Enabling magnetic pulse welding for dissimilar tubular arrester cable joints

IF 2.4 4区 材料科学 Q2 METALLURGY & METALLURGICAL ENGINEERING
M. Graß, N. Sommer, S. Böhm
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引用次数: 0

Abstract

Climate change exacerbates the need for resource-efficient and cost-effective production processes across manifold industries, including the field of electrical connections. This specific field is characterized by a conflict of objectives, i.e., weight reductions while maintaining joint strength and electrical conductivity. From a material point of view, the use of aluminum as a conductor material is suitable for this application, as it is lighter than copper, a classical conductor material. Electrical conductors are often used in the form of flexible cables, so-called stranded wires. This type of conductor as well as the fact that the sole use of aluminum in electrical systems is not feasible, e.g., because the predetermined connection terminals of power electronic components are made of copper, creates a substantial demand for dissimilar aluminum-copper cable arrester joints. However, traditional fusion-based welding processes have proved incapable of reliably producing these dissimilar aluminum-copper joints because of thermophysical effects and chemical incompatibilities, the latter eventually leading to the formation of intermetallic phases. These phases adversely affect the quality of the joint in terms of both mechanical and electrical performance. Yet, magnetic pulse welding, a pressure welding process, is ideally suited for producing dissimilar metal joints on the basis of a low energy input during the welding process. Consequently, the formation of intermetallic phases is restrained. However, magnetic pulse welding has not been sufficiently investigated for the reliable contacting of stranded cables to tubular arresters. As a result, this paper focuses on the fabrication of tubular stranded cable arrester joints using magnetic pulse welding. To shed light on possible material combinations, aluminum-to-aluminum and copper-to-copper joints as well as their dissimilar counterparts are welded. Subsequently, the joints are characterized with regard to their microstructure and quasi-static material strength. Electrical characterization comprises the four-wire Kelvin measurement method to evaluate the resistance of the electrical joints. The results demonstrate that magnetic pulse welding is ideally suited to join the aforementioned material combination and joint configuration due to its process characteristics eventually leading to material continuity. As a result, the stranded wires are welded to the tubular arresters rather than crimped. Consequently, a comparative analysis of the joint properties with those of the joining partners shows that the measured electrical resistances and mechanical tensile forces may be considered very good.

Abstract Image

为异种管状避雷器电缆接头实现磁脉冲焊接
气候变化加剧了各行各业对资源节约型和成本效益型生产工艺的需求,其中包括电气连接领域。这一特定领域的特点是目标冲突,即在保持连接强度和导电性的同时减轻重量。从材料的角度来看,使用铝作为导体材料非常适合这一应用,因为铝比传统导体材料铜更轻。导体通常以柔性电缆的形式使用,即所谓的绞合导线。这种导体类型以及在电气系统中仅使用铝是不可行的,例如,由于电力电子元件的预定连接端子是由铜制成的,因此对异种铝铜电缆避雷器接头的需求量很大。然而,由于热物理效应和化学不相容性(后者最终会导致金属间相的形成),传统的熔融焊接工艺已被证明无法可靠地生产这些异种铝铜接头。这些金属相会对接头的机械和电气性能产生不利影响。然而,磁脉冲焊接是一种压力焊接工艺,在焊接过程中能量输入低,非常适合生产异种金属接头。因此,金属间相的形成受到限制。然而,对于将绞合电缆与管状避雷器可靠连接的问题,磁脉冲焊接尚未得到充分研究。因此,本文重点讨论了利用磁脉冲焊接制造管状绞合电缆避雷器接头的问题。为了揭示可能的材料组合,我们焊接了铝对铝、铜对铜以及它们的异种材料。随后,对接头的微观结构和准静态材料强度进行表征。电气特性分析包括采用四线开尔文测量法评估电气接头的电阻。结果表明,磁脉冲焊接由于其工艺特点,非常适合连接上述材料组合和接头结构,最终实现材料的连续性。因此,绞线是焊接到管状避雷器上的,而不是压接。因此,对接头特性和连接伙伴的特性进行比较分析后发现,测量到的电阻和机械拉力都非常好。
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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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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