This is an unedited manuscript accepted for publication and provided as an Article in Press for early access at the author’s request. The article will undergo copyediting, typesetting, and galley proof review before final publication. Please be aware that errors may be identified during production that could affect the content. All legal disclaimers of the journal apply.
Mr. Maharudra S. Shinde,
Rajesh S. Surjage,
- Research Scholar, Department of Electronics & Communication Engineering, Government College of Engineering, Chandrapur, Maharashtra, India
- Assistant Professor, Department of Electronics & Communication Engineering, Government College of Engineering, Chandrapur, Maharashtra, India
Abstract
Per capita, India has the world’s biggest battery electric vehicle market. For the last several years, there has been a lot of discussion about the challenges and prospects of integrating electric vehicles (EV) with an electric grid. A battery model of an EV should have suitable control mechanisms to interact with an electric grid. The growth of and accessibility of fast-charging technology is one of the many technological concerns being addressed as a result of this concentration. This strategy’s primary objective is to swiftly charge batteries. A personalised charging plan is created by using an optimisation method that considers the maximum permissible temperature and charging rate values, with the goal of minimising charging time, degradation rate, energy loss, and temperature rise. In addition, the study identifies promising new methods and opportunities for system-level research and power electronic converter topologies to advance the fast-charging state-of-the-art. The enhanced charging method was modelled and tested using a scaled-down battery pack with a capacity of 1020 mAh and a nominal voltage of 3.75 V. According to the results, the battery may be charged in under an hour using the rapid charging option. Rather than continuing to charge the battery with constant voltage, it is advised that the battery be charged to up to 85 percent of its rated capacity totally utilising constant current mode. This might cut charging time by 16 percent while also increasing battery longevity by 10 percent.
Keywords: fast charging; electric vehicle; DC Charger, MATLAB, LSTM
[This article belongs to Trends in Electrical Engineering ]
Mr. Maharudra S. Shinde, Rajesh S. Surjage. Investigation of High reliable electric vehicles drive with fast charging system. Trends in Electrical Engineering. 2025; 15(01):-.
Mr. Maharudra S. Shinde, Rajesh S. Surjage. Investigation of High reliable electric vehicles drive with fast charging system. Trends in Electrical Engineering. 2025; 15(01):-. Available from: https://journals.stmjournals.com/tee/article=2025/view=194518
References
1] International Energy Agency. (Apr. 2021). Global EV Outlook. [Online]. Available: https://iea.blob.core.windows.net/assets/ed5f4484-f556-4110-8c5c- 4ede8bcba637/GlobalEVOutlook2021.pdf
2] Pankaj Sharma, Rani Chinnappa Naidu, Optimization techniques for grid-connected PV with retired EV batteries in centralized charging station with challenges and future possibilities: A review, Ain Shams Engineering Journal, Volume 14, Issue 7, 2023, 101985, ISSN 2090-4479, https://doi.org/10.1016/j.asej.2022.101985.
3] C. He, J. Zhu, J. Lan, S. Li, W. Wu and H. Zhu, “Optimal Planning of Electric Vehicle Battery Centralized Charging Station Based on EV Load Forecasting,” in IEEE Transactions on Industry Applications, vol. 58, no. 5, pp. 6557-6575, Sept.-Oct. 2022, doi: 10.1109/TIA.2022.3186870.
4] B. Bose, A. Garg, L. Gao, J. Kim and S. Singh, “Development of novel MSCCCTCV charging strategy for health-aware battery fast charging using QOGA optimization,” in IEEE Transactions on Transportation Electrification, doi: 10.1109/TTE.2023.3314216.
5] J. Li, S. He, Q. Yang, T. Ma and Z. Wei, “Optimal Design of the EV Charging Station With Retired Battery Systems Against Charging Demand Uncertainty,” in IEEE Transactions on Industrial Informatics, vol. 19, no. 3, pp. 3262-3273, March 2023, doi: 10.1109/TII.2022.3175718. 6] N. Kumar, B. Singh and B. K. Panigrahi, “Voltage Sensorless Based Model Predictive Control With Battery Management System: For Solar PV Powered On-Board EV Charging,” in IEEE Transactions on Transportation Electrification, vol. 9, no. 2, pp. 2583-2592, June 2023, doi: 10.1109/TTE.2022.3213253.
7] WanJun Yin, Xuan Qin, Cooperative optimization strategy for large-scale electric vehicle charging and discharging, Energy, Volume 258, 2022, 124969, ISSN 0360-5442, https://doi.org/10.1016/j.energy.2022.124969.
8] Aboelezz, A., Makeen, P., Ghali, H.A. et al. Electric vehicle battery charging framework using artificial intelligence modeling of a small wind turbine based on experimental characterization. Clean Techn Environ Policy 25, 1149–1161 (2023). https://doi.org/10.1007/s10098-022-02430-x
9] Wang, Haoxing “Fault Diagnosis in Hybrid Renewable Energy Sources with Machine Learning Approach” Journalof Trends inComputer Science and Smart technology (TCSST) 3, no. 03 (2021): 222-237.
10] Ranganathan, Dr G “Energy Storage Capacity Expansionof Microgrids for a Long-Term” Journal of Electrical Engineering and Automation 3. No. 1: 55-64.
11] Anzola, J.; Aizpuru, I.; Arruti, A. Partial Power Processing Based Converter for Electric Vehicle Fast Charging Stations. Electronics 2021, 10, 260.
https://doi.org/10.3390/electronics10030260
12] “Sae electric vehicle and plug in hybrid electric vehicle conductive charge coupler,” SAE J1772, pp. 1–1, October 2017.
Trends in Electrical Engineering
| Volume | 15 |
| Issue | 01 |
| Received | 30/12/2024 |
| Accepted | 14/01/2025 |
| Published | 16/01/2025 |