Abstract
A novel concept for modeling pore-scale phenomena included in several enhanced oil recovery (EOR) methods is presented. The approach combines a quasi-static invasion percolation model with a single-phase dynamic transport model in order to integrate mechanistic chemical oil mobilization methods. A framework is proposed that incorporates mobilization of capillary trapped oil. We show how double displacement of reservoir fluids can contribute to mobilize oil that are capillary trapped after waterflooding. In particular, we elaborate how the physics of colloidal dispersion gels (CDG) or linked polymer solutions (LPS) is implemented. The linked polymer solutions consist of low concentration partially hydrolyzed polyacrylamide polymer crosslinked with aluminum citrate. Laboratory core floods have shown demonstrated increased oil recovery by injection of linked polymer solution systems. LPS consist of roughly spherical particles with sizes in the nanometer range (50–150 nm). The LPS process involve mechanisms such as change in rheological properties effect, adsorption and entrapment processes that can lead to a microscopic diversion and mobilization of waterflood trapped oil. The purpose is to model the physical processes occurring on pore scale during injection of linked polymer solutions. A sensitivity study has also been performed on trapped oil saturation with respect to wettability status to analyze the efficiency of LPS on different wettability conditions. The network modeling results suggest that weakly wet reservoirs are more suitable candidates for performing linked polymer solution injection.
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Abbreviations
- A :
-
Langmuir adsorption coefficient (cm3/g)
- AP 1,2,3 :
-
Constant coefficients (cm3/g)
- B :
-
Langmuir adsorption coefficient (cm3/g)
- C lg :
-
Critical concentration for log jamming mechanism (g/cm3)
- C p :
-
Polymer concentration (g/cm3)
- C s :
-
Critical concentration for straining mechanism (g/cm3)
- f :
-
Fractional flow rate (–)
- G :
-
Absolute pore element conductance
- G f :
-
Water corner layer conductance
- g pc :
-
Bonds conductance
- G w :
-
Water bulk conductance
- i, j, k:
-
Bonds index (–)
- N ca :
-
Capillary number (–)
- P :
-
Pressure (Pa)
- Q :
-
Bonds flow rate (m3/s)
- q :
-
Flow rate (m3/s)
- R b :
-
Bond radius (μm)
- R p :
-
Polymer effective hydrodynamic radius (μm)
- S :
-
Log-jamming curve increase (–)
- α :
-
Oil-filled fractional in partially filled bond
- μ :
-
Viscosity (Pa.s)
- μ w :
-
Water viscosity (Pa.s)
- σ :
-
Interfacial tension (N/m)
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Acknowledgment
The authors would like to acknowledge the PETROMAKS program at the Norwegian Research Council and Statoil for financial support to our EOR research.
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Open Access This is an open access article distributed under the terms of the Creative Commons Attribution Noncommercial License (https://creativecommons.org/licenses/by-nc/2.0), which permits any noncommercial use, distribution, and reproduction in any medium, provided the original author(s) and source are credited.
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Bolandtaba, S.F., Skauge, A. Network Modeling of EOR Processes: A Combined Invasion Percolation and Dynamic Model for Mobilization of Trapped Oil. Transp Porous Med 89, 357–382 (2011). https://doi.org/10.1007/s11242-011-9775-0
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DOI: https://doi.org/10.1007/s11242-011-9775-0