Compliant-poroelastic lubrication in cartilage-on-cartilage line contacts

IF 1.6 Q4 MATERIALS SCIENCE, COATINGS & FILMS
G. de Boer, N. Raske, S. Soltanahmadi, M. Bryant, R. Hewson
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引用次数: 4

Abstract

ABSTRACT The mechanisms of friction in natural joints are still relatively unknown and attempts at modelling cartilage-cartilage interfaces are rare despite the huge promise they offer in understanding bio-friction. This article derives a model combining finite strain, porous and thin-film flow theories to describe the lubrication of cartilage-on-cartilage line contacts. The material is modelled as compliant and poroelastic in which the micro-scale fibrous structure is interstitially filled with synovial fluid. This fluid flows over the interface between the bodies and is coupled to pressure generated by relative motion in the thin-film region formed under load. A Stribeck analysis demonstrated that this type of contact is determinable to conventional elastic lubrication but that the friction performance is improved by this interfacial flow. Moreover, the inclusion of periodic flow conditions when contact is onset is a specific novelty which elucidates new observations in the lubrication mechanisms pertaining to natural joints.
软骨与软骨线接触的顺应性多孔弹性润滑
摘要自然关节中的摩擦机制仍然相对未知,尽管软骨-软骨界面在理解生物摩擦方面有着巨大的前景,但对其建模的尝试很少。本文结合有限应变、多孔和薄膜流动理论推导了一个模型来描述软骨在软骨线接触上的润滑。该材料被建模为柔顺和多孔弹性材料,其中微尺度纤维结构被滑膜液间充。该流体在主体之间的界面上流动,并与在负载下形成的薄膜区域中的相对运动产生的压力耦合。Stribeck分析表明,这种类型的接触可确定为传统的弹性润滑,但这种界面流动改善了摩擦性能。此外,当接触开始时,包含周期性流动条件是一个特殊的新颖性,它阐明了与自然接头有关的润滑机制中的新观察结果。
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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来源期刊
Tribology - Materials, Surfaces & Interfaces
Tribology - Materials, Surfaces & Interfaces MATERIALS SCIENCE, COATINGS & FILMS-
CiteScore
2.80
自引率
0.00%
发文量
15
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