2015
Yang, Jun; Pavesi, Giorgio; Yuan, Shouqi; Cavazzini, Giovanna; Ardizzon, Guido
Experimental Characterization of a Pump–Turbine in Pump Mode at Hump Instability Region Journal Article
In: Journal of Fluids Engineering, vol. 137, iss. 5, pp. 051109, 2015, ISSN: 0098-2202, (<b>From Duplicate 2 (<i>Experimental Characterization of a Pump–Turbine in Pump Mode at Hump Instability Region</i> - Yang, Jun; Pavesi, Giorgio; Yuan, Shouqi; ...; Cavazzini, Giovanna; Ardizzon, Guido)<br/></b><br/><b>From Duplicate 8 (<i>Experimental characterization of a pump–turbine in pump mode at hump instability region</i> - Yang, J; Pavesi, G; Yuan, S; ...)<br/></b><br/>Query date: 2017-05-06).
Abstract | Links | BibTeX | Tags: Flow Visualization, high-speed, High-speed flow visualization, Hump-instability, hump-instability region, Pressure measurement, Pump, Pump as Turbine, Pump as Turbine, Rotating Stall, Turbine
@article{pop00008,
title = {Experimental Characterization of a Pump–Turbine in Pump Mode at Hump Instability Region},
author = {Jun Yang and Giorgio Pavesi and Shouqi Yuan and Giovanna Cavazzini and Guido Ardizzon},
url = {http://fluidsengineering.asmedigitalcollection.asme.org/article.aspx?doi=10.1115/1.4029572},
doi = {10.1115/1.4029572},
issn = {0098-2202},
year = {2015},
date = {2015-01-01},
urldate = {2015-01-01},
journal = {Journal of Fluids Engineering},
volume = {137},
issue = {5},
pages = {051109},
publisher = {… .asmedigitalcollection.asme.org},
abstract = {The unsteady phenomena of a low specific speed pump-turbine operating in pump mode were characterized by dynamic pressure measurements and high-speed flow visualization of injected air bubbles. Analyses were carried out on the pressure signals both in frequency and time-frequency domains and by bispectral protocol. The results obtained by high-speed camera were used to reveal the flow pattern in the diffuser and return vanes channels The unsteady structure identified in the return vane channel appeared both at full and part load condition. Furthermore, a rotating stall structure was found and characterized in the diffuser when the pump operated at part load. The characteristics of these two unsteady structures are described in the paper.},
note = {<b>From Duplicate 2 (<i>Experimental Characterization of a Pump–Turbine in Pump Mode at Hump Instability Region</i> - Yang, Jun; Pavesi, Giorgio; Yuan, Shouqi; ...; Cavazzini, Giovanna; Ardizzon, Guido)<br/></b><br/><b>From Duplicate 8 (<i>Experimental characterization of a pump–turbine in pump mode at hump instability region</i> - Yang, J; Pavesi, G; Yuan, S; ...)<br/></b><br/>Query date: 2017-05-06},
keywords = {Flow Visualization, high-speed, High-speed flow visualization, Hump-instability, hump-instability region, Pressure measurement, Pump, Pump as Turbine, Pump as Turbine, Rotating Stall, Turbine},
pubstate = {published},
tppubtype = {article}
}
The unsteady phenomena of a low specific speed pump-turbine operating in pump mode were characterized by dynamic pressure measurements and high-speed flow visualization of injected air bubbles. Analyses were carried out on the pressure signals both in frequency and time-frequency domains and by bispectral protocol. The results obtained by high-speed camera were used to reveal the flow pattern in the diffuser and return vanes channels The unsteady structure identified in the return vane channel appeared both at full and part load condition. Furthermore, a rotating stall structure was found and characterized in the diffuser when the pump operated at part load. The characteristics of these two unsteady structures are described in the paper.
2014
Pavesi, Giorgio; Cavazzini, Giovanna; Yang, Jung; Ardizzon, Guido
Flow Phenomena Related to the Unstable Energy-Discharge Characteristic of a Pump-Turbine in Pump Mode Proceedings Article
In: 15th International Symposium on Transport Phenomena and Dynamics of Rotating Machinery, ISROMAC 2014, pp. 1-8, researchgate.net, 2014.
Abstract | Links | BibTeX | Tags: Francis-type Reversible Turbine, Hump-instability, part load
@inproceedings{pop00016,
title = {Flow Phenomena Related to the Unstable Energy-Discharge Characteristic of a Pump-Turbine in Pump Mode},
author = {Giorgio Pavesi and Giovanna Cavazzini and Jung Yang and Guido Ardizzon},
url = {https://www.researchgate.net/profile/Giorgio_Pavesi/publication/288996574_Flow_phenomena_related_to_the_unstable_energy-discharge_characteristic_of_a_pump-turbine_in_pump_mode/links/568e43ba08ae78cc051591d3.pdf},
year = {2014},
date = {2014-01-01},
urldate = {2014-01-01},
booktitle = {15th International Symposium on Transport Phenomena and Dynamics of Rotating Machinery, ISROMAC 2014},
pages = {1-8},
publisher = {researchgate.net},
abstract = {Renewable energy sources such as wind and sun have varying and, to some extent, unpredictable production. Pumped storage power plants can play an important role in stabilizing the electric power system when the production is either too high or too low. Subsequently, many new pumped storage power plants have been recently initiated in numerous countries where the need for stabilization is high. The use of reversible pumps turbines are widely regarded as the most cost effective solutions. They can, depending on reservoir size, deliver long term energy storage and/or boost production (turbine) or consumption (pump) in peak power situations. Pump-turbines often involve problematic S-shaped and instability regions in their machine char- acteristics. Thus, while may solve some problems in the grid, the operation and control can lead to other problems including severe self-excited oscillation in the hydromechanical system. At off design conditions, neither the distributor, nor the draft tube works properly and give awk- ward boundary conditions to the impeller. In addi- tion there is a strong interaction between the runner and these parts. Flow features such as separation and recirculation occurs heavily in an unsteady manner. (Gonzalez et al. [1], Hong and Kang [2], Guo and Maruta [3], Majidi [4], Rodriguez et al. [5], Pavesi et al. [6, 9], Cavazzini et al. [7], and Feng et al. [8] ). One objective of this research is to understand the underlying physical mechanism of the pump- mode instability of a two-stages reversible-pump turbine. The pressure fluctuations will be monitored while the pump-turbine is operating at different flow rates by flush mounted micro pressure transducers in the guide vanes, in the bladed return channel and in the inflow. The flow pattern was also analysed by high- speed flow visualizations, using injected air bubbles. A quite uniform flow pattern in the vaned channels was evidenced at the normal operating range. Whereas at part load the flow is highly disturbed backflow and vortices during the rotating stall. Moreover, the unsteady numerical flow fields were analyzed by the commercial code ANSYS CFX 14.0, to highlight the fluid-dynamical characteristic of the instabilities and investigate their origin. The evolution of rotating stall was identified by these analyses and compared with the experimental results. The spectral analysis of the unsteady pressure, obtained in the diffuser and in the impeller by the numerical results, helped to underline the role of the rotor stator interaction (RSI) in the develop- ment of the instabilities.},
keywords = {Francis-type Reversible Turbine, Hump-instability, part load},
pubstate = {published},
tppubtype = {inproceedings}
}
Renewable energy sources such as wind and sun have varying and, to some extent, unpredictable production. Pumped storage power plants can play an important role in stabilizing the electric power system when the production is either too high or too low. Subsequently, many new pumped storage power plants have been recently initiated in numerous countries where the need for stabilization is high. The use of reversible pumps turbines are widely regarded as the most cost effective solutions. They can, depending on reservoir size, deliver long term energy storage and/or boost production (turbine) or consumption (pump) in peak power situations. Pump-turbines often involve problematic S-shaped and instability regions in their machine char- acteristics. Thus, while may solve some problems in the grid, the operation and control can lead to other problems including severe self-excited oscillation in the hydromechanical system. At off design conditions, neither the distributor, nor the draft tube works properly and give awk- ward boundary conditions to the impeller. In addi- tion there is a strong interaction between the runner and these parts. Flow features such as separation and recirculation occurs heavily in an unsteady manner. (Gonzalez et al. [1], Hong and Kang [2], Guo and Maruta [3], Majidi [4], Rodriguez et al. [5], Pavesi et al. [6, 9], Cavazzini et al. [7], and Feng et al. [8] ). One objective of this research is to understand the underlying physical mechanism of the pump- mode instability of a two-stages reversible-pump turbine. The pressure fluctuations will be monitored while the pump-turbine is operating at different flow rates by flush mounted micro pressure transducers in the guide vanes, in the bladed return channel and in the inflow. The flow pattern was also analysed by high- speed flow visualizations, using injected air bubbles. A quite uniform flow pattern in the vaned channels was evidenced at the normal operating range. Whereas at part load the flow is highly disturbed backflow and vortices during the rotating stall. Moreover, the unsteady numerical flow fields were analyzed by the commercial code ANSYS CFX 14.0, to highlight the fluid-dynamical characteristic of the instabilities and investigate their origin. The evolution of rotating stall was identified by these analyses and compared with the experimental results. The spectral analysis of the unsteady pressure, obtained in the diffuser and in the impeller by the numerical results, helped to underline the role of the rotor stator interaction (RSI) in the develop- ment of the instabilities.
