Abstract
This paper presents the simulations replicating two well-documented benchmarks on coupled gas-liquid flow in unsaturated soil. The results serve as validation and verification of the formulation of the gas flow in unsaturated geomaterials in the newly developed THMC coupled FEM code Thebes. The paper first discusses the basis of the compositional method and the role of the dry air mass balance equation in the theoretical framework. The fundamental constitutive assumptions related to gas flow, as adopted in the Thebes code, are also discussed in details. Afterwards, the paper discusses simulation of a two-phase infiltration test in unsaturated sand, as well as a one dimensional drainage test. The numerical results of these two examples show that the code is able to capture the main features associated with the gas flow in unsaturated soil. The possible future improvements, both related to the theoretical framework and the numerical implementation, are discussed at the closure of the paper.
Highlights
Bentonite as a sealing material for nuclear waste has to withstand severe environmental conditions
The capability of modelling gas flow is necessary for any code that is designed to be used for simulating nuclear waste sealing related problems
This paper presents verification of the capabilities of Thebes code related to the coupled effects of the gas flow on the thermo-hydro-mechanical-chemical behaviour of geomaterials
Summary
Bentonite as a sealing material for nuclear waste has to withstand severe environmental conditions. In such engineering applications, the assessment of bentonite performance requires sufficient understanding of the influence of the dominant coupled thermo-hydromechanical-chemical (THMC) processes on the bentonite behaviour. The capability of modelling gas flow is necessary for any code that is designed to be used for simulating nuclear waste sealing related problems. The importance of modelling gas flow and migration is not restricted to nuclear waste disposal applications but covers several other serious problems, including, for example design of the clay barriers to control the gas migration accompanying the degradation of organic matters in case of landfills. This paper presents verification of the capabilities of Thebes code related to the coupled effects of the gas flow on the thermo-hydro-mechanical-chemical behaviour of geomaterials. The paper introduces first the adopted mass balance equations and their numerical implementation, which are followed by the two validation examples
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