Abstract
One way to support the development of new safety practices in testing and field failure situations of electric vehicles and their lithium-ion (Li-ion) traction batteries is to conduct studies simulating plausible incident scenarios. This paper focuses on risks and hazards associated with venting of gaseous species formed by thermal decomposition reactions of the electrolyte and electrode materials during thermal runaway of the cell. A test set-up for qualitative and quantitative measurements of both major and minor gas species in the vented emissions from Li-ion batteries is described. The objective of the study is to measure gas emissions in the absence of flames, since gassing can occur without subsequent fire. Test results regarding gas emission rates, total gas emission volumes, and amounts of hydrogen fluoride (HF) and CO2 formed in inert atmosphere when heating lithium iron phosphate (LFP) and lithium nickel-manganese-cobalt (NMC) dioxide/lithium manganese oxide (LMO) spinel cell stacks are presented and discussed. Important test findings include the large difference in total gas emissions from NMC/LMO cells compared to LFP, 780 L kg−1 battery cells, and 42 L kg−1 battery cells, respectively. However, there was no significant difference in the total amount of HF formed for both cell types, suggesting that LFP releases higher concentrations of HF than NMC/LMO cells.
Highlights
The number of vehicles with electrified drivetrains produced annually increase every year as the market penetration rises steadily, still at very low volumes
The LFP cells did not produce enough gas to get a reading on the flow sensor, and, the volume was calculated based on the gas concentration levels measured for volatile organic compounds (VOCs) CO2 and hydrogen fluoride (HF); see Section 4.3 for details
The results indicate that the concentration of HF in gases released from LFP cells is more than an order of magnitude higher than for NMC/lithium manganese oxide (LMO) cells
Summary
The number of vehicles with electrified drivetrains produced annually increase every year as the market penetration rises steadily, still at very low volumes. Electric vehicles (EV) comprise hybrid vehicles (HEV), plug-in hybrid vehicles (PHEV) and pure electric vehicles (PEV). The latter can either be battery powered, referred to as battery electric vehicle BEV or powered by a fuel cell, fuel cell electric vehicle (FEV). A consequence of this development is that vehicle manufacturers, test institutes, and other organizations who perform assessments of vehicle crash worthiness are experiencing a rising demand to perform such tests on EVs as well as component testing on propulsion batteries and battery systems
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