Débordements d'égouts unitaires et protection des sources d'eau potable: intégration des changements globaux

RÉSUMÉ La qualité de l’eau est indéniablement liée à son environnement. En milieu urbain, la qualité de l’eau peut être dégradée par le déversement d’eaux usées sans traitement dans les sources. De plus, cette dégradation peut être accélérée par les changements globaux comme les changements climatiques et l’accroissement de la population. Enfin, l’intensification des précipitations, prévue par plusieurs études, peut mener à l’augmentation des événements de contamination fécale. Pourtant, peu d’études ont été menées pour caractériser les impacts des changements globaux sur la qualité microbienne de l’eau des sources d’approvisionnement en eau potable. Dans ce travail, nous appliquons un modèle hydrodynamique géolocalisé qui permet, à l’aide de scénarios, de caractériser les impacts des changements globaux sur la qualité de l’eau en milieu urbain. La rivière étudiée se situe dans le sud du Québec en bordure de deux municipalités fortement urbanisées et ne peut être explicitement citée pour cause de confidentialité.----------ABSTRACT Water quality is directly linked to its environment. In older urban areas, water quality can be degraded by the outfalls of untreated wastewater from combined sewers and is of concern if these waters are used as drinking water sources. Moreover, this degradation can be accelerated by global changes such as climate change and population growth. In addition, the intensification of rainfall events, as predicted by several studies, will increase the number of fecal contamination events. Yet, few studies have quantified the impacts of global changes on microbial water quality of drinking water sources. In this study, we applied a georeferenced hydrodynamic model, which enabled us to characterize the impacts of global changes in an urban area, through different scenarios. The river studied here is located in the south of the province of Quebec, between two highly urbanized municipalities

Hydrodynamic modelling and the dispersion of water fecal contaminants in current and future climates

10 p.International audienceDuring precipitation events in regions with combined sewers, overflows can occur upstream of drinking water treatment plants. The purpose of the research was to model the transport and propagation of pathogens and pharmaceuticals in the Rivière Des Prairies during flood and low flow events. The water quality is quantified in terms of the behaviour of the river, the interactions of contaminants with the environment and the impacts of climate change. Hydrosim was used for hydrodynamic modeling; Dispersim was used to model the dispersion of contaminants. The impact of climate change was represented by the change of flow in the river. To do so, simulations were performed using Hydrotel, a hydrologic model applied to the Ottawa River. Thus, the impact of dispersion and diffusion of contaminants on the water quality were analyzed to determine the potential impact on raw water quality. Water quality will be affected by lower flows and heavy rains, which will change the frequency distributions of fecal contaminants upon which microbial risk models are based

Cumulative effects of fecal contamination from combined sewer overflows: Management for source water protection

The quality of a drinking water source depends largely on upstream contaminant discharges. Sewer overflows can have a large influence on downstream drinking water intakes as they discharge untreated or partially treated wastewaters that may be contaminated with pathogens. This study focuses on the quantification of Escherichia coli discharges from combined sewer overflows (CSOs) and the dispersion and diffusion in receiving waters in order to prioritize actions for source water protection. E. coli concentrations from CSOs were estimated from monitoring data at a series of overflow structures and then applied to the 42 active overflow structures between 2009 and 2012 using a simple relationship based upon the population within the drainage network. From these estimates, a transport-dispersion model was calibrated with data from a monitoring program from both overflow structures and downstream drinking water intakes. The model was validated with 15 extreme events such as a large number of overflows (n > 8) or high concentrations at drinking water intakes. Model results demonstrated the importance of the cumulative effects of CSOs on the degradation of water quality downstream. However, permits are typically issued on a discharge point basis and do not consider cumulative effects. Source water protection plans must consider the cumulative effects of discharges and their concentrations because the simultaneous discharge of multiple overflows can lead to elevated E. coli concentrations at a drinking water intake. In addition, some CSOs have a disproportionate impact on peak concentrations at drinking water intakes. As such, it is recommended that the management of CSOs move away from frequency based permitting at the discharge point to focus on the development of comprehensive strategies to reduce cumulative and peak discharges from CSOs upstream of drinking water intakes.SCOPUS: ar.jinfo:eu-repo/semantics/publishe

Impacts of global change on the concentrations and dilution of combined sewer overflows in a drinking water source

This study presents an analysis of climate change impacts on a large river located in Québec (Canada) used as a drinking water source. Combined sewer overflow (CSO) effluents are the primary source of fecal contamination of the river. An analysis of river flowrates was conducted using historical data and predicted flows from a future climate scenario. A spatio-temporal analysis of water quality trends with regard to fecal contamination was performed and the effects of changing flowrates on the dilution of fecal contaminants were analyzed. Along the river, there was a significant spatial trend for increasing fecal pollution downstream of CSO outfalls. Escherichia coli concentrations (upper 95th percentile) increased linearly from 2002 to 2012 at one drinking water treatment plant intake. Two critical periods in the current climate were identified for the drinking water intakes considering both potential contaminant loads and flowrates: local spring snowmelt that precedes river peak flow and extra-tropical storm events that occur during low flows. Regionally, climate change is expected to increase the intensity of the impacts of hydrological conditions on water quality in the studied basin. Based on climate projections, it is expected that spring snowmelt will occur earlier and extreme spring flowrates will increase and low flows will generally decrease. High and low flows are major factors related to the potential degradation of water quality of the river. However, the observed degradation of water quality over the past 10. years suggests that urban development and population growth may have played a greater role than climate. However, climate change impacts will likely be observed over a longer period. Source water protection plans should consider climate change impacts on the dilution of contaminants in addition to local land uses changes in order to maintain or improve water quality.SCOPUS: ar.jinfo:eu-repo/semantics/publishe

Modelling the impacts of global change on concentrations of Escherichia coli in an urban river

Discharges of combined sewer system overflows (CSOs) affect water quality in drinking water sources despite increasing regulation and discharge restrictions. A hydrodynamic model was applied to simulate the transport and dispersion of fecal contaminants from CSO discharges and to quantify the impacts of climate and population changes on the water quality of the river used as a drinking water source in Québec, Canada. The dispersion model was used to quantify Escherichia coli (E. coli) concentrations at drinking water intakes. Extreme flows during high and low water events were based on a frequency analysis in current and future climate scenarios. The increase of the number of discharges was quantified in current and future climate scenarios with regards to the frequency of overflows observed between 2009 and 2012. For future climate scenarios, effects of an increase of population were estimated according to current population growth statistics, independently of local changes in precipitation that are more difficult to predict than changes to regional scale hydrology. Under “business-as-usual” scenarios restricting increases in CSO discharge frequency, mean E. coli concentrations at downstream drinking water intakes are expected to increase by up to 87% depending on the future climate scenario and could lead to changes in drinking water treatment requirements for the worst case scenarios. The greatest uncertainties are related to future local discharge loads. Climate change adaptation with regards to drinking water quality must focus on characterizing the impacts of global change at a local scale. Source water protection planning must consider the impacts of climate and population change to avoid further degradation of water quality.SCOPUS: ar.jinfo:eu-repo/semantics/publishe