ABSTRACT
In order to ensure the stability of battery management power system, improve the reliability of on-board electronic products, and ensure the stability of thermal energy recovery power system, the author proposes an electromagnetic compatibility optimization scheme based on wiring harness, power module, and PCB noise, taking the battery management system of vehicle electronic components as an example, the role of electromagnetic compatibility on products is described, the hardware circuit is analyzed and designed by electromagnetic compatibility design theory to ensure the reliability of vehicle components. The electromagnetic stability of the power battery is guaranteed through the electromagnetic compatibility optimization analysis of the battery management system, so as to achieve more stable battery management. The experimental results show that each module of the battery management system works stably, and the disturbance degree test shows that the resonant noise of the battery management system disappears, and there is no obvious narrowband electromagnetic disturbance, and the overall value is below the limit of 20 dB. In conclusion the electomagnetic compatibility optimization scheme can effectively ensure the stability of the battery management power system, and indirectly ensure the stability of the heat recovery power system.
KEYWORDS
PAPER SUBMITTED: 2022-08-08
PAPER REVISED: 2022-10-08
PAPER ACCEPTED: 2022-10-26
PUBLISHED ONLINE: 2023-03-25
THERMAL SCIENCE YEAR
2023, VOLUME
27, ISSUE
Issue 2, PAGES [1167 - 1174]
- Dong, F., Zheng, L., The Impact of Market-Incentive Environmental Regulation on the Development of the New Energy Vehicle Industry: A Quasi-Natural Experiment Based on China's Dual-Credit Policy, Environmental Science and Pollution Research, 6 (2022), 4, 29
- Zhang, Z., et al., Optimal Design of Multi-Channel Water Cooled Radiator for Motor Controller of New Energy Vehicle, CES Transactions on Electrical Machines and Systems, 5 (2022), 1, 6
- Li, M., Bai, C., Application of Electronic Diagnosis Technology in New Energy Vehicle Maintenance, IOP Conference Series: Earth and Environmental Science, 680 (2021), 1, 012043
- He, C., Li, Q., Research on Clean Energy and New Energy Vehicle by Multidimensional Preference Analysis, IOP Conference Series: Earth and Environmental Science, 804 (2021), 3, 032044
- Group, M. T., Investing in Aerospace and New Energy Vehicle Markets, MobileTex, 7 (2022), 5, 17
- Wang, S., et al., Editorial for Special Issue on Electromagnetic Interference and Electromagnetic Compatibility in Power Electronics System, Chinese Journal of Electrical Engineering, 8 (2022), 3, p. 1
- El-Azab, R., et al., Conventional Generation Emulation for Power Grids with a High Penetration of Wind Power, 5 (2021), 1, 11
- Yu, Z., Li, M., Summary of Research on Intelligent Control Algorithm and Application of Power System Automation, Clausius Scientific Press, 5 (2021), 8, pp. 87-89
- Abdelsattar, M., et al., Voltage stability improvement of an egyptian power gridbased wind energy system using statcom. Wind energy, 7 (2022), 6, 25
- Mao, J., et al., Driving Conditions of New Energy Logistics Vehicles Using Big Data Technology, IEEE Access, 42 (2020), 4, pp. 10-15
- Chen, Z., et al., Influence Factors and Risk Analysis of New Energy Vehicles from the Perspective of System, 52 (2021), 2, pp. 58-61
- Gao, D. P., Zhang, X. X., Discussion on the Principle and Fault of High-Voltage Interlocking System for New Energy Vehicles, Value Engineering, 2 (2019), 2, pp. 5452-5456
- Zhao, X., Thermal Performance Analysis and Optimal Control of Power Lithium Cell Thermal Management System for new Energy Vehicles, Thermal Science, 24 (2020), 5B, pp. 3375-3383
- Zhang, H., et al., Design of lng Gasification and Thermal Energy Comprehensive Utilization System for Vehicles, IOP Conference Series: Materials Science and Engineering, 721 (2020), 9, 012077