Transient Hydrogen Diffusion/Elastoplastic Coupling Analysis for Predicting Fatigue Crack Growth Acceleration of Low-Carbon Steel in Gaseous Hydrogen

Volume 6B: Materials and Fabrication Pub Date : 2018-07-15 DOI:10.1115/PVP2018-84390

Kai Kawahara, M. Fujikawa, J. Yamabe

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引用次数: 1

Abstract

In recent years, hydrogen, one of renewable energy, has attracted attention. For widespread commercialization of the hydrogen-energy systems, a useful and reliable evaluation method should be developed for capturing the degradation of strength and fatigue properties of metals in presence of hydrogen. This paper implemented transient hydrogen diffusion-elastoplastic coupling analysis program into a commercial software of Finite Element Analysis (Abaqus) to predict the fatigue crack growth (FCG) acceleration of a low carbon steel (JIS-SM490B) in high-pressure hydrogen gas. For this simulation, hydrogen-diffusion properties (concentration and diffusivity) depending on plastic strain were experimentally obtained. Our thorough numerical results proposed a practical technique to predict an onset of hydrogen-enhanced FCG acceleration measured in experiments, via the numerically obtained gradient of hydrogen concentration at the crack tip. In addition, a practical technique to predict the hydrogen-enhanced FCG acceleration ratio was also discussed based on the gradient of hydrogen concentration.

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预测低碳钢在气态氢中疲劳裂纹扩展加速的氢扩散/弹塑性耦合分析

近年来，氢作为一种可再生能源引起了人们的关注。为了氢能源系统的广泛商业化，应该开发一种有用和可靠的评估方法来捕获氢存在下金属强度和疲劳性能的退化。本文在商用有限元分析软件Abaqus中实现了瞬态氢扩散-弹塑性耦合分析程序，对某低碳钢(JIS-SM490B)在高压氢气作用下的疲劳裂纹扩展加速度进行了预测。在此模拟中，实验得到了氢随塑性应变的扩散特性(浓度和扩散系数)。我们全面的数值结果提出了一种实用的技术来预测氢增强FCG加速度的开始，通过数值计算得到的裂缝尖端的氢浓度梯度。此外，还讨论了一种基于氢浓度梯度预测氢增强FCG加速比的实用技术。

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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