Microstructure and tribological performance of an aluminium alloy based hybrid composite produced by friction stir processing
Materials & Design, 2011•Elsevier
In this study, friction stir processing (FSP) was utilized to incorporate SiC and MoS2 particles
into the matrix of an A356 Al alloy to form surface hybrid composite. A constant tool rotation
rate of 1600rpm and travel speed of 50mm/min with a tool tilt angle of 3° was used. The wear
resistance of the processed samples improved significantly as compared to that of the as-
cast alloy. Microstructural analyses showed a uniform distribution of reinforcement particles
inside the nugget zone, and a MoS2 rich mechanically mixed layer (MML) on the top of worn …
into the matrix of an A356 Al alloy to form surface hybrid composite. A constant tool rotation
rate of 1600rpm and travel speed of 50mm/min with a tool tilt angle of 3° was used. The wear
resistance of the processed samples improved significantly as compared to that of the as-
cast alloy. Microstructural analyses showed a uniform distribution of reinforcement particles
inside the nugget zone, and a MoS2 rich mechanically mixed layer (MML) on the top of worn …
In this study, friction stir processing (FSP) was utilized to incorporate SiC and MoS2 particles into the matrix of an A356 Al alloy to form surface hybrid composite. A constant tool rotation rate of 1600rpm and travel speed of 50mm/min with a tool tilt angle of 3° was used. The wear resistance of the processed samples improved significantly as compared to that of the as-cast alloy. Microstructural analyses showed a uniform distribution of reinforcement particles inside the nugget zone, and a MoS2 rich mechanically mixed layer (MML) on the top of worn surface. This MoS2 layer is considered to stifle plastic deformation and thus, to improve tribological properties of the alloy.
Elsevier
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