Battery Management System and Its Applications

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Informationen zum Autor Xiaojun Tan, Sun Yat-sen University, China, is a Professor and leads the Research Center of New Energy Vehicles at the School of Intelligent Systems Engineering, Sun Yat-sen University. He has nearly two decades' research experience in battery modeling, testing and diagnoses, and has spearheaded many industry partnerships. Andrea Vezzini, Bern University of Applied Sciences, Switzerland is a Professor with more than two decades' experience in battery systems research and development. He leads the Energy Storage Research Centre (ESReC) at Bern University of Applied Sciences and has been involved through several spin-offs in the product development of customized battery system solutions for the industrial and automotive market. Yuqian Fan, received his PhD. in Intelligent Transportation Engineering from Sun Yat-sen University, China. His research interests include intelligent control and optimization design for power battery systems, battery thermal management and thermal safety, and battery state of health prediction. Neeta Khare, is a Director with Iveco Group. Dr. Khare acquired her doctoral degree in Intelligent Battery Monitoring from Banasthali University, India. Her core expertise is in aging algorithms of battery/ cell using AI and adaptive algorithms, Battery Pack, Battery Management System (BMS) development, and more. You Xu, is an Associate Professor at Guangdong Polytechnic Normal University, China, where he has been engaged in power battery system, precision reverse equipment. Dr. You received his PhD. from Sun Yat-sen University. He has authored over 20 scientific publications, and his research interests include battery management for electrical vehicles. Liangliang Wei, is an Associate Professor in Control Science and Engineering at Sun Yat-Sen University, China. Dr. Wei has authored over 20 scientific publications and received his PhD. in Electrical Engineering from the Wuhan University, China. Klappentext BATTERY MANAGEMENT SYSTEM AND ITS APPLICATIONSEnables readers to understand basic concepts, design, and implementation of battery management systemsBattery Management System and its Applications is an all-in-one guide to basic concepts, design, and applications of battery management systems (BMS), featuring industrially relevant case studies with detailed analysis, and providing clear, concise descriptions of performance testing, battery modeling, functions, and topologies of BMS.In Battery Management System and its Applications, readers can expect to find information on:* Core and basic concepts of BMS, to help readers establish a foundation of relevant knowledge before more advanced concepts are introduced* Performance testing and battery modeling, to help readers fully understand Lithium-ion batteries* Basic functions and topologies of BMS, with the aim of guiding readers to design simple BMS themselves* Some advanced functions of BMS, drawing from the research achievements of the authors, who have significant experience in cross-industry researchFeaturing detailed case studies and industrial applications, Battery Management System and its Applications is a must-have resource for researchers and professionals working in energy technologies and power electronics, along with advanced undergraduate/postgraduate students majoring in vehicle engineering, power electronics, and automatic control. Zusammenfassung BATTERY MANAGEMENT SYSTEM AND ITS APPLICATIONSEnables readers to understand basic concepts, design, and implementation of battery management systemsBattery Management System and its Applications is an all-in-one guide to basic concepts, design, and applications of battery management systems (BMS), featuring industrially relevant case studies with detailed analysis, and providing clear, concise descriptions of performance testing, battery modeling, functi...

List of contents

Preface xiii
 
About the Authors xv
 
Part I Introduction 1
 
1 Why Does a Battery Need a BMS? 3
 
1.1 General Introduction to a BMS 3
 
1.2 Example of a BMS in a Real System 5
 
1.3 System Failures Due to the Absence of a BMS 7
 
2 General Requirements (Functions and Features) 11
 
2.1 Basic Functions of a BMS 11
 
2.2 Topological Structure of a BMS 16
 
3 General Procedure of the BMS Design 19
 
3.1 Universal Battery Management System and Customized Battery Management System 19
 
3.2 General Development Flow of the Power Battery Management System 21
 
Part II Li-Ion Batteries 27
 
4 Introduction to Li-Ion Batteries 29
 
4.1 Components of Li-Ion Batteries: Electrodes, Electrolytes, Separators, and Cell Packing 29
 
4.2 Li-Ion Electrode Manufacturing 31
 
4.3 Cell Assembly in an Li-Ion Battery 32
 
4.4 Safety and Cost Prediction 33
 
5 Schemes of Battery Testing 37
 
5.1 Battery Tests for BMS Development 37
 
5.2 Capacity and the Charge and Discharge Rate Test 41
 
5.3 Discharge Rate Characteristic Test 44
 
5.4 Charge and Discharge Equilibrium Potential Curves and Equivalent Internal Resistance Tests 46
 
5.5 Battery Cycle Test 49
 
5.6 Phased Evaluation of the Cycle Process 58
 
6 Test Results and Analysis 67
 
6.1 Characteristic Test Results and Their Analysis 67
 
6.2 Degradation Test and Analysis 80
 
7 Battery Modeling 101
 
7.1 Battery Modeling for BMS 101
 
7.2 Common Battery Models and Their Deficiencies 102
 
7.3 External Characteristics of the Li-Ion Power Battery and Their Analysis 105
 
7.4 A Power Battery Model Based on a Three-Order RC Network 110
 
7.5 Model Parameterization and Its Online Identification 117
 
7.6 Battery Cell Simulation Model 124
 
Part III Functions of BMS 133
 
8 Battery Monitoring 135
 
8.1 Discussion on Real Time and Synchronization 135
 
8.2 Battery Voltage Monitoring 139
 
8.3 Battery Current Monitoring 145
 
8.4 Temperature Monitoring 149
 
9 SoC Estimation of a Battery 153
 
9.1 Different Understandings of the SoC Definition 153
 
9.2 Classical Estimation Methods 158
 
9.3 Difficulty in an SoC Estimation 162
 
9.4 Actual Problems to Be Considered During an SoC Estimation 166
 
9.5 Estimation Method Based on the Battery Model and the Extended Kalman Filter 169
 
9.6 Error Spectrum of the SoC Estimation Based on the EKF 177
 
10 Charge Control 193
 
10.1 Introduction 193
 
10.2 Charging Power Categories 196
 
10.3 Charge Control Methods 198
 
10.4 Effect of Charge Control on Battery Performance 203
 
10.5 Charging Circuits 204
 
10.6 Infrastructure Development and Challenges 209
 
10.7 Isolation and Safety Requirement for EC Chargers 211
 
11 Balancing/Balancing Control 213
 
11.1 Balancing Control Management and Its Significance 213
 
11.2 Classification of Balancing Control Management 218
 
11.3 Review and Analysis of Active Balancing Technologies 221
 
11.4 Balancing Strategy Study 226
 
11.5 Two Active Balancing Control Strategies 234
 
11.6 Evaluation and Comparison of Balancing Control Strategies 245
 
12 State of Health (SoH) Estimation of a Battery 257
 
12.1 Definition and Indices/Parameters of SoH 257
 
12.2 Modeling of Battery Degradation (Aging) and SoH Estimation 265
 
12.3 Battery Degradation Diagnosis for EVs 278
 
13 Communication Interfa