Safety Aspects of Li-Ion Batteries

Julien, C.; Mauger, A.; Vijh, Ashok K.; Zaghib, Karim

doi:10.1007/978-3-319-19108-9_14

Cited by 3 publications

(3 citation statements)

References 67 publications

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“…The cells achieve maximum cycle life only in a narrow operating DoD range from 20% to 40% [6]. Likewise, the optimal operating temperature range for Li-Ion cells is ranging from 0 • C to 55 • C. Increasing the operating temperature of cells above 55 • C has a strongly negative influence on cells, causes a loss of cell capacity, shortens the lifespan, and reduces the total number of charge/discharge cycles [24][25][26]. In addition, a large number of cells used to increase the output voltage or capacity of the battery system reduces the reliability of the entire system since a damaged cell may either break an electrical circuit in a series connection or may cause an electrical short circuit in a parallel connection.…”

Section: Battery Management Systemsmentioning

confidence: 99%

Low Power Modular Battery Management System with a Wireless Communication Interface

Gozdur

Przerywacz

Bogdański³

2021

Energies

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The paper concerns the design and development of large electric energy storage systems made of lithium cells. Most research advances in the development of lithium-ion battery management systems focus solely on safety, functionality, and improvement of the procedures for assessing the performance of systems without considering their energy efficiency. The paper presents an alternative approach to the design and analysis of large modular battery management systems. A modular battery management system and the dedicated wireless communication system were designed to analyze and optimize energy consumption. The algorithms for assembly, reporting, management, and communication procedures described in the paper are a robust design tool for further developing large and scalable battery systems. The conducted analysis of energy efficiency for the exemplary 100S15P system shows that the energy used to power the developed battery management system is comparable to the energy dissipated due to the intrinsic self-discharge of lithium-ion cells.

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Section: Battery Management Systemsmentioning

confidence: 99%

Low Power Modular Battery Management System with a Wireless Communication Interface

Gozdur

Przerywacz

Bogdański³

2021

Energies

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“…In recent years, electric vehicles (EVs) have gradually become the main force in the automobile market due to the introduction of emission regulations of traditional fuel vehicles. The safety of the Li-ion battery under abusive conditions is still a technical barrier for electric vehicles [1,2]. Dendrite growth and overcharging can lead to particularly catastrophic thermal failure due to high rates of heat generation [3].…”

Section: Introductionmentioning

confidence: 99%

“…By comparing the hybrid For the endurance test conditions, a fully charged power battery pack must be able to support the car to run a complete endurance test of 22 km. This article is based on the automobile power balance equation: P e = P f + P w + P i + P j (1) where P f is rolling resistance power; P w is air resistance power; P i is slope resistance power; and P j is Acceleration resistance power.…”

Section: Introductionmentioning

confidence: 99%

Simulation and Optimization of FEV Limit Discharge’s Heat Dissipation Based on Orthogonal Experiments

Yang

et al. 2020

Materials

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The temperature difference between batteries has effects on the performance of the battery packs of electric vehicles (EVs). Therefore, it is necessary to design a battery cooling management system. In order to reduce the maximum temperature difference of the cooling system of the Formula Electric Vehicle (FEV) automobile, the orthogonal experimental design method was adopted in this paper, and the temperature field of the FEV air-cooled cooling system structure under a short-time high-current discharge condition was simulated for many times. The maximum temperature difference after simulating optimization was about 7 K, and the overall optimization degree was close to 40%. The research results showed that the gap between the single battery and the battery pack was very important to heat dissipation.

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