Computational examination of non-Darcian flow of radiative ternary hybridity Casson nanoliquid through moving rotary cone

The goal of this resear c h is to provide a nov el conce ptual base for ternary hybridity nanofluids that will impr ov e heat transmission. This model illustrates how to produce heat conduction that is superior to the hybridity nanofluid. The ternary hybridity nanofluid is made by suspending three distinct kinds of nanostructures (TiO2, Al2O3, and SiO2) in ethylene glycol with varying physical and chemical linkages. The combination of these nanoparticles aids in the decomposition of hazardous compounds, environment cleansing, and the cooling of other equipment. This article describes the ternary hybrid nanofluids such as the conductivity of thermal and electrical, specific heat capacitance, viscosity, and density. The ordinar y differ ential equations for the liquid and temperature are solved utilizing the Keller box method (KBM). The main finding discov er ed that the tri-hybrid nanofluid transferred more heat compared to the hybrid nanofluid. The velocity and temperature field diminishes for these ranges of parameters: 0= ? =2 (velocity slip? ) and 0 = ?(1) =2 (temperature slip ?1). The Dar cy-For c hheimer F r r anges betw een 0 . 5= F r = 1 . 4 diminishes the fluid velocity. The fluid moving subjected to a rotating cone has various applications in engineering like cone clutch, steam generators, loudspeaker cooling, lubricating grease for seals, hydrology, geosciences, etc.