Comparison of the impact of fast charging on the cycle life of three lithium-ion cells under several parameters of charge protocol and temperatures
MATHIEU, Romain
Laboratoire de l'intégration, du matériau au système [IMS]
Technocentre Renault [Guyancourt]
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Laboratoire de l'intégration, du matériau au système [IMS]
Technocentre Renault [Guyancourt]
MATHIEU, Romain
Laboratoire de l'intégration, du matériau au système [IMS]
Technocentre Renault [Guyancourt]
< Réduire
Laboratoire de l'intégration, du matériau au système [IMS]
Technocentre Renault [Guyancourt]
Langue
EN
Article de revue
Ce document a été publié dans
Applied Energy. 2020-12-01, vol. 283, p. 116344
Résumé en anglais
Fast charging of lithium-ion batteries is crucial for electric vehicles. As the charge current is a known degradation factor, assessing the impact of fast charging on battery ageing under several operating conditions is ...Lire la suite >
Fast charging of lithium-ion batteries is crucial for electric vehicles. As the charge current is a known degradation factor, assessing the impact of fast charging on battery ageing under several operating conditions is necessary to derive usage strategies for system integrators. To bridge existing knowledge gaps, this article reports on a comparative experimental ageing study in fast charging conditions. Three cells, differing in their materials and energy densities, were investigated. The impacts of the following three parameters are compared on these cells: charge current, end-of-charge voltage, and ambient temperature. The results reveal that the impact of fast charging on cycle life strongly depends on battery materials and internal design. The degradation of two of the cells significantly increased when the charge current and voltage increased, whereas that of the third cell was nearly independent of these parameters. While considering thermal conditions, the ageing of each cell was minimised at a different temperature, either cold, moderate, or warm. An analysis of degradation root causes indicates that distinct dominant degradation mechanisms occurred depending on the cell materials. The cells with higher energy density had a lower cycle life (between 100 and 900 cycles) than the most high-power cell (more than 1700 cycles). Experimental results allow the identification of three strategies for reducing charging time while minimising battery degradation. These strategies present several contributions to the design of energy storage systems for electric vehicles, including the choice of a cell, design of thermal management systems, and design of optimised fast charging protocols.< Réduire
Mots clés en anglais
Charge protocol
Cycle life
Energy density
Fast charging
Lithium-ion batteries
Temperature sensitivity
Unités de recherche