Effect of ten different physical parameters on solar still productivity: Theoretical modeling

IF 4.6 Q2 MATERIALS SCIENCE, BIOMATERIALS
Adil A. M. Omara, Omer Elfarouk E. Mohamed, Abubaker A. M. Mohammedali, Mustafa Ahmed Khogley Ahmed
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引用次数: 0

Abstract

Solar distillation using solar stills is widely recognized as a clean and cost-effective method for producing freshwater. However, due to its straightforward design, solar still performance is greatly influenced by various physical characteristics. Many researches have evaluated solar still parameters, while only a few articles have concerned physical ones. Therefore, this article aims to investigate the effect of different physical parameters on solar still productivity through thermal modeling. The theoretical results were validated with those of a previous experimental model, showing a good agreement with each other. The results reveal that daily productivity experiences significant improvement with an increase in plate emissivity or insulation thickness. Conversely, an increase in water mass, glass absorptivity or insulation thermal conductivity leads to a substantial reduction in productivity. Notably, water transmissivity and plate absorptivity do not affect productivity. Modest enhancements in productivity can be achieved by reducing the effective emissivity between water and glass. While the initial temperature of water has a minor impact on productivity at low water mass, it exhibits a substantial improvement effect at high water mass. These results can be a good guidance for the designers and manufacturers to develop more efficient designs that maximize the production of clean water.

十种不同物理参数对太阳能蒸发器生产率的影响:理论建模
利用太阳能蒸馏器进行太阳能蒸馏被公认为是一种生产淡水的清洁而经济的方法。然而,由于设计简单,太阳能蒸馏器的性能在很大程度上受到各种物理特性的影响。许多研究对太阳能蒸馏器的参数进行了评估,但只有少数文章涉及物理参数。因此,本文旨在通过热建模研究不同物理参数对太阳能蒸馏器生产率的影响。理论结果与之前实验模型的结果进行了验证,两者显示出良好的一致性。结果表明,随着平板发射率或隔热层厚度的增加,日产量会显著提高。相反,水质量、玻璃吸收率或隔热导热率的增加会导致生产率大幅下降。值得注意的是,透水率和板吸收率不会影响生产率。降低水和玻璃之间的有效发射率可适度提高生产率。在水的质量较低时,水的初始温度对生产率的影响较小,而在水的质量较高时,水的初始温度对生产率的提高有很大影响。这些结果可以很好地指导设计人员和制造商开发更高效的设计,最大限度地提高净水产量。
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
ACS Applied Bio Materials
ACS Applied Bio Materials Chemistry-Chemistry (all)
CiteScore
9.40
自引率
2.10%
发文量
464
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