锂离子电池的单粒子模型 - 模型校准和电动汽车应用中真实数据的验证⁎

Q3 Engineering
Iulian Munteanu , Antoneta Iuliana Bratcu , Pierre-Xavier Thivel , Yann Bultel , Didier Georges , Céline Decaux
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引用次数: 0

摘要

本文研究了电池电化学模型的校准和验证问题,这是精确估算电池重要变量(如充电状态(SoC)和健康状态(SoH))的必经之路。这里考虑的是单粒子模型 (SPM),该模型通过抛物线偏微分方程 (PDE) 从数学上描述了电池内部的控制现象,但其参数众所周知难以测量或估算。在通过线性有限维模型对该模型进行适当近似后,本文提出了一种系统的 SPM 校准程序,并根据电动汽车应用中电池循环(即标准驾驶循环场景)所产生的真实数据进行了验证。在一种新颖的 SoC 估算方法中,经过适当校准的 SPM 与电压和电流测量值一起,可将内部空间分布的离子浓度与平衡浓度进行分析连接,而平衡浓度则是电池 SoC 的图像。结果表明,SPM 可以可靠地预测电池内部离子浓度,并可进一步用于 SoC 的精确估算。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Single-Particle Model of Li-ion Battery – Model Calibration and Validation against Real Data in an Electric Vehicular Application⁎

This paper investigates the problem of calibration and validation of a battery electrochemical model as a mandatory step towards accurate estimation of battery important variables, like state of charge (SoC) and state of health (SoH). Here, the Single Particle Model (SPM) is considered, which mathematically describes the battery internal governing phenomena by means of parabolic partial differential equations (PDEs), but whose parameters are notoriously difficult to measure or estimate. After suitable approximation of this model through a linear finite-dimensional model, a systematic procedure of SPM calibration is here proposed and validated against real data issued from battery cycling in an electric vehicular application, i.e., under standard driving cycle scenarios. In a novel approach of SoC estimation, the suitably calibrated SPM, together with measures of voltage and current, allow to analytically connect the internal spatially distributed ions’ concentrations to the equilibrium concentration, which, at its turn, is an image of battery SoC. Results suggest that SPM can reliably predict the battery internal ions’ concentrations and be further used for SoC accurate estimation.

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来源期刊
IFAC-PapersOnLine
IFAC-PapersOnLine Engineering-Control and Systems Engineering
CiteScore
1.70
自引率
0.00%
发文量
1122
期刊介绍: All papers from IFAC meetings are published, in partnership with Elsevier, the IFAC Publisher, in theIFAC-PapersOnLine proceedings series hosted at the ScienceDirect web service. This series includes papers previously published in the IFAC website.The main features of the IFAC-PapersOnLine series are: -Online archive including papers from IFAC Symposia, Congresses, Conferences, and most Workshops. -All papers accepted at the meeting are published in PDF format - searchable and citable. -All papers published on the web site can be cited using the IFAC PapersOnLine ISSN and the individual paper DOI (Digital Object Identifier). The site is Open Access in nature - no charge is made to individuals for reading or downloading. Copyright of all papers belongs to IFAC and must be referenced if derivative journal papers are produced from the conference papers. All papers published in IFAC-PapersOnLine have undergone a peer review selection process according to the IFAC rules.
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