Mathematical Modeling of Thermal Association in a Porous Medium with a Capillary Effect in Anisotropic Composite Materials

Ekaterina Kuznetsova; Lev Rabinskiy

doi:10.4028/www.scientific.net/KEM.771.136

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Influence of Constant Magnetic Fields on Defect Formation under Conditions of Heat Shock in Surface Layers of Silicon
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Mathematical Modeling of Thermal Association in a Porous Medium with a Capillary Effect in Anisotropic Composite Materials
p.136

HomeKey Engineering MaterialsKey Engineering Materials Vol. 771Mathematical Modeling of Thermal Association in a...

Mathematical Modeling of Thermal Association in a Porous Medium with a Capillary Effect in Anisotropic Composite Materials

Abstract:

Authors developed a mathematical model of heat and mass transfer in multidimensional bodies made of composite materials, taking into account porosity and capillarity. Continuity equations for pyrolysis gases were taken for the research: the pressure ratio at the outer boundary of the body. Based on the nonstationary heat conduction problem, under conditions of high-intensity heat transfer at the boundaries of bodies, taking into account the laws of decomposition and non-linear filtration of pyrolysis gases through a porous residue, the time distribution of the movable boundary of phase transformations and the distribution of the temperature field along the variable coordinate at different instants of time are obtained. It was found that, although the thermal load at the outer boundaries is symmetric with respect to the symmetry axis, there is an obvious asymmetry in the temperature field and the movable boundary of the phase transformations.

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Periodical:

Key Engineering Materials (Volume 771)

Pages:

136-143

DOI:

https://doi.org/10.4028/www.scientific.net/KEM.771.136

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Online since:

June 2018

Authors:

Ekaterina Kuznetsova*, Lev Rabinskiy

Keywords:

Differential Operators, Field Cross-Sections, Heat Transfer Characteristics, Pyrolysis Gas, Two-Dimensional Anisotropic Region

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References

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