Performance of double-circulation water-flow window system as solar collector and indoor heating terminal Chunying LI 1
part can be calculated with convective/radiation heat transfer
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Chunying Li1 2020
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part can be calculated with convective/radiation heat transfer coefficient and temperature difference between the inner glass pane (g6 in Fig. 2) and indoor air. 5 Results and discussions Thermal performance and energy saving potential of double-circulation water-flow window systems (Cases 2–4) are analyzed and compared with common double-pane curtain wall (Case 1). Indoor heat gain through the window, solar thermal collection and system thermal efficiency are evaluated. 5.1 Indoor heat gain through the window The proposed double-circulation water-flow window regulates indoor thermal environment by adjusting the indoor heat gain through the window. As mentioned above, the comprehensive indoor heat gain through the window is composed of direct solar transmission and convective/ radiative heat gains. Year-round thermal performance of the 4 comparative cases is shown in Figs. 4 and 5. Thermal performance of the advanced water-flow window during heating season is presented in Fig. 4. The accumulated incident solar radiation intensity on the south- facing vertical curtain wall during heating season is 365.9 kWh/m 2 , and 125.7 kWh/m 2 is transmitted inward to indoor space directly in Case 1. The overall transmissivity is 34.4%. Whereas the direct solar transmission is only 72.5 kWh/m 2 for water-flow window (Cases 2–4), which is 42.3% lower compared with Case 1. This is caused by thermal insulation of the additional glass panes and the thermal extraction of the flowing water layers. The inlet water temperate is preset to be 34 °C, 37 °C and 40 °C in Cases 2, 3 and 4, so there is heat release from water stream to indoor air through the internal glass pane. Considering this part of heat transfer, the comprehensive indoor heat Download 1.57 Mb. Do'stlaringiz bilan baham: 
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