Finite element solution of the energy equation in lubricated contacts
Application to mechanical face seals
Keywords:
energy, temperature, convection, upwinding, lubrication, mechanical face sealAbstract
In lubricated contacts, moving solids are separated by a strongly sheared thin fluid film. The resulting temperature rise due to viscous dissipation can greatly affect the behaviour of the contact. Therefore, it is essential to determine the temperature field in such contacts. Temperature is obtained by solving the energy equation (convection diffusion equation), which is modified to take into account the particular shape of the fluid film. Upwind schemes for the finite element method are presented for both the one- and twodimensional steady configurations. They are then applied to simple lubrication problems and their results are compared. In some cases numerical oscillations occur. Modifications of the initial schemes are proposed to avoid those numerical problems. The influence of the boundary conditions and the effect of the orientation of the flow are analysed in more detail. Finally, the resolution of the three dimensional energy equation in a mechanical face seal is presented. There is a good correlation between the numerical results and the experimental data and this confirms the accuracy of the upwind scheme.
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References
Bou-Saïd B., Colin F., “Laplace transform to figth the effect of Peclet number in thermal
problems”, International Tribology Conference, JST, Nagasaki, Paper 3P11-7, 2000.
Brooks A., Hughes T.J.R., “Streamline upwind/Petrov Galerkin methods for advection
dominated flows”, Proc. of the 3rd International Conference on FEM in Fluid Flows,
Blanff, Canada, 1980, Vol. 2, pp. 283-292.
Brunetière N., Tournerie B., Frêne J., “TEHD lubrication of mechanical face seals in stable
tracking mode – Part 1 – Numerical model and experiments”, ASME Journal of
Tribology, Vol. 125, No. 3, 2003, pp. 608-616.
Christie I., Griffiths D.F., Mitchell A.R., Zienkiewicz O.C., “Finite element methods for
second order differential equations with significant first derivatives”, International
Journal of Numerical Methods in Engineering, Vol. 10, 1976, pp. 1389-1396.
Davis T.A., Duff I.S., An unsymmetric-patern multifrontal method for sparse LU
factorization, TR94-038, http://www.cise.ufl.edu, 1994.
Davis T.A., Duff I.S., A combined unifrontal/multifrontal method for unsymmetric sparse
matrices, TR97-016, http://www.cise.ufl.edu, 1997.
Donea J., “Generalized Galerkin methods for convection dominated transport phenomena”,
ASME Applied Mechanical Review, Vol. 44, No. 5, 1991.
Faria M.T.C, San Andrès L., “On the numerical modelling of high-speed hydrodynamic gas
bearings”, ASME Journal of tribology, Vol. 122, No. 1, 2000, pp. 124-130.
Frêne J., Nicolas D., Degueurce B., Berthe D., Godet M., Lubrification hydrodynamique –
paliers et butées, Collection de la direction des Etudes et Recherche d’EDF, Eyrolles,
Griffiths D.F., Mitchell A.R., “On generating upwind finite element methods”, Finite Element
Methods for Convection Dominated Flows, ed. T.J.R. Hughes, AMD 34, ASME, New
York, 1979, pp. 91-104.
Heinrich J.C., Huyakorn P.S., Zienkiewicz O.C., Mitchell A.R., “An upwind finite element
scheme for two dimensional convective transport equation”, International Journal of
Numerical Methods in Engineering, Vol. 11, pp. 131-143, 1977.
Huebner K.H., “Analysis of fluid film lubrication – A survey”, Finite elements in fluids, John
Wiley and Sons, Vol. 2, 1975, pp. 225-254.
Hughes T.J.R., “A simple scheme for developing upwind finite elements”, International
Journal of Numerical Methods in Engineering, Vol. 12, 1978, pp. 1359-1365.
Hughes T.J.R., Brooks A., “A multidimensional upwind scheme with no crosswind
diffusion”, Finite Element Methods for Convection Dominated Flows, ed. T.J.R. Hughes,
AMD, 34, ASME, New York, 1979, pp. 19-35.
Kelly D.W., Nakasawa S., Zienkiewicz O.C., Heinrich J.C.. “A note on upwinding and
anisotropic balancing dissipation in finite element approximations to convective diffusion
problems”, International Journal of Numerical Methods in Engineering, Vol. 15,
pp. 1705-1711, 1980.
Kim J., Palazzolo A.B., Gadangi R.K., “TEHD analysis for tilting-pad journal bearings using
upwind finite element method”, Tribology Transactions, Vol. 37, No. 4, 1994, pp. 771-
Kucinschi R.B., Fillon M., Frêne J., Pascovici M.D., “A transient thermoelastohydrodynamic
study of steadily loaded plain journal bearings using Finite Element Method analysis”,
ASME Journal of Tribology, Vol. 122, No. 1, 2000, pp. 219-226.
Lebeck A.O., Principles and design of mechanical face seals, Wiley-Interscience Publication,
Myers G.E., Analytical methods in conduction heat transfer, Mc Graw & Hill, 1971.
Zienkiewicz O.C., Taylor R.L., The finite element method, Vol. 3, Fluid dynamics, Fifth
edition, Butterworth Heineman, 2000.