Development of a Bayesian inference model for assessing ventilation condition based on CO(2) meters in primary schools

Outdoor fresh air ventilation plays a significant role in reducing airborne transmission of diseases in indoor spaces. School classrooms are considerably challenged during the COVID-19 pandemic because of the increasing need for in-person education, untimely and incompleted vaccinations, high occupa...

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Autores principales: Hou, Danlin, Wang, Liangzhu (Leon), Katal, Ali, Yan, Shujie, Zhou, Liang (Grace), Wang, Vicky, Vuotari, Mark, Li, Ethan, Xie, Zihan
Formato: Online Artículo Texto
Lenguaje:English
Publicado: Tsinghua University Press 2022
Materias:
Research Article
Acceso en línea:https://www.ncbi.nlm.nih.gov/pmc/articles/PMC9395798/
https://www.ncbi.nlm.nih.gov/pubmed/36035815
http://dx.doi.org/10.1007/s12273-022-0926-8
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author Hou, Danlin
Wang, Liangzhu (Leon)
Katal, Ali
Yan, Shujie
Zhou, Liang (Grace)
Wang, Vicky
Vuotari, Mark
Li, Ethan
Xie, Zihan
author_facet Hou, Danlin
Wang, Liangzhu (Leon)
Katal, Ali
Yan, Shujie
Zhou, Liang (Grace)
Wang, Vicky
Vuotari, Mark
Li, Ethan
Xie, Zihan
author_sort Hou, Danlin
collection PubMed
description Outdoor fresh air ventilation plays a significant role in reducing airborne transmission of diseases in indoor spaces. School classrooms are considerably challenged during the COVID-19 pandemic because of the increasing need for in-person education, untimely and incompleted vaccinations, high occupancy density, and uncertain ventilation conditions. Many schools started to use CO(2) meters to indicate air quality, but how to interpret the data remains unclear. Many uncertainties are also involved, including manual readings, student numbers and schedules, uncertain CO(2) generation rates, and variable indoor and ambient conditions. This study proposed a Bayesian inference approach with sensitivity analysis to understand CO(2) readings in four primary schools by identifying uncertainties and calibrating key parameters. The outdoor ventilation rate, CO(2) generation rate, and occupancy level were identified as the top sensitive parameters for indoor CO(2) levels. The occupancy schedule becomes critical when the CO(2) data are limited, whereas a 15-min measurement interval could capture dynamic CO(2) profiles well even without the occupancy information. Hourly CO(2) recording should be avoided because it failed to capture peak values and overestimated the ventilation rates. For the four primary school rooms, the calibrated ventilation rate with a 95% confidence level for fall condition is 1.96±0.31 ACH for Room #1 (165 m(3) and 20 occupancies) with mechanical ventilation, and for the rest of the naturally ventilated rooms, it is 0.40±0.08 ACH for Room #2 (236 m(3) and 21 occupancies), 0.30±0.04 or 0.79±0.06 ACH depending on occupancy schedules for Room #3 (236 m(3) and 19 occupancies), 0.40±0.32,0.48±0.37,0.72±0.39 ACH for Room #4 (231 m(3) and 8–9 occupancies) for three consecutive days.
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spelling pubmed-93957982022-08-23 Development of a Bayesian inference model for assessing ventilation condition based on CO(2) meters in primary schools Hou, Danlin Wang, Liangzhu (Leon) Katal, Ali Yan, Shujie Zhou, Liang (Grace) Wang, Vicky Vuotari, Mark Li, Ethan Xie, Zihan Build Simul Research Article Outdoor fresh air ventilation plays a significant role in reducing airborne transmission of diseases in indoor spaces. School classrooms are considerably challenged during the COVID-19 pandemic because of the increasing need for in-person education, untimely and incompleted vaccinations, high occupancy density, and uncertain ventilation conditions. Many schools started to use CO(2) meters to indicate air quality, but how to interpret the data remains unclear. Many uncertainties are also involved, including manual readings, student numbers and schedules, uncertain CO(2) generation rates, and variable indoor and ambient conditions. This study proposed a Bayesian inference approach with sensitivity analysis to understand CO(2) readings in four primary schools by identifying uncertainties and calibrating key parameters. The outdoor ventilation rate, CO(2) generation rate, and occupancy level were identified as the top sensitive parameters for indoor CO(2) levels. The occupancy schedule becomes critical when the CO(2) data are limited, whereas a 15-min measurement interval could capture dynamic CO(2) profiles well even without the occupancy information. Hourly CO(2) recording should be avoided because it failed to capture peak values and overestimated the ventilation rates. For the four primary school rooms, the calibrated ventilation rate with a 95% confidence level for fall condition is 1.96±0.31 ACH for Room #1 (165 m(3) and 20 occupancies) with mechanical ventilation, and for the rest of the naturally ventilated rooms, it is 0.40±0.08 ACH for Room #2 (236 m(3) and 21 occupancies), 0.30±0.04 or 0.79±0.06 ACH depending on occupancy schedules for Room #3 (236 m(3) and 19 occupancies), 0.40±0.32,0.48±0.37,0.72±0.39 ACH for Room #4 (231 m(3) and 8–9 occupancies) for three consecutive days. Tsinghua University Press 2022-08-23 2023 /pmc/articles/PMC9395798/ /pubmed/36035815 http://dx.doi.org/10.1007/s12273-022-0926-8 Text en © Tsinghua University Press 2022 This article is made available via the PMC Open Access Subset for unrestricted research re-use and secondary analysis in any form or by any means with acknowledgement of the original source. These permissions are granted for the duration of the World Health Organization (WHO) declaration of COVID-19 as a global pandemic.
spellingShingle Research Article
Hou, Danlin
Wang, Liangzhu (Leon)
Katal, Ali
Yan, Shujie
Zhou, Liang (Grace)
Wang, Vicky
Vuotari, Mark
Li, Ethan
Xie, Zihan
Development of a Bayesian inference model for assessing ventilation condition based on CO(2) meters in primary schools
title Development of a Bayesian inference model for assessing ventilation condition based on CO(2) meters in primary schools
title_full Development of a Bayesian inference model for assessing ventilation condition based on CO(2) meters in primary schools
title_fullStr Development of a Bayesian inference model for assessing ventilation condition based on CO(2) meters in primary schools
title_full_unstemmed Development of a Bayesian inference model for assessing ventilation condition based on CO(2) meters in primary schools
title_short Development of a Bayesian inference model for assessing ventilation condition based on CO(2) meters in primary schools
title_sort development of a bayesian inference model for assessing ventilation condition based on co(2) meters in primary schools
topic Research Article
url https://www.ncbi.nlm.nih.gov/pmc/articles/PMC9395798/
https://www.ncbi.nlm.nih.gov/pubmed/36035815
http://dx.doi.org/10.1007/s12273-022-0926-8
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