Title :
A Double-Sided LCLC-Compensated Capacitive Power Transfer System for Electric Vehicle Charging
Author :
Fei Lu ; Hua Zhang ; Hofmann, Heath ; Mi, Chris
Author_Institution :
Electr. Eng. & Comput. Sci. Dept., Univ. of Michigan, Ann Arbor, MI, USA
Abstract :
A double-sided LCLC-compensated capacitive power transfer (CPT) system is proposed for the electric vehicle charging application. Two pairs of metal plates are utilized to form two coupling capacitors to transfer power wirelessly. The LCLC-compensated structure can dramatically reduce the voltage stress on the coupling capacitors and maintain unity power factor at both the input and output. A 2.4-kW CPT system is designed with four 610-mm × 610-mm copper plates and an air gap distance of 150 mm. The experimental prototype reaches a dc-dc efficiency of 90.8% at 2.4-kW output power. At 300-mm misalignment case, the output power drops to 2.1 kW with 90.7% efficiency. With a 300-mm air gap distance, the output power drops to 1.6 kW with 89.1% efficiency.
Keywords :
electric vehicles; inductive power transmission; power factor; CPT system; capacitive power transfer system; distance 150 mm; double-sided LCLC; electric vehicle charging; power 2.4 kW; size 610 mm; unity power factor; voltage stress; Capacitance; Capacitors; Couplings; Electric fields; Inductors; Power generation; Topology; Capacitive power transfer; LCLC compensation; capacitive power transfer; electric vehicle charging;
Journal_Title :
Power Electronics, IEEE Transactions on
DOI :
10.1109/TPEL.2015.2446891
