One-Time Prediction of Battery Capacity Fade Curve under Multiple Fast Charging Strategies

IF 4.6 4区 化学 Q2 ELECTROCHEMISTRY Batteries Pub Date : 2024-02-22 DOI:10.3390/batteries10030074
Xiaoming Han, Zhentao Dai, Mifeng Ren, Jing Cui, Yunfeng Shi
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Abstract

Using different fast charging strategies for lithium-ion batteries can affect the degradation rate of the batteries. In this case, predicting the capacity fade curve can facilitate the application of new batteries. Considering the impact of fast charging strategies on battery aging, a battery capacity degradation trajectory prediction method based on the TM-Seq2Seq (Trend Matching—Sequence-to-Sequence) model is proposed. This method uses data from the first 100 cycles to predict the future capacity fade curve and EOL (end of life) in one-time. First, features are extracted from the discharge voltage-capacity curve. Secondly, a sequence-to-sequence model based on CNN, SE-net, and GRU is designed. Finally, a trend matching loss function is designed based on the common characteristics of capacity fade curves to constrain the encoding features of the sequence-to-sequence model, facilitating the learning of the underlying relationship between inputs and outputs. TM-Seq2Seq model is verified on a public dataset with 132 battery cells and multiple fast charging strategies. The experimental results indicate that, compared to other popular models, the TM-Seq2Seq model has lower prediction errors.
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一次性预测多种快速充电策略下的电池容量衰减曲线
对锂离子电池采用不同的快速充电策略会影响电池的衰减率。在这种情况下,预测容量衰减曲线可以促进新电池的应用。考虑到快速充电策略对电池老化的影响,本文提出了一种基于 TM-Seq2Seq(趋势匹配-序列到序列)模型的电池容量衰减轨迹预测方法。该方法利用前 100 个循环的数据,一次性预测未来的容量衰减曲线和 EOL(寿命终止)。首先,从放电电压-容量曲线中提取特征。其次,设计基于 CNN、SE-net 和 GRU 的序列到序列模型。最后,根据容量衰减曲线的共同特征,设计了趋势匹配损失函数,以约束序列到序列模型的编码特征,从而促进对输入和输出之间潜在关系的学习。TM-Seq2Seq 模型在一个包含 132 个电池单元和多种快速充电策略的公共数据集上进行了验证。实验结果表明,与其他流行模型相比,TM-Seq2Seq 模型的预测误差更小。
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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
期刊最新文献
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