Validation of a Human Exhalation Flow Simulation in a Room with Vertical Ventilation

Inés Olmedo, Peter V. Nielsen, M. Ruiz de Adana

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Abstract

We protect ourselves from airborne cross-infection in our indoor environment by supplying fresh air to the room by natural or mechanical ventilation. The air is distributed in the room according to different principles as e.g. mixing ventilation, downward ventilation, displacement ventilation, etc. A large amount of air is supplied to the room to ensure dilution of airborne infection.

The paper discusses both the macroenvironment and the microenvironment. The macroenvironment is the conditions created by the air distribution system, and the microenvironment is the conditions created by the local flow around persons in combination with the surrounding conditions.

Analyses of the flow in the room (macroenvironment) show a number of parameters that play an important role in minimising of airborne cross-infection. The air flow rate to the room must be high, and the air distribution pattern can be designed to have high ventilation effectiveness. Furthermore, personalized ventilation may reduce the risk of cross-infection. Personalized ventilation can be used especially in hospital wards, aircraft cabins and, in general, where people are located at defined positions.

Analyses of the flow in the microenvironment show that a number of variables are important, as e.g. distance between people, people’s posture, surrounding temperature gradients and surrounding temperature, activity level, etc.

Experiments with tracer gas simulating droplet nuclei and experiments with large particles, simulating droplets are used for the study of airborne cross-infection risk and for the study of dropletborne transmission of a disease. CFD predictions are used to support these experiments.
Original languageEnglish
Title of host publicationVentilation 2012 : The 10th International Conference on Industrial Ventilation, Paris, 17 – 19 September 2012
Number of pages6
Place of PublicationParis
PublisherInstitut National de Recherche et de Sécurité
Publication date2012
Publication statusPublished - 2012
EventThe International Conference on Industrial Ventilation - Paris, France
Duration: 17 Sep 201219 Sep 2012
Conference number: 10

Conference

ConferenceThe International Conference on Industrial Ventilation
Number10
CountryFrance
CityParis
Period17/09/201219/09/2012

Fingerprint

Flow simulation
Ventilation
Air
Cabins (aircraft)
Experiments
Thermal gradients
Dilution
Computational fluid dynamics
Thermodynamic properties
Flow rate
Gases

Keywords

  • Human Exhalation Flow
  • Vertical Ventilation
  • Exhaled Contaminants

Cite this

Olmedo, I., Nielsen, P. V., & Adana, M. R. D. (2012). Validation of a Human Exhalation Flow Simulation in a Room with Vertical Ventilation. In Ventilation 2012: The 10th International Conference on Industrial Ventilation, Paris, 17 – 19 September 2012 Paris: Institut National de Recherche et de Sécurité.
Olmedo, Inés ; Nielsen, Peter V. ; Adana, M. Ruiz de. / Validation of a Human Exhalation Flow Simulation in a Room with Vertical Ventilation. Ventilation 2012: The 10th International Conference on Industrial Ventilation, Paris, 17 – 19 September 2012. Paris : Institut National de Recherche et de Sécurité, 2012.
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abstract = "We protect ourselves from airborne cross-infection in our indoor environment by supplying fresh air to the room by natural or mechanical ventilation. The air is distributed in the room according to different principles as e.g. mixing ventilation, downward ventilation, displacement ventilation, etc. A large amount of air is supplied to the room to ensure dilution of airborne infection.The paper discusses both the macroenvironment and the microenvironment. The macroenvironment is the conditions created by the air distribution system, and the microenvironment is the conditions created by the local flow around persons in combination with the surrounding conditions.Analyses of the flow in the room (macroenvironment) show a number of parameters that play an important role in minimising of airborne cross-infection. The air flow rate to the room must be high, and the air distribution pattern can be designed to have high ventilation effectiveness. Furthermore, personalized ventilation may reduce the risk of cross-infection. Personalized ventilation can be used especially in hospital wards, aircraft cabins and, in general, where people are located at defined positions.Analyses of the flow in the microenvironment show that a number of variables are important, as e.g. distance between people, people’s posture, surrounding temperature gradients and surrounding temperature, activity level, etc.Experiments with tracer gas simulating droplet nuclei and experiments with large particles, simulating droplets are used for the study of airborne cross-infection risk and for the study of dropletborne transmission of a disease. CFD predictions are used to support these experiments.",
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Olmedo, I, Nielsen, PV & Adana, MRD 2012, Validation of a Human Exhalation Flow Simulation in a Room with Vertical Ventilation. in Ventilation 2012: The 10th International Conference on Industrial Ventilation, Paris, 17 – 19 September 2012. Institut National de Recherche et de Sécurité, Paris, Paris, France, 17/09/2012.

Validation of a Human Exhalation Flow Simulation in a Room with Vertical Ventilation. / Olmedo, Inés; Nielsen, Peter V.; Adana, M. Ruiz de.

Ventilation 2012: The 10th International Conference on Industrial Ventilation, Paris, 17 – 19 September 2012. Paris : Institut National de Recherche et de Sécurité, 2012.

Research output: Contribution to book/anthology/report/conference proceedingArticle in proceedingResearchpeer-review

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AU - Nielsen, Peter V.

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N2 - We protect ourselves from airborne cross-infection in our indoor environment by supplying fresh air to the room by natural or mechanical ventilation. The air is distributed in the room according to different principles as e.g. mixing ventilation, downward ventilation, displacement ventilation, etc. A large amount of air is supplied to the room to ensure dilution of airborne infection.The paper discusses both the macroenvironment and the microenvironment. The macroenvironment is the conditions created by the air distribution system, and the microenvironment is the conditions created by the local flow around persons in combination with the surrounding conditions.Analyses of the flow in the room (macroenvironment) show a number of parameters that play an important role in minimising of airborne cross-infection. The air flow rate to the room must be high, and the air distribution pattern can be designed to have high ventilation effectiveness. Furthermore, personalized ventilation may reduce the risk of cross-infection. Personalized ventilation can be used especially in hospital wards, aircraft cabins and, in general, where people are located at defined positions.Analyses of the flow in the microenvironment show that a number of variables are important, as e.g. distance between people, people’s posture, surrounding temperature gradients and surrounding temperature, activity level, etc.Experiments with tracer gas simulating droplet nuclei and experiments with large particles, simulating droplets are used for the study of airborne cross-infection risk and for the study of dropletborne transmission of a disease. CFD predictions are used to support these experiments.

AB - We protect ourselves from airborne cross-infection in our indoor environment by supplying fresh air to the room by natural or mechanical ventilation. The air is distributed in the room according to different principles as e.g. mixing ventilation, downward ventilation, displacement ventilation, etc. A large amount of air is supplied to the room to ensure dilution of airborne infection.The paper discusses both the macroenvironment and the microenvironment. The macroenvironment is the conditions created by the air distribution system, and the microenvironment is the conditions created by the local flow around persons in combination with the surrounding conditions.Analyses of the flow in the room (macroenvironment) show a number of parameters that play an important role in minimising of airborne cross-infection. The air flow rate to the room must be high, and the air distribution pattern can be designed to have high ventilation effectiveness. Furthermore, personalized ventilation may reduce the risk of cross-infection. Personalized ventilation can be used especially in hospital wards, aircraft cabins and, in general, where people are located at defined positions.Analyses of the flow in the microenvironment show that a number of variables are important, as e.g. distance between people, people’s posture, surrounding temperature gradients and surrounding temperature, activity level, etc.Experiments with tracer gas simulating droplet nuclei and experiments with large particles, simulating droplets are used for the study of airborne cross-infection risk and for the study of dropletborne transmission of a disease. CFD predictions are used to support these experiments.

KW - Human Exhalation Flow

KW - Vertical Ventilation

KW - Exhaled Contaminants

KW - Human Exhalation Flow

KW - Vertical Ventilation

KW - Exhaled Contaminants

M3 - Article in proceeding

BT - Ventilation 2012

PB - Institut National de Recherche et de Sécurité

CY - Paris

ER -

Olmedo I, Nielsen PV, Adana MRD. Validation of a Human Exhalation Flow Simulation in a Room with Vertical Ventilation. In Ventilation 2012: The 10th International Conference on Industrial Ventilation, Paris, 17 – 19 September 2012. Paris: Institut National de Recherche et de Sécurité. 2012