Selfrunning Free Energy devices up to 5 KW from Tariel Kapanadze

[LtBolo]

I don't think core yoke material has anything to do with it.

One of the team posted here that he had tried 20 or so cores, and only a few exhibited the behavior. T-1000 also said that the core that was currently working for them was 'pure glittering black', as opposed to the gray color most ferrites are. So I will respectfully disagree.

I doubt that it is limited to a specific material, but that certain materials are more subject to it than others. The old MnZn ferrites were known to be very prone to ringing, something that obviously has relevance here.

It occurred to me that to properly align the spins to induce magnetism, you need alignment in two axis. The single turn coil may be creating an electric polarization in one axis...we'll call X, the single turn coil could also be creating a magnetic alignment in the other...we'll call Y, and the resulting X and Y alignment then results in a powerful magnetic field propagating around the toroid, or the Z. By pulsing the one turn coil at the ferrite material's resonant frequency, eventually all of the spins begin to sync and the amplitude of the spin oscillation becomes large. As the individual spins begin to cohere, the material spontaneously magnetizes and demagnetizes along the Z axis.

Think of it this way: Visualize each molecule as a fan that is fully gimballed, blowing air (magnetism) in a completely random direction. The net airflow is zero. If I were to apply a force to the fans to pull them in one axis, they may now be aligned within a single plane, but the resulting airflow is still zero. If I were to align them in another axis, now all of the fans are oriented in same direction, and the airflow along the aligned axis could be extreme.

The amount of force that it took to rotate each fan had nothing to do with how hard each fan was blowing, only with how hard each fan was spring loaded into its starting position. For any material, the total possible magnetic output is a function of permeability. I have no idea what the equivalent of the spring loading is, possibly permittivity. That is really irrelevant though, because the key is that the fan is blowing on its own, I'm just turning it in the direction I want it to go. Some materials may go willingly, others not so much. I'm sure that once you understood the effect and the critical parameters, material selection would be pretty easy. Without a better understanding of what works and what doesn't, we're pissing in the wind. Starting with a known good material seems like a good approach.

[T-1000]

Manual Deflection Yoke Degauss - http://www.youtube.com/watch?v=jfgAwRnyWsY
The ring inside of blue isolation tape is coil powered by mains of 50Hz 220V.

[firlight]

@ All,

New attempt to replicate with advice received from T-1000.
Max. output 188V, but voltage only.
Problem still is the amount of 50Hz voltage to be put into the 15 turn coil
in combination with the lack of solid ferrite resonance point.

Video with subtitles as proposed by user verpies :-)  :  http://www.youtube.com/watch?v=iA5s_3JxAvc


Regards Itsu

Hi Itsu
               I like your effort with this project.Am having ago myself,The problem I have is with the 50Hz
               driving the 15 turn coil ,this does not make any sense to me as the impedance at 50hz from my
                calcs is .0289 ohm ,a short circuit,also if we had the inductance of the windings of the original
               we could adjust our windings to suit.Just a suggestion .
Regards Dave

[jbignes5]

One of the team posted here that he had tried 20 or so cores, and only a few exhibited the behavior. T-1000 also said that the core that was currently working for them was 'pure glittering black', as opposed to the gray color most ferrites are. So I will respectfully disagree.

I doubt that it is limited to a specific material, but that certain materials are more subject to it than others. The old MnZn ferrites were known to be very prone to ringing, something that obviously has relevance here.

It occurred to me that to properly align the spins to induce magnetism, you need alignment in two axis. The single turn coil may be creating an electric polarization in one axis...we'll call X, the single turn coil could also be creating a magnetic alignment in the other...we'll call Y, and the resulting X and Y alignment then results in a powerful magnetic field propagating around the toroid, or the Z. By pulsing the one turn coil at the ferrite material's resonant frequency, eventually all of the spins begin to sync and the amplitude of the spin oscillation becomes large. As the individual spins begin to cohere, the material spontaneously magnetizes and demagnetizes along the Z axis.

Think of it this way: Visualize each molecule as a fan that is fully gimballed, blowing air (magnetism) in a completely random direction. The net airflow is zero. If I were to apply a force to the fans to pull them in one axis, they may now be aligned within a single plane, but the resulting airflow is still zero. If I were to align them in another axis, now all of the fans are oriented in same direction, and the airflow along the aligned axis could be extreme.

The amount of force that it took to rotate each fan had nothing to do with how hard each fan was blowing, only with how hard each fan was spring loaded into its starting position. For any material, the total possible magnetic output is a function of permeability. I have no idea what the equivalent of the spring loading is, possibly permittivity. That is really irrelevant though, because the key is that the fan is blowing on its own, I'm just turning it in the direction I want it to go. Some materials may go willingly, others not so much. I'm sure that once you understood the effect and the critical parameters, material selection would be pretty easy. Without a better understanding of what works and what doesn't, we're pissing in the wind. Starting with a known good material seems like a good approach.

This is the most clearest post I have seen from the forum. Spot on in my opinion. You could think of these axis as surfaces that can each be wavered or modulated but in distinctly different ways. Think of the magnetic quenched spark gap and you can see where this is going. replace the air with ferric matter and the premise stays the same. In order to increase frequency Tesla did this same procedure. The magnetic fields orient the grains of the space in between the electrodes this increases the dots per inch so to speak. You could think about a spark as a little string of pearls going from electrode to electrode. The flow of charges follows these pearls and acts like grease. Now apply a downward water flow(magnetic field polarization) across the pearls and it strips the charges from between the pearls and leaves the grease on the bottom of the pearls still clung to it. The dots become more pronounced and of a very high frequency due to the alignment of a polarizing magnetic quenching.


I believe this is the same method you guys are seeing here. I am wondering what a layered aluminum ring would do? Would it act differently seeing when one drops a magnet along an aluminum plate it moves very strangely. We know something is going on there.. Hmm...

[Cap-Z-ro]

There was a thread relating to moving theb 'bloch wall' of magnets to and fro via a switching method...I wonder could this process be of use in this application ?

Regards...