用于增强电池健康分析的多尺度建模:长寿之路

Kaiyi Yang, Lisheng Zhang, Wentao Wang, Chengwu Long, Shichun Yang, Tao Zhu, Xinhua Liu
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引用次数: 0

摘要

健康评估和寿命预测问题一直是锂离子电池(LIB)大规模应用过程中面临的突出挑战。本文综述了多尺度建模技术及其在电池健康分析中的应用,包括原子尺度计算化学、粒子尺度反应模拟、电极尺度结构模型、宏观尺度电化学模型以及系统级数据驱动模型。多尺度建模可深入了解电池的材料行为和老化过程,从而为电池健康状况的评估和管理策略提供有价值的参考。为了延长电池寿命,我们考虑了利用人工智能进行材料发现和制造工艺优化、实施端云协作电池管理系统以及设计多尺度仿真集成平台。还进一步提出了一个旨在延长电池寿命的管理框架。该框架为解决锂离子电池的健康分析难题提供了一个前景广阔的路线图,最终将为下一代电池提供更可靠、更高效、更耐用的解决方案。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Multiscale modeling for enhanced battery health analysis: Pathways to longevity

Multiscale modeling for enhanced battery health analysis: Pathways to longevity

The issues of health assessment and lifespan prediction have always been prominent challenges in the large-scale application of lithium-ion batteries (LIBs). This paper reviews the multiscale modeling techniques and their applications in battery health analysis, including atomic scale computational chemistry, particle scale reaction simulations, electrode scale structural models, macroscale electrochemical models, and data-driven models at the system level. Multiscale modeling offers a profound insight into material behavior and the aging process of batteries, thereby providing a valuable reference for both estimation and management strategies of battery state of health. To extend the battery lifespan, the utilization of artificial intelligence for material discovery and manufacturing process optimization, the implementation of end-cloud collaborative battery management systems, and the design of a multiscale simulation integration platform are considered. A management framework aimed at extending battery life is further proposed. This framework offers a promising roadmap for addressing health analysis challenges in LIBs, ultimately leading to more reliable, efficient, and durable solutions for next-generation batteries.

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