Evaluation of Concentrated Solar Power Systems and the Impact of Different Heat Transfer Fluids on Performance

Q3 Engineering WSEAS Transactions on Fluid Mechanics Pub Date : 2023-10-16 DOI:10.37394/232013.2023.18.10

Mohamed R. Gomaa, Read Ahmad, M. A. Nawafleh

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Abstract

Concentrated solar power (CSP) is one of the main technologies used. Thus, the object of research is the different concentrated solar power technologies. Moreover, this study aimed to compare the different concentrated solar power technologies in terms of their efficiency, cost, concentration ratio, and receiver temperature. Results showed that technologies were arranged according to high to low temperatures: the parabolic dish reflector, central receiver collector, linear Fresnel reflector, and parabolic trough collector. As well as, in this study, ranges of the heat transfer fluids are compared with each other by using exergy and energy analysis. The heat transfer fluids that are examined are liquid sodium, molten salt (60 % NaNO3, 40 % KNO3), supercritical carbon dioxide (sCO2), water/steam, and air. Results showed that the liquid sodium at an elevated temperature range of (540–740 °C) is performed the best, with exergy efficiency of 61% of solar-to-fluid, the best liquid sodium case is at (do=10.3 mm, nbanks = 1, Δprec= 7.72 bar, ηΠ = 45.47 %) has been found. Finally, vas a positive and effective approach to solving the energy problems.

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聚光太阳能发电系统的评价及不同传热流体对性能的影响

聚光太阳能(CSP)是目前使用的主要技术之一。因此，研究的对象是不同的聚光太阳能发电技术。此外，本研究旨在比较不同的聚光太阳能发电技术在效率、成本、聚光比和接收器温度方面的差异。结果表明:从高到低的温度顺序排列为:抛物面碟形反射器、中央接收集热器、线性菲涅耳反射器、抛物面槽形集热器。此外，本文还采用火用和能量分析的方法，对不同换热流体的传热范围进行了比较。所检测的传热流体为液态钠、熔融盐(60% NaNO3、40% KNO3)、超临界二氧化碳(sCO2)、水/蒸汽和空气。结果表明，液钠在(540 ~ 740℃)高温范围内表现最佳，日流效率为61%，最佳液钠情况为(do=10.3 mm, nbanks =1， Δprec= 7.72 bar， ηΠ = 45.47%)。最后，提出了积极有效的解决能源问题的途径。

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WSEAS Transactions on Fluid Mechanics Engineering-Computational Mechanics

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1.50

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0.00%

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期刊介绍： WSEAS Transactions on Fluid Mechanics publishes original research papers relating to the studying of fluids. We aim to bring important work to a wide international audience and therefore only publish papers of exceptional scientific value that advance our understanding of this particular area. The research presented must transcend the limits of case studies, while both experimental and theoretical studies are accepted. It is a multi-disciplinary journal and therefore its content mirrors the diverse interests and approaches of scholars involved with multiphase flow, boundary layer flow, material properties, wave modelling and related areas. We also welcome scholarly contributions from officials with government agencies, international agencies, and non-governmental organizations.