A Predictive Control Scheme for a Single-Phase Grid-Supporting Quasi-Z-Source Inverter and Its Integration With a Frequency Support Strategy

A Predictive Control Scheme for a Single-Phase Grid-Supporting Quasi-Z-Source Inverter and Its Integration With a Frequency Support Strategy

Small grid-connected inverters are not friendly to the electrical grid, in the sense they do not take any action to support the grid when contingency events occur. For example, because of their relatively low power capacity, small grid-connected inverters are not designed to provide dynamic frequenc...

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Veröffentlicht in:IEEE access 2023, Vol.11, p.5337-5351
Hauptverfasser: Baier, Carlos R., Villarroel, Felipe A., Torres, Miguel A., Perez, Marcelo A., Hernandez, Jesus C., Espinosa, Eduardo E.
Format: Artikel
Sprache:eng
Schlagworte:
Contingency
Direct current
Distributed generation
droop control
FCS-MPC
Frequency control
frequency support
grid connected inverters
impedance source inverters
Inverters
Microgrids
Power grids
Predictive control
QZSI
Renewable energy sources
Semiconductor diodes
Switches
Topology
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container_end_page 5351
container_issue
container_start_page 5337
container_title IEEE access
container_volume 11
creator Baier, Carlos R.
Villarroel, Felipe A.
Torres, Miguel A.
Perez, Marcelo A.
Hernandez, Jesus C.
Espinosa, Eduardo E.
description Small grid-connected inverters are not friendly to the electrical grid, in the sense they do not take any action to support the grid when contingency events occur. For example, because of their relatively low power capacity, small grid-connected inverters are not designed to provide dynamic frequency support to the grid. On the other hand, it is well known that microgrids and weak grids including distributed generation would benefit significantly if all of the grid-connected converters could support and help against grid frequency disturbances. Within the family of small grid-connected converters, single-phase quasi-Z-source inverters (QZSI) have become an attractive topology, because they represent a reliable and economical alternative, and can be very efficient in applications that demand small or medium powers. However, a major disadvantage is that the control strategy must manage both direct current and alternating current variables through the same group of switches. The latter is a challenging task when implementing predictive control schemes. This paper proposes a finite control set model predictive control (FCS-MPC) strategy for a single-phase grid-supporting QZSI. The proposed predictive scheme can be easily integrated with a complementary control block to provide grid frequency support. Experimental results show evidence of the inverter operating under the proposed control strategy and providing grid frequency support, which demonstrates the feasibility of the proposal.
doi_str_mv 10.1109/ACCESS.2023.3236499
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subjects Contingency
Direct current
Distributed generation
droop control
FCS-MPC
Frequency control
frequency support
grid connected inverters
impedance source inverters
Inverters
Microgrids
Power grids
Predictive control
QZSI
Renewable energy sources
Semiconductor diodes
Switches
Topology
title A Predictive Control Scheme for a Single-Phase Grid-Supporting Quasi-Z-Source Inverter and Its Integration With a Frequency Support Strategy
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