Mixed Convection and Entropy Generation Analysis of CNT-Water Nanofluid in a Square Cavity with Cylinders and Flow Deflectors

This study explores the mixed convection of CNT-water nanofluid within a square cavity containing heated cylinders under the influence of a magnetic field, focusing on three geometric configurations: a single heated cylinder, two heated cylinders, and two heated cylinders with a flow deflector. The impact of various parameters, including Reynolds number (Re), Richardson number (Ri), Hartmann number (Ha), wavy wall peaks (n), nanoparticle volume fraction ({\phi}), Hartmann angle ({\gamma}), rotational speed ({\omega}), and inclination angle ({\alpha}), on thermal and fluid dynamic behaviors is analyzed. Results reveal that MWCNT nanofluids consistently achieve higher Nusselt numbers than SWCNT nanofluids, indicating superior heat transfer capabilities. Introducing a second cylinder and a flow deflector enhances thermal interactions, while increasing Ha stabilizes the flow, improving thermal performance. Wavy wall peaks further enhance fluid mixing and heat transfer efficiency. Additionally, SWCNT nanofluids exhibit higher Bejan numbers, indicating a greater dominance of thermal entropy generation over fluid friction. These findings provide valuable insights for optimizing thermal management systems in engineering applications, highlighting the importance of selecting appropriate nanofluids, geometric configurations, and magnetic field parameters to achieve optimal thermal performance and fluid stability.