Hostname: page-component-77c89778f8-swr86 Total loading time: 0 Render date: 2024-07-22T10:07:09.093Z Has data issue: false hasContentIssue false
  • English
  • Français

Steady and transient thermal convection in a fluid layer with uniform volumetric energy sources

Published online by Cambridge University Press:  12 April 2006

F. A. Kulacki  and
A. A. Emara
F. A. Kulacki
Affiliation:
Department of Mechanical Engineering, The Ohio State University, Columbus
A. A. Emara
Affiliation:
Department of Mechanical Engineering, The Ohio State University, Columbus
Get access Rights & Permissions [Opens in a new window]

Abstract

Measurements of the overall heat flux in steady convection have been made in a horizontal layer of dilute aqueous electrolyte. The layer is bounded below by a rigid zero-heat-flux surface and above by a rigid isothermal surface. Joule heating by an alternating current passing horizontally through the layer provides a uniformly distributed volumetric energy source. The Nusselt number at the upper surface is found to be proportional to Ra0[sdot ]227 in the range 1[sdot ]4 ≤ Ra/Rac ≤ 1[sdot ]6 × 109, which covers the laminar, transitional and turbulent flow regimes. Eight discrete transitions in the heat flux are found in this Rayleigh number range. Extrapolation of the heat-transfer correlation to the conduction value of the Nusselt number yields a critical Rayleigh number which is within -6[sdot ]7% of the value given by linearized stability theory. Measurements have been made of the time scales of developing convection after a sudden start of volumetric heating and of decaying convection when volumetric heating is suddenly stopped. In both cases, the steady-state temperature difference across the layer appears to be the controlling physical parameter, with both processes exhibiting the same time scale for a given steady-state temperature difference, or [mid ]ΔRa[mid ]. For step changes in Ra such that [mid ]ΔRa[mid ] > 100Rac, the time scales for both processes can be represented by Fo [vprop ] [mid ]ΔRa[mid ]m, where Fo is the Fourier number of the layer. Temperature profiles of developing convection exhibit a temperature excess in the upper 15–20 % of the layer in the early stages of flow development for Rayleigh numbers corresponding to turbulent convection. This excess disappears when the average core temperature becomes large enough to permit eddy transport and mixing processes near the upper surface. The steady-state limits in the transient experiments yield heat-transfer data in agreement with the results of the steady-state experiments.

Type
Research Article
Information
Journal of Fluid Mechanics , Volume 83 , Issue 2 , 22 November 1977 , pp. 375 - 395
Copyright
© 1977 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

Carbenier, W. A., Cybulskis, P., Denning, R. S., Genco, J. M., Miller, N. E., Ritzman, R. L., Simon, R. & Wooton, R. O. 1975 Physical processes in reactor meltdown accidents. Appendix VIII to Reactor Safety Study. U.S. Nucl. Regulatory Comm. Rep.WASH-1400 (NUREG-75/014).
Chu, T. Y. & Goldstein, R. J. 1973 Turbulent convection in a horizontal layer of water. J. Fluid Mech. 60, 141.Google Scholar
Fiedler, H. & Wille, R. 1971 Wärmetransport bie frier Konvektion in einer horizontalen Flussigkeitsschicht mit Volumenheizung, Teil 1: Integraler Wärmetransport. Rep. Dtsch Forschungs- Varsuchsanstalt Luft-Raumfahrt, Inst. Turbulenzfenschung, Berlin.
Knopoff, L. 1967 In The Earth's Mantle (ed. T. F. Gaskell), chap. 8. Academic Press.
Kulacki, F. A. & Emara, A. A. 1975 High Rayleigh number convection in enclosed fluid layers with internal heat sources. U.S. Nucl. Regulatory Comm. Rep. NUREG-75/065.Google Scholar
Kulacki, F. A. & Emara, A. A. 1976 Transient natural convection in an internally heated fluid layer. U.S. Nucl. Regulatory Comm. Rep. NUREG-0078.Google Scholar
Kulacki, F. A. & Goldstein, R. J. 1972 Thermal convection in a horizontal fluid layer with uniform volumetric energy sources. J. Fluid Mech. 55, 271.Google Scholar
Kulacki, F. A. & Goldstein, R. J. 1974 Eddy heat transport in thermal convection with volumetric energy sources. Proc. 5th Int. Heat Transfer Conf., Tokyo, vol. 3, pp. 6468.
Kulacki, F. A. & Goldstein, R. J. 1975 Hydrodynamic instability in fluid layers with uniform volumetric energy sources. Appl. Sci. Res. 31, 81.Google Scholar
Kulacki, F. A. & Nagle, M. E. 1975 Natural convection in a horizontal fluid layer with volumetric energy sources. J. Heat Transfer 91, 204.Google Scholar
Mckenzie, D. P., Roberts, J. M. & Weiss, N. O. 1974 Convection in the earth's mantle: towards a numerical simulation. J. Fluid Mech. 62, 465.Google Scholar
Richter, F. M. 1973 Dynamical models for sea floor spreading. Rev. Geophys. Space Phys. 11, 223.Google Scholar
Roberts, P. H. 1966 On non-linear Bénard convection, In Non-Equilibrium Thermodynamics, Variational Techniques, and Stability (ed. R. J. Donnelly, R. Herman & I. Prigogine), pp. 125162. University of Chicago Press.
Roberts, P. H. 1967 Convection in horizontal layers with internal heat generation. Theory. J. Fluid Mech. 30, 33.Google Scholar
Runcorn, S. K. 1962 Convection in the earth's mantle. Nature 195, 1245.Google Scholar
Schwiderski, E. W. & Schwab, H. J. A. 1971 Convection experiments with electrolytically heated fluid layers. J. Fluid Mech. 48, 703.Google Scholar
Stuart, J. T. 1958 On the nonlinear mechanics of hydrodynamic stability. J. Fluid Mech. 4, 1.Google Scholar
Thirlby, R. 1970 Convection in an internally heated fluid layer. J. Fluid Mech. 44, 673.Google Scholar
Tritton, D. J. & Zarraga, M. N. 1967 Convection in horizontal layers with heat generation. Experiments. J. Fluid Mech. 30, 21.Google Scholar
Turcotte, D. L. & Oxburgh, E. R. 1972 Mantle convection and the new global tectonics. Ann. Rev. Fluid Mech. 4, 33.Google Scholar