Simple Free Energy Effect Discovered

[kEhYo77]

Hi. You might be onto something here.

Look what I have found recently:

New prototype generation coil compaired to standard coil http://www.youtube.com/watch?v=4MP_5MCPv1Y
VesGen 101a coil test 2 http://www.youtube.com/watch?v=is-6K7i8kjo

and some hints from Romero:

the coil must be built in the 8 figure to get the results I am talking about.I was suggesting air core for simplicity but using ferrite will show much better results.
While you build the coil you will start to understand why the figure of 8 is different than 2 independent coils.

Unusual effects in coils can be found in: where few turns at the begining are wound in one direction then most of the coil in oposite direction then at the end we switch direction again with the same number of turns used to start the coil.
EX: CW 30 turns, CCW 300 turns, CW 30 turns
This type of coil can be used in solid state configuration too.
This is just an example but coils can be made to have self amplification or self power effect but that is not to be discussed now.
If someone can view and separate the electric field from the magnetic field then you can build coils that will manifest no lenz.

Anyway, happy experimenting!

Regards,
Romero

[aether22]

I had the thought that if the inductance is not cancelled by having equal lengths of both wires, then an unequal length could result in zero net inductance, but a net number of turns in one direction.


Now I could be mistaken, but I am of the impression that if you have a net number of turns in one direction, then you can induce a voltage into such a coil.
BUT, if it does not create an inductive field of it's own (on an air-core) then you could essentially pull infinite power from such a coil, although it is possible that the thick and thin would only cancel an a given current level, this would require a given current level to be OU.


At any rate this does seem to be getting more and more interesting.
So I will attempt to make a think/thin coil with zero inductive field now.

[aether22]

I realize that for this to actually mean anything, then the ability for a coil to create an inductive field must become detached with it's ability to respond to an inductive field.


So I tried putting the thick-thin coil this time as the pickup coil, and powered a normal coil with my function generator, my hope is that the ability to respond to an inductive field is not effected by wire gauge, but that it's ability to generate is.
The result?  A slight induction, but possibly just to the extent the coil is imperfect.


I then tried connecting the coil differently, so that the 2 windings were in parallel, the resulting induction was almost 6 times higher than when they were in series.
Next I checked the thick and thin coil separately and I found that there is a little more voltage induced into the thick coil.


Sooooo.


We have the thin coil which according to the online calculator and hence accepted equations should create a stronger inductive field for the same number of ampere turns.
And then when it comes to responding to the inductive field it is either a stalemate or a victory to the thick coil.


This means we can...
Create a thick/thin coil of an (approximately?) equal number of turns that is able to be used to generate an inductive field, but which is unable to have any net voltage induced in it.
And we can make a thick/thin coil of an unequal number of turns that is able to have a voltage induced into it, but is unable to create an inductive field (on an air core anyway).

And finally we could make a complex coil producing negative impedance where one section could create an inductive field that it can't feel, and another part could be induced by it without any ability to create an inductive field.


This is looking very interesting!

[aether22]

It seems abundantly clear to me, that at least if we are looking at a coil that is initially not carrying any current, and we look at the classic case of flux threading a coil, then there is a given voltage induced per turn and the thickness of the wire is not in any way going to change the induced voltage.


My experiments and every source I can find back this up http://en.wikipedia.org/wiki/Flux_linkage, the voltage induced into a coil is not in any way effected be the thickness of the wire forming the coil.[/size]
Provided of course that we don't alter the amount of flux the coil intercepts.


So the thin coil DOES create a more intense inductive field according to accepted calculations, experiments.
But will NOT have a higher voltage induced into it.


This means in addition to other conclusions above, if we keep the same number of turns but use a thicker wire for a secondary coil of a transformer or generator, not having the drift speed it will be challenged to create as much loading at least on an air core.


Also if we use a primary of a thin wire, it will create a greater inductive field.


And again that ideal primary and secondary coils could be made that could induce or absorb energy without any apparent reflection on anything.


Pinch me, no don't.



Addition: I wonder if the calculator TK mentioned, simply used the wire gauge to estimate how effectively the flux of each wire was coupling to the other wires, so a coil made of a thinner gauge would have a greater self inductance, but not when the wires are still spaced as in my coil.
[size=78%]So I changed it to a 1 turn coil, but changing the gauge still had an impact, but is that maybe a fault of the calculator?[/size]
That is the problem with using/writing a calculator or equation
you don't fully understand.

[FatBird]

Aether22,

Please post a Schematic or Wiring Diagram.  A Photo would be Great too.

Thank you.

.