在固体氧化物电池堆上进行的电化学阻抗光谱测量的自动数据管理和分析管道

Christian Frederik Mänken, Dominik Schäfer, Rudiger-A Eichel, Felix Kunz
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引用次数: 0

摘要

为了更好地理解电化学转化器中的降解,并帮助将某些现象与特定的操作条件联系起来,机器学习(ML)方法正越来越多地得到应用。例如,在锂离子电池的退化分析和容量预测领域已经取得了成功。对于固体氧化物电池(SOC)堆栈,ML方法主要用于故障运行模式的识别和与退化相关的故障诊断2。当用于预测模型时,机器学习方法通常需要大量的真实训练数据。为了处理Forschungszentrum j lich在过去几年中收集的soc的历史长期试验台数据,制定了数据整合和管理策略。与该领域开发的其他数据集相比,本工作中提供的数据集包含燃料电池运行中的SOC堆栈测试,在负载下运行时间要长得多。给出了样本实验的汇编和分层数据格式的整合。此外,该策略的一个重要部分是电化学阻抗谱(EIS)测量的自动管理和分析,使用Python中专门开发的程序。过去几年测量质量的变化,以及寄生电感等反复出现的人为因素,都可以通过这种方式解决。执行额外的松弛时间分布(DRT)反卷积和等效电路建模(ECM),作为自动从测量中检索特征值的过程的一部分(参见图1)。据作者所知,新数据集包括一些最长的SOC堆栈测试,可作为若干评估的基础。除了分类和聚类工作,特别是根据环境信息系统数据得出退化模式外,另一个重点是发展预测模式。目前的工作主要关注长短期记忆(LSTM),以及利用时间序列数据和特征测量(如EIS)的回归模型。作者要感谢他们在Forschungszentrum j lich GmbH的同事们的大力支持,感谢亥姆霍兹学会以及德国联邦教育和研究部为这些活动提供资金,作为WirLebenSOFC项目(03SF0622B)的一部分。参考文献1:Jones, p.k., stiming, U. &;李,A.A.。基于阻抗的锂离子电池在不均匀使用中的性能预测。自然通讯13,4806(2022)。2: B. Yang等。固体氧化物燃料电池系统故障诊断:关键总结,分类和观点。储能学报,34(2)(2021)。3: A.K. Padinjarethil, S. Pollok &答:哈根。基于机器学习的新型固体氧化物电池数据库降解研究。燃料电池21,566-576(2021)。图说明:图1:EIS数据策展管道及以EIS测量为例的策展结果流程图。图1
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Automatic Data Curation and Analysis Pipeline for Electrochemical Impedance Spectroscopy Measurements Conducted on Solid Oxide Cell Stacks
Abstract To better understand degradation in electrochemical converters and helping to correlate certain phenomena with specific operating conditions, machine learning (ML) methods are increasingly being applied. Success has already been achieved in the field of degradation analysis and prediction of capacity of lithium ion batteries 1 , for instance. In terms of Solid Oxide Cell (SOC) stacks ML methods have been applied mainly with the aim of identification of faulty operation modes and degradation related fault diagnosis 2 . ML approaches usually require a considerable amount of real training data, when used for forecasting models. A data consolidation and curation strategy was developed with the aim of processing the historic long-term test bench data of SOCs collected by Forschungszentrum Jülich over the past years. In comparison to other datasets developed in this field 3 , the one presented in this work contains SOC stack tests in fuel cell operation with significantly longer operating times under load. A compilation of the sample experiments and the consolidation into a hierarchical data format are presented. Further, an essential part of the strategy is the automatic curation and analysis of electrochemical impedance spectroscopy (EIS) measurements, using a specifically developed procedure in Python. The varying quality of measurements from past years, as well as recurring artefacts such as parasitic inductances, can be addressed in this way. Additional distribution of relaxation times (DRT) deconvolutions and equivalent circuit modelling (ECM) are performed, as part of the procedure to automatically retrieve feature values from measurements (cf. Fig. 1). The novel dataset, which to the authors’ knowledge includes some of the longest SOC stack tests available, serves as the basis for several evaluations. In addition to classification and clustering work to derive degradation patterns, in particular based on the EIS data, another focus is on the development of forecasting models. The current work is primarily concerned with long short-term memory (LSTM), as well as regression models that make use of both the time series data and the characterisation measurements, such as EIS. Acknowledgement The authors would like to thank their colleagues at Forschungszentrum Jülich GmbH for their great support and the Helmholtz Society as well as the German Federal Ministry of Education and Research for financing these activities as part of the WirLebenSOFC project (03SF0622B). References 1: Jones, P.K., Stimming, U. & Lee, A.A. Impedance-based forecasting of lithium-ion battery performance amid uneven usage. Nature Communications 13, 4806 (2022). 2: B. Yang et al. Solid oxide fuel cell systems fault diagnosis: Critical summarization, classification, and perspectives. Journal of Energy Storage 34 , 102153 (2021). 3: A.K. Padinjarethil, S. Pollok & A. Hagen. Degradation studies using machine learning on novel solid oxide cell database. Fuel Cells 21, 566–576 (2021). Figure caption: Fig.1: Flow diagram of EIS data curation pipeline and curation results for example EIS measurement. Figure 1
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