Combining finite element and finite volume methods for efficient multiphase flow simulations in highly heterogeneous and structurally complex geologic media

Sebastian Geiger; S. Roberts; S. K. Matthäi; C. Zoppou; A. Burri

doi:10.1111/j.1468-8123.2004.00093.x

Combining finite element and finite volume methods for efficient multiphase flow simulations in highly heterogeneous and structurally complex geologic media

Sebastian Geiger^*, S. Roberts, S. K. Matthäi, C. Zoppou, A. Burri

^*Corresponding author for this work

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

697 Citations (Scopus)

Abstract

The permeability of the Earth's crust commonly varies over many orders of magnitude. Flow velocity can range over several orders of magnitude in structures of interest that vary in scale from centimeters to kilometers. To accurately and efficiently model multiphase flow in geologic media, we introduce a fully conservative node-centered finite volume method coupled with a Galerkin finite element method on an unstructured triangular grid with a complementary finite volume subgrid. The effectiveness of this approach is demonstrated by comparison with traditional solution methods and by multiphase flow simulations for heterogeneous permeability fields including complex geometries that produce transport parameters and lengths scales varying over four orders of magnitude.

Original language	English
Pages (from-to)	284-299
Number of pages	16
Journal	geofluids
Volume	4
Issue number	4
DOIs	https://doi.org/10.1111/j.1468-8123.2004.00093.x
Publication status	Published - Nov 2004
Externally published	Yes

Keywords

Finite elements
Finite volumes
Fractures
Heterogeneity
Multiphase flow
Porous media
Total variation diminishing

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title = "Combining finite element and finite volume methods for efficient multiphase flow simulations in highly heterogeneous and structurally complex geologic media",

abstract = "The permeability of the Earth's crust commonly varies over many orders of magnitude. Flow velocity can range over several orders of magnitude in structures of interest that vary in scale from centimeters to kilometers. To accurately and efficiently model multiphase flow in geologic media, we introduce a fully conservative node-centered finite volume method coupled with a Galerkin finite element method on an unstructured triangular grid with a complementary finite volume subgrid. The effectiveness of this approach is demonstrated by comparison with traditional solution methods and by multiphase flow simulations for heterogeneous permeability fields including complex geometries that produce transport parameters and lengths scales varying over four orders of magnitude.",

keywords = "Finite elements, Finite volumes, Fractures, Heterogeneity, Multiphase flow, Porous media, Total variation diminishing",

author = "Sebastian Geiger and S. Roberts and Matth{\"a}i, {S. K.} and C. Zoppou and A. Burri",

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AU - Geiger, Sebastian

AU - Roberts, S.

AU - Matthäi, S. K.

AU - Zoppou, C.

AU - Burri, A.

PY - 2004/11

Y1 - 2004/11

N2 - The permeability of the Earth's crust commonly varies over many orders of magnitude. Flow velocity can range over several orders of magnitude in structures of interest that vary in scale from centimeters to kilometers. To accurately and efficiently model multiphase flow in geologic media, we introduce a fully conservative node-centered finite volume method coupled with a Galerkin finite element method on an unstructured triangular grid with a complementary finite volume subgrid. The effectiveness of this approach is demonstrated by comparison with traditional solution methods and by multiphase flow simulations for heterogeneous permeability fields including complex geometries that produce transport parameters and lengths scales varying over four orders of magnitude.

AB - The permeability of the Earth's crust commonly varies over many orders of magnitude. Flow velocity can range over several orders of magnitude in structures of interest that vary in scale from centimeters to kilometers. To accurately and efficiently model multiphase flow in geologic media, we introduce a fully conservative node-centered finite volume method coupled with a Galerkin finite element method on an unstructured triangular grid with a complementary finite volume subgrid. The effectiveness of this approach is demonstrated by comparison with traditional solution methods and by multiphase flow simulations for heterogeneous permeability fields including complex geometries that produce transport parameters and lengths scales varying over four orders of magnitude.

KW - Finite elements

KW - Finite volumes

KW - Fractures

KW - Heterogeneity

KW - Multiphase flow

KW - Porous media

KW - Total variation diminishing

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DO - 10.1111/j.1468-8123.2004.00093.x

M3 - Article

AN - SCOPUS:7244220036

SN - 1468-8115

VL - 4

SP - 284

EP - 299

JO - geofluids

JF - geofluids

IS - 4

ER -

Combining finite element and finite volume methods for efficient multiphase flow simulations in highly heterogeneous and structurally complex geologic media

Abstract

Keywords

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