以 CO 浓度作为室内通风性能的指标，以控制 SARS-CoV-2 的空气传播。

CO concentration as an indicator of indoor ventilation performance to control airborne transmission of SARS-CoV-2.

机构信息

Graduate School, Sungkyunkwan University, Suwon 16419, South Korea.

School of Civil, Architectural Eng., and Landscape Architecture, Sungkyunkwan University, Suwon 16419, South Korea.

出版信息

J Infect Public Health. 2023 Jul;16(7):1037-1044. doi: 10.1016/j.jiph.2023.05.011. Epub 2023 May 10.

DOI:10.1016/j.jiph.2023.05.011

PMID:37196366

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC10170871/

Abstract

BACKGROUND

The Wells-Riley equation has been extensively used to quantify the infection risk of airborne transmission indoors. This equation is difficult to apply to actual conditions because it requires measurement of the outdoor air supply rate, which vary with time and are difficult to quantify. The method of determining the fraction of inhaled air that has been exhaled previously by someone in a building using a CO concentration measurement can solve the limitations of the existing method. Using this method, the indoor CO concentration threshold can be determined to keep the risk of infection below certain conditions.

METHODS

Based on the calculation of the rebreathed fraction, an appropriate mean indoor CO concentration and required air exchange rate to control SARS-CoV-2 airborne transmission was calculated. The number of indoor occupants, ventilation rate, and the deposition and inactivation rates of the virus-laden aerosols were considered. The application of the proposed indoor CO concentration-based infection rate control was investigated through case studies in school classrooms and restaurants.

RESULTS

In a typical school classroom environment with 20-25 occupants and an exposure time of 6-8 h, the average indoor CO concentration should be kept below 700 ppm to control the risk of airborne infection indoors. The ASHRAE recommended ventilation rate is sufficient when wearing a mask in classrooms. For a typical restaurant with 50-100 occupants and an exposure time of 2-3 h, the average indoor CO concentration should be kept below about 900 ppm. Residence time in the restaurant had a significant effect on the acceptable CO concentration.

CONCLUSION

Given the conditions of the occupancy environment, it is possible to determine an indoor CO concentration threshold, and keeping the CO concentration lower than a certain threshold could help reduce the risk of COVID-19 infection.

摘要

背景

韦尔斯-莱利方程被广泛用于量化室内空气传播的感染风险。该方程难以应用于实际情况，因为它需要测量室外空气供应量，而这随时间变化且难以量化。使用 CO 浓度测量确定某人在建筑物中吸入的空气有多少比例是先前呼出的空气的方法可以解决现有方法的局限性。使用这种方法，可以确定室内 CO 浓度阈值，以将感染风险控制在一定条件以下。

方法

基于再呼吸分数的计算，计算了适当的平均室内 CO 浓度和控制 SARS-CoV-2 空气传播所需的空气交换率。考虑了室内人数、通风率以及载病毒气溶胶的沉积和失活率。通过对学校教室和餐厅的案例研究，研究了基于建议的室内 CO 浓度的感染率控制的应用。

结果

在一个典型的有 20-25 名学生的教室环境中，暴露时间为 6-8 小时，为控制室内空气传播感染的风险，应将平均室内 CO 浓度保持在 700 ppm 以下。在教室中戴口罩时，ASHRAE 推荐的通风率是足够的。对于一个典型的有 50-100 名顾客的餐厅，暴露时间为 2-3 小时，应将平均室内 CO 浓度保持在约 900 ppm 以下。在餐厅的停留时间对可接受的 CO 浓度有显著影响。

结论

根据占用环境的条件，可以确定室内 CO 浓度阈值，并且将 CO 浓度保持在一定阈值以下可以帮助降低 COVID-19 感染的风险。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/e4be/10170871/87e43970e9b6/gr1_lrg.jpg

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以 CO 浓度作为室内通风性能的指标，以控制 SARS-CoV-2 的空气传播。

CO concentration as an indicator of indoor ventilation performance to control airborne transmission of SARS-CoV-2.

机构信息

出版信息

BACKGROUND

METHODS

RESULTS

CONCLUSION

背景

方法

结果

结论

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