• DocumentCode
    2625419
  • Title

    Structure of handheld resonant magnetic coupling charger (HH-RMCC) for electric vehicle considering electromagnetic field

  • Author

    Chiuk Song ; Hongseok Kim ; Sunkyu Kong ; Jung, Daniel H. ; In-Myoung Kim ; Young-il Kim ; Jonghoon Kim ; Joungho Kim

  • Author_Institution
    Div. of Future Vehicles, Korea Adv. Inst. of Sci. & Technol. (KAIST), Daejeon, South Korea
  • fYear
    2013
  • fDate
    15-16 May 2013
  • Firstpage
    131
  • Lastpage
    134
  • Abstract
    Inductive charging is a convenient method to transfer electrical power from a source to the batteries without any electrical contact. The problem is that inductive charging technologies may have electromagnetic compatibility (EMC) issues caused by leakage magnetic field. In this paper, an inductive charger design for electric vehicles (EVs) named as Handheld Resonant Magnetic Coupling Charger (HH-RMCC) is proposed. The air gap and thickness of the ferrite core are determined considering the core saturation and leakage magnetic field. The maximum value of the simulated magnetic flux density at the distance of 200 mm away from the charger is 2.28 mG and the simulation result of the power transfer efficiency is approximately 99.5%. The simulation results using 3D Finite Element Analysis (FEA) tool show that HH-RMCC satisfies EMF regulation published by the International Commission on NonIonizing Radiation and Protection (ICNIRP) at the frequency of 20 kHz with high performance.
  • Keywords
    battery powered vehicles; electromagnetic compatibility; electromagnetic fields; inductive power transmission; 3D FEA tool; 3D finite element analysis tool; EMC issue; EMF regulation; HH-RMCC structure; ICNIRP; International Commission on NonIonizing Radiation and Protection; air gap; core saturation; electric vehicle; electric vehicles; electrical contact; electrical power transfer; electromagnetic compatibility; electromagnetic field; ferrite core thickness; handheld resonant magnetic coupling charger; inductive charger design; inductive charging technology; leakage magnetic field; power transfer efficiency; simulated magnetic flux density; Couplings; Ferrites; Magnetic cores; Magnetic fields; Magnetic resonance; Saturation magnetization; Windings; Electromagnetic compatibility; electromagnetic fields; inductive charger; magnetic field resonance;
  • fLanguage
    English
  • Publisher
    ieee
  • Conference_Titel
    Wireless Power Transfer (WPT), 2013 IEEE
  • Conference_Location
    Perugia
  • Print_ISBN
    978--14673-5008-2
  • Type

    conf

  • DOI
    10.1109/WPT.2013.6556900
  • Filename
    6556900