Two VSC-MTDC control strategies with different combinations of controllers are proposed
to eliminate transient fluctuations in the DC voltage stability, resulting from a power imbalance
in a VSC-MTDC connected to wind farms. First, an analysis is performed of a topological
model of a VSC converter station and a VSC-MTDC, as well as of a mathematical model of a wind
turbine. Then, the principles and characteristics of DC voltage slope control, constant active power
control, and inner loop current control used in the VSC-MTDC are introduced. Finally, the
PSCAD/EMTDC platform is used to establish an electromagnetic transient model of a wind farm
connected to a parallel three-terminal VSC-HVDC. An analysis is performed for three cases of single-
phase grounding faults on the rectifier and inverter sides of a converter station and of the withdrawal
of the converter station on the rectifier side. Next, the fault response characteristics of VSCMTDC
are compared and analyzed. The simulation results verify the effectiveness of the two control
strategies, both of which enable the system to maintain DC voltage stability and active power
balance in the event of a fault.
Background: The use of a VSC-MTDC to connect wind power to the grid has attracted considerable
attention in recent years. A suitable VSC-MTDC control method can enable the stable operation
of a power grid.
Objective: The study aims to eliminate transient fluctuations in the DC voltage stability resulting
from a power imbalance in a VSC-MTDC connected to a wind farm.
Method: First, the topological structure and a model of a three-terminal VSC-HVDC system connected
to wind farms are studied. Second, an analysis is performed of the outer loop DC voltage
slope control, constant active power control and inner loop current control of the converter station of
a VSC-MTDC. Two different control strategies are proposed for the parallel three-terminal VSCHVDC
system: the first is DC voltage slope control for the rectifier station and constant active power
control for the inverter station, and the second is DC voltage slope control for the inverter station
and constant active power for the rectifier station. Finally, a parallel three-terminal VSC-HVDC
model is built based on the PSCAD/EMTDC platform and used to verify the accuracy and effectiveness
of the proposed control strategy.
Results: The results of simulation analysis of the faults on the rectifier and inverter sides of the system
show that both strategies can restore the system to the stable operation. The effectiveness of the
proposed control strategy is thus verified.
Conclusion: The control strategy proposed in this paper provides a technical reference for designing
a VSC-MTDC system for wind farms.