1. Role B 4 C Addition on Microstructure, Mechanical, and Wear Characteristics of Al-20%Mg 2 Si Hybrid Metal Matrix Composite.
- Author
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Ghandvar, Hamidreza, Jabbar, Mostafa Abbas, Koloor, Seyed Saeid Rahimian, Petrů, Michal, Bahador, Abdollah, Bakar, Tuty Asma Abu, Kondoh, Katsuyoshi, and Matikas, Theodore
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METALLIC composites ,MICROSTRUCTURE ,BORON carbides ,HYPEREUTECTIC alloys ,SILICON nitride ,SLIDING wear ,WEAR resistance ,COOLING curves - Abstract
In the current study, the effect of different B
4 C additions (0, 2.5, 5, and 10 wt%) on the microstructural, solidification behavior, mechanical, and tribological properties of Al-20%Mg2 Si composite were studied by means of scanning electron microscopy (SEM) equipped with energy dispersive spectroscopy (EDS), X-ray diffraction (XRD), Vickers hardness, tensile, and dry sliding wear tests. The cooling curve thermal analysis (CCTA) approach was utilized to monitor the influence of B4 C particles on the solidification behavior of Al-20%Mg2 Si composite. The results revealed that the addition of B4 C particles up to 10 wt% reduced the nucleation temperature (TN ) and growth temperature (TG ) of the primary Mg2 Si phase. Moreover, the proper amount of B4 C added to Al-20%Mg2 Si composite has a significant effect on the microstructural alteration, mechanical, and tribological properties of the composite. The mean size of primary Mg2 Si in Al-Mg2 Si composite was 47 μm, in which with the addition of 5 wt% B4 C, the particle size decreased to 33 μm. The highest UTS (217 MPa) and El% (7%) was achieved in Al-20%Mg2 Si-5%B4 C hybrid composite. The cast Al-20%Mg2 Si composite revealed the brittle mode of fracture with some cleavage characterization, in which with the addition of 5%B4 C, the fracture mode altered to a more ductile fracture. The wear results revealed that the Al-20%Mg2 Si-5%B4 C hybrid composite has the highest wear resistance with the lowest wear rate (0.46 mm3 /Km) and friction coefficient (µ = 0.52) under 20 N applied load compared to other fabricated composites with mild abrasion as the governed wear mechanism. [ABSTRACT FROM AUTHOR]- Published
- 2021
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