Numerical analysis of the dependence of damage on friction during deep drawing of asymmetric geometries

IF 3.9 Q2 ENGINEERING, INDUSTRIAL
Martina Müller , Lars Uhlmann , Tim Herrig , Thomas Bergs
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Abstract

The manufacturing of three-dimensional sheet metal components, such as car body parts, heavily relies on deep drawing. With the increasing demand for lightweight measures in the automotive industry due to CO2 limitation requirements, various methods are currently employed to reduce the weight of deep drawn components. However, these methods often overlook the potential for influencing the stress-strain dependent damage state within the component, even though it can greatly affect its performance in subsequent applications, and thus offers lightweight potentials. Friction between the deep drawing tools and the sheet metal is a key factor influencing the stress-strain state, and hence, represents a lever that can be utilized to manipulate the damage state in the component. This paper focuses on the numerical analysis of the dependence of damage on friction during deep drawing. Therefore, a rectangular geometry with an asymmetrical material flow is numerically investigated. A friction ratio is introduced with different constant friction coefficients for the corner of the tools and the straight sides. The established load paths at a chosen reference point are then considered in the form of selected stress and strain characteristics and the numerically predicted damage state is compared. The results are used to derive a recommended friction ratio that leads to less damage in the corner of the geometry. Afterwards strip drawing tool surfaces are modified to manipulate their friction properties using machine hammer peening. Subsequently, the influence of the structures of the strip drawing tool surfaces is quantified using strip drawing tests. The identified contact normal stress dependent friction coefficients are then implemented in the numerical simulation and the established numerical predicted damage state is examined to gain a more comprehensive understanding of how the friction ratio and the structure of the tool surfaces influence the damage state.

非对称几何体拉深过程中损伤与摩擦力关系的数值分析
汽车车身部件等三维钣金部件的制造在很大程度上依赖于拉深加工。由于二氧化碳排放量的限制,汽车行业对轻量化措施的要求越来越高,目前采用了各种方法来减轻深冲部件的重量。然而,这些方法往往忽视了影响部件内部应力-应变相关损伤状态的潜力,尽管这会极大地影响部件在后续应用中的性能,从而提供轻量化潜力。拉深工具与金属板材之间的摩擦是影响应力应变状态的关键因素,因此也是操纵部件损伤状态的杠杆。本文的重点是对深拉过程中损伤与摩擦力的关系进行数值分析。因此,本文对具有不对称材料流的矩形几何体进行了数值研究。在工具转角处和直边处引入了不同恒定摩擦系数的摩擦比。然后,以选定的应力和应变特征的形式考虑所选参考点的既定负载路径,并对数值预测的损坏状态进行比较。结果用于推导出推荐的摩擦比,以减少几何形状拐角处的损坏。之后,对带材拉拔工具表面进行修改,利用机器锤击强化处理其摩擦特性。随后,利用带材拉拔试验对带材拉拔工具表面结构的影响进行量化。然后将确定的接触法向应力相关摩擦系数应用于数值模拟,并对建立的数值预测损伤状态进行检查,以更全面地了解摩擦比和工具表面结构如何影响损伤状态。
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
Advances in Industrial and Manufacturing Engineering
Advances in Industrial and Manufacturing Engineering Engineering-Engineering (miscellaneous)
CiteScore
6.60
自引率
0.00%
发文量
31
审稿时长
18 days
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