O.H. Stielau scite author profile

Loosely coupled inductive power transfer (LCIPT) systems are designed to deliver power efficiently from a stationary primary source to one or more movable secondary loads over relatively large air gaps via magnetic coupling. In this paper, a general approach is presented to identify the power transfer capability and bifurcation phenomena (multiple operating modes) for such systems. This is achieved using a high order mathematical model consisting of both primary and secondary resonant circuits. The primary compensation is deliberately designed to make the primary zero phase angle frequency equal the secondary resonant frequency to achieve maximum power with minimum VA rating of the supply. A contactless electric vehicle battery charger was used to validate the theory by comparing the measured and calculated operational frequency and power transfer. For bifurcation-free operation, the power transfer capability and controllability are assured by following the proposed bifurcation criteria. Where controllable operation within the bifurcation region is achievable, a significant increase in power is possible.

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Design of loosely coupled inductive power transfer systems

Stielau

Covic

264

107

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Investigating an LCL Load Resonant Inverter for Inductive Power Transfer Applications

Wang

Covic

Stielau

2004

IEEE Trans. Power Electron.

216

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The design of a contact-less energy transfer system for a people mover system

et al.

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O.H. Stielau

Design Considerations for a Contactless Electric Vehicle Battery Charger

Power Transfer Capability and Bifurcation Phenomena of Loosely Coupled Inductive Power Transfer Systems

Design of loosely coupled inductive power transfer systems

Investigating an LCL Load Resonant Inverter for Inductive Power Transfer Applications

The design of a contact-less energy transfer system for a people mover system

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