This document provides an introduction to lithium battery technology, focusing on lithium ion batteries. It discusses the chemistry and features of lithium metal primary batteries and lithium ion secondary batteries. Lithium ion batteries have benefits like being rechargeable and having high energy density, but also drawbacks like fire potential if not properly designed. The document examines battery failure mechanisms like thermal runaway and the deposition of lithium metal. It analyzes the different classes of battery fires and properties of lithium ion cell burns, noting they can involve multiple fire classes and the release of flammable and toxic gases. EUCAR hazard levels for batteries are presented, ranging from no effect to explosion. Fire suppression methods are also briefly mentioned.
Solid electrolytes for lithium ion solid state batteries patent landscape 201...Knowmade
Report’s Key Features
• PDF with > 250 slides
• Excel file > 5,800 patents
• IP trends, including time-evolution of published patents, legal status, countries of patent filings, etc.
• Ranking of main patent assignees
• Patent categorization by type of electrolyte (polymer, inorganic, inorganic/polymer) and inorganic electrolyte materials (sulfide glass ceramics, Thio-LISICON, argyrodite, oxide glass ceramics, NASICON, perovskite, garnet, anti-perovskite, hydride)
• For each technical segment: IP dynamics, ranking of main patent assignees, newcomers, key IP players (leadership, blocking potential, portfolio strength), key patents, and recent development trends
• For each key IP player (100+ companies): Time-evolution of patenting activity, legal status of patents and countries of patent filings, patent segmentation by electrolyte material, IP strengths and weaknesses by electrolyte material
• Excel database containing all patents analyzed in this report, including technology and material segmentations
Part 1 of the tutorial on the Lithium Battery Explorer provides an overview of Li-ion battery technology and the properties that are relevant to battery researchers.
Interested viewers should refer to the following publications for more details:
1) Review: G. Ceder, G. Hautier, A. Jain, S. P. Ong. Recharging lithium battery research with first-principles methods. MRS Bulletin, 2011, 36, 185--191.
2) Computational Electrode Assessment: G. Hautier, A. Jain, S. P. Ong, B. Kang, C. Moore, R. Doe, and G. Ceder. Phosphates as Lithium-Ion Battery Cathodes: An Evaluation Based on High-Throughput ab Initio Calculations. Chemistry of Materials, 2011, 23(15), 3495-3508.
3) Predicting Battery Safety: S. P. Ong, A. Jain, G. Hautier, B. Kang, & G. Ceder. Thermal stabilities of delithiated olivine MPO4 (M=Fe, Mn) cathodes investigated using first principles calculations. Electrochemistry Communications, 2010, 12(3), 427--430.
Solid electrolytes for lithium ion solid state batteries patent landscape 201...Knowmade
Report’s Key Features
• PDF with > 250 slides
• Excel file > 5,800 patents
• IP trends, including time-evolution of published patents, legal status, countries of patent filings, etc.
• Ranking of main patent assignees
• Patent categorization by type of electrolyte (polymer, inorganic, inorganic/polymer) and inorganic electrolyte materials (sulfide glass ceramics, Thio-LISICON, argyrodite, oxide glass ceramics, NASICON, perovskite, garnet, anti-perovskite, hydride)
• For each technical segment: IP dynamics, ranking of main patent assignees, newcomers, key IP players (leadership, blocking potential, portfolio strength), key patents, and recent development trends
• For each key IP player (100+ companies): Time-evolution of patenting activity, legal status of patents and countries of patent filings, patent segmentation by electrolyte material, IP strengths and weaknesses by electrolyte material
• Excel database containing all patents analyzed in this report, including technology and material segmentations
Part 1 of the tutorial on the Lithium Battery Explorer provides an overview of Li-ion battery technology and the properties that are relevant to battery researchers.
Interested viewers should refer to the following publications for more details:
1) Review: G. Ceder, G. Hautier, A. Jain, S. P. Ong. Recharging lithium battery research with first-principles methods. MRS Bulletin, 2011, 36, 185--191.
2) Computational Electrode Assessment: G. Hautier, A. Jain, S. P. Ong, B. Kang, C. Moore, R. Doe, and G. Ceder. Phosphates as Lithium-Ion Battery Cathodes: An Evaluation Based on High-Throughput ab Initio Calculations. Chemistry of Materials, 2011, 23(15), 3495-3508.
3) Predicting Battery Safety: S. P. Ong, A. Jain, G. Hautier, B. Kang, & G. Ceder. Thermal stabilities of delithiated olivine MPO4 (M=Fe, Mn) cathodes investigated using first principles calculations. Electrochemistry Communications, 2010, 12(3), 427--430.
High energy and capacity cathode material for li ion battriesNatraj Hulsure
Recent development in cathode materials for li-ion batteries drag the industries view towards it due to their high discharge rate compare to older ones.
A feasible way towards safer, better-performing batteries?
Conventional Li-ion battery technologies, based on flammable liquid electrolytes, are continuously improving. However, faster progress towards greater safety, higher performance, and better cost reduction is desired. A next-generation battery technology like solid-state battery, which uses solid electrodes and solid electrolytes, could potentially satisfy these objectives.
More information on : https://www.i-micronews.com/batteries-energy-mgmt/product/solid-state-battery.html
The lithium-ion batteries are first made safe for mechanical treatment, with plastics, aluminum, and copper separated and directed to their own recycling processes. Moreover, the incredible efforts are being made to develop electrode materials, electrolytes, and separators for energy storage devices to meet the needs of emerging technologies such as electric vehicles, decarbonizes electricity, and electrochemical energy storage.
Status of Rechargeable Li-ion Battery Industry 2019 by Yole DéveloppementYole Developpement
E-mobility continues strongly driving the Li-ion battery demand.
More information on https://www.i-micronews.com/products/status-of-rechargeable-li-ion-battery-industry-2019/
This is the academic presentation by Rahmandhika Firdauzha Hary Hernandha for Materials for Energy Storage and Conversion Device course in National Chiao Tung University, Taiwan. The slides based on an academic paper in Electrochem. Soc. Interface, 2016, 25(3), 85-87 by Stefano Passerini and Bruno Scrosati with other 10 papers as supporting information and images.
Lithium-Ion Battery (LIB) Manufacturing Industry. Start a Li-ion Battery Production. Battery Assembling Business
Lithium is a silver-white colored soft metal that belongs to the alkali metal group. Lithium is the lightest element known and has strong electrochemical potential. It is highly reactive element making it flammable and potentially explosive when exposed to air and water and is usually stored in mineral oil to preserve it from corrosion and tarnish.
Lithium-ion batteries have become the most important application of lithium and storage technology in the areas of portable and mobile applications (e.g. laptops, cell phones, smartphones, tablets, power tools, medical devices electric bicycles and electric cars).
See more
https://goo.gl/iaLHB3
Contact us:
Niir Project Consultancy Services
An ISO 9001:2015 Company
106-E, Kamla Nagar, Opp. Spark Mall,
New Delhi-110007, India.
Email: npcs.ei@gmail.com , info@entrepreneurindia.co
Tel: +91-11-23843955, 23845654, 23845886, 8800733955
Mobile: +91-9811043595
Website: www.entrepreneurindia.co , www.niir.org
Tags
#Lithium_Ion_Battery_Assembly, #Li_Ion_Battery_Assembling, Lithium-Ion Battery, #Lithium_Ion_Batteries_Production, Manufacturing of Lithium-Ion Batteries, Lithium-Ion Battery Manufacturing, #Lithium_Ion_Battery_Assembly_Plant, Lithium Ion Battery Manufacturing Process, Lithium Ion Battery Assembly Process, Lithium Ion Battery Manufacturing Cost, How to Set up Lithium Ion Battery Plant in India, #How_to_Start_Lithium_Ion_Battery_Manufacturing_Business, Battery Manufacturing Process, Battery Manufacturing, Lithium Ion Battery Production, Lithium Ion Battery Manufacture, #Production_of_Lithium_Ion_Battery, Battery Assembly, Battery Assembly Plant, Battery Manufacturing Plant, Project Report on Lithium Ion Battery Assembly Industry, Detailed Project Report on Lithium Ion Battery Production, #Project_Report_on_Lithium_Ion_Battery_Manufacturing, Pre-Investment Feasibility Study on Lithium Ion Battery Assembly Plant, Techno-Economic feasibility study on Lithium Ion Battery Assembly Plant, #Feasibility_report_on_Lithium_Ion_Battery_Production, Free Project Profile on Lithium Ion Battery Assembly, Project profile on Lithium Ion Battery Production, #Download_free_project_profile_on_Lithium_Ion_Battery_Assembly, Lithium-Ion Battery Factory, How to Start a Battery Manufacturing Business, Cost of Setting up a Battery Manufacturing Plant, Lithium-Ion Battery Business, #Lithium_Ion_Battery_Manufacturing_Industry
In this presentation we learn basics of how the lithium-ion works and reacts with the environment to produce a unique source of energy storage device called battery.
In this presentation we will deal with:
Introducing Lithium-Ion Battery
It’s Construction
It’s Working
It’s Cell Reactions
It’s Advantages & Disadvantages
It’s Application, etc.
High energy and capacity cathode material for li ion battriesNatraj Hulsure
Recent development in cathode materials for li-ion batteries drag the industries view towards it due to their high discharge rate compare to older ones.
A feasible way towards safer, better-performing batteries?
Conventional Li-ion battery technologies, based on flammable liquid electrolytes, are continuously improving. However, faster progress towards greater safety, higher performance, and better cost reduction is desired. A next-generation battery technology like solid-state battery, which uses solid electrodes and solid electrolytes, could potentially satisfy these objectives.
More information on : https://www.i-micronews.com/batteries-energy-mgmt/product/solid-state-battery.html
The lithium-ion batteries are first made safe for mechanical treatment, with plastics, aluminum, and copper separated and directed to their own recycling processes. Moreover, the incredible efforts are being made to develop electrode materials, electrolytes, and separators for energy storage devices to meet the needs of emerging technologies such as electric vehicles, decarbonizes electricity, and electrochemical energy storage.
Status of Rechargeable Li-ion Battery Industry 2019 by Yole DéveloppementYole Developpement
E-mobility continues strongly driving the Li-ion battery demand.
More information on https://www.i-micronews.com/products/status-of-rechargeable-li-ion-battery-industry-2019/
This is the academic presentation by Rahmandhika Firdauzha Hary Hernandha for Materials for Energy Storage and Conversion Device course in National Chiao Tung University, Taiwan. The slides based on an academic paper in Electrochem. Soc. Interface, 2016, 25(3), 85-87 by Stefano Passerini and Bruno Scrosati with other 10 papers as supporting information and images.
Lithium-Ion Battery (LIB) Manufacturing Industry. Start a Li-ion Battery Production. Battery Assembling Business
Lithium is a silver-white colored soft metal that belongs to the alkali metal group. Lithium is the lightest element known and has strong electrochemical potential. It is highly reactive element making it flammable and potentially explosive when exposed to air and water and is usually stored in mineral oil to preserve it from corrosion and tarnish.
Lithium-ion batteries have become the most important application of lithium and storage technology in the areas of portable and mobile applications (e.g. laptops, cell phones, smartphones, tablets, power tools, medical devices electric bicycles and electric cars).
See more
https://goo.gl/iaLHB3
Contact us:
Niir Project Consultancy Services
An ISO 9001:2015 Company
106-E, Kamla Nagar, Opp. Spark Mall,
New Delhi-110007, India.
Email: npcs.ei@gmail.com , info@entrepreneurindia.co
Tel: +91-11-23843955, 23845654, 23845886, 8800733955
Mobile: +91-9811043595
Website: www.entrepreneurindia.co , www.niir.org
Tags
#Lithium_Ion_Battery_Assembly, #Li_Ion_Battery_Assembling, Lithium-Ion Battery, #Lithium_Ion_Batteries_Production, Manufacturing of Lithium-Ion Batteries, Lithium-Ion Battery Manufacturing, #Lithium_Ion_Battery_Assembly_Plant, Lithium Ion Battery Manufacturing Process, Lithium Ion Battery Assembly Process, Lithium Ion Battery Manufacturing Cost, How to Set up Lithium Ion Battery Plant in India, #How_to_Start_Lithium_Ion_Battery_Manufacturing_Business, Battery Manufacturing Process, Battery Manufacturing, Lithium Ion Battery Production, Lithium Ion Battery Manufacture, #Production_of_Lithium_Ion_Battery, Battery Assembly, Battery Assembly Plant, Battery Manufacturing Plant, Project Report on Lithium Ion Battery Assembly Industry, Detailed Project Report on Lithium Ion Battery Production, #Project_Report_on_Lithium_Ion_Battery_Manufacturing, Pre-Investment Feasibility Study on Lithium Ion Battery Assembly Plant, Techno-Economic feasibility study on Lithium Ion Battery Assembly Plant, #Feasibility_report_on_Lithium_Ion_Battery_Production, Free Project Profile on Lithium Ion Battery Assembly, Project profile on Lithium Ion Battery Production, #Download_free_project_profile_on_Lithium_Ion_Battery_Assembly, Lithium-Ion Battery Factory, How to Start a Battery Manufacturing Business, Cost of Setting up a Battery Manufacturing Plant, Lithium-Ion Battery Business, #Lithium_Ion_Battery_Manufacturing_Industry
In this presentation we learn basics of how the lithium-ion works and reacts with the environment to produce a unique source of energy storage device called battery.
In this presentation we will deal with:
Introducing Lithium-Ion Battery
It’s Construction
It’s Working
It’s Cell Reactions
It’s Advantages & Disadvantages
It’s Application, etc.
A lithium-ion battery (sometimes Li-ion battery or LIB) is a member of a family of rechargeable battery types in which lithium ions move from the negative electrode to the positive electrode during discharge and back when charging. Li-ion batteries use an intercalated lithium compound as one electrode material, compared to the metallic lithium used in a non-rechargeable lithium battery. The electrolyte, which allows for ionic movement, and the two electrodes are the constituent components of a lithium-ion battery cell.
A Lithium Ion Capacitor is a hybrid device which combines the intercalation mechanism of a Lithium battery with the [cathode] of an electric double-layer capacitor (EDLC).
5. 5
Battery Features
Battery Chemistry
Lithium Ion (Secondary)
Drawbacks
•Considerable fire potential
•Requires safety circuitry
•Questionable tolerance for aging
•Transportation and storage restrictions
6. Battery Features
6
Lithium (Ion) Focus
They have a negatively charged Carbon anode,
a positively-charged Metal Oxyde Cathode and Lithium
Ion Compound as electrolyte.
Lithium Ion Batteries run down and require recharging.
Lithium Ion Automotive batteries hold a large amount
of potential energy!
11. 11
Battery Failure
Lithium metal deposits
Lithium Ion cellEnergetic Battery Failure
Electrical Abuse
•Lithium plating
a) A chemical/electrical
process that basically
transforms free lithium
ions into lithium metal
(deposits).
a) Fire and explosion risks
grow substantially
13. 13
Battery Fire Behavior
Battery Fire Classes
Batteries can be “multi-classed”
with some fitting comfortably into
ALL four common classes!
14. 14
Battery Fire Behavior
Battery Fire Classes
Lithium (Primary)
•Combustible build materials (A)
•Combustible metals (D)
•Possibly energized (C)
15. 15
Battery Fire Behavior
Battery Fire Classes
Lithium Ion (Secondary)
•Combustible build materials (A)
•Flammable Electrolyte (B)
•Possibly energized (C)
Question:
Can Lithium Plating add a
“Combustible metals”
component?
16. 16
Battery Fire Behavior
Battery Fire Classes
Class A – Water works Best
Class B- Smother Effects on
flammable liquid, venting
gases, N2 possible
Class C - Non Conductive
Agent, CO2
Class D – Metals, Dry
Powder, Sand
17. 17
Battery Fire Behavior
Composed of many
“ordinary
combustible”
materials
Battery Fire Classes
Question: Why are lithium (ion) batteries not limited
to any one class of fire?
18. 18
Battery Fire Behavior
Battery Fire Classes
Question: Why are lithium (ion) batteries not limited
to any one class of fire?
Contain flammable
liquids in electrolyte
form
19. 19
Battery Fire Behavior
Battery Fire Classes
Question: Why are lithium (ion) batteries not limited
to any one class of fire?
May possess an
electrical shock
hazard
20. 20
Battery Fire Behavior
Battery Fire Classes
Question: Why are lithium (ion) batteries not limited
to any one class of fire?
Lithium (primary)
cells possess
combustible metals
21. 21
Battery Fire Behavior
Battery Fire Properties
Question: What are the properties of
Lithium (ion) cell burn?
Gas release (burn and no burn)
Severe:
•Skin burn
•Eye irritation
•Respiratory issues
•Disorientation
22. 22
Battery Fire Behavior
Battery Fire Classes
Question: What are the properties of
Lithium (ion) cell burn?
•Hydrogen
•Carbon dioxide
•Carbon monoxide
•Methane
•Ethylene
•Ethane
•Propylene
Source: Sandia National Labs. Gas
release during cell venting.
23. 23
EUCAR Hazard Levels
(European Council for Automotive Research)
Hazard
Level
Description Classification Criteria
0 No effect No effect. No loss of functionality
1
Passive protection
activated
No defect; no leakage; no venting fire or flame;
no rupture; no explosion; no exothermic reaction or thermal runaway.
Cell irreversibly damaged. Repair is needed.
2 Defect / Damage
No leakage; no venting fire or flame; no rupture; no explosion; no exothermic
reaction or thermal runaway. Cell irreversibly damaged. Repair is needed.
3
Leakage
Δ mass < 50%
No venting, fire or flame*; no rupture; no explosion.
Weight loss < 50% of electrolyte weight (electrolyte = solvent + salt)
4
Venting
Δ mass ≥ 50%
No fire or flame*; no rupture; no explosion.
Weight loss ≥ 50% of electrolyte weight (electrolyte = solvent + salt)
5 Fire or Flame No rupture; no explosion (i.e., no flying parts)
6 Rupture No explosion, but flying parts of the active mass
7 Explosion Explosion (i.e., disintegration of the cell)