Additively manufactured vacuum grippers for the flexible handling and assembly of hairpin coils in electric motor production

Felix Fraider, Michael Baranowski, Johannes Gerner, Chiara Cassiani, Philipp Geis, Felix Wirth, Jürgen Fleischer
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Abstract

Hairpin technology has recently become the predominant winding technology for the manufacturing of stators used in electric traction motors. In contrast to conventional winding techniques, the manufacturing process chain is based on rectangular wire which is bent into a three-dimensional U-shape – so-called hairpin coils. These hairpin coils have to be individually gripped and assembled to form the stator winding. There can be hundreds of hairpin coils in a single stator, which can also differ in shape. Therefore, gripping and moving the individual hairpin coils is a challenging task in terms of flexibility and cycle time. This paper presents an approach to meet the outlined requirements using additively manufactured vacuum grippers. A concept is investigated in which the vacuum is generated in a conventional vacuum ejector and fed to the vacuum gripper via hose lines. In contrast, the concept of a functionally integrated vacuum gripper manufactured by a new laser-sintering process with automated continuous fibre reinforcement is presented. Based on the laser-sintering process, a lightweight vacuum gripper with an integrated vacuum ejector can be manufactured in a single process step without additional costs for purchased parts. After a review of the state of the art in both hairpin-specific and additively manufactured lightweight grippers, experimental test series are carried out concerning the vacuum quality and the grip strength of the different vacuum gripper designs. Pull-off tests show that high holding forces of several Newtons are possible proving the basic usability of vacuum grippers for hairpins, even though the achievable vacuum quality of the functionally integrated vacuum gripper is lower than that of the conventional ejector. Comparison of the novel approaches with a conventional mechanical hairpin gripper regarding weight, production costs and production time show promising improvements.
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用于在电机生产中灵活搬运和装配发夹线圈的快速制造真空机械手
最近,发夹技术已成为制造电力牵引电机定子的主要绕组技术。与传统绕组技术不同的是,该制造工艺链以矩形线材为基础,将其弯曲成三维 U 形--即所谓的发夹线圈。这些发夹式线圈必须单独抓取并组装成定子绕组。一个定子中可能有数百个发夹线圈,它们的形状也可能各不相同。因此,抓取和移动单个发夹线圈在灵活性和周期时间方面都是一项具有挑战性的任务。本文介绍了一种使用快速成型真空夹具来满足上述要求的方法。本文研究的概念是在传统的真空喷射器中产生真空,并通过软管输送到真空机械手。相比之下,本文提出了一种功能集成式真空机械手的概念,该机械手采用新型激光烧结工艺制造,并配有自动连续纤维加固装置。在激光烧结工艺的基础上,只需一道工序就能制造出带有集成真空喷射器的轻型真空抓取器,而无需增加外购部件的成本。在回顾了发夹式和加成型轻型机械手的技术现状之后,对不同真空机械手设计的真空质量和抓取强度进行了一系列实验测试。拉拔测试表明,尽管功能集成式真空夹具可达到的真空质量低于传统顶出器,但仍可实现几牛顿的高夹持力,这证明真空夹具对发卡的基本可用性。在重量、生产成本和生产时间方面,新方法与传统的机械发夹夹具进行了比较,结果表明两者都有很大的改进。
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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