Hybrid nanofluid flow encompassed of aluminum grade-V nanoparticles through parallel spinning plates: An applications of parametric continuation method

The fluid flow across two parallel permeable spinning sheets is studied in the current analysis. The hybrid nanofluid (HNF) is composed of aluminum alloys (Ti₆Al₄V-AA7075), ethylene glycol (50%) and water (50%). The unification of Ti₆Al₄V and AA7075 alloys delivers an effective functionality of robustness and durability against corrosion. The probable uses take in aviation elements, the automobile sector, athletic apparel and surgical instruments. Therefore, the aim of this study is to mathematically formulate the HNF flow consisting of Ti₆Al₄V-AA7075 alloys in the form of nonlinear coupled PDEs. The flow equations are reconditioned into the dimensionless form by employing a similar approach. The transform equations are further numerically solved through the PCM (parametric continuation method). For the validity of the results, the outcomes are compared to the published studies. The PCM results are presented in the figures. It is noticed that the effect of Reynold number, surface rotation and porosity parameters drops the flow rate. The inclusion of Ti₆Al₄V-NPs in base fluid remarkably enhances the mass and energy conduction rate of HNF. The thermal field upsurges with the effect of heat radiation and exponential heat source/sink, whereas drops with variation Ti₆Al₄V and AA7075 NPs.