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An all-in-one reference on the interdisciplinary area of battery systems engineering, this original work covers the background, models, solution techniques, and systems theory necessary for the development of advanced battery management systems.
Informationen zum Autor Christopher D. Rahn and Chao-Yang Wang The Pennsylvania State University, USA Klappentext A complete all-in-one reference on the important interdisciplinary topic of Battery Systems EngineeringFocusing on the interdisciplinary area of battery systems engineering, this book provides the background, models, solution techniques, and systems theory that are necessary for the development of advanced battery management systems. It covers the topic from the perspective of basic electrochemistry as well as systems engineering topics and provides a basis for battery modeling for system engineering of electric and hybrid electric vehicle platforms.This original approach gives a useful overview for systems engineers in chemical, mechanical, electrical, or aerospace engineering who are interested in learning more about batteries and how to use them effectively. Chemists, material scientists, and mathematical modelers can also benefit from this book by learning how their expertise affects battery management. Approaches a topic which has experienced phenomenal growth in recent years Topics covered include: Electrochemistry; Governing Equations; Discretization Methods; System Response and Battery Management Systems Include tables, illustrations, photographs, graphs, worked examples, homework problems, and references, to thoroughly illustrate key material Ideal for engineers working in the mechanical, electrical, and chemical fields as well as graduate students in these areasA valuable resource for Scientists and Engineers working in the battery or electric vehicle industries, Graduate students in mechanical engineering, electrical engineering, chemical engineering. Zusammenfassung A complete all-in-one reference on the important interdisciplinary topic of Battery Systems EngineeringFocusing on the interdisciplinary area of battery systems engineering, this book provides the background, models, solution techniques, and systems theory that are necessary for the development of advanced battery management systems. It covers the topic from the perspective of basic electrochemistry as well as systems engineering topics and provides a basis for battery modeling for system engineering of electric and hybrid electric vehicle platforms.This original approach gives a useful overview for systems engineers in chemical, mechanical, electrical, or aerospace engineering who are interested in learning more about batteries and how to use them effectively. Chemists, material scientists, and mathematical modelers can also benefit from this book by learning how their expertise affects battery management. Approaches a topic which has experienced phenomenal growth in recent years Topics covered include: Electrochemistry; Governing Equations; Discretization Methods; System Response and Battery Management Systems Include tables, illustrations, photographs, graphs, worked examples, homework problems, and references, to thoroughly illustrate key material Ideal for engineers working in the mechanical, electrical, and chemical fields as well as graduate students in these areasA valuable resource for Scientists and Engineers working in the battery or electric vehicle industries, Graduate students in mechanical engineering, electrical engineering, chemical engineering. Inhaltsverzeichnis 1 Introduction 11.1 Energy Storage Applications 11.2 The Role of Batteries 41.3 Battery Systems Engineering 61.4 A Model-Based Approach 91.5 Electrochemical Fundamentals 101.6 Battery Design 121.7 Objectives of this Book 142 Electrochemistry 172.1 Lead-Acid 172.2 Nickel-Metal Hydride 212.3 Lithium-Ion 252.4 Performance Comparison 272.4.1 Energy Density and Specific Energy 272.4.2 Charge and Discharge 312.4.3 Cycle life 342.4.4 Temperature Operating Range 343 Governing Equations 353.1 Thermodynamics and Faraday's Law 353.2 Electrode Kinetics 39...
Autorentext
Christopher D. Rahn and Chao-Yang Wang
The Pennsylvania State University, USA
Klappentext
A complete all-in-one reference on the important interdisciplinary topic of Battery Systems Engineering Focusing on the interdisciplinary area of battery systems engineering, this book provides the background, models, solution techniques, and systems theory that are necessary for the development of advanced battery management systems. It covers the topic from the perspective of basic electrochemistry as well as systems engineering topics and provides a basis for battery modeling for system engineering of electric and hybrid electric vehicle platforms. This original approach gives a useful overview for systems engineers in chemical, mechanical, electrical, or aerospace engineering who are interested in learning more about batteries and how to use them effectively. Chemists, material scientists, and mathematical modelers can also benefit from this book by learning how their expertise affects battery management. Approaches a topic which has experienced phenomenal growth in recent years Topics covered include: Electrochemistry; Governing Equations; Discretization Methods; System Response and Battery Management Systems Include tables, illustrations, photographs, graphs, worked examples, homework problems, and references, to thoroughly illustrate key material Ideal for engineers working in the mechanical, electrical, and chemical fields as well as graduate students in these areas A valuable resource for Scientists and Engineers working in the battery or electric vehicle industries, Graduate students in mechanical engineering, electrical engineering, chemical engineering.
Inhalt
1 Introduction 1 1.1 Energy Storage Applications 1 1.2 The Role of Batteries 4 1.3 Battery Systems Engineering 6 1.4 A Model-Based Approach 9 1.5 Electrochemical Fundamentals 10 1.6 Battery Design 12 1.7 Objectives of this Book 14 2 Electrochemistry 17 2.1 Lead-Acid 17 2.2 Nickel-Metal Hydride 21 2.3 Lithium-Ion 25 2.4 Performance Comparison 27 2.4.1 Energy Density and Specific Energy 27 2.4.2 Charge and Discharge 31 2.4.3 Cycle life 34 2.4.4 Temperature Operating Range 34 3 Governing Equations 35 3.1 Thermodynamics and Faraday's Law 35 3.2 Electrode Kinetics 39 3.2.1 The Butler-Volmer Equation 40 3.2.2 Double-Layer Capacitance 42 3.3 Solid Phase of Porous Electrodes 42 3.3.1 Ion Transport 44 3.3.2 Conservation of Charge 45 3.4 Electrolyte Phase of Porous Electrodes 47 3.4.1 Ion Transport 47 3.4.2 Conservation of Charge 52 3.4.3 Concentrated Solution Theory 54 3.5 Cell Voltage 54 3.6 Cell Temperature 55 3.6.1 Arrhenius Equation 56 3.6.2 Conservation of Energy 57 3.7 Side Reactions and Aging 58 4 Discretization Methods 67 4.1 Analytical Method 69 4.1.1 Electrolyte Diffusion 69 4.1.2 Coupled Electrolyte/Solid Diffusion in Pb Electrodes 79 4.1.3 Solid State Diffusion in Li-Ion and Ni-MH Particles 81 4.2 Pade Approximation Method 83 4.2.1 Solid State Diffusion in Li-Ion Particles 84 4.3 Integral Method Approximation 85 4.3.1 Electrolyte Diffusion 85 4.3.2 Solid State Diffusion in Li-Ion and Ni-MH Particles 88 4.4 Ritz Method 89 4.4.1 Electrolyte Diffusion in a Single Domain 89 4.4.2 Electrolyte Diffusion in Coupled Domains 91 4.4.3 Coupled Electrolyte/Solid Diffusion in Pb Electrodes 94 4.5 Finite Element Method 97 4.5.1 Electrolyte Diffusion 99 4.5.2 Coupled Electrolyte/Solid Diffusion in Li-Ion Electrodes 101 4.6 Finite Difference Method 102 4.6.1 Electrolyte Diffusion 103 4.6.2 Nonlinear Coupled Electrolyte/Solid Diffusion in Pb Electrodes 104 4.7 System Identification in the Frequency Domain 106 4.7.1 System Model 107 4.7.2 Least Squares Optimization Problem 107 4.7.3 Optimization Approach 109 4.7.4 Multiple Outputs 111 4.7.5 System Identification Toolbox 112 4.7.…