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Towards improved understanding of spontaneous imbibition into dry porous media using pore-scale direct numerical simulations

Luka Malenica, Zhidong Zhang, Ueli Angst

2024Advances in Water Resources12 citationsDOIOpen Access PDF

Abstract

Traditional approaches to mathematically describe spontaneous imbibition are usually based on either macro-scale models, such as Richards equation, or simplified pore-scale models, such as the bundle of capillary tubes (BCTM) or pore-network modeling (PNM). It is well known that such models cannot provide full microscopic details of the multiphase flow processes and that many pore-scale mechanisms still lack proper mathematical descriptions. To improve the predictive capabilities of traditional models, a fundamental understanding of pore-scale dynamics is needed. The focus of this paper is obtaining detailed insight and consistent explanation of particular processes during capillary-controlled water imbibition into dry porous media. We use two-dimensional model geometries and perform fully dynamic volume-of-fluid based direct numerical simulations of air–water multiphase flow at the pore-scale, to study processes that generally are not considered in traditional models. More specifically, we investigate differences between converging and diverging geometries, dynamic pressure and meniscus reconfiguration during pore-filling events, and the influence of inertia and pore size on imbibition dynamics and the occurrence of capillary barriers. Furthermore, we perform a detailed comparison between non-interacting and interacting BCTM and study the impact of the narrow contractions on imbibition dynamics and the trapping of the non-wetting phase. Obtained knowledge can be used to improve predictive models, which are broadly relevant considering the importance of spontaneous imbibition in many different natural and industrial processes. • Investigating pore-level processes through direct numerical simulations of air–water multiphase flow. • Insight into dynamic pressure distribution, complex interface reconfigurations, and inertial effects during pore-filling. • Influence of cross-flow and narrow contractions on imbibition difference between wide and narrow capillaries. • Suggestions for possible enhancement of pore-network and bundle of capillary tube models.

Topics & Concepts

ImbibitionPorous mediumMaterials scienceScale (ratio)PorosityGeotechnical engineeringMechanicsPetroleum engineeringEnvironmental scienceGeologyComposite materialPhysicsQuantum mechanicsBiologyBotanyGerminationEnhanced Oil Recovery TechniquesLattice Boltzmann Simulation StudiesDrilling and Well Engineering