Requirement, Design, and Challenges in Inorganic Solid State Batteries
|
|
- Elinor Rodgers
- 6 years ago
- Views:
Transcription
1 Requirement, Design, and Challenges in Inorganic Solid State Batteries Venkat Anandan Energy Storage Research Department 1
2 Ford s Electrified Vehicle Line-up HEV Hybrid Electric Vehicle C-Max Hybrid Fusion Hybrid Lincoln MKZ Hybrid PHEV Plug-in Hybrid Electric Vehicle C-Max Energy Fusion Energy BEV Battery Electric Vehicle Focus Electric 2
3 Motivation Environment Government Regulations 54.5 mpg 163 gco 2 /mile 250 gco 2 /mile Energy Independence ACCESS Number 41, Fall 2012 Double the mpg/half the emission! Reduce Dependence on Foreign Oil 3
4 US Electrified Vehicle Outlook EV growth, EV future outlook 4
5 Why Li-ion? Higher specific capacity and power density Higher operating voltage Higher energy efficiency No memory effect means simpler controls OCV can be used to monitor SOC Saharan, V. and Nakai, K.SAE Technical Paper ,, Li-ion far exceeds the energy and power capability of Pb-acid, Ni- Cd and Ni-MH 5
6 Vol. energy density (Wh/l) Limitations in SOA Li-ion Batteries for EV Applications Energy Density Limitation Beyond Li-ion? Safety Burned Li-ion in Boeing ~350 Wh/L Supplier Projection 600 Wh/L Samsung Galaxy Note ~275 Wh/L Conventional Li-ion High Packaging Cost Need a Battery technology better than conventional Li-ion battery technology 6
7 Beyond Conventional Lithium-ion Wh/Kg Wh/l solid state batteries could deliver high volumetric energy density than other technologies 7
8 Advanced High Energy Lithium Battery Technologies Cell Type Potential Advantages Key Challenges Li-Air Li-S Low cost, weight cathode (oxygen) High theoretical specific energy Similar to fuel cell technology Low cost cathode High theoretical capacity Sealed cell design Low practical energy density(~550 Wh/l). Low demonstrated current density and cycle life Complex systems requirements - on board air scrubbing or closed O 2 cycling. Safety issues Self discharge and short cycle life Low voltage (high cell count) Safety issues solid state No flammable electrolytes Compatible with existing cathode materials Wide temperature and voltage operating window Low demonstrated current density and cycle life Scalability uncertain Materials compatibility issues Key Takeaways: All the above technologies has to use Li metal as anode to provide high energy density Li-air and Li-S will still have safety concerns due to the presence of liquid electrolyte Solid state batteries offer better safety and vol energy density than other technologies None of the technologies are ready at present for EV applications 8
9 Types of Solid State battery Thin film Battery Commercially available for applications including sensors, RFID tag, medical devices, and smarter cards. Excellent cycle life (many thousands) Very low capacity (~µah/cm 2 ), low current density (~ µa/cm 2 ) Expensive manufacturing process includes vacuum deposition tools such as sputtering, CVD, PVD. Not Suitable for EV applications Thin film Battery Design EFL700A39 EnFilm from STMicroelectronics 3.9V, 700 µah 9
10 Types of Solid State battery Bulk Type Solid State Battery 94 µm 20 µm 230 Wh/kg, 630 Wh/L (Cell Level) 1 Graphite Anode Separator 40 µm 50 µm 230 Wh/kg, 866 Wh/L (Cell Level) 2 Lithium Anode 75 µm Liquid Electrolyte 75 µm Solid Electrolyte NMC Cathode NMC Cathode Conventional Li-ion Solid State battery Benefits High energy density: Enables lithium metal and high voltage cathodes Better safety: Eliminates flammable liquid electrolyte and may prevent dendrite formation Thermal Stability: Stable at high temperature operations Reduce cost: Reduction in cost and complexity may be possible at the pack level 1 Assumed 20um separator, 85 um cathode thickness, 4.0 mah/cm 2 capacity loading 2 Assumed 50um Solid electrolyte separator, 75 um composite cathode thickness, 4.0 mah/cm 2 capacity loading 10
11 Performance to Target Vol. Energy Density (Wh/L) Sp. Energy Density (Wh/kg) Vol. Energy density Sp. Energy density) LCO LCO NCA NCA NMC NMC LMO LMO LFP LFP Cathode 3 Materials4 5 Graphite/NMC Li-ion Cell SSB Design Lithium Anode Solid Electrolyte Cathode Active Material Assumed 50um Solid electrolyte separator, 75 um composite cathode thickness, 4.0 mah/cm 2 capacity loading, 2x lithium metal, cathode layer contain 70% active material, 5% carbon, and 25% solid electrolyte Graphite/NMC Li-ion Cell A bulk type SSB design containing existing active materials can meet energy density target for automotive application 0 1 2Cathode 3 Materials4 5 11
12 Current Inorganic solid electrolytes Ionic conductivity >10-4 S/cm Manufacturability ( <40 µm sheets) Negligible electronic conductivity Relative Density Transference Number=1 Fracture Toughness Electrochemical window 0 to 6V Shear Modulus Chemical Stability with electrode Lithium lanthanum Zirconium Oxide (LLZO) meets most of the requirements! 12
13 Solid Electrolyte Film Processing Solid Electrolyte (LLZO) Sheet Tape Casting Process Conductivity~10-4 S/cm Density=89% 13
14 Li Metal/Solid Electrolyte (SE) Compatibility Potential (V) Li Metal LLZO (SE) Li Metal C Impedance of Li/SE/Li Li/SE Interface Modification Low Li/LLZO interface resistance ~44 Ω.cm Cycling of Li/SE/Li Han et al. Nature Materials With ALD-Al2O3 Coating interface resistance ~1 Ω.cm 2 and excellent cycling was demonstrated 0.3 E (Volts) µA/cm2 50µA/cm2 74µA/cm2 100µA/cm2 Shorting! (Sec) Time (s) Low Li/solid electrolyte interfacial resistance with excellent cycling could be obtained. Cycling performance at high current density need to be evaluated. Li_LLZO_Li_58b_Cycle_Run01_Un1Ch5_Step01.cor Li_LLZO_Li_58b_Cycle_Run01_Un1Ch5_Step02.cor Li_LLZO_Li_58b_Cycle_Run01_Un1Ch5_Step03.cor Li_LLZO_Li_58b_Cycle_Run01_Un1Ch5_Step04.cor Li_LLZO_Li_58b_Cycle_Run01_Un1Ch5_Step05.cor Li_LLZO_Li_58b_Cycle_Run01_Un1Ch5_Step06.cor Li_LLZO_Li_58b_Cycle_Run01_Un1Ch5_Step07.cor Li_LLZO_Li_58b_Cycle_Run01_Un1Ch5_Step08.cor Li_LLZO_Li_58b_Cycle_Run01_Un1Ch5_Step09.cor Li_LLZO_Li_58b_Cycle_Run01_Un1Ch5_Step10.cor Li_LLZO_Li_58b_Cycle_Run01_Un1Ch5_Step11.cor Li_LLZO_Li_58b_Cycle_Run01_Un1Ch5_Step12.cor Li_LLZO_Li_58b_Cycle_Run01_Un1Ch5_Step13.cor Li_LLZO_Li_58b_Cycle_Run01_Un1Ch5_Step14.cor 14
15 Compatibility with Cathode Materials Reactivity between LLZO (SE) and cathodes Y. Ren et al. / J Materiomics xx (2016) 1-9 LLZO/LCO Compatibility LLZO LLZO/LCO LLZO/LCO sintered at 900C for 5 h Observed color change after sintering >800 C 15
16 Electrode Design Lithium Anode Solid Electrolyte NMC Composite Cathode Electronic Conducting Material A thick (>50 µm) composite cathode structure is required. Composite cathode should contain active material, ionic and electronic conducting materials. All these materials should be mechanically, electrochemically, and chemically stable. Ionic Conducting Material NMC Active Material 16
17 Key Challenges in Solid State Battery technology Scalability High Rate SOA SSB Need large format SSB SOA SSB performs at ~1 ma/cm 2, while current Li-ion performs >10 ma/cm 2 Lithium Dendrite Durability Original Solid electrolyte Pellet Cross section of Pellet after short circuited Li dendrite Cycle life of SOA SSB is only about 100, while the current automotive Liion battery has a cycle life of more than 1000 Electrochemistry Communications 57 (2015) Electrochemistry Communications 57 (2015)
18 Summary Conventional Li-ion battery technologies could deliver energy density ~750 Wh/l through engineering optimization, so next generation technologies should target beyond that. Solid state batteries has a potential to deliver more than 900 Wh/l with better safety than conventional Li-ion batteries. Current state of art of the solid state batteries are not yet ready to meet the various 2020 EV requirements. Both material and processing challenges has to be overcome to enable Solid State batteries for EV applications. 18
19 Collaborations 19
20 Thank you! 20
Vehicle Battery R&D Progress and Future Plans
Vehicle Battery R&D Progress and Future Plans Tien Q. Duong Office of Vehicle Technologies U.S. Department of Energy KSAE and IEA IA-HEV International Symposium on Electric Mobility and IA-HEV Task 1 Information
More informationFrom materials to vehicle what, why, and how? From vehicle to materials
From materials to vehicle what, why, and how? From vehicle to materials Helena Berg Outline 1. Electric vehicles and requirements 2. Battery packs for vehicles 3. Cell selection 4. Material requirements
More informationSeoul, Korea. 6 June 2018
Seoul, Korea 6 June 2018 Innovation roadmap in clean mobility materials SPEAKER Denis Goffaux Chief Technology Officer Executive Vice-President Energy & Surface Technologies 2 Agenda Well to wheel efficiency
More informationFuture Lithium Demand in Electrified Vehicles. Ted J. Miller
Future Lithium Demand in Electrified Vehicles Ted J. Miller August 5, 2010 Outline Vehicle Electrification at Ford Advanced Battery Technology Lithium Batteries Electrified Vehicle Market Forecasts Key
More informationThe BEEST: An Overview of ARPA-E s Program in Ultra-High Energy Batteries for Electrified Vehicles
The BEEST: An Overview of ARPA-E s Program in Ultra-High Energy Batteries for Electrified Vehicles David Danielson, PhD Program Director, ARPA-E NDIA Workshop to Catalyze Adoption of Next-Generation Energy
More informationLARGE-SCALE THIN FILM BATTERY
NCCAVS Annual Symposium February 23, 2017 LARGE-SCALE THIN FILM BATTERY Ernest Demaray (Demaray LLC) & Pavel Khokhlov (SpectraPower LLC) SpectraPower High Energy Density Li-metal cells The 6.6Ah battery
More informationDOE OVT Energy Storage R&D Overview
DOE OVT Energy Storage R&D Overview David Howell Hybrid and electric vehicles, energy storage technologies and control systems National and international R&D-projects, research institutions and funding
More informationElectrochemical Energy Storage Devices
Electrochemical Energy Storage Devices Rajeswari Chandrasekaran, Ph.D. from Energy Storage, Materials & Strategy Research and Advanced Engineering, Ford Motor Company, Dearborn, MI-48124. presented at
More informationCSIRO Energy Storage Projects: David Lamb Low Emission Transport Theme Leader
CSIRO Energy Storage Projects: David Lamb Low Emission Transport Theme Leader Energy Storage for Transport Three projects Safe, High-Performance Lithium-Metal Batteries Supercapacitors Ultrabattery 10
More informationReview of status of the main chemistries for the EV market
Review of status of the main chemistries for the EV market EMIRI Energy Materials Industrial Research Initiative Dr. Marcel Meeus Consultant Sustesco www.emiri.eu 1 Agenda 1. Review of status of current
More informationThin film coatings on lithium metal for Li-S batteries AIMCAL 2016 Memphis, TN
Thin film coatings on lithium metal for Li-S batteries AIMCAL 2016 Memphis, TN Stephen Lawes, Research Scientist OXIS Company Background OXIS have been working on Li-S since 2005 at Culham Science Centre
More informationLi-ion Batteries and Electric Vehicles
Li-ion Batteries and Electric Vehicles October 27, 2010 Joel Sandahl ZX Technologies, Inc. 760 Spanish Oak Trail Dripping Springs, TX 78620 USA Phone: +1-512-964-9786 E-Mail: jsandahl@zxtech.net Introduction
More informationKeeping up with the increasing demands for electrochemical energy storage
Keeping up with the increasing demands for electrochemical energy storage Jeff Sakamoto 2015 Top of the learning curve: optimize current technology 2020 Frontiers of Li-ion technology: new materials 2030
More informationBatteries for electric commercial vehicles and mobile machinery
Batteries for electric commercial vehicles and mobile machinery Tekes EVE annual seminar, Dipoli 6.11.2012 Dr. Mikko Pihlatie VTT Technical Research Centre of Finland 2 Outline 1. Battery technology for
More informationLithium-Ion Battery Simulation for Greener Ford Vehicles
Lithium-Ion Battery Simulation for Greener Ford Vehicles October 13, 2011 COMSOL Conference 2011 Boston, MA Dawn Bernardi, Ph.D., Outline Vehicle Electrification at Ford from Nickel/Metal-Hydride to Lithium-Ion
More informationStorage: the state of the technology
Storage: the state of the technology Torbjörn Gustafsson Ångström Advanced Battery Centre Department of Materials Chemistry Uppsala University 1 Acknowledgements Ångström Advanced Battery Centre 2 Over
More informationU.S. Department of Energy
U.S. Department of Energy Vehicle Technologies Office Electric Vehicle Battery Research Pathways and Key Results March 21, 2017 David Howell Brian Cunningham (Presenter) Tien Duong Peter Faguy Samuel Gillard
More informationLarge Format Lithium Power Cells for Demanding Hybrid Applications
Large Format Lithium Power Cells for Demanding Hybrid Applications Adam J. Hunt Manager of Government Programs 2011 Joint Service Power Expo Power to Sustain Warfighter Dominance Myrtle Beach, SC May 4,
More informationUN/SCETDG/47/INF.13/Rev.1
Committee of Experts on the Transport of Dangerous Goods and on the Globally Harmonized System of Classification and Labelling of Chemicals New proper shipping name for rechargeable lithium metal batteries
More informationUnderstanding Lithium-Ion Technology Jim McDowall (updated from Battcon 2008)
Understanding Lithium-Ion Technology Jim McDowall (updated from Battcon 2008) PE/SB Winter Meeting 2015, New Orleans Background History Started with primary batteries with metallic lithium negatives True
More informationPhosphates in Li-ion batteries and automotive applications
Phosphates in Li-ion batteries and automotive applications MY. Saidi*, H. Huang, TJ. Faulkner (Batteries 2009) Valence Technology, Inc., (NV USA) Yazid.Saidi@Valence.com www.valence.com 1 www.valence.com
More informationPrinted Energy Storage
Printed Energy Storage Prof. James W. Evans 1,Jay Keist 1, Christine Ho 1, Ba Quan 1 & Prof. Paul K. Wright 2 1 Material Science and Engineering, University of California Berkeley, Berkeley, CA 2 Mechanical
More informationBattery technology advancements: Solid state electrolyte
MARITIME Battery technology advancements: Solid state electrolyte Presented at NOx Fund Seminar - Oslo, Norway Dr. Benjamin Gully 06 September 2018 1 DNV GL 06 September 2018 SAFER, SMARTER, GREENER Lithium
More informationPortable Power & Storage
Portable Power & Storage NMTC Disruptive Technology Summit and TECH CONN3CT Workshops 28 April 2017 Edward J. Plichta Chief Scientist for Power & Energy Command Power & Integration Directorate Aberdeen
More informationLeveraging developments in xev Lithium batteries for stationary applications
Leveraging developments in xev Lithium batteries for stationary applications International Colloquium on Energy Storage Brussels, Nov 8 th, 2017 Daniel Gloesener Global technical leader- Battery Technologies,
More informationLi-ion Technology Overview NTSB Hearing Washington, D.C. July 12-13, 2006
Li-ion Technology Overview NTSB Hearing Washington, D.C. July 12-13, 2006 Jason Howard, Ph.D. Distinguished Member of the Technical Staff, Motorola, Inc. Board of Directors, Portable Rechargeable Battery
More informationOpportunities & Challenges Energy Storage
M. Scott Faris CEO faris@planarenergy.com 407-459-1442 Opportunities & Challenges Energy Storage February 2011 The National Academies Workshop Phoenix, AZ Battery Industry is Stuck Volumes are Substantial
More informationPROGRESS OF BATTERY SYSTEMS AT GENERAL MOTORS. Manfred Herrmann Roland Matthé. World Mobility Summit Munich October 2016
PROGRESS OF BATTERY SYSTEMS AT GENERAL MOTORS Manfred Herrmann Roland Matthé World Mobility Summit Munich October 2016 AGENDA DEVELOPMENT OF ELECTRIFICATION ELECTRIFICATION BATTERY SYSTEMS PROGRESS OF
More informationEnergy Storage (Battery) Systems
Energy Storage (Battery) Systems Overview of performance metrics Introduction to Li Ion battery cell technology Electrochemistry Fabrication Battery cell electrical circuit model Battery systems: construction
More informationLi-Ion battery Model. Octavio Salazar. Octavio Salazar
Li-Ion battery Model 1 Energy Storage- Lithium Ion Batteries C-PCS: Control and Power Conditioning System Energy Storage- Lithium Ion Batteries Nature [0028-0836] Tarascon (2001) volume: 414 issue: 6861
More informationTechnical Challenges and Barriers Affecting Turbo-electric and Hybrid Electric Aircraft Propulsion
Technical Challenges and Barriers Affecting Turbo-electric and Hybrid Electric Aircraft Propulsion Dr. Ajay Misra Deputy Director, Research and Engineering NASA Glenn Research Center Keynote presentation
More informationBattery Market Trends and Safety Aspects
Battery Market Trends and Safety Aspects Adam Sobkowiak PhD, Battery Technologies adam.sobkowiak@etteplan.com 2018-01-17, Breakfast Seminar at Celltech, Kista 1 Battery Market Trends Engineering with a
More information48V Battery System Design for Mild Hybrid Applications. Angela Duren 11 February 2016
48V Battery System Design for Mild Hybrid Applications Angela Duren 11 February 2016 OEM Portfolio Planning; A Balanced Strategy for Fuel Economy Low voltage hybrids are a cost effective solution for higher
More informationThe Challenges of Electric Energy Storage. Nigel Taylor, Nick Green, Chris Lyness, Steve Nicholls
The Challenges of Electric Energy Storage Nigel Taylor, Nick Green, Chris Lyness, Steve Nicholls Technology Walk Customer familiarity with recharging IC HEV PHEV EV Kinetic energy recovery Plug-in Battery
More informationLi-Ion Batteries for Low Voltage Applications. Christoph Fehrenbacher 19 October 2016
Li-Ion Batteries for Low Voltage Applications Christoph Fehrenbacher 19 October 2016 OEM Portfolio Planning; A Balanced Strategy for Fuel Economy Low voltage hybrids are a cost effective solution for higher
More informationTowards competitive European batteries
Towards competitive European batteries GC.NMP.2013-1 Grant. 608936 Lecture I: Materials improvement and cells manufacturing Leclanché GmbH External Workshop Brussels, 23.05.2016 1 Plan About Leclanché
More informationBattery Power for All-Electric Road Vehicles John B. Goodenough and M. Helena Braga The University of Texas at Austin, and of Porto, Portugal
Battery Power for All-Electric Road Vehicles John B. Goodenough and M. Helena Braga The University of Texas at Austin, and of Porto, Portugal Modern Society runs on the energy stored in fossil fuels. This
More informationEnergy Storage Solutions for xev System. June 4th, 2015
Energy Storage Solutions for xev System June 4th, 2015 Outline Ⅰ. Lithium Secondary Battery Ⅱ. xev system and Requirement for Battery Ⅲ. Technical Feature of SDI Battery Ⅳ. Development Trend for Next Generation
More informationHigh Energy Rechargeable Li-S Battery Development at Sion Power and BASF
High Energy Rechargeable Li-S Battery Development at Sion Power and BASF Y. Mikhaylik*, C. Scordilis-Kelley*, M. Safont*, M. Laramie*, R. Schmidt**, H. Schneider**, K. Leitner** *Sion Power Corporation,
More informationNew proper shipping name for rechargeable lithium metal batteries
Committee of Experts on the Transport of Dangerous Goods and on the Globally Harmonized System of Classification and Labelling of Chemicals New proper shipping name for rechargeable lithium metal batteries
More informationQuallion Matrix Battery Technology for Lithium-ion Lead Acid Replacement & Wide Operating Temperature Range Cells. May 2011
Quallion Matrix Battery Technology for Lithium-ion Lead Acid Replacement & Wide Operating Temperature Range Cells May 2011 Introduction Employing a core strategy of leveraging R&D, niche focus, complementary
More informationGrowth Trends in Li-Ion Batteries
Growth Trends in Li-Ion Batteries The effect on LCE consumption Elewout Depicker Purchase Director 5th Lithium Supply & Markets January 2013, Las Vegas Agenda Introduction: Umicore within the Li-Ion market
More informationImplementation and development of standards for Lithium-ion energy storage technologies within the South African context
Implementation and development of standards for Lithium-ion energy storage technologies within the South African context by Nico Rust, Nelson Mandela University uyilo EMTIP uyilo emobility Technology Innovation
More informationThermal runaway inhibiting electrolytes
Thermal runaway inhibiting electrolytes Surya Moganty, PhD CT HMs Technologies Y-BEST Energy Storage Technology Conference 2017 1 utline Li-ion battery- Safety challenges Liquid electrolyte systems HMs
More informationTHINERGY MEC220. Solid-State, Flexible, Rechargeable Thin-Film Micro-Energy Cell
THINERGY MEC220 Solid-State, Flexible, Rechargeable Thin-Film Micro-Energy Cell DS1013 v1.1 Preliminary Product Data Sheet Features Thin Form Factor 170 µm Thick Capacity options up to 400 µah All Solid-State
More informationCourse of development of the lithium-ion battery (LIB), and recent technological trends
Session 2A : Business Case Course of development of the lithium-ion (LIB), and recent technological trends Dr. Akira Yoshino Yoshino Laboratory Asahi Kasei Corp. E-mail: yoshino.ab@om.asahi-kasei.co.jp
More informationSAEHAN ENERTECH, INC.
SAEHAN ENERTECH, INC. ENERTECH 23. Patent List Subject 1. Device for applying primer to manufacturing Lithium Polymer Battery Application Application Number Date 200036124 2000.06.28 2. Lithium Polymer
More informationChallenges on the Road to Electrification of Vehicles. Hrishikesh Sathawane Analyst Lux Research, Inc. October, 2011
Challenges on the Road to Electrification of Vehicles Hrishikesh Sathawane Analyst Lux Research, Inc. October, 2011 Lux Research Helps clients capitalize on science-driven innovation, identifying new business
More informationELiTE Battery Information
ELiTE Battery Information History of Li- Ion Batteries What is a Lithium-ion Battery? Two or more electrochemical cells, electrically interconnected. Each cell contains two electrodes and an electrolyte.
More information2011 Advanced Energy Conference -Buffalo, NY
2011 Advanced Energy Conference -Buffalo, NY Electrification Technology and the Future of the Automobile Mark Mathias Electrochemical Energy Research Lab General Motors R&D Oct. 13, 2011 Transitioning
More informationBattery technologies and their applications in sustainable developments. Dr. Denis Y.W. Yu Assistant Professor School of Energy and Environment
Battery technologies and their applications in sustainable developments Dr. Denis Y.W. Yu Assistant Professor School of Energy and Environment May 29, 2014 Energy flow Energy Energy generation Energy storage
More informationIonic Additives for Electrochemical Devices Using Intercalation Electrodes
U.S. Army Research, Development and Engineering Command Ionic Additives for Electrochemical Devices Using Intercalation Electrodes Inventor: Dr. Kang Xu ARL 09-18 February 16, 2011 Technology Overview
More informationModel Comparison with Experiments. 341 N. Science Park Road State College, PA U.S.A.
Model Comparison with Experiments 41 N. Science Park Road State College, PA 168 U.S.A. www.ecpowergroup.com AutoLion TM : Unprecedented Accuracy in Capturing Liion Battery Performance Voltage (V) Temperature
More informationCustomcells. Tailormade Energystorage Solutions.
Customcells Tailormade Energystorage Solutions www.customcells.de 02 // Company Company // 03 Customcells Multi-option Lithium-Ion Cells Europe s most versatile manufacturer in the Lithium-Ion cell industry.
More informationMaterial Science and Engineering, University of California Berkeley, Berkeley, CA
Printed Energy Storage Devices Christine C. Ho 1, Prof. James W. Evans 1 and Prof. Paul K. Wright 2 1 Material Science and Engineering, University of California Berkeley, Berkeley, CA 2 Mechanical Engineering,
More informationBattery Monitoring and Roadmapping High-Energy-Batteries from Materials to Production
Battery Monitoring and Roadmapping 2030+ High-Energy-Batteries from Materials to Production Dr. Axel Thielmann Competence Center Emerging Technologies Fraunhofer-Institute for Systems and Innovation Research
More informationFailure Modes & Effects Criticality Analysis of Lithium-Ion Battery Electric and Plug-in Hybrid Vehicles Project Overview
Failure Modes & Effects Criticality Analysis of Lithium-Ion Battery Electric and Plug-in Hybrid Vehicles Project Overview Denny Stephens, Battelle Phillip Gorney, Barbara Hennessey, NHTSA January 26, 2012
More informationSB LiMotive Automotive Battery Technology. Kiho Kim
SB LiMotive Automotive Battery Technology Kiho Kim Contents Introduction Li Ion Cell Technology Page 2 Introduction to SBLiMotive Page 3 SBL Product Portfolio Cell & Module Cooling System BMS Hardware
More informationBatteries for HTM. D. J. McMahon rev cewood
Batteries for HTM D. J. McMahon 141004 rev cewood 2017-10-09 Key Points Batteries: - chemistry; know the characteristic cell voltages of common chemistries: NiCd/ NiMH 1.2V Hg 1.35V Zn Alkaline 1.5V Ag
More informationTechnical Challenges for Vehicle 14V/28V Lithium Ion Battery Replacement
: Dist A. Approved for public release Technical Challenges for Vehicle 14V/28V Lithium Ion Battery Replacement David Skalny Deputy Team Leader, Energy Storage Team, US Army TARDEC May 4, 2011 Agenda Goals
More informationLithium-Ion Batteries for Electric Cars: Elena Aleksandrova Honda R&D Europe (Deutschland) GmbH Automobile Advanced Technology Research
Lithium-Ion Batteries for Electric Cars: Opportunities and Challenges Elena Aleksandrova Honda R&D Europe (Deutschland) GmbH Automobile Advanced Technology Research 19.01.2010 1 Introduction Li-Ion technology
More informationTin Electrodes for Batteries
Tin Electrodes for Batteries Stephanie Moroz Chief Executive Officer Melbourne, 2 November 2016 Nano-Nouvelle background Private company Incorporated in 2011 Based in Queensland 11 employees Platform technology
More informationE-Mobility: Recent developments and outlook into the future
E-Mobility: Recent developments and outlook into the future Lisbon, 03 October, 2018 Latendorf Organisational Development Karl-Juch-Str. 28, D - 45219 Essen Phone: +49 2054 9392 930 Fax: +49 2054 9392
More informationLithium-based Batteries
Lithium-based Batteries Pioneer work with the lithium battery began in 1912 under G.N. Lewis, but it was not until the early 1970s that the first non-rechargeable lithium batteries became commercially
More informationxev Expansion, Key Technology, and Market Development Dr. Menahem Anderman President, Total Battery Consulting, Inc.
xev Expansion, Key Technology, and Market Development Dr. Menahem Anderman President, Total Battery Consulting, Inc. www.totalbatteryconsulting.com 1 Presentation Outline I. xev Market Trends II. Lithium-Ion
More informationKOKAM Li-ion/Polymer Cell
Superior Lithium Polymer Battery (SLPB) KOKAM Li-ion/Polymer Cell Kokam s SLPB cell has proven its outstanding power, high energy density, longer cycle life and safety. Kokam is a pioneer in supplying
More informationBatteries for HTM. Basic Battery Parameters:
Batteries for HTM Key Points Batteries: - chemistry; know the characteristic cell voltages of common chemistries: NiCd/ NiMH 1.2V Hg 1.35V Zn Alkaline 1.5V Ag Oxide 1.55V Pb 2.0V Li 3.0V LiIon/ LiPo 3.6V
More informationElectric Vehicle Battery Chemistry and Pack Architecture
Cedric Weiss, PhD A2Mac1, EV/Hybrid Department Charles Hatchett Seminar High Energy and High Power Batteries for e-mobility Opportunities for Niobium London, England July 4, 2018 Updated on Mar. 2015 Outline
More informationinnovation at work The NanoSafe Battery Alan J. Gotcher, PhD President & CEO Altair Nanotechnologies, Inc. November 29 th, 2006 Research Manufacturing
Research The NanoSafe Battery Manufacturing Alan J. Gotcher, PhD President & CEO Altair Nanotechnologies, Inc. November 29 th, 2006 Products Partners With the exception of historical information, matters
More informationThe lowest cost, highest performance battery separators in the world
The lowest cost, highest performance battery separators in the world Who we are A growth phase company with strong global partners utilizing a unique technology and a tightly targeted strategy to revolutionize
More informationBreaking Lithium-Ion Market Barriers: Safety and Total Cost of Ownership. Dr. Tomasz Poznar
Breaking Lithium-Ion Market Barriers: Safety and Total Cost of Ownership Dr. Tomasz Poznar 1 Storing Energy = Risks Risks are presents in all energy storage systems Storing energy always poses inherent
More informationBattery materials investments. Marc Grynberg, CEO Kurt Vandeputte, Business Line Manager 31 March 2010
Battery materials investments Marc Grynberg, CEO Kurt Vandeputte, Business Line Manager 31 March 2010 1 Investment summary Umicore to invest in new production and development capabilities in Japan, South
More informationA Structure of Cylindrical Lithium-ion Batteries
Introduction A Structure of Cylindrical Lithium-ion Batteries A lithium-ion battery is an energy storage device providing electrical energy by using chemical reactions. A few types of lithium-ion battery
More informationArgonne Mobility Research Impending Electrification. Don Hillebrand Argonne National Laboratory
Argonne Mobility Research Impending Electrification Don Hillebrand Argonne National Laboratory 2018 Argonne: DOE s Largest Transportation Research Program Located 25 miles from the Chicago Loop, Argonne
More informationBOSTON-POWER LITHIUM-ION BATTERY SOLUTIONS BENCHMARK WORLD TOUR 2017 TORONTO APRIL 24, 2017
BOSTON-POWER LITHIUM-ION BATTERY SOLUTIONS BENCHMARK WORLD TOUR 2017 TORONTO APRIL 24, 2017 BOSTON-POWER MISSION Provide Next-Gen Li-Ion Batteries Enabling Enhanced Mobility and Environmental Sustainability
More informationIs there really anything wrong with it? Generation II 2007 Toyota Prius 311,000 miles
Is there really anything wrong with it? Generation II 2007 Toyota Prius 311,000 miles Always make sure that the HV Disconnect is removed! Always use the proper protective equipment! 1,000 volt gloves Battery
More informationState-of-Charge (SOC) governed fast charging method for lithium based batteries. Fahmida Naznin M/s. TVS Motor Company Ltd.
State-of-Charge (SOC) governed fast charging method for lithium based batteries Fahmida Naznin M/s. TVS Motor Company Ltd. Hosur, Tamilnadu Hybrid technology & battery requirement References: 1. Battery
More informationFull-cell Li-ion batteries successfully produced with Campoona graphite
ASX Announcement (ASX:AXE) 21 August 2018 Full-cell Li-ion batteries successfully produced with Campoona graphite Highlights Collaboration with The University of New South Wales (UNSW) has led to the assembly
More informationHow SolidEnergy is transforming the future of transportation and connectivity
>400Wh/kg is here How SolidEnergy is transforming the future of transportation and connectivity The battery literature is full of fake news and empty promises. Many claims often look great on paper, but
More informationProgress and challenges Generation 4
Progress and challenges Generation 4 Battery Workshop, Bruxelles 11 th of January 2018 C. Barchasz, V. Tarnopolskyi, L. Picard, D. Bloch, S. Patoux, S. Perraud CONVENTIONAL LITHIUM-ION SYSTEMS Volumetric
More informationAdvances in Direct Recycling for Lithium-ion Batteries
Advances in Direct Recycling for Lithium-ion Batteries Steve Sloop NDIA Event #7670 Joint Service Power Expo Virgina Beach, VA May 1-4, 2017 Location OnTo Technology is in Bend, Oregon, which has flights
More informationLithium Ion Batteries - for vehicles and other applications
Lithium Ion Batteries - for vehicles and other applications Tekes 2008-12-03 Kai Vuorilehto / European Batteries What do we need? High energy (Wh/kg) driving a car for 5 hours High power (W/kg) accelerating
More informationAltairnano Grid Stability and Transportation Products
Altairnano Grid Stability and Transportation Products Joe Heinzmann Senior Director Energy Storage Solutions 1 Altairnano Overview Altairnano is an emerging growth company which is developing and commercializing
More informationTalga Anode Enables Ultra-Fast Charge Battery
ASX & Media Release 16 October 2018 ASX:TLG Talga Anode Enables Ultra-Fast Charge Battery New test results show Talga s lithium-ion battery anode product outperforming commercial benchmark and enabling
More informationAdvanced Battery for Electric Vehicles in CEGASA.
Advanced Battery for Electric Vehicles in CEGASA. What is CEGASA CEGASA GROUP Main figures Sales 200,000,000 Euros Facilities 124,000 m2 Factories 4 Employees 1014 People CEGASA GROUP More than 75 years
More informationProLogium Lithium Ceramic Battery Profile
ProLogium Lithium Ceramic Battery Profile 2018.07 About ProLogium Milestone Technology Target market About ProLogium ProLogium TM Technology (PLG) is a next generational Lithium battery cell maker who
More informationLithium-Ion Battery for Audi A6 PHEV. Steve Lehnert, AUDI AG
Steve Lehnert, AUDI AG 2 Contents Overview of the battery system Mechanical Overview Advantages/disadvantages of common battery package Architecture Modular set part concept Advantages of set part concept
More informationUltra-thin Flexible Primary Film Battery Manufacturing Technology
Core Part of Subminiature Flexible Device Power Ultra-thin Flexible Primary Film Battery Manufacturing Technology Contact: Heejin Choi Email: hjchoi2@etri.re.kr Phone: +82. 42. 860. 4946 2 TECHNOLOGY BRIEF
More informationMAT4BAT summer school Battery industry prospective in Europe and new technologies. C. Chanson
MAT4BAT summer school Battery industry prospective in Europe and new technologies C. Chanson June 4, 2015 1 RECHARGE Membership throughout the Value Chain 2 RECHARGE Mission RECHARGE s mission is to promote
More informationHAWLEY George C. Hawley & Associates
COMPARISON OF GRAPHITE ANODES WITH COMPETITORS GRAPHITE SUPPLY CHAIN 13-15 NOVEMBER 2016 ISLAND HOTEL NEWPORT BEACH CALIFORNIA USA GEORGE C. George Hawley was Research and Development Chemist at Morgan
More informationBattery Seminar. Battery Technology Mid Term Forecast. Samuel De-Leon
Shmuel De-Leon Energy Ltd. Where Knowledge and Vision Take Place Battery Seminar Battery Technology Mid Term Forecast Samuel De-Leon shmueld33@gmail.com 1 Proprietary Notice This document contains information
More informationCorporate Presentation
Changing How the World Makes Nanomaterials Corporate Presentation Nano One Materials Corp. TSX-V: NNO FF: LBMB OTC: NNOMF January 2018 Nano One Team Dan Blondal CEO 26 yrs in high tech at Kodak, Creo,
More information12V Start-Stop and 48V Mild Hybrid LMO-LTO Batteries
12V Start-Stop and 48V Mild Hybrid LMO-LTO Batteries Veselin Manev Ph.D., Kevin Dahlberg Ph.D., Susmitha Gopu, Steve Cochran 35 th International Battery Seminar & Exhibit Ft. Lauderdale, Florida, March
More informationBeyond the Headlines. An overview of Li-ion in Energy Storage
Beyond the Headlines An overview of Li-ion in Energy Storage Contents Why Lithium-Ion? Chemistry generations Challenges when Scaling Up Safety Thermal Management Why Li-ion? Perfect Energy Storage System
More informationDuracell Battery Glossary
Duracell Battery Glossary 1 Duracell Battery Glossary AB Absorption Alloy Ambient Humidity Ambient Temperature Ampere-Hour Capacity Anode Battery or Pack Bobbin C-Rate (also see Hourly Rate) Capacity Capacity
More informationSAE BATTERY RECYCLING COMMITTEE: BATTERY RECYCLING APPROACHES FOR THE 21 ST CENTURY. Colin Pelletier, Timothy Ellis RSR Technologies Dallas, TX
SAE BATTERY RECYCLING COMMITTEE: BATTERY RECYCLING APPROACHES FOR THE 21 ST CENTURY Colin Pelletier, Timothy Ellis RSR Technologies Dallas, TX Battery Recycling Committee: What is the Mission Mission:
More informationBATTERIES & SUPERCAPS POST MORTEM ANALYSIS PLATFORM EXTERNAL SERVICES
BATTERIES & SUPERCAPS POST MORTEM ANALYSIS PLATFORM EXTERNAL SERVICES CONTEXT Over the last years a remarkable evolution has taken place by the introduction of new batteries & supercapacitors technologies
More informationGLOSSARY: TECHNICAL BATTERY TERMS
GLOSSARY: TECHNICAL BATTERY TERMS AB5 Absorption Alloy Ambient Humidity Ambient Temperature Ampere-Hour Capacity Anode Battery or Pack Bobbin C-Rate (also see Hourly Rate) Capacity Capacity Retention (or
More informationHigh Power Bipolar Nickel Metal Hydride Battery for Utility Applications
High Power Bipolar Nickel Metal Hydride Battery for Utility Applications Michael Eskra, Robert Plivelich meskra@electroenergyinc.com, Rplivelich@electroenergyinc.com Electro Energy Inc. 30 Shelter Rock
More informationBeth Lowery. GM Vice President Environment and Energy
Beth Lowery GM Vice President Environment and Energy Global Energy Consumption 35% of global energy needs are met by petroleum Energy demand will grow 2% annually from 2003-2030 70% more energy will be
More information