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Experimental and numerical studies on lithium-ion battery heat generation behaviors

Chongtian Wu, Linxu Wu, Chenghui Qiu, Jiaming Yang, Xiaolu Yuan, Yufei Cai, Hong Shi

2023Energy Reports33 citationsDOIOpen Access PDF

Abstract

Current predictions of battery HGR (heat generation rate) mainly rely on Bernardi’s empirical equations, which suffer from limitations of adaptability for thermal use. A novel scheme based on experiments and BPNN (BP (back propagation) neural network is a multilayer feedforward neural network trained according to the error back propagation algorithm) is proposed in this paper. In the experiments, the thermal generation behavior of 18650 batteries under 108 different operating conditions was investigated, and the Ta (ambient temperature) as well as ID (discharge current) were extracted as inputs to the BPNN model. The experimental results show that the heat generation performance of the battery is strongly influenced by Ta and ID. The higher Ta and ID, the more obvious this effect is. The maximum error of the battery HGR obtained by using Bernardi’s empirical equations can reach 45.2 %. The predicted battery HGR using BPNN has good accuracy with error control within 5%. Accordingly, this paper provides the technical basis for proposing a promising thermal management solution.

Topics & Concepts

Battery (electricity)Heat generationArtificial neural networkBackpropagationLithium-ion batteryFeed forwardAdaptabilityThermalFeedforward neural networkComputer scienceCurrent (fluid)Lithium (medication)Materials scienceControl theory (sociology)Nuclear engineeringBiological systemEngineeringControl (management)ThermodynamicsElectrical engineeringControl engineeringArtificial intelligencePower (physics)PhysicsEndocrinologyBiologyMedicineEcologyAdvanced Battery Technologies ResearchElectric and Hybrid Vehicle TechnologiesAdvancements in Battery Materials