Coupled deformation–flow analysis for methane hydrate extraction

Methane hydrate is estimated to be present in substantial amounts below deep sea floors. Particular scientific and engineering interests that encourage studies of mechanical behaviour of methane hydrate soils include submarine geohazards, such as the initiation of marine landslides through hydrate d...

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Published in:Géotechnique
Main Authors: KLAR, A., SOGA, K., NG, M.Y.A.
Format: Article in Journal/Newspaper
Language:English
Published: Thomas Telford Ltd. 2010
Subjects:
Methane hydrate
Online Access:http://dx.doi.org/10.1680/geot.9.p.079-3799
https://www.icevirtuallibrary.com/doi/pdf/10.1680/geot.9.P.079-3799
id crtelford:10.1680/geot.9.p.079-3799
record_format openpolar
spelling crtelford:10.1680/geot.9.p.079-3799 2024-10-20T14:10:10+00:00 Coupled deformation–flow analysis for methane hydrate extraction KLAR, A. SOGA, K. NG, M.Y.A. 2010 http://dx.doi.org/10.1680/geot.9.p.079-3799 https://www.icevirtuallibrary.com/doi/pdf/10.1680/geot.9.P.079-3799 en eng Thomas Telford Ltd. Géotechnique volume 60, issue 10, page 765-776 ISSN 0016-8505 1751-7656 journal-article 2010 crtelford https://doi.org/10.1680/geot.9.p.079-3799 2024-09-27T04:15:43Z Methane hydrate is estimated to be present in substantial amounts below deep sea floors. Particular scientific and engineering interests that encourage studies of mechanical behaviour of methane hydrate soils include submarine geohazards, such as the initiation of marine landslides through hydrate dissociation, wellbore stability and estimation of future gas production from wells. To study these problems, a formulation of a multi-physics model of methane hydrate flow coupled to soil deformation is developed. By assuming deformable porous media (soil matrix) that accommodate non-movable but dissociable hydrate, a two-phase flow formulation of water and methane gas is suggested according to Darcy's law and capillary pressure law. A single-phase elastic–perfectly plastic constitutive model for hydrate soil sediments, based on the concept of effective stress, is developed to account for the effect of hydrate saturation on mechanical strength and stiffness. The formulation is incorporated into the explicit scheme of finite-difference code FLAC by solving three boundary value problems in parallel. The code is used to simulate the behaviour of horizontal unsupported and supported wells in hydrate-bearing sediments under different in situ stress conditions during methane hydrate extraction. Axial force, bending moment and well displacements were compared for supported and unsupported wells. Article in Journal/Newspaper Methane hydrate ICE Virtual Library (ICE Publishing) Géotechnique 60 10 765 776
institution Open Polar
collection ICE Virtual Library (ICE Publishing)
op_collection_id crtelford
language English
description Methane hydrate is estimated to be present in substantial amounts below deep sea floors. Particular scientific and engineering interests that encourage studies of mechanical behaviour of methane hydrate soils include submarine geohazards, such as the initiation of marine landslides through hydrate dissociation, wellbore stability and estimation of future gas production from wells. To study these problems, a formulation of a multi-physics model of methane hydrate flow coupled to soil deformation is developed. By assuming deformable porous media (soil matrix) that accommodate non-movable but dissociable hydrate, a two-phase flow formulation of water and methane gas is suggested according to Darcy's law and capillary pressure law. A single-phase elastic–perfectly plastic constitutive model for hydrate soil sediments, based on the concept of effective stress, is developed to account for the effect of hydrate saturation on mechanical strength and stiffness. The formulation is incorporated into the explicit scheme of finite-difference code FLAC by solving three boundary value problems in parallel. The code is used to simulate the behaviour of horizontal unsupported and supported wells in hydrate-bearing sediments under different in situ stress conditions during methane hydrate extraction. Axial force, bending moment and well displacements were compared for supported and unsupported wells.
format Article in Journal/Newspaper
author KLAR, A.
SOGA, K.
NG, M.Y.A.
spellingShingle KLAR, A.
SOGA, K.
NG, M.Y.A.
Coupled deformation–flow analysis for methane hydrate extraction
author_facet KLAR, A.
SOGA, K.
NG, M.Y.A.
author_sort KLAR, A.
title Coupled deformation–flow analysis for methane hydrate extraction
title_short Coupled deformation–flow analysis for methane hydrate extraction
title_full Coupled deformation–flow analysis for methane hydrate extraction
title_fullStr Coupled deformation–flow analysis for methane hydrate extraction
title_full_unstemmed Coupled deformation–flow analysis for methane hydrate extraction
title_sort coupled deformation–flow analysis for methane hydrate extraction
publisher Thomas Telford Ltd.
publishDate 2010
url http://dx.doi.org/10.1680/geot.9.p.079-3799
https://www.icevirtuallibrary.com/doi/pdf/10.1680/geot.9.P.079-3799
genre Methane hydrate
genre_facet Methane hydrate
op_source Géotechnique
volume 60, issue 10, page 765-776
ISSN 0016-8505 1751-7656
op_doi https://doi.org/10.1680/geot.9.p.079-3799
container_title Géotechnique
container_volume 60
container_issue 10
container_start_page 765
op_container_end_page 776
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