Roles of Transient and Local Equilibrium Foam Behavior in Porous Media – Traveling Wave

In foam EOR, complex dynamics of bubble creation and destruction controls foam properties. We assume that local equilibrium applies throughout a foam displacement on the field scale, with the exception of an entrance region and at shock fronts, where saturations and bubble size change abruptly. We find a range of conditions in which the local-equilibrium condition applies even within the shock front. In a waterflood the width of a shock transition zone is determined by capillary-pressure gradients. For foam, this equation is joined by one for evolving foam texture. If there is no gas ahead of the foam, we prove that foam texture is everywhere at local equilibrium within the shock, regardless of the foam model. If there is gas initially in the formation, slow foam generation and coalescence processes can narrow the shock from that assuming local equilibrium. In other cases, the dynamics of the traveling wave leads to oscillations near the shock; these are not numerical artifacts, but reflections of the models. Multiple steady states seen in experiment for some injection rates can be predicted by certain foam models. The approach of solving for the traveling wave can give rule out some of these states.