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For trains I have concerns about loose metal getting caught on the magnets and how well it will handle general debris. That said these might be solvable. For niche uses and for clean environments this looks awesome and promising though. I suspect they will have a future even if it’s a little different than envisioned.

The video completely failed to address the traction system for the railway application. Side loaded traction wheels , what are the issues? They have been used in some types of Fell engine but are maintenance intensive. Btw. Elevators don't have significant friction losses from guide bearings. The car's load hangs from the cables.

Interesting for low speed use, but what about magnetic drag due to eddy currents at higher speed? I would be happy to learn more, are there any scientific / white paper on this tech?

Before watching let me just say this sounds too good to be true…

He DIDNT Explain what was diffferent/specail about the tech -- just said ... magnets!

It works on raised rails, but a lot of pedestrian and car crossings are inset into the pavement and those huge rollers won't fit that

I hoped you could explain how it works. "Path of least resistance" means nothing for magnets.

Maybe not trains but definitely loved the door idea!

The idea of retrofitting maglev onto conventional tracks is a game-changer for industries beyond transportation. It’s exciting to think about the possibilities in urban infrastructure, like elevators or automated systems, reducing costs while enhancing efficiency.

Bend the lines of flux. Basically, you'd house the magnets above the rails, and then use highly magnetic, formed iron/steel to bend the lines of flux where they need to be relative to the rail. I don't understand the exact orientation of the magnets, but I would assume you'd have to have both positive and negative on both sides of the rail for the magnetic locking... so, you'd need a non-magnetic spacer sandwiched between the layers of formed iron/steel to add rigidity as separation for the lines of flux. You lose a little strength when you do this, but by housing the magnets above the rail, you can put in much larger, more powerful magnets. Ensure the formed iron/steel is thin enough to pass through switching stations and road crossings, and you're good to go.

well, permanent magnets are expensive and you need a lot of them to lift a loaded train, also the generated eddi-currents would suck up a lot of the efficiency, i would need to see actuall data from the test-track to make a call, but i assume its minimal gains for tons of upfront cost in the end. for lane switches and crossings you would need a hybrid system that can switch between conventional and maglev anyways.

On the switching tracks, the carriage would have to lift the current undercarriage to the point where other existing train wheels could be stowed and used for jumping the switch points. Would be interesting to see how they overcome this hurdle - but then again perhaps we should re-examine switching tracks and how they can be updated to accommodate this technology.

I think a bigger obstacle greater use of railways is braking technology. Train speed downhill is limited by heat dissipation to much slower speeds than are available uphill. For uphill you just need more horsepower properly distributed. Downhill you need something better than brake shoes on wheels. Disc brakes would require more complicated and expensive trucks. And eddy current braking has the potential to overheat rails. Rail freight is about lowest cost per ton mile. What does this tech do to reduce that?

I have one criticism. And so, design suggestions. Permanent magnets will create eddy currents, creating additional drag/heating track(additional problem of maintanence and accidents in design!). And the load is impressive but how far can it be; because it's tiny with comparison to what is available. Design suggestions were to use a permanent magnets switch (a system which contains a magnetic field of permanent magnets by geometric and mechanical means and it is passive) for transition from low speed to high speed and an electromegnetic linear motor for High speed!

Even if they can't solve the switching problem, this could make future grade-separated high-speed rail projects even more cost effective. They should design switches to work with their existing tech to sell alongside as a system.

I saw a video about this a couple of months ago, and even I acknowledge there's megatons of hurdles. BUT if it comes down to building new tracks or retrofitting a few areas -- few THOUSAND areas -- retrofitting seems easier and more cost effective.

1. Have the rail mechanism at 45° to the track, but leave the face of it perpendicular to the rail, to minimise the footprint. 2. Have one permanent or drop-down wheel, on each corner to handle switching. The wheel doesn't even need to touch the track, it could be 1mm off a the rail and only touch the switching rail. 3. 🎉

Conventional trains are already very efficient and relatively cheap. It would have to be a big step up to make it main stream.

I completed my PTS training recently, so i feel confident in understanding some areas of this video well. Taking away the wheels of the carriage to replace with raised magnets would save the rail from friction and bumps, metal to metal contact but i feel long-term testing of how much Wear and tear can be caused by magnets, needs to be done before increasing to heavier loads...so calculated Calibration can take place. Their using Manganese rail in some places, as it's the most strongest metal used for rail. Hot weather can buckle the rail and cold weather can break the rail, there's a lot to take in overall so I'd love to learn how Magnets effects Rail over time which may be invisible to the eye. Thanks Ricky for your work

This could be used _today_ in any single escalator in any single building, including airpots

3 videos in the first 6 days of the year. I’m digging this! -PJ

In order to have magnetic levitation you have to have opposing magnets and train rails are not a magnet. So how does this work again?

In addition to the physical restraints clearing railroad crossings and turnout frogs and points, wheel friction/traction is essential to propulsion and braking. so you are out of luck on traditional railroads. It would be a new system and the rail is manufactured in volume with mature installation processes, so keep going. It has many benefits.

There is a market opportunity on the monorails that run on cities or airports.

They'll probably need to be able to switch to and from wheels for those problematic spots. To do it, they'll likely need either some kind of LIDAR sensors to track things or to paint the tracks and scan for the paint to know when to go on wheels and when to resume maglev. On the upside, switching to wheels could be used for power generation if it's set up correctly, like regenerative braking.

The Japanese MAGLEV is meant to hit insane high speeds -- it is not just a levitating train. Japan has those, too, but they are not as efficient as regular wheel trains, so they are not widespread. The usecase for the Japanese high speed MAGLEV is to connect cities that would normally require 3 to 4 hours of time on a regular bullet train, down to only 1 hour. Now that is a real game changer. This product is a nice idea as a technology demonstrator, but not as a real usecase satisfying design in any way.

Could this be used on linear rails of 3d printers and CNC machines? That would be a game changer.

This is not new. In 2022, China revealed the world’s first suspended maglev line built with permanent magnets that can keep a “sky train” afloat forever - even without a power supply. The 800-metre (2,600-foot) experimental Red Rail in southern China’s Xingguo county, Jiangxi province, used powerful magnets rich in rare earth elements to produce a constantly repelling force strong enough to lift a train with 88 passengers in the air. The permanent magnet suspension system saved about 31% energy when compared to non maglev-suspended sky trains. name: Maglev Sky Train testing location: Xingguo county, Southern China length: 800 meters capacity: 88 passengers top speed: 80 km/h

That was really cool, thank you! The challenge mentioned at the end, I can see them solving either with stepping stones -- switch back to "wheels" on the dangerous parts -- or, by allowing the pieces "magnetically gripping" the sides of the track to widen. A camera in front as well as comms with the system should help it know when to widen and when it's safe to tighten. It should be designed such that it still operates when widened, just at reduced capacity (i.e., slower, most likely). Thanks again!

NO BRAKES! So you have to have an engine or something touching the rail to propel it forward. But on a train all the cars have brakes. So whats stopping this thing if the engine derails? There are alot of cool technologies like this out there that just aren't practical outside of the lab.

Believe the solution for this product is the fact there is a large space between the wheels of each railcar. A center wheel can be mounted on a fulcrum, which transfers the weight bearing load of the lev-magnets to itself. The outer support mounts of the lev-magnets will hinge at the railcars existing structure of the upper springs, and where the springs themselves are replaced with airbags. Thus the center wheels fulcrum system will put the inner lev-magnets up while being pushed down, the airbags will push the outer wheels down the distance needed the clear switch tracks and road crossings. The rest of the train ride is in lev-mode.

If retrofitting is an issue, I think they should make it to where it alternates between traditional wheels and this. When approaching a switch, just lift it away.

Forza! Che magnifico! Well-done, Ironlev! Good luck figuring out switching stations. This is too brilliant not be figured out. In bocca al lupo!

Obviously, they need a way to magnetically stabilize the maglev horizontally (if possible) to eliminate the guide wheels, and they need a way to _magnetically_ propel the system using eddy currents on the tracks generated by electromagnetism on the system. Hopefully, they can achieve this.

Was thre any experimentation for using the tech to reduce derailments, where existing railcars could have smaller versions of these that helps keep the wheels glued to the rails? I know that is not intended use case, but might be a step towards full wheel truck replacement.

Regarding road crossings, if each section of the maglev unit under the train carriages could automatically raise the one section of the maglev unit to clear the track and tarmac just a little, this would be enough to allow the further maglev units along the track to continue the drive.

Rail head wear is only from guide rollers on this though so that's a huge saving on rail/wheel maintenance. Very interesting. I'm sure the US will want it for their rail mounted rocket sled testing range ^^ , that I would pay money to watch! Thanks for the video!

They should attach this system to a football pitch in one of the stadiums that have sliding pitches for better sunlight, it would be much easier and quicker to move; same goes for stadiums that have sliding roofs.

Can't wait to see Thunderfoot's *BUSTED* video.

Passing a magnet over the soil near train tracks will result in a lot of fine metallic dust building up on it. Would this dust collect on the magnets and how would that affect the working magnetic field?

Always appreciate your topics and presentations!

Rotate the motors 90° so the wheels ride on the top of the rail. Cantilever motor mounts that tension against the magnets as a function of motor torque. Problem 1 solved.

This is an excellent presentation with a very big challenge to conquer over road crossings. But there'll be new innovations that we haven't thought of, yet. Keep Thinking BIG.

I'm amazed that this haven't been made before now

There may be no contact friction, but you’re still going to have energy losses from moving related to the magnetic field changes in the iron, which I’m pretty sure will increase with speed. I forget the exact name, but I could see the things you were sliding around coming to rest on their own. Also, the more you take advantage of the magnetization of permanent magnets, the faster they become demagnetized, so what’s the replacement schedule and cost of that? Large permanent magnets are usually very expensive. It makes sense when you’re talking about some of these objects like sliding doors, where you don’t have multiple tons and you don’t need high speed.

This concept is brilliant to say the least. Thanks for bring it to our attention. The challenges of design optimization, especially the switching and crossing "opportunities for excellence," as Tony Robbins might say, appear to be an ideal candidate for AI to solve. Also, AI could be applied to the system electronics to correlate multiple factors such as crossings, etc with geolocation. Over time, and with "socialized learning to all systems on all tracks. This is a constant six-sigma search for opportunities for improvement. For example, a new maglev train is put into service in Chicago. Instead of learning where the crossings are, but, perhaps what happens over those crossings at any moment in history recorded by all the trains that have travelled anywhere. Like Tesla robots. When one robots learns something, all robots learn it through the super-web of cyber-space. Very large doors like commercial and military hanger doors are a definite candidate. Show them the money to them and you'll have another customer.

We are definitely going to want an update when they start doing stuff with this out in the real world.

is this more efficient than wheels? like you need to accelerate the train on both but you then need to constantly provide power to apply a force against gravity and momentum, like metal on metal is low friction

I would be all for a version of this that was like a Roller Coaster track in the air. You could set up sections that just pushed left or right a section of track into another section. They could be individual cars like bobsleds that were electric vehicles. The system could run several tracks on top of one another and a computer manage them. At certain a thin strip below the car could be used to power in. In fact, if this were covered with solar panels on a roof above the track, it could power the whole system! You could set your destination and go to sleep/read etc. while the computer brought you to your destination. If something broke like a motor, another car could be use to push that unit to another the closest town for persons to disembark while another car was fetched.

It's about time someone did this.

Not all track is the same weight, and the rail width varies accordingly. In the US there are 6 common weights varying from 57 kg per metre (115 pounds per yard) to 73 kg per metre (147 pounds per yard). A maglev system designed for conventional track would need to cope with multiple widths as a train may change from high speed track to lower speed track several times in a journey.

Comment from an old guy. This is a very old idea and one of the two ideas of maglev trains back in the day. The first idea was to use permanent magnets to create a permanent lift. This would be accomplished only by using superconducting magnets using cryogenic liquids to cool them. The second idea was to basically get the train moving on the track. The motion of the magnets on the train would induce Eddy currents in the metal track below and also a magnetic field that matches the train magnets polarity. That is to say, that if you can get the train moving, the train automatically lifts for free. Foward motion=lift. Plus: no friction after liftoff speed. A linear switching magnet could be used to move the system, same as superconductive magnet trains. Two choices presented themselves: the Japanese engineers that initially created such trains chose superconductors in cryogenic containers, the first option, over fifty years ago. Seeing superconducting lift trains basically became so common that people forgot about the eddy current induction train possibility. And, oh yes, it works. Cheap, foolproof, low power and no liquid helium cooled superconducting magnets needed. This simplifies maglev trains enormously.

I can not see it being energetically efficient for freight trains. However, train engines are EVs with their own generators, but can they power all the power needed for this?

You could still have the rails, but the ironironlev system can engage, by levitating, and reduce friction on the track for the long stretches. Concorde wasn't supersonic over land.

How does it handle curves?

how do you change lane with it? is it requires speciallly designed railway switches?

Im just curious what the point is. Its not like You use less energy to move the train. You lower the train's rolling resistance by providing a rediculous amount of electrial energy. Your just shifting the use and type of energy required to move the vehicle. Inductive levitation is NOTHING new. This feels like another "HyperLoop". something feasable but with no actual benefit.

That's amazing! I've always wondered why something like this couldn't work without super cold conducting magnets!

Super cool video as always!!

I like that they have rusty rails in their demonstration bit of rail. I wish them luck. Maybe the old school wheels are just above the mag rail and the mag rail lifts, settling onto the steel wheels that are 5cm out of the way most of the time. Maybe slow upgrades to the infrastructure could reduce the number steel wheel engagements over time as they alter level crossings to have gaps for the trains and infill for the cars.

There are many places where there are simple A to B without road crossings (or where installing one or two underpasses are all that's needed). A and B might be hundreds of kilometers apart. In Australia for example, once you leave Kalgoorlie on the Indian Pacific train you don't cross a road or encounter much until you reach Port Augusta. That's thousands of kilometers. there are some switching spots so that trains going opposite ways can pass each other. They could be eradicated by simply only having the one mag lev' train going back and forth. It could do it at a much higher speed I'm sure. You have to change trains a couple of times to traverse the country, but most people fly from Perth to Sydney anyway. The train trip is for a more adventurous experience. It could also compliment road freight. Vastly speeding up the long middle bit.

I think a hybrid train first where it can use traditional wheels just for crossings and switches would be a good next step.

Totally awesome example of practical innovation!

The problems I see are grade crossings and switches. In most current applications, there is only room for the flange of the wheel to pass. The guide rollers shown in the video would collide with pavement, in the case of grade crossings, or other rail pieces in the case of switches in the case of switches or crossovers.

A retractable conventional wheel system is already used on regular pick-up trucks used for track inspection and whatnot. Adapting a heavier system to handle the load of freight cars is just a matter of scaling. But the added expense for every train car might well be prohibitive.

This is so interesting. Thank you for sharing with us

I think they will just have to use super narrow bearings. Narrow titanium rollers for strength, interspersed with narrower iron to complete the magnetic circuit. This probably has a little less lifting power so the entire assembly needs to be lengthen by some percentage to carry the load. The narrow bearings will roll right through all the narrow gaps on the tracks.

I love this! I am amazed we don't already use magnets all over the place where friction is involved. Batteries/energy is always the difficulty?

How would this system activate crossing signals? This is done today by the train wheels/axles shorting the two rails together in insulated rail sections. The side-to-side guide rollers would be too intermittent to provide that.

Thanks for sharing your thoughts, ideas and videos. Left wondering, you said it’s permanent magnet yet I can obviously see a fairly large electric motor on each corner. How is the electricity being used and how much. Off the charts on cool factor but steel wheels don’t consume power when they are just supporting the load and not going anywhere. If it’s entirely self powered thru permanent magnets than a disclaimer needs to be included to explain away the electric motors. I personally would love to have this as a gantry crane in a workshop and would have no problem with any electrical load if I’m gaining the ease of moving load by hand and the quietness of removing any actuator that would move the carriage. Looking forward to seeing more of this technology in the future. Road crossings and switches aside how does it go around corners? As much as I love the concept I’m guessing the train angle definitely has a few more problems to solve.

Even maglev trains can be resting on wheels when still/slow. Permanent magnets might actually be the problem though. Difficult to make strong enough to lift large mass. They'll induce current which will oppose movement, particularly at speed. Electromagnets are surely required to draw the train into a direction of travel, and potentially regenerative charging on slowdown.

We've all seen the maintenance trucks that the railroads send out to work on the track. They have regular wheels and 'rail guides' that descend to support the truck when on the tracks. The truck uses its drive wheels on the rail to progress. Given the benefits of the mag-lev, I'm imagining that rather than retrofitting existing rail cars, why not adapt to the 'shipping container' load size and a minimal mag-lev (lower weight) that attaches, along with descending rail-guides like on the truck. Lightening the overall load by taking the massive rail cars out of the mix acknowledges that locomotives are also oversized when you reduce the friction. To those who refer to the low rolling resistance of steel wheels on steel rails; you're talking several more orders of reduction with mag-lev over steel rail than you are steel rail over the road. What I'm seeing is by adopting the rolling stock of the road with the mag-lev, you could operate on specific lines - say from a port like Savannah to a distribution point like Atlanta. One could imagine in an effort to rationalize the truck traffic, building rail lines between the east west and north south lanes connecting major cities that would transport maglev containers that are on mobile pedastals that not have rail guides, truck tires and mag-lev capability but are led around the distribution lots by low-speed audtonomous vehicles that put them behind the right semi-tractor for a 30-container truck-train. Who knows, the drop in rolling friction may be so grand that instead of a semi-tractor pulling that train of 30 containers, it is a cybertruck-sized vehicle 'cause it just doesn't take much to move stuff over a mag-lev setup.

This seems prefect for a hanging Mono-rail.

Look, Ma, no brakes! 🤣

System would require one major change to any conventional rail line, from moving point switching to a moving FROG switch, where the rails themselves move rather than just wedging the flange over. EVERY switch on a given line would have to be changed, to accommodate this system. The system, as described, would ultimately be more expensive as EVERY road carriage would need a minimum of two of these electromagnetic trucks, while industrial cars could probably get away with one... with no switching involved. But you're also looking at significant costs involved with trucks like these modified to operate on conventionally-switched track, due to the load-bearing moving parts needing to bring conventional flanged wheels down in order to lift over the rail during the transition to the diverging track. This means maintenance of the cars themselves would be more expensive. Changing the switches to handle either type would be less expensive for the operator, than changing the platform that needs constant monitoring and maintenance.

remove the guide bearings and use traditional bogeys as the guides, just reduce the pressure applied by the bogeys using the mag-lev., the outside part of the mag part could be pneumatically positioned , so you could remove the outside at crossings and use the traditional bogeys at that time. most crossings are taken at slow speeds so it should be manageable.

This is very interesting technology and they are right that it needs to be able to run without changing any infrastructure. When they solve that, I imagine it will be widely used as it will reduce running costs massively.

If we here in Australia got this it would totally change our transport infrastructure

You could rocker down conventional wheels with a rounded profile and rocker lift the bearings. The need is to keep it on the rail. There may be a way to "bump" the magnetic field to lift over the rail, but that means suspension and again, maybe a rocker situation.

You can use rotating magnetic fields to provide the side bearings at road crossings and switches.

I am only speculating and I think what is happening is that an electric current is induced on the rails using pulsed or varying current on the train. Then the magnets on the train ( on either side of the rail) exert a motor force on the induced current creating the lift. Might save a bit of energy compared to wheeled trains, since most of the energy is used to work against air resostance😅. Another possibility is that an electric current is passed directly across the rail guide and the train magnets acr directly on the current. If the train can produce 20T magnetic fields, then to produce a lift force of1000 kg, a current of 1000 X 10 ÷20 ÷0.05 = 10000A needs to pass through the rail, assuming a rail width of 5 cm.

MAGLEV is definitely on the right track. I think the solution to transition from standard rails to flush rails, etc is very simple and can be integrated into the MAGLEV chassis

Perfect for the smaller applications. Ingenious! As for actual trains... They don't even mention the heat a moving magnet will produce and how it will affect (i.e. deform) the rails. They either don't know about it or they intentionally fail to address the issue at this point.

It seems like the ideal large-scale technology demonstration for this would be a retractable roof on a stadium.

Innovation always seems better to me than the original idea or format. What's better old school crank starting your car, or using a push button fob?

It may have some use, for revitalisation of abandoned lines to small passanger stream, without costly full repair of tracks. Or even like some commuter in cities with many tracks but mostly used only for cargo.

This is amazing technology and the maglev train possibilities is interesting but watching you push the sliding door I thought of the skyscraper in New York City that has a counter weight built into the top of the building to offset the sway in the building from wind. This could be a computer controlled pendulum for stability control of buildings.

I'm thinking to use for conveyor belts for the mining and package handling industries. Also for linear actuation of robots and car suspension.

A maglev train has to have TWO sets of magnets: the first provide the lift, which this system seems to accomplish, but you also need the 2nd set of magnets which are the ones that switch between pulling and pushing in tiny fractions of a second in order to actually more the train forward and backward. Nowhere in the video was that even brought up. Everything shown required the host to manually provide the motive force. Thus, this seems like a start of a possible solution, but its maybe only 20% of the total solution needed. There are the problems of switching locations and level crossings acknowledged in the video, plus the problems other commenters have raised such as how the long and (currently at least) straight magnet shown would deal with curves in the track, etc. And what I believe to be current prevailing thinking is that maglev trains can't be reasonably engineered to climb steep track gradients. Like TGV technology trains, maglev really needs straight and level track. Or at least notably shallower gradients than conventional rail.

So for this to make economic sense the reduction in energy lost from friction, which has a cost, must be greater than the cost of the system, retrofitting etc…, and primarily the energy consumed by levitation. Presumably it must be a fair margin in order to incentivize transitioning to Ironlev. Is this correct?

Awesome 👌 game changer, I think changing switching stations and crossings is the solution or moving rails into tunnels

1/10th the power to move the elevator is a HUGE improvement

How would you handle on grade? The whole train could backslide on a pass if there is no friction point for breaking

You have to have lifting wheels with a screw mechanism to be strong enough to lift the whole train with a way to lower the coupler at the same time. Or a new coupler that can change height frome one side to the other.

🤗 GRATEFUL RICKY,YOU ARE ABLE TO MAKE THE JOURNEY AND SHARE THE EXCITING POSSIBILITIES FOR THE FUTURE 🧐💚💚💚

Just need to have an electronic switch on the car to make wheels drop and/or magnets to shut off and pull up. Some physical safety mechanisms should also be implemented or monitored to ensure safety

You cover a lot about the need to move a door using maglev but what about the need for speed? Can conventional rail-line match maglev lines speeds that are already built?

One of the main reasons mag-lev hasn't left the prototype stage, how do you stop it. A train has enormous kinetic energy.

There's probably still a lot of bugs to iron out though it does look promising. It can reduce friction by a lot though if reusing existing tracks with regular curvatures, there won't be much increase in speed, but the power consumption will be significantly lower provided the magnets don't consume too much power. That being said, I wonder what sort of traction it'll use.