Optimal external heating resistance enabling rapid compound self-heating for lithium-ion batteries at low temperatures
Optimal external heating resistance enabling rapid compound self-heating for lithium-ion batteries at low temperatures
Low-temperature preheating to achieve effective thermal management for lithium-ion batteries is a crucial enabler for the efficient and safe operation of electric vehicles in cold conditions. Effective heating is yet challenging due to its implementation complexity and a tricky balance of the heating performance. Here, we develop a lightweight compound self-heating system involving two external light aluminum heaters, which recycle the discharge energy contributing to external heating. Basic electrical and thermal modeling for the compound self-heating system is performed and experimentally validated. We adopt four key but conflicting heating metrics: heating time, heating efficiency, battery degradation, and temperature uniformity, to optimize the resistance of external heaters with the adaptive particle swarm optimization method. We thus propose a rapid compound self-heating strategy that can conveniently warm the battery up with 32.49 °C·min
−1. Experimental results under different states-of-charge and temperatures confirm the good adaptability of the proposed heating strategy. Comparison experiments with the unheated battery demonstrate the proposed heating strategy improves discharge power, charge power, and discharge energy by over 7.4 times, 19.0 times, and 109.9%, respectively. With the optimal external aluminum heaters, battery available discharge energy is enhanced by above 70.4%, implying a huge step forward to boost battery performance.
Lithium-ion batteries, Low temperature, Optimal external heating resistance, Rapid compound self-heating
Ruan, Haijun
70da465d-de16-4607-a4eb-4aaf6a87f34e
Sun, Bingxiang
f1643142-9a04-4776-b4d2-35c55d2fd311
Cruden, Andrew
ed709997-4402-49a7-9ad5-f4f3c62d29ab
Zhu, Tao
2333524f-f55e-4069-85b9-82d89277efc4
Jiang, Jiuchun
f8179175-250c-497f-9810-a2ccaf207547
He, Xitian
6c721531-8ab7-4549-b192-565657d40a02
Su, Xiaojia
6048b4e7-6f91-4d10-9e08-2d6a1af2f789
Ghoniem, Engy
f12f16a4-52e4-4f2f-a452-3cf3139cc3c2
Ruan, Haijun
70da465d-de16-4607-a4eb-4aaf6a87f34e
Sun, Bingxiang
f1643142-9a04-4776-b4d2-35c55d2fd311
Cruden, Andrew
ed709997-4402-49a7-9ad5-f4f3c62d29ab
Zhu, Tao
2333524f-f55e-4069-85b9-82d89277efc4
Jiang, Jiuchun
f8179175-250c-497f-9810-a2ccaf207547
He, Xitian
6c721531-8ab7-4549-b192-565657d40a02
Su, Xiaojia
6048b4e7-6f91-4d10-9e08-2d6a1af2f789
Ghoniem, Engy
f12f16a4-52e4-4f2f-a452-3cf3139cc3c2
Ruan, Haijun, Sun, Bingxiang, Cruden, Andrew, Zhu, Tao, Jiang, Jiuchun, He, Xitian, Su, Xiaojia and Ghoniem, Engy
(2021)
Optimal external heating resistance enabling rapid compound self-heating for lithium-ion batteries at low temperatures.
Applied Thermal Engineering, 200 (January), [117536].
(doi:10.1016/j.applthermaleng.2021.117536).
Abstract
Low-temperature preheating to achieve effective thermal management for lithium-ion batteries is a crucial enabler for the efficient and safe operation of electric vehicles in cold conditions. Effective heating is yet challenging due to its implementation complexity and a tricky balance of the heating performance. Here, we develop a lightweight compound self-heating system involving two external light aluminum heaters, which recycle the discharge energy contributing to external heating. Basic electrical and thermal modeling for the compound self-heating system is performed and experimentally validated. We adopt four key but conflicting heating metrics: heating time, heating efficiency, battery degradation, and temperature uniformity, to optimize the resistance of external heaters with the adaptive particle swarm optimization method. We thus propose a rapid compound self-heating strategy that can conveniently warm the battery up with 32.49 °C·min
−1. Experimental results under different states-of-charge and temperatures confirm the good adaptability of the proposed heating strategy. Comparison experiments with the unheated battery demonstrate the proposed heating strategy improves discharge power, charge power, and discharge energy by over 7.4 times, 19.0 times, and 109.9%, respectively. With the optimal external aluminum heaters, battery available discharge energy is enhanced by above 70.4%, implying a huge step forward to boost battery performance.
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Accepted/In Press date: 1 September 2021
e-pub ahead of print date: 20 September 2021
Additional Information:
Funding Information:
This work is supported by the National Natural Science Foundation of China under Grant 51907005 and 52177206, and in part by the JUICE project under UK EPSRC Grant EP/P003605/1.
Publisher Copyright:
© 2021
Keywords:
Lithium-ion batteries, Low temperature, Optimal external heating resistance, Rapid compound self-heating
Identifiers
Local EPrints ID: 468027
URI: http://eprints.soton.ac.uk/id/eprint/468027
ISSN: 1359-4311
PURE UUID: c2283ac6-3c03-4404-97c1-3a2563e07b08
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Date deposited: 28 Jul 2022 16:34
Last modified: 17 Mar 2024 03:29
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Contributors
Author:
Haijun Ruan
Author:
Bingxiang Sun
Author:
Jiuchun Jiang
Author:
Xitian He
Author:
Xiaojia Su
Author:
Engy Ghoniem
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