TY - JOUR
T1 - Distributed Predictive Secondary Control for Imbalance Sharing in AC Microgrids
AU - Navas-Fonseca, Alex
AU - Burgos-Mellado, Claudio
AU - Gomez, Juan S.
AU - Donoso, Felipe
AU - Tarisciotti, Luca
AU - Saez, Doris
AU - Cardenas, Roberto
AU - Sumner, Mark
N1 - Publisher Copyright:
© 2010-2012 IEEE.
PY - 2022/1/1
Y1 - 2022/1/1
N2 - This paper proposes a distributed predictive secondary control strategy to share imbalance in three-phase, three-wire isolated AC Microgrids. The control is based on a novel approach where the imbalance sharing among distributed generators is controlled through the control of single-phase reactive power. The main characteristic of the proposed methodology is the inclusion of an objective function and dynamic models as constraints in the formulation. The controller relies on local measurements and information from neighboring distributed generators, and it performs the desired control action based on a constrained cost function minimization. The proposed distributed model predictive control scheme has several advantages over solutions based on virtual impedance loops or based on the inclusion of extra power converters for managing single-phase reactive power among distributed generators. In fact, with the proposed technique the sharing of imbalance is performed directly in terms of single-phase reactive power and without the need for adding extra power converters into the microgrid. Contrary to almost all reported works in this area, the proposed approach enables the control of various microgrid parameters within predefined bands, providing a more flexible control system. Extensive simulation and Hardware in the Loop studies verify the performance of the proposed control scheme. Moreover, the controller's scalability and a comparison study, in terms of performance, with the virtual impedance approach were carried out.
AB - This paper proposes a distributed predictive secondary control strategy to share imbalance in three-phase, three-wire isolated AC Microgrids. The control is based on a novel approach where the imbalance sharing among distributed generators is controlled through the control of single-phase reactive power. The main characteristic of the proposed methodology is the inclusion of an objective function and dynamic models as constraints in the formulation. The controller relies on local measurements and information from neighboring distributed generators, and it performs the desired control action based on a constrained cost function minimization. The proposed distributed model predictive control scheme has several advantages over solutions based on virtual impedance loops or based on the inclusion of extra power converters for managing single-phase reactive power among distributed generators. In fact, with the proposed technique the sharing of imbalance is performed directly in terms of single-phase reactive power and without the need for adding extra power converters into the microgrid. Contrary to almost all reported works in this area, the proposed approach enables the control of various microgrid parameters within predefined bands, providing a more flexible control system. Extensive simulation and Hardware in the Loop studies verify the performance of the proposed control scheme. Moreover, the controller's scalability and a comparison study, in terms of performance, with the virtual impedance approach were carried out.
KW - distributed predictive control
KW - Imbalance sharing
KW - secondary controllers
KW - unbalanced microgrids
UR - http://www.scopus.com/inward/record.url?scp=85122337182&partnerID=8YFLogxK
U2 - 10.1109/TSG.2021.3108677
DO - 10.1109/TSG.2021.3108677
M3 - Article
AN - SCOPUS:85122337182
SN - 1949-3053
VL - 13
SP - 20
EP - 37
JO - IEEE Transactions on Smart Grid
JF - IEEE Transactions on Smart Grid
IS - 1
ER -