Slip flow in porous micro-tubes under local thermal non-equilibrium conditions
Authors
Abstract:
In the present work, forced convection heat transfer of slip flow in porous micro-tubes with local thermal non-equilibrium between the gas and the solid matrix is investigated numerically. For this purpose, the flow is considered hydrodynamically developed but thermally developing. The Darcy-Brinkman-Forchheimer model in conjunction with separate energy equations for the gas and the solid matrix is used to describe the flow and heat transfer in the porous media. Moreover, both velocity slip and temperature jump are applied to the fluid at the wall. Simulation results are presented in terms of velocity field, distributions of the fluid and solid temperatures, the local Nusselt number, and the thermal entry length. The results indicate heat transfer improvement as a result of increase in the Peclet/Biot number. Increase in the Knudsen number or the modified conductivity ratio, however, diminishes the heat transfer rate. Although the choice of the Darcy/Forchheimer number may change the computational results, trends are not similar in the developing and the developed regions of the flow.
similar resources
Analysis of gaseous slip flow in a porous micro-annulus under local thermal non-equilibrium condition – An exact solution
Article history: Received 12 April 2015 Received in revised form 31 May 2015 Accepted 1 June 2015 Available online 27 June 2015
full textAnalysis of thermally developing flow in porous media under local thermal non-equilibrium conditions
In the present study, analytical solutions for thermally developing flows in porous media under local thermal non-equilibrium (LTNE) condition are derived for different fundamental models. The analytical solutions are validated by comparison with the numerical results. Based on the analytical solutions, the local Nusselt number is obtained, and the dimensionless thermal entry length nc is predi...
full textModelling Bidispersive Local Thermal Non-Equilibrium Flow
In this work, we present a system of equations which describes non-isothermal flow in a bidispersive porous medium under conditions of local thermal non-equilibrium. The porous medium consists of macro pores, and in the solid skeleton are cracks or fissures which give rise to micro pores. The temperatures in the solid skeleton and in the fluids in the macro and micro pores are all allowed to be...
full textAnalysis of Radiative Effect under Local Thermal Non-equilibrium Conditions in Porous Media-application to a Solar Air Receiver
The effect of thermal radiation within a porous medium while incorporating local thermal nonequilibrium (LTNE) is investigated in this work, with specific application to solar air receivers. It is shown that the radiation effect is significant. The temperature distributions for both solid and fluid phases are affected by conduction-radiation parameter N, the ratio of solid to fluid phase conduc...
full textFlow equations for dissipative quantum systems under non-equilibrium conditions
Flow equations for dissipative quantum systems under non-equilibrium conditions This work investigates dissipative quantum systems by means of flow equations for Hamiltonians. We consider the time evolution of two models out of non-equilibrium initial states. As a first application the dis-sipative harmonic oscillator will be solved exactly. The insights gained will be used in the second and no...
full textModeling for Flow through Unsaturated Porous Media with Constant and Variable Density Conditions using Local Thermal Equilibrium
The Flow through saturated-unsaturated porous media is extremely important in various natural and industrial based applications. While the Darcy's law with various modifications are used to model the flow through a porous media, the flow through unsaturated porous media is largely based on conservation of mass and modified Darcy's law where non-linear relationship exists between the p...
full textMy Resources
Journal title
volume 6 issue 2
pages 79- 87
publication date 2018-07-03
By following a journal you will be notified via email when a new issue of this journal is published.
Hosted on Doprax cloud platform doprax.com
copyright © 2015-2023