Specimen's Geometry Related Influences on Load-Bearing Capacity of Joining Aluminium and UHSS by Innovative Shear-Clinching

R. Hörhold, M. Müller, M. Merklein, G. Meschut
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引用次数: 11

Abstract

Economic conditions as well as comfort and safety-related requirements lead to lightweight design especially in automotive body-in-white production processes. The consequential multi-material mix limits the reliability of conventional thermal joining technologies. Innovative mechanical joining technologies need to be established. Following the lightweight-design requirements, next step for weight-reduction would be the renunciation of additional elements. Clinching technologies support this idea by creating a form- and force-fitting joint, but are limited to the formability of the joining partners. Joining by forming without additional elements even of hot formed ultra-high-strength manganese steels and ductile aluminium can be realised by shear-clinching. A precisely coordinated tool setup initialises a crack in the die-sided material with limited formability without harming the punch-sided ductile aluminium. This paper presents current and detailed investigations of the influences of mechanical loads on strength capacity of multi-material joints using shear-clinching technologies. The results clearly show the promising potential and challenges of this innovative single-step joining technology for multi-material mixes.
试件几何形状对创新剪切夹紧铝与超高压钢连接承载力的影响
经济条件以及与舒适性和安全性相关的要求导致了轻量化设计,特别是在汽车白车身生产过程中。由此产生的多种材料混合限制了传统热连接技术的可靠性。需要建立创新的机械连接技术。在轻量化设计要求之后,减重的下一步将是放弃额外的元素。夹持技术通过创建一个形式和力配合的接头来支持这一想法,但受限于连接伙伴的可成形性。即使是热成型的超高强度锰钢和韧性铝,也可以通过剪切夹紧实现无附加元素的成形连接。精确协调的工具设置初始化模具侧材料的裂纹,具有有限的成形性,而不会损害冲孔侧的韧性铝。本文介绍了利用剪切-夹紧技术对机械载荷对多材料接头强度能力影响的最新研究进展。结果清楚地表明,这种用于多种材料混合的创新单步连接技术具有巨大的潜力和挑战。
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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