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Mutual impact of thermal radiations and temperature dependent thermal conductivity on non-Newtonian multiple flow regimes

Khalil Ur Rehman, Wasfı Shatanawi, Kinza Laraib

2023Case Studies in Thermal Engineering24 citationsDOIOpen Access PDF

Abstract

The transfer of thermal energy is a specialized discipline of thermal engineering and hence own practical applications in an industrial thermal systems like refineries, air-conditioning plants, automotive engines, power plants, jet engines, refrigeration, food processing, and chemical processing plants to mention just a few. Owning such importance we have reported the collective impact of thermal radiations and temperature-dependent thermal conductivity for heat transfer in stagnation point magnetized Casson fluid flow field. The thermal flow regime of Casson fluid is manifested with a viscous dissipation effect as well. The flow equations are tackled numerically by the use of the shooting method. The outcomes are debated comparatively by considering various flow regimes namely (I) Thermal flow regime with thermal radiations (II) Thermal flow regime without thermal radiations (III) Heat flow with heat generation and (IV) Heat flow in the absence of heat generation. We believe that the present thermal comparative analysis will be helpful for the preceding studies which own thermal engineering standpoints for the transfer of thermal energy by means of fluid flow.

Topics & Concepts

Heat transferThermalMechanicsThermal fluidsThermal conductivityThermodynamicsMaterials scienceThermal conductionFlow (mathematics)Thermal engineeringThermal energyThermal reservoirHeat transfer coefficientPhysicsHeat spreaderNanofluid Flow and Heat TransferFluid Dynamics and Turbulent FlowsRheology and Fluid Dynamics Studies
Mutual impact of thermal radiations and temperature dependent thermal conductivity on non-Newtonian multiple flow regimes | Litcius