SSR Mitigation of Series-Compensated DFIG Wind Farms by a Nonlinear Damping Controller Using Partial Feedback Linearization

SSR Mitigation of Series-Compensated DFIG Wind Farms by a Nonlinear Damping Controller Using Partial Feedback Linearization

A nonlinear damping controller using partial feedback linearization (PFL) technique is designed with an aim to mitigate subsynchronous resonance (SSR) in series-compensated doubly-fed induction generator (DFIG)-based wind farms, which is integrated to simplified Nordic power system. The controller u...

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Veröffentlicht in:IEEE transactions on power systems 2018-05, Vol.33 (3), p.2528-2538
Hauptverfasser: Chowdhury, M. A., Shafiullah, G. M.
Format: Artikel
Sprache:eng
Schlagworte:
Computational modeling
Computer simulation
Control stability
Control systems design
Controllers
Damping
damping controller
doubly-fed induction generator
Dynamic stability
Feedback linearization
Induction generators
internal dynamics
Nonlinear control
Nonlinear programming
partial feedback linearization
Power system dynamics
Power system stability
Radio frequency
Stability analysis
Subsynchronous resonance
System dynamics
Torque
Wind farms
Wind power
Wind power generation
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Zusammenfassung:A nonlinear damping controller using partial feedback linearization (PFL) technique is designed with an aim to mitigate subsynchronous resonance (SSR) in series-compensated doubly-fed induction generator (DFIG)-based wind farms, which is integrated to simplified Nordic power system. The controller using PFL technique is implementable into a partially linearized form of a system with DFIG wind farm that results in reduced system order and small computational burden. The derivation of control law does not also demand thorough knowledge of nonlinear and ambiguous system dynamics. The proposed controller design approach has four distinguished steps: 1) scrutinizing partial linearizability, 2) performing partial linearization, 3) assessing stability of internal system dynamics, and 4) obtaining control laws. Small-signal stability analysis is performed that includes electrical damping analysis and eigenvalue analysis. The controller is found to demonstrate a superior performance in SSR mitigation. Time-series simulation is carried out to confirm the veracity of the outcomes obtained from the small-signal stability analysis.
ISSN:0885-8950
1558-0679
DOI:10.1109/TPWRS.2017.2752805