Creep-fatigue Life Design Methods in High-temperature Structures: From Materials to Components

被引：0

作者：

Wang R. ^{[1
]}

Liao D. ^{[2
]}

Zhang X. ^{[1
]}

Zhu S. ^{[2
]}

Tu S. ^{[1
]}

Guo S. ^{[1
]}

机构：

[1] Key Laboratory of Pressure Systems and Safety, Ministry of Education, East China University of Science and Technology, Shanghai

[2] Center for System Reliability & Safety, University of Electronic Science and Technology of China, Chengdu

来源：

Jixie Gongcheng Xuebao/Journal of Mechanical Engineering | 2021年 / 57卷 / 16期

关键词：

Creep-fatigue; Damage assessment; Life design; Multiaxial stress; Reliability method;

D O I：

10.3901/JME.2021.16.066

中图分类号：

学科分类号：

摘要：

Structural components used in many fields operate under harsh environment of high temperatures and cyclic loadings, the service process of which is always associated with serious creep-fatigue interactions. With the urgent demands of long life and high reliability of high-temperature structures, the creep-fatigue life design method has been paid more and more attentions from both engineering and academics. The creep-fatigue interaction is firstly introduced, and microscopic damage mechanisms under complex creep-fatigue loading waveforms are subsequently summarized. At the material level, creep-fatigue life prediction models based on different theoretical methods are reviewed. At the structural level, the effect of multiaxial stress on creep and fatigue damage is clarified and the life design method based on creep-fatigue interaction diagram is elaborated. Moreover, the creep-fatigue reliability analysis method ranging from creep-fatigue crack initiation to propagation is reviewed. Finally, further directions on creep-fatigue study are explored and concluded. © 2021 Journal of Mechanical Engineering.

引用

页码：66 / 86and105

共 133 条

[21] WEN J F, TU S T, XUAN F Z, Et al., Effects of stress level and stress state on creep ductility: evaluation of different models, Journal of Materials Science & Technology, 32, 8, pp. 695-704, (2016)
[22] PLUMBRIDGE W J., Metallography of high temperature fatigue, High temperature fatigue: Properties and prediction, (1987)
[23] HALES R., A quantitative metallographic assessment of structural degradation of type 316 stainless steel during creep-fatigue, Fatigue & Fracture of Engineering Materials & Structures, 3, 4, pp. 339-356, (1980)
[24] YE S, ZHANG C C, ZHANG P Y, Et al., Fatigue life prediction of nickel-based GH4169 alloy on the basis of a multi-scale crack propagation approach, Engineering Fracture Mechanics, 199, pp. 29-40, (2018)
[25] WANG R Z, ZHU S P, WANG J, Et al., High temperature fatigue and creep-fatigue behaviors in a Ni-based superalloy: Damage mechanisms and life assessment, International Journal of Fatigue, 118, pp. 8-21, (2019)
[26] BILLOT T, VILLECHAISE P, JOUIAD M, Et al., Creep-fatigue behavior at high temperature of a UDIMET 720 nickel-base superalloy, International Journal of Fatigue, 32, 5, pp. 824-829, (2010)
[27] MANNAN S L, VALSAN M., High-temperature low cycle fatigue, creep-fatigue and thermomechanical fatigue of steels and their welds, International Journal of Mechanical Sciences, 48, 2, pp. 160-175, (2006)
[28] CHALLENGER K D, MILLER A K, BRINKMAN C R., An explanation for the effects of hold periods on the elevated temperature fatigue behavior of 2 1/4 Cr-1 Mo steel, Journal of Engineering Materials and Technology, 103, 1, pp. 7-14, (1981)
[29] FOURNIER B, SAUZAY M, CAES C, Et al., Creep-fatigue-oxidation interactions in a 9Cr-1Mo martensitic steel. Part II: Effect of compressive holding period on fatigue lifetime, International Journal of Fatigue, 30, 4, pp. 663-676, (2008)
[30] AOTO K, KOMINE R, UENO F, Et al., Creep-fatigue evaluation of normalized and tempered modified 9Cr-1Mo, Nuclear Engineering and Design, 153, 1, pp. 97-110, (1994)

← 1 2 3 4 5 6 7 8 9 10 →