Research on Couple Simulation Method on Effects of Thermal and Wind Environment of Vertical Climbing Green Facades
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摘要: 基于垂直攀援绿化在高密度城市的应用与发展,测试其对于湿热地区半户外空间的热环境与热舒适调节作用。首先对湿热地区的攀援绿化案例进行了夏季典型高温日实测,然后结合计算流体动力学(CFD)工具进行模拟校验。进而,耦合CFD与Ladybug + Honeybee工具对典型架空过渡空间与攀援绿化的组合工况进行了热环境与热舒适模拟测试。得出:1) 实测显示攀援绿化测点比无绿化测点平均温度降低0.06~0.53 ℃,黑球温度降低0.37~1.73 ℃,风速降低0~0.18 m/s,平均辐射温度(MRT)降低0.58~2.74 ℃,生理等效温度(PET)降低0.27~1.43 ℃;2) 架空层CFD模拟结果显示,除了FG-1模型,其他各模型温度均稍有降低,降低幅度约为0.1~0.3 ℃;3) FG-2、FG-3模型风速降幅约为1.3 m/s,DG系列模型风速降幅约为0.8 m/s;4) 耦合模拟结果显示,FG-2、FG-3、DG与WG系列模型的PET值降幅约为0.8~1.1 ℃,进而,FG-2、FG-3、DG系列对空间整体生理等效温度调节较好,为较优的布局选项。Abstract: Based on the application and development of vertical climbing green facde in high-density cities, the vertical climbing green facades on thermal and wind environment in hot-humid climate areas. Firstly, field measurements were conducted to record the thermal indices around a case of climbing green facade in typical extreme hot summer days in hot-humid climate areas. Secondly, a validation was conducted with a CFD simulation method with the software. Then, the combination condition of typical overhead transition space and climbing green facade was simulated and tested for human thermal comfort evaluation coupled with CFD and Ladybug+Honeybee tools. The results showed that: 1)field measurements results revealed that the temperature, globe temperature (Tg), and wind velocity (Va) of the shaded area was reduced by 0.06-0.53 ℃, 0.37-1.73 ℃, and 0-0.18 m/s compared to the unshaded area, relpectively. The mean radiant temperature(MRT) and physiological equivalent temperature(PET) were reduced by 0.58-2.74 ℃ and 0.27-1.43 ℃, respectively; 2)CFD simulation results revealed different greening models reduced the average temperature by 0.1-0.3 ℃ except the model FG-1; 3) the wind velocity of model FG-2 and FG-3 reduced by about 1.3 m/s, the wind velocity of DG model series reduced by about 0.8 m/s; 4) the PET of FG-2, FG-3, DG series and WG series models reduced by about 0.8-1.1 ℃. Furthermore, FG-2, FG-3 and DG series model presented better optimizations on the whole open floor space and could be the better choice for the greenery layout.
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Key words:
- vertical climbing green faç /
- ade /
- thermal and wind environment /
- CFD /
- couple simulation method
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