Design and experimental investigation of a phase change energy storage air-type solar heat pump heating system

•An air-type solar collector with phase change material was developed.•A heating system was designed by combining this solar collector and heat pump.•Solar energy utilization and operating stability are significantly improved.•All-weather efficient heating can be realized through cascade utilization...

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Bibliographic Details
Published in:Applied thermal engineering 2020-10, Vol.179, p.115506, Article 115506
Main Authors: Li, Master Yalun, Li, Baoguo, Liu, Caiyun, Su, Shuqiang, Xiao, Honghai, Zhu, Chuanhui
Format: Article
Language:English
Subjects:
Ambient temperature
Control systems design
Economic analysis
Energy storage
Energy utilization
Exergy
Exergy efficiency
Heat pump
Heat pumps
Heat transfer
Heating
Heating stability
Heating systems
Phase change energy storage
Phase change materials
Photovoltaic cells
Pumps
Solar energy
Solar heating
Solar radiation
Thermodynamic efficiency
Weather
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Summary:•An air-type solar collector with phase change material was developed.•A heating system was designed by combining this solar collector and heat pump.•Solar energy utilization and operating stability are significantly improved.•All-weather efficient heating can be realized through cascade utilization of thermal energy.•The system is a feasible alternative technology solution winter heating in Northern China. To improve solar energy utilization and the stability of solar heating systems, an energy storage air-type solar collector was designed and developed. Phase change material was placed in the middle of the solar vacuum tube to reduce the impact of solar radiation fluctuations on indoor heating. Based on this, a new type of solar heat pump heating system was established, with three heating modes: solar heating, solar-assisted heat pump heating, and heat pump heating. The control system was designed to automatically switch the operational mode when environmental conditions change. The heating performance, exergy efficiency, and economic benefit of the system in engineering application were studied and analyzed for different weather conditions. The results of the investigation show that at an average solar radiation intensity of 613.4 W·m−2 and average ambient temperature of 12.5 °C, the system can provide continuous indoor heating for 9.5 h in the solar heating mode, with the solar collector operating at an average thermal efficiency of 44.8%. The energy stored in the phase change material energy storage core is still capable of running the heat pump efficiently for 3 h after solar heating ends. The exergy efficiency of the heat pump is significantly improved by an average value of 12.1%. Economic analysis shows that the system can adequately meet building heating demands, with an average coefficient of performance of 3.6. Compared with the electric boiler heating system, the proposed system can reduce annual operating costs by 72.8%, with a payback period of approximately five years in Northern China.
ISSN:1359-4311
1873-5606
DOI:10.1016/j.applthermaleng.2020.115506