Simulation of Hydraulic Structures in 2D High-Resolution Urban Flood Modeling

Simulation of Hydraulic Structures in 2D High-Resolution Urban Flood Modeling

Urban flooding as a result of inadequate drainage capacity, failure of flood defenses, etc. is usually featured with highly transient hydrodynamics. Reliable and efficient prediction and forecasting of these urban flash floods is still a great technical challenge. Meanwhile, in urban environments, t...

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Main Authors: Yunsong Cui, Qiuhua Liang, Gang Wang, Jiaheng Zhao, Jinchun Hu, Yuehua Wang, Xilin Xia
Format: Article
Language:English
Published: MDPI AG 2019-10-01
Series:Water
Subjects:
urban flood modeling
hydraulic structures
shock-capturing scheme
shallow water equations
Online Access:https://www.mdpi.com/2073-4441/11/10/2139
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spelling doaj-71ecb63f608445cd9f301968ce5f5e9a2020-11-25T02:32:56ZengMDPI AGWater2073-44412019-10-011110213910.3390/w11102139w11102139Simulation of Hydraulic Structures in 2D High-Resolution Urban Flood ModelingYunsong Cui0Qiuhua Liang1Gang Wang2Jiaheng Zhao3Jinchun Hu4Yuehua Wang5Xilin Xia6State Key Laboratory of Hydrology-Water Resources and Hydraulic Engineering, Hohai University, Nanjing 210098, ChinaState Key Laboratory of Hydrology-Water Resources and Hydraulic Engineering, Hohai University, Nanjing 210098, ChinaState Key Laboratory of Hydrology-Water Resources and Hydraulic Engineering, Hohai University, Nanjing 210098, ChinaSchool of Architecture, Building and Civil Engineering, Loughborough University, LE11 3TU England, UKZhejiang Institute of Hydraulics and Estuary, Hangzhou 310020, ChinaZhejiang Institute of Hydraulics and Estuary, Hangzhou 310020, ChinaSchool of Architecture, Building and Civil Engineering, Loughborough University, LE11 3TU England, UKUrban flooding as a result of inadequate drainage capacity, failure of flood defenses, etc. is usually featured with highly transient hydrodynamics. Reliable and efficient prediction and forecasting of these urban flash floods is still a great technical challenge. Meanwhile, in urban environments, the flooding hydrodynamics and process may be influenced by flow regulation and flood protection hydraulic infrastructure systems, such as sluice gates, which should be effectively taken into account in an urban flood model. However, direct simulation of hydraulic structures is not a current practice in 2D urban flood modeling. This work aims to develop a robust numerical approach to directly simulate the effects of gate structures in a 2D high-resolution urban flood model. A new modeling component is developed and fully coupled to a finite volume Godunov-type shock-capturing shallow water model, to directly simulate the highly transient flood waves through hydraulic structures. Different coupling approaches, i.e., flux term coupling and source term coupling, are implemented and compared. A numerical experiment conducted for an analytical dam-break test indicates that the flux term coupling approach may lead to more accurate results, with the calculated RMSE against water level 28%−38% less than that produced by the source term coupling approach. The flux term coupling approach is therefore adopted to improve the current urban flood model, and it is further tested by reproducing the laboratory experiments of flood routing in a flume with partially open sluice gates, conducted in the hydraulic laboratory at the Zhejiang Institute of Hydraulics and Estuary, China. The numerical results are compared favorably with experimental measurements, with a maximum RMSE of 0.0851 for all the individual tests. The satisfactory results demonstrate that the flood model implemented with the flux coupling approach is able to accurately simulate the flow through hydraulic structures, with enhanced predictive capability for urban flood modeling.https://www.mdpi.com/2073-4441/11/10/2139urban flood modelinghydraulic structuresshock-capturing schemeshallow water equations
collection DOAJ
language English
format Article
sources DOAJ
author Yunsong Cui
Qiuhua Liang
Gang Wang
Jiaheng Zhao
Jinchun Hu
Yuehua Wang
Xilin Xia
spellingShingle Yunsong Cui
Qiuhua Liang
Gang Wang
Jiaheng Zhao
Jinchun Hu
Yuehua Wang
Xilin Xia
Simulation of Hydraulic Structures in 2D High-Resolution Urban Flood Modeling
Water
urban flood modeling
hydraulic structures
shock-capturing scheme
shallow water equations
author_facet Yunsong Cui
Qiuhua Liang
Gang Wang
Jiaheng Zhao
Jinchun Hu
Yuehua Wang
Xilin Xia
author_sort Yunsong Cui
title Simulation of Hydraulic Structures in 2D High-Resolution Urban Flood Modeling
title_short Simulation of Hydraulic Structures in 2D High-Resolution Urban Flood Modeling
title_full Simulation of Hydraulic Structures in 2D High-Resolution Urban Flood Modeling
title_fullStr Simulation of Hydraulic Structures in 2D High-Resolution Urban Flood Modeling
title_full_unstemmed Simulation of Hydraulic Structures in 2D High-Resolution Urban Flood Modeling
title_sort simulation of hydraulic structures in 2d high-resolution urban flood modeling
publisher MDPI AG
series Water
issn 2073-4441
publishDate 2019-10-01
description Urban flooding as a result of inadequate drainage capacity, failure of flood defenses, etc. is usually featured with highly transient hydrodynamics. Reliable and efficient prediction and forecasting of these urban flash floods is still a great technical challenge. Meanwhile, in urban environments, the flooding hydrodynamics and process may be influenced by flow regulation and flood protection hydraulic infrastructure systems, such as sluice gates, which should be effectively taken into account in an urban flood model. However, direct simulation of hydraulic structures is not a current practice in 2D urban flood modeling. This work aims to develop a robust numerical approach to directly simulate the effects of gate structures in a 2D high-resolution urban flood model. A new modeling component is developed and fully coupled to a finite volume Godunov-type shock-capturing shallow water model, to directly simulate the highly transient flood waves through hydraulic structures. Different coupling approaches, i.e., flux term coupling and source term coupling, are implemented and compared. A numerical experiment conducted for an analytical dam-break test indicates that the flux term coupling approach may lead to more accurate results, with the calculated RMSE against water level 28%−38% less than that produced by the source term coupling approach. The flux term coupling approach is therefore adopted to improve the current urban flood model, and it is further tested by reproducing the laboratory experiments of flood routing in a flume with partially open sluice gates, conducted in the hydraulic laboratory at the Zhejiang Institute of Hydraulics and Estuary, China. The numerical results are compared favorably with experimental measurements, with a maximum RMSE of 0.0851 for all the individual tests. The satisfactory results demonstrate that the flood model implemented with the flux coupling approach is able to accurately simulate the flow through hydraulic structures, with enhanced predictive capability for urban flood modeling.
topic urban flood modeling
hydraulic structures
shock-capturing scheme
shallow water equations
url https://www.mdpi.com/2073-4441/11/10/2139
work_keys_str_mv AT yunsongcui simulationofhydraulicstructuresin2dhighresolutionurbanfloodmodeling
AT qiuhualiang simulationofhydraulicstructuresin2dhighresolutionurbanfloodmodeling
AT gangwang simulationofhydraulicstructuresin2dhighresolutionurbanfloodmodeling
AT jiahengzhao simulationofhydraulicstructuresin2dhighresolutionurbanfloodmodeling
AT jinchunhu simulationofhydraulicstructuresin2dhighresolutionurbanfloodmodeling
AT yuehuawang simulationofhydraulicstructuresin2dhighresolutionurbanfloodmodeling
AT xilinxia simulationofhydraulicstructuresin2dhighresolutionurbanfloodmodeling
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