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Effects of occupant behavior and ventilation on exposure to respiratory droplets in the indoor environment
https://orcid.org/0000-0001-8859-8462
https://orcid.org/0000-0002-2281-4529
https://orcid.org/0000-0003-2092-4334
Abstract To quantify the risk of the transmission of respiratory infections in indoor environments, we systematically assessed exposure to talking- and breathing-generated respiratory droplets in a generic indoor environment using computational fluid dynamic (CFD) simulations. The flow field in the indoor environment was obtained with SST k-ω model and Lagrangian method was used to predict droplet trajectories, where droplet evaporation was considered. Droplets can be categorized into small droplets (initial size ≤30 μm or ≤10 μm as droplet nuclei), medium droplets (30–80 μm) and large droplets (>100 μm) according to the exposure characteristics. Droplets up to 100 μm, particular the small ones, can contribute to both short-range and long-range airborne routes. For the face-to-face talking scenario, the intake fraction and deposition fractions of droplets on the face and facial mucosa of the susceptible were up to 4.96%, 2.14%, and 0.12%, respectively, indicating inhalation is the dominant route. The exposure risk from a talking infector decreases monotonically with the interpersonal distance, while that of nasal-breathing generated droplets maintains a relatively stable level within 1.0 m. Keeping an angle of 15° or above with the expiratory flow is efficient to reduce intake fractions to <0.37% for small droplets. Adjusting the orientation from face-to-face to face-to-back can reduce exposure to small droplets by approximately 88.0% during talking and 66.2% during breathing. A higher ventilation rate can reduce the risk of exposure to small droplets but may increase the risk of transmission via medium droplets by enhancing their evaporation rate. This study would serve as a fundamental research for epidemiologist, healthcare workers and the public in the purpose of infection control.
Highlights Inhalation of droplets imposes higher exposure risk than deposition on the facial mucosa. Medium-sized droplets (30–100 μm) can also be inhaled via long-range airborne routes. Adjusting the position or orientation is effective in reducing the risk of exposure. Short-range airborne routes is also affected by the ventilation rate. A higher ventilation rate may increase the intake fraction of medium droplets.
Effects of occupant behavior and ventilation on exposure to respiratory droplets in the indoor environment
https://orcid.org/0000-0001-8859-8462
https://orcid.org/0000-0002-2281-4529
https://orcid.org/0000-0003-2092-4334
Abstract To quantify the risk of the transmission of respiratory infections in indoor environments, we systematically assessed exposure to talking- and breathing-generated respiratory droplets in a generic indoor environment using computational fluid dynamic (CFD) simulations. The flow field in the indoor environment was obtained with SST k-ω model and Lagrangian method was used to predict droplet trajectories, where droplet evaporation was considered. Droplets can be categorized into small droplets (initial size ≤30 μm or ≤10 μm as droplet nuclei), medium droplets (30–80 μm) and large droplets (>100 μm) according to the exposure characteristics. Droplets up to 100 μm, particular the small ones, can contribute to both short-range and long-range airborne routes. For the face-to-face talking scenario, the intake fraction and deposition fractions of droplets on the face and facial mucosa of the susceptible were up to 4.96%, 2.14%, and 0.12%, respectively, indicating inhalation is the dominant route. The exposure risk from a talking infector decreases monotonically with the interpersonal distance, while that of nasal-breathing generated droplets maintains a relatively stable level within 1.0 m. Keeping an angle of 15° or above with the expiratory flow is efficient to reduce intake fractions to <0.37% for small droplets. Adjusting the orientation from face-to-face to face-to-back can reduce exposure to small droplets by approximately 88.0% during talking and 66.2% during breathing. A higher ventilation rate can reduce the risk of exposure to small droplets but may increase the risk of transmission via medium droplets by enhancing their evaporation rate. This study would serve as a fundamental research for epidemiologist, healthcare workers and the public in the purpose of infection control.
Highlights Inhalation of droplets imposes higher exposure risk than deposition on the facial mucosa. Medium-sized droplets (30–100 μm) can also be inhaled via long-range airborne routes. Adjusting the position or orientation is effective in reducing the risk of exposure. Short-range airborne routes is also affected by the ventilation rate. A higher ventilation rate may increase the intake fraction of medium droplets.
Effects of occupant behavior and ventilation on exposure to respiratory droplets in the indoor environment
https://orcid.org/0000-0001-8859-8462
https://orcid.org/0000-0002-2281-4529
https://orcid.org/0000-0003-2092-4334
Abstract To quantify the risk of the transmission of respiratory infections in indoor environments, we systematically assessed exposure to talking- and breathing-generated respiratory droplets in a generic indoor environment using computational fluid dynamic (CFD) simulations. The flow field in the indoor environment was obtained with SST k-ω model and Lagrangian method was used to predict droplet trajectories, where droplet evaporation was considered. Droplets can be categorized into small droplets (initial size ≤30 μm or ≤10 μm as droplet nuclei), medium droplets (30–80 μm) and large droplets (>100 μm) according to the exposure characteristics. Droplets up to 100 μm, particular the small ones, can contribute to both short-range and long-range airborne routes. For the face-to-face talking scenario, the intake fraction and deposition fractions of droplets on the face and facial mucosa of the susceptible were up to 4.96%, 2.14%, and 0.12%, respectively, indicating inhalation is the dominant route. The exposure risk from a talking infector decreases monotonically with the interpersonal distance, while that of nasal-breathing generated droplets maintains a relatively stable level within 1.0 m. Keeping an angle of 15° or above with the expiratory flow is efficient to reduce intake fractions to <0.37% for small droplets. Adjusting the orientation from face-to-face to face-to-back can reduce exposure to small droplets by approximately 88.0% during talking and 66.2% during breathing. A higher ventilation rate can reduce the risk of exposure to small droplets but may increase the risk of transmission via medium droplets by enhancing their evaporation rate. This study would serve as a fundamental research for epidemiologist, healthcare workers and the public in the purpose of infection control.
Highlights Inhalation of droplets imposes higher exposure risk than deposition on the facial mucosa. Medium-sized droplets (30–100 μm) can also be inhaled via long-range airborne routes. Adjusting the position or orientation is effective in reducing the risk of exposure. Short-range airborne routes is also affected by the ventilation rate. A higher ventilation rate may increase the intake fraction of medium droplets.
Effects of occupant behavior and ventilation on exposure to respiratory droplets in the indoor environment
Wei, Jianjian (author) / Wang, Lei (author) / Jin, Tao (author) / Li, Yuguo (author) / Zhang, Nan (author)
Building and Environment ; 229
2022-12-31
Article (Journal)
Electronic Resource
English
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