Temperature Dependence of Fatigue Crack Growth in Low-Alloy Steel Under Gaseous Hydrogen

Volume 6B: Materials and Fabrication Pub Date : 2018-07-15 DOI:10.1115/PVP2018-84438

O. Takakuwa, S. Matsuoka, S. Okazaki, M. Yoshikawa, J. Yamabe, H. Matsunaga

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Abstract

In order to elucidate the temperature dependence of hydrogen-enhanced fatigue crack growth (FCG), the FCG test was performed on low-alloy Cr-Mo steel JIS-SCM435 according to ASTM E647 using compact tension (CT) specimen under 0.1–95 MPa hydrogen-gas at temperature ranging from room temperature (298 K) to 423 K. The obtained results were interpreted according to trap site occupancy under thermal equilibrium state. The FCG was significantly accelerated at RT under hydrogen-gas, that its maximum acceleration rate of the FCG was 15 at the pressure of 95 MPa at the temperature of 298 K. The hydrogen-enhanced FCG was mitigated due to temperature elevation for all pressure conditions. The trap site with binding energy of 44 kJ/mol dominated the temperature dependence of hydrogen-enhanced FCG, corresponding approximately to binding energy of dislocation core. The trap site (dislocation) occupancy is decreased with the temperature elevation, resulting in the mitigation of the FCG acceleration. On the basis of the obtained results, when the occupancy becomes higher at lower temperature, e.g. 298 K, hydrogen-enhanced FCG becomes more pronounced. The lower occupancy at higher temperature does the opposite.

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气态氢作用下低合金钢疲劳裂纹扩展的温度依赖性

为了阐明氢增强疲劳裂纹扩展(FCG)的温度依赖性，根据ASTM E647的要求，在室温(298 K)至423 K的温度范围内，用致密拉伸(CT)试样在0.1-95 MPa的氢气条件下对低合金Cr-Mo钢JIS-SCM435进行了FCG试验。所得结果是根据热平衡状态下的陷阱位置占用来解释的。在加氢条件下，温度298 K、压力95 MPa时，FCG的最大加速速率为15。在所有压力条件下，由于温度升高，氢增强FCG得到了缓解。氢增强FCG的温度依赖性以结合能为44 kJ/mol的阱位为主，与位错核的结合能近似对应。圈闭位置(位错)占用随温度升高而减少，导致FCG加速减缓。根据得到的结果，在较低的温度下，如298 K，占用率越高，氢增强的FCG越明显。温度越高，占用率越低，反之亦然。

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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Volume 6B: Materials and Fabrication

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