%A Wang,Qing
%A Shaffer,Christian Edward
%A Sinha,Puneet K.
%D 2015
%J Frontiers in Energy Research
%C
%F
%G English
%K Li-ion battery,Safety,large-format battery,simulation,Nail penetration
%Q
%R 10.3389/fenrg.2015.00035
%W
%L
%M
%P
%7
%8 2015-August-21
%9 Original Research
%+ Christian Edward Shaffer,EC Power,USA,ceshaffer@ecpowergroup.com
%#
%! Controlling Factors of Cell Design on Large-format Li-ion Battery Safety During Nail Penetration
%*
%<
%T Controlling Factors of Cell Design on Large-Format Li-Ion Battery Safety during Nail Penetration
%U https://www.frontiersin.org/articles/10.3389/fenrg.2015.00035
%V 3
%0 JOURNAL ARTICLE
%@ 2296-598X
%X In this paper, we investigate the controlling design parameters of large-format Li-ion batteries on safety while undergoing nail penetration. We have identified three critical design parameters that control the safety during the nail penetration process: nail diameter (Dnail), single sheet foil area (Afoil), and cell capacity (Qcell).Using commercial AutoLion™ software, we have investigated two typical design problems related to the selection of cell thickness and aspect ratio, namely, (1) the safety ramifications of increasing cell capacity via greater cell thickness for a fixed footprint and (2) the effect of aspect ratio, or single sheet foil size, on safety at a given capacity. For a fixed footprint, our results indicate that the safety of the cell can be predicted by QcellDnail−0.5. For a given cell capacity, our results indicate that typically a larger single sheet foil area leads to a greater likelihood for thermal runaway due to its effect of making the heating more local in nature; however, for small cells (~5 Ah) and large nails (~20 mm), the greater aspect ratio can lead to a safer cell, as the greater surface area strongly cools the global heating of the cell.