Active Damping of Power Oscillations Following Frequency Changes in Low Inertia Power Systems
Citation:
Marios Zarifakis, William T. Coffey, Yuri P. Kalmykov, Serguey V. Titov, Declan J. Byrne and Stephen J. Carrig, Active Damping of Power Oscillations Following Frequency Changes in Low Inertia Power Systems, IEEE Transactions on Power Systems, 34, 6, 2019, 4984 - 4992Abstract:
The absolute requirement to increase the amount of energy generation from renewable sources e.g. predominantly asynchronously connected wind turbines and photovoltaic installations, may in practice during transient events (where frequency changes are examined) excite oscillatory response of the power output of large grid connected synchronous-generators. The response of such generators must be controlled either by varying the applied torque of a turbine or by altering the electromagnetic torque in the airgap. Choosing the latter, the adequacy of a voltage regulator, particularly that of the embedded Power System Stabilizer (PSS) circuit, is investigated using the IEEE PSS1A model for the automatic voltage regulator of a synchronous generator driven by a gas turbine. The response is obtained via closed form analytic solutions for both small (linear) and large (nonlinear) scale transient events in the energy grid system. In tandem with the analytical study, the behavior simulated with a computer model from MatLab-SimPowerSystems is reviewed.
Author's Homepage:
http://people.tcd.ie/wcoffeyDescription:
PUBLISHED
Author: Coffey, William
Type of material:
Journal ArticleSeries/Report no:
IEEE Transactions on Power Systems34
6
Availability:
Full text availableKeywords:
Generators, Mathematical model, Rotors, Oscillators, Torque, Power system stability, Integrated circuit modelingSubject (TCD):
Smart & Sustainable PlanetDOI:
https://doi.org/10.1109/TPWRS.2019.2911845ISSN:
0885-8950Metadata
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