M. A. Endo Kokubun scite author profile

We study a heuristic, core-scale model for the transport of polymer particles in a two phase (oil and water) porous medium. We are motivated by recent experimental observations which report increased oil recovery when polymers are injected after the initial waterflood. The recovery mechanism is believed to be microscopic diversion of the flow, where injected particles can accumulate in narrow pore throats and clog it, in a process known as a log-jamming effect. The blockage of the narrow pore channels lead to a microscopic diversion of the water flow, causing a redistribution of the local pressure, which again can lead to the mobilization of trapped oil, enhancing its recovery. Our objective herein is to develop a core-scale model that is consistent with the observed production profiles. We show that previously obtained experimental results can be qualitatively explained by a simple two-phase flow model with an additional transport equation

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An analytical approach for a Hiemenz flow in a porous medium with heat exchange

Kokubun

Fachini

2011

International Journal of Heat and Mass Transfer

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Singularity of a Combustion Wave Profile: A Clue to the MultiComponent Theory for Liquid-Gas Filtration

Kokubun¹,

Mailybaev²

2017

SIAM J. Appl. Math.

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Stabilization and extinction of diffusion flames in an inert porous medium

Kokubun

Fachini

Matalon

2017

Proceedings of the Combustion Institute

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A pore-scale study of transport of inertial particles by water in porous media

Kokubun

Muntean

Radu

et al. 2019

Chemical Engineering Science

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We study the transport of inertial particles in water flow in porous media. Our interest lies in understanding the accumulation of particles including the possibility of clogging. We propose that accumulation can be a result of hydrodynamic effects: the tortuous paths of the porous medium generate regions of dominating strain/vorticity, which favour the accumulation/dispersion of the inertial particles. Numerical simulations show that essentially two accumulation regimes are identified: for low and for high flow velocities. When particles accumulate in high-velocity regions, at the entrance of a pore throat, a clog is formed. The formation of a clog significantly modifies the flow, as the partial blockage of the pore causes a local redistribution of pressure. This redistribution can divert the upstream water flow into neighbouring pores. Moreover, we show that accumulation in high velocity regions occurs in heterogeneous media, but not in homogeneous media, where we refer to homogeneity with respect to the distribution of the pore throat diameters. *

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M. A. Endo Kokubun

Transport of Polymer Particles in Oil–Water Flow in Porous Media: Enhancing Oil Recovery

An analytical approach for a Hiemenz flow in a porous medium with heat exchange

Singularity of a Combustion Wave Profile: A Clue to the MultiComponent Theory for Liquid-Gas Filtration

Stabilization and extinction of diffusion flames in an inert porous medium

A pore-scale study of transport of inertial particles by water in porous media

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