Damage mechanisms of SiC-coated C/C composites subjected to cyclic loading in combustion gas environment

Chidong Liu; Laifei Cheng; Hui Mei; Xingang Luan; Hui Huang

doi:10.1016/j.msea.2007.09.077

Damage mechanisms of SiC-coated C/C composites subjected to cyclic loading in combustion gas environment

Chidong Liu, Laifei Cheng, Hui Mei, Xingang Luan, Hui Huang

School of Materials Sience and Engineering

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

4 Scopus citations

Abstract

A SiC-coated C/C composite was subjected to cyclic loading in a combustion wind tunnel with flame temperature of 1300 °C. Both the ratchetting strain and hysteresis changes showed that the majority of damage was produced in the first 50 cycles, and then the rate of damage accumulation gradually approached a steady value as the cycles proceeded. Lamellar structure of the C/C composite was observed after oxidation, which was caused by the difference in reactivity between the carbon fiber and carbon matrix. Acoustic emission activities throughout the tensile tests of the cycled specimens showed that little damage was produced before the applied tensile load exceeded the maximum history load of the cyclic loading tests.

Original language	English
Pages (from-to)	511-516
Number of pages	6
Journal	Materials Science and Engineering: A
Volume	486
Issue number	1-2
DOIs	https://doi.org/10.1016/j.msea.2007.09.077
State	Published - 15 Jul 2008

Keywords

C/C composites
Cyclic loading
Damage mechanism
Microstructure
Oxidation

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abstract = "A SiC-coated C/C composite was subjected to cyclic loading in a combustion wind tunnel with flame temperature of 1300 °C. Both the ratchetting strain and hysteresis changes showed that the majority of damage was produced in the first 50 cycles, and then the rate of damage accumulation gradually approached a steady value as the cycles proceeded. Lamellar structure of the C/C composite was observed after oxidation, which was caused by the difference in reactivity between the carbon fiber and carbon matrix. Acoustic emission activities throughout the tensile tests of the cycled specimens showed that little damage was produced before the applied tensile load exceeded the maximum history load of the cyclic loading tests.",

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AU - Liu, Chidong

AU - Cheng, Laifei

AU - Mei, Hui

AU - Luan, Xingang

AU - Huang, Hui

PY - 2008/7/15

Y1 - 2008/7/15

N2 - A SiC-coated C/C composite was subjected to cyclic loading in a combustion wind tunnel with flame temperature of 1300 °C. Both the ratchetting strain and hysteresis changes showed that the majority of damage was produced in the first 50 cycles, and then the rate of damage accumulation gradually approached a steady value as the cycles proceeded. Lamellar structure of the C/C composite was observed after oxidation, which was caused by the difference in reactivity between the carbon fiber and carbon matrix. Acoustic emission activities throughout the tensile tests of the cycled specimens showed that little damage was produced before the applied tensile load exceeded the maximum history load of the cyclic loading tests.

AB - A SiC-coated C/C composite was subjected to cyclic loading in a combustion wind tunnel with flame temperature of 1300 °C. Both the ratchetting strain and hysteresis changes showed that the majority of damage was produced in the first 50 cycles, and then the rate of damage accumulation gradually approached a steady value as the cycles proceeded. Lamellar structure of the C/C composite was observed after oxidation, which was caused by the difference in reactivity between the carbon fiber and carbon matrix. Acoustic emission activities throughout the tensile tests of the cycled specimens showed that little damage was produced before the applied tensile load exceeded the maximum history load of the cyclic loading tests.

KW - C/C composites

KW - Cyclic loading

KW - Damage mechanism

KW - Microstructure

KW - Oxidation

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JO - Materials Science and Engineering: A

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IS - 1-2

ER -

Damage mechanisms of SiC-coated C/C composites subjected to cyclic loading in combustion gas environment

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Keywords

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