Modeling the micro-indentation of metal matrix composites

M. R. ROSENBERGER; E. FORLERER; C.E. SCHVEZOV

MATERIALS SCIENCE AND ENGINEERING A-STRUCTURAL MATERIALS PROPERTIES MICROSTRUCTURE AND PROCESSING

Elsevier Science B.V.

Lugar: Amsterdan, The Netherland; Año: 2007 vol. 463 p. 275 - 283

0921-5093

A finite element model is developed to quantify the effect of the depth and diameter of the reinforcement in the hardness number of metal matrixcomposite. The model includes a spherical indenter pressed against a metal containing one reinforcing particle. The results are validated for thenon-reinforced material comparing the results of the simulation with analytical models that calculate the properties of the material using Brinell andMeyer hardness and the load–displacement curve. A simple composite consisting of a ductile matrix containing one hard particle of size 0.25–1 ofthe indenter size and placed at depths 0.1–0.5 times the indenter radius are assumed. The diameters and depths of the impressions for reinforced andmatrix materials are determined for different particle size and positions, and the influence on the hardness number is calculated. An overestimationin hardness of reinforced materials was observed with the values dependant on the position and size of the particle. Maximum overestimations of15% using visual inspection and of 74% using the Oliver and Pharr technique were found in the reinforced materials. In addition, if the impressiondiameter is at least twice the diameter of the reinforcement, a maximum error of 5% in hardness is produced.