二相ステンレス鋼の溶接金属における水素割れ発生特性に及ぼす微視組織の影響に関する数値解析

DOI DOI Web Site Web Site Web Site 被引用文献1件 参考文献15件 オープンアクセス
  • Ogita Gen
    Division of Materials and Manufacturing Science, Graduate School of Engineering, Osaka University Chiyoda Corporation
  • Matsumoto Koki
    Division of Materials and Manufacturing Science, Graduate School of Engineering, Osaka University
  • Mochizuki Masahito
    Division of Materials and Manufacturing Science, Graduate School of Engineering, Osaka University
  • Mikami Yoshiki
    Joining and Welding Research Institute, Osaka University
  • Ito Kazuhiro
    Joining and Welding Research Institute, Osaka University

書誌事項

タイトル別名
  • Numerical Simulation on Effect of Microstructure on Hydrogen-induced Cracking Behavior in Duplex Stainless Steel Weld Metal
  • ニソウ ステンレスコウ ノ ヨウセツ キンゾク ニ オケル スイソ ワレ ハッセイ トクセイ ニ オヨボス ビシ ソシキ ノ エイキョウ ニ カンスル スウチ カイセキ

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説明

<p>Duplex stainless steels and their deposited weld metal have ferrite and austenite microstructures with different material properties. In addition, the microstructure of the base metal and weld metal clearly differs, affecting hydrogen diffusion and accumulation, and hydrogen-induced cracking behavior at the microstructural scale. In this study, the influence of microstructure on hydrogen-induced cracking behavior of the duplex stainless-steel weld metal was investigated. Duplex stainless-steel weld metal specimens were prepared and slow strain rate tensile test was performed after hydrogen charging. Cracks were observed at the ferrite/austenite boundaries. A microstructure-based finite element simulation was performed to clarify the concentration distribution at the microstructural scale. A finite element model based on the cross-section of the microstructure was designed to calculate the stress and hydrogen concentration distribution. The simulation result showed that hydrogen accumulation occurred at the ferrite/austenite boundaries, which corresponded to the locations where cracks were observed. On the other hand, the hydrogen concentration at the accumulation site in the weld metal was lower than that in the base metal. Therefore, the influence of the phase fraction and stress–strain curves of the ferrite and austenite phases on the hydrogen concentration was investigated by the proposed numerical simulation. Both phase fraction and stress–strain curves significantly influenced the microscopic distribution of hydrogen concentration.</p>

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