Coupled free-flow and porous-medium systems appear in a variety of industrial and environmental applications. Fluid flow in the free-flow domain is typically described by the (Navier–)Stokes equations while Darcy’s law is applied in the porous medium. The correct choice of coupling conditions on the fluid–porous interface is crucial for accurate numerical simulations of coupled problems. We found out that the Beavers–Joseph interface condition, which is widely used not only for fluid flow parallel to the porous layer but also for filtration problems, is unsuitable for arbitrary flow directions. To validate our statement, we provide several examples and compare numerical simulation results for the coupled Stokes–Darcy problems to the pore-scale resolved models. We show also that the Beavers–Joseph parameter cannot be fitted for arbitrary flow directions.
%0 Journal Article
%1 eggenweiler2020unsuitability
%A Eggenweiler, Elissa
%A Rybak, Iryna
%B Journal of Fluid Mechanics
%D 2020
%I Cambridge University Press
%K pa-a rp-a3 sfb1313
%P A10
%R DOI: 10.1017/jfm.2020.194
%T Unsuitability of the Beavers–Joseph interface condition for filtration problems
%U https://www.cambridge.org/core/article/unsuitability-of-the-beaversjoseph-interface-condition-for-filtration-problems/65DA6D26BB4A78322AA29EF403670EE6
%V 892
%X Coupled free-flow and porous-medium systems appear in a variety of industrial and environmental applications. Fluid flow in the free-flow domain is typically described by the (Navier–)Stokes equations while Darcy’s law is applied in the porous medium. The correct choice of coupling conditions on the fluid–porous interface is crucial for accurate numerical simulations of coupled problems. We found out that the Beavers–Joseph interface condition, which is widely used not only for fluid flow parallel to the porous layer but also for filtration problems, is unsuitable for arbitrary flow directions. To validate our statement, we provide several examples and compare numerical simulation results for the coupled Stokes–Darcy problems to the pore-scale resolved models. We show also that the Beavers–Joseph parameter cannot be fitted for arbitrary flow directions.
@article{eggenweiler2020unsuitability,
abstract = {Coupled free-flow and porous-medium systems appear in a variety of industrial and environmental applications. Fluid flow in the free-flow domain is typically described by the (Navier–)Stokes equations while Darcy’s law is applied in the porous medium. The correct choice of coupling conditions on the fluid–porous interface is crucial for accurate numerical simulations of coupled problems. We found out that the Beavers–Joseph interface condition, which is widely used not only for fluid flow parallel to the porous layer but also for filtration problems, is unsuitable for arbitrary flow directions. To validate our statement, we provide several examples and compare numerical simulation results for the coupled Stokes–Darcy problems to the pore-scale resolved models. We show also that the Beavers–Joseph parameter cannot be fitted for arbitrary flow directions.},
added-at = {2020-04-02T12:55:50.000+0200},
author = {Eggenweiler, Elissa and Rybak, Iryna},
biburl = {https://puma.ub.uni-stuttgart.de/bibtex/2895031b32cce8f7b076f3b5d0268a3a9/sfb1313-puma},
booktitle = {Journal of Fluid Mechanics},
doi = {DOI: 10.1017/jfm.2020.194},
interhash = {c5e9b2d502fd629c4bf7da660214a254},
intrahash = {895031b32cce8f7b076f3b5d0268a3a9},
issn = {00221120},
keywords = {pa-a rp-a3 sfb1313},
pages = {A10},
publisher = {Cambridge University Press},
timestamp = {2020-05-28T09:07:41.000+0200},
title = {Unsuitability of the Beavers–Joseph interface condition for filtration problems},
url = {https://www.cambridge.org/core/article/unsuitability-of-the-beaversjoseph-interface-condition-for-filtration-problems/65DA6D26BB4A78322AA29EF403670EE6},
volume = 892,
year = 2020
}