Non-isothermal Transport of Multi-phase Fluids in Porous Media. The Entropy Production

Kjelstrup, Signe; Bedeaux, Dick; Hansen, Alex; Hafskjold, Bjørn; Galteland, Olav

doi:10.3389/fphy.2018.00126

Cited by 25 publications

(61 citation statements)

References 35 publications

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“…The work can be seen as a continuation of our earlier works [10,11]. The work so far considered transport processes in micro-porous, not nano-porous media.…”

Section: Introductionmentioning

confidence: 85%

“…It should contain a statistically representative collection of pores. We have recently discussed [10] a new scheme to define as basis set of additive variables: the internal energy, entropy, and masses of all the components of the REV. These variables are additive in the sense that they are sums of contributions of all phases, interfaces and contact lines within the REV.…”

Section: Introductionmentioning

confidence: 99%

“…Using Euler homogeneity of the first kind, we were able to derive the Gibbs equation for the REV. This equation defines the temperature, pressure and chemical potentials of the REV as partial derivatives of the internal energy of the REV [10].…”

Section: Introductionmentioning

confidence: 99%

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Pressures Inside a Nano-Porous Medium. The Case of a Single Phase Fluid

et al. 2019

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We define the pressure of a porous medium in terms of the grand potential, and compute its value in a nano-confined or nano-porous medium, meaning a medium where thermodynamic equations need be adjusted for smallness. On the nano-scale, the pressure depends in a crucial way on the size and shape of the pores. According to Hill [1], two pressures are needed to characterize this situation; the integral pressure and the differential pressure. Using Hill's formalism for a nano-porous medium, we derive an expression for the difference between the integral and the differential pressures in a spherical phase α of radius R, p α − p α = γ/R. We recover the law of Young-Laplace for the differential pressure difference across the same curved surface. We discuss the definition of a representative volume element for the nano-porous medium and show that the smallest REV is half a unit cell in the direction of the pore in the fcc lattice. We also show, for the first time, how the pressure profile through a nano-porous medium can be defined and computed away from equilibrium.

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“…The work can be seen as a continuation of our earlier works [10,11]. The work so far considered transport processes in micro-porous, not nano-porous media.…”

Section: Introductionmentioning

confidence: 85%

Section: Introductionmentioning

confidence: 99%

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Pressures Inside a Nano-Porous Medium. The Case of a Single Phase Fluid

et al. 2019

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“…A further development somewhat along the same lines, based on non-equilibrium thermodynamics uses Euler homogeneity, more about this later, to define the up-scaled pressure. From this, Kjelstrup et al derive constitutive equations for the flow [10,11].…”

Section: Introductionmentioning

confidence: 99%

Flow-Area Relations in Immiscible Two-Phase Flow in Porous Media

2020

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We present a theoretical framework for immiscible incompressible two-phase flow in homogeneous porous media that connects the distribution of local fluid velocities to the average seepage velocities. By dividing the pore area along a cross-section transversal to the average flow direction up into differential areas associated with the local flow velocities, we construct a distribution function that allows us not only to re-establish existing relationships between the seepage velocities of the immiscible fluids, but also to find new relations between their higher moments. We support and demonstrate the formalism through numerical simulations using a dynamic pore-network model for immiscible two-phase flow with two-and three-dimensional pore networks. Our numerical results are in agreement with the theoretical considerations.

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“…Its structural resemblance with single-phase Darcy and its simplicity led to its widespread use, despite the abundant evidence from both experimental and theoretical analyses of its, often strong, limitations. Multiphase Darcy's law has been rigorously formulated by upscaling the Stoke's equation at the pore scale (e.g., Auriault, 1987;Daly & Roose, 2015;Hassanizadeh & Gray, 1980;Hornung, 1997;Lasseux et al, 2008;Kjelstrup et al, 2018;Whitaker, 1986), and since the microscopic details of the flow are usually neglected, its classical interpretation has been recently questioned. In fact, although the inherent instability of multiphase flows (Ling et al, 2017) may render the analysis of pore-scale distribution of the flowing phases challenging, recurring features in the topology of the nonwetting and wetting phase at the pore scale have been revealed by X-ray microtomography and high-performance computing (Armstrong et al, 2014(Armstrong et al, , 2012Blunt et al, 2013;Berg et al, 2013;Cueto-Felgueroso & Juanes, 2012;Gao et al, 2017;Garing et al, 2017;Li et al, 2005Li et al, , 2018bLin et al, 2018;Prodanovic et al, 2006Prodanovic et al, , 2007Reynolds et al, 2017;Tallakstad et al, 2009;Tahmasebi et al, 2017;Zarikos et al, 2018).…”

Section: Introductionmentioning

confidence: 99%

Relative Permeability Scaling From Pore‐Scale Flow Regimes

Picchi

Battiato

2019

Water Resources Research

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Relative permeability measurements are commonly fitted with the Corey and Brooks‐Corey correlations. Despite such correlations fit experimental data generally well, they are mostly of an empirical nature. Here, we propose a semiempirical model to determine relative permeabilities of the wetting and the nonwetting phases in real 3‐D porous media that accounts for pore‐scale flow regimes. The starting point is the homogenization framework proposed by Picchi and Battiato (2018, https://doi.org/10.1029/2018WR023172), where the upscaling is conducted for different spatial distributions of the flowing phases in the capillary tube setting. First, we extend the approach to realistic media by allowing pore‐scale flow regimes to coexist in a complex geometry while accounting for capillary and viscous limits in the dynamics. Then, we discuss the scaling behavior of normalized relative permeabilities in terms of the phases viscosity ratio and identify three classes which govern their scaling. We also derive an analytical expression for the fractional flow. Finally, we provide a detailed validation of the proposed model for both relative permeabilities and fractional flow against data from numerical simulations and experiments available in the literature. The data set used for validation covers a wide range of systems, ranging from brine‐CO2 to oil‐water flows. The equations derived capture well the trend of both numerical and experimental data.

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Non-isothermal Transport of Multi-phase Fluids in Porous Media. The Entropy Production

Cited by 25 publications

References 35 publications

Pressures Inside a Nano-Porous Medium. The Case of a Single Phase Fluid

Pressures Inside a Nano-Porous Medium. The Case of a Single Phase Fluid

Flow-Area Relations in Immiscible Two-Phase Flow in Porous Media

Relative Permeability Scaling From Pore‐Scale Flow Regimes

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