Entropy Generation and MHD Convection within an Inclined Trapezoidal Heated by Triangular Fin and Filled by a Variable Porous Media

Ahmad Almuhtady,Wael Al-Kouz,Sameh E Ahmed,Muflih Alhazmi,Zehba A S Raizah

doi:10.3390/app11041951

Ahmad Almuhtady, Wael Al-Kouz + Show 3 more

Open Access

https://doi.org/10.3390/app11041951

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Abstract

Analyses of the entropy of a thermal system that consists of an inclined trapezoidal geometry heated by a triangular fin are performed. The domain is filled by variable porosity and permeability porous materials and the working mixture is Al2O3-Cu hybrid nanofluids. The porosity is varied exponentially with the smallest distance to the nearest wall and the permeability is depending on the particle diameter. Because of using the two energy equations model (LTNEM), sources of the entropy are entropy due to the transfer of heat of the fluid phase, entropy due to the fluid friction and entropy due to the porous phase transfer of heat. A computational domain with new coordinates (ξ,η) is created and Finite Volume Method (FVM) in case of the non-orthogonal grids is used to solve the resulting system. Various simulations for different values of the inclination angle, Hartmann number and alumina-copper concentration are carried out and the outcomes are presented in terms of streamlines, temperature, fluid friction entropy and Bejan number. It is remarkable that the increase in the inclination angle causes a diminishing of the heat transfer rate. Additionally, the irreversibility due to the temperature gradients is dominant near the heated fins, regardless of the values of the Hartmann number.

Highlights

Various industrial applications depend on the properties and nature of porous media
The local Bejan number (Be) is the ratio between the local entropy generation due to the transfer of heat and the entropy generation due to the fluid friction; it can be expressed as: Be =
Darcy number is filled by variable properties porous media has been carried out

Summary

Introduction

Various industrial applications depend on the properties and nature of porous media. Thermal insulation, grain stocking and drying processes, the petroleum reservoir, compacted beds for the chemical industry and geophysical systems are good examples of these applications. The outcomes disclose that the boost in the height of the fins augments the transfer of heat rate These irregular geometries with various thermal conditions have been handled by different scientific researchers [31,32,33,34,35]: magneto-convective flow of nanofluids confined open trapezoidal enclosures by Miroshnichenko et al [36] and Astanina et al [37]. As stated previously, using triangular fins within the containers as controlling factors for the nanofluids flows and the variable properties of the porous medium have not been considered widely. Thepermeability porous elements are considered as a is introduced One of the this model is that the depends on the particle compacted size (particle diameter dp) and the porosity of the medium.

Correlations of the Hybrid Nanofluids

Entropy Generation Analysis

Numerical Treatments

Discussion of Results

Conclusions

Methods