Caihao Weng scite author profile

Early detection of an internal short circuit (ISC) in lithium ion batteries has become a crucial task for battery management, as ISC is believed to be the root cause of several large format lithium ion battery fire accidents. In this paper, a scheme of on-line detection of ISC is proposed, and the online ISC detection problem is addressed from a model parameterization and parameter estimation perspective. Using a 3D electrochemical-thermal-ISC coupled model, we explore the correlation between the measured voltage, current, and temperature data and the ISC status. It is identified that the abnormal depletion in the state-of-charge (SOC) and excessive heat generation associated with ISC affect the voltage and temperature responses, and that the correlation can be captured by a properly parameterized phenomenological model. The ISC detection is then recast as a parameter estimation problem, for which a model-based estimation algorithm is proposed and evaluated. It is shown that the estimation algorithm can track the parameter variations in real-time, thereby making it feasible to track ISC incubation status or to detect instantaneously triggered ISC. Moreover, it is observed that the recorded temperature profile is not affected by the location where the ISC occurs, due to the oval shape of the temperature distribution caused by anisotropic heat conduction of the battery core. Therefore, the proposed algorithm can detect the ISC, regardless of its physical location within the battery.

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State-of-health monitoring of lithium-ion battery modules and packs via incremental capacity peak tracking

Weng¹,

Feng²,

Sun³

et al. 2016

Applied Energy

266

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Incremental capacity analysis (ICA) is a widely used technique for lithium-ion battery state-of-health (SOH) evaluation. The effectiveness and robustness of ICA for single cell diagnostics have been reported in many published work. In this study, we extend the ICA based SOH monitoring approach from single cells to battery modules, which consist of battery cells with various aging conditions. In order to achieve on-board implementation, an IC peak tracking approach based on the ICA principles is proposed. Analytical, numerical and experimental results are presented to demonstrate the utility of the IC peak tracking framework on multi-cell battery SOH monitoring and the effects of cell non-uniformity on the proposed method. Results show that the methods developed for single cell capacity estimation can also be used for a module or pack that has parallel-connected cells.

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Online State-of-Health Estimation for Li-Ion Battery Using Partial Charging Segment Based on Support Vector Machine

Feng

Weng

et al. 2019

IEEE Trans. Veh. Technol.

344

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Caihao Weng

On-board state of health monitoring of lithium-ion batteries using incremental capacity analysis with support vector regression

A unified open-circuit-voltage model of lithium-ion batteries for state-of-charge estimation and state-of-health monitoring

Online internal short circuit detection for a large format lithium ion battery

State-of-health monitoring of lithium-ion battery modules and packs via incremental capacity peak tracking

Online State-of-Health Estimation for Li-Ion Battery Using Partial Charging Segment Based on Support Vector Machine

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