Nanofluids are potential heat transfer fluids with enhanced thermal and physical properties. In particular, the fluids embedded with titanium nanoparticles have tendency to control the heat transfer mechanism in surgical implant applications such as glass covering of iris, retina and glaucoma etc. External magnetic fields are capable to set the thermal and physical properties of magnetic-nanofluids and regulate the flow and heat transfer characteristics. With this incentive, a theoretical investigation is performed for exploring the flow and heat transfer behavior of magneto-nanofluids caused by a rotating cone in the presence of temperature dependent viscosity and heat source/sink. For this study, we considered Ti and Ti-alloy (Ti6Al4V is a titanium alloy with 90% titanium, 6% aluminum and 4% Vanadium) nanoparticles embedded in water. With the aid of similarity variables, we transformed the governing equations as ordinary differential equations and numerical solutions are found by employing Runge-Kutta and Newton's methods. We discussed the friction factor coefficients, local Nusselt number, flow and heat transfer performance of both nanofluids with the assistance of graphs and tables. We found that the heat transfer performance of Ti-water nanofluid is high when compared with the heat transfer performance of Ti-alloy water nanofluid. From this we can conclude that Ti-alloy combination nanofluids are useful for cooling processes.

• 出版日期2016-10