Hostname: page-component-78c5997874-s2hrs Total loading time: 0 Render date: 2024-11-10T16:21:59.490Z Has data issue: false hasContentIssue false
  • English
  • Français

The design of hydrodynamic water-lubricated step thrustbearings using CFD method

Published online by Cambridge University Press:  30 May 2014

Xiuli Zhang ,
Zhongwei Yin ,
Dan Jiang  and
Gengyuan Gao
Get access

Abstract

Water-lubricated bearings are expected to be widely used because of convenience, green,safe and energy saving. The purpose of this study is to provide references for designinghydrodynamic water-lubricated step thrust bearings. The numerical analysis is undertakenunder the condition of different pad dimensions, step heights, step positions, water filmthicknesses and rotational speeds of thrust rings based on computational fluid dynamics(CFD). The results including pressure distribution, load carrying capacity, frictiontorque and friction coefficient are gained and compared for optimizing geometryparameters. A reference to determine water-lubricated step thrust bearing dimensions and aformula to check the minimum water film thickness are proposed.

Keywords

Step thrust bearingshydrodynamic lubricationwaterCFD
Type
Research Article
Information
Mechanics & Industry , Volume 15 , Issue 3 , 2014 , pp. 197 - 206
Copyright
© AFM, EDP Sciences 2014

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

Rahmani, R., Shirvani, A., Shirvani, H., Analytical analysis and optimisation of the Rayleigh step slider bearing, Tribol. Int. 42 (2009) 666674 CrossRefGoogle Scholar
Vakilian, M., Gandjalikhan Nassab, S.A., Kheirandish, Z., Study of inertia effect on thermohydrodynamic characteristics of Rayleigh step bearings by CFD method, Mech. Ind. 14 (2013) 275285 CrossRefGoogle Scholar
Wang, J., Yan, F., Xue, Q., Tribological behavior of PTFE sliding against steel in sea water, Wear 267 (2009) 16341641 CrossRefGoogle Scholar
R. Pai, D.J. Hargreaves, Water lubricated bearings, in Green Tribology, Springer, Berlin Heidelberg, 2012
Wang, X., Koji, K., Koshi, A., Kohji, A., The effect of laser texturing of SiC surface on the critical load for the transition of water lubrication mode from hydrodynamic to mixed, Tribol. Int. 34 (2001) 703711 CrossRefGoogle Scholar
Wang, X., Kato, K., Adachi, K., Aizawa, K., Loads carrying capacity map for the surface texture design of SiC thrust bearing sliding in water, Tribol. Int. 36 (2003) 189197 CrossRefGoogle Scholar
Cabrera, D.L., Woolley, N.H., Allanson, D.R., Tridimas, Y.D., Film pressure distribution in water-lubricated rubber journal bearings, Proc. Institution Mech. Eng., Part J: J. Eng. Tribol. 219 (2005) 125132 Google Scholar
Huang, W., Xu, Y., Zheng, Y., Wang, X., The tribological performance of Ti(C,N)-based cermet sliding against Si3N4 in water, Wear 270 (2011) 682687 CrossRefGoogle Scholar
Rayleigh, L., Notes on the theory of lubrication, Philosophical Magazine 35 (1918) 112 CrossRefGoogle Scholar
Archibald, F.R., A simple hydrodynamic thrust bearing, Trans. ASME 72 (1950) 393400 Google Scholar
Kettleborough, C.F., An electrolytic tank investigation into stepped thrust-bearings, Proceedings of the Institution of Mechanical Engineers 169 (1955) 679688 CrossRefGoogle Scholar
Kettlebrough, C.F., Johnston, R.C.R., An experimental investigation into stepped thrust-bearings, Proceedings of the Institution of Mechanical Engineers 170 (1956) 511533 Google Scholar
Rohde, S.M., Finite element optimization of finite stepped slider bearing profiles, ASLE Trans. 17 (1974) 105110 CrossRefGoogle Scholar
Dobrica, M., Fillon, M., Reynolds’ model suitability in simulating Rayleigh step bearing thermohydrodynamic problems, Tribol. Trans. 48 (2005) 522530 CrossRefGoogle Scholar
Chen, P.Y.P., Hahn, E.J., Use of computational fluid dynamics in hydrodynamic lubrication, Proceedings of the Institution of Mechanical Engineers, Part J: Journal of Engineering Tribology 212 (1998) 427436 Google Scholar
Lo, S.W., Huang, K.C., Zhou, M.C., CFD Study on oil-in-water emulsions, Tribol. Trans. 52 (2008) 6672 CrossRefGoogle Scholar
Zhang, J.X., Rodkiewicz, C.M., On the design of thrust bearings using a CFD technique, Tribol. Trans. 40 (1997) 403412 CrossRefGoogle Scholar
Brajdic-Mitidieri, P., Gosman, A.D., Ioannides, E., Spikes, H.A., CFD analysis of a low friction pocketed pad bearing, J. Tribol. 127 (2005) 803812 CrossRefGoogle Scholar
Papadopoulos, C.I., Efstathiou, E.E., Nikolakopoulos, P.G., Kaiktsis, L., Geometry optimization of textured three-dimensional micro-thrust bearings, J. Tribol. 133 (2011) 041702 CrossRefGoogle Scholar
X.L. Wu, Lubrication design handbook, Chemical Industry Press, Beijing, 2006
ANSYS, ANSYS FLUENT, version 14.0: user manual, ANSYS, Inc., Canonsburg, USA, 2011
P.J. Zwart, A.G. Gerber, T. Belamri, A two-phase flow model for predicting cavitation dynamics, in Fifth International Conference on Multiphase Flow, Yokohama, Japan, 2004
Rhim, Y., Tichy, J.A., Entry flow of lubricant into a slider bearing – analysis and experiment, Tribol. Trans. 31 (1988) 351359 CrossRefGoogle Scholar
Yu, T.H., Sadeghi, F., Groove effects on thrust washer lubrication, J. Tribol. 123 (2001) 295 CrossRefGoogle Scholar
B.J. Hamrock, S.R. Schmid, B.O. Jacobson, Fundamentals of fluid film lubrication, McGraw-Hill, New York, 2004