A Frictionless Normal Contact Model for Flattening Elastoplastic Single Asperity Considering Yield Plateau and Strain Hardening

IF 2.9 3区 工程技术 Q2 MECHANICS
Juncheng Luo, Jianhua Liu, Huanxiong Xia, Xiaohui Ao, Jian Zhang, Xuerui Zhang, Hui Zhang, Hao Huang, Xin Liu
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引用次数: 0

Abstract

Contact between solids is a ubiquitous phenomenon in engineering and an enduring topic in tribology. However, material yield plateau and strain hardening are common in ductile metals but rarely considered in contact mechanics. This work develops a three-phase constitutive model that accurately describes the elastic and plastic behaviors considering both yield plateau and strain hardening, and then constructs a finite element model for the contact of a rigid flat and a corresponding elastoplastic hemisphere. The Taguchi method is employed to conduct numerical simulations of material parameters for finding generalized empirical formulations of dimensionless contact load and area versus dimensionless contact interference in the range of ω120. The presented empirical formulations demonstrate good accuracy verified with KE, JG, and Ghaednia’s models. This work fills the gap that the yield plateau has not ever been explored in contact mechanics and provides a basic model for describing the contact behavior of engineering rough surfaces for ductile metal.

考虑屈服台阶和应变硬化的扁平弹塑性单面无摩擦法向接触模型
固体之间的接触是工程学中无处不在的现象,也是摩擦学中一个经久不衰的话题。然而,材料屈服高原和应变硬化在韧性金属中很常见,但在接触力学中却很少考虑。本研究建立了一个三相构成模型,精确描述了同时考虑屈服平台和应变硬化的弹性和塑性行为,然后构建了刚性平面和相应弹塑性半球接触的有限元模型。采用田口方法对材料参数进行数值模拟,以找到在 ω∗≤120 范围内无量纲接触载荷和面积与无量纲接触干涉的广义经验公式。所提出的经验公式与 KE、JG 和 Ghaednia 的模型进行了验证,显示出良好的准确性。这项研究填补了接触力学中屈服台阶研究的空白,为描述韧性金属工程粗糙表面的接触行为提供了一个基本模型。
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来源期刊
CiteScore
5.80
自引率
11.40%
发文量
116
审稿时长
3 months
期刊介绍: The journal has as its objective the publication and wide electronic dissemination of innovative and consequential research in applied mechanics. IJAM welcomes high-quality original research papers in all aspects of applied mechanics from contributors throughout the world. The journal aims to promote the international exchange of new knowledge and recent development information in all aspects of applied mechanics. In addition to covering the classical branches of applied mechanics, namely solid mechanics, fluid mechanics, thermodynamics, and material science, the journal also encourages contributions from newly emerging areas such as biomechanics, electromechanics, the mechanical behavior of advanced materials, nanomechanics, and many other inter-disciplinary research areas in which the concepts of applied mechanics are extensively applied and developed.
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