Flow of Clay Suspensions through Porous Media

Baghdikian, S.Y.; Sharma, Man Mohan; Handy, L.L.

doi:10.2118/16257-ms

Cited by 8 publications

(1 citation statement)

References 7 publications

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“…The researchers have studied DBF experimentally [2][3][4][5][6] and most studies have reported the permeability reduction of the core samples versus time. For example, Baghdikian et al [6] injected clay suspensions in the Ottawa sand pack to study the effect of ionic strength, concentration, and flow rate of the injected fluid. Moghadasi et al [4] injected inert aluminum particles in a cylindrical porous media made from glass bead.…”

Section: Introductionmentioning

confidence: 99%

Application of pore network modeling in deep bed filtration analysis

et al. 2020

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Particle invasion in porous media is an important phenomenon that could lead to formation damage during different operations, such as waterflooding, workover, and drilling. In this paper, a 3D pore network model coupled with a particle tracking method was developed to investigate particle retention and permeability reduction of a pore network system. The proposed model considers the effect of hydraulic drag, gravity, and friction forces. Three mechanisms, including surface deposition, straining, and bridging, have been considered in the development of the proposed pore network model. The results of the proposed model show good agreement with experimental data. A sharp permeability reduction is observed in the early time of the injection, which indicates the blockage of the small radius throats by particles, as well as unstable fluid flow due to the distribution of the particles. Moreover, the number of throats with a small radius and different contributing mechanisms cause the discontinuous decrease of the porous media permeability. The proposed pore network modeling demonstrates that a small section of the pore network can reproduce the results of the experiment, and a big pore network that is too time and cost consuming is not required.

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Section: Introductionmentioning

confidence: 99%

Application of pore network modeling in deep bed filtration analysis

et al. 2020

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A network model for deep bed filtration processes

1987

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Equations for the deep bed filtration problem are obtained as a special case of a general model formulated earlier. The filtration coefficient X is expressed as an explicit function of system parameters such as fluid flow rate, pore density, and pore size distribution. For a unimodal pore size distribution it is found that X remains constant both in space and time. In general, however, Xis shown to decrease. Explicit solutions to the problem, including particle density profiles and permeability, are obtained for the two cases of large values of the coordination number Z (capillary tube model), and for a bimodal pore size distribution with a finite coordination number.

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A network model for deep bed filtration of solid particles and emulsion drops

1988

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A network model has been developed to simulate the flow of emulsions and solid particles through porous media. Particle deposition due to direct interception, as well pore plugging by straining are accounted for in the model. The effects of two important factors-the ratio of particle size to pore size, and the fluid velocity-on particle deposition are also investigated. The strength of the model lies in its ability to predict accurately effluent concentration profiles, permeability changes occurring during deep bed filtration, and the evolution of the filter coefficient with time. Model predictions for different particle and pore size distributions of both solid and emulsion particles are in agreement with experimental data. Vol. 34, No. 11 AIChE Journal Particle of Limitina traiectorv Flow in Parabolic velocity profile Figure 2. Particle capture probability is equivalent to fraction of total flow in annulus between R, and R, -@a.

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Flow of Clay Suspensions through Porous Media

Cited by 8 publications

References 7 publications

Application of pore network modeling in deep bed filtration analysis

Application of pore network modeling in deep bed filtration analysis

A network model for deep bed filtration processes

A network model for deep bed filtration of solid particles and emulsion drops

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