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I am wondering why the focus on multi-filar wound coils, and the seperate transistors for each wire?
Is the idea similar to Paul Babcock's experiment with radiant energy driving a plasma discharge? He gives a first guess at a number of watts per unit length of wire, based on his 8500' coil.
I thought of a test, which is to make two coils of as nearly equal form, inductance, and resistance as possible. One would use a single larger gauge wire and the other an equivalent size litz wire winding. Discharge these two into a large capacitor bank for a finite number of pulses, and see if there is any difference in the rise time of the capacitors. The question to be answered is: Which is the important factor in gethering radiant energy, the length of the magnetic path (as in Babcok's long thin coil wire), or the total length of the wires (as in Bedini's stranded coils, even though the strands are paralleled)?
As for the use of seperate transistors and diodes for each strand, it can't be because of the power levels. My drive input power is less than 10W, and that is certainly well inside the range of one device. If the turn off time is enhanced using multiple paths, that would reason enough, but I can't see why a single device would not be equivalent, given that there are plenty of fast diode and transistors in the world. I am going to look at the wave form and compare as I take and parallel the windings down to just one of the transistors.
I am using FETs and a PWM driver, so there is a slight difference in the circuit from the SG, but otherwise it has comparable function.
If anyone has done these tests, I would like to hear.
Thanks.
Is the idea similar to Paul Babcock's experiment with radiant energy driving a plasma discharge? He gives a first guess at a number of watts per unit length of wire, based on his 8500' coil.
I thought of a test, which is to make two coils of as nearly equal form, inductance, and resistance as possible. One would use a single larger gauge wire and the other an equivalent size litz wire winding. Discharge these two into a large capacitor bank for a finite number of pulses, and see if there is any difference in the rise time of the capacitors. The question to be answered is: Which is the important factor in gethering radiant energy, the length of the magnetic path (as in Babcok's long thin coil wire), or the total length of the wires (as in Bedini's stranded coils, even though the strands are paralleled)?
As for the use of seperate transistors and diodes for each strand, it can't be because of the power levels. My drive input power is less than 10W, and that is certainly well inside the range of one device. If the turn off time is enhanced using multiple paths, that would reason enough, but I can't see why a single device would not be equivalent, given that there are plenty of fast diode and transistors in the world. I am going to look at the wave form and compare as I take and parallel the windings down to just one of the transistors.
I am using FETs and a PWM driver, so there is a slight difference in the circuit from the SG, but otherwise it has comparable function.
If anyone has done these tests, I would like to hear.
Thanks.
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