粉末冶金法制备三维(3D)石墨烯增强铜基复合材料的性能

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Abstract The 0-0.4% (mass fraction) 3D graphene was added as a reinforcement in Cu-5%Sn alloy. The 3D graphene/Cu-5%Sn composites were prepared via powder metallurgy method. The density, resistivity, tensile strength, impact strength, Brinell hardness and friction and wear properties were measured. The results show that with increasing 3D graphene content, the density and tensile strength of 3D graphene/Cu-5%Sn composites decrease, and the resistivity increase slightly, the wear value increases. As the braking speed increases, the friction coefficient decreases. The composite with 0.4% graphene has the best stable friction coefficient. Compared with Cu-5%Sn matrix, when the content of 3D graphene is 0.2%, the maximum impact strength is 32.5 J/cm²,which is increased by 57.0%. When the content of 3D graphene is 0.1%, the Brinell hardness (HBW) and elongation are 122.0 and 11.52%, respectively, which is increased by 22.0% and 10.5% for Cu-5%Sn alloy. The fracture morphology of composite appears a dimple pattern with typical features of plastic fracture.

Key words： 3D graphene powder metallurgy mechanical properties friction and wear

Received: 24 April 2019 Published: 14 November 2019

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	Articles by authors
	YI Chunqiang
	YIN Cailiu
	LIU Chunxuan
	WEN Guofu
	WANG Xiufei

Cite this article:

YI Chunqiang,YIN Cailiu,LIU Chunxuan, et al. Properties of three-dimensional (3D) graphene-reinforced copper matrix composites by powder metallurgy method[J]. Materials Science and Engineering of Powder Metallurgy, 2019, 24(5): 478-484.

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http://pmbjb.csu.edu.cn/EN/ OR http://pmbjb.csu.edu.cn/EN/Y2019/V24/I5/478

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