反向环流喷射撞击(RCFJI)PV/T 集热器:热液和电液分析

IF 2.8 Q2 THERMODYNAMICS Heat Transfer Pub Date : 2024-07-15 DOI:10.1002/htj.23129
Muhammad Amir Aziat Bin Ishak, Adnan Ibrahim
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引用次数: 0

摘要

借助光伏热能(PV/T)系统,太阳能可用于发电和供热。虽然该系统具有多种优势,但也存在很大的局限性。该系统存在一个易受影响的制约因素,即光伏(PV)模块在太阳辐照下温度会升高。为提高其运行效率,有必要集成冷却系统。有人提出了一种称为反向环流喷射撞击(RCFJI)的新方法,作为提高光伏/集热器性能的一种手段。目前的工作旨在评估 RCFJI PV/T 集热器的热液压和电液压性能。实验在 500-900 W/m2 的辐照水平下进行。结果表明,在 0.14 kg/s 的条件下,热液压效率在 900 W/m2 时达到最大值 59.20%。相反,在 500 瓦/平方米、0.13 千克/秒的条件下,电液效率达到最高值 10.91%。结论是,流速越高,摩擦系数越小,压降越大。热液分析和电液分析强调了评估摩擦系数和压降以获得最佳性能的重要性。本研究提出了一种利用射流冲击的新型冷却方法,从而解决了研究不足的问题。此外,本研究还有助于了解 RCFJI PV/T 集热器的热液和电液性能。
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The reversed circular flow jet impingement (RCFJI) PV/T collector: Thermohydraulic and electrohydraulic analysis

Solar energy could be used to generate both electricity and heat with the aid of photovoltaic thermal (PV/T) systems. Although the systems have a variety of advantages, they nevertheless hold a significant constraint. The system suffers a susceptible constraint wherein the photovoltaic (PV) module experiences an increase in temperature due to exposure to solar irradiation. The integration of a cooling system is necessary to enhance its operational efficiency. A novel approach, known as the reversed circular flow jet impingement (RCFJI), was proposed as a means to improve the performance of a PV/T collector. The current work seeks to assess the thermohydraulic and electrohydraulic performance of the RCFJI PV/T collector. The experiment was conducted under an irradiance level of 500–900 W/m2. From the result obtained, the thermohydraulic efficiency reached its maximum value of 59.20% under 900 W/m2 at 0.14 kg/s. Conversely, the electrohydraulic efficiency attained the highest reading of 10.91% under 500 W/m2 at 0.13 kg/s. It was concluded that a higher flow rate reduces the friction coefficient while increasing the pressure drop. The thermohydraulic and electrohydraulic analyses emphasize the importance of assessing the friction coefficient and pressure drop to attain optimal performance. This study addresses the lack of research by presenting a new cooling approach that utilizes jet impingement. In addition, this study provides an understanding of the thermohydraulic and electrohydraulic performance of a RCFJI PV/T collector.

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来源期刊
Heat Transfer
Heat Transfer THERMODYNAMICS-
CiteScore
6.30
自引率
19.40%
发文量
342
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