Power Compensation Control for DFIG-Based Wind Turbines to Enhance Synchronization Stability During Severe Grid Faults
Yihang Yang, Donghai Zhu, Xudong Zou, Yongning Chi, Yong Kang
Abstract
Wind turbines (WTs) are prone to lose the synchronization during severe grid faults due to the absence of equilibrium point. To cope with the issue, this letter proposes a power compensation control for doubly fed induction generator based WT to enhance the transient synchronization stability from the new perspective of active power balance. In the method, the active power of WT is controlled to compensate the power loss on the network. Compared with the existing methods, the proposed method has more widely application scenarios because it avoids using the frequency error as control signal. Experimental tests are performed to validate proposed method.
Topics & Concepts
Control theory (sociology)Wind powerCompensation (psychology)Synchronization (alternating current)Power (physics)GridPower controlComputer scienceInduction generatorAC powerTransient (computer programming)EngineeringControl engineeringControl (management)VoltageTelecommunicationsElectrical engineeringPsychologyGeometryArtificial intelligenceChannel (broadcasting)Operating systemQuantum mechanicsPhysicsMathematicsPsychoanalysisMicrogrid Control and OptimizationWind Turbine Control SystemsIslanding Detection in Power Systems