Heat transfer of incompressible flow in a rotating microchannel with slip boundary conditions of second order

Purpose The paper aims to consider heat transfer in incompressible flow in a rotating flat microchannel with allowance for boundary slip conditions of the first and second order. The novelty of the paper encompasses analytical and numerical solutions of the problem, with the latter based on the latt...

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Bibliographic Details
Published inInternational journal of numerical methods for heat & fluid flow Vol. 29; no. 5; pp. 1786 - 1814
Main Authors Avramenko, A.A., Dmitrenko, N.P., Shevchuk, I.V., Tyrinov, A.I., Shevchuk, V.I.
Format Journal Article
LanguageEnglish
Published Bradford Emerald Publishing Limited 10.06.2019
Emerald Group Publishing Limited
Subjects
Boundary conditions
Computational fluid dynamics
Exact solutions
Flow velocity
Fluid flow
Heat transfer
Hypotheses
Incompressible flow
Investigations
Mathematical models
Methodology
Microchannels
Nanoparticles
Nusselt number
Prandtl number
Reynolds number
Rotation
Slip velocity
Temperature profile
Temperature profiles
Velocity
Velocity distribution
Velocity profiles
Viscosity
Slippage
Lattice Boltzmann method
Rotating
Microchannel
Heat transfer
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Summary:Purpose The paper aims to consider heat transfer in incompressible flow in a rotating flat microchannel with allowance for boundary slip conditions of the first and second order. The novelty of the paper encompasses analytical and numerical solutions of the problem, with the latter based on the lattice Boltzmann method (LBM). The analytical solution of the problem includes relations for the velocity and temperature profiles and for the Nusselt number depending on the rotation rate of the microchannel and slip velocity. It was demonstrated that the velocity profiles at high rotation rates transform from parabolic to M-shaped with a minimum at the channel axis. The temperature profiles tend to become uniform (i.e. almost constant). An increase in the channel rotation rate contributes to the increase in the Nusselt number. An increase in the Prandtl number causes a similar effect. The trend caused by the effect of the second-order slip boundary conditions depends on the closure hypothesis. It is shown that heat transfer in a flat microchannel can be successfully modeled using the LBM methodology, which takes into account the second-order boundary conditions. Design/methodology/approach The paper is based on the comparisons of an analytical solution and a numerical solution, which employs the lattice Boltzmann method. Both mathematical approaches used the first-order and second-order slip boundary conditions. The results obtained using both methods agree well with each other. Findings The analytical solution of the problem includes relations for the velocity and temperature profiles and for the Nusselt number depending on the rotation rate of the microchannel and slip velocity. It was demonstrated that the velocity profiles at high rotation rates transform from parabolic to M-shaped with a minimum at the channel axis. The temperature profiles tend to become uniform (i.e. almost constant). The increase in the channel rotation rate contributes to the increase in the Nusselt number. An increase in the Prandtl number causes the similar effect. The trend caused by the effect of the second-order slip boundary conditions depends on the closure hypothesis. It is shown that heat transfer in a flat microchannel can be successfully modeled using the LBM methodology, which considers the second-order boundary conditions. Originality/value The novelty of the paper encompasses analytical and numerical solutions of the problem, whereas the latter are based on the LBM.
ISSN:0961-5539
1758-6585
DOI:10.1108/HFF-06-2018-0264