A Novel Control Technique for Enhancing the Operation of MTDC Grids

This paper develops a novel control approach for the droop-controlled Voltage Source Converters (VSC) of Multi-Terminal High Voltage Direct Current (MTDC) systems. The frequency consensus controller is shown to assist in damping the inter-area oscillations and providing enhanced mutual frequency support. Such features, however, might be achieved at the expense of overloading some of the VSCs interfaced to the synchronously connected ac grids. Thus, a new power-sharing control loop, based on the proposed power deviation ratio (PDR) index, is developed to enhance the distribution of active power mismatches between those VSCs. The developed PDR loop, which regulates the ratios of the mismatched power-sharing by considering both the scheduled power injections and the available capacities of the VSCs, enhances the mutual frequency support capability between ac areas of the MTDC system. Furthermore, a newly proposed equidistant voltage control (EVC) loop of the proposed controller regulates the dc system's voltages such that they are equally far from upper and lower voltage limits. This technique increases the safety margin in voltage regulation during events that cause dc system's voltage profile variation. The comparative advantage of the proposed controller is verified through modal and participation factor analysis and through comprehensive time-domain simulations.

Automated summary

This paper presents a novel control approach for the droop-controlled Voltage Source Converters (VSC) in Multi-Terminal High Voltage Direct Current (MTDC) systems. The frequency consensus controller is used to dampen inter-area oscillations and provide enhanced mutual frequency support. A new power-sharing control loop based on the proposed power deviation ratio (PDR) index is developed to distribute active power mismatches between the VSCs. Additionally, an equidistant voltage control (EVC) loop is proposed to regulate the dc system's voltages and increase the safety margin in voltage regulation.