Geometric state function for two-fluid flow in porous media

The pore‐scale flow of CO2 and water in 2‐D heterogeneous porous micromodels over a Ca range of nearly three orders of magnitude was explored experimentally. The porous geometry is a close reprint of real sandstone, and the experiments were performed under reservoir‐relevant conditions (i.e., 8 MPa and 21 °C), thus ensuring relevance to practical CO2 operations. High‐speed fluorescent microscopy and image processing were employed to achieve temporally and spatially resolved data, providing a unique view of the dynamics underlying this multiphase flow scenario. Under conditions relevant to CO2 sequestration, final CO2 saturation was found to decrease and increase logarithmically with Ca within the capillary and viscous‐fingering regimes, respectively, with a minimum occurring during regime crossover. Specific interfacial length generally scales linearly with CO2 saturation, with higher slopes noted at high Ca due to stronger viscous and inertial forces, as supported by direct pore‐scale observations. Statistical analysis of the interfacial movements revealed that pore‐scale events are controlled by their intrinsic dynamics at low Ca, but overrun by the bulk flow at high Ca. During postfront flow, while permeability is typically correlated with total CO2 saturation in the porous domain (regardless of its mobility), the saturation of active CO2 pathways in the current study correlated very well with permeability. This alternate approach to characterize relative permeability could serve to mitigate hysteresis in relative permeability curves. Taken together, these results provide unique insights that address inconsistent observations in the literature and previously unanswered questions about the underlying flow dynamics of this important multiphase flow scenario.

Section: Introductionmentioning

confidence: 99%

High‐Speed Quantification of Pore‐Scale Multiphase Flow of Water and Supercritical CO₂ in 2‐D Heterogeneous Porous Micromodels: Flow Regimes and Interface Dynamics

Blois

Kazemifar

et al. 2019

“…Several approaches have been developed to incorporate the evolution of the fluid-fluid interface into macroscopic equations (e.g., Cueto-Felgueroso & Juanes, 2014;Gray & Miller, 2010;Gray et al, 2015;Hassanizadeh & Gray, 1990Hilfer, 1998;Jackson et al, 2009;McClure et al, 2016;Niessner & Hassanizadeh, 2008;Rybak et al, 2015), but additional complexity in the formulation of the closure problem and in the definition of state variables has been inevitably introduced. Only recently, Karadimitriou et al (2014) proposed a method to estimate such state variables from experimental measurements, while Schluter et al (2016) and McClure et al (2018) provided alternative approaches to identify the missing variables in terms of integral geometry (i.e., Euler characteristics). Over the years, more practical and ad hoc formulations of the relative permeabilities have been proposed (Chierici, 1984;Clavier et al, 2017;Dehghanpour et al, 2011;Gunstensen & Rothman, 1993;Li et al, 2018;Oliveira & Demond, 2003;Pasquier et al, 2017;Yiotis et al, 2007;Zhang et al, 2018), including the study of the impact of spatial heterogeneity on relative permeabilities (Jackson et al, 2018).…”

Section: Introductionmentioning

confidence: 99%

Relative Permeability Scaling From Pore‐Scale Flow Regimes

Picchi

Battiato

2019

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.

“…McClure et al () investigated which intrinsic volumes were required to describe the state of quasi‐static two‐phase flow in porous media. Further, they investigated constitutive relations among these parameters.…”

Section: Introductionmentioning

confidence: 99%

“…

In integral geometry, intrinsic volumes are a set of geometrical variables to characterize spatial structures, for example, distribution of fluids in two-fluid flow in porous media. McClure et al (2018, https:// doi.org/10.1103.084306) utilized this principle and proposed a geometric state function based on the intrinsic volumes. In a similar approach, we find a geometrical description for free energy of a porous system with two fluids.

…”

mentioning

confidence: 99%

Description of Free Energy for Immiscible Two‐Fluid Flow in Porous Media by Integral Geometry and Thermodynamics

Khanamiri

Berg

Slotte

et al. 2018

Self Cite

In integral geometry, intrinsic volumes are a set of geometrical variables to characterize spatial structures, for example, distribution of fluids in two‐fluid flow in porous media. McClure et al. (2018, https://doi.org/10.1103/PhysRevFluids.3.084306) utilized this principle and proposed a geometric state function based on the intrinsic volumes. In a similar approach, we find a geometrical description for free energy of a porous system with two fluids. This is also an extension of the work by Mecke (2000, https://doi.org/10.1007/3-540-45043-2_6) for energy of a single fluid. Several geometrical sets of spatial objects were defined, including bulk of the two fluids, interfaces, and three‐phase contact lines. We have simplified the description of free energy by showing how the intrinsic volumes of these sets are geometrically related. We obtain a description for energy as a function of seven microscopic geometrically independent variables. In addition, using a thermodynamic approach, we find an approximation for the free energy as a function of macroscopic parameters of saturation and pressure under quasi‐static conditions. The combination of the two energy descriptions, by integral geometry and thermodynamics, completes the relation between the associated variables and enables us to find the unknown coefficients of the intrinsic volumes and to calculate the amount of dissipated energy in drainage and imbibition processes. We show that the theory is consistent with a set of experiments performed by Schlüter et al. (2016a, https://doi.org/10.1002/2015WR018254, 2017a, https://doi.org/10.1002/2016WR019815). However, in order to be more conclusive, it needs to be tested with larger data sets.