Controller Coordination Strategy for DC Microgrid Using Distributed Predictive Control Improving Voltage Stability

Marvin Lema; Wilson Pavon; Leony Ortiz; Ama Baduba Asiedu-Asante; Silvio Simani

doi:10.3390/en15155442

Controller Coordination Strategy for DC Microgrid Using Distributed Predictive Control Improving Voltage Stability

Marvin Lema, Wilson Pavon, Leony Ortiz, Ama Baduba Asiedu-Asante, Silvio Simani

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Resumen

The paper presents the design and control strategy of an isolated DC microgrid, which is based on classical control techniques, predictive control and iterative algorithms. The design control parameters are maximum overshoot, settling time and voltage ripple. The strategy is designed to operate in two different modes, end-users minimum and maximum demand scenarios, and this is achieved through the incorporation of network dynamic loads. The control methodology developed allows to obtain a fast response of the design set points, and an efficient control for disturbance rejection. The simulation results obtained satisfy the proposed design guidelines by obtaining a maximum overshoot of 4.8%, settling time of 0.012 seconds and a voltage ripple of 0.1 percentage. The implemented system simulation was developed in Matlab-Simulink software.

Idioma original	Inglés
Número de artículo	5442
Publicación	Energies
Volumen	15
N.º	15
DOI	https://doi.org/10.3390/en15155442
Estado	Publicada - ago. 2022

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© 2022 by the authors.

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title = "Controller Coordination Strategy for DC Microgrid Using Distributed Predictive Control Improving Voltage Stability",

abstract = "The paper presents the design and control strategy of an isolated DC microgrid, which is based on classical control techniques, predictive control and iterative algorithms. The design control parameters are maximum overshoot, settling time and voltage ripple. The strategy is designed to operate in two different modes, end-users minimum and maximum demand scenarios, and this is achieved through the incorporation of network dynamic loads. The control methodology developed allows to obtain a fast response of the design set points, and an efficient control for disturbance rejection. The simulation results obtained satisfy the proposed design guidelines by obtaining a maximum overshoot of 4.8%, settling time of 0.012 seconds and a voltage ripple of 0.1 percentage. The implemented system simulation was developed in Matlab-Simulink software.",

keywords = "converter, DC, distributed generation, hierarchical, microgrid, MPC, predictive control, robust control, smart grid",

author = "Marvin Lema and Wilson Pavon and Leony Ortiz and Asiedu-Asante, {Ama Baduba} and Silvio Simani",

note = "Publisher Copyright: {\textcopyright} 2022 by the authors.",

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doi = "10.3390/en15155442",

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volume = "15",

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AU - Lema, Marvin

AU - Pavon, Wilson

AU - Ortiz, Leony

AU - Asiedu-Asante, Ama Baduba

AU - Simani, Silvio

PY - 2022/8

Y1 - 2022/8

N2 - The paper presents the design and control strategy of an isolated DC microgrid, which is based on classical control techniques, predictive control and iterative algorithms. The design control parameters are maximum overshoot, settling time and voltage ripple. The strategy is designed to operate in two different modes, end-users minimum and maximum demand scenarios, and this is achieved through the incorporation of network dynamic loads. The control methodology developed allows to obtain a fast response of the design set points, and an efficient control for disturbance rejection. The simulation results obtained satisfy the proposed design guidelines by obtaining a maximum overshoot of 4.8%, settling time of 0.012 seconds and a voltage ripple of 0.1 percentage. The implemented system simulation was developed in Matlab-Simulink software.

AB - The paper presents the design and control strategy of an isolated DC microgrid, which is based on classical control techniques, predictive control and iterative algorithms. The design control parameters are maximum overshoot, settling time and voltage ripple. The strategy is designed to operate in two different modes, end-users minimum and maximum demand scenarios, and this is achieved through the incorporation of network dynamic loads. The control methodology developed allows to obtain a fast response of the design set points, and an efficient control for disturbance rejection. The simulation results obtained satisfy the proposed design guidelines by obtaining a maximum overshoot of 4.8%, settling time of 0.012 seconds and a voltage ripple of 0.1 percentage. The implemented system simulation was developed in Matlab-Simulink software.

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KW - distributed generation

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KW - MPC

KW - predictive control

KW - robust control

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Controller Coordination Strategy for DC Microgrid Using Distributed Predictive Control Improving Voltage Stability

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