Kapanadze, Stepanov, Barbosa-Leal and the Secret of Free Energy

Zeitmaschine · January 11, 2018, 11:00:25 AM

On the left-hand side there is a 400Hz sine wave drawn by the editor software. The wave on the right-hand side shows the Kapanadze shut down noise. As it looks, it is also 400Hz.

Now someone can explain to me how the device can make a sound at a frequency of 400Hz when it is disconnected from the 50Hz inverter? My guess: The 50Hz frequency is doubled to 100Hz, then (after disconnect) to 200Hz then to 400Hz. Then the resonant frequency doubler can't resonate any higher, so it stays at 400Hz. If someone has a better explanation, I'm all ears.

Void · January 11, 2018, 11:06:49 AM

Quote from: kpannic on January 11, 2018, 10:53:38 AM
a few moments ago I destroy an 220v / 12v1A adapter, but I can not figure out how I did it. The connection between the spark and circuit it was isolated by the optocoupler and toroid transformer (see diagram below). The oscillating circuit and the mosfet are not damaging. WHAT HAPPENED?
A small explosion occurred in the adapter that fed the oscillating cycle when I was playing with the frequency of the oscillator. I think it was a fraction of a second I see yellow flash that does not know where it came from. (from the bulb?). Inside of the adapter I found pieces of an integrated circuit.

Hi kpannic. I have had a similar thing happen where a power adapter for a little portable
signal generator I have has burned up twice now when experimenting with circuits that produce
high voltage spikes. In my case the two power adapters which burned up were the switching regulator
type. I would guess that what is happening is the high voltage spikes are possibly coupled into the switching
regulator circuitry by induction, and this causes the control circuitry to go wonky and can cause something in
the regulator circuitry to burn out. Testing with high voltage AC or pulsing setups can always potentially cause
surrounding circuitry to blow, so it is always risky!

All the best...

Void · January 11, 2018, 11:33:43 AM

Quote from: Zeitmaschine on January 11, 2018, 11:00:25 AM
On the left-hand side there is a 400Hz sine wave drawn by the editor software. The wave on the right-hand side shows the Kapanadze shut down noise. As it looks, it is also 400Hz.

Now someone can explain to me how the device can make a sound at a frequency of 400Hz when it is disconnected from the 50Hz inverter? My guess: The 50Hz frequency is doubled to 100Hz, then (after disconnect) to 200Hz then to 400Hz. Then the resonant frequency doubler can't resonate any higher, so it stays at 400Hz. If someone has a better explanation, I'm all ears.

Hi Zeitmaschine. Just to confirm, are you talking about the 2004 Kapanadze demo video where
he unplugs his device from the inverter output and the lights continue to glow for about
a second or so, and a noise is heard as the lights go dim?

All the best...

Zeitmaschine · January 11, 2018, 12:15:40 PM

@Void, yes.

Still the main question is, how to construct the high voltage anode in detail, and do we need a spark gap or not, and should the second wire of the high voltage transformer be connected directly to ground or could we do something else with it?

To have a spark gap will not hurt anything, because we can bridge it quickly. The problem is the anode. Barbosa and Leal use a copper pipe as secondary coil. What can we do with a copper pipe? First, we can make a closed loop with it, otherwise a current can not flow in that circuit. Second, we can put it through an iron core which generates a magnetic field (not much turns possible though). Third, we can connect it to ground. Fourth, we can wrap something around it. Fifth we can put something in it. The latter is only relevant if we do not use a solid wire (like seen in an other Barbosa-Leal demonstration) instead of a pipe.

What if there were an anode (positive against ground) and in addition a cathode (negative against ground), so ground is not the cathode but something between? The patent drawings do not show this in detail, maybe it is difficult to draw - experienced that myself while drawing the illustration on reply #90.

Void · January 11, 2018, 12:32:04 PM

Here is a FFT audio spectrum analysis of the shut down noise from the Kapanadze 2004 full demo video.
https://www.youtube.com/watch?v=r99g4mjEvTE

This occurs at about 24:32 to 24:33 in this video.
Kapanadze unplugs his device from the output of his inverter and the lights take about a second
or so before they go out. A prominent noise can be heard as the lights are going dim.

I used some decent quality audio FFT analysis software which I have to do this FTT analysis of the audio
when Kapanadze's device is shutting down. See the attached screen shot to see what the
audio frequency spectrum of that shut down noise looks like. The FFT software plugin I used has
a cursor feature that allows you to determine the exact frequency of any peaks in the audio frequency spectrum.
I used this feature to determine the exact frequency of some of the more prominent peaks
in the audio frequency spectrum, and I indicated these frequencies on the attached screen shot.

Prominent peaks are at about 169Hz, 236 Hz, 366Hz, 468 HZ, and 669HZ, give or take a few Hz.

It is also interesting that there are some harmonic looking peaks at frequencies above
6 kHZ which appear to be growing in amplitude as the frequency increases, but the audio from the video
is compressed and the audio compression algorithm used in the Youtube video cuts off the audio at 12 kHz,
so we can't see what is above 12 kHz. These peaks are at about: 6.84 kHz, 7.82 kHz, 9.02 kHz, 10.1 kHz, 11.4 kHz.

It doesn't look like there is any obvious harmonic relationship to 50Hz that I can notice.

All the best...