Solidification microstructure of 3D--meshy SiC/Cu metal matrix composites

Chin J Mater Res

2004, Vol. 18

Issue (6): 597-605 DOI:

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Solidification microstructure of 3D--meshy SiC/Cu metal matrix composites

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中国科学院金属研究所

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. Solidification microstructure of 3D--meshy SiC/Cu metal matrix composites. Chin J Mater Res, 2004, 18(6): 597-605.

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Abstract 3D--meshy SiC/Cu metal matrix composite was fabricated by squeeze casting process. The influence of process conditions on solidification microstructure of the composites was studied. The results showed that 3D--meshy SiC ceramic skeleton played an important role during the solidification of the matrix and the course of crystal growth and crystallization. Under the certain conditions, the dendrites perpendicular to skeleton surface appeared, and the fine and even equiaxed grains structure formed. The influence of skeleton apertures on microstructure was very remarkable. The fine apertures were benefit to grain refining and structure uniformity, while big apertures were apt to produce macroscopic segregation and concentration of plumbum. The tin inverse segregation was lightened for the SiC skeleton, because tin was gathered in a very narrow region near the surface of skeleton, which avoided tin mass segregation in the surface layer of the cast.

Key words: composite metal matrix composites(MMCs) squeeze casting 3D-meshy SiC copper solidification microstru

Received: 29 December 2004

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