海水淡化中多级太阳能斯蒂尔的配置、性能和前沿选择综述

Q2 Engineering Designs Pub Date : 2023-05-18 DOI:10.3390/designs7030067
F. Rashid, Amr Kaood, M. Al‐Obaidi, H. Mohammed, Alanood A. Alsarayreh, N. AL-MUHSEN, A. Abbas, Rana H. A. Zubo, A. Mohammad, S. Alsadaie, M. T. Sowgath, Raed Abd-Alhameed, I. Mujtaba
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引用次数: 2

摘要

海水淡化是生产淡水的可行选择。所有的海水淡化过程都是能源密集型的,可以大规模进行。因此,考虑到当前的能源危机以及化石燃料能源对我们碳足迹的影响,使用可再生能源生产淡水是最理想的选择。在这方面,托盘式蒸馏器是几种太阳能脱盐蒸馏器中的一种,由于其简单的设计、经济的建筑材料和最低的维护要求而广受欢迎,尤其是在能源和天然水供应有限的孤岛地区。传统的托盘式太阳能有一些缺点,例如无法从冷凝中回收潜热,热对流减少,热容量大,以及通过蒸发的驱动功率相对最小。因此,提高板式蒸馏器的传热传质能力一直是许多研究的主题。然而,公开文献中缺乏全面的综述,涵盖多级太阳能蒸馏器的设计和操作细节。本文的目的是从配置、功能和尖端选择方面全面概述过去对多级太阳能蒸馏器的研究。与没有阻盐层的装置相比,综述表明,多级蒸馏装置可以在高辐射下连续运行,产生的纯水是没有阻盐地层的装置的1.7倍左右。最有效的设计是连接在四级蒸馏器上的“V”形太阳能蒸馏器托盘,因为它们比需要两个收集器的“地板”(∧形)设计更便宜、更经济。此外,可以说,当太阳能收集器增加26%(以恒定的水流速度)时,单位热效率、太阳能百分比和收集的太阳能(在一年中)分别增加23%、18%和24%。
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A Review of the Configurations, Capabilities, and Cutting-Edge Options for Multistage Solar Stills in Water Desalination
The desalination of saltwater is a viable option to produce freshwater. All the desalination processes are energy-intensive and can be carried out on a large scale. Therefore, producing freshwater using renewable energy sources is the most desirable option considering the current energy crisis and the effect that fossil-fuel-based energy has on our carbon footprint. In this respect, the tray-type still, one of several solar power desalination still varieties, is popular owing to its straightforward design, economic materials of construction, and minimal maintenance requirements, especially in isolated island regions with restricted energy and natural water supplies. The traditional tray-type solar power has a few drawbacks, such as the inability to recover latent heat from condensation, reduced thermal convection, a large heat capacity, and comparatively minimal driving power through evaporation. Therefore, the improvement of heat and mass transfer capabilities in tray-type stills has been the subject of many studies. However, there is a lack of a comprehensive review in the open literature that covers the design and operational details of multistage solar stills. The purpose of this paper is to present a thorough overview of the past research on multistage solar stills, in terms of configurations, capabilities, and cutting-edge options. In comparison to a unit without a salt-blocking formation, the review indicates that a multistage distillation unit may run continuously at high radiation and generate pure water that is around 1.7 times higher than a unit without a salt-blocking formation. The most effective deign is found to be “V”-shaped solar still trays that attach to four-stage stills, since they are less expensive and more economical than the “floor” (Λ-shape) design, which requires two collectors. Additionally, it can be stated that the unit thermal efficiency, solar percentage, and collected solar energy (over the course of a year) increase by 23%, 18%, and 24%, respectively, when the solar collectors are increased by 26% (at the constant inflow velocity of the water).
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来源期刊
Designs
Designs Engineering-Engineering (miscellaneous)
CiteScore
3.90
自引率
0.00%
发文量
0
审稿时长
11 weeks
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