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Permeability of Municipal Solid Waste in Bioreactor Landfill with Degradation

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Abstract

Bioreactor landfills are operated for rapid stabilization of waste, increased landfill gas generation for cost-effective energy recovery, gain in landfill space, enhanced leachate treatment, and reduced post closure maintenance period. The fundamental process of waste stabilization in bioreactor landfill is recirculation of generated leachate back into the landfills. This creates a favorable environment for rapid microbial decomposition of the biodegradable solid waste. In order to better estimate the generated leachate and design of leachate recirculation system, clear understanding of the permeability of the Municipal Solid Waste (MSW) with degradation and the factors influencing the permeability is necessary. The objective of the paper is to determine the changes in hydraulic properties of MSW in bioreactor landfill with time and decomposition. Four small-scale bioreactor landfills were built in laboratory and samples were prepared to represent each phase of decomposition. Then, the changes in hydraulic properties of MSW in bioreactor landfill with time and decomposition were determined. A series of constant head permeability tests were performed on the samples generated in laboratory scale bioreactor landfills to determine variation of permeability of MSW with degradation. The test results indicated that the permeability of MSW in bioreactor landfills decreases with decomposition. Based on the test results, the permeability of MSW at the first phase of degradation was estimated as 0.0088 cm/s at density 700 kg/m3. However, with degradation, permeability decreased to 0.0013 cm/s at the same density, for MSW at Phase IV.

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References

  • Barlaz MA, Schaefer DM, Ham RK (1989) Bacterial population development and chemical characteristics of refuse decomposition in a simulated sanitary landfill. Appl Environ Microbiol 55(1):55–65

    Google Scholar 

  • Barlaz MA, Ham RK, Schaefer DM (1990) Methane production from municipal refuse: a review of enhancement techniques and microbial dynamics. CRC Crit Rev Environ Control 19(3):557–584

    Google Scholar 

  • Bleiker ED, McBean E, Farquhar G (1993) Refuse sampling and permeability testing at the Brock Westand Keele Valley Landfills. In: Proceedings, sixteenth international Madison waste conference: municipal & industrial waste, September 22–23, 1993, pp 548–567

  • Chen HT (1995) Hydraulic conductivity of compacted municipal solid waste. Bioresour Technol 51:205–212

    Article  Google Scholar 

  • Ettala M (1987) Infiltration and hydraulic conductivity at a sanitary landfill. Aqua Fennica 17:231–237

    Google Scholar 

  • Gabr MA, Valero SN (1995) Geotechnical properties of municipal solid waste. Geotech Test J 18(2):241–255

    Google Scholar 

  • Hyder MM, Khire MV (2004) Evaluation of heterogeneity and anisotropy if waste properties on leachate recirculation in bioreactor landfills. J Solid Waste Technol Manage 30(4):233–242

    Google Scholar 

  • Jang YS, Kim YW, Lee SI (2002) Hydraulic properties and leachate level analysis of Kimpo metropolitan Landfill, Korea. Waste Manage 22:261–267

    Article  Google Scholar 

  • Korman EM, Horvitz EG, Kleppe HJ, Dalton GM (1987) Material properties of landfilled primary waste. In: Environmental conference: Portland Marriott, Portland, OR, April 27–29, pp 179–186

  • Landva A, Clark J (1986) Geotechnical testing of waste fill. In: 9th Canadian geotechnical conference, August 27–30, 1986, pp 371–385

  • Oweis IS, Khera RP (1990) Geotechnology of waste management. Butterworths, Kent, England

    Google Scholar 

  • Powrie W, Beaven RP (1999) Hydraulic properties of household waste and applications for landfills. Proc Inst Civil Eng Geotech Eng 137:235–247

    Google Scholar 

  • Powrie W, Beaven RP, Hudson AP (2005) Factors affecting the hydraulic conductivity of waste. In: International work shop, hydro-physico-mechanics of landfills, LIRIGM Grenoble University of France

  • Reinhart DR, Townsend TG (1998) Landfill bioreactor design and operation. Lewis Publishers, New York

    Google Scholar 

  • Reinhart DR, McCreanor PT, Townsend T (2002) The bioreactor landfill: its status and future. Waste Manage Res 20:172–186

    Article  Google Scholar 

  • U.S. Environmental Protection Agency (USEPA) (1998) User’s manual landfill gas emissions: Model Version 2.0, EPA/600/R-98/054, Research Triangle Park, N.C

Download references

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Authors and Affiliations

  1. Department of Civil and Environmental Engineering, University of Texas at Arlington, Arlington, TX, 76019, USA

    M. S. Hossain, K. K. Penmethsa & L. Hoyos

Authors
  1. M. S. Hossain
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  2. K. K. Penmethsa
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  3. L. Hoyos
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Correspondence to M. S. Hossain.

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Hossain, M.S., Penmethsa, K.K. & Hoyos, L. Permeability of Municipal Solid Waste in Bioreactor Landfill with Degradation. Geotech Geol Eng 27, 43–51 (2009). https://doi.org/10.1007/s10706-008-9210-7

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  • DOI: https://doi.org/10.1007/s10706-008-9210-7

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