ASME Section III, Div 1 NB 2000 16792
User Manual: NB 2000
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ASME Nuclear Codes and Standards Supporting New Build and Nuclear Manufacturing in South Africa Sandton, South Africa, October 7-8, 2008 Session 3 Section III - Component Design and Construction Ralph S. Hill III, PMP Consulting Engineer, Westinghouse Electric Company Today’s Agenda 1. 2. 3. 4. 5. 6. Small Advertisement for the ASME Code Structure and Use of Section III Code Interpretations and Code Cases Basic Terms & Important Concepts Subsections of Section III Appendices ASME Code Usage 60 Countries – ASME B&PV Code 15 Countries –Section III/XI Nuclear Code 20 Countries – Section III Certificate Holders 30 Countries purchase items to Section III/XI Trend for Boiler Explosions in the U.S. 5000 psi 1600 psi 400 psi 650 psi 500 psi PRE SSU RE L EVE L Today’s Agenda 1. Small Advertisement for the ASME Code 2. Structure and Use of Section III 3. 4. 5. 6. Code Interpretations and Code Cases Basic Terms & Important Concepts Subsections of Section III Appendices ASME Section III, Div. 1 – 8 Subsections • • • • • • • • NCA: General Requirements NB: Class 1 Components NC: Class 2 Components ND: Class 3 Components NE: Class MC Components NF: Supports NG: Core Support Structures NH: Class 1 Components in Elevated Temp. Service – Appendices – Code Cases Nuclear Components Component Classification Class 1 Components (III, Subsection NB) Those components that are part of the primary core cooling system Components (III, Subsection NH) Those components that are used in elevated temperature service Class 2 Components (III, Subsection NC) Those components that are part of various important-tosafety emergency core cooling systems Class 3 Components (III, Subsection ND) Those components that are part of the various systems needed for plant operation Section III Subsection Organization “construction” = • • • • • • • • materials design fabrication examination inspection testing overpressure protection certification organization = NX-2000 NX-3000 NX-4000 NX-5000 NX-5000 NX-6000 NX-7000 NX-8000 NCA-1140 Use of Code Editions and Addenda (a)(1) Under the rules of Section III, the Owner or his designee shall establish the Code Edition and Addenda to be included in the Design Specifications. All items of a nuclear power plant may be constructed to a single Code Edition and Addenda, or each item may be constructed to individually specified Code Editions and Addenda. NCA-1140 Use of Code Editions and Addenda (a)(2) In no case shall the Code Edition and Addenda dates established in the Design Specifications be earlier than: (a) 3 years prior to the date that the nuclear power plant construction permit application is docketed; or (b) The latest edition and addenda endorsed by the regulatory authority having jurisdiction at the plant site at the time the construction permit application is docketed. Today’s Agenda 1. Small Advertisement for the ASME Code 2. Structure and Use of Section III 3. Code Interpretations and Code Cases 4. Basic Terms & Important Concepts 5. Subsections of Section III 6. Appendices Code Interpretations • Provide answers to questions about the Code • Anyone can request – Appendix XX provides instructions • Are published in the Code so answers are available to everyone Inquiry on Code Edition and Addenda 10CFR52 Design Certification Process • Regulator may have approved Edition and Addenda earlier than latest endorsed by regulator at time Combined License Application is docketed • Regulator may have approved Edition and Addenda from the Design Certification Document at time Combined License Application is docketed Inquiry on Code Edition and Addenda Inquiry: As described in NCA-1140(a)(2)(b), does “the endorsement of the latest Code Edition and Addenda by the regulatory authority at the time the construction permit is docketed” include the Code Edition and Addenda endorsed by the regulator through the design certification process and included in the combined operating license (COL) at the time the COL is docketed? Proposed Reply: Yes. NCA-1140 Accompanying Code Change Code Cases Provide: • Relief from an existing Code requirement • Treatment of topics not currently addressed Are: • Permissive, not mandatory • Issued periodically by Code Committee NCA-1140 Code Case Regulatory Approval of Code Cases Other Code Case Regulatory Guides • Regulatory Guide 1.147 lists Code Case Acceptability for Section XI, In-Service Inspection • Regulatory. Guide 1.192 lists the Operation and Maintenance Code Case Acceptability. • Unendorsed Code Cases are listed in Regulatory Guide 1.193 Today’s Agenda 1. Small Advertisement for the ASME Code 2. Structure and Use of Section III 3. Basic Terms & Important Concepts 4. Subsections of Section III 5. Appendices 6. Code Cases Basic Definitions • Material • Component Section III Material Requirements • Material Specification – Section II: Parts A, B, C, & D • Control of Material – Section III: NCA-3800 • Special Material Requirements – Section III: NX- 2000 Important Concepts/Requirements TRACEABILITY • Identification – NCA-3856 Identification, Marking, and Material Control – NB-4122 Material Identification • Certification of Material – NCA-3861 Certification Requirements for Material Organizations – NCA-3862 Certification of Material – NCA-3862.1 Material Certification – NCA-3862.2 Quality System Program Statement Important Concepts/Requirements • Thermal stresses explicitly considered • Basis for stress limits shifted from maximum principal stress theory to more accurate maximum shear stress theory • Fatigue recognized as possible failure mode • Brittle fracture specifically treated • Plastic limit analysis established as a reliable predictor of ductile failure after some plastic action Jurisdictional Boundaries Jurisdictional Boundaries (Detail) Today’s Agenda 1. 2. 3. 4. 5. 6. Small Advertisement for the ASME Code Structure and Use of Section III Code Interpretations and Code Cases Basic Terms & Important Concepts Subsections of Section III Appendices Structure of Section III Subsections Article NX-1000 Article NX-2000 Article NX-3000 Article NX-4000 Article NX-5000 Article NX-6000 Article NX-7000 Article NX-8000 Introduction Material Design Fabrication and Installation Examination (NDE) Pressure Testing Overpressure Protection Nameplates, Stamping & Reports Subsection NB Class 1 Components Article NB-1000 Article NB-2000 Article NB-3000 Article NB-4000 Article NB-5000 Article NB-6000 Article NB-7000 Article NB-8000 Introduction Material Design Fabrication and Installation Examination (NDE) Pressure Testing Overpressure Protection Nameplates, Stamping & Reports Article NB-2000 Materials NB-2100 NB-2200 NB-2300 NB-2400 General Requirements for Material Material Test Coupons and Specimens for Ferritic Steel Material Fracture Toughness Requirements Welding and Brazing Material Article NB-2000 Materials (cont.) NB-2500 Examination and Repair of Pressure Retaining Material ─ Plate ─ Forgings and Bars ─ Seamless and Welded Tubular Products and Fittings ─ Tubular Products and Fittings with Filler Metal ─ Statically & Centrifugally Cast Products ─ Bolts, Studs and Nuts Article NB-2000 Materials (cont.) NB-2600 NB-2700 Material Manufacturers’ Quality System Program Dimensional Standards NB-2160 Deterioration of Material – Outside scope of Section III – Covered in Design Specification Design NB-3000 NB-3100 NB-3200 NB-3300 NB-3400 NB-3500 NB-3600 General Design Design by Analysis Vessel Design Pump Design Valve Design Piping Design NB-3100 General Design • Loading Criteria –Loading conditions (pressure, impact loads, weight, reaction, etc.) –Design loadings (design pressure, design temperature and design mechanical loadings) • Special Considerations –Corrosion –Cladding stresses –Welding (dissimilar welds, fillet weld attachments) • External Pressure Analysis NB-3200 Design by Analysis • Design Criteria – Basis for determining stresses (maximum shear stress theory) – Terms relating to stress analysis – Stress classification – Derivation of stress intensities NB-3200 Design By Analysis (cont.) Stress Limit Primary (Pm, Pb & P L ) Primary plus secondary (P+Q) Peak (Sa) Special Failure Mode Plastic deformation and provide nominal factor of safety on ductile burst pressure Excessive plastic deformation leading to incremental collapse and validate fatigue evaluation elastic analysis Fatigue failure as a result of cyclic loadings Elastic and inelastic instability NB-3200 Design By Analysis (cont.) • Stress Limits for Components – – – – – – • • • • • Design Condition Limits Level A Service Condition Limits Level B Service Condition Limits Level C Service Condition Limits Level D Service Condition Limits Test Condition Limits Fatigue Analysis Procedure Thermal Stress Ratchetting Plastic Analysis Limit Analysis Simplified Elastic Plastic Analysis (Normal) (Upset) (Emergency) (Faulted ) Section III Design by Rule • Uses simple equations • Sets rules on geometry of construction • Uses conservative design values for pressure and temperature • Justification is based on allowing only low stresses combined with “over-design” NB-3300 Vessel Design • General Requirements • Design Considerations – Minimum Pressure Thickness Calculations • Openings and Reinforcement • Design of Welded Construction NB-3300 Vessel Design Design, Fabrication & Examination Integration NB-3352.1 Joints of Category A All welded joints of Category A as defined in NB-3351 shall meet the fabrication requirements of NB-4241 and shall be capable of being examined in accordance with NB-5210. Design NC/ND-3000 NC/ND-3100 NC/ND-3200 NC/ND-3300 NC/ND-3400 NC/ND-3500 NC/ND-3600 General Design Alternate Design Rules for Vessels Vessel Design Pump Design Valve Design Piping Design NC/ND-3700 Electrical and Mechanical Penetration Assemblies NC/ND-3800 Atmospheric Storage Tanks NC/ND-3900 Storage Tanks 0-15 psig (0-103 kPa) Fabrication and Installation NB-4000 NB-4100 NB-4200 NB-4300 NB-4400 NB-4500 NB-4600 NB-4700 General Requirements Forming, Fitting and Aligning Welding Qualifications Making, Examining and Repairing Welds Brazing Heat Treatment Mechanical Joints NB-4100 General Requirements • Certification of materials • Fabrication by certificate holder • Repair of materials NB-4200 Forming Fitting and Aligning • Cutting – Material may be cut to shape and sized by mechanical means, such as: • Machining • Shearing • Chipping • Grinding • Thermal cutting • Recommendations for preheating prior to thermal cutting in Appendix D Preheat Procedures NB-4200 Forming Fitting and Aligning (cont.) • Forming and Bending Processes – May be hot or cold provided impact properties are not reduced below specified values – Heat treatment may be used to restore properties • Qualification of Forming Processes for Impact Property Requirements – Procedure qualification test required – Acceptance standard based on impact properties NB-4200 Forming Fitting and Aligning NB-4200 Forming Fitting and Aligning NB-4200 Forming Fitting and Aligning NB-4200 Forming Fitting and Aligning NB-4200 Forming Fitting and Aligning NB-4300 Welding Qualifications • Types of processes permitted • Required qualifications • Requirements for welding procedure qualification tests • Special qualification requirements for tube-totubesheet welds • Qualification requirements for welding specially designed welded seals NB-4400 Rules Governing Making, Examining and Repairing Welds • • • • Precautions before welding Rules for making welded joints Welding of attachments Repair of weld metal defects NB-4500 thru NB-4700 NB-4500 Brazing – – – – Rules for brazing Qualification requirements Fitting and aligning Examination NB-4600 Heat Treatment – – – – Welding preheat requirements Post-weld heat treatment requirements Intermediate post-weld heat treatment Heat treatment after bending or forming for pipes, pumps and valves – Heat treatment of electroslag welds NB-4700 Mechanical Joints NB-4600 Postweld Heat Treatment NC/ND-4000 Fabrication and Installation NC/ND-4100 NC/ND-4200 NC/ND-4300 NC/ND-4400 NC/ND-4500 NC/ND-4600 NC/ND-4700 General Requirements Forming, Fitting and Aligning Welding Qualifications Making, Examining and Repairing Welds Brazing Heat Treatment Mechanical Joints NC/ND-4800 Expansion Joints Examination NB-5000 NB-5100 NB-5200 NB-5300 NB-5400 NB-5500 General Requirements Examination of Welds Acceptance Standards Final Examination of Vessels Qualification and Certification of NDE Personnel NB-5000 Examination NB-5100 General Requirements for Examination – Fabrication (F) Preservice Base Line (PS) NB-5200 Required Examination of Welds – – – – – – – – Category A Welded Joints (Longitudinal Welds) Category B Welded Joints (Circ Welds) Category C Welded Joints (Flange to Shell, etc.) Category D Welded Joints (Nozzle to vessel, etc.) Fillet, partial penetration and socket welds Structural attachment welds Special welds (e.g., Canopy Seal Welds) Preservice Examination NB-5000 Examination (cont.) NB-5300 Acceptance Standards – – – – – – – NB-5400 NB-5500 Radiographic Ultrasonic Magnetic particle Liquid Penetrant Eddy Current Visual Gas and bubble formation testing Final Examination of Vessels Qualifications and Certification of Nondestructive Examination Personnel NC/ND-5000 Examination • NC/ND-5100 • NC/ND-5200 • NC/ND-5300 • NC/ND-5400 • NC/ND-5500 • NC/ND-5700 General Requirements Examination of Welds Acceptance Standards Final Examination of Components Qualification and Certification of NDE Personnel Examination Requirements for Expansion Joints Testing NB-6000 NB-6100 NB-6200 NB-6300 NB-6400 NB-6600 General Requirements Hydrostatic Tests Pneumatic Tests Pressure Test Gauge Special Test Pressure Situations NB-6000 Testing NC/ND-6000 Testing • • • • • NC/ND-6100 NC/ND-6200 NC/ND-6300 NC/ND-6400 NC/ND-6600 General Requirements Hydrostatic Tests Pneumatic Tests Pressure Test Special Test Pressure Situations • • NC/ND-6500 NC/ND-6900 Atmospheric & 0-15 psig Storage Tanks Proof Tests to Establish Design Pressure Overpressure Protection NB/NC/ND-7000 NB-7100 NB-7200 NB-7300 NB-7400 NB-7500 NB-7600 NB-7700 NB-7800 General Requirements Overpressure Protection Report Relieving Capacity Requirements Set pressures of Pressure Relief Devices Operating and Design Requirements for Pressure Relief Valves Non-reclosing Pressure Relief Devices Certification Marking, Stamping & Data Reports NB-7300 Relieving Capacity Requirements At least 2 relief devices are needed for a system – Capacity of the smallest must exceed 50% of the largest – At least 1 relief device needed for each isolatable component NB-7500 Operating Design Requirements for Pressure Relief Valves • • • • Safety, safety relief and relief valves Pilot operated pressure relief valves Power actuated pressure relief valves Safety valves and pilot operated pressure relief valves with auxiliary actuating devices Article NB/NC/ND-8000 Nameplates, Stamping and Reports NA components that are being installed in the power plant. NPT piping, parts, and appurtenances. N completed ASME Code component that the Certificate Holder supplies to a customer. Today’s Agenda 1. 2. 3. 4. 5. 6. Small Advertisement for the ASME Code Structure and Use of Section III Code Interpretations and Code Cases Basic Terms & Important Concepts Subsections of Section III Appendices Section III, Appendices Mandatory • Invoked within the text of a Code paragraph and are required. Nonmandatory • Invoked by a footnote to a Code paragraph and provide information or guidance. Mandatory Appendix Example NB-3680 Stress Indices and Flexibility Factors NB-3681(d) For piping products not covered by NB-3680, stress indices and flexibility factors shall be established by experimental analysis (Appendix II) or theoretical analysis. Nonmandatory Appendix Example NB-3252 Contents of Design Specifications 3 (a) The Design Specification shall contain sufficient detail to provide a complete basis for Division 1 construction … 3 See Appendix B Section III: Mandatory Appendices Appendix I* Appendix II Appendix III Appendix IV Appendix V Appendix VI Appendix VII Design Stress Intensity Values, Allowable Stresses, Material Properties, and Fatigue Curves Experimental Stress Analysis Basis for Establishing Design Stress Intensity Values and Allowable Stress Values Approval of New Materials Under the ASME Boiler and Pressure Vessel Code Certificate Holders’ Data Report Forms, Instructions, and Application Forms Rounded Indications Charts and Tables for Determining Shell Thickness of Cylindrical and Spherical Components Under External Pressure Appendix XI Rules for Bolted Flange Connections for Class 2 and 3 Components and Class MC Vessels Appendix XII Design Considerations for Bolted Flange Connections Appendix XIII Design Based on Stress Analysis for Vessels Designed in Accordance With NC-3200 Appendix XIV Design Based on Fatigue Analysis for Vessels Designed in Accordance With NC-3200 Appendix XVIII Capacity Conversions for Pressure Relief Valves Appendix XIX Integral Flat Head With a Large Opening Appendix XX* Submittal of Technical Inquiries to the Boiler and Pressure Vessel Committee Appendix XXI Adhesive Attachment of Nameplates Appendix XXII Design of Reinforcement for Come-to-Cylinder Junction Under External Pressure Appendix XXIII* Qualifications and Duties of Specialized Professional Engineers Section III: Nonmandatory Appendices Appendix A Appendix B* Appendix C* Appendix D Appendix E Appendix F* Appendix G Appendix J* Appendix K Appendix L Appendix M Appendix N Appendix O Appendix P Appendix Q Appendix R Appendix S Appendix T Appendix U Appendix V Appendix W Stress Analysis Methods Owner’s Design Specifications Certificate Holder’s Design Report Nonmandatory Preheat Procedures Minimum Bolt Cross-Sectional Area Rules for Evaluation of Service Loadings With Level D Service Limits Protection Against Nonductile Failure Owner’s Design Specifications for Core Support Structures Tolerances Class FF Flange Design for Class 2 and 3 Components and Class MC Vessels Control of Welding, Postweld Heat Treatment, and Nondestructive Examination of Welds Dynamic Analysis Methods Rules for Design of Safety Valve Installations Contents of Certified Material Test Reports Design Rules for Clamp Connections Permissible Lowest Service Metal Temperature From TNDT for Classes 2 and MC Construction Pump Shaft Design Methods Recommended Tolerances for Reconciliation of Piping Systems Rules for Pump Internals Interruption of Code Work Environmental Effects on Components Appendices of Interest Mandatory Appendices I XX Material Properties (Fatigue curves and other properties in older Codes) Submittal of Technical Inquiries to the Boiler and Pressure Vessel Committee XXIII Qualifications and Duties of Specialized Professional Engineers Non-Mandatory Appendices B C E F G W Owner’s Design Specification Certificate Holder’s Design Report Minimum Bolt Cross Sectional Area Rules for Faulted (Level D) Condition Analysis Rules for Fracture Mechanics Analysis Environmental Effects on Components Overall Summary ASME Code: • Is Comprehensive - provides rules for materials, design, fabrication, examination, inspection, testing, certification, and pressure relief • Is Integrated – materials, design, fabrication, inspection and testing rules are integrated – a change in one area may require a change in another • Is Dynamic – evolves and changes to reflect new technology and industry needs Thank You Ralph Hill Westinghouse Nuclear Power hillrs@westinghouse.com +1 724-722-6332
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