My absolute FAVORITE part of this video is that as it progresses, we get failure data for parts that aren't even suppose to be tested because the tests keep DESTROYING normal lego parts.

The explosive nature of LEGO, amazing

Carbon fiber has much higher potential, but the fibers in this axle are just in the axial direction. If there were fibers going diagonally around the center axis, the torque would be much higher. But due to the shape of these axles it might not be practically possible. If you could somehow do a pull test, the carbon fiber axle might be stronger than the steel one. But for torque, the carbon fiber axle is probably not much stronger than the resin used to reinforce the fibers.

3:08 I am now convinced that this is how drill bits are made and cannot be persuaded otherwise.

We’re all carefully watching this video like we’re some executives at Lego, and we’re about to approve the new material for a special Lego set.

Four billionaires cried out in terror and were suddenly silenced as the carbon fiber started to crackle.

The steel insertion test is what happens if you forget to chamfer your edges after milling. It had edges at the end that were still sharp, and with a few seconds with a file or abrasive could probably be considerably improved.

1:59 steel Axle is just chilling

Well, now this guy has metal beams, metal gears, metal axles and metal connectors. Should we expect a full-metal lego set?

The twists in the axles were so artistically formed, I could stare at them for ages!

Not sure how feasible this would be, but would be cool to see this test done with different plastics (mostly thinking about Delrin) and maybe even different metals (like Titanium or something)

3:12 The motor- "Time to put on my hollow mask"

Pretty sure the Lego axles had better tolerances, hence the lower friction in the two tests

Who else wanted to see a titanium rod 🧞‍♂️

That twisted steel axle looks seriously cool, and it probably still works well, I'd love to see it return in a future build, just wherever you can fit it :)

8:38 To analyse noise you should record noise values at regular time intervals and find the average value. You can also find the measurement error using the method of least squares.

From the moment I understood the weakness of Lego, it disgusted me. I craved the strength and certainty of Steel. I aspired to the purity of metal. Your kind cling to your Lego, as though it will not decay and fail you. One day the crude plastic you call the temple will wither, and you will beg my kind to save you. But I am already saved, for the Steel is immortal… Even in death I serve the Omnissiah.

1:21 every episode of SpongeBob has one shot like this

Would have been cool to see the amount of torque each could handle before permanent deformation. Feel like that would be more applicable for actual usage in most cases. Edit: nvm, those values are listed in the graph at 11:16

Carbon fiber is good if you want sokething cheap, aluminium is good for if you want something strong and easy, stainless is good for if you want to lift a car, lego is good for if you want more friction.

I feel like in the friction test, you should have accounted for the mass of the axles themselves, the steel axle isn't necessarily doing worse because it has more friction, it might be because it's just heavier than the other parts. Great video!

when the axle is so strong you need to upgrade the testing items themselves to test the connector without problems

The torque test on the aluminium didn't get a fair shake because the grub screws would have created a weak point, which the others didn't have to contend with

0:40 - that looks kinda cool

When using non-POM axles in general it is advised to use some lubricant. That is the biggest other difference between standard Lego axles and the other materials: POM is self-lubricating.

My man is NOT giving up

3:35 This is the best lego destructive pop I've ever seen so far...

Idk why but the sound of the noise test with the single beam took me straight back to my FIRST Lego League days

This is like Project Farm for Lego, continue this series please.

Plastic axles for speed and steel axles for strength As a true train fan, that reminds me of something about steam train's wheel size Big wheels for speed and small wheels for strength

Do you think you could do a test with different types of gears at some point as well? Would love to see how much more durable the metal ones are in high stress scenarios, and how much of a cost it has on the friction (and maybe if lubricant can give even better performance?)

I love all the different tests you came up with. I would absolutely like to see this concept done with other types of pieces.

0:28 damn the Lego plastic axle transformed into Haribo licorice

I never knew i would like watching adult man playing with legos so much 😂😎😎

3:14 Link when he sets the Deku Mask on

Would love to see a similar test comparing the plastic from different decades.

next up: lego rpg vs real rpg

It's very interesting. You also have to realize that the reason why LEGO is all plastic is because it's intended to be used by kids. BUT I will counter-point that with Construx actually had metal axles and was ALSO targeted at kids, it just wasn't around that long to have any incidents that I'm aware of (eg injuries from sitting on one.) I think bigger take away here is that Lego probably could sell metal parts with a warning that "metal parts are intended to be used by adults" , as I could see situations where people lose fingers/eyes/scalp by trying experiments without proper protection.

8:33 the framing on these tests is beautiful, lining up the axle and the line between wall and table. nicely composed

A great way to improve the insertion test results is if all three of the non-official lego parts have their edges smoothed alongside the veins being slimmed just the tiniest bit to match the official part properly more closely. Other than that I think a brass one would probably work really well in terms of the friction tests potentially. Or maybe a different metal that doesn't provide much friction in such conditions if any.

Love the experiments! Very thorough job testing all the aspects of each material. I noticed especially the difference in cross-sectional area between the aluminum and steel axles. The aluminum has very rounded edges while the steel has very sharp edges. Id imagine this probably contributed significantly to the insertion tests. I'm curious if you could do one additional test and report back? (you definitely don't have to, just curious) Use a set of calipers to measure the maximum cross-sectional width and see if there is a difference between the aluminum and steel axle due to the chamfers. Clamp down on the axle at 45deg(where the cross section width would be the smallest) and rotate the axle in the calipers to 90deg. I'm curious if the chamfers of the edges make a significant difference in its maximum cross-sectional width?

3:39 that brick was personal 💀

4:08 now it is an ✨art piece ✨ 😂

For the friction test, I'd like to see a comparison after polishing each of the axles with 1000 girt or finer wet sand paper. You get a more life out of the paper when you do it wet, add a tiny bit of soap and it will polish up faster and give a slightly better finish too.

Lego should make some official steel/aluminum axles

4:34 that one mosquito that refuses to leave the room

The little machine that did the torque test at the beginning was so powerful!!! I can’t believe it was able to twist that steel bar the way it did.

I am learning a lot of these concepts in my engineering courses and its fun to see them built out of lego

Love that you've brought engineering/testing into the mix. I'm even more impressed with LEGO parts.

A salute for every Lego, official and aftermarket that died to bring us this critical data. God speed you brave bricks. o7

Giving us the "3D" view by rotating the axles close up (with lego motors of course) was a really nice touch

That carbon fiber stuff looks pretty resilient, would probably make for a good submarine material

The steel ones need better tolerances but they will grow or shrink depending on temperature they look very roughly machined too

A man just isn't complete without his LEGO torture machine

Love watching these tests, not sure why. Just a suggestion - in a comparison like the friction test, especially where as you rightly decided it wouldn’t be super interesting to watch at full speed, you could show all four videos at once (each doing a quarter of the screen). Could also do something similar with rolling tests by super imposing the videos. Keep ‘‘em coming!

Brilliant! Thanks for the shootout and results!

It likely doesnt matter because the ranking was the same at the higher load, but having a more consistent release in the car friction test would increase the accuracy and precision of the results. Ideally a mechanical release that doesnt impart any forward or backward momentum would be ideal, such as raising a boom gate with a programmed motor or similarly retracting a bump into the ground. Same with the noise test. Using the rpm method from before would have been better. You do what you did on the previous test to could spin it up to 300, then use a laser to test when it reaches 200 rpm and record the 200rpm volume

0:36 AMERICAAAAAAAAAAAA🦅🦅🦅🦅🦅🦅🦅🦅🦅

for the durability test to make sense you need to make both the axle and the bearing from the same material. otherwise the harder material (in this case the axle) will destroy the bearing

😮 3:42 just as i was praying yhe motors didnt break

The cross-section of the steel axle is noticeably different than the others; I wonder how much of a role that played in the insertion test.

You can not make sure you are pushing all the cars with the same amout of impulse on the friction test. I would sugest you to put something in front of the wheels, or in front of the car, and remove it letting the car run freely. If you need it to move for a longer distance, just get a bigger ramp. Thanks! Nice video!

the only channel i know that makes lego cars for a job XD

Lego becoming licorice and then a telephone line.

very cool video, on the second friction test, how were you insuring that the block was rotating at a consistant speed at the beginning of each test?

That carbon fiber had me subconsciously squinting my eyes

Wow! I had no idea that many were made!

the carbon fiber coming apart was sick this is a fucking sick one especially after just finishing material sci

I wish you tested the torque of plastic deformation. While the carbon fiber and lego axles seemed to have similar ultimate failure torques, the lego stick seemed to show plastic deformation much sooner...

1:35 top 10 unexpected turns in whole universe. Number 1:

Basically: Buy LEGO unless you do some extreme stress tests.

0:40 is that black licorice?

Oh no! It's... THE KRAGLE! 😱

I think that the coolest part about this test is that it reveals the design criteria of Lego. What did the Lego succeed in? Quiet, spins well, and it’s easy to put together. As a father of 2, I will happily say thank you to those design requirements.

01:15 there you go carbon-boys... only steel is real ,)

It's nice to see how well the LEGO parts held up here, even though they obviously can't take the same torque as harder materials.

When I got to 10:47, I just realized, Why the heck am I watching this? Hahaha. How could it possibly help me in my life?

I can just picture Jeremy Clarkson screaming "POWERRR!!!" as the torque test is running.

8:48 This is not a very scientific measurement, your time will improve with the number of repetitions because you get better with the number of repetitions and train your muscle memory ;)

That was really cool

at around 3:20 it sounds like the deku scrub transformation in majora's mask.

This channel is so quiet, it's a great breath of fresh air

0:57 Well, this is what ABS looks like..

Killer vid as per usual! Have you considered using graphite dust to smooth the carbon fiber/metal parts? It'd go a long way to reduce friction/noise. An old trick we had for roller derbys I thought it was fitting

Wait wait wait, isn't the friction test flawed? You didn't account for the additional mass of the metal axles

I liked you starting with the thumbnail and then using it, it actually was a cool vibe

4:34 its sounds like a sped up version of a demon being exorcised (sorry just watched the Conjuring lmaooo)

Love these, just a question. How many Lego pieces do you throw away when working on this channel?

1:30 I’ve never seen that happen with that part before 😨 Probably because I mostly just use standard Lego parts 😅

Cool video, but carbonfiber is stronger when laminated with resin and UV-cured

9:26 Skill issue. XD Kidding, of course. From the look of the steel I would assume the smooth shape would make it easier.

Would be interesting to see a sliding test of various pieces down the length of each axle. Both a test that sees how much time it takes for a machine to move a piece down the length of the axle using a fixed force for each, and a test that determines the minimum force required for a machine to slide the piece down the axle.

they've gotta add some graphene rods

The comparison nobody asked for but everybody deserves to know!!!

3:30 justo estaba pensando: muchas piesas plasticas y presion, algo va a salir volando

That's such a niche type of videos on KZbin and I love it.

6:58 it looks like they are spinning in different directions

Wow, congratulations, very detailed

7:06 ASMR

There is something about this channel that makes me believe that Lego could pivot and make actually usable prototyping kits. It feel tantalizingly close to opening up a whole new world of DIY problem solving. Usually when I get this feeling it's because I haven't understood a MAJOR constraint or cost problem that would make it impractical or unaffordable. But if Lego hit the sweet spot, it would really open up some doors. EDIT: I just looked up Lego Technic and it is kind of baffling to me that they don't sell a general prototyping kit (especially with the community that seems to be present) I was thinking about how one would have to make a "Technic" style system that would give you the HIGHEST number of possible working configurations. It's a problem that is mathematically beyond my capability but it seems like it would have to be based off of a starting length and everything being built on its multiple (possibly a length that is a multiple of an approximation of Pi (the number) so the gears would fall into the correct locations) So there would need to be kits based off of the module of the gears used that would be linked to the axial size that would set the spacing of the Lego "buttons." Then adapter plates that would allow you to snap in assemblies of a different module to a larger system (preferably the modules themselves would be multiples of each other such that your adapter plates subdivisions would end up snapping into useful spaces). Is it just me or does it seem like if someone really understood how to solve this problem they would also have a good insight into how the universe itself functions? It's all ratios of some "quanta" or "Planck length" right? Did someone slip me LSD? What's in this coffee???