Numerical investigation of unsteady flow in a reversible pump-turbine

TL;DR

This study uses high-fidelity computational modeling to analyze unsteady flow phenomena in a reversible pump-turbine, revealing complex flow behaviors and potential resonance risks in different operational modes.

Contribution

It provides detailed simulation data and insights into unsteady flow dynamics and harmonic frequencies in pump-turbines, enhancing understanding of flow-induced risks.

Findings

Identification of high harmonic frequencies up to tenth blade passing frequency

Detection of Dean vortices causing asymmetric flow at the runner inlet

Flow characteristics vary significantly between pump and turbine modes

Abstract

Hydropower is an important source of renewable energy that provides clean energy. Pump-turbine type hydraulic turbine is widely used to mitigate the intermittent energy demand and store a large-scale energy. Pump-turbine operates in reverse mode in pump mode to store energy. Flow conditions in turbine mode and pump mode operations is substantially different. This study investigates the unsteady flow field in the model pump-turbine. A computational model of the pump-turbine was created, and the model included hexahedral mesh of 58.19 million nodes. Total verification and validation error was 7.7%. Three operating conditions in turbine mode and four in pump mode were simulated. Flow characteristics, such as blade loading, time-dependent pressure fluctuations, frequency spectra, radial and tangential velocity were investigated. The frequency spectra revealed amplitude of frequencies up to tenth harmonics of the blade passing frequency in pump mode. The higher harmonic frequencies can potentially reach the high mode eigen frequencies and increase the risk of resonance. Flow field analysis in the draft tube indicted the strong presence of Dean vortices causing highly asymmetric flow at the runner inlet in pump mode operation. This study provides essential insights into the complex flow phenomena and advances the understanding of unsteady flow behaviour in pump-turbines.