低于暴露量的紫外线直接照射对空气中病原体的灭活作用

IF 1.3 4区 工程技术 Q3 INSTRUMENTS & INSTRUMENTATION
Gary R Allen, Kevin J Benner, William P Bahnfleth
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引用次数: 0

摘要

描述了一种灭活病原体,特别是空气传播病原体的方法,使用直接发射到占用空间的紫外线(UV)辐射,并将占用者暴露在低于可接受的光化暴露极限(EL)的剂量下。这种方法被称为低于暴露极限的直接照射,或DIBEL。本文证明,低于暴露限值的低强度紫外线辐射可以实现每小时高水平的等效空气变化(ACHeq),并可以成为对抗空气传播病原体的有效组成部分,如导致2019冠状病毒病(新冠肺炎)的严重急性呼吸综合征冠状病毒2(SARS-CoV-2)。目前,使用峰值波长为275 nm的UV-C发光二极管(LED),严重急性呼吸系统综合征冠状病毒2型病毒可以在连续8小时内实现4 h−1的ACHeq,预计未来十年LED技术和光学的改进将达到150 h−1。例如,光化EL在254nm处为60J/m2,并且包括严重急性呼吸系统综合征冠状病毒2型在内的人类冠状病毒在254nm具有约5J/m2的90%灭活所需的紫外线剂量。当UV-C在8小时内以恒定辐照度递送时,在EL处通过254nm UV-C的照射预计将在约40分钟内对空气中的这些生物体提供90%的灭活,或者如果UV-C在1小时内以不变辐照度递送,则在约5分钟内提供90%的失活。由于照射是连续的,初始污染物的灭活累积到99%,然后累积到99.9%,并且它也立即开始在整个8小时期间以相同的速率灭活任何新引入的(例如呼出的)病原体。DIBEL灭活空气传播病原体的功效可以用ACHeq来表示,ACHeq可以与传统的基于通风的空气消毒方法进行比较。DIBEL可用于其他消毒方法,如上层房间紫外线杀菌照射、机械通风和过滤。单独方法的ACHeq是添加剂,可提高累积消毒率。常规空气消毒技术的典型ACHeq值约为1 h-1至5 h-1,最大实际值约为20 h-1。UV-C DIBEL目前提供的ACHeq值通常约为1 h−1至10 h−1,从而补充或可能取代传统技术。本文预测UV-C DIBEL协议将在几年内发展到>100 ACHeq,可能超过传统技术。UV-A(315nm至400nm)和/或UV-C(100nm至280nm)DIBEL在灭活表面上的病原体方面也是有效的。DIBEL使用紫外线LED的相对简单的安装、较低的采购和运营成本以及不引人注目的美学为分层、多智能体消毒策略带来了价值。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Inactivation of Pathogens in Air Using Ultraviolet Direct Irradiation Below Exposure Limits.

A method is described for inactivation of pathogens, especially airborne pathogens, using ultraviolet (UV) radiation emitted directly into occupied spaces and exposing occupants to a dose below the accepted actinic exposure limit (EL). This method is referred to as direct irradiation below exposure limits, or DIBEL. It is demonstrated herein that low-intensity UV radiation below exposure limits can achieve high levels of equivalent air changes per hour (ACHeq) and can be an effective component of efforts to combat airborne pathogens such as the severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2), the virus that causes coronavirus disease 2019 (COVID-19). An ACHeq of 4 h-¹ is presently achievable over a continuous 8 h period for the SARS-CoV-2 virus with UV-C light-emitting diodes (LEDs) having peak wavelength at 275 nm, and future improvements in LED technology and optics are anticipated to enable improvements up to 150 h-¹ in the coming decade. For example, the actinic EL is 60 J/m² at 254 nm, and human coronaviruses, including SARS-CoV-2, have a UV dose required for 90 % inactivation of about 5 J/m² at 254 nm. Irradiation by 254 nm UV-C at the EL is expected to provide 90 % inactivation of these organisms in air in about 40 min when the UV-C is delivered at a constant irradiance over 8 h, or in about 5 min if the UV-C is delivered at a constant irradiance over 1 h. Since the irradiation is continuous, the inactivation of initial contaminants accumulates to 99 % and then 99.9 %, and it also immediately begins inactivating any newly introduced (e.g., exhaled) pathogens at the same rate throughout the 8 h period. The efficacy for inactivating airborne pathogens with DIBEL may be expressed in terms of ACHeq, which may be compared with conventional ventilation-based methods for air disinfection. DIBEL may be applied in addition to other disinfection methods, such as upper room UV germicidal irradiation, and mechanical ventilation and filtration. The ACHeq of the separate methods is additive, providing enhanced cumulative disinfection rates. Conventional air disinfection technologies have typical ACHeq values of about 1 h-¹ to 5 h-¹ and maximum practical values of about 20 h-¹. UV-C DIBEL currently provides ACHeq values that are typically about 1 h-¹ to 10 h-¹, thus either complementing, or potentially substituting for, conventional technologies. UV-C DIBEL protocols are forecast herein to evolve to >100 ACHeq in a few years, potentially surpassing conventional technologies. UV-A (315 nm to 400 nm) and/or UV-C (100 nm to 280 nm) DIBEL is also efficacious at inactivating pathogens on surfaces. The relatively simple installation, low acquisition and operating costs, and unobtrusive aesthetic of DIBEL using UV LEDs contribute value in a layered, multi-agent disinfection strategy.

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来源期刊
自引率
33.30%
发文量
10
审稿时长
>12 weeks
期刊介绍: The Journal of Research of the National Institute of Standards and Technology is the flagship publication of the National Institute of Standards and Technology. It has been published under various titles and forms since 1904, with its roots as Scientific Papers issued as the Bulletin of the Bureau of Standards. In 1928, the Scientific Papers were combined with Technologic Papers, which reported results of investigations of material and methods of testing. This new publication was titled the Bureau of Standards Journal of Research. The Journal of Research of NIST reports NIST research and development in metrology and related fields of physical science, engineering, applied mathematics, statistics, biotechnology, information technology.
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