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ASME Section VIII SET

pdfstandards — Tue, 03 Dec 2024 05:22:48 +0000

Description
ASME publishes and maintains an International Boiler and Pressure Vessel Code (BPVC) that establishes acceptable margins of safety. ASME Section VIII of the code is dedicated to pressure vessels. It gives detailed requirements for the design, fabrication, testing, inspection, and certification of both fired and unfired pressure vessels. It specifically refers to those pressure vessels that operate at pressures, either internal or external, that exceed 15 psig. The latest update was published in 2023.

Section VIII is divided into 3 sections, each of which cover different vessel specifications.
ASME Section VIII Division 1 addresses the requirements for design, fabrication, inspection, testing, and certification.

ASME Section VIII Division 2 provides requirements on materials, design, and nondestructive examination standards.

ASME Section VIII Division 3 provides guidelines for pressure vessels operating at internal or external pressures above 10,000 psi.

ASME NQA 1 2024

Sun, 20 Oct 2024 10:41:40 +0000

This Standard provides requirements and guidelines for the establishment and execution of quality assurance programs during siting, design, construction, operation and decommissioning of nuclear facilities. Nuclear facilities can include nuclear power plants (NPP), small modular reactors (SMR), and advanced reactors. This Standard reflects industry experience and current understanding of the quality assurance requirements necessary to achieve safe, reliable, and efficient utilization of nuclear energy, and management and processing of radioactive materials. The Standard focuses on the achievement of results, emphasizes the role of the individual and line management in the achievement of quality, and fosters the application of these requirements in a manner consistent with the relative importance of the item or activity.

PDF Catalog

PDF Pages	PDF Title
4	CONTENTS
19	FOREWORD
21	ASME NQA COMMITTEE ROSTER
25	CORRESPONDENCE WITH THE NQA COMMITTEE
26	INTRODUCTION
27	ASME NQA-1–2024 SUMMARY OF CHANGES
32	PART I REQUIREMENTS FOR QUALITY ASSURANCE PROGRAMS FOR NUCLEAR FACILITIES (FROM FORMER NQA-1) INTRODUCTION 100 PURPOSE 200 APPLICABILITY 300 RESPONSIBILITY 400 TERMS AND DEFINITIONS
36	REQUIREMENT 1 Organization 100 GENERAL 200 STRUCTURE AND RESPONSIBILITY 201 General 202 Delegation of Work 300 INTERFACE CONTROL
37	REQUIREMENT 2 Quality Assurance Program 100 GENERAL 200 INDOCTRINATION AND TRAINING 201 Indoctrination 202 Training 300 QUALIFICATION REQUIREMENTS 301 Nondestructive Examination (NDE)
38	302 Inspection and Test 303 Lead Auditor 304 Auditors
39	305 Technical Specialists 400 RECORDS OF QUALIFICATION 401 Inspection and Test Personnel 402 Lead Auditor Personnel 500 RECORDS
40	REQUIREMENT 3 Design Control 100 GENERAL 200 DESIGN INPUT 300 DESIGN PROCESS 400 DESIGN ANALYSES 401 Use of Computer Programs 402 Documentation of Design Analyses
41	500 DESIGN VERIFICATION 501 Methods 600 CHANGE CONTROL
42	601 Configuration Management of Operating Facilities 700 INTERFACE CONTROL 800 SOFTWARE DESIGN CONTROL 900 DOCUMENTATION AND RECORDS
43	REQUIREMENT 4 Procurement Document Control 100 GENERAL 200 CONTENT OF THE PROCUREMENT DOCUMENTS 201 Scope of Work 202 Technical Requirements 203 Quality Assurance Program Requirements 204 Right of Access 205 Documentation Requirements 206 Nonconformances 207 Spare and Replacement Parts 300 PROCUREMENT DOCUMENT REVIEW 400 PROCUREMENT DOCUMENT CHANGES
44	REQUIREMENT 5 Instructions, Procedures, and Drawings 100 GENERAL
45	REQUIREMENT 6 Document Control 100 GENERAL 200 DOCUMENT CONTROL 300 DOCUMENT CHANGES 301 Major Changes 302 Minor Changes
46	REQUIREMENT 7 Control of Purchased Items and Services 100 GENERAL 200 SUPPLIER EVALUATION AND SELECTION 300 BID EVALUATION 400 CONTROL OF SUPPLIER-GENERATED DOCUMENTS 500 ACCEPTANCE OF ITEM OR SERVICE 501 General 502 Methods of Acceptance 503 Certificate of Conformance
47	504 Source Verification 505 Receiving Inspection 506 Postinstallation Testing 507 Acceptance of Services Only 600 CONTROL OF SUPPLIER NONCONFORMANCES 700 COMMERCIAL GRADE ITEMS AND SERVICES
48	800 RECORDS
49	REQUIREMENT 8 Identification and Control of Items 100 GENERAL 200 IDENTIFICATION METHODS 201 Item Identification 202 Physical Identification 300 SPECIFIC REQUIREMENTS 301 Identification and Traceability of Items 302 Limited Life Items 303 Maintaining Identification of Stored Items
50	REQUIREMENT 9 Control of Special Processes 100 GENERAL 200 PROCESS CONTROL 201 Special Processes 202 Acceptance Criteria 203 Special Requirements 300 RECORDS
51	REQUIREMENT 10 Inspection 100 GENERAL 200 INSPECTION REQUIREMENTS 300 INSPECTION HOLD POINTS 400 INSPECTION PLANNING 401 Planning 402 Sampling 500 IN-PROCESS INSPECTION 600 FINAL INSPECTIONS 601 Resolution of Nonconformances 602 Inspection Requirements 603 Modifications, Repairs, or Replacements 604 Acceptance 700 INSPECTIONS DURING OPERATIONS 800 RECORDS
53	REQUIREMENT 11 Test Control 100 GENERAL 200 TEST REQUIREMENTS 300 TEST PROCEDURES 400 TEST RESULTS 500 TEST RECORDS
54	REQUIREMENT 12 Control of Measuring and Test Equipment 100 GENERAL 200 SELECTION 300 CALIBRATION AND CONTROL 301 Calibration 302 Reference Standards 303 Control 304 Commercial Devices 400 RECORDS 401 General
55	402 Reports and Certificates
56	REQUIREMENT 13 Handling, Storage, and Shipping 100 GENERAL 200 SPECIAL REQUIREMENTS 300 PROCEDURES 400 TOOLS AND EQUIPMENT 500 OPERATORS 600 MARKING OR LABELING
57	REQUIREMENT 14 Inspection, Test, and Operating Status 100 GENERAL 200 AUTHORITY 300 STATUS INDICATION
58	REQUIREMENT 15 Control of Nonconforming Items 100 GENERAL 200 IDENTIFICATION 300 SEGREGATION 400 DISPOSITION 401 Control 402 Responsibility and Authority 403 Personnel 404 Disposition 405 Reexamination
59	REQUIREMENT 16 Corrective Action 100 GENERAL
60	REQUIREMENT 17 Quality Assurance Records 100 GENERAL 200 GENERATION OF RECORDS 300 AUTHENTICATION OF RECORDS 400 CLASSIFICATION 401 Lifetime Records 402 Nonpermanent Records 500 RECEIPT CONTROL OF RECORDS 600 STORAGE 601 General
61	602 Facility Types 603 Temporary Storage 700 RETENTION 800 MAINTENANCE OF RECORDS
62	REQUIREMENT 18 Audits 100 GENERAL 200 SCHEDULING 201 Internal Audits 202 External Audits 300 PREPARATION 301 Audit Plan 302 Personnel
63	303 Selection of Audit Team 400 PERFORMANCE 500 REPORTING 600 RESPONSE 700 FOLLOW-UP ACTION 800 RECORDS
64	PART II QUALITY ASSURANCE REQUIREMENTS FOR NUCLEAR FACILITY APPLICATIONS INTRODUCTION 100 PURPOSE 200 APPLICABILITY 300 RESPONSIBILITY 400 PLANNING AND PROCEDURES 401 Planning 402 Procedures
65	500 DEFINITIONS 600 MULTIUNIT FACILITY PROVISIONS 601 Planning and Preparation 602 Documentation 603 Installation 604 Inspection
66	SUBPART 2.1 Quality Assurance Requirements for Cleaning and Cleanness Control of Fluid Systems and Associated Componentsfor Nuclear Facilities 100 GENERAL 101 Definitions
67	200 GENERAL REQUIREMENTS 201 Planning 202 Procedures and Instructions
68	203 Rectification of Unacceptable Cleanness 204 Control of Cleaning Solutions 300 CLEANNESS CRITERIA 301 Cleanness Classification 302 Cleanness Class Criteria
69	303 Hydraulic, Instrument Control, and Lubrication Lines and Systems 304 Cleaning and Flushing Fluid Quality Requirements
70	Tables Table 302.5 Summary Table for Cleanness Classes
71	400 MANUFACTURING PHASE CLEANNESS Table 304.1 Water Requirements
72	500 CLEANNESS PRIOR TO INSTALLATION 600 CLEANNESS DURING INSTALLATION Table 304.4 Flushing Requirements for Hydraulic, Instrument Control, and Lubrication Systems
73	700 MAINTENANCE OF INSTALLATION CLEANNESS 800 PREOPERATIONAL CLEANING 801 Preparations 802 Flushing and Cleaning Methods
74	900 LAYUP AND POSTLAYUP CLEANING 1000 POSTOPERATIONAL REPAIRS AND MODIFICATIONS 1100 RECORDS
75	SUBPART 2.2 Quality Assurance Requirements for Packaging, Shipping, Receiving, Storage, and Handling of Items for Nuclear Facilities 100 GENERAL 101 Definitions 200 GENERAL REQUIREMENTS 201 Classification of Items
76	300 PACKAGING 301 General 302 Levels of Packaging
77	303 Cleaning
78	304 Methods of Preservation 305 Caps, Plugs, Tapes, and Adhesives
79	306 Barrier and Wrap Materials and Desiccants
80	307 Containers, Crating, and Skids 308 Cushioning, Blocking, Bracing, and Anchoring
81	309 Marking
82	400 SHIPPING 401 General 402 Transportation Requirements 403 Precautions During Loading and Transit 404 Identification and Markings 405 Nuclear Material Shipments
83	500 RECEIVING 501 General 502 Receiving Inspection Requirements
84	503 Disposition of Received Items 504 Status-Indicating System 505 Marking 506 Documentation 600 STORAGE 601 General 602 Storage Areas
85	603 Storage Methods 604 Control of Items in Storage
86	605 Removal of Items From Storage 606 Storage Records 700 HANDLING 800 RECORDS
87	SUBPART 2.3 Quality Assurance Requirements for Housekeeping at Nuclear Facilities 100 GENERAL 200 GENERAL REQUIREMENTS 201 Planning and Procedures 202 Classification of Cleanness
88	300 REQUIREMENTS 301 Control of Site Area 302 Control of Facilities 303 Material and Equipment 304 Construction Tools, Supplies, and Equipment
89	305 Surveillance and Inspections 400 RECORDS
90	SUBPART 2.5 Quality Assurance Requirements for Installation, Inspection, and Testing of Structural Concrete, Structural Steel, Soils, and Foundations for Nuclear Facilities 100 GENERAL 101 Definitions
91	200 GENERAL REQUIREMENTS 300 REQUIREMENTS 301 Planning and Procedures 302 Control of Measuring and Test Equipment 303 Laboratory Testing 400 PRECONSTRUCTION VERIFICATION 401 General 402 Materials Suitability 403 Construction Processes
92	500 INSPECTION OF SOILS AND EARTHWORK 501 General 502 Materials 503 Placing and Compacting Equipment 504 Preplacement Preparations 505 Soil Compaction 506 In-Process Tests on Compacted Fill
93	600 INSPECTION OF FOUNDATION PILE AND CAISSON CONSTRUCTION 601 Piles Table 506 Required In-Process Tests for Compacted Fill
94	602 Caissons
95	603 Required Qualification Tests 700 INSPECTION OF CONCRETE CONSTRUCTION 701 General 702 Protection of Materials 703 Measuring, Mixing, and Transporting Equipment 704 Preplacement Preparations
96	705 Concrete Placement 706 Finishing and Repairs 707 Curing
97	708 Stress Transfer of Pretensioned Members 709 Post-Tensioning 710 Shipping and Handling of Precast Concrete Members 711 In-Process Tests on Concrete
98	712 Mechanical Splice Testing 713 Welded Reinforcing Bar Splices 714 Bending of Reinforcement 800 INSPECTION OF STEEL CONSTRUCTION 801 General 802 Supporting Structures 803 Assembly and Erection 804 High-Strength Bolting
99	805 Welding 900 DATA ANALYSIS AND EVALUATION 901 General 902 Concrete and Mechanical Splice Test Data Evaluation and Analysis
100	903 Steel Construction Test Data Evaluation and Analysis 904 Soils Test Data Evaluation and Analysis 1000 RECORDS
101	SUBPART 2.7 Quality Assurance Requirements for Computer Software for Nuclear Facility Applications 100 GENERAL 101 Definitions
102	102 Software Engineering 200 GENERAL REQUIREMENTS 201 Documentation and Records 202 Verification
103	203 Software Configuration Management 204 Problem Reporting and Corrective Action
104	300 SOFTWARE ACQUISITION 301 Procured Software and Software Services 302 Otherwise Acquired Software 400 SOFTWARE ENGINEERING METHOD 401 Planning
105	402 Software Requirements 403 Software Design 404 Software Design Implementation 405 Computer Program Testing
106	406 Operation 407 Maintenance 408 Retirement 500 STANDARDS, CONVENTIONS, AND OTHER WORK PRACTICES
107	600 SUPPORT SOFTWARE 601 Software Tools 602 System Software 700 REFERENCE
108	SUBPART 2.8 Quality Assurance Requirements for Installation, Inspection, and Testing of Mechanical Items for Nuclear Facilities 100 GENERAL 101 Definitions 200 GENERAL REQUIREMENTS 201 Planning and Procedures 202 Prerequisites
109	300 PREINSTALLATION VERIFICATION 301 General 302 Identification 303 Installation Process Control 304 Physical Condition 305 Installation Area Conditions
110	400 INSTALLATION INSPECTIONS 401 General 402 Process and Procedures Control 403 Inspection 404 Installation Checks
111	405 Care of Mechanical Items 500 SYSTEMS TURNOVER INSPECTION AND TESTS 501 General
112	502 Preoperational Testing 503 Cold Functional Tests
113	504 Hot Functional Tests 600 DATA ANALYSIS AND EVALUATION 700 RECORDS
114	SUBPART 2.14 Quality Assurance Requirements for Commercial Grade Items and Services 100 GENERAL 101 Definitions
115	200 CGI DEFINITION APPLICATIONS 300 UTILIZATION 400 TECHNICAL EVALUATION 401 General
116	402 Like-for-Like Items 403 Equivalent Items 500 CRITICAL CHARACTERISTICS 600 METHODS OF ACCEPTING COMMERCIAL GRADE ITEMS AND SERVICES 601 Dedication
117	602 Method 1: Special Test(s), Inspection(s), and/or Analyses 603 Method 2: Commercial Grade Survey of the Supplier
118	604 Method 3: Source Verification 605 Method 4: Acceptable Supplier Item or Service Performance Record
119	606 Supplier Deficiency Correction 700 COMMERCIAL GRADE SERVICES 800 DOCUMENTATION 900 REFERENCES
121	SUBPART 2.15 Quality Assurance Requirements for Hoisting, Rigging, and Transporting of Items for Nuclear Power Plants
122	SUBPART 2.17 Quality Assurance Requirements for Electronic Quality Assurance Records Systems 100 GENERAL 101 Definitions 200 GENERAL REQUIREMENTS 300 RECORD RECOVERY
123	301 Record Recovery Plan 400 ACCESS CONTROL AND RETRIEVAL 401 Access Control 402 Retrieval 500 DIGITAL AND PHYSICAL SECURITY 600 ELECTRONIC DATA INTEGRITY 700 DISPOSAL OF RECORDS 800 ACQUISITION, DEVELOPMENT, AND MAINTENANCE OF ELECTRONIC RECORDS SYSTEMS
124	SUBPART 2.18 Quality Assurance Requirements for Maintenanceof Nuclear Facilities 100 GENERAL 200 GENERAL REQUIREMENTS 201 Responsibilities 202 Procedures
125	203 Cleanness Control 204 Environmental and Seismic Qualifications 205 Work Authorization 206 Equipment History 207 Verification of Maintenance Work 208 Updating of Maintenance Procedures From Vendor Technical Manuals and Industry Bulletins 300 PREVENTIVE MAINTENANCE 301 General 302 Plans and Procedures
126	400 CORRECTIVE MAINTENANCE 401 General 402 Identification, Reporting, and Documenting of Equipment or Systems Requiring Corrective Maintenance 403 Assessments and Evaluations 404 Implementing Corrective Maintenance 500 RECORDS
127	SUBPART 2.19 Quality Assurance Requirements for the Use of Supplier Accreditation for Calibration or Testing Services 100 GENERAL 200 REQUIREMENTS 201 Calibration Services 202 Testing Services
129	SUBPART 2.20 Quality Assurance Requirements for Subsurface Investigations for Nuclear Facilities 100 GENERAL 101 Definitions 200 GENERAL REQUIREMENTS 201 Planning 202 Procedures and Instructions
130	203 Results 204 Personnel Qualifications 300 VERIFICATION 301 General 302 Preinvestigation 303 Field Investigation
131	304 Laboratory Testing 305 Engineering Evaluation and Analysis 400 FIELD INVESTIGATION 401 General 402 Field Operations
132	403 Field Equipment 404 Surveying 405 Boring and Excavating 406 Sampling and Testing 407 Classification and Reporting
133	500 LABORATORY TESTING 501 General 502 Scope
134	503 Test Methods 504 Report of Laboratory Tests 600 ENGINEERING EVALUATION AND ANALYSIS 601 General 602 Analysis of Subsurface Conditions 603 Report of Evaluation and Analysis 700 RECORDS
135	SUBPART 2.22 Quality Assurance Requirements for Management Assessment and Quality Improvement for Compliance With 10 CFR 830 and Department of Energy (DOE) Order 414.1for DOE Nuclear Facilities 100 GENERAL 101 Definitions
136	200 MANAGEMENT ASSESSMENT REQUIREMENTS 201 General 202 Assessment Planning and Scheduling 203 Assessment Process
137	204 Evaluation of Assessment Results 300 QUALITY IMPROVEMENT 301 General 302 Evaluation of Work 303 Quality Improvement Tools
138	304 Improvement Identification and Implementation 305 Improvement Evaluation 400 RECORDS 500 REFERENCES
139	SUBPART 2.25 Quality Assurance Requirements for High-Level Waste Custodians 100 GENERAL 101 Definitions 200 REQUIREMENTS 201 Organization: Interface Control 202 Program
140	203 Design Control 204 Procurement Document Control 205 Instructions, Procedures, and Drawings 206 Document Control
141	207 Control of Purchased Items and Services 208 Inspection
142	209 Test Control 210 Control of Measuring and Test Equipment (M&TE) 211 Control of Nonconforming Items 212 Corrective Action 213 Records
143	214 Audits 215 Scientific Investigations and Data Qualification
144	PART III GUIDANCE FOR IMPLEMENTING PARTS I AND II REQUIREMENTS INTRODUCTION 100 PURPOSE 200 APPLICABILITY
145	SUBPART 3.1 Guidance for Implementing Part I Requirements
146	SUBPART 3.1-1.1 Implementing Guidance for Part I, Requirement 1: Organization 100 GENERAL 200 ORGANIZATIONAL STRUCTURE 300 BASIC PRINCIPLES 301 Management Functions 302 Quality Achievement Functions
147	SUBPART 3.1-2.1 Implementing Guidance for Part I, Requirement 2: Quality Assurance Programs 100 GENERAL 200 PROGRAM FORMAT 300 PROGRAM DEVELOPMENT 301 Purpose and Scope
148	302 Timing 400 WORK REQUIREMENTS AND PERFORMANCE 401 Basis and Structure 402 Planning 500 WORK PROCESSES 501 Process Management 502 Graded Approach
149	600 TRAINING AND QUALIFICATION 700 ASSESSMENT OF PERFORMANCE
150	SUBPART 3.1-2.2 Implementing Guidance for Part I, Requirement 2: Quality Assurance Programs, Lead Auditor Qualification 100 GENERAL 200 EDUCATION AND EXPERIENCE 201 Education (4 Credits Maximum) 202 Experience (9 Credits Maximum) 203 Other Credentials of Professional Competence (2 Credits Maximum) 204 Rights of Management (2 Credits Maximum) 300 RECORDS
151	Figures Figure 300 Sample Form for Record of Lead Auditor Qualification
153	SUBPART 3.1-2.3 Implementing Guidance for Part I, Requirement 2: Quality Assurance Programs, Inspection,and Test Personnel Qualification 100 GENERAL 200 FUNCTIONAL QUALIFICATIONS 201 Level I Personnel Capabilities 202 Level II Personnel Capabilities 203 Level III Personnel Capabilities 300 EDUCATION AND EXPERIENCE QUALIFICATIONS 301 Level I 302 Level II
154	303 Level III 400 USE OF INSPECTION AND TEST PERSONNEL
155	SUBPART 3.1-2.4 Implementing Guidance for Part I, Requirement 2: Quality Assurance Programs, Management Assessment of the QA Program 100 GENERAL 200 TYPES OF MANAGEMENT ASSESSMENT 201 QA Program Management Assessment 202 Supplemental Management Assessments 300 SCHEDULING AND PLANNING 301 Scheduling
156	302 Planning Assessments 400 ASSESSMENT PERFORMANCE 401 Assessment Team Responsibilities Table 301
157	402 Assessment Methodologies 500 REPORTING
158	SUBPART 3.1-2.5 Risk-Informed Approach for the Treatment of Structures, Systems, and Components for Nuclear Facilities Not Subject to NRC Regulation11NRC licensed users should consult NEI 00-04, 10 CFR 50.69 SSC Categorization Guideline 100 GENERAL 101 Definitions 102 RISC Descriptions
159	200 SSC CATEGORIZATION 201 SSC Categorization References 202 SSC Categorization Direction 203 SSC Categorization Regulator Approval 204 SSC Categorization Records 300 ADAPTATION Figure 102-1 §50.69 RISC Categories
160	301 Adaptation Application 400 IMPLEMENTATION GUIDANCE 401 RISC-1 SSCs Figure 200-1 Summary of NEI 00-04 Categorization Process
161	402 RISC-2 SSCs 403 RISC-3 SSCs
163	404 RISC-4 SSCs 500 COMPUTER SOFTWARE 600 FEEDBACK AND PROGRESS ADJUSTMENT 601 Monitor RISC-1 and RISC-2 Item Performance 602 Evaluate RISC-3 Related Inspections 700 10 CFR 50.69 IMPLEMENTATION REFERENCES FROM EPRI
164	SUBPART 3.1-3.1 Implementing Guidance for Part I, Requirement 3: Design Control 100 GENERAL 200 DESIGN INPUT
165	300 DESIGN PROCESS
166	400 DESIGN ANALYSIS 401 Use of Computer Programs
167	500 DESIGN VERIFICATION 600 CHANGE CONTROL
168	700 USE OF REVERSE-ENGINEERING TECHNIQUES Table 401.4 Scenarios for Use of Computer Programs in Design Analysis
169	800 INTERFACE CONTROL 900 DOCUMENTATION AND RECORDS 1000 ADDITIONAL GUIDANCE AND RECOMMENDED READING
170	SUBPART 3.1-4.1 Implementing Guidance for Part I, Requirement 4: Procurement Document Control 100 GENERAL 200 PROCUREMENT DOCUMENT REVIEW 300 TYPICAL SCOPE OF PROCUREMENT EFFORT 301 Design, Construction, and Testing Phases 302 Operational Phase
171	400 CATEGORIZATION OF PROCUREMENT ACTIONS 500 GENERAL LOGIC CONSIDERATIONS 501 Importance of Malfunction or Failure of the Item to Plant Safety 502 Complexity or Uniqueness of the Item 503 Need for Special Controls and Surveillance Over Processes and Equipment 504 Degree to Which Functional Compliance Can Be Demonstrated by Inspection and Test 505 Quality History and Degree of Standardization of the Item
172	600 LOGIC CHART 700 METHODS OF SPECIFYING QUALITY ASSURANCE PROGRAM REQUIREMENTS 701 Example of Specifying the Overall Method
173	Figure 600 Logic Chart for Determining Appropriate Quality Requirements
174	702 Example of Specifying the Unique Order Method
175	SUBPART 3.1-7.1 Implementing Guidance for Part I, Requirement 7: Control of Purchased Items and Services 100 GENERAL 200 PROCUREMENT PLANNING 300 SUPPLIER SELECTION 301 Performance History 302 Quality Records
176	303 Facility Survey 400 BID EVALUATION 500 PURCHASER/SUPPLIER COMMUNICATIONS 600 CONTROL OF CHANGES IN ITEMS OR SERVICES 601 Bid Evaluation Changes 602 Control of Changes 603 In Process Control of Deviations 700 PRODUCT ACCEPTANCE 701 Source Verification 702 Receiving Inspection
177	703 Certificate of Conformance 704 Postinstallation Testing 705 Determining Authenticity
178	SUBPART 3.1-10.1 Implementing Guidance for Part I, Requirement 10: Inspection 100 GENERAL 200 INSPECTION AND PROCESS MONITORING 300 IN-SERVICE INSPECTION
179	SUBPART 3.1-15.1 Implementing Guidance for Part I, Requirement 15: Control of Nonconforming Items 100 GENERAL 200 IDENTIFICATION 201 Validation 202 Evaluation 300 SEGREGATION 400 DISPOSITION 401 Allowable Use and Documentation of Preapproved Reject or Rework Process
180	Figure 100 Nonconforming Item Process Chart
181	402 Disposition Control, Documentation, and Closure
182	SUBPART 3.1-16.1 Implementing Guidance for Part I, Requirement 16: Corrective Action 100 GENERAL 200 CORRECTIVE ACTION 300 BASIC CORRECTIVE ACTION ELEMENTS 301 Identification and Documentation 302 Classification
183	Figure 300 Corrective Action Process Chart
184	303 Report to Management 304 Cause Determination 305 Corrective Action Plan 306 Verification of Implementation 307 Effectiveness Review 308 Closure 309 Trend Analysis
185	400 MANAGEMENT INVOLVEMENT 500 PROCESS CHART
186	SUBPART 3.1-16.2 Implementing Guidance for Part I, Requirement 16: Trend Analysis 100 GENERAL 200 DEFINITIONS 300 TRENDING PROGRAM
187	400 DATA COLLECTION 401 Program and Preparation for Effective Trending 402 Data Collection Sources and Methods 500 TREND ANALYSIS PROCESS 501 Graded Approach to Trending 502 Trend Analysis Staff and Teams 503 Data Sorting and Categorization
188	504 Trend Significance Analysis 600 TREND REPORTING 601 Report Content 602 Reporting Frequency
189	700 RECORDS 800 REFERENCES AND RECOMMENDED READING
190	SUBPART 3.1-17.1 Implementing Guidance for Part I, Requirement 17: Quality Assurance Records 100 GENERAL 101 Generation of Records 102 Authentication of Records 103 Indexing 104 Corrected Information in Records 105 Storage
191	106 Preservation and Safekeeping 107 Facilities and Containers 108 Retrieval 109 Records Transfer to Owner or Purchaser 110 Record Destruction 200 LIST OF TYPICAL LIFETIME RECORDS 201 Design and Safety Basis Records 202 Procurement Records
192	203 Manufacturing Records 204 Installation Construction Records 205 Preoperational and Start-Up Test Records 206 Operation Records
193	207 Decommissioning and Destruction
194	SUBPART 3.1-17.2 Implementing Guidance for Part I, Requirement 17: Quality Assurance Records, Electronic Records 100 GENERAL 101 Definitions 200 AUTHENTICATION OF RECORDS 201 Electronic Signatures
195	300 GENERATION OF RECORDS 301 Electronic Records Systems 302 Conversion of Media 303 Indexing Records 400 RECEIPT CONTROL OF RECORDS
196	500 STORAGE 501 Environmental Considerations 502 Facility and System Access 503 Temporary Storage 504 Portable Electronic Media 600 ACCESS CONTROL AND RETRIEVAL
197	700 DISPOSAL OF RECORDS 701 Guidance Factors
198	800 MAINTENANCE OF RECORDS SYSTEM 900 SYSTEM INTEGRITY AND RECORD RECOVERY
199	SUBPART 3.1-18.1 Implementing Guidance for Part I, Requirement 18: Audits 100 GENERAL 200 DEFINITIONS 300 AUDIT ADMINISTRATION 301 Purpose 302 Elements 303 Frequency of Audits
200	304 Shared External Audits 305 Supplemental Audits 306 Audit Equivalents 400 PREPARATION FOR AUDITING 401 Team Selection and Assignment
201	402 Planning the Audit
202	403 Audit Notification 500 AUDIT PERFORMANCE 501 Pre-Audit Conference 502 Methods 503 Audit Implementation
203	504 Post-Audit Conference 600 REPORTING 700 RESPONSE 800 FOLLOW-UP ACTION
204	SUBPART 3.1-18.2 Implementing Guidance on Classification and Handling Audit Issues 100 GENERAL 200 INTRODUCTION 300 CLASSIFICATION OF ISSUES 301 Finding 302 Observation 303 Opportunity for Improvement 304 Strength
205	400 RESPONSES TO ISSUES 401 Finding Responses 402 Observation Responses 403 Opportunities for Improvement 404 Strengths 500 FOLLOW-UP 501 Evaluate the Written Response 502 Monitor Corrective Actions 503 Reaudit
206	SUBPART 3.1-18.3 Implementing Guidance for Part I, Requirement 18: Audits, Use of Surveillance 100 GENERAL 200 PLANNING AND SCHEDULING 201 Planning 202 Scheduling 300 PREPARATION
207	400 PERFORMANCE 401 Notification 402 Conduct of Surveillance 402.1 402.2
208	500 REPORTING AND COMMUNICATION 600 RESOLUTION OF ISSUES 601 Response to Surveillance Reports 602 Follow-Up
209	SUBPART 3.2 Guidance for Implementing Part II Requirements
210	SUBPART 3.2-2.1 Implementing Guidance for Part II, Requirement 2.1: Cleaning of Fluid Systems
211	SUBPART 3.2-2.7.1 Implementing Guidance for Part II, Requirement 2.7: Quality Assurance Requirements for Computer Softwarefor Nuclear Facility Applications 100 GENERAL 101 Definitions
212	102 Software Engineering
213	200 GENERAL REQUIREMENTS 201 Documentation and Records 202 Verification 203 Software Configuration Management
214	204 Problem Reporting and Corrective Action 300 SOFTWARE ACQUISITION 301 Procured Software and Software Services 302 Otherwise Acquired Software
215	400 SOFTWARE ENGINEERING METHOD 401 Planning 402 Software Requirements 403 Software Design
216	404 Software Design Implementation 405 Computer Program Testing
218	406 Operation
219	407 Maintenance
220	408 Retirement 500 STANDARDS, CONVENTIONS, AND OTHER WORK PRACTICES 600 SUPPORT SOFTWARE 601 Software Tools 602 System Software 700 REFERENCES
221	SUBPART 3.2-2.7.2 Implementing Guidance on the Requirements of ASME NQA-1, Parts I and II for Software Used for Nuclear Facility Applications 100 GENERAL 101 Terms and Definitions 200 FLOWCHART APPROACH 201 Flowcharts 202 Legend
222	Figure 201-1 Software Engineering
227	Figure 201-2 Software Design Requirements
228	Figure 201-3 Software Configuration Management
229	Figure 201-4 Support Software and Tools
230	Figure 201-5 Problem Reporting and Corrective Action
232	Figure 201-6 Software Design
233	Figure 201-7 Software Reviews
234	Figure 201-8 Software Design Implementation
235	Figure 201-9 Computer Program Testing
238	Figure 201-10 Software Operation, Maintenance, and Retirement
239	Figure 201-11 Software Acquisition
241	Figure 201-12 Computer Program Use in Design Analysis
242	Figure 202-1 Legend for Flowcharts
243	SUBPART 3.2-2.14 Implementing Guidance for Part II, Requirement 2.14: Quality Assurance Requirements for Commercial Grade Items and Services, Commercial Grade Computer Programs, and Software Services 100 GENERAL 101 Definitions 200 DEFINITION APPLICATIONS
244	300 UTILIZATION 400 TECHNICAL EVALUATION 401 Technical Evaluation Considerations
245	402 Technical Evaluation Documentation Review 500 CRITICAL CHARACTERISTICS 501 Computer Program Critical Characteristics
246	502 Computer Program Acceptance Criteria 600 METHODS FOR ACCEPTING COMMERCIAL GRADE ITEMS AND SERVICES 601 Dedication 602 Method 1: Special Test(s), Inspection(s), and/or Analyses
247	Table 501 Typical Critical Characteristics to Consider for Computer Programs
251	603 Method 2: Commercial Grade Survey of the Supplier
252	604 Method 3: Source Verification 605 Method 4: Acceptable Supplier Item or Service Performance Record 700 COMMERCIAL GRADE SOFTWARE SERVICES 800 DOCUMENTATION 801 Computer Program Procurement Documents
253	802 Dedication Documentation 803 User Documentation 900 REFERENCES
254	SUBPART 3.2-2.15 Implementing Guidance for Part II, Requirement 2.15: Hoisting, Rigging, and Transportation 100 GENERAL
255	SUBPART 3.2-2.18.1 Implementing Guidance for Part II, Requirement 2.18: Maintenance of Nuclear Facilities, Establishing and Maintaining Equipment Histories 100 GENERAL 200 DEVELOPING AN EQUIPMENT HISTORY 300 MAINTAINING HISTORICAL DATA 400 USING MAINTENANCE HISTORY
256	SUBPART 3.2-2.18.2 Implementing Guidance for Part II, Requirement 2.18: Maintenance of Nuclear Facilities, Engineering Evaluations of Equipment Failures 100 INTRODUCTION 200 ENGINEERING EVALUATIONS 201 Initiating Engineering Evaluations 202 Performing Engineering Evaluations
257	203 Using Engineering Evaluation Results
258	SUBPART 3.2-2.20 Implementing Guidance for Part II, Requirement 2.20: Subsurface Investigations for Nuclear Facilities,Sample Control and Identification 100 GENERAL 200 CONTROL OF SUBSURFACE INVESTIGATIONS 300 IDENTIFICATION OF SAMPLES 400 CONTROL OF SAMPLES
259	SUBPART 3.3 Nonmandatory Guidance on Quality Assurance Program Requirements for Collection of Scientific and Technical Information for Site Characterization of High-Level Nuclear Waste Repositories
260	PART IV GUIDANCE ON THE APPLICATIONAND USE OF ASME NQA-1 INTRODUCTION 100 PURPOSE 200 APPLICABILITY
261	SUBPART 4.1 Guides on Use and Comparison of NQA-1 With Other Quality Requirements SUBPART 4.1.1 Guidance to Modification of an ISO 9001:2015 Quality Management System for Compliance With NQA-1, Part I 100 PURPOSE AND SCOPE 200 BACKGROUND 300 TERMS AND DEFINITIONS 400 COMPARISON TABLES
262	Table 400-1 NQA-1, Part I, Requirement 1 (Organization) and Corresponding ISO 9001 Clauses
263	Table 400-2 NQA-1, Part I, Requirement 2 (Quality Assurance Program) and Corresponding ISO 9001 Clauses
264	Table 400-3 NQA-1, Part I, Requirement 3 (Design Control) and Corresponding ISO 9001 Clauses
265	Table 400-4 NQA-1, Part I, Requirement 4 (Procurement Document Control) and Corresponding ISO 9001 Clauses Table 400-5 NQA-1, Part I, Requirement 5 (Instructions, Procedures, and Drawings) and Corresponding ISO 9001 Clauses
266	Table 400-6 NQA-1, Part I, Requirement 6 (Document Control) and Corresponding ISO 9001 Clauses
267	Table 400-7 NQA-1, Part I, Requirement 7 (Control of Purchased Items and Services) and Corresponding ISO 9001 Clauses
268	Table 400-8 NQA-1, Part I, Requirement 8 (Identification and Control of Items) and Corresponding ISO 9001 Clauses Table 400-9 NQA-1, Part I, Requirement 9 (Control of Special Processes) and Corresponding ISO 9001 Clauses
269	Table 400-10 NQA-1, Part I, Requirement 10 (Inspection) and Corresponding ISO 9001 Clauses Table 400-11 NQA-1, Part I, Requirement 11 (Test Control) and Corresponding ISO 9001 Clauses
270	Table 400-12 NQA-1, Part I, Requirement 12 (Control of Measuring and Test Equipment) and Corresponding ISO 9001 Clauses
271	Table 400-13 NQA-1, Part I, Requirement 13 (Handling, Storage, and Shipping) and Corresponding ISO 9001 Clauses Table 400-14 NQA-1, Part I, Requirement 14 (Inspection, Test, and Operating Status) and Corresponding ISO 9001 Clauses
272	Table 400-15 NQA-1, Part I, Requirement 15 (Control of Nonconforming Items) and Corresponding ISO 9001 Clauses Table 400-16 NQA-1, Part I, Requirement 16 (Corrective Action) and Corresponding ISO 9001 Clauses
273	Table 400-17 NQA-1, Part I, Requirement 17 (Quality Assurance Records) and Corresponding ISO 9001 Clauses
274	Table 400-18 NQA-1, Part I, Requirement 18 (Audits) and Corresponding ISO 9001 Clauses
275	SUBPART 4.1.2 Guidance on the Use of NQA-1–2008/1a–2009 for Compliance With Department of Energy Quality Assurance Requirements 10 CFR 830, Subpart A and DOE O 414.1 100 PURPOSE 200 INTRODUCTION 300 DOE RULE AND ORDER GENERAL QAP REQUIREMENTS 400 DOE RULE AND ORDER QA CRITERIA
276	Table 300 10 CFR 830 Subpart A, Dated January 10, 2001 §830.121, Quality Assurance Program; DOE O 414.1C, Dated June 17, 2005
277	Table 400 10 CFR 830 Subpart A, Dated January 10, 2001 §830.122, Quality Assurance Criteria
280	SUBPART 4.1.3 Guidance on the Use of NQA-1–2015 for Compliance With 10 CFR 71 or 10 CFR 72 Requirements 100 PURPOSE 200 INTRODUCTION 300 SUMMARY RESULTS
281	Table 300 10 CFR 71 and 10 CFR 72 Criteria Addressed by ASME NQA-1
286	SUBPART 4.1.4 Guidance to Modification of an IAEA GS-R-3 Quality Program to Meet ASME NQA-1a–2009 Requirements and Modification of an NQA-1a–2009 Quality Program to Meet IAEA GS-R-3 Requirements 100 PURPOSE AND SCOPE 200 APPLICABILITY 300 BACKGROUND 301 Global Uses of NQA-1 and IAEA GS-R-3 302 Conceptual Approaches to the Development of NQA-1 and IAEA GS-R-3
287	400 HOW TO USE THIS GUIDE TO ACHIEVE COMPLIANCE WITH IAEA GS-R-3 OR NQA-1 401 Two Perspectives and Two Tables 402 How to Use Tables I and II
288	Table I The Extent to Which GS-R-3 Addresses NQA-1 Requirements
297	Table II The Extent to Which NQA-1 Addresses GS-R-3 Requirements
305	SUBPART 4.1.5 Guidance to Modification of an ANSI/ANS-15.8-1995 (R2005; R2013) Quality Program to Meet NQA-1–2012 Requirements 100 INTRODUCTION 200 APPLICABILITY 300 BACKGROUND 400 TERMS AND DEFINITIONS 500 HOW TO USE THE GUIDE TO ACHIEVE COMPLIANCE WITH NQA-1 OR AN ANSI/ANS-15.8 QUALITY PROGRAM
306	Table 200-1 Corresponding NQA Sections (Introduction) to ANSI/ANS-15.8 Table 200-2 Corresponding NQA Sections (Requirement 1) to ANSI/ANS-15.8
307	Table 200-3 Corresponding NQA Sections (Requirement 2) to ANSI/ANS-15.8
308	Table 200-4 Corresponding NQA Sections (Requirement 3) to ANSI/ANS-15.8
309	Table 200-5 Corresponding NQA Sections (Requirement 4) to ANSI/ANS-15.8 Table 200-6 Corresponding NQA Section (Requirement 5) to ANSI/ANS-15.8
310	Table 200-7 Corresponding NQA Sections (Requirement 6) to ANSI/ANS-15.8
311	Table 200-8 Corresponding NQA Sections (Requirement 7) to ANSI/ANS-15.8
312	Table 200-9 Corresponding NQA Sections (Requirement 8) to ANSI/ANS-15.8 Table 200-10 Corresponding NQA Sections (Requirement 9) to ANSI/ANS-15.8
313	Table 200-11 Corresponding NQA Sections (Requirement 10) to ANSI/ANS-15.8
314	Table 200-12 Corresponding NQA Sections (Requirement 11) to ANSI/ANS-15.8 Table 200-13 Corresponding NQA Sections (Requirement 12) to ANSI/ANS-15.8
315	Table 200-14 Corresponding NQA Sections (Requirement 13) to ANSI/ANS-15.8 Table 200-15 Corresponding NQA Section (Requirement 14) to ANSI/ANS-15.8
316	Table 200-16 Corresponding NQA Sections (Requirement 15) to ANSI/ANS-15.8 Table 200-17 Corresponding NQA Section (Requirement 16) to ANSI/ANS-15.8
317	Table 200-18 Corresponding NQA Sections (Requirement 17) to ANSI/ANS-15.8 Table 200-19 Corresponding NQA Sections (Requirement 18) to ANSI/ANS-15.8
318	Table 200-20 Corresponding NQA Sections (Parts I and II) to ANSI/ANS-15.8
319	Table 200-21 Corresponding NQA Sections (Part II) to ANSI/ANS-15.8
320	SUBPART 4.1.6 Guidance to Modification of an NQA-1–2019 Quality Program to Meet IAEA GSR Part 2 (2016) Management System Requirements 100 PURPOSE AND SCOPE 200 APPLICABILITY 300 BACKGROUND 301 Global Uses of NQA-1 and GSR Part 2 302 Conceptual Approaches to the Development of NQA-1 and GSR Part 2 400 HOW TO USE THIS GUIDE TO ACHIEVE COMPLIANCE WITH NQA-1
321	Table 400-1 The Extent to Which NQA-1 Addresses GSR Part 2 Requirements
327	SUBPART 4.2 Guides on Application of NQA-1 to Work Processes and Activities SUBPART 4.2.1 Guidance on Graded Application of Nuclear Quality Assurance (NQA) Standard for Research and Development 100 INTRODUCTION 101 Research and Development and Conventional NQA Applications 102 The Quality and Nature of Research and Development Work 103 Research and Development in the Technology Life Cycle
328	104 Research and Development Process Interfaces and Continuity Figure 103 Technology Life Cycle
329	200 RESEARCH AND DEVELOPMENT QUALITY ASSURANCE THROUGH PEER REVIEW 300 A GRADED APPROACH 301 Basic Research 302 Applied Research 303 Development Work and Research and Development Support Activities 400 QUALITY ASSURANCE RESEARCH AND DEVELOPMENT APPLICATIONS
330	500 RESEARCH AND DEVELOPMENT QUALITY ASSURANCE GLOSSARY OF TERMS 600 APPLICATION OF NQA-1 TO RESEARCH AND DEVELOPMENT ACTIVITIES 601 NQA-1, Requirement 1: Organization
331	602 NQA-1, Requirement 2: Quality Assurance Program Table 600-1 Guidance on Graded Application of the NQA Standard for Research and Development Table 600-2 Software Within Research and Development
332	603 NQA-1, Requirement 3: Design Control 604 NQA-1, Requirement 4: Procurement Document Control 605 NQA-1, Requirement 5: Instructions, Procedures, and Drawings
333	606 NQA-1, Requirement 6: Document Control 607 NQA-1, Requirement 7: Control of Purchased Materials, Items, and Services 608 NQA-1, Requirement 8: Identification of Control Items 609 NQA-1, Requirement 9: Control of Processes 610 NQA-1, Requirement 10: Inspection 611 NQA-1, Requirement 11: Test Control
334	612 NQA-1, Requirement 12: Control of Measuring and Test Equipment 613 NQA-1, Requirement 13: Handling, Storage, and Shipping 614 NQA-1, Requirement 14: Inspection, Test, and Operating Status 615 NQA-1, Requirement 15: Control of Nonconforming Items 616 NQA-1, Requirement 16: Corrective Action
335	617 NQA-1, Requirement 17: Quality Assurance Records 618 NQA-1, Requirement 18: Audits 700 TECHNOLOGY LIFE CYCLE (SUBPART 4.2.1) AND TECHNOLOGY READINESS LEVELS
336	Table 700 Comparison of Subpart 4.2.1 Technology Life Cycle and Technology Readiness Levels
337	SUBPART 4.2.3 Guidance on Qualification of Existing Data 100 GENERAL 200 SELECTING DATA SETS FOR QUALIFICATION 300 DATA QUALIFICATION PROCESS 301 Data Qualification Planning 302 Data Qualification Preparation 303 Data Qualification Attributes 400 QUALIFICATION METHODS 401 Quality Assurance Program Equivalency Method
338	402 Data Corroboration Method 403 Confirmatory Testing Method 404 Peer Review Method 500 DOCUMENTATION OF RESULTS
339	SUBPART 4.2.4 Guidance on the Control of Scientific Investigations 100 GENERAL 101 Definitions 200 PLANNING AND PERFORMING SCIENTIFIC INVESTIGATIONS 201 Scientific Investigation Planning 202 Performing Scientific Investigations
340	300 TECHNICAL DATA 301 Data Identification 302 Data Validation, Verification, and Qualification 303 Data Usage 304 Model Validation 400 SAMPLE CONTROL
341	500 PEER REVIEW 501 General Guidance for Peer Review
342	SUBPART 4.2.5 Guidance on the Transition From Construction to Operationfor Nuclear Facilities 100 GENERAL 200 APPLICABILITY 201 Regulatory 300 TRANSITION RECOMMENDATIONS 301 Turnover From Construction to Testing
343	302 Testing of Facility Systems and Components
344	303 Turnover to Operations 304 Preparation for Operation 305 Start-Up Test Program
345	400 RECORDS
346	SUBPART 4.2.6 Guidance on Quality Assurance for Decommissioningof Nuclear Facilities 100 GENERAL 101 Definitions 200 PREREQUISITES
347	300 PREDECOMMISSIONING CHECKS 301 General 302 Plans, Specifications, and Procedures
348	303 Identification 304 Physical Condition
349	305 System Protection 400 CONTROL DURING DECOMMISSIONING 401 General 402 Processes and Procedures Control
350	403 Checks of Systems, Components, and Equipment Required for Decommissioning 404 Checks During Decommissioning 500 POSTDECOMMISSIONING CHECKS 600 RECORDS
351	SUBPART 4.2.7 Guidance on Peer Review 100 GENERAL 200 TERMS AND DEFINITIONS 300 PERFORMANCE 301 General
352	302 Planning
353	303 Methods 400 REVIEWER SELECTION 401 Competence/Technical Expertise 402 Independence/Conflict of Interest 403 Balance 404 Training 500 COMMENT RESOLUTION
354	600 PEER REVIEW REPORT 700 RECORDS
355	SUBPART 4.2.8 Guidance for Prevention, Detection, and Control of Counterfeit, Fraudulent, or Suspect Items (CFSI) 100 GENERAL 101 Definitions 102 Identification Of Potential CFSI
356	103 Situations Increasing the Risk Of CFSI 200 PREVENTION 201 Quality Assurance Program 202 Procurement Document Control 203 Control of Purchased Items and Services 300 DETECTION 301 Organization
357	302 Quality Assurance Program 303 Control Of Purchased Items And Services 304 Inspection 305 Audits 400 CONTROL 401 Organization 402 Control Of Nonconforming Items 403 Corrective Action
358	500 RECORDS 600 REFERENCES
359	SUBPART 4.2.9 Guidance on Quality Assurance for Low-Level Waste Shipping from Nuclear Facilities 100 GENERAL 101 Definitions
360	Table 100-1 Regulation and Other References
364	102 Application of Requirements to LLW Shipping Activities 200 PREREQUISITES 201 Planning and Procedures 202 Requirement Implementation and Quality Maintenance 300 PRESHIPPING CHECKS 301 Personnel Qualifications and Training
365	302 Characterization
366	400 PROCUREMENT OF ITEMS AND SERVICES 500 CONTAINERS/PACKAGING 600 EQUIPMENT AND CALIBRATION 601 Control of Measuring and Test Equipment 700 DISPOSITION 701 DOE Disposal 702 Non-DOE Disposal
367	703 Shipping and Transport Paperwork 800 SHIPPING VEHICLE INSPECTION 801 Vehicles 900 AUDITS 901 Internal Audits 902 External Audits 903 Audits by External Entities 1000 POST-SHIPPING CHECKS 1100 RECORDS
369	Figure 100-1 Low-Level Water Shipper Guidance

ASME B16.15 2024

Sun, 20 Oct 2024 10:41:40 +0000

This Standard covers cast Class 125 and 250 copper alloy threaded pipe fittings with provisions for substituting wrought copper alloys for plugs, bushings, caps, and couplings in small sized. This Standard includes: (a) pressure-temperature ratings (b) size and method of designating openings of reducing pipe fittings (c) marking requirements (d) minimum requirements for casting quality and materials (e) dimensions and tolerances in SI (metric) and U.S. Customary units (f) threading requirements (g) pressure test requirements.

PDF Catalog

PDF Pages	PDF Title
4	CONTENTS
6	FOREWORD
8	ASME B16 COMMITTEE ROSTER
9	CORRESPONDENCE WITH THE B16 COMMITTEE
11	ASME B16.15-2024 SUMMARY OF CHANGES
12	LIST OF CHANGES IN RECORD NUMBER ORDER
14	1 SCOPE 2 GENERAL 2.1 Relevant Units 2.2 References 2.3 Quality Systems 2.4 Denotation 2.5 Time of Purchase, Manufacture, or Installation 2.6 User Accountability 2.7 Service Conditions 2.8 Definitions 3 PRESSURE–TEMPERATURE RATINGS 3.1 General
15	3.2 Rating 3.3 Limitations 4 SIZE 4.1 Nominal Pipe Size 4.2 Reducing Sizes 5 MARKING 5.1 Class 125 Fitting 5.2 Class 250 Fitting 5.3 Exceptions 6 MATERIAL 7 THREADS 7.1 Thread Form
16	7.2 Gaging Tolerances 8 RIBS 9 SURFACE FINISH 10 FITTING DIMENSIONS 10.1 General 10.2 Reducing Fittings 11 TOLERANCES 11.1 Convention 11.2 Metal Thickness 11.3 Dimensions 12 PRESSURE TEST
17	Figure Figure 4.2-1 Identification of Reducing Fittings Tables Table 3.1-1 Pressure–Temperature Ratings
18	Table 7.1.3-1 Dimensions of 90-deg Elbows, Tees, Crosses, 45-deg Elbows, and Couplings (Straight Sizes) — Class 125
19	Table 7.1.3-2 Dimensions of Caps — Class 125
20	Table 7.1.3-3 Dimensions of Outside Head, Inside Head, and Face Bushings — Class 250
22	Table 10.1.2-1 Dimensions of 90-deg Elbows (Reducing Sizes) — Class 125
23	Table 10.1.2-2 Dimensions of Tees (Reducing Sizes) — Class 125
24	Table 10.1.2-3 Dimensions of 90-deg Elbows (Reducing Sizes) — Class 250
25	Table 10.1.2-4 Dimensions of Tees (Reducing Sizes) — Class 250
26	Table 10.1.2-5 Dimensions of Square Head and Square Socket Plugs
27	Table 10.1.2-6 Dimensions of Reducers, Closed and Open Pattern Return Bends, and 45-deg Y Branches (Straight Sizes) — Class 125
28	Table 10.1.2-7 Dimensions of 90-deg and 45-deg Street Elbows — Class 125
29	Table 10.1.2-8 Dimensions of 90-deg Elbows, Tees, Crosses, 45-deg Elbows, and Couplings (Straight Sizes) — Class 250 Table 11.3-1 Inspection Tolerances, Center-to-End and Center-to-Center
30	MANDATORY APPENDIX I REFERENCES
31	NONMANDATORY APPENDIX A QUALITY SYSTEM PROGRAM

ASME STP NU 067 1 2024

Sun, 20 Oct 2024 10:41:40 +0000

None

PDF Catalog

PDF Pages	PDF Title
4	Foreword Summary of Changes 1. Vision Statement and Overview 2.1 Global Stakeholders 2.2 A Phased Approach 2.3 Assumption 3. FED Designs and Information Required 4.1 Research and Development (R&D) Tasks 4.2 Administrative and Technical Tasks 4.3 Specific Code Rule Development Tasks
5	TABLE OF CONTENTS
6	Foreword
7	ACRONYMS AND ABBREVIATIONS
8	1. VISION STATEMENT AND OVERVIEW
9	2. METHODOLOGY 2.1 Global Stakeholders 2.2 Division 4 committee structure
11	2.3 A Phased Approach 2.4 Assumptions
12	3. FED DESIGNS AND INFORMATION REQUIRED
13	4. PROPOSED TASK WORK 4.1 Research and Development (R&D) Tasks
14	4.2 Administrative and Technical Tasks
15	4.3 Specific Code Rule Development Tasks A. Design rules to include: B. Risk Management Application: C. Industrial Guidance, Rules and Application:
16	4.4 Industry Involvement

ASME STP PT 096 1 2024

Sun, 20 Oct 2024 10:31:10 +0000

The goal of this publication is to organize and compile high-temperature material property data for select alloys, to be used in the ASME Boiler and Pressure Vessel Code. It is expected that the properties compiled in this project will be used to support continued and expanded use of elevated temperature design-by-analysis (DBA), to support initiatives such as advanced ultra-supercritical fossil power generation and Gen IV high-temperature nuclear reactor, among other applications.

PDF Catalog

PDF Pages	PDF Title
4	Errata to STP-PT-096-1
6	TABLE OF CONTENTS
9	LIST OF TABLES
12	LIST OF FIGURES
31	FOREWORD
32	ABBREVIATIONS AND ACRONYMS
33	1 INTRODUCTION
34	2 EXECUTIVE SUMMARY
37	3 ANALYSIS 3.1 Compilation and Digitization of Material Properties 3.2 Physical Properties
38	3.3 Yield and Tensile Strength 3.4 Creep Data (Creep Rupture, Minimum Creep Rate, and Ductility) 3.5 Continuous Cycling Fatigue and Hold Time Fatigue Curves
40	4 Grade 91, 9CR-1MO-V 4.1 Physical Properties 4.2 Yield and Tensile Strength 4.3 Creep Data (Creep Rupture, Minimum Creep Rate, and Ductility)
41	4.4 Continuous Cycling Fatigue and Hold Time Fatigue Curves
69	5 CARBON STEEL (SA-516/SA-299) AND SIMILAR 5.1 Physical Properties 5.2 Yield and Tensile Strength 5.3 Creep Data (Creep Rupture, Minimum Creep Rate, and Ductility)
70	5.4 Continuous Cycling Fatigue and Hold Time Fatigue Curves
99	6 CARBON STEEL (SA-508) AND SIMILAR 6.1 Physical Properties 6.2 Yield and Tensile Strength 6.3 Creep Data (Creep Rupture, Minimum Creep Rate, and Ductility)
100	6.4 Continuous Cycling Fatigue and Hold Time Fatigue Curves
118	7 CARBON STEEL (SA-533) AND SIMILAR 7.1 Physical Properties 7.2 Yield and Tensile Strength 7.3 Creep Data (Creep Rupture, Minimum Creep Rate, and Ductility)
119	7.4 Continuous Cycling Fatigue and Hold Time Fatigue Curves
137	8 C-1/2MO 8.1 Physical Properties 8.2 Yield and Tensile Strength 8.3 Creep Data (Creep Rupture, Minimum Creep Rate, and Ductility)
138	8.4 Continuous Cycling Fatigue and Hold Time Fatigue Curves
161	9 GRADE 11, 1.25CR-0.5MO-SI 9.1 Physical Properties 9.2 Yield and Tensile Strength 9.3 Creep Data (Creep Rupture, Minimum Creep Rate, and Ductility)
162	9.4 Continuous Cycling Fatigue Curves
182	10 GRADE 22 (2.25CR-1MO) 10.1 Physical Properties 10.2 Yield and Tensile Strength 10.3 Creep Data (Creep Rupture, Minimum Creep Rate, and Ductility)
183	10.4 Continuous Cycling Fatigue Curves
206	11 GRADE 22V (2.25CR-1MO-V) 11.1 Physical Properties 11.2 Yield and Tensile Strength 11.3 Creep Data (Creep Rupture, Minimum Creep Rate, and Ductility)
207	11.4 Continuous Cycling Fatigue and Hold Time Fatigue Curves
232	12 5CR-0.5MO (GRADE 5) 12.1 Physical Properties 12.2 Yield and Tensile Strength 12.3 Creep Data (Creep Rupture, Minimum Creep Rate, and Ductility)
233	12.4 Continuous Cycling Fatigue and Hold Time Fatigue Curves
256	13 5CR-0.5MO-SI (GRADE 5A) 13.1 Physical Properties 13.2 Yield and Tensile Strength 13.3 Creep Data (Creep Rupture, Minimum Creep Rate, and Ductility)
257	13.4 Continuous Cycling Fatigue and Hold Time Fatigue Curves
279	14 GRADE 9, 9CR-1MO 14.1 Physical Properties 14.2 Yield and Tensile Strength 14.3 Creep Data (Creep Rupture, Minimum Creep rate, and Ductility)
280	14.4 Continuous Cycling Fatigue and Hold Time Curves
303	15 GRADE 92 (9CR-2W) 15.1 Physical Properties 15.2 Yield and Tensile Strength 15.3 Creep Data (Creep Rupture, Minimum Creep Rate, and Ductility)
304	15.4 Continuous Cycling and Hold Time Fatigue Data
325	16 TYPE 304H (AND 304) STAINLESS STEEL 16.1 Physical Properties 16.2 Yield and Tensile Strength 16.3 Creep data (Creep Rupture, Minimum Creep Rate, and Ductility)
326	16.4 Continuous Cycling Fatigue and Hold Time Fatigue Curves
349	17 TYPE 316H (AND 316) STAINLESS STEEL 17.1 Physical Properties 17.2 Yield and Tensile Strength 17.3 Creep Data (Creep Rupture, Minimum Creep Rate, and Ductility)
350	17.4 Continuous Cycling Fatigue and Hold Time Fatigue Curves
374	18 TYPE 347H (AND 347) STAINLESS STEEL 18.1 Physical Properties 18.2 Yield and Tensile Strength 18.3 Creep Data (Creep Rupture, Minimum Creep Rate, and Ductility)
375	18.4 Continuous Cycling Fatigue Curves
396	19 ALLOY 617, 52NI-22CR-13CO-9MO 19.1 Physical Properties 19.2 Yield and Tensile Strength 19.3 Creep Data (Creep Rupture, Minimum Creep Rate, and Ductility)
397	19.4 Continuous Cycling Fatigue and Hold Time Fatigue Curves
422	20 INCONEL 740H 20.1 Physical Properties 20.2 Yield and Tensile Strength 20.3 Creep Data (Creep Rupture, Minimum Creep Rate, and Ductility)
423	20.4 Continuous Cycling Fatigue Curves
438	21 ALLOY 800H, 33NI-42FE-21CR 21.1 Physical Properties 21.2 Yield and Tensile Strength 21.3 Creep Data (Creep Rupture, Minimum Creep Rate, and Ductility)
439	21.4 Continuous Cycling Fatigue and Hold Time Fatigue Curves
468	22 GRADE 12, 1CR-0.5MO 22.1 Physical Properties 22.2 Yield and Tensile Strength 22.3 Creep Data (Creep Rupture, Minimum Creep Rate, and Ductility)
469	22.4 Hold Time Fatigue Curves
490	23 GRADE 23 23.1 Physical Properties 23.2 Yield and Tensile Strength 23.3 Creep Data (Creep Rupture, Minimum Creep Rate, and Ductility)
491	23.4 Continuous Cycling Fatigue and Hold Time Fatigue Curves
508	24 GRADE 21 (3CR) 24.1 Physical Properties 24.2 Yield and Tensile Strength 24.3 Creep Data (Creep Rupture, Minimum Creep Rate, and Ductility)
509	24.4 Continuous Cycling Fatigue and Hold Time Fatigue Curves
527	25 TYPE 410 (13CR)/12CR 25.1 Physical Properties 25.2 Yield and Tensile Strength 25.3 Creep Data (Creep Rupture, Minimum Creep Rate, and Ductility)
528	25.4 Continuous Cycling Fatigue and Hold Time Fatigue Curves
556	26 321H 18CR-10NI-TI 26.1 Physical Properties 26.2 Yield and Tensile Strength 26.3 Creep Data (Creep Rupture, Minimum Creep Rate, and Ductility)
557	26.4 Continuous Cycling Fatigue and Hold Time Fatigue Curves
581	27 ALLOY 601 27.1 Physical Properties 27.2 Yield and Tensile Strength 27.3 Creep Data (Creep Rupture, Minimum Creep Rate, and Ductility)
582	27.4 Continuous Cycling Fatigue Curves
597	28 ALLOY 709 28.1 Physical Properties 28.2 Yield and Tensile Strength 28.3 Creep Data (Creep Rupture, Minimum Creep Rate, and Ductility)
598	28.4 Continuous Cycling Fatigue and Hold Time Fatigue Curves
614	29 B7 BOLTING, 1CR-0.3MO 29.1 Physical Properties 29.2 Yield and Tensile Strength 29.3 Creep Data (Creep Rupture, Minimum Creep Rate, and Ductility)
615	29.4 Continuous Cycling Fatigue and Hold Time Fatigue Curves
634	30 B16 BOLTING, 1CR-0.5MO-V 30.1 Physical Properties 30.2 Yield and Tensile Strength 30.3 Creep Data (Creep Rupture, Minimum Creep Rate, and Ductility)
635	30.4 Hold Time Fatigue Curves
653	31 B8 BOLTING, 18CR-8NI 31.1 Physical Properties 31.2 Yield and Tensile Strength 31.3 Creep Data (Creep Rupture, Minimum Creep Rate, and Ductility)
654	31.4 Continuous Cycling Fatigue and Hold Time Fatigue Curves
671	32 GRADE 660, 25NI-15CR-1MO-2TI-MN-AL-V 32.1 Physical Properties 32.2 Yield and Tensile Strength 32.3 Creep Data (Creep Rupture, Minimum Creep Rate, and Ductility)
672	32.4 Continuous Cycling Fatigue and Hold Time Fatigue Curves
698	33 INCONEL 718 BOLTING 33.1 Physical Properties 33.2 Yield and Tensile Strength 33.3 Creep Data (Creep Rupture, Minimum Creep Rate, and Ductility)
699	33.4 Continuous Cycling Fatigue and Hold Time Fatigue Curves
719	References

ASME BPVC CC NC S5 2023

Sun, 20 Oct 2024 10:31:08 +0000

Code Cases are approved exceptions or alternatives to Code rules. They include specific requirements that, when fully and correctly implemented, help users achieve continued quality and safety. Code Cases are not mandatory but may be used for Code compliance by any user. The majority of Code Cases involve new materials, but many introduce new technologies and concepts, such as nondestructive examination and welding processes, updated design and fabrication methods, and streamlined rules for inspection and quality assurance. Because of their leading-edge content and timely issuance, Code Cases can be an invaluable resource for ASME Code users.

ASME BPVC CC BPV S5 2023

Sun, 20 Oct 2024 10:31:08 +0000

ASME PTC 19.3 2024

Sun, 20 Oct 2024 10:31:07 +0000

The methods for temperature measurement and the protocols used for data transmission are provided in this Code. Guidance is given for setting up the instrumentation and determining measurement uncertainties. Information regarding the instrument type, design, applicable temperature range, accuracy, output, and relative cost is provided. Information on temperature-measuring devices that are not normally used in field environments is given in Mandatory Appendices I, II, and III.

PDF Catalog

PDF Pages	PDF Title
4	CONTENTS
8	NOTICE
9	FOREWORD
10	ASME PTC COMMITTEE ROSTER
11	CORRESPONDENCE WITH THE PTC COMMITTEE
14	Section 1 General 1-1 OBJECT 1-2 SCOPE 1-3 DEFINITIONS 1-4 TEMPERATURE SCALES 1-4.1 Thermodynamic Temperature Scale
15	1-4.2 Units of Measurement for Temperature 1-5 SENSOR AND GAUGE TYPES
16	1-6 THERMOWELLS AND PROTECTION TUBES Tables Table 1-5-1 Typical Temperature Ranges
17	1-7 OTHER ACCESSORIES Table 1-6-1 Factors That Influence Strength and Measurement
18	1-8 INSTALLATION AND PROCESS EFFECTS 1-8.1 Placement Recommendations 1-8.2 Conduction Error
19	1-8.3 Radiation Error 1-8.4 Aerodynamic Heating Effect
20	1-8.5 Heat Transfer at Low Velocity 1-8.6 Heat Transfer at High Velocity
21	1-8.7 Gradients and Stratifications 1-8.8 Speed of Response Contributing to Dynamic Error
22	1-9 UNCERTAINTY 1-9.1 Uncertainty Due to Random Error
23	1-9.2 Uncertainty Due to Systematic Error 1-10 CONCLUSIONS 1-11 REFERENCES 1-11.1 Cited References
27	1-11.2 Additional References
28	Section 2 Thermocouple Temperature Measurements 2-1 THERMOCOUPLES 2-1.1 Scope 2-1.2 Definition Figures Figure 2-1.2-1 Thermocouple Thermometer Systems
29	2-1.3 Principles of Operation 2-1.4 Thermocouple Construction and Terminology Figure 2-1.4-1 Typical Industrial Sheathed Thermocouple With Transition to Lead Wires
30	Figure 2-1.4-2 Hollow Tube Construction Thermocouple With Continuous Leads and Ground Wire
31	Figure 2-1.4-3 Ungrounded Thermocouple With No Housing or Transition
32	Table 2-1.4-1 Specification Information by Thermocouple Calibration Type
33	Figure 2-1.4.2-1 Laboratory Thermocouple With “T” Stem Reference Junction Table 2-1.4-2 Recommended Upper Temperature Limits for Protected Thermocouples by Wire Size
35	2-1.5 Thermocouple Element Materials
37	2-1.6 Thermocouple Characteristics
38	Table 2-1.6.1-1 Temperature emf Relationship for Base Metal and Noble Metal Thermocouples
39	2-2 THERMOCOUPLE ACCESSORIES 2-3 APPLICATION AND INSTALLATION 2-3.1 Sources of Error
40	2-3.2 Essential Considerations
41	2-3.3 Treatment of Data Figure 2-3.2-1 Thermocouples Connected in Series Figure 2-3.2-2 Thermocouples Connected in Parallel
43	2-4 ADVANTAGES AND DISADVANTAGES 2-4.1 Advantages 2-4.2 Disadvantages 2-5 THERMOCOUPLE INSTRUMENTATION 2-5.1 General
44	2-5.2 emf-Measuring Devices 2-5.3 Scanners/Multiplexers
45	2-5.4 Accuracy of the emf Measurement and Noise Table 2-5.2-1 Typical Thermocouple Card Accuracy and Drift
46	2-5.5 Reference Junction Apparatus
48	Figure 2-5.5.8-1 A Zone-Box Circuit Involving Only One Reference Junction
49	Section 3 Resistance Temperature Detectors (RTDs) 3-1 SCOPE 3-2 DEFINITIONS
50	Figure 3-2-1 Pad-Style RTD Element Figure 3-2-2 Averaging RTD in a Duct
51	Figure 3-2-3 Thin-Film Element Figure 3-2-4 Wire-Wound Element
52	3-3 PRINCIPLES OF OPERATION AND SPECIFICATION CHARACTERISTICS 3-3.1 RTD Accuracy Specifications Figure 3-3-1 Typical Industrial Platinum Resistance Thermometer
53	Table 3-3.1-1 Industrial RTD Tolerance Specification Table (U.S. Customary) Table 3-3.1-1M Industrial RTD Tolerance Specification Table (SI)
54	3-3.2 Specification of RTD Lead Wires Table 3-3.1-2 Thin Film Versus Wire Wound Elements
55	3-3.3 Temperature Coefficient of Resistance or Alpha, α Figure 3-3.2-1 RTD Wire Color Code by Standard
56	3-3.4 Platinum Resistance Element Temperature-Resistance Relationships 3-3.5 Measurement Considerations Particular to RTDs
57	3-4 LESS COMMONLY USED RESISTANCE ELEMENTS Table 3-3.5.1-1 Maximum Applied Current for RTDs by Nominal Resistance
58	3-4.1 Copper Resistance Thermometer 3-4.2 Nickel Resistance Thermometer 3-4.3 Nickel–Iron Resistance Thermometer
59	Section 4 Principles of Operation for Filled-System Thermometers 4-1 SCOPE 4-2 DEFINITIONS 4-3 PRINCIPLES OF OPERATION Figure 4-2-1 Filled-System Thermometer
60	4-4 CLASSIFICATION 4-4.1 General Classification 4-4.2 Subclassification
61	Figure 4-4.2.1-1 Fully Compensated Liquid, Mercury, or Gas-Filled Thermal System — Class IA, Class IIIA, or Class VA Figure 4-4.2.1-2 Fully Compensated Liquid, Mercury, or Gas-Filled Thermal System — Class IB, Class IIIB, or Class VB
62	Figure 4-4.2.2-1 Vapor Pressure Thermal System — Class IIA Figure 4-4.2.2-2 Vapor Pressure Thermal System — Class IIB
63	Figure 4-4.2.2-3 Vapor Pressure Thermal System — Class IIC
64	4-5 DESCRIPTION 4-5.1 Bulb Size Figure 4-4.2.2-4 Vapor Pressure Thermal System — Class IID
65	Table 4-5.1-1 Approximate Bulb-Sensitive Dimensions
66	Table 4-5.1-2 Comparison of Thermal Systems
67	Figure 4-5.1-1 Vapor Pressure–Temperature Curves
68	4-6 MATERIALS OF CONSTRUCTION 4-6.1 Bulb Materials 4-6.2 Thermowell Materials 4-6.3 Capillary Materials 4-7 CHARACTERISTICS 4-7.1 Maximum and Minimum Temperatures 4-7.2 Range
69	4-7.3 Sensitivity 4-7.4 Accuracy 4-7.5 Temperature Compensation
70	4-7.6 Response Figure 4-7.6-1 Bulb Response Versus Bulb O.D. in Water (Velocity of 2.5 fps)
71	4-8 ACCESSORIES Figure 4-7.6-2 Bulb Response Rate in Air at Various Velocities
72	4-9 APPLICATION AND INSTALLATION 4-9.1 Sources of Error Figure 4-7.6-3 Preformed Capillary Bulb
73	4-10 ESSENTIAL CONSIDERATIONS
74	4-11 ADVANTAGES AND DISADVANTAGES 4-11.1 Advantages 4-11.2 Disadvantages Figure 4-10.1-1 Attachment of Thermal Systems to Vessels
75	Section 5 Thermistor Thermometry 5-1 SCOPE 5-2 DEFINITIONS 5-3 PRINCIPLES OF OPERATION 5-4 CLASSIFICATION 5-4.1 Description
76	5-5 MATERIALS OF CONSTRUCTION 5-6 CHARACTERISTICS 5-6.1 Temperature-Resistance Relationship Figure 5-3-1 Resistance Versus Temperature for 10-kΩ NTC Thermistor
77	5-6.2 Interchangeability 5-6.3 Range and Accuracy 5-6.4 Precision and Sensitivity 5-6.5 Response 5-7 APPLICATION AND INSTALLATION 5-7.1 Sources of Error
78	5-8 INTEGRATION INTO AUTOMATED MEASUREMENT SYSTEMS 5-9 TREATMENT OF DATA 5-10 ADVANTAGES AND DISADVANTAGES 5-10.1 Advantages 5-10.2 Disadvantages
79	Section 6 Calibration of Temperature Sensors 6-1 SCOPE 6-2 SELECTION OF CALIBRATION VENDORS 6-3 TEMPERATURE SCALES 6-4 THERMODYNAMIC TEMPERATURE SCALE
80	6-5 IDEAL GAS SCALE 6-6 INTERNATIONAL TEMPERATURE SCALE 6-7 PLATINUM RESISTANCE THERMOMETRY 6-7.1 General Table 6-6-1 Relations for Realizing the ITS-90
81	6-7.2 ITS-90 SPRT Specifications 6-8 METHODS OF CALIBRATION 6-8.1 Calibration by Fixed Points Table 6-7.1-1 Subranges of ITS-90 for Platinum Resistance Thermometers
82	6-8.2 Calibration by Comparison to Primary and Working Standards Table 6-8.1-1 Fixed Points of ITS-90 Table 6-8.2.1-1 Comparison of SPRTs Secondary Reference PRTs and Industrial RTDs
83	6-9 CALIBRATION EQUIPMENT 6-9.1 Comparators (Heat and Cold Sources Such as Dry Wells) Table 6-8.2.2-1 Typical Reference Working Standards
84	6-9.2 Meters 6-9.3 Computer Automation Programs 6-10 CALIBRATION OUTPUTS
85	6-11 CALIBRATION INTERVALS 6-12 CALIBRATION CONSIDERATIONS SPECIFIC TO SENSOR TYPE 6-12.1 Thermocouples Table 6-11-1 NIST’s GMP 11 Calibration Intervals for Temperature Sensors
86	Table 6-12.1.1-1 Accuracies Attainable Using Fixed Point Techniques Table 6-12.1.1-2 Accuracies Attainable Using Comparison Techniques in Laboratory Furnaces (Type R or Type S Standard) Table 6-12.1.1-3 Accuracies Attainable Using Comparison Techniques in Stirred Liquid Baths Table 6-12.1.1-4 Tungsten–Rhenium-Type Thermocouples
87	6-12.2 RTD Calibrations and Temperature Coefficients Table 6-12.1.1-5 Accuracies Attainable Using Comparison Techniques in Special Furnaces (Optical Pyrometer Standard)
88	Table 6-12.1.2-1 Secondary Reference Points
89	MANDATORY APPENDIX I NONCONTACT THERMOMETERS I-1 SCOPE I-2 DEFINITIONS
90	I-3 PRINCIPLES OF OPERATION
91	Figure I-3.2-1 Planck’s Blackbody Radiation Distribution Function, Showing Spectral Band Used by an Automatic Optical Pyrometer at 0.65 µm
92	Figure I-4.1-1 Schematic Diagram of an Optical Pyrometer I-4 CLASSIFICATION
93	Figure I-4.3-1 Schematic Optical System of Automatic Optical Pyrometers — Variable Radiance Comparison-Lamp Type
94	Figure I-4.3-2 Electronic System Block Diagram for Automatic Optical Pyrometer — Variable Radiance Comparison-Lamp Type
95	Figure I-4.4-1 Single Mirror Radiation Thermometer Figure I-4.5-1 Double Mirror Radiation Thermometer I-5 CHARACTERISTICS
96	Figure I-4.6-1 Lens-Type Radiation Thermometer
97	Figure I-6-1 Potentiometer Circuit I-6 ACCESSORIES I-7 APPLICATION AND INSTALLATION
100	Table I-7.4-1 Spectral Emissivity of Materials, Smooth Surface, Unoxidized
101	Table I-7.4-2 Spectral Emissivity of Oxides With Smooth Surfaces
104	Table I-7.5.2-1 Window Corrections
105	Table I-7.5.4-1 Emissivity and Transmittance Corrections
106	I-8 ADVANTAGES AND DISADVANTAGES
107	Figure II-2-1 Bimetallic Thermometer MANDATORY APPENDIX II BIMETALLIC THERMOMETERS II-1 SCOPE II-2 DEFINITIONS
108	II-3 PRINCIPLES OF OPERATION
109	Figure II-3.1-1 Bimetallic Thermometer Bulb Figure II-3.1-2 Nomenclature
110	Figure II-3.2-1 Industrial Bimetallic Thermometer: Straight Form Figure II-3.2-2 Industrial Bimetallic Thermometer: Sectional View of Angle Form
111	II-4 CHARACTERISTICS II-5 ACCESSORIES II-6 APPLICATION AND INSTALLATION
112	II-7 ADVANTAGES AND DISADVANTAGES
113	MANDATORY APPENDIX III LIQUID-IN-GLASS THERMOMETERS III-1 SCOPE III-2 LIQUID-IN-GLASS THERMOMETER TYPES AND TERMS III-3 PRINCIPLES OF OPERATION III-4 CLASSIFICATION
114	Figure III-2-1 Partial, Total, and Complete Immersion Thermometer Types
115	Figure III-4.2-1 Straight Industrial Thermometer With Swivel Nut, Mounted in a Well Figure III-4.2-2 90-deg Back Angle Industrial Thermometer With Swivel Nut and Union Bushing Connection
116	Table III-5.1-1 Temperature Exposure Limits for Various Thermometer Glasses III-5 MATERIALS OF CONSTRUCTION
117	Table III-5.2-1 Working Temperature Range for Liquids Commonly Used III-6 CHARACTERISTICS
118	III-7 ACCESSORIES III-8 APPLICATION AND INSTALLATION
119	Figure III-8.1-1 Thermometer Calibrated for Total Immersion and Used for Partial Immersion
120	Figure III-8.1-2 Emergent Stem Corrections for Liquid-in-Glass Thermometers
123	III-9 ADVANTAGES AND DISADVANTAGES

ASME VVUQ 30.1 2024

Sun, 20 Oct 2024 10:31:07 +0000

This Standard is focused on the scaling analysis that is used to evaluate the effects of differences (e.g., distortions) in the phenomenological behavior of experimental facilities compared to the phenomenological behavior of the real-world system. This includes scaling analysis methodologies for supporting the design of facilities and experiments capable of generating data that characterize the phenomena present in an entire system [such facilities are known as integral effects test (IET) facilities] and in components of the system (e.g., the nuclear core or the steam generator)[such facilities are known as separate effects test (SET) facilities].

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PDF Pages	PDF Title
4	CONTENTS
6	Foreword
7	ASME VVUQ Committee Roster
8	CORRESPONDENCE WITH THE VVUQ COMMITTEE
10	1 PURPOSE, SCOPE, INTRODUCTION, AND NOMENCLATURE 1.1 Purpose 1.2 Scope
11	1.3 Introduction Figures Figure 1.3-1 Determination of Model Adequacy
12	1.4 Nomenclature
16	2 CREATION OF THE ADEQUACY MATRIX AND VALIDATION MATRIX USING SCALED EXPERIMENTAL FACILITIES
17	3 SCALING HISTORY AND TYPES 3.1 General Figure 2-1 Process for Creating Assessment Base for Licensing Purposes: Flowchart
18	3.2 Volumetric Scaling Approach
19	4 OVERVIEW AND COMPARISON OF H2TS AND FSA SYSTEM DECOMPOSITION AND HIERARCHY
20	Figure 3.2-1 Comparison of Elongated Representations of Volumes in LOFT and Semiscale Mod-2A Test Facilities
21	Figure 4-1 System Decomposition and Hierarchy for Processes Applied in H2TS
22	Figure 4-2 Four Stages of H2TS
23	5 CONCEPT OF TIME–SCALE MODELING — DIMENSIONLESS GROUPS IN TERMS OF TIME RATIOS 5.1 Introduction
24	5.2 Scale Identification 5.3 Top-Down Approach — Scaling Hierarchy
25	Figure 5.2-1 Subvolumes, Vi, and Control Volume, V
27	5.4 Combination of H2TS and FSA Approaches
28	5.5 Bottom-Up Approach 5.6 Two-Tiered Approach Figure 5.3.2-1 Changes of System Matrix for FSA During the Duration of NPP Transient
29	MANDATORY APPENDIX I REFERENCES
31	NONMANDATORY APPENDIX A EXAMPLES OF EQUATIONS AND DIMENSIONLESS GROUPS USED FOR SCALING ANALYSIS A-1 THE DIMENSIONLESS GROUPS IN H2TS
32	Figure A-1.1-1 Control Volume, Transfer Area, Surface and Volume Effects, and State Variable Tables Table A-1.1-1 Examples of Derivations of H2TS Dimensionless Groups (Time Ratios)
34	A-2 THE DIMENSIONLESS GROUPS IN FSA
35	Table A-2-1 State Variables, Agents of Change, FRCs, and Fractional Changes (Effect Metrics)
36	A-3 REACTOR VESSEL PRESSURE RESPONSE
37	Table A-3-1 Definition of Dimensionless Agents of Change and Fractional Rates of Change for Pressure Response Equation
38	Figure A-3-1 PWR Vessel Pressure Responses for Various Test Facilities in Dimensional Form Figure A-3-2 PWR Vessel Pressure Responses for Various Test Facilities in Dimensionless Form
39	A-4 REACTOR VESSEL WATER LEVEL RESPONSE A-5 PEAK CLADDING TEMPERATURE
40	Table A-4-1 Definition of Dimensionless Agents of Change and Fractional Rates of Change for Void Fractions Equation
43	Table A-5.1-1 Definition of Fractional Rates of Change and Fractional Change Metric for Peak Cladding Temperature Equation
45	Figure A-5.2-1 Dimensionless Temperature and Its Relationship to Biot Number and the Decay Fractional Change Metric
46	Figure A-5.2-2 Normalized PCT for 0.015 < ΠBi < 0.03

ASME RA S 1.2 2024

Sun, 20 Oct 2024 10:31:06 +0000

This standard provides requirements for probabilistic risk assessments (PRAs) used to support risk-informed decisions for commercial light water reactor (LWR) nuclear power plants including small modular reactors (SMR). Unique requirements are specified as needed for specific reactor designs.

PDF Catalog

PDF Pages	PDF Title
3	Contents
5	Foreword
7	Acknowledgments
9	ASME/ANS RA-S Committee
11	Correspondence With the ASME/ANS Joint Committee on Nuclear Risk Management
13	Part 1. General Requirements for A Level 2 PRA Section 1-1. Introduction
20	Section 1-2. Acronyms and Definitions
27	Section 1-3. PRA Scope and Capabilities in Support of Risk-Informed Applications
28	Section 1-4. Requirements for Use of Expert Judgment
29	Section 1-5. PRA Configuration Control Program
32	Section 1-6. Peer Review
35	Section 1-7. Newly Developed Methods
38	Section 1-8. References
39	Nonmandatory Appendix 1-A Meanings of Action Verbs
42	Part 2. Technical requirements for level 2 PRA Section 2-1. Overview of Level 2 PRA Requirements
43	Section 2-2. Level 2 PRA Technical Elements and Requirements
71	Section 2-3. References
72	Nonmandatory Appendix 2-A Explanatory Notes Regarding Application and Review of the Level 2 Supporting Requirements