基于磁耦合无线电能传输系统的能量信号并行传输串扰抑制方法OA
Crosstalk Suppression Method for Parallel Power and Data Transmission in Magnetic Coupling-Wireless Power Transfer Systems
为了提升磁耦合无线电能传输系统的信息传输能力和抗干扰能力,该文提出一种能量与信号并行传输系统的串扰抑制方法,并给出系统拓扑和串扰抑制方法.利用一对屏蔽铝板对能量线圈和大地之间的层间分布电场形成信号传输回路,有效地降低了能量通道对信号通道的影响,同时不影响能量的传输.为了获得 20 Mbit/s 的通信速率,建立信号传输的电路模型,分析系统的信号传输性能,给出层叠方式下能量与信号并行传输系统信号支路参数的设计方法.为了进一步提高数据传输的可靠性,解决变化磁场在屏蔽极板上感应的干扰电压问题,在数据通道中加入滤波网络来抑制线圈上变化磁场在屏蔽铝板上产生的干扰电压.通过对信号传输信道的信道容量分析,给出系统信号传输通道所能达到的最大信号传输速率.最后通过搭建的实验装置实现了在系统输出功率达到 1 015 W 时,信号正向传输速度为 21.6 Mbit/s 和信号反向传输速度为 21.6 Mbit/s,验证了所提系统的可行性.
With the widespread application of wireless power transfer(WPT)systems,there is an increasing demand for flexible adaptation to varying operational environments,necessitating real-time high-speed information exchange between power transmitters and receivers.However,current systems still fall short of engineering requirements for power transfer capacity and data transmission speed.This paper proposes a crosstalk-suppression method for parallel power and data transmission in magnetic resonance-based WPT(MR-WPT)systems,with a primary focus on enabling high-speed bidirectional communication. First,a stacked coupled structure that enables simultaneous power and data transmission is proposed.A pair of shielded aluminum plates forms a data transmission path between the power coil and ground by utilizing interlayer-distributed electric fields,reducing voltage stress on the data circuit caused by power transfer and mitigating crosstalk between the power and data channels.Based on parasitic capacitance distribution between the shielding plates and power coils,an equivalent parasitic capacitance model is established.Then,the equivalent circuit models for both power and data transmission channels are developed.Higher-order filtering networks in the data transmission path suppress strong magnetic interference and system EMI from power transfer,while ensuring high gain for data carrier transmission.The absence of dedicated data coils or shared channels with power transfer simplifies system design. Subsequently,a parameter design method for the simultaneous wireless power and data transfer(SWPDT)system is proposed.This method effectively reduces strong magnetic interference and system EMI while minimizing the impact of power transfer on data transmission speed.As a result,communication rates are improved.Through channel capacity analysis of the data transmission path,the maximum achievable data rates under different power levels are determined. Finally,the experimental setup achieved forward and backward data transmission speeds of 21.6 Mbit/s at a system output power of 1 018 W.Under the magnetic shielding provided by metallic plates,the system maintains excellent power transfer performance and high data transmission speed across varying operating conditions,including different power levels and lateral or longitudinal misalignments.The presence of shielding plates slightly reduces the self-and mutual inductances of the power-coupling coils.The power transfer capability is diminished,and a more pronounced shielding effect against electromagnetic leakage is provided.Compared with existing wireless power and data transmission technologies that use shielding plates or parasitic coil parameters,the feasibility of the proposed approach is verified.
冯占昆;戴欣;成奕憬;秦帅;高文浩
重庆大学自动化学院 重庆 400043重庆大学自动化学院 重庆 400043||国家无线电能传输技术国际联合研究中心 重庆 400043重庆大学自动化学院 重庆 400043重庆大学自动化学院 重庆 400043重庆大学自动化学院 重庆 400043
信息技术与安全科学
无线电能与信号并行传输层间分布电场干扰抑制参数设计
Simultaneous wireless power and data transferinterlayer distributed electric fieldinterference suppressionparameters design
《电工技术学报》 2026 (12)
3968-3986,19
国家自然科学基金(52277003)和中央高校基本科研业务专项基金(2022CDJQY-006,2024CDDJXY027)资助项目.
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