Direct numerical simulation of the turbulent flow generated during a violent expiratory event

Fabregat, Alexandre; Gisbert, Ferran; Vernet, Antón; Dutta, Som; Mittal, Kamal K.; Pallarès, Jordi

doi:10.1063/5.0042086

Cited by 52 publications

(54 citation statements)

References 37 publications

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“…We do not describe in detail the turbulent mechanisms during a cough as this is well explained in the recent literature. 16,30,53,54 However, we note that the larger turbulent eddies that influence the particle transport are resolved through the LES approach which is transient. The particles are transported with the eddies with each small time step.…”

Section: Resultsmentioning

confidence: 96%

“…Vortex structures during the cough are characterized by the well-known vortex ring structures generated at the edge of the jet. 16,53 We note that expiratory events such as a cough are pulsatile; however, this study considered a cough as a single pulse. Figure 8 shows the droplet trajectories for each droplet found in the vortex ring structure at 1 s. The trajectories represent the individual droplet motion colored by velocity.…”

Section: Resultsmentioning

confidence: 99%

“…Studies applying LES include 12 which used a model containing 38 × 10 6 elements modeled for 10 s of physical time and showed that at a higher room temperature, the cough jet and droplet penetration is shorter; 13 investigated the cough jet development with and without the influence of co-flow air; 14 applied high-fidelity LES on a computational grid that was three orders of magnitude finer than most studies; and 15 modeled cough jet plume development in six ventilation cases and found that a vast majority of droplets remained suspended within the puff after the liquid evaporated. Studies using the DNS approach include 16 which detailed the initial jet stage and a dissipative phase over which turbulence intensity decayed; and 17 showed the effects of indoor ventilation and ambient conditions on the virus-laden droplet lifetime. These studies focused on the cough jet in detail, and the longest simulation time covered 10 s.…”

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Large eddy simulation of cough jet dynamics, droplet transport, and inhalability over a ten minute exposure

et al. 2021

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High fidelity simulations of expiratory events such as coughing provide the opportunity to predict the fate of the droplets from the turbulent jet cloud produced from a cough. It is well established that droplets carrying infectious pathogens with diameters of remain suspended in the air for several hours and transported by the air currents over considerable distances (e.g., in meters). This study used a highly resolved mesh to capture the multiphase turbulent buoyant cloud with suspended droplets produced by a cough. The cough droplets' dispersion was subjected to thermal gradients and evaporation and allowed to disperse between two humans standing 2 m apart. A nasal cavity anatomy was included inside the second human to determine the inhaled droplets. Three diameter ranges characterized the droplet cloud, , which made up 93% of all droplets by number; 5 to 100 μ m comprised 3%, and m comprising 4%. The results demonstrated the temporal evolution of the cough event, where a jet is first formed, followed by a thermally driven puff cloud with the latter primarily composed of droplets under 5 μ m diameter, moving with a vortex string structure. After the initial cough, the data were interpolated onto a more coarse mesh to allow the simulation to cover ten minutes, equivalent to 150 breathing cycles. We observe that the critical diameter size susceptible to inhalation was , although most inhaled droplets after 10 min by the second human were approximately . These observations offer insight into the risk of airborne transmission and numerical metrics for modeling and risk assessment.

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Section: Resultsmentioning

confidence: 96%

Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Large eddy simulation of cough jet dynamics, droplet transport, and inhalability over a ten minute exposure

et al. 2021

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“…3,9 In subsequent direct numerical simulation (DNS) analyses, the ambient relative humidity was also found to significantly increase the droplet evaporation time, 25–27 especially those with a diameter below 30 μ m. 27 Rosti et al 26 found that turbulence increases the lifetime of the droplets, and an underestimation of 100% in droplet evaporation time was reported when the turbulence effects were filtered out. Although reasonable estimates of the horizontal displacement of the exhaled puff can be obtained from reduced-order models, 28,29 gas-phase only DNS of a cough 30 has shown that a large deviation from the predicted values could arise due to difficulties in predicting jet-to-puff transition effects and puff topology in such models, in addition to turbulence itself as discussed previously. Still, despite the in-depth physical insight obtained from DNS concerning small-scale interactions between liquid and gas phases, its significant computational cost hinders both the evaluation of long events and the quantification of event-to-event variations.…”

Section: Introductionmentioning

confidence: 92%

Estimates of the stochasticity of droplet dispersion by a cough

et al. 2021

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In this paper, the statistical distributions of the position and the size of the evaporating droplets after a cough are evaluated, thus characterizing the inherent stochasticity of respiratory releases due to turbulence. For that, ten independent realizations of a cough with realistic initial conditions and in a room at 20 °C and 40% relative humidity were performed with large eddy simulations and Lagrangian tracking of the liquid phase. It was found that although turbulence decreases far from the emitter, it results in large variations in the spatial distribution of the droplets. The total suspended liquid mass after 60 s from the cough is in good agreement with that estimated by a one-dimensional model accounting for settling and evaporation under quiescent conditions, while deposition times of droplets in the 10–100 μ m range are found to vary significantly, reflected in the mass of liquid, and hence the virus content, potentially inhaled by a receptor. The high variability between events is due to the local fluctuations of temperature, humidity, and velocity on droplet evaporation and motion. The droplet distribution suggests that, in the absence of face coverings, an unprotected cough is not safe at 2 m away from the emitter even outdoors. The results indicate that mitigation measures, such as ventilation to address long-range transmission, can be based on the total suspended liquid content evaluated from reduced-order models. However, the large variability of viral content in the near field produces wide variations in estimates of risk; therefore, a stochastic approach is needed for evaluating short-range transmission risk.

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“… Talaat et al (2021) used steady Reynolds-Average Navier–Stokes (RANS) simulations to predict the flow field in the cabin of a Boeing 737 airplane to assess mitigation and safety of air travel. Several recent papers presented detailed analyses of the flow physics of a cough using direct numerical simulation ( Fabregat et al. , 2021 ; Monroe et al.…”

Section: Introductionmentioning

confidence: 99%

On the utility of a well-mixed model for predicting disease transmission on an urban bus

2021

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The transport of virus-laden aerosols from a host to a susceptible person is governed by complex turbulent airflow and physics related to breathing, coughing and sneezing, mechanical and passive ventilation, thermal buoyancy effects, surface deposition, masks, and air filtration. In this paper, we study the infection risk via airborne transmission on an urban bus using unsteady Reynolds-averaged Navier–Stokes equations and a passive-scalar model of the virus-laden aerosol concentration. Results from these simulations are directly compared to the widely used well-mixed model and show significant differences in the concentration field and number of inhaled particles. Specifically, in the limit of low mechanical ventilation rates, the well-mixed model will overpredict the concentration far from the infected passenger and substantially underpredict the concentration near the infected passenger. The results reported herein also apply to other enclosed spaces.

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Direct numerical simulation of the turbulent flow generated during a violent expiratory event

Cited by 52 publications

References 37 publications

Large eddy simulation of cough jet dynamics, droplet transport, and inhalability over a ten minute exposure

Large eddy simulation of cough jet dynamics, droplet transport, and inhalability over a ten minute exposure

Estimates of the stochasticity of droplet dispersion by a cough

On the utility of a well-mixed model for predicting disease transmission on an urban bus

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