2022
DOI: 10.1021/acsomega.2c00277
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Practical Mathematical Model for the Evaluation of Main Parameters in Polymer Flooding: Rheology, Adsorption, Permeability Reduction, and Effective Salinity

Abstract: Polymer flooding is one of the most used chemical enhanced oil recovery (CEOR) technologies worldwide. Because of its commercial success at the field scale, there has been an increasing interest to expand its applicability to more unfavorable mobility ratio conditions, such as more viscous oil. Therefore, an important requirement of success is to find a set of design parameters that balance material requirements and petroleum recovery benefits in a cost-effective manner. Then, prediction of oil recovery turns … Show more

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Cited by 3 publications
(10 citation statements)
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“…Now, applying the SL coordinate transformation technique to the 1D model for polymer flooding developed in our previous publication, we can establish the following system of nonlinear differential equations for water, polymer, and salt, i.e., components 1, 4, and 5, respectively t [ S 1 ] + τ [ f 1 ] = 0 t [ C 41 S 1 + 4 ] + τ [ f 1 C 41 ] = 0 t [ C 51 S 1 ] + τ [ f 1 C 51 ] = 0 with S 1 (τ, t ), C 41 (τ, t ), and C 51 (τ, t ) as unknowns. Initial and boundary conditions, that complete the definition of the problem, can be adequate to any condition state of the previous production, polymer injection strategies, and other operational conditions.…”
Section: Mathematical Modeling Of Polymer Floodingmentioning
confidence: 99%
See 3 more Smart Citations
“…Now, applying the SL coordinate transformation technique to the 1D model for polymer flooding developed in our previous publication, we can establish the following system of nonlinear differential equations for water, polymer, and salt, i.e., components 1, 4, and 5, respectively t [ S 1 ] + τ [ f 1 ] = 0 t [ C 41 S 1 + 4 ] + τ [ f 1 C 41 ] = 0 t [ C 51 S 1 ] + τ [ f 1 C 51 ] = 0 with S 1 (τ, t ), C 41 (τ, t ), and C 51 (τ, t ) as unknowns. Initial and boundary conditions, that complete the definition of the problem, can be adequate to any condition state of the previous production, polymer injection strategies, and other operational conditions.…”
Section: Mathematical Modeling Of Polymer Floodingmentioning
confidence: 99%
“…In eqs –, fractional flow, f 1 , is a function of saturation and concentrations, and relative permeabilities (given by Corey-type equations ,,, ) and polymer rheology properties are considered. Although a detailed description of the 1D polymer flooding model is thoroughly discussed in our previous paper, a brief review of the equations for the key phenomena is included as follows (model parameters’ details are in the nomenclature section). Polymer adsorption with salinity variation is represented by a Langmuir-type model in the numerical simulation. , 4 = min [ 4 , a 4 false( 4 4 false) 1 + b 4 false( 4 4 false) ] Viscosity at zero shear rate with salinity variation is modeled with the modified Flory–Huggins equation. , μ 1 normalo = μ 1 [ 1 + ( a p 1 C 41 + a p 2 C 41 2 + a p 3 C …”
Section: Mathematical Modeling Of Polymer Floodingmentioning
confidence: 99%
See 2 more Smart Citations
“…In order to solve the limitation that polymer flooding can only be used in the near-well area. Many scholars try to conduct “high-dose profile control”, also known as “deep profile control” [ 19 , 20 , 21 , 22 , 23 ], but the treatment radius is often no more than 10–20 m and the treatment cost is high. In addition, with the increase of water-cut in oilfields, the water-flooding contradiction changes from the shallow reservoir to the deep reservoir, or even the entire reservoir flow field.…”
Section: Introductionmentioning
confidence: 99%