适用于家用热泵热水器的PV-T太阳能集热器的节能运行

A. James, S. Jayaraj, M. Srinivas, M. Mohanraj
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引用次数: 0

摘要

设计并研制了一种光伏-热(PV-T)混合集热器蒸发器,利用在蒸发器管中循环的制冷剂同时从面板中产生电能和提取热能。制冷剂在从液体到蒸汽的相变过程中吸收光伏板的热量。PV-T蒸发器提供电力和热量输出。研制了一套以R-32制冷剂为基础的太阳能辅助热泵热水系统,其额定输出热量为4千瓦,并测试了其在平均温度为60℃时产生150-200升热水的性能。选择R-32制冷剂是因为它没有任何臭氧消耗潜能值(ODP),并且具有非常低的全球变暖潜能值(GWP)。热泵蒸发器设计用于从面板吸收3.25 kW的热量,并保持面板在30℃以下。平均光伏发电量为6千瓦时,需求为3.5千瓦时。系统平均向电网提供多余功率2.5 kWh,系统平均性能系数(COP)为6.3。在25年的使用寿命中,总等效变暖影响分析(TEWI)产生的CO2值为15,543 kg,远远低于传统系统。进行了经济分析,发现该系统非常适合国内应用,经济上可行,投资回收期为2.5年。关键词:太阳能光伏集热器,变频压缩机,生活热水。
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Energy-Efficient Operation of PV-T Solar Collectors with Heat Pump based Water Heaters Suitable for Domestic Applications
A photovoltaic-thermal (PV-T) hybrid collector evaporator was designed and developed to produce electrical energy and extract thermal energy simultaneously from the panel using the refrigerant circulated the evaporator tubes. The refrigerant absorbs the heat from photovoltaic panels during its phase change from liquid to vapour. The PV-T evaporators deliver both electricity and heat outputs. An R-32 refrigerant-based solar-assisted heat pump water heating system with a rated heat output of  4 kW was developed and tested its performance for producing 150-200 litres of hot water at an average temperature of 60oC. The R-32 refrigerant is selected because it does not have any ozone depletion potential (ODP), and possess very low global warming potential (GWP). The heat pump evaporator was designed to absorb 3.25 kW heat from the panel and maintains the panel below 30oC. The average PV electricity output was 6 kWh, and the requirement was 3.5 kWh. The average excess power of 2.5 kWh has been supplied to the grid, and the average coefficient of performance (COP) of the system was 6.3. For a life span of 25 years, the total equivalent warming impact analysis (TEWI) resulted in a CO2 value of 15,543 kg, which is very much lower than that of conventional systems. The economic analysis performed was reported, and the system is found to be quite suitable for domestic applications and also economically feasible with a payback period of 2.5 years. Keywords: Solar PV-T Collectors, VFD Compressor, Domestic Water Heating.
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