Enhanced Heavy-Oil Recovery by Alkali-Surfactant Flooding

Bryan, J.; Kantzas, Apostolos

doi:10.2118/110738-ms

Cited by 95 publications

(63 citation statements)

References 22 publications

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“…Recovery in chemical flooding of heavy-oil reservoirs have been shown to depend on flow rate, and consequently on the shear rate [5][6][7][8][9][10]. This is consistent with capillary number dependencies associated with emulsion flow [11].…”

Section: Evidence Of Emulsions Conformance Effects: Heavy-oil Eorsupporting

confidence: 66%

“…The issue of mobility ratio or control arises because viscous water has much lower viscosity than heavy oil and consequently the displacement front develops fingers and oil recovery is generally poor. Alkali-surfactant (AS) flooding has been shown to be a potential viable technology for EOR in heavy-oil reservoirs [5][6][7][8][9][10]. However, in the absence of a thickening agent such as polymers, the increase in water saturation as water displaces oil only worsens the mobility control issue.…”

Section: Evidence Of Emulsions Conformance Effects: Heavy-oil Eormentioning

confidence: 99%

“…Bryan and Kantzas [6] state that emulsification, entrainment and entrapment of dispersed phase and wettability reversal mechanisms can contribute to oil recovery during the injection of alkaline agents and surfactants in heavy-oil reservoirs. Recovery in chemical flooding of heavy-oil reservoirs have been shown to depend on flow rate, and consequently on the shear rate [5][6][7][8][9][10].…”

Section: Evidence Of Emulsions Conformance Effects: Heavy-oil Eormentioning

confidence: 99%

See 2 more Smart Citations

Stability Proxies for Water-in-Oil Emulsions and Implications in Aqueous-based Enhanced Oil Recovery

2011

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Several researchers have proposed that mobility control mechanisms can positively contribute to oil recovery in the case of emulsions generated in Enhanced-Oil Recovery (EOR) operations. Chemical EOR techniques that use alkaline components or/and surfactants are known to produce undesirable emulsions that create operational problems and are difficult to break. Other water-based methods have been less studied in this sense. EOR processes such as polymer flooding and LoSal TM injection require adjustments of water chemistry, mainly by lowering the ionic strength of the solution or by decreasing hardness. The decreased ionic strength of EOR solutions can give rise to more stable water-in-oil emulsions, which are speculated to improve mobility ratio between the injectant and the displaced oil. The first step toward understanding the connection between the emulsions and EOR mechanisms is to show that EOR conditions, such as salinity and hardness requirements, among others, are conducive to stabilizing emulsions. In order to do this, adequate stability proxies are required. This paper reviews commonly used emulsion stability proxies and explains the advantages and disadvantage of methods reviewed. This paper also reviews aqueous-based EOR processes with focus on heavy oil to contextualize in-situ emulsion stabilization conditions. This context sets the basis for comparison of emulsion stability proxies.

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Section: Evidence Of Emulsions Conformance Effects: Heavy-oil Eorsupporting

confidence: 66%

Section: Evidence Of Emulsions Conformance Effects: Heavy-oil Eormentioning

confidence: 99%

Section: Evidence Of Emulsions Conformance Effects: Heavy-oil Eormentioning

confidence: 99%

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Stability Proxies for Water-in-Oil Emulsions and Implications in Aqueous-based Enhanced Oil Recovery

2011

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“…Generally speaking, addition of highly hydrophilic surfactants (high HLB), low salinity, and high WOR lead to O/W emulsions (Bryan, 2007). The goal of this work is to identify chemicals for forming oil-in-water emulsions with a heavy Alaskan oil and conduct displacement studies to understand the recovery of heavy oils.…”

Section: Introductionmentioning

confidence: 99%

Chemical Methods for Ugnu Viscous Oils

Mohanty¹

2012

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“…The high viscous nature of heavy oil, viscosity in the range of 1x10 4 cP, requires that the viscosity be reduced to approximately 400cP for its effective and efficient production and transportation. Researchers in this field have reported several techniques employed by industry to achieve reduction in heavy oil/bitumen viscosity such as the use of heating system in the formation and/or pipeline [1,2], addition of liquid diluents and injection of liquids or gaseous diluents into the formation, and the use of water and emulsion [3][4][5]. Although these methods, to an extent have been effective in reducing the oil viscosity the high costs of energy and diluents restrict their frequent applications.…”

Section: Introductionmentioning

confidence: 99%

Study of the influence of asphaltenes on modeling of viscosity of Nigerian crude mixtures

Miadonye¹,

Dan-Ali²,

Onwude³

et al. 2011

Computational Methods and Experimental Measurements XV

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In this study, the effect of asphaltenes on the viscosity of Nigerian light crude oils at different temperatures was studied. Different weight per cent of bitumen containing 14 per cent asphaltenes and deasphalted bitumen samples from Alberta, Canada were mixed with Nigerian crude oils. The mixtures were prepared from five light crude oil samples and two bitumen samples. The experimental viscosity data obtained at different temperatures and weight per cent of the bitumen samples were correlated with the viscosity equation of Singh et al. The viscosity of pure crude oils (for instance, Forcados crude oil) containing asphalted and deasphalted bitumen (Rush Lake and Plover Lake bitumen) increased by as much as 160% and 60% respectively.However, the results obtained from correlating the viscosity data with the equation indicated that the discrepancies in measured data could be mainly attributed to the presence of asphaltenes, but the percent errors between measured and predicted viscosity were consistent for the entire samples. The results were identified the light crude oils as better alternative diluents for the production and transportation of heavy crude petroleum.

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Enhanced Heavy-Oil Recovery by Alkali-Surfactant Flooding

Cited by 95 publications

References 22 publications

Stability Proxies for Water-in-Oil Emulsions and Implications in Aqueous-based Enhanced Oil Recovery

Stability Proxies for Water-in-Oil Emulsions and Implications in Aqueous-based Enhanced Oil Recovery

Chemical Methods for Ugnu Viscous Oils

Study of the influence of asphaltenes on modeling of viscosity of Nigerian crude mixtures

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