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Damping Effect of Virtual Synchronous Machines Provided by a Dynamical Virtual Impedance

Linbin Huang, Huanhai Xin, Hui Yuan, Guanzhong Wang, Ping Ju

2020IEEE Transactions on Energy Conversion77 citationsDOI

Abstract

Virtual synchronous machines (VSMs) emulate the swing equation for grid synchronization and inertia provision. Usually, a large damping coefficient is necessary in VSMs to provide equivalent damper winding effect, which is, however, not aligned with the fact that the physical swing equation of synchronous generators (SGs) contains only a small mechanical friction factor. This large damping coefficient could result in undesired droop characteristics. In this letter, we use damping torque analysis to reveal the damping mechanism of SGs, and show that the damping effect actually comes from the dynamics of the transient/subtransient reactances aggregated as a dynamical impedance. Based on this finding, we elaborate on how to get rid of the large damping coefficient in VSMs by using a dynamical virtual impedance (DVI) to emulate SG's damping mechanism.

Topics & Concepts

Damping torqueControl theory (sociology)InertiaElectrical impedanceDamperSwingDamping factorVoltage droopTransient (computer programming)TorqueSynchronization (alternating current)Computer scienceEngineeringPhysicsControl engineeringInput impedanceControl (management)Topology (electrical circuits)Mechanical engineeringClassical mechanicsElectrical engineeringVoltageDirect torque controlThermodynamicsInduction motorOperating systemVoltage dividerArtificial intelligenceMicrogrid Control and OptimizationPower Systems and Renewable EnergyIslanding Detection in Power Systems
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