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Position-Independent Constant Current or Constant Voltage Wireless Electric Vehicles Charging System Without Dual-Side Communication and DC–DC Converter

Lihao Wu, Bo Zhang, Yanwei Jiang

2021IEEE Transactions on Industrial Electronics68 citationsDOI

Abstract

In this article, a robust wireless power transfer (WPT) system considering a wide variation in load resistance and coupling coefficient is proposed for electric vehicles charging. Here, a new implementation of the parity-time (PT)-symmetric circuit using a phase synchronization method is presented, in which a power-adjustable negative resistor is constructed only by a single-stage inverter. Moreover, based on the PT-symmetric circuit, a control strategy that does not require dual-side communication and extra dc–dc converters is developed for battery charging. Theoretical analysis shows that constant current (CC) and constant voltage (CV) outputs independent of load and position can be achieved, and the charging mode can be switched automatically. A scaled-down prototype with an 8-A charging current and a 120-V charging voltage is built to verify the feasibility of the proposed method. Experimental results demonstrate that within the transfer distance of 10–25 cm, the CC/CV outputs can be maintained during the charging process.

Topics & Concepts

Wireless power transferConstant currentResistorElectrical engineeringVoltageCoupling coefficient of resonatorsElectric vehicleInductive chargingMaximum power transfer theoremConvertersInverterControl theory (sociology)Power (physics)Computer scienceEngineeringPhysicsElectromagnetic coilArtificial intelligenceControl (management)Quantum mechanicsResonatorWireless Power Transfer SystemsEnergy Harvesting in Wireless NetworksInnovative Energy Harvesting Technologies
Position-Independent Constant Current or Constant Voltage Wireless Electric Vehicles Charging System Without Dual-Side Communication and DC–DC Converter | Litcius