Derivation of A Representative Elementary Volume (REV) for Upscaled Two-Phase Flow in Porous Media

Relative permeability plays an important role in the upscaling of multiphase flow in porous media from pore scale to Darcy scale. The entire concept of relative permeability is contingent on the existence of a representative elementary volume (REV). As we move to smaller samples to measure relative permeability, such as with Digital Core Analysis, the concept of a classical REV has become increasingly unlikely when using the conventional approach to defining a representative volume. The ‘conventional’ understanding of an REV is that a large enough volume must be considered such that spatial variability averages out. In Digital Rock methods, such as pore-scale simulations based on micro-CT images the domain size is typically 2-4 mm. This is approximately the length scale of a single-phase flow REV using the classic REV approach. However, the single-phase perspective does not consider the complex dynamics and fluctuations often observed in multiphase flow systems even at centimeter scale experiments and/or simulations. A fundamental question is, therefore, whether the domain size commonly used in Digital Rock simulations can provide a consistent energy budget such that the concept of relative permeability exists. Based on first principles, relative permeability account for the rate of energy dissipated in a stationary process. If the dynamics are fluctuating, the energy dissipated can vary, but will average out over a long enough timescale. The key to determining the validity of the relative permeability is the timescale of the measurement, not the spatial scale. The conventional REV theory assumes that spatial, temporal, and ensemble averages are equivalent in an ergodic system, but it does not provide a way to test this assumption. We provide a formal way to identify the timescale where the relative permeability accurately captures energy dissipation as a way to validate relative permeability measurements and quantitatively assess their accuracy. This result will be tested for a practical SCAL test, determining how long a flow experiment needs to be run to accurately characterize the rate of energy dissipation by the flow. The outcome will be a best practice guide for the determination of relative permeability from core scale experiments and/or digital core simulations that ensures the energy budget is fully accounted for in the relative permeability coefficient.