Description

Book Synopsis
Energy Smart Appliances

Enables designers and manufacturers to manage real-world energy performance and expectations by covering a range of potential scenarios and challenges

Energy Smart Appliances provides utilities and appliance manufacturers, and designers with new approaches to better understand real-world performance, assess actual energy benefits, and tailor each technology to the needs of their customers.

With contributions from a fully international group of experts, including heads of prestigious research organizations and leading universities, and innovation managers of the main appliance manufacturers, Energy Smart Appliances includes discussion on:

  • Enabling technologies for energy smart appliances, covering IoT devices and technology and active energy efficiency measures in residential environments
  • Smart home and appliances, answering questions like Where are we heading in terms of the overall smart homes' future?' and

    Table of Contents

    About the Editors xv

    List of Contributors xvii

    Acknowledgments xxi

    Introduction xxiii
    Antonio Moreno-Munoz and Neomar Giacomini

    1 Demand-Side Flexibility in Smart Grids 1
    Antonio Moreno-Munoz and Joaquin Garrido-Zafra

    1.1 The Energy Sector 1

    1.2 The Power Grid 2

    1.3 The Smart Grid 5

    1.4 Power Grid Flexibility 6

    1.4.1 The Need for Flexibility 7

    1.4.2 Sources of Flexibility 8

    1.4.2.1 Flexible Generation 8

    1.4.2.2 Flexible Transmission and Grid Interconnection 8

    1.4.2.3 Control Over VRES 9

    1.4.2.4 Energy Storage Facilities 9

    1.4.2.5 Demand-Side Management 9

    1.4.2.6 Other Sources of Flexibility 11

    1.5 Power Quality, Reliability, and Resilience 12

    1.5.1 Power Quality Disturbances 13

    1.5.1.1 Transients 14

    1.5.1.2 Short-Duration RMS Variation 16

    1.5.1.3 Long-Duration RMS Variation 17

    1.5.1.4 Imbalance 17

    1.5.1.5 Waveform Distortion 18

    1.5.1.6 Voltage Fluctuation 19

    1.5.1.7 Power Frequency Variations 19

    1.6 Economic Implications and Issues of Poor Power Quality 20

    1.7 Internet of Things 24

    1.8 The Relevance of Submetering 25

    1.9 Energy Smart Appliances 26

    Symbols and Abbreviations 28

    References 29

    2 A Deep Dive into the Smart Energy Home 35
    Neomar Giacomini

    2.1 Smart Home Ecosystem 35

    2.2 Enabling Technologies 44

    2.3 Limitations 46

    2.4 A Look into a Future Anchored in the Past 51

    2.5 Conclusion 59

    Symbols and Abbreviations 60

    Glossary 60

    References 61

    3 Household Energy Demand Management 65
    Esther Palomar, Ignacio Bravo, and Carlos Cruz

    3.1 Introduction 65

    3.2 Technical Opportunities and Challenges for DSM 67

    3.2.1 Software Solutions 67

    3.2.2 Hardware Platforms 69

    3.2.3 Communication Infrastructures 70

    3.2.4 Communication Protocols 74

    3.2.5 Security Concerns 79

    3.3 Pilots and Experimental Settings 82

    3.4 Conclusions 82

    Symbols and Abbreviations 83

    Glossary 84

    References 86

    4 Demand-Side Management and Demand Response 93
    Neyre Tekbıyık-Ersoy

    4.1 Introduction 93

    4.2 Demand Response vs. Demand-Side Management 94

    4.3 The Need for Demand Response/Demand-Side Management 94

    4.4 DSM Strategies 95

    4.4.1 Energy Efficiency/Energy Conservation 95

    4.4.2 Peak Demand Clipping 96

    4.4.3 Demand Valley Filling 96

    4.4.4 Load Shifting 97

    4.4.5 Flexible Load Shaping 97

    4.4.6 Strategic Load Growth 97

    4.5 Demand Response Programs 98

    4.5.1 Types of Loads: Elastic vs. Non-elastic 98

    4.5.2 General Approaches to Demand Response 98

    4.5.3 Smart Pricing Models for DR 99

    4.6 Smallest Communication Subsystem Enabling DSM: HAN 100

    4.6.1 General Structure 100

    4.6.2 Enabling Communication Technologies 101

    4.7 Smart Metering 102

    4.7.1 Smart Meters vs. Conventional Meters 102

    4.7.2 What Should Consumers Know About the Advanced Metering Infrastructure 104

    4.8 Energy Usage Patterns of Households 104

    4.9 Energy Consumption Scheduling 106

    4.10 Demand Response Options for Appliances 107

    4.11 Bidirectional Effects of Demand Response 108

    4.11.1 Value of Demand Response for Balancing Renewable Energy Generation 108

    4.11.2 Value of Demand Response for Reducing Household Energy Expenses 109

    4.12 Consumer Objections and Wishes Related to Smart Appliances and Demand Response 110

    4.13 Costs and Benefits of Demand-Side Management 111

    Symbols and Abbreviations 113

    Glossary 114

    References 114

    5 Standardizing Demand-Side Management: The OpenADR Standard and Complementary Protocols 117
    Rolf Bienert

    5.1 History and Creation of OpenADR 117

    5.2 Re-development of OpenADR 2.0 120

    5.3 How OpenADR Works 122

    5.3.1 Event Service (EiEvent) 125

    5.3.2 Opt Service (EiOpt) 127

    5.3.3 Report Service (EiReport) 128

    5.3.4 Registration Service (EiRegister) 128

    5.4 Cybersecurity 130

    5.5 Other Standards and Their Interaction with OpenADR and Energy Smart Appliances 131

    5.6 Energy Market Aspects for Appliances 139

    5.7 Typical DR and DSM Use Cases 140

    Symbols and Abbreviations 143

    Glossary 144

    References 144

    6 Energy Smart Appliances 147
    Neomar Giacomini

    6.1 Energy Smart Appliances 147

    6.2 Which Appliances? 148

    6.3 Smart Energy Controller 150

    6.4 Large Home Appliances 151

    6.4.1 Dishwashers 151

    6.4.2 Dryers 153

    6.4.3 Grills and Smokers 155

    6.4.4 Hvac 156

    6.4.5 Microwaves 158

    6.4.6 Refrigerators and Freezers 160

    6.4.7 Stoves, Ovens, and Cooktops 162

    6.4.8 Washing Machines 163

    6.4.9 Water Heaters 165

    6.5 Small Appliances 166

    6.5.1 Coffee Machines, Blenders, Faucets, Food Processors, Mixers, and Toasters 166

    6.5.2 Robotic Lawn Mowers and Electric Tools 167

    6.6 Monitoring 167

    6.6.1 Energy Monitors, Haptics Sensors, Weather Sensors, and Others 167

    6.7 Health, Comfort, and Care 168

    6.7.1 Air Purifiers, Humidifiers, Health Monitors, Sleep Sensors, and Tracking Devices 168

    6.7.2 Cat Litter Robots, Pet Feeders, and Other Pet-Related Connected Devices 169

    6.7.3 Hair Dryers, Brushes, and Straighteners 169

    6.7.4 Treadmills, Indoor Exercise Bike, and Other Fitness Equipment 170

    6.7.5 Water Filtration Systems 170

    6.8 House Automation 171

    6.8.1 Blinds & Shades and Light Bulbs 171

    6.8.2 Garage Door Opener 172

    6.8.3 Sprinklers, Gardening Sensors, and Accent Lighting 172

    6.8.4 Smart Power Strips and Smart Power Switches 173

    6.8.5 Presence, Proximity, and Movement Sensors 173

    6.8.6 Thermostats and Temperature Sensors 174

    6.8.7 Vacuum Cleaners, Vacuum Robots, Mop Robots, and Power Tools 174

    6.9 Non-appliances 174

    6.9.1 Electric Cars and Motorcycles 174

    6.9.2 Desktop Computers 175

    6.9.3 Modems and Routers 175

    6.9.4 Power Banks, Uninterrupted Power Supplies 176

    6.9.5 Smartphones, Tablet Computers, Smartwatches, and Video Games 176

    6.10 Entertainment 177

    6.10.1 Aquariums 177

    6.10.2 Audio Systems 177

    6.10.3 Televisions and Streaming Receivers (Cast Feature) 178

    6.10.4 Virtual Assistants (Multiple Forms) 178

    6.10.5 Virtual Reality Goggles and Other Gadgets 178

    6.11 Security 179

    6.11.1 Alarms, Cameras, Door Locks, and Doorbell Cameras 179

    6.12 Conclusion 180

    Symbols and Abbreviations 180

    Glossary 181

    References 181

    7 The ETSI SAREF Ontology for Smart Applications: A Long Path of Development and Evolution 183
    Raúl García-Castro, Maxime Lefrançois, María Poveda-Villalón, and Laura Daniele

    7.1 Introduction 183

    7.2 IoT Ontologies for Semantic Interoperability 184

    7.3 The SAREF Initiative 186

    7.4 Specification and Design of the SAREF Ontology 187

    7.4.1 A Modular and Versioned Suite of Ontologies 187

    7.4.2 Methodology 188

    7.4.3 Version Control and Editing Workflow 190

    7.4.4 Automatization of Requirements and Quality Checks 190

    7.4.5 Continuous Integration and Deployment 191

    7.5 Overview of the SAREF Ontology 191

    7.5.1 Device 193

    7.5.2 Feature of Interest and Property 194

    7.5.3 Measurement 194

    7.5.4 Service, Function, Command, and State 195

    7.6 The SAREF Ontology in the Smart Home Environment 196

    7.6.1 Energy 198

    7.6.2 Water 200

    7.6.3 Building 202

    7.6.4 City 204

    7.6.5 Systems 206

    7.7 The SAREF Ontology in Use 207

    7.8 Lessons Learnt 209

    7.8.1 Specification of Ontology Requirements 209

    7.8.2 Stakeholder’s Workshops 210

    7.8.3 Tool Support 210

    7.8.4 Ontology Modularization 211

    7.8.5 Ontology Patterns 212

    7.9 Conclusions and Future Work 212

    Acknowledgments 213

    References 213

    8 Scheduling of Residential Shiftable Smart Appliances by Metaheuristic Approaches 217
    Recep Çakmak

    8.1 Introduction 217

    8.2 Demand Response Programs in Demand-Side Management 222

    8.3 Time-Shiftable and Smart Appliances in Residences 224

    8.4 Smart Metaheuristic Algorithms 226

    8.4.1 BAT Algorithm 226

    8.4.2 Firefly Algorithm (FFA) 228

    8.4.3 Cuckoo Search Algorithm 229

    8.4.4 SOS Algorithm 231

    8.5 Scheduling of Time-Shiftable Appliances by Smart Metaheuristic Algorithms 232

    Symbols and Abbreviations 237

    Glossary 238

    References 238

    9 Distributed Operation of an Electric Vehicle Fleet in a Residential Area 243
    Alicia Triviño, Inmaculada Casaucao, and José A. Aguado

    9.1 Introduction 243

    9.2 EV Charging Stations 246

    9.3 EV Services 248

    9.3.1 Ancillary Services 248

    9.3.2 Domestic Services 248

    9.4 Dispatching Strategies for EVs 249

    9.4.1 Classification of EV Dispatching Strategies 251

    9.5 Proposed Distributed EV Dispatching Strategy 252

    9.6 Conclusions 259

    Acknowledgments 260

    References 260

    10 Electric Vehicles as Smart Appliances for Residential Energy Management 263
    Indradip Mitra, Zakir Rather, Angshu Nath, and Sahana Lokesh

    10.1 Introduction 263

    10.2 EV Charging Standards and Charging Protocols 265

    10.2.1 EV Charging Standards 265

    10.2.1.1 Iec 61851 265

    10.2.1.2 Sae J 1772 266

    10.2.1.3 Gb/t 20234 267

    10.2.2 Charging Protocols for EV Charging 267

    10.2.2.1 Type 1 AC Charger 267

    10.2.2.2 Type 2 AC Charger 268

    10.2.2.3 CHArge de MOve (CHAdeMO) Protocol 268

    10.2.2.4 Combined Charging System (CCS) 268

    10.2.2.5 Tesla Charging Protocol 268

    10.3 Communication Protocols Used in EV Ecosystem 268

    10.3.1 Open Charge Point Protocol 268

    10.3.2 Open Automated Demand Response (OpenADR) 269

    10.3.3 Open Smart Charging Protocol (OSCP) 269

    10.3.4 Ieee 2030.5 269

    10.3.5 Iso/iec 15118 269

    10.4 Residential EV Charging Infrastructure 270

    10.4.1 Prerequisites to Installation of EV Charge Point 271

    10.4.2 EV Charger Connection Requirements and Recommendations 271

    10.4.2.1 United Kingdom 271

    10.4.2.2 The Netherlands 272

    10.4.2.3 Germany 275

    10.5 Impacts of EV Charging 275

    10.5.1 Impact on Electricity Distribution Network 275

    10.5.1.1 Voltage Issues 276

    10.5.1.2 Increase in Peak Load 278

    10.5.1.3 Congestion 278

    10.5.1.4 Losses 278

    10.6 Smart Charging for Home Charging 282

    10.6.1 Type of Smart Charging 283

    10.6.2 Requirements for Smart Charging 286

    10.6.3 Additional Smart Charging Enablers 287

    10.7 Residential Smart Energy Management 289

    10.7.1 Unidirectional Smart Charging 289

    10.7.2 Vehicle-to-Home/Building 292

    10.7.3 Vehicle-to-Grid (V2G) 296

    10.8 Conclusion 297

    List of Abbreviations 297

    Glossary 298

    References 299

    11 Induction Heating Appliances: Toward More Sustainable and Smart Home Appliances 301
    Óscar Lucía, Héctor Sarnago, Jesús Acero, and José M. Burdío

    11.1 Introduction to Induction Heating 301

    11.1.1 Induction Heating Fundamentals 301

    11.1.2 Induction Heating History 304

    11.2 Domestic Induction Heating Technology 306

    11.2.1 Power Electronics 309

    11.2.2 Electromagnetic Design 314

    11.2.3 Digital Control 315

    11.2.4 Efficiency 318

    11.3 Advanced Features and Connectivity 319

    11.3.1 High-Performance Power Electronics 319

    11.3.2 Advanced Control 321

    11.3.3 Flexible Cooking Surfaces 322

    11.3.4 Connectivity 322

    11.4 Conclusion and Future Challenges 325

    Symbols and Abbreviations 325

    References 326

    Index 333

Energy Smart Appliances

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    A Hardback by Antonio Moreno-Munoz, Neomar Giacomini

      Trusted by thousands of customers. See 2,385+ Customer Reviews

      View other formats and editions of Energy Smart Appliances by Antonio Moreno-Munoz

      Publisher: John Wiley & Sons Inc
      Publication Date: 12/06/2023
      ISBN13: 9781119899426, 978-1119899426
      ISBN10: 1119899427
      Also in:
      Electronics and communications engineering

      Description

      Book Synopsis
      Energy Smart Appliances

      Enables designers and manufacturers to manage real-world energy performance and expectations by covering a range of potential scenarios and challenges

      Energy Smart Appliances provides utilities and appliance manufacturers, and designers with new approaches to better understand real-world performance, assess actual energy benefits, and tailor each technology to the needs of their customers.

      With contributions from a fully international group of experts, including heads of prestigious research organizations and leading universities, and innovation managers of the main appliance manufacturers, Energy Smart Appliances includes discussion on:

      • Enabling technologies for energy smart appliances, covering IoT devices and technology and active energy efficiency measures in residential environments
      • Smart home and appliances, answering questions like Where are we heading in terms of the overall smart homes' future?' and

        Table of Contents

        About the Editors xv

        List of Contributors xvii

        Acknowledgments xxi

        Introduction xxiii
        Antonio Moreno-Munoz and Neomar Giacomini

        1 Demand-Side Flexibility in Smart Grids 1
        Antonio Moreno-Munoz and Joaquin Garrido-Zafra

        1.1 The Energy Sector 1

        1.2 The Power Grid 2

        1.3 The Smart Grid 5

        1.4 Power Grid Flexibility 6

        1.4.1 The Need for Flexibility 7

        1.4.2 Sources of Flexibility 8

        1.4.2.1 Flexible Generation 8

        1.4.2.2 Flexible Transmission and Grid Interconnection 8

        1.4.2.3 Control Over VRES 9

        1.4.2.4 Energy Storage Facilities 9

        1.4.2.5 Demand-Side Management 9

        1.4.2.6 Other Sources of Flexibility 11

        1.5 Power Quality, Reliability, and Resilience 12

        1.5.1 Power Quality Disturbances 13

        1.5.1.1 Transients 14

        1.5.1.2 Short-Duration RMS Variation 16

        1.5.1.3 Long-Duration RMS Variation 17

        1.5.1.4 Imbalance 17

        1.5.1.5 Waveform Distortion 18

        1.5.1.6 Voltage Fluctuation 19

        1.5.1.7 Power Frequency Variations 19

        1.6 Economic Implications and Issues of Poor Power Quality 20

        1.7 Internet of Things 24

        1.8 The Relevance of Submetering 25

        1.9 Energy Smart Appliances 26

        Symbols and Abbreviations 28

        References 29

        2 A Deep Dive into the Smart Energy Home 35
        Neomar Giacomini

        2.1 Smart Home Ecosystem 35

        2.2 Enabling Technologies 44

        2.3 Limitations 46

        2.4 A Look into a Future Anchored in the Past 51

        2.5 Conclusion 59

        Symbols and Abbreviations 60

        Glossary 60

        References 61

        3 Household Energy Demand Management 65
        Esther Palomar, Ignacio Bravo, and Carlos Cruz

        3.1 Introduction 65

        3.2 Technical Opportunities and Challenges for DSM 67

        3.2.1 Software Solutions 67

        3.2.2 Hardware Platforms 69

        3.2.3 Communication Infrastructures 70

        3.2.4 Communication Protocols 74

        3.2.5 Security Concerns 79

        3.3 Pilots and Experimental Settings 82

        3.4 Conclusions 82

        Symbols and Abbreviations 83

        Glossary 84

        References 86

        4 Demand-Side Management and Demand Response 93
        Neyre Tekbıyık-Ersoy

        4.1 Introduction 93

        4.2 Demand Response vs. Demand-Side Management 94

        4.3 The Need for Demand Response/Demand-Side Management 94

        4.4 DSM Strategies 95

        4.4.1 Energy Efficiency/Energy Conservation 95

        4.4.2 Peak Demand Clipping 96

        4.4.3 Demand Valley Filling 96

        4.4.4 Load Shifting 97

        4.4.5 Flexible Load Shaping 97

        4.4.6 Strategic Load Growth 97

        4.5 Demand Response Programs 98

        4.5.1 Types of Loads: Elastic vs. Non-elastic 98

        4.5.2 General Approaches to Demand Response 98

        4.5.3 Smart Pricing Models for DR 99

        4.6 Smallest Communication Subsystem Enabling DSM: HAN 100

        4.6.1 General Structure 100

        4.6.2 Enabling Communication Technologies 101

        4.7 Smart Metering 102

        4.7.1 Smart Meters vs. Conventional Meters 102

        4.7.2 What Should Consumers Know About the Advanced Metering Infrastructure 104

        4.8 Energy Usage Patterns of Households 104

        4.9 Energy Consumption Scheduling 106

        4.10 Demand Response Options for Appliances 107

        4.11 Bidirectional Effects of Demand Response 108

        4.11.1 Value of Demand Response for Balancing Renewable Energy Generation 108

        4.11.2 Value of Demand Response for Reducing Household Energy Expenses 109

        4.12 Consumer Objections and Wishes Related to Smart Appliances and Demand Response 110

        4.13 Costs and Benefits of Demand-Side Management 111

        Symbols and Abbreviations 113

        Glossary 114

        References 114

        5 Standardizing Demand-Side Management: The OpenADR Standard and Complementary Protocols 117
        Rolf Bienert

        5.1 History and Creation of OpenADR 117

        5.2 Re-development of OpenADR 2.0 120

        5.3 How OpenADR Works 122

        5.3.1 Event Service (EiEvent) 125

        5.3.2 Opt Service (EiOpt) 127

        5.3.3 Report Service (EiReport) 128

        5.3.4 Registration Service (EiRegister) 128

        5.4 Cybersecurity 130

        5.5 Other Standards and Their Interaction with OpenADR and Energy Smart Appliances 131

        5.6 Energy Market Aspects for Appliances 139

        5.7 Typical DR and DSM Use Cases 140

        Symbols and Abbreviations 143

        Glossary 144

        References 144

        6 Energy Smart Appliances 147
        Neomar Giacomini

        6.1 Energy Smart Appliances 147

        6.2 Which Appliances? 148

        6.3 Smart Energy Controller 150

        6.4 Large Home Appliances 151

        6.4.1 Dishwashers 151

        6.4.2 Dryers 153

        6.4.3 Grills and Smokers 155

        6.4.4 Hvac 156

        6.4.5 Microwaves 158

        6.4.6 Refrigerators and Freezers 160

        6.4.7 Stoves, Ovens, and Cooktops 162

        6.4.8 Washing Machines 163

        6.4.9 Water Heaters 165

        6.5 Small Appliances 166

        6.5.1 Coffee Machines, Blenders, Faucets, Food Processors, Mixers, and Toasters 166

        6.5.2 Robotic Lawn Mowers and Electric Tools 167

        6.6 Monitoring 167

        6.6.1 Energy Monitors, Haptics Sensors, Weather Sensors, and Others 167

        6.7 Health, Comfort, and Care 168

        6.7.1 Air Purifiers, Humidifiers, Health Monitors, Sleep Sensors, and Tracking Devices 168

        6.7.2 Cat Litter Robots, Pet Feeders, and Other Pet-Related Connected Devices 169

        6.7.3 Hair Dryers, Brushes, and Straighteners 169

        6.7.4 Treadmills, Indoor Exercise Bike, and Other Fitness Equipment 170

        6.7.5 Water Filtration Systems 170

        6.8 House Automation 171

        6.8.1 Blinds & Shades and Light Bulbs 171

        6.8.2 Garage Door Opener 172

        6.8.3 Sprinklers, Gardening Sensors, and Accent Lighting 172

        6.8.4 Smart Power Strips and Smart Power Switches 173

        6.8.5 Presence, Proximity, and Movement Sensors 173

        6.8.6 Thermostats and Temperature Sensors 174

        6.8.7 Vacuum Cleaners, Vacuum Robots, Mop Robots, and Power Tools 174

        6.9 Non-appliances 174

        6.9.1 Electric Cars and Motorcycles 174

        6.9.2 Desktop Computers 175

        6.9.3 Modems and Routers 175

        6.9.4 Power Banks, Uninterrupted Power Supplies 176

        6.9.5 Smartphones, Tablet Computers, Smartwatches, and Video Games 176

        6.10 Entertainment 177

        6.10.1 Aquariums 177

        6.10.2 Audio Systems 177

        6.10.3 Televisions and Streaming Receivers (Cast Feature) 178

        6.10.4 Virtual Assistants (Multiple Forms) 178

        6.10.5 Virtual Reality Goggles and Other Gadgets 178

        6.11 Security 179

        6.11.1 Alarms, Cameras, Door Locks, and Doorbell Cameras 179

        6.12 Conclusion 180

        Symbols and Abbreviations 180

        Glossary 181

        References 181

        7 The ETSI SAREF Ontology for Smart Applications: A Long Path of Development and Evolution 183
        Raúl García-Castro, Maxime Lefrançois, María Poveda-Villalón, and Laura Daniele

        7.1 Introduction 183

        7.2 IoT Ontologies for Semantic Interoperability 184

        7.3 The SAREF Initiative 186

        7.4 Specification and Design of the SAREF Ontology 187

        7.4.1 A Modular and Versioned Suite of Ontologies 187

        7.4.2 Methodology 188

        7.4.3 Version Control and Editing Workflow 190

        7.4.4 Automatization of Requirements and Quality Checks 190

        7.4.5 Continuous Integration and Deployment 191

        7.5 Overview of the SAREF Ontology 191

        7.5.1 Device 193

        7.5.2 Feature of Interest and Property 194

        7.5.3 Measurement 194

        7.5.4 Service, Function, Command, and State 195

        7.6 The SAREF Ontology in the Smart Home Environment 196

        7.6.1 Energy 198

        7.6.2 Water 200

        7.6.3 Building 202

        7.6.4 City 204

        7.6.5 Systems 206

        7.7 The SAREF Ontology in Use 207

        7.8 Lessons Learnt 209

        7.8.1 Specification of Ontology Requirements 209

        7.8.2 Stakeholder’s Workshops 210

        7.8.3 Tool Support 210

        7.8.4 Ontology Modularization 211

        7.8.5 Ontology Patterns 212

        7.9 Conclusions and Future Work 212

        Acknowledgments 213

        References 213

        8 Scheduling of Residential Shiftable Smart Appliances by Metaheuristic Approaches 217
        Recep Çakmak

        8.1 Introduction 217

        8.2 Demand Response Programs in Demand-Side Management 222

        8.3 Time-Shiftable and Smart Appliances in Residences 224

        8.4 Smart Metaheuristic Algorithms 226

        8.4.1 BAT Algorithm 226

        8.4.2 Firefly Algorithm (FFA) 228

        8.4.3 Cuckoo Search Algorithm 229

        8.4.4 SOS Algorithm 231

        8.5 Scheduling of Time-Shiftable Appliances by Smart Metaheuristic Algorithms 232

        Symbols and Abbreviations 237

        Glossary 238

        References 238

        9 Distributed Operation of an Electric Vehicle Fleet in a Residential Area 243
        Alicia Triviño, Inmaculada Casaucao, and José A. Aguado

        9.1 Introduction 243

        9.2 EV Charging Stations 246

        9.3 EV Services 248

        9.3.1 Ancillary Services 248

        9.3.2 Domestic Services 248

        9.4 Dispatching Strategies for EVs 249

        9.4.1 Classification of EV Dispatching Strategies 251

        9.5 Proposed Distributed EV Dispatching Strategy 252

        9.6 Conclusions 259

        Acknowledgments 260

        References 260

        10 Electric Vehicles as Smart Appliances for Residential Energy Management 263
        Indradip Mitra, Zakir Rather, Angshu Nath, and Sahana Lokesh

        10.1 Introduction 263

        10.2 EV Charging Standards and Charging Protocols 265

        10.2.1 EV Charging Standards 265

        10.2.1.1 Iec 61851 265

        10.2.1.2 Sae J 1772 266

        10.2.1.3 Gb/t 20234 267

        10.2.2 Charging Protocols for EV Charging 267

        10.2.2.1 Type 1 AC Charger 267

        10.2.2.2 Type 2 AC Charger 268

        10.2.2.3 CHArge de MOve (CHAdeMO) Protocol 268

        10.2.2.4 Combined Charging System (CCS) 268

        10.2.2.5 Tesla Charging Protocol 268

        10.3 Communication Protocols Used in EV Ecosystem 268

        10.3.1 Open Charge Point Protocol 268

        10.3.2 Open Automated Demand Response (OpenADR) 269

        10.3.3 Open Smart Charging Protocol (OSCP) 269

        10.3.4 Ieee 2030.5 269

        10.3.5 Iso/iec 15118 269

        10.4 Residential EV Charging Infrastructure 270

        10.4.1 Prerequisites to Installation of EV Charge Point 271

        10.4.2 EV Charger Connection Requirements and Recommendations 271

        10.4.2.1 United Kingdom 271

        10.4.2.2 The Netherlands 272

        10.4.2.3 Germany 275

        10.5 Impacts of EV Charging 275

        10.5.1 Impact on Electricity Distribution Network 275

        10.5.1.1 Voltage Issues 276

        10.5.1.2 Increase in Peak Load 278

        10.5.1.3 Congestion 278

        10.5.1.4 Losses 278

        10.6 Smart Charging for Home Charging 282

        10.6.1 Type of Smart Charging 283

        10.6.2 Requirements for Smart Charging 286

        10.6.3 Additional Smart Charging Enablers 287

        10.7 Residential Smart Energy Management 289

        10.7.1 Unidirectional Smart Charging 289

        10.7.2 Vehicle-to-Home/Building 292

        10.7.3 Vehicle-to-Grid (V2G) 296

        10.8 Conclusion 297

        List of Abbreviations 297

        Glossary 298

        References 299

        11 Induction Heating Appliances: Toward More Sustainable and Smart Home Appliances 301
        Óscar Lucía, Héctor Sarnago, Jesús Acero, and José M. Burdío

        11.1 Introduction to Induction Heating 301

        11.1.1 Induction Heating Fundamentals 301

        11.1.2 Induction Heating History 304

        11.2 Domestic Induction Heating Technology 306

        11.2.1 Power Electronics 309

        11.2.2 Electromagnetic Design 314

        11.2.3 Digital Control 315

        11.2.4 Efficiency 318

        11.3 Advanced Features and Connectivity 319

        11.3.1 High-Performance Power Electronics 319

        11.3.2 Advanced Control 321

        11.3.3 Flexible Cooking Surfaces 322

        11.3.4 Connectivity 322

        11.4 Conclusion and Future Challenges 325

        Symbols and Abbreviations 325

        References 326

        Index 333

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