If you care to eliminate this, replace the large magnets with many small magnets separated by thin insulating films. Same thing is done in transformers to limit power transmission losses
You know, that's actually a good thing to know When using magnets in any project I never would have thought about that, but that's actually a very valid idea
Heat above its working temp will lower the magnetic properties but you can get upwards of 100+c for N grade magnets. The shape and dimensions of a magnet play an important role in its working temperature, a high permeance coefficient will help combat heat degradation
If you wish to avoid the frictional heating of the rotor bearings, you can use two nested bearings. in theory the bearing with less mechanical advantage will be driven faster than the other bearing, but if the two bearings are magnetically geared together in a two to one ratio, then the load is equally shared, and the theoretical top speed is doubled, before the bearings become too hot.
If you place a high permeability metal on the outside faces to couple the magnets together you should be able to almost double the flux inside the gearbox. Inspect how cabinet door latches or speaker voice coil magnets are arranged with metal plates to focus the magnetic flux.
@@74KU There are things you can do with magnetic linkages that you simply cannot do with a mechanical ones. One example: transmitting torque through a solid, unbroken sheet of metal. Could be super useful for ultra-high-pressure, high-reliability, and/or hazardous substances applications, where traditional shaft seals can't handle the pressure or where you cannot afford to have any leakage whatsoever under any circumstances. Niche applications like that can still be extremely important.
Ooh, I need to know more about this configuration for an iPad mount application. I’m worried my magnets will have too big of a gap (~2.5 mm) and will lose too much of their pull to be effective. By “behind” I’m understanding that to mean the far side from the other magnet, correct?
thats how bike pedals stay on :), love reverse thread stuff, but I see stuff backwards so when looking at threads, it takes me forever to see if its LH, or RH lol.@@vipvip-tf9rw
Did anyone else see the nuts cycle through loosening then tightening over & over? Would love to see the forces pulsating back & forth to do that. Great vid & love the outside box thinking. Cheers.
Should've been using brass fittings rather than cheaper steel. And either lock washers or lock nuts. A certain amount of flex is wanted, though. Too much rigidity is why the magnets went flying at the beginning of the video... with utterly no safety shield around high speed rotating disks...
@@Autarkethe transfer of torque is probably less than current mechanical systems, otherwise we'd be using it now, the advantage is there's no need for a clutch plate, if they can develop more powerful magnets that could connect the engine to the transmission like a normal one without the loss of torque, then it's the future
Some audio feedback: Your voice has a stronger low-end than its high-end, but you articulate your words with mainly the high-end, this makes for a more difficult listening experience. I suggest an EQ to cut the low mids, boost the high mids and maybe also play around with the highs to make it sound less nasal. If this is also how you sound without a mic, you might to play with how/where you articulate your words to better engage live audiences. That's all, I hope it's helpful!
@@retsetman9698 I'd say a basic de-esser, low shelf, and compressor would be ideal, if you're into that kind of thing. Otherwise, put a thick cloth/foam over your microphone, and record a bit closer to it, facing your breath away from it. Awesome video btw :D I didn't think the audio was distracting at all, personally. I hadn't seen how magnetic gearing works before, and it seems very elegant.
Have a look at particle clutches. They have two cup shaped ends the the in and output shafts, one cup sits inside the other. A soft iron powder is placed inside the cups. There is then a coil that wraps around the outside of both cups, vary the current on the coil which then varies the drive torque through the coupling. They also allow for slip if the torque level is required is exceeded.
There are no such thing as "particle clutches" you are talking about the 1900's electromagnetic clutch with a syncromesh. Syncromesh which uses bronze pre-load conical bearings to take the initial force from the driven gear to the selected gear on the gear drive- enabling smooth shifting and far less stress on gears- enabling quieter, smoother herringbone teeth, vs straight cut teeth. Not new.
Not saying you're wrong, but Wikipedia shows me Magnetic Particle Clutch, which is "a special type of electromagnetic clutch" and does indeed have "a fine powder of magnetically susceptible material to mechanically link ... a disc on one shaft to a rotor attached to the other shaft".
It will never be used for any practical applications, this is just useless, but all these videos are full of engineer wannabes calling any old and useless tech “revolutionary”. “Stirling engines are the future!” “Tesla towers will power the world!!!” 🥴 🥴
No- this will not work when you get to serious torque figures it will not be able to cope. This has been thought of before- and before both of us were alive. It is the basis of the fluid coupling alias the torque converter- which itself is based from Parson's steam turbine driving sympathetically rotating generator via the working fluid of dry steam, no parts touching (and similarly Rover's JETONE turbine car 1948)
yeah, we even have created the better thing, but it uses electromagnetic instead called axial flux motor, and if we use it as a transmission then it will become a hybrid car.
There is not so much friction, but I bet there's hysteresis and eddy current loss, especially when the drivetrain is loaded. I'd love to see a quantitative comparison between a gearbox.
@davidgfbrMaybe, but I would need a couple more pieces of data to say whether or not agree with you. The phenomena I mentioned are velocity-dependent like friction, but not linear like friction.
i used one of these on my capstone project for mechanical engineering technology. My team and I built a velocity head hydro-turbine but found rotary shaft seals difficult for the generator which was under water (an connected to the turbine). Solved all our problems and worked great!
Obviously your university has less than stringent standards- why on earth would you have an immersed generator- how the hell is that 1 supposed to function, 2 be maintained?
It's really beautiful work ! Subscribed! Please consider making the design easly to stack a few of those in series. Also would love to see you add some coils like Robbert Murrey does and make a diy/emergency generator, preferably in gravity-light style, where the system should be stack a few layers to achieve higher loads and max torque , so a heavy weights can out strung high from the ceiling, with big reduction, providing more watt and also a slow and long decent so the cycle time is as large as possible, and therefore the most watt-hours between every pull up and reset of the weight. Thanks a lot and all the best !
This is insanely cool, and to think that I could do that at home with what I have makes me really happy inside, even though I won't try it any time soon. Keep up the amazing work!
amazing stuff. makes me wonder just how difficult it would be to do this with electromagnets. then the torque could be varied and possibly have a device that works as both a clutch and gearbox. triggers a bunch of other ideas in my head. good work!
Yeah but that's be real expensive and complicated, at that point it wouldn't be worth it. Only expensive cars would go for something like that, but a practical reasonably affordable car wouldn't have it.
@@fulconandroadcone9488 umm not really smarta$$.. what i'm thinking of wouldnt provide the drive power itself, would work as i said, as both a clutch and gearbox for another source of drive power. the torque it allows through could be varied. maybe more of a variable torque limiter
interesting idea though i think that the amount of torq transfered will be reduced a lot , you can stop the drive and the drivemotor will only be loaded down not stopped like with gears
I really wonder how much better this could be with non 3D printed/higher quality parts. I noticed a lot of wobble at high speeds and I bet that better manufactoring methods could let you drastically decrease the air gap and unwanted vibrations at high rpm. Maybe larger iron pieces too.
I think this is really incredible engineering! My advice to you is that the space between the magnets should be decreased ... probably almost touching when "hot" so that if it gets hot, it doesn't stall. You will probably need a better material to handle those tolerances. But, I think the improvement in torque will be much better if the space is decreased even further. Could you explain just a little more about how you managed to "smooth" the cogging effect?
@@marcfruchtman9473 I have had past experiences with this transmission. On a very powerful 37kW Unit, the temps approached 450C, and were capable of warping the components. There is also a huge loss in efficiency.
@@peterduxbury927 i have seen pumps with magnetic coupling, because of one single magnet unit it does not produce much heat, when many magnets and have slippage the heat is very high.
That looks like a fun project. Interesting measurements of the forces after certain changes were in the video. As a side note or two: I wish people would stop treating permanent magnets like they're actually permanent. Also, the title says you cannot break these gears, but the video shows sparks and magnets flying off. Might want to redesign the housing for the magnets so they cannot possibly fly off.
I know it would be astronomically more difficult with the tools you have but if you could figure out a maglev bearing to replace those standard ball bearings the results would be very interesting
@@markiobook8639 Might want to look into these large commercial flywheel batteries then. Spinning massive weights between 10k -100k rpm If this isn't serious workload what is? Different form of maglev bearing is the high speed trains.
MagLev is not a bearing. It's a form of propulsion. If you are unable to comprehend that and that it requires far more energy than a conventional high-speed French TGV or ICE and the Germans' ICE being pioneers of air bearings and magnetic bearings- were forced virtue of forces involved use conventional needle bearings, then basic engineering is beyond you. Secondly flywheels are not massive if they rotate at 100k rpm- that defies near all known materials shear strength- they are instead tall and cylindrical- thus if Torque= FxD D is deliberately kept short. High speed is to offset flywheel lack of torque as torque is a function of speed and speed a function of torque hence F1 engines rev enormously high rpm with very short stroke and larger bore.@@WhatTrigger
very awesome how much the gearbox has progressed, n52 magnets will be a serious upgrade. And also what if you add a third layer of magnets on the back as well?
Another new high quality channel, glad i have subscribed. If you were to make any more improvements, trying out lots of designs and doing research, its a delight to watch
Subscribe for N52 magnets!!! If you'd like to support my work, you can join the channel or use the Super Thanks button on the videos. And as a member, you’ll get some exclusive perks too!
Have you considered using a Halbach array for the magnet array? Halbach arrays double the field strength on one side of the array and cancel it out on the other. Supposedly they are perfect for applications like this, but they require more magnets.
4:10 The vibrations from the assembly caused the nut securing the case to fall into it. Go back to 3:15 to see the nut and screw just vibrate loose. Could try a bit of hot glue or school glue to hold it for a bit. Easy to remove when changing things around.
Physicists: magnetic forces can do no work because they're always applied perpendicular to the velocity vector as described by Lorentz This guy: hold my beer
French physicist Pierre Curie would like a word with you about Neodymium magnets and temperatures starting at 80°C. When magnetic materials reach the Curie temperature, the alignment of magnetic moments becomes forcibly disordered. Therefore, as the operating temperature increases, and moves towards the material’s Curie temperature, the magnetic strength of a material weakens due to the moments shifting out of alignment. AlNiCo magnets tolerate the highest maximum operating temperatures of between 450-900°C.
For added torque you can use many smaller magnets that equal the same volume as the previous ones of the same N52 strength. As long as the smaller magnets are of the same strength or greater then you will achieve the most magnetism. Add Tesla's "V" design to eliminate eddy currents and it would be even stronger. Try to make the encasement out of graphene for strength, resistance to heat and magnetic fields. Use the most potent iron you can find to multiply these forces. Add iron in the center of the each magnet. Imagine an iron "V" bar wrapped in magnets or on the top inside of the "V".
Amazing world we live in and the the possibilities of material we have on this planet and also the wisdom to find it out. A creators hand is seen everywhere and even is the reason for the desire to create something!
I'm planning on using something like this in some space hardware I am designing at work. If you can seal the magnets effectively, this kind of shaft coupling can be used to make a pump or other rotating machinery that does not have any dynamic seals, which reduces the chance for a leak during the machinery's service life greatly. If you use a thrust bearing, you can use some very strong magnets, which allows for a higher max (possible) torque.
Yes, there are indeed magdrive pumps without dynamic seals in the industry and they are being used, I have this idea in mind, but I really need some really strong magnets for the clutch and btw I think one of the areas where magnetic gears will be most useful is space because there is no need for maintenance.
Did you know, older tractors use to use a version of this on the pto to isolate the tractor from hammering of machinery. It was only largr ceramic magnets on one side, and a thick copper disk bolted to a steel one on the output. The magnets would apparently drag the copper around as it setup currents that resist the magnetic charge change.
its a great concept, and yes the heat the magnets get exposed to over time would deteriorate them , thats another technical challenge, but the industry is so dependent on oils, lubricants , even maintenance intervals for conventional transmissions, that even if you could solve all the technical problems , it would just be shunned like any other invention, that cuts out everyone else looking to get a piece of the pie . perhaps a similar version, that uses oil to cool the magnets would be more practical , because then you still have something in todays market, reliant on lubricants, and it may help solve the degradation of the magnets from the heat, and still produce a transmission that is both far more reliable and efficient .
Yes you can break them, the simplest way is with over torque. If you define breakage as not working as intended, then if you apply to much torque load at the output and the magnets can’t overcome it, then your gears are broken.
Interesting topic! To increase torque and magnetic flux even more you can add back-iron behind magnets. Back-iron is very common for axial flux motors.
If you add a variable-current stator plate in between, you could use it for infinitely-variable gear ratios. And the other thing is, if this is used as an electromagnetic coupling, there would be no need for a hydraulic torque converter to decouple the driveline when the vehicle comes to a stop. And if further modifications are added in, it could also have an electromagnetic clutch to connect the input and output together using friction material.
Several companies tried to commercialize magnet gearing/clutches, etc. The best known is probably MagnaDrive which is only a niche supplier. Problems are heating of plates and magnetics, foreign object attraction, interference with external systems, and several others. Cool but kind of useless. But a nice video showing some neat experiments.
My grandpa made one of these quite similar in the 80s still have a vhs tale somewhere in his attic of it changing 6 gears and getting up to 7k rpm which is crazy for the time
To avoid any unwanted back flow currents, instead of using that plate with screws in it, try using a copper plate that has cut slits that inline with the plate that holds the magnets. This insures that the back flow currents wont be powerful enough to effect the spin of the machine but as far as getting useful electric power out of such a machine I leave up to you.
Interesting fact: neodymium magnets are not indestructible, the heat generated in the eddy curent destroys them
If you care to eliminate this, replace the large magnets with many small magnets separated by thin insulating films. Same thing is done in transformers to limit power transmission losses
You know, that's actually a good thing to know When using magnets in any project I never would have thought about that, but that's actually a very valid idea
Try mounting magnets with hot glue. Then wondering why Hall sensors don't work anymore.
Heat above its working temp will lower the magnetic properties but you can get upwards of 100+c for N grade magnets. The shape and dimensions of a magnet play an important role in its working temperature, a high permeance coefficient will help combat heat degradation
@@tomascancelliere4348 What other kinds of geometric shapes are available? Any that might specifically improve performance?
If you wish to avoid the frictional heating of the rotor bearings, you can use two nested bearings. in theory the bearing with less mechanical advantage will be driven faster than the other bearing, but if the two bearings are magnetically geared together in a two to one ratio, then the load is equally shared, and the theoretical top speed is doubled, before the bearings become too hot.
This is an awesome idea and such an underrated comment!
Maybe replace the bearings with Magnetic Bearings
You can use diamond bearings from US signetics. They withstand high heat and pressure
the rotor itself can be part of passive cooling, if made of aluminium, finlets along the rim and slots
@@getl0st That would introduce way too much eddy current, probably overheating the bearings and demagnetizing them way quicker than mechanical ones.
If you place a high permeability metal on the outside faces to couple the magnets together you should be able to almost double the flux inside the gearbox. Inspect how cabinet door latches or speaker voice coil magnets are arranged with metal plates to focus the magnetic flux.
You mean the back iron? You'll probably see them in the optimised version.
@@retsetman9698have you considered 3d printing some parts with filament which has iron powder mixed into it?
@@kingarthurthe5th I had completely forgotten about it until you said it, I'll see if I can use it.
Look up halbach arrays
Wahhhhhh this is some cool stuff! Thank you for this comment! :)
The way that you made the magnetic gear reduction is GENIUS!
If you add thin steel behind each magnet, you can nearly double the pull strength. This is an awesome video btw!!
Or hallbach array shape
still doesn't fix all the drawbacks to make it actually worth using over existing linkages, otherwise it would be.
@74KU it's useful in extreme applications
@@74KU There are things you can do with magnetic linkages that you simply cannot do with a mechanical ones.
One example: transmitting torque through a solid, unbroken sheet of metal. Could be super useful for ultra-high-pressure, high-reliability, and/or hazardous substances applications, where traditional shaft seals can't handle the pressure or where you cannot afford to have any leakage whatsoever under any circumstances. Niche applications like that can still be extremely important.
Ooh, I need to know more about this configuration for an iPad mount application. I’m worried my magnets will have too big of a gap (~2.5 mm) and will lose too much of their pull to be effective. By “behind” I’m understanding that to mean the far side from the other magnet, correct?
You should use self tightening nuts, that way the vibration will not unscrew the tightening screws. Great video.
Or blue loctite
@@joshuacaylor881or counter clockwise thread, like in many applications of this type
thats how bike pedals stay on :), love reverse thread stuff, but I see stuff backwards so when looking at threads, it takes me forever to see if its LH, or RH lol.@@vipvip-tf9rw
stover nuts would work best.
Self what?
Did anyone else see the nuts cycle through loosening then tightening over & over? Would love to see the forces pulsating back & forth to do that. Great vid & love the outside box thinking. Cheers.
I saw that too
Should've been using brass fittings rather than cheaper steel.
And either lock washers or lock nuts.
A certain amount of flex is wanted, though. Too much rigidity is why the magnets went flying at the beginning of the video... with utterly no safety shield around high speed rotating disks...
Of all the magnetic gearbox videos on youtube, this is one of them!
it really is!
Profound
This concept was actually built in 1918 it was sold as the transmission you didn't need to shift, Stahl auto museum has one in Michigan
Why it's not used in cars?
@@Autarkethe transfer of torque is probably less than current mechanical systems, otherwise we'd be using it now, the advantage is there's no need for a clutch plate, if they can develop more powerful magnets that could connect the engine to the transmission like a normal one without the loss of torque, then it's the future
@@pihermoso11 electromagnets are more powerful but then you've invented the electric car so we're already kinda there
High heat kills permenant magnets. The friction just kills this. Its neat and a great physics demo just not practical.
@@Autarke
@@danr.5017 Iron is so abundant on Earth. Can’t ya! simply change out the magnets after so many miles or get them recharged.
Very neat idea for low torque applications. There is a limit to how strong this can be with permanent magnets.
Torque was my first idea as well.
Yeah, anything too strong will make them slip like cartoon characters on a banana peel. Also LOL at "You can't break these gears".
@@EldeNice they wont break when a load is applied, its true
Could be interesting in machining
how does it respond to a load?
With an open mouth
Like my sister
@@jumpgrass71WTF!?!?
5:04
Some audio feedback: Your voice has a stronger low-end than its high-end, but you articulate your words with mainly the high-end, this makes for a more difficult listening experience. I suggest an EQ to cut the low mids, boost the high mids and maybe also play around with the highs to make it sound less nasal.
If this is also how you sound without a mic, you might to play with how/where you articulate your words to better engage live audiences.
That's all, I hope it's helpful!
Honestly, thank you so much, I will pay attention to that.
@@retsetman9698 I'd say a basic de-esser, low shelf, and compressor would be ideal, if you're into that kind of thing. Otherwise, put a thick cloth/foam over your microphone, and record a bit closer to it, facing your breath away from it.
Awesome video btw :D I didn't think the audio was distracting at all, personally. I hadn't seen how magnetic gearing works before, and it seems very elegant.
1:30 "just like your mother"
Lol, that made me laugh.
very generous and open heart in your patience and your delivery. refreshing scientist-tinkerer channel. and you saved the best for very last.
Have a look at particle clutches. They have two cup shaped ends the the in and output shafts, one cup sits inside the other. A soft iron powder is placed inside the cups. There is then a coil that wraps around the outside of both cups, vary the current on the coil which then varies the drive torque through the coupling. They also allow for slip if the torque level is required is exceeded.
There are no such thing as "particle clutches" you are talking about the 1900's electromagnetic clutch with a syncromesh. Syncromesh which uses bronze pre-load conical bearings to take the initial force from the driven gear to the selected gear on the gear drive- enabling smooth shifting and far less stress on gears- enabling quieter, smoother herringbone teeth, vs straight cut teeth. Not new.
Not saying you're wrong, but Wikipedia shows me Magnetic Particle Clutch, which is "a special type of electromagnetic clutch" and does indeed have "a fine powder of magnetically susceptible material to mechanically link ... a disc on one shaft to a rotor attached to the other shaft".
This absolutely so cool and amazing, please keep going with this concept. I love it so much. I wanna see this used in car or other applications.
This idea is old. An American Car (built in the 1950's) had a Magnetic Transmission. Sorry, but I cannot remember the make of car.
@@peterduxbury927it was the Owen Magnetic, made around the time of the First World War. Jay Leno has one.
@@chrishenniker5944 YES! Thanks for that. I knew that I had seen this somewhere. It is old technology that didn't take off due to inefficiency.
It will never be used for any practical applications, this is just useless, but all these videos are full of engineer wannabes calling any old and useless tech “revolutionary”. “Stirling engines are the future!” “Tesla towers will power the world!!!” 🥴 🥴
Its an old idea that couldn't do any actual work then, just like it can't now.
No- this will not work when you get to serious torque figures it will not be able to cope. This has been thought of before- and before both of us were alive. It is the basis of the fluid coupling alias the torque converter- which itself is based from Parson's steam turbine driving sympathetically rotating generator via the working fluid of dry steam, no parts touching (and similarly Rover's JETONE turbine car 1948)
yeah, we even have created the better thing, but it uses electromagnetic instead called axial flux motor, and if we use it as a transmission then it will become a hybrid car.
There is not so much friction, but I bet there's hysteresis and eddy current loss, especially when the drivetrain is loaded. I'd love to see a quantitative comparison between a gearbox.
A geared gearbox of this size can pull a car at least
@davidgfbrMaybe, but I would need a couple more pieces of data to say whether or not agree with you. The phenomena I mentioned are velocity-dependent like friction, but not linear like friction.
F1 or Lemans would already be using this if it was actually useful irl.
@@briankale5977this cannot transmit any meaningfull amount of torque so it's pretty much useless in the real world.
i used one of these on my capstone project for mechanical engineering technology. My team and I built a velocity head hydro-turbine but found rotary shaft seals difficult for the generator which was under water (an connected to the turbine). Solved all our problems and worked great!
Obviously your university has less than stringent standards- why on earth would you have an immersed generator- how the hell is that 1 supposed to function, 2 be maintained?
@@markiobook8639underwater currents?
Just like we maintain underwater pipes and oil infrastructure?
I was playing with this idea 40 years ago, glad you made it right , you got it is just a mater of the right metal to mass produce, congratulations.
Brilliant!
Thanks Cody!!!!
It also has the torque of a 90 year old grandmother with osteoporosis that's why it's not widely adopted.
This is the most important question to start with, why isn't it already adopted. Makes such videos obsolete.
@@bobdebouwer7835 Many of these videos are made for clicks and views, not for the actual information they provide.
Very cool! A more advance setup would be to alter the polarity electrically to get whatever gear ratio you want. Very nice!
Yeah, but he would need to change his setup to make the center piece rotate to incorporate electromagnets in his design
That would basically be an electric motor xD
as an alternative magnets on the secondary wheel could be rotated physically in the slot
Dude..
The toys you had growing up were so much better than mine.
I just had a Light Brite and some Cooties 😓
There was still too much space between magnets. Get them to be almost touching, separated by the thickness of a sheet of paper.
I seriously love science, this is the coolest stuff ever. Need one of these for a electric mtb transmission.
Awesome investigation of magnetic forces!
If this was viable on a commercial scale it would have been done a long time ago. It's an obvious solution.
Gearless Magnetic Transmission - You Can't Break These Gears **PROCEEDS TO BREAK GEARS**
This was actually pretty cool.
Excellent work as expected! Keep it up and thanks for sharing!
Neat model, but my take-away here is the magical film that can see magnetism.
It's really beautiful work ! Subscribed!
Please consider making the design easly to stack a few of those in series. Also would love to see you add some coils like Robbert Murrey does and make a diy/emergency generator, preferably in gravity-light style, where the system should be stack a few layers to achieve higher loads and max torque , so a heavy weights can out strung high from the ceiling, with big reduction, providing more watt and also a slow and long decent so the cycle time is as large as possible, and therefore the most watt-hours between every pull up and reset of the weight.
Thanks a lot and all the best !
all of what you said are great video ideas and definitely worth a try. Thank you so much for the good wishes
That what also be very good for slowly turning a large solar array. Have you made any estimates for this kind of thing?
@@retsetman9698thanks for responding :) let me know if any of what I suggested stayed with you.. really hope to see it happen 💜
Brilliant! Thank you Retsetman for sharing this video on Magnetic Transmission. Greetings from Madang, Papua new Guinea!
This is insanely cool, and to think that I could do that at home with what I have makes me really happy inside, even though I won't try it any time soon.
Keep up the amazing work!
"You can't break these gears" Me: Try doing a burnt out with my magnetic transmission but ending up with cooked magnets that lost all their property.
Absolutely wonderful. Very methodically done
Great job as a retired mechanic I love the way you approach gear reduction
amazing stuff. makes me wonder just how difficult it would be to do this with electromagnets. then the torque could be varied and possibly have a device that works as both a clutch and gearbox. triggers a bunch of other ideas in my head. good work!
Yeah but that's be real expensive and complicated, at that point it wouldn't be worth it. Only expensive cars would go for something like that, but a practical reasonably affordable car wouldn't have it.
All real Cars are expensive
I think that would be called electric motor.
@@fulconandroadcone9488 Indeed. Prius had that for more than 2 decades!
@@fulconandroadcone9488 umm not really smarta$$.. what i'm thinking of wouldnt provide the drive power itself, would work as i said, as both a clutch and gearbox for another source of drive power. the torque it allows through could be varied. maybe more of a variable torque limiter
I can see screws turning loose (3:20 min) while turning under high speed/power. Thank you for the presentation.
interesting idea though i think that the amount of torq transfered will be reduced a lot , you can stop the drive and the drivemotor will only be loaded down not stopped like with gears
This could be a great way to pass torque into or out of a hermetically sealed enclosure. This is very cool: well done, and thanks :)
I really wonder how much better this could be with non 3D printed/higher quality parts. I noticed a lot of wobble at high speeds and I bet that better manufactoring methods could let you drastically decrease the air gap and unwanted vibrations at high rpm. Maybe larger iron pieces too.
I wonder about that too, though it's obviously going to get a lot better. Hopefully I will make a new one with metal parts soon.
Adding iron or steel discs/plates could play havoc magnetic fields, all metals/alloys suffer from a degree eddy current effect but ferris more so .
so many back seat engineers and nothing to show..great video sir. keep em coming.
I think this is really incredible engineering! My advice to you is that the space between the magnets should be decreased ... probably almost touching when "hot" so that if it gets hot, it doesn't stall. You will probably need a better material to handle those tolerances. But, I think the improvement in torque will be much better if the space is decreased even further.
Could you explain just a little more about how you managed to "smooth" the cogging effect?
If this concept does any serious work, it will get very hot.
@@peterduxbury927 Hmm, hard to say for sure how much heat tho. I am definitely interested in more tests!
@@marcfruchtman9473 I have had past experiences with this transmission. On a very powerful 37kW Unit, the temps approached 450C, and were capable of warping the components. There is also a huge loss in efficiency.
@@peterduxbury927 i have seen pumps with magnetic coupling, because of one single magnet unit it does not produce much heat, when many magnets and have slippage the heat is very high.
That looks like a fun project. Interesting measurements of the forces after certain changes were in the video. As a side note or two: I wish people would stop treating permanent magnets like they're actually permanent. Also, the title says you cannot break these gears, but the video shows sparks and magnets flying off. Might want to redesign the housing for the magnets so they cannot possibly fly off.
Very cool! I never would have guessed the interactions between the groups and number of magnets in the group like that.
This kind of motors/transmission is very common in industrial applications
I know it would be astronomically more difficult with the tools you have but if you could figure out a maglev bearing to replace those standard ball bearings the results would be very interesting
maglev bearings will only tolerate certain weights, they will not tolerate serious working condition loads. Even air bearings have their limitations.
@@markiobook8639 Might want to look into these large commercial flywheel batteries then. Spinning massive weights between 10k -100k rpm If this isn't serious workload what is?
Different form of maglev bearing is the high speed trains.
MagLev is not a bearing. It's a form of propulsion. If you are unable to comprehend that and that it requires far more energy than a conventional high-speed French TGV or ICE and the Germans' ICE being pioneers of air bearings and magnetic bearings- were forced virtue of forces involved use conventional needle bearings, then basic engineering is beyond you. Secondly flywheels are not massive if they rotate at 100k rpm- that defies near all known materials shear strength- they are instead tall and cylindrical- thus if Torque= FxD D is deliberately kept short. High speed is to offset flywheel lack of torque as torque is a function of speed and speed a function of torque hence F1 engines rev enormously high rpm with very short stroke and larger bore.@@WhatTrigger
Actually nice concept for low power devices, like bikes, scooters, electric drones, large toys.
very awesome how much the gearbox has progressed, n52 magnets will be a serious upgrade. And also what if you add a third layer of magnets on the back as well?
adding magnets will of course increase the torque, but at some point you will have to consider the weight.
@@retsetman9698 true but maybe weight can also be useful? ala flywheel effect
Brilliant!!!, the only drawback to this would be the cost since magnets are quite expensive.
Another new high quality channel, glad i have subscribed. If you were to make any more improvements, trying out lots of designs and doing research, its a delight to watch
This was so goddamn interesting. It's bafflingly simple but I'd have never even thought of it. Wild
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Have you considered using a Halbach array for the magnet array? Halbach arrays double the field strength on one side of the array and cancel it out on the other. Supposedly they are perfect for applications like this, but they require more magnets.
4:10 The vibrations from the assembly caused the nut securing the case to fall into it. Go back to 3:15 to see the nut and screw just vibrate loose. Could try a bit of hot glue or school glue to hold it for a bit. Easy to remove when changing things around.
subscribed and cant wait to work with magnetic gears
Ok I suscribed. N52 magnets GOOOOOOOOOO!!!!!
Just did before this comment :)
i envisioned something like this around 2005 and never pursued it, this is really interesting to see
Physicists: magnetic forces can do no work because they're always applied perpendicular to the velocity vector as described by Lorentz
This guy: hold my beer
You are going to do big things my friend. Excellent work
No contact
No wear
No Lube
Aaaaaaaaaand
NO TORQUE
😂😂😂
There is a SEVERE risk of slippage in any magnetic coupling undergoing high amounts of torque
This was a pretty damn cool project to watch.
Good job 😮 This project can increase the number of horsepower in the electric motor
Actually it has very short lifespan. Heat demagnetize magnets quickly.
This is BRILLIANT dude. Thank you. I'm guessing you have a strong bg in physics.
French physicist Pierre Curie would like a word with you about Neodymium magnets and temperatures starting at 80°C. When magnetic materials reach the Curie temperature, the alignment of magnetic moments becomes forcibly disordered. Therefore, as the operating temperature increases, and moves towards the material’s Curie temperature, the magnetic strength of a material weakens due to the moments shifting out of alignment. AlNiCo magnets tolerate the highest maximum operating temperatures of between 450-900°C.
I frikkin love your videos!
Es una excelente aportación
Saludos de mecatrónic 🇲🇽
If you manage to use this setup on a bike with the gear chain you would have a relatively nice ebike. Amazing stuff btw.
For added torque you can use many smaller magnets that equal the same volume as the previous ones of the same N52 strength. As long as the smaller magnets are of the same strength or greater then you will achieve the most magnetism. Add Tesla's "V" design to eliminate eddy currents and it would be even stronger. Try to make the encasement out of graphene for strength, resistance to heat and magnetic fields. Use the most potent iron you can find to multiply these forces. Add iron in the center of the each magnet. Imagine an iron "V" bar wrapped in magnets or on the top inside of the "V".
Wow, this principle is cool! Imagine if you could change the polarity of the magnets electronically whilst they are still rotating!
real scientist at work! BRAVO!!! SIR!
Amazing world we live in and the the possibilities of material we have on this planet and also the wisdom to find it out. A creators hand is seen everywhere and even is the reason for the desire to create something!
Cringe
Wow, I was just thinking of building something like this as an actuator in a humanoid robot! Good work.
I'm planning on using something like this in some space hardware I am designing at work.
If you can seal the magnets effectively, this kind of shaft coupling can be used to make a pump or other rotating machinery that does not have any dynamic seals, which reduces the chance for a leak during the machinery's service life greatly.
If you use a thrust bearing, you can use some very strong magnets, which allows for a higher max (possible) torque.
Yes, there are indeed magdrive pumps without dynamic seals in the industry and they are being used, I have this idea in mind, but I really need some really strong magnets for the clutch and btw I think one of the areas where magnetic gears will be most useful is space because there is no need for maintenance.
Lol the Own Magnetic used this type transmission in 1916 and the electomagnetic drive was and is patented
@@justmengracie en.wikipedia.org/wiki/Owen_Magnetic
This was great to watch. Also, many knowledgeable comments...
Thanks a lot
We have just been waiting for the one that actually runs longer than a minute. Now we can collaborate and improve on these
Magnifico, l'applicazione si può trasferire facilmente a pompe oleodinamiche e paranchi
What about dust and mud?
this is so cool. Great work!
"No Contact. No Wear. No Lube." Sounds like my personal life.
Did you know, older tractors use to use a version of this on the pto to isolate the tractor from hammering of machinery. It was only largr ceramic magnets on one side, and a thick copper disk bolted to a steel one on the output. The magnets would apparently drag the copper around as it setup currents that resist the magnetic charge change.
Simply gorgeous concept
its a great concept, and yes the heat the magnets get exposed to over time would deteriorate them , thats another technical challenge, but the industry is so dependent on oils, lubricants , even maintenance intervals for conventional transmissions, that even if you could solve all the technical problems , it would just be shunned like any other invention, that cuts out everyone else looking to get a piece of the pie . perhaps a similar version, that uses oil to cool the magnets would be more practical , because then you still have something in todays market, reliant on lubricants, and it may help solve the degradation of the magnets from the heat, and still produce a transmission that is both far more reliable and efficient .
I can see you use in those motorized bike kits it’s always great when a UA-cam video makes you think and wanting to make something
That kick back on slip is nasty
Yes you can break them, the simplest way is with over torque. If you define breakage as not working as intended, then if you apply to much torque load at the output and the magnets can’t overcome it, then your gears are broken.
Neat idea. I suggest making a cool clock (a lot of magnets but low torque)
Title: You can't break these gears.
First 10 seconds of the video: breaks these gears.
Interesting topic! To increase torque and magnetic flux even more you can add back-iron behind magnets. Back-iron is very common for axial flux motors.
"You Can't Break These Gears"
Goes on and breaks his gears 5 times in the video :D
If you add a variable-current stator plate in between, you could use it for infinitely-variable gear ratios. And the other thing is, if this is used as an electromagnetic coupling, there would be no need for a hydraulic torque converter to decouple the driveline when the vehicle comes to a stop. And if further modifications are added in, it could also have an electromagnetic clutch to connect the input and output together using friction material.
use lock washers on the nuts that keep the plastic plates together, this will prevent vibration and heat. and keep magnets in place.
Several companies tried to commercialize magnet gearing/clutches, etc. The best known is probably MagnaDrive which is only a niche supplier. Problems are heating of plates and magnetics, foreign object attraction, interference with external systems, and several others. Cool but kind of useless. But a nice video showing some neat experiments.
Thanks for the insights! I will build one and use it on my project.
love it, great idea and i hope you keep improving your gear box
"Unbreakable" - broke in first seconds of the video. Oh, the joy of engineering! :)
What happens when you apply load?
My grandpa made one of these quite similar in the 80s still have a vhs tale somewhere in his attic of it changing 6 gears and getting up to 7k rpm which is crazy for the time
with zero torque transfer ability
Him: You can't break these gears
Also him: *broke gears just at the beginning
Made one like this 20 years ago. Interesting but full of practical isssues with torque
To avoid any unwanted back flow currents, instead of using that plate with screws in it, try using a copper plate that has cut slits that inline with the plate that holds the magnets. This insures that the back flow currents wont be powerful enough to effect the spin of the machine but as far as getting useful electric power out of such a machine I leave up to you.
Great idea. Has lots of potentials.