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A Mechanical Model for Predicting Gas-Induced Bulging in Pouch-Cell Batteries


Основні поняття
This paper presents a new analytical model to predict the deformation and stress caused by gas formation in pouch-cell batteries, offering a potential method for monitoring battery state of health (SOH) by analyzing the bulging deformation.
Анотація

Bibliographic Information:

Giudici, A., Chapman, J., & Please, C. (2024). Gas-induced bulging in pouch-cell batteries: a mechanical model. arXiv:2411.13197v1 [cond-mat.soft].

Research Objective:

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.

Methodology:

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.

Key Findings:

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.

Main Conclusions:

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.

Significance:

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.

Limitations and Future Research:

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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Статистика
Strains as large as 70% were observed in the middle of bulging pouch cells. Battery materials have a reported stiffness of about 1 GPa. Some studies report internal pressures on the order of one atmospheric pressure.
Цитати
"Over the long timescale of many charge/discharge cycles, gas formation can result in large bulging deformations of a Lithium-ion pouch cell, which is a key failure mechanism in batteries." "Tracking the evolution of gas volume and pressure within a pouch cell would offer a way to monitor the state of health (SOH) of the battery." "Our naive analysis suggests that the only way in which we can get a significant strain in the through-cell direction with more realistic pressures is if the effective stiffness of the battery under extension is lower than the reported values."

Ключові висновки, отримані з

by Andrea Giudi... о arxiv.org 11-21-2024

https://arxiv.org/pdf/2411.13197.pdf
Gas-induced bulging in pouch-cell batteries: a mechanical model

Глибші Запити

How might this model be adapted for other battery form factors, such as cylindrical or prismatic cells?

Adapting this model for cylindrical or prismatic cells presents some challenges due to their differing geometries and inherent structural differences compared to pouch cells: Geometry: The model relies on the relatively simple, planar geometry of a pouch cell. Cylindrical and prismatic cells have more complex geometries that would require modifications to the mathematical framework. For instance, the current model might be adapted by considering cylindrical or rectangular coordinates and boundary conditions relevant to the new shapes. Clamping Mechanism: The pouch cell model leverages the clamping at the edges by the casing. Cylindrical and prismatic cells have different clamping mechanisms, which would alter the stress distribution and bulging behavior. The model would need to account for these different boundary conditions. Material Distribution: The arrangement of electrodes, separators, and other components within cylindrical and prismatic cells is often different from pouch cells. This difference in material distribution would affect the overall stiffness and deformation characteristics. The model would need adjustments to incorporate these variations. Despite these challenges, the core principles of the model, based on balancing internal pressure with material stiffness, remain relevant. Adaptations would involve: Modified Geometry and Boundary Conditions: Adjusting the mathematical equations to reflect the specific shape and clamping of the cell. Cell-Specific Parameters: Incorporating parameters relevant to the specific cell type, such as material properties and layer thicknesses. Validation with Experimental Data: Rigorously validating the adapted model against experimental data from cylindrical or prismatic cells to ensure accuracy.

Could the model be inaccurate if the gas distribution within the pouch cell is not uniform?

Yes, the model's accuracy could be compromised if the gas distribution within the pouch cell is not uniform. The model, as described, assumes a homogeneous internal pressure exerted by the gas. Here's why non-uniform gas distribution poses a problem: Localized Bulging: Non-uniform pressure could lead to localized bulging or deformation in areas of higher gas concentration. The model, assuming uniform pressure, wouldn't accurately predict these localized effects. Inaccurate Stress Predictions: The model's stress distribution calculations rely on the assumption of uniform pressure. Uneven pressure would result in inaccurate stress predictions, potentially misrepresenting the mechanical strain on different battery components. Erroneous SOH Estimation: As the model correlates bulging with internal pressure (and consequently, gas volume) to estimate SOH, non-uniform gas distribution could lead to erroneous SOH estimations. To address potential non-uniformity in gas distribution, the model could be enhanced by: Compartmentalization: Dividing the pouch cell into smaller compartments and allowing for varying pressure in each compartment. Fluid Dynamics Integration: Incorporating basic fluid dynamics principles to model gas flow and distribution within the cell, potentially coupled with gas generation models. Experimental Validation: Validating the model's predictions against experimental data that considers and measures gas distribution within the cell.

What are the broader implications of being able to accurately monitor battery SOH for applications like electric vehicles and grid storage?

Accurately monitoring battery State of Health (SOH) has significant implications for electric vehicles (EVs) and grid storage, potentially revolutionizing these sectors: Enhanced EV Performance and Reliability: Optimized Battery Management: Accurate SOH information allows for more precise battery management system (BMS) algorithms, optimizing charging/discharging protocols, and extending battery lifespan. Range Anxiety Reduction: Reliable SOH estimation provides drivers with more accurate estimates of remaining range, reducing range anxiety and increasing EV adoption. Predictive Maintenance: Early detection of battery degradation through SOH monitoring enables predictive maintenance, minimizing downtime and costly repairs. Improved Grid Storage Efficiency and Stability: Grid Reliability: Accurate SOH assessment of grid-scale batteries ensures reliable power delivery during peak demand or outages, enhancing grid stability. Renewable Integration: Optimized battery operation based on SOH maximizes the effectiveness of grid-scale energy storage systems, facilitating greater integration of intermittent renewable energy sources like solar and wind. Economic Benefits: Extending battery lifespan through accurate SOH monitoring and optimized operation reduces replacement costs, improving the economic viability of grid storage solutions. Circular Economy and Sustainability: Second-Life Applications: Batteries retired from EVs, with their SOH accurately known, can be repurposed for less demanding applications like grid storage, maximizing resource utilization. Recycling Optimization: SOH information aids in determining the optimal time for battery recycling, minimizing waste and environmental impact. Overall, accurate battery SOH monitoring is crucial for unlocking the full potential of EVs and grid storage, driving wider adoption, improving performance, and enabling a more sustainable energy future.
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