Impact of sample geometry on the measurement of pressure-saturation curves: experiments and simulations

TL;DR

This study investigates how sample geometry influences pressure-saturation curves in two-phase flow through porous media, combining experiments and simulations to identify boundary effects and propose a simplified, scalable relationship.

Contribution

The paper demonstrates the impact of sample size and aspect ratio on pressure-saturation measurements and introduces a simplified relationship applicable to large systems unaffected by boundary effects.

Findings

Boundary effects significantly influence pressure-saturation curves.

A simplified pressure-saturation relationship is proposed for large systems.

Simulations confirm experimental observations about boundary influence.

Abstract

In this paper we study the influence of sample geometry on the measurement of pressure-saturation relationships, by analyzing the drainage of a two-phase flow from a quasi-2D random porous medium. The medium is transparent, which allows for the direct visualization of the invasion pattern during flow, and is initially saturated with a viscous liquid (a dyed glycerol-water mix). As the pressure in the liquid is gradually reduced, air penetrates from an open inlet, displacing the liquid which leaves the system from an outlet on the opposite side. Pressure measurements and images of the flow are recorded and the pressure-saturation relationship is computed. We show that this relationship depends on the system size and aspect ratio. The effects of the system's boundaries on this relationship are measured experimentally and compared with simulations produced using an invasion percolation algorithm. The pressure build up at the beginning and end of the invasion process are particularly affected by the boundaries of the system whereas at the central part of the model (when the air front progresses far from these boundaries), the invasion happens at a statistically constant capillary pressure. These observations have led us to propose a much simplified pressure-saturation relationship, valid for systems that are large enough such that the invasion is not influenced by boundary effects. The properties of this relationship depend on the capillary pressure thresholds distribution, sample dimensions and average pore connectivity and its applications may be of particular interest for simulations of two-phase flow in large porous media.