A Green Approach to Safe Domestic Drinking Water Supply by Using Solar Geyser

Q4 Engineering

Journal of Environmental Health and Sustainable Development Pub Date : 2022-03-15 DOI:10.18502/jehsd.v7i1.8964

D. Rabbani, A. Mahvi, M. Shaterian, Reyhaneh Hesamifard, Mohammad Rezvani Ghalhari, Morteza Kabiri, G. Mostafaii

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引用次数: 1

Abstract

Introduction: Accessibility to safe drinking water is an important human health issue, so water reuse and water resources management are critical in arid parts of developing regions. This study aimed to investigate the use of a combined simple designed solar geyser/photocell for drinking water disinfection. Materials and Methods: In this study, a solar geyser with a simple design was combined with a solar cell and its efficiency on the disinfection of contaminated water was investigated. This study was carried out with artificially polluted tap water by a solar geyser joined with a solar photovoltaic cell. The heated water (55°C) was kept for 2 hours using a solenoid valve. The pilot plant was operated and monitored for one year. The volume of the collected effluent was measured every 24 h. The most probably number (MPN) of total coliforms and fecal coliforms in 100 mL of 24-hour composed samples were measured. Results: The mean volume of disinfected water production was calculated as 2095.74 ± 270.28 mL/day. The strongest correlation was found between disinfected water and the maximum daily ambient air temperature with a linear model (R2 = 0.9937). The results showed that by increasing the sunny time, the volume of water outlet increased. Therefore, sunny time and UV radiation have direct effect on volume of disinfected water. Conclusion: The simple designed solar geyser for drinking water disinfection was efficient and recommended for tropical areas, emergency conditions, and farms for agricultural activities.

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利用太阳能间歇泉实现安全生活饮用水供应的绿色途径

引言：获得安全饮用水是一个重要的人类健康问题，因此在发展中地区的干旱地区，水的再利用和水资源管理至关重要。本研究旨在研究使用简单设计的太阳能间歇泉/光电管组合进行饮用水消毒。材料和方法：本研究将设计简单的太阳能间歇泉与太阳能电池相结合，研究其对污染水的消毒效果。这项研究是通过将太阳能间歇泉与太阳能光伏电池连接在一起，用人工污染的自来水进行的。使用电磁阀将热水（55°C）保持2小时。中试装置运行并监测了一年。每24小时测量一次收集的流出物的体积。测量100 mL 24小时合成样品中总大肠菌群和粪便大肠菌群的最可能数量（MPN）。结果：消毒水平均产生量为2095.74±270.28mL/天。消毒水与最高日环境空气温度之间的相关性最强，呈线性模型（R2=0.9937）。结果表明，随着日照时间的增加，出水量增加。因此，日照时间和紫外线辐射对消毒水量有直接影响。结论：设计简单的太阳能间歇泉用于饮用水消毒是有效的，建议用于热带地区、紧急情况和农业活动农场。

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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来源期刊

Journal of Environmental Health and Sustainable Development Engineering-Engineering (miscellaneous)

CiteScore

1.10

自引率

0.00%

发文量

审稿时长

9 weeks