Title :
Model-Based Virtual Thermal Sensors for Lithium-Ion Battery in EV Applications
Author_Institution :
Renewable Energy & Vehicular Technol. (REVT) Lab., Univ. of Texas at Dallas, Richardson, TX, USA
Abstract :
Continuous monitoring of temperature distribution in lithium-ion (Li-ion) batteries is critical in preventing rapid degradation, mismatch in cell capacity, and potentially thermal runaway. A model based on virtual thermal sensor (VTS) for automotive grade Li-ion batteries is presented in this paper. This model, using a small number of physical sensors, is able to estimate temperature distribution throughout the battery in real time. First, the thermal model of the battery is developed and the characteristic parameters of the battery are tuned using the prediction error minimization method. Then, the tuned model is combined with a Kalman filter to estimate the temperature distribution of the battery under unknown initial values and model uncertainty. The proposed model-based VTS has been experimentally validated on an automotive grade 70-Ah lithium iron phosphate (LiFePO4) battery.
Keywords :
Kalman filters; battery powered vehicles; error analysis; iron compounds; lithium compounds; phosphorus compounds; secondary cells; temperature distribution; temperature sensors; thermal analysis; EV applications; Kalman filters; LiFePO4; VTS; automotive grade lithium-ion batteries; cell capacity mismatch; characteristic parameters; continuous monitoring; degradation prevention; electric vehicles; model uncertainty; model-based virtual thermal sensors; physical sensors; potentially thermal runaway; prediction error minimization method; temperature distribution estimation; Batteries; Heat transfer; Heating; Temperature distribution; Temperature measurement; Temperature sensors; Energy storage system; Thermal modeling; energy storage system; lithium-ion battery; temperature distribution; thermal modeling;
Journal_Title :
Industrial Electronics, IEEE Transactions on
DOI :
10.1109/TIE.2014.2386793
