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DC Microgrids

Advances, Challenges, and Applications
Edited by Nikita Gupta, Mahajan Sagar Bhaskar, Sanjeevikumar Padmanaban, and Dhafer Almakhles
Copyright: 2022   |   Status: Published
ISBN: 9781119777168  |  Hardcover  |  
350 pages
Price: $225 USD
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One Line Description
Written and edited by a team of well-known and respected experts in the field, this new volume on DC microgrids presents the state-of-the-art developments and challenges in the field of microgrids for sustainability and scalability for engineers, researchers, academicians, industry professionals, consultants, and designers.

Audience
Electrical engineers and other designers, engineers, and scientists working with microgrids

Description
The electric grid is on the threshold of a paradigm shift. In the past few years, the picture of the grid has changed dramatically due to the introduction of renewable energy sources, advancements in power electronics, digitalization, and other factors. All these megatrends are pointing toward a new electrical system based on Direct Current (DC). DC power systems have inherent advantages of no harmonics, no reactive power, high efficiency, over the conventional AC power systems. Hence, DC power systems have become an emerging and promising alternative in various emerging applications, which include distributed energy sources like wind, solar and Energy Storage System (ESS); distribution networks; smart buildings, remote telecom systems; and transport electrification like electric vehicles (EVs) and shipboard.

All these applications are designed at different voltages to meet their specific requirements individually because of the lack of standardization. Thus, the factors influencing the DC voltages and system operation needed to be surveyed and analyzed, which include voltage standards, architecture for existing and emerging applications, topologies and control strategies of power electronic interfaces, fault diagnosis and design of the protection system, optimal economical operation, and system reliability.

This groundbreaking new volume presents these topics and trends of DC microgrids, bridging the research gap on DC microgrid architectures, control and protection challenges to enable wide-scale implementation of energy-efficient DC microgrids.
Whether for the veteran engineer or the student, this is a must-have for any library.


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Supplementary Data
--Covers not only the state-of-the-art of DC microgrids, but also the basics, making this volume useful not just to the veteran engineer, but the new-hire or student as well

--Offers a comprehensive coverage of DC microgrids, which includes DC microgrid demonstration systems, sites, grid standards, system optimization, and much more

--Is filled with workable examples and designs that are helpful for practical applications

--Is useful as a textbook for researchers, students, and faculty for understanding new ideas in this rapidly emerging field


Author / Editor Details
Nikita Gupta, PhD, is an assistant professor in the Department of Electrical Engineering, University Institute of Technology, Himachal Pradesh University, India.. She received her BTech degree in electrical and electronics engineering from the National Institute of Technology, Hamirpur, India in 2011 and MTech degree in power systems from Delhi Technological University, Delhi, India in 2014. She earned her PhD from the Department of Electrical Engineering at Delhi Technological University, Delhi, India, in 2018. Her research interests include power system analysis, power quality, power electronics applications in renewable energy, and microgrids.

M. S. Bhaskar, PhD, is with the Renewable Energy Lab, in the Department of Communications and Networks Engineering at the College of Engineering, Prince Sultan University, Riyadh, Saudi Arabia. After receiving his PhD in electrical and electronic engineering from the University of Johannesburg, South Africa in 2019, he was a post-doctoral researcher in the Department of Energy Technology, Aalborg University, Esbjerg, Denmark. He has several years of research experience from several universities, and he has authored over 100 scientific papers in the area of DC/AC power, receiving several awards, as well. He is a member of a number of scientific societies and is a reviewer for several technical journals and conferences, including IEEE and IET.

P. Sanjeevikumar, PhD, is a professor in the Department of Business Development and Technology, CTIF Global Capsule (CGC) Laboratory, Aarhus University, Herning, Denmark. He earned his PhD in electrical engineering from the University of Bologna, Bologna, Italy, in 2012. He has nearly ten years of teaching and industry experience and has authored over 300 scientific papers, including winning several awards at conferences for having the best paper. He is a fellow or member of numerous scientific societies and associations and is an editor, associate editor, or on the boards of numerous scientific and technical journals.

Dhafer J. Almakhles, PhD, is the Chairman of the of the Communications and Networks Engineering Department, and the Director of the Science and Technology Unit and Intellectual Property Office, Prince Sultan University, Saudi Arabia. He earned his PhD from The University of Auckland, New Zealand 2016. He is also the leader of the Renewable Energy Research Team and Laboratory. He is a member of multiple scientific societies and is a reviewer for a number of technical journals.

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Table of Contents
reface xv
1 On the DC Microgrids Protection Challenges, Schemes, and
Devices – A Review 1
Mohammed H. Ibrahim, Ebrahim A. Badran and
Mansour H. Abdel-Rahman
1.1 Introduction 2
1.2 Fault Characteristics and Analysis in DC Microgrid 4
1.3 DC Microgrid Protection Challenges 7
1.3.1 Low Inductance of DC System 7
1.3.2 Fast Rise Rate of DC Fault Current 7
1.3.3 Difficulties of Overcurrent (O/C) Relays Coordination 7
1.3.4 Fault Detection and Location 8
1.3.5 Arcing Fault Detection and Clearing 10
1.3.6 Short-Circuit (SC) Analysis and Change of Its Level 13
1.3.7 Non-Suitability of AC Circuit Breakers (ACCBs) 16
1.3.8 Inverters Low Fault Current Capacity 17
1.3.9 Constant Power Load (CPL) Impact 17
1.3.10 Grounding 18
1.4 DC Microgrid Protection Schemes 21
1.4.1 The Differential Protection-Based Strategies 25
1.4.2 The Voltage-Based Protection Strategies 27
1.4.3 The Adaptive Overcurrent Protection Schemes 28
1.4.4 Impedance-Based Protection Strategy
(Distance Protection) 29
1.4.5 Non-Conventional Protection Schemes (Data-Based
Protection Scheme) 32
1.5 DC Microgrid Protective Devices (PDs) 34
1.5.1 Z-Source DC Circuit Breakers (ZSB) 35
1.5.2 Hybrid DC Circuit Breakers (HCB) 38
1.5.3 Solid State Circuit Breakers (SSCBs) 42
1.5.4 Arc Fault Current Interrupter (AFCI) 45
1.5.5 Fuses 47
1.6 Conclusions 48
References 50
2 Control Strategies for DC Microgrids 63
Bhabani Kumari Choudhury and Premalata Jena
2.1 Introduction: The Concept of Microgrids 63
2.1.1 DC Microgrids 64
2.2 Introduction: The Concept of Control Strategies 65
2.2.1 Basic Control Schemes for DC MGs 66
2.2.1.1 Centralized Control Strategy 66
2.2.1.2 Decentralized Controller 67
2.2.1.3 Distributed Control 68
2.2.2 Multilevel Control 68
2.2.2.1 Primary Control 69
2.2.2.2 Secondary Control 73
2.2.2.3 Tertiary Control 74
2.2.2.4 Current Sharing Loop 74
2.2.2.5 Microgrid Central Controller (MGCC) 74
2.3 Control Strategies for DGs in DC MGs 76
2.3.1 Control Strategy for Solar Cell in DC MGs 76
2.3.1.1 Control Strategy for Wind Energy in DC MGs 77
2.3.1.2 Control Strategy for Fuel Cell in DC MGs 77
2.3.1.3 Control Strategy for Energy Storage System
in DC MGs 78
2.4 Conclusions and Future Scopes 79
References 80
3 Protection Issues in DC Microgrids 83
Bhabani Kumari Choudhury and Premalata Jena
3.1 Introduction 83
3.1.1 Protection Challenge 84
3.1.1.1 Arcing and Fault Clearing Time 84
3.1.1.2 Stability 85
3.1.1.3 Multiterminal Protections 85
3.1.1.4 Ground Fault Challenges 85
3.1.1.5 Communication Challenges 86
3.1.2 Effect of Constant Power Loads (CPLs) 86
3.2 Fault Detection in DC MGs 87
3.2.1 Principles and Methods of Fault Detection 87
3.2.1.1 Voltage Magnitude-Based Detection 87
3.2.1.2 Current Magnitude-Based Detection 88
3.2.1.3 Impedance Estimation Method 88
3.2.1.4 Power Probe Unit (PPU) Method 88
3.3 Fault Location 92
3.3.1 Passive Approach 92
3.3.1.1 Traveling Wave-Based Scheme 92
3.3.1.2 Differential Fault Location 93
3.3.1.3 Local Measurement-Based Fault Location 93
3.3.2 Active Approach for Fault Location 94
3.3.2.1 Injection-Based Fault Location 94
3.4 Islanding Detection (ID) 94
3.4.1 Types of IDSs 95
3.4.2 Passive Detection Schemes (PDSs) for DC MGs 96
3.4.3 Active Detection Schemes (ADS) for DC MGs 96
3.5 Protection Coordination Strategy 97
3.6 Conclusion and Future Research Scopes 97
References 97
4 Dynamic Energy Management System of Microgrid using
AI Techniques: A Comprehensive & Comparative Study 101
Priyadarshini Balasubramanyam and Vijay K. Sood
Nomenclature 102
4.1 Introduction 103
4.1.1 Background and Motivation 103
4.1.2 Prior Work 103
4.1.3 Contributions 104
4.1.4 Layout of the Chapter 104
4.2 Problem Statement 104
4.3 Mathematical Modelling of Microgrid 105
4.3.1 Cost Functions 106
4.3.1.1 Diesel Generator 106
4.3.1.2 Solar Generation 106
4.3.1.3 Wind Generation Unit 106
4.3.1.4 Energy Storage System (ESS) 107
4.3.1.5 Transaction with Utility 108
4.3.2 Objective Function 109
4.3.3 Constraints 109
4.4 Optimization Algorithm 110
4.4.1 Heuristic-Based Genetic Algorithm (GA) 110
4.4.2 Pattern Search Algorithm (PSA) 111
4.5 Results 113
4.6 Conclusion 118
References 118
5 Energy Management Strategies Involving Energy Storage in
DC Microgrid 121
S. K. Rai, H. D. Mathur and Sanjeevikumar Padmanaban
5.1 Introduction 121
5.2 Literature Review 123
5.2.1 Classic Approaches of EMS 124
5.2.2 Meta-Heuristic Approach of EMS 129
5.2.3 Artificial Intelligence Approach of EMS 134
5.2.4 Model Predictive, Stochastic and Robust
Programming Approach of EMS 139
5.3 Case Study 142
5.3.1 Energy Management System 144
5.3.2 Objective Functions 144
5.3.3 Result and Discussion 145
5.4 Conclusion 151
References 151
6 A Systematic Approach for Solar and Hydro Resource
Assessment for DC Microgrid Applications 159
Sanjay Kumar, Nikita Gupta, Vineet Kumar and
Tarlochan Kaur
6.1 Introduction 160
6.1.1 Micro Hydro and Solar PV 162
6.1.2 Renewable Energy for Rural Electrification in Indian
Perspective 162
6.1.3 Solar Resource Assessment 163
6.1.4 Hydro Resource Assessment 166
6.1.5 Demand Assessment 167
6.2 Methodology 168
6.2.1 Data Collection 168
6.2.1.1 Meteorological and Geographical Data 168
6.2.1.2 Discharge Data for Hydro Potential Estimation 168
6.3 Result and Discussion 172
6.3.1 ANN Architecture 172
6.3.2 Hydro Resource Estimation 176
6.4 Conclusion 178
References 179
7 Secondary Control Based on the Droop Technique for
Power Sharing 183
Waner W.A.G. Silva, Thiago R. de Oliveira, Rhonei P. Santos
and Danilo I. Brandao
7.1 Introduction 184
7.2 Voltage Deviation and Power Sharing Issues in
Droop Technique 186
7.2.1 Approaches for Correcting Power and
Current Sharing 190
7.2.2 Hybrid Secondary Control: Distributed Power
Sharing and Decentralized Voltage Restoration 197
7.2.2.1 Dynamics and Convergence of the Power
Sharing Correction 200
7.2.2.2 Communication Delays in Consensus-Based
Algorithm 203
7.2.2.3 Secondary Control Modeling 204
7.2.2.4 Computational and Experimental
Validation 208
7.2.3 Secondary Level Control Based on Unique
Voltage-Shifting (vs) 215
7.2.3.1 Power Sharing and Average Voltage
Convergence Analysis 218
7.2.3.2 Secondary Control Level Modeling 223
7.2.3.3 Computational and Experimental
Validation 226
7.3 Design and Implementation of the Communication System 230
7.4 Conclusions 234
References 235
8 Dynamic Analysis and Reduced-Order Modeling Techniques
for Power Converters in DC Microgrid 241
Divya Navamani J., Lavanya A., Jagabar Sathik, M.S. Bhaskar
and Vijayakumar K.
8.1 Introduction 242
8.2 Need of Dynamic Analysis for Power Converters 243
8.3 Various Modeling Techniques 245
8.3.1 Analysis from Modeling Method 249
8.4 Reduce-Order Modeling 253
8.4.1 Faddeev Leverrier Algorithm 253
8.4.1.1 Procedure for Faddeev Leverrier Algorithm 253
8.4.1.2 Illustrative Example with Switched-Inductor-
Based Quadratic Boost Converter 254
8.4.2 Order Reduction of Transfer Function 257
8.4.3 Techniques for Model Order Reduction 257
8.4.4 Pole Clustering Method 258
8.4.5 Procedure for Improved Pole Clustering Technique 258
8.4.5.1 Computation of Denominator Polynomial
of Lower-Dimensional Model 259
8.4.5.2 Computation of Numerator Polynomial
of Lower-Dimensional Model 261
8.4.5.3 Design of Controller 261
8.5 Illustrative Example with the Power Converter 262
8.5.1 Derivation of the Denominator 263
8.5.2 Derivation of the Numerator 264
8.6 Controllers for Power Converter 265
8.6.1 Need of Controller 265
8.6.2 Types of Controller 265
8.7 Conclusion 267
References 267
9 Matrix Converter and Its Probable Applications 273
Khaliqur Rahman
9.1 Introduction 274
9.2 Classification of Matrix Converter 275
9.2.1 Classical Matrix Converter 277
9.2.2 Sparse Matrix Converter 277
9.2.3 Very Sparse Matrix Converter 277
9.2.4 Ultra-Sparse Matrix Converter 278
9.3 Problems Associated with the MC and the Drives 280
9.3.1 Commutation Issues 280
9.3.2 Modulation Issues 280
9.3.3 Common-Mode Voltage and Common-Mode
Current Issues 280
9.3.4 Protection Issues 281
9.4 Control Techniques 282
9.5 Basic Components of the Matrix Converter Fed Drive
System 283
9.6 Industrial Applications of Matrix Converter 289
9.7 Summary 294
References 294
10 Multilevel Converters and Applications 299
P. Prem, Jagabar Sathik and K.T. Maheswari
10.1 Introduction 300
10.2 Multilevel Inverters 301
10.2.1 Multilevel Inverters vs. Two-Level Inverters 301
10.2.2 Advantages of Multilevel Converters Based on
Waveforms 303
10.2.3 Advantages of Multilevel Converters Based on
Topology 304
10.3 Traditional Multilevel Inverter Topologies 305
10.3.1 Diode Clamped Multilevel Inverter 305
10.3.1.1 Features of DCMLI 308
10.3.1.2 Advantages of DCMLI 308
10.3.1.3 Disadvantages of DCMLI 308
10.3.1.4 Applications of DCMLI 309
10.3.2 Flying Capacitor Multilevel Inverter 309
10.3.2.1 Features of FCMLI 312
10.3.2.2 Advantages of FCMLI 312
10.3.2.3 Disadvantages of FCMLI 312
10.3.2.4 Applications of FCMLI 313
10.3.3 Cascaded H Bridge Multilevel Inverter 313
10.3.3.1 Features of CHBMLI 315
10.3.3.2 Advantages of CHBMLI 315
10.3.3.3 Disadvantages of CHBMLI 316
10.3.3.4 Applications of CHBMLI 316
10.4 Advent of Active Neutral Point Clamped Converter 316
10.4.1 Comparison with Traditional Topologies 319
10.4.2 Advantages of ANPC MLI 320
10.4.3 Disadvantages of ANPC MLI 320
10.5 Conclusion 322
References 322
11 A Quasi Z-Source (QZS) Network-Based Quadratic Boost
Converter Suitable for Photovoltaic-Based DC Microgrids 325
Amir Ghorbani Esfahlan and Kazem Varesi
11.1 Introduction 326
11.2 Proposed Converter 328
11.3 Steady-State Analyses 331
11.4 Comparison with Other Structures 335
11.5 Converter Analyzes in Discontinuous Conduction Mode
(DCM) 335
11.6 Simulation Results 342
11.7 Real Voltage Gain and Losses Analyzes 346
11.8 Dynamic Behavior of the Proposed Converter 352
11.9 The Maximum Power Point Tracking (MPPT) 354
11.10 Conclusions 356
11.11 Appendix 357
References 358
12 Research on Protection Strategy Utilizing Full-Scale Transient
Fault Information for DC Microgrid Based on Integrated
Control and Protection Platform 361
Shi Bonian and Sun Gang
12.1 Introduction 362
12.2 Topological Structure and Grounding Model of Studied
Microgrid 363
12.2.1 Proposed DC Distribution Network Topology 363
12.2.2 Neutral Grounding Model 366
12.2.2.1 Grounding Position Selection 366
12.2.2.2 Grounding Mode Selection 366
12.3 Fault Characteristics of DC Microgrid 367
12.3.1 DC Unipolar Fault Characteristics 368
12.3.2 DC Bipolar Fault Characteristics 370
12.4 DC Microgrid Protection Strategy 373
12.4.1 Protection Zone Division and Protection
Configuration 373
12.4.1.1 Protection Zone Division 373
12.4.1.2 Protection Configuration 375
12.4.2 Integrated Control and Protection Platform 376
12.4.3 Fault Isolation and Recovery Strategy Utilizing
Full-Scale Transient Fault Information 378
12.4.3.1 Unipolar Fault Isolation and Recovery
of DC Line/Bus 378
12.4.3.2 Bipolar Fault Isolation and Recovery
of DC Line/Bus 380
12.5 Simulation Verification 384
12.5.1 Verification under DC Unipolar Fault 386
12.5.1.1 Metal Short Circuit Fault of DC Line 386
12.5.1.2 Unipolar Fault with High Transition
Resistance 386
12.5.1.3 High Resistance Unipolar Fault with
Parallel Resistance Switching Strategy 386
12.5.2 Verification under DC Bipolar Fault 390
12.6 Conclusion 394
References 395
13 A Decision Tree-Based Algorithm for Fault Detection
and Section Identification of DC Microgrid 397
Shankarshan Prasad Tiwari and Ebha Koley
Acronyms 398
Symbols 398
13.1 Introduction 398
13.2 DC Test Microgrid System 400
13.3 Overview of Decision Tree-Based Proposed Scheme 401
13.4 DC Microgrid Protection Using Decision Tree Classifier 403
13.5 Performance Evaluation 404
13.5.1 Mode Detection Module 408
13.5.2 Fault Detection/Classification 409
13.5.3 Section Identification 409
13.5.4 Comparative Analysis of the Proposed Scheme
with other DC Microgrid Protection Techniques 412
13.6 Conclusion 416
References 417
14 Passive Islanding Detection Method using Static Transfer
Switch for Multi-DGs Microgrid 421
Rahul S. Somalwar and S. G. Kadwane
14.1 Introduction 422
14.1.1 Technical Challenges of Microgrid and Benefits 424
14.1.2 System with Multi-DGs 425
14.1.3 Power Sharing Methods 426
14.1.3.1 Conventional Droop Control Method 426
14.2 Islanding 427
14.2.1 Challenges with Islanding 427
14.2.2 Different Standards for Microgrid 428
14.2.3 Islanding Detection Methods 428
14.3 Static Transfer Switch (STS) 431
14.3.1 Simulation Results of STS 432
14.4 Proposed Scheme of Islanding 435
14.4.1 Proposed PV System 435
14.4.2 Mathematical Analysis of Harmonic Extraction 436
14.5 Flow Chart 437
14.6 Simulation Results 438
14.7 Experimental Results 441
14.8 Conclusion 445
References 446
Index 449

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BISAC SUBJECT HEADINGS
TEC031020 : TECHNOLOGY & ENGINEERING / Power Resources / Electrical
SCI024000 : SCIENCE / Energy
BUS070040 : BUSINESS & ECONOMICS / Industries / Energy
 
BIC CODES
THR: Electrical engineering
TJF: Electronics engineering
UTG: Grid computing

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