Experimental Study of Sidewall Rupture of Cylindrical Lithium-Ion Batteries under Radial Nail Penetration

Chen, Haodong; Kalamaras, Evangelos; Abaza, Ahmed; Tripathy, Yashraj; Page, Jason S.; Barai, Anup

doi:10.1149/1945-7111/acadac

Cited by 10 publications

(2 citation statements)

References 42 publications

(71 reference statements)

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“…On the experimental side, several non-invasive detection methods have been studied in recent years. For identifying mechanical defects like an open CID or delaminated electrode layers, methods like X-ray measurements and computer tomography (CT) have been validated as well-suited methods [37][38][39]. The detection of triggered CIDs is particularly crucial for a safe and fast diagnosis of batteries, as it indicates severe abuse or defects such as overcharge, high cell pressure, or high temperature and thus immediately leads to a low SOU classification [19].…”

Section: Non-invasive Defect Detectionmentioning

confidence: 99%

On the State of Usability for Lithium–Ion Batteries

Wett,

Lampe,

Haß

et al. 2024

Batteries

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Lithium–ion batteries are well established as traction batteries for electric vehicles. This has led to a growing market for second-life batteries that can be used in applications like home energy storage systems. Moreover, the recyclability and safe handling of aged or damaged cells and packs has become more important. While there are several indicators, like state of health (SOH), state of power (SOP), or state of safety (SOS), which describe the state of a battery before its defined end of life (EOL), there is no consistent classification methodology by which to describe the usability of a cell or pack after its EOL is reached. The proposed state of usability (SOU) provides a new indicator that accounts for the usability for second life, recyclability, and possible required safety handling of a lithium–ion battery after its first intended life cycle. This work presents a decision tree method, which in turn leads to five discrete usability levels enabling a fast and rough determination of the SOU for practical use. Further, a calculation methodology for reasonable continuous regions of the SOU is proposed. Both methods are based on a literature-based rating of all of the relevant defect and aging mechanisms displayed in a risk matrix. Finally, some experimental methods that can be used for SOU determination are proposed. The developed methodology and the hands-on approach using a decision tree are well-suited for real world application in recycling companies and battery test laboratories.

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Section: Non-invasive Defect Detectionmentioning

confidence: 99%

On the State of Usability for Lithium–Ion Batteries

Wett,

Lampe,

Haß

et al. 2024

Batteries

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“…Recent research on single cylindrical and single pouch cells demonstrates that a direct impact perpendicular to the electrode plane will weaken and fracture the thin electrode layers covering the current collector, allowing the separator layer and electrolyte to mix into the electrode (Figure ). − This will lead to an internal short circuit and cause ignition during the discharge process.…”

Section: Battery Thermal Runaway Studiesmentioning

confidence: 99%

Overview of the Thermal Runaway in Lithium-Ion Batteries with Application in Electric Vehicles: Working Principles, Early Warning, and Future Outlooks

Le,

Vuong,

Natsuki

et al. 2023

Energy Fuels

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Energy and environmental issues are more pressing than ever with the task of reducing carbon emissions and finding new fuel sources to replace fossil fuels. One of the directions that is in line with the requirements of the time is to develop electric cars using completely electrified batteries to replace gasoline. Considering their high energy density and lengthy cycle life, lithium-ion batteries are frequently utilized in electric cars. The personal and property safety of passengers is gravely threatened by the spontaneous combustion accidents of electric cars caused by the thermal runaway of lithium-ion batteries. Therefore, studies on early warning as well as solutions to overcome when a thermal runaway incident occurs have become increasingly important and urgent. The current study provides advancements in the thermal management, electrical management, and structural design of early warning battery thermal runaway applications in electric vehicles. This minireview aims to provide the most concise but complete information to provide an overview of the story of thermal runaway and development trends for early warning in the next decade.

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