Fatigue resistance of deep drawn parts: A scale bridging simulative study using representative volume elements and crystal plasticity simulations

Materials Research Proceedings Pub Date : 2024-05-15 DOI:10.21741/9781644903131-235

N. Fehlemann

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引用次数: 0

Abstract

Abstract. The mechanical properties of formed components are determined by the interaction between the microstructure and the load path of the forming process. To investigate and understand these effects, micromechanical simulation concepts can be used, such as statistically Representative Volume Elements (sRVE) coupled with crystal plasticity simulations. This study presents a concept that uses sRVE simulations to quantify the influence of three different deep drawing load paths on the fatigue resistance of DP800 steel. The first step is a scale-bridging simulation approach that employs macroscopic simulations of the deep drawing process to extract the boundary conditions for the sRVE simulations with Damask. Subsequent cyclic loading is then simulated. 50 sRVE are computed for each load path to estimate fatigue resistance based on a Fatigue Indicator Parameter. The results indicate that fatigue resistance increases with increasing deformation-induced strain hardening. Additionally, a positive correlation between the martensitic ligament structures and fatigue resistance was observed.

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深冲部件的抗疲劳性：使用代表性体积元素和晶体塑性模拟进行尺度桥接模拟研究

摘要成型部件的机械性能取决于成型过程中微观结构与载荷路径之间的相互作用。为了研究和了解这些影响，可以使用微观机械模拟概念，如统计代表体积元素（sRVE）与晶体塑性模拟相结合。本研究提出了一种使用 sRVE 模拟来量化三种不同深冲载荷路径对 DP800 钢抗疲劳性影响的概念。第一步是采用尺度桥接模拟方法，通过对深冲过程进行宏观模拟，为使用 Damask 的 sRVE 模拟提取边界条件。然后模拟随后的循环加载。每个加载路径计算 50 个 sRVE，以根据疲劳指标参数估计抗疲劳性。结果表明，抗疲劳性随着变形引起的应变硬化的增加而增加。此外，还观察到马氏体韧带结构与耐疲劳性之间存在正相关。

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

Materials Research Proceedings

CiteScore

0.30

自引率

0.00%

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