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Hybrid modeling and control of ICPT system with synchronous three-phase triple-parallel Buck converter

Published online by Cambridge University Press:  28 January 2020

Songcen Wang
Affiliation:
China Electric Power Research Institute, Beijing100192, China
Xiaokang Wu
Affiliation:
China Electric Power Research Institute, Beijing100192, China
Ying Yang
Affiliation:
School of Electrical and Power Engineering, China University of Mining and Technology, Xuzhou221116, China
Cong Zhu
Affiliation:
School of Electrical and Power Engineering, China University of Mining and Technology, Xuzhou221116, China
Zhen Wu
Affiliation:
School of Electrical and Power Engineering, China University of Mining and Technology, Xuzhou221116, China
Chenyang Xia*
Affiliation:
School of Electrical and Power Engineering, China University of Mining and Technology, Xuzhou221116, China
*
Author for correspondence: Chenyang Xia, School of Electrical and Power Engineering, China University of Mining and Technology, Xuzhou221116, China. E-mail: bluesky198210@163.com
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Abstract

Aiming at the influence of coupling coefficient variation on the output voltage of a high-power LCC-S topology inductively coupled power transfer (ICPT) system, a synchronous three-phase triple-parallel Buck converter is used as the voltage adjustment unit. The control method for the three-phase current sharing of synchronous three-phase triple-parallel Buck converter and the constant voltage output ICPT system under the coupling coefficient variation is studied. Firstly, the hybrid model consisting of the circuit averaging model of the three-phase triple-parallel Buck converter and the generalized state-space average model for the LCC-S type ICPT system is established. Then, the control methods for three-phase current sharing of the synchronous three-phase triple-parallel Buck converter and constant voltage output of ICPT system are studied to achieve the multi-objective integrated control of the system. Finally, a 3.3 kW wireless charging system platform is built, the experimental results have verified the effectiveness of the proposed modeling and control method, and demonstrated the stability of the ICPT system.

Type
Research Article
Copyright
Copyright © Cambridge University Press 2020

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References

Xia, C, Zhu, W, Ma, N, Jia, R and Yu, Q (2018) A load identification method for ICPT system utilizing harmonics. Journal of Electrical Engineering & Technology 13, 21782186.Google Scholar
Li, Y, Sun, Y and Dai, X (2013) μ-Synthesis for frequency uncertainty of the ICPT system. IEEE Transactions on Industrial Electronics 60, 291300.CrossRefGoogle Scholar
Madawala, UK and Thrimawithana, DJ (2011) A bidirectional inductive power interface for electric vehicles in V2G systems. IEEE Transactions on Industrial Electronics 58, 47894796.CrossRefGoogle Scholar
Badr, BM, Somogyi-Csizmazia, R, Leslie, P and Delaney, KR (2017) Design of a wireless measurement system for use in wireless power transfer applications for implants. Wireless Power Transfer 4, 2132.CrossRefGoogle Scholar
Zhang, Z, Zhang, B, Deng, B, Wei, X and Wang, J (2018) Opportunities and challenges of metamaterial-based wireless power transfer for electric vehicles. Wireless Power Transfer 5, 919.CrossRefGoogle Scholar
Xia, C, Xie, G, Lin, K, Chen, G, Ren and Zhang, Y (2016) Study of dual resonance point characteristics and maximum output power of ICPT based on double LCL compensation. Proceedings of the CSEE 36, 52005209.Google Scholar
Xia, C, Wang, W, Chen, G, Wu, X, Zhou, S and Sun, Y (2017) Robust control for the relay ICPT system under external disturbance and parametric uncertainty. IEEE Transactions on Control Systems Technology 25, 21682175.10.1109/TCST.2016.2634502CrossRefGoogle Scholar
Li, Y, Du, H, Yang, M and He, Z (2018) Two-Degree-of-Freedom h infinity robust control optimization for the IPT system with parameter perturbations. IEEE Transactions on Power Electronics 33, 1095410969.10.1109/TPEL.2018.2809725CrossRefGoogle Scholar
Van, DPFFA, Castilla, M and Bauer, P (2013) Adaptive Sliding-Mode control for a Multiple-User inductive power transfer system without need for communication. IEEE Transactions on Industrial Electronics 60, 271279.Google Scholar
Narimani, M and Moschopoulos, G (2014) An investigation on the novel use of High-Power Three-Level converter topologies to improve Light-Load efficiency in low power DC/DC Full-Bridge converters. IEEE Transactions on Industrial Electronics 61, 56905692.10.1109/TIE.2014.2300063CrossRefGoogle Scholar
Luo, B, Chen, L and Li, Y (2017) Investigation of output voltage control for the inductive power. Transactions of China Electrotechnical Society 32, 235242.Google Scholar
Zhang, X, Xu, J, Bao, B and Zhou, G (2016) Asynchronous-Switching Map-Based stability effects of circuit parameters in fixed Off-Time controlled buck converter. IEEE Transactions on Power Electronics 31, 66866697.CrossRefGoogle Scholar
Hu, A P and Hussmann, S (2004) Improved power flow control for contactless moving sensor applications.IEEE Power Electronics Letters 2, 135138.10.1109/LPEL.2004.841311CrossRefGoogle Scholar
Wang, J, Tzeng, L, Hsu, M and Jian, H (2018) A simple control scheme to avoid the sensing noise for the DC-DC buck converter with synchronous rectifier. IEEE Transactions on Industrial Electronics 65, 50865091.10.1109/TIE.2017.2772195CrossRefGoogle Scholar
Orabi, M and Shawky, A (2015) Proposed switching losses model for integrated Point-of-Load synchronous buck converters. IEEE Transactions on Power Electronics 30, 51365150.10.1109/TPEL.2014.2363760CrossRefGoogle Scholar
Hu, A P (2009) Modeling a contactless power supply using GSSA method. Proc. IEEE Int. Conf. Ind. Technol, 16.Google Scholar
Maksimovic, D and Zane, R (2007) Small-signal discrete-time modeling of digitally controlled PWM converters. IEEE Transactions on Power Electronics 22, 25522556.CrossRefGoogle Scholar
Huang, X, Peng, Y and Li, Y (2013) Current balancing for three-phase buck-type interleaving parallel rectifier. Power Electronics 47, 8183.Google Scholar