Magnetohydrodynamic (MHD) effects on conjugate mixed convection in a triangular enclosure with swirling reactive fluid: A computational approach

In this research, we investigate the quantitative characteristics of conjugate mixed convection heat transfer, internal heat generation/absorption due to chemical reaction and the magnetohydrodynamic impact on a lid-driven right-angled triangular enclosure which has a solid circular cylinder situated at the center. The perpendicular edges of the enclosure remain stationary and maintain a constant cold temperature. The tilted side is adiabatic, while the bottom edge slides uniformly, maintaining a constant elevated temperature. The solid cylinder was rotated at different angular velocities in clockwise and counterclockwise directions while applying a constant magnetic field to the enclosure. By varying the Reynolds (31.623 ≤ Re ≤ 316.23), Richardson (0.1 ≤ Ri ≤ 10), Grashof number (10³ ≤ Gr ≤ 10⁵), internal heat generation or absorption coefficient (−10 ≤ Δ ≤ 10), and the rotating cylinder’s speed (−2 ≤ Re_c ≤ 2) along with a given magnetohydrodynamic effect of the cylinder, parametric simulation is used. Plots of streamlines and isotherms are used to depict qualitative results. In contrast, the average Nusselt number, normalized Nusselt number, and average drag coefficient are used to calculate the configuration’s quantitative thermal performance and flow characteristics. To the best of our knowledge, this study is the first to present a comprehensive numerical investigation of conjugate heat transfer in a lid-driven triangular enclosure that simultaneously considers: (1) magnetohydrodynamic effects, (2) both clockwise and counterclockwise rotation of an internal solid cylinder, and (3) internal heat generation and absorption. The results reveal a strong interactive influence among these factors. Most notably, internal heat absorption enhances the average Nusselt number by up to 74.5 % and reduces the average drag coefficient by 89 % when both Reynolds and Grashof numbers are at their maximum values. Parallel to this, streamline and isotherm plots show overall heat distribution and flow separation within the enclosure. The simulations clearly show that higher Reynolds and Grashof numbers, combined with internal heat absorption, markedly enhance heat transfer, while the effect of cylinder rotation remains relatively minor.