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New Analysis Framework for Transient Stability Evaluation of DC Microgrids

Yanghong Xia, Wei Wei, Teng Long, Frede Blaabjerg, Peng Wang

2020IEEE Transactions on Smart Grid32 citationsDOIOpen Access PDF

Abstract

Because of the low inertia of dc microgrids, system state variables are easily changed acutely after being disturbed. Hence, dc microgrids meet the serious transient stability issues especially for some stressed states. But the transient stability analysis is a very challenging problem since the dc microgrid system is high-order and nonlinear. To offer a new and more effective analysis framework, this paper proposes a nonlinear decoupling method to evaluate the transient stability of dc microgrids. The proposed nonlinear decoupling method takes full consideration of the nonlinearity of the dc microgrid system and approximately transforms the original nonlinear system into a series of decoupled first-order quadratic or second-order quadratic systems. For these decoupled low-order quadratic systems, their dynamics and stability can be analyzed easily, then the transient stability of the original system can be reflected indirectly. Also, the nonlinear decoupling based analysis framework can be extended to other power electronics dominated power systems to evaluate their transient stability. The accuracy of the proposed analysis method has been validated through related case studies.

Topics & Concepts

Decoupling (probability)Control theory (sociology)Transient (computer programming)Nonlinear systemMicrogridElectric power systemQuadratic equationStability (learning theory)Computer scienceEngineeringControl engineeringPower (physics)MathematicsVoltagePhysicsControl (management)Electrical engineeringGeometryMachine learningQuantum mechanicsOperating systemArtificial intelligenceMicrogrid Control and OptimizationPhotovoltaic System Optimization TechniquesIslanding Detection in Power Systems