Determination of the load acting on the probe by separating force and torque during FSW of AA 6060 T66

IF 2.4 4区 材料科学 Q2 METALLURGY & METALLURGICAL ENGINEERING
Martin Sennewald, Ramon Wüstefeld, Michael Hasieber, Torsten Löhn, Jean Pierre Bergmann
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引用次数: 0

Abstract

The development of suitable welding processes is required to meet the ever-increasing demands on joining processes, particularly for lightweight construction and increasing environmental awareness. Friction stir welding (FSW) represents a promising alternative to conventional fusion welding processes, particularly for the joining of low-melting-point materials such as aluminium and magnesium alloys, which present a number of challenges, including the formation of pores and the occurrence of hot cracks. The central element of the process is the friction stir welding tool, which consists of a shoulder and a probe. The rotation and the simultaneous application of pressure during the joining process create a friction-based heat input through the tool. The excellent mechanical properties resulting from dynamic recrystallisation during the welding process are a major advantage of the process. As a result, strengths comparable to those of the base material can be achieved. However, FSW is subject to process-specific challenges, including high process forces, which result in the fabrication of complex and robust devices. Additionally, high dynamic loads on the friction stir welding tools must be considered. In many cases, the design of friction stir welding tools is based on empirical data. However, these empirical values are machine-, component- and material-specific, which often results in under- or overmatching of friction stir welding tools. Sudden probe failure, component scrap, and low process reliability are the direct consequences of undermatching. Overmatching results in enlarged tools with limited accessibility, high heat input, and high process forces, leading to component deformation. The aim of this study is to determine the load on the probe by separating the forces and torque of the shoulder and the probe in order to be able to make statements about the load acting on the probe and the resulting stress state. The knowledge of the stress state can be employed to design friction stir welding tools, both statically and dynamically, for a specific welding task. A strategy was devised to distribute the load exerted on the shoulder and probe. To this end, the length of the probe was gradually reduced between the welding tests. The investigations were carried out with a force-controlled robotized welding setup in which AA 6060 T66 sheets with a thickness of 5 mm were welded. A Kistler multicomponent dynamometer type 9139AA allows to measure the Cartesian forces to be recorded in the x-, y-, and z-directions with a sampling rate of 80 kHz. The weld seam properties were determined by visual and metallographic inspections as well as tensile and bending tests in accordance with DIN EN ISO 25239–5.

Abstract Image

通过分离 AA 6060 T66 FSW 过程中的力和扭矩确定作用在探针上的载荷
为了满足对焊接工艺日益增长的需求,特别是轻质建筑和日益增强的环保意识,需要开发合适的焊接工艺。搅拌摩擦焊(FSW)是传统熔化焊接工艺的一种很有前途的替代工艺,尤其是在连接铝合金和镁合金等低熔点材料时,因为这些材料会产生气孔和热裂纹。该工艺的核心要素是搅拌摩擦焊接工具,它由一个肩部和一个探头组成。焊接过程中的旋转和同时施加的压力会通过工具产生摩擦热输入。焊接过程中的动态再结晶产生的优异机械性能是该工艺的一大优势。因此,可以达到与母材相当的强度。然而,FSW 焊接工艺也面临着一些特定工艺的挑战,其中包括高工艺力,这导致了复杂和坚固设备的制造。此外,还必须考虑搅拌摩擦焊接工具所承受的高动态载荷。在许多情况下,搅拌摩擦焊接工具的设计都是基于经验数据。然而,这些经验值是针对特定机器、部件和材料的,这往往会导致搅拌摩擦焊工具匹配不足或匹配过度。探头突然失效、部件报废和工艺可靠性低是匹配不足的直接后果。过度匹配则会导致工具变大,可操作性受限,输入热量高,加工力大,从而导致部件变形。本研究的目的是通过分离肩部和测头的力和扭矩来确定测头上的载荷,从而能够对作用在测头上的载荷以及由此产生的应力状态做出说明。应力状态的知识可用于设计搅拌摩擦焊接工具,无论是静态还是动态,以完成特定的焊接任务。我们设计了一种策略来分散施加在肩部和探针上的载荷。为此,探针的长度在两次焊接试验之间逐渐缩短。研究使用了力控机器人焊接装置,对厚度为 5 毫米的 AA 6060 T66 板材进行焊接。基斯勒 9139AA 型多分量测力计可测量记录 x、y 和 z 方向上的笛卡尔力,采样率为 80 kHz。根据 DIN EN ISO 25239-5 标准,通过目视和金相检验以及拉伸和弯曲测试确定焊缝性能。
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来源期刊
Welding in the World
Welding in the World METALLURGY & METALLURGICAL ENGINEERING-
CiteScore
4.20
自引率
14.30%
发文量
181
审稿时长
6-12 weeks
期刊介绍: The journal Welding in the World publishes authoritative papers on every aspect of materials joining, including welding, brazing, soldering, cutting, thermal spraying and allied joining and fabrication techniques.
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