Electricity Amplification by Neo Magnet

[libra_spirit]

What I am percieving from this excellent thread,

1 - Electrons want to jump off a North pole and want to enter a South pole magnet. Thus arcing to one side of the magnet should produce a faster rise time of the arc, and the other side a faster cut off time.

2 - By moving to opposite sides of the magnet on each arc we are maximizing both a faster rise time and a faster disconnect time.

3 - Now if one was to make the contact at the South pole side, slide the wire up and disconnect it from the North side, all the faster pulsing would dissappear.

4 - Conversly if we connect on the North side, and then disconnect from the South side, we would have the strongest square waves possible and the voltage should increase faster.

By hitting the wire back and forth I would assume that possibly we are creating the last instance sited.

This could be tested by sliding only one way across the magnets each time.

This would appear to be a sharp square wave generator, without introducing semiconductor heat!

Further you will discover that adding certain materials on each side of the magnet will alter its interaction.

I discovered that when arcing onto a large copper tube, placing even a small layer of water inside the tube will stop the arc from wanting to jump, and the gap becomes much smaller for the same voltage.
Arcs do not want to jump to Aluminum at all and almost as bad as water.

Copper and iron suck up arcs like electron magnets and with a 4 foot tube you no longer need a return ground wire to keep making beautiful arcs to them.

So placing an Aluminum layer on the south pole of the magnet may increase the disconnect pulse intensity, and placing copper or iron on the north pole side may increase the connect intensity. Simply wrap these over the ends of the magnet such that they touch at the center, the wire can now slide along them, and one direction of slide may do more then the other direction.

Dave L

[gotoluc]

Hi Dave,

thanks for looking at this tread It has been a while since someone has looked here. This effect is intersting and I have new developments but have not posted them. Maybe I'll do a new video and also test your copper and aluminum theory at the same time.

Luc

[poynt99]

Luc,

yes this is most interesting

please post your latest experiments, results, and findings/conclusions

thanks

[gotoluc]

Luc,

yes this is most interesting

please post your latest experiments, results, and findings/conclusions

thanks

Okay, I've got many things I'm working on at this time, so it may take some days to get it together.

Luc

[libra_spirit]

Just did an experiment.

I am using the +12 volts of a PC power supply to fire off an automotive HV coil. Approx 15 Kv I would guess.

As I hit the coil with +12 volts, the HV side is arcing between a Copper and Aluminum tube. It jumps from the copper to the aluminum.
Normally I can get about 1/16" jump using my hands to pulse the coil.

OK I add one fairly large cylindrical neo magnet to the low voltage side of the circuit. Using copper wires to tap the magnet pole to pole.

The HV side will now jump well over 1/4" into the aluminum tube. A very healthy spark for sure.
You can see why Tesla would have started using magnets for this kind of work, wow. Big difference on the output side.
As well on the low voltage current side of the circuit I am also getting wilder sparks.

I placed a copper sheath over the magnet in an attempt to protect its surface from damage. Now the sparks are reduced but still higher, The highest arcs are when I directly hit the magnet with the connections. The magnet is sucking the electricity flow into it and off the copper sheath. The arcs jump between the copper sheath and the magnet even when the wires are only on the copper sheath.

I next tried using a nail passing through a cylindrical magnet with a hole in the center, this also works, but slightly less increase. You can see you must pass the electricity through the magnetic material itself to get the strongest increase.

I started trying to increase the arc on the HV side of this circuit by placing the magnet inside the copper tube electrode, and this gave very minimal increase in the gap length. Using the magnet in the low voltage side produced far greater results.

There is a slight increase in the arc with the south pole up on the common of the power, [negative voltage leaving the South pole into the arc], but there is an increase in arc in both directions through the magnet over just using copper wire to wire connection.

A magnet would appear to be a negative resistance in this case boosting the energy of a transition.

This would tend to confirm the observation that we are lowering the transition time of the voltage on the low voltage side of the coil which causes a faster transition in the coil, and thus a greater EMF on the discharge side of the coil.

I next placed the magnet on a large copper wire such that the wire is passing inside the magnet, I also tried wrapping a coil around the magnet, and with these I now arced copper wire to copper wire and observed no increase in the HV spark. The current must move through the magnetic material to use this effect. Now using an aluminum tube I also get a minimal increase with a magnet next to it verses no magnet, now arcing copper to aluminum.

It might be intresting to add water to the experiment but will take more thought.

Dave L