Authors: Josefina Barnachea Janier, Radzuan B. Razali, Afza Shafie, Brahim Belhaouari Samir

Abstract:

In the Enhanced Oil Recovery (EOR) method, use of Carbon dioxide flooding whereby CO₂ is injected into an oil reservoir to increase output when extracting oil resulted significant recovery worldwide. The carbon dioxide function as a pressurizing agent when mixed into the underground crude oil will reduce its viscosity and will enable a rapid oil flow. Despite the CO₂’s advantage in the oil recovery, it may result to asphaltene precipitation a problem that will cause the reduction of oil produced from oil wells. In severe cases, asphaltene precipitation can cause costly blockages in oil pipes and machinery. This paper presents reviews of several studies done on mathematical modeling of asphaltene precipitation. The synthesized result from several researches done on this topic can be used as guide in order to better understand asphaltene precipitation. Likewise, this can be used as initial reference for students, and new researchers doing study on asphaltene precipitation.

Keywords: Asphaltene precipitation, crude oil, carbon dioxide flooding, enhanced oil recovery.

Digital Object Identifier (DOI): doi.org/10.5281/zenodo.1088472

Procedia APA BibTeX Chicago EndNote Harvard JSON MLA RIS XML ISO 690 PDF Downloads 3942

References:

[1] “Types of Crude Oil-Classification of Crude Oil”, Oil Proces.org News on Oil, Natural Gas & Energy Prices http://www.oilprices.org/types-ofcrude- oil.html. Accessed on Jan. 18,2013.
[2] “What is Crude Oil? A Detailed Explanation on this Essential Fossil Fuel” http://oilprice.com/Energy/Crude-Oil/.What-is-Crude-Oil-ADetailed Explanation-on-this-Essential-Fossil-Fuel. Accessed on January 18, 2013.
[3] API Gravity, Wikipedia, the Free Encyclopedia, http://en.wikipedia.org
[4] /wiki/API_gravity. Accessed on Jnauary 17,2013. Neste Oil.org Refining the Future, http://twitter.com/nesteoilgroup. Accessed on January 18, 2013.
[5] L.W. Lake, R.L. Schim AND p. b. Venuto, “A Niche for Enhanced Oil Recovery in the 1990’s, 1992.
[6] Enhanced Oil Recovery Wikipedia the Free Encyclopedia, http://en.wikipedia.org/wikiEnhanced_oil_recovery, Accessed on January 21, 2013.
[7] F.M. Nazir and Y.Y. Chong, The Effect of Didderent Carbon Dioxide Modes on Oil Recovery, International Journal of Engineering and Technology IJET Vol.9, No. 10, pp. 66-72, November 2009.
[8] D Green and G. Willhite, “Enhanced Oil Recovery”, Society of Petroleum Engineers, Richardson, Texas, 1998.
[9] I. H. Auflem, “Influence of Asphaltene Agregation and Pressure on Crude Oil Emulsion Stability”, PhD Dissertation, Department of Chemical Engineering Norwegian University of Science and Technology, Trondheim, p. 10, June, 2002.
[10] s. Sim, K. Takabayashi, K. Okashu and D. Fisher, “Asphaltene Induced Formation Damage: Effect of Asphaltene Particle Size and Core Permeability”, SPE95515, Proceedings in SPE Annual technical Conference and Exhibition, Dallas, Texas, USA, October 9-12,2005.
[11] S.L. Kokal and S.G. Sayegh, “Asphaltenes: The Cholesterol of Petroleum”, SPE29787, Proceedings in SPE1995 Middle East Oil Show, Bahrain, March 11-14, 1995.
[12] Paraffin Deposition and Control, http://paraffindepositionand control.wikispaces.com/5.+Asphaltene, Accessed on January 21, 2013.
[13] G. King, “Asphaltenes”. GEKingengineering.com, http://gekinginengineering.com.Downloads/Free_Downloads/Asphalten e_Deposition_and_Removal.pdf, Accessed on September 15, 2011.
[14] Micelle-Wikipedia, the Free Encyclopedia, http://en.wikipedia.org/wiki/ Micelle, Accessed on January 21, 2013.
[15] S. Takahashi, Y. Hayashi, N. Yazawa and H. Sarma, Characteristics and Impact of Asphaltene Precipitation During CO2 Sandstone and Carbonate Cores: An Investigation Analysis through Laboratory Test and Compositional Simulations, SPE 84895, 2003.
[16] D. Fisher, N. Yazawa, H. Sarma, M. Girard, A. Turta, H. Huang, A New Method to Characterize the Size and Shape Dynamics of Asphaltene Deposition Process in CO2 Miscible Flooding, SPE84893, International Improved Oil Recovery Conference Asia Pacific in Kuala Lumpur, Oct. 20-21,2003.
[17] R.S.Srivasttava, S. Huang, Asphaltene Deposition during CO2 Flooding: A Laboratory Assessment, SPE 37468, 1977.
[18] S. Verdier, H. Carrier, S. Andersen, J. Daridon, Study of Pressure and Temperature Effects on Asphaltene Stability in Presence of CO2 Energy Fuels, Vol. 20, pp. 1584-1590,2006.
[19] D Gonzales, F. Vargas, G. Hirasaki, W. Chapman, Modeling Study of CO2 –Induced Asphaltene Precipitation, Energy and Fuels Vol. 22, pp. 757-762, 2008.
[20] L. Nghiem and D. Combe, “Modeling Asphaltene Precipitation During Primary Depletion”, SPE 36106, SPE 4th Latin America and Carribean Petroleum Engineering Conference, Spain, Trinidad and Tobago, April 23-26, 1966.
[21] S. Alian, A. Omar and I Hani, “Study of Asphaltene Precipitation Induced Formation Damage during CO2 Injection for a Malaysian Light Oil”, World Academy of Science, Engineering and Technology, 78, pp. 733-737.
[22] A. Khanifar, B. Demiral, S. Alian and N. Darman, “Study of Asphaltene Precipitation and Deposition Phenomenon”, IEEE, 2011
[23] L. Nabzar, M. Aguilera and Y. Rajoub, Experimental Study on Asphaltene Induced Formation Damage, SPE International Symposium on Oilfield Chemistry, Society of Petroleum Engineers Inc., The Woodlands, Texas, 2005.
[24] S. Wang and F. Civan, Productivity Decline of Vertical and Horizontal Wells by Asphaltene Deposition in Petroleum Reservoirs, SPE International Symposium on Oilfield Chemistry, SPE Inc., Houston Texas, 2001.
[25] R.T. Okwen, Formation Damage by CO2 Asphaltene Precipitation, International Symposium and Exhibition on Formation Damage Control, SPE, Lafayette, Louisiana, USA, 2006.
[26] A. Kalantari-Dahghi, et al., Formation Damage through Asphaltene precipitation Resulting from CO2 Gas Injection in Iranian Carbonate Reservoir, SPE Production and Operation 23(2),2008.
[27] B.D. Zarin Nasri, Effect of Asphaltene Deposition on Oil Reservoir Characteristics Including Two-Phase Flow, Journal of the Japan Petroleum Institute, 2009.
[28] L. Minssieux, Core Damage From Crude Asphaltene Deposition, International Symposium on Oilfield Chemistry, SPE Inc., 1997.
[29] L. X. Nghiem, et al., Efficiency Modeling of Asphaltene Precipitation, SPE Annual Technical Conference and Exhibition, SPE Inc., 1993.
[30] E. Buenrostro Gonzales, C. Lira Galeana, A. Gil Villegran, and J. Wu, “Asphaltene Precipitation in Crude Oils’ Theory and Experiments”, American Institute of Chemical Engineers Journal, Vol. 50,10, pp.. 2552-2570, October 2004.
[31] N. Burke, R. Hobbs, and S. Kashou, “Measurement and Modeling of Asphaltene Precipitation”, Journal of Petrol Technology, 42,1440,1990
[32] S. Kawanaka, S. Park, and G. Mansoori, “Organic Deposition from reservoir Fluids: A Thermodynamic Predictive Technique”, SPE, Reservoir Engineering, 185, May 1991.
[33] K. Mannistu, H. Yarranton, and J. Masliyah, “Solubility Modeling of Asphaltene in Organic Solvents”, Energy Fuels, 11, 615, 1997.
[34] S. Godbole and K. Thele, “EOS Modeling and Experimental Observations of Three-Hydrocarbon-Phase Equilibria”, SPE24936, SPE Annual Technical Conference and Exhibition, Washington D.C., October 4-7, 1992.
[35] B. Koshe, L. Nghiem, H. Maeda, and K. Ono, “Modeling Phase Behavior Including the Effect of Pressure and Temperature on Asphaltene Precipitation”, SPE 64465, SPE Asia Pacific Oil and Gas Conference and Exhibition, Brisbane, Oct. 16-18, 2000.
[36] W. Chapman, K. Gubbins, G. Jackson, and M. Radosz, “SAFT: Equation of State Solution Model for Associating Fluids”, Fluid Phase equilibria, 52,31,1989.
[37] W. Chapman, K. Gubbins, G. Jackson, and M. Radosz, “New Reference Equation of State for Associating Liquids”, Ind. Eng. Chem. Research, 29, 1709, 1990.