Abstract
Human-generated droplets constitute the main route for the transmission of coronavirus. However, the details of such transmission in enclosed environments are yet to be understood. This is because geometrical and environmental parameters can immensely complicate the problem and turn the conventional analyses inefficient. As a remedy, this work develops a predictive tool based on computational fluid dynamics and machine learning to examine the distribution of sneezing droplets in realistic configurations. The time-dependent effects of environmental parameters, including temperature, humidity and ventilation rate, upon the droplets with diameters between 1 and 250μm are investigated inside a bus. It is shown that humidity can profoundly affect the droplets distribution, such that 10% increase in relative humidity results in 30% increase in the droplets density at the farthest point from a sneezing passenger. Further, ventilation process is found to feature dual effects on the droplets distribution. Simple increases in the ventilation rate may accelerate the droplets transmission. However, carefully tailored injection of fresh air enhances deposition of droplets on the surfaces and thus reduces their concentration in the bus. Finally, the analysis identifies an optimal range of temperature, humidity and ventilation rate to maintain human comfort while minimising the transmission of droplets.
Highlights
Since late 2019, the transmission of SARS-CoV-2 [1] has significantly affected humankind in the entire world
Viruscarrying droplets cover a range of sizes, and the larger they are, the more likely they become to deposit on surfaces, while the smaller ones may remain suspended in the air for a long time
Two types of droplets can be found in the range of 1–250 μm: those initially produced at this range and those experiencing evaporation and breakdown along the path
Summary
Since late 2019, the transmission of SARS-CoV-2 [1] has significantly affected humankind in the entire world. It has been shown that cough ing, sneezing [2], and speaking [3] constitute the main routes of virus transmission. This could be through the deposited droplets over surfaces or the suspended droplets entering the mouth, nose and eyes. It has been argued that these airborne droplets are responsible for virus transmission [2]. It follows that predicting the distribution of such droplets is an essential requirement for understanding the transmission routes of the virus
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Schedule a callMore From: Chemical engineering journal (Lausanne, Switzerland : 1996)
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