Impacts of Grid Structure on PLL-Synchronization Stability of Converter-Integrated Power Systems.

Small-signal instability of grid-connected power converters may arise when the converters use phase-locked loop (PLL) to synchronize with a weak grid. Commonly, this stability problem (referred as PLL-synchronization stability in this paper) was studied by employing a single-converter system that connected to an infinite bus, which however, omits the impacts of power grid structure and the interactions among multiple converters. Motivated by this, we investigate how the grid structure affects PLL-synchronization stability of multi-converter systems. By using Kron reduction to eliminate the interior nodes, an equivalent network is obtained which only contains the converter nodes. Then, we explicitly show how the converters are coupled via the Kron-reduced network and how the system can be decoupled in its modes. Importantly, we demonstrate that the smallest eigenvalue of the grounded Laplacian matrix of the Kron-reduced network dominates the stability margin. Then, sensitivity analysis of this smallest eigenvalue is conducted to explore how a perturbation in the original network affects the stability margin. On this basis, we provide guidelines on improving the PLL-synchronization stability by changing the grid structure. Finally, simulation results based on a 39-bus test system verify the validity of the analysis.