Electric and Hybrid Vehicles: Power Sources, Models, Sustainability, Infrastructure and the Market reviews the performance, cost, safety, and sustainability of battery systems for hybrid electric vehicles (HEVs) and electric vehicles (EVs), including nickel-metal hydride batteries and Li-ion batteries. Throughout this book, especially in the first chapters, alternative vehicles with different power trains are compared in terms of lifetime cost, fuel consumption, and environmental impact. The emissions of greenhouse gases are particularly dealt with. The improvement of the battery, or fuel cell, performance and governmental incentives will play a fundamental role in determining how far and how substantial alternative vehicles will penetrate into the market. An adequate recharging infrastructure is of paramount importance for the diffusion of vehicles powered by batteries and fuel cells, as it may contribute to overcome the so-called range anxiety.' ' Thus, proposed battery charging techniques are summarized and hydrogen refueling stations are described.

Electric and Hybrid Vehicles: Design Fundamentals. Posted on July 29, 2013 electric-and-hybrid-vehicles-design-fundamentals. Book: Electric and Hybrid Vehicles: Design Fundamentals. Publisher: CRC Press. Posted in Engineering . Electric and hybrid vehicles design fundamentals second edition Download Book Electric And Hybrid Vehicles Design Fundamentals Second Edition in PDF format.

The final chapter reviews the state of the art of the current models of hybrid and electric vehicles along with the powertrain solutions adopted by the major automakers. Key Features. Contributors Preface 1. Economic and Environmental Comparison of Conventional and Alternative Vehicle Options 1. Introduction 2. Results and discussion 4.

Conclusions Acknowledgement Nomenclature References 2. Lifetime Cost of Battery, Fuel-Cell, and Plug-in Hybrid Electric Vehicles 1. Introduction 2. Lifetime cost of battery-electric vehicles 3. Lifetime cost of plug-in hybrid electric vehicles 4. Lifetime cost of fuel-cell electric vehicles 5. Discussion Acknowledgments References 3.

Cards Against Humanity 4th Expansion Pdf To Excel. Relative Fuel Economy Potential of Intelligent, Hybrid and Intelligent–Hybrid Passenger Vehicles 1. Introduction 2. Vehicle models for simulation studies 3. Velocity scheduling using traffic preview 4.

Hybrid vehicles with telematics 5. Optimal management of hybrid vehicles with telematics 6. Conclusions and future opportunities Acknowledgements Nomenclature References 4. Cost-Effective Vehicle and Fuel Technology Choices in a Carbon-Constrained World: Insights from Global Energy Systems Modeling 1. Introduction 2. Discussion and conclusions Acknowledgments References 5. Expected Greenhouse Gas Emission Reductions by Battery, Fuel Cell, and Plug-In Hybrid Electric Vehicles 1.

Introduction 2. Background and previous research 3.

Formation of GHG emissions from EV fuel cycles 4. Estimates of GHG emissions from EV fuel cycles 5. Magnitude of possible GHG reductions—scaling up the EV industry 6.

Key uncertainties and areas for further research 7. Conclusions Acknowledgments References Appendix 6. Analysis of Design Tradeoffs for Plug-in Hybrid Vehicles 1. Introduction 2.

Methods for studying PHEV design 3. PHEV subsystem description and tradeoff analysis 4. Case studies 5. Concluding remarks References 7. Evaluation of Energy Consumption, Emissions, and Costs of Plug-in Hybrid Vehicles 1. Introduction 2.

Factors affecting plug-in hybrid fuel consumption and emissions 3. SAE J1711 recommended practice 4. Methodology 5. United States, Europe, and Japan analysis 6. Conclusions Acknowledgments Nomenclature References 8. Improving Petroleum Displacement Potential of PHEVs Using Enhanced Charging Scenarios 1.

Introduction 2. Conclusions Acknowledgments References 9. Fuel Cell Electric Vehicles, Battery Electric Vehicles, and their Impact on Energy Storage Technologies: An Overview 1. Introduction 2. The boundary conditions for automotive technology development 3. Fuel cell electric and battery electric vehicles — two competing concepts?

Fuel cell electric vehicles 5. Extended-range electric vehicles 6. Infrastructure issues 7. Conclusions Acknowledgements List of abbreviations References 10. On the Road Performance Simulation of Battery, Hydrogen, and Hybrid Cars 1. Introduction 2. Simulation of efficient internal combustion vehicle 3.

Simulation of fuel cell vehicle 4. Simulation of battery vehicle 5. Simulation of hybrid vehicles 6. Optimization of hybrid configuration 7. Conclusions References Appendix: Performance Measures 11.

Life Cycle Assessment of Hydrogen Fuel Cell and Gasoline Vehicles 1. Introduction 2. Methodology 3. Limitations 5. Results and discussion 6. Concluding remarks References 12.

DOE’s National Fuel Cell Vehicle Learning Demonstration Project — NREL’s Data Analysis Results 1. Introduction 2. Approach and industry partners 3. Demonstration logistics 4. Concluding remarks Acknowledgments Definitions, Acronyms, Abbreviations References 13. Battery Requirements for HEVs, PHEVs, and EVs: An Overview 1. Introduction 2.

General requirements 3. Specific requirements and examples 4. Fuel cell hybrid vehicles 5.

Summary of the different Li ion chemistries existing at present, and to be used in HEVs, PHEVs, or EVs 6. The future References 14.

Battery Environmental Analysis 1. Introduction 2. Quantitative analyses: LCA 3. Impact of the different battery technologies 5. Electric vehicles traction batteries 6. Qualitative analysis References 15. A Roadmap to Understand Battery Performance in Electric and Hybrid Vehicle Operation 1.

Introduction 2. Field test data collection and analysis 3. Laboratory battery tests 4. Single cell and battery pack modeling 5.

Vehicle drivetrain platform modeling 6. Concluding remarks Acknowledgement References 16. Batteries for PHEVs: Comparing Goals and the State of Technology 1. Introduction 2.

Basic PHEV design concepts 3. PHEV battery goals 4. Battery technologies 5. Li-ion battery prospects 6. What PHEV could be made with near-term battery technologies? Discussion and conclusion Acknowledgements References 17. Battery Size and Capacity Use in Hybrid and Plug-In Hybrid Electric Vehicles 1.

Introduction 2. Defining the maximum pulse-power capability 3. A simple model for battery size and capacity use 4. A combined model for battery size and capacity use 5. Conclusions Acknowledgements Terminology References 18.

Safety of Lithium-Ion Batteries for Hybrid Electric Vehicles 1. Introduction 2. Li-ion flavors 3.

Li-ion cell failures 4. Why do Li-ion cells go into thermal runaway? Typical safety circuits 6. HEV battery safety standards 7.

System specific safety evaluation 8. Voltage introduced safety considerations 9.

Summary Acknowledgments References 19. Management of Batteries for Electric Traction Vehicles 1. Introduction 2. Application introduction 3. Battery management systems 4.

Battery management system examples 5. Conclusion Acknowledgments Glossary References 20. Electric Vehicle Charging Infrastructure 1. Introduction 2.

Charging power levels 3. Charging modes for conductive charging 4. Communication issues 5.

Accessories for charging 6. “Fast” charging 7. Inductive charging 8. Conclusions References 21. Market Prospects of Electric Passenger Vehicles 1. Introduction 2. Technical aspects 3.

Relevant stakeholders and outline of calculation model 4. Scenario calculations 5. Игры Для Nokia 3250 Бесплатно there.

Conclusions and future opportunities Nomenclature References 22. Automakers’ Powertrain Options for Hybrid and Electric Vehicles 1. Introduction 2. Hybrid electric vehicles 3. Battery electric vehicles 4.

Fuel cell hydrogen electric vehicles 5. Multi-purpose electrified traction platforms and architectures, and auto innovation design 6. Conclusions Appendix 1. Selected references for topics not specifically treated in this book (to January 2010) 2. Further reading on recharging networks and market issues (to January 2010) Index.

2003 ISBN: English 288 Pages PDF 5.5 MB With advances driven by pressure from governments, environmental activists, and its associated industries, the subject of electric and hybrid vehicles is becoming increasingly important. Trends clearly suggest that we must educate the engineers of today and tomorrow in the technical details of these vehicles. While there are many books that provide narrative descriptions of electric and hybrid vehicle components, none cover the technical aspects from a mathematically derived, design point of view, and none serve well as a textbook.

Electric and Hybrid Vehicles: Design Fundamentals presents a comprehensive, systems-level perspective of these vehicles that strikes an outstanding balance between technical details, design equations, numerical examples, and case studies. Starting with some historic background, the author describes the system components, the laws of physics governing vehicle motion, the mathematical relationships within and between the components, energy sources, and designing components to meet the complete vehicle specifications.

As this text illustrates, the electric vehicle is an excellent example of electro-mechanical and electro-chemical systems, one that is technically challenging as well as highly motivating to engineering students. The material presented is designed to be covered comfortably in a one-semester course. Its multidisciplinary nature and systems approach makes Electric and Hybrid Vehicles ideal for teaching electrical, mechanical, and chemical engineers all in one course.