蠕变疲劳检测标准

原创来源：北检院发布时间：2023-02-08 07:42:23 点击数：

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蠕变疲劳检测标准相关标准参考信息

GB/T 38822-2020 金属材料蠕变-疲劳试验方法
简介：
信息：ICS：77.040.10 CCS：H22 发布：2020-06-02 00:00:00.0 实施：2021-01-01 00:00:00.0

ASTM E2714-2009e1 蠕变疲劳试验的标准试验方法
简介：Creep-fatigue testing is typically performed at elevated temperatures and involves the sequential or simultaneous application of the loading conditions necessary to generate cyclic deformation/damage enhanced by creep deformation/damage or vice versa. Unless such tests are performed in vacuum or an inert environment, oxidation can also be responsible for important interaction effects relating to damage accumulation. The purpose of creep-fatigue tests can be to determine material property data for (a) assessment input data for the deformation and damage condition analysis of engineering structures operating at elevated temperatures (b) the verification of constitutive deformation and damage model effectiveness (c) material characterization, or (d) development and verification of rules for new construction and life assessment of high-temperature components subject to cyclic service with low frequencies or with periods of steady operation, or both. In every case, it is advisable to have complementary continuous cycling fatigue data (gathered at the same strain/loading rate) and creep data determined from test conducted as per Practice E139 for the same material and test temperature(s). The procedure is primarily concerned with the testing of round bar test specimens subjected (at least remotely) to uniaxial loading in either force or strain control. The focus of the procedure is on tests in which creep and fatigue deformation and damage is generated simultaneously within a given cycle. Data which may be determined from creep-fatigue tests performed under such conditions may characterize (a) cyclic stress-strain deformation response (b) cyclic creep (or relaxation) deformation response (c) cyclic hardening, cyclic softening response or (d) cycles to crack formation, or both. 4.3 While there are a number of testing Standards and Codes of Practice that cover the determination of low cycle fatigue deformation and cycles to crack initiation properties (See Practice E606, BS 7270: 2000, JIS Z 2279x2013;1992, PrEN 3874, 1998, PrEN 3988x2013;1998, ISO 12106x2013;2003, ISO 12111x2013;2005, and Practice E2368-04 and (1, 2, 3) , some of which provide guidance for testing at high temperature (for example, Practice E606, ISO 12106x2013;2003, and Practice E2368-04, there is no single standard which specifically prescribes a procedure for creep-fatigue testing.1.1 This test method covers the determination of mechanical properties pertaining to creep-fatigue deformation or crack formation in nominally homogeneous materials, or both by the use of test specimens subjected to uniaxial forces under isothermal conditions. It concerns fatigue testing at strain rates or with cycles involving sufficiently long hold times to be responsible for the cyclic deformation response and cycles to crack formation to be affected by creep (and oxidation). It is intended as a test method for fatigue testing performed in support of such activities as materials research and development, mechanical design, process and quality control, product performance, and failure analysis. The cyclic condi......
信息：ICS：19.060 (Mechanical testing) CCS：H22 发布：2009 实施：

简介： 信息：

ASTM E2714-13(2020) 蠕变疲劳试验的标准试验方法
简介：
信息：ICS：19.060 CCS：发布：2020-05-01 实施：

ASME STP-NU-018-2009 91级和哈斯特洛伊耐蚀镍基合金XR用蠕变疲劳数据和现有的评定规程
简介：This document describes the results of investigation on Task 5 of DOE/ASME Materials Project based on a contract between ASME Standards Technology, LLC (ASME ST-LLC) and Japan Atomic Energy Agency (JAEA). Task 5 is to collect available creep-fatigue data and study existing creep-fatigue evaluation procedures for Grade 91 steel and Hastelloy XR. Part I of this report is devoted to Grade 91 steel. Part II of this report is devoted to Hastelloy XR.
信息：ICS：27.120.10;77.140.20 CCS：H22 发布：2009 实施：

简介： 信息：

ASTM E2760-19 蠕变疲劳裂纹扩展试验的标准试验方法
简介：
信息：ICS：77.040.10 CCS：发布：2019-11-01 实施：

ASTM E2714-2009 蠕变疲劳试验的标准试验方法
简介：Creep-fatigue testing is typically performed at elevated temperatures and involves the sequential or simultaneous application of the loading conditions necessary to generate cyclic deformation/damage enhanced by creep deformation/damage or vice versa. Unless such tests are performed in vacuum or an inert environment, oxidation can also be responsible for important interaction effects relating to damage accumulation. The purpose of creep-fatigue tests can be to determine material property data for (a) assessment input data for the deformation and damage condition analysis of engineering structures operating at elevated temperatures (b) the verification of constitutive deformation and damage model effectiveness (c) material characterization, or (d) development and verification of rules for new construction and life assessment of high-temperature components subject to cyclic service with low frequencies or with periods of steady operation, or both. In every case, it is advisable to have complementary continuous cycling fatigue data (gathered at the same strain/loading rate) and creep data determined from test conducted as per Practice E139 for the same material and test temperature(s). The procedure is primarily concerned with the testing of round bar test specimens subjected (at least remotely) to uniaxial loading in either force or strain control. The focus of the procedure is on tests in which creep and fatigue deformation and damage is generated simultaneously within a given cycle. Data which may be determined from creep-fatigue tests performed under such conditions may characterize (a) cyclic stress-strain deformation response (b) cyclic creep (or relaxation) deformation response (c) cyclic hardening, cyclic softening response or (d) cycles to crack formation, or both. 4.3 While there are a number of testing Standards and Codes of Practice that cover the determination of low cycle fatigue deformation and cycles to crack initiation properties (See Practice E606, BS 7270: 2000, JIS Z 2279x2013;1992, PrEN 3874, 1998, PrEN 3988x2013;1998, ISO 12106x2013;2003, ISO 12111x2013;2005, and Practice E2368-04 and (1, 2, 3) , some of which provide guidance for testing at high temperature (for example, Practice E606, ISO 12106x2013;2003, and Practice E2368-04, there is no single standard which specifically prescribes a procedure for creep-fatigue testing.1.1 This test method covers the determination of mechanical properties pertaining to creep-fatigue deformation or crack formation in nominally homogeneous materials, or both by the use of test specimens subjected to uniaxial forces under isothermal conditions. It concerns fatigue testing at strain rates or with cycles involving sufficiently long hold times to be responsible for the cyclic deformation response and cycles to crack formation to be affected by creep (and oxidation). It is intended as a test method for fatigue testing performed in support of such activities as materials research and development, mechanical design, process and quality control, product performance, and failure analysis. The cyclic condi......
信息：ICS：19.060 (Mechanical testing) CCS：H22 发布：2009 实施：

简介： 信息：

ASTM E2760-19e1 蠕变疲劳裂纹扩展试验的标准试验方法
简介：
信息：ICS：77.040.10 CCS：发布：2019-11-01 实施：

ASME STP-NU-013-2008 91级微小蠕变和蠕变疲劳用ASME NH的改进
简介：This document provides recommendations for improvement of ASME Section III-NH, Components in Elevated Temperature Service, for Grade 91 in the areas of negligible creep and creep-fatigue. The report is separated into the following four parts. Part I - Examines the current approaches available to define negligible creep and checks their applicability to Grade 91 steel. The work is based on material data available in France and the U.S. Part II - Compares Subsection NH and RCC-MR creep-fatigue procedures. Comparisons are performed on cases defined on the basis of experimental test results available from Japan, France and the U.S. on Grade 91 steel. Particular attention was paid to the definition of safety factors and creep-fatigue damage envelope. Improvements to existing procedures are recommended. Part III - Aimed at defining tests necessary to validate negligible creep conditions for Mod 9Cr-1 Mo material. Part IV - Completes the work performed in Part II which, on the basis of creep-fatigue tests results available from Japan, Europe and the US, compared creep-fatigue procedures of ASME Subsection NH and RCC-MR Subsection RB.
信息：ICS：27.120.10;77.140.20 CCS：H22 发布：2008 实施：

简介： 信息：

ASTM E2760-16 蠕变疲劳裂纹扩展试验的标准试验方法
简介：
信息：ICS：77.040.10 CCS：发布：2016-11-01 实施：

ISO/TTA 5-2007 开裂构件的蠕变/疲劳试验用实施规程的规则
简介：The scope of this document is to recommend and establish standardized techniques for measuringand analysing Creep Crack Initiation (CCI), Creep Crack Growth (CCG), and Creep Fatigue CrackGrowth (CFCG) characteristics using a wide range of pre-cracked standard and non-standard 'feature'geometries. Specimens considered in this document are shown in APPENDIX I. The list of geometriesis not by any means complete and the user is advised to use appropriate information from otherdatabases for other geometries to derive the relevant fracture mechanics parameters (see Section 11)to use in the analysis. The validation of the parameters that are to be used however is important,especially where concern exists regarding the compatibility of test geometry with the actualcomponent in terms of size, the type of loading and stress state. This document allows increasedflexibility and a wider choice of geometries than previously were made available without comprisingon the important issues such as accuracy of testing and data measurements and the appropriatederivation of the correlating parameter. Less emphasis and detail has been placed on cycle dependentfatigue test methods compared to time dependent creep test methods as fatigue testing has beencomprehensively dealt with in other standards [g] and the parameters needed for its analysis arelinear elastic in nature and therefore simpler than the non-linear time dependent creep regime.
信息：ICS：19.060 CCS：P32 发布：2007-10-15 实施：

简介： 信息：

ASME STP-PT-070-2014 根据经分析设计和无损检验验收标准的蠕变, 疲劳以及蠕变疲劳检验效果用设计指南
简介：
信息：ICS： CCS：发布：2014-06-20 实施：

ISO/TTA 5:2007 破裂部件的蠕变/疲劳试验规范
简介：
信息：ICS：19.060 CCS：发布：2007-10-09 实施：

简介： 信息：

ASTM E2714-13 蠕变疲劳试验的标准试验方法
简介：
信息：ICS：19.060 CCS：发布：2013-06-15 实施：

ISO/TTA 5-2006 裂纹部件蠕变/疲劳试验实施规程
简介：
信息：ICS：19.060 CCS：发布：2006-12-05 实施：

简介： 信息：

ASTM E2714-2013 蠕变疲劳试验的标准试验方法
简介：4.1x00a0;Creep-fatigue testing is typically performed at elevated temperatures and involves the sequential or simultaneous application of the loading conditions necessary to generate cyclic deformation/damage enhanced by creep deformation/damage or vice versa. Unless such tests are performed in vacuum or an inert environment, oxidation can also be responsible for important interaction effects relating to damage accumulation. The purpose of creep-fatigue tests can be to determine material property data for (a) assessment input data for the deformation and damage condition analysis of engineering structures operating at elevated temperatures (b) the verification of constitutive deformation and damage model effectiveness (c) material characterization, or (d) development and verification of rules for new construction and life assessment of high-temperature components subject to cyclic service with low frequencies or with periods of steady operation, or both. 4.2x00a0; In every case, it is advisable to have complementary continuous cycling fatigue data (gathered at the same strain/loading rate) and creep data determined from test conducted as per Practice E139 for the same material and test temperature(s). The procedure is primarily concerned with the testing of round bar test specimens subjected (at least remotely) to uniaxial loading in either force or strain control. The focus of the procedure is on tests in which creep and fatigue deformation and damage is generated simultaneously within a given cycle. Data which may be determined from creep-fatigue tests performed under such conditions may characterize (a) cyclic stress-strain deformation response (b) cyclic creep (or relaxation) deformation response (c) cyclic hardening, cyclic softening response or (d) cycles to crack formation, or both. 4.3x00a0;While there are a number of testing Standards and Codes of Practice that cover the determination of low cycle fatigue deformation and cycles to crack initiation properties (See Practice E606, BS 7270: 2000, JIS Z 2279x2013;1992, PrEN 3874, 1998, PrEN 3988x2013;1998, ISO 12106x2013;2003, ISO 12111x2013;2005, and Practice E2368-04 and (1, 2, 3)7, some of which provide guidance for testing at high temperature (for example, Practice
信息：ICS：19.060 (Mechanical testing) CCS：发布：2013 实施：

MNC 323-1972 高温试验、蠕变试验、松弛试验和疲劳试验瑞典标准概述
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信息：ICS： CCS：发布：1972-06-30 实施：

简介： 信息：

ASME STP-NU-039-2012 焊接和结构性间断中的疲劳蠕变裂纹扩展和蠕变
简介：
信息：ICS：27.120.10 CCS：F69 发布：2012 实施：

简介： 信息：

ASME STP-NU-039-2011 非连接性结构和焊接处的蠕变和蠕变疲劳裂纹扩展
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信息：ICS： CCS：发布：2011-06-30 实施：

简介： 信息：

ASME STP-NU-041-2011 更新和改进分段NH.可替代简化的蠕变疲劳设计方法
简介：This report investigates five newly proposed creep-fatigue evaluation methods to improve the provisions on creep-fatigue evaluation of Mod.9Cr-1Mo steel in ASME Subsection NH (Class 1 Components in Elevated Temperature Service) of ASME Boiler and Pressure Vessel Code Section III: 1) Modified Ductility Exhaustion Method (MDEM), 2) Strain Range Separation Method (SRSM), 3) Approach for Pressure Vessel Applications (APVA), 4) Hybrid Method of Time Fraction and Ductility Exhaustion (Hybrid) 5) Simplified Model Test Approach (SMT).
信息：ICS：27.120.10;77.140.20 CCS：F69 发布：2011 实施：

简介： 信息：

ASME STP-NU-041-2011 更新和改进分段NH.可替代简化的蠕变疲劳设计方法
简介：
信息：ICS：27.120.10;77.140.20 CCS：F69 发布：2011 实施：

简介： 信息：

ASTM E2760-10e2 蠕变疲劳裂纹扩展试验的标准试验方法
简介：
信息：ICS：77.040.10 CCS：发布：2010-05-01 实施：

简介： 信息：

ASTM E2760-10e1 蠕变疲劳裂纹扩展试验的标准试验方法
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信息：ICS：77.040.10 CCS：发布：2010-05-01 实施：

简介： 信息：

ASTM E2760-10 蠕变疲劳裂纹扩展试验的标准试验方法
简介：
信息：ICS：77.040.10 CCS：发布：2010-05-01 实施：

简介： 信息：

ASTM E2760-2010e1 蠕变疲劳裂纹扩展试验的标准试验方法
简介：Creep-fatigue crack growth testing is typically performed at elevated temperatures over a range of frequencies and hold-times and involves the sequential or simultaneous application of the loading conditions necessary to generate crack tip cyclic deformation/damage enhanced by creep deformation/damage or vice versa. Unless such tests are performed in vacuum or an inert environment, oxidation can also be responsible for important interaction effects relating to damage accumulation. The purpose of creep-fatigue crack growth tests can be to determine material property data for (a) assessment input data for the damage condition analysis of engineering structures operating at elevated temperatures, (b) material characterization, or (c) development and verification of rules for design and life assessment of high-temperature components subject to cyclic service with low frequencies or with periods of steady operation, or a combination thereof. In every case, it is advisable to have complementary continuous cycling fatigue data (gathered at the same loading/unloading rate), creep crack growth data for the same material and test temperature(s) as per Test Method E1457, and creep-fatigue crack formation data as per Test Method E2714. Aggressive environments at high temperatures can significantly affect the creep-fatigue crack growth behavior. Attention must be given to the proper selection and control of temperature and environment in research studies and in generation of design data. Results from this test method can be used as follows: Establish material selection criteria and inspection requirements for damage tolerant applications where cyclic loading at elevated temperature is present. Establish, in quantitative terms, the individual and combined effects of metallurgical, fabrication, operating temperature, and loading variables on creep-fatigue crack growth life. The results obtained from this test method are designed for crack dominant regimes of creep-fatigue failure and should not be applied to cracks in structures with wide-spread creep damage. Localized damage in a small zone around the crack tip is permissible, but not in a zone that is comparable in size to the crack size or the remaining ligament size.1.1 This test method covers the determination of creep-fatigue crack growth properties of nominally homogeneous materials by use of pre-cracked compact type, C(T), test specimens subjected to uniaxial cyclic forces. It concerns fatigue cycling with sufficiently long loading/unloading rates or hold-times, or both, to cause creep deformation at the crack tip and the creep deformation be responsible for enhanced crack growth per loading cycle. It is intended as a guide for creep-fatigue testing performed in support of such activities as materials research and development, mechanical design, process and quality control, product performance, and failure analysis. Therefore, this method requires testing of at least two specimens that yield overlapping crack growth rate data. The cyclic conditions responsible for creep-fatigue deformation and enhanced crack growth vary with material and with temperature for a given material. The effects of environment such as time-dependent oxidation in enhancing the crack growth rates are assumed to be included in the test results; it is thus essential to conduct testing in an environment that is representative of the intended application. 1.2 Two types of crack growth mechanisms are observed during creep/fatigue tests: (1) time-dependent intergranular creep and (2) cycle dependent transgranular fatigu......
信息：ICS：77.040.10 (Mechanical testing of metals) CCS：H22 发布：2010 实施：

简介： 信息：

ASTM E2760-2010e2 蠕变-疲劳裂纹发展测试的标准试验方法
简介：4.1x00a0;Creep-fatigue crack growth testing is typically performed at elevated temperatures over a range of frequencies and hold-times and involves the sequential or simultaneous application of the loading conditions necessary to generate crack tip cyclic deformation/damage enhanced by creep deformation/damage or vice versa. Unless such tests are performed in vacuum or an inert environment, oxidation can also be responsible for important interaction effects relating to damage accumulation. The purpose of creep-fatigue crack growth tests can be to determine material property data for (a) assessment input data for the damage condition analysis of engineering structures operating at elevated temperatures, (b) material characterization, or (c) development and verification of rules for design and life assessment of high-temperature components subject to cyclic service with low frequencies or with periods of steady operation, or a combination thereof. 4.2x00a0;In every case, it is advisable to have complementary continuous cycling fatigue data (gathered at the same loading/unloading rate), creep crack growth data for the same material and test temperature(s) as per Test Method E1457, and creep-fatigue crack formation data as per Test Method E2714. Aggressive environments at high temperatures can significantly affect the creep-fatigue crack growth behavior. Attention must be given to the proper selection and control of temperature and environment in research studies and in generation of design data. 4.3x00a0;Results from this test method can be used as follows: 4.3.1x00a0;Establish material selection criteria and inspection requirements for damage tolerant applications where cyclic loading at elevated temperature is present. 4.3.2x00a0;Establish, in quantitative terms, the individual and combined effects of metallurgical, fabrication, operating temperature, and loading variables on creep-fatigue crack growth life. 4.4x00a0;The results obtained from this test method are designed for crack dominant regimes of creep-fatigue failure and should not be applied to cracks in structures with wide-spread creep damage. Localized damage in a small zone around the crack tip is permissible, but not in a zone that is comparable in size to the crack size or the remaining ligament size. 1.1x00a0;This test method covers the determination of creep-fatigue crack growth properties of nominally homogeneous materials by use of pre-cracked compact type, C(T), test specimens subjected to uniaxial cyclic forces. It concerns fatigue cycling with sufficiently long loading/unloading rates or hold-times, or both, to cause creep deformation at the crack tip and the creep deformation be responsible for enhanced crack growth per loading cycle. It is intended as a guide for creep-fatigue testing performed in support of such activities as materials research and development, mechanical design, process and quality control, product performance, and failure analysis. Therefore, this method requires testing of at least two specimens that yield overla......
信息：ICS：77.040.10 (Mechanical testing of metals) CCS：发布：2010 实施：

简介： 信息：

ASTM E2760-2010 蠕变—疲劳龟裂增大试验的标准试验方法
简介：Creep-fatigue crack growth testing is typically performed at elevated temperatures over a range of frequencies and hold-times and involves the sequential or simultaneous application of the loading conditions necessary to generate crack tip cyclic deformation/damage enhanced by creep deformation/damage or vice versa. Unless such tests are performed in vacuum or an inert environment, oxidation can also be responsible for important interaction effects relating to damage accumulation. The purpose of creep-fatigue crack growth tests can be to determine material property data for (a) assessment input data for the damage condition analysis of engineering structures operating at elevated temperatures, (b) material characterization, or (c) development and verification of rules for design and life assessment of high-temperature components subject to cyclic service with low frequencies or with periods of steady operation, or a combination thereof. In every case, it is advisable to have complementary continuous cycling fatigue data (gathered at the same loading/unloading rate), creep crack growth data for the same material and test temperature(s) as per Test Method E1457, and creep-fatigue crack formation data as per Test Method E2714. Aggressive environments at high temperatures can significantly affect the creep-fatigue crack growth behavior. Attention must be given to the proper selection and control of temperature and environment in research studies and in generation of design data. Results from this test method can be used as follows: Establish material selection criteria and inspection requirements for damage tolerant applications where cyclic loading at elevated temperature is present. Establish, in quantitative terms, the individual and combined effects of metallurgical, fabrication, operating temperature, and loading variables on creep-fatigue crack growth life. The results obtained from this test method are designed for crack dominant regimes of creep-fatigue failure and should not be applied to cracks in structures with wide-spread creep damage. Localized damage in a small zone around the crack tip is permissible, but not in a zone that is comparable in size to the crack size or the remaining ligament size.1.1 This test method covers the determination of creep-fatigue crack growth properties of nominally homogeneous materials by use of pre-cracked compact type, C(T), test specimens subjected to uniaxial cyclic forces. It concerns fatigue cycling with sufficiently long loading/unloading rates or hold-times, or both, to cause creep deformation at the crack tip and the creep deformation be responsible for enhanced crack growth per loading cycle. It is intended as a guide for creep-fatigue testing performed in support of such activities as materials research and development, mechanical design, process and quality control, product performance, and failure analysis. Therefore, this method requires testing of at least two specimens that yield overlapping crack growth rate data. The cyclic conditions responsible for creep-fatigue deformation and enhanced crack growth vary with material and with temperature for a given material. The effects of environment such as time-dependent oxidation in enhancing the crack growth rates are assumed to be included in the test results; it is thus essential to conduct testing in an environment that is representative of the intended application. 1.2 Two types of crack growth mechanisms are observed during creep/fatigue tests: (1) time-dependent intergranular creep and (2) cycle dependent transgranular fatigu......
信息：ICS：77.040.10 CCS：H22 发布：2010 实施：

简介： 信息：

ASTM E2714-09 蠕变疲劳试验的标准试验方法
简介：
信息：ICS：19.060 CCS：发布：2009-11-01 实施：

简介： 信息：

ASTM E2714-09e1 蠕变疲劳试验的标准试验方法
简介：
信息：ICS：19.060 CCS：发布：2009-11-01 实施：

简介： 信息：