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Turbulent source flow between parallel stationary and co-rotating disks

Published online by Cambridge University Press:  29 March 2006

E. Bakket ,
J. F. Kreider  and
F. Kreith
E. Bakket
Affiliation:
Department of Chemical Engineering, University of Colorado, Boulder Present address: Director of Research and Developement, Pulverizing MikroPul, Division of Slick Corp., Summit, New Jersey.
J. F. Kreider
Affiliation:
Department of Chemical Engineering, University of Colorado, Boulder
F. Kreith
Affiliation:
Department of Chemical Engineering, University of Colorado, Boulder
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Abstract

The research summarized in this paper is an experimental study of the velocity and turbulence fields in the gap between two parallel co-rotating or stationary disks with a source in the centre. Detailed hot-wire measurements over a wide range of source strengths and disk speeds are presented; the average velocity components are correlated in terms of dimensionless quantities; and the radial pressure distribution is analysed. Also, transition phenomena and conditions under which similarity in the velocity profiles can be expected are discussed.

Type
Research Article
Information
Journal of Fluid Mechanics , Volume 58 , Issue 2 , 17 April 1973 , pp. 209 - 231
Copyright
© 1973 Cambridge University Press

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References

Adams, R. & Rice, W. 1970 Experimental investigation of the flow between co-rotating disks. J. Appl. Mech. 92, 844849.Google Scholar
Bakke, E. 1969 A theoretical and experimental investigation of the flow phenomena between two co-rotating parallel disks with source flow. Ph.D. thesis, University of Colorado.
Bakke, E. & Kreith, F. 1969 Inverse transition in radial diffusers. A.8.M.E.-A.1.Ch.E. Heat Transfer Con., Minneapolis; A.S.M.E. Paper, no. 69-HT-33.Google Scholar
Berger, E., Freymuth, P. & Frobel, E. 1963 Use of feedback control in the development of a constant-temperature hot-wire anemometer. Boeing Sci.Res. Lab. Trans. no. 198.Google Scholar
Breiter, M. C. & Pohlhausen, K. 1962 Laminar flow between two parallel rotatsing disks. Aero. Res. Lab. Wright-Patterson AFB, Ohio Rep. ARL62-318.Google Scholar
Daily, J. W., Ernst, W. D. & Asbedian, V. V. 1964 Enclosed rotating disks with superimposed through flow. Hydrodyn. Lab. Rep. Dept. Civil Engng, M.I.T. no. 64.Google Scholar
Daily, J. W. & Nece, R. E. 1960 Chamber dimension effects on induced flow and frictional resistance of enclosed rotating disks. J. Basic Engng, Tram. A.S.M.E. 82, 217 & 232.Google Scholar
Dorfman, L. A. 1963 Hydrodynamic Resistance and the Heat Loss of Rotating Solids. (trans. N, Kemmer). Oliver & Boyd.
Freymuth, P. 1967 Feedback control theory for constant-temperature hot-wire anemo meters. Rev. Sci. Instrum. 38, 677681.Google Scholar
Greenspan, H. P. 1968 The Theory of Rotating Fluids. Cambridge University Press.
Hagiwara, T. 1962 Studies on the characteristics of radial-flow nozzles. Bull. A.S.M.E., 5 (20), 656683.Google Scholar
Hasinger, S. H. & Kehrt, L. G. 1963 Investigation of a shear-force pump. J. Erzgng for Power, 85, 201207.Google Scholar
Kreith, F. 1968 Convection heat transfer in rotating systems. Adv. Heat Transfer, 5, 129251.Google Scholar
Kreith, F., Doughman, E. & Kozlowski, H. 1963 Mass and heat transfer from an enclosed rotating disk with and without source flow. J. Heat Transfer, 85, 153163.Google Scholar
Light, L. & Fuller, D. C. 1954 A preliminary investigation of an air lubricated hydrostatic thrust bearing. A.S.M.E. Paper, 54-LUB-18.Google Scholar
Livesey, J. L. 1960 Inertia effects in viscous flow. Int. J. Mech. Sci. 1, 84.Google Scholar
Matsch, L. A. & Rice, W. 1968 An asymptotic solution for laminar flow of an incompressible fluid between rotating disks, J. AppZ. Mech. 90, 155159.Google Scholar
Moller, P. S. 1963 Radial flow without swirl between parallel disks. Aero. Quart. 24, 163186.Google Scholar
Osterle, J. F., Chou, Y. T & Saibel, E. A. 1957 The effects of lubricant inertia in journal bearing lubrication. J. AppZ. Mech., 24, 494496.Google Scholar
Peube, J. L. & Kreith, F. 1966 Ecoulement permanent d'un fluide visquex incompressible entre deux disques pardlhles en rotation. J. Mdcanipue, 5, 260286.Google Scholar
Rice, W. 1963 An analytical and experimental investigation of multiple disk pumps and compressors. J. Engng for Power, 85, 191200.Google Scholar
Savage, S. B. 1964 Laminar flow between parallel plates. J. Appl. Mech. 86, 594596.Google Scholar
Schlic, S., Ting, H. 1968 Boundary Lager Theory, 6th edn.: MoGraw-Hill.