The Structure of Advanced Converters in Rechargeable Hybrid Electric Vehicles
محورهای موضوعی : Electronics
Naghmeh Malekiye
1
,
Mahdiyeh Eslami
2
,
mehdi jafari
3
1 - Islamic Azad University, Kerman, Iran
2 - Department of Electrical Engineering, Kerman Branch, Islamic Azad University, Kerman, Iran.
3 - Department of electronic Engineering, Kerman Branch, Islamic Azad University, Kerman, Iran
کلید واژه: Power Converters, Inverters, Rechargeable Hybrid Vehicles,
چکیده مقاله :
The main goal of this article was to compare advanced converters in plug-in hybrid electric vehicles. In this article, there are two examples of integrated chargers, the first charger integrates two DC/DC converters and uses the obtained converter in the structure of the charger, and the second charger integrates two power converters and inverters. It introduces a second integrated charger. These two chargers were simulated using valid references and compared with each other and finally the results showed that the second structure is a better structure in the car. The second structure reduced the volume, consumption, charging cost and losses by reducing the power electronic elements. This structure also had a better and higher capacity than the first structure. When it comes to getting the battery voltage to a high enough level to power the motor, the performance of the two structures was not much different, but in all other cases, the second structure performed better than its counterpart. Therefore, it is better and more economical to use this converter in rechargeable hybrid cars.
The main goal of this article was to compare advanced converters in plug-in hybrid electric vehicles. In this article, there are two examples of integrated chargers, the first charger integrates two DC/DC converters and uses the obtained converter in the structure of the charger, and the second charger integrates two power converters and inverters. It introduces a second integrated charger. These two chargers were simulated using valid references and compared with each other and finally the results showed that the second structure is a better structure in the car. The second structure reduced the volume, consumption, charging cost and losses by reducing the power electronic elements. This structure also had a better and higher capacity than the first structure. When it comes to getting the battery voltage to a high enough level to power the motor, the performance of the two structures was not much different, but in all other cases, the second structure performed better than its counterpart. Therefore, it is better and more economical to use this converter in rechargeable hybrid cars.
[1] Adams, S. , Klobodu, E. K. M. , & Apio, A. Renewable and non-renewable energy, regime type and economic growth. Renewable Energy, 125 (2018). 755–767 Sep.
[2] Bhaskar, M. S. , Padmanaban, S. , Iqbal, A. , Meraj, M. , Howeldar, A. , & Kamuruzza- man, J. (2018). L-L Converter for fuel cell vehicular power train applications: hard- ware implementation of primary member of X-Y converter family. In Proceedings of the IEEE international conference on power electronics, drives and energy systems (PEDES) (pp. 1–6). Dec. .
[3] Feng, H.; Tavakoli, R.; Onar, O.C.; Pantic, Z. Advances in High-Power Wireless Charging Systems: Overview and Design Considerations. IEEE Trans. Transp. Electrif, 6 (2020). 886–919.
[4] Pandav, K., Padmanaban, S., Bhaskar R., Mahajan & Ramachandaramurthy, Vigna & Blaabjerg, F.,The State-of-The-Art of Power Electronics Converters Configurations in Electric Vehicle Technologies. Power Electronic Devices and Components. 1 (2021). 100001. 10.1016/j.pedc.2021.100001.
[5] Bhaskar, M. S. , Padmanaban, S. , & Holm-Nielsen, J. B., Double stage double out- put dc–dc converters for high voltage loads in fuel cell vehicles, ”. Energies, 12 (19) (2019b). Art. no. 19, Jan .
[6] Krishna, M. , Daya, F. , Sanjeevikumar, P. , & Mihet-Popa, L., Real-time analysis of a modified state observer for sensorless induction motor drive used in electric vehicle applications. Energies, MDPI, Open Access Journal, 10 (8), (2017). 1–23 pagesJuly .
[7] Poorfakhraei, A.; Narimani, M.; Emadi, A. A Review of Multilevel Inverter Topologies in Electric Vehicles: Current Status and Future Trends. IEEE Open J. Power Electron. 2(2021). 155–170.
[8] Zhao, Y. , He, X. , Yao, Y. , & Huang, J., Plug-in electric vehicle charging management via a distributed neurodynamic algorithm. Applied Soft Computing, 80 (2019). 557–566 Jul. .
[9] Reimers, J.; Dorn-Gomba, L.; Mak, C.; Emadi, A. Automotive Traction Inverters: Current Status and Future Trends. IEEE Trans. Veh. Technol., 68(2019). 3337–3350.
[10] Choi, S.Y.; Gu, B.W.; Jeong, S.Y.; Rim, C.T. Advances in Wireless Power Transfer Systems for Roadway-Powered Electric Vehicles. IEEE J. Emerg. Sel. Top. Power Electron., 3(2014). 18–36.
[11] Premkumar, K.; Kandasamy, P.; Vishnu Priya, T.; Thamizhselvan, T.; Carter, S.B.R. Three-Phase Rectifier Control Techniques: A Comprehensive Literature Survey. Int. J. Sci. Technol. Res. 9, (2020), 3183–3188.
[12] Ronanki, D.; Kelkar, A.; Williamson, S.S. Extreme Fast Charging Technology—Prospects to Enhance Sustainable Electric Transportation. Energies , 12,(2019). 3721.
[13] Un-Noor, F. , Padmanaban, S. , Mihet-Popa, L. , Mollah, M. N. , & Hossain, E., A com- prehensive study of key electric vehicle (EV) components, technologies, challenges, impacts, and future direction of development. Energie, 10(2017). 1217 .
[14] Zhou, W. , Yang, L. , Cai, Y. , & Ying, T., Dynamic programming for new energy ve- hicles based on their work modes part I: Electric vehicles and hybrid electric vehicles. Journal of Power Sources, 406, (2018). 151–166 Dec. .
[15] Daramy-Williams, E. , Anable, J. , & Grant-Muller, S.. A systematic review of the evidence on plug-in electric vehicle user experience. Transportation Research Part D: Transport and Environment, 71 (2019). 22–36 Jun. .
[16] Lee, Y.J.; Bak, Y.; Lee, K.-B. Control Method for Phase-Shift Full-Bridge Center-Tapped Converters Using a Hybrid Fuzzy Sliding Mode Controller. Electronics, 8,(2019). 705.
[17] Awasthia, A. , Karthikeyan, V. , Sanjeevikumar, P. , Rajasekar, S. , Blaabjerg, F. , & Singh, A. K., Optimal planning of electric vehicle charging station at the dis- tribution system using hybrid optimization algorithm. Energy Journal, Elsevier Journal Publications, 133 , (2017). 70–78 August .
[18] Galigekere, V.P.; Pries, J.; Onar, O.C.; Su, G.; Anwar, S.; Wiles, R.; Seiber, L.; Wilkins, J. Design and Implementation of an Optimized 100 kW Stationary Wireless Charging System for EV Battery Recharging. In Proceedings of the 2018 IEEE Energy Conversion Congress and Exposition (ECCE), Portland, OR, USA, 23–27 September 2018; pp. 3587–3592.
[19] Gielen, D. , Boshell, F. , Saygin, D. , Bazilian, M. D. , Wagner, N. , & Gorini, R. The role of renewable energy in the global energy transformation. Energy Strategy Reviews, 24 (2019). 38–50 Apr.
[20] Subramaniam, U. , Ganesan, S. , Bhaskar, M. S. , Padmanaban, S. , Blaabjerg, F. , & Al- makhles, D. J., Investigations of AC microgrid energy management systems using distributed energy resources and plug-in electric vehicles. Energies, 12 (14)(2019). Art. no. 14, Jan .
[21] Morales-Morales J, Rivera-Cruz MA, Cruz-Alcantar P, Bautista Santos H, Cervantes-Camacho I, Reyes Herrera VA. Performance Analysis of a Hybrid Electric Vehicle with Multiple Converter Configuration. Applied Sciences. 10(3) (2020).1074. https://doi.org/10.3390/app10031074
[22] Iqbal, M. , Wang, T. , Li, G. , Chen, D. and Al-Nehari, M. A Study of Advanced Efficient Hybrid Electric Vehicles, Electric Propulsion and Energy Source. Journal of Power and Energy Engineering, 10 (2022). 1-12. doi: 10.4236/jpee.2022.107001.
[23] Lee, Y., Khaligh, A., & Emadi, A., Advanced Integrated Bidirectional AC/DC and DC/DC Converter for Plug-In Hybrid Electric Vehicles. IEEE Transactions on Vehicular Technology, 58(2009). 3970-3980.
[24] Tomaszewska, A.; Chu, Z.; Feng, X.; O’kane, S.; Liu, X.; Chen, J.; Ji, C.; Endler, E.; Li, R.; Liu, L.; et al. Lithium-ion battery fast charging: A review. eTransportation 2019, 1, 100011.
[25] Kyungjin Yu, Song-Yul Choe, Jinseong Kim, Energy Management Strategies for Series-Parallel Hybrid Electric Vehicles Considering Fuel Efficiency and Degradation of Lithium-Ion Batteries, SAE International Journal of Electrified Vehicles, 10.4271/14-12-03-0022, 12 (2023), 3.
[26] Verma, Shrey & Mishra, Shubham & Gaur, Ambar & Chowdhury, Subhankar & Mohapatra, Subhashree & Dwivedi, Gaurav & Verma, Puneet., A comprehensive review on energy storage in hybrid electric vehicle. Journal of Traffic and Transportation Engineering (English Edition). 8(2021). 10.1016/j.jtte.2021.09.001.
