Surfactant flooding characteristics of dodecyl alkyl sulfate for enhanced oil recovery

Kwan Min Ko; Bo Hyun Chon; Sung Bum Jang; Hee Yeon Jang

Journal of Industrial and Engineering Chemistry, Vol.20, No.1, 228-233, January, 2014

DOI10.1016/j.jiec.2013.03.043 Export Citation

Surfactant flooding characteristics of dodecyl alkyl sulfate for enhanced oil recovery

Kwan Min Ko, Bo Hyun Chon^†, Sung Bum Jang, and Hee Yeon Jang

Department of Energy Resources Engineering, INHA University, Incheon 402-751, Republic of Korea

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Surfactant-enhanced oil recovery is a type of enhanced oil recovery (EOR), a method to produce residual oil by injecting surfactant solution into the reservoir. The application of surfactant EOR requires knowledge of the phase behavior for more efficient production of residual oil. In this study, the relationship between dodecyl alkyl sulfate and some specific crude oils was examined through phase behavior test. It was found that the branched surfactant was more effective than the linear surfactant. The system was stable at salinities <3 wt%. On adding a small amount of cosurfactant, the emulsion activity was increased. The gravity drainage flooding test (GDFT) was performed to determine the potential of dodecyl alkyl sulfate to produce residual oil in porous media. It was found that the solution could be flooded at temperatures of 60 ℃ or higher. In the core flooding test, injecting one pore volume of 2 wt% surfactant solution with 3 wt% salinity produced 26.6% more oil after water flood. With the addition of only 0.01 wt% co-surfactant, oil production increased by 1.6%. Contrary to the phase behavior test, the linear surfactant produced 1.3% more oil than the branched surfactant in the core flooding test.

Keywords:Enhanced oil recovery (EOR);Surfactant EOR;Dodecyl alkyl sulfate;Phase behavior test;Gravity drainage flooding test (GDFT)

[References]

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Austad T, Fjelde I, Veggeland K, Taugbol K, Journal of Petroleum Science and Engineering., 10, 255 (1994)
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[Referenced By]

[1] Watkins C, Chemically Enhanced Oil Recovery Stages a Comeback, Inform, 682 (2009)

[2] Mjeni RA, Arora S, Cherukupalli P, Van Wunnik J, Edwards J, Felber BJ, Gurpinar O, Hirasaki GJ, Miller CA, Jackson C, Kristensen MR, Lim F, Ramamoorthy R, Schlumberger, 22, (2010/2011) 16

[3] Austad T, Fjelde I, Veggeland K, Taugbol K, Journal of Petroleum Science and Engineering., 10, 255 (1994)

[4] Jung J, Zhang K, Chon B, Choi H, Journal of Applied Polymer Science., 6, 4833 (2013)

[5] Bo G, Sharma MM, Ann. Tech. Conf. Society of Petroleum Engineers, San Antonio, TX, USA (2012)

[6] Sriram S, Christopher B, Jun L, Do Hoon K, Upali W, Gary AP, Improved Oil Sriram, B. Christopher, L. Jun, K. Do Hoon, W. Upali, A.P. Gary, Improved Oil (2012)

[7] Aoudia M, Wade WH, Weerasooriya V, Journal of Dispersion Science and Technology., 2, 16 (1995)

[8] Laurier L, Schramm, Surfactants Fundamentals and Applications in the Petroleum Industry, Cambridge University, Cambridge, United Kingdom (2000)

[9] Drew M, Surfactant Science and Technology, 3rd ed., John Wiley & Sons, Inc., Hoboken, New Jersey (2006)

[10] Levitt DB, Jackson AC, Heinson C, Britton LN, Malik T, Dwarakanth V, Pope GA, SPE Reservoir Evaluation & Engineering., 12, 2 (2009)

[11] Ping Z, Adam Jackson C, Chris B, Do Hoon K, Britton NL, David DB, Gary A, Improved Oil Recovery Symp. Society of Petroleum Engineers, Tulsa, OK, USA (2008)

[12] Barnes JR, Smit JP, Smith R, Puerto MC, Improved Oil Recovery Symp. Society of Petroleum Engineers, Tulsa, OK, USA (2008)

[13] Jayanti S, Brieeon LN, Dwarakanath V, Pope GA, Environmental Science and Technology., 36, 5491 (2002)

[14] Levitt DB, Thesis MS, University of Texas at Austin, Austin, Texas (2006)

[15] Jackson AC, Thesis MS, University of Texas at Austin, Austin, Texas (2006)

[16] Winsor PA, Solvent Properties of Amphiphilic Compounds, Butterworths Scientific Publ. Ltd., London (1954)

[17] Aarra MG, Hoiland H, Skauge A, J. Colloid Interface Sci., 215(2), 201 (1999)

[18] Nakamae M, Abe M, Ogino K, Journal of Colloid and Interface Science., 31, 466 (1988)

[19] Sripriya R, Raja KM, Santhosh G, Chandrasekaran M, Noel M, J. Colloid Interface Sci., 314(2), 712 (2007)

[20] Chai JL, Zhao JR, Gao YH, Yang XD, Wu CJ, Colloids and Surfaces A, 302, 31 (2007)

[21] Chen L, Shang Y, Liu H, Hu Y, Colloids and Surfaces A., 305, 29 (2007)

[22] Bazin B, SPE Chemical EOR Workshop, Chemical EOR Surfactant Design and Crude Oil Compatibility for ASP, Penang, Malaysia (2011)

[23] Marten B, SPE Chemical EOR Workshop, Chemical EOR Surfactant Design and Crude Oil Compatibility for ASP, Penang, Malaysia (2011)

[24] Cha JH, Journal of The Korean Society for Geosystem Engineering., 48, 178 (2011)