Kapanadze Cousin - DALLY FREE ENERGY

[d3x0r]

I am not changing the duty cycle, so not sure what you mean. Duty cycle in my testing was
kept to a very minimum -> about 10% to 20% max. I have actually been using the pulser circuit board
made by RM Cybernetics, and I don't know the exact circuit, but it is basically a control circuit
to set the frequency and duty cycle, which drives a FET. I need to build one now which is simpler
so I can try again and compare results. A simpler circuit should be easier to analyze. I might
try building Akula's pulser circuit for comparison, but I will have to order some parts first.

The pulser module I have been testing with is very close to this one on the RM Cybernetics website,
but I have the prior version of this module. The one on the website is their version 2 module, which has
a few changes.
http://www.rmcybernetics.com/shop/pulse-modulator-ocx

so the pulser, a fet, and a coil.
What I was saying is that the (I dunno I guess they're) flyback pulses happen at a fixed time from the turn on of the gate/base.  If you increase the freqeuncy, this reduces the time between pulses, but also reduces the on time of the gate... so the flyback will not be as strong, so that's probably why it fades faster at higher frequency.  10% of 1Khz = 100uS; where 10% of 10Khz is only 10uS....
the time is variable based on the core and gap in the core... but for a set configuration there's a set time.
I'm assuming that your scope probe is on the source. 


Here's an english translation https://www.youtube.com/watch?v=rbyJKRuzFLw (of akula vid) especially 2:18 of the video to explain resonance

[Thaelin]

This timing reminds me of the issue seen with the reluctance motor.

In that you do not want to pulse the coil longer than it takes for the
current in the coil to level out or basicly quite rising . So the pulse
length should be long enough to fully energize the coil but then shut
off not to waste input.

[NickZ]

   Void:
    The pulse modulator unit that you posted the link to is only working in the Mhz range. Although their cheaper units do go up to 100khz. So, I don't know if the pulser that you're using is apt for the Akula second device type of operation, or not.
But, it's good to see that someone is trying out those commercially made pulsers.
 
   All: I've been having a hard time getting the Akula type air coils to work correctly, along with my previous shown Mazilli/yoke core set up.
  It seams as if there is not enough windings to actually produce the same output that my yoke by itself can obtain. I did not wind the two 48 turns initial windings on on this air core output coil, just a single layer of 48 turns, then a single layer 24 turns, then two layers of 12 turns on top. As I'm trying to obtain only 120 to 160 volts output, not 220v.
 
   I may have to make another coils with all 48,48, 24,24, 12,12 turns, like is shown in some diagrams. But, what I find interesting to see, is that on Ruslan's  Akula 2nd device replication, he does not conform to the above turn windings either. As his air coil's output coil is showing about 24 turns as the last outer set of winding, not 12 turns.
  It would be good to know just what the Akula output air coil produces for him, by itself without the pulser connection attached, just as a voltage/amp comparison.

  Anyway, I can only get one or two bulbs barely glowing with my current Akula air coils set up, connected to my Mazilli/yoke core. I tried different caps on it, but they only give just a slight improvement in bulb brightness.  I'm only using 12v, and not the 24v that Ruslan is drawing from his self runner device.
  Any ideas are welcome.

[Void]

so the pulser, a fet, and a coil.
What I was saying is that the (I dunno I guess they're) flyback pulses happen at a fixed time from the turn on of the gate/base.  If you increase the freqeuncy, this reduces the time between pulses, but also reduces the on time of the gate... so the flyback will not be as strong, so that's probably why it fades faster at higher frequency.  10% of 1Khz = 100uS; where 10% of 10Khz is only 10uS....
the time is variable based on the core and gap in the core... but for a set configuration there's a set time.
I'm assuming that your scope probe is on the source. 

Here's an english translation https://www.youtube.com/watch?v=rbyJKRuzFLw (of akula vid) especially 2:18 of the video to explain resonance

Yes, that sounds right to me. My scope probe is across the coil terminals.

Thanks very much for posting that link to the translation of Akula's lantern 4 video.
I did not realize that translation existed. That translation helps quite a bit in understanding
what those scope shots were about. I was missing a few key concepts in there. Akula actually
seems to be saying that your pulse on-time duration (duty cycle) at the base/gate needs to be set to a certain
minimum on-time for the ferromagnetic resonance to come into effect. What that will need to be set to will depend on the
exact ferrite core you are using. It is also interesting that Akula says that this 'ferromagnetic resonance' frequency
seems to be changing on him a few times over the period of an hour or so, which makes his circuit quit.
He said he is not sure why this is happening but thinks the ferrite core is maybe being affected by temperature change.
He was going to add circuitry to try to automatically compensate for those changes.

I have to say that now that I have an English translation of this video, that Akula does at least seem
quite serious about this. If he is just trying to trick people, he sure is putting a lot of time and effort into building
and testing all kinds of circuits. Anyway, with that translation, I have a better idea of what I should be looking for,
although I still don't fully understand some things that he is saying in that video.

For people who have been testing with the Akula TV yoke core circuits, it may possibly be the principle
is the same or similar behind it, and that may be why Akula is driving the yoke core with a driver
in which he can make adjustments to duty cycle and frequency. To test the Akula TV yoke core circuits, I think
it might be a good idea to build Akula's adjustable driver circuit or similar to drive the yoke core. That pulsing of
the ferromagnetic core at a specific duty cycle and frequency may be key to getting results. I don't know, 
just throwing that out there, but that is why I included this discussion in this thread, since to me
it does seem to potentially at least tie together.

I will keep experimenting with this 'ferromagnetic resonance' concept, and I will report back
if I find anything interesting.

All the best...

[Void]

   Void:
    The pulse modulator unit that you posted the link to is only working in the Mhz range. Although their cheaper units do go up to 100khz. So, I don't know if the pulser that you're using is apt for the Akula second device type of operation, or not.
But, it's good to see that someone is trying out those commercially made pulsers.

Hi Nick. That module is supposed to work from low Hz to 1.5 MHz.
MHz (megahertz) is higher in frequency than kHz (kilohertz).
You can select different frequency ranges on the pulser depending on what
capacitor you plug into a socket. With my version 1 module I found that it doesn't work
so great at the higher frequencies due to long rise and fall time on the pulse, but
maybe I didn't try the best capacitor value for the higher frequencies. They may also
have made improvements in the version 2 module.