Thermal Management of Electric Vehicle Battery Systems

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Langue : Anglais
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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.

Preface
Acknowledgements

1 - Introductory Aspects of Electric Vehicles
. 1.1 Introduction
. 1.2 Technology Development and Commercialization
. 1.3 Vehicle Configurations
. 1.4 Hybridization Rate
. 1.5 Vehicle Architecture
. 1.6 Energy Storage System
. 1.7 Grid Connection
. 1.8 Sustainability, Environmental Impact and Cost Aspects
. 1.9 Vehicle Thermal Management
. 1.10 Vehicle Drive Patterns and Cycles
. 1.11 Case Study
. 1.12 Concluding Remarks
. Nomenclature
. Study Questions/Problems
. References

2 - Electric Vehicle Battery Technologies
. 2.1 Introduction
. 2.2 Current Battery Technologies
. 2.3 Battery Technologies under Development
. 2.4 Battery Characteristics
. 2.5 Battery Management Systems
. 2.6 Battery Manufacturing and Testing Processes
. 2.7 Concluding Remarks
. Nomenclature
. Study Questions/Problems
. References

3 - Phase Change Materials for Passive TMSs
. 3.1 Introduction
. 3.2 Basic Properties and Types of PCMs
. 3.3 Measurement of Thermal Properties of PCMs
. 3.4 Heat Transfer Enhancements
. 3.5 Cost and Environmental Impact of Phase Change Materials
. 3.6 Applications of PCMs
. 3.7 Case Study I: Heat Exchanger Design and Optimization Model for EV Batteries using PCMs
. 3.8 Case Study 2: Melting and Solidification of Paraffin in a Spherical Shell from Forced External Convection
. 3.9 Concluding Remarks
. Nomenclature
. Study Questions/Problems
. References

4 - Simulation and Experimental Investigation of Battery TMSs
. 4.1 Introduction
. 4.2 Numerical Model Development for Cell and Submodules
. 4.3 Cell and Module Level Experimentation Set Up and Procedure
. 4.4 Vehicle Level Experimentation Set Up and Procedure
. 4.5 Illustrative Example: Simulations and Experimentations on the Liquid Battery Thermal Management System Using PCMs
. 4.6 Concluding Remarks
. Nomenclature
. Study Questions/Problems
. References

5 - Energy and Exergy Analyses of Battery TMSs
. 5.1 Introduction
. 5.2 TMS Comparison
. 5.4 Energy and Exergy Analyses
. 5.4.1 Conventional Analysis
. 5.5 Illustrative Example: Liquid Battery Thermal Management Systems
. 5.6 Case Study: Transcritical CO2–Based Electric Vehicle BTMS
. 5.7 Concluding Remarks
. Nomenclature
. Study Questions/Problems
. References

6 - Cost, Environmental Impact and Multi–Objective Optimization of Battery TMSs
. 6.1 Introduction
. 6.2 Exergoeconomic Analysis
. 6.3 Exergoenvironmental Analysis
. 6.4 OptimizationMethodology
. 6.5 Illustrative Example: Liquid BatteryThermal Management Systems
. 6.6 Concluding Remarks
. Nomenclature
. Study Questions/Problems
. References

7 - CaseStudies
. 7.1 Introduction
. 7.2 Case Study 1: Economic and Environmental Comparison of Conventional, Hybrid, Electric and Hydrogen Fuel Cell Vehicles
. 7.3 Case Study 2: Experimental and Theoretical Investigation of Temperature Distributions in a Prismatic Lithium–Ion Battery
. 7.4 Case Study 3: Thermal Management Solutions for Electric Vehicle Lithium–Ion Batteries based on Vehicle Charge and Discharge Cycles
7.5 Case Study 4: Heat Transfer and Thermal Management of Electric Vehicle Batteries with Phase Change Materials
. 7.6 Case Study 5: Experimental and Theoretical Investigation of Novel Phase Change Materials For Thermal Applications
. Nomenclature
. References

8 - Alternative Dimensions and Future Expectations
. 8.1 Introduction
. 8.2 Outstanding Challenges
. 8.3 Emerging EV Technologies and Trends
. 8.4 Future BTM Technologies
. 8.5 Concluding Remarks
. Nomenclature
. Study Questions/Problems
. References
. Index