A Hierarchical Control Approach for Power Loss Minimization and Optimal Power Flow within a Meshed DC Microgrid

A Hierarchical Control Approach for Power Loss Minimization and Optimal Power Flow within a Meshed DC Microgrid

This work considers the DC part of a hybrid AC/DC microgrid with a meshed topology. We address cost minimization, battery scheduling and the power loss minimization within the power distribution network through constrained optimization. The novelty comes from applying differential flatness propertie...

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Bibliographic Details
Main Authors: Igyso Zafeiratou, Ionela Prodan, Laurent Lefévre
Format: Article
Language:English
Published: MDPI AG 2021-08-01
Series:Energies
Subjects:
DC microgrid architecture
meshed topology
power dissipation
load balancing
model predictive control
differential flatness
Online Access:https://www.mdpi.com/1996-1073/14/16/4846
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spelling doaj-579608c70b5948098f472c83c4e800a32021-08-26T13:42:31ZengMDPI AGEnergies1996-10732021-08-01144846484610.3390/en14164846A Hierarchical Control Approach for Power Loss Minimization and Optimal Power Flow within a Meshed DC MicrogridIgyso Zafeiratou0Ionela Prodan1Laurent Lefévre2Grenoble INP, Graduate Schools of Engineering and Management, University Grenoble Alpes, LCIS, F-26000 Valence, FranceGrenoble INP, Graduate Schools of Engineering and Management, University Grenoble Alpes, LCIS, F-26000 Valence, FranceGrenoble INP, Graduate Schools of Engineering and Management, University Grenoble Alpes, LCIS, F-26000 Valence, FranceThis work considers the DC part of a hybrid AC/DC microgrid with a meshed topology. We address cost minimization, battery scheduling and the power loss minimization within the power distribution network through constrained optimization. The novelty comes from applying differential flatness properties to the microgrid components and formulating the cost and constraints in terms of the associated B-splines parametrization of the flat outputs (the voltages and currents of the system). This allows us to obtain optimal power profiles to minimize the power dissipation and the cost of the electricity purchase from the external grid. These profiles are tracked by a model predictive controller at the higher level, while at a a lower level a controller deals with the operation of the switches within the DC/DC converters. Extensive simulations under nominal and fault-affected scenarios using realistic data validate the proposed approach.https://www.mdpi.com/1996-1073/14/16/4846DC microgrid architecturemeshed topologypower dissipationload balancingmodel predictive controldifferential flatness
collection DOAJ
language English
format Article
sources DOAJ
author Igyso Zafeiratou
Ionela Prodan
Laurent Lefévre
spellingShingle Igyso Zafeiratou
Ionela Prodan
Laurent Lefévre
A Hierarchical Control Approach for Power Loss Minimization and Optimal Power Flow within a Meshed DC Microgrid
Energies
DC microgrid architecture
meshed topology
power dissipation
load balancing
model predictive control
differential flatness
author_facet Igyso Zafeiratou
Ionela Prodan
Laurent Lefévre
author_sort Igyso Zafeiratou
title A Hierarchical Control Approach for Power Loss Minimization and Optimal Power Flow within a Meshed DC Microgrid
title_short A Hierarchical Control Approach for Power Loss Minimization and Optimal Power Flow within a Meshed DC Microgrid
title_full A Hierarchical Control Approach for Power Loss Minimization and Optimal Power Flow within a Meshed DC Microgrid
title_fullStr A Hierarchical Control Approach for Power Loss Minimization and Optimal Power Flow within a Meshed DC Microgrid
title_full_unstemmed A Hierarchical Control Approach for Power Loss Minimization and Optimal Power Flow within a Meshed DC Microgrid
title_sort hierarchical control approach for power loss minimization and optimal power flow within a meshed dc microgrid
publisher MDPI AG
series Energies
issn 1996-1073
publishDate 2021-08-01
description This work considers the DC part of a hybrid AC/DC microgrid with a meshed topology. We address cost minimization, battery scheduling and the power loss minimization within the power distribution network through constrained optimization. The novelty comes from applying differential flatness properties to the microgrid components and formulating the cost and constraints in terms of the associated B-splines parametrization of the flat outputs (the voltages and currents of the system). This allows us to obtain optimal power profiles to minimize the power dissipation and the cost of the electricity purchase from the external grid. These profiles are tracked by a model predictive controller at the higher level, while at a a lower level a controller deals with the operation of the switches within the DC/DC converters. Extensive simulations under nominal and fault-affected scenarios using realistic data validate the proposed approach.
topic DC microgrid architecture
meshed topology
power dissipation
load balancing
model predictive control
differential flatness
url https://www.mdpi.com/1996-1073/14/16/4846
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