Abstract
The nail penetration test has been widely adopted as a battery safety test for reproducing internal short-circuits. In this paper, the effects of cell initial State-of-Charge (SOC) and penetration location on variations in cell temperature and terminal voltage during penetration tests are investigated. Three different initial SOCs (10%, 50%, and 90%) and three different penetration locations (one is at the center of the cell, the other two are close to the edge of the cell) are used in the tests. Once the steel cone starts to penetrate the cell, the cell terminal voltage starts to drop due to the internal short-circuit. The penetration tests with higher initial cell SOCs have larger cell surface temperature increases during the tests. Also, the penetration location always has the highest temperature increment during all penetration tests, which means the heat source is always at the penetration location. The absolute temperature increment at the penetration location is always higher when the penetration is close to the edge of the cell, compared to when the penetration is at the center of the cell. The heat generated at the edges of the cell is more difficult to dissipate. Additionally, a battery cell internal short-circuit model with different penetration locations is built in ANSYS Fluent, based on the specifications and experimental data of the tested battery cells. The model is validated with an acceptable discrepancy range by using the experimental data. Simulated data shows that the temperature gradually reduces from penetration locations to their surroundings. The gradients of the temperature distributions are much larger closer to the penetration locations. Overall, this paper provides detailed information on the temperature and terminal voltage variations of a lithium-ion polymer battery cell with large capacity and high power under penetration tests. The presented information can be used for assessing the safety of the onboard battery pack of electric vehicles.
Highlights
Lithium-ion batteries have been widely used in many applications, ranging from consumer electronics such as cell phones and laptops, to transportation such as electric vehicles
This paper aims to present more realistic penetration test results for battery cells used in the plug-in hybrid electric vehicles (PHEVs) and electric vehicles (EVs)
Once the steel cone starts to penetrate the cell, the cell terminal voltage starts to drop due to the internal short-circuit
Summary
Lithium-ion batteries have been widely used in many applications, ranging from consumer electronics such as cell phones and laptops, to transportation such as electric vehicles. Featuring many advantages such as high specific energy, high energy density, low self-discharge rate, and minimal memory effect, lithium-ion batteries still have safety issues, such as catching fire or explosion [1,2]. To assess the risk of battery failure, abusive tests such as overcharging [3,4], external heating [5,6], dynamic impact [7,8], and short-circuiting are usually performed. Short-circuits can cause a temperature rise of several hundred degrees Celsius in a few seconds and even trigger thermal runaway [9]. External short-circuits can usually be well controlled by assembling fuses
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