Duty-cycle characterisation of large-format automotive lithium ion pouch cells for high performance vehicle applications

•A novel high-performance duty cycle is validated and used in a cycle-life study.•Two test groups undergo 200 cycles representing racing and conventional driving.•Cells show an increase in capacity and improved charge-transfer kinetics.•The changes are more pronounced for cells subject to the high-p...

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Bibliographic Details
Published inJournal of energy storage Vol. 19; pp. 170 - 184
Main Authors Kellner, Quirin, Worwood, Daniel, Barai, Anup, Widanage, Widanalage Dhammika, Marco, James
Format Journal Article
LanguageEnglish
Published Elsevier Ltd 01.10.2018
Subjects
Characterisation
Degradation
Electric vehicles
High-performance
Lithium ion battery
OCV
HP
HP-EV
CC-CV
Degradation
Lithium ion battery
DOD
p-OCV
Characterisation
High-performance
IECC
HP-C
G-NMC
LIB
NMC
SOC
BTMS
PMC
EIS
EV
BEV
OEM
SEI
WLTP
Electric vehicles
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Summary:•A novel high-performance duty cycle is validated and used in a cycle-life study.•Two test groups undergo 200 cycles representing racing and conventional driving.•Cells show an increase in capacity and improved charge-transfer kinetics.•The changes are more pronounced for cells subject to the high-performance cycle.•Electrode cracking is a potential cause of improved cell characteristics. The long-term behaviour of lithium ion batteries in high-performance (HP) electric vehicle (EV) applications is not well understood due to a lack of suitable testing cycles and experimental data. As such a generic HP duty cycle (HP-C), representing driving on a race track is validated, and six NMC graphite cells are characterised with respect to cycle-life. To enable a comparison between the HP-EV environment and conventional road driving, two test groups of cells are subject to an experimental evaluation over 200 duty cycles that includes a representative HP-C and a standard duty cycle from the IEC 62660-1 standard (IECC). After testing, both test groups display increased energy capacity, increased pure Ohmic resistance, lower charge transfer resistance an extended OCV operating window. The changes are more pronounced for cells subject to the HP-C. Based on capacity tests, Electrochemical Impedance Spectroscopy (EIS), pseudo-OCV tests, and Pulse Multisine Characterisation, it is concluded that the changes in cell characteristics are most likely caused by cracking of the electrode material caused by high electrical current pulses. With continued cycling, cells cycled with the HP-C are expected to show degradation at an increased rate due to raised temperatures, and more pronounced electrode cracking.
ISSN:2352-152X
2352-1538
DOI:10.1016/j.est.2018.07.018