Authors: Ali Jahanfar, Brajesh Dubey, Bahram Gharabaghi, Saber Bayat Movahed

Abstract:

Ever increasing population growth of major urban centers and environmental challenges in siting new landfills have resulted in a growing trend in design of mega-landfills some with extraordinary heights and dangerously steep slopes. Landfill failure mobility risk analysis is one of the most uncertain types of dynamic rheology models due to very large inherent variabilities in the heterogeneous solid waste material shear strength properties. The waste flow of three historic dumpsite and two landfill failures were back-analyzed using run-out modeling with DAN-W model. The travel distances of the waste flow during landfill failures were calculated approach by taking into account variability in material shear strength properties. The probability distribution function for shear strength properties of the waste material were grouped into four major classed based on waste material compaction (landfills versus dumpsites) and composition (high versus low quantity) of high shear strength waste materials such as wood, metal, plastic, paper and cardboard in the waste. This paper presents a probabilistic method for estimation of the spatial extent of waste avalanches, after a potential landfill failure, to create maps of vulnerability scores to inform property owners and residents of the level of the risk.

Keywords: Landfill failure, waste flow, Voellmy rheology, friction coefficient, waste compaction and type.

Digital Object Identifier (DOI): doi.org/10.5281/zenodo.1124319

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References:

F. Koelsch, K. Fricke, C. Mahler, and E. Damanhuri, “Stability of Landfills – the Bandung Dumpsite Desaster,” City, vol. 2000, no. July 2000.
[2] L. Quan, “Dynamic numerical run-out modeling for quantitative landslide risk assessment,” Thesis Univ. Twente, ITC, 2012.
[3] A. Rotaru, D. Oajdea, and P. Răileanu, “Analysis of the landslide movements,” Int. J. Geol., vol. 1, no. 3, 2007.
[4] G. Blight, “Slope failures in municipal solid waste dumps and landfills: a review.,” Waste Manag. Res., vol. 26, no. 5, pp. 448–463, 2008.
[5] S. M. Merry, E. Kavazanjian Jr., and W. U. Fritz, “Reconnaissance of the July 10 , 2000 , Payatas Landfill Failure,” J. Perform. Constr. Facil., vol. 19, no. 2, pp. 100–107, 2005.
[6] M. Chang, “A 3D slope stability analysis method assuming parallel lines of intersection and differential straining of block contacts,” Can. Geotech. J., vol. 39, no. 4, pp. 799–811, 2002.
[7] Robert M. Koernerl-Hon. Member ASCE and Te-Yang Soong 2, “Stability Assessment of Ten Large Landfill Failures Robert M. Koernerl-Hon. Member ASCE and Te-Yang Soong 2.”
[8] O. Hungr, “A model for the runout analysis of rapid flow slides, debris flows, and avalanches,” Canadian Geotechnical Journal, vol. 32, no. 4. pp. 610–623, 1995.
[9] M. Pirulli and F. Marco, “Description and numerical modelling of the October 2000 Nora debris flow, Northwestern Italian Alps,” Can. Geotech. J., vol. 47, no. 2, pp. 135–146, 2010.
[10] P. Revellino, O. Hungr, F. M. Guadagno, and S. G. Evans, “Velocity and runout simulation of destructive debris flows and debris avalanches in pyroclastic deposits, Campania region, Italy,” Environ. Geol., vol. 45, no. 3, pp. 295–311, 2004.
[11] S. McDougall and O. Hungr, “Dynamic modelling of entrainment in rapid landslides,” Can. Geotech. J., vol. 42, no. 5, pp. 1437–1448, 2005.
[12] M. Hürlimann, D. Rickenmann, V. Medina, and A. Bateman, “Evaluation of approaches to calculate debris-flow parameters for hazard assessment,” Eng. Geol., vol. 102, no. 3–4, pp. 152–163, 2008.
[13] M. McKinnon, “Landslide runout: statistical analysis of physical characteristics and model parameters,” no. June, 2010.
[14] A. Strouth and E. Eberhardt, “Integrated back and forward analysis of rock slope stability and rockslide runout at Afternoon Creek, Washington,” Can. Geotech. J., vol. 46, no. 10, pp. 1116–1132, 2009.
[15] O. Hungr and S. G. Evans, “Entrainment of debris in rock avalanches: An analysis of a long run-out mechanism,” Bull. Geol. Soc. Am., vol. 116, no. 9–10, pp. 1240–1252, 2004.
[16] M. McKinnon, O. Hungr, and S. McDougall, “Dynamic analyses of Canadian landslides,” in Proceedings of the Fourth Canadian Conference on GeoHazards: From Causes to Management., 2008, pp. 594–602.
[17] J. Zhang, W. H. Tang, and L. M. Zhang, “Efficient Probabilistic Back-Analysis of Slope Stability Model Parameters,” J. Geotech. Geoenvironmental Eng., vol. 136, no. January, pp. 99–109, 2010.
[18] G. L. S. Babu, M. Asce, K. R. Reddy, F. Asce, A. Srivastava, and A. M. Asce, “Influence of Spatially Variable Geotechnical Properties of MSW on Stability of Landfill Slopes,” J. Hazardous, Toxic, Radioact. WASTE© ASCE, pp. 27–37, 2014.
[19] S. Zhang and Y. Guo, “An Analytical Probabilistic Model for Evaluating the Hydrologic Performance of Green Roofs,” J. Hydrol. Eng., no. January, p. 399, 2013.
[20] J. M. Duncan, “Factors of Safety and Reliability in Geotechnical Engineering,” J. Geotech. Geoenvironmental Eng., vol. 126, no. 4, pp. 307–316, 2000.
[21] G. E. Blight, “A flow failure in a municipal solid waste landfill ? the failure at Bulbul, South Africa,” in Advances in geotechnical engineering: The Skempton conference, Thomas Telford Publishing, 2004, pp. 777–788.
[22] A. K. Chugh, T. D. Stark, and K. a DeJong, “Reanalysis of a municipal landfill slope failure near Cincinnati, Ohio, USA,” Can. Geotech. J., vol. 44, no. 1, pp. 33–53, 2007.
[23] T. Stark and H. Eid, “Municipal solid waste slope failure. II: Stability analyses,” J. Geotech. …, 2000.
[24] F. Koelsch, “Stability problems of landfills – The Payatas landslide,” pp. 1–7, 2007.