Title :
Inductive Power Transfer System With Self-Calibrated Primary Resonant Frequency
Author :
Trigui, Aref ; Hached, Sami ; Mounaim, Faycal ; Ammari, Ahmed Chiheb ; Sawan, Mohamad
Author_Institution :
Electr. Eng. Dept., Polytech. Montreal, Montreal, QC, Canada
Abstract :
Inductive power transfer (IPT) is a commonly employed technique for wirelessly supplying power to implantable medical devices. A major limit of this approach is the sensitivity of the inductive link to coupling factor variations between transmitting and receiving coils. We propose in this paper a new method for compensating these variations and improving the inductive link efficiency. The proposed technique is based on a mechatronic module that dynamically tunes the primary resonant capacitor value in order to maintain the resonance state of the IPT system. The module is able to maintain resonance state for apparent primary inductance range at least from 0.5 to 5 μH using a high capacitance resolution of 0.032 pF. Experimentations conducted on a 13.56MHz IPT system showed a 65% higher power transfer compared to a traditional IPT system.
Keywords :
circuit tuning; inductive power transmission; capacitance 0.032 pF; coupling factor variations; frequency 13.56 MHz; implantable medical device; inductive link; inductive power transfer; mechatronic module; primary inductance range; primary resonant capacitor value tuning; resonance state; self-calibrated primary resonant frequency; Capacitance; Capacitors; Coils; Couplings; Logic gates; RLC circuits; Resonant frequency; Class E amplifier; Feedback circuits; Implantable biomedical devices; Inductive power transmission; feedback circuits; implantable biomedical devices; inductive power transmission;
Journal_Title :
Power Electronics, IEEE Transactions on
DOI :
10.1109/TPEL.2015.2399417
