Occupancy-aided ventilation for both airborne infection risk control and work productivity

Zhang, Sheng; Ai, Zhengtao; Lin, Zhang

doi:10.1016/j.buildenv.2020.107506

Cited by 41 publications

(48 citation statements)

References 30 publications

(39 reference statements)

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“…The well-recognized Wells-Riley model and its modification (the rebreathed-fraction model) estimate the airborne infection risk with the infector's quantum generation rate, considering the biological properties of pathogens implicitly [ 14 ]. However, the Wells-Riley model has no spatial and temporal resolutions and the rebreathed-fraction model has no temporal resolution, resulting in overestimation/underestimation of airborne infection risk [ 14 , 18 , 21 ]. The proposed dilution-based evaluation of airborne infection risk, as a thorough expansion of the Wells-Riley model, has both spatial and temporal resolutions (Sections 2 , 5 ).…”

Section: Discussionmentioning

confidence: 99%

“…The quantum generation rate of a COVID-19 infector is assigned to be 142 quanta/h and the breathing rate of a standing susceptible is 0.54 m 3 /h [ 26 ]. It should be noted that the quantum generation rate of COVID-19 varies when the activity level and viral load of the infector vary [ 26 ], and the quantum generation rate of 142 quanta/h is used as a specific case [ 21 ] for the application demonstration of the proposed dilution-based evaluation of airborne infection risk. Two scenarios are considered, one with no masks and the other with surgical masks for both the infector and susceptible.…”

Section: Demonstration Of Applicability Of Methods Proposed For Both Smentioning

confidence: 99%

“…, the concentrations of exhaled air by the infectors) in the space air and ventilation supply air respectively (ppm); D ms is the dilution ratio under the well-mixed and steady condition; G is the contaminant generation rate in the space ( i.e. , exhaled air by the infectors which can be represented by exhaled CO 2 or other tracer gases) (m 3 /s) [ 18 , 20 , 21 ]; P D,ms is the airborne infection risk estimated by the dilution-based estimation method proposed under the well-mixed and steady condition; V is the volume of the space (m 3 ).…”

Section: Benchmark With Wells-riley Model Under Well-mixed and Steadymentioning

confidence: 99%

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Dilution-based evaluation of airborne infection risk - Thorough expansion of Wells-Riley model

Sheng

Lin

2021

Building and Environment

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Evaluation of airborne infection risk with spatial and temporal resolutions is indispensable for the design of proper interventions fighting infectious respiratory diseases ( e.g. , COVID-19), because the distribution of aerosol contagions is both spatially and temporally non-uniform. However, the well-recognized Wells-Riley model and modified Wells-Riley model ( i.e. , the rebreathed-fraction model) are limited to the well-mixed condition and unable to evaluate airborne infection risk spatially and temporally, which could result in overestimation or underestimation of airborne infection risk. This study proposes a dilution-based evaluation method for airborne infection risk. The method proposed is benchmarked by the Wells-Riley model and modified Wells-Riley model, which indicates that the method proposed is a thorough expansion of the Wells-Riley model for evaluation of airborne infection risk with both spatial and temporal resolutions. Experiments in a mock hospital ward also demonstrate that the method proposed effectively evaluates the airborne infection risk both spatially and temporally. The proposed method is convenient to implement for the development of healthy built environments.

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Section: Discussionmentioning

confidence: 99%

Section: Demonstration Of Applicability Of Methods Proposed For Both Smentioning

confidence: 99%

Section: Benchmark With Wells-riley Model Under Well-mixed and Steadymentioning

confidence: 99%

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Dilution-based evaluation of airborne infection risk - Thorough expansion of Wells-Riley model

Sheng

Lin

2021

Building and Environment

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“…However, this occupancy-aided ventilation may reduce work productivity. Therefore, Zhang et al. (2021) further optimized the occupancy schedule to maximize the total duration of normal occupancy, balancing low airborne infection risks and work productivity.…”

Section: Infection Control Strategiesmentioning

confidence: 99%

“…(2021) further optimized the occupancy schedule to maximize the total duration of normal occupancy, balancing low airborne infection risks and work productivity. Despite the innovation of occupancy-aided ventilation, there are limitations such as potential corridor blockage, simplification of work productivity evaluation, assumption of uniform virus distribution, and difficulty in obtaining infector numbers ( Zhang et al., 2021 ), and further research is required.…”

Section: Infection Control Strategiesmentioning

confidence: 99%

Recent research on expiratory particles in respiratory viral infection and control strategies: A review

Ooka

Kikumoto

et al. 2021

Sustainable Cities and Society

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The global spread of coronavirus disease 2019 poses a significant threat to human health. In this study, recent research on the characteristics of expiratory particles and flow is reviewed, with a special focus on different respiratory activities, to provide guidance for reducing the viral infection risk in the built environment. Furthermore, environmental influence on particle evaporation, dispersion, and virus viability after exhalation and the current methods for infection risk assessment are reviewed. Finally, we summarize promising control strategies against infectious expiratory particles. The results show that airborne transmission is a significant viral transmission route, both in short and long ranges, from infected individuals. Relative humidity affects the evaporation and trajectories of middle-sized droplets most, and temperature accelerates the inactivation of SARS-CoV-2 both on surfaces and in aerosols. Future research is needed to improve infection risk models to better predict the infection potential of different transmission routes. Moreover, further quantitative studies on the expiratory flow features after wearing a mask are needed. Systematic investigations and the design of advanced air distribution methods, portable air cleaners, and ultraviolet germicidal irradiation systems, which have shown high efficacy in removing contaminants, are required to better control indoor viral infection.

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Occupancy-aided ventilation for airborne infection risk control: Continuously or intermittently reduced occupancies?

2022

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Ventilation is an important engineering measure to control the airborne infection risk of acute respiratory diseases, e.g., Corona Virus Disease 2019 (COVID-19). Occupancy-aided ventilation methods can effectively improve the airborne infection risk control performance with a sacrifice of decreasing working productivity because of the reduced occupancy. This study evaluates the effectiveness of two occupancy-aided ventilation methods, i.e., the continuously reduced occupancy method and the intermittently reduced occupancy method. The continuously reduced occupancy method is determined by the steady equation of the mass conservation law of the indoor contaminant, and the intermittently reduced occupancy method is determined by a genetic algorithm-based optimization. A two-scenarios-based evaluation framework is developed, i.e., one with targeted airborne infection risk control performance (indicated by the mean rebreathed fraction) and the other with targeted working productivity (indicated by the accumulated occupancy). The results show that the improvement in the airborne infection risk control performance linearly and quadratically increases with the reduction in the working productivity for the continuously reduced occupancy method and the intermittently reduced occupancy method respectively. At a given targeted airborne infection risk control performance, the intermittently reduced occupancy method outperforms the continuously reduced occupancy method by improving the working productivity by up to 92%. At a given targeted working productivity, the intermittently reduced occupancy method outperforms the continuously reduced occupancy method by improving the airborne infection risk control performance by up to 38%.

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Occupancy-aided ventilation for both airborne infection risk control and work productivity

Cited by 41 publications

References 30 publications

Dilution-based evaluation of airborne infection risk - Thorough expansion of Wells-Riley model

Dilution-based evaluation of airborne infection risk - Thorough expansion of Wells-Riley model

Recent research on expiratory particles in respiratory viral infection and control strategies: A review

Occupancy-aided ventilation for airborne infection risk control: Continuously or intermittently reduced occupancies?

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