Abstract
In engineering practice, the unsteady flows generated from the operation of hydropower station in the upstream region could significantly change the navigation system of waterways located in the middle-lower reaches of the river. In order to study the complex propagation, convergence and superposition characteristics of unsteady flows in a long channel with flow confluence, a numerical model based on the coupling of implicit and explicit solution algorithms of Shallow Water Equations (SWEs) has been applied to two large rivers in the reach of Yangtze River, China, which covers the distance from Yibin to Chongqing located upstream side of the Three Gorges Dam. The accuracy of numerical model has been validated by both the steady and unsteady flows using the prototype hydrological data. It is found that the unsteady flows show much more complex water level and discharge behaviors than the steady ones. The studied unsteady flows arising from the water regulation of two upstream hydropower stations could influence the region as far as Zhutuo hydrologic station, which is close to the city of Chongqing. Meanwhile, the computed stage–discharge rating curves at all observation stations demonstrate multi-value loop patterns because of the presence of additional water surface gradient. The present numerical model proves to be robust for simulating complex flows in very long engineering rivers up to 400 km.
Highlights
The Yangtze River ranks first importance in China and it serves as the key navigation route between the east and west part of the country
A highly efficient numerical model based on the coupled explicit–implicit Eulerian–Lagrangian
[14]middle has been simulate flood flow propagation and confluence confluence in the andapplied lower to reaches of the unsteady
Summary
The Yangtze River ranks first importance in China and it serves as the key navigation route between the east and west part of the country. It would be of practical interest to study the unsteady flow propagation and influence along the river route due to the water regulation of two upstream hydropower stations, which are located at Jinsha River and Min River, respectively. Zhou from et al upstream [8] presented a 2D morphological model propagation due to the water regulation hydropower stations. Nowadays more and more hydropower stations have been put into operations Their discharged unsteady flows should generate considerable influence on the downstream navigation, water supply and sediment transport. The present work aims to use a highly efficient numerical model to investigate the water regulation effect after the completion of Jinsha and Min River hydropower stations.
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