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Abstract

The goal of the work was to develop and verify a one-dimensional monthly water budget model (MWBM) to predict leachate generation rates from operating landfills. Although there has been a considerable modelling work on the hydraulic behaviour of landfills after they reach closure, less attention has been given on such modelling for operating landfills that have a continuously changing geometry. A MWBM was developed here that accounted for landfill cell development, precipitation and evaporation, the change of the water holding capacity of a waste cell and waste decomposition. The MWBM was verified using a two-year leachate generation rate database from a new operating sanitary landfill in Greece. The MWBM results showed a very good agreement with field data whilst it was observed that peak precipitation rates followed a parallel trend with peak leachate generation rates. A distinct two-month lag phase between the model results and actual values was observed during a certain period, which is a likely indication of the presence of channelling within the waste mass. A sensitivity analysis performed in the MWBM showed that the leachate is affected by the initial municipal solid waste moisture content as well as by the precipitation rates. A linear regression empirical model showed that precipitation can still be an adequate predictor of leachate generation rates in operating landfills.

Keywords

Hydraulic modelling landfill leachate landfill hydrology water budget model leachate generation

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References

Abdoli

Ramke

Ghiasinejad

(2010) Direct evaporation from the waste body and its influence on leachate generation in landfills in arid areas. Journal of Biological Sciences 10: 107–111.

Aljaradin

Persson

(2013) Proposed water balance equation for municipal solid waste landfills in Jordan. Waste Management and Research 31: 1028–1034.

Athiniotou

Papaspyros

Komilis

(2012) Modeling leachate generation from an active sanitary landfill. In: proceedings of the 4th international solid waste conference of the Hellenic Solid Waste Association, September, Athens, Greece.

Bendz

Bengtsson

(1996) Evaporation from an active, uncovered landfill. Journal of Hydrology 182: 143–155.

Bengtsson

Bendz

Hogland

. (1994) Water balance for landfills of different age. Journal of Hydrology 158: 203–217.

Blakey

(1992) Model prediction of landfill leachate production. In: Christensen

Cossu

Stegmann

(eds) Landfilling of Waste: Leachate. London: E & FN Spon, pp.17–34.

Blight

Ball

Blight

(1992b) Moisture and suction in sanitary landfills in semiarid areas. Journal of Environmental Engineering 118: 865–877.

Blight

Hojem

Ball

(1992a) Production of landfill leachate in water-deficient areas. In: Christensen

Cossu

Stegmann

(eds) Landfilling of Waste: Leachate. London: E & FN Spon, pp.35–51.

Di Bella

Di Trapani

Mannina

. (2012) Modeling of perched leachate zone formation in municipal solid waste landfills. Waste Management 32: 456–462.

10.

Evangelou

Kotsiari

Gerassimidou

. (2013) Monitoring the performance of two municipal solid waste mechanical and biological pre-treatment facilities in Greece. In: proceedings of the 13th international conference on environmental science and technology (CEST 2013), September, Athens, Greece.

11.

Farquhar

(1989) Leachate: production and characterization. Canadian Journal of Civil Engineering 16: 317–325.

12.

Fenn

Hanley

Degeare

(1975) Use of the water balance method for predicting leachate generation from solid waste disposal sites. EPA 530/SW-168, Cincinnati, Ohio: US Environmental Protection Agency, PA, DC, USA.

13.

Kmet

(1982) Environmental Protection Agency’s 1975 water balance method – its use and limitations. Guidance Report. Bureau of Solid Waste Management, Wisconsin DNR, Madison, WI, USA.

14.

Komilis

Ham

Stegmann

(1999) The effect of municipal solid waste pretreatment on landfill behavior: A literature review. Waste Management & Research 17: 10–19.

15.

Lobo

Herrero

Montero

. (2002) Modelling of environmental assessment of municipal solid waste landfills (Part 1: Hydrology). Waste Management and Research 20: 198–210.

16.

Lobo

Monzón

(2007) MODUELO 2: A new version of an integrated simulation model for municipal solid waste landfills. Environmental Modelling & Software 22: 59–72.

17.

Lobo

Munoz

Sánchez

. (2003) Comparative analysis of three hydrological landfill models (Moduelo 1, HELP and Moduelo 2) through a practical application. In: proceedings of the 9th international waste management and landfill symposium, Sardinia, Italy.

18.

Oni

(2010) Numerical simulation of the mass flow of leachate in a municipal waste fill (Part 1) – Closed recycling flow systems. Journal of Applied Sciences Research 6: 742–750.

19.

Orta de Velasquez

Cruz-Rivera

Rojas-Valencia

. (2003) Serial water balance method for predicting leachate generation in landfills. Waste Management & Research 21: 127–136.

20.

Perrier

Gibson

(1981) Hydrologic simulation on solid waste disposal sites. Report no. EPA-530/SW-868, US Environmental Protection Agency, PA, DC, USA.

21.

Poulsen

Moldrup

(2005) Factors affecting water balance and percolate production for a landfill in operation. Waste Management and Research 23: 72–78.

22.

Schroeder

Dozier

Zappi

. (1994) The Hydrologic Evaluation of landfill performance (HELP) model: Engineering documentation for version 3. EPA/600/R-94/168b US Environmental Protection Agency, PA, DC, USA.

23.

Tchobanoglous

Theisen

Vigil

(1993) Integrated Solid Waste Management: Engineering Principles and Management Issues. New York: McGraw-Hill, pp.508–523.

24.

Vardavas

(2010) The water resources of Greece under changing climatic conditions-GREEK Waters. Latsis Research Final Technical Report. Available at: http://www.latsis-foundation.org/files/Programmes2008–2009/Vardavas-Final-Report.pdf (accessed March 2014).

25.

Yildiz

Ünlü

Rowe

(2004) Modelling leachate quality and quantity in municipal solid waste landfills. Waste Management Research 22: 78–92.

26.

Yuen

Wang

Styles

. (2001) Water balance comparison between a dry and a wet landfill – a full-scale experiment. Journal of Hydrology 251: 29–48.

A water budget model for operating landfills: An application in Greece

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