滴定-气相色谱技术在锂离子电池析锂定量检测中的应用

doi:10.19799/j.cnki.2095-4239.2022.0117

储能科学与技术 ›› 2022, Vol. 11 ›› Issue (8): 2564-2573.doi: 10.19799/j.cnki.2095-4239.2022.0117

滴定-气相色谱技术在锂离子电池析锂定量检测中的应用

孙涛¹(), 沈腾腾¹^,², 刘昕²^,⁴, 任东生²^,³(), 刘金海⁴, 郑岳久¹, 王鲁彦¹^,², 卢兰光², 欧阳明高²

^1.上海理工大学机械工程学院，上海 200093
^2.清华大学汽车安全与节能国家重点实验室
^3.清华大学核能与新能源技术研究院，北京 100084
^4.北京昇科能源科技有限责任公司，北京 102101

收稿日期:2022-03-07 修回日期:2022-03-21 出版日期:2022-08-05 发布日期:2022-08-03
通讯作者: 任东生 E-mail:tao_sun531@usst.edu.cn;rends@tsinghua.edu.cn
作者简介:孙涛（1974—），男，博士，副教授，主要研究方向为新能源汽车智能化与智能电池管理技术，E-mail：tao_sun531@usst.edu.cn；
基金资助:
广东省重点领域研发计划(2020B0909030001);国家自然科学基金项目(52007099);中国博士后科学基金会面上项目(2020M680550)

Application of titration gas chromatography technology in the quantitative detection of lithium plating in Li-ion batteries

Tao SUN¹(), Tengteng SHEN¹^,², Xin LIU²^,⁴, Dongsheng REN²^,³(), Jinhai LIU⁴, Yuejiu ZHENG¹, Luyan WANG¹^,², Languang LU², Minggao OUYANG²

^1.College of Mechanical Engineering, University of Shanghai for Science and Technology, Shanghai 200093, China
^2.State Key Laboratory of Automotive Safety and Energy, Tsinghua University
^3.Institute of Nuclear and New Energy Technology, Tsinghua University, Beijing 100084, China
^4.Thinkenergy technology Co. , LTD. , Beijing 102101, China

Received:2022-03-07 Revised:2022-03-21 Online:2022-08-05 Published:2022-08-03
Contact: Dongsheng REN E-mail:tao_sun531@usst.edu.cn;rends@tsinghua.edu.cn

摘要/Abstract

摘要：

锂离子电池在快速充电时会诱发负极析锂，造成严重的容量衰减和可能的安全问题。因此，准确识别电池内部的析锂量对于解决这些问题至关重要。本工作研究了滴定-气相色谱仪(titration gas chromatography，TGC)技术在石墨负极锂离子电池上定量检测析锂的有效性，实现了该方法在石墨负极析锂定量检测上的应用，最小检测极限为2.4 μmol金属锂。首先，利用已知浓度的标准气体对气相色谱仪(gas chromatography，GC)进行标定，确定了氢气浓度与GC检测到氢气信号面积之间的关系，进一步通过不同金属锂含量的样本对实验装置的可行性进行分析，证明了所开发的检测系统可以实现金属锂含量的定量检测，并确定了金属锂含量与TGC检测到氢气浓度的关系。在此基础上，使用核磁共振定量析锂检测技术，对TGC方法用于石墨负极析锂的定量检测的有效性和准确性进行了验证。最后，利用所开发的TGC检测系统，对两个不同析锂程度的1 Ah软包电池进行了析锂定量检测，与根据容量衰减估算的电池析锂的量相比，TGC检测的析锂量的误差小于7%，实现了电池析锂量的准确检测。

关键词: 锂离子电池, 析锂检测, 滴定-气相色谱技术, 核磁共振技术

Abstract:

Lithium plating is induced in lithium-ion batteries during fast charging, resulting in severe capacity fading and possible safety issues. Therefore, the accurate detection of lithium plating is vital for the safe operation of lithium-ion batteries. This study explored the application of titration gas chromatography (TGC) quantitatively detect lithium plating in lithium-ion batteries. The TGC can accurately detect the amount of plated lithium on the graphite anode, with a detection limit of 2.4 μmol Li. First, the relationship between H₂concentration and H₂ signal area detected using TGC was calibrated using a standard gas of known concentration. The feasibility of the experimental device was further analyzed through tests on samples containing different lithium metal contents, which demonstrated that the developed detection system could quantitatively detect lithium plating, and the relationship between the amount of metallic lithium and the H₂ concentration detected using TGC was determined. Moreover, the amount of plated lithium on the anode detected using the TGC method was consistent with the results measured by nuclear magnetic resonance, demonstrating the TGC method's high accuracy. Finally, the TGC method was used to detect the amount of plated lithium within two 1 Ah lithium-ion batteries after low-temperature charging. The results were consistent with the amount of plated lithium estimated from battery capacity loss, with errors less than 7%. This study demonstrates that the TGC method can be used to quantitatively detect lithium plating in lithium-ion batteries and that it has the advantages of low cost, feasibility, and scalability.

Key words: lithium-ion battery, lithium plating detection, titration gas chromatography, nuclear magnetic resonance

中图分类号:

TM 912.9

孙涛, 沈腾腾, 刘昕, 任东生, 刘金海, 郑岳久, 王鲁彦, 卢兰光, 欧阳明高. 滴定-气相色谱技术在锂离子电池析锂定量检测中的应用[J]. 储能科学与技术, 2022, 11(8): 2564-2573.

Tao SUN, Tengteng SHEN, Xin LIU, Dongsheng REN, Jinhai LIU, Yuejiu ZHENG, Luyan WANG, Languang LU, Minggao OUYANG. Application of titration gas chromatography technology in the quantitative detection of lithium plating in Li-ion batteries[J]. Energy Storage Science and Technology, 2022, 11(8): 2564-2573.

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参考文献 34

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样品	参数	厂家数据	单位
单体	容量@1/3C	1	Ah
	反应面积	4.35×10^-2	m²
	上限电压	4.2	V
	下限电压	3.0	V
负极	材料	graphite	—
	颗粒直径	7.1	μm
	孔隙率	0.318	1
正极	材料	Li _x Ni_0.5Co_0.2Mn_0.3O₂	—
	颗粒直径	3.2	μm
	孔隙率	0.313	1
隔膜	孔隙率	0.4	1

测试参数	设置
拉莫频率	232.76 MHz
脉冲宽度	1.6 s
延迟时间	20 s
旋转频率	15 kHz
扫描次数	16
扫描范围	-500～500 ppm

序号	Li质量/mg	反应容器/mL	测试样品 Li摩尔量/mol	理论H₂浓度/(mol/L)	GC谱图特征峰面积			GC测试 H₂浓度/(mol/L)
1	1.2	587	1.73×10^-4	1.49×10^-4	12560	12610	12630	1.64×10^-4
2	3.3	587	4.76×10^-4	4.09×10^-4	31434	33021	33577	4.25×10^-4
3	4.7	587	6.77×10^-4	5.82×10^-4	47979	48250	48009	6.25×10^-4
4	7.0	587	1.009×10^-3	8.67×10^-4	68899	69024	68968	8.97×10^-4
5	10.7	1124	1.542×10^-3	6.89×10^-4	52100	51596	52001	6.75×10^-4

序号	Li质量/mg	LiCl质量/mg	Li质量比/%	LiCl质量比/%	测试粉末质量/mg	测试样品Li摩尔量/mol	NMR谱图特征峰面积
1	2.3	500.4	0. 4575	99.5425	0.06343	4.15E-05	0.056606
2	5.1	499.0	1.0117	98.9883	0.06168	8.91E-05	0.126313
3	8.4	500.0	1.6522	98.3478	0.06441	0.000152	0.182615
4	9.9	500.7	1.9389	98.0611	0.06447	0.000179	0.226653
5	14.7	501.4	2.8483	97.1517	0.06537	0.000266	0.297649

样品序号	TGC测试析锂量 /(mol/g)	NMR测试析锂量 /(mol/g)	误差/%
1	2.10×10^-3	2.11×10^-3	0.5
2	1.53×10^-3	1.64×10^-3	7.2
3	1.73×10^-3	1.84×10^-3	6.4

滴定-气相色谱技术在锂离子电池析锂定量检测中的应用

Application of titration gas chromatography technology in the quantitative detection of lithium plating in Li-ion batteries

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参考文献 34

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样品	初始容量/Ah	容量衰减率/%	容量衰减量/Ah	依据容量衰减估算析锂/g	TGC测量值/g	相对误差/%	去掉噪声背景/g	相对误差/%
A	1.097	62.6	0.687	0.178	0.179	0.6	0.167	6.2
B	1.110	64.9	0.720	0.186	0.204	9.7	0.191	2.7

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样本	粉末样本中锂的含量/(g/g)	极片样本中锂的含量/(g/g)	差值
1	0.112	0.033	3.4倍
2	0.065	0.030	2.2倍
3	0.099	0.029	3.4倍

样本	金属锂含量/g	换算残余容量/mAh
1	0.014	54
2	0.011	42
3	0.013	50
平均值	0.0127	49