Electromagnetic Aircraft Launcher

DIY railgun content is seriously nostalgic youtube material

I feel like Tom Stanton is bringing big OG youtube energy.
“But what if I engineered a railgun to fire wieners”
Classic.

Fun idea. Some improvements: iron strips on the outside of the magnets to close the field lines; square coils to get get the drive currents perpendicular to the field; graphite core to increase field strength; graphite brushes to reduce contact resistance; use finer wire with more turns to reduce current, all things being equal you'll get the same force and mass if you halve the wire cross section and double the turns (or you can then double the voltage to double the force for the same mass).

i an a retired engineer, but I still love to watch people figure stuff out, and great job!
I worked a lot on rail gun tech. It's pretty scary when you get up to levels they use for weapons. I also love how you designed and printed the parts out.
Thanks for the posting. I know you put a lot on work in this video.
Smiles!

There's a very good reason brushed motors do not use metal brushes, but graphite (with a little powdered metal). Though brittle, and not really that hard, these brushes are very slippery and hard wearing, and will conform to small scrapes and wear on the contact points on the rotor shaft. So if you actually machined the contact points on the rail, some very cheap replacement brushes made for, say, an 18V drill, or even a 220V drill, will work for ages. Some of them even come with their own springs, and basically all of them come with a wire already attached, so you wouldn't need crimping. moving the power rails to the middle might be a good idea as well, having the brushes pinch a power rail, rather than push out on either side. With graphite brushes pinching a central power rail, you can also put much more force into the contact (remember they're slippery), therefore making the contact with each electrode (I'm missing the proper word for this, please tell me if you know one) "promptly, precisely, with force and without hesitation, as expected". You may also have to use copper/brass as electrodes. And maybe make a tool with two brushes to clean them if you still get arcing.
Anyway, love the vid, and can't wait to see what you'll do with this!

Absolutely in love with how analog and raw this thing is haha. And it works awesome!

You could integrate this launcher into ProjectAir's giant RC aircraft carrier and you'd have the ultimate model plane takeoff from the sea - please consider the collab! Amazing stuff as always Tom. :D

14:53 the reason it goes faster than your estimation is because the magnets cause less back EMF in the coils at lower speeds. Also a tip, as the coil speeds up down the rail you need to "advance" the polarity switch timing to account for the lag of the inductor/s responding to the voltage applied. They do not immediately produce a magnetic field. This could be limiting your speed (as well as back EMF providing a maximum limit for any voltage you apply).

8:00 very cool solution to make your own reed type switch!
Another idea that first came to me, was making a latch at the top that as it hits, holds it up and won't let it bounce at all. Then to reset, you lift the latch and put in the lower latch

Spending the day building rail sleds in the English countryside with Tom Stanton would be my idea of zen.

Two suggestions: Insert an iron core into the coil to focus the magnetic flux. And exponentially increase the magnets along the track to build up the acceleration.

The sound of propeller revving up at 14:32 is so satisfying for some reason.

Seeing all the sparks and spark damage, I have quick and simple recommendation:
I'm not sure the voltage you are running, but across the terminals of the coil, solder something like an MOV in parallel.
The sparks are created by inductive kick. So if you have 24v going through like 2 ohms, you're going to have 12A running through the coil. When the contact is broken, it is slow to change current, and will try to force 12A through open air, resulting in a huge voltage spike.
An MOV becomes more conductive at higher voltages to protect against voltage spikes. This could drastically reduce the voltage of the spikes. There would still be sparks, but they would be less damaging.
I didn't think this over too much, though. So there might be other effects to contend with. For instance, since the coil could "free-wheel" at the threshold voltage, it might make the current in the coil last longer, so you might get slowdown. It would be something to test. You might want a reverse-current bypass diode on your output source as well.
EDIT: Dang, now I'm thinking about it.
You could even try a capacitor as well as the MOV, Have it store some of that remaining energy into a capacitor that is ready to discharge in the opposite direction. But that might be tricky due to all the phase issues at different speeds.

The one thing i really enjoy about your channel is taking really science based applications and shrinking it down so the methods and practical usages can be seen. Launchers like this will be how loads and ship might be launched from low atmosphere planets in the distant future.

Thank God for magnets, we would be lost without them

12:37 If you're using a cap screw to hold your sled brushes in place, you can probably fold the brush around the strip and skip the solder. The cap screw should be fine for a compression fit, if not, a little tweaking to your design and you're good.

Who else heard "i built a similar launcher a few years ago" checked the video, saw it was 2 years ago, and then stopped to question wtf is going on with time.

Graphite carbon brushes are used in electric motors that have a high durability, don't leave molten splatter, and can be held to the contacts under pressure with a spring. Love the all mechanical design!

To prevent solder wicking, cool it down with something cold. Bits of metal would be ideal. Also, solder does not flow upwards easily, use this to your advantage.

The redo and the detailed reasoning done here is mindblowing 😊

You absolutely need to make some kind of 3D printed launched rollercoaster model using this Tom !

The more turns the coil has, the higher the inductance, that causes current to increase slower. From video you can see that you have a few ms per contact point, so minimizing the time to hit max current is important. Magnetic field is proportional to current, and also proportional to number of turns, but number of turns is also proportional to inductance, and that is something you want to reduce.

We finally got the “how to build a railgun” video🎉

At 10:00 it was The Grape Escape.

I’m not an engineer but I have always been interested in learning about this topic. This is very well explained. Thank you for sharing your knowledge. You have another subscriber 👍🔔.

I believe you will find a performance increase if you wound the windings in a much neater way rather than crossing over itself so many times. Also I'd be curious to know how adding a core to the windings would also help but yes it would increase the weight, I think it's worth a shot. also also... I grew up playing with AFX cars, they used springs to push out the contacts to keep them connected to the rails as best as possible, I think if you switched from the braid to springs pushing strips of metal you might get better contact

Place a steel core in the coils. Also use multstranded wire for coil (litz wire) to avoid skin effect and increase speed at which fields are formed. Perhaps add caps/supercaps to avoid power dips if any.
Awesome idea, I build a rail gun way back for my thesis at Uni.

Neat seeing the prop blades deploying midair.

Cool and fun video.
Few thoughts:
1. Adding back iron will probably increase your flux level in the coil, markedly.
2. Don't have the carriage in the range of contacts when turning on the power to the rails. Have a spring launch the carriage at a 'slow' roll at the first contact pair, with power delivered to rails with no load. Fraction of second switch bounce won't matter.
3. Widen your magnet spacing to get higher speed, either widen them all evenly, or space them out as function of distance from first contacts. It will show the early acceleration, but should increase your final velocity.
4. Consider figuring out how much BEMF your seeing from the coil moving in the magnets. Without power, STEADILY pull the carriage down the rails and measure the voltage generated across the rails according to position, and speed. Really needs to be captured with a scope and a 2nd channel for position info.
BEMF is proportional to speed.
Record of BEMF will let you adjust the contacts position with respect to the magnets.
(BEMF is motor-speak for what keeps you from pushing more current into a motor at "full speed" - the voltage you're applying is fighting the voltage generated by moving the coil through the magnetic field.)
5. Consider voltage jumps as you go down the rail. Later contacts will have more voltage than earlier ones, and magnets can be spaced out further at the same time. A series of batteries with multiple taps can feed multiple rail segments. Bit more complex, but still pretty manageable. It will cause a step/jump in the acceleration, so the load should not be too delicate (foam wings?)

I have no idea how I've missed your channel all these years but I'm glad I've finally found it. Epic content, keep it up!

What an awesome project. I love the elegant simplicity of this launcher. Although it makes you wonder just how much current those Navy electromatic aircraft launchers are pulling. That has got to be a wild setup.

for speed, alter the spacing/timing of the contacts and magnets in the later stages. use the vid tracker to see where the current acceleration stops....start spreading them out after that point.

you should add a ferrite or iron (but the ferrite it not that heavy like iron ) core to the coil to concentrate the magnetic field facing the magnets, you will get more force

you can attach anti-bounce piston mass to the spring-loaded hammer: pour metal powder into a small cylinder, filling 1/3 with it. the mass would prevent hammer from bouncing. the metal powder will move forward and "stick" the hammer in forward position due to inertia

The solution for the trigger mechanism and way to complete the circuit legit blew my mind. That was crazy creative! Coolest thing I've seen in a while

9:46 The amazement about the 3 grapes cracks me up so much lol
"Hey, I built a freakin railgun.", "But what if you put 3 grapes in there?", "Ohhhhhhhh" 😮
Like that was the most mindblowing part of the project :D

As a Physics teacher, I can say this is inspirational engineering! Bravo and thank you.

Tom, for your magnets, try arranging them in a Halbach array for more power . For your switch, have a look at compliant mechanisms to eliminate springs.

I remember watching the first video when it came out. How you've innovated and found a much simpler solution is impressive engineering. Great Video.

This is awesome. I graduated from Hertfordshire a couple of years ago. Your videos helped me get through my aerospace degree.

By the way, feed your current in on the exit. So the voltage drop over your busbars is less and less obvious to the end, increasing force instead of dropping. 90A is starting to get serious

11:45 I would also note the increased inductance from more turns, meaning that the coil's field will take longer to reach its full strength. I suspect this may be a factor in why the force you're seeing from more turns is not directly proportional.

Excellent build! The first rail gun I saw was in 1976 at the Francis Bitter Magnet Lab, at MIT. They had capacitor banks the size of fridges lining the wall. At one point the operator used his grounding hook to discharge a bank. About 12" of the 1/2" Dia. rod vaporized. They had 10 feet of foam stacked as a target. Very impressive.

1. Use Ferrite core on the sled to increase magnetic force applied to the sled. Ferrite would also work better with fewer turns.
2. You can use Electric Motor brushes made out of graphite to avoid plating problem. usually Motor brushes have springs to apply a small amount of force on the contacts to get a good connection. Only one side of the static brush contacts needs to be intermettent. You could just use a single bus bar along one side & just make the other side segmented.
3. Adding local capacitors for each stage (segment) would increase the current for the coil providing more acceleration power.

14:14 was waiting for some miscalculations, and expecting the pliers to launch five houses over. Lol

Induction also plays a large part in the coil. I think the sparking is mostly caused by the induction, when inductors are disconnected they create extremely high voltages from the induced magnetic field. (add capacitors across the rails to protect your power supply!)
Another improvement to the launcher would be to increase the spacing down the rail, this allows for the coil to get to the right polarity on time.

Man this was so cool. I remember watching the original launcher video and this one is completely next level.

4:20 this looks like something straight out of a scifi movie. So cool.

10:26 this is for sure gonna be in a daily dose of internet video

14:48 That is so smooth and perfect!!! Like rocket science running a pre-programmed stage! Love it!

actually excited that you made a relay for a coilgun

Cool projetct. A tip: In the trigger, you just needed to remove the slack from the spring so that the hammer doesn’t retract. The pressure would keep it pressed against the electrode when it strikes. No magnets required.

I love that you made an analog version, but honestly I am really happy as well to see that the fancy electronics did compete really well.

Offering some more thoughts after reading some of the other comments:
- To improve the accelerating force:
> - Optimize the solenoid field strength by adjusting current (as a function of coil turns and wire gauge) and coil turns. As you increase the number of turns, at a fixed voltage, the current decreases due to the increased resistance of the coil, so simply adding more turns will pass the peak and yield diminishing returns.
> - Another way to squeeze more performance out of a fixed length of rail and magnet spacing, is to increase the voltage for later segments. The faster the sled moves, the less time contacts have to transfer current and flip the polarity of the coil's field. Increasing the voltage at a given resistance will automatically give you more current and a faster d2i/dt2. The quicker the coil can flip to the correct polarity and reach max strength, the more time it will add to the sleds acceleration.
- To reduce or quench the back-EMF:
> - Adding a capacitor to the sled on the coil would reduce the acceleration, as the rise time of the coil is dependent on discharging the coil from the previous contact segment's polarity, and adding capacitance would sustain the negative current and cause delayed current rise time, and potentially suckback if it's severe.
> - Adding a bank of TVS diodes on the sled would reduce arcing by quenching any overvoltage, but would not quench the remaining stored energy below the TVS breakdown voltage. TVS diodes can be purchased as unpolarized components so the sled remains simple and light, and conduct quickly. Make sure to take into account the stored energy of the coil (ie: joules) and ensure that the TVS diodes can handle the entire amount.
> - Adding reverse current diodes at every segment (alternating polarities) will improve it further - note that the diodes need to be as close to the contacts as possible, so that the power rails themselves do not become a large source of inductance themselves. Any intrinsic inductance in a pulse power circuit will hinder rise time in current.
> - One potential experiment to do (even if not for optimization, simply to visualize on high speed video) is to place a bicolour LED across the coil with more than a series resistor (you will have to clamp significant overvoltage from ringing) so you can visualize current in the coil on high speed video, and understand how quickly the coil's begin to suffer suckback.

Use 3 coils one 3 sids of the track. So the magnetic field dosnot get wasted. It will also increase the force of the projectile

For the slot cars: The good old Carrera system had solid metal contacts and was really reliable, easy to maintain, and also had many tricks up their sleeves like being able to control 2 car individually on the same lane.
And for the bounce: Aside from not using a mechanical switch directly as the main switch - why even make it straight contacts? Your switch is a rotating arm: use that. Have the contact follow the arc, with the brush being held slightly flexible and the outside stationary contact having a slight inwards curve: Now once the contact is established the arm is "gently" slowed down and the force of that does not lead to bounceback but rather squishes the the contacts together more firmly.
The magnets and contacts also should not all be the same dimensions as at the end of the rail it is already travelling at a significant speed. Either the coils are over-saturated at the start of the run, or at the end it can barely build up a magnetic field cause it is wizzing by too fast.

Wow, that's a lot of work. Both the launcher, and making the video. Thank you! Very cool.

You are by far the coolest DIY youtuber this kind of content inspired me I'm starting collage and doing engineering as this content has inspired me and has gave me enjoyment watching this makes me want to do this myself and a big thank you for entertaining and inspiring us viewers with your crazy but interesting content creations.
Thank you.

10:50 i felt that

@09:33 "That was a splat!", no, actually the grape gave up a little wine.

That's great! I would have used the trigger mechanism to move the sled into the magnets, that way you eliminate the electrical bounce completely, also you could add a small RC shock absorber at the end of the rail to stop the sled going off the rails, since the RC plane will be faster the moment of the sled slowing down, the shock absorber will just need to stop the mass of the sled.
And If you want extra points just put a linear rail so the friction is virtually zero.

If you don't go after what you want, you'll never have it. If you don't ask, the answer is always no. If you don't step forward, you're always in the same place.

That is seriously right on the money. That plane shoots off that ramp perfect!

Did you consider using graphite on the contacts, they would minimise the sparking and energy loss?

7:45 I don't get it, why not just put in a simple on-off switch that you don't need to print and waste time on it? A simple on-off switch has a variety of A ratings, so why not simplify everything?

2:00 CARRERA!! MY OLD FRIEND AND JOY

I saw a short about this project, immediately came to the channel and now I’m an immediate subscriber. I love this kind of stuff and wish and hope that one day I’ll have a similar workshop to do fun stuff like this and keep me busy. Brilliant work, well done 👏🏿

That was amazing as always.
If you ever mess with the switch again, I recommend copying a distributor. The contacts slide into place radially (laterally?) so a little bounce doesn't disconnect them.

10:35 pump em full of sled

I am seriously shocked, how people make the same mistakes over and over again, when they attempf to build a Gauss-gun (or variants): Lorentz force laws says, flax density and conductor length matters. To achieve a high flux density, C-magnets with closed magnetic flux path are mandatory. Furthermore, everything, that uses ferromagnetic cores undergoes saturation. More windings provide higher magnetic flux densities, but sincd the impedance of a coil is Z=R+jwL and u(t)=L·di/dt, there are time limits. Therefore this kind of party has its physical limits. The better way is to use the induction principle with air cores. There is no saturation. The most extreme construction derived from this principle is the rail gun.

3:53 I'd add a small inductor, that should calm down the arcing as it will impede the flow of electricity when the brushes initially make contact :)

Can't believe you actually didn't do this from the start. This is the most logical way.
Nice work!

Brilliant switch idea. You should see how small you can make it and enclose it. You could market that. Great video!

Love this. Only change I would made is to print the plane base in bright/neon yellow. Definitely the coolest way to launch your plane. 👍

TH-cam is probably going to be the home of the first succesfull railgun design

Thanks for the awesome video with a nostalgic feel for the good old days of "Railgun vs Coilgun" videos!

Definitely the coolest rc place launcher I’ve seen yet.

I agree that practical has its purpose but entertaining is what belongs here.

Wow, that take of the plane "deploying" the propeller as the mount detaches and falls was very sci-fi, it looked very cool, good job 👍

It's definitely one of the coolest ways I've seen a model airplane launched

2:45 fun fact, put this in a circle, and you have a brushed DC motor.

With thinner wire, you could get more windings on the launcher spool, without higher mass - thus, hopefully more "torque" from the launcher.
Also, something I remember from my time with RC cars, is that you can pack the windings a bit better, if you have two very thin wires in parallel.
ie. I had a 15 turn motor, and a 15 Quad (4 wires) motor - And the 15 Quad had more lowdown torque, but also required a bit more power to run.

14:31 That's some good asmr there
You can hear the propellers spinning up, in slow motion, after the launch

Definitely the coolest way to launch a model airplane! Nice work!

Awesome. Top tip- look at old school car distributor point systems. Cam driven contact closure for high current. Designed basically for exactly what you’re trying to achieve :)

Proved what an engineer can do using one priciple there are many thing which could be designed. Generally these are used in train suspension systems like EMS (Electro magnetic suspension) and EDS (Electro dynamic suspension). My favourite part was designing a reed switch. You proved that you are an engineer with a single video

Replace the solder wick with rollers, and offset the rail contacts by a fraction on one side. All the energy at the point of contact will be on one rail. You could also replace the energized rail with a graphite for better contact and longevity. Float the sled with rail vs sled magnets. In all, your DIY rail-gun is cool! Thanks for sharing...

Cool that you got this far without any electronics. But as an EE, I kinda smiled when, among other things, you devised a complex mechanical switch debouncer, something us EEs have known how to do electronically and very simply for a very long time. I'm also sure that the judicious use of electronic switching could greatly reduce your many arcing problems.

The Sound that thing makes on launch is just magical, BRRRRRRRRVVVVT!

lol that entire grape scene is so unbelievably relatable, it’s perfect
e: ok i spoke way too soon, it got so much better

It's also a very repeatable way to launch. This could come in really handy for testing different designs. You might even be able to modell the exact amount of inertia you give the launched object via a series of tests, so that you can punch in the desired speed and/or acceleration and get the parameters to acchieve just that.

Niceeeee guess I'm not the only one working on electromagnetic accelerators this month... :D

You need a tether to catch the sled after it departs from the plane.
I love these videos!

I know they weren't designed to do this, but the way the prop folded back as the plane launched and pops back plout when it's turned on looked like it was perfectly design for that launcher

OUTSTANDING! Now all we need are scale model aircraft carriers, destroyers and FAIREY SWORDFISH!

14:48 That is flawless and extremely smooth! Like a pre-programmed stage being run by rocket scientists! adore it

You needed to build a model aircraft carrier with that as the catapult! That would be the coolest ever!!

That is amazing!! I love how you show us the whole development process, very informative.

It wouldn't let me add a normal comment until I replied to someone else's! For all of you saying this is going to lead to a railgun I need you to realize railguns use a different concept. The fact that he said this was not practical is kind of not true considering now you don't have to have someone throw your aircraft. You can repeat it in a more scientific fashion. I would like to see him upscale this but I know that's going to be expensive. All in all this is an amazing design! Good work Tom!

To improve the main connector switch the ideal situation is it is held closed under spring tension, and then you release the open position. As then it's biased closed it'll want to stay closed and prevent bounce. Mains disconnect panels use spring tension systems to ensure the contacts are made/broken as fast as possible and held in position to not bounce.