Finite-element analysis of deformation during indentation and scratch tests on elastic-perfectly plastic materials

Philosophical Magazine A Pub Date : 2002-07-01 DOI:10.1080/01418610208235712

J. Bucaille, E. Felder

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引用次数: 46

Abstract

Abstract We have studied the distribution of plastic strain around normal indentation and scratches in elastic-perfectly plastic materials. A three-dimensional finite-element analysis of a cone scratching and indenting elastic-perfectly plastic materials is presented. The indenter is the axisymmetric equivalent cone of the Berkovich indenter, with semiapical angle θ = 70.3°. The plastic behaviour of the material is modelled with the yield stress σ0. No strain hardening and no sensitivity to the strain rate occur. The elasticity of the material is modelled with Young's modulus E, which varies from 2.79 to 2793 GPa. In fact, the behaviour of the scratched or indented material depends on the parameter X = (E/σ0) cotθ, called the rheological factor (X = 1, …, 1000). For small rheological factors, the deformation is mainly elastic; for high rheological factors, the deformation is essentially plastic, and in this case the behaviour of the material is close to the behaviour of a metal. The contact between the indenter and the mesh is frictionless. We have defined a mean representative strain in indentation and scratch tests. This value is independent of the scratch length and the penetration depth. It has been shown that the mean representative strain increases with X, and that it is larger in scratch tests than in indentation tests.

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弹塑性材料压痕和划痕试验变形的有限元分析

摘要研究了理想弹塑性材料法向压痕和划痕周围的塑性应变分布。本文对弹塑性材料锥面划痕和压痕进行了三维有限元分析。该压头为Berkovich压头的轴对称等效锥体，其半尖角θ = 70.3°。材料的塑性行为用屈服应力σ0来模拟。没有应变硬化，对应变速率不敏感。材料的弹性用杨氏模量E来建模，其变化范围为2.79到2793 GPa。事实上，划痕或压痕材料的行为取决于参数X = (E/σ0) cottθ，称为流变因子(X = 1，…，1000)。对于较小的流变因子，变形以弹性为主;对于高流变因子，变形本质上是塑性的，在这种情况下，材料的行为接近于金属的行为。压头与网格之间的接触是无摩擦的。我们在压痕和划痕试验中定义了一个平均代表性应变。该值与划痕长度和穿透深度无关。结果表明，具有代表性的平均应变随X的增大而增大，且划痕试验的平均应变比压痕试验的平均应变大。

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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Philosophical Magazine A

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