Noninvasive ultrasound for Lithium-ion batteries state estimation

2021 IEEE UFFC Latin America Ultrasonics Symposium (LAUS) Pub Date : 2021-10-04 DOI:10.1109/LAUS53676.2021.9639104

Simon Montoya-Bedoya, M. Bernal, Laura A. Sabogal-Moncada, H. V. Martínez-Tejada, E. Garcia-Tamayo

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引用次数: 1

Abstract

Lithium-ion battery degradation estimation using fast and noninvasive techniques is a crucial issue in the circular economy framework of this technology. Currently, most of the approaches used to establish the battery-state (i.e., State of Charge (SoC), State of Health (SoH)) require time-consuming processes. In the present preliminary study, an ultrasound array was used to assess the influence of the SoC and SoH on the variations in the time of flight (TOF) and the speed of sound (SOS) of the ultrasound wave inside the batteries. Nine aged 18650 Lithium-ion batteries were imaged at 100% and 0% SoC using a Vantage-256 system (Verasonics, Inc.) equipped with a 64-element ultrasound array and a center frequency of 5 MHz (Imasonic SAS). It was found that second-life batteries have a complex ultrasound response due to the presence of many degradation pathways and, thus, making it harder to analyze the ultrasound measurements. Although further analysis must be done to elucidate a clear correlation between changes in the ultrasound wave properties and the battery state estimation, this approach seems very promising for future nondestructive evaluation of second-life batteries

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无创超声用于锂离子电池状态评估

在锂离子电池循环经济框架中，使用快速、无创技术进行电池退化评估是一个关键问题。目前，用于确定电池状态(即充电状态(SoC)、健康状态(SoH))的大多数方法都需要耗时的过程。在本初步研究中，利用超声阵列评估了SoC和SoH对电池内超声波飞行时间(TOF)和声速(SOS)变化的影响。使用Vantage-256系统(Verasonics, Inc.)，在100%和0% SoC下对9个老化的18650锂离子电池进行成像，该系统配备64元超声阵列，中心频率为5 MHz (Imasonic SAS)。研究发现，由于存在许多降解途径，二次电池具有复杂的超声响应，因此使超声测量分析变得更加困难。虽然需要进一步的分析来阐明超声波特性变化与电池状态评估之间的明确相关性，但这种方法对于未来对二次寿命电池的无损评估似乎是非常有希望的

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2021 IEEE UFFC Latin America Ultrasonics Symposium (LAUS)

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