Intersonic crack propagation in homogeneous media under shear-dominated loading: Theoretical analysis

Dhirendra V. Kubair; Philippe H. Geubelle; Yonggang Y. Huang

doi:10.1016/S0022-5096(02)00005-4

Intersonic crack propagation in homogeneous media under shear-dominated loading: Theoretical analysis

Dhirendra V. Kubair, Philippe H. Geubelle, Yonggang Y. Huang

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

Abstract

The mechanics of cohesive failure under mixed-mode loading is investigated for the case of a steadily propagating subsonic and intersonic dynamic crack subjected to a follower tensile and shear distributed load. The cohesive failure model chosen in this study is rate independent but accounts for the coupling between normal and tangential damage. Special emphasis is placed here on mixed-mode cases with predominantly shear loading. The analysis shows that the size of the mixed-mode cohesive zone is smaller than that obtained in the pure shear case. The relative extent of the shear and tensile cohesive damage zones depends on the crack speed and the mode mixity. In the intersonic regime, the failure process takes place exclusively in shear, even under remote mixed-mode loading conditions.

Original language	English (US)
Pages (from-to)	1547-1564
Number of pages	18
Journal	Journal of the Mechanics and Physics of Solids
Volume	50
Issue number	8
DOIs	https://doi.org/10.1016/S0022-5096(02)00005-4
State	Published - Aug 2002

Keywords

A. Dynamic fracture
B. Elastic material
C. Boundary integral equations

ASJC Scopus subject areas

Condensed Matter Physics
Mechanics of Materials
Mechanical Engineering

Online availability

10.1016/S0022-5096(02)00005-4

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title = "Intersonic crack propagation in homogeneous media under shear-dominated loading: Theoretical analysis",

abstract = "The mechanics of cohesive failure under mixed-mode loading is investigated for the case of a steadily propagating subsonic and intersonic dynamic crack subjected to a follower tensile and shear distributed load. The cohesive failure model chosen in this study is rate independent but accounts for the coupling between normal and tangential damage. Special emphasis is placed here on mixed-mode cases with predominantly shear loading. The analysis shows that the size of the mixed-mode cohesive zone is smaller than that obtained in the pure shear case. The relative extent of the shear and tensile cohesive damage zones depends on the crack speed and the mode mixity. In the intersonic regime, the failure process takes place exclusively in shear, even under remote mixed-mode loading conditions.",

keywords = "A. Dynamic fracture, B. Elastic material, C. Boundary integral equations",

author = "Kubair, {Dhirendra V.} and Geubelle, {Philippe H.} and Huang, {Yonggang Y.}",

note = "Funding Information: Part of this work has been supported by the ASCI Center for the Simulation of Advanced Rockets funded by the US Department of Energy through the University of California under subcontract number B341494. Y.H. acknowledges the support from ONR (grant N00014-01-1-0205, program monitor Dr. Y.D.S. Rajapakse). ",

year = "2002",

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doi = "10.1016/S0022-5096(02)00005-4",

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T1 - Intersonic crack propagation in homogeneous media under shear-dominated loading

T2 - Theoretical analysis

AU - Kubair, Dhirendra V.

AU - Geubelle, Philippe H.

AU - Huang, Yonggang Y.

N1 - Funding Information: Part of this work has been supported by the ASCI Center for the Simulation of Advanced Rockets funded by the US Department of Energy through the University of California under subcontract number B341494. Y.H. acknowledges the support from ONR (grant N00014-01-1-0205, program monitor Dr. Y.D.S. Rajapakse).

PY - 2002/8

Y1 - 2002/8

N2 - The mechanics of cohesive failure under mixed-mode loading is investigated for the case of a steadily propagating subsonic and intersonic dynamic crack subjected to a follower tensile and shear distributed load. The cohesive failure model chosen in this study is rate independent but accounts for the coupling between normal and tangential damage. Special emphasis is placed here on mixed-mode cases with predominantly shear loading. The analysis shows that the size of the mixed-mode cohesive zone is smaller than that obtained in the pure shear case. The relative extent of the shear and tensile cohesive damage zones depends on the crack speed and the mode mixity. In the intersonic regime, the failure process takes place exclusively in shear, even under remote mixed-mode loading conditions.

AB - The mechanics of cohesive failure under mixed-mode loading is investigated for the case of a steadily propagating subsonic and intersonic dynamic crack subjected to a follower tensile and shear distributed load. The cohesive failure model chosen in this study is rate independent but accounts for the coupling between normal and tangential damage. Special emphasis is placed here on mixed-mode cases with predominantly shear loading. The analysis shows that the size of the mixed-mode cohesive zone is smaller than that obtained in the pure shear case. The relative extent of the shear and tensile cohesive damage zones depends on the crack speed and the mode mixity. In the intersonic regime, the failure process takes place exclusively in shear, even under remote mixed-mode loading conditions.

KW - A. Dynamic fracture

KW - B. Elastic material

KW - C. Boundary integral equations

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U2 - 10.1016/S0022-5096(02)00005-4

DO - 10.1016/S0022-5096(02)00005-4

M3 - Article

AN - SCOPUS:0036681260

SN - 0022-5096

VL - 50

SP - 1547

EP - 1564

JO - Journal of the Mechanics and Physics of Solids

JF - Journal of the Mechanics and Physics of Solids

IS - 8

ER -

Intersonic crack propagation in homogeneous media under shear-dominated loading: Theoretical analysis

Abstract

Keywords

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