ジャーナル論文 Distinctive fatigue properties of additively-formed CoCrFeNiTiMo multi-principal element alloy: Excellent fatigue crack growth resistance against ordinally high cycle fatigue strength
Hideaki Nishikawa (author) (この著者で検索)
ORCID https://orcid.org/0000-0002-2484-6903
National Institute of Materials Science (NIMS)
SAMURAI NIMS Researchers Directory SAMURAI
ORCID SAMURAI ;
Yoshiyuki Furuya (author) (この著者で検索)
National Institute of Materials Science (NIMS)
;
Houichi Kitano (author) (この著者で検索)
National Institute of Materials Science (NIMS)
;
Yoshiharu Kanegae (author) (この著者で検索)
Proterial, Ltd.
;
Kinya Aota (author) (この著者で検索)
Proterial, Ltd.
;
Kosuke Kuwabara (author) (この著者で検索)
Proterial, Ltd.
コレクション

引用
Hideaki Nishikawa, Yoshiyuki Furuya, Houichi Kitano, Yoshiharu Kanegae, Kinya Aota, Kosuke Kuwabara. Distinctive fatigue properties of additively-formed CoCrFeNiTiMo multi-principal element alloy: Excellent fatigue crack growth resistance against ordinally high cycle fatigue strength. MATERIALS SCIENCE AND ENGINEERING A-STRUCTURAL MATERIALS PROPERTIES MICROSTRUCTURE AND PROCESSING. 2023, 891 (), 0-0. https://doi.org/10.1016/j.msea.2023.145938
SAMURAI

説明:

(abstract)

In this study, the fatigue characteristics of additively-formed multi-principal element alloy (MPEA) of Co1.5CrFeNi1.5Ti0.5Mo0.1 (CoCrFeNiTiMo alloy) were systematically compared with conventional hot-rolled and additively-formed Alloy 718 nickel-based super alloy, which have comparable mechanical properties. Evaluated fatigue properties were the low- to high-cycle fatigue strengths of plane and notched specimens, and long / short fatigue crack growth (FCG) resistance. The results showed the fatigue strength of CoCrFeNiTiMo alloy to be comparable to that of Alloy 718 for smooth specimens, while the fatigue strength of notched specimens was 50% higher. Superior notch fatigue strength can be quantitatively explained in terms of outstanding long fatigue crack growth resistance. Regardless of load ratio, CoCrFeNiTiMo exhibits
superior FCG resistance that greatly surpasses that of conventional Fe and Ni alloys. In contrast, the short FCG resistance of CoCrFeNiTiMo was comparable to that of Alloy 718, which corresponds to the fatigue strength level of a smooth specimen. Investigation of fatigue fracture surface and microscopic slip deformation morphology around the fatigue crack indicates that CoCrFeNiTiMo alloy exhibits more planar slip
deformation than Alloy 718. Slip constraint stimulated by slip planarity appears to have an important role in short and long FCG resistance when cracks cross grain boundaries.

権利情報:

キーワード: Fatigue, Additive manufacturing, High entropy alloy, Multi principal element alloy, Short fatigue crack

刊行年月日: 2023-11-25

出版者: Elsevier BV

掲載誌:

  • MATERIALS SCIENCE AND ENGINEERING A-STRUCTURAL MATERIALS PROPERTIES MICROSTRUCTURE AND PROCESSING (ISSN: 18734936) vol. 891 p. 0-0

研究助成金:

原稿種別: 著者最終稿 (Accepted manuscript)

MDR DOI: https://doi.org/10.48505/nims.4289

公開URL: https://doi.org/10.1016/j.msea.2023.145938

関連資料:

その他の識別子:

連絡先: Hideaki Nishikawa (National Institute of Materials Science (NIMS)) NISHIKAWA.Hideaki@nims.go.jp

更新時刻: 2025-11-25 08:30:10 +0900

MDRでの公開時刻: 2025-11-25 08:21:41 +0900

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