Selfrunning Free Energy devices up to 5 KW from Tariel Kapanadze

[dllabarre]

  At power up the capacitor is charged to 150 volts, depending how fast I short points A and B I can raise the charge to 220 volts. One question I have is 'Why does the sudden disruption across the cap. raise the voltage so much higher?' I'm guessing it has to do with the rapid creation then collapsing of the magnetic field in the inductor. Another question is 'Why does the speed of disruption between points 'A' and 'B' vary the voltage widely'?

Respectfully,

Core

NICE!

Whats the value/size of the other capacitor near the FWBR?

Thank you
DonL

[Magluvin]

Yes the rotary gap goes between points A & B on the print. My electrodes on the rotary fouled fairly quick. I'm going to try a better design. On one of TK's video's you can here a 'clanking' sound. I believe this is his mechanical break.

Respectfully,

Core

Hey core

I understood it.  I had suggested trying like a smaller cap. Say 1uf or smaller. It will cause less damage to the rotor contacts. If you have a smaller value cap that is lets say 1kv 1uf  you will get a higher voltage to your cap. I found that when I used a 1 uf at 200v, I could also get about the same discharge results as a .5uf at 400v.  imagine .05uf at 4kv.  same dooda.  But 80uf at 300 v will burn those contact bad.  Thats what got me thinkin above that the rotary switch should handle HV from a small cap better than the situation you had.  ;]

Mags

[Magluvin]

core

What is your diode rated at voltage wise and amps?   Maybe when you hold the wire on to long, 2 things could be happening

1 current in the diode 2 high and causes less current when over heated
2 maybe the voltage produced is too high for the diode to hold back

Just ideas.  I dont see why it is less when longer. 

Mags

[alstream]

   What does this mean exactly? What is this myth of "Cold" electricity again?

"In my opinion the cold electricity phenomenon has something to do with the fact that Tesla was dealing not just with high voltage but high frequency. At high frequencies electricity tends to travel only along the surface of the conductor. That is why Tesla could allow his coils to pass electricty through his body and the electricity would radiate from his skin but not harm his internal organs. There are actually many wonderful therapuetic devices based on this effect using a tesla coil. Now if we have electricity with a frequency high enough, it could be changing directions almost once every planck second. At this level of rapid frequency so-called quantum mechanics may start to come into play to where it appears that instead of changing direction very rapidly the electricity is actually travelling in both directions simultaneously! In my opinion this is what cold electricity is. It is two simultaneously electric currents which are travelling in opposite directions in the same conductor. The two currents spiral and twist so as to avoid running into eachother. Therefore the resistance of one current cancels out the resistance of the other and that is why you have no heating of the conductor. Of course I could be wrong, but that is my guess."

[exnihiloest]

...
Now if we have electricity with a frequency high enough, it could be changing directions almost once every planck second.
...

Certainly not. Suppose a frequency of 1 Ghz, which is much more than Tesla's frequencies. Even at 1 Ghz (period = 10^-9 s), there would be 10³⁴ elementary Planck "seconds" in only one period of the HF signal (Planck time = 5*10^-44 s).
Even at gamma highest frequencies, which are the highest known frequencies (around 100 Exahertz=10²⁰ Hz), one period corresponds to 10²⁴ Planck times.
As the planck time is the shortest time interval, i.e the minimal possible unit of measure of time, it is obvious that no timed event can take place inside. At this scale, every thing if frozen.