适用于下一代太阳能热发电的集热颗粒磨损特性研究  

作　　者：陈冬 吕洪坤 丁历威 来振亚 肖刚 祝培旺[1,2,3] Chen Dong;Lyu Hongkun;Ding Liwei;Lai Zhenya;Xiao Gang;Zhu Peiwang(State Key Laboratory of Clean Energy Utilization,Hangzhou 310027,China;Jiaxing Research Institute of Zhejiang University,Jiaxing 314031,China;Qingshanhu Energy Research Center Zhejiang University,Hangzhou 311300,China;State Grid Zhejiang Electric Power Corporation Research Institute,Hangzhou 310014,China)

机构地区：[1]能源高效清洁利用全国重点实验室,杭州310027 [2]浙江大学嘉兴研究院,嘉兴314031 [3]浙江大学青山湖能源研究基地,杭州311300 [4]国网浙江省电力有限公司电力科学研究院,杭州310014

出　　处：《太阳能学报》2024年第8期432-440,共9页Acta Energiae Solaris Sinica

基　　金：国网浙江省电力有限公司科技项目资助(B311DS230006)。

摘　　要：以铝矾土惰性颗粒为研究对象,使用三腔磨损试验台获取颗粒耐磨性能和粒径分布变化规律,颗粒120 h磨损率约2.5%,粒径分布演变模型中转化比例符合正态分布(σ=1/2,d_(s)=4d)时模拟效果最好。提出磨损转换系数,通过引入磨损耗散能量作为中间量,将磨损测试设备中获取的颗粒磨损特性推广到实际太阳能热发电系统中。以100 kW太阳能热发电系统为例,计算得铝矾土惰性颗粒在系统各设备间循环一次的磨损相当于在三腔磨损试验台中运行0.0114 h,从而获得系统补料策略。Solid particles have emerged as a promising new heat transfer and storage medium for solar thermal power generation,offering the potential to improve efficiency.Using bauxite inert particles as the research object,a three-chamber attrition test rig was used to obtain the particle attrition resistance and particle size distribution variation rules.The particles experienced a mass loss of approximately 2.5%after 120 hours,and the most effective simulation was achieved when the mass exchange ratio in the particle size distribution evolution model was in accordance with a normal distribution(σ=1/2,d_(s)=4d).To extend these findings to the solar thermal power system,an attrition conversion coefficient was proposed using attrition dissipation energy as an intermediate quantity.Using a 100 kWe system as an example,it’s calculated that one cycle of bauxite inert particles between the system devices is equivalent to 0.0114 hours of operation in a three-chamber attrition test rig.These findings offer valuable insights for the calculation of long-term system economics and the development of operating strategies.

关 键 词：太阳能热发电系统 磨损特性 热化学颗粒 粒径分布 惰性颗粒 运行策略 

分 类 号：TM615[电气工程—电力系统及自动化] TK512[动力工程及工程热物理—热能工程]