Hamed Rasam, Vincenzo Maria Gentile, Paolo Tronville, Marco Simonetti
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引用次数: 0
Abstract
Vulnerable individuals close to infected people emitting a respiratory cloud containing infectious load can inhale a pathogen dose, experiencing a more severe impact on their health compared to other individuals breathing the mixed air in the same room. In crowded spaces, this issue is crucial. Employing local airflow patterns can reduce the proximity risk of inhalation and subsequent transmission across short distances. This study proposes an experimental and numerical analysis of a novel personal and portable device creating a short-range air barrier to transmitting airborne pathogens in proximity. The portable device adopts V-shaped air blades affecting the trajectory of the particle-laden respiratory cloud emitted by the respiratory system of the infected individual. Experimental results, supported by CFD analysis, indicate that controlling local airflow through the V-shaped jet significantly reduces local particle concentrations by more than 60%, compared to typical scenarios without a local airflow control.
与在同一房间内呼吸混合空气的其他人相比,靠近散发着含有感染负荷的呼吸云的感染者的易感人群会吸入一定剂量的病原体,对其健康造成更严重的影响。在拥挤的空间,这个问题至关重要。采用局部气流模式可以降低近距离吸入风险和随后的短距离传播。本研究通过实验和数值分析,提出了一种新型的个人便携式装置,它能在短距离内形成空气屏障,阻止空气中的病原体近距离传播。该便携式装置采用 V 型气流叶片,可影响受感染者呼吸系统散发的含微粒呼吸云的轨迹。通过 CFD 分析得出的实验结果表明,与没有局部气流控制的典型方案相比,通过 V 形喷流控制局部气流可将局部颗粒浓度显著降低 60% 以上。
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