Fully developed opposing mixed convection of a Jeffery tri-hybrid nanofluid between two parallel inclined plates subjected to wall-slip condition

We analyze the effect of wall slip on the fully developed reverse mixed convection of Jeffery nanofluids between two inclined parallel plates with uniform wall heat flux conditions. The theory of tri-hybrid water-based nanoparticles with unique shapes, namely, cylindrical (copper), spherical (titanium oxide), and platelet (aluminum oxide) for heat transfer enhancement is utilized since it has better heat performance applicable in a dynamic of fuels and coolant in automobiles as compared with regular Newtonian fluid and nanofluid. The equations describing the above transport phenomena are nondimensional through appropriate scale transformations. Analytical solutions for velocity, temperature, and pressure distributions are obtained. Four different flow regimes including no reversal, bottom reversal, top reversal, and on both walls reversal are found for different combinations of buoyancy and pressure. Particularly, we notice that the wall slip significantly affects flow reversal. Furthermore, we notice that Magyari 's conclusion that the results of the homogeneous nanofluid flow model can be recovered from the corresponding Newtonian fluid model has great limitations. Besides, the effect of several physical factors on velocity and temperature distributions and important physical quantities, including skin friction coefficient and Nusselt number, are analyzed and graphically discussed.

Automated summary

This paper analyzes the effect of wall slip on the fully developed reverse mixed convection of Jeffery nanofluids between two inclined parallel plates. By utilizing three different shapes of nanoparticles, it is found that wall slip significantly affects flow reversal. Furthermore, the paper provides theoretical support by analyzing the effect of physical factors on velocity and temperature distributions.