/// Examples of applications:
- Separating and concentrating metal nanoparticles
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 hydraulics laboratory of the civil engineering department has several equipment to reproduce flows with free surface and load. 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. As part of research activities, specific editing can be done. Currently, we can observe a test bench to assess, in full size, the hydraulic capacity of the storm sewer grilles.
/// Features
- A 5-litre digester with autonomous programming for anaerobic digestion
LIASHyC aims to be a world reference in the field of complex hydrogeological systems through the quality and relevance of its research and innovation, training and transfer activities. The research and innovation program focuses on fractured media hydrogeology, hydrogeology of northern and alpine regions, and characterization of hydrogeological heterogeneities. LIASHyC consists of the following parties:
- Institute of Earth Sciences of the UNIL (ISTE-UNIL)
- Center of Hydrogeology and Geothermal Energy of UNINE (CHYN-UNINE)
- Center Eau Terre Environnement of the INRS
- Department of Geology and Geological Engineering of Laval University
This laboratory is used in particular to carry out research work on understanding the environmental fate of energetic materials. The laboratory consists of two experimental pans, the size of which makes it possible to carry out restoration experiments similar to field conditions, but under controlled experimental conditions. These tanks can contain 4 to 9 m3 of soil from contaminated sites or clean soils to which specific contaminants can be added.
This laboratory aims to develop electrolytic techniques and oxidative processes to improve municipal and industrial wastewater treatment systems or replace conventional low efficiency technologies to remove refractory, inorganic and microbial organic contaminants. It includes 4 facilities: a) Laboratory treatment and control units, b) Analytical instrumentation units, c) Assembly of units, storage of reagents, installation ovens and scales, d) Heavy lab (pre-industrial pilot unit).
This laboratory consists of a physical model of a municipal drinking water distribution network aimed at better management of these networks. The infrastructure replicates a typical sector of a municipal drinking water system. The pipes are about 2/3 of the actual diameter and pressure of a real network. The network is equipped with numerous sensors (flow, pressure, conductivity), pressure regulators, isolation valves and faucets (to simulate water usage or leaks) that are all connected to a central computer system . The assembly is designed to be more versatile.
The BioEngine laboratory in the Department of Chemical Engineering at Université Laval includes high-end equipment and pilots for resource recovery from waste materials and polluted water. It includes methanogenic potential reactors (BMP), semi-continuous biomethanization reactors in 1, 2 or 3 phases, composting and controlled aerobic conditioning reactors, a fluidized bed granulator, a pilot for phosphorus recovery by adsorption, a nitrogen recovery set-up by stripping and absorption, a membrane bioreactor, a measurement station for real-time monitoring of physicochemical and biological parameters, as well as equipment for characterizing water and residual organic matter.
Analysis of trace metals in liquid or solid samples (biological tissues, suspended matter, sediments, soils) and bio-optical analysis. Research focuses on the path of toxic metals in the food chain, the bioavailability of contaminants, the impacts of anthropogenic activities and the assessment of the sensitivity of the natural environment. The main equipment is as follows: Particle and radioactivity counters (beta and gamma emissions); Atomic and mass emission spectrometers, by inductively coupled plasma (ICP-AES and ICP-MS); Liquid, gas and ion chromatography devices (HPLC, LC-MS-MS, GC, GC-MS); ICP-MS coupled to an HPLC; Mercury analyzer.
