TY - JOUR
T1 - Electro-thermal modeling of large format lithium-ion pouch cells
T2 - A cell temperature dependent linear polarization expression
AU - Rheinfeld, Alexander
AU - Kosch, Stephan
AU - Erhard, Simon V.
AU - Osswald, Patrick J.
AU - Rieger, Bernhard
AU - Jossen, Andreas
N1 - Publisher Copyright:
© 2016 The Electrochemical Society.
PY - 2016
Y1 - 2016
N2 - In the work presented here, a well-known semi-empirical electro-thermalmodel of large format lithium-ion pouch cells is extended by accounting for a cell temperature dependency of electrode polarization gained from full cell measurement. Formodel parametrization, the cell was discharged at varying discharge rates and ambient temperatures within a climate chamber. By relating the measured cell potential to its current temperature, a cell temperature dependency of cell polarization is established. Evaluating the advantages of this approach, the extended model is compared to the initial model regarding the quality of predicting the electrical and thermal cell behavior. For further means of model validation, the cell was investigated at cooling conditions varying from the parametrization measurements via infrared thermography. It can be shown that a temperature dependency of electrode polarization shows superior quality especially when predicting the overall electrical and thermal cell performance at ambient conditions varying from the parametrization scenario. Controlling the thermal boundary conditions further allows to evaluate the impact of local heat generation on the temperature distribution. For a laminar, directed airflow of 1 m/s along the cell, the influence of local heat generation is minor in comparison to the thermal boundary conditions prevailing at the cell's surface and tabs.
AB - In the work presented here, a well-known semi-empirical electro-thermalmodel of large format lithium-ion pouch cells is extended by accounting for a cell temperature dependency of electrode polarization gained from full cell measurement. Formodel parametrization, the cell was discharged at varying discharge rates and ambient temperatures within a climate chamber. By relating the measured cell potential to its current temperature, a cell temperature dependency of cell polarization is established. Evaluating the advantages of this approach, the extended model is compared to the initial model regarding the quality of predicting the electrical and thermal cell behavior. For further means of model validation, the cell was investigated at cooling conditions varying from the parametrization measurements via infrared thermography. It can be shown that a temperature dependency of electrode polarization shows superior quality especially when predicting the overall electrical and thermal cell performance at ambient conditions varying from the parametrization scenario. Controlling the thermal boundary conditions further allows to evaluate the impact of local heat generation on the temperature distribution. For a laminar, directed airflow of 1 m/s along the cell, the influence of local heat generation is minor in comparison to the thermal boundary conditions prevailing at the cell's surface and tabs.
UR - http://www.scopus.com/inward/record.url?scp=85006375130&partnerID=8YFLogxK
U2 - 10.1149/2.0701614jes
DO - 10.1149/2.0701614jes
M3 - Article
AN - SCOPUS:85006375130
SN - 0013-4651
VL - 163
SP - A3046-A3062
JO - Journal of the Electrochemical Society
JF - Journal of the Electrochemical Society
IS - 14
ER -