Viscoplastic deformations and compressive damage in an A359/SiCp metal-matrix composite

Y. Li; K. T. Ramesh; E. S.C. Chin

doi:10.1016/S1359-6454(99)00430-9

Viscoplastic deformations and compressive damage in an A359/SiC_p metal-matrix composite

Y. Li, K. T. Ramesh, E. S.C. Chin

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Abstract

Recent work by the authors has examined the high-strain-rate compression of a metal-matrix composite consisting of an A359 Al alloy matrix reinforced by 20 vol.% of silicon carbide particulates (SiC_p). The work-hardening that is observed in the experiments is much lower than that predicted by analytical and computational models which assume perfect particle-matrix interfaces and undamaged particles. In this work, we show that the discrepancy is a result of particle damage that develops within the A359/SiC_p composite under compression. The evolution of particle damage has been characterized using quantitative microscopy, and is shown to be a function of the applied strain. A simple analytical model that incorporates evolving damage within the composite is proposed, and it is shown that the analytical predictions are consistent with the experimental observations over a wide range of strain rates.

Original language	English
Pages (from-to)	1563-1573
Number of pages	11
Journal	Acta Materialia
Volume	48
Issue number	7
DOIs	https://doi.org/10.1016/S1359-6454(99)00430-9
State	Published - 19 Apr 2000
Externally published	Yes

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AB - Recent work by the authors has examined the high-strain-rate compression of a metal-matrix composite consisting of an A359 Al alloy matrix reinforced by 20 vol.% of silicon carbide particulates (SiCp). The work-hardening that is observed in the experiments is much lower than that predicted by analytical and computational models which assume perfect particle-matrix interfaces and undamaged particles. In this work, we show that the discrepancy is a result of particle damage that develops within the A359/SiCp composite under compression. The evolution of particle damage has been characterized using quantitative microscopy, and is shown to be a function of the applied strain. A simple analytical model that incorporates evolving damage within the composite is proposed, and it is shown that the analytical predictions are consistent with the experimental observations over a wide range of strain rates.

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Viscoplastic deformations and compressive damage in an A359/SiC_p metal-matrix composite

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