater Nozzle with Cracking Location), 9Figure 41.10 (Improved Sleeve Design and Temperature
Variation), 11Figure 41.11 (Fracture Mechanics Results for BWRs), 9, 12
Figure 41.12 (BWR Feedwater Nozzle Inspection Zones), 12Figure 41.13 (BWR Set-in CRD Stub Tube Design), 12Figure 41.14 (Stub Tube Narrow Groove Welded Partial Design), 13Figure 41.15 (BWR-2 Shroud Support Geometry), 14Figure 41.16 (Calculated Values of Total K and the Polynomial
Fit), 14Figure 41.17 (Predicted Crack Growth as Function of Operating
Hours), 14Figure 41.18 (Steam Dryer Support Bracket Crack), 14–15Figure 41.19 (Temperature-Time Variations during Automatic
Blowdown Transient), 15–16Figure 41.20 (Assessment for Level C Conditions), 15–16Figure 41.21 (Weld Overlay Repair), 17Figure 41.22 (Dissimilar Metal Weld Overlay), 19Figure 41.23 (Design versus Actual Number of Transient Events),
21Figure 41.24 (Severity of Transient Actual Temperature Change
versus Percentage of Design Basis), 21Figure 41.25 (Effect of Loading Conditions on Environmentally
Assisted Fatigue Crack Growth and Comparison with ASMESection XI Curves), 22, 24
Figure 41.26 (Crack Growth Rate Prediction Model), 22–23Figure 41.27 (Comparison of BWRVIP-14 and Japan Maintenance
Lines), 23Figure 41.29 (Crack Length versus Total Time-on-Test), 24Figure 41.30 (Predicted Crack Growth in Safe End), 24
Section XI, Division 1, Nonmandatory AppendicesFigure 43.1 (Mm Factor for Membrane Stress Intensity Factor), 46Figure 43.2 (Mt Factor vs. Thickness for Bending Stress Intensity
Factor), 46Figure 43.3 (Linearized Representation of Stresses for Surface
Flaws), 46–47Figure 43.4 (Examples of 50°F/hr. Cooldown Curves), 48Figure 43.5 (Assumed Axial Flaws in Circumferential Welds), 49Figure 43.6 (Circumferential Flaws in Girth Welds), 49Figure 43.7 (Fixed LTOP Setpoint Affects Operating Window), 50Figure 43.8 (Charpy V-Notch Surveillance Data Showing RTNDT
Shift Due to Irradiation), 50Figure 43.9 (ASME Code KIC Toughness Curves), 51Figure 43.10 (Static Fracture Toughness Data (KJC) Now
Available, Compared to KIC), 52Figure 43.11 (Original Reference Toughness Curve, with
Supporting Data), 52Figure 43.12 (KIC Reference Toughness Curve with Screened Data
in the Lower Temperature Range), 52Figure 43.13 (Original ASME KIC Data and New Variable TKIC-T),
53Figure 43.14 (Original KIC Toughness Data versus T-T0), 54Figure 43.15 (Fracture Toughness Data Normalized to 1T and
Compared to Code Case N-629 Curve), 54Figure 43.16 (Comparison of Residuals from ASTM E 900-02 and
Recent NRC Embrittlement Trend Curve Equations), 55Figure 43.17 (Estimates of Crack Initiation Compared to P-T
Limits for Normal Cooldown Transient), 55Figure 43.18 (Relationship Between Maximum Postulated Defect
and Allowable Surface Indications), 56Figure 43.19 (Framework for Implementation of Aging
Management Using Inspections and Flaw Evaluation), 59–60Figure 44.8 (Typical Small Volume of Leakage from CDRM
Nozzle), 69, 72
Section VIII, Division 1, Subsection C (continued)
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COMPANION GUIDE TO THE ASME BOILER & PRESSURE VESSEL CODE • 733
Figure 44.9 (Large Volume of Wastage on Davis-Besse ReactorVessel Head), 70, 74
Figure 44.10 (Through-Wall Crack and Part-Depth CircumferentialCrack in V.C. Summer Reactor Vessel Hot-Leg OutletNozzle), 70
Figure 44.11 (Leak from South Texas 1 BMI Nozzle), 71–73Figure 44.12 (Schematic of RPV Top-Head Nozzle Geometry and
Nature of Observed Cracking), 74Figure 44.13 (Plan and Cross-Section through Corroded Part of
Figure 44.23 (Typical Results of Strategic Planning EconomicAnalysis for PPV Head Nozzles), 85
Figure 45.2 (Overall Risk-Informed ISI Process), 90Figure 45.3 (Potential Evolution to Nuclear Systems Code), 109Figure 46.1 (Effect of Fracture Toughness on the Governing
Failure Mechanism), 113–114Figure 46.2 (The EPRI J Estimation Scheme), 115Figure 46.3 (True-Stress True-Strain Curve for A333 Grade 6 Base
Material in NRC/BCL 4111-1 Pipe), 115Figure 46.4 (Fully Plastic J Integral for Circumferential
Through-Wall Flaws in Cylinders), 115–116Figure 46.5 (Determination of Instability J, T, and Associated Load
for Load Control EPFM Analysis), 116–117Figure 46.6 (Net-Section Collapse Load vs. Estimation Scheme
Maximum Load for Axially Loaded 304SS Pipe withThrough-Wall Circumferential Crack), 117
Figure 46.7 (Determination of J and T at Crack Instability forAustenitic SAW at 550°F), 117
Figure 46.8 (DPFAD for Failure Mode Screening Criterion), 119Figure 46.9 (Elastic-Plastic Fracture Mechanics Flow Chart for
Screening Criteria), 119–120Figure 46.10 (Ferritic Material J-T Curves used in EPFM
Evaluation), 119–120Figure 46.11 (Instability Point Determination in DPFAD Space),
15–16Table 41.4 (Comparison of Required Thickness of Weld Overlay
Repair), 20Table 46.1 (Fully Plastic .3Integral for Circumferential
Through- Wall Flaws in Cylinders), 115, 117Table 46.2 (Safety/Structural Factors for Circumferential and Axial
Flaws), 118Table 46.3 (Default Material Properties and Z Factors for Ferritic
Piping with Circumferential Flaws), 117Table 46.4 (Z Factors for Circumferential Flaws in Ferritic Piping),
120–121Table 46.5 (Appendix K Requirements), 122Table H-4211–1 (46.3)(Material Properties for Carbon Steel Base
Metals and Weldments), 119Table H-5310-1, 119Table H-5310-2, 120Table H-6310-1 (Load Multipliers for Carbon Steel Base Metals
and Weldments), 119–120Table H-6310-2 (Load Multipliers for Carbon Steel Base Metals
and Weldments for User-Specified Data), 119–120Table H-6320, 120Task Group for Piping Flaw Evaluation, flaw evaluation in
austenitic steel piping, 127Task Group of Subgroup on Welding, 19Task Group on Risk-Based Examination, 942001 Edition, 20volumetric examination of RPV pressure-retaining shell welds, 7White Paper (Reactor Vessel Integrity Requirements for Levels A
and B Conditions), 13, 55Working Group on Flaw Evaluation, 15, 20, 118Working Group on Implementation of Risk-Based Examination, 95Working Group on Operating Plant Criteria, 49–50, 55
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TD-102 (Thickness Tolerances of Plates and Piping), 360TD-103 (Thickness Tolerances of Plates and Piping), 360TD-104 (Dimensional Symbols Representing Geometry in
Corroded Condition), 360TD-140 (Maximum and Minimum Design Temperatures), 360TD-150 (Design Pressure and Maximum Allowable Working
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COMPANION GUIDE TO THE ASME BOILER & PRESSURE VESSEL CODE • 735
TD-160 (Maximum Allowable Working Pressure), 360TD-200 (Loadings of Transport Tanks), 360–362, 364TD-210 (Maximum Allowable Stresses for Internal and External
Pressure), 362–363TD-301 (Internal Pressure Design), 362TD-312 (Design of Formed Heads under Internal Pressure),
TG-100 (Definitions), 358TG-102, 363TG-110.2, 365TG-130, 363Table TG-130, 364TG-320 (Manufacturer’s Responsibilities), 365TG-330 (Inspector’s Duties), 365TG-430, 366TG-440, 366Article TG-1 (Boundaries of Section XII), 358Article TG-2 (Organization of Section XII), 358Article TG-3 (Requirements on Responsibilities and Duties of
the Owner, User, and Manufacturer), 358, 365Article TG-4 (General Rules for Inspection), 358, 365–366Table 53.2 (Vessel Classification), 365–366
Part TM (Material Requirements), 358Article TM-2 (Rules on Toughness Requirements), 359TM-110 (Nonpressure Parts), 359
TM-111 (CVN Impact Test Method), 359TM-112, 359TM-113, 359TM-114, 359TM-115, 359TM-116 (Unidentified Materials), 359TM-117, 359TM-118 (Bolts and Studs), 359TM-119, 359TM-120, 359TM-121, 359TM-132, 359Table 132.1 (Carbon and Low-Alloy Steels for Transport Tanks),
359Table 132.2 (High-Alloy Steels for Transport Tanks), 359Table 132.3, 359Table 132.4, 359Table 132.5, 359Table 132.6, 359Table 132.7, 359TM-212 (Impact Test Specimens), 359TM-221 (CVN Acceptance Values), 359Figure TM-221, 359TM-222 (Rules on Lateral Expansion Requirements), 359TM-241 (CVN Exemption Rules for Carbon and Low-Alloy
Steel), 359Figure TM-241 (Allowable MDMT for a Given Material and
Thickness), 359–360Figure TM-241.2, 359TM-243 (Allowable Temperature Reduction in Design
Temperature), 359TM-244 (Impact Test Exemption Guidelines for Carbon Steels),
359–360TM-250 (Toughness Rules on High Alloy Steels), 360TM-260 (Ferritic Steels for Transport Tanks), 360TM-262, 360
Part TP (Requirements for Repair, Alteration, Testing and Inspectionfor (Continued Service), 358, 366–367
TP-100, 367TP-200, 366Article TP-1 (General Requirements and Responsibilities), 366Article TP-2 (Use of National Board Inspection Code), 366Article TP-3 (Rules for When Vessels Inspected), 366Article TP-4 (Inspections and Tests for Transport Tanks), 366–367Article TP-5 (Acceptance Criteria for Tests and Inspections), 367Article TP-6 (Reports and Records from Inspections and Tests),
367Part TR (Rules for Pressure Relief Devices), 358Article TR-1 (Regulations on Set Points and Capacity), 358Article TR-2 (“UV” Valves as Alternative to “TV” Valves), 358Article TR-3 (Nonreclosing Pressure Relief Devices), 358Article TR-4 (Capacity Certification), 359Article TR-5 (Marking and Certification), 359
Part TS (Stamping and Certification Requirements, Manufacturer’sData Reports and Other Records), 358–359
Article TS-1 (Content and Method of Stamping), 359Article TS-2 (Obtaining and Applying Code Symbol Stamps), 359Article TS-3 (Data Reports), 359Article TS-4 (Special Requirements), 359
Part TT (Testing Requirements), 358, 366Article TT-1, 366Article TT-2 (Pneumatic and Hydrostatic Testing), 366
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736 • Index
Article TT-3 (Proof Testing for Maximum Allowable WorkingPressure), 366
Article TT-4 (Spark Testing on Vessels with Elastomeric Lining),366
Part TW (Welded Construction Requirements), 358, 364–365TW-100.1 (Requirements for Specific Fluid Service), 364–365Figure TW-100.1, 364TW-130.3 (Weld Joint Categories), 364TW-130.4 (Weld Joint Efficiencies), 364Table TW-130.4, 364TW-130.5 (Rules on Weld Details, Shells and Flat Plates), 364Figure TW-130.5, 364Figure TW-130.5-1, 367Figure TW-130.5-2, 364Figure TW-130.5-3, 364TW-130.7 (Nozzle Attachment Rules), 364Table TW-134, 362TW-140 (Nozzle Attachment Rules), 364Article TW-1 (General Requirements for Tanks Fabricated by
Welding), 357–359pressure relief devices, 357–359reports and records, 357–359requirements, 357–359rules on design requirements, 360–364rules on materials requirements, 359–360stamping, 357, 359Table 53.1 (Design Load Factors for Normal Operations in
Shutdown system, CANDU® 6 reactor, 165SI. See International System of units.Siemens, discontinuation of use of alloy 600, 64Simple pressure vessels, New Approach Directive, 145Simplified elastic-plastic analysis (Notification 501), 272–273SIN-TAP, 121SKI Report TR 89:20 (Research Project 87116), 121, 128Slenderness ratio, 262–267
Part TT (Testing Requirements) (continued)
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COMPANION GUIDE TO THE ASME BOILER & PRESSURE VESSEL CODE • 737
storage, risk analysis and security of, 110Spot radiography, pressure vessels, Japanese codes, 262Spring back, 397SR. See Safety related.SR. See Supporting requirements.SRM. See Staff Requirements Memorandum.SRP-LR. See United States Nuclear Regulatory Commission
Standard Review Plan for review of License RenewalApplications for nuclear power plants.
SSC. See Standards Steering Committee.SSC. See System, structure, or component supports.SSY. See Small-scale yielding.Staff Requirements Memorandum (SRM)
00-0117, 349–350SECY-98-300, 98–99Option 1 (Risk-Informed Changes on a Case-by-Case Basis), 98Option 2 (Risk-Informed Regulation Initiative), 98Option 3 (Direct Risk-Inform the Technical Requirements in
PWSCC cracks, 68, 73use of nickel alloys in, 63–64
Steel bolting, for pressure vessels, French codes, 201–202Steel containment vessel (SCV), Japanese codes, 288
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738 • Index
Steel plates, ferrous and nonferrous material clad, for pressurevessels, French codes, 201–202, 206
Steels, for pressure vessels, Japanese codes, 262, 264Stiffeners, 313–314
of austenitic stainless steel, in BWR plants, 63–64boiling water reactor, and fitness-for-service (Japanese), 277–279in boiling water reactor jet pumps, 5–6
Spanish Regulation in the Nonnuclear Industry, 563Spanish NDE Qualification Methodology, 569caustic, 63
Structural failure probabilities, for piping systems ranking, 95Structural integrity treatment requirements, LSS safety-related items
for, 101Structural reliability model, risk evaluation, 95Structural reliability theory, 126Structural specifications, Canadian standards, 163Structural steel specifications, Canadian standards, 163Stub tube, 12, 13, 24Submerged arc welding (SAW), 15
failure mechanism in welds, 117Z factor value in welds, 117
Sulfur, 67Superheated water boilers, French codes, 191, 217. See also COVAP.
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COMPANION GUIDE TO THE ASME BOILER & PRESSURE VESSEL CODE • 739
Super-heaters, 156Supervisory Control and Data Acquisition (SCADA), 393, 417, 420,
Surface treatmentFrench codes, 191As remedial measure for PWSCC, 63–68
Surry Power Station Unit 1, 100Surveillance program, French codes, 229Surveillance sample coupons, 43Sustained stress intensity factor, 23Swedish SKI Report TR 89:20 (Research Project 87116), 121Syndicat national de la Chaudronnerie, Tôlerie et Tuyauterie (SNCT)
(French organization of pressure vessel and pipingmanaufacturers association), 191–193, 195, 198, 209, 217,254
description and purpose, 191headquarters address, 193Web site, 193
Synthetic aperture radar (SAR) imaging, 418System, structure or component (SSC), 92, 162System-based code (SBC), using risk insights, 109System classification list, CANDU® nuclear power plant, 174System designer, CANDU® nuclear power plants, 172
Tadotsu Technical Test Center of NUPEC, 297Tangential shear stress, concrete containment vessels, 288Taylor Forge method, 317TCs. See Technical committees.Tearing instability, 121, 647Tearing moduli, 116Technical committees (TCs), 168
French codes, 191, 192Technical documentation, of pressure equipment, 137Technical Guidelines for Seismic Design of Nuclear Power Plant,
294, 295, 298Technical Standards and Safety Authority (TSSA), 168Technical Standards on Thermal Facilities for Electricity Generation,
270TEMA Standard, 262, 263Temperature
corrosion rate of hot concentrated aerated boric acid on hot low-alloy steel surface, 74
effect on PWSCC in hydrogen concentration variables, 67ferritic steel fracture toughness and, 53fluctuations in, 21lowering RPV head, 79lower range, fracture toughness and, 51potential for age-related degradation of internals, 57, 59
pressurized water reactor operation, 45of radioactive materials, packaging, 339, 348, 352of radioactive materials, restrictions, 337–338rate of PWSCC initiation and growth, 67reduction, as remedial measure for PWSCC, 82snubber service life and, 105–106stress intensity factor of safety, 45transients, effect on fatigue life, 35upper-shelf, 113
Temperature-dependent material properties, 15, 53Temperature indexing, 44Temperature monitoring devices, in pressure equipment, 154Temper-bead welding, ambient temperature, 19TENPES. See Thermal and Nuclear Power Engineering Society.Tensile strength, PED limit, 310–311Tensile stresses, 66–67, 288Tensile testing, 249
piping, Japanese codes, 297of pressure equipment, 157
10th International Conference on Nuclear Engineering (ICONE 10-22733), 98, 112
against pressurized, 30, 32Thermal sleeve bypass leakage detection system, 9Thermal stress(es), 14, 43, 45–47, 122–123, 245. See also Stresses.
of containment vessels for radioactive materials, 346, 347feedwater nozzle, 9Japanese codes, 287use in predicting crack growth rate, 76from vessel heatup/cooldown, 55
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for industrial piping, French codes, 202for pressure vessels, French codes, 203–205
Thiosulfate ion content, radiographic film processing qualityevaluation, 249
Third party damage (TPD) index, 382Thorium-231, 6513-D influence coefficients, 48Three-layer polyolefin coatings, for pipeline systems, 409–414Three Mile Island (TMI), 89Three Mile Island Unit 1 nuclear power plant, 813 Sm rule, 243Threshold level, distribution of times to occurrence at, 76Through-wall circumferential crack
Through-wall stress, 47Through-wall temperature gradient, 17–18TI. See Transport Index.TIG. See Tungsten inert gas welding. Time-history analysis, stress analysis at crack location, 5–6Time-limited aging analysis (TLAA), 30–32, 34–35, 38, 41Titanium
for pressure equipment, PD 5500 (U.K.), 311for pressure vessels, Japanese codes, 265, 286
Titanium alloysCODAP future specifications, 208for pressure equipment, Japanese codes, 286
TLAA. See Time-limited aging analysis.TMI. See Three Mile Island. TOFD, 254Tokamak-type D-T facility (ITER) for fusion reaction, 291–293Tolerance specifications and pressure boundary standards, Canadian
Transient events, 20–21, 51, 648Transient monitoring, effect on critical locations, 35Transient operation, 8, 9, 614Transient temperature, 53Transmission line, 170, 372, 373Transportable cylinders, Japanese codes, 261Transportation of Explosives and Other Dangerous Articles Act, 335,
337, 341Transportation Security Administration (TSA), 420, 421Transport Canada, regulating transportation of dangerous goods, 168Transport Groups, radioactive materials, 342Transport Index (TI), 351, 352Transport tanks, 357. See also Section XII (Transport Tank Code).Transport unit, 337Transverse flux, for pipeline system assessment, 391Transverse upper-shelf energy (USE), 15, 16, 121, 124, 318, 388To reference fracture toughness transition temperature, 44Trend curve prediction, for shifts in nil-ductility reference
temperature, 43Trending, 58Tresca yield criterion, 316Trigger-point temperature, 125Triple thermal sleeve design, 9Tripping, stiffener, 314, 471Tritium, total package limit, 172, 428, 437Trunk line, 372TRVP. See Trojan Reactor Vessel Package.TSA. See Transportation Security Administration.TSCA. See Toxic Substances Control Act.TS-R-1. See International Atomic Energy Agency, TS-R-1.TSSA. See Technical Standards and Safety Authority.“T” Stamp, 367Tsuruga-1 nuclear power plant, 13
stress-corrosion cracks in alloy 182 welds, 13–14Tsuruga-2 nuclear power plant, 70Tubes and tubing
Tubesheet heat exchangers, French code design rules, 208Tuboscope, 387Tungsten inert gas (TIG) welding, 65“TV” mark, 359Two-parameter method, fracture evaluation of piping, Japanese
codes, 2812004 ICONE-12 conference, 84Type A(F) radioactive materials, Type A radioactive materials, quantities allowed in packaging, 334,
340, 342, 343Type A-Type B quantity provisions of IAEA regulations, 340Type B containers, 342, 354Type B(DP) dual-purpose packages, radioactive material, 339Type B fissile shipping containers, 339Type B(F) radioactive materials, Type B(M)F radioactive materials, 346
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COMPANION GUIDE TO THE ASME BOILER & PRESSURE VESSEL CODE • 741
Type B(M) (Multilateral) packaging standards, 346Type B quantity, definition, 342Type B radioactive materials, quantities allowed in packaging, 334,
340, 342, 345, 355Type B(U)F radioactive materials, Type B(U) (Unilateral) packaging standards, 346, 348Type C packages, 350, 352, 353
U Certificate of Authorization, 264ULC. See Underwriters’ Laboratories of Canada.Ultimate strength, of pressure equipment, 157Ultimate stress, piping, 118Ultimate tensile strength (UTS)
French codes, PED limit, 310and plastic collapse of pipe, 387of pressure equipment, PD 5500 (U.K.), 311–312
Uncracked ligament length, 115Underground cable, testing, 39Underwriters’ Laboratories of Canada (ULC), 160, 162Unfired vessels, 133–134Uniform Building Code, 461Unified Procedure,Uniform dose basis, 351United Kingdom (U.K.) See also British standards, specific types
United Nations Recommendations on the Transport of DangerousGoods, Model Regulations, 357
United Nations Sub-Committee of Experts on the Transport ofDangerous Goods, 357
United States Atomic Energy Act of 1954, 341, 343United States Atomic Energy Commission (AEC), 339
Directorate of Licensing, 344Directorate of Regulatory Operations, 344Division of Materials Licensing, 342
manual, 342Reactor Safety Study, 89
United States Bureau of Statistics, pipeline incidents and propertydamage, 372
United States Coast Guard, 339United States Code, sections 552 and 553, 341, 343United States Competent Authority, 340, 350, 357for transport tanks, 357United States Department of Defense (DOD), 89United States Department of Energy (DOE), 425, 443, 447, 449, 450
decommissioning plan to remove radioactive material, 661nuclear waste disposal, 685
United States Department of Energy, Office of Civilian RadioactiveWaste Management (DOE/OCRWM), 349
United States Department of Health, Education and Welfare, 260United States Department of Homeland Security, 110United States Department of Labor, 260United States Department of Transportation, 357, 358
Hazardous Materials Regulations, 339–341, 357hazardous (including radioactive) material transportation, 350National Response Centerpipeline system assessment requirements, 390special permit, 340–343transport tank code, 357, 359
United States Department of Transportation Office of Pipeline Safety,property damage from oil pipeline incidents, 371
United States Department of Transportation/Pipeline and HazardousMaterial Safety Administration (USDOT/PHMSA), 357
United States Department of Transportations, Research and SpecialPrograms Administration (USDOT/RSPA), 357, 358
United States Hazardous Materials Regulations (HMR), 357United States National Environmental Policy Act of 1969, 30United States National Pipeline Mapping System initiative, 378United States Navy, refuel and defuel U.S. nuclear powered warships,
43, 483United States Nuclear Regulatory Commission (NRC) (USNRC), 3,
306, 440, 441, 444, 446, 447, 448, 450, 512, 514acceptable long-term repair, 19, 81acceptance of weld overlay repairs, 17, 19adoption of ASME Boiler and Pressure Vessel Code, 357Advanced Notice of Public Rulemaking (2000), 98aging management program (AMP), 21, 32allowable crack depth, 14AMP/AMR audits, 34approval of IST pilot programs, 103approval of weld overlay repair application, 19boiling water reactor flaw evaluation, 23boiling water reactor inspection, repair methods, 1, 3boiling water reactor RPV equivalent margin review summary, 16bounding crack growth rates for flaw evaluation, 22defining decommissioning, 471–485draft radiation embrittlement trend equations, 54evaluating crack length direction, 2evaluation of existing plant AMPs, 58Generic Aging Lessons Learned (GALL) Report, 21, 41inspection plans for PWSCC of alloy 600 base materials, 63, 68,
69, 83inspection program to manage effects of fatigue, 38inspection requirements for reactor pressure vessel (RPV) top head
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United States Nuclear Regulatory Commission (NRC) (USNRC) (continued)
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COMPANION GUIDE TO THE ASME BOILER & PRESSURE VESSEL CODE • 743
United States Nuclear Regulatory Commission (USNRC) DocumentControl Desk, 594
United States Nuclear Regulatory Commission (USNRC) DraftRegulatory Analysis (Draft RA), 441
United States Nuclear Regulatory Commission (USNRC) DraftRegulatory Guide, DG-1.121, 594
United States Nuclear Regulatory Commission (USNRC) FederalRegister (FR), 350
revisions of 10CFR71, 450United States Nuclear Regulatory Commission (USNRC) Generic
Letters (GL), 546GL 81-11, 9GL 88-20 (Individual Plant Examination (IPE) for Severe Accident
Vulnerabilities), 33GL 92-01, 15
United States Nuclear Regulatory Commission (USNRC)Information Notices, 30
United States Nuclear Regulatory Commission (USNRC) Issuance ofOrder, EA-03-009 (Establishing Interim InspectionRequirements for Reactor Pressure Vessel Heads atPressurized Water Reactors (PWR)), 72, 73
United States Nuclear Regulatory Commission (USNRC)Maintenance Rule, 94
plant expert panel, 96United States Nuclear Regulatory Commission (USNRC) Metrication
Policy, 351United States Nuclear Regulatory Commission (USNRC) Operations
Center, 355United States Nuclear Regulatory Commission (USNRC) Regulatory
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744 • Index
plus plutonium, 337, 343–345Uranium fuel pellets, 478Uranium hexafluoride, 350, 351Uranium isotopes, 438Uranium metal, 351Uranyl nitrate solutions, 436URN 99/1147 (DTI Guidance Booklet on PED Requirements), 309Usage factor, French codes, 245USDOT/PHMSA. See United States Department of
Transportation/Pipeline and Hazardous Material SafetyAdministration.
USDOT/RSPA. See United States Department of Transportation,Research and Special Programs Administration.
USE. See Upper-shelf energy.USI. See Unresolved Safety Issue.“U” Stamp, 367UT. See Ultrasonic test (UT) (examination).UTS. See Ultimate tensile strength.U-tubes, Japanese codes, 263“UV” mark, 359V. See Volume, internal, of chamber.Vacuum box testing, CANDU® nuclear power plant components, 181Vaccum vessel (VV), Japanese codes, 292Valve(s)
inservice testing (IST), 99pressure-temperature rating, 246probabilistic methods in qualification standards, 109probabilistic risk assessment for, 519risk-informed IST application, 104in scope of PED, 129
Valve design rules, French codes, 246V.C. Summer nuclear power plant, 69
of snubbers, 106startup, 5stress range, steps in calculating, 5
Vibration tests, piping, seismic influences in Japan, 295, 296Visible spectrum and in the very near infrared (VNIR), 418Visual examination/testing (Examination Level: VT-1, VT-2, VT-3),
72. See also VT-1 examination; VT-2 examination; VT-3examination
alloys 82/182 butt weld leakage, 70bare metal, 71–73bare metal for PWSCC, 71, 75bare metal of BMI nozzles, 71bare metal of RPV head surface, 71of BWR shrouds, 3CANDU® nuclear power plant components, 163of crack repair, 15to detect aging effects, 58enhanced, as aging management strategy, 60French codes, 250joint coefficients allowed, 139of low-safety-significant (LSS) pipe segments, 90, 96, 100NRC requirements, 11as Section XI provision, 103
of sparger, 9, 10steam generator tubes, of vessel-to-shroud support weld cracking, 13zirconium alloy components, 176–177
VNIR. See Visible spectrum and in the very near infrared. Voidswelling, irradiation-induced
as aging management strategy, 59–60of BWR steam dryer, 6character recognition height, 60enhanced, 59–60of inner radii surface of nozzles, 10maximum direct examination distance, 60of welds in beltline region, 72
VT-2 examinationas aging management strategy, 59–60of low-safety-significant (LSS) piping segments, 96of reactor vessel pressure-retaining boundary during the system
leak test, 72VT-3 examination
as aging management strategy, 59-60enhanced, 60maximum direct examination distance, 60of welds outside the beltline region, 72
VV. See Vacuum vessel.WASH-1400 study, 89WASRD. See Waste Acceptance System Requirements Document.Waste Acceptance System Requirements Document (WASRD),Waste disposal containers, Waste-heat boilers, 156Waste incineration boilers, 156Waste Isolation Pilot Plant Land Withdrawal Act, Water chemistry
Water environment, 2–3alloy 600 corrosion resistance in high temperature, 63austenitic stainless steels fatigue crack growth rate, 21–22effects on reduction of fatigue life of light-water reactor
components, 21ferritic steels fatigue crack growth rate, 21high-temperature primary, alloy 600 SCC in, 64high-temperature pure, alloy 600 SCC in, 64intergranular stress corrosion cracking of stub tube, 12
Water gauges, visibility, 169Water hammer, and piping failure, 96Water heaters, Canadian standards, 169–170Water-jet conditioning, 84Water-moderated reactors, long-term operation safety aspects, 42Watertube boilers, French codes, 216–217. See also COVAP.WBS. See Work Breakdown Structure.Weibull statistical distribution, 53, 79
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COMPANION GUIDE TO THE ASME BOILER & PRESSURE VESSEL CODE • 745
in predicting initiation of PWSCC in pressurized water reactors(PWRs), 74–76
Welds(s). See also Weld metals, specific types.attachment, 72axial, 8base metal, 52BMI, 72boric acid leakage, 69–71butt, alloy (82/182), 65butt, outlet nozzle, through wall axial crack, 69–70Canadian standards, 170circumferential, 7, 8, 48CRDM, 74crevice, 17defects in pipeline systems, 400dissimilar metal, 19, 72, 83dissimilar metal, flaw evaluation, 277–279fitness-for-service flaw evaluation, Japanese, 276–278flat ends and covers, PD 550 (U.K.), 317–318full penetration, 52, 66full penetration double bevel, generic J-integral fracture resistance curve equation constants, 124girth, 17, 49on high-fatigue lines, 38hot-leg, 69impact testing, 144inservice inspection of HSS segments, inspection in pressure coils exposed to direct radiant heat,
vessel-to-shroud support cracking, 13–14water-jet conditioning of, 82
WeldabilityFrench codes, stainless steels, 233
Weld-deposited hardfacing, French NF M 64-100 standard, 248Welded joint(s)
defects during construction, 102efficiency, pressure vessels, French codes, 203fracture evaluation, Japanese codes, 281French codes, 252In pressure vessels, design of, 65Transport tanks, 364
Welded joint coefficientEN 13445 vs. PD 5500, 309, 310, 312French codes, 252industrial piping, French codes, 212
Welded structures, fracture analysis, 114Weld efficiency factor, French codes, 246Welding, 17–20. See also Gas tungsten arc welding; Shielded metal
arc welding; Tungsten inert gas welding.ambient temperature temper-bead, 19code compliance, 80cold temperatures and, 17criteria for fabrication of shipping containers for radioactive
Welding consumables, for pressure equipment, 143, 144, 201Welding Data Package, French codes, 247Welding Procedure Qualification Test (WPQT), 262, 263, 264Welding procedures, registration, Canadian, 172Welding Research Council (WRC), 308
Welding specifications, Canadian standards, 162, 163Welding Specifications, W series, 162, 163Weld joint efficiency, 201, 203, 208, 212, 222, 290, 363
boilers, French codes, 212, 234pressure vessels, Japanese codes, 262
Weldments, piping, carbon steel, circumferential flaws, 119Weld metal
cladding with duplex, 17crack growth data, 21, 76in dissimilar metal weld overlay, 19requirements for weld overlay repairs, 18
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746 • Index
Weld metals, specific typesalloy 52, 81, 82
in PWSCC-resistant repairs, 82resistance to PWSCC, 81
alloy 82, 63, 65, 66, 67, 70–74, 76, 77, bare metal visual inspection of butt welds, 71butt weld leak, 69chromium concentration, 66composition, 65crack growth behavior in PWSCC, 77crack growth rate testing, 76crack initiation behavior in PWSCC, 79inspection methods/requirements, 71–72location in PWR Vessel, 64primary water stress corrosion cracking of, 63PWSCC cracks in CRDM nozzles, 70PWSCC cracks in inlet/outlet nozzle butt welds, 69–70PWSCC in, 66, 69uses, 64–66weld overlay repair, 81
alloy 152, 65resistance to PWSCC, 67
alloy 182, 17, 65, 66, 69, 76, 77bare metal visual inspection of butt welds, 73butt weld leakage, 69chromium concentration, 66composition, 65crack growth behavior in PWSCC, 77crack growth rate testing, 76crack initiation behavior in PWSCC, 79inspection methods/requirements, 71–72location in PWR Vessel, 64primary water stress corrosion cracking (PWSCC) of, 63PWSCC cracks in CRDM nozzles, 70PWSCC cracks in inlet/outlet nozzle butt joints, 69–70PWSCC in, 66, 69uses, 64–66visual inspection, 71weld overlay repair, 81
Weld overlay repair (WOR), 17–20, 25, 81Weld replacement, as a PWSCC repair, 81–82Weld shrinkage, 67Westinghouse, 193Westinghouse designed PWR power plants, 456
bottom-mounted instrument (BMI) nozzle, 65CRDM nozzles in, 65
use of alloy 82/182 butt welds, 65Westinghouse Owners Group (WOG), 68
Method A application, 97WGM. See Working Group Materials.WGP. See Working Group Pressure.WIPP. See Waste Isolation Pilot Plant.WOG. See Westinghouse Owner’s Group.WOL. See Weld overlay.WOR. See Weld overlay repairs.Working Group Materials (WGM), 142Working Group Pressure (WGP), 131, 143, 144
Guideline 7/17, 143Guideline 7/24, 143
World Health Organization, 365WPQT. See Welding Procedure Qualification Test.WRC. See Welding Research Council.WTO/TBT Agreement, 257, 259, 260Yield (plastic collapse), as pipeline failure mode, 374Yield strength
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