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Compressible Radial Flow Between Parallel Discs*

Published online by Cambridge University Press:  07 June 2016

P. S. Moller
P. S. Moller*
Affiliation:
University of California, Davis, U.S.A.
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Summary

A combined experimental and theoretical study has been made of radial compressible flow without swirl between parallel discs when the fluid velocity is everywhere subsonic. It constitutes an extension of a previous analysis, wherein the flow was considered to be incompressible.

A similarity solution for the radial pressure distribution is shown to be possible only in special cases where certain terms in the equations of motion can be neglected. Approximate solutions are obtained for the laminar and the turbulent radial pressure distributions, using an integral momentum method. Both theories agree well with experiment. The critical Reynolds number for reverse transition is found to be approximately the same as that for incompressible flow in radial channels and circular pipes. The radial pressure level for compressible radial flow between parallel discs is found to be less than that for incompressible flow at the same mass-flow rate. The non-linear form, in pressure, of the compressible solution can be shown to account for this result.

Type
Research Article
Information
Aeronautical Quarterly , Volume 15 , Issue 3 , August 1964 , pp. 219 - 238
Copyright
Copyright © Royal Aeronautical Society 1964 

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Footnotes

*

This paper is abstracted from the author' Ph.D. thesis presented to McGill University, Canada, in 1963.

References

1. Moller, P. S. Radial Flow Without Swirl Between Parallel Discs. Aeronautical Quarterly, Vol. XIV, p. 163, May 1963.Google Scholar
2. Gottwald, F. Investigations on Bearing Devices with Small Friction. Foreign Document Evaluation Branch, Ordinance Research and Development Centre, Aberdeen Proving Ground, Maryland, Report No. 15, April 1946.Google Scholar
3. Weber, R. R. The Analysis and Design of Hydrodynamic Gas Bearings. North American Aviation Incorporated, Aerophysics Laboratory Report AL-699, 1949.Google Scholar
4. Licht, L. and Fuller, D. D. A Preliminary Investigation of an Air-Lubricated Hydro- static Thrust Bearing. American Society of Mechanical Engineers, Paper No. 54-LUB-18, 1954.Google Scholar
5. Deuker, E. A. and Wojtech, H. Ecoulement Radial d'un Fluide Visqueux Entre Deux Disques Très Rapproches; Théorie du Palies à Air. Revue Generate de L'Hydraulique, Vol. 17, p 227234, 285-294, 1953.Google Scholar
6. Gross, W. A. Gas Film Lubrication, p. 268. John Wiley, New York, 1962.Google Scholar
7. Sibulkin, M. Transition from Turbulent to Laminar Pipe Flow. The Physics of Fluids, Vol. 5, No. 3, March 1962.Google Scholar
8. Sternberg, J. The Transition from Turbulent to Laminar Pipe Flow. Ballistic Research Laboratories, Aberdeen Proving Ground, Maryland, Report 906, 1954.Google Scholar
9. Woolard, H. W. A Study of the Flow in a Narrowly-Spaced Radial Diffuser. M.Sc. Thesis, Graduate School of the University of Buffalo, New York, 1954.Google Scholar
10. Welantz, L. F. A Suction Device Using Air Under Pressure. Journal of Applied Mechanics. Transactions of the American Society of Mechanical Engineers, Vol. 78, p. 269, June 1956.Google Scholar
11. Grinnell, S. K. Flow of a Compressible Fluid in a Thin Passage. Transactions of the American Society of Mechanical Engineers, Vol. 78, p. 765, 1956.Google Scholar
12. Comolet, R. Ecoulement d'un Fluide Entre Deux Plans Paralleles, Contribution a l'Etude des Butees d'Air. Publications Scientiflques et Techniques du Ministère de l'Air, No. 334, 1957.Google Scholar
13. Lin, C. C. Turbulent Flows and Heat Transfer, p. 89. Princeton University Press, 1959.Google Scholar
14. Keenan, J. H. and Neumann, E. P. Measurements of Friction in a Pipe for Subsonic and Supersonic Flow of Air. Journal of Applied Mechanics, Paper No. A-91, June 1946.Google Scholar
15. Nikuradse, J. Turbulente Strömung in nicht kreisformigen Rohren. Ingenieur-Archiv, Vol. 1, p. 306, 1930.Google Scholar
16. Schiller, L. Über den Strömungswiderstand von Rohren verschiedenen Querschnitts und rauhig Keitsgrades. Zeitschift für angewandte Mathematik und Mechanik, Vol. 3, p. 2, 1923.Google Scholar
17. Vroomen, L. J. The Pressure Transducer Rack. Memo. 62-6, McGill University, 1962.Google Scholar