A novel order-reduced thermal-coupling electrochemical model for lithium-ion batteries

doi:10.1088/1674-1056/ad1f52

中国物理B ›› 2024, Vol. 33 ›› Issue (5): 58203-058203.doi: 10.1088/1674-1056/ad1f52

A novel order-reduced thermal-coupling electrochemical model for lithium-ion batteries

Yizhan Xie(谢奕展)^1,2,3,†, Shuhui Wang(王舒慧)^1,2,†, Zhenpo Wang(王震坡)^1,2, and Ximing Cheng(程夕明)^1,2,‡

1 School of Mechanical Engineering, Beijing Institute of Technology, Beijing 100081, China;
2 National Engineering Research Center for Electric Vehicles, Beijing Institute of Technology, Beijing 100081, China;
3 The Hong Kong University of Science and Technology (Guangzhou), Sustainable Energy and Environment Thrust and Guangzhou Municipal, Key Laboratory of Materials Informatics, Guangzhou 511400, China

收稿日期:2023-11-11 修回日期:2024-01-16 接受日期:2024-01-17 出版日期:2024-05-20 发布日期:2024-05-20
通讯作者: Shuhui Wang E-mail:ximingcheng@163.com
基金资助:
The authors appreciate the financial support from the National Key Research and Development Program of China (Grant No. 2021YFF0601101).

A novel order-reduced thermal-coupling electrochemical model for lithium-ion batteries

Yizhan Xie(谢奕展)^1,2,3,†, Shuhui Wang(王舒慧)^1,2,†, Zhenpo Wang(王震坡)^1,2, and Ximing Cheng(程夕明)^1,2,‡

1 School of Mechanical Engineering, Beijing Institute of Technology, Beijing 100081, China;
2 National Engineering Research Center for Electric Vehicles, Beijing Institute of Technology, Beijing 100081, China;
3 The Hong Kong University of Science and Technology (Guangzhou), Sustainable Energy and Environment Thrust and Guangzhou Municipal, Key Laboratory of Materials Informatics, Guangzhou 511400, China

Received:2023-11-11 Revised:2024-01-16 Accepted:2024-01-17 Online:2024-05-20 Published:2024-05-20
Contact: Shuhui Wang E-mail:ximingcheng@163.com
Supported by:
The authors appreciate the financial support from the National Key Research and Development Program of China (Grant No. 2021YFF0601101).

摘要/Abstract

摘要： Although the single-particle model enhanced with electrolyte dynamics (SPMe) is simplified from the pseudo-two-dimensional (P2D) electrochemical model for lithium-ion batteries, it is difficult to solve the partial differential equations of solid-liquid phases in real-time applications. Moreover, working temperatures have a heavy impact on the battery behavior. Hence, a thermal-coupling SPMe is constructed. Herein, a lumped thermal model is established to estimate battery temperatures. The order of the SPMe model is reduced by using both transfer functions and truncation techniques and merged with Arrhenius equations for thermal effects. The polarization voltage drop is then modified through the use of test data because its original model is unreliable theoretically. Finally, the coupling-model parameters are extracted using genetic algorithms. Experimental results demonstrate that the proposed model produces average errors of about 42 mV under 15 constant current conditions and 15 mV under nine dynamic conditions, respectively. This new electrochemical-thermal coupling model is reliable and expected to be used for onboard applications.

关键词: lithium-ion batteries, order-reduced electrochemical models, SPMe, thermal-coupling model, transient polarization voltage drop

Abstract: Although the single-particle model enhanced with electrolyte dynamics (SPMe) is simplified from the pseudo-two-dimensional (P2D) electrochemical model for lithium-ion batteries, it is difficult to solve the partial differential equations of solid-liquid phases in real-time applications. Moreover, working temperatures have a heavy impact on the battery behavior. Hence, a thermal-coupling SPMe is constructed. Herein, a lumped thermal model is established to estimate battery temperatures. The order of the SPMe model is reduced by using both transfer functions and truncation techniques and merged with Arrhenius equations for thermal effects. The polarization voltage drop is then modified through the use of test data because its original model is unreliable theoretically. Finally, the coupling-model parameters are extracted using genetic algorithms. Experimental results demonstrate that the proposed model produces average errors of about 42 mV under 15 constant current conditions and 15 mV under nine dynamic conditions, respectively. This new electrochemical-thermal coupling model is reliable and expected to be used for onboard applications.

Key words: lithium-ion batteries, order-reduced electrochemical models, SPMe, thermal-coupling model, transient polarization voltage drop

中图分类号: (Electrochemical engineering)

82.47.Wx

Yizhan Xie(谢奕展), Shuhui Wang(王舒慧), Zhenpo Wang(王震坡), and Ximing Cheng(程夕明). A novel order-reduced thermal-coupling electrochemical model for lithium-ion batteries[J]. 中国物理B, 2024, 33(5): 58203-058203.

Yizhan Xie(谢奕展), Shuhui Wang(王舒慧), Zhenpo Wang(王震坡), and Ximing Cheng(程夕明). A novel order-reduced thermal-coupling electrochemical model for lithium-ion batteries[J]. Chin. Phys. B, 2024, 33(5): 58203-058203.

参考文献

[1] Subramanian V R, Boovaragavan V and Diwakar V D 2007 Electrochemical and Solid-State Letters 10 A225
[2] Mehta R and Gupta A 2021 Electrochimica Acta 389 138623
[3] Li J, Lotf N, Landers R G and Park J 2017 Journal of the Electrochemical Society 164 A874
[4] Marcicki J, Canova M, Conlisk A T and Rizzoni G 2013 Journal of Power Sources 237 310
[5] Luo W, Lyu C, Wang L and Zhang L 2013 Journal of Power Sources 241 295
[6] Li C, Cui N, Wang C and Zhang C 2021 Journal of Power Sources 497 229900
[7] Atlung S, West K and Jacobsen T 1979 Journal of the Electrochemical Society 126 1311
[8] Wang Y, Zhang X, Liu K, Wei Z, Hu X, Tang X and Chen Z 2023 Etransportation 18 100295
[9] Khaleghi R S, Rayman S and White R E 2013 Journal of Power Sources 224 180
[10] Subramanian V R, Diwakar V D and Tapriyal D 2005 Journal of the Electrochemical Society 152 A2002
[11] Yuan S, Jiang L, Yin C, Wu H and Zhang X 2017 Journal of Power Sources 352 245
[12] Lai Q, Jangra S, Ahn H J, Kim G, Joe W T and Lin X 2020 Journal of Power Sources 472 228338
[13] Forman J C, Bashash S, Stein J and Fathy H 2010 Proceedings of the ASME Dynamic Systems and Control Conference 2 178
[14] Smith K A, Rahn C D and Wang C 2008 Journal of Dynamic Systems Measurement and Control-Transactions of the ASME 130 011012
[15] Smith K A, Rahn C D and Wang C 2007 Energy Coversion and Management 48 2565
[16] Basdevant J L 1972 Fortschritte Der Physik 20 283
[17] Ma S, Jiang M, Tao P, Song C, Wu J, Wang J, Deng T and Shang W 2018 Progess in Natural Science-Materials International 28 653
[18] Liu H, Wei Z, He W and Zhao J 2017 Energy Conversion and Management 150 304
[19] Chen Y, Kang Y, Zhao Y, Wang L, Liu J, Li Y, Liang Z, He X, Li X, Tavajohi N and Li B 2021 Journal of Energy Chemistry 59 83
[20] Chen Y and Evans J W 1994 Electrochimica Acta 39 517
[21] Wang Q, Shen J, Ma Z and He Y 2021 Chemical Engineering Journal 424 130308
[22] Bahiraei F, Ghalkhani M, Fartaj A and Nazri G A 2017 Applied Thermal Engineering 125 904
[23] Xu M, Zhang Z, Wang X, Jia L and Yang L 2015 Energy 80 303
[24] Wang C Y and Srinivasan V 2002 Journal of Power Sources 110 364
[25] Zhao R, Gu J and Liu J 2018 International Journal of Energy Research 42 2728
[26] Liu F, Lan F and Chen J 2016 Journal of Mechanical Engineering 52 141
[27] Wang Q, He Y, Shen J, Ma Z and Zhong G 2017 Energy 138 118
[28] Panchal S, Dincer I, Agelin-Chaab M, Fraser R and Fowler M 2016 Applied Thermal Engineering 96 190
[29] Dai H, Zhu L, Zhu J, Wei X and Sun Z 2015 Journal of Power Sources 293 351
[30] Cheng X, Tang Y and Wang Z 2021 Journal of the RMAL Science 30 477
[31] Xiong R and Li X 2020 Journal of Mechanical Engineering 56 146
[32] Kuang K, Sun Y, Ren D, Han X, Zheng Y and Geng Z 2021 Journal of Mechanical Engineering 57 10
[33] Allafi W, Zhang C, Uddin K, Worwood D, Truong Quang D, Ormeno P A, Li K and Marco J 2018 Applied Thermal Engineering 143 472
[34] Ma Y, Mou H and Zhao H 2020 Energy 201 117678
[35] Feng X, He X, Ouyang M, Lu L, Wu P, Kulp C and Prasser S 2015 Applied Energy 154 74
[36] Ngoc T T, Farrell T, Vilathgamuwa M, Choi S S and Li Y 2019 Journal of the Electrochemical Society 166 A3059
[37] Prada E, Di Domenico D, Creff Y, Bernard J, Sauvant-Moynot V and Huet F 2012 Journal of the Electrochemical Society 159 A1508
[38] Jaguemont J, Boulon L and Dube Y 2016 Applied Energy 164 99
[39] Bernardi D, Pawlikowski E and Newman J 1985 Journal of the Electrochemical Society 132 5
[40] Doyle M, Fuller T F and Newman J 2018 Journal of the Electrochemical Society 165 X13
[41] Santhanagopalan S, Guo Q, Ramadass P and White R E 2006 Journal of Power Sources 156 620
[42] Santhanagopalan S and White R E 2006 Journal of Power Sources 161 1346
[43] Moura S J, Argomedo F B, Klein R, Mirtabatabaei A and Krstic M 2017 IEEE Transcations on Control Systems Technology 25 453
[44] Xie Y and Cheng X 2021 Electrochimica Acta 399 139391
[45] Xie Y and Cheng X 2022 Journal of the Electrochemical Society 169 063516
[46] Hekmat S and Molaeimanesh G R 2020 Applied Thermal Engineering 166 114759
[47] Ping P, Zhang Y, Kong D and Du J 2021 Journal of Energy Storage 36 102448
[48] Jouhara H, Serey N, Khordehgah N, Bennett R, Almahmoud S and Lester S P 2020 International Journal of Thermofluids 1-2 100004
[49] Baba N, Yoshida H, Nagaoka M, Okuda C and Kawauchi S 2014 Journal of Power Sources 252 214
[50] Tanim T R, Rahn C D and Wang C 2015 Energy 80 731
[51] Cai L and White R E 2009 Journal of the Electrochemical Society 156 A154
[52] Rodriguez A, Plett G L and Trimboli M S 2019 Etransportation 1 100009
[53] Xu S, Wang Y, Shao J, Li J and Yu Q 2022 Applied Thermal Engineering 217 119282

A novel order-reduced thermal-coupling electrochemical model for lithium-ion batteries

A novel order-reduced thermal-coupling electrochemical model for lithium-ion batteries

RichHTML

PDF (PC)

赞

可视化

摘要/Abstract

引用本文

使用本文

参考文献

相关文章 12

Metrics

本文评价

推荐阅读 0

[1]	Tongtong Shang(尚彤彤), Dongdong Xiao(肖东东), Qinghua Zhang(张庆华), Xuefeng Wang(王雪锋), Dong Su(苏东), and Lin Gu(谷林). Electron density distribution of LiMn₂O₄ cathode investigated by synchrotron powder x-ray diffraction[J]. 中国物理B, 2021, 30(7): 78202-078202.
[2]	Fangrong Hu(胡放荣), Mingyang Zhang(张铭扬), Wenbin Qi(起文斌), Jieyun Zheng(郑杰允), Yue Sun(孙悦), Jianyu Kang(康剑宇), Hailong Yu(俞海龙), Qiyu Wang(王其钰), Shijuan Chen(陈世娟), Xinhua Sun(孙新华), Baogang Quan(全保刚), Junjie Li(李俊杰), Changzhi Gu(顾长志), and Hong Li(李泓). Silicon micropillar electrodes of lithiumion batteries used for characterizing electrolyte additives[J]. 中国物理B, 2021, 30(6): 68202-068202.
[3]	闫昭, 潘弘毅, 汪君洋, 陈汝颂, 罗飞, 禹习谦, 李泓. Suppressing transition metal dissolution and deposition in lithium-ion batteries using oxide solid electrolyte coated polymer separator[J]. 中国物理B, 2020, 29(8): 88201-088201.
[4]	王乾坤, 沈佳妮, 贺益君, 马紫峰. Design and management of lithium-ion batteries: A perspective from modeling, simulation, and optimization[J]. 中国物理B, 2020, 29(6): 68201-068201.
[5]	王怡, 刘柏男, 周格, 聂凯会, 张杰男, 禹习谦, 李泓. Improved electrochemical performance of Li(Ni_0.6Co_0.2Mn_0.2)O₂ at high charging cut-off voltage with Li_1.4Al_0.4Ti_1.6(PO₄)₃ surface coating[J]. 中国物理B, 2019, 28(6): 68202-068202.
[6]	张杰男, 李庆浩, 李泉, 禹习谦, 李泓. Improved electrochemical performances of high voltage LiCoO₂ with tungsten doping[J]. 中国物理B, 2018, 27(8): 88202-088202.
[7]	仝毓昕, 张庆华, 谷林. Scanning transmission electron microscopy: A review of high angle annular dark field and annular bright field imaging and applications in lithium-ion batteries[J]. 中国物理B, 2018, 27(6): 66107-066107.
[8]	孙维毅, 闵海涛, 郭冬妮, 于远彬. Modeling of LiFePO4 battery open circuit voltage hysteresis based on recursive discrete Preisach model[J]. 中国物理B, 2017, 26(12): 127503-127503.
[9]	Ting Zhu. Mechanics of high-capacity electrodes in lithium-ion batteries[J]. 中国物理B, 2016, 25(1): 14601-014601.
[10]	索鎏敏, 方铮, 胡勇胜, 陈立泉. FT-Raman spectroscopy study of solvent-in-salt electrolytes[J]. 中国物理B, 2016, 25(1): 16101-016101.
[11]	高健, 赵予生, 施思齐, 李泓. Lithium-ion transport in inorganic solid state electrolyte[J]. 中国物理B, 2016, 25(1): 18211-018211.
[12]	陈颖超, 谢凯, 盘毅, 郑春满, 王华林. High power nano-LiMn₂O₄ cathode materials with high-rate pulse discharge capability for lithium-ion batteries[J]. 中国物理B, 2011, 20(2): 28201-028201.