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A. Mahmood, A. Ismail, Z. Zaman, H. Fakhar, Dr.Zeeshan Najam, M. Hasan, Saeed Ahmed (2014)
A Comparative Study of Wireless Power Transmission Techniques
Yuichi Nagatsuka, N. Ehara, Y. Kaneko, S. Abe, T. Yasuda (2010)
Compact contactless power transfer system for electric vehiclesThe 2010 International Power Electronics Conference - ECCE ASIA -
Seungyong Shin, Jaegue Shin, Boyune Song, Seokhwan Lee, Yangsu Kim, Guho Jung, Seongjeub Jeon (2013)
Wireless power transfer system for high power application and a method of segmentation2013 IEEE Wireless Power Transfer (WPT)
T. Shijo, K. Ogawa, S. Obayashi (2015)
Optimization of thickness and shape of core block in resonator for 7 kW-class wireless power transfer system for PHEV/EV charging2015 IEEE Energy Conversion Congress and Exposition (ECCE)
Takahiro Kudo, Takahiro Toi, Y. Kaneko, S. Abe (2014)
Contactless power transfer system suitable for low voltage and large current charging for EDLCs2014 International Power Electronics Conference (IPEC-Hiroshima 2014 - ECCE ASIA)
(2008)
Simulation and experimental analysis on wireless energy transfer on magnetic resonances
L. Tan, S. Pan, Xueliang Huang, Changfu Xu (2017)
System optimization for wireless power transfer system with double transmitters2017 IEEE PELS Workshop on Emerging Technologies: Wireless Power Transfer (WoW)
(2001)
Contactless battery charger with wireless control link
T. Bechtold, J. Acevedo, D. Hohlfeld (2017)
Compact model of a wireless power transfer system2017 IEEE Wireless Power Transfer Conference (WPTC)
B. Dursun, E. Kurt, Mehmet Tekerek (2019)
A power circuit design for the poloidal field coils in a torus shaped plasma systemJournal of Energy Systems
M. Chigira, Yuichi Nagatsuka, Y. Kaneko, S. Abe, T. Yasuda, Akira Suzuki (2011)
Small-size light-weight transformer with new core structure for contactless electric vehicle power transfer system2011 IEEE Energy Conversion Congress and Exposition
M. Frah, V. Belyaev (2019)
Parameters of electromagnetic pollution from different sources and their hazard impactJournal of Physics: Conference Series, 1309
B. Minnaert, N. Stevens (2018)
Maximizing the Power Transfer for a Mixed Inductive and Capacitive Wireless Power Transfer System2018 IEEE Wireless Power Transfer Conference (WPTC)
Sheik Ramasamy, T. Shanmuganantham, Ben Johnston, W. Brown, J. Mims, L. Epp, A. Khan, H. Smith (2010)
Wireless Power Transmission - A Next Generation Power Transmission SystemInternational Journal of Computer Applications, 1
Wanmei Feng, Nan Zhao, Shaopeng Ao, Jie Tang, Xiuyin Zhang, Yuli Fu, D. So, Kai‐Kit Wong (2020)
Joint 3D Trajectory Design and Time Allocation for UAV-Enabled Wireless Power Transfer NetworksIEEE Transactions on Vehicular Technology, 69
(2003)
System for wirelessly supplying a large number of actuators of a machine with electrical power
(2017)
Geoengineering Tesla’s Wireless Power Transmission
S. Syaza, Roslan Umar, S. Hazmin, M. Kamarudin, Abdul Hassan, H. Juahir (2018)
Non-ionizing radiation as threat in daily lifeJournal of Fundamental and Applied Sciences, 9
ヒュプナー・ブルクハルト (2009)
Apparatus for transmitting electrical energy
Stephen Brown, David Pyke, P. Steenhof (2010)
Electric vehicles: The role and importance of standards in an emerging marketEnergy Policy, 38
I. Mahariq, S. Beryozkina (2019)
Experimental realization of electromigration at high power for copper wires, 3
Xiaoyu Liu, Fei Zhang, S. Hackworth, R. Sclabassi, Mingui Sun (2009)
Modeling and simulation of a thin film power transfer cell for medical devices and implants2009 IEEE International Symposium on Circuits and Systems
R. Moffatt (2009)
Wireless transfer of electric power
Tobias Diekhans, R. Doncker (2014)
A dual-side controlled inductive power transfer system optimized for large coupling factor variations2014 IEEE Energy Conversion Congress and Exposition (ECCE)
Ryota Inoue, D. Miyagi, M. Tsuda, H. Matsuki (2017)
High-Efficiency Transmission of a Wireless Power Transmission System for Low-Frequency Using REBCO Double-Pancake CoilsIEEE Transactions on Applied Superconductivity, 27
In this study, a low frequency wireless power transfer (LFWPT) device has been designed and implemented. The aim of investigation of low frequency system is to eliminate the un-healthy situation due to non-ionized radiation of the high frequency regimes. The transmitter uses a special winding to transmit the electromagnetic signals to the environment, especially for a few centimeters distance. The receiver winding, which is the same with the transmitter winding catches the signal and stores it in capacitor. The system uses maximum 17,649 Hz to transmit the signal, that is fairly low compared to the other studies in the literature. A DC-AC inverter is used to obtain high frequency signals for the transmitter circuit. The experiments have proven that the receiving antenna can get 1 V amplitude from the transmitted peak-to-peak amplitude of 140 V at the operation frequency.
Technology and Economics of Smart Grids and Sustainable Energy – Springer Journals
Published: May 17, 2021
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