1. Experimental Optimization of Gate-Opening Modes to Minimize Near-Field Vibrations in Hydropower Stations
- Author
-
Y. Peng, Matteo Rubinato, Jianming Zhang, and Weilin Xu
- Subjects
energy dissipation ,lcsh:Hydraulic engineering ,0208 environmental biotechnology ,Geography, Planning and Development ,near-field vibration ,Near and far field ,02 engineering and technology ,Aquatic Science ,Biochemistry ,lcsh:Water supply for domestic and industrial purposes ,lcsh:TC1-978 ,fluctuating pressure ,Hydropower ,Water Science and Technology ,Stilling basin ,lcsh:TD201-500 ,Fluctuating pressure ,business.industry ,Mechanics ,gate-opening modes ,Flow pattern ,Dissipation ,020801 environmental engineering ,Vibration ,multi-horizontal-submerged jets ,Environmental science ,business - Abstract
Multi-Horizontal-Submerged Jets are successfully applied to dissipate energy within a large-scale hydropower station. However, notable near-field vibrations are generated when releasing high discharges through the gates, which is generally typical in a flooding case scenario. Under these conditions, the magnitude of the vibrations varies when applying different gate-opening modes. To investigate and find optimized gate-opening modes to reduce the near-field vibration, multiple combinations were tested by varying gate-opening modes and hydraulic conditions. For each of the tests conducted, fluctuating pressures acting on side-walls and bottoms of a stilling basin were measured. The collected datasets were used to determine the maximum and minimum fluctuating pressure values associated with the correspondent gate-opening mode and a detailed comparison between each of the gate-opening modes was completed. The paper presents the quantitative analysis of the discharge ratio&rsquo, s effect on fluctuating pressures. It also investigates the influence of different gate-opening modes by including side to middle spillways and upper to lower spillways configurations. The flow pattern evolutions triggered by each different gate-opening mode are discussed and optimal configurations that minimize near-field vibrations at high discharges are recommended to support both the design of new systems and assessment of the performance of existing ones.
- Published
- 2018