Amplitude Effect on Convection Induced by Time-Periodic Horizontal Heating
B. V. Antohe and J. L. Lage
Internatinal Journal of Heat and Mass Transfer ,
Vol. 39, pp. 1121-1133, 1996
Abstract
Heat and momentum transport is investigated theoretically
and numerically considering a rectangular enclosure filled with clear
fluid or with fully saturated porous medium, under time-periodic
horizontal heating. Numerical simulations, of various configurations,
indicate that the natural convection activity within the enclosure peaks
wat several discrete frequencies, with the climax attained at a heating
frequency referred to as resonance frequency. A general theory for
predicting this resonance frequency is developed from the natural
frequency of the flow circulating inside the enclosure. The resonance
frequency can be calculated by solving a system of non linear equations,
function of the averaged Rayleigh number, the Prandtl number, the enclosure
aspect ratio, the heating amplitude, and the Darcy number for the porous
medium case. Theoretical predictions agree well with numerical results.
It is shown that the convection intensity within the enclosure increases
linearly with heating amplitude for a wide range of parameters. Moreover,
the flow response to pulsating heat is continuously enhanced as the system
becomes more permeable. Time evolution graphs, phase-plane portraits, and
streamlines highlight several distinct phases of the periodic heating process.