PREDICTION OF REGRESSION BASED WEAR BEHAVIOUR MODELS OF ALUMINIUM ALLOY 356 – ZrSiO4 COMPOSITES

Q4 Engineering

Academic Journal of Manufacturing Engineering Pub Date : 2022-02-11 DOI:10.37255/jme.v16i4pp124-126

J.Althaf Hasan Khan, S.Akmal Jahan, A.Biju Kumar, V.Murali, A.Arul Marcel Moshi

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Abstract

The term composite is a combination of two materials with different physical and chemical properties. When combined, they create a specialised material to do a certain job, for instance, to become stronger, lighter or resistant to electricity. They can also improve strength and stiffness. Metal matrix composites have much improved properties, including high tensile strength, toughness, hardness, low density and good wear resistance compared to alloys or any other metal. Aluminium alloys are becoming important today, especially in the automobile, space and electrical industries. Unfortunately, due to poor wear resistance, aluminium alloy can deteriorate quickly. So the present investigation aims at developing Aluminium 356 alloy (AA356) composites reinforced with 5 wt.% Zirconium Silicate (ZrSiO4) with better wear resistance. The composites have been fabricated using the ‘stir-casting’ method in which the particles were added to molten metal during the stirring process at a rotating speed of 700 rpm. A wear test has been performed on a pin on the disc apparatus. Three process parameters have been considered: normal load, sliding velocity, and sliding distance at three different levels. An experimental plan has been made using Taguchi’s L9 orthogonal array table. The output responses such as wear rate and coefficient of friction have been considered for the investigation. Regression models have been generated for each output response. Using the generated regression models, one can predict the value of the output parameters even without actually performing the experimentation within the range of input factor combinations.

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基于回归的356 - ZrSiO4铝合金复合材料磨损行为模型预测

复合材料是两种具有不同物理和化学性质的材料的组合。当它们结合在一起时，就会产生一种特殊的材料来完成特定的工作，例如，变得更强、更轻或耐电。它们还可以提高强度和硬度。与合金或任何其他金属相比，金属基复合材料具有许多改进的性能，包括高抗拉强度，韧性，硬度，低密度和良好的耐磨性。铝合金在今天变得越来越重要，特别是在汽车、航天和电气工业中。不幸的是，由于耐磨性差，铝合金会很快变质。因此，本研究的目标是开发出具有较好耐磨性的5%硅酸锆(ZrSiO4)增强356铝合金(AA356)复合材料。复合材料是用“搅拌铸造”方法制造的，在搅拌过程中，以700转/分的转速将颗粒添加到熔融金属中。对圆盘装置上的一个销进行了磨损试验。考虑了三个过程参数:正常载荷、滑动速度和三个不同水平的滑动距离。利用田口L9正交阵表，制定了实验方案。研究中考虑了输出响应如磨损率和摩擦系数。已经为每个输出响应生成了回归模型。使用生成的回归模型，即使不实际在输入因子组合范围内进行实验，也可以预测输出参数的值。

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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来源期刊

Academic Journal of Manufacturing Engineering Engineering-Industrial and Manufacturing Engineering

CiteScore

0.40

自引率

0.00%

发文量