Performance of double-circulation water-flow window system as solar collector and indoor heating terminal Chunying LI 1
Fig. 4 Indoor heat gain through the window during heating season (per 1 m 2 window) Fig. 5
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Chunying Li1 2020
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Fig. 4
Indoor heat gain through the window during heating season (per 1 m 2 window) Fig. 5 Indoor heat gain through window during cooling season (per 1 m 2 window) gains through the window are as high as 161.6 kWh, 176.5 kWh and 191.4 kWh for Cases 2, 3 and 4, higher than the 141.7 kWh of Case 1. The increment percentages are Li et al. / Building Simulation / Vol. 13, No. 3 581 14.0%, 24.6% and 35.1% respectively compared with Case 1. This means the water-flow window can provide room heating and partly replace the conventional air-conditioning terminals during heating season. As for the cooling season, the inlet water temperatures in both window cavities (f2 and f5) are preset at the same temperature of ambient, i.e. to use municipal water as cooling source to bring heat away from the room. Also, solar thermal energy is absorbed by the flowing water and exploited for water pre-heating. This energy transportation help to reduce indoor heat gain and achieve energy saving of Air-conditioning system. The monthly indoor heat gain from direct solar transmission and comprehensive indoor heat gain from window from May to October are shown in Fig. 5. The cooling season is long and hot in Shenzhen, lasting from May to October every year. The accumulated incident solar radiation on every 1 m 2 of curtain wall during the 6 months is 493.8 kWh, of which 150.9 kWh is transmitted into indoor environment directly in Case 1. The equivalent comprehensive transmissivity is 30.6%, which is slightly lower compared with heating season, mainly due to the larger solar elevation angle in summer. For double-circulation water-flow window, the direct solar transmission is 78.7 kWh for Cases 2–4, which is 47.9% lower compared with Case 1. The comprehensive indoor heat gain from window is 158.8 kWh for Cases 2, 3 and 4, which is 18.5% lower compared to the 194.9 kWh room heat gain in Case 1. The decrease in room heat gain means the cooling load of air-conditioning can be reduced by large scale, which is favorable for energy conversation. 5.2 Solar collection rate and system efficiency A predominant advantage of water-flow window is the absorption and utilization of renewable solar energy. As in Fig. 2, the flowing water in Cir1 keeps absorbing solar thermal energy during daytime throughout the year. As for the flowing water in Cir2, the solar energy is utilized from March to November, i.e. the months without room heating demand. The amount of monthly solar collection and the variation of system efficiency are given in Fig. 6 and Table 3. Download 1.57 Mb. Do'stlaringiz bilan baham: 
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