Thermo-electrochemical simulation of the cooling process in a compact battery pack considering various configurations

Thermo-electrochemical simulation of the cooling process in a compact battery pack considering various configurations

Lithium-ion battery (LIB) packs with high power density are necessary in battery-powered system development. In this study, we investigated LIB packs made of compact cylindrical Li-ion batteries. We arranged the batteries in various patterns, including square, lozenge, elliptical, and circular, with...

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Bibliographic Details
Published in:Journal of power sources Vol. 553. P. 232112 (1-20)
Other Authors: Pordanjani, Ahmad Hajatzadeh, Aghakhani, Saeed, Afrand, Masoud, Zhang, Ping, Tang, Rongjiang, Mahian, Omid, Wongwises, Somchai, Rashidi, Mohammad Mehdi
Format: Article
Language:English
Subjects:
литий-ионные аккумуляторы
конфигурации батарей
управление температурным режимом
входное поперечное сечение
статьи в журналах
Online Access:http://vital.lib.tsu.ru/vital/access/manager/Repository/koha:001009804
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245 1 0 |a Thermo-electrochemical simulation of the cooling process in a compact battery pack considering various configurations  |c A. H. Pordanjani, S. Aghakhani, M. Afrand [et al.] 
336 |a Текст 
337 |a электронный 
504 |a Библиогр.: 57 назв. 
520 3 |a Lithium-ion battery (LIB) packs with high power density are necessary in battery-powered system development. In this study, we investigated LIB packs made of compact cylindrical Li-ion batteries. We arranged the batteries in various patterns, including square, lozenge, elliptical, and circular, with all patterns occupying the same total area. We solved the thermal and electrochemical equations governing the batteries using the finite-element method (FEM), and we coupled the airflow around the batteries, meant to lower their temperature, with the LIB equations and solved them using the same method. The results reveal that LIB cooling enhancement and a smaller temperature gradient occur with an increase in the LIB distribution at the center, reducing their outward dissemination and shortening the LIB length. Additionally, increasing the cross-sectional area and airflow velocity enhanced heat transfer from the batteries and decreased their temperature. Finally, we demonstrated that better cooling enhances the cells’ long-term performance. With a circular configuration, the pressure drop and heat transfer rise by 48.01% and 85.14%, respectively, with an increase in the inlet cross-section area. Furthermore, the pressure drop and heat transfer in this configuration increased by 89.09% and 66.90%, respectively, when the velocity increases. 
653 |a литий-ионные аккумуляторы 
653 |a конфигурации батарей 
653 |a управление температурным режимом 
653 |a входное поперечное сечение 
655 4 |a статьи в журналах 
700 1 |a Pordanjani, Ahmad Hajatzadeh 
700 1 |a Aghakhani, Saeed 
700 1 |a Afrand, Masoud 
700 1 |a Zhang, Ping 
700 1 |a Tang, Rongjiang 
700 1 |a Mahian, Omid 
700 1 |a Wongwises, Somchai 
700 1 |a Rashidi, Mohammad Mehdi 
773 0 |t Journal of power sources  |d 2023  |g Vol. 553. P. 232112 (1-20)  |x 0378-7753 
852 4 |a RU-ToGU 
856 4 |u http://vital.lib.tsu.ru/vital/access/manager/Repository/koha:001009804 
908 |a статья 
999 |c 1009804  |d 1009804 

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