Abstract
In this paper, we investigate numerically the effect of thermal boundary conditions on conjugated conduction-free convection heat transfer in an annulus between two concentric cylinders using Fourier Spectral method. The inner wall of the annulus is heated and maintained at either CWT (Constant Wall Temperature) or CHF (Constant Heat Flux), while the outer wall is maintained at constant temperature. CHF case is relatively more significant for high pressure industrial applications, but it has not received much attention. This study particularly focuses the latter case (CHF). The main influencing parameters on flow and thermal fields within the annulus are: Rayleigh number Ra; thickness of inner wall Rs; radius ratio Rr and inner wall-fluid thermal conductivity ratio Kr. The study has shown that the increase in Kr increases the heat transfer rate through the annulus for heating at CWT and decreases the inner wall dimensionless temperature for heating at CHF and vice versa. It has also been proved that as the Rs increases at fixed Ra and Rr, the heat transfer rate decreases for heating at CWT and the inner wall dimensionless temperature increases for heating at CHF at Kr <1. The study has also discussed that the effect of increase in Rs for both cases of heating at Kr>1 depends on Rr. It has been shown that for certain combinations of controlling parameters there will be a value of Rr at which heat transfer rate will be minimum in the annulus in case of heating at CWT, while there will be a value of Rr at which inner wall dimensionless temperature will be maximum in case of heating at CHF.
Highlights
Buoyancy driven flow and associated heat transfer in an annular enclosure between two concentric/eccentric circular walls has long been investigated because of its pertinence to many practical engineering applications
The influencing parameters on conjugate heat transfer in the annulus are Rayleigh number Ra, Prandtl number Pr, radius ratio Rr(=ro/ri), thickness of the solid wall given by Rs(=rsf/ri) and the thermal conductivity of solid wall relative to that of fluid Kr (= ks /kf)
The available results for both heating cases are only associated with horizontal concentric annulus having zero thickness of inner wall
Summary
Buoyancy driven flow and associated heat transfer in an annular enclosure between two concentric/eccentric circular walls has long been investigated because of its pertinence to many practical engineering applications. These applications include thermal storage systems, solar collector-receivers, underground power transmission cables, cooling system in nuclear reactor and many others [1]. The case of isothermal heating (CWT) approximates the cooling of microelectronic equipment while dissipation of heat generated within an underground power transmission cables from its surface to the surrounding enclosure is a practical example of heating at CHF [2]
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