Traveling wave solutions for non-Newtonian foam flow in porous media

TL;DR

This paper uses traveling wave analysis to estimate propagation profiles and velocities of non-Newtonian foam flows in porous media, providing insights into foam rheology and flow behavior.

Contribution

It reformulates Hirasaki and Lawson's viscosity formula explicitly and derives traveling wave solutions for non-Newtonian foam models in porous media.

Findings

Explicit traveling wave solutions for non-Newtonian foam models.

Comparison between Newtonian and non-Newtonian foam flow behaviors.

Quantitative analysis of foam rheology in porous media.

Abstract

The injection and in-situ generation of foam in porous media successfully control gas mobility and improve the fluids' sweep efficiency inside porous media. Mathematical models describing this problem use two phases, foamed gas and fluid, and usually have a term for foam generation and destruction. Moreover, the non-Newtonian foam behavior is frequently modeled using the Hirasaki and Lawson's formula for foamed gas viscosity. In this paper, we detail how the traveling wave analysis can be used to estimate the propagation profiles and velocity for a range of non-Newtonian foam models in porous media at constant total superficial flow velocity. We reformulate Hirasaki and Lawson's formula in an explicit form allowing us to find traveling wave solutions for the non-Newtonian Linear Kinetic model. Comparing the solution with the one for the Newtonian version, allows us to analyze qualitatively and quantitatively the rheology of the foam flow in porous media.