A narrative loom of hybrid nanofluid-filled wavy walled tilted porous enclosure imposing a partially active magnetic field

Improved controllability along with enhanced thermal performance in modern thermal devices could be achieved using the combination of partial magnetic fields and hybrid nanofluid flow. The present attempt demonstrates the impact of partially active magnetic fields on the enhanced thermal performance of hybrid nanofluid (Cu-Al2O3-H2O) flow in an oblique wavy porous enclosure. The enclosure is partially heated from the bottom and cooled through its wavy sides and suffers from a partially active magnetic field normal to the sidewalls. The transport equations involving complex wavy walls, localized thermal gradient, porous substance, hybrid nanofluid, partial magnetic fields are solved by the finite volume approach numerically using a written FORTRAN code. The effectiveness of the novel implementation of a partial magnetic field is examined rigorously for wide ranges of variations of active heating length (Lh), active width of the partial magnetic field (Wb) and its positions, magnetic field strength (Ha), the inclination of the cavity (gamma), Darcy-Rayleigh number (Ram), Darcy number (Da), and hybrid nanoparticles concentration (zeta) additionally applying no and whole-domain magnetic field. The correlation for the average Nusselt number is derived. Finally, the results conclude that the presence of complex wavy walls enhances the heat transfer of -x223C 22.16% compared to a plain vertical wall; however, the strength of circulation drops. A partially active magnetic field can be utilized as an effective means to control field variables with a lesser reduction in heat transfer (-x223C 13.97%) compared to the whole domain magnetic field. The middle-centered partial magnetic field offers a significant impact on the overall thermal behavior depending on the active width and intensity of the magnetic field, active heating length, and all other involved parameters. Tilting of the cavity reduces the heat transfer rate.

Automated summary

The study demonstrates that combining partial magnetic fields and complex wavy walls can enhance heat transfer efficiency while reducing circulation strength; compared to the whole-domain magnetic field, a partially active magnetic field has a smaller impact on reducing heat transfer; the middle-centered partial magnetic field plays a significant role in overall thermal behavior depending on parameters like active width, magnetic field intensity, and other factors.