Bedini's "Zero Force Motor" from Aaron Murakami :

https://www.youtube.com/watch?v=YPUajezZUng

My magnets arrived today. I'll begin work on the buzzer spinner soon.

Oersted and "Zero Force Motor" neutral zone.

Both the "Oersted Motor" and the Bedini "Zero Force Motors" are propelling rotor magnets from the center of the power coils between the poles:

Carbon Rod Oscillator.

Look at this "Pencil Lead" carbon rod oscillator from Lidmotor; This is not a "buzzer type" and runs silently without a transistor:

https://www.youtube.com/watch?v=UgXgwIea6pk

This "Carbon Plasma Arc" can definitely power a magnet spinner. Lidmotor: "It's pulsed DC (boosted to a higher voltage pulsed DC) by using a transformer. There is no sine wave though, so it is not alternating current".

Lasersaber: "The effect looks crazy on the oscilloscope"!

Oersted Carbon Arc Magnet Motor.

This looks like this may be the final, ultimately simple and least costly, test bed configuration: A thick wire between two uprights, just like the "Ludic Science" Oersted experiment; With a piece of mechanical pencil lead for one end connected to the positive pole of a battery by a wire clip. The negative pole attached to the other end of the wire, and a frictionless axial polarized neo magnet spinner underneath on a darning needle. The trick to running this as an "Oersted Spark Gap Magnet Motor" would simply be to precisely position the pencil lead just closely enough to the open end of the wire to trigger the spark. The end of the wire may need a smaller flimsy electric wire attached to it to act as a fluctuating contact. The "Full Spectrum Frequency" spark should make the magnet spinner take off and "spin like crazy"!

Precaution!

Get a protective PVC coupling sleeve around the magnet spinner before you try to power it up by spark. Wear protective eye goggles. A sudden burst of speed may send potentially lethal fragments into your face.

You can saw a notch accross the center of the coupling collar so the wire seats down inside the coupling for extra protection, and cover the top. You can cut a small window to "Laser Tach" through. SAFETY FIRST!

Lidmotor say's he drew 1 amp from his 12 volt battery through his transformer primary by spark. That's (12 Huge Watts) of wildly oscillating D.C. pulse power to rotate a tiny magnet spinner; So, you gotta watch it!

Hi-voltage winding.

My first experiment proves the need for a coil to increase the voltage sufficiently to generate a powerful enough spark. The single wire won't work with too low a voltage spark. We need a power coil with at least the number of turns Lidmotor has in his transformer primary, or a higher voltage input like the one below:

The coil I used that worked well on my prototype was a bifilar wound series connected solenoid. There's a carbon arc pictured below made with two pencils and two 12 volt batteries in series.

"The carbon arc oscillator is a crude form of "CW" oscillator and was actually used in the early days of radio to transmit AM voice before the vacuum tube came into wide use".

Two carbon arcs, one to pulse the primary of a 12 to 120 volt transformer, and another to spin the magnet from the secondary coil should work well.

Oersted test.

Doubling the wire under the axial magnetized Oersted neo spinner definitely results in twice the revolutions of the suspended neo magnet rotor per pulse contact on the 6volt battery electrode. Creating a tiny spark with the pencil lead semi-conductor held next to the 6 volt battery electrode produces a noticeable "Jiggling" effect on the rotor. This motion alone would be sufficient to generate current in a secondary output coil. Experimenting with low voltage like this is very safe.

These modest test results are actually very significant in view of their extended consequences; A spark of high enough voltage run through enough copper mass coupled with enough jiggling magnets would have to generate a COP>1 at some point!

"Carbon Arc" Oersted Fluttering Effect MEG or TPU.

Oersted's original simple experiment had a profound effect on the development of science in it's time. My simple test, anyone can replicate with the most modest materials, may have a profound effect on the development of electric generators too. It's not always necessary to have a fully equipped laboratory to perform important experiments. How we inference simple effects that would otherwise go over looked as inconsequential sometimes turns out to be more important.

We have to scrutinize how the fluttering effect of spark oscillation in a wire on an adjacent magnet might also effect a wire wound with a charged electro-magnetic seconday and an output tertiary towards a functioning MEG or TPU.

The relationships in Hob Nilre's electro-magnetic formulas demonstrate that twice the wire length and copper mass equals double the magnetic force per unit of input. Therefore, sending constant oscillating spark power input through a long enough wire with a charged seconday and tertiary output coil, has to deliver OU output at some dimension!

Placing a charged magnet wire around the primary spark oscillated conductor would have a similar effect to placing a ferrite core inside the bore hole of a copper wound inductor, increasing the magnetic force a thousand times.

The COP of this kind of solid state power generator would be directly proportional to it's weight.

I think a tuned "Ruhmkopff Coil" sending the high voltage secondary spark through a long thick copper rod, threaded through radial ring neo magnets and wrapped with an output coil would perform best.

Magnet wire insulation.

Coil wire insulation is an enemy of magnetic field strength. The thinner the wire, the less field strength per unit of volume.

Induction coil

Heating induction coils are run with low voltage and high current. Look at the picture below: What effect would running high voltage and low current from a spark arc have on this kind of coil's magnetic field?

I found this picture interesting because it appears to have what looks like a seconday coil wrapped around the base of the thick copper primary:

Magnet spark "Teetering" oscillation.

I bought a 120 A.C. to 12 volt D.C. transformer and succeeded in sustaining a carbon arc spark through the Oersted wire with the axial polarized stack of disc magnets suspended closely overhead.

I noticed something different: The magnet rotor is see-sawing rapidly up and down in addition to swinging on a rotational axis from the sustained spark; This kind of rapid "teetering motion" is not produced by the pulse current alone, but is unique to the spark.

Current must be zig zagging in all directions, not just traveling straight through the wire, causing this "rocking" and also "shivering" from the wild, full spectrum frequency spark oscillation's magnetic field.

We know the spark broadcasts an "Omni-directional RF signal"; It appears that the spark is also generating an "Omni-directional magnet field" in the wire; Of course, we already know this from the Marconi "Coherer Reciever" effect.

Graphene conductor grid.

Grid power transmission towers couldn't support the additional weight of an output winding on the wires unless the weight of the conductor was reduced. Graphene conducts five times as much as copper per area, while weighing a fifth as much, It's still stronger then steel. High voltage A.C. electrical transmission current carries a magnetic wave component that can generate power all along the length of the wire without requiring any additional input from the primary generator source. Replacing the current transmission lines with this kind of conductor material would allow us to generate power from the A.C. current passing through the wires. This would amount to a "Big Step", but we could decommission all our nuclear fission plants, stop building unsightly wind mills and save alot of coal while safely meeting all our power needs.

Magnetic neutralization and amplification.

The number of dancing magnets over the spark charged "Oersted" wire could be multiplied untill all the available space were occupied with no additional input.

A few years back, I wrapped a "Haywire" spiral coil with a magnet wire secondary, and tested the neutralization effect of masking the primary field by charging the secondary, and the results were very pronounced.

Output is dependent on a time area magnet field motion accross a conductor. Charging a seconday to create a magnetic field around a primary current carrying wire is comparable to placing a ferrite core in the bore hole of a wire coil. The permeability of the core can be compared to the intensity of the magnet field in the secondary wire; If the core permeability is too low, the material won't release its attraction and the field is not flexible enough to move fast in time. The same principle would apply to the magnetic secondary. Too much magnetic field strength would slow the time constant of flux change in the output winding.

The power to regulate the field strength in the electro-magnetic secondary wire with a variable resistor is superior to a bracelet of ring magnets, with no field intensity control. The two approaches could be combined to save power. The seconday could increase the field strength of the PM'S to amplify the primary oscillation to just the right field strength to maximize the time constant for tertiary output, any more or less would kill it.

It might help to fill a copper pipe with a high permeability core material, then run a tuned and regulated high voltage seconday spark from a "Ruhmkopff Coil" into the pipe of sufficient length. This pipe could be surrounded by ring magnets, covered by a secondary electro-magnetic winding to control the amplification field followed by the final output winding. The ring magnets may be circular one way field "Halbach Arrays" (Pictured below) to prevent core saturation. The "Ruhmkopff Coil" would allow us to turn the power up and down to the copper conductor, and the electro-magnetic winding, the field strength of the output amplifier. This constitutes the completed MEG design. This design would have to generate a COP>1 at some length, probably calculable by formula.

Oersted and Hertz.

I just completed a second set of tests with my Oersted wire; Placing a second unconnected wire along side the Oersted wire rotates the suspended magnet over it just like the primary does when the primary alone is charged. This effect has awesome consequences! Take a look at "Ludic Science's" Hertz experiment:

https://www.youtube.com/watch?v=9gDFll6Ge7g

Hertz experiment.

"Ludic Science" demonstrates the transmission of the electrical portion of the electro-magnetic wave in his Hertz experiment video, lighting a bulb.

Transmission of the magnet side of the wave is just as easy to demonstrate with a second wire and magnet spinner in adjacency to the primary Oersted wire. This effect is not induction, but broadcast transmission of the magnet wave, like the electrical radio signal.

A one foot length of copper wire will generate "X" amount of magnetic force per unit of input. Three feet of wire will generate "3X" the amount of magnetic force for the same unit of input.

Now, One foot of wire with two additional one foot wires along side in adjacency will generate the same "3X" the magnetic force for the same unit of input as if they were connected end to end, even though they're separated, due to broadcast transmission.

The tripling of magnetic force is a product of the increased copper mass, just as Hob Nilre's formulas bear out, whether the wires are connected end to end, or separated side to side in (transmission-reception) range.

Bedini powers a rotor from the side of a solenoid pulse coil in his "Zero Force Motor". The same coil could power four rotors arranged around the sides, and two more, one on each end. The proportion of copper mass to field force is the same in the power coil as the copper wire, except we only put a fraction of the coil field to work.

Where did the power come from in Tesla's "Wardenclyffe" magnifying transmitter? Answer: The receiver antennas!