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On the Closed Motion of a Fluid in a Square Cavity

Published online by Cambridge University Press:  04 July 2016

Ronald D. Mills
Ronald D. Mills*
Affiliation:
Department of Mechanical Engineering, University of Strathclyde
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Summary

This paper is concerned with two-dimensional, incompressible fluid motion generated within a square cavity (a) by an outer stream and (b) by the action of a flat surface passing over one of its sides. This type of motion (“cavity flow”) is considered to consist of a boundary layer surrounding an inviscid “core.” A solution of a linearised form of von Mises’ equation is obtained for steady flow in the boundary layer for constant pressure and that of a small periodic variation around the walls of the cavity. From this analysis the vorticity imparted to the core is obtained. The motion in the core is then determined on the basis of the persistence of this value of the vorticity. Experimental results are given for (a) and (b) and compared with the theory. A method of solution of the non-linear boundary layer problem is indicated.

Type
Research Article
Information
The Aeronautical Journal , Volume 69 , Issue 650 , February 1965 , pp. 116 - 120
Copyright
Copyright © Royal Aeronautical Society 1965

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References

1.Squire, H. B.Note on the Motion Inside a Region of Re- circulation (Cavity Flow), Journal of the Royal Aeronautical Society, 60, 203205, March 1956.Google Scholar
2.Batchelor, G. K.On Steady Laminar Flow with Closed Streamlines at Large Reynolds Numbers, j Fluid Mechs., 1(2), 177190, July 1956.Google Scholar
3.Mabey, D. G. The Formation and Decay of Vortices, M.Sc. Thesis, London University, 1955.Google Scholar
4.Roshko, A. Some Measurements of Flow in a Rectangular Cut-out, NACA TN 3488, 1955.Google Scholar
5.Mills, R. D. Flow in Rectangular Cavities, Ph.D. Thesis, London University, 1961.Google Scholar
6.Foster, D. J. Flow Past a Step Down, D.I.C. Thesis, Imperial College, 1955.Google Scholar
7.Tani, I. Experimental Investigations of Flow over a Step. Paper presented at a Symposium on Boundary Layer Re search, Freiburg, 1957.CrossRefGoogle Scholar
8.Maull, D. J. and East, L. F.Three Dimensional Flow in Cavities, J. Fluid Mechs., 16(4), 620632, 1963.Google Scholar
9.Wood, W. W.Boundary Layers whose Streamlines are Closed, J. Fluid Mechs., 2, 7787, 1957.CrossRefGoogle Scholar
10.Korst, H. H.A Theory for Base Pressures in Transonic and Supersonic Flow, J. App. Mech., 23, 593600, 1956.CrossRefGoogle Scholar
11.Chapman, D. R., Kuehn, D. M. and Larsen, H. K. Investigation of Separated Flows in Supersonic and Subsonic Streams with Emphasis on the Effect of Transition, NACA TN 3869, 1957.Google Scholar
12.Harper, J. F.On Boundary Layers in Two Dimensional Flow with Vorticity, J. Fluid Mechs., 17(1), 141153, Sept. 1963.Google Scholar
13.Wieghardt, K.Erhöhung des Turbulenten Reibungswiderstandes durch Oberflächenstörungen, Schiffstechnik, 2 Heft, Hansa Verlag, Hamburg, 1953.Google Scholar
14.Linke, W. Stromungsvorgänge in Zwangsbelufteten Raumen, 21, V.D.I. Berichte, 1957.Google Scholar
15.Baturin, W. W.Lüftungsanlagen fur Industriebauten, 2nd Edn., Veb Verlag Technik, Berlin, p. 187, 1959.Google Scholar
16.Lighthill, M. J.Contributions to the Theory of Heat Transfer Through a Laminar Boundary Layer, Proc. Roy. Soc. A, 202, 359377, 1950.Google Scholar
17.Kaplun, S.The Role of Coordinate Systems in Boundary Layer Theory, Z. angew. Math. Phys., 5, 111135, 1954.Google Scholar