Abstract
The highly efficient and economically feasible technology for bitumen recovery from U.S. oil sands using a water-extraction approach was developed at the end of the last century. This water-based bitumen extraction process has been optimized based on observations and analysis of microscopic mechanisms of bitumen release from oil sands and the bitumen transfer to a froth product as well as measurements of interfacial properties of bitumen. The wetting mechanisms that occur in the diluent-assisted water-based processing of U.S. oil sands include bitumen film rupture and recession on sand grains and bitumen transfer to nucleated and injected gas bubbles. These mechanisms are reviewed in this contribution.
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References
Basu, S., Nandakumar, K., and Masliyah, J., 1996, “A study on oil displacement on model surfaces,” J. Colloid interface Sci., Vol. 182, pp. 82–84.
Bowman, C.W., 1967, “Molecular and interfacial properties of Athabasca tar sands,” Proceedings of the 7th World Petroleum Congress, Vol. 3, Amsterdam, The Netherlands, Elsevier Publishing Co., pp. 583–604.
Bukka, K., Miller, J.D., and Oblad, A.G., 1991a, “Fractionation and characterization of Utah tar sand bitumens: influence of chemical composition on bitumen viscosity,” Energy Fuels, Vol. 5, pp. 333–340.
Bukka, K., Miller, J.D., Hanson, F.V., and Oblad, A.G., 1991b, “Mineral matter distribution during the hot water processing of Utah tar sand,” AOSTRA J. Res., Vol. 7, pp. 101–109.
Camp, F.W., 1974, “The Tar Sands of Alberta, Canada,” Cameron Engineers Inc., Denver, CO
Camp, F.W., 1977, “Processing Athabasca tar sands — tailings disposal,” Can. J. Chem. Eng., Vol. 55, pp. 581–591.
Cha, S.M., 1991, “Pyrolysis of Oil Sands from the Whiterocks Tar Sand Deposit in a Rotary Kiln,” Ph.D. Thesis, University of Utah, Salt Lake City, Utah.
Churaev, N.V, Ershov, A.P., Esipova, N.E., Iskandarjan, G.A., Madjarova, E.A., Sergeeva, I.P., Sobolev, V.D., Svitova, T.F., Zakharova, M.A., Zorin, Z.M., and Poirier, J.E., 1994, “Interaction of oil droplets with silica surfaces,” Colloids Surfaces A: Physicochem. Eng. Aspects, Vol. 91, pp. 97–112.
Clark, K.A., 1923, “Hot water Separation of Bitumen from Alberta Bituminous Sand,” Research Council of Alberta, Report 1922, Edmonton, Alberta, Canada.
Clark, C.A., 1944, “Hot water separation of Alberta bituminous sand,” Can. Inst. Mining Metall. Trans., Vol. 47, pp. 257–274.
Clark, K.A., and Pasternack, D.S. 1932, “Hot water separation of bitumen from Alberta bituminous sand,” Ind. Eng. Chem., Vol. 24, pp. 1410–1416.
Czamecka, E., and Gillott, J.E., 1980, “Formation and characterization of clay complexes with bitumen from Athabasca oil sand,” Clays Clay Miner, Vol. 3, pp. 197–203.
Czamecki, J., Radoev, B., Schramm, L.L., and Slavchev, R., 2005, “On the nature of Athabasca oil sands,” Adv. Colloid Interface Sci., Vol. 114–115, pp. 53–60.
Dorius, J.C., 1985, “The Pyrolysis of Bitumen-Impregnated Sandstone from the PR Spring (Utah) Deposit,” Ph.D. Thesis, University of Utah, Salt Lake City.
Drelich, J., 1993, “The Role of Wetting Phenomena in the Hot Water Process for Bitumen Recovery from Tar Sand,” Ph.D. Dissertation, University of Utah, Salt Lake City.
Drelich, J., and Miller, J.D., 1994, “Surface and interfacial tension of the Whiterocks bitumen and its relationship to bitumen release from tar sands during hot water processing,” Fuel, Vol. 73, pp. 1504–1510.
Drelich, J., Hupka, J., Miller, J.D., and Hanson, F.V., 1992, “Water recycle in moderate-temperature bitumen recovery from Whiterocks oil sands,” AOSTRA J. Res., Vol. 8, pp. 139–147.
Drelich, J., Bukka, K., Miller, J.D., and Hanson, F.V., 1994, “Surface tension of toluene-extracted bitumens from Utah oil sands as determined by Wilhelmy plate and contact angle techniques,” Energy Fuels, Vol. 8, pp. 700–704.
Drelich, J., Lelinski, D., Hupka, J., and Miller, J.D., 1995, “The role of gas bubbles in bitumen release during oil sand digestion,” Fuel, Vol. 74, pp. 1150–1155.
Drelich, J., Lelinski, D., and Miller, J.D., 1996, “Bitumen spreading and formation of thin bitumen films at a water surface,” Colloids Surf. A: Physicochem. Eng. Aspects, Vol. 116, pp. 211–223.
Dussan, V.E., and Davis, S., 1974, “On the motion of a fluid-fluid interface along a solid surface,” J. Fluid Mech., Vol. 65, pp. 71–95.
Geoghegan, M., and Krausch, G., 2002, “Wetting at polymer surfaces and interfaces,” Prog. Polymer Sci., Vol. 28, pp. 261–302.
Gonzalez, G., and Middea, A., 1987, “Asphaletenes adsorption by quartz and feldspar,” J. Dispersion Sci. Technol., Vol. 8, pp. 525–548.
Gonzalez, G., and Middea, A., 1988, “The properties of the calcite-solution interface in the presence of adsorbed resins or asphaltenes,” Colloids Surfaces, Vol. 33, pp. 217–229.
Hall, A.C., Collins, S.H., and Melrose, J.C, 1983, “Stabilityof aqueous wettingfilms in Athabasca tar sands,” Soc. Petrol. Eng. J., April Issue, pp. 249–258.
Hall, E.S., and Tollefson, E.L., 1982, “Stabilization and destabilization of mineral fines-bitumen-water dispersions in tailings from oil sand extraction of Athabasca oil sands,” Can. J. Chem. Eng., Vol. 60, pp. 812–821.
Hupka, J., and Miller, J.D., 1991a, “Moderate-temperature water-based bitumen recovery from tar sand,” Fuel, Vol. 70, pp. 1308–1312.
Hupka, J., and Miller, J.D., 1991b, “Electrophoretic characterization and processing of Asphalt Ridge and Sunnyside tar sands,” Intern. J. Mineral Proces., Vol. 31, pp. 217–231.
Hupka, J., and Miller, J.D., 1992, “Tar sand pretreatment with diluent,” Paper presented at the 1992 SME Annual Meeting, Phoenix, AZ, 24–27 February 1992, Preprint No 92-122.
Hupka, J., Miller, J.D., and Cortes, A., 1983, “Importance of bitumen viscosity in the hot water processing of domestic tar sands,” Mining Eng., Vol. 35, pp.1635–1641.
Hupka, J., Oblad, A.G., and Miller, J.D., 1987, “Diluent-assisted hot-water processing of tar sands,” AOSTRA J. Res., Vol. 3, pp. 95–102.
Hupka, J., Drelich, J., Miller, J.D., White, R.R., Hanson, F.V, and Oblad, A.G., 1991, “Impact of water recycle on water-based processing of Whiterocks tar sand,” Fuel, Vol. 70, pp. 1313–1316.
Hupka, J., Miller, J.D., and Drelich, J., 2004, “Water-based bitumen recovery from diluent-conditioned oil sands,” Can. J. Chem. Eng., Vol. 82, pp. 978–985.
Johnson, L.A., Fahy, L.J., Romanowski, L.J., Barbour, R.V., and Thomas, K.P., 1980, “An echoing in-situ combustion oil recovery project in a Utah tar sand,” J. Petrol. Technol., Vol. 32, pp. 295–305.
Johnson, L.A., Fahy, L.J., Romanowski, Thomas, K.P., and Hutchinson, H.L., 1982, “A steamflood in a Utah tar sand,” J. Petrol. Technol., Vol. 34, pp. 1119–1128.
Kotlyar, L.S., Sparks, B.D., and Kodama, H., 1984, “Some chemical and mineralogical properties of fine solids derived from oil sands,” AOSTRA J. Res., Vol. 1, pp.99–106.
Kuuskraa, V.V., and Hammershaimb, V.A., eds., 1984, “Major Tar Sand and Heavy Oil Deposits of the United States,” Oklahoma City, The Interstate Oil Compact Commission.
Lamb, H., 1916, Statics, London: Cambridge University Press.
Leja, J., and Bowman, C.W., 1968, “Application of thermodynamics to the Athabasca tar sands,” Can. J. Chem. Eng., Vol. 46, pp. 479–481.
Lelinski, D., Drelich, J., Miller, J.D., and Hupka, J., 2004, “Rate of bitumen film transfer from a quartz surface to an air bubble as observed by optical microscopy,” Can. J. Chem. Eng., Vol. 82, pp. 794–800.
Liu, J., Xu, Z., and Masliyah, J., 2003, “Studies on bitumen-silica interaction in aqueous solutions by atomic force microscopy,” Langmuir, Vol. 19, pp. 3911–3920.
Liu, J., Xu, Z., and Masliyah, J., 2004, “Interaction between bitumen and fines in oil sands extraction system: Implication to bitumen recovery,” Can. J. Chem. Eng., Vol. 82, pp. 655–666.
Liu, J., Xu, Z., and Masliyah, J., 2005, “Colloidal forces between bitumen surfaces in aqueous solutions measured with atomic force microscope,” Colloids Surfaces A. Physicochem. Eng. Aspects, Vol. 260, pp. 217–228.
Long, J., Xu, Z., and Masliyah, J., 2005, “On the role of temperature in oil sands processing,” Energy Fuels, Vol. 19, pp. 1440–1446.
Long, J., Drelich, J., Xu, Z., and Masliyah, J., 2007, “Effect of operating temperature on water-based oil sands processing,” Can. J. Chem. Eng., Vol. 85, pp. 726–738
Majid, A., Sparks, B.D., and Ripmeester, J.A., 1990, “Characterization of insoluble organic matter associated with non-settling clay minerals from Syncrude sludge pond tailings,” Fuel, Vol. 69, pp. 145–150.
Malysa, K., Ng, S., Cymbalisty, L., Czamecki, J., and Masliyah, J., 1999, “A method of visualization and characterization of aggregate flow inside a separation vessel, Part 1,” Int. J. Miner. Process., Vol. 55, pp. 171–188.
Masliyah, J., Zhou, Z., Xu, Z., Czamecki, J., and Hamza, H., 2004, “Understanding water-based bitumen extraction from Athabasca oil sands,” Can. J. Chem. Eng., Vol. 82, pp. 628–654.
Miller, J.D., and Misra, M., 1982a, “Hot water process development for Utah tar sands,” Fuel Proces. Technol., Vol. 6, pp. 27–59.
Miller, J.D., and Misra, M., 1982b, “Concentration of Utah tar sands by an ambient temperature flotation process,” Intern. J. Miner Proces., Vol. 9, pp. 269–287.
Misra, M., 1981, “Physical Separation of Bitumen from Utah Tar Sands,” Ph.D. Thesis, University of Utah, Salt Lake City.
Misra, M., and Miller, J.D., 1980, “The effect of feed source in the hot water processing of Utah tar sand,” Mining Eng., Vol. 32, pp. 302–311.
Misra, M., and Miller, J.D., 1991, “Comparison of water-based physical separation processes for US tar sands,” Fuel Proces. Technol., Vol. 27, pp.3–20.
Mossop, G.D., 1980, “Geology of the Athabasca oil sands,” Science, Vol. 207, pp. 145–152.
Oblad, A.G., Bunger, W.B., Hanson, F.V., Miller, J.D., Ritzma, H.R., and Seader, J.D., 1987, “tar sand research and development at the University of Utah,” Ann. Rev. Energy, Vol. 12, pp. 283–356.
Petrov, J.G., Ralston, J., Schneemilch, M., and Hayes, R.A., 2003, “Dynamics of partial wetting and dewetting of an amorphous fluoropolymer by pure liquids,” Langmuir, Vol. 19, pp. 2795–2801.
Schramm, L.L., 1989, “The influence of suspension viscosity on bitumen rise velocity and potential recovery in the hot water flotation process for oil sands,” J. Can. Petrol. Technol., Vol. 28, pp. 73–80.
Schulze, H.J., 1993, “Flotation as a heterocoagulation process: possibilities of calculating the probability of flotation,” in Coagulation and Flocculation-Theory and Application, B. Dobias, ed., Marcel Dekker, New York, pp. 321–353.
Sepulveda, J.E., 1977, “Hot Water Separation of Bitumen from Utah Tar Sands,” M.Sc. Thesis, University of Utah, Salt Lake City.
Sepulveda, J.E., and Miller, J.D., 1978, “Separation of bitumen from Utah tar sands by a hot water digestion-flotation technique,” Mining Eng., Vol. 30, pp. 1311–1320.
Sharma, A., 1993, “Disintegration of macroscopic fluid sheets on substrates: a singular perturbation approach,” J. Colloid Interface Sci., Vol. 156, pp. 96–103.
Smith, R.J., 1980, “Asphalt Ridge Tar Sands — Flotation Behavior and Process Design,” M.Sc. Thesis, University of Utah, Salt Lake City.
Takamura, K., 1982, “Microscopic Structure of Athabasca Oil Sand,” Can. J. Chem. Eng., Vol. 60, pp. 538–545.
Takamura, K., and Chow, R.S., 1983, “A mechanism for initiation of bitumen displacement from oil sand,” J. Can. Petrol. Technol., Vol. 22, pp. 22–30.
Takamura, K., and Wallace, D., 1988, “The physical chemistry of the hot water process,” J. Can. Petrol. Technol., Vol. 27, pp. 98–106.
Van Oss, C.J., 1994, Interfacial Forces in Aqueous Media, Marcel Dekker, Inc., New York.
Vittoratos, E., Scott, G.R., and Beattle, C.I., 1990, “Cold Lake cyclic steam stimulation: a multiwell process,” SPE Reservoir Eng., Vol. 5, pp. 19–24.
Zaijic, J.E., Copper, D.G., Marshall, J.A., and Gerson, D.F., 1981, “Microstructure of Athabasca bituminous sand by freeze-fracture preparation and transmission electron microscopy,” Fuel, Vol. 60, pp. 619–623.
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Drelich, J. Wetting phenomena in oil sand systems and their impact on the water-based bitumen extraction process. Mining, Metallurgy & Exploration 25, 1–12 (2008). https://doi.org/10.1007/BF03403379
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DOI: https://doi.org/10.1007/BF03403379