Improved observability in the power system: Rotor angle measurements and support from faster voltage control |
SweGRIDS research area | Flexible Power Systems |
SweGRIDS project code | FPS20 |
Project type | PhD |
Status | running |
Researcher | Vinicius Albuquerque (webpage) |
University | UU |
Project period | 2020-05 to 2023 |
Project supervisor | Urban Lundin (webpage) |
Industrial sponsors | Svenska kraftnät, Vattenfall |
Project abstract
This project is linked with FPS19, having the same reference group and shared supervision.
The new kinds of energy producers connected to the grid add challenges to the power stability by not contributing to inertia, voltage control, or damping.
Power system stability relies that larger synchronous machines stay synchronized. During contingencies, and even normal operation, the rotor angle swings. If the swings are too large the electrical machine falls out of phase with the grid and is disconnected. The stability is governed the equal area criteria, but also depends on the amount of damping from voltage regulators and damper circuits. The rotor angle can be estimated from knowledge of stator voltages and currents, field current and machine constants including saturation.
The project aims at investigating rotor oscillations in hydropower stations during faults, in expectation on finding ways to damp oscillations that may cause de-synchronization.
Summary of work
Real data from the Älvkarleby Hydroelectric station has been processed through a frequency-estimation algorithm on SIMULINK. This data has allowed the estimation of both electrical and rotor angles, making it possible to identify small-signals oscillations on the rotor angle. The same oscillations were also identified on the instantaneous power, in both active and reactive, delivered by the machine. In the near future, we expect to use the same code to analyze more prominent grid faults, and its effects on the physical quantities of the generator.
Additionally, we have been working on a parallel project that aims at further controlability of the exciter circuit of a generator by placing a rotating power electronics box at the rotor of the machine. We hope to investigate how fast-switching at the exciter field can help with oscillations damping through experimental work.
Event log
2020-11-12. Project Pitch Presentation at SweGRIDS 2020 Conference (digital).
Project reference-group
Project-specific reference group
Robert Eriksson, SvK
Jonas Persson, Vattenfall
Mehrdad Ghandhari, KTH
Urban Lundin, UU
Broader reference group connecting to other generator-related work at UU
Jouni Ahtiainen, Fortum Hydro AB
Peter Altzar, Fortum Hydro AB
Per-Olof Andersson, Vattenfall Hydro AB
Rolf Gustavsson, Vattenfall R&D
Mats Wahlén, Svea Power AB
Mattias Nässelqvist, Vattenfall Hydro AB
Per Norrlund, UU/Vattenfall R&D
Bo Hernnäs, VOITH Hydro
Jesper Nyberg, Svenska kraftnät
Mikael Sendelius, SWECO
Håkan Hermansson, Vattenfall V-kraft emeritus
Joakim Näsström, Vattenfall R&D
Christer Lundblad, Skellefteå kraft AB
Publications by this researcher
See alternatively the researcher's full DiVA list of publications, with options for sorting.
Publications in journals and conferences usually will not show until a while after they are published.
An alternative Run-Up Strategy for Salient Pole Wound Field Synchronous Machines
Roberto Felicetti, Vinícius M. Albuquerque, Urban Lundin.
2024, IEEE Open Journal of Industrial Applications, vol. 5
Multi-mode converter control for linear generator-based wave energy system
Md Imran Ullah, Jéssica Santos Döhler, Vinícius M. de Albuquerque, Johan Forslund, Cecilia Boström, Irina Temiz.
2024, IET Renewable Power Generation
Grid-forming control for the linear-generator-based wave energy converter for the electrification of remote islands
Md Imran Ullah, Jéssica Santos Döhler, Vinicius Albuquerque, Cecilia Boström, Irina Temiz.
2023, International Conference on Power Electronics, Machines and Drives
Publication list last updated from DiVA on 2024-08-22 22:58.
Page started: 2020-05
Last generated: 2024-08-22