Inaccessible Pore Volume of Associative Polymer Floods

Inaccessible pore volume, also known as dead pore space, is used when simulating enhanced oil recovery by polymer injection. We show that a widely used model for inaccessible pore volume can lead to an ill-posed problem, resulting in unphysical results. By considering shock solutions of the one-dimensional problem, we derive a necessary condition that an inaccessible pore volume model must fulfill in order to obtain well-posed equations. In this derivation, we use the Rankine-Hugoniot jump condition as a selection criterion for acceptable solutions. There are other possible criteria for the one-dimensional problem, in particular δ-shock solutions, which we also briefly describe, but these are challenging and impractical to use. Based on a heuristic understanding of relative permeability, we subsequently derive two modified models for inaccessible pore volume. The first model follows directly from the modeling assumptions, but it has limited applicability. If the inaccessible pore volume is larger than the irreducible water saturation, then the equations are ill-posed for convex relative permeabilities. A second model is derived by relaxing the assumption of inaccessibility, allowing a limited fraction of the polymer to enter the smallest pores. This second model fulfills our necessary condition for well-posedness for all values of the inaccessible pore volume and any choice of relative permeabilities. Through one-and two-dimensional numerical examples, the different models for inaccessible pore volume are compared. For our second suggested model, the polymer concentration is observed to stay below the maximum injected value, which is not the case for the conventional model. This enables a more stable implementation of the highly nonlinear system, and a reduction in the number of nonlinear iterations is also observed in some cases. As this suggested model is straightforward to B Xavier Raynaud xavier.raynaud@sintef.no Sindre T. Hilden 123 S. T. Hilden et al.implement into existing reservoir simulators and can be used for a wide range of polymer models, it serves as a possible alternative to the conventional model.

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“…In the numerical simulations in Pancharoen et al (2010), the authors use a fractional flow formulation and the equation for polymer is given by…”

Section: Percolation-based Velocity Enhancement Modelmentioning

confidence: 99%

Study of the Well-Posedness of Models for the Inaccessible Pore Volume in Polymer Flooding

2016

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“…4 Reduction in the mobility ratio leads to an increase in the macroscopic displacement efficiency. 5,6 Recently, it was discovered that the viscoelastic nature of the polymers also helps in increasing the microscopic efficiency. [7][8][9][10] A cEOR method which makes use of polymers is called polymer flooding (PF).…”

Section: Introductionmentioning

confidence: 99%

Review on Polymer Flooding: Rheology, Adsorption, Stability, and Field Applications of Various Polymer Systems

Kamal¹,

Sultan²,

et al. 2015

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Polymer flooding is one of the most promising techniques for the recovery of remaining oil from light oil reservoirs. Water soluble polymers are used to enhance the viscosity of displacing fluid and to improve the sweep efficiency. In this paper, water soluble polymers used for chemical enhanced oil recovery are reviewed. Conventional and novel modified polymers are discussed along with their limitations. The review covers thermal stability, rheology, and adsorption behavior of various polymer systems in sandstone and carbonate reservoirs. Field and laboratory core flooding data of several polymers are covered. The review describes the polymer systems that are successfully applied in low-temperature and low-salinity reservoirs. Comprehensive review of current research activities aiming at extending polymer flooding to high-temperature and high-salinity reservoirs is performed. The review has identified current and future challenges of polymer flooding.

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“…In aqueous solution, intramolecular association generated at low polymer concentration and strong intermolecular association form 3D network structures with large hydrodynamic volumes when the concentration is up to critical association concentration (CAC), namely hydrophobic association, resulting in excellent anti-shearing property. 24,25 As inorganic particles, ultrane silica has the advantages of high strength and excellent stability. The difference between ultrane silica and common branched monomer is that ultra-ne silica can interact with unsaturated bonds of polymer, increasing the density of electron cloud, improving the chemical properties.…”

Section: Introductionmentioning

confidence: 99%