Solar Based Electric Vehicle Charging

Year : 2024 | Volume :11 | Issue : 01 | Page : 27-32
By

Parnal Anil Gaikwad

Nakul Dipak Shirsale

R.U. Shekokar

  1. Student Department of Electronics & Telecommunication, Sinhgad College of Engineering, Savitribai Phule University, Pune Maharashtra India
  2. Student Department of Electronics & Telecommunication, Sinhgad College of Engineering, Savitribai Phule University, Pune Maharashtra India
  3. Professor Department of Electronics & Telecommunication, Sinhgad College of Engineering, Savitribai Phule University, Pune Maharashtra India

Abstract

The “Solar-Based Wireless Power Transmission Highways” project aims to revolutionize the way we generate and distribute electrical energy on highways. This innovative system harnesses solar energy through strategically placed solar panels along the highway, converting it into electricity. The electricity is then wirelessly transmitted to electric vehicles (EVs) passing overhead, enabling them to charge without the need for physical connections. This technology not only addresses the growing demand for sustainable transportation but also reduces greenhouse gas emissions by promoting the use of clean energy sources. The project’s methodology involves the design and implementation of a solar-based wireless power transmission system, comprehensive testing, and the evaluation of its efficiency and environmental impact. The results demonstrate the feasibility and potential benefits of integrating solar-based wireless power transmission into our infrastructure, paving the way for a more sustainable and efficient future for transportation systems. Solar-based wireless power transmission highways are a new and innovative technology that has the potential to revolutionize the transportation industry. By using solar energy to generate electricity and wirelessly transmit it to electric vehicles, these highways could provide a clean, sustainable, and efficient way to power transportation.

Keywords: WPT, inductive coupling, magnetic resonance, radio frequency

[This article belongs to Journal of Refrigeration, Air conditioning, Heating and ventilation(jorachv)]

How to cite this article: Parnal Anil Gaikwad, Nakul Dipak Shirsale, R.U. Shekokar. Solar Based Electric Vehicle Charging. Journal of Refrigeration, Air conditioning, Heating and ventilation. 2024; 11(01):27-32.
How to cite this URL: Parnal Anil Gaikwad, Nakul Dipak Shirsale, R.U. Shekokar. Solar Based Electric Vehicle Charging. Journal of Refrigeration, Air conditioning, Heating and ventilation. 2024; 11(01):27-32. Available from: https://journals.stmjournals.com/jorachv/article=2024/view=146461

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References

  1. R. Islam, M. T. Iqbal, and M. K. Hannan, “Electric vehicle wireless charging systems and a review on wireless vehicle dynamics,” Energies, vol. 11, no. 2,p.456, 2018.
  2. Mi, S. Kang, J. Huh, and J. M. Park, “Design and analysis of an inductive power transfer system for electric vehicle charging applications,” Energies, vol.12,no. 10,p. 1916, 2019.
  3. Raval, A. Jain, and A. Khan, “A review on dynamic wireless power transfer for electric vehicles,” in 2016 International Conference on Signal Processing, Communication, Power and Embedded System (SCOPES), 2016, pp. 1048-1052.Arne Sund.2015.
  4. A. Arkadan, H. W. Ho, and M. A. Karim, “Wireless power transfer to an electric vehicle during its moving using series-series resonant converter,” IET Power Electronics, vol. 8, no. 8, pp. 1461-1471, 2015.
  5. Chen, H. Liu, S. Chen, and C. C. Mi, “Dynamic wireless charging of electric vehicles: principles, standards, and trends,” IEEE Electrification Magazine, vol.5, no. 1, pp. 33- 44, 2017.
  6. Kim, S. Kim, and C. Kim, “A study on electric vehicle dynamic wireless charging system based on road surface segments,” Energies, vol. 13, no. 13, p. 3325, 2020.
  7. You, C. Mi, and L. Sun, “Recent advances in wireless power transfer via human movements for wearable and implantable devices,” IEEE Access, vol. 8, pp. 123860- 123887, 2020.
  8. K. Song, C. Mi, and F. Du, “Optimal design of a series-series inductive power transfer system for on-road EV charging,” IEEE Transactions on Power Electronics, vol. 32, no. 9, pp. 7167-7177, 2016.
  9. Zhang, X. Li, S. Ji, and Q. Tang, “Dynamic charging for electric vehicles on the road: an overview,” IEEE Transactions on Vehicular Technology, vol. 66, no. 8, pp. 6430-6442, 2017.
  10. M. Perera, M. M. Rashid, and N. G. J. Fonseka, “Electric road vehicles: an overview of the concept, technology, and classification,” IEEE Transactions on Vehicular Technology, vol. 68, no. 4, pp. 3016-3032, 2019.
  11. Li, X., Zheng, F., Wang, H., Sun, Y., Dai, X., & Hu, J. (2023). A Simultaneous Power and Data transfer Method for Dynamic Wireless Charging Electric Vehicles. IEEE Journal of Emerging and Selected Topics in Power Electronics.
  12. Mohamed, N., Aymen, F., Alharbi, T. E., El-Bayeh, C. Z., Lassaad, S., Ghoneim, S. S., & Eicker, U. (2022). A comprehensive analysis of wireless charging systems for electric vehicles. IEEE Access, 10, 43865-43881.
  13. Park, J., An, J., Han, K., Choi, H. S., & Park, I. S. (2022). Enhancement of cooling performance in traction motor of electric vehicle using direct slot cooling method. Applied Thermal Engineering, 217, 119082.
  14. Karthik, D. R., Bandi, M., Marati, N., Vaithilingam, B., & Karuppazhagi, K. (2022). Recent Trends and Technologies of Electric Vehicles and Their Wireless Charging Methods: A Review. Smart Charging Solutions for Hybrid and Electric Vehicles, 399-418.
Regular Issue Subscription Review Article
Volume 11
Issue 01
Received April 5, 2024
Accepted May 3, 2024
Published May 17, 2024
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