N95 FFR在干燥和中等湿度空气中对抗燃烧和NaCl气溶胶的性能:基于人体模型的研究。

Annals of Occupational Hygiene Pub Date : 2016-07-01 Epub Date: 2016-04-19 DOI:10.1093/annhyg/mew019
Shuang Gao, Jinyong Kim, Michael Yermakov, Yousef Elmashae, Xinjian He, Tiina Reponen, Ziqing Zhuang, Samy Rengasamy, Sergey A Grinshpun
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引用次数: 0

摘要

目的:本研究的第一个目的是通过美国国家职业安全与健康研究所(NIOSH)认证的N95过滤面罩呼吸器(FFR),使用基于人体模型的方案,评估塑料燃烧产生的颗粒物的渗透性,并将数据与NaCl颗粒物的穿透性进行比较。第二个目的是研究相对湿度(RH)对N95 FFR过滤性能的影响。方法:将两个NIOSH认证的N95 FFRs(A和B)完全密封在人体模型人头模型上,并用塑料和NaCl颗粒燃烧产生的颗粒进行攻击。测试使用两种循环流量[平均吸气流量(MIF)=30和85 l/min(-1),代表低和中等工作负荷条件下的人类呼吸]和两种RH水平(≈20和≈80%,代表干燥和中等潮湿的空气)进行。使用冷凝颗粒计数器和气溶胶粒径光谱仪测量呼吸器内部(C in)和外部(C out)的总颗粒浓度和粒径比浓度。每次试验后计算渗透值(C in/C out)。结果:激发气溶胶、RH、MIF率和呼吸器类型对人体模型密封FFR的性能有显著影响(P<0.05)。与NaCl气溶胶相比,当用塑料燃烧颗粒测试FFR时,其效率显著降低。例如,在RH≈80%和MIF=85 l/min(-1)时,分别有7.03%和8.61%的燃烧颗粒物穿透N95口罩A和B。燃烧产生的塑料燃烧颗粒和气体化合物可能会降低纤维上的电荷,从而增加颗粒的穿透力。增加呼吸流速或湿度会增加所有测试气溶胶的穿透力(降低呼吸器效率)。颗粒大小对穿透的影响因挑战气溶胶和呼吸器类型而异。观察到燃烧颗粒的尺寸分布的峰值几乎与它们最具穿透性的颗粒尺寸一致,而NaCl颗粒的情况并非如此。这一发现被用于数据解释。结论:与NaCl颗粒相比,当受到燃烧产生的污染物颗粒的挑战时,N95 FFR的过滤效率较低,尤其是在高湿度条件下使用时。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Performance of N95 FFRs Against Combustion and NaCl Aerosols in Dry and Moderately Humid Air: Manikin-based Study.

Performance of N95 FFRs Against Combustion and NaCl Aerosols in Dry and Moderately Humid Air: Manikin-based Study.

Performance of N95 FFRs Against Combustion and NaCl Aerosols in Dry and Moderately Humid Air: Manikin-based Study.

Performance of N95 FFRs Against Combustion and NaCl Aerosols in Dry and Moderately Humid Air: Manikin-based Study.

Objectives: The first objective of this study was to evaluate the penetration of particles generated from combustion of plastic through National Institute for Occupational Safety and Health (NIOSH)-certified N95 filtering facepiece respirators (FFRs) using a manikin-based protocol and compare the data to the penetration of NaCl particles. The second objective was to investigate the effect of relative humidity (RH) on the filtration performance of N95 FFRs.

Methods: Two NIOSH-certified N95 FFRs (A and B) were fully sealed on a manikin headform and challenged with particles generated by combustion of plastic and NaCl particles. The tests were performed using two cyclic flows [with mean inspiratory flow (MIF) rates = 30 and 85 l min(-1), representing human breathing under low and moderate workload conditions] and two RH levels (≈20 and ≈80%, representing dry and moderately humid air). The total and size-specific particle concentrations inside (C in) and outside (C out) of the respirators were measured with a condensation particle counter and an aerosol size spectrometer. The penetration values (C in/C out) were calculated after each test.

Results: The challenge aerosol, RH, MIF rate, and respirator type had significant (P < 0.05) effects on the performance of the manikin-sealed FFR. Its efficiency significantly decreased when the FFR was tested with plastic combustion particles compared to NaCl aerosols. For example, at RH ≈80% and MIF = 85 l min(-1), as much as 7.03 and 8.61% of combustion particles penetrated N95 respirators A and B, respectively. The plastic combustion particles and gaseous compounds generated by combustion likely degraded the electric charges on fibers, which increased the particle penetration. Increasing breathing flow rate or humidity increased the penetration (reduced the respirator efficiency) for all tested aerosols. The effect of particle size on the penetration varied depending on the challenge aerosol and respirator type. It was observed that the peak of the size distribution of combustion particles almost coincided with their most penetrating particle size, which was not the case for NaCl particles. This finding was utilized for the data interpretation.

Conclusions: N95 FFRs have lower filter efficiency when challenged with contaminant particles generated by combustion, particularly when used under high humidity conditions compared to NaCl particles.

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