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Wear behavior and dry sliding tribological properties of ultra-fine grained Al5083 alloy and boron carbide-reinforced Al5083-based composite at room and elevated temperatures

Matin Saessi, Ali Alizadeh, Alireza Abdollahi

2021Transactions of Nonferrous Metals Society of China22 citationsDOIOpen Access PDF

Abstract

Tribological behavior and wear mechanisms of mechanically milled Al5083 alloy and Al5083−5wt.%B4C composite at room temperature and 200 °C were discussed. Results revealed that due to the oxidative wear at room temperature, a mechanically mixed layer (MML) was formed to protect the surface of the samples. Under 80 N of load at room temperature, the milled Al5083 and the Al5083−5wt.%B4C samples showed evidence of abrasion with limited volume loss. In this case, the wear rates were 5.8×10−7 and 4.4×10−7 mm3/(m·N), respectively. At 200 °C and under 80 N of applied load, severe wear occurred in the milled Al5083 sample, and wear rate reached 10.8×10−7 mm3/(m·N) while the Al5083−5wt.%B4C sample showed mild wear with local 3-body abrasion and the wear rate reached 5.3×10−7 mm3/(m·N). Strengthening mechanisms such as dislocation pinning and the Hall−Petch theory, high hardness and the load transfer effect were crucial in determining the wear behavior of the Al5083−5wt.%B4C composite. On the other hand, the milled Al5083 sample represented a relatively high wear rate at 200 °C, which seemed to be related to the local grain growth and a drop in its hardness.

Topics & Concepts

Materials scienceAlloyAbrasion (mechanical)Composite numberTribologyMetallurgyComposite materialBoron carbideAluminum Alloys Composites PropertiesMagnesium Alloys: Properties and ApplicationsAdvanced materials and composites
Wear behavior and dry sliding tribological properties of ultra-fine grained Al5083 alloy and boron carbide-reinforced Al5083-based composite at room and elevated temperatures | Litcius