Kapanadze Cousin - DALLY FREE ENERGY

[corry]

Hi to All

If this is true: (from http://prezi.com/fiwgtl78it85/donz-device/)

[d3x0r]

Hi to All

50 hz resonance requires a LOT more turns than 50 with 470n. So no.
Power supply does not need 50hz, but is likely to work up to a few hundred kilohertz; but even so the bridge before it is probably fast enough to transform the AC to DC anyway.  The powersupply isn't going to care if it's DC... will just end up using one side of its internal BR.
and F=? is probably less than 100kHz... the original NAND gate pulser doesn't adjust up that far... and only down to like 2Khz(IIRC).

[corry]

Tnx d3x0r,

maybe, you will get the 50Hz to beat, for example: f1 = 20000Hz + f2 = 19950Hz (or 20050Hz) ...

00 says:

[Void]

I did some tuning this evening, but there seems to be a strange selftuning mechanism working in this Mazzilli circuit, so any calculated value capacitance does offset things instead of improve.
Finally when trying to peak the output with some magnets in the yoke (works good) both MOSFETs popped.
Guess they just got to hot 
Anyway, not much progress today.
Regards Itsu

Sorry to hear that. That is not so fun when that happens. 

I have been experimenting with a pulser circuit, trying to find anything that
might look like 'ferromagnetic resonance', and also tested out Melnichenko's transformer which
does not give anywhere near overunity for me, but does show an interesting effect.

Also no ferromagnetic resonance found so far, but I did notice that the pulser circuit I am using breaks into major
uncontrolled oscillations when I am pulsing a coil wound on a ferrite core if I touch the frequency adjust pot's knob
while the circuit is pulsing the coil. Even with just 2 volts applied to the drain of the MOSFET, these oscillations were
producing negative peaks around 400V to 500 V peak or more on the primary winding coil being pulsed, with an expanding
trumpet waveform. I found I could also make the pulser circuit break into these same oscillations if I just ran a wire near the
coil and connected it to the control knob on the frequency adjust pot. The voltage peaks generated across the coil were so high
that it caused corona discharge arcing between the insulated magnet wire in my step up secondary winding, burning right
through the insulating coating on the magnet wire. This also caused my power supply, which is not a switching
power supply, but a regular transformer power supply with some digital control circuitry, to go completely out
of whack as well, with the meters showing much higher current and voltages than the regulated power supply
was set to. Even though the drain was only being driven with 2 volts, I had to have the current limiting
on the power supply set to limit to just about 0.3 A and I was still getting negative peaks in an increasing trumpet waveform
in pulses across the coil that were in the 400V to 500V range. I thought maybe the ground clip on my scope was causing a ground loop
or RF feedback back to the regulated power supply, so I isolated my scope from ground and these major uncontrolled
oscillations would still happen when I touched the frequency adjust knob on the pulser. I may try this again
using a battery for the power supply, but it seems the pulser circuit is prone to major unstable oscillations.
I have been connecting everything together with alligator clip test leads, so that can be a cause of making oscillator
circuits unstable. Anyway, although the huge unstable oscillations in my pulser circuit are interesting to see, it
doesn't appear to be anything related to 'ferromagnetic resonance' that I can pinpoint anyway. It just seems to be
an instability in the pulser circuit, probably enhanced by the long alligator leads I am using in my test setup.
It is odd though that the regulated power supply seems to be going berserk and outputting much higher voltages
and currents than it is set to. I will try to get a battery or two to test this with since it may be that the control
circuitry in the regulated power supply is getting messed up by the large pulses feeding back into the power supply
terminals. I tried putting chokes on the power supply lines and this reduced the tendancy for the unstable
oscillations in the pulser somewhat , but it did still happen.

[Void]

At this moment it is just stimulation as shown.

Ah OK, I see. Simulators can be very helpful when designing circuits, but they can give misleading 
results sometimes depending on limitations and quirks of any given simulator, so I think it is
always a good idea to build the circuit and test to see if it behaves the way the simulator is suggesting,
before attempting to draw any conclusions. Even though you may be seeing unusual results in a simulator,
until you actually build and test the circuit you really just can't be sure how it will really behave.
All the best...