PLASTIC-FLOW AND FRACTURE OF A PARTICULATE METAL-MATRIX COMPOSITE

The effects of particle volume fraction and matrix temper on the flow and fracture characteristics of a series of particle-reinforced metal matrix composites under tensile and compressive loadings have been exa mined. Under compressive loading, a steady-state regime is attained in which the composite flow stress is proportional to the matrix flow st ress at the same level of strain. The strength enhancement associated with the particles increases with increasing particle content and the matrix hardening exponent. The trends are consistent with predictions of finite element calculations of unit cell models, treating the parti cles as either spheres or cylinders with unit aspect ratio. Under tens ile loading, the particles crack al a rate dependent on the intrinsic strength characteristics of the particles as well as the flow characte ristics of the matrix. Particle cracking causes local softening, which reduces the work hardening rate as compared with compression deformat ion. This lowers both the strength and the ductility. Experimental mea surements have been combined with finite element calculations to devel op a damage law, incorporating the effects of the matrix strength on t he particle stress. The damage law has been used to simulate the tensi le flow response of the composites, using appropriate cell models unde r either isostrain or isostress conditions. Though the trends obtained from the simulations are in qualitative agreement with the experiment al results, they tend to underestimate the flow stress. In all cases, tensile fracture is preceded by the formation of a neck. The condition at the onset of necking is consistent with the Considere criterion. D ifferences in necking strains between the composites and the monolithi c matrix alloy have been rationalized on the basis of the rate of dama ge accumulation. Copyright (C) 1996 Acta Metallurgica Inc.