Integration of Hybrid Porous Casting in Solar Receivers to Increase Solar Systems Efficiency

Sara Gören, F. Barbosa, Erany D. G. Constantino, H. Puga, J. Teixeira
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Abstract

Concentrated solar thermal (CST) technologies have been considered a promising solution to achieve carbon neutrality by 2050. However, to make CST systems attractive to the international energy sector, their efficiency must be enhanced and low-cost manufacturing processes should be used. In this context, an innovative solar receiver for parabolic-dish solar concentrators is developed in this work, focusing on the improvement of the absorption capacity and heat transfer to the thermal fluid. To enhance solar radiation absorption, a pyramid-shaped texture surface is constructed. In addition, the multiple jet impingement process combined with porous media is applied to ensure high heat transfer rates to the thermal fluid. To evaluate the system efficiency, an experimental setup is developed using a parabolic reflector with a solar tracking system and the flow dynamics of multiple jets impinging on the porous surface is analyzed using Particle Image Velocimetry (PIV). The results show that the tested absorber surface increases the solar absorption efficiency by 6.5 %, compared to the smooth surface. Furthermore, the jet’s flow dynamics and heat transfer analysis shows that the porous surface combined with the air jets increases the heat transfer rate, obtaining optimal values for jets velocities ranging between 5 and 10 ms−1.
混合多孔铸造在太阳能接收器中的集成以提高太阳能系统效率
聚光太阳能热(CST)技术被认为是到2050年实现碳中和的一个有前途的解决方案。但是,为了使CST系统对国际能源部门具有吸引力,必须提高其效率,并应使用低成本的制造工艺。在此背景下,本文开发了一种创新的抛物面式太阳能聚光器太阳能接收器,重点是提高吸收量和对热流体的传热。为了增强太阳辐射的吸收,构造了一个金字塔形的纹理表面。此外,采用多射流冲击工艺与多孔介质相结合,保证了对热流体的高传热率。为了评估系统的效率,建立了带有太阳跟踪系统的抛物面反射器实验装置,并利用粒子图像测速(PIV)分析了多束射流撞击多孔表面的流动动力学。结果表明,与光滑表面相比,该表面的太阳能吸收效率提高了6.5%。此外,射流的流动动力学和传热分析表明,多孔表面与空气射流的结合增加了传热速率,在5 ~ 10 ms−1的射流速度范围内获得了最佳值。
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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