Performance of double-circulation water-flow window system as solar collector and indoor heating terminal Chunying LI 1
Download 1.57 Mb. Pdf ko'rish
|
Chunying Li1 2020
|
4 Numerical model development
The incident solar irradiation provides important heating source during winter and brings about cooling load during summer. In the present study, the incident solar irradiation on water-flow window (G total ) is divided into 14 parts, including the reflected and the transmitted parts, the absorbed parts by the glass panes, as well as the absorbed and delivered parts by the flowing water stream, as in Eq. (1). Total ref trans 1 2 3 4 5 6 7 8 9 10 11 12 G G G Q Q Q Q Q Q Q Q Q Q Q Q = + + + + + + + + + + + + + (1) where, G Total , the total incident solar radiation (W); G ref = γ·G T , the reflected solar radiation at outside surface of glass pane g1 (W); G trans = τ·G T , the solar radiation transmitted through the window to indoor (W); Q 1 = h c,1a · A·(T g1 − T a ), the convective heat flow from outside surface of glass pane g1 back to ambient environ- ment (W); Q 2 = h c,6rm · A·(T g6 − T rm ), the convective heat flow from indoor surface of glass pane g6 to room space (W); Q 3 = h r,1a · A·(T g1 − T a ), the radiation heat flow from outdoor surface of glass pane g1 to environment that includes the sky and surrounding solid surfaces (W); Q 4 = h r,6rm · A·(T g6 − T rm ), the radiation heat flow from indoor surface of glass pane g6 to room surfaces (W); g 1 g 1 g 1 g 1 T Q ρ D C A t 5 ¶ = ¶ , the rate of heat storage within glass pane g1 (W); g 3 g 3 g 3 g 3 T Q ρ D C A t 6 ¶ = ¶ , the rate of heat storage within glass pane g3 (W); g 4 g 4 g 4 g 4 T Q ρ D C A t 7 ¶ = ¶ , the rate of heat storage within glass pane g4 (W); g 6 g 6 g 6 g 6 T Q ρ D C A t 8 ¶ = ¶ , the rate of heat storage within the glass pane g6 (W); f 2 f 2 f 2 f 2 T Q ρ D C A t 9 ¶ = ¶ , the rate of heat storage within the water volume of external window cavity f2 (W); f f f f T Q ρ D C A t 5 10 5 5 5 ¶ = ¶ , the rate of heat storage within the water volume of internal window cavity f5 (W), ( ) f 2 f 2 f 2 f 2 Q m C T T 11 ,out ,in = - , the rate of heat extraction by the flowing water within external window cavity f2 (W), ( ) f 5 f 5 f 5 f 5 Q m C T T 12 ,out ,in = - , the rate of heat extraction by the flowing water within internal window cavity f5 (W). The simulation code was developed with FORTRAN and finite difference approach based on simplified unidirectional steady-state model. A previously validated program (single- circulation water-flow window system) was modified accordingly. The simulation results coincide well with the results from experiments, with both scale-down cell and full-scale air-conditional room (Li 2012). In the present simulation model, the double-circulation water-flow window system was taken as 2 superimposed single-circulation water-flow window systems. In the previous investigations, the code of the single-circulation configuration was validated with different glazing properties and weather conditions. This means that the decomposition of incident solar radiation, the calculation of heat transfer through the window components, as well as the heat absorption process of the flowing liquid within window cavities are modeled correctly. Thus, the models and the program in use are accurate enough to predict the performance of water-flow window. At every time step, the program read in weather data Li et al. / Building Simulation / Vol. 13, No. 3 580 and inlet water temperature of both circulations, and processed the heat/mass flow calculation. The temperatures of glass panes and flowing water were calculated by solving the heat balance equations. Afterwards, the system solar thermal collection could be calculated with water flow rate and its temperature rise in the window cavity. Whereas the system thermal efficiency is calculated as solar thermal collection divided by the simultaneous incident solar radiation. Meanwhile, the comprehensive indoor heat gain through the window is composed of two parts: the directly transmitted solar thermal energy, and the heat release from the inner glass pane (g6 in Fig. 2) through convective and radiation heat transfer. The first part, i.e. G trans can be calculated with total incident solar energy and the com- prehensive solar transmissivity of the window. The second Download 1.57 Mb. Do'stlaringiz bilan baham: 
|