I guess the next step is to build a superconductor clutch to avoid the heat issues. That'll totally work.

I'm a physics professor and this whole project is incredible! That's one whole chapter of the textbook in a single short video!

The positioning of the weights at 7:44 is such a pleasing real-world representation of a log graph, I love it

"...and this result wasn't linear" @7:38 Beautiful visualization. Nicely Done!

The side by side comparisons are astonishing, it’s amazing to visualise the different behaviours induced by different configurations of magnets and weights

As a bicycle mechanic over in Germany I gotta say, I really love your bike related videos. They give me great aspiration, sadly I lack the funding to copy your concepts for my own fun. But they make great talk in the break room!

Those calculations with the dropping weight videos were awesome, such an excellent visualization.that section was great!

I like how you're talking with simple language and not just scientific things so everyone could understand you Thanks man

The alternating magnets for stronger eddy currents was a great idea! You might want to look into the Halbach Array (a specific way of alternating magnets) that makes the field strength even higher. I think it might perform better than only alternating the magnets.

I think you may have missed a trick. Putting an iron backing plate on both back sides of the magnets (ie facing opposite the copper disc) would give you two additional advantages. One being the flux would be more constrained and not grab the chain/spokes and the field facing the copper disc would be more intense. However the heat due to loss will definitely be more severe when the clutch starts slipping and will equally affect the magnets, which in your case, due to their size might have been a bit cooked too, but cooled faster due to less thermal mass. But in theory, the increase in efficiency would mean less slipping. Another factor is that neodymium magnets permanently lose their magnetism when heated to approximately 85deg C, which is why when these types of clutches are used in industrial applications, there is usually a significant liquid cooling system that either flows through the clutch components, or the clutch is immersed in it. They are very precise and consistent (repeatable) clutch designs that can absorb massive dynamic changes in force, so they are very useful in other applications, where longevity and smoothness are more important than efficiency in the force transfer. They are also used as brakes and dampers for similar reasons and also have more traditional lockup mechanisms and or clutches for greater efficiency when output (or input in the case of braking) has reached a certain speed. Obviously these are stupid expensive, mostly due to materials, proper matching of the specifications, and definitely being customised for the application, not to mention bulky, but sometimes they are worth it, to solve particularly difficult problems where traditional force coupling mechanisms don’t work as well. Anyway, sorry for being “that guy” at the party, great video and demonstration of a very useful and niche device!

The comparison shots of the falling weights was incredibly well done

I would suggest utilizing the Eddy currents to store energy so it can act as an electric bike when needed. The heat is generated from those unutilized currents. That would solve your inefficiency.

Making the copper plate thicker would reduce the number of magnets needed by decreasing the resistance for the eddy currents. And as other people have commented mounting the magnets in a steel mount would also improve the performance by helping to concentrate the flux. Similar just for kicks project would be to try to convert this into a homopolar motor regenerative braking setup with some big capacitors.

As a retired engineer who cycles a lot, I enjoyed this immensely!

Tom again shows us not only how clever and creative he is, but also just how great KZbin can be with the right content providers!

I was very dubious at the start, thinking, “oh, yeah, another magnets perpetual motion scam”. . . but no. I learned a lot from this. . . an honest presentation. Nobody’s going to win the Tour de France with this setup (especially me, a 79-year old time triallist)😊 Well done, sir!

Your meticulous research and trials of materials and forces is truly impressive. Then to advise us that it didn't work as you had hoped shows your humility. Thanks for sharing this whole story.

One factor you seem to have overlooked is that if you want higher braking at low speed you could always just pedal backwards and increase the effective relative speed of the wheel vs the magnets. I do otherwise agree with people's suggestions of reducing the amount of copper used. I'd also suggest, from my limited electrical engineering knowledge, that you cut air gaps between sections of the copper, as that should cause greater eddy currents since the air will act as a dilectric and theoretically cause increased resistance. Will admit I'm unsure if that'd improve the effective coupling overall, but it seems like something that would at least have an impact.

This channel was new to me. I was blown away by the concept, quality of the build, quality of the experimentation, and the quality of the video production. You, Sir, are really good at this!

There is a bicycle trainer device called the Kinetic that has used this principle for decades. The resistance unit is hydraulic, that has a sealed chamber to prevent leaking. It’s hard to seal around a shaft, so they drive an impeller inside the sealed chamber with a magnetic clutch. My trainer is decades old still works great and no leaks.

Hi Tom The checkerboard is only useful if you also want drag in the left-right direction.; generally the magnet diameter should be greater than the gap between facing magnets. More importantly, please look into "back irons" - these will easily improve the effectiveness by 2x or 3x and shall also eliminate the problem of the chain sticking to the magnets :)

In home exercise bikes, a magnetic brake is sometimes used in the form of a set of fixed permanent magnets (or electric magnets in expensive devices), and a perforated metal disk (similar to an aluminum alloy) that rotates through an upshift pedals. The adjustment of the braking force is regulated by changing the distance of the magnets from the rotating disc. Excess heat is dissipated from the disk into the air by means of a small impeller with blades on the disk shaft. Thus, it turns out to achieve a fairly wide range of loads (from 50 watts to 1.5 kW) with modest dimensions of the device.

I noticed that this is much the same as the way my exercise bike works. There are two belt-and-pulley setups that spin an aluminium disc between a couple of magnets. The resistance is varied by moving the magnets in or out. And yes, my efforts go into making the disc get hot!

I think the best use of this sort of thing would be if you had a normal chain drive, but you could engage and disengage it like caliper brakes for coasting down really long and/or steep hills. Much quieter and no brake pads to wear out. Also have conventional brakes for emergency stops.

Tom, I really like your focus on the subject of your videos. Been watching you for years and as many other channels over-hype, fast-cut, force jokes, etc... you've stayed one of my favorites. I can watch you when having a slight headache and it's not too much but rather interesting and calming. Also, good on you to commit to all your interesting ideas, figure out if something would work and show it. You test so many things a lot of people probably have wondered about but no one has seriously tried yet, let alone shown it to the world. Please keep being you, lovely to watch always!

Even after 3 years of engineering school, I still learn so much from your channel. Great videos!

I am never more excited then when i see a video from Tom. The step by step research to prototype of an idea is unmatched in my opinion. Truly top notch content!

I am speechless and you are a highly underrated engineer. I really loved the project.

I think you calculated based on cruising power rather than the power needed to accelerate/decelerate. Really interesting build!

Magnetic coupling is very useful for underwater applications, where you want to disconnect the propeller from the internal electronics. Back when I was in highschool, we built an autonomous underwater vehicle and faced a real problem with isolating the propeller's entrance.

It's always so mesmerizing to witness eddy currents. I was playing with magnets and a copper pipe a while back and it's so so interesting to see it happen. The clutch idea is interesting, I could see this being useful in some kind of application that may get sudden changes of resistance, and it would save the output shaft of the motor. Rollercoaster brakes also work similarly to this.

I'd love to see a return to this experiment with more designs and maybe some alterations with additional parts to see if this could be further built on as a viable drive method. The concept seems really awesome, and I'm sure there's got to be some utility in this somewhere.

Babe wake up, new Tom Stanton video

What happens if you pedal backwards? Would that provide more braking force? How would the addition of an electrical current affect the resistance? Great videos! I really enjoy watching and learning such interesting concepts!

Two points I'd have tested; 1. how much does it slow you if you pedal backwards? 2. what does it do for controlling speed when going down a hill (something steep enough to normally require braking)? Interesting as always! 👍👍

You could try mounting the magnets as a halbach array, it's used to point most of the magnetic field in a single direction meaning you'd get more Eddy currents and less chain sticking!

You had an idea and you concisely show how you went about implementing it and the methods you use. Thank you Tom for inspiring the younglings, I have no doubt we'll get some amazing innovations in the future, influenced by your ability to educate. Even though I pay little attention to the numbers and equations I still end up feeling slightly smarter from watching your videos.

would be cool to see how pedalling backwards while moving forwards would effect the braking power.

The thermal issue and the images at 15:55 are good things to point out to the perpetual motion tinkerers.

Great video, with brilliant visual comparisons. A few options to make life easier: 1. Use a disk hub (machined mount ready to use. 2. For mag interference with chain...Use belt drive instead of chain... they are superior in some ways and used by touring cyclists.. 3. For spoke mag interferrence, "string" spokes are already succesfully used

Hey that's pretty neat to learn about the alternating polarity creating a greater resistance. I didn't think of that. You could print a little cube grid that holds multiple magnets with opposing fields and probably get a much more impressive slow down when dropping it down a pipe.

Great work! I think this is essentially an induction motor. What helps the induction motor work more efficiently will help this clutch as well, e.g. adding slots to the disk to limit the directions of Eddy current, adding iron cores into the slots to increase the magnetic flux density (B = muH)

An interesting experiment - I was watching this with my son, who did an engineering foundation at uni before his computer science degree, and I predicted the heat problem. Well done - it didn't work as well as you'd thought but it's a good experiment.

I have an idea for you mate. You could have a variable gearing effect by mounting the magnet cages attached to radially mounted springs. Mill slots in the disc around where the magnets sit under spring tension to reduce the eddy currents formed there. Use the centripedal acceleration to have them push outwards from centre and thus engage with the intact portion of disc on the perimeter at an RPM detemined by the spring rate. You'll have basically combined the centrifugal clutch with the magnetic drive.

Watched a number of your videos. So nice to see someone who truly understands engineering, can explain it well and actually make some impressive things. Keep up the good work!

I was familiar with this phenomenon from roller coaster brakes, but you explored far deeper than I had ever seen before. Fascinating video and good explanations.

2:25 this is sweet but you need to account for the moment of inertia... by adding some extra weight on the disc for example. side note, on a bicycle you'll probably want the lighter material... 11:10 by intuition I would have attached the magnets to the wheel, not the pedals: you'd save on the zip ties ;-) 14:57 yeah obviously... it's like the arrow halving the distance to the target each time you look at it ; the clutch alone will never bring you to a complete halt 15:54 I was waiting for that one XD the 8kJ obviously don't account for the energy dissipated in the air. Please please please try again with the thermal camera mounted on the bike while riding! We want a graph!! I'd really like to know what happens to the torque transfer capacity (and heat losses) in relation to the temperature of the copper disc. I pretty much knew where this was going, but this is brilliant : good preliminary testing, and I've been looking for a way to transfer torque without using hydraulics and this is just what I needed! Thanks!

Appreciate you Tom, the amount of time and effort put in to every video shows.

Although you may not see this as a success, there's some great ideas here. You learned so much through it also. I think you will come up with practical solutions in the future. It's great that you have the mind and the tools to create what you envision. Great work.

In case you weren't aware, mag clutches do exist and are in wide use, up to around 20 horsepower I believe. Should be no issue for your uses. I miss the air engine videos.

Wrap coils around the magnets and power them through an adjustable source to get variable torque coupling strength. If you put rotary encoders on the wheel and pedal crank you could implement a control system that always allowed a peak efficiency to be maintained for the pedal angular velocity. You could also implement kers on braking using the same equipment.

You always have the most interesting bike technology builds. Your anti-lock brakes from a while back inspired me to design my own and I love the way they work

That was a brilliant, thoroughly well-thought and very well executed way to find out something is a not such a good idea. The effort put into this is admirable!

Halbach array would give you even more magnetic force per magnet given to the field direction you want. Of course you would simply heat your disc faster, so there's that. This is a super interesting concept though, for sure! You could also have direct magnetic interlock with a squirrel cage style ferro-magnetic core, like how induction motors work. I like the idea of creating a 0 friction gap in the drivetrain.

I feel like you could put this in a car to assist the normal clutch and reduce clutch wear. Especially the dual clutch ones would greatly benefit from this.

If you revisit this project, you should try a halbach array for the magnets. Should get you a much stronger field

This is cool. If you decide to revisit this idea, I suggest you use a one-way clutch bearing for freewheeling and also add a U shaped back-irons for the magnets. This helps steer the fields in a shorter path and should increase the flux (IIRC) in the gap on the copper disc while reducing the magnetic forces on the chain and forks. Soft iron is best however plain steel should be fine as the magnetic field in the magnets are 'static'.

That was incredible, thanks a lot! Two improvements are yelling to be done from a bike tech perspective: 1. just use a hub with a disc brake mount. It's exactly what you are looking for. (attaching a metal disc rigidly to a bike wheel) 2. use a bike with a chain shift as a basis: when you remove the cassette, you'll have a lot of clearance between the wheel and the frame Also I'd bet that a FDM printed sprocket in flat orientation out of nylon will outperform any resin printed sprocket

First video I've seen of yours and I really enjoyed. I like the way you're passionate but not loud! You stick to the subject whilst allowing small tangents and your explanations are totally understandable! Great work!

I love how you had an idea and made it reality to test it. That's the sort of real-world findings that could prove to be useful for all kinds of applications that may even be totally unrelated to your project. I bet someone out there will see this and get inspired to try this in something else

I actually think this project is really interesting. Unfortunately the transfer of torque will always be determined by the change in magnetic flux. Meaning that you will have to pedal faster to get it going and keep it going.

I would recommend not using a disc of copper, but an annulus. You could have "gearings" by having several nested annuli with notched / cutout bracing supporting them, and different gears would correspond to different magnet arrays for each radii associated with each annulus, where the field strength would differ for each array. But either way, this was a very cool (warm?) experiment!

What a madman! Fascinating project, nicely executed. Legend mate

You have to admire Tom's enthusiasm, he had an idea and he set about trying to bring it to fruition. Not all experiments work , but I am sure this attempt has brought him some useful insights of what he might try next.

The shot at 7:41 showing the effect of different magnet amounts was amazing. I bet it lines up with it's plotted graph.

I'm so glad to see this channel doing well. It started out with such goofy ideas but Tom has kept at it and it and always comes back with interesting ideas and very good executions. Bravo mate

Don't care that it didn't turn out to be a game-changer. You had an interesting idea and with a lot of thought and effort, you actually made it happen. And that's pretty amazing. :)

Flip it (put your clutch on pedal side, not the wheel side) and use electro magents instead of permanent magnents. That way you can harvest energy while braking and increase your magnetism when you're applying power.

Amazing idea! You can also separate copper segments into angles. This way the current must go in and out of radius. Your coupling will be much much greater! You can also drill lots of holes in the copper plate.

Audio glitching in the clip @12:11

Hello! I'm master mechanic with experience in 3D-Printing and CAD, so I watched this video enthusiastic. I'm really sad, the efficiency is so poor. But - if You don't test it, You didn't know it. I'm sure, You had fun to do it. Great work!

The sense of innovation in this video is rising by every minute. I love your work, sir

HI Tom, first of all this video is great. Secondly, I strongly suggest you to repeat the experiment trying to reduce the air gap. The first thing you shuld do is mounting the magnets with a plate of steel on the outside, the steel will increase the conductance of the magnetic flux increasing the flux in the copper plate (this steel plate would also act as a shield between the chain and the magnets). Other improvement could be to mount the magnets between two copper plates, that would also increase the efficiency of the magnets, I estimate that doing that would give you the same torque with half of the magnets. The hard part is mounting the attachment. On the mechanical side, it could be interesting adding a stage to the transmition in order to multiply the speed of the magnets.

Fantastic project! Thank you for going through the trouble of recording the entire development process and sharing it with the world!

While it was completely useless against a conventional direct chain drive, it was one heck of an experiment! Probably one of the the most interesting scientific/engineering experiments on KZbin! Love your videos!😄

Just thought I'd drop a line to say that I find this type of thing absolutely fascinating.. such great work and thoroughly entertaining! Keep it up my friend!

You could solve the magnets attracting to the chain and spokes using Mu Metal. In mechanical hard drives, they are thick and attach to the magnets, but completely prevent the magnetic field from progressing further, and help to contain the field in the gap where the voice coil moves the heads in and out of the platters.

Really like how you put the different tests with different variables are shown alongsude each other in real time. It really helps visualise the relationship between the variables, like a real life graph. 👏👏

***Change the design slightly - put slots in the back magnet wheel so the magnets can move back and forth based on RPM maybe you would get some variability in torque base on how much centrifical force the wheel is applying the magnets since the RPM would would be larger when they are at the bottom of the slot and lower at the top of the slot.

About 35 years ago, Schwinn Bicycle Co. had a frame you could mount your bike to that had your rear wheel run on a roller that was tied to an almost identical arrangement. You could vary the position of the magnets in the assembly by turning a knob.

You're amazing to tackle and command this new concept! I wasn't surprised when the plastic wheel gear broke. There would be a lot of torque on that part to cause sheer. More MAG power and Innovation to you!

Just be careful of road man holes lifting up to stick with the magnet matrix

my eyes were stuck to the screen from the beginning up until the very end. what an interesting concept I had absolutely zero knowledge about.

12:19 “still able to oop”

A halbach array instead of a simple N-S magnet setup would would make the effect stronger for the same size/number of magnets. Besides, that, pretty cool!

Cool concept! Great execution! To brake/stop better, you could pedal backwards to keep the speed difference up as you slow down.

This could be a bachelors thesis in physics in a video. Beautiful work and amazing topic!

I think you have one of the best engineering explanation videos on the internet. You always come up with some great crazy idea and introduce and explain bunch of ideas along the way. I'm super excited every time you upload!

Damn Tom, as a physicist I am excited about every new video you bring out. Your ideas have inspired me more than once to build fancy stuff.

Great video Tom! I had an aha moment when you showed the five side by side videos of the varying magnet configurations. Excellent description and presentation of the science behind the results.

Nice bit of work! I would imagine that the heat created in the disk would also be created in the magnets, so the plastic magnet housing will soon loose strength. This scheme would make a nice water heater driven by a windmill. Wrap copper pipe around the static magnets to cool them, and using a pair of rotating copper disks with water bled between them via a gland on the shaft to cool the disks. Could be a nice build! Thanks.

The amount of tests and information is amazing! Thank you for sharing all of this ! It opens new application ideas and creative visions!

Tom, your simply unmatched ability to logically apply principles of analytic geometry, test and evaluation, and the linking of the governing physics to mathematical expression is a masterclass that I wish I had in my undergraduate aerospace engineering degree program. I want you to know that your channel is more valuable than most engineering curriculum due to your ability to efficiently distill and demonstrate the power of iterative design for real-world applications; your content is the truest expression of what it means to be an engineer. Keep up the stellar content!

The experimental setups are so clean and pragmatic. Well done!

This is so cool. Totally impractical, but a great, fun eddy current demonstration with a few simple benchtop experiments to figure out the details.

This reminds me a lot of a torque converter in a conventional automatic transmission for an automobile. You could take this one step further, as the auto manufacturers did, and have the option to lock the torque convert up so that there are no frictional losses between the copper disc and the magnetic drive.

Nice video! I think you can brake faster if you pedal backwards. The higher difference in RPM will make you brake faster, even at low speed.

I just discovered your channel and I love it! Your editing, your ideas, your explanations - incredibly well done! Thank you so much and this is so cool

You're the most brilliant human I've ever encountered.

Wonderful sample of applied science, experimentation and prototyping. Thank you so much for putting this together!!!