Performance of double-circulation water-flow window system as solar collector and indoor heating terminal Chunying LI 1
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Chunying Li1 2020
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7 Conclusions
Thermal, energy and economic performances of double- circulation water-flow window under the climate of Shenzhen are analyzed numerically in the current study. The energy savings from both solar energy utilization for water heating and indoor heat gain increment/reduction in heating/cooling seasons are taken into consideration. By subtracting the extra energy consumption caused by the pumps and heating device within the system, the annual electricity charge saving and the static payback period are predicted. The results show promising application potential of water- flow window in buildings with strong incident solar radiation and stable hot water demand. The main conclusions are: (1) The direct solar transmission is largely reduced with double-circulation water-flow window, compared with common curtain wall. The comprehensive solar transmissivity is reduced from 30.6% to 16.0% during cooling season. (2) Solar energy can be absorbed by the flowing water and contributes to energy saving of water heating device. The thermal collection efficiency is about 16.2% for the external water circulation (Cir1) and 4.3% for the internal water circulation (Cir2). (3) With the assumption of extra investment of 1500 CNY for this 9 m 2 of water-flow window compared with common curtain wall, the static payback period is predicted to be around 7 years. The payback period is influenced by the water temperature at the inlet of window cavity. In conclusion, the double-circulation water-flow window under investigation is able to reduce building energy con- sumption compared with common curtain wall. The related extra investment can be earned back with electricity charge saving. After around 7 years, the system can realize over 20 CNY/m 2 saving annually. Considering the continuous payback and convenient maintenance of the system, there is a great potential for its extensive application. In the present investigation, the lower supply water temperature at the inlet of window cavity promotes larger amount of electricity saving, which provides possibility of utilizing low-grade heat source in buildings, such as solar thermal collector and ground source heat pump (GSHP). Meanwhile, the indoor heat gain through the window can be regulated according to occupants’ demand by adjusting the inlet temperature and flow rate of water within the window cavity. Download 1.57 Mb. Do'stlaringiz bilan baham: 
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