Authors: Stella A. Arnaouti, Demos C. Angelides, Theodoros N. Chatzigogos, Witold M. Pytel

Abstract:

The Želazny Most tailing pond is one of the largest facilities worldwide for waste disposal from the copper mines located in South-West Poland. A potential failure of the dam would allow more than 10 million cubic meters of contaminated slurry to flow to the valley, causing immense environmental problems to the surrounding area. Thus, the determination of the strength properties of the dam's soils and their variability is of utmost importance. An extensive site investigation consisting of more than 480 cone penetration tests (CPTs) with or without pore water pressure measurements were conducted within a period of 13 years to study the mechanical properties of the tailings body. The present work investigates the point variability of the soil strength parameters (effective friction angle

Keywords: Soil strength variability, friction angle spatial variability, Želazny Most tailing dam.

Digital Object Identifier (DOI): doi.org/10.5281/zenodo.1329863

Procedia APA BibTeX Chicago EndNote Harvard JSON MLA RIS XML ISO 690 PDF Downloads 4120

References:

[1] KGHM, Tailings Management Division. Retrieved Feb. 2011 from KGHM Polska Miedz S.A.: http://www.kghm.pl.
[2] M. Jamiolkowski, W. Carrier, R. Chandler, K. Hoeg, W. Swierczynski, and W. Wolski, "The geotechnical problems of the second world largest copper tailings pond at Želazny Most, Poland", Geotechnical Engineering Journal of the SEAGS & AGSSEA, pp. 1-15, March 2010.
[3] W. Tschuschke, Z. Mlynarek and M. Werno, "Assessment of subsoil variability with the cone penetration test", Proceedings of the Conference on Probabilistic Methods in Geotechnical Engineering, Balkema Pub., Rotterdam, 1993.
[4] Z. Mlynarek, W. Tschuschke and E. Welling, "Control of strength parameters of tailings used for costruction of reservoir dams", Proceedings of the 5th Int. Conference on Tailings and Mine Waste, Fort Collins, 26-28 January, Balkema Pub., Rotterdam, pp. 213-221, Jan. 1998.
[5] Z. Mlynarek, E. Lunne and W. Tschschke, "Use of CPT in mine tailings", Proceedings of the Int. Symposium on Cone Penetration Test, Linkoping, Sweden, pp. 211-216, 1995.
[6] P. Robertson, T. Lunne and J. Powell, Cone Penetration Testing in Geotechnical Practice, E & FN Spon/Routledge, London, 1997.
[7] S. Liao and R. Whitman, "Overburden correction factors for SPT in sand", Journal of Geotechnical Engineering, vol. 112 (3), pp. 373-377, 1986.
[8] R. Peck. W. Hanson and T. Thornburn, Foundation Engineering, John Wiley and Sons, New York, 1953.
[9] Shannon and Wilson, Inc. and T. Wolff, "Probability models for geotechnical aspects of navigation structures", prepared for St. Louis District, U.S. Army Corps of Engineers, in connection with the Upper Mississippi River Study, January, 1994.
[10] R. Sarsby, Environmental Geotechnics, Thomas Telford, London, 2000.
[11] E. Vanmarcke, "Probabilistic modeling of soil profiles", Journal of the Geotechnical Engineering Division, vol. 103 (GT11), pp. 1227-1246, 1977.
[12] E. Vanmarcke, "Reliability of earth slopes", Journal of the Geotechnical Engineering Division, vol. 103 (GT11), pp. 1247-1265, 1977.
[13] D. Cornforth, Landslides in practice, John Wiley and Sons, Inc., New Jersey, pp. 195, 2005.