A Novel Quick Temperature Prediction Algorithm for Battery Thermal Management Systems Based on a Flat Heat Pipe

IF 4.6 4区 化学 Q2 ELECTROCHEMISTRY Batteries Pub Date : 2024-01-03 DOI:10.3390/batteries10010019
Weifeng Li, Yiqiang Xie, Wei Li, Yueqi Wang, Dana Dan, Yuping Qian, Yangjun Zhang
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Abstract

Predicting the core temperature of a Li-ion battery is crucial for precise state estimation, but it is difficult to directly measure. Existing quick temperature-predicting approaches can hardly consider the thermal mass of complex structure that may cause time delays, particularly under high C-rate dynamic conditions. In this paper, we developed a quick temperature prediction algorithm based on a thermal convolution method (TCM) to calculate the core temperature of a flat heat pipe-based battery thermal management system (FHP-BTMS) under dynamic conditions. The model could predict the core temperature rapidly through convolution of the thermal response map which contains full physical information. Firstly, in order to obtain a high fidelity spatio-temporal temperature distribution, the thermal capacitance-resistance network (TCRN) of the FHP-BTMS is established and validated by constant and dynamic discharging experiments. Then, the response map of the core temperature motivated by various impulse heat sources and heat sinks is obtained. Specifically, the dynamic thermal characteristics of an FHP are discussed to correct the boundary conditions of the TCM. Afterwards, the temperature prediction performances of the TCM and a lumped model under different step operating conditions are compared. The TCM results show a 70–80% accuracy improvement and better dynamic adaptivity than the lumped model. Lastly, a vertical take-off and landing (VTOL) profile is employed. The temperature prediction accuracy results show that the TCM can maintain a relative error below 5% throughout the entire prediction period.
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基于扁平热管的电池热管理系统新型快速温度预测算法
预测锂离子电池的电芯温度对于精确的状态估计至关重要,但却很难直接测量。现有的快速温度预测方法很难考虑复杂结构的热质量,这可能会导致时间延迟,尤其是在高 C 率动态条件下。本文开发了一种基于热卷积法(TCM)的快速温度预测算法,用于计算动态条件下基于扁平热管的电池热管理系统(FHP-BTMS)的核心温度。该模型通过对包含完整物理信息的热响应图进行卷积,可快速预测电芯温度。首先,为了获得高保真的时空温度分布,建立了 FHP-BTMS 的热容阻网络(TCRN),并通过恒定和动态放电实验进行了验证。然后,获得了由各种脉冲热源和散热器激发的核心温度响应图。具体而言,讨论了 FHP 的动态热特性,以修正 TCM 的边界条件。随后,比较了 TCM 和块状模型在不同步骤运行条件下的温度预测性能。结果表明,与块状模型相比,TCM 的精度提高了 70-80%,动态适应性更好。最后,采用了垂直起降(VTOL)剖面。温度预测精度结果表明,TCM 可以在整个预测期间将相对误差保持在 5%以下。
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来源期刊
Batteries
Batteries Energy-Energy Engineering and Power Technology
CiteScore
4.00
自引率
15.00%
发文量
217
审稿时长
7 weeks
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