Kapanadze Cousin - DALLY FREE ENERGY

[itsu]

Black_Bird,

earlier you said you got 960V:
"4) used two 1N5408 in parallel as the output diode, assembled directly at the input of the coaxial cable".
does this mean no voltage divider? And was the coax shorted at the end?

So now you got 1920V (wow), but in a 200 Ohm load, right?
Could you try to keep a 50 Ohm load with a voltage divider of 1:10, so 47 Ohm and 4.7 Ohm.
This way its much easier to compare.

I tried 2 KD226D DSR diodes parallel, but the peak voltage stays the same (1100V at 110V drain voltage)
Idem when putting them in series.

I can try the 1N5408's

Regards Itsu

[T-1000]

@itsu
Your nanopulser seems fine and even more "perfect" than Dally had.
All you need to get its power source from same toroid(yoke in your version) so it will have relationship with current going into L1 coil.
When nanopulser fires there is loop created and what I really would love to see on scope is this:
http://www.youtube.com/watch?v=66-DV9kY2dM#t=0h13m06s
(the sinus wave is your primary current driving frequency, the spikes are BEMF. It is important to have them set into 180 degrees from current cycle)

Also there is very important moment when to take energy out of system:
http://www.youtube.com/watch?v=EVDNkF1npHs#t=0h6m25s
(when spark gap is firing in Tesla coil, you hold off from taking energy and allow free flow to charge secondary on explosive capacitor discharge. As soon as it stops the longditudal wave fires right after this discharge in EM field collapse you take energy out of all tuned coils (as many as you can place) around secondary coil.)

Sorry if it sounds greek in Youtube maybe someone can translate that fully into English.
P.S.> Some teaser: Romanov (the guy who explained all stuff) demonstrated self runner in the end of same video - http://www.youtube.com/watch?v=7eKi7ol12c4#t=0h44m0s

Cheers!

[Black_Bird]

Black_Bird,

earlier you said you got 960V:
"4) used two 1N5408 in parallel as the output diode, assembled directly at the input of the coaxial cable".
does this mean no voltage divider? And was the coax shorted at the end?

So now you got 1920V (wow), but in a 200 Ohm load, right?
Could you try to keep a 50 Ohm load with a voltage divider of 1:10, so 47 Ohm and 4.7 Ohm.
This way its much easier to compare.

I tried 2 KD226D DSR diodes parallel, but the peak voltage stays the same (1100V at 110V drain voltage)
Idem when putting them in series.

I can try the 1N5408's

Regards Itsu

itsu: in all tests, the coaxial cable was connected to the diodes, and shorted in the far end. So when I inserted the voltage divider, it was in parallel with the coaxial cable. One important fact, my coax is 75 ohms, not 50, because it was the one I had available. The curious fact is that 75 // 192= 53 ohms!!!

[Black_Bird]

@itsu

I reviewed the measurements and the pulse amplitude is not 1920V ( it was too good to be true!). It remained the same, when I increased the capacitor. I was fooled by some ground noise.
Sorry for the bad information.

[itsu]

@itsu

I reviewed the measurements and the pulse amplitude is not 1920V ( it was too good to be true!). It remained the same, when I increased the capacitor. I was fooled by some ground noise.
Sorry for the bad information.

No problem, i know how hard it is to interpret the data sometimes.
Not sure about the parallel coax though, as it is shorted it still would "show" this short to the diode and cause reflections.
Try to measure the pulse only with a 50 Ohm resistor across the diodes, it probably looks much cleaner/more stable.

Regards Itsu