Oscillating sine wave LC tank magnet motor.

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The C/CCW feature would allow two turntable motors to power a tube rotor from each end after the gears were removed; Turning in opposite directions for double (Posi-Traction) power. The two motors could also power the rotor from one side while simultaneously generating 220volts from the other.

The turntable rotor magnet turned out not be diametric after all. A small collar bushing between the magnets would solve any unwanted repulsion problems.

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Microwave Turntable Motor Test:

https://vimeo.com/33734382

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A ferrite toroid ring with a light indctance suppressing D.C. wrap, covered with layers of magnet wire large enough to pass the diametric tube through, would have the right direction of the copper wire to face the rotor magnet field.

I think the toroid power coil would handle the distribution of A.C. oscillation best. One of my High Voltage bifilar spirals would maximize the A.C. influence, and has already proven to be a superior design. We need to tie a tank capacitor into the spiral coil to deliver a resonant frequency of 60 hertz.  We can generate 220 volts with the the turntable motors while powering the tube rotor with A.C. with our experimental "LC Tank Assistance". The motor generator would loop and run itself if the power coil tank oscillation did work assisting the A.C. input.

The two turntable motors can send their 220 volt output directly to the "Hi-Voltage Power Spiral" at 60 hertz. Feeding a small amount of power to the LC tank may sustain the rotor speed. Tinman's super capacitor might help do it.

There's two ways to power the large spiral: Through a Dimmer Switch directly from the A.C. wall socket, or pulsing D.C. through a transformer into the LC tank capacitor.

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The "Primary Transformer Wire" from the Microwave transformer is the correct gauge wire for the spiral, or the facing solenoids in parallel, to handle the high voltage wall current. The thicker wire and larger magnet rotor provides drive advantage to the Hi-Voltage side of the circuit. Both types are air core coils with fixed capacitance and resonant frequency.

Naturally, both input circuits, wall current and turntable output, would need diodes positioned to protect each from the other.

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Closer scrutiny has uncovered that the Turntable rotor magnet has a "6 pole, side to side, N.S. polarization". The turntable rotor's only spinning at 600 R.P.M. as a result; The larger rotor needs 6 N.S. poles also, to match the R.P.M. and run as A.C. synchronous. There are a number of different ways to handle that. A small 6 magnet N.S pole wheel sandwiched between PVC couplings glued to the turntable magnets would work well. 600 R.P.M'S is low enough to help keep the friction bearing cool with the increased weight of the larger wheel.

This kind of motor grows more efficient under load. Taxing it with ouput burden from the beginning should help. These motors come in the 120 volt variety too. The microwave transformer primary wire from the 120 volt oven, or an equivalent gauge, would be needed to wrap the larger A.C. solenoid power coils for the 120 volt input from the turntable generators. We need to place diodes between the generator output wires and the coils, along with the wires conducting the direct A.C. input.

The auxiliary LC tank is a seperate circuit.

We can run the large 6 pole rotor directly from 120 volt wall current through a dimmer switch with the turntable output looped. Start off with a zero power setting, and slowly turn it up and see how the motor reacts to feeding itself it's own output.

Apparently the turntable rotor magnet comes in an 8 pole variety. Naturally, if you buy a pair it should be easy to test the magnet poles and decide if you need a 6 or 8 pole N.S. magnet rotor. This 8 pole version lowers the 60 hertz 6 pole R.P.M. from 600 to 450.