Study on Local Thermal Equilibrium in a Porous Medium

We examine the effect of local thermal non-equilibrium on the infiltration of a hot fluid into a cold porous medium. The temperature fields of the solid porous matrix and the saturating fluid are governed by separate, but coupled, parabolic equations, forming a system governed by three dimensionless parameters. A scale analysis and numerical simulations are performed to determine the different manners in which the temperature fields evolve in time. These are supplemented by a large-time analysis showing that local thermal equilibrium between the phases is eventually attained. It is found that the thickness of the advancing thermal front is a function of the governing parameters rather than being independent of them. This has the implication that local thermal equilibrium is not equivalent to a single equation formulation of the energy equation as might have been expected. When the velocity of the infiltrating fluid is sufficiently large, the equations reduce to a hyperbolic system and a thermal shock wave is formed within the fluid phase. The strength of the shock decays exponentially with time, but the approach to local thermal equilibrium is slower and is achieved algebraically in time.

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Transient Mixed Convection In Channels Partially Heated Filled With A Porous Medium In Non-Local Thermal Equilibrium

10.1063/1.3453840 ◽

2010 ◽

Author(s):

Bernardo Buonomo ◽

Oronzio Manca ◽

Paolo Mesolella ◽

Sergio Nardini ◽

Kambiz Vafai

Keyword(s):

Porous Medium ◽

Mixed Convection ◽

Thermal Equilibrium ◽

Local Thermal Equilibrium ◽

Non Local

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Local Thermal Equilibrium in Forced Convection Through Porous Media

ASME 2010 3rd Joint US-European Fluids Engineering Summer Meeting: Volume 1, Symposia – Parts A, B, and C ◽

10.1115/fedsm-icnmm2010-30832 ◽

2010 ◽

Author(s):

A. Nouri-Borujerdi

Keyword(s):

Porous Medium ◽

Pressure Gradient ◽

Forced Convection ◽

Thermal Equilibrium ◽

Fluid Transport ◽

Convection Heat Transfer ◽

Darcy Number ◽

Equation Model ◽

Temperature Fields ◽

Local Thermal Equilibrium

Forced convection heat transfer through a channel filled with a porous medium is investigated using perturbation method. Two-energy equation model is utilized to represent the assumption of local thermal non-equilibrium which exists between the solid and fluid phases. The Brinkman-Forchheimer extension of the Darcy model is used to represent the fluid transport within the porous medium. Analytical solution is obtained for both fluid and solid temperature fields incorporating the effects of various pertinent parameters such as the Darcy number, the Biot number, the thermal conductivity and the pressure gradient. It is found that the Darcy number and the pressure gradient have significant effects on the local thermal equilibrium assumption.

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Experimental Estimation of the Phase Front Under Local Thermal Non-Equilibrium Condition: Phase Change Phenomena in Porous Media

Electronic and Photonic Packaging, Electrical Systems Design and Photonics, and Nanotechnology ◽

10.1115/imece2002-39705 ◽

2002 ◽

Author(s):

A. G. Agwu Nnanna ◽

A. Haji-Sheikh ◽

Kendall T. Harris

Keyword(s):

Porous Medium ◽

Phase Change ◽

Change Process ◽

Thermal Equilibrium ◽

Equilibrium Condition ◽

Local Thermal Equilibrium ◽

Solid Matrix ◽

Phase Front ◽

Phase Change Process ◽

Non Equilibrium

A systematic experimental method of estimating the extent of the phase front under local thermal non-equilibrium condition in porous media saturated with phase change material has been developed. During phase change in porous medium, the solid matrix and the pore material are under thermodynamic non-equilibrium condition until the phase change process is complete. It is often hypothesized that the solid matrix and the pore material are in local thermal equilibrium (LTE) condition hence, the arrival of the phase front is predicted based on this hypothesis. An understanding of the rate of freezing and thawing in a porous medium undergoing the phase change process is important to permit proper implementation of procedures such as cryopreservation, cryosurgery, and to predict the thermal performance of passive cooling systems for electronic devices. In this paper, a systematic method of estimating the extent of the phase change front is developed. Results show that during the phase change process the porous medium is far from local thermal equilibrium condition.

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