Optimization of Wear Factors of Aluminium Hybrid Metal Matrix Composites Using Taguchi Method

Journal of Minerals and Materials Characterization and Engineering Pub Date : 2021-01-01 DOI:10.4236/JMMCE.2021.91003

P. Asha, S. Murthy, C. P. Rao, V. Kumar, R. Kiran, C. Suresha

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引用次数: 2

Abstract

Hybrid metal matrix composites (Hmmc) are found to be more superior than the conventional composite materials because of their improved mechanical properties, which can be suited for an extensive range of engineering applications. Automobile and aerospace industries widely make use of hybrid composites as they possess excellent corrosion, wear resistance, low density, and high strength. This paper displays the strategy to build the hybrid composite utilizing Stir casting Method. Present investigation includes the creation of composites utilizing boron carbide (2%, 4%, 6% volume) and Red mud (2% volume) as the reinforcements and Structural aluminium as the matrix. Experimental investigation of wear analysis of the composites was carried out according to the L9 Taguchi method. The designated number of experiments was accomplished to probe the impact of control factors on the specific wear rate (SWR) of the developed composites. ANOVA was carried out and Wt%. Reinforcement was found to be the decisive factor on the SWR of the developed hybrid composite. The Confirmatory test was successfully carried out and the computed error was found to be varying from 0.878% to 2.58%.

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用田口法优化铝杂化金属基复合材料的磨损系数

杂化金属基复合材料(Hmmc)具有比传统复合材料更优越的力学性能，可用于广泛的工程应用。混合复合材料具有优良的耐腐蚀、耐磨损、低密度和高强度等特点，在汽车和航空航天工业中得到广泛应用。介绍了利用搅拌铸造法构建复合材料的策略。目前的研究包括使用碳化硼(2%，4%，6%体积)和赤泥(2%体积)作为增强材料和结构铝作为基体的复合材料的创建。根据L9田口法对复合材料进行了磨损分析实验研究。为探讨控制因素对复合材料比磨损率(SWR)的影响，完成了指定次数的试验。进行方差分析，Wt%。结果表明，增强是影响复合材料SWR的决定性因素。验证试验成功进行，计算误差在0.88% ~ 2.58%之间。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Journal of Minerals and Materials Characterization and Engineering

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