SS316L和Ti6Al4V材料在混合模态加载条件下的塑性区分析

International Journal for Computational Methods in Engineering Science and Mechanics Pub Date : 2021-10-28 DOI:10.1080/15502287.2021.1992542

Swapnil Patil, U. Chavan

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引用次数: 1

摘要

在本研究中，研究了塑性区大小和形状来预测髋关节植入材料Ti6Al4V和SS316L(分别为钛和不锈钢)的失效。一般来说，它们的断裂是由于裂纹在磨损的作用下扩展而产生的。SS316L和Ti6Al4V的塑性区分析是在第一破坏模式和混合破坏模式(拉伸和剪切加载)下进行的。裂纹倾角是模拟混合模式加载条件的重要参数之一。基于von-Mises准则的有限元模型验证了塑性区分析的解析公式。此外，还绘制了等值线，解释了裂纹尖端附近塑性区和几何形状的变化。在平面应变和平面应力条件下，通过解析公式得到的结果与有限元分析结果密切相关。结果表明，与Ti6Al4V相比，SS316L具有较大的塑性区，裂纹扩展速度较慢，寿命较长。

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Plastic zone analysis of SS316L and Ti6Al4V materials under mixed mode loading conditions

Abstract In present work, plastic zone size and shapes are investigated to predict failure of hip implant materials Ti6Al4V and SS316L (titanium and stainless steel, respectively). Generally, they fracture due to crack propagation in presence of wear which initiates the crack. Plastic zone analysis of SS316L and Ti6Al4V are carried out under standard fracture modes of failure that are first and mixed mode (tensile and shear loading). Crack inclination angle is one of the important parameters to simulate mixed-mode loading conditions. Analytical formulations of plastic zone analysis validated by finite element modeling based on von-Mises criteria. Further, isolines are plotted which explains the variation of plastic zone and geometry near the crack tip. Results obtained under plane strain and plane stress conditions through analytical formulations are in close relevance with FEM. Finally, it is observed that SS316L has large plastic zone which results in slower crack propagation and better life as compared to Ti6Al4V.

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International Journal for Computational Methods in Engineering Science and Mechanics

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