The effect of g-jitter on vertical free convection boundary-layer flow in porous media
The subject of thermal convection in porous media has attracted considerable attention in the last three decades and is now considered to be an important field of study in the general areas of fluid mechanics and heat transfer in view of its importance in various engineering applications, such as heat transfer associated with storage of nuclear waste, exothermic reaction in packed-bed reactors, heat removal from nuclear fuel debris, heat recovery from geothermal systems and particularly in the field of large storage systems of agricultural products, to name a few applications. The authors consider how the boundary-layer flow induced by a constant temperature vertical surface embedded in a porous medium is modified by time-periodic variations in the gravitational acceleration. The amplitude of these variations is assumed to be small compared with the mean acceleration. An amplitude expansion is used to determine the detailed effect of such g-jitter, and the expansion is carried through to fourth order. It is found that the mathematical problem has no free parameters when Darcy-flow is assumed; the resulting nonsimilar boundary-layer equations are solved using the Keller-box technique. The numerical and asymptotic solutions show that the g-jitter effect is eventually confined to a thin layer embedded within the main boundary-layer, but it becomes weak at increasing distances from the leading edge.
- Research Organization:
- Univ. of Bath (GB)
- OSTI ID:
- 20030404
- Journal Information:
- International Communications in Heat and Mass Transfer, Vol. 27, Issue 3; Other Information: PBD: Apr 2000; ISSN 0735-1933
- Country of Publication:
- United States
- Language:
- English
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