Litcius/Paper detail

Modeling of Grid-Forming and Grid-Following Inverters for Dynamic Simulation of Large-Scale Distribution Systems

Wei Du, Francis Tuffner, Kevin P. Schneider, R.H. Lasseter, Jing Xie, Zhe Chen, Bishnu Bhattarai

2020IEEE Transactions on Power Delivery310 citationsDOIOpen Access PDF

Abstract

Historically, distribution system planning studies mainly focused on steady state and quasi-steady state analysis, with limited attention paid to dynamic analysis. This paper develops three-phase, electromechanical models for both grid-forming and grid-following inverters, and integrates them into an open source, three-phase distribution network solver, thereby enabling dynamic simulation of large-scale, three-phase unbalanced distribution systems with high penetration of inverter-based DERs. The proposed inverter models are validated against electromagnetic simulation and field test data from the CERTS/AEP microgrid testbed, and simulated in an islanded 5252 node distribution system in the GridLAB-D simulation environment. Simulation verifies the effectiveness of the proposed inverter models for large-scale distribution system analysis. Study results show that compared to traditional grid-following inverters, the high penetration of grid-forming inverters can improve the voltage and frequency stability of islanded distribution systems.

Topics & Concepts

GridInverterMicrogridTestbedComputer scienceSolverDynamic simulationElectronic engineeringVoltageEngineeringSimulationElectrical engineeringComputer networkProgramming languageGeometryMathematicsMicrogrid Control and OptimizationIslanding Detection in Power SystemsOptimal Power Flow Distribution