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Effect of Salt on the Flocculation Behavior of Nano Particles in Oil Sands Fine Tailings

Published online by Cambridge University Press:  28 February 2024

L. S. Kotylar
Affiliation:
Institute for Environmental Research and Technology, National Research Council of Canada, Ottawa, Ontario, Canada, K1A 0R6
B. D. Sparks
Affiliation:
Institute for Environmental Research and Technology, National Research Council of Canada, Ottawa, Ontario, Canada, K1A 0R6
R. Schutte
Affiliation:
Syncrude Canada Limited, Edmonton, Alberta, Canada, T6P 1V8
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Abstract

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Currently, two commercial plants, operating in the Athabasca region of Alberta, produce approximately 20 percent of Canada's petroleum requirements from oil sands. Surface mined oil sand is treated in a water based separation process that yields large volumes of clay tailings with poor settling and compaction characteristics. Clay particles, suspended in the pond water, interact with salts, dissolved from the oil sands ore, to produce mature fine tailings (MFT) containing only 20 to 50 w/w% solids. As a result, large sedimentation ponds are required to produce enough process water to recycle for the plant. Tailings pond dykes can only be constructed during a short summer season. Consequently, the capability to predict production rate and final volume of MFT is essential for mine planning and tailings disposal operations.

Previous research has demonstrated that a small fraction of nano sized clay particles (20 to 300 nm) effectively controls the bulk properties of MFT. These particles are present in the original ore and become mobilized into the water phase during the oil separation process. In this work, the nano sized particles have been separated from the bulk tailings and subjected to a fundamental study of their flocculation behavior in model tailings water.

Photon correlation spectroscopy and a deuterium NMR method were used to follow particle flocculation and gelation processes. These results were correlated with particle settling data measured under the same conditions. It was determined that the nano particles form fractal flocs that eventually interact to give a thixotropic gel. The ultimate sediment volume produced is almost entirely dependent on the original concentration of nano particles while the rate of water release is governed primarily by electrolyte concentration.

Type
Research Article
Copyright
Copyright © 1996, The Clay Minerals Society

References

Berne, B.J. and Pecora, R.. 1976. Dynamic Light Scattering. New York: Wiley. 376p.Google Scholar
Brinker, C.J. and Scherer, G.W.. 1990. Sol-gel science: The Physics and Chemistry of Sol-gel Processing. Boston: Academic Press Inc. 908p.Google Scholar
Cametti, C., Codestafano, P. and Tartaglia, P.. 1989. Aggregation kinetics in model colloidal systems: a light scattering study. J Coll Interf Sci 131: 409422.CrossRefGoogle Scholar
Camp, F.W.. 1977. Processing Athabasca tar sand: tailings disposal. Proceedings 26th Can. Chem. Eng. Conference, Symp. on Tar Sands, Toronto. Paper 9a.CrossRefGoogle Scholar
Hoekstra, L.L., Vreeker, R. and Agterof, W.G.M.. 1992. Aggregation of colloidal nickel hydroxycarbonate studied by light scattering. J Coll Interf Sci 151: 1725.CrossRefGoogle Scholar
Kotlyar, L.S., Sparks, B.D., Schutte, R. and Capes, C.E.. 1992a. Gel forming attributes of colloidal solids from fine tailings, formed during extraction of bitumen from Athabasca oil sands by the Hot Water process. AOSTRA J Res 8: 5561.Google Scholar
Kotlyar, L.S., Lynds, M.M., Sparks, B.D., Schutte, R. and Woods, J.R.. 1992b. Colloidal solids from sludge: effect of particle size on gel forming propensity in distilled and pond water. To Oil Sands Fine Tailings Fundamentals Consortium, NRCC Internal Report. EC-1243-92S, Ottawa, Ontario, Canada.Google Scholar
Kotlyar, L.S., Deslandes, Y., Sparks, B.D., Kodama, H. and Schutte, R.. 1993. Characterization of colloidal solids from Athabasca sludge. Clays and Clay Miner 41: 341345.CrossRefGoogle Scholar
Kotlyar, L.S., Sparks, B.D., Deslandes, Y. and Schutte, R.. 1994. The role of biwetted colloidal solids in structure formation in oil sands fine tailings. Fuel Sci Technol 12: 923935.CrossRefGoogle Scholar
Lin, M.Y., Lindsay, H.M., Weitz, D.A., Ball, R.C., Klein, R. and Meakin, P.. 1990. Universal reaction limited colloid aggregation. Phys Rev 41: 20052020.CrossRefGoogle ScholarPubMed
Mandelbrot, B.B.. 1982. The fractal geometry of nature. San Francisco: W.H. Freeman. 460p.Google Scholar
Ripmeester, J.A., Kotlyar, L.S. and Sparks, B.D.. 1993. 2H NMR and the sol-gel transition in suspensions of colloidal clays. Colloids and Surfaces 78: 5763.CrossRefGoogle Scholar
Verwey, E.J.W. and Overbeek, J.T.G.. 1948. Theory of stability of lyophobic colloid. Amsterdam: Elsevier. 205p.Google Scholar
Weitz, D.A., Huang, J.S., Lin, M.Y. and Sung, J.. 1984. Dynamics of Diffusion-Limited Kinetic Aggregation. Phys Rev Lett 53: 16571660.CrossRefGoogle Scholar
Weitz, D.A., Lin, M.Y. and Lindsay, H.M.. 1991. Universality laws in coagulation. Chemomet Intell Lab Syst 10: 133140.CrossRefGoogle Scholar