Flow-driven compaction of a fibrous porous medium

Paterson, Daniel T.; Eaves, Tom S.; Hewitt, Duncan R.; Balmforth, N. J.; Martinez, D. Mark

doi:10.1103/physrevfluids.4.074306

Cited by 11 publications

(26 citation statements)

References 25 publications

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“…In steady state, mass conservation for each phase, Darcy's law, and stress balance are as follows [19,20,[13][14][15]…”

Section: Equations Of Motion In the Shunting Zonementioning

confidence: 99%

“…In consolidation theory, the network stressŜ is typically modeled via a φ-dependent isotropic plastic yield pressure,Ŝ = −p Y (φ)I, whenever network deformation occurs (∇ •û s = 0); otherwise, the magnitude ofŜ is smaller than p Y (φ) [13]. More generally, it is possible for such networks to exhibit rate-dependent behaviour once deformation occurs [19,20], and this extension to the effective network stress was found necessary to describe the behaviour of paper-making fibre suspensions [14,15]. We therefore writeŜ =ŜI, withŜ < 0 under compression, and set the mean solid network stress to bê…”

Section: Equations Of Motion In the Shunting Zonementioning

confidence: 99%

“…To model the screw press, we therefore adopt a two-phase formulation for the material [13], and break the press up into the two compartments. The formulation incorporates Darcy's law for the flow of the fluid; for the solid, we take the effective solid network stress to be given by a plastic compressive yield pressure (as in conventional compaction models [13]) and a rate-dependent viscous term that has proven critical in filtration studies of pulp suspensions [14,15]. Because the churning section has uniform pressure, no detailed model is needed to describe this complicated region; all that is required is the imposition of the conditions holding at the transition point.…”

Section: Introductionmentioning

confidence: 99%

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Dewatering saturated, networked suspensions with a screw press

et al. 2019

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A model is presented for the dewatering of a saturated two-phase medium in a screw press. The model accounts for the detailed two-phase rheological behaviour of the pressed material and splits the press into two zones, an initial well-mixed constant-pressure region followed by an axial transport region in which the total pressure steadily increases. In this latter region, a slowly-varying helical coordinate transformation is introduced to help reduce the dynamics to an annular bi-axial compression of the two-phase medium. Unlike previous modeling, the transition point between the two zones is determined self-consistently, rather than set a priori, and the pressure along the length of the press is deduced from the rheology of the two-phase flow rather than averaging the two-phase dynamics over a cross-section of the press. The model is compared to experimental observations of the dewatering of a paper-making fibre suspension and of a clay slurry, and is shown to reproduce operational data.

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“…In steady state, mass conservation for each phase, Darcy's law, and stress balance are as follows [19,20,[13][14][15]…”

Section: Equations Of Motion In the Shunting Zonementioning

confidence: 99%

Section: Equations Of Motion In the Shunting Zonementioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Dewatering saturated, networked suspensions with a screw press

et al. 2019

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“…Compaction occurs in a variety of natural and industrial processes, such as sedimentary basin formation, paper pulp dewatering, and particle flocculation, and has motivated numerous experiments and mathematical models (e.g. Landman et al, 1991;Fowler and Noon, 1999;Fowler, 2011;Hewitt et al, 2016a, b;Paterson et al, 2019). In this section, we describe the theory outlined by Hewitt et al (2016b).…”

Section: Modelmentioning

confidence: 99%

A model for French-press experiments of dry snow compaction

Meyer¹,

Keegan²,

Baker³

et al. 2019

Preprint

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Abstract. Compaction is the process by which snow densifies, storing water in alpine regions and transforming snow into ice on the surface of glaciers. Despite its importance in determining snow-water equivalent and glacier-induced sea level rise, we still lack a complete understanding of the physical mechanisms underlying snow compaction. In essence, compaction is a rheological process, where the rheology evolves with depth due to variation in temperature, pressure, humidity, meltwater. The rheology of snow compaction can be determined in a few ways, for example, through empirical investigations (e.g. Herron & Langway,1980 J. Glaciol.), by microstructural considerations (e.g. Alley, 1987 J. Phys.), or by measuring the rheology directly, which is the approach we take here. Using a ``French-press'' compression stage, Wang and Baker (2013, J. Geophys. Res.) compressed numerous snow samples of different densities. Here we derive a mixture theory for compaction and air flow through the porous snow to compare against these experimental data. We find that a plastic compaction law explains experimental results. Taking standard forms for the permeability and effective pressure as functions of the porosity, we show that this compaction mode persists for a range of densities and overburden loads. These findings suggest that measuring compaction in the lab is a promising direction for determining the rheology of snow though its many stages of densification.

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“…After the seminal work by Hill [30], a further attempt to experimentally investigate fingering between miscible fluids has been reported by Wooding [37], who however did not discuss the linear stability problem that provides a prediction for the expected wavelength at the onset of the instability. Only some authors [26,31,38,39,40,33] have explored the initial growth of fingers and derived expressions for the incipient fingers with maximum growth rate or maximum amplitude [34]. In all cases but one [41], the introduced models predict that, as interfacial tension tends to zero, the finger wavelength tends to zero possibly with diverging growth rates.…”

Section: Displacing Fluids: Saffman-taylor Instabilitiesmentioning

confidence: 99%

Hydrodynamic instabilities in miscible fluids

Truzzolillo

Cipelletti

2017

J. Phys.: Condens. Matter

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Hydrodynamic instabilities in miscible fluids are ubiquitous, from natural phenomena up to geological scales, to industrial and technological applications, where they represent the only way to control and promote mixing at low Reynolds numbers, well below the transition from laminar to turbulent flow. As for immiscible fluids, the onset of hydrodynamic instabilities in miscible fluids is directly related to the physics of their interfaces. The focus of this review is therefore on the general mechanisms driving the growth of disturbances at the boundary between miscible fluids, under a variety of forcing conditions. In the absence of a regularizing mechanism, these disturbances would grow indefinitely. For immiscible fluids, interfacial tension provides such a regularizing mechanism, because of the energy cost associated to the creation of new interface by a growing disturbance. For miscible fluids, however, the very existence of interfacial stresses that mimic an effective surface tension is debated. Other mechanisms, however, may also be relevant, such as viscous dissipation. We shall review the stabilizing mechanisms that control the most common hydrodynamic instabilities, highlighting those cases for which the lack of an effective interfacial tension poses deep conceptual problems in the mathematical formulation of a linear stability analysis. Finally, we provide a short overview on the ongoing research on the effective, out of equilibrium interfacial tension between miscible fluids.

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Flow-driven compaction of a fibrous porous medium

Cited by 11 publications

References 25 publications

Dewatering saturated, networked suspensions with a screw press

Dewatering saturated, networked suspensions with a screw press

A model for French-press experiments of dry snow compaction

Hydrodynamic instabilities in miscible fluids

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