Giudici, A., Chapman, J., & Please, C. (2024). Gas-induced bulging in pouch-cell batteries: a mechanical model. arXiv:2411.13197v1 [cond-mat.soft].
This research paper aims to develop a reliable mechanical model for predicting the deformation and stress distribution in pouch-cell batteries caused by gas formation, a significant factor in battery degradation. The authors intend to provide a tool for monitoring battery state of health (SOH) by analyzing the bulging deformation.
The authors propose a homogenized mechanical model based on experimental X-ray tomography data of a bulging pouch cell. This model considers the internal pressure generated by gas formation and the opposing elastic force of the battery materials. By fitting the model to experimental data and considering the bending stiffness of battery components, the model aims to predict internal pressure and gas volume.
The study highlights that gas formation, a byproduct of long-term battery cycling, leads to significant bulging deformation in pouch cells. The deformation is particularly prominent in the middle of the structure, while the edges remain constrained by the casing. The research suggests that the effective stiffness of the battery under tension is lower than previously reported values, explaining the significant strain observed with relatively low internal pressures.
The proposed mechanical model offers a novel approach to predict the shape and stress distribution of gas-induced bulging in pouch-cell batteries. This model can be integrated into battery simulation models to account for mechanical degradation. Furthermore, by analyzing the bulging deformation and considering the bending stiffness of battery components, the model can estimate internal pressure and gas volume, providing a potential non-invasive method for monitoring battery SOH.
This research contributes significantly to the field of battery degradation modeling by providing a new tool for understanding and predicting gas-induced bulging. The proposed model and its potential for SOH monitoring could lead to improved battery design, management strategies, and ultimately, longer-lasting batteries.
The paper acknowledges the need for further validation of the model with more extensive experimental data and different battery chemistries. Future research could explore the impact of varying operating conditions and battery aging on the model's accuracy. Additionally, investigating the integration of this model with other SOH estimation techniques could enhance its reliability and applicability.
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by Andrea Giudi... a las arxiv.org 11-21-2024
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