Equations governing the transient heat conduction in porous materials consisting of solids and fluids of different thermal properties were derived with a volumetric average scheme under the assumption of nonthermal equilibrium. The derivation leads to a macroscopic two-equation system which requires the closure modeling of new unknown terms due to interfacial transport, namely, the tortuosity term and the interfacial heat transfer term. Closure relations were obtained from the microscopic equations for temperature fluctuation under quasi-steady assumption. The closure coefficients appeared in the closure relations then depend on the media geometry as well as thermal properties. To demonstrate these dependencies, the closure coefficient for the thermal tortuosity is evaluated based on the effective stagnant thermal conductivity model proposed by Hsu et al. (1995) for periodically packed cubes, and the coefficient for interfacial heat transfer based on a quasi-steady heat conduction of dispersed spheres immersed in fluids. The salient features as well as the applicability and limitation of the newly proposed transient heat conduction model were discussed.
Skip Nav Destination
e-mail: mechthsu@usthk.ust.hk
Article navigation
Technical Briefs
A Closure Model for Transient Heat Conduction in Porous Media
C. T. Hsu
C. T. Hsu
Department of Mechanical Engineering, Hong Kong University of Science and Technology, Clear Water Bay, Kowloon, Hong Kong
e-mail: mechthsu@usthk.ust.hk
Search for other works by this author on:
C. T. Hsu
Department of Mechanical Engineering, Hong Kong University of Science and Technology, Clear Water Bay, Kowloon, Hong Kong
e-mail: mechthsu@usthk.ust.hk
J. Heat Transfer. Aug 1999, 121(3): 733-739 (7 pages)
Published Online: August 1, 1999
Article history
Received:
March 31, 1997
Revised:
March 25, 1999
Online:
December 5, 2007
Citation
Hsu, C. T. (August 1, 1999). "A Closure Model for Transient Heat Conduction in Porous Media." ASME. J. Heat Transfer. August 1999; 121(3): 733–739. https://doi.org/10.1115/1.2826043
Download citation file:
Get Email Alerts
Cited By
Entropic Analysis of the Maximum Output Power of Thermoradiative Cells
J. Heat Mass Transfer
Molecular Dynamics Simulations in Nanoscale Heat Transfer: A Mini Review
J. Heat Mass Transfer
Related Articles
Transient Temperature Computation for a System of Multiply Contacting Spheres in a 180-Degree Orientation
J. Heat Transfer (August,1999)
Evaluation of Thermal Conductivities of Disordered Composite Media Using a Fractal Model
J. Heat Transfer (February,1999)
Study of Flow and Heat Transfer Characteristics in Asymmetrically Heated Sintered Porous Heat Sinks With Periodical Baffles
J. Electron. Packag (September,2006)
Observation, Prediction, and Correlation of Geometric Shape Evolution Induced by Non-Isothermal Sintering of Polymer Powder
J. Heat Transfer (November,1997)
Related Proceedings Papers
Related Chapters
Conclusion
Introduction to Finite Element, Boundary Element, and Meshless Methods: With Applications to Heat Transfer and Fluid Flow
Thermal Interface Resistance
Thermal Management of Microelectronic Equipment, Second Edition
What Is a Watt?
Hot Air Rises and Heat Sinks: Everything You Know about Cooling Electronics Is Wrong