Micro Textures in Concentrated-Conformal-Contact Lubrication: Effect of Distribution Patterns

Ren, Nanqi; Nanbu, Toshikazu; Yasuda, Yoshiteru; Zhu, Dong; Wang, Qian

doi:10.1007/s11249-007-9271-4

Cited by 78 publications

(55 citation statements)

References 24 publications

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“…The primary parameters of the lubricated sliding contact are given as follows: sliding velocity U is 1 m/s (the corresponding Reynolds number R e is 1 [23,25,29,31,33], and the critical shear stresses range from 0 to 1,000 Pa, reasonable values based on literature [34][35][36][37][38]. All parameters and the range in which they are varied for all cases investigated in the present study are summarized in Table 1.…”

Section: Resultsmentioning

confidence: 99%

“…The range of Reynolds numbers tested is from 0.001 to 20. In the following simulations, the critical shear stresses range from 0-1,000 Pa, reasonable values based on literature [17][18][41][42][43] are used, and the slip coefficient α varies from 0 to 0.1 m 2 s/kg (the corresponding slip length is 1x10 -4 m) based on the results published in literature [25,28,31,37]. All parameters and the range in which they are varied for all cases investigated in the present study are summarized in Table 1.…”

Section: Resultsmentioning

confidence: 99%

“…As noted, most of the results from the literature review show that there is a little effect of the texture shape on the tribological performances of the LST (laser surface textured) surfaces. In addition, based on recent publications [37,38], in relation to the orientation effect of the texture on sliding surfaces, it was stated that for noncircular texture shapes, which are similar to what is used in this study, the strongest hydrodynamic load support is offered when its main axis is perpendicular to the sliding direction.…”

mentioning

confidence: 75%

“…During the past decade, with the development of advanced experimental techniques, numerous experiments have shown that boundary slip can occur at both a hydrophobic surface [14,18,[35][36][37][38] and a hydrophilic surface [15,16,38,39]. For most hydrophilic surfaces, however, no slip occurs.…”

Section: Slip Modelsmentioning

confidence: 99%

“…Bayada and Meurisse [36], using a relatively simple simulation, demonstrated that the pressure distribution induced by deterministic roughness is smaller than that induced by the artificial slip. Rao [37] employed an artificial slip on a stationary surface having a single-groove at a slider and a journal bearing and derived the pressure, the shear stress, stiffness and damping coefficients. The modified Reynolds equation based on the slip length model was solved.…”

Section: Introductionmentioning

confidence: 99%

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Lubricated MEMS: effect of boundary slippage and texturing

Tauviqirrahman¹

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SummaryMany types of micro-electro-mechanical-system (MEMS) based products are currently employed in a variety of applications. Recently, there has been an increase in the demand for higher reliability of MEMS which incorporate moving parts for each intended application. This is because the reliability of MEMS containing moving parts is poor and has a limited lifetime. Applying a lubricant to these systems to avoid wear hampers the movement due to the adhesive/surface forces, leading to stiction. By modifying the contacting surfaces, one is able to enhance the behavior of surfaces in a controlled way and thus alter the flow pattern in the liquid lubricating film for an enhanced performance. In this thesis, the concept of complex slip surface (CSS) as an artificial (deterministic) boundary slip surface is introduced. The thesis examines the exploitation of the artificial boundary slip to improve the performance of liquid lubricated-MEMS, with the emphasis on increasing the load support and reducing the coefficient of friction. Therefore, it is of great importance to get a clear view of the concept of the artificial boundary slip with respect to the performance of lubricated-MEMS.A main principle of fluid film lubrication, as well as a touchstone of the Reynolds equation, is that there is no boundary slip of the liquid lubricant along the two solid surfaces. As a result, lubrication with boundary slip cannot be analyzed by the classical Reynolds equation, which specifically excludes the possibility of slip. The aim of the present work is to build a modified form of the Reynolds equation in which boundary slip is allowed to occur on both of the opposing surfaces. Two different models of boundary slip are discussed, namely: the two-component slip model and the critical shear stress model. The first model assumes that boundary slip will occur when the shear stress at the surface reaches a critical value, and, once the slip begins, that it takes place at a constant slip length. This model is adopted to incorporate some possible slip directions, as well as slip velocities directly.The second model, the critical shear stress model, is based on the assumption that there is a critical shear stress on the liquid-solid interface. No slip occurs at the interface if the surface shear stress is less than the critical shear stress, but the slip takes place if the shear stress reaches the point of critical shear stress. The modified Reynolds equation with the critical shear stress model that was developed in the current work is based on the assumption that a slip is treated to occur both at the stationary and the moving surface. The model is converted to a finite volume form and solved by tri-diagonal-matrix-algorithm (TDMA) combined with alternating-direction-implicit (ADI) scheme. In this way, the model is able to incorporate the influence of boundary slip on the lubrication performance of MEMS, while keeping the computational time within a reasonable range. The model is validated through experimental work published in the lit...

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Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

mentioning

confidence: 75%

Section: Slip Modelsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Lubricated MEMS: effect of boundary slippage and texturing

Tauviqirrahman¹

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Friction Reduction Induced by Elliptical Surface Patterns under Lubricated Conditions

et al. 2017

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Recording Stribeck-like curves is an efficient way to evaluate the frictional performance and efficiency of patterned surfaces. Elliptical patterns with varying area density and structural depth are fabricated by micro-coining on steel substrates (AISI 304). A ball-on-disc tribometer is used to perform unidirectional sliding experiments for the polished reference and the elliptical patterns dependent on the sliding velocity. In this study, a clear connection between structural parameters such as length of long and short axis, aspect ratio, and pitch with the frictional behavior can be found. Comparing patterns with comparable depth and area density underlines that elliptical patterns having larger individual features (increased length of both axes) separated by a larger pitch reduce the COF more significantly. The number of tribologically active individual elliptical structures, recirculation effects of the lubricant, as well as the pattern geometry that may lead to undesired edge effects and stress concentrations need to be taken into consideration to explain those findings. The sample with the smallest structural depth, the smallest area density, and the lowest aspect ratio (A1) leads to the maximum friction reduction (4-fold) for all velocities which underlines the enormous potential of elliptical structures in terms of friction reduction.

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Dimple patterns design for different circumstances

Wang

2011

Lubrication Science

115

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The appealing and enigmatic properties of biological surfaces inspire people that a smooth surface is not always the best. Currently, the patterns of microdimples have attracted more attentions since such closed texture cells are supposed to generate hydrodynamic pressure easily. The advanced manufacturing techniques provide precision and freedom for the fabrication of microdimples, which enables the optimisation of dimple geometry and distribution to obtain better tribological performances. Over the past decade, experiments were carried out to investigate the effects of microdimples on various materials under different operating conditions. Analytical models were established to evaluate the hydrodynamic effect of the dimple patterns. The results suggest that the design of dimple pattern following hydrodynamic principle would obtain good tribological performance under high‐speed low‐load conditions; however, for the case of low‐speed high‐load conditions, shallow and small dimples would have more obvious friction reduction effect than those designed based on hydrodynamic pressure generation. Copyright © 2011 John Wiley & Sons, Ltd.

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Micro Textures in Concentrated-Conformal-Contact Lubrication: Effect of Distribution Patterns

Cited by 78 publications

References 24 publications

Lubricated MEMS: effect of boundary slippage and texturing

Lubricated MEMS: effect of boundary slippage and texturing

Friction Reduction Induced by Elliptical Surface Patterns under Lubricated Conditions

Dimple patterns design for different circumstances

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