Hydraulic Performance and Capillary Irrigation Feasibility of a Novel Drainage System for Green Roofs

Featured Application The proposed novel drainage and capillary irrigation system can be used in green roofs and other nature-based solutions. By integrating filters to increase stormwater retention capacity and passive subsurface capillary irrigation to improve irrigation efficiency into a single configuration, the novel system enhances the efficiency of conventional systems and expands their applications. This approach can reduce pressure on urban drainage networks, particularly during dry periods, and reuse retained runoff for irrigation without requiring external energy, while supporting sustainable urban stormwater management.Abstract Nature-based solutions (NBSs), such as green roofs, are among the most effective ways to manage urban stormwater, improve building energy efficiency, and adapt to climate change. However, conventional green roofs confront several restrictions related to stormwater drainage, retention capacity, irrigation demand, and pressure on urban water networks during dry periods. This study proposes and experimentally validates a novel system applicable to green roofs and other NBS, including streetside planting systems and vegetated sports grounds. The novelty of the proposed system lies in a double-layer design, the integration of filters within soil substrate to enhance short-term stormwater retention and controlled drainage, and passive subsurface capillary irrigation with cords to improve irrigation efficiency. Infiltration tests showed that filter hydraulic conductivity strongly depends on pore size, with measured infiltration rates ranging from 0.01 mm/min (ceramic, 0.1 mu m) to 20 mm/min (polypropylene, 50 mu m). The results showed that filter material and pore size significantly influence infiltration behaviour and short-term storage capacity. When integrated with the soil substrate, the combined system exhibited infiltration rates of 0.8-2.0 mm/min, decreasing as hydraulic head declined. Capillary rise experiments demonstrated a maximum vertical rise of 32 cm and horizontal rise of 39 cm for polyester cords (6 mm width), confirming the feasibility of passive subsurface irrigation through stored runoff reuse without external energy. The experiments were conducted at a laboratory scale (25 & times; 25 cm) as a proof-of-concept validation. Finally, the study results demonstrate the feasibility of the proposed system as a multifunctional NBS solution that enhances stormwater retention while enabling passive irrigation using retained runoff.