Application of the mixed multiscale finite element method to parallel simulations of two-phase flows in porous media

Application of the mixed multiscale finite element method to parallel simulations of two-phase flows in porous media

The Mixed Multiscale Finite Element method (MMsFE) is a promising alternative to traditional upscaling techniques in order to accelerate the simulation of flows in large heterogeneous porous media. Indeed, in this method, the calculation of the basis functions which encompass the fine-scale variatio...

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Main Authors: Puscas Maria Adela, Enchéry Guillaume, Desroziers Sylvain
Format: Article
Language:English
Published: EDP Sciences 2018-01-01
Series:Oil & Gas Science and Technology
Online Access:https://doi.org/10.2516/ogst/2018022
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spelling doaj-c58b2e1ad65340fa987e190582d799df2021-02-02T00:15:55ZengEDP SciencesOil & Gas Science and Technology1294-44751953-81892018-01-01733810.2516/ogst/2018022ogst180002Application of the mixed multiscale finite element method to parallel simulations of two-phase flows in porous mediaPuscas Maria AdelaEnchéry GuillaumeDesroziers SylvainThe Mixed Multiscale Finite Element method (MMsFE) is a promising alternative to traditional upscaling techniques in order to accelerate the simulation of flows in large heterogeneous porous media. Indeed, in this method, the calculation of the basis functions which encompass the fine-scale variations of the permeability field, can be performed in parallel and the size of the global linear system is reduced. However, we show in this work that a two-level MPI strategy should be used to adapt the calculation resources at these two steps of the algorithm and thus obtain a better scalability of the method. This strategy has been implemented for the resolution of the pressure equation which arises in two-phase flow models. Results of simulations performed on complex reservoir models show the benefits of this approach.https://doi.org/10.2516/ogst/2018022
collection DOAJ
language English
format Article
sources DOAJ
author Puscas Maria Adela
Enchéry Guillaume
Desroziers Sylvain
spellingShingle Puscas Maria Adela
Enchéry Guillaume
Desroziers Sylvain
Application of the mixed multiscale finite element method to parallel simulations of two-phase flows in porous media
Oil & Gas Science and Technology
author_facet Puscas Maria Adela
Enchéry Guillaume
Desroziers Sylvain
author_sort Puscas Maria Adela
title Application of the mixed multiscale finite element method to parallel simulations of two-phase flows in porous media
title_short Application of the mixed multiscale finite element method to parallel simulations of two-phase flows in porous media
title_full Application of the mixed multiscale finite element method to parallel simulations of two-phase flows in porous media
title_fullStr Application of the mixed multiscale finite element method to parallel simulations of two-phase flows in porous media
title_full_unstemmed Application of the mixed multiscale finite element method to parallel simulations of two-phase flows in porous media
title_sort application of the mixed multiscale finite element method to parallel simulations of two-phase flows in porous media
publisher EDP Sciences
series Oil & Gas Science and Technology
issn 1294-4475
1953-8189
publishDate 2018-01-01
description The Mixed Multiscale Finite Element method (MMsFE) is a promising alternative to traditional upscaling techniques in order to accelerate the simulation of flows in large heterogeneous porous media. Indeed, in this method, the calculation of the basis functions which encompass the fine-scale variations of the permeability field, can be performed in parallel and the size of the global linear system is reduced. However, we show in this work that a two-level MPI strategy should be used to adapt the calculation resources at these two steps of the algorithm and thus obtain a better scalability of the method. This strategy has been implemented for the resolution of the pressure equation which arises in two-phase flow models. Results of simulations performed on complex reservoir models show the benefits of this approach.
url https://doi.org/10.2516/ogst/2018022
work_keys_str_mv AT puscasmariaadela applicationofthemixedmultiscalefiniteelementmethodtoparallelsimulationsoftwophaseflowsinporousmedia
AT encheryguillaume applicationofthemixedmultiscalefiniteelementmethodtoparallelsimulationsoftwophaseflowsinporousmedia
AT desrozierssylvain applicationofthemixedmultiscalefiniteelementmethodtoparallelsimulationsoftwophaseflowsinporousmedia
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