Selfrunning Free Energy devices up to 5 KW from Tariel Kapanadze

[Farmhand]

This is obviously not radiant energy.

http://www.youtube.com/watch?v=yKeIzFabINU

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[Farmhand]

Farmhand:  Voltage spikes= radiant energy.

Only if they are measured outside of the closed circuit, otherwise the energy responsible for them was not radiated, and so therefore couldn't possibly be "radiant" energy because it wasn't radiated.

The video clip in the previous post show the very same effect. It is an effect of conduction not radiation.

Even a neon with one leg held in the hand and the other leg touched to the battery top is an effect of conduction.

Cheers

[wattsup]

@all

Guys let's not panic at this stage since we need everyones perspective regardless of what it may be. As long as it is device pertinent.

For radiant energy (RE), yes it is high voltage spikes but the total energy produced is always minimal. I have done it so many times with very impressive sine wave peaks but when all is leveled down by a small load, the total output is very minimal. My personal view is that to produce 500 or 1000 watts of steady continuous output via an RE system would require voltages in the 100kv range that would then be leveled by the load to an RMS value. There is no way that 2004 device was built to withstand such high levels of voltages as we would have seen sparking from all around the device. Also with RE producing such high frequency airborne particles that screw up my computer and everything I did to try and contain it was of no use. If in the tent system they used RE, that whole area would have been hyper charged with particles, so I really do not think that is the way go approach this. Regarding the use of plexiglass, again with the energy levels required for that heater element, I don't think this is the reason. They probably put it in a plexi box to contain the noise and prohibit anyone from getting into the hidden parts of the system. As for the styrofoam, yes it is used in coax cable as a dielectric.

Regarding the diode plate, once Сергей В. posted that schematic, I took time to look again at the diode plate to see if the connections follow the dual series diagram. The damn video is the shits (when have we said that before) but I now have realized what he his doing. I am 99% sure now.

The biggest problem for me was to reconcile the heavy secondary transformer winding compared to why TK was then using those thin wires going from the secondary terminal to the diode plate that did not make any sense knowing that secondary was producing higher amperage levels. Why have such thin wires? But now I see that the wires are not copper but a heavy dark probably iron wire that has no insulation. Without the insulation that wire now becomes a pretty hefty wire capable of handling some good wattage. So then I looked again at the connections to the diode plate.

The problem with looking at video visual vagaries is that you can mentally perform the conception of what you see, then try to put it into a logical format of function. If both do not agree, you keep looking until what you see starts to make sense. But if the person who made the device tells you what you are looking at, you then start realizing that what you see does in fact make sense. So the idea is to get to that level of certainty even though the visual is never good enough to be flat out certain. Anyways, after a good while it finally dawned on me.

The four diodes are in parallel. There are two connected by the top copper strip. That's where one side of the secondary iron wire goes to that copper strip (left). Then there are two more iron wires that go from the copper strip to the two other diodes at their top pins. I can then surmise that the diode bottoms (studs) are all paralleled as well and I know there is a wire from there going to one side of the capacitor.  The other side of the capacitor goes to the tin can and one wire from the secondary also goes directly to the tin can. So the secondary AC neutral heads into the tin can and the AC Hot goes through the plate, a capacitor then to the tin can. The capacitor is in series.

So the four diodes are paralleled, but there is another curiosity. The far right diode has a blue colored insulation while the others are black. I tried to find on the net if there was a standard coding convention for stud diode insulation colors but could not find anything. But if that blue diode is different to the others, then I am thinking it is because it points in the other direction. This would make the diode plate what we know as an Avramenko plug but in this instance there are three diodes pointing one way and one diode pointing the other way probably for flyback return to the secondary that props up the primary side and reduces the primary consumption.

If the output of the inverter showed 0.6 amps consumption at 220 volts would be 132 watts, so each of the three diodes would need to handle around 44 watts each if this was strictly a linear set-up.

So basically if the inverter is reading 0.6 amps, this includes both the AC5 line and the transformer secondary output or DC10 line as a total consumption. The Avremenko plug is only passing half the AC waveform, and, if in that half the device produces enough flyback return, the other diode of the Avremenko plug will send it back into the secondary. This may be what TK refers to a recycling the energy whereas if the diode plate was a standard FWBR, there would be no possibility for any energy return. So this also makes more functional sense.

So I will test this next. If it pans out to better results I will change the mapping diagram accordingly. hehehe

wattsup

[Сергей В.]

to wattsup The Avramenko plug need only 2 diodes to work. But for high currnet you can put in parallel as many diodes as you wish. For example on this way.
The question is: Where are high amperage wires to bring a high current to Avramenko plug ?

If he used Diffusion type rectifier diodes for DSRD Nano-Pulsing he can masking with easy small ferite transformer under diodes pcb or can put it in the tin-can.
The question is how he was made High Voltage Nano Pulses ?? Using DSRD Pulaser or Step-up transformer ?? His sparks were not a Zeus thunderbolts !! 

[itsu]

@all,

perhaps somewhat off topic, but certainly relevant.
I did some further experiments with my copper tube like coax coils.

Pulsing the inner or outer members of these coax coils show normal inductive and/or capacitive coupling as measured with a scope.

The coil with the least capacitive coupling between inner and outer member (the one with the HV wire inside) shows the highest voltage transfer (2600V p2p put in, 2420 V p2p out at 10nS).

Next will be the installation and testing of some ordered RG316U coax cable (at least the inner part of it) which has  some iron (steel) conductor:  Inner conductor Stranded copperclad steel wires, silver coated 7 x 0.17

Video here: http://www.youtube.com/watch?v=UV5GprnHusA&list=UUdJ2A-075yx9y4bKqu_8Q8A&index=1&feature=plcp

Photo of the used pulse signal below

Regards Itsu