Calorimetric Measurements of Lithium-Ion Batteries Under Use and Abuse

January 21, 2020 | 7:40 pm

$0.00

This presentation will describe two main types of calorimetric techniques that can be used to carry out performance and safety testing on batteries. These are isothermal calorimetry and adiabatic calorimetry.

The first half of the presentation will introduce isothermal calorimetry; the various types of instruments, the method of operation, and examples of data that can be obtained. The second half of the presentation will cover battery testing methods for the ARC adiabatic calorimeter system. The theoretical background of the test method will be described, and recommended practice for various types of testing will be discussed.

The presentation will also mention complementary test methods that can be integrated with calorimetry to provide even more useful analysis.

This webinar will focus on the following key topics:

• Principles of isothermal and adiabatic calorimetry for batteries
• Advantages and limitations of these two methods
• Discussion of applications and results
• Recommended testing practices

Presenter
Danny Montgomery – Technical Performance Manager at THT

Danny Montgomery has worked in Thermal Hazard Technology UK for 11 years. He joined the company after graduating from Southampton University with a master’s degree in physics. His current position is Technical Performance Manager. He manages THT’s test lab and continues to expand THT’s testing capability into new areas of interest for a range of high-profile clients. As well as managing the lab, Danny is involved with technical support, installation and training for THT’s calorimeter systems. He has provided training for major international companies such as Panasonic, LG, Samsung, BMW and Underwriters Laboratory.

Thermal Hazard Technology (THT) is a proud sponsor of this event.

Categories: , ,

Related products

  • Placeholder

    Beyond Electrochemical Analysis – 2D to 4D Correlation of Microstructure and Chemistry in Li-ion Batteries

    Single imaging instruments as well as correlative microscopy workflows have demonstrated some unique abilities to support LIB research beyond electrochemical analysis methods. Light microscopy delivers insights about ablation effects & phase orientations in the active material, while scanning electron microscopy (SEM) reveals information about aging effects, nanometer cracks & the composition of the active material. Combining SEM with in-situ Raman spectroscopy extends the traditional SEM capabilities to organic and inorganic material identification. X-ray microscopy, furthermore, delivers 3D non-destructive imaging of full battery packs and localized high-resolution information, thus allowing the identification of regions of interest within the battery material volume. This presentation will demonstrate the application of these techniques to Li-ion battery research, including examples on anode, cathode, binder, and separator materials.

    This webinar will focus on the following key topics:

    • Introduction to available microscopic investigation techniques
    for Li-ion battery research:
    – Light Microscopy
    – Scanning Electron Microscopy
    – X-ray Microscopy
    – Raman Spectroscopy
    • Review of recent battery imaging studies in published literature
    • Case studies on using correlative microscopy to characterize battery performance & failure mechanisms

    Presenter
    Stefanie Freitag – Market Segment Manager at Carl Zeiss

    Stefanie is Market Segment Manager in Materials Research at Carl Zeiss Microscopy in Munich. She holds a Diploma in Engineering Physics, gained first work experiences in a nuclear fusion reactor with a pioneering concept in Greifswald, then worked 3 years in the solar industry in Ulm & Hsinchu, Taiwan. In her current position she analyzes and defines new microscopic solutions for specific materials segments including light microscopy, electron microscopy, x-ray microscopy and chemical methods like Raman spectroscopy.

    Buy Now
  • Placeholder

    Battery Selection Tutorial Course 3/3: Integrating Your Battery Into Your Product – Designing for Worst-Case Scenarios

    The last part in Exponent’s three-part series, this webinar will focus on the finished product from the viewpoint of the battery. How can you best protect your battery within your device? Is your battery going to be user-replaceable? If you’re creating multi-cell packs, how should they be separated from (yet still connected to) each other? Should a thermal event occur, how can you prevent that from cascading through the whole pack? This webinar will help to answer many of those questions, and discuss design questions to help safeguard your battery pack throughout its entire lifecycle.

    This webinar will focus on the following key topics:

    • Creating multi-cell packs
    • Containing thermal runaway events

    Presenter
    Exponent – a multidisciplinary engineering and scientific consulting firm with significant experience in various aspects of battery design, safety testing and failure analysis.

    Buy Now
  • Placeholder

    Battery Selection Tutorial Course 1/3: Selecting your Cell and Cell Manufacturer(s)

    After designing your product, you need to ensure the battery with which you are operating it will ensure the right performance and lifetime. When deciding this, narrowing down which chemistry (e.g. Li-ion, lithium primary, NiMH, etc.) best fits your product and which form factor are some of the first steps. Choosing a cell design (high-power vs. high-energy, for example) is another step and finally, finding the right cell manufacturer to fabricate your cells and packs. This webinar is the first in a three-part series on designing the right battery for your product. It will cover many of the key differences in chemistries, form factors, and cell designs and other best practices.

    This webinar will focus on the following key topics:

    • Choosing the right chemistry for your application
    • Choosing the right form factor
    • Choosing cell designs (e.g. high power vs. high-energy)

    Presenter
    Exponent – a multidisciplinary engineering and scientific consulting firm with significant experience in various aspects of battery design, safety testing and failure analysis.

    Buy Now
  • Placeholder

    Understand and Prevent Battery Fires and Explosions – and Avoid Costly Failures Like the Samsung Note 7

    Modern batteries (eg Li-Ion) contain hazardous chemicals & they heat up during use: this combination always has the potential to cause fires & explosions. This presentation will focus on improving the understanding of how these incidents occur, what can be done to avoid them & how the risk can be minimized during early stage design.

    The Samsung Note 7 phone & Boeing Dreamliner airplane fires are very costly examples of how even large corporations fail to understand the potential fire risk of batteries.

    The solution lies in knowledge of heat generation rate during normal use & information about safe boundaries such as temperature, discharge rate & overcharge, in realistic situations that represent actual use conditions. Data from commercial batteries of different types will be used to illustrate these points.

    A relatively new technique will also be discussed with data, which allows total heat output during discharge to be measured on-line and this can be used both for design and battery modelling. Examples of the data will be provided.

    This webinar will focus on the following key topics:

    • Why battery fires & explosions occur
    • How to design safer batteries though understanding of heat generation
    • Video evidence of batteries under explosive conditions
    • How better thermal management systems can be designed – based on heat measurement from isothermal calorimetry
    • Laboratory instruments suitable for testing and data generation

    Presenter
    Dr. Jasbir Singh – Managing Director at Hazard Evaluation Laboratory

    Jasbir is a chemical engineer specializing in thermal hazards and calorimetry, traditionally for the chemical industry but now increasingly involved in battery safety, especially Li-ion EV and related types.

    A graduate of Imperial College (London), where he undertook PhD into combustion and explosions, his experience includes many years in process design for the chemical and petrochemical industries. He is currently developing test methods and instruments for use in design of battery thermal management systems.

    Buy Now

Leave a Reply