Litcius/Paper detail

Modeling Inhomogeneities during Parallel-Connected Fast Charging of Lithium-Ion Battery Systems

Alexander Frank, Stefan Schaeffler, Cedric Kirst, Franz Roehrer, Simon Kücher, Axel Durdel, M. Scheller, Andreas Jossen

2025Journal of The Electrochemical Society12 citationsDOIOpen Access PDF

Abstract

Parallel connections of lithium-ion cells in battery systems lead to current distributions between the cells, which impacts fast charging capabilities. This study examines the influence of interconnection resistance, format, electrode design, cell-to-cell variations, and temperature differences on system inhomogeneity and identifies anode potential safety margins that ensure safe charging without lithium plating. To this end, a physico-chemical parameterization of the Molicel INR21700-P45B is presented. An optimized fast-charging profile enables charging from 10%–80% cell capacity in under 10 minutes. The experimental application of the fast-charging profile yielded a result of over 300 equivalent full cycles before reaching 90% state of health. Furthermore, the cell model is scaled to different parallel-connected systems in an extensive simulation study. The interconnection resistance, and analogously the internal-to-interconnection resistance ratio, was found to be the primary factor influencing inhomogeneity in high parallel configurations, whereas cell-to-cell resistance variations are the most significant determinant in low parallel configurations. Variations in cooling were found to be more impactful than initial temperature disparities.

Topics & Concepts

Lithium (medication)Battery (electricity)IonLithium-ion batteryMaterials scienceComputer sciencePhysicsThermodynamicsPower (physics)MedicineQuantum mechanicsEndocrinologyAdvanced Battery Technologies ResearchAdvancements in Battery MaterialsAdvanced Battery Materials and Technologies