Storage Capacity and Slope Stability Analysis of Municipal Solid Waste Landfills
Publication: Journal of Performance of Constructed Facilities
Volume 32, Issue 4
Abstract
Landfill storage capacity and slope stability are among the most significant engineering concerns in municipal solid waste (MSW) landfill operation. Factors that affect the landfill storage capacity and slope stability are interrelated. Research on the effects of settlement on the landfill storage capacity and stability is insufficient. In this article, storage capacity and slope stability analysis of MSW landfills was conducted on a typical valley-type landfill. A practical approach was utilized to obtain the landfill settlement and storage capacity with the one-dimensional compression model that considered different MSW compression mechanisms and the compressibility property of MSW. The influences of settlement over time on the landfill storage capacity and stability were reflected by changing the landfill scheme and the MSW property including shear strength and bulk unit weight. The factor of safety of the deformed landfill slope was estimated by the limit-equilibrium method with consideration of varied bulk unit weight and shear strength indices for MSW with a high food waste content. The quantitative effects of operational practices, including MSW filling rate, final height of MSW body, designed front slope angle and main leachate level, on the landfill storage capacity and stability were investigated. The results showed that: (1) the main leachate level is of importance to the landfill storage capacity and stability; (2) reducing the filling rate of MSW has multiple advantages: the requirement to control the main leachate level thickness in the MSW body can be diminished, more waste can be filled, and the stability of landfills can be sustained; (3) although the landfill storage capacity can be effectively improved by increasing the height of the MSW body, at the same time, it becomes more important to control the main leachate level in the MSW body to sustain the landfill stability; and (4) reducing the slope angle will help weaken the requirement of the main leachate level to sustain the landfill stability, but not necessarily decrease the landfill expansion ratio. In addition, the landfill stability assessment should be associated with the construction stage, because the factor of safety varies with time due to the development of landfill settlement and the biodegradation process.
Get full access to this article
View all available purchase options and get full access to this article.
Acknowledgments
The National Basic Research Program of China (973 Program) (No. 2012CB719806) and the China Scholarship Council are gratefully acknowledged.
References
Chen, Y. M., H. Ke, D. G. Fredlund, L. T. Zhan, and Y. Xie. 2010. “Secondary compression of municipal solid wastes and a compression model for predicting settlement of municipal solid waste landfills.” J. Geotech. Geoenviron. Eng. 136 (5): 706–717.
Chen, Y. M., T. L. Zhan, H. Y. Wei, and H. Ke. 2009. “Aging and compressibility of municipal solid wastes.” Waste Manage. 29 (1): 86–95.
Dixon, N., and D. R. V. Jones. 2005. “Engineering properties of municipal solid waste.” Geotext. Geomembr. 23 (3): 205–233.
Eid, H. T., T. D. Stark, W. D. Evans, and P. E. Sherry. 2000. “Municipal solid waste slope failure. I: Waste and foundation soil properties.” J. Geotech. Geoenviron. Eng. 126 (5): 397–407.
Ering, P., and G. L. Sivakumar Babu. 2016. “Slope stability and deformation analysis of Bangalore MSW Landfills using constitutive model.” Int. J. Geomech. 16 (4): 04015092.
Gao, W., X. C. Bian, W. J. Xu, and Y. M. Chen. 2017a. “An equivalent-time-lines model for municipal solid waste based on its compression characteristics.” Waste Manage. 68: 292–306.
Gao, W., Y. M. Chen, L. T. Zhan, and X. C. Bian. 2015. “Engineering properties for high kitchen waste content municipal solid waste.” J. Rock Mech. Geotech. Eng. 7 (6): 646–658.
Gao, W., W. J. Xu, X. C. Bian, and Y. M. Chen. 2017b. “A practical approach for calculating the settlement and storage capacity of landfills based on the space and time discretization of the landfilling process.” Waste Manage. 69: 202–214.
Gharabaghi, B., M. K. Singh, C. Inkratas, I. R. Fleming, and E. McBean. 2008. “Comparison of slope stability in two Brazilian municipal landfills.” Waste Manage. 28 (9): 1509–1517.
Gourc, J. P., M. J. Staub, and M. Conte. 2010. “Decoupling MSW settlement into mechanical and biochemical processes—Modelling and validation on large-scale setups.” Waste Manage. 30 (8): 1556–1568.
He, P. J. 2011. Solid waste disposal and recycling technology. [In Chinese.] Beijing: Higher Education Press.
Hossain, M. S., and M. A. Haque. 2009. “Stability analyses of municipal solid waste landfills with decomposition.” Geotech. Geol. Eng. 27 (6): 659–666.
Huang, Y., and G. Fan. 2016. “Engineering geological analysis of municipal solid waste landfill stability.” Nat. Hazard. 84 (1): 93–107.
Jahanfar, A., M. Amirmojahedi, B. Gharabaghi, B. Dubey, E. McBean, and D. Kumar. 2017. “A novel risk assessment method for landfill slope failure: Case study application for Bhalswa Dumpsite, India.” Waste Manage. Res. 35 (3): 220–227.
Jiang, J. G., Y. Yong, S. H. Yang, B. Ye, and C. Zhang. 2010. “Effects of leachate accumulation on landfill stability in humid regions of China.” Waste Manage. 30 (5): 848–855.
Kavazanjian, E., N. Matasović, R. Bonaparte, and G. R. Schmertmann. 1995. “Evaluation of MSW properties for seismic analysis.” In Proc., Specialty Conf. on Geotechnical Practice in Waste Disposal, Part 1 (of 2), 1126–1141. Reston, VA: ASCE.
Koerner, R. M., and T. Y. Soong. 2000. “Leachate in landfills: The stability issues.” Geotext. Geomembr. 18 (5): 293–309.
Li, Y. C., H. L. Liu, P. J. Cleall, H. Ke, and X. C. Bian. 2013. “Influences of operational practices on municipal solid waste landfill storage capacity.” Waste Manage. Res. 31 (3): 273–282.
Manassero, M., W. F. Van Impe, and A. Bouazza. 1996. “Waste disposal and containment.” In Vol. 3 of Proc., 2nd Int. Congress on Environmental Geotechnical, 1425–1474. Rotterdam, Netherlands: A.A. Balkema.
Merry, S. M., E. Kavazanjian, and W. U. Fritz. 2005. “Reconnaissance of the July 10, 2000, Payatas landfill failure.” J. Perform. Constr. Facil. 19 (2): 100–107.
Mitchell, J. K., R. B. Seed, and H. B. Seed. 1990. “Kettleman Hills waste landfill slope failure. I: Liner-system properties.” J. Geotech. Eng. 116 (4): 647–668.
MOHURD (Ministry of Housing and Urban-Rural Development of the People’s Republic of China). 2012. Technical code for geotechnical e of municipal solid waste sanitary landfill. [In Chinese.] CJJ 176-2012. Beijing: MOHURD.
Qian, X. D., R. M. Koerner, and D. H. Gray. 2001. Geotechnical aspects of landfill design and construction. Upper Saddle River, NJ: Prentice Hall.
Savoikar, P., and D. Choudhury. 2012. “Translational seismic failure analysis of MSW landfills using pseudodynamic approach.” Int. J. Geomech. 12 (2): 136–146.
Shen, L. 2011. “Liquid depth study and stability analysis of municipal solid waste landfill.” [In Chinese.] Master thesis, Zhejiang Univ.
Sivakumar Babu, G. L., K. R. Reddy, S. K. Chouskey, and S. K. Hanumanth. 2010. “Prediction of long-term municipal solid waste landfill settlement using constitutive model.” Pract. Period. Hazard. Toxic Radioact. Waste Manage. 14 (2): 139–150.
Varga, G. 2011. “Some geotechnical aspects of bioreactor landfills.” Period. Polytech. Civ. 55 (1): 39–44.
Zekkos, D., J. D. Bray, E. Kavazanjian, and N. Matasovic. 2006. “Unit weight of municipal solid waste.” J. Geotech. Geoenviron. Eng. 132 (10): 1250–1261.
Zhan, L. T., Y. M. Chen, and W. A. Ling. 2008. “Shear strength characterization of municipal solid waste at the Suzhou landfill, China.” Eng. Geol. 97 (3): 97–111.
Zhan, L. T., X. Y. Luo, R. Q. Guan, X. Zeng, J. W. Lan, Y. M. Chen, and W. A. Lin. 2013. “Failure mechanism of sludge pit and downstream waste slope of a MSW landfill.” [In Chinese.] Chin. J. Geotech. Eng. 35 (7): 1189–1196.
Zhan, L. T., H. Xu, Y. M. Chen, L. Fan, J. W. Lan, L. M. Shao, W. A. Lin, and P. J. He. 2017. “Biochemical, hydrological and mechanical behaviors of high food waste content MSW landfill: Preliminary findings from a large-scale experiment.” Waste Manage. 63: 27–40.
Zhang, W. J. 2007. “Experimental numerical study on water/leachate transport in landfill of municipal solid waste.” [In Chinese.] Ph.D. thesis, Zhejiang Univ.
Zhang, W. J., G. G. Zhang, and Y. M. Chen. 2013. “Analyses on a high leachate mound in a landfill of municipal solid waste in China.” Environ. Earth Sci. 70 (4): 1747–1752.
Information & Authors
Information
Published In
Journal of Performance of Constructed Facilities
Volume 32 • Issue 4 • August 2018
Copyright
©2018 American Society of Civil Engineers.
History
Received: Sep 25, 2017
Accepted: Jan 5, 2018
Published online: Apr 26, 2018
Published in print: Aug 1, 2018
Discussion open until: Sep 26, 2018
Authors
Metrics & Citations
Metrics
Citations
Download citation
If you have the appropriate software installed, you can download article citation data to the citation manager of your choice. Simply select your manager software from the list below and click Download.