Fatigue crack growth under compressive loading

Koichi Kasaba; Takahiro Sano; Souichi Kudo; Tetsuo Shoji; Kazumune Katagiri; Tadashi Sato

doi:10.1016/S0022-3115(98)00343-2

Fatigue crack growth under compressive loading

Koichi Kasaba^*, Takahiro Sano, Souichi Kudo, Tetsuo Shoji, Kazumune Katagiri, Tadashi Sato

^*この論文の責任著者

工学科　機械工学コース

研究成果: ジャーナルへの寄稿 › 学術論文 › 査読

37 被引用数 (Scopus)

抄録

S/C magnets have many components which were designed to be compressively stressed. This paper describes a possible fatigue crack growth even under fully compressive stresses. In general crack is thought to close under compressive stress condition. But, if there is a tensile residual stress field in the specimen, the crack can open and grow to a considerable length. Compressive cyclic loading tests were made on the compact tension specimen with a hole at the center of ligament region where a tensile residual stress field was introduced by an excessive compressive pre-stress. Elastoplastic Finite Element Method (FEM) analysis indicated that the crack growth relaxed and re-distributed the residual tensile stress to some extent. In consequence it is experimentally verified that the crack grew to the length nearly to the fracture.

本文言語	英語
ページ（範囲）	2059-2063
ページ数	5
ジャーナル	Journal of Nuclear Materials
巻	258-263
号	PART 2 B
DOI	https://doi.org/10.1016/S0022-3115(98)00343-2
出版ステータス	出版済み - 1998/10

ASJC Scopus 主題領域

核物理学および高エネルギー物理学
材料科学一般
原子力エネルギーおよび原子力工学

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10.1016/S0022-3115(98)00343-2

引用スタイル

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title = "Fatigue crack growth under compressive loading",

abstract = "S/C magnets have many components which were designed to be compressively stressed. This paper describes a possible fatigue crack growth even under fully compressive stresses. In general crack is thought to close under compressive stress condition. But, if there is a tensile residual stress field in the specimen, the crack can open and grow to a considerable length. Compressive cyclic loading tests were made on the compact tension specimen with a hole at the center of ligament region where a tensile residual stress field was introduced by an excessive compressive pre-stress. Elastoplastic Finite Element Method (FEM) analysis indicated that the crack growth relaxed and re-distributed the residual tensile stress to some extent. In consequence it is experimentally verified that the crack grew to the length nearly to the fracture.",

author = "Koichi Kasaba and Takahiro Sano and Souichi Kudo and Tetsuo Shoji and Kazumune Katagiri and Tadashi Sato",

year = "1998",

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T1 - Fatigue crack growth under compressive loading

AU - Kasaba, Koichi

AU - Sano, Takahiro

AU - Kudo, Souichi

AU - Shoji, Tetsuo

AU - Katagiri, Kazumune

AU - Sato, Tadashi

PY - 1998/10

Y1 - 1998/10

N2 - S/C magnets have many components which were designed to be compressively stressed. This paper describes a possible fatigue crack growth even under fully compressive stresses. In general crack is thought to close under compressive stress condition. But, if there is a tensile residual stress field in the specimen, the crack can open and grow to a considerable length. Compressive cyclic loading tests were made on the compact tension specimen with a hole at the center of ligament region where a tensile residual stress field was introduced by an excessive compressive pre-stress. Elastoplastic Finite Element Method (FEM) analysis indicated that the crack growth relaxed and re-distributed the residual tensile stress to some extent. In consequence it is experimentally verified that the crack grew to the length nearly to the fracture.

AB - S/C magnets have many components which were designed to be compressively stressed. This paper describes a possible fatigue crack growth even under fully compressive stresses. In general crack is thought to close under compressive stress condition. But, if there is a tensile residual stress field in the specimen, the crack can open and grow to a considerable length. Compressive cyclic loading tests were made on the compact tension specimen with a hole at the center of ligament region where a tensile residual stress field was introduced by an excessive compressive pre-stress. Elastoplastic Finite Element Method (FEM) analysis indicated that the crack growth relaxed and re-distributed the residual tensile stress to some extent. In consequence it is experimentally verified that the crack grew to the length nearly to the fracture.

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VL - 258-263

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EP - 2063

JO - Journal of Nuclear Materials

JF - Journal of Nuclear Materials

IS - PART 2 B

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Fatigue crack growth under compressive loading

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