The Surface Cell Cooling Coefficient: A Standard to Define Heat Rejection from Lithium Ion Battery Pouch Cells

Hales, Alastair; Marzook, Mohamed Waseem; Diaz, Laura Bravo; Patel, Yatish; Offer, Gregory J.

doi:10.1149/1945-7111/ab6985

Cited by 27 publications

(37 citation statements)

References 50 publications

(88 reference statements)

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“…Note that a rapid change of the battery temperature by a large external heating or cooling power leads to a large temperature gradient. That indicates the optimal battery temperature depends on a balance between the temperature rise and the temperature uniformity [9,[93][94][95][96][97].…”

Section: Temperature Uniformitymentioning

confidence: 99%

A review of thermal physics and management inside lithium-ion batteries for high energy density and fast charging

Zeng

Chalise

Lubner

et al. 2021

Energy Storage Materials

103

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Traditionally it has been assumed that battery thermal management systems should be designed to maintain the battery temperature around room temperature. That is not always true as Lithium-ion battery (LIB) R&D is pivoting towards the development of high energy density and fast charging batteries. Therefore, it is necessary to have a comprehensive review of thermal considerations for LIBs targeted for high energy density and fast charging, i.e., the optimal thermal condition, thermal physics (heat transport and generation) inside the battery, and thermal management strategies. As the energy density and charge rate increases, the optimal battery temperature can shift to be higher than room temperature. To improve the temperature uniformity and avoid excessive internal temperature rise, heat transfer inside the battery needs to be enhanced, and reducing the thermal contact resistance between the electrodes and separator can significantly increase the effective thermal conductivity of batteries. In the first part of the review various challenges and latest developments related to thermal transport and properties of LIBs are discussed. In the second part of the review various sources of heat generation inside LIBs and various approaches to minimizing battery heat generation are summarized. The importance of heat of mixing due to ion diffusion during fast charging is also highlighted. Finally, a summary of latest advancement on smart control of internal temperature of LIBs is discussed as depending on the ambient temperature and the optimal temperature; the battery heat needs to be retained or dissipated to elevate or avoid temperature rise. Lithium-ion battery; Optimal battery temperature; High energy density; Fast charging; Battery thermal management

show abstract

Section: Temperature Uniformitymentioning

confidence: 99%

A review of thermal physics and management inside lithium-ion batteries for high energy density and fast charging

Zeng

Chalise

Lubner

et al. 2021

Energy Storage Materials

103

View full text Add to dashboard Cite

show abstract

“…We have developed a metric called the cell cooling coefficient 3,4 . It can be used to describe the temperature gradient across a cell in operation in watts per kelvin (W K -1 ).…”

Section: Key Metricmentioning

confidence: 99%

“…The first step is for the battery industry to report routinely on thermal management. We have developed a standardized performance metric for this purpose 3,4 . It compares different electrochemical cells and can be measured using equipment that is readily available in battery laboratories.…”

mentioning

confidence: 99%

Cool metric for lithium-ion batteries could spur progress

Offer

Patel

Hales

et al. 2020

Nature

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Lithium-ion batteries get hot, and it is hard to keep them cool. Industry has paid too little attention to this problem for the past decade. The focus has been elsewhere: on cutting costs and on boosting the amount of energy a single cell in a battery can store (energy density). This strategy has, for example, increased the longevity and capabilities of mobile phones. Future applications, such as electric vehicles and smart grids, need thousands of cells in a battery pack. These are prone to overheating.Manufacturers of large, high-energy battery packs must design complicated systems to manage heat. The battery pack in electric-vehicle maker Tesla's Model 3 car, for example, holds more energy than 6,000 iPhone 11 handsets. Coolant fluid is pumped through a network of channels to carry heat away from the individual cells. But these cumbersome additions make the battery pack heavy and drain its energy 1 . Developers are wasting time and money on these inefficient designs. Heat-removal strategies must be improved to make battery packs both light and powerful.Why this lack of attention? One reason is that there is no standard way of judging the thermal performance of battery packs. Manufacturers of single cells compete by chasing ever greater energy density. Their product-specification sheets do not cover how easy it is to remove heat from a cell. Designers of battery packs A new measure for the rate of heat removal from battery packs gives manufacturers a simple way to compare products.

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“…These are limited to enabling just qualitative comparison because determination of a cell's effective thermal conductivity or characteristic length requires unjustifiable assumptions. In response to this the Cell Cooling Coefficient (CCC) has been developed to provide a universal thermal performance metric, specific to the lithium-ion battery industry, for tab cooling [23] and for surface cooling [24]. The CCC is a constant for each cell (manufacturer and model number), and thermal management method.…”

Section: Figure 2 the Ocv-soc Relationship At Different Temperatures From Pulse Charge And Discharge Tests For A123mentioning

confidence: 99%

“…The capability of the two cells to reject heat through either their surface or tabs may be quantified by evaluating the cells' CCCs. The method for empirically deriving the CCC has been published in previous work by Hales et al [23,24],…”

Section: C]mentioning

confidence: 99%

The role of cell geometry when selecting tab or surface cooling to minimise cell degradation

et al. 2020

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The Surface Cell Cooling Coefficient: A Standard to Define Heat Rejection from Lithium Ion Battery Pouch Cells

Cited by 27 publications

References 50 publications

A review of thermal physics and management inside lithium-ion batteries for high energy density and fast charging

A review of thermal physics and management inside lithium-ion batteries for high energy density and fast charging

Cool metric for lithium-ion batteries could spur progress

The role of cell geometry when selecting tab or surface cooling to minimise cell degradation

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