基于蒸汽压缩制冷循环的常压水发生器的设计与制造

Saad Alshahrani
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摘要

从大气中产生水是一种环境友好的选择,也是一种提取纯净淡水的可持续过程。大气水发生器(AWG)是一种利用除湿从空气中的水分中产生饮用水的设备。空气中的水分或湿度被冷却到露点温度以下,因此,水蒸气凝结成水滴。收集的水滴经过过滤和再矿化,产生新鲜和可饮用的饮用水。利用这些原理,我们设计并制造了一个原型系统,用于使用蒸汽压缩制冷循环从大气中提取清洁饮用水。AWG采用容量为18000 Btu/h的二手窗口空调机组制造。该装置由空气过滤器、压缩机、冷凝器、节流装置和冷却盘管组成。此外,该装置利用除湿后的冷空气对冷凝器进行冷却,大大提高了冷凝器的效率。在两天的运行中,系统能够收集5800 mL。最初从2020年10月3日中午12点开始到2020年10月5日中午12点开始使用两天。之后,AWG又使用了两天,从2020年10月5日下午12:30开始,到2020年10月7日中午12点。在这次运行中,收集了4100毫升的水。结果发现,从AWG收集的水的质量与正常饮用水的质量相当。收集的水质由Oakton PC 450防水便携式水表评估,该水表具有组合探头和校准系统。瞬时温度和相对湿度值表示在干湿图上,以了解产生水的可能性,并显示在结果和讨论中。在上述试验期间,2020年10月5日下午12:30至2020年10月7日中午12点,记录温度和相对湿度读数。
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Design and Fabrication of an Atmospheric Water Generator Based on Vapor Compression Refrigeration Cycle
Water generation from the atmosphere is an environmentally friendly alternative and a sustainable process to extract pure and fresh water. An atmospheric water generator (AWG) is a device that uses dehumidification to generate potable water out of moisture present in the air. The moisture or humidity present in the air is cooled below the dew point temperature and as a result, water vapor is condensed into water droplets. The collected water droplets are filtered and re-mineralized to produce fresh and potable drinking water. Using these principles, we have designed and fabricated a prototype system for extracting clean drinking water from atmospheric air using a vapor compression refrigeration cycle. An AWG is fabricated by using a secondhand window air conditioning unit with a capacity 18000 Btu/h. The device consists of an air filter, compressor, condenser, throttling device, and cooling coils. In addition, the device utilizes the dehumidified cool air to cool the condenser and improves its effectiveness considerably. During two operating days, the system was able to collect 5800 mL. Initially it was employed for two days starting from 12 noon, on October 3, 2020 to 12 noon, October 5th 2020. After that, the AWG was employed for two more days, staring from 12:30 pm, October 5th 2020 to 12 noon, October 7th 2020. During this run, 4100 mL of water was collected. It was found that the quality of collected water from the AWG was on par with that of normal drinking water. The quality of the collected water was assessed by an Oakton PC 450 waterproof portable meter with a combination probe and calibration system. The instantaneous temperature and relative humidity values are represented on the psychrometric chart to understand the possibility of water generation and are shown in results and discussions. During the aforementioned trial between 12:30 pm, October 5th 2020 and 12 noon, October 7th 2020, temperature and relative humidity readings were recorded.
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