BATTERIES & SUPERCAPS POST MORTEM ANALYSIS PLATFORM EXTERNAL SERVICES
|
|
- Opal Franklin
- 6 years ago
- Views:
Transcription
1 BATTERIES & SUPERCAPS POST MORTEM ANALYSIS PLATFORM EXTERNAL SERVICES
2 CONTEXT Over the last years a remarkable evolution has taken place by the introduction of new batteries & supercapacitors technologies in both traditional and new applications. It s lead to a fast rising number of manufacturers and new suppliers appearing in the market place. At the same time, more than thirty years of R+D in material science have resulted in better batteries and supercapacitors. These outcomes came from a better understanding of mechanism of the materials level. From the demand point of view, more stringent specifications are requested aiming at longer lifetime systems, while at the same time those energy storage devices become complex and expensive. In the context of supply and demand, within a very competitive market, it is essential to count with all possible tools that will allow an optimal integration of these technology providers amongst different end-user applications. The idea is to contribute not only to the added value of the final product, but also to gain competitive advantage to the company. A post-mortem study at material science level provides invaluable information on what type of treatment, quality of control and monitoring the battery and supercapacitor has been subjected during its lifetime. What it s learned will provide very useful information to extract the maximum possible economic advantage from those batteries and supercapacitors. The ageing behaviour depends on a wide range of parameters (e.g. state of charge, depth of discharge, charge/discharge rate, charge variability, and temperature). All those parameters must be studied in depth to better understanding the effects of different environmental conditions during ageing. The mechanisms of electrochemical device ageing can therefore be evaluate and correlate with them applications.
3 REQUIREMENTS FOR ADVANCED BATTERIES AND SUPERCAPS Power density Advanced Batteries Safety Operating Temperature Cycle/Calendar life Energy density Cost EXAMPLE OF ANALYSED SYSTEM Pouch cell Batteries 16.2 Ah, 3.7 V Supercaps F, 2.7V Prismatic battery Batteries 40 Ah, ~3.7 V Supercaps F, 2.7V Cylindrical battery Batteries 2.3 Ah, 3.3 V Supercaps F, 2.7V All-solid-state battery 300 mah, 3.75 V Coin cell < 1 mah, V
4 AGEING MECHANISMS IN LI-ION BATTERIES AND SUPERCAPACITORS AGEING CAUSES ENHANCING FACTORS IMPACT Electrolyte Electrolyte decomposition High T ( C), High C-rate Capacity, Safety Carbon anodes - electrode/electrolyte interface Electrolyte decomposition (Continuous side reaction at low rate) Solvent co-intercalation, gas evolution and subsequent cracking formation in particles Changes in porosity due to volume changes, SEI formation and growth Contact loss of active material particles due to volume changes during cycling High T ( C), High SOC (high voltage) Overcharge High C-rate and High SOC (high voltage), High T( ) High C-rate, High DOD Capacity, Power Capacity Power Capacity Decomposition of binder High SOC (high voltage) and High T ( C) Capacity Current collector corrosion Overdischarge, Low SOC Power Metallic lithium plating and subsequent electrolyte decomposition by metallic Li Binder decomposition Low T ( C), High C-rates Poor cell balance, Geometric misfits Electrolyte and electrode degradation by-product Oxidation conductive particle High T ( C), water trace in electrolyte Power Corrosion current collectors High T ( C), water trace in electrolyte Power Capacity, (Power) Power, Safety Li Metal Oxide - Structural desordering High T ( C), high C-rate Capacity Li Metal Oxide - Interphase transition High C-rate, High T ( C) Capacity Li Metal Oxide Metal dissolution High T ( C) Capacity, Power Electrolyte decomposition High T ( C), High C-rates, Poor cell airtight Power Separator Separator degradation High voltage Capacity Casing/ packaging Corrosion on hard casing High voltage Capacity Gas permeation on soft packaging High T ( C) Capacity Ageing will be different for each single type of battery and for each application
5 DEFINITION Post mortem Analysis is a process involving testing and characterization of battery & supercapacitor components, pre- and post-cycling, aiming to provide unique insight for establishing a correlation between battery / supercapacitor design operating conditions battery degradation. This will allow: * * Battery and supercapacitor companies to improve cell manufacturing processes refining their technology. End-user companies to: SCOPE Establishing a baseline of raw materials, followed by post-mortem analysis of electrodes and electrolytes complement performance testing. SIZE: Test methods are readily applied from button and coin cell to prismatic product. DEPTH: Phase I: basic system knowledge to have a first selection criteria input. * * Select the best technology to be implemented in their systems. Adapt the integration process providing solutions for more efficient Battery Management System (BMS). Better motoring the SOH and SOC of the battery / supercapacitor induced by the ageing and/or operating conditions. Phase II: deeper study involving not only Analytical Testing but also electrode & electrolyte surface characterization as well as current collectors. CIC postmortem-line Battery ageing Assessment Understanding of ageing mechanisms Advanced materials (lab scale) New design
6 PHASE I basic system knowledge to have a first selection criteria input Task 1: Disassembling of electrode-containing devices: include the ante-mortem and post-mortem cells. Task 2 : Physical, chemical and morphological characterization of aged components. Structural characterization to study the effect of ageing on the materials and possible sidereactions Optical characterization of the materials (visual observations) Optical microscopy Adhesion test Electron microscopy (EM) measurements to study changes in the microstructure, particle size, salt deposits, etc Deliverable: REPORT
7 PHASE II deeper study involving not only Analytical Testing but also electrode & electrolyte surface characterization as well as electrode compound (binder, current collector, conducting agent, porosity) and interactions between positive and negative material Task 3: XPS in order to characterize the surface of aged electrodes, separators and SEI Other characterization techniques. ICP-OES to determine the chemical composition/ impurities Raman spectroscopy, IR: e.g. surface groups on carbon Solid state NMR to characterize for example Solid-state lithiumion batteries polymer electrolyte Task 4: Post-tests electrochemical characterization on aged electrodes. Electrochemical tests to study the electrochemical behaviour of each electrode EIS will be used to evaluate the performance of supercapacitors and to study SEI layer, resistance, capacitance and charge transfer of Li-ion batteries electrode OTHER CONDITION OF LITHIUM BATTERY AGEING Analysis of cycle aged batteries at different temperatures, SOC windows and C-rates. TEMPERATURE ºC Copper Anode Current Collector Dissolves Cathode Breakdown Short Circuit LITHIUM ION CELL OPERATING WINDOW Thermal Runaway Death and Law Suits Possible Venting Cathode Active Material Breakdown Oxygen Release and Ignition Exothermic Breakdown of Electrolyte Release of Flammable Gases Pressure and Temperature Increase Separator Melts Breakdown of SEI Layer Temperature Rise Lithium Ion Safety Window Lithium Plating During Charging Capacity Loss Overheating Lithium Plating During Charging No Fires Yet CELL VOLTAGE (V)
8 BENEFITS Diagnostic of aged cells. Complete physico-chemical and morphological and electrochemical analysis including surface analysis (interaction electrode/liquid electrolyte) of the system components. Understandin g of ageing mechanisms for improvement of battery and supercaps materials. Understanding of ageing mechanisms for optimal use of the device. Rigorous protocols of investigation which can be easily reproduced. On the contrary of other centers, the focus of the post-mortem research line will be not only on the study of Li-ion technology for automotive applications but also development post mortem analysis applicable for other technologies such as Li-S or supercapacitors for various applications. TEAM Experienced team with more than five years of deep knowledge on the area. REFERENCES European projects within horizon MAT4BAT (European project 2016) Collaboration with local, national and international partners CEGASA IKERLAN Zentrum für Sonnenenergie- und Wasserstoff- Forschung (ZSW) Argonne National Laboratory CIC Energigune Industrial partners on a confidential basis CONTACT Dr. Emilie Bekaert. Research Line Manager ebekaert@cicenergigune.com Parque Tecnológico C/Albert Einstein, Miñano (Alava) Spain Jose Castellanos. Corporate Development Director jcastellanos@cicenergigune.com Parque Tecnológico C/Albert Einstein, Miñano (Alava) Spain Make a request and our team will contact you for a proposal.
// ZSW Laboratory for Battery Technology (elab)
// ZSW Laboratory for Battery Technology (elab) Now that the elab has been extended with industrial manufacturing technology, we have all the areas of battery research housed uniquely under one roof with
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 informationBatteries & Fuel Cells for a Sustainable Growth
Green Motions Ulm, 01.04.2014 Batteries & Fuel Cells for a Sustainable Growth Prof. Dr. Werner Tillmetz Zentrum für Sonnenenergie- und Wasserstoff-Forschung Baden-Württemberg (ZSW) -1- Targets in Energy
More informationAnalytical thermal model for characterizing a Li-ion battery cell
Analytical thermal model for characterizing a Li-ion battery cell Landi Daniele, Cicconi Paolo, Michele Germani Department of Mechanics, Polytechnic University of Marche Ancona (Italy) www.dipmec.univpm.it/disegno
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 informationImpact of Vehicle-to-Grid (V2G) on Battery Life
Impact of Vehicle-to-Grid (V2G) on Battery Life The Importance of Accurate Models David Howey, Jorn Reniers, Grietus Mulder, Sina Ober-Blöbaum Department of Engineering Science, University of Oxford EnergyVille,
More informationU.S. DOE Perspective on Lithium-ion Battery Safety
U.S. DOE Perspective on Lithium-ion Battery Safety David Howell US Department of Energy Washington, DC Technical Symposium: Safety Considerations for EVs powered by Li-ion Batteries The National Highway
More informationInternal Shorts Background
Internal Shorts Background Judy Jeevarajan, Ph.D. Underwriters Laboratories Inc. USA Battery Safety Council Forum 3 January 2017 and the logo are trademarks of LLC 2015 Charge / Discharge Characteristics
More informationDeliverable Abuse Test Plan for Li Batteries and SC
Responsible (Name, Organisation) F. V. Conte, Austrian Institute of Technology GmbH DELIVERABLE REPORT Issuer (Name, Organisation) H. Popp, Austrian Institute of Technology GmbH Subject Abuse testing procedure
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 informationUN/SCETDG/52/INF.11. Sodium-Ion Batteries. Introduction
Committee of Experts on the Transport of Dangerous Goods and on the Globally Harmonized System of Classification and Labelling of Chemicals UN/SCETDG/52/INF.11 Sub-Committee of Experts on the Transport
More informationStefan van Sterkenburg Stefan.van.sterken
Stefan van Sterkenburg Stefan.vansterkenburg@han.nl Stefan.van.sterken burgr@han.nl Contents Introduction of Lithium batteries Development of measurement equipment Electric / thermal battery model Aging
More informationSmart Batteries. Smart Battery Management SMBus v1.1. Rev
Smart Batteries Smart Battery Management SMBus v1.1 1 Rev 1.5 01.12.2014 Smart Battery Packs STANDARD PACKS CUSTOMISED PACKS 2 Hazardous failures of lithium-ion 1. Lithium ions travel through the separator
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 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 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 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 informationFRAUNHOFER INSTITUTE FOR CHEMICAL TECHNOLOGY ICT REDOX-FLOW BATTERY
FRAUNHOFER INSTITUTE FOR CHEMICAL TECHNOLOGY ICT REDOX-FLOW BATTERY REDOX-FLOW BATTERY REDOX-FLOW BATTERY Redox-flow batteries are efficient and have a longer service life than conventional batteries.
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 informationSupercapacitors: A Comparative Analysis
Supercapacitors: A Comparative Analysis Authors: Sneha Lele, Ph.D., Ashish Arora, M.S.E.E., P.E. Introduction Batteries, fuel cells, capacitors and supercapacitors are all examples of energy storage devices.
More informationLithium Coin Handbook and Application Manual
: Lithium coin cells were originally developed in the 1970 s as a 3 volt miniature power source for low drain and battery backup applications. Their high energy density and long shelf life made them well
More informationNational Highway Traffic Safety Administration
National Highway Traffic Safety Administration Status Update on NHTSA s Lithium-ion based Rechargeable Energy Storage System Safety Research Programs November 2014 Phil Gorney NHTSA Vehicle Safety Research
More informationDr. Pierrot S. Attidekou RA Newcastle University
Dr. Pierrot S. Attidekou RA Newcastle University Research collaboration between 2 schools: CEAM & EEE School of Chemical Engineering and Advance Materials School of Electrical and Electronic Engineering
More informationState of Health Estimation for Lithium Ion Batteries NSERC Report for the UBC/JTT Engage Project
State of Health Estimation for Lithium Ion Batteries NSERC Report for the UBC/JTT Engage Project Arman Bonakapour Wei Dong James Garry Bhushan Gopaluni XiangRong Kong Alex Pui Daniel Wang Brian Wetton
More informationSPECIALTY CARBON BLACKS HIGH PERFORMANCE MATERIALS FOR ADVANCED LITHIUM-ION BATTERIES
SPECIALTY CARBON BLACKS HIGH PERFORMANCE MATERIALS FOR ADVANCED LITHIUM-ION BATTERIES Introduction Cabot Corporation is a global performance materials company and we strive to be our customers commercial
More informationGuidelines for Battery Electric Vehicles in the Underground
Guidelines for Battery Electric Vehicles in the Underground Energy Storage Systems Rich Zajkowski Energy Storage Safety & Compliance Eng. GE Transportation Agenda Terminology Let s Design a Battery System
More informationEnhancing the Reliability & Safety of Lithium Ion Batteries
Enhancing the Reliability & Safety of Lithium Ion Batteries Over the past 20 years, significant advances have been made in rechargeable lithium-ion (Li-Ion) battery technologies. Li-Ion batteries now offer
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 informationarxiv:submit/ [math.gm] 27 Mar 2018
arxiv:submit/2209270 [math.gm] 27 Mar 2018 State of Health Estimation for Lithium Ion Batteries NSERC Report for the UBC/JTT Engage Project Arman Bonakapour Wei Dong James Garry Bhushan Gopaluni XiangRong
More informationOur Solutions for Automotive.
Our Solutions for Automotive www.horiba.com info.sci@horiba.com Solutions for Automotive Your Lab Partner Analytical examples of all vehicle parts We support new material developments required for next-generation
More informationSafeguarding lithium-ion battery cell separators
Safeguarding lithium-ion battery cell separators Executive Summary Technical advances in the design and construction of lithium-ion battery cells have played an essential role in the widespread deployment
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 informationZSW - laboratory for battery technology
5th conference on Transport and Research in the Danube Region 13-14 November 2018, Ljubljana ZSW - laboratory for battery technology Dr Mario Marinaro, Dr. Margret Wohlfahrt-Mehrens E-Mail: mario.marinaro@zsw-bw.de
More informationCURRENT AND FUTURE PROPAGATION TEST AND THE EMBEDDING IN PRODUCT SAFETY THOMAS TIMKE, JRC
CURRENT AND FUTURE PROPAGATION TEST AND THE EMBEDDING IN PRODUCT SAFETY THOMAS TIMKE, JRC 09.03.2018 SOLARWATT COMMITMENT Safety Not negotiable Lifetime & Performance Current main topic in Germany Complete
More informationLithium Ion Medium Power Battery Design
Bradley University Lithium Ion Medium Power Battery Design Project Proposal By: Jeremy Karrick and Charles Lau Advised by: Dr. Brian D. Huggins 12/10/2009 Introduction The objective of this project is
More informationProgress on thermal propagation testing
The European Commission s science and knowledge service Joint Research Centre Progress on thermal propagation testing Akos Kriston, Andreas Pfrang, Vanesa Ruiz, Ibtissam Adanouj, Franco Di Persio, Marek
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 informationProgress on thermal propagation testing
The European Commission s science and knowledge service Joint Research Centre Progress on thermal propagation testing Andreas Pfrang, Vanesa Ruiz, Akos Kriston, Natalia Lebedeva, Ibtissam Adanouj, Theodora
More informationEnergy Storage Technology Roadmap Lithium Ion Technologies
Energy, Mining and Environment Portfolio Energy Storage Technology Roadmap Lithium Ion Technologies Isobel Davidson, Principal Research Officer 19 November 2014 Energy Storage Technology Roadmap Li ion
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 informationMidterm Event. Holger Czuday, Bayern Innovativ 7th February Automotive Battery Recycling and 2nd Life
Midterm Event Holger Czuday, Bayern Innovativ 7th February 2014 Automotive Battery Recycling and 2nd Life 1 Consortium: D NL - F External: Paris, 15 janvier 2014 2 Problem description Daily message at
More informationDesign of Electric Drive Vehicle Batteries for Long Life and Low Cost
Design of Electric Drive Vehicle Batteries for Long Life and Low Cost Robustness to Geographic and Consumer-Usage Variation Kandler Smith* Tony Markel Gi-Heon Kim Ahmad Pesaran Presented at the IEEE 2010
More informationPractical aspects & hurdles in the development of low-cost highperformance
Practical aspects & hurdles in the development of low-cost highperformance supercapacitors A.G. Pandolfo, A.M.Vassallo, CSIRO Division of Coal & Energy Technology, PO Box 136 North Ryde, NSW 2113 Australia
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 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 informationRequirement, Design, and Challenges in Inorganic Solid State Batteries
Requirement, Design, and Challenges in Inorganic Solid State Batteries Venkat Anandan Energy Storage Research Department 1 Ford s Electrified Vehicle Line-up HEV Hybrid Electric Vehicle C-Max Hybrid Fusion
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 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 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 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 informationLithium-ion Batteries Material Strategy and Positioning. Energy Storage HARDWARE
HARDWARE Energy Storage Lithium-ion Batteries Material Strategy and Positioning Lithium-ion batteries are to replace the nickel-metal hydride batteries that are currently being used in hybrid motor vehicles
More informationBattery Fingerprint Technologies
Battery Fingerprint Technologies Battery diagnostics for manufacturers and users to improve capacity, reliability, and safety Emilia Silletta AEC 2018 - March 27 th, 2018 Samsung Galaxy Note 7 Current
More informationLithium battery charging
Lithium battery charging How to charge to extend battery life? Why Lithium? Compared with the traditional battery, lithium ion battery charge faster, last longer, and have a higher power density for more
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 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 informationI. Equivalent Circuit Models Lecture 3: Electrochemical Energy Storage
I. Equivalent Circuit Models Lecture 3: Electrochemical Energy Storage MIT Student In this lecture, we will learn some examples of electrochemical energy storage. A general idea of electrochemical energy
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 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 informationKeeping Higher Current Lithium-ion Battery Cells Safe with Effective Overtemperature Protection
Keeping Higher Current Lithium-ion Battery Cells Safe with Effective Overtemperature Protection INTRODUCTION WHITE PAPER The explosion in use of consumer electronics is the result of multiple trends not
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 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 informationEENERGY EFFICIENCY. German-Japanese Energy Symposium Lithium-Ion-Technology in mobile und stationary applications. February 10 th, 2011
German-Japanese Energy Symposium 2011 Lithium-Ion-Technology in mobile und stationary applications EENERGY EFFICIENCY CO EENERGY EFFICIENCY CLIMATE PROTECTION2 February 10 th, 2011 Carsten Kolligs Evonik
More informationFrom the material to the cell
F R A U N H O F E R B atter y A lliance Fraunhofer Battery Alliance 1 2 High-performance batteries are key components in mobile and stationary electrically-powered applications, and are also the most complex
More informationThermal Battery Development Reduced Product Variability Through Six Sigma and Materials Finger-Printing
Power Sources Center 50 th Annual NDIA Fuze Conference Norfolk, VA 9-11 May 2006 Thermal Battery Development Reduced Product Variability Through Six Sigma and Materials Finger-Printing Authors: Paul F.
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 informationINTERNATIONAL STANDARD
INTERNATIONAL STANDARD IEC 62281 Edition 2.0 2012-12 colour inside Safety of primary and secondary lithium cells and batteries during transport INTERNATIONAL ELECTROTECHNICAL COMMISSION PRICE CODE T ICS
More informationCongratulations, Dorothy!
Congratulations, Dorothy! Battery Overview Steve Garland Kyle Jamieson Outline Why is this important? Brief history of batteries Basic chemistry Battery types and characteristics Case study: ThinkPad battery
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 informationTRANSPORT OF DANGEROUS GOODS
Recommendations on the TRANSPORT OF DANGEROUS GOODS Manual of Tests and Criteria Fifth revised edition Amendment 1 UNITED NATIONS SECTION 38 38.3 Amend to read as follows: "38.3 Lithium metal and lithium
More informationFormation and finishing
System Engineering for the battery industry Formation and finishing of lithium-ion cells 2 3 Extensive experience, a global leader with close proximity to the customers thyssenkrupp System Engineering
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 informationEnergy Storage. 9. Power Converter Demo. Assoc. prof. Hrvoje Pandžić. Vedran Bobanac, PhD
Energy Storage 9. Power Converter Demo Assoc. prof. Hrvoje Pandžić Vedran Bobanac, PhD Lecture Outline Rechargeable batteries basics Power converter for experimenting with rechargeable batteries Rechargeable
More informationAalborg Universitet. Published in: ECS Transactions. DOI (link to publication from Publisher): / ecst. Publication date: 2015
Aalborg Universitet Study on Self-discharge Behavior of Lithium-Sulfur Batteries Knap, Vaclav; Stroe, Daniel-Ioan; Swierczynski, Maciej Jozef; Teodorescu, Remus; Schaltz, Erik Published in: ECS Transactions
More informationBattery Pack Design. Mechanical and electrical layout, Thermal modeling, Battery management. Avo Reinap, IEA/LU
mvkf25vt18 Battery Pack Design Mechanical and electrical layout, Thermal modeling, Battery management Avo Reinap, IEA/LU Energy Management Battery management system Information Energy Monitoring measure
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 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 informationStudy of Thermal and Electrochemical Characteristics of Li-ion Battery
Study of Thermal and Electrochemical Characteristics of Li-ion Battery 1 Anand R. Savandkar, 2 D. S. Watvisave 1 P.G. Student, 2 Assistant Professor (Dept. of Mechanical Engineering, SCoE, Pune University,
More informationSafety information on VIKING type AAI lithium-ion batteries for use in imow robotic mowers
Safety information on VIKING type AAI lithium-ion batteries for use in imow robotic mowers Revised on: 18/03/2015 1 Company and product designations... 2 1.1 Trade name... 2 1.2 Manufacturer/supplier information...
More informationNickel Zinc Battery Evaluation at Crane
Nickel Zinc Battery Evaluation at Crane Presented By: Alex Potter and Scott Lichte 5/3/17 CAPT JT Elder, USN Commanding Officer NSWC Crane Dr. Brett Seidle, SES Technical Director NSWC Crane Distribution
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 informationDevelopment and application of CALB olivine-phosphate batteries
Development and application of CALB olivine-phosphate batteries 1 Agenda Introducing CALB Application and research on LFP/C batteries Development of high energy NCM+LMFP/C batteries Summary 2 Advanced
More informationLITHIUM-ION BATTERIES SUSTAINABLE ENERGY NEW SCIENCE JOURNAL ISSUE IV UL.COM/NEWSCIENCE
NEW SCIENCE SUSTAINABLE ENERGY LITHIUM-ION BATTERIES COMPUTATIONAL MODELING OF LITHIUM-ION BATTERIES SAFEGUARDING LITHIUM-ION BATTERY SEPARATORS THERMAL ANALYSIS OF LITHIUM-ION BATTERIES JOURNAL ISSUE
More informationThis short paper describes a novel approach to determine the state of health of a LiFP (LiFePO 4
Impedance Modeling of Li Batteries for Determination of State of Charge and State of Health SA100 Introduction Li-Ion batteries and their derivatives are being used in ever increasing and demanding applications.
More informationCATALOG. <Japanese> <English>
CATALOG About delivery style, consult the sales representative. About the minimum order quantity, consult the sales representative. Product specification and appearance are subject to change for improvement.
More informationFREUDENBERG SEALING TECHNOLOGIES Preventing thermal propagation approaches & effort to implement them in a battery system
FREUDENBERG SEALING TECHNOLOGIES Preventing thermal propagation approaches & effort to implement them in a battery system March 09, 2018 Mario Harwar // Stefan Morgenstern // Peter Kritzer Freudenberg
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 informationModeling the Lithium-Ion Battery
Modeling the Lithium-Ion Battery Dr. Andreas Nyman, Intertek Semko Dr. Henrik Ekström, Comsol The term lithium-ion battery refers to an entire family of battery chemistries. The common properties of these
More informationEUROBAT EUROBAT GUIDE FOR MOTIVE POWER VRLA BATTERIES
EUROBAT EUROBAT GUIDE FOR MOTIVE POWER VRLA BATTERIES EUROBAT, the Association of European Storage Battery Manufacturers, has 36 regular and associate member companies and represents more than 85 % of
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 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 informationUNIVERSITY OF MICHIGAN BATTERY MANUFACTURING COURSE OUTLINE
UNIVERSITY OF MICHIGAN BATTERY MANUFACTURING COURSE OUTLINE An instructional team composed of battery experts from industry and the University of Michigan teach this 4-day course. The program outline is
More informationThe Future of Advanced Lead Batteries and the New ALABC Program
Threats The Future of Advanced Lead Batteries and the New ALABC Program Boris Monahov* and Alistair Davidson** *Advanced Lead Acid Battery Consortium **International Lead Association ILA and ALABC PRODUCT
More informationZinc-Air Batteries for UAVs and MAVs
Zinc-Air Batteries for UAVs and MAVs Dr. Neal Naimer, Vice President R&D (speaker) Binyamin Koretz, Vice President Business Development Ronald Putt, Director of Technology Electric Fuel Corporation Auburn,
More informationMetal-air batteries. Joan Gómez Chabrera Alejandro Andreu Nácher Pablo Bou Pérez
Metal-air batteries Joan Gómez Chabrera Alejandro Andreu Nácher Pablo Bou Pérez Index 1. Introduction 2. Principle of operation of metal-air batteries 3. Air cathodes 4. Types 5. General aplications 6.
More informationWORKSHOP ON BATTERY TESTING
WORKSHOP ON BATTERY TESTING PROCEDURES Maciej Swierczynski Post Doc mas@et.aau.dk 9/10/2014 Agenda 10:00 11:00 Round the table, battery cells connection methods, battery holders, low resistance cell connection
More informationFINAL REPORT For Japan-Korea Joint Research Project
FINAL REPORT For Japan-Korea Joint Research Project AREA 1. Mathematics & Physics 2. Chemistry & Material Science 3. Biology 4. Informatics & Mechatronics 5. Geo-Science & Space Science 6. Medical Science
More informationBattery Selection, Safety, and Monitoring in Mobile Applications
Battery Selection, Safety, and Monitoring in Mobile Applications Yevgen Barsukov, Texas Instruments ABSTRACT The battery is often considered by engineers as a constant voltage source that does not require
More informationVehicle 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 informationElectric cars: Technology
Alternating current (AC) Type of electric current which periodically switches its direction of flow. Ampere (A) It is the SI unit of electric current, which is equivalent to flow of 1 Coulumb electric
More informationBAllistic SImulation Method for Lithium Ion Batteries(BASIMLIB) using Thick Shell Composites (TSC) in LS-DYNA
BAllistic SImulation Method for Lithium Ion Batteries() using Thick Shell Composites (TSC) in LS-DYNA DISCLAIMER: Reference herein to any specific commercial company, product, process, or service by trade
More information