Investigations on design limits and improved material utilization of press-fit connections using elastic-plastic design

IF 2.2 Q2 ENGINEERING, MULTIDISCIPLINARY
Jan Falter, Hansgeorg Binz , Matthias Kreimeyer
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引用次数: 2

Abstract

Today, there are a number of analytical and numerical calculation methods for the elastic-plastic design of press-fit connections. However, these are largely constrained by their restriction to elastic-ideal-plastic material behavior. In addition, recommendations for limiting the plasticized hub cross section that have been provided to date do not exploit the full potential of the materials, with the result that opportunities for lightweight design and improved transmission capacity have remained unused so far. Yet, no experimental validations exist to this end, which is why the existing design method could not be validated until today. In addition, there is still a lack of research on how to evaluate the potential for increasing the force and torque transmission under consideration of the strain hardening of the material during plastic deformation. The lack of knowledge today prevents a targeted design and thereby the industrial application of this type of connection; the transmission capacity and lightweight design potentials have thus remained unused until now (Kröger and Binz, 2020). This article presents the actual design and joining limits of hubs made of EN AW-5083 (AlMg4,5Mn), which were determined as part of an Industrial Collective Research (IGF) project. This allows the hub materials to be better utilized, which leads to a reduction in mass and/or an increase in the force and torque transmission. In addition, the experimental validation of the numerical investigations helps to establish the design method in industrial practice.

使用弹塑性设计研究压配合连接的设计极限和提高材料利用率
目前,压配合连接的弹塑性设计有许多分析和数值计算方法。然而,这些在很大程度上受到其对弹性理想塑性材料行为的限制。此外,迄今为止提供的限制塑化轮毂横截面的建议并没有充分利用材料的潜力,因此迄今为止,轻质设计和提高传动能力的机会仍未得到利用。然而,目前还没有实验验证,这就是为什么现有的设计方法直到今天才能得到验证的原因。此外,考虑到材料在塑性变形过程中的应变硬化,如何评估增加力和扭矩传递的潜力仍然缺乏研究。当今知识的缺乏阻碍了有针对性的设计,从而阻碍了这种类型的连接的工业应用;因此,直到现在,传输容量和轻量化设计潜力仍未得到利用(Kröger和Binz,2020)。本文介绍了EN AW-5083(AlMg4,5Mn)轮毂的实际设计和连接极限,这些轮毂是作为工业集体研究(IGF)项目的一部分确定的。这允许更好地利用轮毂材料,这导致质量的减少和/或力和扭矩传递的增加。此外,数值研究的实验验证有助于在工业实践中建立设计方法。
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
Applications in engineering science
Applications in engineering science Mechanical Engineering
CiteScore
3.60
自引率
0.00%
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审稿时长
68 days
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