压痕松弛试验中速率依赖性粘附的临时建模

Ad Hoc Modeling of Rate-Dependent Adhesion in Indentation Relaxation Testing.

作者信息

Argatov Ivan I, Lyashenko Iakov A, Popov Valentin L

机构信息

Institut für Mechanik, Technische Universität Berlin, 10623 Berlin, Germany.

Center of Advanced Studies in Mechanics, Tribology, Bio- and Nanotechnologies, Samarkand State University, Samarkand 140104, Uzbekistan.

出版信息

Materials (Basel). 2024 Aug 8;17(16):3944. doi: 10.3390/ma17163944.

DOI:10.3390/ma17163944

PMID:39203121

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11355375/

Abstract

The phenomenon of rate-dependent adhesion has long been recognized as an intricate problem, and the so-far-developed physics and mechanics-based approaches resulted in analytical relations between the implicit form between the work of adhesion and the contact front velocity which are difficult to implement in practice. To address this issue in the framework of spherical indentation, the adhesion relaxation test in a nominal point contact is introduced to estimate the rate-dependent adhesion. Based on a stretched exponent approximation for the contact radius evolution with time, a relatively simple four-parameter model is proposed for the functional relation between the work of adhesion and the contact front velocity, and its fitting performance is compared to that of the known Greenwood-Johnson and Persson-Brener models.

摘要

速率依赖粘附现象长期以来一直被认为是一个复杂的问题，而迄今为止基于物理和力学的方法得出了粘附功与接触前沿速度之间隐含形式的解析关系，这些关系在实际中难以应用。为了在球形压痕框架内解决这个问题，引入了名义点接触中的粘附松弛试验来估计速率依赖粘附。基于接触半径随时间演变的拉伸指数近似，提出了一个相对简单的四参数模型来描述粘附功与接触前沿速度之间的函数关系，并将其拟合性能与已知的格林伍德 - 约翰逊模型和佩尔松 - 布雷纳模型进行了比较。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/984c/11355375/5c94301b30d1/materials-17-03944-g001.jpg

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压痕松弛试验中速率依赖性粘附的临时建模

Ad Hoc Modeling of Rate-Dependent Adhesion in Indentation Relaxation Testing.

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