Thermal Performance Enhancement in a Hexagonal Cavity Filled with Hybrid Nanofluid with a Steering Shaped Insertion

Bijan Krishna Saha¹Goutam Barai¹Nithan Majumdar¹Md Aslam Hossain²Goutam Saha³Suvash C. Saha^4*

• ¹University of Barishal, Barishal, Barisal, Bangladesh
• ²Pabna University of Science & Technology, Pabna, Rajshahi, Bangladesh
• ³University of Dhaka, Dhaka, Dhaka, Bangladesh
• ⁴School of Chemistry, Physics and Mechanical ENgineering, University of Technology Sydney, Sydney, Queensland, Australia

Background: Steering shaped obstacle are extensively employed in various thermal engineering applications, including heat exchangers, transformers, semiconductors, microelectronics, chemical sensors, air-cooled engines, gas turbines, automotive radiators, and hydrogen fuel cells.Aims: The main goal of this study is to examine how key dimensionless parameters-such as the Reynolds number (Re), Richardson number (Ri), Hartmann number (Ha), Nusselt number (Nu), Bejan number (Be), and magnetic field angle (γ)-affect the heat transfer, fluid flow, and entropy generation in a hybrid nanofluid (TiO_2-Cu-H_2 O) system. A mixed convection flow is analyzed inside a hexagonal cavity containing a heated steering-shaped obstacle. The cavity has two moving walls that drive the flow, while a magnetic field is applied at an angle. The focus is to reduce entropy generation and enhance thermal performance, which is important for improving the efficiency of advanced cooling systems.Method and validations: The governing equations and boundary conditions are solved using the Galerkin weighted residual finite element method, with extensive validation against existing results to ensure the accuracy of the findings.Parameters: The study investigates a range of parameters: nanoparticles concentration (φ) varying from 1% to 5%, Re from 1 to 300, Ha from 0 to 60, Ri from 0.1 to 10, and γ ranging from 0° to 90°.Results: The study shows that lid-driven motion of the top and bottom walls, along with a steering-shaped heated obstacle, enhances HT and reduces E_gen. Thermal performance improves with increasing Ri and Re but decreases with rising Ha. For fixed Re = 300, at the highest magnetic field strength (Ha = 60), the HT rate reaches its minimum, exhibiting a 22.41% decrease relative to the no magnetic-field condition (Ha = 0). An increase in the Ri number leads to a 68.76% enhancement in thermal performance. At a fixed Ri=10, increasing the Re number from 1 to 300 leads to a 263.83% enhancement in thermal performance. The addition of TiO_2-Cu-H_2 O HNF further enhances thermal performances.Conclusion: The study reveals that MC HNF and heated steering shaped obstacle play a significant role in enhancing HT and reducing E_avg within the cavity.