Abstract
The self-designed indoor simulated rainfall device was used to rain on five types of pavement structures with 4 types of rainfall intensity (2.5 mm/min, 3.4 mm/min, 4.6 mm/min, and 5.5 mm/min). The effect of rainfall intensity on the surface runoff, the relation between the subgrade soil moisture content changes, and the influence of initial soil water content on rain infiltration rate are studied. The test results show that the surface runoff coefficient of densely asphalted pavement is greater than 90% in drainage pavements and it has little influence on the reducing and hysteresis of the flood peak. The surface runoff coefficient of large-void asphalt pavement (permeable) is less than 40%. Although the large-void asphalt pavement (permeable) can reduce a small amount of surface runoff, it has no obvious effect on the reduction and hysteresis of the flood peak. In semipermeable pavement, with the increasing of the thickness of base (graded gravel), the surface runoff coefficient decreases at different rainfall intensities, parts of the surface runoff are reduced, and the arrival of flood peaks is delayed. In permeable roads, almost no surface runoff occurred. As time continued, the soil moisture content quickly reached a saturated state and presented a stable infiltration situation under the action of gravity and the gradient of soil water suction. As the initial moisture content increases, the initial infiltration rate decreases and the time to reach a stable infiltration rate becomes shorter. The drier the soil, the greater the initial infiltration rate and the higher the soil moisture content after infiltration stabilization. Permeable roads can greatly alleviate the pressure of urban drainage and reduce the risk of storms and floods.
Highlights
According to China’s National Bureau of Statistics, China’s urbanization rate had reached 57.35% in 2016 [1]. e densely asphalted road surface has increased significantly
Zhu [1] used storm water management model (SWMM) software to simulate the effects of different permeable pavement structures under different rainfall conditions on reducing surface runoff and controlling flood peaks
In order to measure the change of soil water content during and after rainfall, 4 soil moisture analyzers were embedded in the soil to measure the soil water change at different depths. e layout diagram is shown in Figures 7 and 8
Summary
According to China’s National Bureau of Statistics, China’s urbanization rate had reached 57.35% in 2016 [1]. e densely asphalted road surface has increased significantly. Zhu [1] used storm water management model (SWMM) software to simulate the effects of different permeable pavement structures under different rainfall conditions on reducing surface runoff and controlling flood peaks. It is not enough to study the comparative effects of three permeable pavement structures on urban rainwater surface runoff. E correlation between the base layer thickness and surface runoff and the change of soil moisture content in roadbed with time need to be studied further. The effect of base layer thickness on surface runoff, the relationship between soil moisture content and time, and the influence of initial soil moisture content on rainwater infiltration rate were analyzed. E objective of this study is to provide more theoretical basis for the application of permeable pavement structure and theoretical support for the “sponge city.”
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