防倾斜和可制造的雾耙，用于高效集水

Droplet Pub Date : 2023-08-01 DOI:10.1002/dro2.78

Jimmy K. Kaindu, Kevin R. Murphy, Nicholas G. Kowalski, Alexandra N. Jones, Matthew Davis Fleming, Brook S. Kennedy, Jonathan B. Boreyko

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引用次数: 2

摘要

雾Harps比传统的基于网格的收割机收获更多的水。然而，到目前为止，所有大规模的Fog Harps都是在低线张力下手工缠绕的，并且存在弹性毛细管线缠结。在这里，我们开发了可制造和防倾斜的大型高张力雾灯。这些雾Harp保留了其优化比例模型对应物的创纪录的雾收集效率（η≈17$\eta\approximate 17$%），同时独特地实现了实际应用。可制造性是通过调整制造竖琴筛的工业工艺来实现的，这是一种用于筛选固体材料的预先存在的技术。通过改进的弹性毛细管缠结模型，合理化了使金属丝缠结最小化所需的临界张力。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

Antitangling and manufacturable Fog Harps for high-efficiency water harvesting

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Antitangling and manufacturable Fog Harps for high-efficiency water harvesting

Fog Harps harvest substantially more water than conventional mesh-based harvesters. However, to date, all large-scale Fog Harps have been impractically hand-wound at low wire tensions and suffer from elastocapillary wire tangling. Here, we develop large-scale and high-tension Fog Harps that are manufacturable and antitangling. These Fog Harps retain the record-setting fog harvesting efficiency ( $η \approx 17$ %) of their optimized scale-model counterparts, while uniquely enabling practical real-life implementation. Manufacturability was achieved by adapting the industrial process for making harp screens, a pre-existing technology used for screening solid materials. The critical tension required to minimize wire tangling was rationalized by an improved elastocapillary tangling model.

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来源期刊

Droplet

CiteScore

6.60

自引率

0.00%

发文量