The researchers at the Environmental Engineering Laboratory are tasked with acquiring knowledge to improve the quality of the environment. In particular, they work in two major areas of research, namely the development of innovative environmental technologies for the rehabilitation of contaminated environments, and the characterization of contaminated environments.
The main objective of this project is to evaluate different final cover scenarios to reduce the production of leachate in a Saint-Nicéphore landfill, located in Drummondville, Quebec. In order to assess the percolation, the Université de Sherbrooke team proposed to build an experimental plan on the existing coverage of the site. Five lysimeters were built in 4 enclosures, that is to say areas where all the runoff water is collected in order to monitor their quantity and quality over time. The quality must be monitored due to the presence of contaminated soil in some of the scenarios under study, while the quantities are used to carry out water balances over time. This project is done in collaboration with the company Waste Management and receives financial support from WM, CRSNG and CRIBIQ.
The UdeS hydraulic laboratory is one of the largest in Canada. It is used as much for the courses as for the research or the realization of expertises. Numerous assemblies and several channels allow the visualization and the experimentation of almost all the phenomena of the hydraulics with free surface and under pressure. It includes a 40 hp pump, a charging system, a gauging station, channels, numerous valves and a wave channel. Measuring instruments using the latest technologies, such as acoustic doppler velocimetry, are connected to computerized data acquisition systems.
The hydrology, hydraulics and environment research complex is a unique research infrastructure in Canada. The research complex, located outside the main campus of the University of Sherbrooke, consists of an experimental watershed and an experimental river. Covering an area of approximately 0.4 ha, the watershed is 100 m long and varies in width from 30 m at its outlet to about 50 m at its widest point. The bottom and the walls are made up of an assembly of concrete walls and geomembranes to ensure complete watertightness of the basin. The depth of the basin varies between 3 m at its outlet to almost 5 m upstream. The basin is filled with mixed soil taken from the site and made up of till, sand and gravel with spatial heterogeneities. A groundwater collection system with drainage pipes and valves is used to control the water table. A set of instruments and sensors include rain gauges, soil moisture probes, piezometers, pressure monitors, lysimeters, a weather station and a snowpack analyzer which provides a detailed portrait of the state and flux variables in the watershed.
The experimental river is made up of a dynamic river channel 3 m wide and 50 m long with an initial slope of 0.5%. The canal can wind freely in a valley 20 m wide. The corridor is filled with a mobile substrate at least 1 m thick which allows to modify the shape, the slope, the roughness and the topography. An impermeable membrane is placed under the bed and the banks of the canal to minimize water loss by infiltration. The backfill material is composed of a mixture of gravel/rounded sand. The river operates as a closed circuit system. The water, which circulates in a loop, is conveyed by two variable speed centrifugal pumps totaling 0.8 m3/s to a supply channel and a head tank and will flow into the experimental river via a weir. The depth of flow at the downstream end of the river is controlled by a flow valve, after which the water flows into a sedimentation basin and then to the pumping basin. The transported sediments are collected in the sedimentation basin and will be transported/stored upstream via the sediment recirculation system.
The infrastructure will be accessible as a priority to researchers who obtained the grant that allowed the construction, some of which are members of CentrEau, as well as to collaborating researchers. Researchers who do not collaborate with the principal investigators will also be able to use the infrastructure. Charges may apply.
