Electrodynamic removal of dust from solar mirrors and its applications in concentrated solar power (CSP) plants

2014 IEEE Industry Application Society Annual Meeting Pub Date : 2014-12-08 DOI:10.1109/IAS.2014.6978347

M. Mazumder, M. Horenstein, J. Stark, John N. Hudelson, A. Sayyah, C. Heiling, J. Yellowhair

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引用次数: 28

Abstract

Concentrating Solar Power (CSP) systems based on parabolic trough and power tower technologies provide inherent advantage of energy storage and high efficiency for utility-scale solar plants. The specular reflectance efficiency of the solar mirrors plays a critical role in the efficiency of electric power generation. The deposition of atmospheric dust on the surface of the mirrors reduces its reflectance efficiency and requires frequent cleaning to avoid energy-yield loss. Electrodynamic screen (EDS) can provide an efficient method for maintaining the specular reflectivity above 90% by removing the deposited dust particles. In this paper, we briefly review (1) electrostatic charging mechanisms involved in EDS, (2) optimization of EDS for high dust removal efficiency, and (3) minimization of cleaning cost and water consumption. Prototype EDS-integrated solar mirrors were produced and tested in an environmental test chambers simulating desert atmospheres. The test results show that frequent removal of dust layer can maintain the specular reflectivity of the mirrors above 90% subjected to dust deposition ranging from 0 to 10 g/m2.

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太阳能镜面电动力除尘技术及其在聚光太阳能电站中的应用

基于抛物线槽和塔式发电技术的聚光太阳能发电(CSP)系统为公用事业规模的太阳能发电厂提供了能量存储和高效率的固有优势。太阳能反射镜的镜面反射效率对发电效率起着至关重要的作用。大气尘埃在反射镜表面的沉积降低了反射效率，需要经常清洗以避免能量损失。电动力屏(EDS)通过去除沉积的粉尘颗粒，使镜面反射率保持在90%以上，是一种有效的方法。本文将从以下几个方面进行综述:(1)能谱仪的静电充电机制;(2)高效除尘能谱仪的优化;(3)清洁成本和用水量的最小化。制作了原型eds集成太阳镜，并在模拟沙漠大气的环境测试室中进行了测试。试验结果表明，在0 ~ 10 g/m2的粉尘沉降范围内，频繁去除粉尘层可使反射镜的镜面反射率保持在90%以上。

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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2014 IEEE Industry Application Society Annual Meeting

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