Time-frequency analysis of Li solid-phase diffusion in spherical active particles under typical discharge modes

IF 14 1区 化学 Q1 CHEMISTRY, APPLIED
Qiu-An Huang , Yuxuan Bai , Liang Wang , Juan Wang , Fangzhou Zhang , Linlin Wang , Xifei Li , Jiujun Zhang
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引用次数: 3

Abstract

Li transient concentration distribution in spherical active material particles can affect the maximum power density and the safe operating regime of the electric vehicles (EVs). On one hand, the quasi-exact/exact solution obtained in the time/frequency domain is time-consuming and just as a reference value for approximate solutions; on the other hand, calculation errors and application range of approximate solutions not only rely on approximate algorithms but also on discharge modes. For the purpose to track the transient dynamics for Li solid-phase diffusion in spherical active particles with a tolerable error range and for a wide applicable range, it is necessary to choose optimal approximate algorithms in terms of discharge modes and the nature of active material particles. In this study, approximation methods, such as diffusion length method, polynomial profile approximation method, Padé approximation method, pseudo steady state method, eigenfunction-based Galerkin collocation method, and separation of variables method for solving Li solid-phase diffusion in spherical active particles are compared from calculation fundamentals to algorithm implementation. Furthermore, these approximate solutions are quantitatively compared to the quasi-exact/exact solution in the time/frequency domain under typical discharge modes, i.e., start-up, slow-down, and speed-up. The results obtained from the viewpoint of time-frequency analysis offer a theoretical foundation on how to track Li transient concentration profile in spherical active particles with a high precision and for a wide application range. In turn, optimal solutions of Li solid diffusion equations for spherical active particles can improve the reliability in predicting safe operating regime and estimating maximum power for automotive batteries.

Abstract Image

典型放电模式下球形活性颗粒中Li固相扩散的时频分析
球形活性物质颗粒中锂离子的瞬态浓度分布影响着电动汽车的最大功率密度和安全运行状态。一方面,在时域/频域得到的准精确/精确解耗时长,只能作为近似解的参考值;另一方面,近似解的计算误差和适用范围不仅与近似算法有关,还与放电模式有关。为了在可容忍的误差范围内和较宽的适用范围内跟踪球形活性颗粒中Li固相扩散的瞬态动力学,需要根据放电模式和活性物质颗粒的性质选择最优近似算法。本研究从计算基础到算法实现,比较了球形活性粒子Li固相扩散的扩散长度法、多项式剖面近似法、pad近似法、伪稳态法、基于特征函数的Galerkin配置法、分离变量法等近似方法。此外,将这些近似解与典型放电模式(启动、减速和加速)下的时频域准精确/精确解进行了定量比较。从时频分析的角度得到的结果为如何高精度、宽应用范围地跟踪球形活性粒子中Li瞬态浓度分布提供了理论基础。球形活性粒子Li固体扩散方程的最优解可以提高汽车电池安全运行状态预测和最大功率估计的可靠性。
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来源期刊
CiteScore
23.60
自引率
0.00%
发文量
2875
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