Mechanical properties of unidirectional carbon fiber composites based on domestic T800H carbon fiber, M40J graphite fiber and their mixtures

PENG Gong-qiu; LI Ke; ZHONG Xiang-yu; LI Guo-li; LI Wei-dong; BAO Jian-wen; WANG Jin

doi:10.19869/j.ncm.1007-8827.20190172

Volume 35 Issue 6

Dec. 2020

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Article Navigation > New Carbon Mater. > 2020 > 35(6): 776-784

PENG Gong-qiu, LI Ke, ZHONG Xiang-yu, LI Guo-li, LI Wei-dong, BAO Jian-wen, WANG Jin. Mechanical properties of unidirectional carbon fiber composites based on domestic T800H carbon fiber, M40J graphite fiber and their mixtures. New Carbon Mater., 2020, 35(6): 776-784. doi: 10.19869/j.ncm.1007-8827.20190172

Citation:

PENG Gong-qiu, LI Ke, ZHONG Xiang-yu, LI Guo-li, LI Wei-dong, BAO Jian-wen, WANG Jin. Mechanical properties of unidirectional carbon fiber composites based on domestic T800H carbon fiber, M40J graphite fiber and their mixtures. New Carbon Mater., 2020, 35(6): 776-784. doi: 10.19869/j.ncm.1007-8827.20190172

Citation:

PENG Gong-qiu, LI Ke, ZHONG Xiang-yu, LI Guo-li, LI Wei-dong, BAO Jian-wen, WANG Jin. Mechanical properties of unidirectional carbon fiber composites based on domestic T800H carbon fiber, M40J graphite fiber and their mixtures. New Carbon Mater., 2020, 35(6): 776-784. doi: 10.19869/j.ncm.1007-8827.20190172

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Mechanical properties of unidirectional carbon fiber composites based on domestic T800H carbon fiber, M40J graphite fiber and their mixtures

doi: 10.19869/j.ncm.1007-8827.20190172

PENG Gong-qiu^{1,2,3
,},
LI Ke⁴,
ZHONG Xiang-yu^1,2,3,
LI Guo-li^1,2,3,
LI Wei-dong^1,2,3,
BAO Jian-wen^1,2,3,
WANG Jin⁴

1.
China Academy of Aeronautical Manufacturing Technology Composite Technology Center, Beijing 101300, China;
2.
AVIC Composite Corporation Ltd., Beijing 101300, China;
3.
National Key Laboratory of Advanced Composites, Beijing 101300, China;
4.
Shen Yang Aircraft Design Institute, Shenyang 110035, China

Received Date: 2019-12-27
Rev Recd Date: 2020-10-11
Publish Date: 2020-12-31

Abstract

Abstract

Three unidirectional carbon fiber composites impregnated with molten epoxy resin were prepared from T800H carbon fiber, M40J graphite fiber, and their mixtures containing alternating and parallel tows of 12 K fibers with a volume ratio of 1∶1. Their tensile strength and modulus in directions parallel (0°) and perpendicular (90°) to fiber axis as well as the compressive strength in quasi-isotropic(＋45°/0°/-45°/90°)_4S after a drop weight impact according to ASTM 7136/7137 were investigated. Results indicate that the 0° tensile modulus of the mixed composite observes the laws of mixing, the 0° tensile strength and inter-laminar shear stress negatively deviate from the laws of mixing, and the 90° tensile strength and the compressive strength positively deviate from the laws of mixing. Compared with the T800H composite, the 0° tensile modulus of the hybrid is increased by 13%. Compared with the M40J composite, the compressive strength of the hybrid is increased by 35%. The hybrid composite has both a high tensile modulus and a high compressive strength.
- Composites,
- Inner-ply hybrid,
- Hybrid effect,
- Mechanical properties

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References(33)

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