Dynamic Voltage Stiffness Control Technique for a Virtual Oscillator based Grid-forming Controller (2210.02832v1)

Abstract: Virtual oscillator control is the latest control technique for grid-forming inverters. Virtual Oscillator based Controllers (VOCs) provide all the steady-state droop functionalities of conventional droop controllers and, in addition, the time-domain synchronization with a connected electrical network. However, existing literature does not consider the aspect of dynamic control over the voltage stiffness of a VOC. Voltage stiffness is a vital parameter for a grid-forming inverter. If the voltage stiffness is too high, the inverter picks up all the reactive power demand of the PCC. In contrast, if the stiffness is too low, the inverter does not participate in voltage regulation at all. Limiting the reactive power output during a higher voltage sag, especially when connected to a weak grid, is challenging for a VOC. Entering into the current control mode is the existing solution, but it severely affects the effective synchronization between the VOC and the voltages of the PCC. As a result, the grid-forming mode of operation becomes inefficient. This article has introduced a Virtual Impedance (VIm) based dynamic voltage stiffness control technique for VOCs. The systematic design procedure for the proposed voltage stiffness controller is presented. In addition, a rigorous approach for stability analysis is presented.