Nonlinear Finite-Volume Scheme for Complex Flow Processes on Corner-Point Grids
M. Schneider, D. Gläser, B. Flemisch, and R. Helmig. Finite Volumes for Complex Applications VIII - Hyperbolic, Elliptic and Parabolic Problems, page 417-425. Cham, Springer International Publishing, (2017)
Abstract
The numericalSchneider, Martinsimulation ofGläser, Dennissubsurface processesHelmig, Rainerrequires efficientFlemisch, Berndand robust methods due to the large scales and the complex geometries involved. In this article, a nonlinear finite-volume scheme is presented and applied to non-isothermal two-phase two-component flow in porous media. The idea of the scheme and the model used for the simulations are outlined and a comparison to a standard scheme used in industrial codes is made. Large-scale offshore CO\$\$\_2\$\$storage in the Johansen formation serves as a benchmark problem, where it is demonstrated that the new scheme can handle highly complex corner-point grids and reproduces the physical processes with a higher accuracy than the standard discretization scheme.
%0 Conference Paper
%1 10.1007/978-3-319-57394-6_44
%A Schneider, Martin
%A Gläser, Dennis
%A Flemisch, Bernd
%A Helmig, Rainer
%B Finite Volumes for Complex Applications VIII - Hyperbolic, Elliptic and Parabolic Problems
%C Cham
%D 2017
%E Cancès, Clément
%E Omnes, Pascal
%I Springer International Publishing
%K EXC310 curated
%P 417-425
%T Nonlinear Finite-Volume Scheme for Complex Flow Processes on Corner-Point Grids
%X The numericalSchneider, Martinsimulation ofGläser, Dennissubsurface processesHelmig, Rainerrequires efficientFlemisch, Berndand robust methods due to the large scales and the complex geometries involved. In this article, a nonlinear finite-volume scheme is presented and applied to non-isothermal two-phase two-component flow in porous media. The idea of the scheme and the model used for the simulations are outlined and a comparison to a standard scheme used in industrial codes is made. Large-scale offshore CO\$\$\_2\$\$storage in the Johansen formation serves as a benchmark problem, where it is demonstrated that the new scheme can handle highly complex corner-point grids and reproduces the physical processes with a higher accuracy than the standard discretization scheme.
%@ 978-3-319-57394-6
@inproceedings{10.1007/978-3-319-57394-6_44,
abstract = {The numericalSchneider, Martinsimulation ofGläser, Dennissubsurface processesHelmig, Rainerrequires efficientFlemisch, Berndand robust methods due to the large scales and the complex geometries involved. In this article, a nonlinear finite-volume scheme is presented and applied to non-isothermal two-phase two-component flow in porous media. The idea of the scheme and the model used for the simulations are outlined and a comparison to a standard scheme used in industrial codes is made. Large-scale offshore CO{\$}{\$}{\_}2{\$}{\$}storage in the Johansen formation serves as a benchmark problem, where it is demonstrated that the new scheme can handle highly complex corner-point grids and reproduces the physical processes with a higher accuracy than the standard discretization scheme.},
added-at = {2024-01-11T14:28:06.000+0100},
address = {Cham},
author = {Schneider, Martin and Gläser, Dennis and Flemisch, Bernd and Helmig, Rainer},
biburl = {https://puma.ub.uni-stuttgart.de/bibtex/24755a9c906c93f967337b44bc7fa6855/simtech},
booktitle = {Finite Volumes for Complex Applications VIII - Hyperbolic, Elliptic and Parabolic Problems},
editor = {Cancès, Clément and Omnes, Pascal},
interhash = {7be6c6df51167b9684ca94061eb06570},
intrahash = {4755a9c906c93f967337b44bc7fa6855},
isbn = {978-3-319-57394-6},
keywords = {EXC310 curated},
pages = {417-425},
publisher = {Springer International Publishing},
timestamp = {2024-02-26T18:00:29.000+0100},
title = {Nonlinear Finite-Volume Scheme for Complex Flow Processes on Corner-Point Grids},
year = 2017
}
