A pseudo three-dimensional electrochemical-thermal model of a cylindrical LiFePO4/graphite battery

Chiew, J; Chin, Cheng Siong; Toh, WD; Gao, ZC; Jia, JB; Cz, Zhang

doi:10.1016/j.applthermaleng.2018.10.108

Cited by 84 publications

(24 citation statements)

References 46 publications

(69 reference statements)

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“…The chemical reactions involved in lithium‐ion are very complicated, so it is difficult to take all these reactions and parameters into consideration. Therefore, the chemical reactions are simplified, and the assumptions are from Doyle et al, Chiewa et al, and Tang et al…”

Section: Establishment and Verification Of Modelmentioning

confidence: 99%

Study on electrochemical and thermal characteristics of lithium-ion battery using the electrochemical-thermal coupled model

et al. 2019

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Summary The higher specific energy leads to more heat generation of a battery, which affects the performance and cycle life of a battery and even results in some security problems. In this paper, the capacity calibration, Hybrid Pulse Power Characteristic (HPPC), constant current (dis)charging, and entropy heat coefficient tests of chosen 11‐Ah lithium‐ion batteries are carried out. The entropy heat coefficient increases firstly and then decreases with the increase of the depth of discharge (DOD) and reaches the maximum value near 50% DOD. An electrochemical‐thermal coupled model of the chosen battery is established and then verified by the tests. The simulation voltage and temperature trends are in agreement with the test results. The maximum voltage and temperature error is within 2.06% and 0.4°C, respectively. Based on the established model, the effects of adjustable parameters on electrochemical characteristic are systematically studied. Results show that the average current density, the thickness of the positive electrode, the initial and maximum lithium concentration of the positive electrode, and the radius of the positive electrode particle have great influence on battery capacity and voltage. In addition, the influence degree of the internal resistance of the solid electrolyte interface (SEI) layer, the thickness of negative electrode, and the initial and maximum lithium concentration of the negative electrode on the capacity and voltage is associated with certain constraints. Meanwhile, the influences of adjustable parameters related to thermal characteristic are also systematically analyzed. Results show that the average current density, the convective heat transfer coefficient, the thickness, and the maximum lithium concentration of the positive electrode have great influence on the temperature rise. Besides, the uniformity of the temperature distribution deteriorates with the increase of the convective heat transfer coefficient.

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Section: Establishment and Verification Of Modelmentioning

confidence: 99%

Study on electrochemical and thermal characteristics of lithium-ion battery using the electrochemical-thermal coupled model

et al. 2019

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“…The electrochemical-thermal coupled modeling is one of the viable options that can potentially predict the electrical and thermal characteristics of the battery accurately. In the literature, there are significant numbers of studies that employ the electrochemical-thermal coupled model for various types of cells including prismatic [1][2][3][4][5][6][7][8], pouch [9,10], and cylindrical cells with 14 mm [11], 18 mm [11,12], 26 mm [11,13,14] and 38 mm [15] diameters. The thermal model employs the solution of the general heat diffusion equation considering the convective and radiative heat transfers on the cell surface.…”

Section: Introductionmentioning

confidence: 99%

“…Table 1. Convective heat transfer coefficient values used in electrochemical-thermal coupled models in the literature h (Wm -2 K -1 ) References 0-5 [10], [13], [15][16][17] 5-10 [3-5], [12][13][14], [17] 10-50 [4][5][6], [11], [13] 50-150 [5], [6], [16] 150-350 [4] *Bold numbers are included in the given range.…”

Section: Introductionmentioning

confidence: 99%

Numerical and experimental investigation of the thermal and electrical characteristics of a lithium ion cell

2021

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In this study, an electrochemical-thermal coupled model was developed to investigate the electrical and thermal behaviors of the commercial NCR18650b Li-ion cell during three different discharge rates. The 1-dimensional electrochemical model consists of a positive electrode, electrolyte, and a negative electrode and employs the related mass and charge transfer equations for both solid and liquid phases predicting the cell's voltage variation. The 3-dimensional thermal model involves a mandrel, an active battery part, and a shell. The thermal model solves the general heat diffusion equation and predicts the temperature variation of the cell. The results show that the predicted temperature-voltage profiles follow the same trend with experimental data and are consistent. The maximum calculated root mean square errors are obtained as 0.11 V for voltage, and 0.96 °C for temperature predictions. On the other hand, the maximum temperature differences within the cell was found to be 0.16 °C, 0.43 °C, and 1.29 °C after the 0.5 C, 1C and 1.5 C rate discharging processes, respectively. Finally, the results from the 3-dimensional thermal model reveal that the type of mandrel affects the temperature variation within the cell. However, the average surface temperature of the cell remains comparable for the investigated C rates.

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“…There are more and more researchers focusing on the study of Li‐ion battery cells' thermal performance. Some of the previous studies combined thermal, electric, and chemical principles to predict battery cells' thermal performance . The majority of these researches are related to the model construction and thermal analysis of lithium‐ion cells, enhancement of heat conduction such as proposing novel coolants for huge heat generation or designing cooling structure for large heat generation .…”

Section: Introductionmentioning

confidence: 99%

“…Some of the previous studies combined thermal, electric, and chemical principles to predict battery cells' thermal performance. 8,[14][15][16][17] The majority of these researches are related to the model construction and thermal analysis of lithiumion cells, enhancement of heat conduction such as proposing novel coolants for huge heat generation or designing cooling structure for large heat generation. 18 Considering the medium of heat conduction, BTMs are generally classified as three types: air cooling, 19 liquid cooling, 20 and phase change materials (PCMs) 21 based cooling systems.…”

Section: Introductionmentioning

confidence: 99%

An experimental investigation of liquid cooling scheduling for a battery module

et al. 2020

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Summary The thermal safety of electric vehicle battery modules attracts public concern; controlling the severe temperature rise and ensuring uniform temperature distribution are essential to addressing this problem. In this research, a liquid cooling‐based cooling structure equipped with minichannels is proposed to prevent a battery module's overheating. A novel cooling scheduling study is proposed to arrange the coolant flow rates at different cooling stages. The temperature rise, temperature difference, and energy consumption of all the cooling schedules are measured in experiments. Experimental findings indicate that appropriate cooling scheduling achieves the thermal objectives and reduces energy consumption through scheduling the coolant flow rate in the cooling process. A comprehensive cooling schedule selection is carried out to select the optimal cooling schedule with the highest cooling efficiency through evaluating both the thermal and energy consumption objective parameters under different discharging current rates (0.5C, 1C, and 1.5C). The optimal cooling schedule maintains the maximum temperature of the battery module within 26°C, 32°C, and 40°C under 0.5C, 1C, and 1.5C discharging current rates, respectively. Moreover, the temperature SD and the energy consumption of the liquid cooling‐based battery pack can be controlled within 3.5°C and 40 J, respectively.

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A pseudo three-dimensional electrochemical-thermal model of a cylindrical LiFePO4/graphite battery

Cited by 84 publications

References 46 publications

Study on electrochemical and thermal characteristics of lithium-ion battery using the electrochemical-thermal coupled model

Study on electrochemical and thermal characteristics of lithium-ion battery using the electrochemical-thermal coupled model

Numerical and experimental investigation of the thermal and electrical characteristics of a lithium ion cell

An experimental investigation of liquid cooling scheduling for a battery module

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