Experimental and environmental analysis of an autonomous desalination system based on evapo-condensation heated by a Scheffler reflector in Marrakesh climate

IF 4.4 2区 工程技术 Q2 ENERGY & FUELS
Chaymae Lachguer , Fatima Ait nouh , Saida Bahsine , Nader Frikha , Slimane Gabsi , Ayoub El Berkaoui
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Abstract

Excessive consumption of water resources is a major problem almost everywhere through the world due to the global increasiness of population and the underlying high rates of urbanization and industrialization. In this context, Solar desalination is proposed as an effective solution not only to produce water but also to mitigate the emissions of CO2, which thereby contributes to the limitation of global warming. This study presents an experiment that explores the use of solar energy in desalination systems, consisting in a parabolic dish solar concentrating “SCHEFFLER REFLECTOR” for desalination-hot water system (PDSCHWS) conducted in the weather conditions of Marrakesh in Morocco also an environmental analysis conducts to calculate the emission of CO2 and the carbon credit gained. The performance of the desalination system was achieved in real thermal conditions from January to May 2022 on several days each month. The investigated results reported that the efficiency of the system is 28.75 %. It actually produced 9000 cm3/day of distilled water with an electrical conductivity of 3.4 μS/cm which presented a significant reduction from the initial level of 4 ∗ 103 μS/cm. The environmental analysis concluded that the carbon credit gained from the system is 529.69($), and the net carbon dioxide mitigation is 37.83 tons of CO2 emission over the lifetime of the system.

Abstract Image

马拉喀什气候下基于谢弗勒反射器加热蒸发冷凝的自主海水淡化系统的实验和环境分析
由于全球人口的不断增长以及城市化和工业化的高速发展,水资源的过度消耗几乎成为全球各地的一个主要问题。在这种情况下,太阳能海水淡化被认为是一种有效的解决方案,不仅可以生产水,还可以减少二氧化碳的排放,从而限制全球变暖。本研究介绍了一项探索在海水淡化系统中使用太阳能的实验,包括在摩洛哥马拉喀什的天气条件下,使用抛物面碟形太阳能聚光 "SCHEFFLER REFLECTOR "海水淡化-热水系统(PDSCHWS),并进行环境分析,计算二氧化碳排放量和获得的碳信用额度。海水淡化系统的性能是在 2022 年 1 月至 5 月每月若干天的实际热量条件下实现的。调查结果显示,该系统的效率为 28.75%。该系统每天实际生产 9000 立方厘米的蒸馏水,电导率为 3.4 μS/cm,与最初的 4 ∗ 103 μS/cm 相比,电导率显著降低。环境分析得出的结论是,该系统获得的碳信用额为 529.69(美元),在该系统的生命周期内净减排二氧化碳 37.83 吨。
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来源期刊
Energy for Sustainable Development
Energy for Sustainable Development ENERGY & FUELS-ENERGY & FUELS
CiteScore
8.10
自引率
9.10%
发文量
187
审稿时长
6-12 weeks
期刊介绍: Published on behalf of the International Energy Initiative, Energy for Sustainable Development is the journal for decision makers, managers, consultants, policy makers, planners and researchers in both government and non-government organizations. It publishes original research and reviews about energy in developing countries, sustainable development, energy resources, technologies, policies and interactions.
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