Air quality assessments are essential elements of design and due diligence studies for various developments including: transportation corridors, research facilities, industrial facilities and infrastructure, such as wastewater treatment plants. While issues related to air quality are often more acute in urban centers or in proximity to the source, long range transport and atmospheric interactions cannot be ignored when considering ambient levels and long term effects.
Poor air quality affects human beings directly in terms of health effects and odour annoyance, as well as indirectly in terms of deterioration of the natural habitat.
Industrial emissions from point and area sources have short-range impacts on nearby sensitive areas. The level of impact is influenced by local topography and wind conditions. In addition, emissions can have long-range impacts that are influenced by atmospheric chemistry.
Research and development facilities at universities, in the pharmaceutical industry, and the photonics sector, among others, handle a wide variety of gaseous emissions that vary in toxicity and odour impact. GWE has been involved with modelling and resolving problems with highly toxic and odorous emissions. The impacts of these emissions have been studied on various levels, such as how they influence the occupants when they re-enter the building through fresh air intakes, as well as their impacts on the surrounding community. Furthermore, our work extends into wastewater treatment plants where the odour control is important.
The assessment of air quality and its impact is done through dispersion modelling analysis. This process models the emission, distribution, and dilution of a plume of gas as it spreads from the source to a receiver (point of impingement).
Factors affecting dilution include the distance between source and receiver, localized air flow around buildings, variations in wind direction, wind speed, temperature, and humidity. ASHRE, AERMOD, and CALQHC3R are empirical models used for air dispersion modelling, which generally provide conservative results.
More refined studies include the use of computational fluid dynamics (CFD) and the testing of a physical-scale model in a wind tunnel. A wind tunnel can also be used to confirm the results of a computational fluid flow analysis, which is better suited for sensitivity or parametric analysis. In broad terms, our engineers can assist on a wide variety of projects related to air quality, including;
- Exhaust Re-entrainment into building fresh air intakes
- Ontario Ministry of the Environment, Environmental Compliance Approvals (Section 9 Environmental Protection Act)
- Environmental Assessments for transportation corridors