Crack propagation behavior of different zones in weldment under creep-fatigue loadings

Dewen Zhou; Xiaowei Wang; Letian Gao; Heng Li; Jianxin Liu; Zitong Kang; Tianyu Zhang; Xiancheng Zhang; Jianming Gong; Shantung Tu

doi:10.1016/j.engfracmech.2024.110416

Crack propagation behavior of different zones in weldment under creep-fatigue loadings

Dewen Zhou, Xiaowei Wang, Letian Gao, Heng Li, Jianxin Liu, Zitong Kang, Tianyu Zhang, Xiancheng Zhang, Jianming Gong, Shantung Tu

School of Mechanical and Power Engineering

Research output: Contribution to journal › Article › peer-review

1 Scopus citations

Abstract

In this paper, crack propagation behaviors in a weldment are simulated under cyclic loadings using crystal plasticity finite element coupled with the XFEM. The result shows that the cracks in heat affected zone grow faster than that in the welded zone. Short crack propagation dominated by dislocation activity takes approximately 4 to 5 grains, followed by long crack propagation which is unrelated to dislocation activity and the growth direction kept an angle to the loading direction (45°-51°). Experimentally observed deflections within grains and at grain boundaries, retardation at grain boundaries are captured by the simulation.

Original language	English
Article number	110416
Journal	Engineering Fracture Mechanics
Volume	310
DOIs	https://doi.org/10.1016/j.engfracmech.2024.110416
State	Published - 8 Nov 2024

Keywords

Crack propagation
Crystal plasticity finite element
eXtended Finite Element Method
P92 steel welded joint

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10.1016/j.engfracmech.2024.110416

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title = "Crack propagation behavior of different zones in weldment under creep-fatigue loadings",

abstract = "In this paper, crack propagation behaviors in a weldment are simulated under cyclic loadings using crystal plasticity finite element coupled with the XFEM. The result shows that the cracks in heat affected zone grow faster than that in the welded zone. Short crack propagation dominated by dislocation activity takes approximately 4 to 5 grains, followed by long crack propagation which is unrelated to dislocation activity and the growth direction kept an angle to the loading direction (45°-51°). Experimentally observed deflections within grains and at grain boundaries, retardation at grain boundaries are captured by the simulation.",

keywords = "Crack propagation, Crystal plasticity finite element, eXtended Finite Element Method, P92 steel welded joint",

author = "Dewen Zhou and Xiaowei Wang and Letian Gao and Heng Li and Jianxin Liu and Zitong Kang and Tianyu Zhang and Xiancheng Zhang and Jianming Gong and Shantung Tu",

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doi = "10.1016/j.engfracmech.2024.110416",

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T1 - Crack propagation behavior of different zones in weldment under creep-fatigue loadings

AU - Zhou, Dewen

AU - Wang, Xiaowei

AU - Gao, Letian

AU - Li, Heng

AU - Liu, Jianxin

AU - Kang, Zitong

AU - Zhang, Tianyu

AU - Zhang, Xiancheng

AU - Gong, Jianming

AU - Tu, Shantung

PY - 2024/11/8

Y1 - 2024/11/8

N2 - In this paper, crack propagation behaviors in a weldment are simulated under cyclic loadings using crystal plasticity finite element coupled with the XFEM. The result shows that the cracks in heat affected zone grow faster than that in the welded zone. Short crack propagation dominated by dislocation activity takes approximately 4 to 5 grains, followed by long crack propagation which is unrelated to dislocation activity and the growth direction kept an angle to the loading direction (45°-51°). Experimentally observed deflections within grains and at grain boundaries, retardation at grain boundaries are captured by the simulation.

AB - In this paper, crack propagation behaviors in a weldment are simulated under cyclic loadings using crystal plasticity finite element coupled with the XFEM. The result shows that the cracks in heat affected zone grow faster than that in the welded zone. Short crack propagation dominated by dislocation activity takes approximately 4 to 5 grains, followed by long crack propagation which is unrelated to dislocation activity and the growth direction kept an angle to the loading direction (45°-51°). Experimentally observed deflections within grains and at grain boundaries, retardation at grain boundaries are captured by the simulation.

KW - Crack propagation

KW - Crystal plasticity finite element

KW - eXtended Finite Element Method

KW - P92 steel welded joint

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U2 - 10.1016/j.engfracmech.2024.110416

DO - 10.1016/j.engfracmech.2024.110416

M3 - 文章

AN - SCOPUS:85203189353

SN - 0013-7944

VL - 310

JO - Engineering Fracture Mechanics

JF - Engineering Fracture Mechanics

M1 - 110416

ER -

Crack propagation behavior of different zones in weldment under creep-fatigue loadings

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Keywords

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