Mechanical properties of hot pressed SiCp and B4Cp/Alumix 123 composites alloyed with minor Zr

• Published in: Composites. Part B, Engineering Vol. 54; pp. 34 - 40
• Main Author: Gode, Ceren
• Format: Journal Article
• Language: English
• Published: Kidlington Elsevier Ltd 01.11.2013; Elsevier
• Subjects: A. Metal–matrix composites (MMCs); alloys; aluminum; Applied sciences; B. Mechanical properties; B. Wear; bending strength; copper; Dispersion hardening metals; E. Isostatic processing; Exact sciences and technology; hardness; Metals. Metallurgy; microstructure; Powder metallurgy. Composite materials; pressing; Production techniques; tensile strength; zirconium; B. Mechanical properties; A. Metal–matrix composites (MMCs); B. Wear; E. Isostatic processing; Strengthening; Hot isostatic pressing; Composition effect; Boron carbide; Composite material; Dispersion strengthened metal; Non oxide ceramics; Wear resistance; Sliding wear; Metal matrix composite; Mechanical properties; Zirconium alloy; Aluminium alloy; Hardness; Experimental study; Tensile strength; Bending strength; Silicon carbide; A. Metal-matrix composites (MMCs); Yield strength; Microstructure; Tribology
• ISSN: 1359-8368; 1879-1069
• DOI: 10.1016/j.compositesb.2013.04.068

In the present study, effect of Zr addition on the microstructure and wear behavior of aluminum alloy composites (AMCs) reinforced with B4Cp and SiCp particles fabricated via hot pressing were investigated. The samples for the study composed of unreinforced aluminum alloy (Alumix 123) and the composites reinforced with 10% B4Cp and % SiCp were prepared by hot isostatic pressing (HIP) method. Similarly, all the samples alloyed with 0.2% Zr were also produced in order to make a comparison. The produced samples were evaluated for microstructural properties and mechanical tests for hardness, tensile and bending strength were performed. Wear test was carried out at 5mm/s sliding speed under 3.0N load for the all kind of hot pressed produced samples. The hot pressed composite microstructures have a more uniform distribution of the reinforcements. After HIP process, the composites were successfully produced with high density (>99%). The addition of Zr increased the yield and tensile strength of the samples. The highest strength value was found for the sample Al 123 matrix alloy with Zr. Evaluation of microstructures showed that copper and zirconium dispersed equally within the matrix microstructure without agglomeration. For the composite samples, Al3Zr, appeared as white precipitate, were inspected around B4C and SiC particles. The composite containing SiC particles and Zr had wear resistance value superior to those of the other counterparts.