From capture to transport: A review of engineered surfaces for fog collection

Droplet Pub Date : 2023-04-10 DOI:10.1002/dro2.55
Youhua Jiang, Christian Machado, Kyoo-Chul K. Park
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引用次数: 12

Abstract

Collecting microscale water droplets suspended in the wind, that is, fog, using permeable surfaces is a promising solution to the worldwide problem of water scarcity and is of great interest to industries, such as mist elimination and recapturing water in cooling towers. In the past few decades, this topic has attracted a drastically increasing number of researchers across a wide range of subjects. However, many aspects remain unclear, such as the definition and process of fog collection, fog collection determined from the perspectives of both the fog capture process and the liquid transport process, and how surface characteristics affect fog collection performance. In this review, we introduce and discuss fog collection from the perspectives of aerodynamics-governed fog-capturing processes and interfacial-phenomena-determined liquid transport processes. Then, an emphasis is given to the design and engineering of permeable surfaces at different length scales to optimize the fog collection performance, including the dimension, morphology, and arrangement of wires at the millimetric scale, unidirectional spreading, and Laplace pressure gradient induced by asymmetric surface geometry and nano-/microstructures. At last, a brief outlook of future research directions is provided.

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从捕获到运输:雾收集工程表面综述
利用可渗透表面收集悬浮在风中的微小水滴,即雾,是解决全球缺水问题的一种很有前途的解决方案,对工业界来说也很有意义,例如消除薄雾和在冷却塔中回收水。在过去的几十年里,这个话题吸引了越来越多的研究人员,涉及广泛的学科。然而,许多方面仍不清楚,如雾收集的定义和过程,从雾捕获过程和液体传输过程的角度确定的雾收集,以及表面特性如何影响雾收集性能。在这篇综述中,我们从空气动力学控制的雾捕获过程和界面现象决定的液体传输过程的角度介绍和讨论了雾收集。然后,重点研究了不同长度尺度下可渗透表面的设计和工程,以优化雾收集性能,包括毫米尺度下金属丝的尺寸、形态和排列、单向扩展以及不对称表面几何形状和纳米/微观结构引起的拉普拉斯压力梯度。最后,对未来的研究方向进行了简要展望。
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Issue Information Front Cover, Volume 3, Number 4, October 2024 Inside Back Cover, Volume 3, Number 4, October 2024 Back Cover, Volume 3, Number 4, October 2024 Inside Front Cover, Volume 3, Number 4, October 2024
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