Abstract

The free convection heat transfer of hybrid nanofluids in a cavity space composed of a clear flow, porous medium and a solid part is addressed. The cavity is heated from the bottom and cooled from the top. The side walls are well insulated. The upper part of the cavity is a clear space with no porous or solid materials and is filled with hybrid nanofluid. The bottom part is divided into two parts of a porous space saturated with the hybrid nanofluid and a solid thermal conductive block. There are conjugate heat transfer mechanisms between the solid block and the porous medium filled with the hybrid nanofluid as well as the hybrid nanofluid in the clear space. For the porous medium model, the local thermal non-equilibrium effects are considered. The hybrid nanofluids contain copper (20 nm) and alumina nanoparticles (40 nm) hybrid nanoparticles. The governing equations for the flow and heat transfer of the hybrid nanofluid in the clear space and the porous medium are introduced. Considering the conjugate heat transfer between the solid block and the hybrid nanofluid fluid in the pores and the porous matrix, appropriate boundary conditions for heat channeling are utilized. The governing equations are transformed into non-dimensional form to generalize the model. The finite element method is employed to solve the equations. The grid check and validation procedure are performed. Subsequently streamlines, isotherms, and Nusselt number are studied as important aspects of flow and heat transfer in the cavity. The increase in the portion of the clear flow part in the cavity enhances heat transfer due to better hybrid nanofluid circulation.

Highlights

  • Heat transfer from a cavity has been investigated in many engineering sciences due to its various applications

  • The conductivity (k) of Cu is much higher than that of Al2 O3, and adding Cu can help to overcome the drawbacks of Al2 O3 and water and obtain a hybrid nanofluid with higher conductivity

  • The cavity was in a square form such its bottom and top walls were assumed to be insulated in hot and cold temperatures, respectively

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Summary

Introduction

Heat transfer from a cavity has been investigated in many engineering sciences due to its various applications. Some of these applications include building insulation, electrical appliances, cooling and designing heat exchangers and HVAC. Vahl Davis [2], Turan et al [3], Deng and Tang [4], and Sathiyamoorthy and Chamkha [5] have examined the natural convection heat transfer in a closed square cavity. They found that heat transfer is under the strong influence of the Rayleigh number.

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