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Thermal Management of Electric Vehicle Battery Systems Automotive Series

Langue : Anglais

Auteurs :

Couverture de l’ouvrage Thermal Management of Electric Vehicle Battery Systems

Thermal Management of Electric Vehicle Battery Systems provides a thorough examination of various conventional and cutting edge electric vehicle (EV) battery thermal management systems (including phase change material) that are currently used in the industry as well as being proposed for future EV batteries. It covers how to select the right thermal management design, configuration and parameters for the users? battery chemistry, applications and operating conditions, and provides guidance on the setup, instrumentation and operation of their thermal management systems (TMS) in the most efficient and effective manner. 

This book provides the reader with the necessary information to develop a capable battery TMS that can keep the cells operating within the ideal operating temperature ranges and uniformities, while minimizing the associated energy consumption, cost and environmental impact. The procedures used are explained step-by-step, and generic and widely used parameters are utilized as much as possible to enable the reader to incorporate the conducted analyses to the systems they are working on. Also included are comprehensive thermodynamic modelling and analyses of TMSs as well as databanks of component costs and environmental impacts, which can be useful for providing new ideas on improving vehicle designs.

Key features:

  • Discusses traditional and cutting edge technologies as well as research directions
  • Covers thermal management systems and their selection for different vehicles and applications
  • Includes case studies and practical examples from the industry
  • Covers thermodynamic analyses and assessment methods, including those based on energy and exergy, as well as exergoeconomic, exergoenvironmental and enviroeconomic techniques
  • Accompanied by a website hosting codes, models, and economic and environmental databases as well as various related information

Thermal Management of Electric Vehicle Battery Systems is a unique book on electric vehicle thermal management systems for researchers and practitioners in industry, and is also a suitable textbook for senior-level undergraduate and graduate courses.

Preface xiii

Acknowledgements xvii

1 Introductory Aspects of Electric Vehicles 1

1.1 Introduction 1

1.2 Technology Development and Commercialization 2

1.3 Vehicle Configurations 4

1.3.1 Internal Combustion Engine Vehicles (ICEV) 4

1.3.2 All Electric Vehicles (AEVs) 6

1.3.3 Hybrid Electric Vehicles (HEVs) 7

1.3.4 Fuel Cell Vehicles (FCVs) 10

1.4 Hybridization Rate 10

1.4.1 Micro HEVs 11

1.4.2 Mild HEVs 11

1.4.3 Full or Power-Assist HEVs 12

1.4.4 Plug-In HEVs (or Range-Extended Hybrids) 12

1.5 Vehicle Architecture 13

1.5.1 Series HEVs 14

1.5.2 Parallel HEVs 14

1.5.3 Parallel/Series HEVs 14

1.5.4 Complex HEVs 15

1.6 Energy Storage System 15

1.6.1 Batteries 15

1.6.2 Ultracapacitors (UCs) 17

1.6.3 Flywheels 18

1.6.4 Fuel Cells 18

1.7 Grid Connection 20

1.7.1 Charger Power Levels and Infrastructure 20

1.7.2 Conductive Charging 21

1.7.3 Inductive Charging 22

1.7.4 Smart Grid and V2G/V2H/V2X Systems 23

1.8 Sustainability, Environmental Impact and Cost Aspects 27

1.9 Vehicle Thermal Management 28

1.9.1 Radiator Circuit 29

1.9.2 Power Electronics Circuit 29

1.9.3 Drive Unit Circuit 30

1.9.4 A/C Circuit 30

1.10 Vehicle Drive Patterns and Cycles 33

1.11 Case Study 34

1.11.1 Introduction 34

1.11.2 Research Programs 34

1.11.3 Government Incentives 35

1.11.3.1 Tax Benefits 35

1.11.3.2 EV Supply Equipment and Charging Infrastructure 36

1.11.3.3 EV Developments in the Turkish Market 36

1.11.3.4 HEVs on the Road 38

1.11.3.5 Turkey’s Standing in the World 39

1.11.3.6 SWOT Analysis 43

1.12 Concluding Remarks 43

Nomenclature 44

Study Questions/Problems 44

References 45

2 Electric Vehicle Battery Technologies 49

2.1 Introduction 49

2.2 Current Battery Technologies 49

2.2.1 Lead Acid Batteries 51

2.2.2 Nickel Cadmium Batteries 52

2.2.3 Nickel Metal Hydride Batteries 52

2.2.4 Lithium-Ion Batteries 54

2.3 Battery Technologies under Development 57

2.3.1 Zinc-Air Batteries 59

2.3.2 Sodium-Air Batteries 60

2.3.3 Lithium-Sulfur Batteries 60

2.3.4 Aluminum-Air Batteries 61

2.3.5 Lithium-Air Batteries 61

2.4 Battery Characteristics 63

2.4.1 Battery Cost 63

2.4.2 Battery Environmental Impact 64

2.4.3 Battery Material Resources 68

2.4.4 Impact of Various Loads and Environmental Conditions 70

2.5 Battery Management Systems 72

2.5.1 Data Acquisition 75

2.5.2 Battery States Estimation 76

2.5.2.1 SOC Estimation Algorithm 76

2.5.2.2 SOH Estimation Algorithms 78

2.5.2.3 SOF Estimation Algorithms 78

2.5.3 Charge Equalization 78

2.5.3.1 Hierarchical Architecture Platform/Communication 80

2.5.3.2 Cell Equalization 80

2.5.4 Safety Management/Fault Diagnosis 81

2.5.5 Thermal Management 83

2.6 Battery Manufacturing and Testing Processes 83

2.6.1 Manufacturing Processes 83

2.6.2 Testing Processes 85

2.7 Concluding Remarks 88

Nomenclature 88

Study Questions/Problems 88

References 89

3 Phase Change Materials for Passive TMSs 93

3.1 Introduction 93

3.2 Basic Properties and Types of PCMs 93

3.2.1 Organic PCMs 100

3.2.1.1 Paraffins 101

3.2.1.2 Non-Paraffins 101

3.2.2 Inorganic PCMs 102

3.2.2.1 Salt Hydrates 102

3.2.2.2 Metals 103

3.2.3 Eutectics 104

3.3 Measurement of Thermal Properties of PCMs 104

3.4 Heat Transfer Enhancements 107

3.5 Cost and Environmental Impact of Phase Change Materials 110

3.6 Applications of PCMs 111

3.7 Case Study I: Heat Exchanger Design and Optimization Model for EV Batteries using PCMs 114

3.7.1 System Description and Parameters 114

3.7.1.1 Simplified System Diagram 114

3.7.1.2 PCM Selection For the Application 115

3.7.1.3 Nano-Particles and PCM Mixture For Thermal Conductivity Enhancement 116

3.7.1.4 Thermal Modeling of Heat Exchanger 117

3.7.2 Design and Optimization of the Latent Heat Thermal Energy Storage System 119

3.7.2.1 Objective Functions, Design Parameters and Constraints 119

3.7.2.2 Effective Properties of the PCM and Nanotubes 119

3.7.2.3 Combined Condition 121

3.7.2.4 Model Description 121

3.7.2.5 Sensitivity Analysis 121

3.7.2.6 Helical Tube Heat Exchanger 127

3.8 Case Study 2: Melting and Solidification of Paraffin in a Spherical Shell from Forced External Convection 128

3.8.1 Validation of Numerical Model and Model Independence Testing 130

3.8.2 Performance Criteria 133

3.8.3 Results and Discussion 135

3.9 Concluding Remarks 141

Nomenclature 141

Study Questions/Problems 143

References 143

4 Simulation and Experimental Investigation of Battery TMSs 145

4.1 Introduction 145

4.2 Numerical Model Development for Cell and Submodules 146

4.2.1 Physical Model for Numerical Study of PCM Application 146

4.2.2 Initial and Boundary Conditions and Model Assumptions 147

4.2.3 Material Properties and Model Input Parameters 148

4.2.3.1 Li-ion Cell Properties 148

4.2.3.2 Phase Change Material (PCM) 149

4.2.3.3 Foam Material 153

4.2.3.4 Cooling Plate 153

4.2.4 Governing Equations and Constitutive Laws 153

4.2.5 Model Development for Simulations 155

4.2.5.1 Mesh Generation 156

4.2.5.2 Discretization Scheme 156

4.2.5.3 Under-Relaxation Scheme 157

4.2.5.4 Convergence Criteria 157

4.3 Cell and Module Level Experimentation Set Up and Procedure 157

4.3.1 Instrumentation of the Cell and Submodule 158

4.3.2 Instrumentation of the Heat Exchanger 159

4.3.3 Preparation of PCMs and Nano-Particle Mixtures 161

4.3.4 Improving Surface Arrangements of Particles 163

4.3.5 Setting up the Test Bench 164

4.4 Vehicle Level Experimentation Set Up and Procedure 166

4.4.1 Setting Up the Data Acquisition Hardware 166

4.4.2 Setting Up the Data Acquisition Software 168

4.5 Illustrative Example: Simulations and Experimentations on the Liquid Battery Thermal Management System Using PCMs 172

4.5.1 Simulations and Experimentations on Cell Level 174

4.5.1.1 Grid Independence Tests 175

4.5.1.2 Effect of Contact Resistance on Heat Transfer Rate 176

4.5.1.3 Simulation Results For Li-ion cell Without PCM in Steady State and Transient Response 177

4.5.1.4 Simulation Results For PCM in Steady-State and Transient Conditions 180

4.5.1.5 Cooling Effectiveness In the Cell 185

4.5.2 Simulation and Experimentations Between the Cells in the Submodule 186

4.5.2.1 Effective Properties of Soaked Foam 187

4.5.2.2 Steady State Response of the Cells in the Submodule 188

4.5.2.3 Transient Response of the Submodule 189

4.5.2.4 Submodule with Dry and Wet Foam at Higher Heat Generation Rates 191

4.5.3 Simulations and Experimentations on a Submodule Level 192

4.5.3.1 Steady-State Response of the Submodule Without PCMs 193

4.5.3.2 Steady-State Results of the Submodule with PCMs 196

4.5.3.3 Transient Response of the Submodule 197

4.5.3.4 Quasi-Steady Response of the Submodule 198

4.5.3.5 Model Validation 201

4.5.4 Optical Observations 203

4.5.4.1 Thermal Conductivity Enhancement by Nanoparticles 203

4.5.4.2 Data For the Case of Pure PCM (99% Purity) 208

4.5.4.3 Optical Microscopy Analysis of the PCM and Nanoparticle Mixture 208

4.5.5 Vehicle Level Experimentations 214

4.5.5.1 Test Bench Experimentations 215

4.5.5.2 Test Vehicle Experimentations 218

4.5.6 Case Study Conclusions 225

4.6 Concluding Remarks 226

Nomenclature 227

Study Questions/Problems 228

References 229

5 Energy and Exergy Analyses of Battery TMSs 231

5.1 Introduction 231

5.2 TMS Comparison 232

5.2.1 Thermodynamic Analysis 233

5.2.2 Battery Heat Transfer Analysis 237

5.2.2.1 Battery Temperature Distribution 237

5.2.2.2 Battery Temperature Uniformity 239

5.3 Modeling of Major TMS Components 240

5.3.1 Compressor 242

5.3.2 Heat Exchangers 243

5.3.3 Thermal Expansion Valve (TXV) 245

5.3.4 Electric Battery 246

5.3.5 System Parameters 246

5.4 Energy and Exergy Analyses 247

5.4.1 Conventional Analysis 247

5.4.2 Enhanced Exergy Analysis 253

5.5 Illustrative Example: Liquid Battery Thermal Management Systems 256

5.6 Case Study: Transcritical CO2-Based Electric Vehicle BTMS 269

5.6.1 Introduction 270

5.6.2 System Development 272

5.6.3 Thermodynamic Analysis 275

5.6.4 Results and Discussion 276

5.6.5 Case Study Conclusions 281

5.7 Concluding Remarks 282

Nomenclature 282

Study Questions/Problems 284

References 285

6 Cost, Environmental Impact and Multi-Objective Optimization of Battery TMSs 287

6.1 Introduction 287

6.2 Exergoeconomic Analysis 288

6.2.1 Cost Balance Equations 288

6.2.2 Purchase Equipment Cost Correlations 290

6.2.3 Cost Accounting 291

6.2.4 Exergoeconomic Evaluation 293

6.2.5 Enhanced Exergoeconomic Analysis 293

6.2.6 Enviroeconomic (Environmental Cost) Analysis 294

6.3 Exergoenvironmental Analysis 295

6.3.1 Environmental Impact Balance Equations 295

6.3.2 Environmental Impact Correlations 296

6.3.3 LCA of the Electric Battery 297

6.3.4 Environmental Impact Accounting 299

6.3.5 Exergoenvironmental Evaluation 300

6.4 Optimization Methodology 301

6.4.1 Objective Functions 301

6.4.2 Decision Variables and Constraints 302

6.4.3 Genetic Algorithm 303

6.5 Illustrative Example: Liquid Battery Thermal Management Systems 306

6.5.1 Conventional Exergoeconomic Analysis Results 307

6.5.2 Enhanced Exergoeconomic Analysis Results 309

6.5.3 Battery Environmental Impact Assessment 314

6.5.4 Exergoenvironmental Analysis Results 316

6.5.5 Multi-Objective Optimization Results 319

6.5.5.1 Case Study Conclusions 324

6.6 Concluding Remarks 325

Nomenclature 326

Study Questions/Problems 327

References 328

7 Case Studies 329

7.1 Introduction 329

7.2 Case Study 1: Economic and Environmental Comparison of Conventional, Hybrid, Electric and Hydrogen Fuel Cell Vehicles 329

7.2.1 Introduction 329

7.2.2 Analysis 330

7.2.2.1 Economic Criteria 330

7.2.2.2 Environmental Impact Criteria 331

7.2.2.3 Normalization and General Indicator 334

7.2.3 Results and Discussion 335

7.2.4 Closing Remarks 338

7.3 Case Study 2: Experimental and Theoretical Investigation of Temperature Distributions in a Prismatic Lithium-Ion Battery 339

7.3.1 Introduction 339

7.3.2 System Description 340

7.3.3 Analysis 341

7.3.3.1 Temperature Measurements 341

7.3.3.2 Heat Generation 342

7.3.4 Results and Discussion 342

7.3.4.1 Battery Discharge Voltage Profile 342

7.3.4.2 Battery Internal Resistance Profile 343

7.3.4.3 Effect of Discharge Rates and Operating Temperature on Battery Performance 344

7.3.4.4 Model Development and Validation 344

7.3.5 Closing Remarks 350

7.4 Case Study 3: Thermal Management Solutions for Electric Vehicle Lithium-Ion Batteries based on Vehicle Charge and Discharge Cycles 351

7.4.1 Introduction 351

7.4.2 System Description 351

7.4.3 Analysis 352

7.4.3.1 Design of Hybrid Test Stand For Thermal Management 352

7.4.3.2 Battery Cooling System 356

7.4.3.3 Sensors and Flow Meter 356

7.4.3.4 Compression Rig 356

7.4.3.5 Battery 359

7.4.3.6 Thermal Management System – Experimental Plan and Procedure 359

7.4.3.7 Data Analysis Method 361

7.4.4 Results and Discussion 364

7.4.4.1 Battery Surface Temperature Profile 365

7.4.4.2 Average Surface Temperature of Battery 366

7.4.4.3 Average Heat Flux 368

7.4.4.4 Peak Heat Flux 369

7.4.4.5 Heat Generation Rate 369

7.4.4.6 Total Heat Generated 373

7.4.4.7 Effect of Discharge Rate and Operating Temperature on Discharge Capacity 373

7.4.5 Closing Remarks 374

7.5 Case Study 4: Heat Transfer and Thermal Management of Electric Vehicle Batteries with Phase Change Materials 375

7.5.1 Introduction 375

7.5.2 System Description 375

7.5.3 Analysis 378

7.5.3.1 Exergy Analysis 378

7.5.3.2 Numerical Study 379

7.5.4 Results and Discussion 379

7.5.4.1 CFD Analysis 379

7.5.4.2 Part II: Exergy Analysis 385

7.5.5 Closing Remarks 388

7.6 Case Study 5: Experimental and Theoretical Investigation of Novel Phase Change Materials For Thermal Applications 389

7.6.1 Introduction 389

7.6.2 System Description 390

7.6.2.1 Experimental Layouts 393

7.6.2.2 Challenges 397

7.6.3 Analysis 397

7.6.3.1 Analysis of Constant Temperature Bath 402

7.6.3.2 Analysis of Hot Air Duct 402

7.6.3.3 Analysis of Battery Cooling 403

7.6.3.4 Energy and Exergy Analyses 403

7.6.4 Results and Discussion 407

7.6.4.1 Test Results of Base PCM 408

7.6.4.2 Results of Battery Cooling Tests 410

7.6.4.3 Results of Energy and Exergy Analyses on Base Clathrate 412

7.6.4.4 Results of Thermoeconomic Analysis 415

7.6.5 Closing Remarks 417

Nomenclature 419

References 423

8 Alternative Dimensions and Future Expectations 425

8.1 Introduction 425

8.2 Outstanding Challenges 425

8.2.1 Consumer Perceptions 425

8.2.2 Socio-Technical Factors 427

8.2.3 Self-Reinforcing Processes 429

8.3 Emerging EV Technologies and Trends 431

8.3.1 Active Roads 431

8.3.2 V2X and Smart Grid 432

8.3.3 Battery Swapping 433

8.3.4 Battery Second Use 435

8.4 Future BTM Technologies 437

8.4.1 Thermoelectric Materials 437

8.4.2 Magnetic Cooling 438

8.4.3 Piezoelectric Fans/Dual Cooling Jets 438

8.4.4 Other Potential BTMSs 440

8.5 Concluding Remarks 441

Nomenclature 441

Study Questions/Problems 441

References 442

Index 445

Ibrahim Dincer is a full professor of Mechanical Engineering and director of Clean Energy Research Laboratory at UOIT. Renowned for his pioneering works in the area of sustainable energy technologies, including clean transportation options, he has authored/co-authored many books, book chapters, and refereed journal and conference papers. He has chaired national and international conferences, symposia, workshops and technical meetings and delivered many keynote and invited lectures. He is an active member of various international scientific organizations and societies, and serves as editor-in-chief, associate editor, regional editor, and editorial board member on various prestigious international journals. He is a recipient of several research, teaching and service awards, including the Premier's research excellence award in Ontario, Canada. He has recently been recognized by Thomson Reuters as one of The Most Influential Scientific Minds in Engineering.

Halil S. Hamut is a Chief Senior Researcher at The Scientific and Research Council of Turkey (TÜBITAK) and the project manager for developing Turkey’s first brand of national electric vehicles. He received his PhD from the Faculty of Engineering and Applied Science, University of Ontario Institute of Technology in Canada, in 2013. He has previously collaborated with General Motors Company in Oshawa, Canada and worked for Ford Motor Company in Michigan, U.S.A He has published many journals and conference papers and has been a reviewer for several journals. His research interests are primarily concerned with exergy, exergoeconomic and exergoenvironmental analyses of electric and hybrid electric vehicle thermal management systems.

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