Aerodynamic Prediction of Time Duration to Becoming Infected with Coronavirus in a Public Place

Abstract

The COVID‐19 pandemic has caused panic and chaos that modern society has never seen before. Despite their paramount importance, the transmission routes of coronavirus SARS‐ CoV‐2 remain unclear and a point of contention between the various sectors. Recent studies strongly suggest that COVID‐19 could be transmitted via air in inadequately ventilated environ-ments. The present study investigates the possibility of the aerosol transmission of coronavirus SARS‐CoV‐2 and illustrates the associated environmental conditions. The main objective of the current work is to accurately predict the time duration of getting an infection while sharing an indoor space with a patient of COVID‐19 or similar viruses. We conducted a 3D computational fluid dynamics (CFD)‐based investigation of indoor airflow and the associated aerosol transport in a restaurant setting, where likely cases of airflow‐induced infection of COVID‐19 caused by asymp-tomatic individuals were reported in Guangzhou, China. The Eulerian–Eulerian flow model coupled with the k‐Ɛ turbulence approach was employed to resolve complex indoor processes, including human respiration activities, such as breathing, speaking, and sneezing. The predicted results suggest that 10 minutes are enough to become infected with COVID‐19 when sharing a Table with coronavirus patients. The results also showed that although changing the ventilation rate will im-prove the quality of air within closed spaces, it will not be enough to protect a person from COVID‐19. This model may be suitable for future engineering analyses aimed at reshaping public spaces and indoor common areas to face the spread of aerosols and droplets that may contain pathogens.