Microstructure Characterization, Mechanical, and Tribological Properties of Slow-Cooled Sb-Treated Al-20Mg 2 Si-Cu In Si
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JMEPEG DOI: 10.1007/s11665-017-2624-8
Microstructure Characterization, Mechanical, and Tribological Properties of Slow-Cooled Sb-Treated Al-20Mg2Si-Cu In Situ Composites Saeed Farahany, Hamidreza Ghandvar, Nur Azmah Nordin, and Ali Ourdjini (Submitted August 15, 2016; in revised form January 22, 2017) Role of Sb addition on structural characteristics, mechanical properties, and wear behavior of Al-20Mg2SiCu in situ composite under slow cooling condition was thoroughly investigated in this study using stereomicroscopy, optical and scanning electron microscopy, thermal analysis, tensile, impact, hardness tests, and wear tester. Results show that addition of 0.8 wt.% Sb was found to produce a change in the morphology of primary Mg2Si from dendrite to fine polygonal shape. At this Sb addition, the primary Mg2Si phase also exhibited a reduction in size from 179.4 to 128.6 lm, an increase in density of Mg2Si per area from 12.5 to 32.2 particle/mm2, and a decrease in the aspect ratio from 1.24 to 1.11. Increasing the amount of Sb added up to 1 wt.% also resulted in a decrease in both nucleation and growth temperatures of the eutectic Mg2Si by 2.6 and 1.7 °C respectively, which is most likely due to change of eutectic Mg2Si morphology from flake to fibrous structure. Thermal analysis technique showed that distribution of Mg2Si particles influences the heat conductivity during the solidification process of Al-Mg2Si composite. The results also showed that improvements in mechanical properties of composite were obtained with increasing Sb content due to modification of both primary and eutectic Mg2Si and due to intermetallic compound transformation from b-Al5FeSi to a-Al15(Fe,Mn)3Si2. Examination of fracture surfaces from tensile and impact samples showed that the base composite failed in a brittle manner with decohered or debonded Mg2Si particles, whereas the 0.8 wt.% Sb-treated composite showed more cracked Mg2Si and ductile fracture in the matrix. Wear properties improved significantly with addition of Sb due to modification and better dispersion of fine Mg2Si particles in matrix. Keywords
casting, composite, mechanical properties, Mg2Si, microstructure, wear
1. Introduction The in situ route for fabricating metal matrix composites (MMCs) has few challenges in terms of thermodynamic instability of the reinforcement within the matrix, weak matrix/reinforcement interface bonding, and non-uniform distribution of reinforcement particles compared to the conventional route (Ref 1). Moreover, in situ method is more economical and reliable. Thus, Al-Mg2Si in situ composites in which the Mg2Si reinforcing particles are formed in situ during solidification make these materials ideal candidates to replace traditional Al-SiC or Al-Al2O3 composites in the automotive industry. In addition, Al-Mg2Si in situ, which are more light-weight than Al-Si alloys and possess practically high mechanical properties, have received greater attention by Saeed Farahany, Department of Chemical and Materials Engineering, Buein Zahra Technical University, Qazvin
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