Understanding leachate flow in municipal solid waste landfills by combining time-lapse ERT and subsurface flow modelling – Part I: Analysis of infiltration shape on two different waste deposit cells

•MICS on two ERT time-lapse monitoring.•Leachate flow behaviour.•Useful for hydrodynamic models. Landfill bioreactors are based on an acceleration of in-situ waste biodegradation by performing leachate recirculation. To quantify the water content and to evaluate the leachate injection system, in-sit...

Full description

Saved in:
Bibliographic Details
Published in:Waste management (Elmsford) 2016-09, Vol.55, p.165-175
Main Authors: Audebert, M., Clément, R., Moreau, S., Duquennoi, C., Loisel, S., Touze-Foltz, N.
Format: Article
Language:English
Subjects:
Biodegradation, Environmental
Bioreactors
Computational fluid dynamics
Deposits
Electrical resistivity tomography
Environmental Sciences
Fluid flow
Hydrodynamic
Hydrodynamics
Infiltration
Infiltration shape
Landfills
Leachate flow
Leachates
Models, Theoretical
Refuse Disposal - methods
Solid Waste - analysis
Waste Disposal Facilities
Wastes
Water Movements
Water Pollutants, Chemical - analysis
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:•MICS on two ERT time-lapse monitoring.•Leachate flow behaviour.•Useful for hydrodynamic models. Landfill bioreactors are based on an acceleration of in-situ waste biodegradation by performing leachate recirculation. To quantify the water content and to evaluate the leachate injection system, in-situ methods are required to obtain spatially distributed information, usually electrical resistivity tomography (ERT). In a previous study, the MICS (multiple inversions and clustering strategy) methodology was proposed to improve the hydrodynamic interpretation of ERT results by a precise delimitation of the infiltration area. In this study, MICS was applied on two ERT time-lapse data sets recorded on different waste deposit cells in order to compare the hydrodynamic behaviour of leachate flow between the two cells. This comparison is based on an analysis of: (i) the volume of wetted waste assessed by MICS and the wetting rate, (ii) the infiltration shapes and (iii) the pore volume used by the leachate flow. This paper shows that leachate hydrodynamic behaviour is comparable from one waste deposit cell to another with: (i) a high leachate infiltration speed at the beginning of the infiltration, which decreases with time, (ii) a horizontal anisotropy of the leachate infiltration shape and (iii) a very small fraction of the pore volume used by the leachate flow. This hydrodynamic information derived from MICS results can be useful for subsurface flow modelling used to predict leachate flow at the landfill scale.
ISSN:0956-053X
1879-2456
DOI:10.1016/j.wasman.2016.04.006