首页|期刊导航|电工技术学报|多组织层结构经皮电场耦合的人体植入式设备无线电能传输系统

多组织层结构经皮电场耦合的人体植入式设备无线电能传输系统OA

Multi-Layer Tissue Structure Transcutaneous Electric Field Coupled Wireless Power Transfer System for Human Implantable Devices

中文摘要英文摘要

当前人体植入式设备电场耦合无线电能传输系统的研究通常是以单层人体组织作为传能介质展开.但在实际应用场景中,接收极板作为柔性薄膜电极通常植入在皮下,多组织层的结构会对传能能力有较大的影响.对此,该文首先对人体组织介电特性展开研究,建立精确的多组织层电路模型,对传能链路的损耗、传能效率及负载功率展开分析,确定影响参数.其次通过COMSOL对耦合装置的绝缘层厚度以及补偿电路参数等进行了仿真分析,以最大传能效率以及尽可能高的负载功率作为目标来设计非对称绝缘层耦合装置参数.进一步以IEEE C95.1 准则对比吸收率、电刺激以及组织温升进行了安全评估,接收端以 55.01%的传能效率接收了 83 mW的能量.最后搭建实验平台,以新鲜猪肉模拟人体组织进行了实验验证,实现以 45.48%的效率传递 107 mW功率到负载.

Electric-field-coupled wireless power transfer(WPT)offers the advantages of low electro-magnetic interference,low eddy current loss,and lightweight coupler structures.However,current research on electric-field-coupled WPT for human implantable devices typically assumes a single-layer human-tissue model as the energy-transmission medium.In practical applications,the flexible film electrode,used as a receiver,is usually implanted between the skin and fat.Thus,the structure of multi-layer tissue has significant research potential for electric-field-coupled WPT.In this paper,a multi-layer tissue-structure transcutaneous electric-field-coupled WPT system is investigated from three aspects:circuit modeling,coupling device design,and safety assessment. To address the limitations of traditional circuit models in complex human environments,a precise human-tissue circuit model is developed.The dielectric properties of human tissues are studied using the fourth-order Cole-Cole model,and the tissue loss angle,which quantifies energy dissipation across frequencies,serves as the criterion for frequency selection.A multi-tissue-layer circuit model of the human body that incorporates current and voltage distributions is developed.Accordingly,the power distribution in the power transfer link and the system efficiency are analyzed to identify the parameters that affect the transcutaneous link's energy transfer performance. To address the specific requirements of the multi-layer tissue circuit model,the coupler is designed,and its transmission characteristics are investigated.Firstly,the insulation layer thickness is optimized using power transfer efficiency as the criterion.The insulation layer thickness is selected,and the resonant frequency is determined to be 3 MHz.Then,the S-S compensation circuit is designed to clarify the influence on the power transfer link.Ultimately,the power-transfer capacity of the designed coupler is examined.The results show that the designed coupler is insensitive to transmitter separation and to misalignment in the X and Y directions,making it suitable for subcutaneous implants. To ensure the safety of the transcutaneous power transfer link,a safety assessment is conducted on the designed coupler.Using IEEE C95.1 as the safety criterion,the safety assessment is based on the electric field's specific absorption rate in COMSOL.The energy transfer capabilities at different frequencies are compared.Subsequently,the tissue temperature rise is evaluated using the temperature field simulation.The tissue temperature rise during one hour of charging is under 0.789℃,which meets the IEEE C95.1 thermal safety regulations. An experimental platform using fresh pork is set up.The optimized coupler design is verified through comparative experiments with insulating layers of different thicknesses.The simulation,analytical calculation,and experimental results agree well with the proposed circuit model.The power delivered to the load is 107 mW,and the link efficiency is 45.48%,thereby verifying the excellent energy transmission capability of the designed coupler.

蔡春伟;陈天;武帅;焦宇杰;刘希琛

哈尔滨工业大学(威海)新能源学院 威海 264209||青岛哈尔滨工业大学(威海)研究院 青岛 266109国网湖北省电力有限公司武汉供电公司 武汉 430010哈尔滨工业大学(威海)新能源学院 威海 264209||青岛哈尔滨工业大学(威海)研究院 青岛 266109哈尔滨工业大学(威海)新能源学院 威海 264209哈尔滨工业大学(威海)新能源学院 威海 264209

信息技术与安全科学

人体植入式设备无线电能传输经皮电场耦合模型建立与设计

Human implantable deviceswireless power transfertranscutaneous electric field couplingmodeling and design

《电工技术学报》 2026 (10)

3260-3272,13

山东省重大科技创新工程(2022ZLGX04)、国家自然科学基金(52571379)和山东省泰山学者青年专家基金(tsqnz20240801)资助项目.

10.19595/j.cnki.1000-6753.tces.241219

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