基于平面双解耦型信号线圈的无线电能与全双工信号同步传输系统

doi:10.19595/j.cnki.1000-6753.tces.242161

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摘要无线电能与信号传输系统无需额外增设通信模块就可以实现原边和副边之间的信号传输,且不影响能量的谐振状态。该文提出一种双解耦型信号线圈,信号线圈与能量磁耦合机构、同侧信号发射和接收线圈间都是相互解耦的,进而消除了能量通道与信号通道间的干扰。除此之外,该文还提出一种基于双谐振电路的信号通道拓扑实现信号的全双工通信模式。在某一方向传输频率下,另一方向传输的接收端和发射端呈高阻抗状态,以此来隔离双向信号传输的串扰。首先,基于有限元仿真,建立双解耦型信号线圈的磁场模型,分析能量磁耦合机构与信号线圈、信号发射与接收线圈的磁场分布特性,进一步提出一种提升信号传输性能的线圈优化方法。然后,基于双解耦型信号线圈与能量磁耦合机构,提出一种无线电能与全双工信号同步传输拓扑。针对信号通道在全双工模式下的串扰问题,分析基于双谐振电路的信号通道阻抗,研究正反向信号传输的增益特性,得到了全双工模式下减小串扰的信号通道参数设置方法。最后,搭建无线电能与信号传输实验平台进行验证。实验结果表明,所提双解耦型信号线圈与能量磁耦合机构相互无干扰,实现了175 W的功率传输与120 kbit/s的全双工信号传输,能够满足大多数串口信号通信。

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关键词 ：无线电能传输, 无线电能与信号传输, 双解耦型信号线圈, 全双工通信

Abstract：The wireless power and signal transfer system can achieve signal transmission between the primary and secondary sides without additional communication modules, thereby avoiding interference with the resonance state of power. This paper proposes a double-decoupled signal coil. This signal coil and the power magnetic coupling mechanism are decoupled, and the same side signal transmitting and receiving coils are also decoupled. Thus, the interference between the power channel and the signal channel is eliminated. In addition, this paper proposes a signal channel topology based on a dual resonant circuit to achieve a full duplex communication mode.
At a particular transmission frequency in one direction, the receiving and transmitting sides in the other direction are in a high impedance state to isolate crosstalk in bidirectional signal transmission. This paper first establishes a magnetic field model of a dual decoupling signal coil based on finite element simulation. The magnetic field distribution characteristics of the power magnetic coupling mechanism and the signal coil are analyzed, as well as the signal transmission and reception coils. A coil optimization method is proposed to improve signal transmission performance. Then, based on the dual decoupling signal coil and power magnetic coupling mechanism, a wireless power and full duplex signal synchronous transmission topology is proposed. In response to the crosstalk problem of signal channels in full duplex mode, the impedance of signal channels based on dual resonant circuits was analyzed, and the gain characteristics of forward and reverse signal transmission were studied. A method for setting signal channel parameters was obtained to reduce crosstalk in full duplex mode. Finally, a wireless power and signal transmission experimental platform was established. The experimental results show that the proposed dual decoupling signal coil achieves wireless power and signal transmission without interference with the power magnetic coupling mechanism. The proposed full duplex signal topology can achieve bidirectional signal communication at 120 kbit/s under the 175 W power condition, which can meet most serial port signal communication needs.

Key words： Wireless power transfer (WPT) wireless power and signal transfer (WPST) double-decoupled signal coil full-duplex communication

收稿日期: 2024-11-29

PACS:

TM724

基金资助:国家重点研发计划项目（2022YFB3304502）、国家自然科学基金项目（52307004）、中国博士后基金面上项目（2023MD744133）、重庆市自然科学基金项目（2024NSCQ-MSX1785）和重庆市教育委员会科学技术研究项目（KJQN202400626）资助

通讯作者: 蒋金橙男,1993年生,博士研究生,研究方向为无线电能传输技术。E-mail: jiangjinc@cqupt.edu.cn

作者简介: 王佩月男,1992年生,博士研究生,研究方向为无线电能与信号同步传输技术。E-mail: wangpy@cqupt.edu.cn

引用本文:

王佩月, 蒋金橙, 冯天旭, 史可, 王军. 基于平面双解耦型信号线圈的无线电能与全双工信号同步传输系统[J]. 电工技术学报, 2025, 40(24): 7891-7905. Wang Peiye, Jiang Jincheng, Feng Tianxu, Shi Ke, Wang Jun. Wireless Power and Full-Duplex Signal Transfer System Based on the Planar Double-Decoupled Signal Coil. Transactions of China Electrotechnical Society, 2025, 40(24): 7891-7905.

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