Thermal modeling of fire propagation in lithium-ion batteries
Paper i proceeding, 2015
The objective of the present work is to assess the risk of spreading of fire between Lithium-ion battery cells
initiated by a thermal runaway. In particular it aims at developing means to predict the temperature of cells in
the vicinity of an overheated cell during the first 5-7 minutes after the thermal event in a Li-ion cell that has an
organic based electrolyte which is flammable. Finite-Element (FE) modelling is used to compute the heat
transfer between cells. The spreading model is assessed modeling a scenario where the cells are exposed to a
15 kW propane burner. Two different models where utilized, one that considers the conjugate heat transfer
between the surrounding hot gases and the battery cells while the second is a thermal model where the
boundary conditions are measured in a mock-up test. The results from the two models are contrasted to
experimental data where the heat release rate (HRR) is utilized as an input to the simulation. It is found that
the temperature increase in a neighboring cell can be quantitatively estimated in certain cases during the early
stages of the fire taking into account the anisotropic thermal conductivity of the cells using the conjugate heat
transfer model. Moreover, the thermal model captures the qualitative behavior of the test results, however, the
temperature increase is slower in the computational model.
lithium-ion
propagation
thermal model
battery
fire
thermal runaway