Inertial Effects on Dynamics of Immiscible Viscous Fingering in Homogenous Porous Media

We present a comparative study of the onset and propagation dynamics of the fingering phenomenon in uniform porous media with a radial configuration. With the help of the Finite Element Method (FEM)-based 2D simulations and image processing techniques, we investigate finger morphology, growth rate,...

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Bibliographic Details
Published inFluids (Basel) Vol. 4; no. 2; p. 79
Main Authors Rabbani, Abderrahmane, Sassi
Format Journal Article
LanguageEnglish
Published Basel MDPI AG 01.06.2019
Subjects
Acceleration
Comparative studies
Enhanced oil recovery
Experiments
fingering
Finite element method
Flow geometry
Fluid dynamics
Fluid flow
Growth rate
High Reynolds number
hydrodynamic instability
Image processing
inertial effects
Interface stability
multiphase flow
Oil recovery
Porous media
porous media flow
Propagation
Radial flow
Reynolds number
Viscosity
Viscosity ratio
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Summary:We present a comparative study of the onset and propagation dynamics of the fingering phenomenon in uniform porous media with a radial configuration. With the help of the Finite Element Method (FEM)-based 2D simulations and image processing techniques, we investigate finger morphology, growth rate, interfacial length, finger length and the number of fingers which are affected due to inertial forces and convective acceleration in a two-phase porous media flow. We considered a modified Darcy’s law with inertial force coupled with convective acceleration and investigate their impact on interfacial instability with different velocity-viscosity combinations. Interestingly, the consequences of inertial corrections become significant with changes in viscosity at high Reynolds numbers. Due to the intrinsic bifurcation nature of inertial forces in the radial flow geometry, finger morphology is changed mostly at high viscosity ratios. We find that the effects of inertia and convective acceleration are markedly significant at relatively high Reynolds numbers while the interfacial length and the number of fingers—which are important parameters for Enhanced Oil Recovery (EOR)—are most affected by the neglecting of these forces. Moreover, at high Reynolds numbers, the rate of growth of fingering instabilities and the fractal number tend to deviate from that for Darcy’s law.
ISSN:2311-5521
2311-5521
DOI:10.3390/fluids4020079