Selfrunning Free Energy devices up to 5 KW from Tariel Kapanadze

[slapper]

What is this chip DD.1 used as clock source on Tiger and SR schematic? Bi-lateral switches?

nand gates. i'd go schmitt trigger for the inputs and don't short the inputs. try to use just one
of the inputs and the other tie to one of the rails depending on what you want to achieve. it
will add some to stability to the clock.

using schmitt trigger inverters would be easier but less flexible with your logic.

take care.

nap

[stivep]

nand gates. i'd go schmitt trigger for the inputs and don't short the inputs. try to use just one
of the inputs and the other tie to one of the rails depending on what you want to achieve. it
will add some to stability to the clock.

using schmitt trigger inverters would be easier but less flexible with your logic.

take care.

nap

sounds right
Thank you  slapper


TLC ferrite rings permeability 2000

[ePrick]

I do. We build digital equipment, not RF. I have logic analyzers, scopes, meters, microscopes, and a full state-of-the-art surface mount line...but no spectrum analyzer...because we don't need one. Never fear, it will be here in a few days.

SR's device sounds like an exact replication of Michel Meyer's Fe56 transmutation device. I certainly cannot say whether it is real or not, but it most certainly does not work the way you are thinking.

Kapanadze's device may work the same way as Meyer's copper excitation device, but that is anyone's guess.

And what is the spectrum of a dead short? You obviously haven't ever played with a Tesla hairpin. That dead short happens to be a high Q resonator that contains a wide range of frequencies. Might be nice to have a spectrum analyzer to figure out exactly what they are.

I do. We build digital equipment, not RF. I have logic analyzers, scopes, meters, microscopes, and a full state-of-the-art surface mount line...but no spectrum analyzer...because we don't need one. Never fear, it will be here in a few days.

SR's device sounds like an exact replication of Michel Meyer's Fe56 transmutation device. I certainly cannot say whether it is real or not, but it most certainly does not work the way you are thinking.

Kapanadze's device may work the same way as Meyer's copper excitation device, but that is anyone's guess.

And what is the spectrum of a dead short? You obviously haven't ever played with a Tesla hairpin. That dead short happens to be a high Q resonator that contains a wide range of frequencies. Might be nice to have a spectrum analyzer to figure out exactly what they are.

Your assumption that I have not built a hairpin would be incorrect. If it works the way you claim, perhaps you could explain why SR's coil is center tapped?

Also - It would be an assumption to claim it worked at all since nobody has replicated or even knows how.

Naturally you will see the LC resonance but I think that you will see harmonics of the elemental resonance of the element and since every part of the coil is made of it...

Tesla published a resonate frequency of the elements table which is surprisingly absent from the web. I probably have it somewhere and maybe one of the Tesla experts could post that.

Here are some thoughts from:

http://answers.yahoo.com/question/index?qid=20071211144856AAHro9K

You won't find something that does not exist. If you want to know about vibrations of solids, you need to learn the theory of phonons, i.e. quantized vibrational modes. Phonons do not have point spectra but form bands. This results from the large number of degrees of freedom in a macroscopic solid. The number that counts is the number of atoms, not the number of different types of atoms.

At the lower end of their spectrum, phonons are indeed nothing else than the acoustic modes of the solid (minus the transition from quantum mechanics to classical mechanics for the case of large quantum numbers, of course). But unfortunately these are not well defined because they depend mostly on the shape of your sample and not on its composition. So what you are measuring with an acoustic transducer is really how well you did as a bell-maker (or how much you suck at it). And then all of this is also very temperature dependent because indicidual phonons can only be measured at ultra-low temperatures. At room temperature all you are ever going to see are thermodynamic averages.

If you are interested in the parts of the phonon spectrum which depend mostly on the crystal structure and the element or compound, you will have to go to the GHz and THz region. Physicists have many methods to measure phonon spectra up there, but they are substantially different from an acoustic measurement.


http://en.wikipedia.org/wiki/Phonon

[ePrick]

nand gates. i'd go schmitt trigger for the inputs and don't short the inputs. try to use just one
of the inputs and the other tie to one of the rails depending on what you want to achieve. it
will add some to stability to the clock.

using schmitt trigger inverters would be easier but less flexible with your logic.

take care.

nap

Thanks slapper. The number of pins works out right. Stan Meyer used a similar technique to produce ultra short pulses 4-8 ns on his PWM owing to lag time between switching states.

Do you think that is what is going on in that configuration? Of course that would not make much sense if Tiger's schematic is correct since he his using some low speed transistors.

I've built clocks lots of different ways but never using a nand gate. Any other thoughts on that?

[slapper]

@ePrick: it's almost as if you had the answer before you asked it.
it's been a while but you'll want to buffer the clock output similar to what they show in their schematic.

can't recall for sure but i think you'll get a more symmetrical clock output if you stay with how they've
got the resistor and capacitor connected to the logic.

you can use steering diodes in series with the resistor to control pwm to some extent.

fairly decent way to prototype yourself a square wave source.

one way to get short pulses out of your clock is to connect your buffered output to another nand gate.
use both inputs but put an rc into one of your inputs. at ns speeds your going to want the fastest logic
gates available. a pulse this fast would probably only require a resistor in series with the input. probably
talking about 1M to 10K in values. at lower pulse speeds simple cr/rc with a switching diode will do.

don't know much about Tiger's schematic. i'd like to see the link to it if someone could repost.
they probably used the clock source for a high voltage step-up transformer through a driver for their
sparkgap source.

@LtBolo: did you catch the way Dr. Stiffler tuned his coils?
what spec's would you recommend for a spectrum analyzer? i'd like to do some shopping.

take care.

nap