The Co-Moving Velocity in Immiscible Two-Phase Flow in Porous Media

TL;DR

This paper develops a continuum model for immiscible two-phase flow in porous media, introducing the co-moving velocity to better describe fluid interactions and improve upon traditional relative permeability approaches.

Contribution

It introduces the co-moving velocity as a new parameter and provides a framework to incorporate power-law constitutive equations into flow modeling.

Findings

The co-moving velocity differs from the velocity difference between fluids.

The model aligns with experimental and computational data across various flow regimes.

The approach improves flow description beyond traditional relative permeability theory.

Abstract

We present a continuum (i.e., an effective) description of immiscible two-phase flow in porous media characterized by two fields, the pressure and the saturation. Gradients in these two fields are the driving forces that move the immiscible fluids around. The fluids are characterized by two seepage velocity fields, one for each fluid. Following Hansen et al.\ (Transport in Porous Media, 125, 565 (2018)), we construct a two-way transformation between the velocity couple consisting of the seepage velocity of each fluid, to a velocity couple consisting of the average seepage velocity of both fluids and a new velocity parameter, the co-moving velocity. The co-moving velocity is related but not equal to velocity difference between the two immiscible fluids. The two-way mapping, the mass conservation equation and the constitutive equations for the average seepage velocity and the co-moving velocity form a closed set of equations that determine the flow. There is growing experimental, computational and theoretical evidence that constitutive equation for the average seepage velocity has the form of a power law in the pressure gradient over a wide range of capillary numbers. Through the transformation between the two velocity couples, this constitutive equation may be taken directly into account in the equations describing the flow of each fluid. This is e.g., not possible using relative permeability theory. By reverse engineering relative permeability data from the literature, we construct the constitutive equation for the co-moving velocity. We also calculate the co-moving constitutive equation using a dynamic pore network model over a wide range of parameters, from where the flow is viscosity dominated to where the capillary and viscous forces compete.