病房的通风率和气流路径:生物气溶胶控制和去除的案例研究。

Annals of Occupational Hygiene Pub Date : 2015-11-01 Epub Date: 2015-07-17 DOI:10.1093/annhyg/mev048
Ehsan S Mousavi, Kevin R Grosskopf
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引用次数: 33

摘要

大多数关于传染性空气传播疾病的研究都集中在病房每小时换气量(ACH)以及ACH如何提供病原体稀释和去除。合乎逻辑但大多未经证实的前提是,较大的空气变化率降低了传染性颗粒的浓度,从而降低了空气传播疾病的可能性。最近,越来越多的研究表明,致病源(患者)和控制者(废气)之间的途径可能是主要的环境因素。虽然空气传播疾病的增加与低于2ach的换气率有关,但相对较少的数据可用于量化临床空间中较高换气率的好处。因此,在实际医院进行了一系列测试,以观察普通病房和空气传播感染隔离室的通风率和定向气流对可吸入性气溶胶(0.5-10µm)的遏制和清除。研究发现,较高的通风量对降低气溶胶浓度没有成比例的效果。具体来说,将机械通气从2.5 ACH增加到5.5 ACH,平均只能降低30%的气溶胶浓度。然而,在源和排气之间的路径中,颗粒浓度高出40%以上,在整个病房中悬浮和迁移的较大颗粒(3-10µm)也是如此。计算分析用于验证实验结果,并进一步量化通风率对病房排气和沉积清除以及其他颗粒传输现象的影响。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Ventilation Rates and Airflow Pathways in Patient Rooms: A Case Study of Bioaerosol Containment and Removal.

Most studies on the transmission of infectious airborne disease have focused on patient room air changes per hour (ACH) and how ACH provides pathogen dilution and removal. The logical but mostly unproven premise is that greater air change rates reduce the concentration of infectious particles and thus, the probability of airborne disease transmission. Recently, a growing body of research suggests pathways between pathogenic source (patient) and control (exhaust) may be the dominant environmental factor. While increases in airborne disease transmission have been associated with ventilation rates below 2 ACH, comparatively less data are available to quantify the benefits of higher air change rates in clinical spaces. As a result, a series of tests were conducted in an actual hospital to observe the containment and removal of respirable aerosols (0.5-10 µm) with respect to ventilation rate and directional airflow in a general patient room, and, an airborne infectious isolation room. Higher ventilation rates were not found to be proportionately effective in reducing aerosol concentrations. Specifically, increasing mechanical ventilation from 2.5 to 5.5 ACH reduced aerosol concentrations only 30% on average. However, particle concentrations were more than 40% higher in pathways between the source and exhaust as was the suspension and migration of larger particles (3-10 µm) throughout the patient room(s). Computational analyses were used to validate the experimental results, and, to further quantify the effect of ventilation rate on exhaust and deposition removal in patient rooms as well as other particle transport phenomena.

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