Particle Image Velocimetry of Human Cough

VanSciver, Meg; Miller, Shelly L.; Hertzberg, Jean

doi:10.1080/02786826.2010.542785

Cited by 108 publications

(128 citation statements)

References 27 publications

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“…The maximum coughing airflow velocity at the mouth has been measured in the order of 10 m/s [13,29,32]. The Schlieren technique using human volunteers reveals the turbulent cough jet with a leading vortex [33], with similar properties to a jet or puff [34]. Trajectories of large droplets from coughing and sneezing were recently visualised by Bourouiba and Bush [35].…”

Section: Introductionmentioning

confidence: 99%

Enhanced spread of expiratory droplets by turbulence in a cough jet

Wei

2015

Building and Environment

260

271

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Section: Introductionmentioning

confidence: 99%

Enhanced spread of expiratory droplets by turbulence in a cough jet

Wei

2015

Building and Environment

260

271

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“…The velocity field of human coughs has been extensively examined using various experimental methods, including particle image velocimetry (PIV) (Zhu et al 2006;Chao et al 2009;VanSciver et al 2011;Nishimura et al 2013) and Schlieren imaging (Tang et al 2009). A typical cough has a peak velocity in a range of 6-22 m/s with a duration ranging from 0.25 s to 0.8 s (Zhu et al 2006;Gupta et al 2009).…”

Section: Introductionmentioning

confidence: 99%

Transport of Airborne Particles from an Unobstructed Cough Jet

Liu

Novoselac

2014

Aerosol Science and Technology

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“…Starting from critic analysis of literature results and experimental evidence, the present article provides a multiphysics approach to investigate the condition that particles emitted from patients coughing can have a very high probability of interacting with the patient's breathing and vice versa. All the practical difficulties, mainly depending from long time legal permissions, and low cooperation of the technicians of the hospital plants, for realizing experimental measurements (no spot test) in the isolation room e.g., particle image velocimetry (PIV); see Gupta et al 2009;VanSchiver et al 2009), also without patients, made these collected literature results and experimental evidence very important to validate the CFD-FEM simulation. In particular, referring to the steady sate condition, concerning the air distribution and the assessment of the ventilation effectiveness, a good agreement between simulation results and literature can be deduced.…”

Section: Experimental Evidence Of Droplet Transmission and Depositionmentioning

confidence: 99%

Hospital ventilation simulation for the study of potential exposure to contaminants

Balocco¹

2011

Build. Simul.

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Airflow and ventilation are particularly important in healthcare rooms for controlling thermohygrometric conditions, providing anaesthetic gas removal, diluting airborne bacterial contamination and minimizing bacteria transfer airborne. An actual hospitalization room was the investigate case study. Transient simulations with computational fluid dynamics (CFD), based on the finite element method (FEM) were performed to investigate the efficiency of the existing heating, ventilation and air-conditioning (HVAC) plant with a variable air volume (VAV) primary air system. Solid modelling of the room, taking into account thermo-physical properties of building materials, architectural features (e.g., window and wall orientation) and furnishing (e.g., beds, tables and lamps) arrangement of the room, inlet turbulence high induction air diffuser, the return air diffusers and two patients lying on two parallel beds was carried out. Multiphysics modelling was used: a thermo-fluidynamic model (convection-conduction and incompressible Navier-Stokes) was combined with a convectiondiffusion model. Three 3D models were elaborated considering different conditions/events of the patients (i.e., the first was considered coughing and/or the second breathing). A particle tracing and diffusion model, connected to cough events, was developed to simulate the dispersal of bacteria-carrying droplets in the isolation room equipped with the existing ventilation system. An analysis of the region of droplet fallout and the dilution time of bacteria diffusion of coughed gas in the isolation room was performed. The analysis of transient simulation results concerning particle path and distance, and then particle tracing combined with their concentration, provided evidence of the formation of zones that should be checked by microclimatic and contaminant control. The present study highlights the fact that the CFD-FEM application is useful for understanding the efficiency, adequacy and reliability of the ventilation system, but also provides important suggestions for controlling air quality, patients' comfort and energy consumption in a hospital.

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Particle Image Velocimetry of Human Cough

Cited by 108 publications

References 27 publications

Enhanced spread of expiratory droplets by turbulence in a cough jet

Enhanced spread of expiratory droplets by turbulence in a cough jet

Transport of Airborne Particles from an Unobstructed Cough Jet

Hospital ventilation simulation for the study of potential exposure to contaminants

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