Enhancing the Thermal Performance of a Central Tower Tubular Solar Receiver with Direct Steam Generation by Using Internal Fins and Thicknesses Variation

IF 2.8 4区工程技术 Q2 ENGINEERING, MECHANICAL

Journal of Heat Transfer-transactions of The Asme Pub Date : 2023-06-20 DOI:10.1115/1.4062785

V. M. Maytorena, J. Hinojosa, Saul F Moreno, Resty L. Duran

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Abstract

This study provides a comprehensive analysis of the thermal behavior of tubular solar receivers used for direct steam generation, focusing on the effects of different wall thicknesses and longitudinal rectangular fins on the internal surface. The study evaluated six tubes, including two tubes with distinct wall thicknesses (5mm and 3mm) without fins and four tubes with fins but varying configurations. These tubes represent external tubular receivers used in solar central tower plants and operate at 4.5 MPa with a non-uniform solar flux averaging 0.8 MW/m2. Adding longitudinal fins to the tubes significantly reduced the maximum temperature on the irradiated surface and improved heat transfer to the fluid. The study concluded that the 45F5 receiver, which has three fins on the internal section, outperforms the other receivers, presenting a higher vapor generation. Furthermore, the 45F5 geometry enhances heat transfer, allowing the lowest maximum Biot number. These results are crucial for designing tubular solar receivers with direct steam generation systems and improving their efficiency in generating energy from renewable sources.

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利用内翅片和厚度变化提高中央塔管式直接产汽太阳能接收器的热性能

本文全面分析了用于直接蒸汽产生的管式太阳能接收器的热行为，重点研究了不同壁厚和内表面纵向矩形翅片的影响。该研究评估了六根管子，包括两根没有鳍的不同壁厚(5mm和3mm)的管子和四根有鳍但结构不同的管子。这些管代表在太阳能中心塔式电站中使用的外部管状接收器，工作在4.5 MPa下，平均0.8 MW/m2的非均匀太阳通量。在管道上添加纵翅片可以显著降低辐照表面的最高温度，并改善流体的传热。该研究得出结论，45F5接收器的内部部分有三个鳍，表现出更高的蒸汽产生，优于其他接收器。此外，45F5的几何形状增强了传热，允许最低的最大Biot数。这些结果对于设计具有直接蒸汽产生系统的管式太阳能接收器以及提高其从可再生能源中产生能量的效率至关重要。

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

Journal of Heat Transfer-transactions of The Asme 工程技术-工程：机械

自引率

0.00%

发文量

182

审稿时长

4.7 months

期刊介绍： Topical areas including, but not limited to: Biological heat and mass transfer; Combustion and reactive flows; Conduction; Electronic and photonic cooling; Evaporation, boiling, and condensation; Experimental techniques; Forced convection; Heat exchanger fundamentals; Heat transfer enhancement; Combined heat and mass transfer; Heat transfer in manufacturing; Jets, wakes, and impingement cooling; Melting and solidification; Microscale and nanoscale heat and mass transfer; Natural and mixed convection; Porous media; Radiative heat transfer; Thermal systems; Two-phase flow and heat transfer. Such topical areas may be seen in: Aerospace; The environment; Gas turbines; Biotechnology; Electronic and photonic processes and equipment; Energy systems, Fire and combustion, heat pipes, manufacturing and materials processing, low temperature and arctic region heat transfer; Refrigeration and air conditioning; Homeland security systems; Multi-phase processes; Microscale and nanoscale devices and processes.