Advances of Heat Transfer in Porous Media

Advances of Heat Transfer in Porous Media

This reprint is a collection of recent advanced studies in the field of heat and fluid flow in porous media. The pore size of the studied porous media in this reprint starts from a nanoscale, and the applications include the drying process of materials such as clay and lentil grain as well as the en...

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Bibliographic Details
Other Authors: Mobedi, Moghtada (Editor), Hooman, Kamel (Editor)
Format: Electronic Book Chapter
Language:English
Published: Basel MDPI - Multidisciplinary Digital Publishing Institute 2023
Subjects:
Research & information: general
Physics
mass
heat
sisal fiber
experimental
simulation
drying
lentil grain
oblate spheroid
modeling
numerical simulation
ceramic materials
industrial brick
lumped model
metal foam
graphite foam
geometric modelling
heat transfer
porous media
metal foams
thickness ratio
pore density
porosity
pressure drop
trade-off
TOPSIS
unidirectional porous tube
gas cooling
high heat flux condition
fusion reactor
divertor
effective thermal conductivity
sintered particles
porous silicon
thermal cloak
phonon localization
molecular dynamics
nanoscale
porous media modeling
woven wire-mesh
LTNE
correlations
stacking types
ceramic block
lumped analysis
analytical
local thermal nonequilibrium model (LTNE)
forced convection
performance factor
solar air heater
single pass
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Description
Summary:This reprint is a collection of recent advanced studies in the field of heat and fluid flow in porous media. The pore size of the studied porous media in this reprint starts from a nanoscale, and the applications include the drying process of materials such as clay and lentil grain as well as the enhancement of heat transfer by using high thermal conductive porous media such as metal foams and stacked woven wire mesh. The use of a suitable porous structure for helium gas cooling under high heat flux conditions of a nuclear fusion divertor is an interesting application of porous structures for heat transfer enhancement, which is discussed in this reprint. A method for the trade-off thermo-hydrodynamic performance of a porous medium, which is an important issue for heat transfer enhancement, is also discussed. In the performed numerical studies, different methods such as finite volume method, lumped analysis and molecular dynamics are employed. Heat and mass transfer in structural ceramic blocks is analyzed by an analytical and phenomenological approach. All chapters of this reprint are advanced studies including wide application areas of porous media as well as interesting computational models that are useful for the researchers in the field of "Heat Transfer in Porous Media".
Physical Description:1 electronic resource (222 p.)
ISBN:books978-3-0365-6711-2
9783036567105
9783036567112
Access:Open Access

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