A Simulation Framework for Battery Cell Impact Safety Modeling Using LS-DYNA

Marcicki, James; Zhu, Min; Bartlett, Alexander; Yang, Xiaoling; Chen, Yijung; Miller, Ted; L’Eplattenier, P.; Çaldichoury, Iñaki

doi:10.1149/2.0661701jes

Cited by 51 publications

(39 citation statements)

References 22 publications

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“…Marcicki et al developed a coupled structural-electrochemical-thermal model in LS Dyna to simulate the response of pouch cells under spherical and cylindrical impact loading [68]. Tensile tests in different directions as well as compression tests were conducted on the separator and electrodes to determine their material properties and FE models were developed to validate the models.…”

Section: Pouched Cellsmentioning

confidence: 99%

Review: Characterization and Modeling of the Mechanical Properties of Lithium-Ion Batteries

Kermani

Sahraei

2017

Energies

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Li-ion batteries have become a dominant power source in consumer electronics and vehicular applications. The mobile use of batteries subjects them to various mechanical loads. The mechanisms that follow a mechanical deformation and lead to damage and failure in Li-ion batteries have only been studied in recent years. This paper is a comprehensive review of advancements in experimental and computational techniques for characterization of Li-ion batteries under mechanical abuse loading scenarios. A number of recent studies have used experimental methods to characterize deformation and failure of batteries and their components under various tensile and compressive loading conditions. Several authors have used the test data to propose material laws and develop finite element (FE) models. Then the models have been validated against tests at different levels from comparison of shapes to predicting failure and onset of short circuit. In the current review main aspects of each study have been discussed and their approach in mechanical testing, material characterization, FE modeling, and validation is analyzed. The main focus of this review is on mechanical properties at the level of a single battery.

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Section: Pouched Cellsmentioning

confidence: 99%

Review: Characterization and Modeling of the Mechanical Properties of Lithium-Ion Batteries

Kermani

Sahraei

2017

Energies

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“…In a review of mechanical modelling of lithium-ion batteries, Zhu identified aspects of mechanical behaviour inherent to lithium-ion cells that should be represented by accurate homogenized material models that included [10]: the pressure dependence of the compression stiffness of porous layers, the poromechanics of the electrolyte-filled porous structure of the jellyroll, anisotropy of individual layers, plasticity, and crack propagation. Despite the complexity of multi-physics in the jellyroll [11][12][13], a notable consensus has arisen within a growing body of research that structural properties can be adequately approximated in solid mechanical terms for the practical finite element simulation of lithium-ion cells [6,[14][15][16][17][18][19]. Due to the common motivation of simulating automotive crash events, research has been predominantly concerned with bending and compression deformation.…”

Section: Introductionmentioning

confidence: 99%

“…Poisson's ratio [20] and has been likened to the behaviour of cellular materials [21]. To this purpose, crushable foam and honeycomb material models have been frequently employed for homogenization techniques in commercial finite element codes such as LS DYNA and Abaqus [4,15,18,[21][22][23][24][25][26][27][28][29][30][31][32][33][34][35][36]. The stiffness of polymeric foams is strain-rate dependent and is generally characterized by three phases of compression [37][38][39][40].…”

Section: Introductionmentioning

confidence: 99%

Dynamic Mechanical Compression Impulse of Lithium-Ion Pouch Cells

2020

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Strain rate sensitivity has been widely recognized as a significant feature of the dynamic mechanical properties of lithium-ion cells, which are important for their accurate representation in automotive crash simulations. This research sought to improve the precision with which dynamic mechanical properties can be determined from drop tower impact testing through the use of a diaphragm to minimize transient shock loads and to constrain off-axis motion of the indenter, specialized impact absorbers to reduce noise, and observation of displacement with a high speed camera. Inert pouch cells showed strain rate sensitivity in an increased stiffness during impact tests that was consistent with the poromechanical interaction of the porous structure of the jellyroll with the liquid electrolyte. The impact behaviour of the inert pouch cells was similar to that of an Expanded Polypropylene foam (EPP), with the exception that the inert pouch cells did not show hysteretic recovery under the weight of the indenter. This suggests that the dynamic mechanical behaviour of the inert pouch cells is analogous to a highly damped foam.

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“…Marcicki and Zhu 18 used a combination of material testing and finite element simulation of components to study the thermal runaway phenomenon of a power battery during a sudden external short circuit. The finite element model could predict the distributed thermal response of the battery in an external short circuit.…”

Section: Introductionmentioning

confidence: 99%

Study on the failure behavior of the current interrupt device of lithium‐ion battery considering the effect of creep

Lin

et al. 2020

Int J Energy Res

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The working condition of the CID (current interrupt device) has an important impact on the safety of the prismatic lithium-ion batteries. One of the important factors that causes the failure of the prismatic power battery is the overturning of CID due to material creep. The tensile and creep tests of the MFX2 aluminum alloy which is the material of CID were designed. Based on the experimental data the isotropic hardening multilinear elastic-plastic constitution and creep constitution at the battery working temperature were established. The constitutions were also verified by the notch test. The finite element model of the CID and the cap was established to analyze the effect of creep on the failure behavior of the CID throughout life. The simulation tests in the constant temperature and constant load of CID is designed. The simulation results showed that the constitution characterizes the basic mechanical properties of the CID reasonably. During the life of the CID, the creep behavior would go through the fast stage firstly and then fall into the slow steady-state stage. The creep effect of the material would cause the CID to overturn in advance, overturning pressure would be reduced, the life of the power battery would also be reduced.

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A Simulation Framework for Battery Cell Impact Safety Modeling Using LS-DYNA

Cited by 51 publications

References 22 publications

Review: Characterization and Modeling of the Mechanical Properties of Lithium-Ion Batteries

Review: Characterization and Modeling of the Mechanical Properties of Lithium-Ion Batteries

Dynamic Mechanical Compression Impulse of Lithium-Ion Pouch Cells

Study on the failure behavior of the current interrupt device of lithium‐ion battery considering the effect of creep

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