Abstract During an Alkaline-Surfactant-Polymer (ASP) flood in reservoir rock, often an in situ microemulsion phase forms upon contact of the injected ASP fluid with the residing oil. These microemulsions form as a result of the required ultra-low interfacial tensions (IFT) for oil mobilization and displacement of the residual oil, but they can have a high viscosity. The success of an ASP flood on oil recovery depends on the complex flow of the injected ASP solution, the mobilized oil and the in situ microemulsion phase, which the latter often has a higher shear-dependent viscosity than the other two.
In this study, steady-state (SS) corefloods have been performed to investigate the in situ microemulsion formation and rheology during the multiphase flow. The aqueous phase, namely brine, AS or ASP, was co-injected with n-decane or reservoir ‘dead’ crude in Berea outcrop cores for a range of fractional flow ratios. The pressure differential was continuously recorded, and was then converted in an apparent, in situ, viscosity value. For this stage of the project the water and oil phase saturations in the plugs were not yet measured.
For brine/oil systems some dependence of apparent viscosity on rock permeability was observed; for systems with surfactants no such trend was noticable. The addition of surfactants substantially reduced the apparent viscosities; the viscosity reducing impact of surfactants could be balanced by the addition of polymer. Fractional flow analysis showed that the addition of surfactants reduces the impact of capillary forces resulting in straightened relative permeability curves and higher aqueous phase relative permeability end points.
It is anticipated that this study leads to a fast and fit for purpose characterization method of ASP-crude oil systems that provides data in a form, such as relative permeability data and residual oil saturation that can be applied directly in reservoir simulators.