Wildfire-resilient mechanical ventilation systems for single-detached homes in cities of Western Canada

Abstract

The increasing prevalence and severity of wildfire events around the world have emphasized the importance of wildfire resiliency in indoor environmental design. This study focuses on developing wildfire-resilient mechanical ventilation systems and ventilation strategies for application in single-detached residences in western Canada. Outdoor PM2.5 concentration datasets during wildfire conditions were used in conjunction with indoor air quality (IAQ) mathematical models to assess the impact of ventilation and building-related input variables on indoor PM2.5 levels. A cost-benefit analysis was conducted to compare the cost of ventilation retrofit options with regional estimates of reasonable monetary contributions per resident towards health risk mitigation. Ventilation retrofit options were recommended based on IAQ simulations, model sensitivity, and cost-benefit analysis results. It was recommended that residential ventilation systems increase the minimum filter efficiency from MERV6 to MERV11 or MERV13 during wildfire operation and implement higher recirculation ratios during peak exposure scenarios. Multi-filter mechanical ventilation system configurations were recommended for residential dwellings located in regions prone to severe PM2.5 exposure. This study provides insight into the integration of wildfire-resiliency in existing residential mechanical ventilation systems for indoor air quality improvement. This work sets the foundation for future experimental verification of the performance of ventilation strategies to improve urban safety, health and wellness in wildfire conditions.