Abstract
In the present work, various thermal parameters of an annular fin subjected to thermal loading are inversely estimated using differential evolution (DE) method. In order to obtain the temperature field, the second order nonlinear differential equation for heat transfer with variable thermal conductivity and internal heat generation is solved using Homotopy Perturbation Method (HPM). Classical thermoelasticity approach coupled with an HPM solution for temperature field is employed for the forward solution of thermal stresses. It is interesting that the internal heat generation does not affect the radial stresses, while the temperature field and the tangential stresses are influenced by the heat generation parameters. As the tangential stresses are mainly responsible for mechanical failure due to thermal loading in an annular fin, the unknown thermal parameters are inversely estimated from a prescribed tangential stress field. The reconstructed stress fields obtained from the inverse parameters are found to be in good agreement with the actual solution.
Highlights
In todays engineering development, heat dissipation has become an important concern
The aim of this study is an inverse estimation of unknown thermal parameters for an annular fin subjected to thermal stresses
The main purpose of this study is the inverse estimation of various unknown thermal parameters for an annular fin subjected to thermal stresses
Summary
Heat dissipation has become an important concern. There are different modes to enhance heat transfer. Das extended surface is one mode of heat transfer which has wide application for industrial purposes. Fin has effective application in the case of natural convection and it is always applied towards less heat transfer coefficient. In this regard, the increase of surface area helps to decrease the convective thermal resistance. A comprehensive literature review reveals that most of the heat transfer studies neglect the influence of internal heat generation. This consideration certainly simplifies the mathematical formulation of heat transfer. Because of heat conduction, the contribution of internal heat generation cannot be ignored and it varies with temperature in a real situation. Due to large temperature variation from the base to the tip of the fin, the thermal conductivity varies with the temperature
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