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Non-local effects in the stability of flow between eccentric rotating cylinders

Published online by Cambridge University Press:  29 March 2006

R. C. Diprima
Affiliation:
Mathematics Department, Rensselaer Polytechnic Institute, Troy, New York
J. T. Stuart
Affiliation:
Mathematics Department, Imperial College, London

Abstract

In this paper the linear stability of the flow between two long eccentric rotating circular cylinders is considered. The problem, which is of interest in lubrication technology, is an extension of the classical Taylor problem for concentric cylinders. The basic flow has components in the radial and azimuthal directions and depends on both of these co-ordinates. As a consequence the linearized stability equations are partial differential equations rather than ordinary differential equations. Thus standard methods of stability theory are not immediately useful. However, there are two small parameters in the problem, namely δ, the clearance ratio, and ε, the eccentricity. By letting these parameters tend to zero in such a way that δ½ is proportional to ε, a global solution to the stability problem is obtained without recourse to the concept of ‘local instability’, or ‘parallel-flow’ approximation, so commonly used in boundary-layer stability theory. It is found that the predictions of the present theory are at variance with what is given by a ‘local’ theory. First, the Taylor-vortex amplitude is found to be largest at about 90° downstream of the region of ‘maximum local instability’. This result is given support by some experimental observations of Vohr (1968) with δ = 0·1 and ε = 0·475, which yield a corresponding angle of about 50°. Second, the critical Taylor number rises with ε, rather than initially decreasing with ε as predicted by local stability theory using the criteria of maximum local instability. The present prediction of the critical Taylor number agrees well with Vohr's experiments for ε up to about 0·5 when δ = 0·01 and for ε up to about 0·2 when δ = 0.1.

Type
Research Article
Copyright
© 1972 Cambridge University Press

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References

Baldwin, P. 1972 The linear stability of flow in a circular pipe in the presence of a strong transverse magnetic field. Quart. J. Mech. Appl. Math. 25 (3), to appear.Google Scholar
Castle, P. & Mobbs, F. S. 1968 Hydrodynamic stability of the flow between eccentric rotating cylinders: visual observations and torque measurements. Proc. Inst. Mech. Eng. 182 (3N), 4152.Google Scholar
Castle, P., Mobbs, F. R. & Markho, P. H. 1971 Visual observations and torque measurements in the Taylor-vortex regime between eccentric rotating cylinders. J. Lub. Tech., Trans. A.S.M.E. Series F Paper, no. 70-Lub-13.Google Scholar
Chandrasekhar, S. 1961 Hydrodynamic and Hydromagnetic Stability. Oxford University Press.
Cole, J. A. 1957 Experiments on the flow in rotating annular clearances. Proc. Conf. Lub. & Wear. London: Inst. Mech. Eng.
Cole, J. A. 1965 Experiments on Taylor vortices between eccentric rotating cylinders. Proc. 2nd Aust. Conf. Hydr. Fluid Mech.Google Scholar
Coney, J. E. R. & Mobbs, F. R. 1970 Hydrodynamie stability of the flow between eccentrie rotating cylinders with axial flow: visual observations. Proc. Inst. Mech. Eng. 184, 3L.Google Scholar
Davey, A. 1962 The growth of Taylor vortices in flow between rotating cylinders J. Fluid Mech. 14, 336368.Google Scholar
Davey, A., DiPrima, R. C. & Stuart, J. T. 1968 On the instability of Taylor vortices J. Fluid Mech. 31, 1752.Google Scholar
DiPrima, R. C. 1963 A note on the stability of flow in loading journal bearings A.S.L.E. Trans. 6, 249253.Google Scholar
DiPrima, R. C. & Stuart, J. T. 1972 Flow between eccentric rotating cylinders. J. Lub. Tech., Trans. A.S.M.E., Series F Paper no. 72-Lub-J.Google Scholar
Eagles, P. M. 1971 On the stability of Taylor vortices by fifth-order amplitude expansions J. Fluid Mech. 49, 529550.Google Scholar
Frěne, J. & Godet, M. 1971 Transition from laminar to Taylor-vortex flow in journal bearings Tribology, 4, 216217.Google Scholar
Görtler, H. 1940 Über eine dreidimensionale Instabilität laminarer Grenzschichten an konkaven Wänden. Nachr. Ges. Wiss. Gött Math. Phys. Kl. 126. (see also N.A.C.A. Tech. Memo. Aero. no. 1375.)Google Scholar
Kamal, M. M. 1966 Separation in the flow between eccentric rotating cylinders. J. Basic Eng., Trans. A.S.M.E. D 88, 717724.Google Scholar
Ritchie, G. S. 1968 On the stability of viscous flow between eccentric rotating cylinders J. Fluid Mech. 32, 131144.Google Scholar
Roberts, P. H. 1965 Stability of viscous flow between rotating cylinders: appendix. Proc. Roy. Soc A 283, 531546.Google Scholar
Rosenblat, S. & Herbert, D. M. 1970 Low-frequency modulation of thermal instability J. Fluid Mech. 43, 385398.Google Scholar
Stuart, J. T. 1958 On the nonlinear mechanics of hydrodynamic stability J. Fluid Mech. 4, 121.Google Scholar
Taylor, G. I. 1923 Stability of a viscous liquid contained between two rotating cylinders. Phil. Trans A 223, 289343.Google Scholar
Versteegen, P. L. & Jankowski, D. F. 1969 Experiments on the stability of viscous flow between eccentric rotating cylinders Phys. Fluids, 12, 11381143.Google Scholar
Vohr, J. A. 1967 Experimental study of super laminar flow between non-concentric rotating cylinders. N.A.S.A. Contractor Rep. no. 749.Google Scholar
Vohr, J. A. 1968 An experimental study of Taylor vortices and turbulence in flow between eccentric rotating cylinders. J. Lub. Tech., Trans. A.S.M.E. F 90, 285296.Google Scholar
Wood, W. W. 1957 The asymptotic expansions at large Reynolds numbers for steady motion between non-co-axial rotating cylinders J. Fluid Mech. 3, 159175.Google Scholar