Successful TPU-ECD replication !

[Drossen]

@Ergo

When a power is first put into a wire, it jumps a little.  As an example, when you hook up a jumper cable to a car battery, the cable jumps a little.  Have you ever wondered why transformers vibrate?  It is because the wires move each time there is a major change in potential or polarity.  Also, the magnetic field is created as electrons move.  Electrons travel at the speed of light in a vacuum, and at lower speeds in a wire.  Therefore, it takes time for the electrons to migrate to the other end of a coil, which in turn causes a delay in the creation of the magnetic field coming from the end of the coil.  What this means is that the magnetic field does not instantly appear throughout the coil.  Also, did you know that a magnetic field is a vector?  In other words, it travels in a given direction, the direction of which may be warped or changed by another magnetic field.  If the north pole of a magnetic field from the end of one control coil is attracted towards the south pole of the magnetic field of the next, and so on, then the field will travel in a circle (a rotating magnetic field).  It is well documented that a rotating magnetic field may be generated using coils.  In fact the coils in an AC motor is actually a rotating magnetic field.  If you take out the permanent magnets, the coils will still generate a rotating magnetic field.  Just do a search on google for rotating magnetic fields, and you will find that there are documents and websites from universities, various companies, and even organizations such as IEEE, which talk about how to generate rotating magnetic fields using electromagnetic coils.

Drossen

[Drossen]

@Ergo

As I said before, I don't want to argue with you anymore.  I have important research to do, and arguing with you is just wasting precious time.  I shall try to ignore you from now on.

Drossen

[Ergo]

Transformers vibrate because the magnetic field is forcing the ferromagnetic core
to vibrate when being attracted to the induced AC field.

A cable jump because the field interact with the earths magnetic field.
But this interaction is so small that you can't notice it without special equipment unless
you run high currents through small wire. But then heating will cause most movement.
And there is no free energy to be harvested from this "jumping interacting"

You can have an alternating field split into several phases within a coil but you
cannot have a moving rotating field. I believe this is what you are trying to say.
Every induced field is stationary around each set of wires. The next phase will just alternate
the location of a newly formed field. But the field itself is not rotating, just alternating.
From an outside view it might look as it is rotating but this is just bad understanding.

And there is still no real proof what so ever on the things I asked for. Bedini and so on.
I guess this is telling the real truth.

OK, let's stop arguing and please continue the hunt for the holy graal. I wish you good luck.

[Feynman]

@Ergo:

If you are not willing to do the research, experiments, or reading, you are really on the wrong forum.  Extraordinary discoveries require open minds and hard work.  You are honestly wasting your time here.


@Drossen:

You were discussing speed of propagation of waves.  I find this subject very interesting.  Are you familiar with quantum tunneling?   

In recent years, some physicists have conducted experiments in which faster-than-light (FTL) speeds were measured. On the other hand, Einstein's theory of special relativity gives light speed as the absolute speed limit for matter and information! If information is transmitted faster, then a host of strange effects can be produced, e.g. for some observers it looks like the information was received even before it was sent (how this comes about should be described in elementary literature on special relativity). This violation of causality is very worrysome, and thus special relativity's demand that neither matter nor information should move faster than light is a pretty fundamental one, not at all comparable to the objections some physicists had about faster-than-sound travel in the first half of this century.

So, has special relativity been disproved, now that FTL speeds have been measured? The first problem with this naive conclusion is that, while in special relativity neither information nor energy are allowed to be transmitted faster than light, but that certain velocities in connection with the phenomena of wave transmission may well excede light speed. For instance, the phase velocity of a wave or the group velocity of a wave packet are not in principle restricted below light speed.

[zerotensor]

Nothing you said made any sense....

Well, if you liked that then you'll love this:

When a short pulse is sent down a wire, it takes time for the pulse to reach the other end, due to the finite propagation speed of light.  If the wire is wound on some topological surface, the associated magnetic field created by a short pulse will vary in time and space.  Consider a single pulse sent through a coil.  At one instant, a number of adjacent loops of the coil are energized, and a magnetic field appears there.  The next moment, the pulse has moved on a bit, and along with it, the magnetic field so induced has also moved. My point is that for long wires and short pulses there is a finite propagation speed which can give rise to an overall magnetic field that moves in space and time, and yes, it can even be made to rotate.  Introduce a core material which reacts with the applied field and you have some pretty rich dynamics.

Concerning the theory that the ferromagnetic and magnetostrictive properties of the core wire employed in the TPU are responsible for the generation of current in the device,  consider a single loop of iron wire.  Application of a current to the loop causes its radius to slightly decrease due to the magnetostrictive properties of iron.  If there is an external magnetic field present, the magnetic flux through the loop will decrease, and by Lenz's law, a current will be induced in the wire which opposes this change.  It can be arranged such that the induced current will be in the same direction as the initial current, resulting in an additive effect. A "kick", if you will...

This scenario is just a sketch, but if the wire itself is changing its shape / orientation in a vibratory manner, then the coil isn't really static anymore..  Perhaps this happens at a microscopic scale, or even at the scale of the domain lattice of the conductor itself.

Beware of the notion of instantaneity.  I'll concede a possible quantization of time at the Plank limit, but that leaves a whole lot of "room at the bottom" of the time scale as we watch the electromagnetic field fluctuate within our devices.  Claims such as "Ones a field is applied it is immediately present and it stays put until shut down." should be treated with some skepticism. There are underlying dynamics to the application and removal of the field itself;  sometimes you have to look at it in "slow motion" or adjust your reference frame to see what's going on.