Gearless Magnet Bike

A boring fixed gear can do that, too

Nah, he should just invent a room temperature superconductor instead. Seems simpler.

A supercunductor plate would cause it to be locked together lol. It would be almost impossible to slip it. That's essentially how magnetic levitation works.

@@rubiconnn but then it could be controlled. Connecting a grounded resistor to the superconducting plate would disturb the eddy currents, and provide momentary 100% slip. You could switch it on and off PWM style to tightly control slip.
Now we just need room temeprature supeconductor. :(

Yeah that would induce instantaneous eddy currents of such proportion to effectively bolt it together, it would be an expensive, weighty and very cold cog.

might be a hyperbola

i tought the same !!! cool

​@@canteatpi or a root of some power. I think it's more likely to be a square root graph, due to the powers in the formulas for kinetic energy

@@mikhail_from_afar ты говоришь по русски? я учус, но это очень трудный язык :)

@@datbubby учусь*

Hmm... but copper is three times heavier than aluminum. If we consider that in the equation...(brain stops)

Right? It literally generated the graph.

@@operatorchakkoty4257 It makes sense on why it *looks* like a graph ... but then still "holy-shit" nevertheless

I loved how you could visually see the logarithmic, non-linear curve in that one test.

But don't the magnets need to be really close to the disc for reasonably efficient power transfer, so if you have to put the waterproof bit of the boat/vehicle between the two then that's quite a lot of spacing you didn't want. How well does it work across 3mm of fibreglass (or whatever is sufficient to keep the water/pressure out).

​@@xxwookeyYou can design for the gap with larger magnets or different materials that don't block the field as much.

These days there is no need for a watertight prop shaft as brushless motors perform quite happily in water and can be outside of the submersible.

@@robwilton9539 *barnacles grow on your windings*

​@@xxwookeyIf you're worried about pressure you could fill the engine room with another liquid and seal it off.

True. I just wished he had filmed them with his infrared camera, so that we also see the amount of heat loss

@@MrGustavier yeah true

@@MrGustavierYeah that would probably be really interesting, but I still think it’s good as it is of course

Tom is brilliant, I wouldn't be surprised at all if the heat generation turns out to be a huge positive for future project potential, surely this magnetic contactless set up could harness all sorts of free incidental energy

He could've used an off the shelf thread on 6 bolt brake adaptor for $10 instead of printing such a disc

That's why I regularly substitute lectures with TH-cam videos - sometimes there is incredible stuff to find, that saves the student (me) hours of agony and self hatred. Hehe.
Idk what these people do differently, maybe it's because they're closer to the point where they didn't understand it themselves than most professors are, but they sometimes have an incredible efficient way of teaching. (Helped me most with theoretical physics stuff)

You are not good at physics. Because you don't understand the science behind math, electricity, chemistry and biology.
You are not a professor.
You are just on papers, but the reality is painful. If my kids will have a teacher like you, I will remove my kids from the school.
You are a shame for all the italian schools and physics and science departments.

@@braindecay9477 Personally I suspect it's just numbers. If there's hundreds of youtube videos explaining an idea, you're only likely to see the best ones, and the many many terrible videos just drop into obscurity.
Whereas with your actual college course it's unlikely you have all the best professors for every subject.
Although that does create an interesting idea. Imagine if you had access to lectures from hundreds of professors worldwide and your tuition went to the ones you watched the most.

@@peterhoulihan9766 But how would that help to promote the woke communist global takeover?

Well I don't think most physics teachers have a small team, a budget that allows for cnc machining and 3d printing custom parts, and weeks/months to dedicate to creating a single 30 minute lesson (when would they do their marking?)

How about just a magnetic frictionless bearing...

In another life, I was a bike mechanic too. I probably enjoy as much these videos as you. Now that I’m doing more software and hardware, after building a few robots, it tickles me to try and build a braking system idea I had a long time ago!

as a bike mechanic in Germany, do you work on Rohloffs or other internal gearhubs. How do you like them? If this magnetic clutch/gear works, it would be fantastic!

I'm wondering if being able to vary the strength of the magnets (by making them tiny electromagnets) would make it a practical device. Sort of like gearing through magnetism. Probably not, but it's so tantalizingly almost useful.

By having Flux collector on each magnet of Faris metal you could greatly increase the magnetic strength of each magnet in the desired direction. If done correctly it could reduce the attraction to the chain.

Why not start a youtube channel with bike experimentation? It probably will pay for itself if done right... viel Glück!

oh yeah, you can literally see the non linear curve which was beautiful

This is the stuff that science is made of!

No wonder white men created all the modern science and tech

oh yes, one immediately gets it! Incredible communication

@H K And more expense! It could be a government mandate!

Totally agree, TH-cam at it’s best.

If my damned AWFUL home feed could learn this... I would be sooooo happy.

^^ I made a new account and seeded it with a Playlist of content types that I wanted and now my algorithm is much better than the old account. Probably a good idea to do this every few years to get a fresh look.

​@@DerrickBommarito replies are broken

you are very correct

Exactly what I was Thinking.
Also can't he put a steel plate on one side of the array to cancel the magnetic field so he won't have issues with the chain and spokes?

Also it makes magnetic field much stronger on one side (the clutch side) than on the other side (the chain side).

@@oodmboo If he made the diameter of the disks bigger he could fit more magnets in to give him the torque he needs to go uphill and it would also solve the spoke problem since the spokes are already sloped away from the magnets further out.
Might run into torque issues breaking the disc though.

the steel plate (ie completing the magnetic circuit) is better than a halbach array unless you are extremely concerned with size and weight

@@5naxalotl Rotational inertia is certainly important, though I don't know how much.

The answer is seen in electromobile vehicles- Alternating current (in motor wire-windings) is far more efficient than permanent magnets only (which are also present in many EV motors). Also stopping power in EV regenerative/recuperative braking had same weakness as described in this video. But - with alternating current oposing the magnet rotation, it can be managed to fullstop in most current EV vehicles.
Which translate to even not using normal friction brakes/pads at all = rusting.
So this research is not completely wasted- it just needs to simulate EV motor = induce some current in copper disc (made from thousands of copper wires, insulated of course). And electronics with variable frequency of alternating current, made by using Gate-transistors.
Of course it is not needed as you can buy such a bicycle now, but- exactly the same proces they do in Tesla, Mercedes factories/labs.

He's a mechanical engineer

Completely agreed, very impressive testing and engineering

Check his railgun project

There's another guy, James Bruton, who does very similar experiments, uses 3D printers, uses a very similar methodology AND sounds like he is from the same part of the world as Tom here. I think they should work together on a project! For example: th-cam.com/video/6YG8CsCE0WM/w-d-xo.html

Seems like youtube as a whole is new to you...

Also:
If you look at induction motor rotor design you see that they commonly have slots.
Part of the reason for these is to reduce the reach of eddy currents that cause those heating losses you see.
So cutting a bunch of wedge-slots in the copper disk would probably improve performance a lot

acceleration power is lower if acceleration is slow

@Blox117 right. And if you design the magnetic coupling to handle the cruise power, the acceleration is limited to what that power can provide
It's not a big deal, but it does show on the real-world performance tests

@@argledotorg those Eddy currents are a feature here, not a bug. It won't function without.

@@Azeazezar if they travel too far, they generate heat rather than force.
This is an induction motor stretched out onto a plane, with the moving electric fields provided by physically driven permanent magnets instead of AC/stepper controller driven electromagnets.
It's an elegant and clever device, for certain.

I think you're the guy we very much needed on this party. Thank you.

Chain sticking is solved by using a rubber belt

Tom, this response is on the money. Ferrous materials will provide a much lower magnetic impedance than air, increasing the magnetic flux density experienced by the copper. So putting some of the outside faces of the magnet groups will improve performance.
Again, on the money; watch out for heating and ideally turn that ferrous material into a heatsink for the magnets.
Finally, milling a shallow pattern into the copper to sort of turn it into a centrifugal fan, (increasing air turbulence and heat transfer) may also extend the operating envelope.
Mind you, it will always be lossy. Maybe it's more of a mobile cardio machine?

​@@pchandle c'mon peleton!

Electro mechatronics engineer here and were about to write pretty mich the same thing! However I disagree on the heat part... Yes the magnets suffer from higher temperatures but the heat is generated in the disk and not in the magnets. The suggested ferromagnetic parts to close the magnetic flux would alsobserve as additional radiators for the magnets to get rid of heat.

Yes! I think this would probably double the performance at least. Mumetal is ideally suited for the job (which is why they use it in hard drive voice coils)

Would it not work better if there were magnets distributed around the disc ?
(perhaps at pitch centres corresponding to say 9/10ths of the pitch of magnets, to get a sort of vernier effect).
I guess the poles on the frame would want to be opposite polarity to those on the rotating disc. You'd want magnets both sides of the disc, to balance out the axial forces.

@@Gottenhimfella Quite a few drawbacks to your scheme - The damping (i.e. conversion of kinetic energy to heat) happens in the conductor, not in the magnet. A magnet shall store energy as potential energy (and then is mire like to demagnetize too, but that is a different story). So, to convert KE to heat, a conductive disc is essential. The added moving magnets shall add inertia to the rotor (non-issue in a bicycle, agreed) Second issue is that of axial (parallel to the axle of the wheel) force - rare-earth magnets of this size pull hard - a symmetric construction with two sets of fixed magnets and one moving conductor has no axial forces, and hence can be thin and slim.. to work-around this, perhaps 8/10th or 7/10th would be better. The third issue is cogging. Even with the Vernier, you would feel some. The advantage in your scheme (if I understand it correctly) is that you eliminate the air-gap on one side of the damper. The disadvantages that you have to pay as a price are, imo, not worthwhile (at least with my understanding of your described concept. Feel free to 3-d print a holder with 7-magnets and 10-magnets arranged in a circle and try twisting them against one another :) (without a conductor, it will feel more like a detent than a damper)

You didn't learn how electric motors work in engineering school?

@@trentvlak To preserve your remaining dignity, I suggest you stop speaking now.

@@NikitaOsito explain

From the perspective of a computer guy, on a value-per-hour basis, school is outpaced by deliberately playing around, especially after a certain point

quit paying that place you call a school

Add 80w of power and no need to pedal?

I was going to ask the same question. Thanks!

It looks to me like the rear sprocket has a ratchet, so pedalling backwards wouldn't turn the magnets in reverse. I think.

​@@ParaBellum2024 actually on rear sprocketed wheels you *can* go backwards. its just VERY slow, if your not in a BMX park or on a slope.

I think it did pan out. If the copper disk is replaced with some coils like in a motor, you can improve efficiency greatly. This is a first design and there is lots of room for improvement.

Seeing your comments across a few different channels at the moment. Dont you have videos to make!!😊

@@UncleChopChop22 have and owe are two different words as per the dictionary.

If you thought about it for a minute, you would know this. Here's an important thought experiment: what if you replaced the ring of alternating magnets with an actual machined ring neodymium magnet concentric with the axle? How much torque would be transferred?
Zero. The answer is zero. It would spin freely.
Eddy currents form when there's a *change* in magnetic field, not just whenever there's a magnetic field. So the more changes there are, the more eddy currents form. The only limiting factor is when the magnets get so small that the changes in magnetic field don't bridge the gap from the magnets to the conductor.

Maybe the printable magnet company featured on SmarterEveryDay could create a tiny alternating pattern th-cam.com/video/IANBoybVApQ/w-d-xo.html

@@Squancherino You people do understand that the efficiency asymptote this thing is approaching with more effective magnetic fields is identical to just gluing the two plates together, correct? There is literally zero benefit to this clutch? I feel like everyone is missing this fundamental concept.

Do not forget that Trains are fitted with induction breaks. No wear, and at high speeds to stationairy rails incredibly effective.

Roller coasters use this for emergency brakes.(obviously using a secondary brake so the train comes to a complete stop)

“D-did he make a new air engine dear?”

@@diet-water No but it's just as pointless

​@Don't Read My Profile Picture this is getting pretty old

Lol

"Speaking of nowhere..."

It's fine for a brake, where you are trying to convert energy to heat. That's not what you want for a transmission, where you want to waste zero.

Its also used for high speed trains to stop it from a high speed. Its a huge magnet thats dtops down to like a millimeter above the rail. de.m.wikipedia.org/wiki/Magnetschienenbremse

@@jonkess2768 Not just on high-speed trains. Old trams had an electromagnet braking system on the rails. But in both cases the rail is steel, and permanent magnetism is used; in the case of aluminum, a different principle of operation is used, due to the induction of an EMF in a short-circuited circuit, the so-called “Foucault current” or eddy currents, which occurs in a conductor in the form of an aluminum disk its own magnetic field arises, which slows it down. By the way, the same problem occurs in speakers, which reduces the output at high frequencies due to increased electromagnetic induction, and to compensate for this phenomenon, copper short-circuited caps are used on the core of the magnetic system.

It could be the basis for a new kind of automatic transmission in cars. Instead of an epicyclic gearbox driven by fluid, pressure and friction with wet clutches and bands, it's magnets!!! Clutches, bands and the hydraulic fluid in an automatic transmission will wear down over time, but magnets will probably last a lot longer.
The magnets could be turned on and off electronically (they would be electromagnets, not permanent ones). Instead of clutch packs being pushed together by a piston, it's a current turning on electromagnets to make two discs lock together. The current would replace fluid going through solenoid valves in a valve body.

There are row machines with similar magnet setups too.

The purpose of your exercise bike is to give you exercise - to make you work, by resisting your pedaling. I'm sure you will notice that the disk between the magnets warms up, because your work being used to generate heat. In Tom Stanton's case, however, the desire was to convert the work into distance. So the desired outcome of the two machines is opposite, one to waste your effort as heat; the other to use your effort to go so0mewhere - but the actual outcome is much the same. Work produces heat. Your exercise machine uses *_all_* your work for heat generation; Tom's machine gives some distance travelled, but it is limited by its inefficiency, which produced heat.

@@DownhillAllTheWay i agree totally. Which was not difficult because you basically told nothing new.
It is basic logic.
IF your exercise machine was using your work to give you some distance it would become a problem because you need a large room to house it in.
Btw, you could just take a bike outside if you want some distance travelled while you work.
The whole idea of an exercise bike is that it is stationary and doesnt travel any distance.
SO by that way of thinking i would say it is kinda pretty logic what you explained.
And, some would then be very rude and say: Jeez, thanks Sherlock.
But i wont.
I just think it.
>:)
(yeah, i am a stupid dutch guy, so i blame it on that)

@@DownhillAllTheWay o damn, sorry, i forgot to add this but it has to be added.
The first part you typed:
The purpose of your exercise bike is to give you exercise.
I forgot to add it but it should be somewhere in the start of my comment to make it more clear why i would think: Jeez, thanks Sherlock.
>:)
Just a joke sir, just a joke.

@@bertjesklotepino Hi there! Don't worry, I took it as a joke. I was commenting on the video - not trying to explain it - but I'm sure you understood the intent of my comment. All of the best to you, Sir!

Remember that the Lord Jesus Christ died on a cross for you because He loves you so much. He then rose up from the dead three days later
The Ten Commandments are called the moral law, (most of us are lying thieving blasphemous adulterer at heart and deserve hell) you and I broke the law, Jesus paid the fine. That’s what happened on that cross.
By believing that Jesus died on the cross and rose up from the dead 3 days later and not just confessing your sin, but also repenting of all sin you have done and putting all your trust in Him in prayer, He will grant you everlasting life as a free Gift

@@dove3853 Bit off topic mate.

@@Billybobble1 That bible bashing fool didn't even knock on your door before randomly spouting his completely irrelevant BS at you. Pretty damned rude I'd say.
Completely agree with your assessment and way of seeing this and others of his videos. There's so much I'll never understand but, I still learn from this sort of thing. One question I had he did answer was, whether the resistance was converted to heat or not. If it hadn't, it could have opened up a few more interesting possible uses like speed control of things without wear, obviously but, heat can be a problem too and a non heat generating device could be extremely useful in some situations. Still very interesting stuff though.

@@dove3853 Tell Jesus I'm not interested

From an engineering standpoint, I see two obvious improvements.
Although copper is a better conductor than aluminum, aluminum is stronger and better for transferring work. Use aluminum instead.
For the magnets interfering with the chain, modify the sprocket to cross the whole axle and put the magnets on the other side.
As for coasting, modify the clutch so that the bike rolls freely even if the sprocket and aluminum plate are stopped. I wouldn't even try adding a magnetic braking system to this setup because that would transfer a ton of momentum to a small part (the sprocket area) which would wear out the sprocket very fast.
If you wanted magnetic braking I would suggest a secondary aluminum plate on the chain side of the wheel. Make it fixed so it moves with the wheel at all times. Then have magnets slide in and out from a fixed position on the bike, probably under the seat and well away from the chain.

One of his tests demonstrates that the torque generated was proportional to the difference in RPM between the disc and the magnets, so yes, pedaling backward would increase this difference in speeds, and therefore produce more braking torque.
The other question is interesting. The eddy currents that the magnets induce in the copper disc flow in a ring around the magnets, lagging behind the magnets because it takes some time for the current to die off once it's induced into a particular path. This is really how the torque is created - the ring of current induced by the magnets produces an opposite magnetic flux to that of the magnets, that's constantly trying to align itself with the magnets, so any rotation of the disc produces a "back torque" that opposes the motion. If you were to fit carbon brushes either ahead of or behind the magnets, current passed through the disc through these brushes will also produce a torque for similar reasons. You will have created a DC motor, but this would be very inefficient because the current you apply to the brushes would not just flow through the copper directly between the brushes, but also though many other paths that would not produce usable work. This could be improved by cutting slots radially at intervals around the disc, between the brushes, which would reduce the undesired currents without affecting the intended current path, but now you're getting closer to a conventional commutated DC motor. Which sounds like something interesting. However, if you look up radial flux brushless DC motor, you will find that this is very close to what is already being used for low-speed, high torque brushless motors.

Pedaling backwards does increase the braking resistance, because it means the sprocket RPM becomes 'negative' and the net RPM difference becomes larger.
Regarding electrical current, the current in the disc is not DC but it's a localized AC current which moves along with the magnet's rotation. To get the disc to spin using electrical current, you need to apply a rotating magnetic field through a set of coils. In his experiment, the magnets are replacing the pole pairs of a motor.

thats what i was asking myself the whole vid too😭

@BrightBlueJim Thanks for the response. I'm not an engineer and am not up to speed on the theory of DC motors. I know enough about electricity to be dangerous. My crude thought process was that an electrical current might increase the amount of torque that is being applied to the wheel from pedaling and provide a better braking action. Thanks again!

@@BrightBlueJim The homopolar generator designed by Michael Faraday was a similar design as well, very cool seeing how this is basically that but with no wires connected to it.

Don't those work by increasing the viscosity of the ferrofluid? No eddy currents involved.

I think magnetic clutches use magnets on both sides? So it'll be equal speed up to a certain torque. I doubt anyone would want to run something with constant slip.

@C. I think that's specifically when you want to lose energy, I.e., braking. You would want to use something like that for driving something.

I believe the air conditioning compressor also engages with a magnet clutch

Yeah thought the same. Does not make any difference just pedalling backwards when trying to brake?

It will make a big difference. The speed of the magnets and copper disc relative to each other determines how much force they exert on each other. So at higher speed he exerts a lot of effort just to hold the pedals still, but at lower speed it should be possible to pedal backwards and therefore create enough force at the wheel to stop in a reasonable distance.

I mean the force was so strong it was basicly pushing his feet forward. Maybe peddling backwards wouldn't even be possible at higher speeds.

@@jackbauer2698 if you look into the world of fixed gear cycling, you find that people can break the traction of the rear tire and lock it by pulling up on the straps that they install on the pedals. The only thing preventing you from pedaling backwards is the traction of the rear tire.

It would either be enough resistance to break something on the bike, or open a rift in the fabric of reality...

It will give you a stronger field but you also have to keep in mind that he didn't much space to mount the magnets. The magnets would touch or overlap with the chains and spokes if he would use the halbach config

​@@Player-pj9kt he don't have to use chains there are belt driven bikes already and they make much more sense because the belt isn't magnetic

@fischX it still might get in the way. The spikes as well if he puts the magnets on both sides. Easiest solution is to use smaller cube magnets but those magnets are probably not as strong

wouldn’t it just give you a stronger field on one side? so instead of a bunch of change in flux from north to south from the individual magnets to a change in flux of let’s say north to nothing but with a bigger north?
would it actually be any better?

I was looking for this comment, I agree that a Halbach array should make even weaker magnets work better.

up

I agree... He definitely needs to make a version 2, with some kind of centripetal action, because he wants a CVT. I'm not clear on whether the low RPM engagement should be at the outermost diameter of the copper disc, or the innermost, for the proper torque multiplication (I think it should be on the outermost at 0 RPM and move towards the center as wheel speed increases).

I wonder if he could get the copper hot enough that it stops being able to produce eddy currents. I know heat can kill a permanent magnet and hot iron won't stick to a magnet until it cools down.

@@andrewdescant Well, the heat would certainly affect the resistance of the copper, just as it does in any other electrical component.

@@andrewdescant I don't think you could reach those temperatures by pedaling outdoors, since the rate at which it loses heat increases with the difference in temperature vs the air. Would be wild though

Was thinking the same thing. Halbach arrays are often used in permanent magnet motors due to the lower weight and cost. It would be perfect for a project like this.

Could you use a belt instead of a chain to help with the weak points on the sprocket and the magnetic interference?

This was meant to go in the main comments. Whoops

*manhole covers

not possible

They are magnetic but it would slow you down if anything

​@@Pooopersno shit!

Or the chain passing thru the magnetic fields developing a current and shocking you!

But this is already in use. It's basically how an old school speedometer works. A spring loaded aluminium cup is driven by a magnet inside, that's it. Also many old record players use magnets to fine tune the speed (eddy current brake).

@@westelaudio943 Cool. I did not know that

if only he didnt have that bloody accent

Seriously, that was brilliant

That's correct but he will have to either have to cube magnets with the same field strength or he will have to increase the gap between the magnets chains and spoke for it to work

@@Player-pj9kt not really. A halbach array produces weaker field "outside", so the spokes and the chain should actually stick less!

@quinor I'm not talking about the sookes and chains attracting to the magnets I'm saying that the magnets he us using will physically collide with the chains

ehh clearances... fair point.

thats good suggestion. It would increase the torque for that design but not the efficiency of the system right? The main losses are in the copper if I understand it correctly.

Actually, they now call it dynamo iron, as it is no pure iron anymore, but an iron silicon alloy.

@@LaggerSVK My experience with electro-magnetics is somewhat limited. My most recent experiment was a axial-flux motor for a heated stir plate I was making. I couldn't source suitable materials so I recycled the windings and core laminations from a large transformer to build it; not ideal for the frequencies that I drive it at but it ended up working reasonably well.

@notfiveo If you have electro magnets you're building a motor. More speed holes.

@@1800Supreme well steel is not as good as copper. And you'd need a battery for running the electromagnets. But the advantage is that you can switch them on and off to create some kind of a gear ratio I guess.

The magnets on the other side of the disk we cant see may be interfering or attenuating the magnetic field. I would test by first removing them leaving just one side full of magnets and the next test with different patterns, e.g. opposite sides, same plane. also using metal back-plates on the magnet helps allot
[S N] |Cu| [N S]
[N S] |Cu| [S N]
config 1/5
[N S] |Cu| [N S]
[S N] |Cu| [S N]
config 2/5
X X |Cu| [S N]
X X |Cu| [S N]
config 3/5
X X |Cu| [S N]\Fe\a
X X |Cu| [N S]\Fe\a
X X |Cu| [S N]/Fe/b
X X |Cu| [N S]/Fe/b
X X |Cu| [S N]\Fe\c
X X |Cu| [N S]\Fe\c
config 4/5
d\Fe\[N S] |Cu| [S N]\Fe\a
d\Fe\[N S] |Cu| [N S]\Fe\a
e\Fe\[N S] |Cu| [S N]/Fe/b
e\Fe\[N S] |Cu| [N S]/Fe/b
f\Fe\[N S] |Cu| [S N]\Fe\c
f\Fe\[N S] |Cu| [N S]\Fe\c
config 5/5
d\Fe\ or /Fe/a represents iron plates that connects two magnets together, one magnetic pole to another on the same side. a to a, b to b, c to c.....
X X represents the absence of magnets, Iron, or Copper. Nothing basically.
|Cu| represents the copper disk
[N S] or [S N] represent dipole magnets, N being North and S being South

I hope Tom in the event he finds a real game changer, he registers it first with the Patent Office London.

@@matsuz100 patents only prove said person invented said thing. He can demonstrate that he came up with said idea here 1st icluding the dates of all the footage he has used.
But from watching all he has done I think with more work he is onto something great hopefully no toerag will steal his idea.
Finally he has inspired me, period