Title :
State-space based multi-nodes thermal model for Lithium-ion battery
Author :
Ying Xiao ; Fahimi, Babak
Author_Institution :
Renewable Energy & Vehicular Technol. Lab., Univ. of Texas at Dallas, Dallas, TX, USA
Abstract :
Continuous monitoring of temperature distribution for Lithium-ion (Li-ion) batteries is critical to prevent them from rapid degradation, mismatch in cell capacity, and potentially thermal runaway. Existing techniques for estimating temperature profile of batteries are either computationally inefficient or costly; the concept of state-space based multi-nodes thermal model is introduced in this paper to estimate both the surface and core temperatures of batteries. The effectiveness of the proposed model has been validated through experimental results from a 70Ah Lithium iron Phosphate (LiFePO4) battery.
Keywords :
heat transfer; secondary cells; state-space methods; temperature distribution; cell capacity mismatch; continuous temperature distribution monitoring; core temperature estimation; heat transfer; lithium iron phosphate battery; lithium-ion battery; potential thermal runaway; prediction error minimization; rapid degradation prevention; state-space based multinode thermal model; surface temperature estimation; temperature profile estimation; Batteries; Heat transfer; Heating; Mathematical model; Temperature distribution; Temperature measurement; Temperature sensors; heat transfer; lithium-ion battery; model-based temperature estimation; prediction error minimization;
Conference_Titel :
Transportation Electrification Conference and Expo (ITEC), 2014 IEEE
Conference_Location :
Dearborn, MI
DOI :
10.1109/ITEC.2014.6861846
