Disinfection of Transparent Screens by Side-Coupled UVA LED Radiation

3区物理与天体物理 Q1 Materials Science

Progress in Optics Pub Date : 2023-05-15 DOI:10.3390/opt4020023

Ben Sicks, Anna-Maria Gierke, Florian Sommerfeld, Martin Klein, M. Hessling

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引用次数: 0

Abstract

(1) Background: Applications using touch screens are increasingly deployed in medical facilities, as well as in public areas. When touching the display with fingers, potentially pathogenic microorganisms such as methicillin-resistant Staphylococcus aureus (MRSA) can be transmitted. An automated process to decontaminate the device in between users would be highly useful. (2) Methods: Thin glass plates were superficially contaminated with the non-pathogenic Staphylococcus carnosus in a controlled manner. Subsequently, UVA radiation of 400 or 380 nm was laterally coupled into the glass plate, which acted as a light guide. Contact agar plates recorded the change in the staphylococci concentration over time. Additionally, the UVA radiation emitted by the glass plates was measured and the potential risk to humans assessed. (3) Results: Staphylococci concentration decreased as a result of UVA radiation for both wavelengths. At 400 nm, it took about 7.5 h and at 380 nm about 1 h until a reduction of 90% was reached. To meet higher disinfection requirements, disproportionately longer irradiation times were necessary. The potential UVA irradiation of humans in front of the glass pane was about 35 µW/cm2 or less and posed no risk to humans. (4) Conclusions: Side-coupled UVA radiation is in principle capable of safely automatically disinfecting microorganisms on touch screens. However, the required irradiation times are still in the hour range, so that a rapid disinfection within a minute or less is not yet possible with the presented setup. However, higher UVA intensities might reduce the current disinfection durations.

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侧耦合UVA LED辐射对透明屏幕的消毒

(1)背景:使用触摸屏的应用越来越多地部署在医疗设施和公共场所。当用手指触摸显示器时，可能会传播潜在的致病微生物，如耐甲氧西林金黄色葡萄球菌(MRSA)。在用户之间对设备进行消毒的自动化过程将非常有用。(2)方法:控制非致病性胭脂红葡萄球菌污染薄玻璃板表面。随后，将400或380 nm的UVA辐射侧向耦合到玻璃板中，玻璃板起到导光作用。接触琼脂板记录葡萄球菌浓度随时间的变化。此外，测量了玻璃板发出的长波紫外线辐射，并评估了对人类的潜在风险。(3)结果:两种波长的UVA辐射均导致葡萄球菌浓度下降。在400 nm处，大约需要7.5 h，在380 nm处大约需要1 h，直到还原达到90%。为了满足更高的消毒要求，需要更长的辐照时间。人体在玻璃板前受到的潜在UVA辐射约为35 μ W/cm2或更低，对人体没有风险。(4)结论:侧耦合UVA辐射原则上能够安全自动消毒触摸屏上的微生物。然而，所需的辐照时间仍在小时范围内，因此，目前的装置尚不可能在一分钟或更短时间内进行快速消毒。然而，较高的UVA强度可能会缩短当前的消毒时间。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Progress in Optics 物理-光学

CiteScore

4.50

自引率

0.00%

发文量