Formation of a jump by the dam-break wave over a granular bed

H. CAPART; D. L. YOUNG

doi:10.1017/S0022112098002250

Abstract

A previously unreported shock feature associated with the scouring of a horizontal granular bed by a dam-break wave is discussed. Near the wave centre, the present study shows, the free surface breaks backward and a hydraulic jump forms. This behaviour is described from the standpoint of shallow-water theory, suitably extended to deal with non-equilibrium sediment transport. The shock formation involves a particularly strong coupling between flow free-surface evolution and bed morphodynamics. Support for our conclusions is sought through experimental and numerical approaches. In order to magnify the observed phenomena, measurements were performed for the case of light bed particles moving in sheet and debris flow modes. A detailed picture of the transient two-phase flow is presented, based on whole field acquisition of the grain motions by particle tracking techniques. Corresponding shallow-water solutions are constructed numerically using a shock capturing scheme. Finally, an interpretation of the jump formation is proposed based on the theory of characteristics.

Crossref Citations

This article has been cited by the following publications. This list is generated based on data provided by Crossref.

Fraccarollo, L. Capart, H. and Zech, Y. 2003. A Godunov method for the computation of erosional shallow water transients. International Journal for Numerical Methods in Fluids, Vol. 41, Issue. 9, p. 951.

Cao, Zhixian Day, Rodney and Egashira, Shinji 2003. Closure to “Coupled and Decoupled Numerical Modeling of Flow and Morphological Evolution in Alluvial Rivers” by Zhixian Cao, Rodney Day, and Shinji Egashira. Journal of Hydraulic Engineering, Vol. 129, Issue. 9, p. 743.

Chanson, H. 2004. Experimental study of flash flood surges down a rough sloping channel. Water Resources Research, Vol. 40, Issue. 3,

Ancey, C. 2004. Powder snow avalanches: Approximation as non‐Boussinesq clouds with a Richardson number–dependent entrainment function. Journal of Geophysical Research: Earth Surface, Vol. 109, Issue. F1,

2004. Environmental Hydraulics of Open Channel Flows. p. 406.

Cao, Zhixian Pender, Gareth Wallis, Steve and Carling, Paul 2004. Computational Dam-Break Hydraulics over Erodible Sediment Bed. Journal of Hydraulic Engineering, Vol. 130, Issue. 7, p. 689.

Cao, Zhixian 2004. Comment on “STAND, a dynamic model for sediment transport and water quality” by W. Zeng and M. Beck, 2003. Journal of Hydrology 277, 125–133. Journal of Hydrology, Vol. 297, Issue. 1-4, p. 301.

Wu, Weiming and Wang, Sam S. Y. 2006. 1-D Numerical Simulation of Morphodynamic Processes under Dam Break and Overtopping flows. p. 1.

Cao, Zhixian Pender, Gareth and Carling, Paul 2006. Shallow water hydrodynamic models for hyperconcentrated sediment-laden floods over erodible bed. Advances in Water Resources, Vol. 29, Issue. 4, p. 546.

Simpson, Guy and Castelltort, Sébastien 2006. Coupled model of surface water flow, sediment transport and morphological evolution. Computers & Geosciences, Vol. 32, Issue. 10, p. 1600.

Rosatti, G. and Fraccarollo, L. 2006. A well-balanced approach for flows over mobile-bed with high sediment-transport. Journal of Computational Physics, Vol. 220, Issue. 1, p. 312.

Lin, Pengzhi and Xu, Weilin 2006. NEWFLUME: a numerical water flume for two-dimensional turbulent free surface flows. Journal of Hydraulic Research, Vol. 44, Issue. 1, p. 79.

Leal, João Gouveia Ferreira, Rui Miguel and Cardoso, António Heleno 2006. Dam-Break Wave-Front Celerity. Journal of Hydraulic Engineering, Vol. 132, Issue. 1, p. 69.

Spinewine, B. and Zech, Y. 2007. Small-scale laboratory dam-break waves on movable beds. Journal of Hydraulic Research, Vol. 45, Issue. sup1, p. 73.

Pu, Jaan Hussain, Khalid and Tait, Simon 2007. River, Coastal and Estuarine Morphodynamics: RCEM 2007, Two Volume Set. p. 507.

Wu, Weiming and Wang, Sam S. 2007. One-Dimensional Modeling of Dam-Break Flow over Movable Beds. Journal of Hydraulic Engineering, Vol. 133, Issue. 1, p. 48.

2007. Computational River Dynamics. p. 361.

Soares-Frazão, S. Le Grelle, N. Spinewine, B. and Zech, Y. 2007. Dam-break induced morphological changes in a channel with uniform sediments: measurements by a laser-sheet imaging technique. Journal of Hydraulic Research, Vol. 45, Issue. sup1, p. 87–95.

Rosatti, G. Murillo, J. and Fraccarollo, L. 2008. Generalized Roe schemes for 1D two-phase, free-surface flows over a mobile bed. Journal of Computational Physics, Vol. 227, Issue. 24, p. 10058.

Mel’nikova, O. N. 2008. Vortices in a wave travelling over dry ground. Izvestiya, Atmospheric and Oceanic Physics, Vol. 44, Issue. 2, p. 250.

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Formation of a jump by the dam-break wave over a granular bed

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