Performance Analysis of Indentation Punch on High Energy Lithium Pouch Cells and Simulated Model Improvement

In this research, the aim relates to the material characterization of high-energy lithium-ion pouch cells. The development of appropriate model cell behavior is intended to simulate two scenarios: the first is mechanical deformation during a crash and the second is an internal short circuit in lithi...

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Veröffentlicht in:	Polymers 2021-06, Vol.13 (12), p.1971
Hauptverfasser:	Ye, Lihua, Ashfaq, Muhammad Muzamal, Shi, Aiping, Shah, Syyed Adnan Raheel, Shi, Yefan
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Sprache:	eng
Schlagworte:	Deformation Electric cells Electric vehicles Electrolytes Electrolytic cells Energy storage Indentation Lithium Lithium-ion batteries Mathematical models Parameters Position measurement Rechargeable batteries Short circuits State of charge
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container_title	Polymers
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creator	Ye, Lihua Ashfaq, Muhammad Muzamal Shi, Aiping Shah, Syyed Adnan Raheel Shi, Yefan
description	In this research, the aim relates to the material characterization of high-energy lithium-ion pouch cells. The development of appropriate model cell behavior is intended to simulate two scenarios: the first is mechanical deformation during a crash and the second is an internal short circuit in lithium-ion cells during the actual effect scenarios. The punch test has been used as a benchmark to analyze the effects of different state of charge conditions on high-energy lithium-ion battery cells. This article explores the impact of three separate factors on the outcomes of mechanical punch indentation experiments. The first parameter analyzed was the degree of prediction brought about by experiments on high-energy cells with two different states of charge (greater and lesser), with four different sizes of indentation punch, from the cell's reaction during the indentation effects on electrolyte. Second, the results of the loading position, middle versus side, are measured at quasi-static speeds. The third parameter was the effect on an electrolyte with a different state of charge. The repeatability of the experiments on punch loading was the last test function analyzed. The test results of a greater than 10% state of charge and less than 10% state of charge were compared to further refine and validate this modeling method. The different loading scenarios analyzed in this study also showed great predictability in the load-displacement reaction and the onset short circuit. A theoretical model of the cell was modified for use in comprehensive mechanical deformation. The overall conclusion found that the loading initiating the cell's electrical short circuit is not instantaneously instigated and it is subsequently used to process the development of a precise and practical computational model that will reduce the chances of the internal short course during the crash.
doi_str_mv	10.3390/polym13121971
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The repeatability of the experiments on punch loading was the last test function analyzed. The test results of a greater than 10% state of charge and less than 10% state of charge were compared to further refine and validate this modeling method. The different loading scenarios analyzed in this study also showed great predictability in the load-displacement reaction and the onset short circuit. A theoretical model of the cell was modified for use in comprehensive mechanical deformation. 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This article is an open access article distributed under the terms and conditions of the Creative Commons Attribution (CC BY) license (https://creativecommons.org/licenses/by/4.0/). 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subjects	Deformation Electric cells Electric vehicles Electrolytes Electrolytic cells Energy storage Indentation Lithium Lithium-ion batteries Mathematical models Parameters Position measurement Rechargeable batteries Short circuits State of charge
title	Performance Analysis of Indentation Punch on High Energy Lithium Pouch Cells and Simulated Model Improvement
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