Optical and thermal performance of a novel solar particle receiver

SOLARPACES 2018: International Conference on Concentrating Solar Power and Chemical Energy Systems Pub Date : 2019-07-26 DOI:10.1063/1.5117577

Xiangyu Xie, G. Xiao, M. Ni, Jian-hua Yan, H. Dong, K. Cen

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引用次数: 4

Abstract

A novel particle receiver is proposed and tried to improve the flexibility of control, the reliability and the efficiency of the existing solar particle receivers. The novel particle receiver is mainly composed of an inclined plate where the particles flow due to gravity and absorb concentrating radiation directly meanwhile, and a pneumatic control system where the particle flow rate can be regulated by fluidization gas. The performance has been experimentally and numerically investigated preliminarily. The experimental results of cold tests show that the solid-gas ratio can reach up to ∼25 for different cross sections, indicating that the heat loss caused by fluidization gas is acceptable, usually less than 2%, and particle flow rate could be adjusted flexibly. The experimental results of hot test show that the outlet temperature of particle flow ranges from ∼709 K to ∼938 K and the average outlet temperature of particle flow is ∼807 K under the incident radiation power of ∼8 kw and the particle flow rat...

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一种新型太阳粒子接收器的光学和热性能

为了提高现有太阳能粒子接收器的控制灵活性、可靠性和效率，提出了一种新型的粒子接收器。该新型颗粒接收器主要由倾斜板和气流控制系统组成，倾斜板使颗粒在重力作用下流动，同时直接吸收集中辐射。对其性能进行了初步的实验和数值研究。冷试验结果表明，不同截面固气比可达~ 25，表明流化气体引起的热损失是可接受的，通常小于2%，颗粒流速可灵活调节。热测试实验结果表明，在入射辐射功率为~ 8 kw时，粒子流出口温度在~ 709 K ~ ~ 938 K之间，粒子流出口平均温度为~ 807 K，粒子流速率为~ 807 K。

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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SOLARPACES 2018: International Conference on Concentrating Solar Power and Chemical Energy Systems

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