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一种小尺寸磁谐振耦合无线能量传输系统的实验研究(英文) 被引量:7

The Experimental Research on a Small Size Magnetic Coupling Resonance Wireless Energy Transmission System
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摘要 随着科技的进步,越来越多的小型家用电器、体内植入器件等电子设备得到广泛应用。但能量供应问题制约了设备的发展,尤其是体内植入器件,电池的续航问题未得到有效的解决。磁耦合谐振无线能量传输技术作为一种新的无线能量传输方式,能够实现中距离传输电能,可解决上述问题。本文应用Ansoft软件对磁耦合谐振系统工作时的电场分布进行仿真分析,同时将系统放置于空气、模拟人体组织液、新鲜猪肉中进行实验,对系统传输效率进行实验研究。实验表明系统可以在上述环境中满足体内植入器件等用电设备的供电需求,能有效解决植入器件的能量续航问题,具有广阔的应用前景。 With the progress of technology, more and more small household electrical appliances, implanted devices and other electronic equipment have been widely used. But energy supply problem has restricted the development of electronic equipment, especially the implanted device. As a new wireless energy transmission mode, magnetic coupling resonance wireless energy transmission system can realize the middle distance power transmission that can solve the problems above. In this paper, Ansoft software was used to simulate the electric field distribution of the magnetic coupling resonance system. At the same time experiments were carried out to place the system into air, simulating human tissue fluid and a piece of pork respectively to compute the transmission efficiency. The result shows that the system can satisfy the power requirement of implanted device, which has a broad application prospect.
作者 杨新生 赵军 徐桂芝 李煊 李伟 李阳
机构地区 河北工业大学电磁场与电器可靠性省部共建重点实验室 天津工业大学电工电能新技术天津市重点实验室
出处 《电工技术学报》 EI CSCD 北大核心 2016年第2期13-17,共5页 Transactions of China Electrotechnical Society
基金 Project Supported by the Naional Natural Science Foundation of China(51407058 5207106) Research project of science and technology in Hebei Province(QN2014072)
关键词 能量传输 体内植入器件 磁耦合谐振 小型谐振器 传输效率对比 Wireless energy transfer, vivo implanted device, magnetic coupling resonance, smallsized resonator, transmission efficiency
分类号 TM15 [电气工程—电工理论与新技术] TM72 [电气工程—电力系统及自动化]
  • 相关文献

参考文献9

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二级参考文献17

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共引文献123

同被引文献37

  • 1徐栋,王冬青.磁共振无线电能传输系统的共振频率跟踪控制[J].自动化与仪器仪表,2020(4):20-24. 被引量:4
  • 2赵军,杨新生,徐桂芝,李阳.Witricity系统对作用于人体胸腔电磁环境的研究(英文)[J].电工技术学报,2013,28(S2):200-203. 被引量:2
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引证文献7

二级引证文献13

电工技术学报
2016年 第2期

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