Hostname: page-component-78c5997874-m6dg7 Total loading time: 0 Render date: 2024-11-06T05:16:22.119Z Has data issue: false hasContentIssue false
  • English
  • Français

Three-dimensional transition of natural-convection flows

Published online by Cambridge University Press:  26 April 2006

R. A. W. M. Henkes  and
P. Le QUéré
R. A. W. M. Henkes
Affiliation:
Delft University of Technology, J. M. Burgers Centre for Fluid Mechanics, Faculty of Aerospace Engineering, PO Box 5058, 2600 GB Delft, The Netherlands
P. Le QUéré
Affiliation:
LIMSI/CNRS, PO Box 133, F-91403 Orsay Cédex, France
Get access Rights & Permissions [Opens in a new window]

Abstract

The stability with respect to two- and three-dimensional perturbations of natural-convection flow of air in a square enclosure with differentially heated vertical walls and periodic boundary conditions in the lateral direction has been investigated. The horizontal walls are either conducting or adiabatic. The solution is numerically approximated by Chebyshev–Fourier expansions. In contrast to the assumption made in earlier studies, three-dimensional perturbations turn out to be less stable than two-dimensional perturbations, giving a lower critical Rayleigh number in the three-dimensional case for the onset of transition to turbulence. Both the line-symmetric and line-skew-symmetric three-dimensional perturbations are found to be unstable. The most unstable wavelengths in the lateral direction typically are of the same size as the enclosure. In the nonlinear solution new symmetry breaking occurs, giving either a steady or an oscillating final state. The three-dimensional structures in the nonlinear saturated solution consist of counter-rotating longitudinal convection rolls along the horizontal walls. The energy balance shows that the three-dimensional instabilities have a combined thermal and hydrodynamic nature. Besides the stability calculations, two- and three-dimensional direct numerical simulations of the weakly turbulent flow were performed for the square conducting enclosure at the Rayleigh number 108. In the two-dimensional case, the time-dependent temperature shows different dominant frequencies in the horizontal boundary layers, vertical boundary layers and core region, respectively. In the three-dimensional case almost the same frequencies are found, except for the horizontal boundary layers. The strong three-dimensional mixing leaves no, or only very weak, three-dimensional structures in the time-averaged nonlinear solution. Three-dimensional effects increase the maximum of the time- and depth-averaged wall-heat transfer by 15%.

Type
Research Article
Information
Journal of Fluid Mechanics , Volume 319 , 25 July 1996 , pp. 281 - 303
Copyright
© 1996 Cambridge University Press

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

Armfield, S. 1992 Conduction blocking effects in stratified intrusion jets. Proc. 11th Australasian Fluid Mech. Conf., pp. 335339.
Briggs, D. G. & Jones, D. N. 1985 Two-dimensional periodic natural convection in a rectangular enclosure of aspect ratio one. Trans. ASME J. Heat Transfer 107, 850854.Google Scholar
Hiller, W. J., Koch, S., Kowalewski, T. A., Vahl Davis, G. De & Behnia, M. 1989 Experimental and numerical investigation of natural convection in a cube with two heated side walls. In Topological Fluid Mechanics (ed. H. K. Moffatt & A. Tsinober), pp. 717726. Cambridge University Press.
Janssen, R. J. A. 1994 Instabilities in natural-convection flows in cavities. PhD thesis, Delft University of Technology, The Netherlands.
Janssen, R. J. A. & Henkes, R. A. W. M. 1995a The first instability mechanism in differentially heated cavities with conducting horizontal walls. Trans. ASME J. Heat Transfer 117, 626633.Google Scholar
Janssen, R. J. A. & Henkes, R. A. W. M. 1995b Influence of Prandtl number on instability mechanisms and transition in a differentially heated square cavity. J. Fluid Mech. 290, 319344.Google Scholar
Janssen, R. J. A., Henkes, R. A. W. M. & Hoogendoorn, C. J. 1993 Transition to time periodicity of a natural-convection flow in a three-dimensional differentially heated cavity. Intl J. Heat Mass Transfer 36, 29272940.Google Scholar
Le Quéré, P. 1987 Etude de la transition à l'instationnarité des écoulements de convection naturelle en cavité verticale différentiellement chauffée par méthodes spectrales Chebyshev. PhD thesis, University of Poitiers.
Le Quéré, P. 1991 Accurate solutions to the square thermally driven cavity at high Rayleigh number. Computers Fluids 20, 2941.Google Scholar
Le Quéré, P. & Alziary de Roquefort, T. 1982 Sur une méthode spectrale semi-implicit pour la résolution des équations de Navier-Stokes d'un écoulement bidimensionnel visqueux incompressible. C.R. Acad. Sci. Paris 294 II, 941944.Google Scholar
Le Quéré, P. & Alziary de Roquefort, T. 1985 Computation of natural convection in two-dimensional cavities with Chebyshev polynomials. J. Comput. Phys. 57, 210228.Google Scholar
Le Quéré, P. & Alziary de Roquefort, T. 1986a Transition to unsteady natural convection of air in differentially heated vertical cavities. ASME Heat Transfer Div. Vol. 60, pp. 2939.
Le Quéré, P. & Alziary de Roquefort, T. 1986b Transition to unsteady natural convection of air in vertical differentially heated cavities: influence of thermal boundary conditions on the horizontal walls. Proc. 8th Intl Heat Transfer Conf., San Francisco, pp. 15331538.
Paolucci, S. & Chenoweth, D. R. 1989 Transition to chaos in a differentially heated vertical cavity. J. Fluid Mech. 201, 379410.Google Scholar
Ravi, M. R., Henkes, R. A. W. M. & Hoogendoorn, C. J. 1994 On the high Rayleigh number structure of steady laminar natural-convection flow in a square enclosure. J. Fluid Mech. 262, 325351.Google Scholar
Schladow, S. G., Patterson, J. C. & Street, R. L. 1989 Transient flow in a side-heated cavity at high Rayleigh number: a numerical study. J. Fluid Mech. 200, 121148.Google Scholar
Turner, J. S. 1973 Buoyancy Effects in Fluids. Cambridge University Press.
Vahl Davis, G. De & Jones, I. P. 1983 Natural convection in a square cavity: a comparison exercise. Intl J. Num. Meth. Fluids 3, 227248.Google Scholar
Winters, K. H. 1987 Hopf bifurcation in the double-glazing problem with conducting boundaries. J. Heat Transfer 109, 894898.Google Scholar