Theoretical and Experimental Analysis of Atmospheric Water Harvesting Device

Progress in Canadian Mechanical Engineering. Volume 3 Pub Date : 2020-09-01 DOI:10.32393/CSME.2020.1278

A. Adeyanju

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引用次数: 2

Abstract

A semi-open atmospheric water harvesting device using atmospheric water vapor processing technology was designed and built. The processor is a device which extract water molecules from the atmosphere, ultimately causing a phase change from vapor to liquid. This is done by concentrating air, containing water vapor through a solid desiccant. Then heating the desiccant to remove the air and allow it to condense and then collect the condensate. The research focuses on the development of a relationship for the amount of silica gel to the amount of water produced to determine the sufficient amount required for the specific application. This relationship was found to be 𝑀 𝑤 = 1.0776 𝑀 𝑠 − 0.4752, with a solar panel efficiency of 10.7%. The recorded values collected were then used to calculate the amount of water produced and were compared to the actual amount of water collected. The study concentrates on the extracting potable water from air especially with respect to the remote/rural arid places with deficit of natural fresh water and electricity supply. Solar energy as a power supply were focused on with discussing their strengths and limitations.

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大气集水装置的理论与实验分析

设计并制造了一种采用大气水蒸气处理技术的半开放式大气集水装置。处理器是一种从大气中提取水分子的装置，最终导致从蒸汽到液体的相变。这是通过通过固体干燥剂浓缩含有水蒸气的空气来完成的。然后加热干燥剂以除去空气并使其凝结，然后收集冷凝物。研究的重点是建立硅胶用量与产水量之间的关系，以确定具体应用所需的足够量。该关系发现𝑀𝑤= 1.0776𝑀𝑠−0.4752，太阳能电池板效率为10.7%。然后使用收集的记录值来计算出水量，并将其与实际收集的水量进行比较。本研究主要针对自然淡水和电力供应不足的偏远/农村干旱地区，研究从空气中提取饮用水的方法。重点讨论了太阳能作为一种电源的优势和局限性。

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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Progress in Canadian Mechanical Engineering. Volume 3

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