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http://dx.doi.org/10.3741/JKWRA.2014.47.11.1077

Hydraulic Characteristics of Dam Break Flow by Flow Resistance Stresses and Initial Depths  

Song, Chang Geun (Dept. of. Safety Engrg., Incheon National Univ.)
Lee, Seung Oh (Dept. of Civil Engrg., Hongik Univ.)
Publication Information
Journal of Korea Water Resources Association / v.47, no.11, 2014 , pp. 1077-1086 More about this Journal
Abstract
The flood wave generated due to dam break is affected by initial depth upstream since it is related with hydraulic characteristics propagating downstream, and flow resistance stress has influence on the celerity, travel distance, and approaching depth of shock wave in implementing numerical simulation. In this study, a shallow water flow model employing SU/PG scheme was developed and verified by analytic solutions; propagation characteristics of dam break according to flow resistance and initial depth were analyzed. When bottom frictional stress was applied, the flow depth was relatively higher while the travel distance of shock wave was shorter. In the case of Coulomb stress, the flow velocity behind the location of dam break became lower compared with other cases, and showed values between no stress and turbulent stress at the reach of shock wave. The value of Froude number obtained by no frictional stress at the discontinuous boundary was the closest to 1.0 regardless of initial depth. The adaption of Coulomb stress gave more appropriate results compared with turbulent stress at low initial depth. However, as the initial depth became increased, the dominance of flow resistance terms was weakened and the opposite result was observed.
Keywords
dam break; initial depth; flow resistance stress; bottom frictional stress; Coulomb stress;
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Times Cited By KSCI : 4  (Citation Analysis)
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