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Magnetic mixed convection within wavy trapezoidal thermal energy storage systems using nano enhanced phase change material
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Journal Article
Magnetic mixed convection within wavy trapezoidal thermal energy storage systems using nano enhanced phase change material
2024
Overview
The three-dimensional (3D) MHD mixed convection mode confined 3D wavy trapezoidal enclosure is examined. The bottom plane of the trapezoidal system is irregular, particularly a wavy plane with various undulation numbers
. The forced convection phenomenon arises due to the displacement of the top region plane, whereas the porosity-enthalpy methodology characterizes the progression of charging. The heat transfer is enhanced using the nanoencapsulation phase change material (NePCM), consisting of Polyurethane as a shell and Nonadecane as a core, with water as the primary liquid base. The (GFEM) is used to treat the governing system, and a comparison between the HT (heat transmission) irreversibility and FF (fluid friction) irreversibility is performed using the function of the Be
Avg
. The significant findings revealed that parabolic behaviors for the melting ribbon curve are given at lower values of
Re
and higher values of
Ha
. Also, reducing the undulation number is better for obtaining a higher heat transmission rate. The average Nusselt number was lowered by 60% and 19%, respectively, at the highest Reynolds number when the Hartmann number increased from 0 to 100 and N from 2 to 8. Also, the values of
between 1 and 100 improve the heat transfer rates up to 51%.
Publisher
Nature Publishing Group UK,Nature Publishing Group,Nature Portfolio
