石英纤维增强聚酰亚胺树脂基复合材料的疲劳特性

Jie Wang; Wancheng Zhou; Fa Luo; Dongmei Zhu; Zhibin Huang; Yuchang Qing

doi:10.3969/j.issn.1001-9731.2019.06.014

石英纤维增强聚酰亚胺树脂基复合材料的疲劳特性

Jie Wang, Wancheng Zhou, Fa Luo, Dongmei Zhu, Zhibin Huang, Yuchang Qing

材料学院

Northwestern Polytechnical University Xian

科研成果: 期刊稿件 › 文章 › 同行评审

摘要

The tensile stress-strain behavior and tensile strength of quartz fiber reinforced polyimide matrix (QFRP) composite were measured at room and elevated temperatures. The average tensile strength and elasticity modulus decreased with increasing temperature, and remained 68% and 80% at 300 ℃, respectively. Tension-tension fatigue behavior of a QFRP composite was studied at room and elevated temperatures. At the same cyclic stress level, a longer fatigue life of QFRP composites was obtained at room temperature, compared to elevated temperature. Damage evolution was discussed on the basis of cross-section and mechanical variation. The dominant damage mechanism of warp yarn cracking was mitigated at elevated temperatures as a direct result of resin softening, which was also the case for the fatigue test specimens. This study yielded an improved understanding of damage mechanisms and local deformation behavior for QFRP composite, which was valuable for designers.

投稿的翻译标题	Fatigue performance of quartz fiber/polyimide composite at elevated temperature
源语言	繁体中文
页（从-至）	6079-6082
页数	4
期刊	Gongneng Cailiao/Journal of Functional Materials
卷	50
期	6
DOI	https://doi.org/10.3969/j.issn.1001-9731.2019.06.014
出版状态	已出版 - 30 6月 2019

关键词

Elevated-temperature tension-tension fatigue
Failure mechanisms
S-N curves
Ultimate tensile strength

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10.3969/j.issn.1001-9731.2019.06.014

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abstract = "The tensile stress-strain behavior and tensile strength of quartz fiber reinforced polyimide matrix (QFRP) composite were measured at room and elevated temperatures. The average tensile strength and elasticity modulus decreased with increasing temperature, and remained 68% and 80% at 300 ℃, respectively. Tension-tension fatigue behavior of a QFRP composite was studied at room and elevated temperatures. At the same cyclic stress level, a longer fatigue life of QFRP composites was obtained at room temperature, compared to elevated temperature. Damage evolution was discussed on the basis of cross-section and mechanical variation. The dominant damage mechanism of warp yarn cracking was mitigated at elevated temperatures as a direct result of resin softening, which was also the case for the fatigue test specimens. This study yielded an improved understanding of damage mechanisms and local deformation behavior for QFRP composite, which was valuable for designers.",

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AU - Wang, Jie

AU - Zhou, Wancheng

AU - Luo, Fa

AU - Zhu, Dongmei

AU - Huang, Zhibin

AU - Qing, Yuchang

PY - 2019/6/30

Y1 - 2019/6/30

N2 - The tensile stress-strain behavior and tensile strength of quartz fiber reinforced polyimide matrix (QFRP) composite were measured at room and elevated temperatures. The average tensile strength and elasticity modulus decreased with increasing temperature, and remained 68% and 80% at 300 ℃, respectively. Tension-tension fatigue behavior of a QFRP composite was studied at room and elevated temperatures. At the same cyclic stress level, a longer fatigue life of QFRP composites was obtained at room temperature, compared to elevated temperature. Damage evolution was discussed on the basis of cross-section and mechanical variation. The dominant damage mechanism of warp yarn cracking was mitigated at elevated temperatures as a direct result of resin softening, which was also the case for the fatigue test specimens. This study yielded an improved understanding of damage mechanisms and local deformation behavior for QFRP composite, which was valuable for designers.

AB - The tensile stress-strain behavior and tensile strength of quartz fiber reinforced polyimide matrix (QFRP) composite were measured at room and elevated temperatures. The average tensile strength and elasticity modulus decreased with increasing temperature, and remained 68% and 80% at 300 ℃, respectively. Tension-tension fatigue behavior of a QFRP composite was studied at room and elevated temperatures. At the same cyclic stress level, a longer fatigue life of QFRP composites was obtained at room temperature, compared to elevated temperature. Damage evolution was discussed on the basis of cross-section and mechanical variation. The dominant damage mechanism of warp yarn cracking was mitigated at elevated temperatures as a direct result of resin softening, which was also the case for the fatigue test specimens. This study yielded an improved understanding of damage mechanisms and local deformation behavior for QFRP composite, which was valuable for designers.

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KW - Failure mechanisms

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石英纤维增强聚酰亚胺树脂基复合材料的疲劳特性

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