Articles producció científica> Enginyeria Mecànica

Effects of upper respiratory tract anatomy and head movement on the buoyant flow and particle dispersion generated in a violent expiratory event

  • Datos identificativos

    Identificador: imarina:9280529
    Autores:
    Pallares JFabregat ACito S
    Resumen:
    In the wake of the COVID-19 pandemic, interest in understanding the turbulent dispersion of airborne pathogen-laden particles has significantly increased. The ability of infectious particles to stay afloat and disperse in indoor environments depends on their size, the environmental conditions and the hydrodynamics of the flow generated by the exhalation. In this work we analyze the impact of three different aspects, namely, the buoyancy force, the upper airways geometry and the head rotation during the exhalation on the short-term dispersion. Large-Eddy Simulations have been used to assess the impact of each separate effect on the thermal puff and particle cloud evolution over the first 2 s after the onset of the exhalation. Results obtained during this short-term period suggest that due to the rapid mixing of the turbulent puff, buoyancy forces play a moderate role on the ability of the particles to disperse. Because of the enhanced mixing, buoyancy reduces the range and increases the vertical size of the small particle clouds. In comparison to the fixed frame case, head rotation has been found to notably affect the size and shape of the cloud by enhancing the vertical transport as the exhalation axial direction sweeps vertically during the exhalation. The impact of the upper airway geometry, in comparison to an idealized mouth consisting in a pipe of circular section, has been found to be the largest when it is considered along with the head rotation.
  • Otros:

    Autor según el artículo: Pallares J; Fabregat A; Cito S
    Departamento: Enginyeria Mecànica
    Autor/es de la URV: Cito, Salvatore / Fabregat Tomàs, Alexandre / Pallarés Curto, Jorge María
    Palabras clave: Unsteady jet Turbulent puff Turbulent dispersion Transport Particle dispersion Large-eddy simulation Expiratory event unsteady jet turbulent puff turbulent dispersion particle dispersion large-eddy simulation aerosols
    Resumen: In the wake of the COVID-19 pandemic, interest in understanding the turbulent dispersion of airborne pathogen-laden particles has significantly increased. The ability of infectious particles to stay afloat and disperse in indoor environments depends on their size, the environmental conditions and the hydrodynamics of the flow generated by the exhalation. In this work we analyze the impact of three different aspects, namely, the buoyancy force, the upper airways geometry and the head rotation during the exhalation on the short-term dispersion. Large-Eddy Simulations have been used to assess the impact of each separate effect on the thermal puff and particle cloud evolution over the first 2 s after the onset of the exhalation. Results obtained during this short-term period suggest that due to the rapid mixing of the turbulent puff, buoyancy forces play a moderate role on the ability of the particles to disperse. Because of the enhanced mixing, buoyancy reduces the range and increases the vertical size of the small particle clouds. In comparison to the fixed frame case, head rotation has been found to notably affect the size and shape of the cloud by enhancing the vertical transport as the exhalation axial direction sweeps vertically during the exhalation. The impact of the upper airway geometry, in comparison to an idealized mouth consisting in a pipe of circular section, has been found to be the largest when it is considered along with the head rotation.
    Áreas temáticas: Química Pollution Meteorology & atmospheric sciences Mechanical engineering Materials science (miscellaneous) General materials science Fluid flow and transfer processes Environmental sciences Environmental engineering Environmental chemistry Engineering, mechanical Engineering, chemical Atmospheric science
    Acceso a la licencia de uso: https://creativecommons.org/licenses/by/3.0/es/
    Direcció de correo del autor: salvatore.cito@urv.cat alexandre.fabregat@urv.cat jordi.pallares@urv.cat
    Identificador del autor: 0000-0001-7626-3374 0000-0002-6032-2605 0000-0003-0305-2714
    Fecha de alta del registro: 2024-09-07
    Versión del articulo depositado: info:eu-repo/semantics/publishedVersion
    Enlace a la fuente original: https://www.sciencedirect.com/science/article/pii/S0021850222000908
    URL Documento de licencia: https://repositori.urv.cat/ca/proteccio-de-dades/
    Referencia al articulo segun fuente origial: Journal Of Aerosol Science. 166 106052-
    Referencia de l'ítem segons les normes APA: Pallares J; Fabregat A; Cito S (2022). Effects of upper respiratory tract anatomy and head movement on the buoyant flow and particle dispersion generated in a violent expiratory event. Journal Of Aerosol Science, 166(), 106052-. DOI: 10.1016/j.jaerosci.2022.106052
    DOI del artículo: 10.1016/j.jaerosci.2022.106052
    Entidad: Universitat Rovira i Virgili
    Año de publicación de la revista: 2022
    Tipo de publicación: Journal Publications
  • Palabras clave:

    Atmospheric Science,Engineering, Chemical,Engineering, Mechanical,Environmental Chemistry,Environmental Engineering,Environmental Sciences,Fluid Flow and Transfer Processes,Materials Science (Miscellaneous),Mechanical Engineering,Meteorology & Atmospheric Sciences,Pollution
    Unsteady jet
    Turbulent puff
    Turbulent dispersion
    Transport
    Particle dispersion
    Large-eddy simulation
    Expiratory event
    unsteady jet
    turbulent puff
    turbulent dispersion
    particle dispersion
    large-eddy simulation
    aerosols
    Química
    Pollution
    Meteorology & atmospheric sciences
    Mechanical engineering
    Materials science (miscellaneous)
    General materials science
    Fluid flow and transfer processes
    Environmental sciences
    Environmental engineering
    Environmental chemistry
    Engineering, mechanical
    Engineering, chemical
    Atmospheric science
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