Mathematical Model for Friction Stir Lap Welded AA5052 and SS304 Joints and Process Parameters Optimization for High Joint Strength

IF 1.5 Q4 MATERIALS SCIENCE, MULTIDISCIPLINARY
Veerendra Chitturi, S. R. Pedapati, M. Awang
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引用次数: 3

Abstract

Abstract Due to the numerous challenges faced during the dissimilar welding, choosing the right process parameters and their optimization yields better results. In this context, the current investigation is focused on the optimization of process parameters. Taguchi’s L9 orthogonal array was selected to carry out the experimental investigations. The welded samples were tested for shear strength, and the results were analysed using Taguchi’s S/N ratio analysis with “larger the better” criteria. Log-linear regression analysis was applied to formulate an empirical correlation between the process parameters and shear strength. According to S/N ratio analysis, the tool rotational speed of 800 rpm, welding speed of 20 mm/min and a penetration depth of 4.1 mm are the optimized parameters that achieve high joint strength. The achieved joint strength was 3.46 kN that is 70% of the base aluminium metal. It was noticed from the Analysis of variance of the regression model that penetration depth and tool rotational speed are the significant contributors with p-values less than 0.5. Confirmation tests show that the error between the predicted and calculated shear strength is 2.06% which is considered acceptable. R2 and adjusted R2 values of the model with a standard error of 0.076 show that the developed model is statistically significant.
AA5052与SS304搅拌摩擦搭接接头数学模型及高强度接头工艺参数优化
由于异种焊接面临诸多挑战,选择正确的工艺参数并对其进行优化可以获得较好的效果。在此背景下,目前的研究重点是工艺参数的优化。采用田口L9正交阵列进行实验研究。对焊接试样进行抗剪强度测试,并采用“越大越好”的田口信噪比分析方法对结果进行分析。采用对数线性回归分析,建立了工艺参数与抗剪强度之间的经验相关性。根据信噪比分析,刀具转速为800 rpm,焊接速度为20 mm/min,焊深为4.1 mm是获得高接头强度的优化参数。得到的接头强度为3.46 kN,为母材的70%。从回归模型的方差分析中可以看出,穿透深度和刀具转速是显著的影响因素,p值小于0.5。验证试验表明,预测抗剪强度与计算抗剪强度误差为2.06%,可以接受。模型的R2和调整后的R2值的标准误差为0.076,表明所建立的模型具有统计学意义。
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来源期刊
Advances in Materials Science
Advances in Materials Science MATERIALS SCIENCE, MULTIDISCIPLINARY-
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