High-temperature fatigue behavior of SiC-coated carbon/carbon composites in oxidizing atmosphere

Chidong Liu; Laifei Cheng; Xingang Luan; Hui Mei

doi:10.1016/j.jeurceramsoc.2008.06.014

High-temperature fatigue behavior of SiC-coated carbon/carbon composites in oxidizing atmosphere

Chidong Liu, Laifei Cheng, Xingang Luan, Hui Mei

School of Materials Sience and Engineering

Northwestern Polytechnical University Xian

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

19 Scopus citations

Abstract

Tensile fatigue-stressed oxidation experiments were conducted at 1300 °C in oxidizing atmosphere to identify the failure modes and degradation mechanism of a SiC-coated carbon/carbon composite. Five peak fatigue stresses were selected between 90 and 150 MPa and the results showed that the higher the applied stress, the shorter the composite life. Electrical resistance of the composite was acquired in real-time. The composite resistance appeared a slight drop in the initial fatigue period and followed by a continuous increase until failure. Both the changes in modulus and resistance revealed the shrinking core mechanism in the fatigue-stressed oxidation experiments. A model was developed based on a half-cylinder oxidation pattern. Simulations were conducted on the basis of this model, and the results agreed with the experimental data fairly well.

Original language	English
Pages (from-to)	481-487
Number of pages	7
Journal	Journal of the European Ceramic Society
Volume	29
Issue number	3
DOIs	https://doi.org/10.1016/j.jeurceramsoc.2008.06.014
State	Published - Feb 2009

Keywords

Carbon/carbon composites
Corrosion
Electrical properties
Fatigue
Lifetime

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10.1016/j.jeurceramsoc.2008.06.014

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title = "High-temperature fatigue behavior of SiC-coated carbon/carbon composites in oxidizing atmosphere",

abstract = "Tensile fatigue-stressed oxidation experiments were conducted at 1300 °C in oxidizing atmosphere to identify the failure modes and degradation mechanism of a SiC-coated carbon/carbon composite. Five peak fatigue stresses were selected between 90 and 150 MPa and the results showed that the higher the applied stress, the shorter the composite life. Electrical resistance of the composite was acquired in real-time. The composite resistance appeared a slight drop in the initial fatigue period and followed by a continuous increase until failure. Both the changes in modulus and resistance revealed the shrinking core mechanism in the fatigue-stressed oxidation experiments. A model was developed based on a half-cylinder oxidation pattern. Simulations were conducted on the basis of this model, and the results agreed with the experimental data fairly well.",

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AU - Liu, Chidong

AU - Cheng, Laifei

AU - Luan, Xingang

AU - Mei, Hui

PY - 2009/2

Y1 - 2009/2

N2 - Tensile fatigue-stressed oxidation experiments were conducted at 1300 °C in oxidizing atmosphere to identify the failure modes and degradation mechanism of a SiC-coated carbon/carbon composite. Five peak fatigue stresses were selected between 90 and 150 MPa and the results showed that the higher the applied stress, the shorter the composite life. Electrical resistance of the composite was acquired in real-time. The composite resistance appeared a slight drop in the initial fatigue period and followed by a continuous increase until failure. Both the changes in modulus and resistance revealed the shrinking core mechanism in the fatigue-stressed oxidation experiments. A model was developed based on a half-cylinder oxidation pattern. Simulations were conducted on the basis of this model, and the results agreed with the experimental data fairly well.

AB - Tensile fatigue-stressed oxidation experiments were conducted at 1300 °C in oxidizing atmosphere to identify the failure modes and degradation mechanism of a SiC-coated carbon/carbon composite. Five peak fatigue stresses were selected between 90 and 150 MPa and the results showed that the higher the applied stress, the shorter the composite life. Electrical resistance of the composite was acquired in real-time. The composite resistance appeared a slight drop in the initial fatigue period and followed by a continuous increase until failure. Both the changes in modulus and resistance revealed the shrinking core mechanism in the fatigue-stressed oxidation experiments. A model was developed based on a half-cylinder oxidation pattern. Simulations were conducted on the basis of this model, and the results agreed with the experimental data fairly well.

KW - Carbon/carbon composites

KW - Corrosion

KW - Electrical properties

KW - Fatigue

KW - Lifetime

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High-temperature fatigue behavior of SiC-coated carbon/carbon composites in oxidizing atmosphere

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Keywords

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