Dam-break waves over an erodible embankment: experiments and simulations

Dam-break waves over an erodible embankment: experiments and simulations

The impact of a dam-break wave on an erodible embankment with a steep slope is studied in the paper using both experimental and numerical approaches. The laboratory experiments have been specifically designed and performed for a range of the storage water levels and the embankment elevations and slo...

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Bibliographic Details
Published in:Journal of hydraulic research Vol. 56; no. 2; pp. 196 - 210
Main Authors: Di Cristo, Cristiana, Evangelista, Stefania, Greco, Massimo, Iervolino, Michele, Leopardi, Angelo, Vacca, Andrea
Format: Journal Article
Language:English
Published: Madrid Taylor & Francis 04-03-2018
Taylor & Francis Ltd
Subjects:
Bank failure
Computer simulation
Dam failure
dam-break
Dams
Embankments
erodible bank
Free surfaces
Geotechnical engineering
Mathematical models
Slope
Slopes
Storage
two-phase depth-integrated model
Water levels
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Summary:The impact of a dam-break wave on an erodible embankment with a steep slope is studied in the paper using both experimental and numerical approaches. The laboratory experiments have been specifically designed and performed for a range of the storage water levels and the embankment elevations and slopes. The simulations were carried out using a recently-developed two-phase depth-integrated model, supplemented with a geofailure operator to account for the possible occurrence of geotechnical collapses. A comparison between numerical and experimental results indicates that the two-phase model reproduces the experimental free surface elevation well, with or without the geofailure operator. On the other hand, especially for high embankment slopes, this operator appears to be important for predicting the observed morphological evolution. The results also show that, due to the geotechnical collapses, water and sediment velocities may have opposite signs. While the models based on equal direction of the liquid and the solid motions cannot reproduce this effect, the proposed two-phase approach easily accounts for such a peculiarity of the investigated process.
ISSN:0022-1686
1814-2079
DOI:10.1080/00221686.2017.1313322