A case in subtropical climate city: Assessing the bioretention hydraulic performance on storm in response to poor permeability soil

Jun Huang; Zebin Yu; Yinghong Qin; Li Wang; Yiyi Huang; Yimin Huang

doi:10.1016/j.jenvman.2021.112952

A case in subtropical climate city: Assessing the bioretention hydraulic performance on storm in response to poor permeability soil

J Environ Manage. 2021 Sep 1:293:112952. doi: 10.1016/j.jenvman.2021.112952. Epub 2021 Jun 5.

Authors

Jun Huang¹, Zebin Yu², Yinghong Qin¹, Li Wang³, Yiyi Huang³, Yimin Huang³

Affiliations

¹ College of Civil Engineering and Architecture, Guangxi University, Nanning 530004, PR China.
² College of Civil Engineering and Architecture, Guangxi University, Nanning 530004, PR China; Hualan Design & Consulting Group, Nanning, 530004, PR China. Electronic address: yuzebin@gxu.edu.cn.
³ Hualan Design & Consulting Group, Nanning, 530004, PR China.

PMID: 34102494
DOI: 10.1016/j.jenvman.2021.112952

Abstract

Bioretention has been widely used in China for the purpose of sponge city construction. In subtropical climate areas, the performance of bioretention cell under condition of low infiltration underlying soil and heavy storms is still poorly understood. This study aimed to assess the effects of low infiltration underlying soil and precipitation characteristics on the hydraulic performance of a bioretention cell using the Storm Water Management Model (SWMM). The hydraulic performance of a bioretention cell were investigated under a Typical year rainfall event (P_(total) (total precipitation) = 1299.2 mm) and seven heavy storms (i.e., P_total range from 53.1 mm to 287.3 mm), at different S_F(i) (seepage rates of the underlying soil) (i.e., range from 2.5 mm/h to 15 mm/h). Then, sensitivity of the optimal design to the different design parameters, including the hydraulic conductivity of soil medium layer and the berm height of surface layer, was examined. The results show that the increase in S_F(i) was effective in increasing the AR_VR(i) (annual runoff volume reduction) and R_VR(i) (runoff volume reduction), while little effective in increasing P_FR(i) (peak flow reduction). Moreover, the AR_VR(i) could meet the designed goal of 70% when the S_F(i) was more than 7.5 mm/h. For R_VR(i), the key variable of precipitation characteristic changes from P_total to P_4h(max) (maximum precipitation in 4 h) as S_F(i) increases, while P_4h(max) remains as the key variable for P_FR(i) all the time. The sensitivity studies demonstrate that the hydraulic conductivity is more effective in increasing P_FR(i) than the berm height. For the bioretention cell under condition of low infiltration underlying soil and heavy storms, in order to simultaneously achieve expected reduction goal of both peak flow and runoff volume, and make the best comprehensive performance of bioretention cell, it requires not only a maintenance action to increase the hydraulic conductivity of soil medium layer, but also a drain pipe to be added in the storage layer, and meanwhile other LID practices should be combined.

Keywords: Bioretention; Peak flow reduction; Runoff volume reduction; Subtropical climate; Underlying soil infiltration.

MeSH terms

China
Cities
Hydrology
Permeability
Rain
Soil*
Water Movements*

Substances

Soil