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Input-Series Output-Equivalent-Parallel Multi-Inverter System for High-Voltage and High-Power Wireless Power Transfer

Hong Zhou, Jing Chen, Qijun Deng, Fengwei Chen, Ao Zhu, Wenshan Hu, Xingran Gao

2020IEEE Transactions on Power Electronics56 citationsDOI

Abstract

This article presents an input-series output-equivalent-parallel (ISOEP) multi-inverter system for high-power wireless power transfer (WPT), where preisolation dc/dc converter is concealed to achieve higher efficiency, and the number of inverter modules is allowed to be flexibly adjusted to satisfy different voltage and power requirements. The main contribution of this article is to analyze the possible factors that may lead to voltage unbalance in the series inverters of the proposed ISOEP multi-inverter topology. At the same time, the dividing capacitor suppression and duty cycle adjustment are adopted to achieve input voltage sharing. To confirm and validate the effectiveness and merit of the proposed WPT system, a prototype consisting of three inverters connected in series was designed, built, and tested. Experiments show that the proposed topology achieved both high-power output and effective input voltage sharing. The maximum output power is 38.37 kW with an efficiency of 89.31%.

Topics & Concepts

Duty cycleInverterCapacitorTopology (electrical circuits)Wireless power transferPower (physics)Electronic engineeringVoltageSeries and parallel circuitsEngineeringMaximum power transfer theoremElectrical engineeringComputer scienceControl theory (sociology)PhysicsElectromagnetic coilQuantum mechanicsArtificial intelligenceControl (management)Wireless Power Transfer SystemsEnergy Harvesting in Wireless NetworksAdvanced Battery Technologies Research
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