Kapanadze Cousin - DALLY FREE ENERGY

[gyulasun]

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By reading Magpwr's post, i recalled something that still is a mystery to me. It is an effect that farmhand reported before a month on Akula's 30W thread, and it has to do with the tv yokes. I replicated this experiment and it is just astonishing to me! Perhaps some of you can help to analyze it. Farmhand had made two coils of 100 turns on each half of the yoke core. At 1MHz, he noticed a very high amplitude peak at 200V at the output, just by feeding the primary with 18V from a signal gen. In my replication, with 150 turns on each half, at 237KHz i take an output of almost 600V pk-pk with just 10V square input. You guys find it normal? Think that both coils have exactly the same turns. For me, something happens inside the core when we are in resonance.

Hi Jeg,

Normally any coil having an L inductance and a C self capacitance will give a parallel resonant LC circuit at a certain (high enough) frequency. And at this frequency the AC impedance of the LC will peak to a maximum value and this is which increases the AC voltage across it. This is normal.

It is okay that the circulating AC current in the coil will also have a maximum value at resonance and this current can already influence the core, one such effect is saturation, etc.

The fact that resonance was found with a coil at say 1 MHz wound onto one yoke core and another coil resonated at 273 kHz on a different yoke core just shows the permeability, the shape factor and the number of turns difference of the two, the higher voltage amplitude in your case came from the the difference in the losses between the two yokes and coils. This is what I think.

Gyula

[Jeg]

Hi Jeg,

Normally any coil having an L inductance and a C self capacitance will give a parallel resonant LC circuit at a certain (high enough) frequency. And at this frequency the AC impedance of the LC will peak to a maximum value and this is which increases the AC voltage across it. This is normal.

It is okay that the circulating AC current in the coil will also have a maximum value at resonance and this current can already influence the core, one such effect is saturation, etc.

The fact that resonance was found with a coil at say 1 MHz wound onto one yoke core and another coil resonated at 273 kHz on a different yoke core just shows the permeability, the shape factor and the number of turns difference of the two, the higher voltage amplitude in your case came from the the difference in the losses between the two yokes and coils. This is what I think.

Gyula

Hi Gyula
I believed that is a strange behavior, because primary and secondary are wounded with same number of turns. What makes this huge amplitude difference between prim. and sec? In an isolation transformer when we tune in 50Hz it will pass easier the pwr from prim. to sec. but it will not exceed the 220V voltage input. The reason is that the no. of turns are almost equal in number. Isn't the same rule apply also here?

[Farmhand]

I think it's the inherent capacitance in the scoped coil and the capacitance of the scope probe maybe causing the scoped coil to build up a resonant rise while the driven coil acts just to excite the scoped tank. And due to the split core as well, I did notice if I separated the cores by the right amount the voltage in the scoped coil was even more. This stored oscillating energy would be quite small I think.

Even with a primary secondary transformation of say 1:2 then 10 volts on the primary can cause a lot more than 20 volts on the secondary if resonant rise is allowed or caused especially if the coupling is not tight.

..

[Jeg]

This stored oscillating energy would be quite small I think.

That is true! Even with capacitor at the output the current is very small. I charge a cap with diode, but when i connect even a high resistance load, after some secs discharges the cap almost completely.

If i remember T-1000 the guy who involved to this Lithuanian experiment, spoke about 3D oscillations. I wonder what will happen if on the same yoke that we are discussing, we wind an other third coil around the periphery of the yoke core, and give there some DC voltage for making a steady magnetic field perpendicular to the other! I think it deserves a try.

[NickZ]

   We would do well to study further on what Akula and others similar devices are doing, to understand the workings of these self runners.  Akula is using an induction heater circuit going to a ferrite yoke core. Which may also have an Exciter (or Kacher) circuit, (or just rectified pulsed DC from the inverter), connected to the same yoke core's secondary coil. Then down stepping the output through the thick 3 turn coil (third coil), the combined effect of the two circuits which are pulsing onto the same yoke core. Further sending that combined output through a capacitor(s), to some other air cores, such as the resonator coil, feed back coil, choke/capacitor coil, and the biggest coil being the output coil that goes to the lights. Which is also grounded at one end.  Sorry I can't explain it too well. 
  But, that May Not be the only way to go to obtain the same types of results.

  The main idea is the combining of the two different voltage/current circuits, coils, and their effects together in such a way,  using "resonance of their magnetic domains",  to obtain a magnetic type of non shocking output which allows the device to self run. 
That effect generation method(s) is what we need to study.