Hydrodynamics of long-duration urban floods: experiments and numerical modelling

Arrault, Anaïs; Finaud-Guyot, Pascal; Archambeau, Pierre; Bruwier, Martin; Erpicum, Sébastien; Pirotton, Michel; Dewals, Benjamin

doi:10.5194/nhess-16-1413-2016

Cited by 45 publications

(40 citation statements)

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“…This model has been extensively validated and applied for simulating flow induced by dam and dike breaching Roger et al, 2009) as well as for conducting flood risk analysis (Arrault et al, 2016;Beckers et al, 2013;Bruwier et al, 2015;Detrembleur et al, 2015;Ernst et al, 2010).…”

Section: Hydraulic Modellingmentioning

confidence: 99%

Formation, breaching and flood consequences of a landslide dam near Bujumbura, Burundi

Nibigira

Havenith

Archambeau

et al. 2018

Nat. Hazards Earth Syst. Sci.

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Abstract. This paper investigates the possible formation of a landslide dam on the Kanyosha River near Bujumbura, the capital of Burundi, as well as the interplay between the breaching of this landslide dam and the flooding along the river. We present an end-to-end analysis, ranging from the origin of the landslide up to the computation of flood waves induced by the dam breaching. The study includes three main steps. First, the mass movement site was investigated with various geophysical methods that allowed us to build a general 3-D model and detailed 2-D sections of the landslide. Second, this model was used for dynamic landslide process modelling with the Universal Distinct Element Code. The results showed that a 15 m high landslide dam may form on the river. Finally, a 2-D hydraulic model was set up to find out the consequences of the breaching of the landslide dam on flooding along the river, especially in an urban area located downstream. Based on 2-D maps of maximum water depth, flow velocity and wave propagation time, the results highlight that neglecting the influence of such landslide dams leads to substantial underestimation of flood intensity in the downstream area.

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Section: Hydraulic Modellingmentioning

confidence: 99%

Formation, breaching and flood consequences of a landslide dam near Bujumbura, Burundi

Nibigira

Havenith

Archambeau

et al. 2018

Nat. Hazards Earth Syst. Sci.

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“…The HLM was used to get streamflow boundary conditions for the local model created in XPSWMM. Instead of focusing on a single street or block (Arrault et al, 2016), this study uses the necessary detail to analyze how flooding propagates in a whole urban district.…”

Section: Chapter 4: Methodologymentioning

confidence: 99%

“…With an increase in model resolution, the number of grid cells increased by square Schubert & Sanders, 2012; G. P. Smith, Wasko, & Miller, 2012;Syme, 2008). There are a few experimental studies on the flow behavior in urban areas both focusing on a single street intersection and those that analyze the entire flow field in an urban area (Arrault et al, 2016;Dottori & Todini, 2013). Numerous methods have been devised to represent the influence of buildings on flood flow behavior in either account for the effect of buildings by physically including them in the topography or by introducing additional head loss in the model computational gird points at the building footprints.…”

Section: Modeling Approachesmentioning

confidence: 99%

“…The XPSWWM 2D landuse types used in the Manchester model The Manning's roughness (n) describes how the sheet flow moves over the gridded surface. There are difficulties for estimating the roughness parameters which vary significantly in space, particularly in floodplains(Arrault et al, 2016). The typical range of values for the Manning's roughness values are listed below(Engineering, 2016;Janses & SCE, 2016).…”

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confidence: 99%

“…The 2D overland flow was calculated by solving the dynamic wave version of the SWE. Flows in urban areas are supercritical with high Froude numbers which usually require smaller timesteps(Arrault et al, 2016;Dottori & Todini, 2013). The flow is subject to viscous effects of the frictional surfaces.…”

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Urban and rural flood forecasting

Grimley¹

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iii ACKNOWLEDGEMENTS Thanks to Witold Krajewski for giving me the opportunity to work with him and others at the Iowa Flood Center. Thank you for advising me in my research and for showing me the value (and necessity) of clear communication whether to scientists or the public. I appreciate your patience and sincerity. What a privilege to work with such a leading scientist in the field of hydrology who was approachable and generous in his guidance of my work.I would like to acknowledge Felipe Quintero who was a great mentor and friend constantly giving research guidance, a practical outlook to solving problems, and most importantly a good sense of humor. To all my colleagues and friends at IIHR, thanks to everyone who shared their passions with me and enlightened me on the many exciting areas within hydrology. The community at IIHR made my graduate experience formative and enriching, and I am honored to have had the chance to work with the students, staff, and faculty. This project was possible thanks to Ryan Wicks and others at Fehr and Graham for making data available and hosting me at Manchester. The project's momentum was continually fueled by the participation of Shirley Johnson (USACE) and members of other local agencies. Thank you to all other local agencies who provided data and models for this project. iv ABSTRACT Floods are the most common natural disaster in the U.S. as reported by the Federal Emergency Management Administration (FEMA), and there is a need to provide advance warning to vulnerable communities on the potential risks of flooding after intense storms. The key drivers of urban hydrological research include climate change impacts and adaption, city resilience to hydrological extremes, and integration with emergency management and city planning disciplines. Significant advances in modeling techniques and computational resources have made real-time flood forecasting tools in urban and rural areas an achievable goal, but there is no universal method for flood modeling. Urban landscapes pose a challenge because of fine-scale features and heterogeneities in the landscape including streets, buildings, pipes, and impervious land cover.A nested regional-local modeling approach was used to evaluate its capabilities to provide useful and accurate flood related information to a small community in Iowa. The advantage of a nested approach is the ability to harness the computational efficiency of the regional model while providing reasonably accurate streamflow boundary conditions to the local model. The nested model incorporates the tools and products maintained at the Iowa Flood Center (IFC) including the streamflow bridge sensors, rain gauges, radar rainfall product, and statewide model. A one-way connection was made between the regional model of the upper Maquoketa Watershed (275 mi 2 ) and the local model of the City of Manchester (5 mi 2 ). The uncalibrated, nested model was validated using photos and streamflow records for flood events that occurred in July 2010 and September 2016.Multiple radar rai...

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Assessing the impact of flood inundation dynamics on an urban environment

Gao

2021

Nat Hazards

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Hydrodynamics of long-duration urban floods: experiments and numerical modelling

Cited by 45 publications

References 45 publications

Formation, breaching and flood consequences of a landslide dam near Bujumbura, Burundi

Formation, breaching and flood consequences of a landslide dam near Bujumbura, Burundi

Urban and rural flood forecasting

Assessing the impact of flood inundation dynamics on an urban environment

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