Heat transfer improvement in hybrid nanofluid flow over a moving sheet with magnetic dipole.

Heat transfer improvement in industrial and engineering applications has attained a lot of interest from investigators in recent years. This is due to fact that the improvement of the much equipment in this sector such as electronic devices and heat exchangers are highly dependent on rate of the thermal transport. Due to their low thermal conductivity, base fluids such as oil, water, and ethylene glycol limit the heat transport rate. Because of its many functions in various manufacturing problems, hybrid convective heat transfer has piqued the interest of many engineers. The heat transfer flow with magnetic dipole features in hybrid nanoparticles $ ({\textrm{CuO} - \textrm{CoF}{\textrm{e}_\textrm{2}}{\textrm{O}_\textrm{4}}}) $ (CuO − CoF e 2 O 4 ) , $ ({\textrm{CoF}{\textrm{e}_\textrm{2}}{\textrm{O}_\textrm{4}}}) $ (CoF e 2 O 4 ) and used blood as a base fluid over a spreading sheet are investigated. The flow problem of PDEs is transmuted into structure of nonlinear ODEs by employing suitable similarity conversions. For numerical solution, bvp4c solver in MATLAB computing software is considered. Graphs depict the effects of important controlling flow parameters on velocity distribution and temperature profile. Furthermore, the table discusses the thermo physical characteristics of nanoparticles and hybrid nanofluids. [ABSTRACT FROM AUTHOR]