Mechanical properties of fine ceramic particle-reinforced aluminum composites produced by high-energy milling

Abstract

In order to develop particle-reinforced aluminum composites with advanced properties, the effect of submicron ceramic particles dispersed by high-energy milling was investigated. The composites consisted of commercially pure aluminum matrix and 0.5μm Al₂O₃ particles; the volume fraction of particles ranged from 0 to 30%. The composites showed high tensile strength paticularly at elevated temperatures and good resistance to softening; the composite with 30vol% Al₂O₃ particles had a tensile strength of 20kgf/mm² at 400°C. This excellent heat-resistance of the composites was considered to arise from the very fine dispersoids of aluminum oxides and carbides generated during high-energy milling. The composites also exhibited good ductilities under compressive conditions. The dispersed Al₂O₃ particles increased elastic modulus and decreased thermal expansion coefficient. The wear resistance of the composites was also improved by Al₂O₃ particles.