Simulation and Experiment Research of a New Small Size Resonator Used in Magnetic Coupling Resonance Wireless Energy Transmission System
ZhaoJun1, Xu Guizhi1, Zhang Chao2, Li Xuan1, Chen Yun1
1. Province-Ministry Joint Key Laboratory of Electromagnetic Field and Electrical Apparatus Reliability Hebei University of Technology Tianjin 300130 China; 2. Institute of Electrical Engineering Chinese Academy of Science Beijing 100190 China
Abstract:Magnetic coupling resonance wireless energy transmission is a new technology, which provides fast, convenient and safe energy supply for small size household electrical appliances, body implanted devices and so on. In this technology, it is necessary to design small size resonators for the above devices for energy transfer. Here, a new kind small size resonator, which is 1.35 cm3 in volume, is designed. This design is based on the coupled-mode theory (CMT), which is applied to explain the magnetic coupling resonance system’s transmission rule. Extensive simulations have been conduced to validate the design. The Ansoft software is used in the simulation of the resonator’s resonance frequency. The relationships between resonator parameters and resonant frequency are obtained. It is found that the simulations are consistent well with experimental results and the resonator can meet the requirements of small size electrical appliances.
赵军, 徐桂芝, 张超, 李烜, 陈韵. 一种适用于磁耦合谐振无线能量传输系统的新型小尺寸谐振器的仿真与实验[J]. 电工技术学报, 2014, 29(1): 208-214.
ZhaoJun, Xu Guizhi, Zhang Chao, Li Xuan, Chen Yun. Simulation and Experiment Research of a New Small Size Resonator Used in Magnetic Coupling Resonance Wireless Energy Transmission System. Transactions of China Electrotechnical Society, 2014, 29(1): 208-214.
[1] 杨庆新, 陈海燕, 徐桂芝, 等. 无接触电能传输技术的研究进展[J]. 电工技术学报, 2010, 25(7): 6-13. Yang Qingxin, Chen Haiyan, Xu Guizhi, et al. Research progress in contactless power transmission technology[J]. Transactions of China Electro- technical Society, 2010, 25(7): 6-13. [2] Kurs A, Karalis A, Moffatt R, et al. Wireless power transfer via strongly coupled magnetic resonances[J]. Science, 2007, 317: 83-86. [3] Zhang Xian, Yang Qingxin, Chen Haiyan, et al. The application of non-contact power transmission technology(NPT) in the modern transport system[C]. Mechatronics and Automation(ICMA), 2010: 345-349. [4] Karalis A, Joannopoulos, Soljacic M. Efficient wireless non-radiative mid-range energy transfer[J]. Analysis of Physics, 2008, 323: 34-48. [5] Yang Qingxin, Xu Guizhi, Jin Jianqiang. Optimal design of energy transmission system for implantable device base on WiTricity[C]. Electromagnetic Field Computation(CEFC), 2010: 10-13. [6] Liu X, Zhang F, Hackworth S A, et al. Modeling and simulation of a thin film cell for power transfer to medical devices and implants[C]. IEEE International. Symposium on Circuits and Systems, 2009(5): 24-27. [7] Liu X, Zhang F, Hackworth SA, et al. Wireless power transfer system design for implanted and worn devices[C]. 35th IEEE Northeast Biomedical Enginee- ring Conference, 2009(7): 3-5. [8] Zhang F, Liu X, Hackworth SA, et al. In vitro and in vivo studies on wireless powering of medical sensors and implantable devices[C]. IEEE-NIH 2009 Life Science Systems and Applications Workshop, 2009(3): 9-10. [9] Zhuo Yan, Chao Zhang, Haiyan Chen, Qingxin Yang, Sumei Yang. Simulation analysis on detachable transformer in contactless electrical energy trans- mission system[C]. International Conference on Electrical Machines and Systems.(ICEMS2010), 2010: 1777-1780.
2014, Vol. 29 
