Nearly Constant Power Tuning Network for Wireless Inductive Power Transfer Systems

被引:0
|
作者
Chawla, Mayank [1 ]
Maksimovic, Dragan [2 ]
Kamineni, Abhilash [1 ]
机构
[1] Utah State Univ, Dept Elect & Comp Engn, Logan, UT 84341 USA
[2] Univ Colorado Boulder, Dept Elect Comp & Energy Engn, Boulder, CO 80309 USA
来源
2023 IEEE WIRELESS POWER TECHNOLOGY CONFERENCE AND EXPO, WPTCE | 2023年
关键词
Wireless inductive power transfer (IPT); dynamic wireless power transfer (DWPT); zero voltage switching (ZVS); parallel resonant series-series (PRSS) tuning; DESIGN;
D O I
10.1109/WPTCE56855.2023.10216214
中图分类号
TM [电工技术]; TN [电子技术、通信技术];
学科分类号
0808 ; 0809 ;
摘要
Wireless inductive power transfer (IPT) is being widely used for applications ranging from phone charging, implantable medical devices to electric vehicle charging. One challenge associated with IPT systems is misalignment between the primary coil and secondary coil. This paper proposes a parallel resonant series-series (PRSS) tuning which is a new design methodology for tuning IPT systems to maintain constant power for range of coupling coefficients. With PRSS tuning, power variations with misalignment in wireless charging systems are reduced while maintaining high efficiencies and also achieving zero voltage switching (ZVS) for the primary switches. A detailed design procedure for PRSS tuning method for IPT systems is shown in this paper. Design methodology has been verified using analysis and simulation results for dynamic wireless power transfer system (DWPT) for electric vehicle charging. Comparison of the PRSS tuning method with series-series and double-sided LCC tuning in terms of constant power transfer has been presented in this paper.
引用
收藏
页数:6
相关论文
共 50 条
  • [1] Power Transfer With an Inductive Link and Wireless Tuning
    Brusamarello, Valner J.
    Blauth, Yeddo Braga
    de Azambuja, Ricardo
    Muller, Ivan
    de Sousa, Fernando Rangel
    IEEE TRANSACTIONS ON INSTRUMENTATION AND MEASUREMENT, 2013, 62 (05) : 924 - 931
  • [2] A Study on Inductive Power Transfer with Wireless Tuning
    Brusamarello, V. J.
    Blauth, Y. B.
    Azambuja, R.
    Mueller, I.
    2012 IEEE INTERNATIONAL INSTRUMENTATION AND MEASUREMENT TECHNOLOGY CONFERENCE (I2MTC), 2012, : 1098 - 1103
  • [3] Frequency Tuning in Inductive Power Transfer Systems
    Bertoluzzo, Manuele
    Buja, Giuseppe
    ELECTRONICS, 2020, 9 (03)
  • [4] Magnetic Power Tuning Architectures in Wireless Power Transfer Systems
    Mohamed, Nagi F. Ali
    Agbinya, Johnson I.
    2018 IEEE PELS WORKSHOP ON EMERGING TECHNOLOGIES: WIRELESS POWER TRANSFER (WOW), 2018,
  • [5] Power Stability Enhancement in Inductive Wireless Power Transfer Systems: A Review
    Zheng, Yangxin
    Feng, Fan
    Wang, Xueyuan
    Huang, Yonghai
    Xie, Peng
    IEEE ACCESS, 2024, 12 : 145968 - 145987
  • [6] Effect of tuning capacitance of passive power repeaters on power transfer capability of inductive power transfer systems
    Hua, Rong
    Hu, Aiguo Patrick
    WIRELESS POWER TRANSFER, 2018, 5 (02): : 97 - 104
  • [7] Review of Tuning Methods in Wireless Power Transfer Systems
    Lu, Jianghua
    Sun, Shixiong
    Ke, Haojie
    Zhu, Guorong
    PROCEEDINGS OF 2023 INTERNATIONAL CONFERENCE ON WIRELESS POWER TRANSFER, VOL 3, ICWPT 2023, 2024, 1160 : 434 - 447
  • [8] A Constant-Power and Optimal-Transfer-Efficiency Wireless Inductive Power Transfer Converter for Battery Charger
    Iam, Io-Wa
    Choi, Chio-Kuan
    Lam, Chi-Seng
    Mak, Pui-In
    Martins, Rui Paulo
    IEEE TRANSACTIONS ON INDUSTRIAL ELECTRONICS, 2024, 71 (01) : 450 - 461
  • [9] Theoretical Modeling of Complicated Inductive Wireless Power Transfer Systems
    Roman, Scott
    Durgin, Gregory D.
    2020 IEEE INTERNATIONAL CONFERENCE ON RFID (IEEE RFID 2020), 2020,
  • [10] A Power Converter Decoupled from the Resonant Network for Wireless Inductive Coupling Power Transfer
    Chen, Lin
    Hong, Jianfeng
    Guan, Mingjie
    Wu, Wei
    Chen, Wenxiang
    ENERGIES, 2019, 12 (07)
12345