2017
DOI: 10.1016/j.colsurfa.2017.03.059
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Foam front displacement in improved oil recovery in systems with anisotropic permeability

Abstract: A foam front propagating through an oil reservoir is considered in the context of foam improved oil recovery. Specifically the evolution of the shape of a foam front in a strongly anisotropic reservoir (vertical permeability much smaller than horizontal permeability) is determined via the pressure-driven growth model. The shape of the foam front is demonstrated to be extremely close to that predicted in the limiting case of a reservoir with no vertical permeability whatsoever, in particular any deviations from… Show more

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Cited by 3 publications
(2 citation statements)
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“…In what follows, the improvement to the Velde solution is derived: those readers who wish to skip the derivation should turn directly to equations (3.13)-(3.14) and the results in section 3.3.1. The derivation that we follow is similar to one that has already been employed by Grassia (2017) to describe pressure-driven growth within porous media with anisotropic permeability. Here the system is considered to be isotropic, and there are some subtle (albeit significant) differences in the equations obtained: see Grassia (2017) for details.…”
Section: Improving the Velde Solutionmentioning
confidence: 99%
“…In what follows, the improvement to the Velde solution is derived: those readers who wish to skip the derivation should turn directly to equations (3.13)-(3.14) and the results in section 3.3.1. The derivation that we follow is similar to one that has already been employed by Grassia (2017) to describe pressure-driven growth within porous media with anisotropic permeability. Here the system is considered to be isotropic, and there are some subtle (albeit significant) differences in the equations obtained: see Grassia (2017) for details.…”
Section: Improving the Velde Solutionmentioning
confidence: 99%
“…Pressure-driven growth (in 2-D) has been used to describe a number of foam IOR scenarios in reservoirs including effects of reservoir heterogeneity [48] and anisotropy [49,50], the influence of surfactant migrating downward through a reservoir [51], and also the effect of an increase in injection pressure used to drive the foam along [52]. There is however a scenario that pressure-driven growth has not yet tackled successfully, namely a decrease in net driving pressure moving the foam along, net driving pressure here being the difference between an injection pressure and a pressure downstream of the displacing foam.…”
Section: Introductionmentioning
confidence: 99%