Fabrication and Thermal Analysis of Hybrid A356 Aluminium Metal Matrix Composites Prepared by Stir Casting Process

Current Materials Science Pub Date : 2023-05-19 DOI:10.2174/2666145416666230519111414

J. Naik, S. Jagadeesh, P. S. Babu, S. M. Naidu, P. Muruganandhan, S. Lionel Beneston

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Abstract

Electronic packaging makes use of hybrid A356 aluminium alloy MMCs (matrix metal composites). Enhanced endurance limit, increased production and energy, low maintenance cost, and benefits to the environment, such as reduced noise and airborne pollutants, are among the features that are recommended to be evaluated. This study aimed to analyze the thermal properties of A356 aluminium alloy with graphite (Gr) and boron carbide (B4C) hybrid metal matrix composites. For this purpose, the A356 hybrid composite was primed by the stir casting process with the addition of 5 wt % and 10 wt % of Gr and B4C reinforcements. In general, A356 hybrid composite material thermal analysis is crucial for electrical equipment. The liquid-in-filtration method was used to create the hybrid composites, which were then tested thermally for parameters, like melting point, thermal diffusivity, and thermal coefficient of expansion. The thermocouple sensor of a calorimeter was used to examine the disparity in the composites. A thermal analysis tool called TGA was used to visually represent the relationship between a material's weight and temperature. The temperature was found to be 300oC at the 0.411 W/g maximum heat flow rate. Thermal conductivity is the ratio of the temperature difference divided by the area of the heat transfer from one substance to another. The thermal coefficient of expansion illustrates how a material's dimensions and weight change as temperature increases. The proportion of the weight of the hybrid composites was found to fall with a rise in the temperature. The melting point curve of the composites demonstrated a little increase in temperature to be accompanied by a sharp increase in heat flow.

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搅拌铸造A356铝基复合材料的制备及热分析

电子封装使用混合A356铝合金mmc(基体金属复合材料)。增强的续航能力，增加的产量和能源，低维护成本，以及对环境的好处，如减少噪音和空气污染物，是建议进行评估的特征之一。本研究旨在分析石墨(Gr)和碳化硼(B4C)混杂金属基复合材料对A356铝合金的热性能。为此，采用搅拌铸造工艺对A356复合材料进行浇注，分别添加5 wt %和10 wt %的Gr和B4C增强剂。一般来说，A356混合复合材料的热分析对电气设备至关重要。采用液体过滤法制备混合复合材料，然后对其进行热参数测试，如熔点、热扩散系数和热膨胀系数。利用量热计的热电偶传感器来检测复合材料的差值。热分析工具TGA被用来直观地表示材料的重量和温度之间的关系。在0.411 W/g最大热流速率下，温度为300℃。导热系数是温度差除以从一种物质到另一种物质的热传递面积之比。热膨胀系数说明了材料的尺寸和重量如何随着温度的升高而变化。混杂复合材料的重量比例随温度的升高而下降。复合材料的熔点曲线显示出温度的小幅升高伴随着热流的急剧增加。

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来源期刊

Current Materials Science Materials Science-Materials Science (all)

CiteScore

0.80

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0.00%

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