Review of Experimental Investigations of Dam-Break Flows over Fixed Bottom

Aureli, Francesca; Maranzoni, Andrea; Petaccia, Gabriella; Frazao, Sandra Soares

doi:10.3390/w15061229

Cited by 9 publications

(11 citation statements)

References 243 publications

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“…An extensive review of the state-of-the-art experimental investigations into dam-break flows was performed by Aureli et al (2023) [Contribution No. 4], limited to schematic test cases with fixed, non-erodible bottoms.…”

Section: New Laboratory Experiments and Test Cases For The Validation...mentioning

confidence: 99%

“…The comprehensive review of experimental studies on dam-break flow reported by Aureli et al (2023) [Contribution No. 4] shows that in the past, an impressive number of experimental investigations were performed on this topic in a variety of test conditions, and many extensive and accurate datasets are available for the validation of dam-break numerical models.…”

Section: New Laboratory Experiments and Test Cases For The Validation...mentioning

confidence: 99%

See 1 more Smart Citation

Advances in Dam-Break Modeling for Flood Hazard Mitigation: Theory, Numerical Models, and Applications in Hydraulic Engineering

Aureli,

Maranzoni,

Petaccia

2024

Water

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Section: New Laboratory Experiments and Test Cases For The Validation...mentioning

confidence: 99%

Section: New Laboratory Experiments and Test Cases For The Validation...mentioning

confidence: 99%

Advances in Dam-Break Modeling for Flood Hazard Mitigation: Theory, Numerical Models, and Applications in Hydraulic Engineering

Aureli,

Maranzoni,

Petaccia

2024

Water

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“…Pereira (2017) also stated that hydraulic dam projects must be supported by studies/tests in a physical model, to carry out spillway capacity and flow energy dissipation tests (downstream erosive processes). In fact, physical models or reduced-scale models integrate the study of the flow with complex hydraulic structures (Motta, 1972;Marques & Unas, 2010;Aureli et al, 2021Aureli et al, , 2023Trautwein et al, 2022) mainly through cause-consequence scenarios of simulation. Several parameters are the main focus on the present state of art, including soil composition (Correia et al, 2018;Alzamily & Abed, 2022;Trautwein et al, 2022) and the understanding of the phenomenon of failure due to overtopping (inflow hydrograph).…”

Section: Introductionmentioning

confidence: 99%

Dam-break due to overtopping failure: experiments in homogeneous earthfill dams

Von Ahn,

Manica

2024

RBRH

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This work physically simulates the effect of low and high flow rates and filling times of reservoirs and rupture due to overtopping (caused by intense rains) of small homogeneous silty-sand earthfill dams. The experiments seek to verify how input variations impact the formation of the breach and the rupture wave. The results show that different filling times, soil moisture and composition, and degree of compaction affect landfill saturation, failure time, and breach formation. The result confirms that smaller breaches with a higher degree of compaction led to a lower peak rupture flow compared to dams with low degree of compaction. The rupture hydrograph presents a faster descent stage than an exponential hydrograph. Simulations and models based on this law may minimize the effect of the dam-break wave, also impacting water resource decision-making for damage reduction. The results were extrapolated to a real prototype, providing information and a database for the studies of overtopping dam-break waves.

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“…Therefore, the comparison of numerical results with measured data is crucial to assess the performance of the mathematical models. Both Chanson (2009) and Aureli et al (2023) have highlighted that apart from few exceptions (e.g. Aureli et al, 2015), detailed experimental data to fully assess the predictive capabilities of such models are not widely available, although such data are of utmost importance for numerical models validation (Aureli et al, 2015;Fang et al, 2022;Lara et al, 2012;Robertson et al, 2013;Stamataki et al, 2018;Wang et al, 2022;Wüthrich et al, 2018;Wúthrich et al2019).…”

Section: Introductionmentioning

confidence: 99%

Modelling the impact of a dam‐break wave on a vertical wall

Del Gaudio,

La Forgia,

Constantinescu

et al. 2024

Earth Surf Processes Landf

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SummaryDam‐Break waves arise from the sudden release of the water stored behind a wall, and they cause destruction and losses on nearby areas. Characterisation of the impact force on obstacles is very important for risk assessment. In this work, we performed a series of lock‐release experiments to evaluate the wave‐induced impact force on a vertical end wall situated some distance from the lock. Laboratory data were used to evaluate the performance of several types of numerical models to predict the wave‐induced force on the vertical end wall. The selected models were as follows: the hydrostatic 1D De Saint‐Venant model, the multi‐layer hydrostatic model and the Navier–Stokes two‐phase flow. For the latter two models, both 2D (in the ‐ plane) and 3D simulations were performed. The results show that, independently of the hydrostatic assumption, the 2‐D simulations generate nonphysical oscillations which are not present in the measured temporal histories of the pressure and force values. By contrast, the predictions of both 3D numerical models better reproduce the temporal variation of the pressure forces on the end wall. The present study also shows that from a practical point of view, the 1D De Saint‐Venant model predicts with sufficient accuracy the impact time and the magnitude of the peak value of the impact force. Therefore, if the use of a fully 3D models is not a feasible option, in terms of a trade‐off between computation cost and accuracy, the use of a simple hydrostatic 1D De Saint‐Venant model is preferable to a 2D model.

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Review of Experimental Investigations of Dam-Break Flows over Fixed Bottom

Cited by 9 publications

References 243 publications

Advances in Dam-Break Modeling for Flood Hazard Mitigation: Theory, Numerical Models, and Applications in Hydraulic Engineering

Advances in Dam-Break Modeling for Flood Hazard Mitigation: Theory, Numerical Models, and Applications in Hydraulic Engineering

Dam-break due to overtopping failure: experiments in homogeneous earthfill dams

Modelling the impact of a dam‐break wave on a vertical wall

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