The <mml:math xmlns:mml="http://www.w3.org/1998/Math/MathML" altimg="si69.svg" display="inline" id="d1e1600"><mml:mrow><mml:mi>Δ</mml:mi><mml:mi>Q</mml:mi></mml:mrow></mml:math>-method: State of health and degradation mode estimation for lithium-ion batteries using a mechanistic model with relaxed voltage points
Tobias Hofmann, Jiahao Li, Jacob Hamar, Simon V. Erhard, Jan Philipp Schmidt
Abstract
Lithium-ion batteries exhibit path-dependent aging behavior. dm! (dm!) estimation is a first step towards accurate soh! (soh!) representations by clustering degradation mechanisms. Mechanistic models shift and scale pristine half-cell ocp! (ocp!) curves of both electrodes to reconstruct the ocv! (ocv!) curve by minimizing the difference between measured and reconstructed ocv!. Alignment parameters describe the shift and scaling of the ocp!s and can be used to estimate soh! and dm!s. This study introduces the ΔQ-method, which relies on relaxed voltage points and accumulated charge between these points. It is independent of current rates and applicable after almost every event. The optimization problem minimizes deviation between measured and reconstructed ΔQ. The method is developed with an automotive cell dataset and validated with real-world vehicle data from the BMW i3. The ΔQ-method achieves a mean absolute soh! estimation error of 2.52 % and a mean absolute ocv! reconstruction error of 7.19 mV. Reliable estimations are ensured by predefined filters. The method remains effective with restricted soc! (soc!) windows or limited data points. It is robust against variations in input data, solver choice, and optimization settings. Convergence is improved by constraining the solution space.