2013
DOI: 10.1016/j.petrol.2013.09.009
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Numerical simulation of surfactant–polymer coreflooding experiments for carbonates

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Cited by 42 publications
(11 citation statements)
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“…The experiments performed on the Kenali Asam and the Tempino fields' core samples both showed that the relative permeabilities of the investigated cores, even from the same formation, varied significantly from one core plug to another, as has been stated by Alsofi, et al [21]. According to them, this is probably caused by the relatively wide changes in topology.…”
Section: Discussion Of Interpolation Setsupporting
confidence: 55%
See 1 more Smart Citation
“…The experiments performed on the Kenali Asam and the Tempino fields' core samples both showed that the relative permeabilities of the investigated cores, even from the same formation, varied significantly from one core plug to another, as has been stated by Alsofi, et al [21]. According to them, this is probably caused by the relatively wide changes in topology.…”
Section: Discussion Of Interpolation Setsupporting
confidence: 55%
“…Otherwise, whether the prediction the simulation has good agreement can only be shown by the different scenarios of varying the slug size of the injected blended surfactant-polymer. This result has pointed to some researches carried out that have reported on similar cases, in which, in order to attain a chemical EOR flooding match, the end-point of the relative permeability needed to be changed intentionally [21][22][23]. In this research, the authors have employed Eq.…”
Section: Discussion Of Interpolation Setmentioning
confidence: 99%
“…Surfactant-polymer flooding is an important process, because it offers the co-acting mechanisms of reduced interfacial tension and mobility control that efficiently increases oil recovery [8]. Numerical simulations have been conducted to evaluate the effect of surfactant-polymer slugs' sizes, polymer and surfactant concentrations, brine salinity, and the onset of hydrodynamic instability during the displacement of viscous oils by lower viscosity driving fluids such as surfactant-polymer, among others [120,121]. Polymer flooding in unconsolidated sand formations has also been studied through numerical modeling and laboratory-scale experiments, which indicates that polymer properties, fluid mobility, and formation plasticity influence the fracturing mechanisms in unconsolidated porous media during polymer flooding; for more details, the readers are referred to Khodaverdian et al [122] and the references therein.…”
Section: Flow Behavior Of Polymers Through Porous Mediamentioning
confidence: 99%
“…Although ASP flooding has been proven to be an effective method for enhancing oil recovery and has been fruitful in actual oil fields [25][26][27], due to the late birth of this technique, its enhanced recovery mechanism and characteristics, especially the evolution of pressure field, remain to be explored. Physical experiments [27][28][29] and numerical simulation [30][31][32][33][34] about ASP have been conducted in recent years. Li et al [35] studied performance of ASP systems and effects of the individual component.…”
Section: Introductionmentioning
confidence: 99%