Optimizing Low Impact Development for Stormwater Runoff Treatment: A Case Study in Yixing, China

Optimizing Low Impact Development for Stormwater Runoff Treatment: A Case Study in Yixing, China

Low-impact development (LID) practices have been recognized as a promising strategy to control urban stormwater runoff and non-point source pollution in urban ecosystems. However, many experimental and modeling efforts are required to tailor an effective LID practice based on the hydraulic and envir...

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Bibliographic Details
Published in:Water (Basel) Vol. 15; no. 5; p. 989
Main Authors: Cao, Qian, Cao, Jiashun, Xu, Runze
Format: Journal Article
Language:English
Published: Basel MDPI AG 01-03-2023
Subjects:
Analysis
Calibration
Case studies
Chemical oxygen demand
Control systems
first flush effect
generalized likelihood uncertainty estimation
Green belts
Green buildings
Green roofs
Hydrologic cycle
Hydrology
InfoWorks ICM
LID optimization
Non-point source pollution
Nonpoint source pollution
Object oriented programming
Point source pollution
Pollutants
Pollution control
Pollution sources
Rain
Rain and rainfall
Rainfall
Rainfall-runoff relationships
Response surface methodology
River networks
Runoff
Sediments
Sensitivity analysis
Simulation
Storm runoff
Stormwater
Stormwater management
Surface water
Sustainable design
Uncertainty analysis
Urban runoff
Urbanization
Water quality
China
Taihu Lake
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Summary:Low-impact development (LID) practices have been recognized as a promising strategy to control urban stormwater runoff and non-point source pollution in urban ecosystems. However, many experimental and modeling efforts are required to tailor an effective LID practice based on the hydraulic and environmental characteristics of a given region. In this study, the InfoWorks ICM was applied to simulate the runoff properties and determine the optimal LID design in a residential site at Yixing, China, based on four practical rainfall events. Additionally, the software was redeveloped using Ruby object-oriented programming to improve its efficiency in uncertainty analysis using the Generalized Likelihood Uncertainty Estimation method. The simulated runoff was in good agreement with the observed discharge (Nash–Sutcliffe model efficiency coefficients >0.86). The results of the response surface method indicated that when the sunken green belt, permeable pavement, and green roof covered 8.6%, 15%, and 10%, respectively, of the 11.3 ha study area, the designed system showed the best performance with relatively low cost. This study would provide new insights into designing urban rainfall-runoff pollution control systems.
ISSN:2073-4441
2073-4441
DOI:10.3390/w15050989