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access icon openaccess Extended control strategies of voltage source converter stations linked to converter dominated systems

This is an open access article published by the IET under the Creative Commons Attribution -NonCommercial License (http://creativecommons.org/licenses/by-nc/3.0/)
Received 28/08/2018, Accepted 19/09/2018, Published 24/10/2018

The state of the art of control strategies of modular multi-level converter based high-voltage DC systems can be categorised into two classes according to the connecting system, i.e. the active control strategies such as the vector control and the passive control ones such as the voltage and frequency control. These two control modes need to be transformed to each other under some circumstances. The traditional method to deal with this problem is to switchover the control modes. However, this process takes time and there is risk to lose stability during this period. Thus, an extended control strategy to control the converter in both modes is wanted. An extended control strategy is designed by introducing supplementary feedback property into the traditional vector control strategy. The extended and traditional vector control strategies are compared under various cases by simulation. Simulations show that the system controlled by the traditional vector control strategy loses stability when synchronous machines drop out. However, the extended vector control strategy is superior under weak or even passive grid conditions.

Inspec keywords: feedback; power convertors; frequency control; power generation control; machine vector control; power grids

Other keywords: extended vector control strategy; extended control strategy; traditional vector control strategies; traditional vector control strategy; high-voltage DC systems; control modes; passive control ones; extended vector control strategies; voltage source converter stations; modular multilevel converter; active control strategies; frequency control

Subjects: Power convertors and power supplies to apparatus; Power system control; Control of electric power systems

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