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Thermohydrodynamic behaviors of finite journal bearings withcavitation

Published online by Cambridge University Press:  16 March 2011

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Abstract

This paper presents thermohydrodynamic solutions for a finite-width journal bearing withsingle axial groove on the crown by considering turbulent effects in lubricant film.Appropriate governing equations and boundary conditions are used for the fluid flow andheat transfer process occurring in finite full journal bearings. A general computerprogram is developed to numerically solve the set of governing equations. Results areprovided for THD characteristics of journal bearing in terms of Reynolds number, clearanceratio and eccentricity ratio. Good agreement with published experimental results wasachieved. The results indicate that the bearing temperature field and pressure field areconsiderably influenced by the journal bearing parameters.

Type
Research Article
Copyright
© AFM, EDP Sciences 2011

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References

Milne, A.A., On the effect of lubricant inertia in the theory of hydrodynamic lubrication, ASME J. Basic Eng. 81 (1959) 239 Google Scholar
Fritz, R.J., The effect of an annular fluid on the vibration of a long rotor; Part I, Theory, ASME J. Basic Eng. (1970) 923929 CrossRefGoogle Scholar
A.J. Smalley, J.H. Vohr, V. Castelli, C. Wachmann, An analytical and experimental investigation of turbulent flow in bearing films involving convective fluid inertia forces, ASME Paper 73-LubS-l (1973)
Saibel, E.S., Macken, N.A., Nonlaminar behavior in bearings: a critical review of the literature, J. Lubr. Technol. 96 (1974) 174181 CrossRefGoogle Scholar
Taylor, C.M., Dowson, D., Turbulent lubrication theory- application to design, J. Lubr. Technol. 96 (1974) 3647 CrossRefGoogle Scholar
Constantinescu, V.N., On turbulent lubrication, Proc. Inst. Mech. Eng., London 173 (1959) 881900 CrossRefGoogle Scholar
Ng, C.W., Pan, C.H.T., A linearized turbulent lubrication theory, ASME J. Basic Eng. 87 (1965) 675688 CrossRefGoogle Scholar
Ho, M.K., Vohr, J.H., Application of energy model of turbulence to calculation of lubricant flows, J. Lubr. Technol. 96 (1974) 95102 CrossRefGoogle Scholar
Hirs, G.G., A bulk-flow theory for turbulence in lubricant films, ASME J. Lubr. Technol. 95 (1973) 137146 CrossRefGoogle Scholar
J.W. Lund, E.B. Arwas, A simultaneous solution of the lubrication and the energy equations for turbulent journal bearing films. MT1 Rep. No. 64-TR-31, Mech. Tech. Inc. (1964)
Constantinescu, V.N., Basic relations in turbulent lubrication and their extension to include thermal effects, J. Lubr. Technol. 95 (1973) 147154 CrossRefGoogle Scholar
Safar, Z., Szeri, A.Z., Thermohydrodynamic lubrication in laminar and turbulent regimes, Trans. ASME, J. Lubr. Technol. 96 (1974) 4857 CrossRefGoogle Scholar
Safar, Z., Inertia and thermal effects in turbulent flow journal bearing, Wear 53 (1979) 325335 CrossRefGoogle Scholar
Hashimoto, H., Wada, S., Theoretical approach to turbulent lubrication problems including surface roughness effects, Trans, ASME, J. Lubr. Technol. 111 (1989) 1722 Google Scholar
Venkaeswarlu, K., Rao, N.J., Venugopal, E.V., Akella, S., Three-dimensional laminar and turbulent lubrication in journal bearings, Wear 126 (1990) 263279 CrossRefGoogle Scholar
Tieu, A.K., Kosasih, P.B., An expression of Reynolds stress in turbulent lubrication theory. Trans. ASME, J. Lubr. Technol. 114 (1992) 5760 Google Scholar
Granville, P.S. A modified Van Driest formula for the mixing length of turbulent boundary layers in pressure gradients, ASME, J. Fluids Eng. 111 (1989) 9497 CrossRefGoogle Scholar
Lee, D.W., Kim, K.W., Turbulent lubrication theory using Algebraic Reynolds Stress model in finite journal bearings with cavitation boundary conditions, JSME, Int. J., Series II 33 (1990) 200207 Google Scholar
Chun, S.M., Ha, D.H., Thermohydrodynamic lubrication analysis of high-speed journal bearing considering variable density and variable specific heat, Trib. Int. 37 (2004) 405413 CrossRefGoogle Scholar
Peng, Z.C., Khonsari, M.M., A thermohydrodynamic analysis of foil journal bearings, Trans. ASME, J. Trib. 128 (2006) 534541 CrossRefGoogle Scholar
Abe, K., Kondoh, T., Nagano, Y., A new turbulence model for predicting fluid flow and heat transfer in separating and reattaching flows-1. Flow field calculation, Int. J. Heat Mass Transf. 37 (1994) 139151 CrossRefGoogle Scholar
Mistry, K., S. Biswas Study of thermal profile and cavitation in a circular journal bearing, Wear 159 (1992) 7987 CrossRefGoogle Scholar
Heshmat, H., Pinkus, O., Mixing inlet temperatures in hydrodynamic bearings, ASME J. Trib. 108 (1986) 221248 CrossRefGoogle Scholar
Khonsari, M.M., Jang, J.Y., M, Fillon On the generalization of thermohydrodynamic analyses for journal bearings, Trans. ASME, J. Trib. 118 (1996) 571580 CrossRefGoogle Scholar
Heshmat, H., The mechanism of cavitation in hydrodynamic lubrication, Trib. Trans. 34 (1991) 177186 CrossRefGoogle Scholar
Wada, S., Hashimoto, H., Turbulent lubrication theory using the frictional law, Bull. JSME 22 (1979) 257263 CrossRefGoogle Scholar