ASME STP-PT-070 DESIGN GUIDELINES FOR THE EFFECTS OF CREEP, FATIGUE & CREEP-FATIGUE INTERACTION WITH DESIGN-BY-ANALYSIS AND NONDESTRUCTIVE INSPECTION ACCEPTANCE CRITERIA
Данный раздел/документ содержится в продуктах:
- Техэксперт: Машиностроительный комплекс
- Картотека зарубежных и международных стандартов
- CEN CEN/TR 13931 Rotodynamic pumps - Forces and moments on flanges - Centrifugal, mixed flow and axial flow horizontal and vertical shafts pumps - Incorporating Corrigendum June 2010
- CEN EN ISO 9908 Technical specifications for centrifugal pumps - Class III - Incorporates Amendment A1: 2011
- ISO 1940-1 CORR 1 Mechanical vibration — Balance quality requirements for rotors in a constant (rigid) state — Part 1: Specification and verification of balance tolerances TECHNICAL CORRIGENDUM 1 - Second Edition
- CEN EN ISO 9908 Technical specifications for centrifugal pumps - Class III - Incorporates Amendment A1: 2011
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- CEN CEN/TR 13931 Rotodynamic pumps - Forces and moments on flanges - Centrifugal, mixed flow and axial flow horizontal and vertical shafts pumps - Incorporating Corrigendum June 2010
- CEN EN ISO 9908 Technical specifications for centrifugal pumps - Class III - Incorporates Amendment A1: 2011
- ISO 1940-1 CORR 1 Mechanical vibration — Balance quality requirements for rotors in a constant (rigid) state — Part 1: Specification and verification of balance tolerances TECHNICAL CORRIGENDUM 1 - Second Edition
- CEN EN ISO 9908 Technical specifications for centrifugal pumps - Class III - Incorporates Amendment A1: 2011
- 23.080
- CEN CEN/TR 13931 Rotodynamic pumps - Forces and moments on flanges - Centrifugal, mixed flow and axial flow horizontal and vertical shafts pumps - Incorporating Corrigendum June 2010
- CEN EN ISO 9908 Technical specifications for centrifugal pumps - Class III - Incorporates Amendment A1: 2011
- ISO 1940-1 CORR 1 Mechanical vibration — Balance quality requirements for rotors in a constant (rigid) state — Part 1: Specification and verification of balance tolerances TECHNICAL CORRIGENDUM 1 - Second Edition
- CEN EN ISO 9908 Technical specifications for centrifugal pumps - Class III - Incorporates Amendment A1: 2011
- CEN CEN/TR 13931 Rotodynamic pumps - Forces and moments on flanges - Centrifugal, mixed flow and axial flow horizontal and vertical shafts pumps - Incorporating Corrigendum June 2010
- CEN CEN/TR 13931 Rotodynamic pumps - Forces and moments on flanges - Centrifugal, mixed flow and axial flow horizontal and vertical shafts pumps - Incorporating Corrigendum June 2010
- CEN EN 16480 Pumps - Minimum required efficiency of rotodynamic water pumps
- CEN EN ISO 5198 Centrifugal, Mixed Flow and Axial Pumps - Code for Hydraulic Performance Tests - Precision Class
- BSI BS EN 13275 Cryogenic Vessels - Pumps for Cryogenic Service
- CEN EN ISO 9908 Technical specifications for centrifugal pumps - Class III - Incorporates Amendment A1: 2011
- ISO 1940-1 CORR 1 Mechanical vibration — Balance quality requirements for rotors in a constant (rigid) state — Part 1: Specification and verification of balance tolerances TECHNICAL CORRIGENDUM 1 - Second Edition
- CEN EN ISO 9908 Technical specifications for centrifugal pumps - Class III - Incorporates Amendment A1: 2011
- BSI BS EN 13275 Cryogenic Vessels - Pumps for Cryogenic Service
- CEN EN ISO 5198 Centrifugal, Mixed Flow and Axial Pumps - Code for Hydraulic Performance Tests - Precision Class
- CEN EN ISO 5198 Centrifugal, Mixed Flow and Axial Pumps - Code for Hydraulic Performance Tests - Precision Class
- BSI BS EN 13275 Cryogenic Vessels - Pumps for Cryogenic Service
- CEN EN ISO 9908 Technical specifications for centrifugal pumps - Class III - Incorporates Amendment A1: 2011
- ISO 1940-1 CORR 1 Mechanical vibration — Balance quality requirements for rotors in a constant (rigid) state — Part 1: Specification and verification of balance tolerances TECHNICAL CORRIGENDUM 1 - Second Edition
- CEN EN ISO 9908 Technical specifications for centrifugal pumps - Class III - Incorporates Amendment A1: 2011
- BSI BS EN 13275 Cryogenic Vessels - Pumps for Cryogenic Service
- BSI BS EN 13275 Cryogenic Vessels - Pumps for Cryogenic Service
- CEN EN ISO 9908 Technical specifications for centrifugal pumps - Class III - Incorporates Amendment A1: 2011
- ISO 1940-1 CORR 1 Mechanical vibration — Balance quality requirements for rotors in a constant (rigid) state — Part 1: Specification and verification of balance tolerances TECHNICAL CORRIGENDUM 1 - Second Edition
- CEN EN ISO 9908 Technical specifications for centrifugal pumps - Class III - Incorporates Amendment A1: 2011
- CEN EN ISO 9908 Technical specifications for centrifugal pumps - Class III - Incorporates Amendment A1: 2011
- ISO 1940-1 CORR 1 Mechanical vibration — Balance quality requirements for rotors in a constant (rigid) state — Part 1: Specification and verification of balance tolerances TECHNICAL CORRIGENDUM 1 - Second Edition
- ISO 1940-1 CORR 1 Mechanical vibration — Balance quality requirements for rotors in a constant (rigid) state — Part 1: Specification and verification of balance tolerances TECHNICAL CORRIGENDUM 1 - Second Edition
- ASME B73.1 Specification for Horizontal End Suction Centrifugal Pumps for Chemical Process
- ASME B16.42 Ductile Iron Pipe Flanges and Flanged Fittings Classes 150 and 300
- ASME/BPVC SEC XII SECTION XII RULES FOR CONSTRUCTION AND CONTINUED SERVICE OF TRANSPORT TANKS
- API 579-1 ERTA Fitness-For-Service - Second Edition
- ASME STP-PT-071 STRESS INTENSITY FACTOR SOLUTIONS FOR INTERNAL CRACKS IN THICK-WALLED CYLINDER VESSELS
- ASME FFS-1 ERTA Fitness-For-Service - Second Edition
- CEN CEN/TR 13931 Rotodynamic pumps - Forces and moments on flanges - Centrifugal, mixed flow and axial flow horizontal and vertical shafts pumps - Incorporating Corrigendum June 2010
- Картотека зарубежных и международных стандартов
ASME International
DESIGN GUIDELINES FOR THE EFFECTS OF CREEP, FATIGUE & CREEP-FATIGUE INTERACTION WITH DESIGN-BY-ANALYSIS AND NONDESTRUCTIVE INSPECTION ACCEPTANCE CRITERIA
N STP-PT-070
Annotation
As part of the modernization of Section I – Rules for Construction of Power Boilers of the ASME Boiler and Pressure Vessel Code (Section I), a project was established to develop design guidelines for the effects of creep-fatigue interaction and flaw size acceptance criteria within the overall framework of Design-By-Analysis (DBA). The existing methods within Section I, which are based around Design-By- Rule/Formula and do not explicitly consider creep, fatigue or their interaction. The oversimplifications involved are such that the safety of boilers operating at higher steam cycle conditions, and under cyclic service, has been questioned. Design-By-Analysis (as an alternative to Design-By-Rule/Formula) is gaining acceptance as a viable approach for design of components that will experience cyclic loading and which will operate at elevated temperatures where creep may occur. Such Design-By-Analysis approaches have been introduced into other international codes, including other sections of the ASME Boiler and Pressure Vessel Code (ASME Code) and the EN Code.
This report has been prepared to recommend design guidelines for components in Section I - Power Boilers. As such, it does provide a comprehensive review of issues. However, to properly introduce the context of the recommendations, some background is provided to a number of philosophical topics that surround Design-By-Analysis, Design-By-Formula, Design-For-Safety and Design-For-Lifetime. As several other recognized Codes and Standards have approaches that are relevant to Design-By-Analysis, or which provide methods for including creep-fatigue interaction effects, a summary of these documents is provided. In particular, the summary compares and contrasts key aspects to provide insight into benefits and shortcomings (or inconsistencies) associated with particular approaches. From this review it is evident that no single Code or Standard has a method that can be universally adopted, particularly when the methods have to be used in the context of other Sections of Codes, such as material properties, or standardized design features. That is, a particular Design-By-Analysis methodology needs to be developed that could be used within the overall context of the ASME Code (particularly Section I).
