Performance analysis of Al stainless steel joints fabricated by friction stir welding: Microstructure, mechanical, and tribology

Proceedings of the Institution of Mechanical Engineers, Part J: Journal of Engineering Tribology Pub Date : 2024-04-15 DOI:10.1177/13506501241246841

Fayaz A Mir, N. Z. Khan, K. Sheikh, I. Badruddin, S. Kamangar

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Abstract

Hybrid structures, incorporating both aluminum and steel, hold potential for applications in automobile, aerospace, and marine industries. This research delves into the effects of friction stir welding on dissimilar joints (AA2024-T3 and SS304), with a focus on microstructural, mechanical, and tribological aspects. The study identifies optimal welding conditions at (tool rotational speed 710 r/min, traverse speed20 mm/min, tool pin offset1.5 mm towards aluminum, and tilt angle of 1.75 deg) that yield a well-defined joint interface, contrasting with flaws observed at a 40 mm/min traverse speed due to insufficient heat input. Under optimal conditions at 20 mm/min, a well-clean serrated interface, defect-free microstructural evolution, improved surface characteristics; enhanced mechanical performance resulting in higher ultimate tensile strength of 319 MPa with joint efficiency of 72.5 and better tribological performance were achieved with lower wear rate of 1.1607 × 10−5 g/Nm compared to those at 40 mm/min, highlighting the crucial role of optimized friction stir welding parameters in achieving high-quality dissimilar joints with desirable properties.

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通过搅拌摩擦焊制造的铝不锈钢接头的性能分析：微观结构、机械和摩擦学

铝与钢的混合结构在汽车、航空航天和船舶工业中具有潜在的应用前景。本研究深入探讨了搅拌摩擦焊对异种接头（AA2024-T3 和 SS304）的影响，重点关注微观结构、机械和摩擦学方面。研究确定了最佳焊接条件（工具旋转速度 710 r/min，横移速度 20 mm/min，工具针向铝偏移 1.5 mm，倾斜角度 1.75 deg），这些条件可产生轮廓清晰的接头界面，而在横移速度为 40 mm/min 时，由于热量输入不足，则会出现缺陷。在 20 毫米/分钟的最佳条件下，可获得洁净的锯齿状界面、无缺陷的微观结构演变、更好的表面特性；与 40 毫米/分钟的条件相比，机械性能得到提高，极限抗拉强度达到 319 兆帕，接头效率达到 72.5；摩擦学性能更好，磨损率更低，仅为 1.1607 × 10-5 g/Nm。

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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Proceedings of the Institution of Mechanical Engineers, Part J: Journal of Engineering Tribology

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