%0 Journal Article %T Design and Development of High Efficiency 150 kW Very Compact PLA Core Electromagnetic Coupler for Highly Resonant Power Transfer Technology %A Fatima Zahra Boudara %A Marc Rivaletto %A Laurent Pecastaing %A Antoine Silvestre de Ferron %A Sylvain Paquet %A Jean-Pierre Brasile %J Journal of Electromagnetic Analysis and Applications %P 131-144 %@ 1942-0749 %D 2020 %I Scientific Research Publishing %R 10.4236/jemaa.2020.129011 %X Highly Resonant Power Transfer (HRPT) technology is currently receiving very significant attention from the industry and the smart power grid distribution community in particular. This technology ensures electrical power transmission between two points while controlling the level of transmitted power and ensures the immediate shutdown of the transmitted power in the event of a problem. This paper reviews the inductive power transfer method and describes the design of an ultra-compact PLA core electromagnetic coupler. The proposed architecture confines the magnetic field in a toroidal PLA core transformer, and by avoiding the use of heavy and bulky shielding plates, reduces magnetic losses and avoids the Curie point. As a result, the overall unit has a weight of 5 kg and a volume of only 0.013 m3. The electromagnetic coupler is capable of transferring a peak power of 150 kW with an operating frequency of 193 kHz, giving a satisfactory efficiency of 95%. The proposed novel system was first investigated through CST 3D numerical modelling to determine the electrical parameters of the coupler¡¯s equivalent circuit and its efficiency, to verify its compatibility with the ICNIRP 2010 standard and to evaluate its temperature rise with an air-cooling system. Afterwards, the designed coupler was built with a 3D printing device and finally tested experimentally. Simulation and experimental results are compared and show a good agreement. %K PLA Core %K Toroidal Coupler %K Resonant System %K Low Stray Emission %K Smart Grid %U http://www.scirp.org/journal/PaperInformation.aspx?PaperID=103338