Abstract
In a traditional inductive coupling power transfer (ICPT) system, the converter and the resonant network are strongly coupled. Since the coupling coefficient and the parameters of the resonant network usually vary, the resonant network easily detunes, and the system efficiency, power source capacity, power control, and soft switching conditions of the ICPT system are considerably affected. This paper presents an ICPT system based on a power converter decoupled from the resonant network. In the proposed system, the primary inductor is disconnected from the resonant network during the energy injection stage. After storing a certain amount of energy, the primary inductor is reconnects with the resonant network. Through this method, the converter can be decoupled from the resonant network, and the resonant network can be tuned under various coupling coefficients. Theoretical analysis was explored first. Simulations and experimental work are carried out to verify the theoretical analysis. The results show that the proposed ICPT system has the virtues of low power source capacity, independent power control, and soft switching operation under different coupling coefficients.
Highlights
Since the late 2000s, inductive coupling power transfer (ICPT) has been widely used for wireless energy transmission over large air gaps [1,2,3,4,5]
We found that the bus current iB and the primary current ip increase linearly in the energy injection stage τ 1, which shows that the primary inductor is completely decoupled from the resonant tank
We found that the bus current iB and the primary current ip increase linearly in the energy injection stage τ1, which shows that the primary inductor is completely decoupled from the resonant tank
Summary
Lin Chen 1,2 , Jianfeng Hong 1,3,4 , Mingjie Guan 1 , Wei Wu 1,5 and Wenxiang Chen 1,3,4, *.
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