Search engine for discovering works of Art, research articles, and books related to Art and Culture
Javascript must be enabled to continue!
Mixed Convection in a Casson Fluid Flow towards a Heated Shrinking Surface
View through CrossRef
In this paper, an extensive analysis of mixed convection effects on steady two-dimensional stagnation point flow of a Casson fluid over a heated horizontal sheet has been numerically investigated. The governing Navier-Stokes equations of the present problem are transformed into nonlinear ordinary differential equations by applying a similarity transformation. A numerical solution of the problem has been obtained by employing the linearization technique along with the finite difference discretization. The impact of the Casson fluid parameter, the thermo-radiative parameter, the mixed convection parameter, the slip parameter, and the Prandtl number on the fluid motion and temperature is studied through graphical data. The convection parameter, the slip parameter and the Casson fluid parameter tends to accelerate the flow. The temperature distribution is however reduced by the convection parameter, slip parameter, thermal radiation and the Prandtl number.
This work is based on [25] in which micropolar fluid flow over a heated surface was investigated by using the homotopy analysis method. We have extended the problem by considering the combined impact of mixed convection and thermal radiation on the Casson fluid flow towards a heated shrinking sheet, by using a numerical method.
Earthline Publishers
Title: Mixed Convection in a Casson Fluid Flow towards a Heated Shrinking Surface
Description:
In this paper, an extensive analysis of mixed convection effects on steady two-dimensional stagnation point flow of a Casson fluid over a heated horizontal sheet has been numerically investigated.
The governing Navier-Stokes equations of the present problem are transformed into nonlinear ordinary differential equations by applying a similarity transformation.
A numerical solution of the problem has been obtained by employing the linearization technique along with the finite difference discretization.
The impact of the Casson fluid parameter, the thermo-radiative parameter, the mixed convection parameter, the slip parameter, and the Prandtl number on the fluid motion and temperature is studied through graphical data.
The convection parameter, the slip parameter and the Casson fluid parameter tends to accelerate the flow.
The temperature distribution is however reduced by the convection parameter, slip parameter, thermal radiation and the Prandtl number.
This work is based on [25] in which micropolar fluid flow over a heated surface was investigated by using the homotopy analysis method.
We have extended the problem by considering the combined impact of mixed convection and thermal radiation on the Casson fluid flow towards a heated shrinking sheet, by using a numerical method.
Related Results
The Cambridge Hundred Rolls
The Cambridge Hundred Rolls
The chapter provides new translations of these previously unpublished documents....
Air convection in coarse blocky permafrost : a numerical modelling approach to improve the understanding of the ground thermal regime
Air convection in coarse blocky permafrost : a numerical modelling approach to improve the understanding of the ground thermal regime
Permafrost is a thermal phenomenon, defined as subsurface material with a temperature remaining below 0°C for at least two consecutive years. Permafrost occurs at high latitudes an...
Analytical Solution of Unsteady Casson Fluid Flow Through a Vertical Cylinder with Slip Velocity Effect
Analytical Solution of Unsteady Casson Fluid Flow Through a Vertical Cylinder with Slip Velocity Effect
Casson fluid is a non-Newtonian fluid with its unique fluid behaviour because it behaves like an elastic solid or liquid at a certain condition. Recently, there are several studies...
Magnetohydrodynamic Effect in Mixed Convection Casson Hybrid Nanofluids Flow and Heat Transfer over a Moving Vertical Plate
Magnetohydrodynamic Effect in Mixed Convection Casson Hybrid Nanofluids Flow and Heat Transfer over a Moving Vertical Plate
The current study examined the effect of nanoparticles shapes on magnetohydrodynamics (MHD), Casson hybrid nanofluids flow, and heat transfer over a moving vertical plate with conv...
Grain size evolution and heat transfer regime in the shells of icy moons
Grain size evolution and heat transfer regime in the shells of icy moons
IntroductionTogether with the ice shell thickness, grain size due to its effect on viscosity is perhaps the most crucial parameter determining the heat transfer regime inside the ...
Numerical analysis of Casson nanofluid three-dimensional flow over a rotating frame exposed to a prescribed heat flux with viscous heating
Numerical analysis of Casson nanofluid three-dimensional flow over a rotating frame exposed to a prescribed heat flux with viscous heating
AbstractThis study investigates heat transfer characteristics and three-dimensional flow of non-Newtonian Casson nanofluid over a linearly stretching flat surface in the rotating f...
The Velocity, Temperature and Concentration Profiles for Triple Diffusive Casson Fluid Flow Subjected to the Soret-Dufour Parameters
The Velocity, Temperature and Concentration Profiles for Triple Diffusive Casson Fluid Flow Subjected to the Soret-Dufour Parameters
The triple-diffusive convection with the involvement of non-Newtonian fluid has many applications in the science and technology field, industrial processes, and also in research wo...
Entropy and heat transfer investigation of Casson–Maxwell, Casson–Jeffrey, and Casson–Oldroyd-B binary nanofluids in a parabolic trough solar collector: a comparative study
Entropy and heat transfer investigation of Casson–Maxwell, Casson–Jeffrey, and Casson–Oldroyd-B binary nanofluids in a parabolic trough solar collector: a comparative study
AbstractIn this paper, we compared copper-engine oil Casson–Maxwell, Casson–Jeffrey, and Casson–Oldroyd-B binary nanofluids in a parabolic trough solar collector. Using appropriate...