This is a design of a bifilar coil, meaning that when this design is fabricated on a two-layer printed circuit board (PCB), there will be a single bifilar coil wired primarily on the top copper layer.
The theory is that when you drive the coil with a sine wave at its resonant frequency, it can transfer power at its greatest efficiency.
The beauty of this design is that it is parametric.
Both coils are concentric and wind in the same direction. Therefore the magnetic field from each coil section combines uniformly with the other coil resulting in a stronger, cohesive field.
Here is a diagram showing how it is wired:
This shows the various layers on a small (n=20) coil to highlight the wiring and various layers of the PCB:
In this design, coils can be created with varying trace widths, gaps between traces, and number of spirals per coil. As a result, this parametric design could theoretically be used for coils of any manufacturable size (from microscopic on up).
In this section, we will document emperically-measured resistances and resonant frequencies of fabricated coils as they become available.
Coil 1 consists of:
PCB thickness = 1.6mm
trace width = 0.15mm (6 mils)
gap width = 0.15mm
number of coils per spiral = 100
| From point | To point | DC resistance (Ω) | Inductance (mH) | Resonant Frequency (Hz) |
|---|---|---|---|---|
| TR | TR/TL | 91.2 | ||
| TR/TL | TL | 91.2 | ||
| TR | TL | 179.8 | 2.9 |
Enjoy!
Copyright 2019 Glenn M. Lewis. All Rights Reserved.
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