Investigation of the influence of the rivet geometry on joint formation for a versatile self-piercing riveting process

Fabian Kappe, Mathias Bobbert, Gerson Meschut
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Abstract

Climate change has led to a large number of countries deciding to reduce carbon dioxide (CO2) emissions significantly. As the mobility sector is a major contributor to CO2, various strategies are being pursued to achieve the climate targets set. An increasingly applied lightweight design method is the use of multi-material constructions. To join these structures, mechanical joining technologies such as self-pierce riveting are being used. As a result of the currently rigid tool systems, which cannot react to changing boundary conditions, a large number of rivet–die combinations is required to join the rising number of materials as well as material thickness combinations. Thus, new, versatile joining technologies are needed that can react to the described changes. The versatile self-piercing riveting (V-SPR) process is one possible approach. In this process, different material thicknesses can be joined by using a multi-range capable rivet which is set by a joining system with extended actuator technology. In this study, the V-SPR joining process is analysed numerically according to the influence of the geometrical rivet parameters on the joints characteristics as well as the resulting material flow. The investigations showed that the shank geometry has a decisive influence on the expansion of the rivet. Furthermore, the rivet length could be proven to be an influencing factor. By changing the head radii and the protrusion height, the forming behaviour of the rivet head onto the punch-sided joining part could be improved and thus the formation of air pockets was prevented. Based on the numerical investigations, a novel rivet geometry was developed and produced by machining. Subsequently, experimentally produced joints were analysed according to their joint formation and load-bearing capacity.
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研究铆钉几何形状对多功能自冲铆接工艺接头形成的影响
气候变化导致许多国家决定大幅减少二氧化碳(CO2)排放量。由于汽车行业是二氧化碳的主要排放源,因此各国正在采取各种策略来实现既定的气候目标。一种应用日益广泛的轻质设计方法是使用多材料结构。为了连接这些结构,目前正在使用自冲铆接等机械连接技术。由于目前的工具系统比较僵硬,无法对不断变化的边界条件做出反应,因此需要大量的铆钉-模具组合来连接不断增加的材料和材料厚度组合。因此,需要能够应对上述变化的新型多功能连接技术。多功能自冲铆接(V-SPR)工艺就是一种可行的方法。在这种工艺中,不同厚度的材料可以通过使用多范围铆钉进行连接,而这种铆钉是由采用扩展致动器技术的连接系统设置的。在本研究中,根据铆钉几何参数对接头特性以及由此产生的材料流动的影响,对 V-SPR 连接工艺进行了数值分析。研究表明,铆钉柄的几何形状对铆钉的膨胀有决定性影响。此外,铆钉长度也是一个影响因素。通过改变铆钉头的半径和突出高度,可以改善铆钉头在冲压连接部件上的成型性能,从而防止气穴的形成。在数值研究的基础上,开发了一种新型铆钉几何形状,并通过机械加工生产出来。随后,根据铆接成型和承载能力对实验生产的接头进行了分析。
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来源期刊
CiteScore
3.80
自引率
16.70%
发文量
370
审稿时长
6 months
期刊介绍: The Journal of Process Mechanical Engineering publishes high-quality, peer-reviewed papers covering a broad area of mechanical engineering activities associated with the design and operation of process equipment.
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