Combining a Data Driven and Mechanistic Model to Predict Capacity and Potential Curve-Degradation

IF 5.1 4区材料科学 Q2 ELECTROCHEMISTRY

Batteries & Supercaps Pub Date : 2024-07-10 DOI:10.1002/batt.202400211

Jochen Stadler, Dr. Johannes Fath, Dr. Madeleine Ecker, Prof. Arnulf Latz

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Abstract

This work compares a state of the art data-driven model to predict the state of health (SoH) in lithium ion batteries with a new prediction model based on the mechanistic framework. The mechanistic approach attributes the degradation to individual components such as loss of available capacity on each electrode as well as loss of cyclable lithium. By combining the mechanistic framework with data-driven models for the component losses based on a design of experiment, we achieve a cycle aging model that can predict capacity degradation as well as degradation-induced changes to the discharge potential curve. Using this cycle aging model alongside with a semi-empirical calendar aging model, we present a holistic aging model that we validate on independent validation tests containing time-variant load profiles. While the purely data-driven model is better at predicting the SoH, the mechanistic model clearly has it advantages in a deeper understanding that can potentially enhance the current methods of tracking and updating the characteristic open-circuit voltage curve over lifetime.

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结合数据驱动模型和机理模型预测容量和潜在曲线衰减

这项研究将用于预测锂离子电池健康状况（SoH）的最新数据驱动模型与基于机理框架的新预测模型进行了比较。机理方法将退化归因于单个组件，如每个电极上可用容量的损失以及可循环锂的损失。通过将机理框架与基于实验设计的组件损耗数据驱动模型相结合，我们建立了一个循环老化模型，该模型可以预测容量衰减以及衰减引起的放电电位曲线变化。利用该循环老化模型和半经验日历老化模型，我们提出了一个整体老化模型，并在包含时变负载曲线的独立验证测试中进行了验证。虽然纯粹的数据驱动模型在预测 SoH 方面更胜一筹，但机理模型显然在更深入的理解方面具有优势，有可能增强当前跟踪和更新寿命期间开路电压特性曲线的方法。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Batteries & Supercaps Multiple-

CiteScore

8.60

自引率

5.30%

发文量

223

期刊介绍： Electrochemical energy storage devices play a transformative role in our societies. They have allowed the emergence of portable electronics devices, have triggered the resurgence of electric transportation and constitute key components in smart power grids. Batteries & Supercaps publishes international high-impact experimental and theoretical research on the fundamentals and applications of electrochemical energy storage. We support the scientific community to advance energy efficiency and sustainability.