Viscous Dissipation Effects on the Motion of Casson Fluid over an Upper Horizontal Thermally Stratified Melting Surface of a Paraboloid of Revolution: Boundary Layer Analysis

The problem of a non-Newtonian fluid flow past an upper surface of an object that is neither a perfect horizontal/vertical nor inclined/cone in which dissipation of energy is associated with temperature-dependent plastic dynamic viscosity is considered. An attempt has been made to focus on the case...

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Bibliographic Details
Published inJournal of Applied Mathematics Vol. 2017; no. 2017; pp. 1 - 13-003
Main Authors Ajayi, T. M., Animasaun, I. L., Omowaye, A. J.
Format Journal Article
LanguageEnglish
Published Cairo, Egypt Hindawi Limiteds 2017
Hindawi Publishing Corporation
Hindawi
John Wiley & Sons, Inc
Hindawi Limited
Subjects
Boundary layer
Chemical reactions
Continuous casting
Dissipation
Dynamics
Energy dissipation
Fluid flow
Heat conductivity
Heat transfer
Mathematical analysis
Mathematical models
Melting
Non Newtonian fluids
Properties
Reynolds number
Studies
Velocity
Viscosity
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Summary:The problem of a non-Newtonian fluid flow past an upper surface of an object that is neither a perfect horizontal/vertical nor inclined/cone in which dissipation of energy is associated with temperature-dependent plastic dynamic viscosity is considered. An attempt has been made to focus on the case of two-dimensional Casson fluid flow over a horizontal melting surface embedded in a thermally stratified medium. Since the viscosity of the non-Newtonian fluid tends to take energy from the motion (kinetic energy) and transform it into internal energy, the viscous dissipation term is accommodated in the energy equation. Due to the existence of internal space-dependent heat source; plastic dynamic viscosity and thermal conductivity of the non-Newtonian fluid are assumed to vary linearly with temperature. Based on the boundary layer assumptions, suitable similarity variables are applied to nondimensionalized, parameterized and reduce the governing partial differential equations into a coupled ordinary differential equations. These equations along with the boundary conditions are solved numerically using the shooting method together with the Runge-Kutta technique. The effects of pertinent parameters are established. A significant increases in Rex1/2Cfx is guaranteed with St when magnitude of β is large. Rex1/2Cfx decreases with Ec and m.
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ISSN:1110-757X
1687-0042
DOI:10.1155/2017/1697135