Non-Newtonian flow in porous media

Sochi, Taha

doi:10.1016/j.polymer.2010.07.047

Cited by 233 publications

(209 citation statements)

References 113 publications

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“…Equation (26) is the approximation used e.g., by Roux and Herrmann [17] in their study of Bingham fluids in disordered networks. Since the effective pressure threshold, Equation (27) is proportional to the real threshold, it is still given by Equation (14). This justifies the approach of Roux and Herrmann [17].…”

Section: Bingham Flow In a Rough Channel: General Resultssupporting

confidence: 57%

“…There have been a number of experimental [2,9], numerical [10][11][12][13][14][15][16] and theoretical [17,18] studies of the flow of yield stress fluids in porous media. One of the main objective is to derive an generalized Darcy equation for yield stress fluids relating mean flow rate, the pressure gradient and a critical pressure gradient.…”

Section: Introductionmentioning

confidence: 99%

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Effective rheology of Bingham fluids in a rough channel

2014

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We derive the volumetric flow rate vs. pressure drop of a Bingham fluid in one-dimensional channels of variable apertures in the lubrication approximation. A characteristic length scale, a * characterizing the flow is introduced in order to distinguish between a high and a low flow rate regime. We illustrate the calculation for channels with periodically varying apertures. We then go on to consider apertures that are self affine. We determine how the scaling properties of the aperture field is reflected in the effective flow equations. Finally, a series expansion for high and low flow rates that works very well over the entire range of flow rates is proposed. This truncated expansion allows us to predict the domain of validity of the two expansions by comparing a * to the aperture distribution.

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Section: Bingham Flow In a Rough Channel: General Resultssupporting

confidence: 57%

Section: Introductionmentioning

confidence: 99%

Effective rheology of Bingham fluids in a rough channel

2014

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“…We therefore present a general background on this subject followed by a rather detailed account of one of the network models as an example. This is the model developed by Blunt and co-workers [66,67,68]. One reason for choosing this example is because it is a well developed model that incorporates the main features of network modeling in its current state.…”

Section: Pore-scale Network Modelingmentioning

confidence: 99%

Flow of non‐newtonian fluids in porous media

Sochi

2010

J Polym Sci B Polym Phys

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125

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The study of flow of non‐Newtonian fluids in porous media is very important and serves a wide variety of practical applications in processes such as enhanced oil recovery from underground reservoirs, filtration of polymer solutions and soil remediation through the removal of liquid pollutants. These fluids occur in diverse natural and synthetic forms and can be regarded as the rule rather than the exception. They show very complex strain and time dependent behavior and may have initial yield‐stress. Their common feature is that they do not obey the simple Newtonian relation of proportionality between stress and rate of deformation. Non‐Newtonian fluids are generally classified into three main categories: time‐independent whose strain rate solely depends on the instantaneous stress, time‐dependent whose strain rate is a function of both magnitude and duration of the applied stress and viscoelastic which shows partial elastic recovery on removal of the deforming stress and usually demonstrates both time and strain dependency. In this article, the key aspects of these fluids are reviewed with particular emphasis on single‐phase flow through porous media. The four main approaches for describing the flow in porous media are examined and assessed. These are: continuum models, bundle of tubes models, numerical methods and pore‐scale network modeling. © 2010 Wiley Periodicals, Inc. J Polym Sci Part B: Polym Phys, 2010

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“…The general strategy in network modeling is to use the rheology of the fluid and the void space description of the porous medium as an input to the model. The flow simulation in a network starts by modeling the flow in a single capillary and is subsequently extended to the network of capillaries, represented by a set of equations and satisfying mass conservation and momentum balance, which are solved simultaneously to find the pressure field and other relevant physical quantities (Sochi 2007). 4.…”

Section: Introductionmentioning

confidence: 99%

Microfluidic systems for the analysis of viscoelastic fluid flow phenomena in porous media

Galindo-Rosales

Campo-Deaño

Pinho

et al. 2011

Microfluid Nanofluid

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The Strathprints institutional repository (https://strathprints.strath.ac.uk) is a digital archive of University of Strathclyde research outputs. It has been developed to disseminate open access research outputs, expose data about those outputs, and enable the management and persistent access to Strathclyde's intellectual output. RESEARCH PAPERMicrofluidic systems for the analysis of viscoelastic fluid flow phenomena in porous media Abstract In this study, two microfluidic devices are proposed as simplified 1-D microfluidic analogues of a porous medium. The objectives are twofold: firstly to assess the usefulness of the microchannels to mimic the porous medium in a controlled and simplified manner, and secondly to obtain a better insight about the flow characteristics of viscoelastic fluids flowing through a packed bed. For these purposes, flow visualizations and pressure drop measurements are conducted with Newtonian and viscoelastic fluids. The 1-D microfluidic analogues of porous medium consisted of microchannels with a sequence of contractions/expansions disposed in symmetric and asymmetric arrangements. The real porous medium is in reality, a complex combination of the two arrangements of particles simulated with the microchannels, which can be considered as limiting ideal configurations. The results show that both configurations are able to mimic well the pressure drop variation with flow rate for Newtonian fluids. However, due to the intrinsic differences in the deformation rate profiles associated with each microgeometry, the symmetric configuration is more suitable for studying the flow of viscoelastic fluids at low De values, while the asymmetric configuration provides better results at high De values. In this way, both microgeometries seem to be complementary and could be interesting tools to obtain a better insight about the flow of viscoelastic fluids through a porous medium. Such model systems could be very interesting to use in polymer-flood processes for enhanced oil recovery, for instance, as a tool for selecting the most suitable viscoelastic fluid to be used in a specific formation. The selection of the fluid properties of a detergent for cleaning oil contaminated soil, sand, and in general, any porous material, is another possible application.

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Non-Newtonian flow in porous media

Cited by 233 publications

References 113 publications

Effective rheology of Bingham fluids in a rough channel

Effective rheology of Bingham fluids in a rough channel

Flow of non‐newtonian fluids in porous media

Microfluidic systems for the analysis of viscoelastic fluid flow phenomena in porous media

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