2018
Pavesi, Giorgio; Cavazzini, Giovanna; Ardizzon, Guido
Numerical Simulation of a Pump–Turbine Transient Load Following Process in Pump Mode Journal Article
In: Journal of Fluids Engineering, vol. 140, iss. 2, pp. 021114, 2018, ISSN: 0098-2202.
Abstract | Links | BibTeX | Tags: Francis-type Reversible Turbine, hump-instability region, part load, Transient load
@article{Pavesi2018a,
title = {Numerical Simulation of a Pump–Turbine Transient Load Following Process in Pump Mode},
author = {Giorgio Pavesi and Giovanna Cavazzini and Guido Ardizzon},
url = {http://fluidsengineering.asmedigitalcollection.asme.org/article.aspx?doi=10.1115/1.4037988},
doi = {10.1115/1.4037988},
issn = {0098-2202},
year = {2018},
date = {2018-01-01},
journal = {Journal of Fluids Engineering},
volume = {140},
issue = {2},
pages = {021114},
abstract = {This paper presents the simulation of the dynamic behavior of variable speed pump-turbine. A power reduction scenario at constant wicket gate opening was numerically analyzed from 100% to 93% rpm corresponding to a power reduction from full load to about 70% with a ramp rate of 1.5% per second. The flow field analysis led to the onset and development of unsteady phenomena progressively evolving in an organized rotating partial stall during the pump power reduction. These phenomena were characterized by frequency and time-frequency analyses of several numerical signals (pressure, blade torque, and flow rate in blade passages). The unsteady pattern in return channel strengthened emphasizing its characteristic frequency with the rotational velocity decreasing reaching a maximum and then disappearing. At lower rotational speed, the flow field into the wickets gates channel starts to manifest a full three-dimensional (3D) flow structure. This disturbance was related to the boundary layer separation and stall, and it was noticed by a specific frequency.},
keywords = {Francis-type Reversible Turbine, hump-instability region, part load, Transient load},
pubstate = {published},
tppubtype = {article}
}
This paper presents the simulation of the dynamic behavior of variable speed pump-turbine. A power reduction scenario at constant wicket gate opening was numerically analyzed from 100% to 93% rpm corresponding to a power reduction from full load to about 70% with a ramp rate of 1.5% per second. The flow field analysis led to the onset and development of unsteady phenomena progressively evolving in an organized rotating partial stall during the pump power reduction. These phenomena were characterized by frequency and time-frequency analyses of several numerical signals (pressure, blade torque, and flow rate in blade passages). The unsteady pattern in return channel strengthened emphasizing its characteristic frequency with the rotational velocity decreasing reaching a maximum and then disappearing. At lower rotational speed, the flow field into the wickets gates channel starts to manifest a full three-dimensional (3D) flow structure. This disturbance was related to the boundary layer separation and stall, and it was noticed by a specific frequency.
