Study on Transient Flow Characteristics of Pump Turbines during No-Load Condition in Turbine Mode Startup

To address the escalating demand for power grid load regulation, pumped storage power stations must frequently switch between operational modes. As a key component of such stations, the pump turbine has seen extensive research on its steady-state flow behavior. However, the intricate dynamics of its...

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Bibliographic Details
Published in:Water (Basel) 2024-10, Vol.16 (19), p.2741
Main Authors: Li, Xianliang, Dong, Haiyang, Lu, Yonggang, Li, Xiji, Wang, Zhengwei
Format: Article
Language:English
Subjects:
Computer simulation
Computer-generated environments
Efficiency
Energy
Entropy
Environmental aspects
Hydraulic measurements
Hydraulics
Measurement
Mechanical properties
Pump turbines
Simulation
Transients (Dynamics)
Turbines
Turbulence models
Vortices
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Summary:To address the escalating demand for power grid load regulation, pumped storage power stations must frequently switch between operational modes. As a key component of such stations, the pump turbine has seen extensive research on its steady-state flow behavior. However, the intricate dynamics of its transient flow have not yet been thoroughly examined. Notably, the no-load condition represents a quintessential transient state, the instability of which poses challenges for grid integration. Under certain extreme conditions, this could result in the impairment of the unit’s elements, interruption of its functioning, and endangerment of the security of the power station’s output as well as the stability of the power network’s operations. Thus, investigating the flow characteristics of pump turbines under no-load conditions is of significant practical importance. This paper focuses on the transient flow characteristics of a Weifang hydro-generator unit under no-load conditions, exploring the internal unsteady flow features and their underlying mechanisms. The study reveals that under no-load conditions, the runner channel is obstructed by a multitude of vortices, disrupting the normal pressure gradient within the runner and resulting in substantial hydraulic losses. Within the draft tube, a substantial reverse flow zone is present, predominantly along the walls. This irregular flow pattern within the tube generates a potent, stochastic pressure fluctuation. In addition to the interference frequencies of dynamic and static origins, the pressure pulsation frequency at each measurement point also encompasses a substantial portion of low-frequency, high-amplitude components.
ISSN:2073-4441
2073-4441
DOI:10.3390/w16192741