This book discusses relevant microgrid technologies in the context of integrating renewable energy and also addresses challenging issues. The authors summarize long term academic and research outcomes and contributions. In addition, this book is influenced by the authors' practical experiences on microgrids (MGs), electric network monitoring, and control and power electronic systems. A thorough discussion of the basic principles of the MG modeling and operating issues is provided. The MG structure, types, operating modes, modelling, dynamics, and control levels are covered. Recent advances in…mehr
This book discusses relevant microgrid technologies in the context of integrating renewable energy and also addresses challenging issues. The authors summarize long term academic and research outcomes and contributions. In addition, this book is influenced by the authors' practical experiences on microgrids (MGs), electric network monitoring, and control and power electronic systems. A thorough discussion of the basic principles of the MG modeling and operating issues is provided. The MG structure, types, operating modes, modelling, dynamics, and control levels are covered. Recent advances in DC microgrids, virtual synchronousgenerators, MG planning and energy management are examined. The physical constraints and engineering aspects of the MGs are covered, and developed robust and intelligent control strategies are discussed using real time simulations and experimental studies.Hinweis: Dieser Artikel kann nur an eine deutsche Lieferadresse ausgeliefert werden.
Hassan Bevrani, PhD, is a Professor at University of Kurdistan, Kurdistan, Iran. Bruno Francois, PhD, is a Professor at Centrale Lille, Lille, France. Toshifumi Ise, PhD, is a Professor at Osaka University, Osaka, Japan.
Inhaltsangabe
Foreword xix
Preface xxi
Acknowledgments xxvii
1 Grid-connected Renewable Energy Sources 1
1.1 Introduction 1
1.2 Renewable Power Generation 3
1.2.1 Renewable Energy Development 5
1.3 Grid-connectedWind Power 6
1.3.1 Wind Power GeneratorWithout Power Electronic Converters 7
1.3.2 Wind Power Generator Using Partial-Scale Power Electronic Converters 7
1.3.3 Wind Power Generator Using Full-Scale Power Electronic Converters 7
1.4 Grid-Connected PV Power 35
1.4.1 Solar Power Generators with Embedded Energy Storage Systems 36
1.4.2 Solar Energy Conversion System: Modeling, Control, and Analysis 38
1.4.3 Experimental Results 55
1.4.4 Control of Grid-Connected Solar Power Inverters: A Review 59
1.5 Summary 66
References 66
2 Renewable Power for Control Support 69
2.1 Introduction 69
2.2 Wind-Energy-based Control Support 73
2.2.1 Wind Turbines Inertial Response 73
2.2.2 Study on a Real Isolated Power System 77
2.2.3 Primary Frequency and Inertial Controls 81
2.2.4 Using Secondary Control 89
2.3 Renewable Primary Power Reserve 89
2.3.1 InstantaneousWind Power Reserve 89
2.3.2 An Evaluation on the Real Case Study 92
2.3.3 Comparison of the Reserve Allocation Strategies 96
2.4 PV-Energy-Based Control Support 102
2.5 Integration of Renewable Energy SystemsThrough Microgrids 105
2.5.1 A Solution for Renewable Power Penetration 105
2.5.2 Microgrids in Future Smart Grids 108
2.6 Summary 112
References 113
3 Microgrids: Concept, Structure, and Operation Modes 119
3.1 Introduction 119
3.2 Microgrid Concept and Structure 125
3.3 Operation Modes 129
3.4 Control Mechanism of the Connected Distributed Generators in a
Microgrid 130
3.4.1 Speed Control of Classical Distributed Generators 130
3.4.2 Control of Inverter-based Distributed Generators 131
3.5 Contribution in the Upstream Grid Ancillary Services: Frequency
Control Support Example 137
3.5.1 Participation in the Frequency Regulation 138
