Thermal and entropy analyses on buoyancy-driven flow of nanofluid inside a porous enclosure with two square cylinders: Finite element method

The present article reveals the study of heat transfer via buoyancy-driven flow and entropy generation of magnetic Fe3O4-H2O nanoliquid inside a porous enclosure using two square cylinders. The shape factor of diverse particle shapes may well be also considered. Numerical technique called FEM is implemented for the transformed governing equations. Results of Nusselt number, entropy generation, Bejan number along with the streamlines and the isotherms are obtained for disparate contributing parameters. Validation with earlier studies exhibits an excellent agreement in particular case and findings portray that entropy generation rises with growing Hartmann number and mounting Rayleigh number could overshoot the velocity gradient within the enclosure.

Automated summary

This article investigates the heat transfer, entropy generation, and fluid flow behavior inside a porous enclosure using a numerical method called FEM for a square cylinder filled with magnetic nanoliquid. The study found that entropy generation increases with rising Hartmann number and Rayleigh number, leading to velocity gradient overshooting within the enclosure. Results show different heat transfer and fluid flow characteristics for varying parameters combinations.