Effect of tools rotational speed on the mechanical properties of one-step double-acting friction stir welded aluminum alloy AA 6061 hollow panel

Mohammad Inggi Hilmawan , Ericha D.W. Syah Putri , Nurul Muhayat , Yupiter H.P. Manurung , Ilhamdi , Sulardjaka , Hendrato , Triyono
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Abstract

The utilization of Aluminum hollow panels enhances structural strength while simultaneously ensuring a lightweight and efficient use of materials. During their application, these panels necessitate a welding process that is susceptible to porosity due to the disparity in hydrogen gas solubility between liquid and solid aluminum. Solid-state welding techniques, such as Friction Stir Welding (FSW), have proven to be effective and appropriate solutions for overcoming this issue. However, due to the thickness of the hollow panels, FSW process is unfeasible as it requires welding on both sides, resulting in prolonged production times. Consequently, the development of a one-step double-acting FSW technique becomes necessary, involving the simultaneous utilization of two tools. The usage of two tools introduces two sources of friction-stir forces, heat, and axial forces, demanding an assessment of the novel response from the specimens. This research aims to analyze the effect of a specific parameter, namely the tool rotation speed, within the one-step double-acting FSW process on the physical and mechanical properties of the AA6061 hollow panels. The One-Step Double-Acting FSW process involved conducting variations in the tool rotation speed on both sides of the welds. Specifically, for the 4G weld position (underside of the workpiece with an overhead weld position), speeds of 1200, 1500, and 1800 rpm were employed. Meanwhile, a consistent rotation speed of 1500 rpm was maintained for the 1G weld position (overside of the material with a flat weld position). The transverse speed and tilt angle are set at 30 mm/min and 2°, respectively. Elevating the tool rotation speed results in increased hardness, load capacity, and bending strength of the weld joints. The specimen subjected to the highest rotational speed (1800 rpm) exhibits the most exceptional mechanical properties, including a hardness of 73.46 HVN, load capacity of 18.47 kN, and bending strength of 60.56 MPa.

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工具转速对一步法双作用摩擦搅拌焊接铝合金 AA 6061 空心板机械性能的影响
铝制空心板的使用增强了结构强度,同时确保了材料的轻量化和高效利用。在应用过程中,由于液态铝和固态铝之间氢气溶解度的差异,这些板材的焊接工艺很容易产生气孔。事实证明,固态焊接技术,如搅拌摩擦焊(FSW),是克服这一问题的有效而适当的解决方案。然而,由于空心板的厚度,FSW 工艺并不可行,因为它需要两面焊接,导致生产时间延长。因此,有必要开发一种同时使用两种工具的一步双动 FSW 技术。使用两个工具会产生两个摩擦力源--搅拌力、热量和轴向力,这就要求对试样的新型响应进行评估。本研究旨在分析特定参数(即一步法双作用 FSW 工艺中的工具旋转速度)对 AA6061 空心板物理和机械性能的影响。一步双动式 FSW 工艺包括在焊缝两侧改变工具旋转速度。具体来说,在 4G 焊接位置(工件底部,焊接位置在上方),采用了 1200、1500 和 1800 rpm 的转速。同时,在 1G 焊缝位置(材料的上方,平焊位置),转速始终保持在 1500 rpm。横向速度和倾斜角度分别设定为 30 毫米/分钟和 2°。提高工具转速可提高焊点的硬度、承载能力和抗弯强度。采用最高转速(1800 rpm)的试样显示出最优异的机械性能,包括 73.46 HVN 的硬度、18.47 kN 的承载能力和 60.56 MPa 的弯曲强度。
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来源期刊
International Journal of Lightweight Materials and Manufacture
International Journal of Lightweight Materials and Manufacture Engineering-Industrial and Manufacturing Engineering
CiteScore
9.90
自引率
0.00%
发文量
52
审稿时长
48 days
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