Performance Investigation of HFR Full-bridge Inverter in Resonant Inductive Coupled Power Transfer System for an Electric Vehicle

Authors

DOI:

https://doi.org/10.4108/ew.5227

Keywords:

Wireless Charging Technique, Electric Vehicle, Battery Charging Type, Resonant Inductively Coupled Power Transfer, High-Frequency inverter, Wireless Power Transmission, WPT

Abstract

Inductive WPT of the resonant category is generally employed for medium and high-power transmission applications like electric vehicle charging due to it contributes excellent efficiency. The high-frequency resonant full-bridge inverter using series-series resonant topology is proposed. The design of the high-frequency resonant inverter is simulated and verified by MATLAB/SIMULINK software. The charging scheme which is available in the AC-DC as well as in the DC-DC converter should operate with the two steps to achieve a duty cycle-based voltage control and hysteresis current control. The resonant frequency of the proposed system has a frequency range of 65 kHz with a DC voltage of 12V. The simulation has been carried out successfully and transmitted a 5KW power load of constant current and voltage control. The Performance chart of with the existing method is carried out in terms of parameters and the efficiency can be achieved by 95%.

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References

Jan-Mou Li, Jianlin Li. Exploratory spatial distribution of dynamic wireless charging demand for EVs: Front. Energy Res.. 2019; 7(3): 126-134.

Purwadi, A, Haryanto, D, Pribadi, J, Rohmatulloh, S, Hindersah, H, Haroen, Y. Modelling and Analysis of High-Frequency Inductive Power Transfer for Electric Vehicle Charging System: IEEE PELS Workshop on Emer. Tech. 2019; 61: 618-625.

Al-Waeli, A, H, A, Sopian, K, Yousif, J, H, Kazem, H, A, Boland, J, Chaichan, M, T. Artificial neural network modeling and analysis of photovoltaic/thermal system based on the experimental study: Energy Convers. Manag.. 2017; 186: 368–379. DOI: https://doi.org/10.1016/j.enconman.2019.02.066

Zhang, Z, Huo, H, Zhang, X. Research on three-coils magnetic coupling resonant wireless power transmission with power amplifier: IREE. 2021; 16(4): 360-367. DOI: https://doi.org/10.15866/iree.v16i4.20449

Anyapo, C, Teerakawanich, N, Mitsantisuk, C. Development of multi-coiled dynamic wireless power transfer for electric vehicle: IREE. 2021; 17(2): 185-195. DOI: https://doi.org/10.15866/iree.v17i2.21583

Manganiello, P, Ricco, M, Petrone, G, Monmasson, E, Spagnuolo, G. Optimization of perturbative PV MPPT methods through online system identification: IEEE Trans. Ind. Elec. 2015; 61(12): 6812-6821. DOI: https://doi.org/10.1109/TIE.2014.2317143

Jirasuwankul, N, Klongboonjit, S, Manop, C. Effects of demand fluctuation and mitigation strategy in low voltage EV charging station by battery energy storage system: IREE. 2019; 16(5): 409-417. DOI: https://doi.org/10.15866/iree.v16i5.18865

Yenchamchalit, K, Kongjeen, Y, Bhumkittipich, K, Stativa, A, Mithulananthan, N. Control of Low-Frequency oscillation on electrical power system under large EV-charging station installation using PSO technique for turning PSS parameters: IREE. 2020; 16(5): 401-408. DOI: https://doi.org/10.15866/iree.v16i5.20753

Shafei, M, Salama, M, Mansour, A, Ibrahim, D. Recharging Portable devices by photovoltaic modules using inductive power transfer: IRECON. 2021; 9(5): 230-238. DOI: https://doi.org/10.15866/irecon.v9i5.20274

Carigiet, F, Knecht, R, Baumann, T, Brabec, C,J, Baumgartner, F,P. New PV system Concept: inductive power transfer for PV modules: Int. J. Euro. Photo. Sol. Ener. 2018; 172(3): 332-350.

Thrimawithana, D,J, Madawala, U, K. A primary side controller for inductive power transfer systems: IEEE Int. J. Ind. Tech. 2018; 112: 661-666.

Kuditi Kamalapathi, Panugothu Srinivasa Rao Nayak, Vipul Kumar Tyagi. Design and implementation of dual-source (WPT + PV) charger for EV battery charging. Energies. 2021; 31(11): 376-389. DOI: https://doi.org/10.1002/2050-7038.13084

Abdelhamid, M, Singh, R, Qattawi, A, Omar, M, Haque, I. Evaluation of on-board photovoltaic modules options for electric vehicles: IEEE Journal of PV. 2020: 32(3): 334-346.

Satya Prakash Oruganti, K, Aravind Vaithilingam, C, Rajendran, G, Ramasamy, A. Design and sizing of the mobile solar photovoltaic power plant to support rapid charging for electric vehicles: Energies. 2019; 12(18): 302-330. DOI: https://doi.org/10.3390/en12183579

Teck Chuan Beh, Imura, T, Kato, M, Hori, Y. Basic study of improving the efficiency of wireless power transfer via magnetic resonance coupling based on impedance matching: Circuit Theory. 2016; 18: 203-215.

Mirsad Hyder Shah, Nasser Hassan Abosaq. Wireless power transfer via inductive coupling: Int. J. Pow. Elec. 2020; 15(3): 2254 – 4143.

Thrimawithana, D, J, Madawala, U,K. A generalized steady-state model for bidirectional IPT systems: IEEE Trans. Pow. Elec. 2016; 28(10): 4681 – 4689.

Samanta, S, Rathore, A,K. Analysis and design of load-independent ZPA operation for P/S and PS/S tank networks in IPT applications: IEEE App. Elec. Phy. 2018; 14: 2470-6647. DOI: https://doi.org/10.1109/APEC.2018.8341549

Thrimawithana, D.J, Madawala, U,K. A Generalized steady-state model for bidirectional IPT systems: IEEE Trans. Pow. Elec. 2019; 28(10): 4681-4689. DOI: https://doi.org/10.1109/TPEL.2012.2237416

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Published

28-02-2024

How to Cite

1.
Geetha P, Usha S. Performance Investigation of HFR Full-bridge Inverter in Resonant Inductive Coupled Power Transfer System for an Electric Vehicle. EAI Endorsed Trans Energy Web [Internet]. 2024 Feb. 28 [cited 2024 Dec. 22];11. Available from: https://publications.eai.eu/index.php/ew/article/view/5227