Multi-scale three-domain approach for coupling free flow and flow in porous media including droplet-related interface processes

Drops on a free-flow/porous-medium-flow interface have a strong influence on the exchange of mass, momentum and energy between the two macroscopic flow regimes. Modeling droplet-related pore-scale processes in a macro-scale context is challenging due to the scale gap, but might be rewarding due to relatively low computational costs. We develop a three-domain approach to model drop formation, growth, detachment and film flow in a lower-dimensional interface domain. A simple upscaling technique allows to compute the drop-covered interface area fraction which affects the coupling fluxes. In a first scenario, only drop formation, growth and detachment are taken into account. Then, spreading and merging due to lateral fluxes are considered as well. The simulation results show that the impact of these droplet-related processes can be captured. However, extensions are necessary to represent the influence on the free flow more precisely. (C) 2020 Elsevier Inc. All rights reserved.

Automated summary

Drops on a free-flow/porous-medium-flow interface play a strong role in mass, momentum, and energy exchange between two macroscopic flow regimes. A three-domain approach has been developed to model droplet-related processes and compute the drop-covered interface area fraction that affects coupling fluxes. Further extensions are needed to more accurately represent the influence on free flow.