Investigation of alkaline-crude oil reaction

James J. Sheng

Petroleum ›› 2015, Vol. 1 ›› Issue (1) : 31 -39.

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Petroleum ›› 2015, Vol. 1 ›› Issue (1) :31 -39. DOI: 10.1016/j.petlm.2015.04.004
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Investigation of alkaline-crude oil reaction
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Abstract

One of the mechanisms of alkaline flooding relies on alkaline reaction with organic acids (saponifiable components) in the crude oil to produce an in situ surfactant called soap that lowers interfacial tensions. However, this mechanism is not quantified in the literature. For example, what is the fraction of acid components which react with alkaline solution to generate soap? How much soap can be generated?

In this paper, this mechanism and related issues are discussed, analyzed or quantified. In particular, the numerical simulation approach is used. The results show that only a fraction of acid components can be converted into soap; the amount of generated soap could be low. A minimum pH (e.g. 9) is needed for the acids to be converted to soap. The literature information on the effect of amount of acid components (total acid number) on oil recovery is also discussed.

Keywords

Alkali / Alkaline flooding / Crude oil / Acid number / Soap / Surfactant

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James J. Sheng. Investigation of alkaline-crude oil reaction. Petroleum, 2015, 1(1): 31-39 DOI:10.1016/j.petlm.2015.04.004

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References

Publishing order | Descend order by publishing year | Descend order by cited within
[1]

D. Bhuyan, Development of an Alkaline/Surfactant/Polymer Flood Compositional Reservoir Simulator, Ph.D. dissertation, The University of Texas at Austin, 1989.
[2]

T.P. Castor, W.H. Somerton, J.F. Kelly,Recovery mechanisms of alkaline flooding, in: D. O. Shah (Ed.), Surface Phenomena in Enhanced Oil Recovery, Plenum Press, New York, 1981, pp. 249e291.
[3]

J.L. Cayias, R.S. Schechter, W.H. Wade, The utilization of petroleum sulfonates for producing low interfacial tensions between hydrocarbons and water, J. Colloid Interf. Sci. 59 (1) (1977) 31-38.
[4]

H.L. Chang, Z.-Q. Zhang, Q.-M. Wang, Z.-S. Xu, Z.-D. Guo, H.-Q. Sun, X.-X.- L. Cao, Q. Xiao, Advances in polymer flooding and alkaline/surfactant/polymer processes as developed and applied in the People's Republic of China, JPT (2006) 84e89 (February).
[5]

C.E. Cooke, R.E. Williams, P.A. Kolodzie, Oil recovery by alkaline waterflooding, JPT (1974) 1365e1374 (February).
[6]

E.F. deZabala, J.M. Vislocky, E. Rubin, C.J. Radke, A chemical theory for linear alkaline flooding, SPEJ (1982) 245e258 (April).
[7]

H.N. Dunning, J.W. Moore, M.O. Denekas, Interfacial activities and porphrin contents of petroleum extracts, Ind. Eng. Chem. 45 (1953) 1759e1765 (August).
[8]

R. Ehrlich, R.J. Wygal, Interaction of crude oil and rock properties with the recovery of oil by caustic waterflooding, SPEJ (1977) 263e279 (August).
[9]

T. Fan J.S. Buckley, Acid number measurements revisited, in: Paper SPE 99884 presented at the SPE/DOE Symposium on Improved Oil Recovery in Tulsa, Oklahoma, 22e26 April, 2006.
[10]

Geochmist's Workbench®: http://www.geology.uiuc.edu/Hydrogeology/hydro_gwb.htm.
[11]

G.R. Glinsmann, 1978. Aqueous surfactant systems for in situ multiphase microemulsion formation. US Patent 4,125,156, 14 November.
[12]

R.N. Healy, R.L. Reed, Immiscible microemulsion flooding, SPEJ (1977) 129e139 (April).
[13]

G.J. Hirasaki, Ion exchange with clays in the presence of surfactant, SPEJ 22 (2) (1982) 181-192.
[14]

C. Huh, Interfacial tension and solubilizing ability of a microemulsion phase that coexists with oil and brine, J. Colloid Interf. Sci. 71 (1979) 408-428.
[15]

H.Y. Jennings Jr., C.E. Johnson Jr., C.D. McAuliffe, A caustic waterflooding process for heavy oils, JPT (1974) 1344e1352 (December).
[16]

C.E. Johnson Jr., Status of caustic and emulsion methods, JPT (1976) 85e92 (January).
[17]

V. Karpan, R. Farajzadeh, M. Zarubinska, H. Dijk, T. Matsuura, M. Stoll, Selecting the “right” ASP model by history matching coreflood experiments, in: Paper SPE 144088 presented at the SPE Enhanced Oil Recovery Conference, Kuala Lumpur, Malaysia, 19e21 July, 2011.
[18]

S. Liu, Alkaline Surfactant Polymer Enhanced Oil Recovery Processes, Ph.D. dissertation, Rice University, 2007.
[19]

E.H. Mayer, R.L. Berg, J.D. Carmichael, R.M. Weinbrandt, Alkaline injection for enhanced oil recoveryea status report, JPT (1983) 209e221 (January).
[20]

N. Mungan, Certain wettability effects in laboratory waterfloods, JPT (1966) 247e252 (February).
[21]

N. Mungan, Interfacial effects in immiscible liquid-liquid displacement in porous medium, SPEJ (1966) 247e253 (September).
[22]

R.C. Nelson, J.B. Lawson, D.R. Thigpen, G.L. Stegemeier, Cosurfactantenhanced alkaline flooding, in: Paper SPE 12672 presented at the SPE/DOE Fourth Symposium on Enhanced Oil Recovery Held in Tulsa, Oklahoma, 15e18 April, 1984.
[23]

C.H. Pasquarelli, D.T. Wasan,The effect of film-forming materials on the dynamic interfacial properties of crude oileaqueous system, in: Paper presented at the Third International Conference on Surface and Colloid Science, Stockholm, 20e25 August, 1979.
[24]

PHREEQC. http://wwwbrr.cr.usgs.gov/projects/GWC_coupled/phreeqc/.
[25]

W.E. Rudzinski, L. Oehlers, Y. Zhang, Tandem mass spectrometric characterization of commercial naphthenic acids and a Maya crude oil, Energy Fuels 16 (5) (2002) 1178-1185.
[26]

A.M. Sarem,Secondary and tertiary recovery of oil by MCCF (mobilitycontrolled caustic flooding) process,in:Paper SPE 4901 presented at the SPEeAIME 44th Annual California Regional Meeting, San Francisco, California, 4e5 April, 1974.
[27]

W.K. Seifert, Carboxylic Acids in Petroleum Sediments. Progress in Chemistry of Natural Products, Springer-Verlag New York Inc., New York City, 1975.
[28]

J.J. Sheng, Modern Chemical Enhanced Oil Recovery: Theory and Practice, Elsevier, 2011.
[29]

P.J. Shuler, D.L. Kuehne, R.M. Lerner, Improving chemical flood efficiency with micellar/alkaline/polymer process, JPT (1989) 80e88 (January).
[30]

P. Subkow.Process for the removal of bitumen from bituminous deposits, US Patent No. 2,288,857, 7 July (1942).
[31]

UTCHEM,Technical Documentation for UTCHEM-9.0, a Three-dimensional Chemical Flood Simulator, 2000 (Austin, Texas, July).
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