Effect of temperature-dependent viscosity on forced convection heat transfer from a cylinder in crossflow of power-law fluids

The steady, two-dimensional and incompressible flow of power-law fluids across an unconfined isothermal heated circular cylinder is investigated numerically to ascertain the effect of temperature-dependent viscosity on the flow and forced convection heat transfer phenomena. Extensive numerical resul...

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Bibliographic Details
Published in:International journal of heat and mass transfer 2010-10, Vol.53 (21), p.4728-4740
Main Authors: Soares, A.A., Ferreira, J.M., Caramelo, L., Anacleto, J., Chhabra, R.P.
Format: Article
Language:English
Subjects:
Circular cylinder
Computational fluid dynamics
Convection and heat transfer
Cylinders
Exact sciences and technology
Fluid dynamics
Fluid flow
Fluids
Fundamental areas of phenomenology (including applications)
Heat transfer
Mathematical analysis
Mathematical models
Non-newtonian fluid flows
Nusselt number
Physics
Shear-thickening
Shear-thinning
Temperature-thinning
Turbulent flows, convection, and heat transfer
Viscosity
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Summary:The steady, two-dimensional and incompressible flow of power-law fluids across an unconfined isothermal heated circular cylinder is investigated numerically to ascertain the effect of temperature-dependent viscosity on the flow and forced convection heat transfer phenomena. Extensive numerical results elucidating the variation of the heat transfer characteristics and drag coefficient on the severity of temperature dependence of viscosity (0 ⩽ b ⩽ 0.5), power law index (0.6 ⩽ n ⩽ 1.6), Prandtl number (1 ⩽ Pr ⩽ 100) and Reynolds number (1 ⩽ Re ⩽ 30) are presented. The coupled momentum and energy equations are expressed in the stream function/vorticity formulation and solved using a second-order accurate finite difference method to determine the local and surface-averaged Nusselt numbers, the drag coefficient, and to map the flow domain in terms of the temperature and flow fields near the cylinder. The variation of viscosity with temperature is shown to have a substantial effect on both the local and surface-averaged values of the Nusselt number. As expected, the results also suggest that the rate of heat transfer shows positive dependence on the Reynolds number and Prandtl number. Furthermore, stronger the dependence of viscosity on the temperature, the greater is the enhancement in the rate of heat transfer. Finally, all else being equal, shear-thinning fluid behaviour facilitates heat transfer while the shear-thickening behaviour has deleterious effect on heat transfer.
ISSN:0017-9310
1879-2189
DOI:10.1016/j.ijheatmasstransfer.2010.06.019