My dear friend Fabio,
Today i had some time to make more drawings of the VIC.
The target was trying to understand its working, like many others have done in the past.
I did the same in the past, but with too many parameters.
Like you, i looked for resonance etc etc etc. I looked at PFN's, standing waves etc etc.
Trying to figure out how it could work.
But today i took a different approach. I looked at it just as it is, a transformer setup.
4 coils on 1 core.
When the primary is charged, a magnetic field will be created.
So, what happens at the other coils? They will receive that magnetic field and all produce a potential difference and current will flow, if they have a closed circuit attached.
What i did was that i drew all coils on one strait core, so its easier to see how it is all connected and also to draw graphs behind it on how the voltage potentials and currents would develop when the magnetic flux rises in the core when the primary charges up.
For what its worth are here some of my conclusions:
The two chokes are basically 1 big coil with the cell exactly in the middle of that one big coil. This is funny with the knowledge in mind of that strange coil/core of the other inventor with his type of tubecell who meet Meyer. mr. Dan Danforth.
I also see that the secondairy coil is placed in parallel to the " big coil". That basically says nothing more then that if the 2 coils would be equal, the voltage would stay the same and amps are doubled. However, in the VIC case, the two chokes are double in size then the secondairy.
Question is now how that will behave, but U=I*R will explain most of it, ill guess.But i do not think that that is important for the moment.
Ronnie has more succes with the separated chokes with their own core. The cell as a resistor in the middle of those two charging coils and discharging slowly thru the secondairy.
So, the time factor here is also a critical one...
Other question is: What happens in the middle of a coil? Maybe something with phase differences?