Abstract
This paper presents a virtual inertia and mechanical power-based control strategy to provide a stable operation of the power grid under high penetration of renewable energy sources (RESs). The proposed control technique is based on a new active and reactive power-based dynamic model with the permanent magnet synchronous generator (PMSG) swing equation, in which all PMSG features i.e., inertia and mechanical power are embedded within the controller as the main contribution of this paper. To present an accurate analysis of the virtual PMSG-based parameters, the desired zero dynamics of the grid angular frequency are considered to evaluate the effects of virtual mechanical power (VMP) on the active and reactive power sharing, as well as the investigation of virtual inertia variations for the grid angular frequency responses. Moreover, by considering various active power errors and virtual inertia, the impacts of active power error on reactive power in the proposed control technique, are precisely assessed. Simulation results are employed in Matlab/Simulink software to verify the stabilizing abilities of the proposed control technique.
Highlights
A control technique based on the characteristics of permanent magnet synchronous generator (PMSG) has been proposed in this paper to to deal with the power grid stability issues under high penetration of renewable energy sources
Virtual inertia and mechanical power (VMP) have been embedded in an active and reactive power-based dynamic model of the interfaced converter as the main contribution of this paper, power-based dynamic model of the interfaced converter as the main contribution of this paper, that that could provide a stable operation for the power grid, with properly varying the virtual parameters
The accurate active reactive power sharing have been improved by appropriately controlling virtual mechanical power (VMP) and the error of angular and reactive power sharing have been improved by appropriately controlling VMP and the error of frequency
Summary
Emulating the behaviours of a synchronous generator (SG) in the structure of novel control techniques for power electronics converters has been increased in recent years in order to guarantee the stability of the power grid under high penetration of renewable energy sources [1,2,3,4,5,6,7]. VMP variable and its error as the main effective parameters, in the proposed control technique is introduced in this paper for the first time Providing such a power-based dynamic model, along with embedding the PMSG features in this model, leads to more effective interfaced converter analogous to PMSG for providing the needed inertia that cannot found in existing methods. The performance of the proposed control technique is completely assessed through the simulation results
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