Mid-Range Wireless Power Transfer at 100 MHz using Magnetically-Coupled Loop-Gap Resonators

TL;DR

This paper presents a highly efficient 100 MHz inductive power transfer system using magnetically-coupled loop-gap resonators that confine electric fields and are immune to interference, demonstrating effective power transfer up to 32 W.

Contribution

The study introduces the use of electrically-small, high-Q loop-gap resonators for mid-range wireless power transfer, highlighting their advantages over traditional resonators and demonstrating practical implementation.

Findings

Efficient power transfer at 100 MHz with minimal interference.

Toroidal LGR geometry offers improved magnetic flux confinement.

System successfully transfers up to 32 W of power.

Abstract

We describe efficient four-coil inductive power transfer (IPT) systems that operate at 100 MHz. The magnetically-coupled transmitter and receiver were made from electrically-small and high-Q loop-gap resonators (LGRs). In contrast to the commonly-used helical and spiral resonators, the LGR design has the distinct advantage that electric fields are strongly confined to the capacitive gap of the resonator. With negligible fringing electric fields in the surrounding space, the IPT system is immune to interference from nearby dielectric objects, even when they are in close proximity to the transmitter and/or receiver. We experimented with both cylindrical and split-toroidal LGR geometries. Although both systems performed well under laboratory conditions, the toroidal geometry has the additional advantage that the magnetic flux is weak everywhere except within the bore of the LGR and in the space directly between the transmitter and receiver. Furthermore, we show that the toroidal LGR system can be operated efficiently at a fixed frequency for a wide range of transmitter-receiver distances. The experimental results are complimented by 3-D finite-element simulations which were used to investigate the electromagnetic field profiles and surface current density distributions. Finally, we demonstrate the use of our IPT system at powers up to 32 W and discuss possible applications.