Research on thermal safety of soft-pack LiFePO4 battery after high-voltage float charge

doi:10.19799/j.cnki.2095-4239.2022.0088

Abstract

Abstract:

LiFePO₄ batteries are widely used in the field of energy storage because of their safety. The test object was a soft-pack LiFePO₄ LFP battery with a rated capacity of 21 Ah that was float-charged at high voltages of 4.05 V, 4.25 V, 4.50 V, and 5.0 V for 24 h at 25 ℃. The high-temperature thermal runaway and battery material thermal stability were investigated. The results show that bulging occurs at voltages of 4.25 V, 4.50 V, and 5.0 V, and the bulging increases as the voltage increases. At the 5.0 V battery rupture, the anode active material was dissolved, the copper current collector was exposed, and a substantial amount of lithium was deposited simultaneously. In the high-temperature thermal runaway test after float charging at 4.05 V, 4.25 V, and 4.50 V, the battery's rupture temperature decreased as the voltage increased. The thermal runaway-triggering temperature increased from 249.86 ℃ to 278.65 ℃, and the early rupture-released energy raised the thermal runaway trigger temperature; however, the system was unsafe. The maximum temperature of the thermal runaway increased from 484.67 ℃ to 516.08 ℃, the maximum temperature rise rate also increased significantly, and the time of thermal runaway to the maximum temperature decreased. The battery's thermal stability deteriorated after high-voltage float-charging, and the thermal runaway became more severe. The separator begins to undergo a phase transition at 120.63 ℃ and begins to decompose at 367.06 ℃. However, the positive and negative electrodes did not decompose and had good thermal stability. Therefore, the float voltage must be precisely controlled to make the battery safe and stable to use.

Key words: LiFePO₄ battery, high voltage float charge, thermal runaway, material thermal stability, safety

CLC Number:

TM 911.3

Tao YIN, Longzhou JIA, Xiuliang CHANG, Zuoqiang DAI, Lili ZHENG. Research on thermal safety of soft-pack LiFePO₄ battery after high-voltage float charge[J]. Energy Storage Science and Technology, 2022, 11(8): 2546-2555.

Figures/Tables 17

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参数	规格
正极	磷酸铁锂
负极	石墨
容量	0.2 C充0.5 C放/21 Ah
充电倍率	持续≤0.5 C
放电倍率	持续≤1 C、瞬间≤3 C
尺寸	12.5 mm×90 mm×200 mm
极耳	正极铝转镍、负极镍
内阻	≤5 mΩ
工作电压	2.5～3.65 V

序号	参数	数值
1	初始温度	35 ℃
2	初始标定时长	120 min
3	截止温度	250 ℃
4	温升步长	5 ℃
5	等待时间	15 min
6	搜索时间	5 min

特征参数	新电池	4.05 V	4.25 V	4.50 V	5.0 V
Q/Ah	21.363	21.380	21.317	21.336	20.990
T/℃	125.24	132.76	131.41	125.56	—
t₁/s	36354	24697	27436	34025	—
T_d/℃	138.46	144.46	149.82	152.73	—
t₂/s	37560	25263	28480	35483	—
T_s/℃	284.36	249.86	275.68	278.65	—
t₃/s	38312	25686	28986	36196	—
t₃-t₂/s	752	423	506	713	—
t₃-t₁/s	1958	989	1550	2171	—
T_m/℃	562.08	484.67	520.55	516.08	—
dT/dt max/(℃/min)	392.97	298.67	305.35	315.08	—
热失控前后质量变化/g	421.30/341.46	427.06/341.18	421.65/336.94	421.31/334.25	422.57/396.63
减重比/%	18.95	20.11	20.85	20.6	6.14

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Research on thermal safety of soft-pack LiFePO₄ battery after high-voltage float charge

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