The dam break pattern of rock-fill dams is normally gradual failure. This kind of dam failure is caused by seepage piping or overtopping, in which dam crest overflow is more common. The dam breach expansion process shall depend comprehensively on the structure pattern, material property of dam, and damsite cross sectional topography. And the break duration has a significant impact?on the magnitude of break flood and the counter-measures for excess-standard?flood. Take the Karot Hydropower Project constructed on the Jhelum River in Pakistan as an example, the dam break mathematical model is set up to analyze the sensitivity of damsite discharge process, downstream highest flood water surface profile and flood peak appearance time to dam break duration. The results show that: with the increase of dam break duration, damsite peak discharge is decreased sharply, flood peak appearance time extends, on-way highest water levels below Karot dam are lowered significantly, and some settlement places below Karot dam can avoid being inundated until the break duration reaches a critical value. If encountering probable maximum flood, the dam break occurs when the reservoir water level reaches dam top EL, some measures can be taken to extend the break duration, so as to effectively reduce the loss of downstream flood. The research results will help to understand the relationship mechanism between rock-fill dam break flood and break duration and provide a scientific basis or some solutions for optimization design of dam and counter-measures of dam break flood.
References
[1]
Chen, S.S., Chen, Z.Y. and Zhong, Q.M. (2019) Progresses of Studies on Failure Mechanism and Numerical Dam Failure Model of Earth-Rockfill Dam and Landslide Dam. Water Resources and Hydropower Engineering, 50, 27-36.
[2]
Chen, Z.Y., Chen, S.S., Wang, L. and Zhang, Q. (2019) Analysis of Earth-Rock Dam Break Flood: Theory and Calculation Program. Hydro Science and Cold Zone Engineering, 2, 12-19.
[3]
Dam Safety Management Center of Ministry of Water Resources (2019) National Register of Dam Breaks. Dam Safety Management Center of Ministry of Water Resources, Beijing.
[4]
DHI Water & Environment (2004) MIKE 11—A Modelling System for Rivers and Channels. DHI Water & Environment, Denmark.
[5]
Du, X.H. (2019) Analysis and Research on the Safety Status of Dams in China. Water Power, 45, 64-69, 73.
[6]
Jia, X.H. (2019) Sensitivity Analysis of Seismic Dynamic Response about Earth-Rock Dams of the Plain Reservoir. Pearl River, 40, 18-23, 42.
[7]
Li, C.W., Ma, Q., Jiang, L., et al. (2019) Analysis on Karot Dam (Cofferdam) Break Flood in Pakistan. Changjiang Survey, Planning, Design and Research Co., Ltd, Wuhan.
[8]
Liu, H.L. and Li, H.Q. (2019) Simulation of Dam-Break Flow Based on Smoothed Particle Hydrodynamics. Yangtze River, 50, 150-154, 159.
[9]
Mei, J.S., Zhong, Z.Y., An, Y.G., et al. (2015) Water Conservancy Industry Standard of the People’s Republic of China (SL 104-2015): Regulations for Water Conservancy Computation of Water Projects. Ministry of Water Resources, People’s Republic of China, Beijing.
[10]
Ministry of Water Resources, National Bureau of Statistics, People’s Republic of China (2013) Bulletin of First National Census for Water. China Water & Power Press, Beijing.
[11]
Ministry of Water Resources, People’s Republic of China (2018) 2017 Statistic Bulletin on China Water Activities. China Water & Power Press, Beijing.
[12]
Pratiwi, V., Kusuma, M.S.B., Kardhana, D. and Farid, M. (2021) Comparison of Physical and Numerical Model on Dam Break Flood Wave Propagation in Horizontal Channel. IOP Conference Series: Materials Science and Engineering, 1158, Article ID: 012015. https://doi.org/10.1088/1757-899X/1158/1/012015
[13]
Oguzhan, S. and Aksoy, A.O. (2020) Experimental Investigation of the Effect of Vegetation on Dam Break Flood Waves. Journal of Hydrology and Hydromechanics, 68, 231-234. https://doi.org/10.2478/johh-2020-0026
[14]
Xu, Z.M., Wang, Y.Z. and Ning, L. (2008) Main Understanding of Tangjiashan Dammed Lake Break Flood Calculation. Yangtze River, 39, 86-88, 104.
[15]
Zhang, X.F., Jiang, H.P., Huang, G.B., et al. (2006) Electrical Industry Standard of the People’s Republic of China (DL/T 5360-2006): Code for Simulation of Dam-Break Flow for Hydropower and Hydraulic Engineering. National Development and Reform Commission, People’s Republic of China, Beijing.
[16]
Zhou, C., Xu, W.L., Huang, M.H., et al. (2010) Water Conservancy Industry Standard of the People’s Republic of China (SL 164-2010): Regulations for Simulation of Dam-Break Flow. Ministry of Water Resources, People’s Republic of China, Beijing.
