A stochastic model for filtration of particulate suspensions with incomplete pore plugging

Shapiro, Alexander; Bedrikovetsky, Pavel; Santos, A.; Medvedev, Oleg O.

doi:10.1007/s11242-006-0029-5

Cited by 53 publications

(57 citation statements)

References 24 publications

(4 reference statements)

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“…It is, therefore, advisable to use . (13) and (14). In order to evaluate uncertainties in the values of critical retention concentrations derived from the models (13) and (14), u(σ model cr ), it is necessary to know uncertainties in the parameters of these models.…”

Section: A Evaluation Of Uncertainty For Extrapolated Resultsmentioning

confidence: 99%

“…The drag coefficient was adopted as 21 via fitting equation (14) to the experimental critical retention concentration data. Applying formula (3) to (17) Table III).…”

Section: A Evaluation Of Uncertainty For Extrapolated Resultsmentioning

confidence: 99%

“…Applying formula (3) to (17) Table III). Model (14) represents experimental σ cr = σ cr (U)-data less accurately than model (13) due to the presence in Eq. (14) of the attractive electrostatic force, whose value and uncertainty cannot be reliably established due to unavailability of dielectric data.…”

Section: A Evaluation Of Uncertainty For Extrapolated Resultsmentioning

confidence: 99%

“…Analysis of model (14) shows that when U = 0 m/s, then, σ model cr = (1 − φ c )φ, meaning that the critical retention concentration depends only on cake and filter porosities. Filter porosity is measured experimentally with the appropriately calculated uncertainty.…”

Section: B Evaluation Of Uncertainty For Particle Attachment Modelmentioning

confidence: 99%

“…Theoretical models for different particle capture mechanisms have been developed and represent the respective experimental data with various degrees of agreement. [12][13][14][15] However, according to Al-Abduwani et al, 16 validation of such models via different experimental methods is limited. Additionally, unavailability of uncertainty analyses for models describing suspension transport in porous media and limited information about uncertainties for the respective experimental data makes validation of such models difficult.…”

Section: Introductionmentioning

confidence: 99%

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Critical analysis of uncertainties during particle filtration

Badalyan

Carageorgos

Bedrikovetsky

et al. 2012

Review of Scientific Instruments

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Using the law of propagation of uncertainties we show how equipment- and measurement-related uncertainties contribute to the overall combined standard uncertainties (CSU) in filter permeability and in modelling the results for polystyrene latex microspheres filtration through a borosilicate glass filter at various injection velocities. Standard uncertainties in dynamic viscosity and volumetric flowrate of microspheres suspension have the greatest influence on the overall CSU in filter permeability which excellently agrees with results obtained from Monte Carlo simulations. Two model parameters “maximum critical retention concentration” and “minimum injection velocity” and their uncertainties were calculated by fitting two quadratic mathematical models to the experimental data using a weighted least squares approximation. Uncertainty in the internal cake porosity has the highest impact on modelling uncertainties in critical retention concentration. The model with the internal cake porosity reproduces experimental “critical retention concentration vs velocity”-data better than the second model which contains the total electrostatic force whose value and uncertainty have not been reliably calculated due to the lack of experimental dielectric data.

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Section: A Evaluation Of Uncertainty For Extrapolated Resultsmentioning

confidence: 99%

“…The drag coefficient was adopted as 21 via fitting equation (14) to the experimental critical retention concentration data. Applying formula (3) to (17) Table III).…”

Section: A Evaluation Of Uncertainty For Extrapolated Resultsmentioning

confidence: 99%

Section: A Evaluation Of Uncertainty For Extrapolated Resultsmentioning

confidence: 99%

Section: B Evaluation Of Uncertainty For Particle Attachment Modelmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Critical analysis of uncertainties during particle filtration

Badalyan

Carageorgos

Bedrikovetsky

et al. 2012

Review of Scientific Instruments

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Depressurization‐Induced Fines Migration in Sediments Containing Methane Hydrate: X‐Ray Computed Tomography Imaging Experiments

et al. 2018

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Depressurization of hydrate‐bearing sediments (HBS) can cause the movement of fine particles, and in turn, such fines migration affects fluid flow and mechanical behavior of sediments, ultimately affecting long‐term hydrocarbon production and wellbore stability. This study investigated how and to what extent depressurization of HBS causes fines migration using X‐ray computed tomography (CT) imaging. Methane hydrate was synthesized in sediments with 10% fines content (FC), composed of sands with silt and/or clay, and the hydrate‐bearing samples were stepwisely depressurized while acquiring CT images. The CT images were analyzed to quantify the spatial changes in FC in the host sediment and thus to capture the fines migration during depressurization. It was found that the FC changes began occurring from the hydrate dissociation regions. This confirms that the multiphase flow caused by depressurization accompanies fines migration. Depressurization of HBS with a hydrate saturation of ~20–40% caused FC reduction from ~10% to ~6–9%, and the extent of fines migration differed with the particle sizes of the host sands and the types of fines. It was found that fines migration was more pronounced with coarse sands and with silty fines. Such observed level of FC reduction is estimated to increase sediment permeability by several factors based on the Kozeny‐type permeability model. Our results support the notion that the extent of fines migration and its effect on fluid flow behavior need to be assessed in consideration of physical properties of host sediment and fine particles to identify optimum depressurization strategies.

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Simulation of deformable preformed particle gel propagation in porous media

et al. 2017

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Preformed particle gel (PPG) treatment is a proven cost‐effective method for improving oil recovery. Although PPG system has a suspension‐like property, it has different propagation rules from the rigid particle suspension in porous media because of its good deformation property. In this study, an advanced phenomenological model of PPG propagation in porous media is presented. The model includes both PPG plugging and restarting behaviors. Log‐normal and normal distribution functions have been introduced in this model to calculate the PPG plugging probability. Power‐law equation is used to calculate the PPG restarting rate. This method can represent the commensurate relation between PPG and throat size. Then, the equations are solved numerically, using an explicit finite‐difference formulation in conjunction with a fourth‐order Runge‐Kutta method. The results match favorably with several laboratory experiments. Finally, the propagation rules and sensitivity analysis of PPG size, permeability and injection rate to propagation rules, and permeability reduction are performed. © 2017 American Institute of Chemical Engineers AIChE J, 63: 4628–4641, 2017

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A stochastic model for filtration of particulate suspensions with incomplete pore plugging

Cited by 53 publications

References 24 publications

Critical analysis of uncertainties during particle filtration

Critical analysis of uncertainties during particle filtration

Depressurization‐Induced Fines Migration in Sediments Containing Methane Hydrate: X‐Ray Computed Tomography Imaging Experiments

Simulation of deformable preformed particle gel propagation in porous media

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