Mechanism-based strength criterion for 3D needled C/C–SiC composites under in-plane biaxial compression

Zhen Chen; Guodong Fang; Junbo Xie; Jun Liang

doi:10.1080/15376494.2018.1452316

Mechanism-based strength criterion for 3D needled C/C–SiC composites under in-plane biaxial compression

Zhen Chen, Guodong Fang^*, Junbo Xie, Jun Liang

^*Corresponding author for this work

Institute of Advanced Structure Technology

Harbin Institute of Technology

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

6 Citations (Scopus)

Abstract

Biaxial compressive experiments for 3D needled C/C–SiC composites parallel to the nonwoven cloth were conducted. The failure mechanisms and mechanical properties of the composites were greatly related to the biaxial compressive stress confinement ratio, R. It was found that out-of-plane shear failure controlled the failure of the composites. The failure shear plane was aligned with one of the major loading axes for R (0:1 or 1:3), while the failure shear plane occurred along both loading axes for R (1:2 or 1:1). Compared with uniaxial strength, the biaxial compressive strength increased obviously, which also significantly depended on the value of R. Based on the failure modes, a modified twin-shear strength criterion was established to predict the failure surface of 3D needled C/C–SiC composites under biaxial compressive loading.

Original language	English
Pages (from-to)	1841-1848
Number of pages	8
Journal	Mechanics of Advanced Materials and Structures
Volume	26
Issue number	22
DOIs	https://doi.org/10.1080/15376494.2018.1452316
Publication status	Published - 17 Nov 2019

Keywords

Needled composites
biaxial testing
failure mechanisms
failure shear plane
strength criterion

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10.1080/15376494.2018.1452316

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title = "Mechanism-based strength criterion for 3D needled C/C–SiC composites under in-plane biaxial compression",

abstract = "Biaxial compressive experiments for 3D needled C/C–SiC composites parallel to the nonwoven cloth were conducted. The failure mechanisms and mechanical properties of the composites were greatly related to the biaxial compressive stress confinement ratio, R. It was found that out-of-plane shear failure controlled the failure of the composites. The failure shear plane was aligned with one of the major loading axes for R (0:1 or 1:3), while the failure shear plane occurred along both loading axes for R (1:2 or 1:1). Compared with uniaxial strength, the biaxial compressive strength increased obviously, which also significantly depended on the value of R. Based on the failure modes, a modified twin-shear strength criterion was established to predict the failure surface of 3D needled C/C–SiC composites under biaxial compressive loading.",

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AU - Chen, Zhen

AU - Fang, Guodong

AU - Xie, Junbo

AU - Liang, Jun

PY - 2019/11/17

Y1 - 2019/11/17

N2 - Biaxial compressive experiments for 3D needled C/C–SiC composites parallel to the nonwoven cloth were conducted. The failure mechanisms and mechanical properties of the composites were greatly related to the biaxial compressive stress confinement ratio, R. It was found that out-of-plane shear failure controlled the failure of the composites. The failure shear plane was aligned with one of the major loading axes for R (0:1 or 1:3), while the failure shear plane occurred along both loading axes for R (1:2 or 1:1). Compared with uniaxial strength, the biaxial compressive strength increased obviously, which also significantly depended on the value of R. Based on the failure modes, a modified twin-shear strength criterion was established to predict the failure surface of 3D needled C/C–SiC composites under biaxial compressive loading.

AB - Biaxial compressive experiments for 3D needled C/C–SiC composites parallel to the nonwoven cloth were conducted. The failure mechanisms and mechanical properties of the composites were greatly related to the biaxial compressive stress confinement ratio, R. It was found that out-of-plane shear failure controlled the failure of the composites. The failure shear plane was aligned with one of the major loading axes for R (0:1 or 1:3), while the failure shear plane occurred along both loading axes for R (1:2 or 1:1). Compared with uniaxial strength, the biaxial compressive strength increased obviously, which also significantly depended on the value of R. Based on the failure modes, a modified twin-shear strength criterion was established to predict the failure surface of 3D needled C/C–SiC composites under biaxial compressive loading.

KW - Needled composites

KW - biaxial testing

KW - failure mechanisms

KW - failure shear plane

KW - strength criterion

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ER -

Mechanism-based strength criterion for 3D needled C/C–SiC composites under in-plane biaxial compression

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