Tensegrity Explained

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this is actually one of those videos where i explain a thing by making a 2d version of that thing because the 2d version is easier to understand like these two videos link in the description and in the card the difference with this video is that it's not about a hydrodynamic mechanism it's about a structure a type of structure called a tensegrity structure like this beautiful tensegrity table here i got this from a company called sterling engines dot code at uk it's also where i got my sterling engine which you'll recognize from my video explaining entropy link in the description for that as well studying engines.credit uk aren't sponsoring this video i just really like the things that they make but anyway in this video i'm going to explain how a tent segregated look table like this works by making a 2d version of it but first let's clarify what's the criteria for a tensegrity structure well the first thing is it needs to have components that are in compression and components that are in tension so these rods here are in compression they're being compressed they're made of aluminium they're really good at that and they've got these wires here that are in tension wires are really good in tension the other criteria for a tensegrity structure is there needs to be at least two separate parts that are in compression that are entirely separate from each other and only joined by parts that are in tension so here for example the bottom part and the top part are separate from each other they're not touching except for these wires that are in tension so this is an example of a tensegrity structure as well you've got these six uh wooden rods that are in compression they're only joined together by these elastic parts in tension so the wooden parts aren't touching each other uh at all and i'll tell you a bit more about this later on because there's some really interesting stuff about this particular structure but first just to go back to the table like it's really counter-intuitive isn't it it's all being held together by wires like how is that possible and that's what i want to explain in this video so here's the 2d version and i've built it with elastic bands instead of wires because i want you to see how they bend and stretch when you try to collapse the structure so why is this structure stable well any way that you try to collapse the structure it turns out that at least one of the elastic bands ends up being stretched and when you stretch an elastic band it pulls back so for example when i try and collapse the structure in this direction this elastic band stretches and it restores the structure back to its equilibrium position and we can look at individual elastic bands for example if we try to keep this elastic band and this elastic band the same length and try to collapse the structure what would happen well we need to sort of do this um something like that and of course in doing so we're stretching this elastic band similarly if we try to keep these two elastic bands the same length you know we're trying to collapse the structure this one is stretching or if we try to keep these two the same length we'd have we'd end up doing something like that wouldn't we or something like that and so the middle elastic band stretches so hopefully just by inspection you can see that no matter how you try and distort this tensegrity structure the stretching of the elastic bands will restore it back to its equilibrium position just to hammer the point home i've replaced two of the elastic bands with a string so we really can't stretch these ones now and look we don't have that much freedom of movement i can do that and i can do that and either direction that i go in the elastic band ends up stretching a 2d tensegrity structure actually isn't stable in three dimensions which is why i've got it leaning on this incline here that keeps the whole thing from falling apart so a 2d tensegrity table requires two outer cables to remain stable but for it to be stable in three dimensions you need to add a third cable like in this one here and that makes sense intuitively it's the same reason why a stool requires three legs to be stable it's that old saying two points fix a line three points fix a plane so it doesn't matter what direction you try and push the top of the table in it will stretch the wires in such a way as to restore the table back to equilibrium it does mean that actually there is a bit of motion laterally like that because there is some flexibility in the wires and it's a really strange sensation actually because you know you can move it laterally like that but it's really strong in the up and down position it's very strange you can even set up a bit of simple harmonic motion in the top isn't that cool actually with this design you can tune the stiffness of the wires so if i let out a bit of the stiffness in these you get a much wobblier table having said all that it is actually possible to create a stable three-dimensional tensegrity table with just two outer cables this one's made of lego and you can see because the center of mass is here the whole top section wants in inverted commas to tilt this way but it can't because of these cables in tension and it's only stable for as long as you don't push it in this direction it's not an official lego product but if you search for tensegrity lego you'll find one if you want to make one for yourself strictly speaking for a structure to be classed as tensegrity it needs to follow an extra criteria which is that all the parts that are in compression need to be only in compression and that's actually not true here so you've got that bend there so this part is experiencing a bending force so there'll be a part on the inside that's in compression part on the outside that's in tension which is okay because white is probably aluminium and aluminium is pretty good in tension but this structure is a tensegrity structure even under the strict criteria all the bits in compression are straight all the bits in tension are straight as well and so the bits in compression only feel compression the bits and tension only feel tension so by building the structure this way you can make it much stronger because the parts that are good at compression are only experiencing compression the bits that are good in tension are only experiencing tension you can also make it lighter as well you can use less material to get the same strength like this bass wood is good in compression but if i bend it like this it experiences tension at the top and it snaps which is why nasa are designing a planetary lander based on this exact configuration because it's incredibly robust you know you can bounce it around you can land it on a planet it might squish a little bit but if you put a payload in the middle maybe it will survive and by changing the length of the cables in tension you can actually move the structure around robotically because tensegrity structures optimize for strength and lightness and because evolution often optimizes for things like strength and lightness it wouldn't be unreasonable to expect to find tensegrity structures in nature and in fact if you look at the bones in your body that are under compression and the muscles tendons and ligaments in your body that are under tension you sometimes find them in tensegrity-like arrangements and of course architects and engineers have put tensegrity structures to good use for example the curlipa bridge in brisbane australia all right final thing on the subject if you take some blue tack and squeeze it in one direction it gets wider in the other direction which makes intuitive sense and most things behave that way but not all structures are like that some structures when you squeeze them in one direction will actually contract in the other direction that's called an oxetic structure and some tensegrity structures behave that way as well for example the nasa lander structure see if i pull these two rods apart perhaps you can see very slightly that the green and red rods come apart as well so there you go tensegrity structures i actually showcased the tensegrity structure without even realizing it in a previous video the first episode of five interesting things so check that out if you haven't already i've got a few more skillshare course recommendations for you they're sponsoring this video you've heard me talk about online video learning before because i've come to the conclusion that when you're learning something new it can be a real false economy to try and do it on your own to muddle through by yourself by searching online and things like that i've realized that if you can front load your learning experience like invest time in the beginning literally just an hour or so with an expert someone who really knows what they're talking about then it's just going to supercharge your learning once you're practicing on your own here are the recommendations creativity unleashed interesting one because it doesn't focus on a specific thing but if you want to put stuff out online of a creative nature there are some general lessons that you can learn really interesting course hand coding your first website you know i think it's really important if you want to build websites to get your hands dirty get inside the code and see how it all works even if you end up using a cms how to use notion to organize your life ah notion is so good if you haven't tried it you've got to try it but it's not super obvious straight out of the box all the ways you can use it so i really think a course is useful the first 1000 people to go to my special url school dot forward slash stevemold0121 will get a free trial of skillshare premium no strings attached and it's just ten dollars a month after that the link is also in the description so check out skillshare today i hope you enjoyed this video if you did don't forget to hit subscribe and i'll see you next time [Music] hey

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Channel: Steve Mould

Views: 3,900,586

Rating: 4.9407806 out of 5

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Length: 11min 6sec (666 seconds)

Published: Thu Jan 14 2021