The Effect of Slider Configuration on Lubricant Depletion at the Slider/Disk Contact Interface

IF 3.1 3区工程技术 Q2 ENGINEERING, MECHANICAL

Lubricants Pub Date : 2024-01-08 DOI:10.3390/lubricants12010017

Yuxin Chen, Dongdong Zhou, Zhengqiang Tang

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引用次数: 0

Abstract

With decreasing clearance between the protrusion of a slider and a disk interface, there is a higher likelihood of contact occurring during shock or vibration experienced by hard disk drives (HDDs), which may induce lubricant depletion. Based on the molecular dynamics (MD) model of perfluoropolyether lubricant with a coarse-grained beads spring approach, we compared the slider configurations’ influence on the lubricant transfer volume quantitatively. By further investigating the parameters of the cylindrical asperities, including the width and depth, as well as considering the asperity amounts of the slider, we successfully observed the lubricant depletion process during slider and disk contact. The results demonstrate that the penetration depth was reduced as the asperity amount increased, mainly owing to the increased contact area between the surfaces. The decreasing depth of the asperity and the increasing width of the asperity helped to reduce the depletion volume. In addition, the utilization of a cylindrical slider configuration can contribute to a reduction in lubricant depletion resulting from contact between the head and disk.

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滑块配置对滑块/磁盘接触界面润滑剂消耗的影响

随着滑块突起与磁盘接口之间的间隙不断减小，硬盘驱动器（HDD）在受到冲击或振动时发生接触的可能性就会增大，从而导致润滑剂耗竭。基于全氟聚醚润滑剂的分子动力学（MD）模型和粗粒珠状弹簧方法，我们定量比较了滑块配置对润滑剂转移量的影响。通过进一步研究圆柱形突起的宽度和深度等参数，并考虑滑块的突起量，我们成功地观察了滑块与圆盘接触过程中的润滑剂消耗过程。结果表明，随着表面粗糙度的增加，渗透深度减小，这主要是由于表面之间的接触面积增大所致。渐开线深度的减小和渐开线宽度的增加有助于减少损耗量。此外，采用圆柱形滑块结构也有助于减少磁头和磁盘之间接触造成的润滑油损耗。

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

Lubricants Engineering-Mechanical Engineering

CiteScore

3.60

自引率

25.70%

发文量

293

审稿时长

11 weeks

期刊介绍： This journal is dedicated to the field of Tribology and closely related disciplines. This includes the fundamentals of the following topics: -Lubrication, comprising hydrostatics, hydrodynamics, elastohydrodynamics, mixed and boundary regimes of lubrication -Friction, comprising viscous shear, Newtonian and non-Newtonian traction, boundary friction -Wear, including adhesion, abrasion, tribo-corrosion, scuffing and scoring -Cavitation and erosion -Sub-surface stressing, fatigue spalling, pitting, micro-pitting -Contact Mechanics: elasticity, elasto-plasticity, adhesion, viscoelasticity, poroelasticity, coatings and solid lubricants, layered bonded and unbonded solids -Surface Science: topography, tribo-film formation, lubricant–surface combination, surface texturing, micro-hydrodynamics, micro-elastohydrodynamics -Rheology: Newtonian, non-Newtonian fluids, dilatants, pseudo-plastics, thixotropy, shear thinning -Physical chemistry of lubricants, boundary active species, adsorption, bonding