Evaluation of Performance Factors for a Multistage Falling Particle Receiver

ASME 2020 14th International Conference on Energy Sustainability Pub Date : 2020-06-17 DOI:10.1115/es2020-1692

Reid Shaeffer, Brantley Mills, L. Yue, C. Ho

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引用次数: 4

Abstract

An important factor identified for the efficiency of falling particle concentrating solar applications is the falling particle curtain opacity. Low curtain opacity results in increased radiative losses. Candidate multi-stage configurations that can increase particle-curtain opacity were simulated for the existing 1 MWth falling particle on-sun receiver at Sandia’s NSTTF. In the candidate configurations, falling particles were collected periodically in sloped troughs spanning the width of the receiver. A small lip at the front of each trough causes particles to accumulate, allowing subsequent particles to spill over. Particle surface boundary conditions were represented with an empirically based model created to approximate particle behavior observed in testing. Curtain opacity increased using a multi-stage approach and decreases in radiative losses were outweighed by decreases in advective losses which were the dominant loss mechanism. The ability to alter the flow of air within the receiver using multi-stage release resulted in the greatest efficiency gains by reducing advective losses. Additionally, multi-stage release substantially decreased back wall temperatures within receiver.

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多级落粒接收器性能因素的评价

影响落粒聚光太阳能应用效率的一个重要因素是落粒幕不透明度。低帷幕不透明度导致辐射损失增加。对桑迪亚国家科学技术研究小组现有的1兆瓦太阳落粒子接收器进行了模拟，模拟了可增加粒子幕不透明度的候选多级配置。在候选配置中，落粒被周期性地收集在横跨接收器宽度的倾斜槽中。在每个槽的前面有一个小的唇导致颗粒堆积，允许随后的颗粒溢出。粒子表面边界条件用一个基于经验的模型来表示，以近似测试中观察到的粒子行为。使用多阶段方法，幕不透明度增加，辐射损失的减少被平流损失的减少所抵消，平流损失是主要的损失机制。利用多级释放改变接收器内空气流动的能力，通过减少平流损失，获得了最大的效率收益。此外，多级释放大大降低了接收器内的后壁温度。

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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ASME 2020 14th International Conference on Energy Sustainability

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