Título : Cycling ageing analysis in 18650 batteries at low temperature
Autor(es) : Díaz, Verónica
López Vazquez, Carlos
Teliz, Erika
Fecha de publicación : 2023
Tipo de publicación: Documento de conferencia
Versión: Enviado
Publicado en: WCCEE11, 11th World Congress of Chemical Engineering. Buenos Aires - Argentina, 4 de junio 2023
Areas del conocimiento : Ingeniería y Tecnología
Ingeniería de los Materiales
Otros descriptores : Baterias
Envejecimiento
SoH
Resumen : Decarbonization efforts are motivated due to the need to reduce greenhouse gas (GHG) emissions and anticipate the depletion of fossil fuels. The transport sector is one of the largest GHG producers where it is most difficult to reduce GHG emissions. Lithium-ion batteries currently represent an excellent alternative to meet the growing demand for energy storage and the electrification of the transport sector. However, there is still a considerable amount of research on degradation mechanisms to be performed to predict the remaining lifespan. Ageing mechanism of Li-ion batteries is a complex multi-causal process strongly affected by temperature. Ageing mechanisms could be grouped into three degradation modes: Loss of Conductivity (LC), Loss of Active Material (LAM) and Loss of Lithium Inventory (LLI). In this work, we studied the cycling ageing of 18650 commercial NMC lithium-ion batteries at 10°C. For this purpose, we carried out life cycle tests at different charge and discharge c-rates (Fig.1). We also performed galvanostatic Intermittent Titration Technique (GITT) (Fig. 2) tests in the voltage range for charge and discharge processes for different states of health (SoH). In order to perform GITT experiments, a short current pulse of current 1 A for charge and 3A for discharge was applied for a transient time of 13 min and 4 min, respectively; followed by a relaxation time of 30 min, which is required for achieving electrochemical equilibrium for the system. Tests were performed on the Gamry Interface 5000E™ potentiostat/galvanostat. Furthermore, we performed Electrochemical Voltage Spectroscopy studies through incremental capacity (IC) curves. IC curves peaks are associated with battery phase transformations due to ageing phenomena and each peak has a unique peak height, area, and position associated with a degradation mode. This research focuses on IC curves derived from discharge capacities. Deconvolution was carried out from these curves from Gaussian adjustments, determining the area, position, and height of resulted peaks. The height of the IC peaks decreases over cycle number, and it is observed a shift of IC peak position towards lower voltages. The peak at the lowest potential position results as an interesting health indicator for degradation evolution. Thermodynamics and faradaic effects were identified (Fig. 3). As a conclusion, LLI was identified as a critical degradation mode in the first cycles while LAM effects were depicted during the last cycles.
URI / Handle: https://hdl.handle.net/20.500.12381/2351
Financiadores: Agencia Nacional de Investigación e Innovación
Identificador ANII: FSE_1_2019_1_158806
Nivel de Acceso: Acceso abierto
Licencia CC: Reconocimiento 4.0 Internacional. (CC BY)
Aparece en las colecciones: Publicaciones de ANII

Archivos en este ítem:
archivo  Descripción Tamaño Formato
ABSTRACT_Template_WCCE11_batterry.pdfDescargar 340.05 kBAdobe PDF

Las obras en REDI están protegidas por licencias Creative Commons.
Por más información sobre los términos de esta publicación, visita: Reconocimiento 4.0 Internacional. (CC BY)