DOCSLIB.ORG

The Xev Industry Insider Report

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text
The Xev Industry Insider Report Assessing the Future of Hybrid and Electric Vehicles: The xEV Industry Insider Report Based on private onsite interviews with leading technologists and executives advanced automotive batteries Company Visits Assessing the Future of Automakers/Automotive Systems: Hybrid and Electric Vehicles • Audi • Opel AG A comprehensive analysis of the plans of major • AVL • Porsche automakers and regional market conditions • BMW • PSA Peugeot • Chrysler Citroën worldwide, set against the cost-benefit ratios of • Continental AG • Renault emerging vehicles and battery technologies • Daimler • Robert Bosch • Ford • Toyota Key Topics • General Motors • Valeo • Honda • Volkswagen • Low and high-voltage hybrid market challenges • Hyundai • ZF Sachs for EV-PHEV • Magna E-Car • The market challenges for EV-PHEV • Mitsubishi Motors • Future technology and market positions of automotive Lead-Acid and Nickel-Metal Hydride batteries and ultracapacitors Battery Producers: • Vehicle- and battery-market projections • A123 Systems • LG Chem • Cell and pack technology • AESC • Li Energy Japan • Deutsche Accumotive • Primearth EV Energy Benefits • Dow Kokam • Panasonic-Sanyo Automakers: • Exide • Robert Bosch Benefit from the Report balanced analysis of • GS Yuasa • Samsung the future cost, performance, and durability of • Hitachi • SK Innovation • Johnson Controls • Toshiba advanced automotive batteries Battery producers: Other Participants: Gain insights into the direction of both the advanced automotive market and individual • California Air • NEC Devices carmakers Resources Board • Showa Denko Material producers: • Hitachi Chemical • Umicore • Mitsubishi Chemical Learn about the prospects of battery materials in the xEV market Energy providers: Stay abreast of the technology and trends behind “We consider AAB the leading industry organization for automotive batteries; I always find great insight in Dr. vehicle electrification Anderman’s conclusions and outlook” William J. Wallace, Director of Global Battery Systems, Corporate and financial investors: General Motors Profit from this comprehensive assessment of the technology and market challenges to better guide “Dr. Anderman is one of the most knowledgeable people your investment decisions I have met in the battery field, particularly with regards to automotive applications. He exhibits a rare blend in his deep understanding of the technology and the Published markets. He is a consultant of the highest value.” Richard A. Clark, New Technology Business Director, Morgan First edition May 2013 Advanced Materials and Technology Second edition September 2013 Will the advances in battery technology Table of Contents be sufficient to sustain market growth, Executive Summary 1. xEV Vehicle Technology independent of government incentives 2. HEV Battery Technology 3. Battery Requirements and Battery Selection for Each and regulations? Hybrid-Vehicle Category 4. Batteries for EVs & PHEVs 5. xEV Vehicle Market HEV 6. Battery Market for xEVs • What are the new opportunities for low-voltage CHAPTER I: Introduction and Hybrid-Vehicle Technologies hybrids? 1. Introduction 2. Powertrain Technology • Where is the market headed for moderate and 3. Electrical Power on Board Vehicles strong hybrids? 4. The Stop/Start Function 5. Hybrid-Vehicle Powertrain Architectures • What are the crucial challenges for Lead-Acid 6. Levels of Powertrain Hybridization and ultracapacitor technologies? 7. Hybridization of Specialty Vehicles • Does the Nickel-Metal Hydride technology have 8. Hybridization Summary lasting potential? CHAPTER II: Energy Storage Technologies for HEVs 1. High-Power Battery Technology Key Attributes • What are the winning Lithium-Ion battery 2. Energy-Storage Systems and Module/Pack Technology designs for each of the hybrid architectures? 3. Lead-Acid Batteries 4. Nickel-Metal Hydride Batteries 5. Lithium-Ion Batteries PHEVs 6. Ultracapacitors 7. Summary and Comparison • What is the ideal electric range? CHAPTER III: Battery Requirements and the Choice of • What battery cost is needed for a positive Battery for Each Hybrid Vehicle Category business case and is it feasible? 1. Overview 2. Basic Requirements and Conventional SLI Applications • Which vehicles and battery makers will take 3. Micro-1 – Stop/Start Vehicles with No Regenerative Braking significant market share? 4. Micro-2 – Stop/Start Vehicles with Regenerative Braking 5. Mild-1 – 48V Systems 6. Mild-2 Hybrid Vehicles EVs 7. Moderate Power-Assist Hybrids 8. Strong-Hybrid Vehicles • Where is the EV market and who are the 9. Summary long-term players? 10. Power-assist Fuel-Cell Hybrid Vehicles 11. Hybridization of Specialized Heavy Vehicles • Cell and pack cost, how far down can they go? CHAPTER IV: Lithium-Ion EV and PHEV Battery Technology • Where are the business opportunities for 1. Battery Manufacturing and Cost existing and new players? 2. Battery Design and Key Attributes 3. Battery Durability and Safety 4. Technology Enhancement Roadmap CHAPTER V: xEV Vehicle Market Ordering Information 1. Market Drivers and Challenges for xEVs Report price includes 2. Market Conditions in Key Regions 3. Market Forecast for xEVs two encrypted electronic copies and 4. Activities of Key Automakers one hardbound copy: ......................................$7,600 CHAPTER VI: Battery Market for xEVs 1. Batteries for Micro-Hybrids Upgrade to a corporate network license .......$4,800 2. Mild, Moderate, and Strong HEV Battery Market One day consulting visit 3. PHEV Battery Market 4. EV Battery Market (including travel expenses): ...................................$2,800 5. The xEV Battery Market Summary 6. Advanced Automotive Li-Ion Cell Materials Market Additional copies: ..............................................$125 7. Cell and Pack Business Structure 8. Notes on Key xEV Battery Producers The Vision Reducing the harmful impact of vehicles on the environment is a vital task for the industrial world. With the introduction of advanced electrical and hybrid functions in vehicles, the automotive industry is now approaching cost-effective ways to reduce fuel consumption and emissions. Energy storage technology is the key to the commercial success of these advanced vehicles. The objective of the Report is to make available to industry professionals around the world infor- mation that will help them focus their financial and human resources on the most technologically viable and economically affordable solutions to the future needs of automotive energy storage. It will thus contribute to the development and support of more eco-friendly vehicles, a cleaner environment, and more responsible usage of our planet’s resources. The Author Dr. Menahem Anderman, President Total Battery Consulting, Inc. Menahem Anderman has directed development programs for high-power nickel-based and Li-Ion batteries as well as electrochemical capacitors. His corporate experience ranges from materials research, cell design, and product develop- ment, to battery-product application, market development, technology and business assessment and general management. He holds a PhD with honors in Physical Chemistry from the University of California, and founded Total Battery Consulting in 1996 to offer consulting services in lithium- and nickel-based battery development and application, intellectual property issues in battery-related markets, and investment assessment. Dr. Anderman provides technology and market assessments to international clients and government agencies including the U.S. Senate, the California Air Resources Board, the National Research Council, the U.S. Department of Energy, and others. As the world’s leading independent expert on advanced automo- tive batteries, Dr. Anderman is routinely quoted in news and business journals including The Wall Street Journal, The Washington Post, and The New York Times. The Company In 2000, Dr. Anderman founded Advanced Automotive Batteries (AAB) to pro- vide up-to-date technology and market assessments of the rapidly growing field of energy storage for advanced automotive applications. Advanced Automotive Batteries published the 2002 and 2007 Advanced Automotive Battery Industry Reports, the 2005 Ultracapacitor Report and the 2010 Plug-In Hybrid and Electric Vehicle Opportunity Report. Advanced Automotive Batteries also organizes the main international event in the industry: the Advanced Automotive Battery Conference (AABC), with Dr. Anderman serving as Chairman. For over a decade, the annual AABC has attracted professionals from the hybrid and electric vehicle world and the three tiers of the battery supply chain. Renowned as a global meeting place, AABC features presentations and discussions that address the most pivotal issues affecting the technology and market of advanced vehicles and the batteries that will power them. In 2010, to keep pace with the rapidly expanding technology and market development, AAB started hosting two conferences annually, in the U.S. and Europe for the first four years (together attracting an average of 1,400 participants). AABC 2014 will take place in Atlanta, Georgia, February 3 – 7 and the first AABC Asia will take place in Kyoto, Japan, May 19-23, 2014. advanced automotive batteries P.O. Box 1059 Oregon House, CA 95962 tel: 1 (530) 692 0140 fax: 1 (530) 692 0142 [email protected] www.advancedautobat.com.
Load more

Recommended publications
  • Signature Redacted,.--- Michael A
    A Global Analysis and Market Strategy in the Electric Vehicle Battery Industry By MASSACHUSETTS INSToT1JE. OFTECHNOLOGY Young Hee Kim 8 2014 B. A. Mass Communications and B.B.A. Business Administration, Sogang University, 2005 MBA, Sungkyunkwan University, 2014 LIBRARIES SUBMITTED TO THE MIT SLOAN SCHOOL OF MANAGEMENT IN PARTIAL FULFILLMENT OF THE REQUIREMENTS FOR THE DEGREE OF MASTER OF SCIENCE IN MANAGEMENT STUDIES AT THE MASSACHUSETTS INSTITUTE OF TECHNOLOGY JUNE 2014 ( 2014 Young Hee Kim. All Rights Reserved. The author hereby grants to MIT permission to reproduce and to distribute publicly paper and electronic copies of this thesis document in whole or in part in any medium now known or hereafter created. Signature of Author: Signature redacted MIT Sloan School of Management May 9, 2014 redacted, Certified By: Signature Michael A. Cusumano LI SMR Distinguished Professor of Management Thesis supervisor Accepted By: Signature redacted,.--- Michael A. Cusumano SMR Distinguished Professor of Management Faculty Director, M.S. in Management Studies Program MIT Sloan School of Management [Page intentionallyleft blank] 2 A Global Analysis and Market Strategy in the Electric Vehicle Battery Industry By Young Hee Kim Submitted to the MIT Sloan School of Management on May 9, 2014 in partial fulfillment of the requirements for the degree of Master of Science in Management Studies Abstract As use of electric vehicles has been expected to grow, the batteries for the electric vehicles have become critical because the batteries are a key part of the paradigm shift in the automotive industry. However, the demand for electric vehicles has been growing slowly and the electric vehicle battery industry still has internal and external competitions to become a standardized energy source for electric vehicles.
    [Show full text]
  • Assessing the Future of Hybrid and Electric Vehicles: the Xev Industry Insider Report
    Assessing the Future of Hybrid and Electric Vehicles: The xEV Industry Insider Report Based on private onsite interviews with leading technologists and executives advanced automotive batteries ACKNOWLEDGEMENTS This study was conducted by Advanced Automotive Batteries. Dr. Menahem Anderman, President of Advanced Automotive Batteries and principal author of the study wishes to acknowledge the valuable contributions of the following individuals: • Dr. James George, former President, George Consulting International, Inc. • Mr. Kevin Konecky, Associate Consultant, Total Battery Consulting, Inc. • Dr. Robert Spotnitz, President, Battery Design Company • Prof. Martin Winter, Chair, Applied Material Science for Energy Conversion and Storage, Institute of Physical Chemistry, University of Muenster The author also wishes to acknowledge the cooperation of forty-three organiza- tions—listed below—who shared their professional know-how and views in sup- port of this study during and following one or more on-site interviews throughout the last ten months. Automakers/Automotive Systems Battery Producers Other Participants • Audi • A123 Systems • California Air Resources Board • AVL • AESC • Hitachi Chemical • BMW • Deutsche Accumotive • Mitsubishi Chemical • Chrysler • Dow Kokam • NEC Devices • Continental AG • Exide • Showa Denko • Daimler • GS Yuasa • Umicore • Ford • Hitachi • General Motors • Johnson Controls • Honda • LG Chem • Hyundai • Li Energy Japan • Magna E-Car • Primearth EV Energy • Mitsubishi Motors • Panasonic-Sanyo • Opel AG • Robert Bosch • Porsche • Samsung • PSA Peugeot Citroën • SK Innovation • Renault • Toshiba • Robert Bosch • Toyota • Valeo • Volkswagen • ZF Sachs Finally, our thanks to Catherine Searle for her dedicated work in the preparation of this report and to Jennifer for her support. TABLE OF CONTENTS Executive Summary ............................................. 1 Chapter I: 1. xEV Vehicle Technology ....................................................
    [Show full text]
  • EV/Hybrid Batteries & Battery Material Suppliers: an Automotive Market
    Research Report ABOUT Automotive EV/Hybrid Batteries & E Battery Material Suppliers: An automotive market review V January 2012 I By Roger Schreffler T O M O T U A Contents © ABOUT Publishing Limited 2012 Contents 1 Executive Summary 5 Chapter 1: EV and Hybrid Batteries 5 1.1: Battery trends – the market 9 1.1.2: The power of Toyota 9 1.1.3: Post-2020 10 1.2: EV/Hybrid battery manufacturers 11 1.3: EV Battery manufacturer review 11 1.3.1: GS Yuasa Corp. (Lithium Energy Japan) 11 1.3.2: GS Yuasa Corp. (Blue Energy Co. Ltd) 13 1.3.3: Hitachi Vehicle Energy Ltd. 15 1.3.4: Johnson Controls Inc. and Saft Groupe SA 17 1.3.5: LG Chem Ltd. 19 1.3.6: Mitsubishi Heavy Industries Ltd. 19 1.3.7: NEC Corp. (Automotive Energy Supply Corp.) 21 1.3.8: Panasonic Corp. 23 1.3.9: Primearth EV Energy Co. 26 1.3.10: BYD Battery Co. 26 1.3.11: Sanyo Electric Co. 28 1.3.12: SB LiMotive 29 1.3.13: Toshiba Corp. 32 Chapter 2: Automotive battery material supplier market 32 2.1: Japanese dominance 33 2.2: The market 33 2.2.1: Separators 34 2.2.2: Anode materials 34 2.2.3: Cathode materials 35 2.2.4: Electrolytes 36 2.2.5: Electrolyte salt 36 2.3: Japanese material manufacturers 36 2.3.1: Asahi Kasei 37 2.3.2: Celgard 38 2.3.3: Toray Tonen Specialty Goro Kaisha 38 2.3.4: Sumitomo Chemical Co., Ltd.
    [Show full text]
  • 2013 Vehicle Technologies Market Report
    Vehicle Technologies 2013 Market Report Quick Facts Energy and Economics • Transportation accounts for 28% of total U.S. energy consumption. • Dependence on oil cost the U.S. economy $500 billion in 2012. • The average price of a new car is just over $25,000. • Almost 18% of household expenditures are for transportation. • Over 9 million people are employed in the transportation industry. Light Vehicles • The top nine manufacturers selling vehicles in the U.S. produce about half of the world’s vehicles. • U.S. sales volumes continued to rise in 2012. • Sales-weighted data on new light vehicles sold show a 121% increase in horsepower and 35% decrease in 0-60 time from 1980 to 2013, with the fuel economy of vehicles improving 25%. • Nearly 17% of cars sold in 2013 have continuously variable transmissions. • Almost two-thirds of new light vehicles sold in 2013 have transmissions with more than 5 speeds. Heavy Trucks • Class 8 combination trucks consume an average of 6.5 gallons per thousand ton-miles. • Class 3 truck sales have continued to increase in 2012. • Sales of class 4-7 trucks continued to increase in 2012, but were more than 5% below the 2008 level. • Class 8 truck sales continued to increase in 2012 and have risen drastically above 2009 figures. • Diesel comprised 74% of the class 3-8 trucks sold in 2012, up from 72% in 2008. • Combination trucks are driven an average of over 66,000 miles per year. • Idling a truck-tractor’s engine can use more than a gallon of fuel per hour.
    [Show full text]
  • Lithium-Ion Batteries for Electric Vehicles: the U.S. VALUE CHAIN
    Lithium-ion Batteries for Electric Vehicles: THE U.S. VALUE CHAIN Marcy Lowe, Saori Tokuoka, Tali Trigg October 5, 2010 and Gary Gereffi Contributing CGGC researcher: Ansam Abayechi Lithium-ion Batteries for Hybrid and All-Electric Vehicles: the U.S. Value Chain This research was prepared on behalf of Environmental Defense Fund: http://www.edf.org/home.cfm The authors would like to thank our anonymous interviewees and reviewers, who gave generously of their time and expertise. We would also like to thank Jackie Roberts of EDF for comments on early drafts. None of the opinions or comments expressed in this study are endorsed by the companies mentioned or individuals interviewed. Errors of fact or interpretation remain exclusively with the authors. We welcome comments and suggestions. The lead author can be contacted at [email protected]. List of Abbreviations ANL Argonne National Laboratory ARRA American Recovery and Reinvestment Act BEV Battery Electric Vehicle CGGC Center on Globalization, Governance & Competitiveness CNT Carbon nano-tubes DOE Department of Energy EPA Environmental Protection Agency EV Electric Vehicle JV Joint Venture LBNL Lawrence Berkeley National Laboratory METI Ministry of Economy, Trade And Industry in Japan NaS Sodium-Sulfur (battery) NEDO New Energy and Industrial Technology Development Organization (Japan) Ni-Cd Nickel Cadmium Ni-MH Nickel Metal Hydride NREL National Renewable Energy Laboratory ORNL Oakridge National Laboratory PHEV Plug-in Hybrid Electric Vehicle R&D Research and Development SNL Sandia National Laboratory UPS Uninterruptible Power Supply V2G Vehicle to Grid Cover photo courtesy of Argonne National Laboratory © October 5, 2010. Center on Globalization, Governance & Competitiveness Duke University Posted: October 5, 2010 Revised version: November 4, 2010 2 Lithium-ion Batteries for Hybrid and All-Electric Vehicles: the U.S.
    [Show full text]
  • Supply Chain Assessment
    DOCKETED Docket Number: 19-IEPR-04 Project Title: Transportation TN #: 228787-13 Document Title: US Department of Energy - Supply Chain Assessment - May 2019 Class 3-8 Hybrid and Electric Vehicles Operating on North American Description: Roads: Supply Chain Assessment of Vehicles, Drive-Train Motors, Inverters, Converters and Batteries Filer: Wendell Krell Organization: California Energy Commission Submitter Role: Commission Staff Submission Date: 6/19/2019 9:22:42 AM Docketed Date: 6/19/2019 Open Source Intelligence for Better Decisions. Class 3-8 Hybrid and Electric Vehicles Operating on North American Roads: Supply Chain Assessment of Vehicles, Drive-Train Motors, Inverters, Converters and Batteries. *** Prepared for the US Department of Energy, Office of Energy Efficiency and Renewable Energy, Vehicle Technologies Office. Approved for Public Release Please contact Mr. Steven Boyd, Vehicle Technologies Office, US Department of Energy at ([email protected]), or Mr. Chris Whaling, Synthesis Partners, LLC at ([email protected]), with questions or comments. Publication Date: May 2019 Collection cut-off date: July 30, 2018 Contract No. DE-DT0006388 Synthesis Partners, LLC www.synthesispartners.com Open Source Intelligence for Better Decisions. This page intentionally left blank. May 2019 www.synthesispartners.com 2 Open Source Intelligence for Better Decisions. Acknowledgements The Department of Energy, Office of Energy Efficiency and Renewable Energy, Vehicle Technologies Office (VTO) provided funding for this work under contract number DE- DT0006388. We provide special thanks to Mr. Steven Boyd, Technology Development Manager, for his technical guidance and management of this effort. We also would like to thank Ms. Adrienne Riggi, Contracting Officer at the National Energy Technology Laboratory (NETL) for her technical oversight of this effort.
    [Show full text]
  • Lithium-Ion Battery Supply Chain for E-Drive Vehicles in the United States
    CONTENTS ACKNOWLEDGMENTS ........................................................................................................... xiii ABBREVIATIONS AND ACRONYMS .................................................................................... xiv EXECUTIVE SUMMARY .......................................................................................................... xv 1 INTRODUCTION .................................................................................................................... 1 2 PEV BATTERY AND SUPPLIER DEVELOPMENT ............................................................ 3 3 BATTERY MANUFACTURING LOCATIONS AND DATA ASSUMPTIONS .................. 9 4 HISTORICAL TRENDS: PEV BATTERY PACK AND CELL PRODUCTION ................ 10 5 LITHIUM-ION BATTERIES IN HEVs ................................................................................. 13 6 FUTURE EV BATTERY CAPACITY EXPANSIONS ........................................................ 15 7 DISCUSSION ......................................................................................................................... 18 8 REFERENCES ....................................................................................................................... 20 APPENDIX A: LI-ION BATTERY CELL AND PACK FLOW DIAGRAMS FOR PEVs ....... 23 APPENDIX B: VEHICLE MAKE AND MODEL DATA .......................................................... 65 FIGURES ES-1 Annual battery cell and battery pack capacity supplied to the U.S. PEV market by production country ......................................................................................................
    [Show full text]
  • 2016 Vehicle Technologies Market Report
    Vehicle Technologies 2016 Market Report Quick Facts Energy and Economics • Transportation accounts for about 28% of total U.S. energy consumption. • The average price of a new light vehicle was nearly $32,000 in 2016. • In 2015, about 17% of household expenditures were for transportation. • Over 10 million people were employed in the transportation industry in 2015. Light Vehicles • Thirteen percent of vehicles worldwide were produced in the United States in 2015. • U.S. new light truck sales volumes rose each year from 2011 to 2016 while new car sales continued to fall from 2014 to 2016. • Sales-weighted data on new light vehicles sold show a 120% increase in horsepower and a 47% improvement in acceleration (0-60 time) from 1980 to 2016, with the fuel economy of vehicles improving 33%. • More than 26% of new cars sold in 2016 had continuously variable transmissions. • More than 90% of new light vehicles sold in 2016 have transmissions with 6 speeds or more. Heavy Trucks • Class 8 combination trucks consumed an average of 6.5 gallons per thousand ton-miles (2010 data). • Class 3 truck sales increased by 33% from 2012 to 2016. • Sales of class 4-7 trucks increased by 38% from 2012 to 2016. • Class 8 truck sales decreased 23% from 2015 to 2016. • Diesel vehicle sales of Class 4 trucks declined 70% from 2011-2015 while increasing 4% for Class 6 trucks. • In 2015, combination trucks were driven an average of almost 62,000 miles per year, down from over 68,000 miles in 2013. • Idling a truck-tractor’s engine can use half a gallon of fuel per hour or more.
    [Show full text]
  • Nobel Prize in Chemistry and Future Outlook of the Japanese Battery Industry
    ESPEC Technical Information Technical Report Nobel Prize in Chemistry and Future Outlook of the Japanese Battery Industry Noboru Sato, Doctor of Engineering Executive Adviser, ESPEC CORP. Visiting Professor, Institute of Materials Innovation, Institute of Innovation for Future Society, Nagoya University Abstract The lithium-ion battery, the star of the 2019 Nobel Prize in Chemistry, is currently used all over the world and is becoming a major factor in the creation of a battery-based society. This momentum is expected to bring about the successful development and commercialization of next-generation innovative batteries in Japan. In the current battery market, Japanese automobile companies are leading the charge toward electrification, and the successful construction of supply chains by Japanese battery companies is expected to lead to stable business succession in the future. However, it is also important to develop a strategy for confronting the top three battery companies in South Korea and the major battery companies in China. 1. LIBs: The star of the 2019 Nobel Prize in Chemistry First, congratulations are in order for Dr. Akira Yoshino, Honorary Fellow of Asahi Kasei, for receiving the 2019 Nobel Prize in Chemistry. In 1980, Professor John B. Goodenough of Oxford University in the UK (co-winner along with Dr. Yoshino and Prof. Stanley Whittingham) discovered a lithium cobalt oxide, a positive electrode material that would later be used in lithium -ion batteries (LIBs). Following this discovery, Dr. Yoshino concentrated his research on a negative electrode material that could be used with this positive electrode material. Through trial and error, Dr. Yoshino settled on using a carbon material.
    [Show full text]
  • Lithium-Ion Batteries for Electric Vehicles: the U.S
    Lithium-ion Batteries for Electric Vehicles: THE U.S. VALUE CHAIN Marcy Lowe, Saori Tokuoka, Tali Trigg October 5, 2010 and Gary Gereffi Contributing CGGC researcher: Ansam Abayechi Lithium-ion Batteries for Hybrid and All-Electric Vehicles: the U.S. Value Chain This research was prepared on behalf of Environmental Defense Fund: http://www.edf.org/home.cfm The authors would like to thank our anonymous interviewees and reviewers, who gave generously of their time and expertise. We would also like to thank Jackie Roberts of EDF for comments on early drafts. None of the opinions or comments expressed in this study are endorsed by the companies mentioned or individuals interviewed. Errors of fact or interpretation remain exclusively with the authors. We welcome comments and suggestions. The lead author can be contacted at [email protected]. List of Abbreviations ANL Argonne National Laboratory ARRA American Recovery and Reinvestment Act BEV Battery Electric Vehicle CGGC Center on Globalization, Governance & Competitiveness CNT Carbon nano-tubes DOE Department of Energy EPA Environmental Protection Agency EV Electric Vehicle JV Joint Venture LBNL Lawrence Berkeley National Laboratory METI Ministry of Economy, Trade And Industry in Japan NaS Sodium-Sulfur (battery) NEDO New Energy and Industrial Technology Development Organization (Japan) Ni-Cd Nickel Cadmium Ni-MH Nickel Metal Hydride NREL National Renewable Energy Laboratory ORNL Oakridge National Laboratory PHEV Plug-in Hybrid Electric Vehicle R&D Research and Development SNL Sandia National Laboratory UPS Uninterruptible Power Supply V2G Vehicle to Grid Cover photo courtesy of Argonne National Laboratory © October 5, 2010. Center on Globalization, Governance & Competitiveness Duke University 2 Lithium-ion Batteries for Hybrid and All-Electric Vehicles: the U.S.
    [Show full text]
  • Design of Battery Pack and Internal Combustion Engine Thermal Models for Hybrid Electric Vehicles
    University of Windsor Scholarship at UWindsor Electronic Theses and Dissertations Theses, Dissertations, and Major Papers 2013 Design of battery pack and internal combustion engine thermal models for hybrid electric vehicles Gabriele Catacchio University of Windsor Follow this and additional works at: https://scholar.uwindsor.ca/etd Recommended Citation Catacchio, Gabriele, "Design of battery pack and internal combustion engine thermal models for hybrid electric vehicles" (2013). Electronic Theses and Dissertations. 4964. https://scholar.uwindsor.ca/etd/4964 This online database contains the full-text of PhD dissertations and Masters’ theses of University of Windsor students from 1954 forward. These documents are made available for personal study and research purposes only, in accordance with the Canadian Copyright Act and the Creative Commons license—CC BY-NC-ND (Attribution, Non-Commercial, No Derivative Works). Under this license, works must always be attributed to the copyright holder (original author), cannot be used for any commercial purposes, and may not be altered. Any other use would require the permission of the copyright holder. Students may inquire about withdrawing their dissertation and/or thesis from this database. For additional inquiries, please contact the repository administrator via email ([email protected]) or by telephone at 519-253-3000ext. 3208. Design of battery pack and internal combustion engine thermal models for hybrid electric vehicles By Gabriele Catacchio A Thesis Submitted to the Faculty of Graduate Studies through the Department of Mechanical, Automotive and Materials Engineering in Partial Fulfillment of the Requirements for the Degree of Master of Applied Science at the University of Windsor Windsor, Ontario, Canada 2013 © 2013 Gabriele Catacchio Design of battery pack and internal combustion engine thermal models for hybrid electric vehicles By Gabriele Catacchio Approved by: ______________________________________________ Dr.
    [Show full text]