Analysis of the spread of cough droplets and body deposition fraction in the smart classroom in different seasons

Mengfan Jia , Dan Mei , Jiaqian Li , Zihan Liu , Wenzhu Duan , Shanshan Hou
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引用次数: 1

Abstract

Smart classrooms are a relatively confined public space for college students. SARS-COV-2 and other respiratory viruses have been shown to pose a more significant threat to human health in relatively confined spaces. Using numerical simulation method to simulate the transmission and concentration distribution of virus-carrying droplets in smart classrooms in three different seasons (summer, winter, transitional seasons: spring and autumn). The Realizable k-ε model is used to simulate the airflow pattern in the smart classroom, and the Lagrangian method is used to simulate the transmission of droplets. The transmission process of droplets produced from the teacher standing on the platform and the student sitting on the seat is studied. The influence of three kinds of outdoor temperature on droplet transmission and the body deposition fraction of people in the smart classroom is analyzed. The results show that droplet transmission speed is maximum at the temperature of 5 degrees when the outdoor temperature is 5 °C, 20 °C, and 35 °C respectively. At 10 s, the transmission distance of droplets increases by 9.55% compared with that at 20 °C and 10.31% compared with that at 35 °C. In addition, the body deposition fraction is also affected by the location of the vent, with downwind contact being 6 times more likely than upwind contact. The research results can provide suggestions and measures for epidemic prevention and control in smart classrooms.

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智能教室不同季节咳嗽飞沫传播及体沉降率分析
智能教室对于大学生来说是一个相对封闭的公共空间。已证明,SARS-COV-2和其他呼吸道病毒在相对密闭的空间中对人类健康构成更大的威胁。采用数值模拟的方法,模拟了三个不同季节(夏、冬、春、秋过渡季节)智能教室中携带病毒飞沫的传播和浓度分布。采用Realizable k-ε模型模拟智能教室内的气流形态,采用拉格朗日法模拟液滴的传播。研究了站在讲台上的教师和坐在座位上的学生产生的飞沫的传播过程。分析了三种室外温度对智能教室内人员的飞沫传播和体沉积率的影响。结果表明,室外温度分别为5℃、20℃和35℃时,液滴在5℃温度下传播速度最大;在10 s时,液滴的传播距离比20℃时增加了9.55%,比35℃时增加了10.31%。此外,机体沉积分数也受到排气口位置的影响,顺风接触的可能性是逆风接触的6倍。研究结果可为智能教室的疫情防控提供建议和措施。
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来源期刊
Hygiene and environmental health advances
Hygiene and environmental health advances Environmental Science (General)
CiteScore
1.10
自引率
0.00%
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0
审稿时长
38 days
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