Modeling Microstructural and Mechanical Properties of Solidified Al-Sn-Cu System

Malaysian Journal on Composites Science and Manufacturing Pub Date : 2023-11-29 DOI:10.37934/mjcsm.12.1.84101

Mahin Muntasir, Razia Khan Sharme, Mohammad Borhan Uddin, Mohammad Salman Haque, Fahim Khan

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Abstract

In this study,three samples were created using gravity die casting, i.e.,two modelsof immiscible alloys, Alloy1 (Al-12wt.%Sn-8wt.%Cu) and Alloy2 (Al-20wt.%Sn-10wt.%Cu),along with a control sample of pure Al.These gravity die-cast samples,homogenized at 700°Cfor 2hours,are analyzed formechanical properties and microstructures.Optical microscopy and scanning electron microscopy with energy dispersive spectroscopy (EDS) were used to analyze the changes in the Al-Sn-Cu solidified system resulting from the addition of specific alloying elements. Both Alloy1 and Alloy2 showed better mechanical properties than the control sample of pure Al. The tensile strength of Alloy2 shows a decrease from 110.878 MPato 105.750 MPacompared to Alloy1. However, there isan increase in the yield strength from 30.239 MPa to 32.362 MPa when the addition of tin exceeds 12% and copper exceeds 8%, respectively, which might be because of the alpha-phase solid solution’s interdendritic region that produces lattice strains.The impact resistance and ductility of the alloy are compromised as the hardness increases with the addition of more alloying elements. Alloy2 exhibited the highest hardness at 50.92 HB. The Brinell hardness values suggest these alloys arepotential candidatesto replace antifriction bronzes. However, hard CuAl2 is produced at the grain boundaries when copper percentages are increased, reducingthe impact properties. The effects of different alloying constituents and melt treatment on the microstructural control of Al-Sn-Cu solidified alloy werealso studied. The aluminum matrix with a semi-continuous network (reticular) distribution of tin on the grain boundary was observed. The grain size gradually decreased from 19.65 μm to 16.94 μm and became more equiaxed for Al-20wt.%Sn-10wt.%Cu than Al-12wt.%Sn-8wt.%Cu. The bond between tin and matrix improved with the increasing alloying element. The data obtained from this experiment will undoubtedly contribute to future research in this field

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凝固铝锡铜体系的微观结构和力学性能建模

本研究采用重力压铸法制作了三个样品，即这些重力压铸样品在 700°C 下均质 2 小时，对其力学性能和微观结构进行了分析。利用光学显微镜和扫描电子显微镜以及能量色散光谱（EDS）分析了添加特定合金元素后铝锡铜凝固体系的变化。合金 1 和合金 2 的机械性能均优于纯铝对照样品。与合金 1 相比，合金 2 的抗拉强度从 110.878 兆帕下降到 105.750 兆帕。然而，当锡的添加量超过 12%、铜的添加量超过 8%时，屈服强度分别从 30.239 兆帕增加到 32.362 兆帕，这可能是由于α相固溶体的树枝晶间区产生了晶格应变。合金 2 的硬度最高，为 50.92 HB。布氏硬度值表明，这些合金是替代抗摩擦青铜的潜在候选材料。然而，当铜的百分比增加时，在晶界处会产生硬的 CuAl2，从而降低了冲击性能。此外，还研究了不同合金成分和熔体处理对 Al-Sn-Cu 固化合金微观结构控制的影响。观察到铝基体晶界上锡呈半连续网状（网状）分布。铝-20wt.%锡-10wt.%铜的晶粒尺寸从 19.65 μm 逐渐减小到 16.94 μm，并且比铝-12wt.%锡-8wt.%铜更加等轴。锡与基体之间的结合力随着合金元素的增加而提高。本实验所获得的数据无疑将有助于该领域未来的研究。

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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Malaysian Journal on Composites Science and Manufacturing

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