ENERGY AMPLIFICATION

[crazycut06]

O wonder about "strange factors about toroidal transformers.Any tip ? Do you have a picture how is magnetic field shaped around such transformer and where are the poles ?

Do magetic poles collide inside the toroid? Or spin chasing each other? 

[Magluvin]

I found this part below from Titos pdf interesting. I dont really understand the kicks. But I do get the 1000ft wire thing I think.

What it seems like he is saying is, lets say we have 1 wire 12in and 1 wire 24in. If we induce only 12in of the 24in wire we should get only as much as we would from the 12in wire being affected by the same. But if we induce the whole 24in wire we should get more out, being that we have more in.

One of the things Ive been playing with lately is trying to get pulse motor windings to be fully affected by the magnets field instead of just 1/2 of the coil on the magnets approach then the other half as the magnet passes tdc of the coil. Here is the reason Im trying to accomplish this.

If the approaching magnet mostly or only affects the 1 half of the coil, what ever emf that is produced has to fight against the self induction of the other side of the coil that hasnt been induced by the magnet yet. Unless there is a magnet of opposite magnetic polarity in place on the rotor that is leaving the coil while the other mag is approaching. But we will still have the top and the bottom of the coil that wont be induced by either magnet because those parts of the winding are partially in line with the field motion of the rotating magnet.    So how do we get the rotor magnet to induce all of the wire of the coil without having dead spots where self induction in those areas of the coil that impedes what we are trying to induce? I dont know if it means anything or not yet.

The pics below are of  2 air(pvc ) stators that encircle the whole rotor. The fine wire  stator ring is single filar and the other ring is bifi wound. So 1 long wire for the fine wire and 2 long wires wound together on the other. The fine wire winding was done minimally for testing against a full winding ill do on that ring after.

Havnt tested them yet. Gunna try one tonight. The way the windings go is from a starting point I zig zag the wire till IM back at the start, then instead of continuing around, I just loop around the last post and zig zag the other way back to the beginning. If I just continue around, only the tops of half of the posts will have windings and just the bottoms of the others. A reversal at the start covers all bases equally. If just the tops of some and the bottoms of others are covered by just continuing winding around, the pushes and pulls on the rotor by those could cause up and down tensions on the rotor, even though the are evenly spaced out, mags are not all the same, even from the same batch.

Whats interesting about the tops and the bottom windings is that they do play a part in pulling and pushing the rotor but virtually no generation in the windings being they are inline with the rotating magnetic fields. So here we have the ability to rotate the rotor but the magnets dont affect the windings as they would in a conventional motor. That would be true if I figure out a way to make the vertical portions of the windings go away. Got some ideas. Dont know if there are advantages there yet. Kinda like delayed lenz gen but the other way around. Ill explain more if any of that is not understood.

Another thing IM thinking about is to make portions of the windings that are not affected by the passing magnets to not have self inductance, such as the tops and the bottoms of the posts by creating a winding scheme that has currents in half of the wires on top and the bottoms going in one direction and the other half in the other direction thereby eliminating self induction in those areas. Then the only portions of the winding that will be affected by the rotor or parts that will affect the rotor are the wires in the vertical slots.  I realize that there will be a lot of wire on the tops an the bottoms that will be wasted and just add resistance, but currents should flow freely beyond the resistance by eliminating self inductance in the dead zones of the winding. Like trying to get a gen coil to pump AC currents to a load while having an inductor in series with the gen coil. Or trying to capture coil collapse currents with an inductor in series with the diode and cap. It doesnt work well.

Anyways, Im gunna git.  Will make a vid of the motor in the next day or so. I think the motor should accelerate pretty good being that all mags of the rotor will be pushed and pulled every pulse. Will see.




31. If you had a short wire and you move the magnet across it, you would always
have limited potential because the length of the wire was so short.
Ok, now what if we increase the length of the wire to many miles in length ,
even with a very weak magnetic field moving across the wire you still have a
much greater potential flow of power available.
If we out it into perspective of power per inch, it may be easier to understand.
If you have a small magnetic field moving across a wire 12 inches long, it can
generate an electron flow equal to let's say 1 milivolt per inch.
If you move the magnetic 12 inches at the same speed , you get 12 milivolts
as you transgress the 12 inches of wire.
Understand that I am trying to convey a principle that you can understand for
use in the future.
So you have a wire 12 inches long, and you can make 12 milivolts moving a
magnet across it.
If you have a wire 1000 feet long and you move the same small magnetic
field across the length of it, you can create much more voltage potential
perhaps 12,000 milivolts let's say.
So, you have managed to generate a significant amount of electric power
with a weak magnetic force.
Ok, how does this help us? Where am I going with this?
Suppose you have 1000 pieces of wire 12 inches long and you run the same
weak magnetic field over them all at the same time....... You get the same
flow of electrons.
If the wires are run in series , then you will get the 12,000 milivolts etc.
If you connect the wires in parallel, you will get a higher current but lower
voltage.
However, the power potential is the same whether you run the wires in series
or parallel.
32. If you know how to find a circuit potential, you tune into the frequency and
you have enough short pieces of wire you can convert as much power as you
wish in a given space.
33. How it IS POSSIBLE to use what appears to be a weak magnetic force to
generate large usable amounts of power.


Mags

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Text version of steven mark conversation.

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