铝合金韧性损伤模型:冲压试验的实验与数值验证

Q4 Engineering
M. Mastrone, L. Fraccaroli, F. Concli
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引用次数: 2

摘要

正确预测机械部件的韧性断裂需要塑性领域的物理量知识。该区域具有非线性特征,经典屈服准则仅适用于弹性场,不能应用。应力三轴性和塑性应变等参数在破坏机制中起决定性作用。借助仿真软件,可以通过求解偏微分方程实现能够数值计算这些参数的虚拟模型。这些参数可以用来描述材料的断裂轨迹,进而预测部件的失效。在这项工作中,Rice和Tracey损伤模型针对铝合金进行了校准,并利用有限元分析在冲压试验中进行了验证。实验结果与数值结果吻合较好,证明了所考虑的模型在实际测试用例中预测故障的能力。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Ductile damage model of an alluminum alloy: experimental and numerical validation on a punch test
The correct prediction of ductile fracture of mechanical components requires the knowledge of physical quantities that are in the plastic field. This region is characterized by non-linearities, and the classical yield criteria cannot be applied since they work only in the elastic field. It has been observed that parameters such as stress triaxiality and plastic strain play a determinant role in failure mechanisms. Thanks to simulation software, it is possible to implement the virtual models capable of calculating these parameters numerically by solving partial differential equations. These parameters can then be used to describe the fracture locus of a material that, in turn, allows to predict failure of a component. In this work, the Rice and Tracey damage model was calibrated for an aluminum alloy and validated on a punch test exploiting Finite Element Analysis. Good agreement between experimental observations and numerical results was obtained, demonstrating the capability of the considered model to predict failure on a real test case.
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来源期刊
CiteScore
1.10
自引率
0.00%
发文量
24
审稿时长
33 weeks
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