Anand N. P. Radhakrishnan, M. Buckwell, M. Pham, D. Finegan, A. Rack, G. Hinds, D. Brett, P. Shearing
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This facilitated the estimation of the displacement of electrodes undergoing abuse via nail penetration, and also the tracking of objects, such as the nail, as it propagates through a cell. Further, by cross-correlating the Gabor signals, we have produced practical, illustrative spatiotemporal maps of the failure events. From these, we can quantify the propagation rates of electrode displacement prior to the onset of thermal runaway. The highest recorded acceleration (≈ 514 mm s-2) was when a nail penetrated a cell radially (perpendicular to the electrodes) as opposed to axially (parallel to the electrodes). The initiation of thermal runaway was also resolved in combination with electrode displacement, which occurred at a lower acceleration (≈ 108 mm s-2). Our assistive toolbox can also be used to study other types of failure mechanisms, extracting otherwise unattainable kinetic data. 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引用次数: 1
摘要
为了制定新的安全标准和策略,对锂离子电池进行了广泛的滥用测试。然而,在整个研究界,测试方法并没有标准化,特别是失效机制本身就难以重现。高速x射线摄影被证明是捕获细胞衰竭过程中发生的事件的有价值的工具,但所做的观察在很大程度上仍然是定性的。因此,我们开发了一个强大的图像处理工具箱,可以首次量化高速x射线照相揭示的电池故障机制的传播速率。使用Gabor滤波器,工具箱选择性地跟踪电极结构在失效的开始。这有助于估计通过指甲穿透滥用电极的位移,也有助于跟踪物体,如指甲,因为它在细胞中传播。此外,通过交叉相关的Gabor信号,我们已经产生了实际的,说明性的失效事件的时空图。由此,我们可以量化在热失控发生之前电极位移的传播速率。当钉子沿径向(垂直于电极)而不是轴向(平行于电极)穿透细胞时,记录到的最高加速度(≈514 mm s-2)。在较低的加速度(≈108 mm s-2)下,电极位移也解决了热失控的引发问题。我们的辅助工具箱也可用于研究其他类型的失效机制,提取否则无法获得的动力学数据。最终,该工具不仅可用于验证现有的理论力学模型,还可用于标准化电池故障测试程序。
Quantitative spatiotemporal mapping of thermal runaway propagation rates in lithium-ion cells using cross-correlated Gabor filtering
Abuse testing of lithium-ion batteries is widely performed in order to develop new safety standards and strategies. However, testing methodologies are not standardised across the research community, especially with failure mechanisms being inherently difficult to reproduce. High-speed X-ray radiography is proven to be a valuable tool to capture events occurring during cell failure, but the observations made remain largely qualitative. We have therefore developed a robust image processing toolbox that can quantify, for the first time, the rate of propagation of battery failure mechanisms revealed by high-speed X-ray radiography. Using Gabor filter, the toolbox selectively tracks the electrode structure at the onset of failure. This facilitated the estimation of the displacement of electrodes undergoing abuse via nail penetration, and also the tracking of objects, such as the nail, as it propagates through a cell. Further, by cross-correlating the Gabor signals, we have produced practical, illustrative spatiotemporal maps of the failure events. From these, we can quantify the propagation rates of electrode displacement prior to the onset of thermal runaway. The highest recorded acceleration (≈ 514 mm s-2) was when a nail penetrated a cell radially (perpendicular to the electrodes) as opposed to axially (parallel to the electrodes). The initiation of thermal runaway was also resolved in combination with electrode displacement, which occurred at a lower acceleration (≈ 108 mm s-2). Our assistive toolbox can also be used to study other types of failure mechanisms, extracting otherwise unattainable kinetic data. Ultimately, this tool can be used to not only validate existing theoretical mechanical models, but also standardise battery failure testing procedures.