Optimizing the performance of solar evacuated tube collector systems for seawater desalination

IF 2.1 4区 环境科学与生态学 Q3 ENGINEERING, CHEMICAL Environmental Progress & Sustainable Energy Pub Date : 2024-09-05 DOI:10.1002/ep.14467
Nitesh Patel, Unnati Joshi, Vijay Patel, Anand Joshi, Ankit D. Oza, Abhinav Kumar, Vladimir Ivanovich Velkin
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Abstract

Solar thermal collectors, such as evacuated tube collectors (ETCs), are essential for harnessing renewable energy, yet their efficiency is often hindered by thermal losses and limited heat transfer. This study focuses on enhancing ETC performance for seawater desalination by using nanofluids as heat transfer fluids. These modifications aim to improve heat transfer rates, reduce thermal losses, increase the maximum temperature attainable, and minimize the collector area required. An experimental setup has been developed at Parul University in Vadodara, Gujarat, India. Key parameters such as air mass flow rate, inclination angle, water mass flow rate, nanofluid volume percentage, and screw conveyor speed were optimized to achieve ideal temperature levels. Results indicate that the optimal configuration for steam generation includes a high air mass flow rate and a 40° inclination angle for the ETC. Additionally, a water mass flow rate of 10 LPH and a screw conveyor speed of 30 rpm are crucial for optimal performance. Data collected showed the highest solar energy levels between 12 PM and 1 PM, which significant decreases post this peak period. These findings highlight the potential of nanomaterial-based enhancements in improving the efficiency and cost-effectiveness of solar thermal systems for renewable energy applications.

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优化用于海水淡化的太阳能真空管集热器系统的性能
真空管集热器(ETC)等太阳能集热器对利用可再生能源至关重要,但其效率往往受到热损失和有限传热的阻碍。本研究的重点是通过使用纳米流体作为传热液体,提高 ETC 在海水淡化方面的性能。这些改进旨在提高传热率,减少热损失,提高可达到的最高温度,并最大限度地减少所需的集热器面积。在印度古吉拉特邦瓦多达拉的帕鲁尔大学开发了一套实验装置。对空气质量流量、倾斜角度、水质量流量、纳米流体体积百分比和螺旋输送机速度等关键参数进行了优化,以达到理想的温度水平。结果表明,产生蒸汽的最佳配置包括高空气质量流量和 40° 的 ETC 倾斜角。此外,10 LPH 的水流量和 30 rpm 的螺旋输送机速度也是实现最佳性能的关键。收集到的数据显示,中午 12 点到下午 1 点之间的太阳能水平最高,高峰期过后太阳能水平显著下降。这些发现凸显了纳米材料在提高可再生能源应用中太阳能热系统的效率和成本效益方面的潜力。
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来源期刊
Environmental Progress & Sustainable Energy
Environmental Progress & Sustainable Energy 环境科学-工程:化工
CiteScore
5.00
自引率
3.60%
发文量
231
审稿时长
4.3 months
期刊介绍: Environmental Progress , a quarterly publication of the American Institute of Chemical Engineers, reports on critical issues like remediation and treatment of solid or aqueous wastes, air pollution, sustainability, and sustainable energy. Each issue helps chemical engineers (and those in related fields) stay on top of technological advances in all areas associated with the environment through feature articles, updates, book and software reviews, and editorials.
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