双端口构网型互联电力变换器在交直流混合电网中的小信号稳定性及硬件验证

Interconnecting power converters (IPCs) are the main elements enabling the interconnection of multiple high-voltage alternating current (HVac) and high-voltage direct current (HVdc) subgrids. To ensure stable operation of the resulting hybrid ac/dc systems, grid-following (GFL) and grid-forming (GFM) controls need to be carefully assigned to individual IPC terminals when using common IPC controls. In contrast, dual-port GFM control imposes a stable voltage on the ac and dc terminals and can be deployed on all IPCs regardless of the network configuration. In this work, we use hybrid ac/dc admittance models, eigenvalue sensitivities, and case studies to analyze and quantify the underlying properties of ac-GFM control, ac-GFL, and dual-port GFM control. Compared to common ac-GFM and ac-GFL controls, dual-port GFM control: 1) renders IPCs dissipative over a much wider range of frequencies and operating points; 2) significantly reduces the sensitivity of IPC small-signal dynamics to operating point changes; and 3) exhibits an improved dynamic response to severe contingencies. Finally, the results are illustrated and validated in an experimental scaled-down point-to-point HVdc system.