Description
Book SynopsisLike most industries around the world, the energy industry has also made, and continues to make, a long march toward green energy. The science has come a long way since the 1970s, and renewable energy and other green technologies are becoming more and more common, replacing fossil fuels. It is, however, still a struggle, both in terms of energy sources keeping up with demand, and the development of useful technologies in this area.
To maintain the supply for electrical energy, researchers, engineers and other professionals in industry are continuously exploring new eco-friendly energy technologies and power electronics, such as solar, wind, tidal, wave, bioenergy, and fuel cells. These technologies have changed the concepts of thermal, hydro and nuclear energy resources by the adaption of power electronics advancement and revolutionary development in lower manufacturing cost for semiconductors with long time reliability. The latest developments in renewable resources have pro
Table of Contents
Preface xix
1 Fabrication and Manufacturing Process of Solar Cell: Part I 1
S. Dwivedi
1.1 Introduction 2
1.1.1 Introduction to Si-Based Fabrication Technology 2
1.1.2 Introduction to Si Wafer 4
1.1.3 Introduction to Diode Physics 5
1.1.3.1 Equilibrium Fermi Energy (EF) 10
1.2 Fabrication Technology of Diode 19
1.3 Energy Production by Equivalent Cell Circuitry 27
1.4 Conclusion 30
References 31
2 Fabrication and Manufacturing Process of Solar Cell: Part II 39
Prabhansu and Nayan Kumar
2.1 Introduction 39
2.2 Silicon Solar Cell Technologies 41
2.2.1 Crystalline Structured Silicon (c-Si) 41
2.2.2 Silicon-Based Thin-Film PV Cell 43
2.3 Homojunction Silicon Solar Cells 44
2.3.1 Classic Structure and Manufacture Process 44
2.3.2 Plans for High Productivity 45
2.4 Solar Si-Heterojunction Cell 46
2.5 Si Thin-Film PV Cells 48
2.5.1 PV Cell Development Based on p-I-n and n-I-p 49
2.5.2 Light-Based Trapping Methodologies 49
2.5.3 Approach to Tandem 51
2.5.4 Current Trends 51
2.6 Perovskite Solar Cells 52
2.6.1 Introduction 52
2.6.2 Specific Properties with Perovskites-Based Metaldhalide for Photovoltaics 53
2.6.3 Crystallization of Perovskite 55
2.6.4 Current Trends 56
2.7 Future Possibility and Difficulties 56
2.8 Conclusions 57
References 58
3 Fabrication and Manufacturing Process of Perovskite Solar Cell 67
Nandhakumar Eswaramoorthy and Kamatchi R
3.1 Introduction 67
3.2 Architectures of Perovskite Solar Cells 68
3.3 Working Principle of Perovskite Solar Cell 70
3.4 Components of Perovskite Solar Cell 73
3.4.1 Transparent Conducting Metal Oxide (TCO) Layer 73
3.4.2 Electron Transport Layer (ETL) 74
3.4.3 Perovskite Layer 74
3.4.4 Hole Transport Layer (HTL) 75
3.4.5 Electrodes 75
3.5 Fabrication of Perovskite Films 76
3.5.1 One-Step Method 77
3.5.2 Two-Step Method 77
3.5.3 Solid-State Method 78
3.5.4 Bifacial Stamping Method 78
3.5.5 Solvent-Solvent Extraction Method 78
3.5.6 Pulse Laser Deposition Method 78
3.5.7 Vapor Deposition Method 79
3.5.8 Solvent Engineering 79
3.5.9 Additive Engineering 79
3.6 Manufacturing Techniques of Perovskite Solar Cells 79
3.6.1 Solution-Based Manufacturing Technique 80
3.6.1.1 Spin Coating 80
3.6.1.2 Dip Coating 81
3.6.2 Roll-to-Roll (R2R) Process 82
3.6.2.1 Knife-Over-Roll Coating 82
3.6.2.2 Slot-Die Coating 83
3.6.2.3 Flexographic Printing 84
3.6.2.4 Gravure Printing 85
3.6.2.5 Screen Printing 85
3.6.2.6 Inkjet Printing 86
3.6.2.7 Spray Coating 87
3.6.2.8 Brush Painting 88
3.6.2.9 Doctor Blade Coating 88
3.7 Encapsulation 89
3.8 Conclusions 90
References 90
4 Parameter Estimation of Solar Cells: A State-of-the-Art Review with Metaheuristic Approaches and Future Recommendations 103
Shilpy Goyal, Parag Nijhawan and Souvik Ganguli
4.1 Introduction 104
4.2 Related Works 106
4.3 Problem Formulation 107
4.3.1 Single-Diode Model (SDM) 113
4.3.2 Double-Diode Model (DDM) 115
4.3.3 Three-Diode Model (TDM) 117
4.4 Salient Simulations and Discussions for Future Work 121
4.5 Conclusions 134
References 134
5 Power Electronics and Solar Panel: Solar Panel Design and Implementation 139
Nayan Kumar, Tapas Kumar Saha and Jayati Dey
5.1 Chapter Overview 139
5.2 Challenges in Solar Power 141
5.3 Solar PV Cell Design and Implementation 141
5.3.1 Solar PV Cell Basics 145
5.3.2 Single-Diode-Based PV Cells (SDPVCs) 148
5.3.3 Determination of the Parameters 151
5.3.4 Double-Diode-Based PV Cell (DDPVC) 152
5.3.5 Solar PV System Configuration 153
5.4 MPPT Scheme for PV Panels 154
5.4.1 Operation and Modeling of MPPT Schemes for Solar PV Panels 155
5.4.2 Comparisons of Existing Solar MPPT Schemes 156
5.4.2.1 Perturbation and Observation (P&O)-MPPT Algorithms 156
5.4.2.2 Incremental-Conductance MPPT Algorithm 158
5.5 Way for Utilization of PV Schemes 159
5.5.1 Stand-Alone (SA) Based PV System 159
5.5.2 Grid-Integration–Based PV System 161
5.6 Future Trends 161
5.7 Conclusion 162
References 162
6 An Effective Li-Ion Battery State of Health Estimation Based on Event-Driven Processing 167
Saeed Mian Qaisar and Maram Alguthami
6.1 Introduction 168
6.2 Background and Literature Review 169
6.2.1 Rechargeable Batteries 169
6.2.2 Applications of Li-Ion Batteries 171
6.2.3 Battery Management Systems 171
6.2.4 State of Health Estimation Methods 173
6.2.4.1 Direct Assessment Approaches 173
6.2.4.2 Adaptive Model–Based Approaches 173
6.2.4.3 Data-Driven Approaches 174
6.3 The Proposed Approach 175
6.3.1 The Li-Ion Battery Model 175
6.3.2 The Event-Driven Sensing 176
6.3.3 The Event-Driven State of Health Estimation 177
6.3.3.1 The Conventional Coulomb Counting Based SoH Estimation 178
6.3.3.2 The Event-Driven Coulomb Counting Based SoH Estimation 178
6.3.4 The Evaluation Measures 179
6.3.4.1 The Compression Ratio 179
6.3.4.2 The Computational Complexity 179
6.3.4.3 The SoH Estimation Error 181
6.4 Experimental Results and Discussion 181
6.4.1 Experimental Results 181
6.4.2 Discussion 185
6.5 Conclusion 187
Acknowledgement 187
References 188
7 Effective Power Quality Disturbances Identification Based on Event-Driven Processing and Machine Learning 191
Saeed Mian Qaisar and Raheef Aljefri
7.1 Introduction 192
7.2 Background and Literature Review 194
7.2.1 Types of PQ Disturbances 195
7.2.1.1 Transient 196
7.2.1.2 Voltage Fluctuation 196
7.2.1.3 Long Duration Voltage Interruption 196
7.2.1.4 Noise 196
7.2.1.5 Flicker 196
7.2.1.6 Waveform Distortion 196
7.2.2 Reasons for Generation of the PQ Disturbances 196
7.2.3 PQ Disturbances Monitoring Techniques 197
7.2.4 Facilities Effected by Power Quality Disturbances 198
7.2.5 Power Quality (PQ) Disturbances Model 198
7.2.6 Extraction of Features 199
7.2.7 Classification Techniques 200
7.3 Proposed Solution 201
7.3.1 Power Quality (PQ) Disturbances Model 201
7.3.1.1 The Pure Signal 202
7.3.1.2 The Sag 203
7.3.1.3 The Interruption 203
7.3.1.4 The Swell 203
7.3.2 The Signal Reconstruction 204
7.3.3 The Event-Driven Sensing 206
7.3.4 The Event-Driven Segmentation 207
7.3.5 Extraction of Features 207
7.3.6 Classification Techniques 208
7.3.6.1 k-Nearest Neighbor (KNN) 208
7.3.6.2 Naïve Bayes 209
7.3.7 Evaluation Measures 209
7.4 Results 210
7.5 Discussion 213
7.6 Conclusion 215
Acknowledgement 215
References 215
8 Sr2SnO4 Ruddlesden Popper Oxide: Future Material for Renewable Energy Applications 221
Upendra Kumar and Shail Upadhya
8.1 Introduction 222
8.1.1 Needs of Renewable Energy 222
8.1.2 Ruddlesden Popper Oxide Phase 224
8.1.3 Application of Ruddlesden Popper Phase 227
8.1.4 Motivation of Present Work 229
8.2 Experimental Work 230
8.2.1 Preparation of Materials 230
8.2.2 Characterizations of Materials 231
8.3 Experimental Results 231
8.3.1 Thermogravimetric and Differential Scanning Calorimetry Analysis 231
8.3.2 Characterization of Sr2-xBaxSnO4 232
8.3.2.1 Phase Determination using XRD 232
8.3.2.2 Optical Properties 234
8.3.2.3 Dielectric Analysis of Samples 236
8.3.3 Characterization of Sr2-xLaxSnO4 239
8.3.3.1 Structural Analysis using XRD 239
8.3.3.2 UV-Vis. Spectroscopy 242
8.3.3.3 Electrical Analysis 244
8.4 Conclusions 245
Acknowledgement 246
References 246
9 A Universal Approach to Solar Photovoltaic Panel Modeling 251
Chitra A., M. Manimozhi, Sanjeevikumar P, Nirupama Nambiar and Saransh Chhawchharia
9.1 Introduction 251
9.2 PV Panel Modeling: A Brief Overview 252
9.3 Proposed Model 254
9.4 Current Model 259
9.5 Voltage Model 260
9.6 Simulation Results 260
9.7 Conclusion 265
Acknowledgement 265
References 266
10 Stepped DC Link Converters for Solar Power Applications 271
Dr. R. Uthirasamy, Dr. V. Kumar Chinnaiyan, Dr. J. Karpagam and Dr. V. J.Vijayalakshmi
10.1 Introduction 272
10.1.1 Photovoltaic Cell 272
10.1.2 Photovoltaic Module 272
10.1.3 Photovoltaic Array 273
10.1.4 Working of Solar Cell 273
10.1.5 Modeling of Solar Cell 273
10.1.6 Effect of Irradiance 277
10.1.7 Effect of Temperature 279
10.1.8 Maximum Efficiency 280
10.1.9 Fill Factor 280
10.1.10 Modeling of Solar Panel 281
10.1.11 Simulation Model of PV Interfaced Boost Chopper Unit 282
10.2 Power Converters for Solar Power Applications 283
10.2.1 Introduction 283
10.2.2 DC-DC Converters 284
10.2.2.1 Boost Converter 285
10.2.2.2 Buck-Boost Converter 286
10.2.3 DC-AC Converters 288
10.2.3.1 Structure of Boost Cascaded Multilevel Inverter 288
10.2.3.2 Analysis of DC Sources in BCMLI System 298
10.2.4 Structure of Single-Phase Seven-Level BCDCLHBI 298
10.2.4.1 Operation of Boost Cascaded DC Link Configuration 300
10.2.4.2 Operation of H-Bridge Inverter Configuration 309
10.2.4.3 Calculation of Losses in BCDCLHBI 310
10.2.5 Realization of Boost Cascaded Dc Link H-Bridge Inverter 312
10.2.5.1 Peripheral Interface Controller 312
10.2.5.2 Features of PIC16F877A Microcontroller 312
10.2.5.3 Equivalent Circuit of Boost Cascaded DC Link H-Bridge Inverter 313
10.2.5.4 Design of Boost Chopper Parameters 314
10.2.6 Conclusion 315
References 315
11 A Harris Hawks Optimization (HHO)–Based Parameter Assessment for Modified Two-Diode Model of Solar Cells 319
Shilpy Goyal, Parag Nijhawan and Souvik Ganguli
11.1 Introduction 320
11.2 Problem Formulation 322
11.3 Proposed Methodology of Work 325
11.3.1 Exploration Phase 326
11.3.2 Switching from Exploration to Exploitation 327
11.3.3 Exploitation Phase 327
11.4 Simulation Results 327
11.5 Conclusions 340
References 341
12 A Large-Gain Continuous Input-Current DC-DC Converter Applicable for Solar Energy Systems 345
Tohid Taghiloo, Kazem Varesi and Sanjeevikumar Padmanaban
12.1 Introduction 345
12.2 Proposed Configuration 348
12.3 Steady-State Analysis 351
12.4 Component Design 354
12.5 Real Gain Relation 355
12.6 Comparative Analysis 356
12.7 Simulation Outcomes 360
12.8 Conclusions 364
References 364
13 Stability Issues in Microgrids: A Review 369
Sonam Khurana and Sheela Tiwari
13.1 Introduction 370
13.2 Stability Issues 373
13.2.1 Control System Stability 375
13.2.2 Power Supply and Balance Stability 376
13.3 Analysis Techniques 378
13.3.1 Large-Perturbation Stability 379
13.3.2 Small-Perturbation Stability 381
13.4 Microgrid Control System 382
13.4.1 Control Methods for AC Microgrids 384
13.4.1.1 Primary Control 384
13.4.1.2 Secondary Control 389
13.4.1.3 Tertiary Control 391
13.4.2 Control Methods for DC Microgrid 392
13.4.2.1 Primary Control 392
13.4.2.2 Secondary Control 394
13.4.2.3 Tertiary Control 396
13.5 Conclusion 396
References 396
14 Theoretical Analysis of Torque Ripple Reduction in the SPMSM Drives Using PWM Control-Based Variable Switching Frequency 411
Mohamed G. Hussien and Sanjeevikumar Padmanaban
14.1 Introduction 411
14.2 Prediction of Current and Torque Ripples 413
14.2.1 Current Ripple Prediction 413
14.2.2 Torque Ripple Prediction 416
14.3 Variable Switching Frequency PWM (VSFPWM) Method for Torque Ripple Control 418
14.4 Conclusion 422
References 422
Appendix: Simulation Model Circuits 424
Main Model 424
Speed & Current Loop Controllers 425
VSFPWM for Torque Ripple Control 426
15 Energy-Efficient System for Smart Cities 427
Dushyant Kumar Singh, Ashish Kumar Singh and Himani Jerath
15.1 Introduction 428
15.2 Factors Promoting Energy-Efficient System 429
15.2.1 Smart and Clean Energy 429
15.2.2 Smart Grid 430
15.2.3 Smart Infrastructure 431
15.2.4 Smart Home 431
15.2.4.1 Home Automation 432
15.2.5 Smart Surveillance 437
15.2.6 Smart Roads and Traffic Management 438
15.2.7 Smart Agriculture and Water Distribution 439
References 440
16 Assessment of Economic and Environmental Impacts of Energy Conservation Strategies in a University Campus 441
Sunday O. Oyedepo, Emmanuel G. Anifowose, Elizabeth O. Obembe, Joseph O. Dirisu, Shoaib Khanmohamadi, Kilanko O., Babalola P.O., Ohunakin O.S., Leramo R.O. and Olawole O.C.
16.1 Introduction 442
16.2 Materials and Methods 444
16.2.1 Study Location 445
16.2.2 Instrumentation 446
16.2.2.1 Building Energy Simulation Tool – eQUEST Software 446
16.2.3 Procedure for Data Collection and Analysis 446
16.2.4 Analysis of Electrical Energy Consumption 447
16.2.5 Economic Analysis 448
16.2.6 Environmental Impacts Analysis 449
16.3 Electricity Consumption Pattern in Covenant University 449
16.3.1 Result of Electricity Demand in Covenant University for Various End Uses 450
16.3.1.1 Results of Energy Audit in Cafeterias 1 & 2 450
16.3.1.2 Results of Energy Audit in Academic Buildings (Mechanical Engineering Building) 453
16.3.1.3 Results of Energy Audit in University Library 455
16.3.1.4 Results of Energy Audit in Health Center 457
16.3.1.5 Results of Energy Audit in the Student Halls of Residence (Daniel Hall) 459
16.3.2 Comparison of Energy Use Among the University Buildings 461
16.3.3 Results of Greenhouse Gas Emissions 462
16.3.4 Qualitative Recommendation Analysis 463
16.3.4.1 Replacement of Lighting Fixtures with LED Bulbs 463
16.3.4.2 Installation of Solar Panels on the Roofs of Selected Buildings 464
16.4 Conclusion 465
References 466
17 A Solar Energy–Based Multi-Level Inverter Structure with Enhanced Output-Voltage Quality and Increased Levels per Components 469
Fatemeh Esmaeili, Kazem Varesi and Sanjeevikumar Padmanaban
17.1 Introduction 470
17.2 Proposed Basic Topology 471
17.2.1 Topology of Basic Unit 471
17.2.2 Operation of Basic Configuration 472
17.2.3 Switching of Basic Unit for Different Magnitudes of Input Sources 473
17.2.3.1 Symmetric Value of Input DC Supplies (P1) 473
17.2.3.2 DC Sources with Binary Order Magnitudes (P2 ) 475
17.2.3.3 DC Sources with Trinary Manner Magnitudes (P3) 476
17.3 Proposed Extended Structure 478
17.3.1 Structure 478
17.3.2 Determination of Values of DC Supplies 478
17.3.3 Blocking Voltage (BV) on Switches 479
17.4 Efficiency and Losses Analysis in Suggested Structure 480
17.4.1 Conduction Power Loss 480
17.4.2 Switching Power Loss 481
17.5 Comparison Results 483
17.6 Nearest Level Technique 485
17.7 Simulation Results 485
17.8 Conclusions 490
References 490
18 Operations of Doubly Fed Induction Generators Applied in Green Energy Systems 495
Bhagwan Shree Ram and Suman Lata Tripathi
18.1 Introduction 496
18.2 Doubly Fed Induction Generators (DFIG) Systems Operated by Wind Turbines 496
18.3 Control Scheme of Direct Current Controller 497
18.4 Simulation Studies of Direct Current Control of DFIG System 498
18.5 Characteristics of DFIG at Transient and After Transient Situation 499
18.6 Pulsation of DFIG Parameters with DCC Control Technique 501
18.7 Effects of 5th and 7th Harmonics of IS and VGRID 502
18.8 Load Contribution of DFIG in Grid with DCC Control Technique 503
18.9 Speed Control Scheme of Generators 505
18.10 DFIG Control Scheme 506
18.11 General Description About PI Controller Design 507
18.12 GSC Controller 508
18.13 Characteristics of DFIG with Wind Speed Variations 509
18.14 Conclusion 511
References 512
19 A Developed Large Boosting Factor DC-DC Converter Feasible for Photovoltaic Applications 515
Hussein Mostafapour, Kazem Varesi and Sanjeevikumar Padmanaban
19.1 Introduction 515
19.2 Suggested Topology 518
19.2.1 Configuration 518
19.2.2 Operating Modes during CCM 520
19.2.3 Operating Modes during DCM 521
19.3 Steady State Analyses 524
19.3.1 Gain Calculation 524
19.3.2 Average Currents and Current Ripple of Inductors 527
19.3.3 Stress on Semiconductors 528
19.3.4 Efficiency 529
19.4 Design Consideration 531
19.4.1 Design Consideration of Capacitors 531
19.4.2 Design Consideration of Inductors 531
19.5 Comparison 532
19.6 Simulation 539
19.7 Conclusion 544
References 545
20 Photovoltaic-Based Switched-Capacitor Multi-Level Inverters with Self-Voltage Balancing and Step-Up Capabilities 549
Saeid Deliri Khatoonabad, Kazem Varesi and Sanjeevikumar Padmanaban
20.1 Introduction 550
20.2 Suggested First (13-Level) Basic Configuration 551
20.3 Suggested Second Basic Configuration 556
20.4 Modulation Method 561
20.5 Design Consideration of Capacitors 562
20.6 Efficiency and Losses Analysis 563
20.7 Simulation Results 567
20.7.1 First Structure 567
20.7.2 Second Structure 571
20.8 Comparative Analysis 575
20.9 Conclusions 578
References 579
Index 583
