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Journal:Journal of Cleaner Production
Key Words:High concentrating photovoltaics Dynamic building integrated design Photoelectric performance test Optical and thermal performance Airflow cooling
Abstract:Concentrating solar technology is one of the advanced solar energy utilization approaches. A high magnification (500X) solar concentrating module suitable for dynamic building integration was designed. Light concentrated efficiency of the module was about 65% according to tests. The simulation results showed the efficiency of the module was 78.68% under unbiased incident condition. The maximum temperature of the solar cell could reach 78.49 ◦C without active airflow cooling. Results showed that the temperature of solar cell and module decreased significantly with the increase of the airflow velocity within 3 m s − 1. Comparative study results showed different airflow directions had different effects on the heat dissipation efficiency of different components of the module. Airflow entered from bottom of the module was superior to top and side for solar cell heat dissipation efficiency. Comprehensive consideration, the recommended cooling method for the module was airflow entered from bottom at a speed of 3 m s − 1 .
Indexed by:Journal paper
Translation or Not:no
Included Journals:SCI
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孙良,男,汉族,山东滕州人,教授,博导,国家一级注册建筑师,同济大学建筑设计及其理论博士。现任中国矿业大学可持续设计研究院执行院长,建筑与设计学院教授、博士生导师,徐州市泉山区政协副主席(不驻会)。兼任中国建筑学会地下空间专业委员会常务委员、中国建筑学会计算性设计专业委员会委员、中国建筑学会环境行为专业委员会委员、高层建筑人居环境专业委员会委员,江苏省土木建筑学会建筑创作委员会委员。
主要研究领域:城市更新与建筑改造、环境行为与空间设计等。主持或参与国家自然科技基金项目、国家重点研发计划项目、建设部科技项目等多项。主持建筑设计、城市设计、旧建筑改造、地下空间设计项目等30余项,作品多次获得各级各类奖励。发表高水平科研和教学论文50余篇,主编及参编专著和教材4部、授权国内国际发明专利5项。先后获校教学成果特等奖、一等奖,煤炭行业教学成果一等奖等。指导学生参加高水平设计竞赛、学科竞赛获奖30余项。