Fully coupled thermo-hydro-mechanical analysis by an algebraic multigrid method

Xicheng Wang; B. A. Schrefler

doi:10.1108/02644400310465326

Fully coupled thermo-hydro-mechanical analysis by an algebraic multigrid method

Xicheng Wang, B. A. Schrefler

Research output: Contribution to journal › Article › peer-review

8 Scopus citations

Abstract

In this paper, an algebraic multigrid method is suggested for the fully coupled thermo- hydro-mechanical analysis in deforming porous media. The mathematical model consists of balance equations of mass, linear momentum and energy and of the appropriate constitutive equations. The chosen macroscopic field variables are temperature, capillary pressure, gas pressure and displacement. The gas phase is considered to be an ideal gas composed of dry air and vapour, which are regarded as two miscible species. Phase change as well as heat transfer through conduction and convection and latent heat transfer (evaporation-condensation) are taken into account. The problem hence presents an interaction problem between several fields with very different response characteristics. Further, the matrices are non-symmetric and not diagonally dominated. Numerical examples are given to demonstrate the efficiency of this method.

Original language	English (US)
Pages (from-to)	211-229
Number of pages	19
Journal	Engineering Computations (Swansea, Wales)
Volume	20
Issue number	1-2
DOIs	https://doi.org/10.1108/02644400310465326
State	Published - 2003

Keywords

Algorithms
Heat transfer
Phase change

ASJC Scopus subject areas

Computational Theory and Mathematics
Computer Science Applications
Computational Mechanics
Mechanical Engineering
Mechanics of Materials
Safety, Risk, Reliability and Quality
Applied Mathematics

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10.1108/02644400310465326

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abstract = "In this paper, an algebraic multigrid method is suggested for the fully coupled thermo- hydro-mechanical analysis in deforming porous media. The mathematical model consists of balance equations of mass, linear momentum and energy and of the appropriate constitutive equations. The chosen macroscopic field variables are temperature, capillary pressure, gas pressure and displacement. The gas phase is considered to be an ideal gas composed of dry air and vapour, which are regarded as two miscible species. Phase change as well as heat transfer through conduction and convection and latent heat transfer (evaporation-condensation) are taken into account. The problem hence presents an interaction problem between several fields with very different response characteristics. Further, the matrices are non-symmetric and not diagonally dominated. Numerical examples are given to demonstrate the efficiency of this method.",

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AU - Wang, Xicheng

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AB - In this paper, an algebraic multigrid method is suggested for the fully coupled thermo- hydro-mechanical analysis in deforming porous media. The mathematical model consists of balance equations of mass, linear momentum and energy and of the appropriate constitutive equations. The chosen macroscopic field variables are temperature, capillary pressure, gas pressure and displacement. The gas phase is considered to be an ideal gas composed of dry air and vapour, which are regarded as two miscible species. Phase change as well as heat transfer through conduction and convection and latent heat transfer (evaporation-condensation) are taken into account. The problem hence presents an interaction problem between several fields with very different response characteristics. Further, the matrices are non-symmetric and not diagonally dominated. Numerical examples are given to demonstrate the efficiency of this method.

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KW - Heat transfer

KW - Phase change

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Fully coupled thermo-hydro-mechanical analysis by an algebraic multigrid method

Abstract

Keywords

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