Effects of vertical greenery systems on microclimate in urban blocks with different plan area indices: Scaled outdoor experiments

The thermal performance of vertical greenery systems (VGSs) in indoor/outdoor environments has been extensively studied; nevertheless, spatiotemporal observational experiments of VGSs at block-scale are scarce, with the evapotranspiration and cooling potential of VGSs in response to urban morphology remaining unclear. Therefore, scaled outdoor experiments were conducted to investigate the effects of VGSs on the wind, radiation, and thermal parameters in urban blocks with plan area index (λ_p) of 11% and 25% in the temperate region of Xingtai, China. VGSs reduce wind speed in the crossroads by 26% in the block with λ_p=25%, but no significant effect for λ_p=11%. Compared with non-VGS cases, VGS cases have more net radiation capture and lower albedo. VGS cases experience significant temperature reductions in wall (T_w), indoor, canyon air (T_a), and ground (T_g), as well as mean radiant temperature (T_mrt) and physiological equivalent temperature (PET). The south walls in blocks with λ_p=11% and 25% exhibit the best cooling effect, with maximum reductions of 22.2 and 18.4 °C at 0.1 m height, respectively, while the north walls show weaker cooling. The east and south streets experience better air and ground cooing than the crossroads. In the south street of blocks with λ_p=11% and 25%, the maximum reductions of T_a are 1.5 and 3.9 °C, respectively. VGSs in urban block with λ_p=11% have a greater evapotranspiration rate than that with λ_p=25%. Thus, block with λ_p=11% achieve more pronounced cooling effects on walls and indoor air, whereas block with λ_p=25% exhibit better air and ground cooling due to lower wind speed. Moreover, the reductions in T_mrt and PET in block with λ_p=25% are 36.7 and 20.2 °C, respectively, significantly higher than those with λ_p=11%.