ISBN-13: 9781119063643 / Angielski / Twarda / 2018 / 560 str.
ISBN-13: 9781119063643 / Angielski / Twarda / 2018 / 560 str.
Empowers engineering professionals and students with the knowledge and skills required to engineer electric vehicle powertrain architectures, energy storage systems, power electronics converters and electric drives.
Hayes and Goodarzi have focused their considerable talent and experience to teaching the inner workings of the electric car. Readers, whether engineers, students, or the interested public will find this book a treasure trove of knowledge on modern automotive technology. In conclusion, what a great book! John M Miller, J–N–J Miller Design Services PLLC, Longview, Texas, USA
I highly recommend ′Electric Powertrain: Energy Systems, Power Electronics and Drives for Hybrid, Electric and Fuel Cell Vehicles′ by Dr John G. Hayes and Dr G. Abas Goodarzi. I use this book as my core teaching text on my module Transportation Power and Systems 3, which I teach to third year BEng and MEng Mechanical Engineering undergraduates in Queen′s University Belfast. This book captures the fundamentals and in–depth aspects of the key elements of the course I teach including drive cycles, power trains for hybrids, vehicle dynamics, batteries and machines. The worked examples are excellent. The text book is very well laid out with superb well thought–out practical problems at the end of each chapter. This book is very relevant to those who wish to expand their knowledge of hybrid vehicles. It seamlessly integrates the electrical, civil and mechanical disciplines in this growing and multidisciplinary area. This is especially important considering the sustainable direction of land–based transport will take over the next decade as we strive to combat global warming and reduce greenhouse gas emissions. Dr Aoife Foley, School of Mechanical and Aerospace Engineering, Queen′s University Belfast, United Kingdom
Contents
Preface xix
Acknowledgments xxi
Textbook Structure and Suggested Teaching Curriculum xxii
About the Companion Web Site xxiv
Part 1 Vehicles and Energy Sources 1
1 Electromobility and the Environment 3
1.1 A Brief History of the Electric Powertrain 4
1.1.1 Part I The Birth of the Electric Car 4
1.1.2 Part II The Resurgent Electric Powertrain 5
1.1.3 Part III Success at Last for the Electric Powertrain 6
1.2 Energy Sources for Propulsion and Emissions 10
1.2.1 Carbon Emissions from Fuels 12
1.2.1.1 Example: Carbon Dioxide Emissions from the Combustion of Gasoline 12
1.2.2 Greenhouse Gases and Pollutants 13
1.2.2.1 The Impact of NOx 14
1.3 The Advent of Regulations 15
1.3.1 Regulatory Considerations and Emissions Trends 17
1.3.2 Heavy–Duty Vehicle Regulations 18
1.4 Drive Cycles 19
1.4.1 EPA Drive Cycles 19
1.5 BEV Fuel Consumption, Range, and mpge 24
1.6 Carbon Emissions for Conventional and Electric Powertrains 25
1.6.1 Well–to–Wheel and Cradle–to–Grave Emissions 27
1.6.2 Emissions due to the Electrical Grid 28
1.6.2.1 Example: Determining Electrical Grid Emissions 28
1.7 An Overview of Conventional, Battery, Hybrid, and Fuel Cell Electric Systems 29
1.7.1 Conventional IC Engine Vehicle 30
1.7.2 BEVs 30
1.7.3 HEVs 31
1.7.3.1 Series HEV 32
1.7.3.2 Parallel HEV 32
1.7.3.3 Series–Parallel HEV 33
1.7.4 FCEV 33
1.7.5 A Comparison by Efficiency of Conventional, Hybrid, Battery, and Fuel Cell Vehicles 34
1.7.6 A Case Study Comparison of Conventional, Hybrid, Battery, and Fuel Cell Vehicles 35
1.8 A Comparison of Automotive and Other Transportation Technologies 36
References 37
Further Reading 38
Problems 38
Assignments 39
2 Vehicle Dynamics 40
2.1 Vehicle Load Forces 40
2.1.1 Basic Power, Energy, and Speed Relationships 41
2.1.2 Aerodynamic Drag 42
2.1.2.1 Example: Aerodynamic Drag 43
2.1.2.2 Example: Aerodynamic Drag and Fuel Consumption 45
2.1.3 Rolling Resistance 45
2.1.3.1 The Ford Explorer Recall 45
2.1.3.2 The A–Class Mercedes in the 1990s 46
2.1.3.3 The Tesla Model S in 2013 46
2.1.3.4 Example: Rolling Resistance 46
2.1.4 Vehicle Road–Load Coefficients from EPA Coast–Down Testing 46
2.1.5 Battery Electric Vehicle Range at Constant Speed 49
2.1.5.1 Example: Plot of BEV Range Versus Speed 49
2.1.5.2 Example: Estimate of BEV Range 50
2.1.5.3 Example: Effect of Auxiliary Loads on Range 50
2.1.6 Gradability 51
2.1.6.1 Example: Downgrade Force and Regeneration 51
2.2 Vehicle Acceleration 52
2.2.1 Regenerative Braking of the Vehicle 54
2.2.2 Traction Motor Characteristics 54
2.2.2.1 Example: 2015 Nissan Leaf Rated Speed 55
2.2.3 Acceleration of the Vehicle 57
2.2.3.1 Time–Step Estimation of Vehicle Speed 57
2.2.3.2 A Simplified Equation Set for Characterizing Acceleration by Ignoring Load Forces 57
2.3 Simple Drive Cycle for Vehicle Comparisons 60
References 62
Further Reading 62
Problems 62
Assignment: Modeling of a BEV 66
3 Batteries 68
3.1 Introduction to Batteries 68
3.1.1 Batteries Types and Battery Packs 68
3.1.1.1 Recent EVs and Battery Chemistries 70
3.1.2 Basic Battery Operation 73
3.1.3 Basic Electrochemistry 74
3.1.3.1 Lead–Acid Battery 74
3.1.3.2 Nickel–Metal Hydride 75
3.1.3.3 Lithium–Ion 76
3.1.4 Units of Battery Energy Storage 76
3.1.5 Capacity Rate 77
3.1.5.1 Example of the 2011 Nissan Leaf Battery Pack 78
3.1.6 Battery Parameters and Comparisons 79
3.1.6.1 Cell Voltage 79
3.1.6.2 Specific Energy 80
3.1.6.3 Cycle Life 80
3.1.6.4 Specific Power 81
3.1.6.5 Self–Discharge 81
3.2 Lifetime and Sizing Considerations 81
3.2.1 Examples of Battery Sizing 84
3.2.1.1 Example: BEV Battery Sizing 84
3.2.1.2 Example: PHEV Battery Sizing 85
3.2.2 Battery Pack Discharge Curves and Aging 86
3.3 Battery Charging, Protection, and Management Systems 88
3.3.1 Battery Charging 88
3.3.2 Battery Failure and Protection 88
3.3.3 Battery Management System 89
3.4 Battery Models 90
3.4.1 A Simple Novel Curve Fit Model for BEV Batteries 92
3.4.2 Voltage, Current, Resistance, and Efficiency of Battery Pack 95
3.4.2.1 Example: Determining the Pack Voltage Range for a BEV 96
3.4.3 A Simple Curve–Fit Model for HEV Batteries 96
3.4.3.1 Example: Determining the Pack Voltage Range for a HEV 97
3.4.4 Charging 97
3.4.4.1 Example: Fast Charging a Battery Pack 98
3.4.5 Determining the Cell/Pack Voltage for a Given Output\Input Power 99
3.4.5.1 Example: Battery Discharge 99
3.4.5.2 Example: Battery Charge 100
3.4.6 Cell Energy and Discharge Rate 100
3.4.6.1 Example: Cell Capacity 101
3.5 Example: The Fuel Economy of a BEV Vehicle with a Fixed Gear Ratio 102
References 105
Further Reading 106
Problems 106
Appendix: A Simplified Curve–Fit Model for BEV Batteries 108
4 Fuel Cells 111
4.1 Introduction to Fuel Cells 111
4.1.1 Fuel Cell Vehicle Emissions and Upstream Emissions 113
4.1.2 Hydrogen Safety Factors 113
4.2 Basic Operation 114
4.2.1 Fuel Cell Model and Cell Voltage 116
4.2.1.1 Example: No–Load and Load Voltages of a PEM Fuel Cell 117
4.2.2 Power and Efficiency of Fuel Cell and Fuel Cell Power Plant System 118
4.2.2.1 Example: Full–Load Power and Efficiency of PEM Fuel Cell Stack 118
4.2.3 Fuel Cell Characteristic Curves 119
4.3 Sizing the Fuel Cell Plant 120
4.3.1 Example: Sizing a Fuel Cell 121
4.3.2 Toyota Mirai 121
4.3.3 Balance of Plant 121
4.3.4 Boost DC–DC Converter 122
4.4 Fuel Cell Aging 122
4.5 Example: Sizing Fuel Cell System for Heavy Goods Tractor Trailer Combination 124
4.6 Example: Fuel Economy of Fuel Cell Electric Vehicle 126
References 129
Problems 129
Assignments 130
5 Conventional and Hybrid Powertrains 131
5.1 Introduction to HEVs 131
5.2 Brake Specific Fuel Consumption 134
5.2.1 Example: Energy Consumption, Power Output, Efficiency, and BSFC 135
5.3 Comparative Examples of Conventional, Series, and Series–Parallel Hybrid Systems 138
5.3.1 Example: Fuel Economy of IC Engine Vehicle with Gasoline or Diesel Engine 138
5.3.2 Example: Fuel Economy of Series HEV 144
5.3.3 Example: Fuel Economy of Series–Parallel HEV 146
5.3.4 Summary of Comparisons 148
5.4 The Planetary Gears as a Power–Split Device 148
5.4.1 Powertrain of 2004 Toyota Prius 150
5.4.2 Example: CVT Operating in Electric Drive Mode (Vehicle Launch and Low Speeds) 151
5.4.3 Example: CVT Operating in Full–Power Mode 153
5.4.4 Example: CVT Operating in Cruising and Generating Mode 154
References 155
Problems 155
Assignments 156
Part 2 Electrical Machines 159
6 Introduction to Traction Machines 161
6.1 Propulsion Machine Overview 161
6.1.1 DC Machines 162
6.1.2 AC Machines 163
6.1.3 Comparison of Traction Machines 167
6.1.4 Case Study Mars Rover Traction Motor 169
6.2 Machine Specifications 170
6.2.1 Four–Quadrant Operation 170
6.2.2 Rated Parameters 171
6.2.3 Rated Torque 172
6.2.4 Rated and Base Speeds 172
6.2.5 Rated Power 172
6.2.6 Peak Operation 173
6.2.7 Starting Torque 173
6.3 Characteristic Curves of a Machine 173
6.3.1 Constant–Torque Mode 173
6.3.2 Constant–Power Mode 174
6.3.3 Maximum–Speed Mode 174
6.3.4 Efficiency Maps 174
6.4 Conversion Factors of Machine Units 176
References 177
7 The Brushed DC Machine 178
7.1 DC Machine Structure 178
7.2 DC Machine Electrical Equivalent Circuit 180
7.3 DC Machine Circuit Equations 182
7.3.1 No–Load Spinning Loss 183
7.3.2 No–Load Speed 184
7.3.3 Maximum Power 184
7.3.4 Rated Conditions 184
7.4 Power, Losses, and Efficiency in the PM DC Machine 185
7.5 Machine Control using Power Electronics 186
7.5.1 Example: Motoring using a PM DC Machine 186
7.6 Machine Operating as a Motor or Generator in Forward or Reverse Modes 189
7.6.1 Example: Generating/Braking using a PM DC Machine 190
7.6.2 Example: Motoring in Reverse 191
7.7 Saturation and Armature Reaction 191
7.7.1 Example: Motoring using PM DC Machine and Machine Saturation 192
7.8 Using PM DC Machine for EV Powertrain 193
7.8.1 Example: Maximum Speeds using PM DC Machine 194
7.9 Using WF DC Machine for EV Powertrain 195
7.9.1 Example: Motoring using WF DC Machine 197
7.10 Case Study Mars Rover Traction Machine 199
7.11 Thermal Characteristics of Machine 201
7.11.1 Example of Steady–State Temperature Rise 202
7.11.2 Transient Temperature Rise 203
7.11.3 Example of Transient Temperature Rise 203
References 204
Problems 204
8 Induction Machines 206
8.1 Stator Windings and the Spinning Magnetic Field 207
8.1.1 Stator Magnetic Flux Density 209
8.1.2 Space–Vector Current and the Rotating Magnetic Field 211
8.2 Induction Machine Rotor Voltage, Current, and Torque 216
8.2.1 Rotor Construction 216
8.2.2 Induction Machine Theory of Operation 216
8.3 Machine Model and Steady–State Operation 219
8.3.1 Power in Three–Phase Induction Machine 222
8.3.2 Torque in Three–Phase Induction Machine 223
8.3.3 Phasor Analysis of Induction Motor 225
8.3.4 Machine Operation When Supplied by Current Source 225
8.3.4.1 Example: Motoring at Rated Speed using Induction Machine 228
8.3.4.2 Example: Motoring at Rated Speed using Induction Machine Ignoring Leakage 231
8.3.4.3 Example: Generating at Rated Speed using Induction Machine 232
8.4 Variable–Speed Operation of Induction Machine 234
8.4.1 Constant Volts per hertz Operation 235
8.4.1.1 Example: Maintaining a Constant Volts per Hertz 235
8.4.2 Variable–Speed Operation 235
8.4.2.1 Example: Field–Weakened Motoring at Twice the Rated Speed using Induction Machine 236
8.4.2.2 Example: Stall/Start–Up using Induction Machine 238
8.4.2.3 Effects of Rotor Heating 240
8.5 Machine Test 240
8.5.1 DC Resistance Test 240
8.5.2 Locked–Rotor Test 240
8.5.3 No–Load Test 242
8.5.3.1 Example of Machine Characterization 243
References 244
Further Reading 244
Problems 245
Sample MATLAB Code 246
9 Surface–Permanent–Magnet AC Machines 249
9.1 Basic Operation of SPM Machines 249
9.1.1 Back EMF of a Single Coil 249
9.1.2 Back EMF of Single Phase 250
9.1.2.1 The Experimental Back EMF 253
9.1.2.2 Distributed Winding 253
9.1.3 SPM Machine Equations 253
9.1.3.1 Example: Phase Voltage of SPM Machine 255
9.2 Per–Phase Analysis of SPM Machine 255
9.2.1 Per–Phase Equivalent Circuit Model for SPM Machine 256
9.2.2 Phasor Analysis of SPM Machine 257
9.2.2.1 Example: Motoring using SPM Machine 260
9.2.3 Machine Saturation 263
9.2.3.1 Example: Motoring using SPM Machine 263
9.2.4 SPM Torque Speed Characteristics 264
9.2.4.1 Example: Determining No–Load Speed 265
9.2.5 High–Speed Operation of SPM Machine above Rated Speed 266
9.2.5.1 Example: Motoring using SPM Machine in Field Weakening 269
9.2.6 Machine Characteristics for Field–Weakened Operation 270
References 272
Further Reading 273
Problems 273
MATLAB Code 274
10 Interior–Permanent–Magnet AC Machine 276
10.1 Machine Structure and Torque Equations 276
10.2 d– and q–Axis Inductances 278
10.2.1 Example: Estimating the d–axis and q–axis Inductances for 2004 Toyota Prius Motor 281
10.3 IPM Machine Test 281
10.3.1 No–Load Spin Test 282
10.3.2 DC Torque Test 282
10.4 Basic Theory and Low–Speed Operation 286
10.4.1 Example: Motoring at Rated Condition 287
10.4.2 Maximum Torque per Ampere (MTPA) 289
10.4.3 Maximum Torque per Volt (MTPV) or Maximum Torque per Flux (MTPF) 289
10.5 High–Speed Operation of IPM Machine 289
10.5.1 Example: Motoring at High Speed using IPM Machine 289
10.6 dq Modeling of Machines 291
10.6.1 Constant Current Transformation 292
10.6.2 Constant Power Transformation 294
References 295
Further Reading 295
Problems 296
Assignments 298
Part 3 Power Electronics 299
11 DC–DC Converters 301
11.1 Introduction 301
11.2 Power Conversion Common and Basic Principles 304
11.2.1 The Basic Topologies 306
11.2.2 The Half–Bridge Buck–Boost Bidirectional Converter 307
11.3 The Buck or Step–Down Converter 307
11.3.1 Analysis of Voltage Gain of Buck Converter in CCM 309
11.3.1.1 Analysis of Buck Converter in CCM 311
11.3.1.2 Determining Low–Voltage Capacitor RMS Current 312
11.3.1.3 Capacitor Voltages 314
11.3.1.4 Example: Designing Buck Converter for CCM Operation 315
11.3.2 BCM Operation of Buck Converter 317
11.3.2.1 Example of Buck in BCM 317
11.3.3 DCM Operation of Buck Converter 319
11.3.3.1 Example: Buck Converter in DCM Operation 324
11.4 The Boost or Step–up Converter 325
11.4.1 Analysis of Voltage Gain of Boost Converter in CCM 326
11.4.1.1 Analysis of Boost Converter in CCM 327
11.4.1.2 Example: Analyzing Boost for CCM Operation 329
11.4.2 BCM Operation of Boost Converter 330
11.4.2.1 Example: Boost Converter in BCM 332
11.4.3 DCM Operation of Boost Converter 332
11.4.3.1 Example: Boost Converter in DCM Operation 335
11.5 Power Semiconductors 336
11.5.1 Power Semiconductor Power Loss 337
11.5.1.1 Conduction Losses of IGBT and Diode 337
11.5.1.2 Example: Boost IGBT Conduction Losses 339
11.5.1.3 Switching Losses of IGBT and Diode 339
11.5.1.4 Example: Switching Losses of IGBT Module 340
11.5.2 Total Semiconductor Power Loss and Junction Temperature 341
11.5.2.1 Example: Total IGBT Module Loss and Die Temperatures 342
11.6 Passive Components for Power Converters 342
11.6.1 Example: Inductor Sizing 342
11.6.2 Capacitor Sizing 343
11.6.2.1 Example: Capacitor Sizing 343
11.7 Interleaving 343
11.7.1 Example: Two–Phase Interleaved Boost Converter 345
References 346
Further Reading 346
Problems 346
Assignments 349
Appendix I 349
Appendix II: Buck–Boost Converter 349
12 Isolated DC–DC Converters 353
12.1 Introduction 353
12.1.1 Advantages of Isolated Power Converters 353
12.1.2 Power Converter Families 354
12.2 The Forward Converter 355
12.2.1 CCM Currents in Forward Converter 357
12.2.1.1 Example: Current Ratings in Medium–Power Forward Converter 360
12.2.2 CCM Voltages in Forward Converter 362
12.2.2.1 Example: Voltage Ratings in a Medium–Power Forward Converter 364
12.2.3 Sizing the Transformer 365
12.2.3.1 Example: AP of a Forward Converter Transformer 365
12.3 The Full–Bridge Converter 365
12.3.1 Operation of Hard–Switched Full–Bridge Converter 367
12.3.2 CCM Currents in Full–Bridge Converter 370
12.3.2.1 Example: Current Ratings in a Medium–Power Full–Bridge Converter 373
12.3.3 CCM Voltages in the Full–Bridge Converter 376
12.3.3.1 Example: Voltage Ratings in a Full–Bridge Converter 376
12.4 Resonant Power Conversion 377
12.4.1 LCLC Series–Parallel Resonant Converter 377
12.4.2 Desirable Converter Characteristics for Inductive Charging 378
12.4.2.1 Basic Converter Operation 379
12.4.2.2 Design Considerations 381
12.4.3 Fundamental–Mode Analysis and Current–Source Operation 381
12.4.3.1 Example 384
12.4.4 Simulation 385
References 388
Further Reading 388
Problems 388
Assignments 390
Appendix I: RMS and Average Values of Ramp and Step Waveforms 390
Appendix II: Flyback Converter 391
13 Traction Drives and Three–Phase Inverters 392
13.1 Three–Phase Inverters 392
13.2 Modulation Schemes 393
13.2.1 Sinusoidal Modulation 395
13.2.2 Sinusoidal Modulation with Third Harmonic Addition 396
13.2.3 Overmodulation and Square Wave 398
13.2.3.1 Example: AC Voltages Available from DC Link 398
13.3 Sinusoidal Modulation 398
13.3.1 Modulation Index m 399
13.3.2 Inverter Currents 401
13.3.3 Switch, Diode, and Input Average Currents 401
13.3.4 Switch, Diode, DC Link, and Input Capacitor RMS Currents 403
13.3.5 Example: Inverter Currents 404
13.4 Inverter Power Loss 405
13.4.1 Conduction Loss of IGBT and Diode 405
13.4.2 Switching Loss of IGBT Module 405
13.4.2.1 Example: Power Losses of Power Semiconductor Module 405
13.4.3 Total Semiconductor Power Loss and Junction Temperature 407
13.4.3.1 Example: Total IGBT Module Loss and Die Temperatures 408
13.4.4 Example: Regenerative Currents 408
References 409
Further Reading 409
Problems 410
Assignments 410
14 Battery Charging 412
14.1 Basic Requirements for Charging System 412
14.2 Charger Architectures 414
14.3 Grid Voltages, Frequencies, and Wiring 416
14.4 Charger Functions 418
14.4.1 Real Power, Apparent Power, and Power Factor 419
14.5 Charging Standards and Technologies 422
14.5.1 SAE J1772 422
14.5.2 VDE–AR–E 2623–2–2 425
14.5.3 CHAdeMo 425
14.5.4 Tesla 425
14.5.5 Wireless Charging 425
14.5.5.1 Inductive 425
14.5.5.2 Wireless 427
14.6 The Boost Converter for Power Factor Correction 427
14.6.1 The Boost PFC Power Stage 428
14.6.2 Sizing the Boost Inductor 430
14.6.2.1 Example: Sizing the Inductor 430
14.6.3 Average Currents in the Rectifier 431
14.6.3.1 Example: Input Rectifier Power Loss 432
14.6.4 Switch and Diode Average Currents 432
14.6.5 Switch, Diode, and Capacitor RMS Currents 434
14.6.6 Power Semiconductors for Charging 434
14.6.6.1 Example: Silicon MOSFET and SiC Diode Power Losses 435
14.6.6.2 Example: PFC Stage Losses 437
References 438
Further Reading 438
Problems 439
Assignments 440
15 Control of the Electric Drive 441
15.1 Introduction to Control 441
15.1.1 Feedback Controller Design Approach 442
15.2 Modeling the Electromechanical System 443
15.2.1 The Mechanical System 443
15.2.2 The PM DC Machine 446
15.2.3 The DC–DC Power Converter 447
15.2.4 The PI Controller 447
15.3 Designing Torque Loop Compensation 448
15.3.1 Example: Determining Compensator Gain Coefficients for Torque Loop 449
15.4 Designing Speed Control Loop Compensation 449
15.4.1 Example: Determining Compensator Gain Coefficients for Speed Loop 451
15.5 Acceleration of Battery Electric Vehicle (BEV) using PM DC Machine 451
15.6 Acceleration of BEV using WF DC Machine 452
References 455
Problems 455
Assignment and Sample MATLAB Codes 456
Part 4 Electromagnetism 459
16 Introduction to Electromagnetism, Ferromagnetism, and Electromechanical Energy Conversion 461
16.1 Electromagnetism 462
16.1.1 Maxwell s Equations 462
16.1.1.1 Ampere s Circuital Law (Based on Ampere Maxwell Law) 463
16.1.1.2 Right Hand Screw Rule: Direction of Magnetic Flux 464
16.1.1.3 Magnetic Flux Density Vector (B) 465
16.1.1.4 Magnetic Flux 465
16.1.1.5 Gauss Law for Magnetism 466
16.2 Ferromagnetism 467
16.2.1 Magnetism and Hysteresis 467
16.2.2 Hard and Soft Ferromagnetic Materials 470
16.2.2.1 Soft Ferromagnetic Materials 470
16.2.2.2 A Review of Commonly Used Soft Ferromagnetic Materials 471
16.3 Self–Inductance 473
16.3.1 Basic Inductor Operation 474
16.3.2 Inductor Equations 475
16.3.2.1 Example: A Gapped Inductor 477
16.3.2.2 Inductance Variation with Magnetization Curve 477
16.3.3 Reluctance 478
16.3.3.1 Example: A Gapless Inductor 480
16.3.3.2 Reluctance of Gapped Magnetic Structures 480
16.3.3.3 Example: Reluctances of Gapped Inductor 481
16.3.4 Energy Stored in Magnetic Field 481
16.3.4.1 Example: Inductor Energy Storage 482
16.3.5 Core Loss 482
16.3.5.1 Hysteresis Loss 482
16.3.5.2 Eddy Current Loss 483
16.3.5.3 Core Loss 484
16.3.5.4 Example: Core Loss 484
16.3.5.5 Core Loss Equivalent Parallel Resistance 484
16.3.6 Copper Loss 484
16.3.6.1 Copper Loss of Wire 485
16.3.6.2 Example: Copper Loss 485
16.3.6.3 Copper Loss of CC Core with Helical Winding 485
16.3.6.4 Example: MLT of Winding 486
16.3.7 Inductor Sizing using Area Product 487
16.3.8 High–Frequency Operation and Skin Depth 488
16.4 Hard Ferromagnetic Materials and Permanent Magnets 489
16.4.1 Example: Remanent Flux Density 490
16.4.2 Example: The Recoil Line 492
16.4.3 Example: Air Gap Flux Density due to a Permanent Magnet 494
16.4.4 Maximum Energy Product 494
16.4.5 Force due to Permanent Magnet 494
16.4.5.1 Example: Lifting Force of Magnet with no Gap 496
16.4.5.2 Example: Lifting Force of Magnet with Gap 496
16.4.6 Electromagnet 497
16.4.6.1 Example: Air Gap Flux Density due to Field Winding 497
16.5 The Transformer 498
16.5.1 Theory of Operation 498
16.5.2 Transformer Equivalent Circuit 500
16.5.3 Transformer Voltages and Currents 501
16.5.3.1 Exciting the Transformer with Sinusoidal Wave 503
16.5.3.2 Example: Induction Machine Magnetizing Current 504
16.5.3.3 Exciting the Transformer with a Square Wave Voltage 504
16.5.3.4 Example: High–Frequency Transformer 505
16.5.4 Sizing the Transformer using the Area–Product (AP) Method 505
16.6 The Capacitor 506
16.6.1 Sizing Polypropylene High–Voltage Capacitor 508
16.7 Electromechanical Energy Conversion 509
16.7.1 Ampere s Force Law 509
16.7.1.1 Fleming s Left Hand Rule 509
16.7.2 General Expression for Torque on Current–Carrying Coil 510
16.7.3 Torque, Flux Linkage, and Current 511
16.7.4 Faraday s Law of Electromagnetic Induction 512
16.7.5 Lenz s Law and Fleming s Right Hand Rule 512
References 513
Further Reading 514
Further Viewing 515
Problems 515
Assignments 518
Reference Conversion Table 519
Index 521
John G. Hayes, PhD, MSEE, MBA, lectures at University College Cork, Ireland, and specialises in automotive, industrial and renewable energy systems and related power electronics, machines and electromagnetism. He previously worked in Southern California for ten years at General Motors′ Hughes Aircraft subsidiary developing EV propulsion and inductive charging systems for the General Motors EV1, the first modern production EV. John′s recent focus has been on the development of integrated and holistic EV teaching materials for the engineering student and the automotive professional.
G. Abas Goodarzi, PhD, P.E., is the Chief Executive Officer and President of US Hybrid Corporation, Torrance, California, which he founded in 1999. He is also the President of US FuelCell, a company formed with the acquisition by US Hybrid of the United Technologies PEM fuel cell transportation division. He served as Senior Scientist at General Motors′ Hughes Aircraft subsidiary, and as Technical Director for the General Motors EV1. He has designed various EV, HEV, and FCEV powertrain systems for light, medium, and heavy–duty, on–road, off–road, and special–purpose vehicles.
The why, what and how of the electric vehicle powertrain
Empowers engineering professionals and students with the knowledge and skills required to engineer electric vehicle powertrain architectures, energy storage systems, power electronics converters and electric drives.
The modern electric powertrain is relatively new for the automotive industry, and engineers are challenged with designing affordable, efficient and high–performance electric powertrains as the industry undergoes a technological evolution. Co–authored by two electric vehicle (EV) engineers with decades of experience designing and putting into production all of the powertrain technologies presented, this book provides readers with the hands–on knowledge, skills and expertise they need to rise to that challenge.
This four–part practical guide provides a comprehensive review of battery, hybrid and fuel cell EV systems and the associated energy sources, power electronics, machines, and drives.
Electric Powertrain: Energy Systems, Power Electronics and Drives for Hybrid, Electric and Fuel Cell Vehicles is an important professional resource for practitioners and researchers in the battery, hybrid, and fuel cell EV transportation industry. The resource is a structured, holistic textbook for the teaching of the fundamental theories and applications of energy sources, power electronics, and electric machines and drives to engineering undergraduate and postgraduate students.
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