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Hi,
Making well balanced IB coils at home was always too difficult for me to do at home. That's why I decided to design an inductively balanced PCB coil for a PI detector. On the top layer there are two separate TX coils (9.5" x 4") wound in opposite direction connected in series and on the bottom layer there's a 4" RX coil. Entire design is completely symmetrical so induction balance is achieved by geometry of the coil.
The parameters of the PCB coil are:
- Overall dimensions: 10" x 10";
- TX inductance: ~ 300 uH;
- TX resistance: 19 Ohm
- RX inductance: ~ 1 mH
- RX resistance: 95 Ohm;
Some benefits of a PCB coil are less interwinding capacitance and the extremely low weight of the coil.
I'm going to drive the TX with a square current wave circuit.
Any ideas of more improvements/optimizations are welcomed.
Making well balanced IB coils at home was always too difficult for me to do at home. That's why I decided to design an inductively balanced PCB coil for a PI detector. On the top layer there are two separate TX coils (9.5" x 4") wound in opposite direction connected in series and on the bottom layer there's a 4" RX coil. Entire design is completely symmetrical so induction balance is achieved by geometry of the coil.
The parameters of the PCB coil are:
- Overall dimensions: 10" x 10";
- TX inductance: ~ 300 uH;
- TX resistance: 19 Ohm
- RX inductance: ~ 1 mH
- RX resistance: 95 Ohm;
Some benefits of a PCB coil are less interwinding capacitance and the extremely low weight of the coil.
I'm going to drive the TX with a square current wave circuit.
Any ideas of more improvements/optimizations are welcomed.
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