Avik Ray - Mechanical Engineering, Heritage Institute of Technology, Kolkata, Assistant Professor
Sumanta Banerjee - Mechanical Engineering, Assistant Professor, Heritage Institute of Technology, Kolkata, India
Prokash Roy - Mechanical Engineering, Jadavpur University, Kolkata, India

In this paper numerical analysis is carried out to find out the heat transfer performance of Al۲O۳/Cu nanofluid and Al۲O۳ nanofluid for different nanoparticle mixture ratios dispersed in water. The Al۲O۳ and Al۲O۳/Cu are simulated to flow in between a plain linear pipe with rectangular cross section. The channel is uniformly heated under constant wall heat flux conditions. The computational model is validated with experimental results from a recent literature study for Nusselt number within ۷.۸۹ % error and friction factor within ۸.۵۵% error. The simulation studies are performed with ۰.۵ %, ۱.۰% and ۲.۰% volume fraction of nano particle in the carrier fluid. The Reynolds number varies with the flow velocity, and ranges from ۲۰۰۰ to ۱۲۰۰۰ for the present study. The heat flux applied along the tube is ~۷۹۵۵ W⁄m^۲ and corresponds to realistic values obtained from literature review. The impacts of the flow Reynolds number, volume fraction and composition of nanofluids on heat transfer characteristics and friction factor are analyzed for the hybrid nanofluid, and compared with the thermal performance of the chosen single-particle nanofluid. The validation of the numerical model has been performed with the published experimental results available in literature. The studies reveal that in comparison to water, the heat transfer coefficients of Al۲O۳ nanofluid are higher by ۲.۷%, ۵.۲%, and ۱۰.۹%, while those of Al۲O۳⁄Cu nanofluid are higher by ۴.۱%, ۸.۰%, and ۱۶.۲%, respectively, for (nanoparticle) volume fractions of ۰.۵%, ۱.۰%, and ۲.۰%. As compared to other working fluids, ۲%Al۲O۳ shows the highest pressure drop. The thermal performance of the Al۲O۳/Cu hybrid nanofluid is better to the single-particle Al۲O۳ nanofluid dispersed in water. The study shows that for any representative value of volume fraction for the single-particle or hybrid nanofluid, the wall-averaged Nusselt number and the pressure drop increases monotonically with the Reynolds number.

Forced convection,,, ,،Heat transfer coefficient,,, ,،Hybrid nanofluid,,, ,،Single particle nanofluid,,, ,،Volume fraction