Friction and Wear Properties of Copper-Based Sintered Materials Containing Various Intermetallic Compounds

Abstract

The friction and wear characteristics of copper-based sintered materials containing various intermetallic compounds were investigated under dry sliding conditions over a speed range of 1-4m/s, and compared with those of the Cu-A1₂O₃ sintered compact. Four different kinds of intermetallics; CuAI, Cu₂AI, Co₂Ti and Ni₃Al, were used to take account of both hardness and softening temperature. The fraction of added hard powder with a particle size of 105-150 μm was 16 vol% to copper powder,
The addition of the intermetallic powder with relatively high softening temperature such as Co₂Ti and Ni₃Al was quite effective, irrespective of the hardness, indicating that the softening temperature was the crucial factor for the improvement of the friction and wear behaviours. The Cu-Ni₃A1 sintered material exhibited the most excellent tribological performance. The superiority of Ni₃Al as an anti-wear additive may be caused by the formation of the softer diffusion layer which envelops the harder core of Ni₃A1 particles, besides the high softening temperature and the positive temperature dependence of hardness. Al₂O₃ powder was further crushed to several fragments during sliding, because it is devoid of ductility. This results in an inferior wear resistance for the Cu-Al₂O₃ sintered material.