绘制传染病在宽体飞机客舱传播的可能性

Seif Mahmoud, J. Bennett, M. Hosni, B. Jones
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引用次数: 1

摘要

每年有20多亿乘客乘坐飞机,飞机上传染病的传播是一个主要的全球健康问题。人们普遍认为,与大多数呼吸道传染病有关的航空旅行的主要传播风险仅限于传染性乘客的两排以内。然而,几名乘客尽管与感染的乘客隔了几排,但还是被感染了。这项工作彻底调查了疾病在飞机机舱内传播的可能性,使用示踪气体量化空气传播。测量是在一个全尺寸、11排的宽体飞机机舱模型中进行的。加热的人体模型被放置在客舱座椅上,以模拟乘客的热负荷。示踪气体被注入到四个不同的假设感染乘客的呼吸水平。示踪气体浓度沿径向距离注射位置3.35 m处测量,代表一架标准飞机的四排。采用四端口采样树同时在四个不同的径向位置采集呼吸水平的样本。每个端口采样30分钟。共进行了42项配对试验,以减轻潜在的统计或测量偏差。结果表明,模拟飞机客舱内气流形态对示踪气体浓度的影响较大,不同方向相同径向距离处的示踪气体浓度不一定相同。此外,由于空气分布模式和客舱壁,某些座位的浓度可能高于源座位。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Mapping the Potential for Infectious Disease Transmission in a Wide-Body Aircraft Cabin
With more than two billion passengers annually, in-flight transmission of infectious diseases is a major global health concern. It is widely believed that principal transmission risk associated with air travel for most respiratory infectious diseases is limited to within two rows of an infectious passenger. However, several passengers became infected despite sitting several rows away from the contagious passenger. This work thoroughly investigated the potential for disease spread inside airplane cabins using tracer gas to quantify airborne dispersion. Measurements were conducted in a full-scale, 11-row mock-up of a wide-body aircraft cabin. Heated mannequins to simulate passengers’ thermal load were placed on the cabin seats. Tracer gas was injected at the breathing level at four different hypothetical contagious passenger locations. The tracer gas concentration was measured radially up to 3.35 m away from the injection location representing four rows of a standard aircraft. A four-port sampling tree was used to collect samples at the breathing level at four different radial locations simultaneously. Each port was sampled for 30 minutes. A total of 42 tests were conducted in matching pairs to alleviate potential statistical or measurements bias. The results showed that the airflow pattern inside the mock-up airplane cabin plays a major role in determining tracer gas concentration meaning that the concentration at the same radial distance in different directions are not necessarily the same. Also, due to the air distribution pattern and cabin walls, concentrations at some seats may be higher than the source seat.
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