Improving Next-Generation Falling Particle Receiver Designs Subject to Anticipated Operating Conditions

Brantley Mills, Reid Shaeffer, L. Yue, C. Ho
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引用次数: 3

Abstract

The thermal performance of a candidate next-generation falling particle receiver (FPR) is analyzed subject to various expected operating conditions. This receiver design was created from the result of an extensive optimization study and developed to support the Generation 3 Particle Pilot Plant (G3P3) project. Previous analysis demonstrated high thermal efficiencies for the receiver at nominal quiescent conditions, but further analysis was required to demonstrate that the receiver could maintain that thermal performance in a wide range of anticipated environments. In this study, the thermal efficiency was numerically evaluated using a CFD model for different wind conditions and shown to maintain a thermal efficiency above 83% for considered wind conditions. Moreover, the effect of radiative spillage from the incoming concentrated solar beam on the receiver exterior was investigated using ray tracing and CFD models. The exterior wall material temperature limits were not exceeded for the anticipated design power from the heliostats. Additional features were numerically explored including the addition of a chimney to capture particle fines and waste heat and a multi-stage concept to maximize curtain opacity. Particle fines of 10 μm were shown to preferentially flow into this chimney rather than out of the aperture, and the multi-stage design decreased radiative losses and minimized wall temperatures behind the particle curtain.
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根据预期操作条件改进下一代落粒子接收器设计
分析了新一代候选落粒子接收器(FPR)在不同工作条件下的热性能。该接收器设计基于广泛的优化研究结果,并为支持第三代颗粒中试工厂(G3P3)项目而开发。先前的分析表明,该接收器在额定静态条件下具有较高的热效率,但需要进一步的分析来证明,该接收器可以在广泛的预期环境中保持这种热效率。在本研究中,使用CFD模型对不同风况下的热效率进行了数值评估,结果表明在考虑的风况下热效率保持在83%以上。此外,利用射线追踪和CFD模型研究了入射集中太阳光束的辐射溢出对接收器外部的影响。外墙材料的温度限制没有超过定日镜的预期设计功率。在数值上探索了其他功能,包括增加一个烟囱来捕获颗粒和废热,以及一个多阶段的概念来最大化窗帘的不透明度。结果表明,粒径为10 μm的细颗粒优先流入烟囱而非流出,多级设计降低了辐射损失,降低了颗粒幕后壁面温度。
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