Quantum Energy Generator (QEG) Open Sourced (by HopeGirl)

[isim]

@synchro1
"A tiny collapse accompanies the current reversal of the sine wave in the coil. Running A.C current through a single wire solenoid will heat the wire up. The tesla series bifilar, as I've pointed out out has no negative micro Henries. This means there is no resistance to the change in current direction from the sine wave, unlike the single wire. This translates into no heat! A caloric measurement would highlight the major difference between the coils. The bifilar is an A.C. current coil, the single wire's not!"

This is a very curious theory.
- If you speak of the "collapse" on the pictures of uQEG:
The collapses are due to a bad command of the gate!
- Otherwise can you indicate some information on where we can learn more on this things, and in particular on  "negative micro Henries" and "there is no resistance to the change in current direction from the sine wave, unlike the single wire"?
Thanks
@+

[TinselKoala]

THERE IS NO COLLAPSE SPIKE HAPPENING ANY WHERE IN THE ENTIRE microQEG SYSTEM."


A tiny collapse accompanies the current reversal of the sine wave in the coil. Running A.C current through a single wire solenoid will heat the wire up. The tesla series bifilar, as I've pointed out out has no negative micro Henries. This means there is no resistance to the change in current direction from the sine wave, unlike the single wire. This translates into no heat! A caloric measurement would highlight the major difference between the coils. The bifilar is an A.C. current coil, the single wire's not!

Whatever, dude.

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

[isim]

@TinselKoala
May I ask how many turns (approximately) each coil has, their diameter and their  length?
Thank you
@+

[MarkE]

THERE IS NO COLLAPSE SPIKE HAPPENING ANY WHERE IN THE ENTIRE microQEG SYSTEM."


A tiny collapse accompanies the current reversal of the sine wave in the coil. Running A.C current through a single wire solenoid will heat the wire up. The tesla series bifilar, as I've pointed out out has no negative micro Henries. This means there is no resistance to the change in current direction from the sine wave, unlike the single wire. This translates into no heat! A caloric measurement would highlight the major difference between the coils. The bifilar is an A.C. current coil, the single wire's not!

Synchro1 I don't know where you acquired these wrong ideas.  A sine wave has no abrupt changes.  There is no sudden disruption of one current path to another.  The field builds up and builds down smoothly.  There is no tiny collapse even for very large values of zero.

There is no negative inductance in a coil of any construction. 

Until we get into very high frequencies where we need to take things like proximity effect into account, the resistance of a conductor is a function of the material bulk resistivity, the shape of the conductor, and the frequency (components for non-sinusoid) of applied voltage across the conductor's length.  One can wrap a wire into any shape one wants and for a given current wave shape through the wire, the I²*R losses will be constant.

[TinselKoala]

@TinselKoala
May I ask how many turns (approximately) each coil has, their diameter and their  length?
Thank you
@+

I suppose you are talking about the loopstick. I don't know the turn count, I have not unwound one. I am estimating 300-600 turns. It is one continuous winding in two sections, for cooling probably, and is wound in a herringbone kind of pattern which allows it to hold the cylinder shape without a bobbin. The wire is Litz wire, many tiny strands of enameled wire bundled together then wrapped with cotton (I think). I don't know how many strand Litz, either. I suppose I should take one apart, but they are so dear. DC resistance is around 72 Ohms.

However I do know the inductance of the loopstick. As I show in the electrosmog harvester video, they measure somewhat under 2 milliHenry with the core removed, and with the core all the way in they are 9 to 10 milliHenry. The one I am using as the HV Receptor (thanks for that word!) is set to about 5 milliHenry or a bit less.