Predicting the heat release variability of Li-ion cells under thermal runaway with few or no calorimetry data
Karina Masalkovaitė, Paul Gasper, Donal P. Finegan
Abstract
Accurate measurement of the variability of thermal runaway behavior of lithium-ion cells is critical for designing safe battery systems. However, experimentally determining such variability is challenging, expensive, and time-consuming. Here, we utilize a transfer learning approach to accurately estimate the variability of heat output during thermal runaway using only ejected mass measurements and cell metadata, leveraging 139 calorimetry measurements on commercial lithium-ion cells available from the open-access Battery Failure Databank. We show that the distribution of heat output, including outliers, can be predicted accurately and with high confidence for new cell types using just 0 to 5 calorimetry measurements by leveraging behaviors learned from the Battery Failure Databank. Fractional heat ejection from the positive vent, cell body, and negative vent are also accurately predicted. We demonstrate that by using low cost and fast measurements, we can predict the variability in thermal behaviors of cells, thus accelerating critical safety characterization efforts. Characterizing the variation in thermal behavior of Li-ion cells during thermal runaway is time-consuming and expensive. Here, authors show that by training a machine learning model on open-access data, the thermal behavior of a Li-ion cell can be predicted with high accuracy using the specifications of the cell and the ejected mass.