TY - JOUR
T1 - Exploring Thermal Runaway Propagation in Li-Ion Batteries through High-Speed X-Ray Imaging and Thermal Analysis: Impact of Cell Chemistry and Electrical Connections
T2 - Article No. 234916
AU - Fransson, Matilda
AU - Pfaff, Jonas
AU - Broche, Ludovic
AU - Buckwell, Mark
AU - Kirchner-Burles, Charlie
AU - Reid, Hamish
AU - Schopferer, Sebastian
AU - Rack, Alexander
AU - Finegan, Donal
AU - Shearing, Paul
PY - 2024
Y1 - 2024
N2 - Battery safety design is important to consider from the individual Li-ion cell to the level of the macro-system. On the macro-level, failure in one single cell can lead to propagation of the thermal runaway and rapidly set a whole battery pack on fire. Factors that can impact the propagation outcome, such as cell model/chemistry and electrical connection are here investigated using a combination of measurements. Several abusive tests were conducted, combining two different cell models (Molicel P42A and LG M50, both 21700s) in series and parallel connections (16 tests per configuration). Overall, a propagation outcome of 56% was measured from the 32 conducted tests, a minimum temperature of 150 degrees C was required to initiate propagation, and the fastest propagation occurred in 123 s. Temperature measurements were higher in series connected cells, initiating the discussion of cell chemistry and internal resistance on this effect. The difference in current-flow during thermal runaway in series and parallel connections, and how this can affect the temperature evolution is further discussed. Spatio-temporal mapping of X-ray radiography allowed us to derive the speed of thermal runaway evolution inside the battery and has shown that series connected cells, in particular P42A, occur faster. It was further observed that deviant sidewall behaviors such as temperature-induced breaches and pressure-induced ruptures occurred in P42As only respective nail-penetrated cells only.
AB - Battery safety design is important to consider from the individual Li-ion cell to the level of the macro-system. On the macro-level, failure in one single cell can lead to propagation of the thermal runaway and rapidly set a whole battery pack on fire. Factors that can impact the propagation outcome, such as cell model/chemistry and electrical connection are here investigated using a combination of measurements. Several abusive tests were conducted, combining two different cell models (Molicel P42A and LG M50, both 21700s) in series and parallel connections (16 tests per configuration). Overall, a propagation outcome of 56% was measured from the 32 conducted tests, a minimum temperature of 150 degrees C was required to initiate propagation, and the fastest propagation occurred in 123 s. Temperature measurements were higher in series connected cells, initiating the discussion of cell chemistry and internal resistance on this effect. The difference in current-flow during thermal runaway in series and parallel connections, and how this can affect the temperature evolution is further discussed. Spatio-temporal mapping of X-ray radiography allowed us to derive the speed of thermal runaway evolution inside the battery and has shown that series connected cells, in particular P42A, occur faster. It was further observed that deviant sidewall behaviors such as temperature-induced breaches and pressure-induced ruptures occurred in P42As only respective nail-penetrated cells only.
KW - Li-ion battery safety
KW - synchrotron
KW - thermal runaway
KW - X-ray imaging
U2 - 10.1016/j.jpowsour.2024.234916
DO - 10.1016/j.jpowsour.2024.234916
M3 - Article
SN - 0378-7753
VL - 617
JO - Journal of Power Sources
JF - Journal of Power Sources
ER -