P92钢不同保温时间的相热疲劳研究

IF 1.6 4区 材料科学 Q4 MATERIALS SCIENCE, MULTIDISCIPLINARY
Xin Li, Chang-yu Zhou, X. Pan, L. Chang, Lei Lu, Guodong Zhang, F. Xue, Yanfen Zhao
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引用次数: 0

摘要

摘要0、20和40的保持时间的影响 研究了P92钢的同相热机械疲劳行为和寿命。TMF试验是在机械应变控制下进行的,应变幅度分别为0.4、0.6、0.6和0.8%,温度范围为550–650°C,这与发电厂的运行条件密切相关。TMF试验是在R=−1 R=-1的机械应变比和120的循环时间下进行的 s.疲劳寿命变化遵循N f 0 s本文章由计算机程序翻译,如有差异,请以英文原文为准。
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In-phase thermomechanical fatigue studies on P92 steel with different hold time
Abstract The effect of hold time with 0, 20, and 40 s on in-phase thermomechanical fatigue (TMF) behavior and life of P92 steel is investigated in this study. TMF tests are carried out under mechanical strain control with strain amplitudes of 0.4 0.4 , 0.6 0.6 , and 0.8 % 0.8\text{\%} , and temperature range of 550–650°C which is closely relevant to the operating condition in power plant. TMF tests are performed in a mechanical strain ratio of R = − 1 R=-1 and cycle time of 120 s. The fatigue life variation follows the sequence of N f 0 s < N f 20 s < N f 40 s {N}_{\text{f}}^{0\hspace{.1em}\text{s}}\lt {N}_{\text{f}}^{20\hspace{.1em}\text{s}}\lt {N}_{\text{f}}^{40\hspace{.1em}\text{s}} for the same mechanical strain amplitude. In addition, the influence of hold time on fatigue life decreases with the increasing strain amplitude. A continuous softening can be observed from the cyclic stress response under all test conditions. Fractographic and microstructural tests indicate that the fracture surfaces are characterized by a multi-source cracking initiation and an oxidation phenomenon. Furthermore, a modified Ostergren model is used to predict the fatigue life and achieves a good predicted result.
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来源期刊
High Temperature Materials and Processes
High Temperature Materials and Processes 工程技术-材料科学:综合
CiteScore
2.50
自引率
0.00%
发文量
42
审稿时长
3.9 months
期刊介绍: High Temperature Materials and Processes offers an international publication forum for new ideas, insights and results related to high-temperature materials and processes in science and technology. The journal publishes original research papers and short communications addressing topics at the forefront of high-temperature materials research including processing of various materials at high temperatures. Occasionally, reviews of a specific topic are included. The journal also publishes special issues featuring ongoing research programs as well as symposia of high-temperature materials and processes, and other related research activities. Emphasis is placed on the multi-disciplinary nature of high-temperature materials and processes for various materials in a variety of states. Such a nature of the journal will help readers who wish to become acquainted with related subjects by obtaining information of various aspects of high-temperature materials research. The increasing spread of information on these subjects will also help to shed light on relevant topics of high-temperature materials and processes outside of readers’ own core specialties.
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