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Abstract

The objective of this paper is to develop an accurate numerical procedure for the analysis of nominally flat contacts with spiral grooves lubricated by gases. The numerical procedure, which is based on the control-volume method, enables the solutions of the non-linear Reynolds equation to be obtained without limitation in geometry and operating conditions. Satisfactory flow balance was achieved on the control volumes as well as on the whole boundary and the method was proved to be very accurate. Convergence of the method was quick for any compressibility number.

Three types of contact with spiral grooves were analysed. They were hydrodynamic bearings without interior chambers, hydrodynamic bearings with interior chambers and hybrid bearings. The effects of spiral angle, groove geometry (length, depth and width) and compressibility on performances were investigated for all possible designs.

Keywords

gas lubrication thrust bearing spiral groove numerical analysis control-volume method

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References

Wildman

Grooved plate, gas lubricated thrust bearings, with special reference to the spiral groove bearing

Trans. ASME, J. Lubric. Technol., 1964, 2–15.

Malanoski

S. B.

Pan

C. H. T.

The static and dynamic characteristics of the spiral-grooved bearing

Trans. ASME, J. Basic Engng, 1965, 547–558.

Muijderman

E. A.

Spiral Groove Bearings, 1966 (N.V. Philips’ Gloeilampenfabrieken).

James

D. D.

Potter

A. F.

Numerical analysis of the gas-lubricated spiral-groove thrust bearing-compressor

Trans. ASME, J. Lubric. Technol. October 1967, 439–444.

Reddi

M. M.

Chu

T. Y.

Finite element solution of the steady-state compressible lubrication problem

Trans. ASME, J. Lubric. Technol., July 1970, 495–503.

Bonneau

Huitric

Tournerie

Finite element analysis of grooved gas thrust bearings and grooved gas face seals

Trans. ASME, J. Tribology, 1993, 115, 348–354.

Tournerie

Huitric

Bonneau

Frene

Optimisation and performance prediction of grooved face seals for gases and liquids. In Fourteenth International Conference on

Fluid Sealing, Italy, 6-8 April 1994.

Hernandez

Boudet

Modelling of the behaviour of dynamical gas seals: Calculation with a finite element method implicitly assuring the continuity of flow

Proc. Instn Mech. Engrs, Part J. 1995, 209 (J3), 195–201.

Zhu

Xie

Xue

Calculation of a spiral groove thrust bearing of constant depth with boundary element method (BEM)

Mocaxue Xuebao/Tribology, January 1993, 13 (1), 17–24.

10.

Zhu

Xie

Xue

Calculation of a spiral groove thrust bearing of constant depth with boundary element method (BEM)

Mocaxue Xuebao/Tribology, January 1993, 13 (1), 17–24.

11.

Patankar

S. V.

Numerical Heat Transfer and Fluid Flow, 1980 (McGraw-Hill, New York).

12.

Constantinescu

V. N.

Gas Lubrication, 1969 (American Society of Mechanical Engineers, New York).

Numerical prediction of the performance of gas-lubricated spiral groove thrust bearings

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