视频:单层和多层口罩中替代咳嗽飞沫的二次雾化和阻塞

Shubham Sharma, Roven Pinto, A. Saha, Swetaprovo Chaudhuri, S. Basu
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引用次数: 1

摘要

到目前为止,人们都很清楚,使用口罩可以防止通过呼出和吸入呼吸道飞沫传播病毒载量。因此,在当前的Covid-19大流行期间,卫生官员强烈建议使用口罩。虽然一般建议使用三层口罩,但许多常见的或自制的口罩只有单层和双层。在这项研究中,我们通过详细的物理分析和高速成像显示,高动量咳嗽液滴撞击单层和双层口罩会导致明显的部分穿透,更重要的是会雾化成许多更小的子液滴,从而增加气溶胶的总数,这些微粒可以悬浮更长时间。高动量咳嗽液滴通过口罩纤维网络中的微孔撞击、流体动力聚焦和挤压产生二次雾化的可能性此前尚未被探索过。然而,正如这项工作所示,这种独特的气溶胶产生模式造成了有限的感染风险。我们还证明,在单层掩模中,给定液滴体积的近70%被雾化,只有30%被困在纤维中。双层掩模的捕获体积接近90%,这仍然允许一些雾化成更小的液滴。然而,我们发现三层外科口罩的穿透性可以忽略不计,因此应该有效地防止疾病传播。
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Video: ON SECONDARY ATOMIZATION AND BLOCKAGE OF SURROGATE COUGH DROPLETS IN SINGLE AND MULTI-LAYER FACE MASKS
By now it is well-understood that the usage of facemasks provides protection from transmission of viral loads through exhalation and inhalation of respiratory droplets. Therefore, during the current Covid-19 pandemic the usage of face masks is strongly recommended by health officials. Although three-layer masks are generally advised for usage, many commonly available or homemade masks contain only single and double layers. In this study, we show through detailed physics based analyses and high speed imaging that high momentum cough droplets on impingement on single- and double-layer masks can lead to significant partial penetration and more importantly atomization into numerous much smaller daughter droplets, thereby increasing the total population of the aerosol, which can remain suspended for a longer time. The possibility of secondary atomization of high momentum cough droplets due to impingement, hydrodynamic focusing and extrusion through the microscale pores in the fibrous network of the mask has not been explored before. However, this unique mode of aerosol generation poses a finite risk of infection as shown in this work. We also demonstrate that in single layer masks close to 70 % of a given droplet volume is atomized and only 30 % is trapped within the fibers. The entrapped volume is close to 90 % for double layer masks which still allows some atomization into smaller droplets. We however found that a triple-layer surgical mask permits negligible penetration and hence should be effective in preventing disease transmission.
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