An implicit integral formulation for the modeling of inviscid fluid flows in domains containing obstacles

Clément Colas; Martin Ferrand; Jean Marc Hérard; Erwan Le Coupanec; Xavier Martin

doi:10.1007/978-3-319-57394-6_6

An implicit integral formulation for the modeling of inviscid fluid flows in domains containing obstacles

Clément Colas
, Martin Ferrand
, Jean Marc Hérard
, Erwan Le Coupanec
, Xavier Martin

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

Abstract

We focus here on an integral approach to compute compressible inviscid fluid flows in physical domains cluttered up with many small obstacles. This approach is based on a multidimensional porous integral formulation of Euler system of equations. Its discretization uses a first order semi-implicit finite volume scheme with pressure-correction algorithm preserving the positivity of both density and pressure. Numerical tests are completed by simulating a 2D channel flow containing two aligned tubes. The results are compared to reference solutions obtained with a pure fluid approach on a fine mesh.

Original language	English
Title of host publication	Finite Volumes for Complex Applications VIII— Hyperbolic, Elliptic and Parabolic Problems - FVCA8 2017
Editors	Pascal Omnes, Clement Cances
Publisher	Springer New York LLC
Pages	53-61
Number of pages	9
ISBN (Print)	9783319573939
DOIs	https://doi.org/10.1007/978-3-319-57394-6_6
Publication status	Published - 1 Jan 2017
Externally published	Yes
Event	8th International Symposium on Finite Volumes for Complex Applications - Hyperbolic, Elliptic and Parabolic Problems, FVCA8 2017 - Lille, France Duration: 12 Jun 2017 → 16 Jun 2017

Publication series

Name	Springer Proceedings in Mathematics and Statistics
Volume	200
ISSN (Print)	2194-1009
ISSN (Electronic)	2194-1017

Conference

Conference	8th International Symposium on Finite Volumes for Complex Applications - Hyperbolic, Elliptic and Parabolic Problems, FVCA8 2017
Country/Territory	France
City	Lille
Period	12/06/17 → 16/06/17

Keywords

Compressible flow
Finite volumes
Integral formulation
Porous media

Access to Document

10.1007/978-3-319-57394-6_6

Cite this

Colas, C., Ferrand, M., Hérard, J. M., Coupanec, E. L., & Martin, X. (2017). An implicit integral formulation for the modeling of inviscid fluid flows in domains containing obstacles. In P. Omnes, & C. Cances (Eds.), Finite Volumes for Complex Applications VIII— Hyperbolic, Elliptic and Parabolic Problems - FVCA8 2017 (pp. 53-61). (Springer Proceedings in Mathematics and Statistics; Vol. 200). Springer New York LLC. https://doi.org/10.1007/978-3-319-57394-6_6

Colas, Clément ; Ferrand, Martin ; Hérard, Jean Marc et al. / An implicit integral formulation for the modeling of inviscid fluid flows in domains containing obstacles. Finite Volumes for Complex Applications VIII— Hyperbolic, Elliptic and Parabolic Problems - FVCA8 2017. editor / Pascal Omnes ; Clement Cances. Springer New York LLC, 2017. pp. 53-61 (Springer Proceedings in Mathematics and Statistics).

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title = "An implicit integral formulation for the modeling of inviscid fluid flows in domains containing obstacles",

abstract = "We focus here on an integral approach to compute compressible inviscid fluid flows in physical domains cluttered up with many small obstacles. This approach is based on a multidimensional porous integral formulation of Euler system of equations. Its discretization uses a first order semi-implicit finite volume scheme with pressure-correction algorithm preserving the positivity of both density and pressure. Numerical tests are completed by simulating a 2D channel flow containing two aligned tubes. The results are compared to reference solutions obtained with a pure fluid approach on a fine mesh.",

keywords = "Compressible flow, Finite volumes, Integral formulation, Porous media",

author = "Cl{\'e}ment Colas and Martin Ferrand and H{\'e}rard, \{Jean Marc\} and Coupanec, \{Erwan Le\} and Xavier Martin",

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Colas, C, Ferrand, M, Hérard, JM, Coupanec, EL & Martin, X 2017, An implicit integral formulation for the modeling of inviscid fluid flows in domains containing obstacles. in P Omnes & C Cances (eds), Finite Volumes for Complex Applications VIII— Hyperbolic, Elliptic and Parabolic Problems - FVCA8 2017. Springer Proceedings in Mathematics and Statistics, vol. 200, Springer New York LLC, pp. 53-61, 8th International Symposium on Finite Volumes for Complex Applications - Hyperbolic, Elliptic and Parabolic Problems, FVCA8 2017, Lille, France, 12/06/17. https://doi.org/10.1007/978-3-319-57394-6_6

An implicit integral formulation for the modeling of inviscid fluid flows in domains containing obstacles. / Colas, Clément; Ferrand, Martin; Hérard, Jean Marc et al.
Finite Volumes for Complex Applications VIII— Hyperbolic, Elliptic and Parabolic Problems - FVCA8 2017. ed. / Pascal Omnes; Clement Cances. Springer New York LLC, 2017. p. 53-61 (Springer Proceedings in Mathematics and Statistics; Vol. 200).

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

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AU - Colas, Clément

AU - Ferrand, Martin

AU - Hérard, Jean Marc

AU - Coupanec, Erwan Le

AU - Martin, Xavier

N1 - Publisher Copyright: © Springer International Publishing AG 2017.

PY - 2017/1/1

Y1 - 2017/1/1

N2 - We focus here on an integral approach to compute compressible inviscid fluid flows in physical domains cluttered up with many small obstacles. This approach is based on a multidimensional porous integral formulation of Euler system of equations. Its discretization uses a first order semi-implicit finite volume scheme with pressure-correction algorithm preserving the positivity of both density and pressure. Numerical tests are completed by simulating a 2D channel flow containing two aligned tubes. The results are compared to reference solutions obtained with a pure fluid approach on a fine mesh.

AB - We focus here on an integral approach to compute compressible inviscid fluid flows in physical domains cluttered up with many small obstacles. This approach is based on a multidimensional porous integral formulation of Euler system of equations. Its discretization uses a first order semi-implicit finite volume scheme with pressure-correction algorithm preserving the positivity of both density and pressure. Numerical tests are completed by simulating a 2D channel flow containing two aligned tubes. The results are compared to reference solutions obtained with a pure fluid approach on a fine mesh.

KW - Compressible flow

KW - Finite volumes

KW - Integral formulation

KW - Porous media

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BT - Finite Volumes for Complex Applications VIII— Hyperbolic, Elliptic and Parabolic Problems - FVCA8 2017

A2 - Omnes, Pascal

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T2 - 8th International Symposium on Finite Volumes for Complex Applications - Hyperbolic, Elliptic and Parabolic Problems, FVCA8 2017

Y2 - 12 June 2017 through 16 June 2017

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Colas C, Ferrand M, Hérard JM, Coupanec EL, Martin X. An implicit integral formulation for the modeling of inviscid fluid flows in domains containing obstacles. In Omnes P, Cances C, editors, Finite Volumes for Complex Applications VIII— Hyperbolic, Elliptic and Parabolic Problems - FVCA8 2017. Springer New York LLC. 2017. p. 53-61. (Springer Proceedings in Mathematics and Statistics). doi: 10.1007/978-3-319-57394-6_6

An implicit integral formulation for the modeling of inviscid fluid flows in domains containing obstacles

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