Authors: S. Desouky, A. Al sabagh , M. Betiha, A. Badawi, A. Ghanem, S. Khalil

Abstract:

Two Amphiphilic catalysts, iron (III) dodecylbenzene sulfonate and nickel (II) dodecylbenzene sulfonate, were synthesized and used in the catalytic aquathermolysis of heavy crude oil to reduce its viscosity. The prepared catalysts exhibited good performance in the aquathermolysis and the viscosity is reduced by ~ 78.9 % for Egyptian heavy crude oil. The chemical and physical properties of heavy oil both before and after reaction were investigated by FT-IR, dynamic viscosity, molecular weight and SARA analysis. The results indicated that the content of resin, asphaltene, average molecular weight and sulfur content of heavy oil is reduced after the catalytic aquathermolysis.

Keywords: Amphiphilic catalyst, Aquathermolysis, Heavy oil, Viscosity reduction.

Digital Object Identifier (DOI): doi.org/10.5281/zenodo.1086831

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References:

[1] Thomas S. and S. M. Farouq Ali, "Status and Assessment of Chemical Oil Recovery Methods", Energy Sources, 21,1999, 177–189
[2] Hitzman D. O., G. T. Sperl, "A New Microbial Technology for Enhanced Oil Recovery and Sulfide Prevention and Reduction" 1994, 171-179,SPE/DOE ninth Symposium on Improved Oil Recovery, Tulsa, OK, USA,.
[3] Xia T.X., M. Greaves, Upgrading Athabasca tar sand using toetoheel air injection, Journal of Canadian Petroleum Technology, 41 (2002) ,51– 57.
[4] Pineda–Perez L.A., L. Carbognani, R.J. Spencer, B. Maini, P. PereiraAlmao, "Hydrocarbon depletion of Athabasca core at near steamassisted gravity drainage (SAGD) conditions", Energy & Fuels 24 (2010) 5947–5954.
[5] Lee DG and Noureldin A. "Effect of water on the low-temperature oxidation of heavy oil", Energy & Fuels 3(6),1989; 713-715.
[6] Bagci S., M.V. Kok, In-situ combustion laboratory studies of Turkish heavy oil reservoirs, Fuel Processing Technology 74 (2001) 65–79.
[7] Shokrlu Y. H., Y. Maham, X. Tan , T. Babadagli, M. Gray, "Enhancement of the efficiency of in situ combustion technique for heavy-oil recovery by application of nickel ions", Fuel 105 (2013) 397– 407.
[8] Hu CZ. 'Heavy oil exploitation technology". Beijing: Petroleum Industry Publishing Inc.; 1998.
[9] Lu LH, Li MH, Su YL. "The overview of the heavy oil" AOSTRA J Res., 29(3): 269-272.
[10] Dabbous M, Fulton PF. Low-temperature-oxidation reaction kinetics and effects on the in situ combustion process. SPEJ 14(3):1974; 53–62.
[11] He B, Chen Q, Castanier LM, Kovscek AR. Improved in situ combustion performance with metallic salt additives. 2005,In: SPE 93901, SPE western regional meeting, Irvine, CA, USA.
[12] Maity, S. K., Ancheyta, J., and Marroquı´n, G., Catalytic Aquathermolysis Used for Viscosity Reduction of Heavy Crude Oils: A Review, Energy & Fuels 24, (2010), 2809–2816
[13] Hyne J B, Clark PD. Studies on the chemical reactions of heavy oils under steam stimulation condition. AOSTRAJ Res, 6(1): 1990, 29-39
[14] Clark P D, Hyne J B. Steam-oil chemical reactions: mechanism for the aquathermolysis of heavy oil. AOSTRA J Res, 1(1): 1984, 15−20 .
[15] Clark P D, Hyne J B, Tyrer J D. Chemistry of organosulfur compound types occurring in heavy oil sands: 1 High temperature hydrolysis and thermolysis of tetrahydrothiophene in relation to steam stimulation processes. Fuel, 62(8):1983, 959-962
[16] Clark P D, Hyne J B, Tyrer J D. Chemistry of organosulfur compound types occurring in heavy oil sands:2 Influence of PH on the high temperature hydrolysis of tetrathiophene and thiophene. Fuel, 63(1): 1984, 125-128
[17] Fan H F, Liu Y J, Zhao X F. Study on composition changes of heavy oils under steam treatment. Journal of Fuel Chemistry and Technology, 29(3): 2001, 269−272.
[18] Fan H F, Liu Y J, Zhao X F. A study on heavy oil recovery by in-situ catalytic aquathermal cracking. Oilfield Chemistry, 18(1): 2001, 13−16.
[19] Clark P D, Clarke R A, Hyne J B, Lesage K L. Studies on the effect of metal species on oil sands undergoing steam treatments. AOSTRA J Res, 6(1):1990, 53−64.
[20] Fan Z X, Zhao F L, Wang J X, Gong Y G. Upgrading and viscosity reduction of super heavy oil by aquathermolysis with hydrogen donor. Journal of Fuel Chemistry and Technology, 34(3):2006, 315−318.
[21] Vayssilov, G. N. "Structural and Physicochemical Features of Titanium SilicalitesCatal. Rev.sSci. Eng. 39, 1997, 209.
[22] A. Budnyk , A. Damin, S. Bordiga, A. Zecchina, "Synthesis and Characterization of High-Surface-Area Silica–Titania Monoliths" J. Phys. Chem. C, 116 (18), 2012, pp 10064–10072.
[23] Zhang, W.-H.; Lu, J.; Han, B.; Li, M.; Xiu, J.; Ying, P.; Li, C. " Direct Synthesis and Characterization of Titanium-Substituted Mesoporous Molecular Sieve SBA-15 Chem. Mater". 14, 2002, 3413−3421.
[24] B.C. Barja, J. Herszage and M. dos Santos Afonso, "Upgrading and viscosity reduction of super heavy oil by aquathermolysis" Polyhedron 20 (2001) 1821–1830
[25] Susan, M. A.; Kaneko, T.; Noda, A. and Watanabe, M. "Ion gels prepared by in situ radical polymerization of vinyl monomers in an ionic liquid and their characterization as polymer electrolytes" J. Am. Chem. Soc. 127,2005, 4976–4983.
[26] Seki, S.; Susan, A. B. H.; Kaneko, T.; Tokuda, H.; Noda, A.; Watanabe, M. " Distinct Difference in Ionic Transport Behavior in Polymer Electrolytes Depending on Matrix Polymers and Incorporated Salts" J. Phys. Chem. B 109, 2005, 3886–3892.
[27] Glasstone, S., Laidler, K.J., Eyring, H., in “The Theory of Rate Processes - The Kinetics of Chemical Reactions, Viscosity, Diffusion and Electrochemical Phenomena” McGraw-Hill, New York. 1941.
[28] LI Wei, ZHU Jian-hua, QI Jian-hua, "Application of nano-nickel catalyst in the viscosity reduction of Liaohe extra-heavy oil by aquathermolysis" J Fuel Chem Technol, 35, 2007, 176−180.