Convective heat transfer in axisymmetric porous bodies

Rajesh Rajamani; C. Srinivas; P. Nithiarasu; K. N. Seetharamu

doi:10.1108/EUM0000000004126

Convective heat transfer in axisymmetric porous bodies

Rajesh Rajamani, C. Srinivas, P. Nithiarasu, K. N. Seetharamu

Mechanical Engineering

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Abstract

A finite element method employing Galerkin's approach is developed to analyze free convection heat transfer in axisymmetric fluid saturated porous bodies. The method is used to study the effect of aspect ratio and radius ratio on Nusselt number in the case of a proous cylindrical annulus. Two cases of isothermal and convective boundary conditions are considered. The Nusselt number is always found to increase with radius ratio and Rayleigh number. It exhibits a maximum when the aspect ratio is around unity; maximum shifts towards lesser aspect ratios as Rayleigh number increases. Results are compared with those in the literature, wherever available, and the agreement is found to be good.

Original language	English (US)
Pages (from-to)	829-837
Number of pages	9
Journal	International Journal of Numerical Methods for Heat & Fluid Flow
Volume	5
Issue number	9
DOIs	https://doi.org/10.1108/EUM0000000004126
State	Published - Sep 1 1995

Keywords

Cylindrical annulus
Heat transfer
Porous bodies

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AU - Rajamani, Rajesh

AU - Srinivas, C.

AU - Nithiarasu, P.

AU - Seetharamu, K. N.

PY - 1995/9/1

Y1 - 1995/9/1

N2 - A finite element method employing Galerkin's approach is developed to analyze free convection heat transfer in axisymmetric fluid saturated porous bodies. The method is used to study the effect of aspect ratio and radius ratio on Nusselt number in the case of a proous cylindrical annulus. Two cases of isothermal and convective boundary conditions are considered. The Nusselt number is always found to increase with radius ratio and Rayleigh number. It exhibits a maximum when the aspect ratio is around unity; maximum shifts towards lesser aspect ratios as Rayleigh number increases. Results are compared with those in the literature, wherever available, and the agreement is found to be good.

AB - A finite element method employing Galerkin's approach is developed to analyze free convection heat transfer in axisymmetric fluid saturated porous bodies. The method is used to study the effect of aspect ratio and radius ratio on Nusselt number in the case of a proous cylindrical annulus. Two cases of isothermal and convective boundary conditions are considered. The Nusselt number is always found to increase with radius ratio and Rayleigh number. It exhibits a maximum when the aspect ratio is around unity; maximum shifts towards lesser aspect ratios as Rayleigh number increases. Results are compared with those in the literature, wherever available, and the agreement is found to be good.

KW - Cylindrical annulus

KW - Heat transfer

KW - Porous bodies

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Convective heat transfer in axisymmetric porous bodies

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