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Lenz's law states that when a moving magnet passes a wire coil, it induces a current that causes an opposition magnetic field to appear in the output coil. The output coil's induced opposition field repels the passing magnet creating drag. A "two pole" rotating magnet spinner causes the output coil's poles to shift from one side to the other side of the coil. Lenz propulsion phase shift occurs when the spinner rotates a little faster then the output coil can switch it's poles; For a 1" spinner around 20k for a ferrite bifilar series wrap. Less r.p.m with multiple rotor magnets.
Coil capacitance, is a consequence of self induction, and directly proportional to the Lenz delay phase shift. The output coil's Capacitive reactance, slows the output coil's ability to shift it's poles fast enough to sustain the drag lag: Thus, This slowing reactance allows the high speed spinner to edge out in front of TDC, catching a push.
A second way, is to position one or more diametric ring or tube magnets attached end to end, snugly inside the core of a bifilar series wrap output coil. Magnetic interferance now retards the output coil's pole shift instead of it's capacitive reactance. A second charge effect now augments the Lenz delay propulsion. I call this the "Dragone" effect, of power generated by the core magnet's field see sawing over the output coil's windings.
Overunity's Lynxstream Joule Motor sends a backspike to a secondary output coil by Zener diode, and his motor seems to accelerate as if the Lenz propulsion r.p.m threshold is greatly reduced. I theorized that the BEMF is charging the seconday output coil above it's natural capacitive potential, causing Lenz delay with a third possible approach. Here's Lynxstream's latest video of an acceleration effect:
Lynx Joule Motor 3 - YouTube
My tests have demonstrated that multiple output coils merely divide the available output along with the Lenz propulsion effect. One diametric ring magnet's core hi-voltage bifilar spool output coil is all one needs to go OU, with the output looped back to source, via FWBR, for a load. Axially magnentized rings will not work.
Coil capacitance, is a consequence of self induction, and directly proportional to the Lenz delay phase shift. The output coil's Capacitive reactance, slows the output coil's ability to shift it's poles fast enough to sustain the drag lag: Thus, This slowing reactance allows the high speed spinner to edge out in front of TDC, catching a push.
A second way, is to position one or more diametric ring or tube magnets attached end to end, snugly inside the core of a bifilar series wrap output coil. Magnetic interferance now retards the output coil's pole shift instead of it's capacitive reactance. A second charge effect now augments the Lenz delay propulsion. I call this the "Dragone" effect, of power generated by the core magnet's field see sawing over the output coil's windings.
Overunity's Lynxstream Joule Motor sends a backspike to a secondary output coil by Zener diode, and his motor seems to accelerate as if the Lenz propulsion r.p.m threshold is greatly reduced. I theorized that the BEMF is charging the seconday output coil above it's natural capacitive potential, causing Lenz delay with a third possible approach. Here's Lynxstream's latest video of an acceleration effect:
Lynx Joule Motor 3 - YouTube
My tests have demonstrated that multiple output coils merely divide the available output along with the Lenz propulsion effect. One diametric ring magnet's core hi-voltage bifilar spool output coil is all one needs to go OU, with the output looped back to source, via FWBR, for a load. Axially magnentized rings will not work.
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