Effect of dual reinforced ceramic particles on high temperature tribological properties of aluminum composites

• Published in: Ceramics international Vol. 39; no. 6; pp. 6333 - 6342
• Main Authors: Kumar, Suresh, Panwar, Ranvir Singh, Pandey, O.P.
• Format: Journal Article
• Language: English
• Published: Elsevier Ltd 01.08.2013
• Subjects: Aluminium; Aluminum; Aluminum base alloys; Aluminum matrix composite; Ceramics; Debris; Particulate composites; Reinforcement; Sand; SEM; Silicon carbide; Wear; SEM; Debris; Aluminum matrix composite; Wear
• ISSN: 0272-8842; 1873-3956
• DOI: 10.1016/j.ceramint.2013.01.059

The nature and distribution of hard ceramic particles in composite materials influences the properties to greater extent. In the present work, the role of hard ceramic reinforced particles on the tribological behaviour of aluminum metal matrix composites consisting of single (SRP) and dual reinforced particles (DRP) is studied at different temperatures. Zircon sand and silicon carbide particles of size 20–32μm were used as reinforcement in commercial grade LM13 piston alloy. Composites of dual reinforced particles in aluminum matrix (DRP-AMCs) were developed by mixing 15wt% reinforced particles by two step stir casting technique. The wear behaviour of DRP-AMCs and SRP-AMCs (single reinforced particles aluminum matrix composite) was investigated using a pin-on-disc method at high temperatures under dry sliding condition. The microstructural examination of developed composites shows globular and finely distributed eutectic silicon in the vicinity of the reinforced particles. Metallographic investigation revealed that the wear zone of the SRP composite consisted of a hardened layer, which is responsible for high wear loss observed in the SRP composite. The results further indicate a transition in the wear mode that occurs after 150°C for all composites. Study reveals that the dual reinforcement of particles enhances the wear resistance as compared to single reinforced particles if mixed in a definite ratio. A combination of 3% zircon sand and 12% silicon carbide particle reinforced composite exhibits better wear resistance as compared to other combinations at all the temperatures for low and high loads both.