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Author Topic: A Solid State Homopolar "Motor"  (Read 4565 times)

broli

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A Solid State Homopolar "Motor"
« on: May 01, 2021, 10:34:28 PM »
Well I have had this idea for a while but due to lack of resources never did much with it so I thought I would share it instead of it collecting dust.


Based on the homopolar motor (and if you went balls deep into the sometime controversial research) we know that that a current carrying wire which goes towards the rim of a magnet can induce a torque on the magnet. The problem is that this current or charge needs a return path, but any return path will torque the magnet in the other direction so the only way to fix this is to attach a conducting disc to the magnet. Now this "return" current will also induce a torque but since it's attached to the magnet it cancels out and thus only our stationary current wire will induce the torque on the magnet (+disc). But the "problem" here is that an EMF is generated in the disc due to rotating charges in a magnetic field. This is a short crash course for a classical homopolar motor and illustrated in fig 1 below.


Now comes the interesting question, how can we eliminate the return path? If we could we would have the benefit of the torque on the magnet without the back EMF side effect right? Sadly we can't make charges disappear as soon as they reach the rim of the magnet due to something called Kirchhoff's current law. But what if they did not have to disappear what if they could just move back along the same path. This is illustrated in Fig 2.


This thought made me realize that this setup would pretty much be a capacitor or even an antenna due to its open nature.


Which brings us to the final 3d design. It's a capacitor/antenna setup where charge is moved back and forward. The coils contain many turns and act like the "magnet" in a homopolar motor. The hypothesis here is that when the charges move towards the coils (aka the rim of the magnet) they will induce a "torque" in the coils, aka an EMF. There's still some other interesting things to discuss but I'll leave it at that first.


I know some community members are very experienced with high voltage and frequency devices so this is also a shoutout for help to just check if anything at all would be seen on a scope when such setup is put together. I'm not sure if a DC bias on the coil is necessary or not as well.


PS: I find it interesting how this is also similar to many designs out there in the OU communities. Such as the infamous kapanadze device. Only using a very simple and basic explanation.




Smudge

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Re: A Solid State Homopolar "Motor"
« Reply #1 on: May 03, 2021, 10:25:20 AM »
I think your reasoning is wrong here.  Looking at your Figure 2 I agree that you can use the equivalent current concept for a permanent magnet to deduce forces on the magnet.  With the positive charge moving towards the rim you depict the force on the charge correctly, but the force on the magnet is not the induction force (acting on the charge carriers of the current) that you predict, at that point the force is zero.  If you meant that to represent a rotational force on the magnet then that also is wrong.  This is one of the paradoxes for charge moving towards (or away from) a line current.  If your line current came from minus infinity and went to plus infinity then Newton’s Law of action and reaction would be broken.  However for closed currents as you depict Newton’s Law holds, and in your case the forces on the current loop are maximum towards the top and the bottom in the counter direction that you show.  The magnetic field ahead of the moving charge forms concentric circles around the velocity axis, and you can deduce the force on each current element from their intersection with the current using Fleming’s LH rule.  They integrate to a net force on the whole circular current, i.e. a linear force on the magnet, not a rotational one.  If you consider the field circles to be moving at the charge velocity, then the induction into each current element by Fleming’s RH rule is zero, the force there is radial.  Note tor the charge moving away from the current loop in Figure 2 you have the force arrow on the moving charge in the wrong direction.

Smudge   

broli

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Re: A Solid State Homopolar "Motor"
« Reply #2 on: May 03, 2021, 06:01:52 PM »
I think your reasoning is wrong here.  Looking at your Figure 2 I agree that you can use the equivalent current concept for a permanent magnet to deduce forces on the magnet.  With the positive charge moving towards the rim you depict the force on the charge correctly, but the force on the magnet is not the induction force (acting on the charge carriers of the current) that you predict, at that point the force is zero.  If you meant that to represent a rotational force on the magnet then that also is wrong.  This is one of the paradoxes for charge moving towards (or away from) a line current.  If your line current came from minus infinity and went to plus infinity then Newton’s Law of action and reaction would be broken.  However for closed currents as you depict Newton’s Law holds, and in your case the forces on the current loop are maximum towards the top and the bottom in the counter direction that you show.  The magnetic field ahead of the moving charge forms concentric circles around the velocity axis, and you can deduce the force on each current element from their intersection with the current using Fleming’s LH rule.  They integrate to a net force on the whole circular current, i.e. a linear force on the magnet, not a rotational one.  If you consider the field circles to be moving at the charge velocity, then the induction into each current element by Fleming’s RH rule is zero, the force there is radial.  Note tor the charge moving away from the current loop in Figure 2 you have the force arrow on the moving charge in the wrong direction.

Smudge


I'm really glad someone is willing to have an intellectual discussion about this. And even more glad it's you Smudge, seeing your experience and knowledge on this topic.


I totally agree that this idea is riddled with paradoxes and controversies one of which you mentioned is the reaction force paradox. This is also related to the question of where the recoil of a railgun is located. And as research has shown this is at the back of the the railgun where the return path connection is made, not so in the rails. As the next thesis on that also concludes:

An Experimental Study of Electromagnetic Lorentz Force and Rail Recoil

The relevant conclusion:

Quote
combined with the results from the split rail Lorentz-recoil measurements (Figure 21), leads to the conclusion that there are not any internal stresses within the rails.

Or the "Railgun recoil, ampere tension, and the laws of electrodynamics" paper attached below which indeed shows no longitudinal force EVEN using the classical and forgotten Ampere force law (which imo is a good thing):

Again I quote:
Quote
The net longitudinal force on any element of the armature, and onthe armature as a while, is zero to with the accuracy of the calculation.

Another more recent paper (which cites the previous) also shows with Finite element modeling that this force is is mainly on the transverse part of the circuit rather longitudinal parts.

Comparative study on longitudinal momentum characteristics of L-type and I-type breech in railgun

Quote
The simulation results show that the longitudinal force on the breech is concentrated on the current injector plates. The longitudinal force on the power connector of L-type breech is much bigger than that of the I-type breech, up to nine times.

To me this makes total sense as well, even from an intuitive point of view without any equations. If you would replace the free flowing current with water in a U-shaped tube and apply pressure on both ends, the resulting pressure will emerge perpendicular to the surface causing a reaction force at the returning U path of the tube at the bottom. Moving the whole container down, it would be silly to think that the force would be longitudinally on the straight tube pieces cause them to crunch as I illustrate in Fig 3.
 
So now that we have established that I can comment on your points. The thing is that the force equation aka the Lorentz force goes hand in hand with the Biot-Savart Law as you know, to be of any kind of use. This implies that you indeed can calculate the force acting on a free moving charge due to a magnetic field. But it's always assumed that this magnet field source comes from a closed current loop. The Biot-Savart Law breaks down the other way around, as a free moving charge is not a current carrying loop.

This is why, in my brain, I always go back to classical formulations such as the Ampere Force law (not the one about parallel current wires) or Weber's electrodynamics. That can handle charge on charge interactions in a Newtonian way i.e. along the connecting radial vector. This allows you to analyze interactions of isolated charged particles in an n-body simulation. I show this in fig. 4. Here a free charge moving towards a "wire" will act on the current elements (depicted as red circles) in such a way that "opposes" the current, when it passes the wire the direction is reversed, and when combined we indeed see that the total force would be perpendicular to the "wire".

This is also the basis of this proposed idea/experiment. I have yet to come across any such experiment, and a magnet in a homopolar motor is not a current carrying wire either so this proposed current "inducing" force can only manifest as a mechanical force on a perpetually spinning electron I believe.

The key here is that the charge never crosses the edge/wire where everything is reversed including the force that just induced an EMF. In fact I intentionally left something wrong in fig 2 that you mentioned, but it's not the force direction as this should be in accordance with the left hand rule no? What I left out is the fact that when the charge moves back no matter the direction of the current loop, this proposed EMF will always be in the opposite direction. This is why the the current loop must have NO current when the charge needs to move back. It can only have current when the charge moves towards it. I see this as a square wave sigbak, where the signal is off when the charge moves back again.

I hope this will interest someone enough to do some basic experiments, all of this is deduced from first principles thinking. There is no magic Russian special sauce or UFO alien technology involved. This experiment can be performed with reasonable voltages, obviously the higher the better but regardless the induced voltage may be tiny.

broli

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Re: A Solid State Homopolar "Motor"
« Reply #3 on: May 04, 2021, 10:02:34 AM »
I wanted to share the following interesting paper.

This one almost is exactly describing the same setup/idea I'm bringing forth here:

Experimental Confirmation of Weber Electrodynamics Against Maxwell Electrodynamics

However that experiment was performed on a magnet and mechanical force was measured. The one I propose is pure electrical in nature and thus the "solid state" label.

Smudge

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Re: A Solid State Homopolar "Motor"
« Reply #4 on: May 04, 2021, 04:35:02 PM »
Broli,

I can't follow all that math in Kuhn's paper so I can't comment on his assertion that Maxwell electrodynamics offers a reverse force direction to Weber electrodynamics.  I am just happy that the observed direction agrees with the LH rule.

You might care to look at my paper on the Inverse Corbino Effect in cylinders that offers the possibility of a solid state generator.

Smudge

P.S.  Is there any way you could resize your images so that the text fits the screen?  Having to scroll right to get to the buttons is a pain.

broli

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Re: A Solid State Homopolar "Motor"
« Reply #5 on: May 04, 2021, 07:11:12 PM »
Well this is why I liked it when I saw your first post. Your ideas and interests are along the same line. I think I have seen that paper of yours in the past but didn't really understand it or had the same knowledge on this topic back then as I do now. I completely understand the reasoning now and should indeed generate a voltage as you show. In fact this voltage should be a positive sinusoidal wave which never crosses zero if I'm not wrong.

Wouldn't there be a negative feedback loop that would ultimately try to stop the eddy currents? I mean let's say you used a superconducting sleeve then the eddy currents will match the coil currents exactly. These eddy currents will indeed experience a transverse force acting on them due the hall effect/ICE/ampere force law/(pick your name). Then this newly induced current will on its own cause a circular EMF opposing the eddy current, reducing the initial transverse force aka the induced corbino EMF. So you end having magnetic induction effect being reduced by the inverse Corbino effect until no eddy currents or ICE current flow at all.


Quote
P.S.  Is there any way you could resize your images so that the text fits the screen?  Having to scroll right to get to the buttons is a pain.

Sadly I can't edit posts that have been older than a few hours it seems. I will try to avoid that from now, I work on an ultrawide screen so the issue is not really visible to me, but I don't understand how this forum does not support thumbnail previews that you need to click to open in full glory.

broli

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Re: A Solid State Homopolar "Motor"
« Reply #6 on: May 05, 2021, 08:44:57 AM »
Btw I did not mention this in the previous post but the Corbino effect is something I would like to avoid in the proposed design. That would actually be a part of why there would be no back EMF on the source (aka the capacitor).  I did not illustrate this to not overly complicate things put preferably the capacitor/antenna design would have slits or be made of individual wire strands like you can see below to eliminate the Corbino effect.
« Last Edit: May 05, 2021, 12:44:57 PM by broli »

broli

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Re: A Solid State Homopolar "Motor"
« Reply #7 on: May 06, 2021, 08:01:05 PM »
Well here is a potential improvement. Typically in a dipole antenna the current is maximum near the terminals and goes to zero at the tips. But I thought how can we get this larger current closer to the edge of the pickup coils as this higher current will definitely generate more voltage in theory.


Well the solution is quite simple, we do NOT want to cross the edge of the magnet as this will negate the theoretical induced voltage BUT if we were to stay on the edge we would be fine as long as the charge does not cross the coils. Hence the design below here a part of the antenna goes around the pickup coil. One part goes clockwise and the other counterclockwise to eliminate any classical magnetic induction as much as possible as we are only interested in the induction caused by the straight antenna piece which in theory should have no back EMF reaction.


This design offers more current as the higher current will be much closer to the edge of the pickup coil offering maximum forces.