Title of article
Non-Similar Computational Solution for Boundary Layer Flows of Non-Newtonian Fluid from an Inclined Plate with Thermal Slip
Author/Authors
Rao، A. Subba نويسنده Department of Mathematics,Madanapalle Institute of Technology and Science,Madanapalle,India , , Prasad، V. Ramachandra نويسنده Department of Mathematics,Madanapalle Institute of Technology and Science,Madanapalle,India , , Nagendra، N نويسنده Department of Mathematics,Madanapalle Institute of Technology and Science,Madanapalle,India , , Reddy، N. Bhaskar نويسنده Department of Mathematics,Sri Venkateswara University,Tirupathi,India , , Beg، O. Anwar نويسنده Gort Engovation Research (Propulsion and Biomechanics),Bradford,UK ,
Issue Information
فصلنامه با شماره پیاپی 28 سال 2016
Pages
13
From page
795
To page
807
Abstract
The laminar boundary layer flow and heat transfer of Casson non-Newtonian fluid from an inclined (solar
collector) plate in the presence of thermal and hydrodynamic slip conditions is analysed. The inclined plate
surface is maintained at a constant temperature. The boundary layer conservation equations, which are
parabolic in nature, are normalized into non-similar form and then solved numerically with the well-tested,
efficient, implicit, stable Keller-box finite-difference scheme. Increasing velocity slip induces acceleration in
the flow near the inclined plate surface. Increasing velocity slip consistently enhances temperatures
throughout the boundary layer regime. An increase in thermal slip parameter strongly decelerates the flow
and also reduces temperatures in the boundary layer regime. An increase in Casson rheological parameter acts
to elevate considerably the velocity and this effect is pronounced at higher values of tangential coordinate.
Temperatures are however very slightly decreased with increasing values of Casson rheological parameter.
Keywords
Non-Newtonian fluid mechanics; Inclined plate; Solar energy; Yield stress; Slip condition , Keller-box numerical method; Heat transfer; Skin friction; Nusselt number; Boundary layers.
Journal title
Journal of Applied Fluid Mechanics (JAFM)
Journal title
Journal of Applied Fluid Mechanics (JAFM)
Record number
2401035
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