Advanced hierarchical control and stability analysis of DC microgrids / Andrei-Constantin Braitor.
2022
TK3106 .B73 2022
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Title
Advanced hierarchical control and stability analysis of DC microgrids / Andrei-Constantin Braitor.
ISBN
9783030954154 (electronic bk.)
3030954153 (electronic bk.)
9783030954147
3030954145
3030954153 (electronic bk.)
9783030954147
3030954145
Published
Cham : Springer, [2022]
Copyright
©2022
Language
English
Description
1 online resource : illustrations (some color).
Item Number
10.1007/978-3-030-95415-4 doi
Call Number
TK3106 .B73 2022
Dewey Decimal Classification
621.319/12
Summary
This book introduces several novel contributions into the current literature. Firstly, given that microgrid topologies are paramount in theoretical analysis, the author has proposed a rigorous method of computing the network's admittance matrix and developed to facilitate the stability analysis of DC microgrids supplying nonlinear loads. This unique approach enabled the factorisation of the admittance matrix in a particular way that facilitates a rigorous theoretical analysis for deriving the stability conditions. Secondly, author has proposed a unified control structure at the primary control layer that maintains the widely accepted droop-based approaches and additionally ensures crucial current- and voltage-limiting properties, thus offering an inherent protection to distributed energy resources. He has formalised the control design proofs using Lyapunov methods and nonlinear ultimate boundedness theory, for both parallel and meshed microgrid configurations. Moreover, he has developed a distributed secondary controller using a diffusive coupling communication network, on top of the primary control, to achieve voltage restoration and improve the power sharing. In this way, the author has formulated the complete hierarchical control scheme. In this high-order nonlinear setting, he has analytically proven closed-loop system stability of the overall system, for the first time, using two-time scale approaches and singular perturbation theory, by formulating rigorous theorems that introduce straightforward conditions that guide the system and control design and demonstrate system stability at the desired equilibrium point. In addition, the author has provided a straightforward algorithm for simple testing of system stability and explored from a graphical perspective by giving an interpretation to the effect of the nonlinear load onto the system performance and stability.
Note
"Doctoral thesis accepted by The University of Sheffield, Sheffield, UK."
Bibliography, etc. Note
Includes bibliographical references.
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Access limited to authorized users.
Source of Description
Online resource; title from PDF title page (SpringerLink, viewed February 24, 2022).
Series
Springer theses. 2190-5061
Available in Other Form
Print version: 9783030954147
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Table of Contents
Introduction
Literature review
Notations and theoretical preliminaries
Admittance matrix computation and stability analysis of droopcontrolled DC microgrids
Control design and stability analysis of DC microgrids consisting of unidirectional DC/DC boost converters
Stability analysis of parallel-operated bidirectional AC/DC and DC/DC converters
Stability analysis of DC microgrids under decentralised primary and distributed secondary control
Droop-controlled DC microgrids with overvoltage protection
Conclusions.
Literature review
Notations and theoretical preliminaries
Admittance matrix computation and stability analysis of droopcontrolled DC microgrids
Control design and stability analysis of DC microgrids consisting of unidirectional DC/DC boost converters
Stability analysis of parallel-operated bidirectional AC/DC and DC/DC converters
Stability analysis of DC microgrids under decentralised primary and distributed secondary control
Droop-controlled DC microgrids with overvoltage protection
Conclusions.