Heat transfer enhancement in a lithium-ion cell through improved material-level thermal transport

Vishwakarma, Vivek; Waghela, Chirag; Zi, Wei; Prasher, Ravi; Nagpure, Shrikant C.; Li, Jianlin; Liu, Fuqiang; Daniel, Claus; Jain, Ankur

doi:10.1016/j.jpowsour.2015.09.028

Cited by 63 publications

(49 citation statements)

References 36 publications

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“…Thermal property measurements are primarily done either at material level or at the cell level in Li-ion cells. At material level, the thermal property measurements of electrodes [45][46][47][48][49], electrolyte [50], separator [51,52], electrode stack [46,53], and contact thermal resistance [54,55] have been reported. Such material-level measurements are key in understanding the heat transfer inside a Li-ion cell and in determining the rate-limiting heat transfer processes.…”

Section: Thermal Propertymentioning

confidence: 99%

Measurement of Multiscale Thermal Transport Phenomena in Li-Ion Cells: A Review

Shah

Vishwakarma

Jain

2016

Journal of Electrochemical Energy Conversion and Storage

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The performance, safety, and reliability of electrochemical energy storage and conversion systems based on Li-ion cells depend critically on the nature of heat transfer in Li-ion cells, which occurs over multiple length scales, ranging from thin material layers all the way to large battery packs. Thermal phenomena in Li-ion cells are also closely coupled with other transport phenomena such as ionic and charge transport, making this a challenging, multidisciplinary problem. This review paper presents a critical analysis of recent research literature related to experimental measurement of multiscale thermal transport in Li-ion cells. Recent research on several topics related to thermal transport is summarized, including temperature and thermal property measurements, heat generation measurements, thermal management, and thermal runaway measurements on Li-ion materials, cells, and battery packs. Key measurement techniques and challenges in each of these fields are discussed. Critical directions for future research in these fields are identified.

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Section: Thermal Propertymentioning

confidence: 99%

Measurement of Multiscale Thermal Transport Phenomena in Li-Ion Cells: A Review

Shah

Vishwakarma

Jain

2016

Journal of Electrochemical Energy Conversion and Storage

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“…For reference, the C-rate of a charge/discharge process is defined as the reciprocal of the number of hours needed to complete charge or discharge the cell [1,7]. However, due to poor thermal conductance of the cell [9] resulting from material and interfacial thermal resistances in the cell [10], this causes significant temperature rise [11,12], particularly in the core of the cell, where heat accumulation tends to occur due to the lack of a direct access for heat removal [13]. While high core temperature may improve cell performance due to reduced internal resistance, it is also known that high cell temperature increases the rate of capacity fade [14,15].…”

Section: Introductionmentioning

confidence: 99%

Non-invasive measurement of internal temperature of a cylindrical Li-ion cell during high-rate discharge

Anthony

Wong

Wetz

et al. 2017

International Journal of Heat and Mass Transfer

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Li-ion cells are a technologically important class of devices for electrochemical energy storage and conversion. Overheating of a Li-ion cell during operation is undesirable as it directly affects performance and safety. Although a number of methods have been used for temperature measurement in Li-ion cells, there is a lack of non-invasive techniques to determine the peak temperature at the core of the cell. Measuring only the outside surface temperature, while straightforward, is not sufficient since the core temperature is in most cases much higher. This paper presents non-invasive measurement of the core temperature of a Li-ion cell using a recently developed technique that utilizes space and time integrals of the measured temperature field at the outside surface. The surface temperature field of an operating Li-ion cell is measured using infrared thermography at multiple discharge rates up to 10C, using which, the core temperature is predicted as a function of time. In each case, there is excellent agreement throughout the discharge period between the predicted core temperature and measurements from a thermocouple embedded at the core of the cell. These measurements quantify the temperature gradient within the cell, which is particularly high at large discharge rates. This paper may result © 2016. This manuscript version is made available under the Elsevier user license http://www.elsevier.com/open-access/userlicense/1.0/ 2 in non-invasive core measurement methods that may contribute towards performance optimization and improved safety of Li-ion cells.

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“…When the cell is not being cooled effectively by external convection, a larger increase in thermal conductivity may be required to influence the thermal runaway behavior of the cell. Some work has been carried out on improving cell thermal conductivity by improving material and interfacial thermal transport . Figure A helps evaluate the actual impact of such improvements on the thermal runaway performance of the cell.…”

Section: Resultsmentioning

confidence: 99%

“…Some work has been carried out on improving cell thermal conductivity by improving material and interfacial thermal transport. 38,39 Figure 5A helps evaluate the actual impact of such improvements on the thermal runaway performance of the cell.…”

Section: Effect Of Heat Transfer Parametersmentioning

confidence: 99%

Prediction of thermal runaway and thermal management requirements in cylindrical Li‐ion cells in realistic scenarios

Shah

Jain

2019

Int J Energy Res

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Summary Li‐ion cells suffer from significant safety and performance problems due to overheating and thermal runaway. Effective thermal management can lead to increased energy conversion efficiency and energy storage density. Critical needs towards these goals include the capability to predict thermal behavior in extreme conditions and determine thermal management requirements to prevent thermal runaway. This paper presents an experimentally validated theoretical model to predict the temperature distribution in a cell in response to nonlinear heat generation rate that is known to occur during thermal runaway. This problem is solved by linearization of the nonlinear term over successive time intervals. Experimental measurements carried out on a thermal test cell in conditions similar to thermal runaway show good agreement with the theoretical model. Experimental measurements and model predictions indicate strong dependence of the fate of the cell on its reaction kinetics, thermal properties, and ambient conditions. Specifically, a sudden change in thermal runaway behavior is predicted once the ambient temperature crosses a certain threshold, consistent with past experimental observations. The impact of increasing cell thermal conductivity on improved thermal runaway performance is quantified. Results presented here provide a fundamental understanding of thermal runaway, and may lead to improved performance and safety of Li‐ion–based energy conversion and storage systems.

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Heat transfer enhancement in a lithium-ion cell through improved material-level thermal transport

Cited by 63 publications

References 36 publications

Measurement of Multiscale Thermal Transport Phenomena in Li-Ion Cells: A Review

Measurement of Multiscale Thermal Transport Phenomena in Li-Ion Cells: A Review

Non-invasive measurement of internal temperature of a cylindrical Li-ion cell during high-rate discharge

Prediction of thermal runaway and thermal management requirements in cylindrical Li‐ion cells in realistic scenarios

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