Darcy’s law for yield stress fluid flowing through a porous medium

Chevalier, Thibaud; Chevalier, Christophe; Clain, Xavier; Dupla, Jean Claude; Canou, Jean; Rodts, Stéphane; Coussot, Philippe

doi:10.1016/j.jnnfm.2012.12.005

Cited by 83 publications

(88 citation statements)

References 23 publications

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“…This gives the total flow rate Q as a function of pressure difference P across the length of the channel. Whatever the geometry of the channel, close to the pressure threshold P c , the flow rate scales like ( P − P c ) 2 with a prefactor function of the fluid and aperture properties.…”

Section: Resultsmentioning

confidence: 99%

“…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. Experimentally [2,9,19] they establish various laws which have quite essentially the same structure,…”

Section: Introductionmentioning

confidence: 96%

“…fluids that require that the applied stress is above a non-zero threshold-a yield stress-for flowing [1], are found in many practical applications, such as in oil industry. Indeed, emulsions [2], mud [3,4], heavy oil [5], polymeric gels such as carbopol [2] and foams [6] generate non-zero yield stress for flowing. In an oil recovery context, such fluids are injected to control premature production of water or gas.…”

Section: Introductionmentioning

confidence: 99%

“…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: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 96%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Effective rheology of Bingham fluids in a rough channel

2014

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“…Another analysis of one-dimensional flow within a two-dimensional network was considered by Chen et al (2005), but this was in the context of imbibition and the displacement of a Bingham fluid by a Newtonian fluid. We would also wish to draw the readers' attention to the papers by Chevalier et al (2013Chevalier et al ( , 2014, which report on the experimental determination of a suitable Darcy's law for HerschelBulkley fluids, and the paper by Bleyer and Coussot, which is concerned with the numerical modelling of a Bingham fluid through an array of circular cylinders. Entrance effects have also been considered by Philippou et al (2016).…”

Section: Introductionmentioning

confidence: 99%

The Effect of Microstructure on Models for the Flow of a Bingham Fluid in Porous Media: One-Dimensional Flows

Nash

Rees

2017

Transp Porous Med

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The Buckingham-Reiner models for the one-dimensional flow of a Bingham fluid along a uniform pipe or channel are well-known, but are modified here to cover much more general one-dimensional configurations. These include selections of channels with different widths, and five different probability density functions describing distributions of channel widths. It is found that the manner in which breakthrough occurs at the threshold pressure gradient depends very strongly on the type of distribution of pores and that a pseudo-threshold pressure gradient, which might be inferred from measurements of flow at relatively high pressure gradients, may be more than twice the magnitude of the true threshold gradient.

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Flow of yield stress and Carreau fluids through rough‐walled rock fractures: Prediction and experiments

Castro

Radilla

2017

Water Resources Research

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Many natural phenomena in geophysics and hydrogeology involve the flow of non‐Newtonian fluids through natural rough‐walled fractures. Therefore, there is considerable interest in predicting the pressure drop generated by complex flow in these media under a given set of boundary conditions. However, this task is markedly more challenging than the Newtonian case given the coupling of geometrical and rheological parameters in the flow law. The main contribution of this paper is to propose a simple method to predict the flow of commonly used Carreau and yield stress fluids through fractures. To do so, an expression relating the “in situ” shear viscosity of the fluid to the bulk shear‐viscosity parameters is obtained. Then, this “in situ” viscosity is entered in the macroscopic laws to predict the flow rate‐pressure gradient relations. Experiments with yield stress and Carreau fluids in two replicas of natural fractures covering a wide range of injection flow rates are presented and compared to the predictions of the proposed method. Our results show that the use of a constant shift parameter to relate “in situ” and bulk shear viscosity is no longer valid in the presence of a yield stress or a plateau viscosity. Consequently, properly representing the dependence of the shift parameter on the flow rate is crucial to obtain accurate predictions. The proposed method predicts the pressure drop in a rough‐walled fracture at a given injection flow rate by only using the shear rheology of the fluid, the hydraulic aperture of the fracture, and the inertial coefficients as inputs.

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Darcy’s law for yield stress fluid flowing through a porous medium

Cited by 83 publications

References 23 publications

Effective rheology of Bingham fluids in a rough channel

Effective rheology of Bingham fluids in a rough channel

The Effect of Microstructure on Models for the Flow of a Bingham Fluid in Porous Media: One-Dimensional Flows

Flow of yield stress and Carreau fluids through rough‐walled rock fractures: Prediction and experiments

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