In order to fully obtain the working performance of the battery, each test needs to be tested separately at multiple different temperatures and different aging conditions to realize the full-life efficient management of the full-climate battery.

Data completion time: cell: 2018-11-31, module: 2015-11-30

1.Basic battery parameters

2.Test process

Cell: Arbin BT-2000 5V-100A. Characteristic tests are performed every 100 cycles. The test process is shown in the figure below.

Figure 1 Test process of the cell

3.Introduction to the data set

Cell: 1500 cycles. Tests of CAP/HPPC/OCV/working condition are performed every 100 cycles in three temperatures (10°C, 25°C and 45°C).

4.Related papers

[1] J. Tian, R. Xiong*, W. Shen and W. Ju, “A Comparative Study of Fractional Order Models on State of Charge Estimation for Lithium-ion Batteries”, Chinese Journal of Mechanical Engineering, vol. 33, pp. 51, Jul 2020. （Download）

[2] R. Xiong*, JP Tian, H Mu*, C. Wang, “A systematic model-based degradation behavior recognition and health monitor method of lithium-ion batteries”, Applied Energy, vol. 207, pp. 367-378, Dec 2017.（Download）

[3] J. Tian, R. Xiong* and Q. Yu, “Fractional order model based incremental capacity analysis for degradation state recognition of lithium-ion batteries”, IEEE Transactions on Industrial Electronics, vol. 66, no.2, pp. 1576 - 1584, Feb 2019.（Download）

[4] R. Xiong*, J.Tian, W. Shen and F. Sun, “A novel fractional order model for state of charge estimation in lithium ion batteries”, IEEE Transactions on Vehicular Technology, vol. 68, no.5, pp.4130-4139, May 2019.（Download）

[5] R. Yang, R. Xiong*, H He, H. Mu, C. Wang, “A novel method on estimating the degradation and state of charge of lithium-ion batteries used for electrical vehicles”, Applied Energy, vol. 207, pp. 331-340, Dec 2017.（Download）