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Collaborative Research: Effective Face Masks to Mitigate COVID-19 Transmission: Insights from Multimodal Quantitative Analysis

合作研究：有效缓解 COVID-19 传播的口罩：多模态定量分析的见解

基本信息

批准号：
2035002
负责人：
Kenneth Breuer
金额：
$ 32万
依托单位：
Brown University
依托单位国家：
美国
项目类别：
Standard Grant
财政年份：
2020
资助国家：
美国
起止时间：
2020-11-15 至 2024-10-31
项目状态：
已结题

来源：
https://www.nsf.gov/awardsearch/showAward?AWD_ID=2035002&HistoricalAwards=false
关键词：
Collaborative Research Effective Face Masks

项目摘要

The years ahead will likely see face masks become a critical and widely used “medical appliance.” Understanding the physics that underpins the effectiveness of face masks as a defense against airborne pathogens is therefore more important than ever. The protection afforded by face masks has emerged as a particularly important issue in the COVID-19 pandemic, but the flow physics of face masks is complex and is not well-studied. The increased pressure inside the mask during expiration pushes the face mask outwards, resulting in increased perimeter leakage. This fluid-structure interaction problem is mediated by the structural design and the permeability of the mask, as well as the fit on the face. Spasmodic events such as coughing and sneezing generate high transient expulsion velocities and significantly diminish the outward protection of face masks. However, in a conceivable future where people will wear face masks while engaged in their daily routines, outward protection during normal activities such as breathing and talking, might be equally important. The objectives of this project are (i) to develop improved computational and experimental tools necessary to characterize the performance of face masks, (ii) to employ these tools to perform a detailed characterization of mask performance under a variety of conditions and (iii) to generate, in a timely manner, data that can be used for improved facemask design and to guide more effective public health policy.The project will develop a set of innovative, powerful and accurate computational and experimental tools, rooted in flow physics and mechanics that can be used for the quantitative analysis of the protective performance of face masks. Computational tools will couple fluid flows with the motion of elastic structures in complex geometries defined by a wide range of facial geometries. Experimental tools will include simultaneous measurements of mask motion and the aerosol cloud, using Digital Image Correlation and Particle Image Velocimetry, respectively. Visible and X-ray techniques will be used to take measurements outside and inside the mask. The combined results of the simulations and experiments are expected to yield critical insights regarding the features that contribute to the protective performance of masks, and to provide timely guidance for improved mask design and effective public health policies. The project will promote the multidisciplinary education of students in Science and Engineering, and increase public knowledge about the fluid dynamics principles of effective facemasks.This award reflects NSF's statutory mission and has been deemed worthy of support through evaluation using the Foundation's intellectual merit and broader impacts review criteria.

未来几年，口罩可能会成为一种重要且广泛使用的“医疗器械”。因此，了解支撑口罩有效防御空气传播病原体的物理学比以往任何时候都更加重要。在COVID-19大流行中，口罩提供的保护已成为一个特别重要的问题，但口罩的流动物理学很复杂，尚未得到充分研究。呼气期间面罩内部增加的压力将面罩向外推，导致周边泄漏增加。这种流体-结构相互作用问题由面罩的结构设计和渗透性以及在面部上的贴合性来调节。突发事件，如咳嗽和打喷嚏，会产生高的瞬时排出速度，并显著降低口罩的向外保护。然而，在一个可以想象的未来，人们在日常生活中会戴口罩，在呼吸和说话等正常活动中的外部保护可能同样重要。该项目的目标是（i）开发表征口罩性能所需的改进的计算和实验工具，（ii）使用这些工具在各种条件下对口罩性能进行详细表征，以及（iii）及时生成，这些数据可用于改进口罩设计，并指导更有效的公共卫生政策。该项目将开发一套创新的，强大而精确的计算和实验工具，植根于流动物理学和力学，可用于定量分析口罩的防护性能。计算工具将耦合流体流动与弹性结构的运动在复杂的几何形状所定义的广泛的面部几何形状。实验工具将包括掩模运动和气溶胶云的同时测量，分别使用数字图像相关和粒子图像测速。可见光和X射线技术将用于测量面罩的外部和内部。预计模拟和实验的综合结果将产生关于有助于口罩防护性能的特征的关键见解，并为改进口罩设计和有效的公共卫生政策提供及时的指导。该项目将促进科学和工程专业学生的多学科教育，并增加公众对有效口罩流体动力学原理的了解。该奖项反映了NSF的法定使命，并通过使用基金会的智力价值和更广泛的影响审查标准进行评估，被认为值得支持。