Tomoyuki Shimura scite author profile

Tomoyuki Shimura

5Publications

4Citation Statements Received

33Citation Statements Given

How they've been cited

How they cite others

Affiliations

Obayashi (Japan)

Publications

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Extended two-phase flow model with mechanical capability to simulate gas migration in bentonite

Tawara¹,

Hazart²,

Mori³

et al. 2014

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Long-term gas migration through clays cannot be simulated by conventional two-phase flow models alone owing to the presence of material deformation. In this article, an extended twophase flow model that incorporates mechanical effects is proposed. The model allows the formation of preferential pathway and considers the relation between pore moisture and pore deformation. It was carried out with the intention of avoiding the complexity of a fully coupled thermal, hydraulic and mechanical modelling. In the new model, porosity, permeability, swelling pressure and pathways formation threshold depend on the water saturation. The model is validated on different gas injection experiments with controlled flow rate and controlled pressure. Some experiments are well known in the literature; some are new. In each case, an inverse approach is used to identify the model parameters. The results confirm that, depending on the type of bentonite (MX80, Avonlea, KunigelV1), modelling the gas migration could require the existence of a pressureinduced saturation-depending preferential pathway. In laboratory-scale experiments, the model leads to an accurate evaluation of the long-term gas migration trends, including not just the gas migration stage but also the water re-saturation level. In a field-scale experiment, the behaviour of the model in a realistic context is revealed.

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Laboratory gas injection tests of compacted bentonite buffer material for TRU waste disposal

Namiki¹,

Asano²,

Takahashi

et al. 2014

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The Radioactive Waste Management Funding and Research Center (RWMC) is leading a research programme to evaluate the gas transport mechanisms through a TRU (TRans-Uranium) waste disposal facility in Japan and acquire information on gas migration properties. In this paper we describe a series of laboratory gas injection tests using the bentonite adopted for use in Japanese TRU disposal, as well as an attempted visualization of the gas migration path inside the bentonite used as a buffer. By building a conceptual model from the results of these tests, the characteristics of gas migration through to breakthrough for bentonite can now be better understood in the context of Japanese TRU disposal. Thanks to the outcome of this research project, advanced knowledge may be applied to the conceptualization of TRU waste disposal.

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Development of a New Prediction Method of Rock Mass Stability Based on the Results of the Back Analysis During Excavation

Takeuchi¹,

Shimura²,

Akutagawa³

et al. 2002

Doboku Gakkai Ronbunshu

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Buffer Construction Technique Using Granular Bentonite

Masuda¹,

Asano²,

TOGURI³

et al. 2007

J. Nucl. Sci. Technol.

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Back Analysis to Model Out Rock Mass Behaviour Due to Inhomogeneity and Its Application to Cavern Construction

Takeuchi¹,

Shimura²,

Akutagawa³

et al. 2000

Doboku Gakkai Ronbunshu

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