Stuff You Should Know - Selects: Bridges: Nature Abhors Them
Episode Date: February 27, 2021From prehistoric logs across streams to the 102-mile Kunshan Grand Bridge, nature works ceaselessly to take down spans. In this classic episode, learn about the fascinating ins and outs of bridge desi...gn and building and the mind-boggling challenges structural engineers face. Learn more about your ad-choices at https://www.iheartpodcastnetwork.comSee omnystudio.com/listener for privacy information.
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Hello, SYSK fam. It's Josh. And for this week's Stuff You Should Know Selects,
I've chosen Bridges. Nature abhors them, which we released back in June of 2015.
And it's a pretty good one. It's got a lot of engineering, believe it or not.
But it's not like the eye-glazy kind. It's like the, oh my god, this is amazingly fascinating
kind. I hope you feel that way at least, and I'll bet you will. So enjoy Bridges. Nature abhors them.
Starting now.
Welcome to Stuff You Should Know, a production of iHeart radio.
Hey, and welcome to the podcast. I'm Josh Clark with Charles W. Chuck Bryant with Jerry Rowland,
with me, Josh Clark. And this is Stuff You Should Know, featuring Josh Clark.
It's about to say you never introduce yourself and then you done did it twice.
Three times. Oh yeah, you always introduce yourself. But you never say your last name.
I think that's what struck me. No, I say I'm Josh Clark. Do you? Yeah, every time.
I should listen to these sometime. Yeah. That explains the glazed over look in your eyes whenever
we start. Bridges. Yeah. Is that your intro? Yep. I like them. Maybe we can add like a
scat drummer on top of that. We have that kind of when we're doing listener mail. There's a
little bit of... Oh yeah. Well, that's not scat drumming. I would say that's more of a shuffle.
Scats like... Like that? Yeah, you should get Hodgeman to scat for you sometime. He's good.
Oh, I'll bet he's good at scatting, yeah. A lot of boop-boop-badoos going on when he's scatting.
Any jazz hands? No, it's not exactly Manhattan transfer level. Oh, he's intermediate? Yeah.
Yeah, so again, bridges. Yeah, you know, I bet we're going to hear from some folks because there
are bridge enthusiasts. Yeah. Which I think is kind of neat. Yeah, well, I mean, they're like
modern marvels of engineering. And actually, there's some ancient marvels of engineering too,
as far as bridges go. I'm just about to say that, dude. Yeah, basically, I was talking to
our pal, Adam, the architect. Oh, the bridge builder? No. Yeah. He's a building builder,
or a building designer. Yeah. I don't know if he actually knows how to build the buildings. He
just knows how to tell other people how to build. I bet Adam can't swing a hammer.
So he was saying that basically, the structural engineers who design bridges are just straight
up geniuses. Oh, I'm sure. Like it requires basically a genius to factor in all of this stuff.
Yeah, anyone can design a building. You know, those are four walls and a bunch of floors.
Right. Put a roof on it. Bridge, though. It's different. Yes, right. Aren't walls really?
They can be. Bridges of Madison County. They had walls. Oh, yeah, they had walls. I was going
to mention the bridges of Madison County. Yeah, I love those. That'd be a beam bridge, I guess.
Yeah. With a truss. Right. A top truss. What's the top truss called?
A thru truss. Yeah, thru truss. And then below that, if it were below, it'd be a deck truss.
But I don't know if that counts as a truss. It's more just like a house on top of the bridge.
I bet there's structural support there. I thought it was mainly just to keep the
rain off of you when you cross the bridge. Like just an extra little thank you for crossing the
bridge. I thought it was just to draw in lackey tourists who wanted to have their picture made.
Another famous bridge, the one that the headless horseman couldn't cross and the
legend of Sleepy Hollow. Oh, yeah. Wouldn't that a bridge? Sure. Trolls of under bridges?
Bats. Troll bridges are pretty cool. Have you ever seen Maximum Overdrive, the beginning of that
movie? It's been many, many years. I saw it again in the 80s. I saw it again very recently,
like this year. And it is, it's maybe better than it was before. It holds up as a crappy movie still.
Yes. Yeah. The whole soundtrack is ACDC, by the way, which you should love.
Whole soundtrack. I do love that. And I do remember that. And didn't Stephen King direct that?
Yep. Which he doesn't do much, right? No. That may be his only one. It was definitely his first.
Interesting. But there's a great draw bridge scene in there.
Did someone jump it, jump the span as it raised? No, I think their car fell in or their truck
fell in. Okay. Because usually the draw bridge scene is like, I can make it. No, this one was
you're all doomed kind of draw bridge scene. Gotcha. And let me also recommend Budapest
for bridges. You mean I went to Budapest a couple of years ago? Yeah, I went there like
20 years ago. Okay, so yeah, you know, the bridges are amazing. I think like five.
Yeah, because they connect the two sides. Yeah, Buda and Pest, right? And each one is totally
different. Like it's just a completely different design. Yeah. And they're just all gorgeous.
Yeah. Let's just start with a bunch of bridge recommendations. I'm going to recommend the
city of Pittsburgh. Oh, yeah. I went to a baseball game there and it's just gorgeous. Those
beautiful bridges that you can see from the baseball stadium and the river.
That was when we were shooting a Toyota commercial thing, right? Yeah. I stayed in
the hotel and just ate sogg, no chicken sogg. Just like a cord of it.
But you could see the baseball stadium out your hotel window. Yeah, and I saw some bridges too.
Yeah, you walk across the bridge to get there. Right. Or at least we did.
What else? Any other bridges? Well, Brooklyn Bridge. Sure, Golden Gate Bridge. Yeah. Those are
like the famous ones. They're barely even worth mentioning. Yeah, but the Brooklyn Bridge is
for your money, which is free. It's a pretty great thing to do to walk across it. It's
just beautiful. I've never done that. Yeah, you should do it. Even the Geico lizard did it and I
haven't. That guy's like Australian or something. Well, maybe we should just animate you and have
you walk across it. One more thing. If you want to know more about the Brooklyn Bridge,
I don't remember which one we talked about it in, but there is a really cool
documentary about the Brooklyn Bridge and its building by Ken Burns. Oh, wow. I believe it's
on Netflix. I'll have to check that out then. Yep, because I like Ken Burns and Brooklyn Bridges.
Yeah. All right. You ready? Yeah, man. So bridges have been around for a very long time.
This article is by Robert Layam and another dude named Michael Morrissey together. Yeah. I believe
they were locked away in a closet for like a couple of months while they worked this out together.
Well, one of the first ones talking about ancient bridges that they mentioned in here,
the Arcadico Bridge in ancient Greece. Did you see that thing? No. It's really neat. I mean,
it still stands. It's a 3,000-year-old bridge and it's just kind of cool to think about, you know,
ancient civilizations and ancient times. People said, well, I want to get over there.
Right. And I'm here. Yeah. And so let's build something to do that. I need something to walk on.
Yeah. Or drive my car over. It's that simple. I saw the world's oldest bridge that's still in use
is in Turkey over the Milos River, I believe. Yeah. From 850 BCE. Do you know what that one's,
how it's constructed? It is a single stone slab arch. No. It is a stone slab single arch.
Yeah. That makes sense. Yeah. Very basic. Yeah. But the arch, it's super old, but it's still in
use today because whoever figured it out came upon this very elegant solution to a lot of
problems that a bridge poses. Because as you were saying, when you come upon like a river or creek
or something, you say, I'm on this side and I need to be on the other side. So I need something to
walk across. Yeah. Okay. That's a basic solution. But the further and further you get, the more
and more problems, like as bridge billers say, most span, most problems. Yeah. I guess what we
should have said is I want to walk across and live. I want to walk all the way across. Right.
I don't want to fall down. No. I don't want to get halfway across and have it snap. Right.
So over the years as people have come upon problems where you are going to build a bridge
that will snap and kill you, they've come up with solutions to prevent that from happening.
That's pretty much the pursuit of bridge building. Yeah. It's coming up with ways to
prevent a bridge from collapsing. Yeah. And a lot of trial and error over the years.
Yeah. And a lot of real significant disasters. In fact, there's a time magazine slide show
called Worst Bridge Collapses in Past 100 Years. And it's got all these photos of collapse bridges
and little descriptions and the number of fatalities and everything. But it's really
interesting. All these different bridges have collapsed and failed for all these different
reasons. Well, and after each one, it's very sad, of course, but after each one, someone goes,
oh, well, we should do this for the next one. Right. We should not forget that bolt next time.
Well, that could be human error, true. That's happened. Yeah. I'm sure.
All right. So should we start off with the bats? Yeah. B-A-T-S. Beams, arches, trusses,
and suspensions are the main components, structural components of a bridge. It's very
simple. Boom. That's it. That's all you needed to construct your own bridge. And with these four
things, you can make almost any kind of bridge. We're going to cover mainly beam bridges, arch
bridges, truss bridges, suspension bridges, and then the super cool looking cable-stayed bridge.
It is super cool. Probably my favorite looking bridge in the world that I came across in
research. Researching this is a cable-stayed bridge, the one that's in the article. Oh,
yeah. They look like sales. It's gorgeous. The big triangle is rising up. It's lovely.
But they look a little more modern to me. They don't have that classic
architecture like the Brooklyn Bridge does, or like the Tower Bridge in London.
Yeah, I think that's why I like it. Yeah, you like the modern look. Yeah. You're a modern guy.
I'm super modern. All right. They point out in the article, which is very key, what you talked
about, the span of the bridge is the distance between the supports. And that's where it all
goes down, basically. Yes. That's got to be strong there. Those are something that every single bridge
has, is a span and at least one support, most likely two. Yeah. And there's different,
the reason that there are different types of bridges is because different bridge designs
that bats designs. What is it? Beams, arches, trusses, and suspension. They provide stability
for varying span lengths. Yeah. So like a beam, if you have like a 50-foot span, just put a
very long log over the span. And there you go. There's your bridge. But as you get further and
further along, you have more and more problems supporting that span. So you need different
types of solutions. And the different length of the span calls usually for a specific type of bridge
design. Yeah. And generally, there's a lot of overlap, of course, but beam bridges tend to
be the shortest, followed by arch bridges and then suspension bridges. Right. And I think those,
the cable-stayed bridge is kind of a suspension bridge, so that counts. It's like a kind of a
variation. Yeah. But those are, they can be very long as well. Yeah. Yeah. Not quite as long as
suspension bridges, though. From what I understand in this, the suspension bridge affords the longest
span. Okay. So you got a big long span, it's suspension time. Yeah. And they're also super
expensive. Yeah. Suspension bridges. Because all the bridge builders know that you got a long span
that you're trying to cross, you probably got some deep pockets and they're going to milk you for it.
Oh, yeah. Every penny. Yeah. Yeah. Like you need a suspension bridge? I'm your guy. Yeah.
All right. So let's talk about, there are a lot of different forces that can act on a bridge
to make it not as stable. We'll cover a few of the other ones later, but the main two
here early on are tension and compression. Yeah. And the very easy way to think about these two
things is tension is like if you, if you and I are pulling a rope, like you're on one end and I'm on
the other, we're going to pull that sucker tight and I'm going to fall over due to your massive
strength. I'm pretty huge. But there will be some tension in that rope. Yeah. And maybe between us.
After you fall down. Yeah. And I'd start laughing. There would be tension. Sure. But tension is the
lengthening of something. Yes. Compression is the shortening of something. Yeah. Like a spring
collapse. Right. So it's easy to visualize when you're talking like springs and ropes and that
kind of thing. But if you're talking about just a single deck of a bridge, which you think of as
one piece, it's tough to, it starts to get tough to visualize it until you realize that you have
to look at like a bridge deck, like the roadway on the bridge as really having a top and a bottom.
Yes. And forces, while the compression acts in the downward
motion on the top and the tension acts from the underneath coming up on the bottom. Right. So
the bottom of the bridge underneath it of the deck is going to be spread out
under the force of tension. We're on top where it's being pushed down compressed.
That's compression. Yeah. And they kind of in a weird way work together,
even though they're sort of opposite things. They're definitely related. Yeah. Right.
And what will happen is if these, if you aren't a very good bridge builder,
buckling will occur when it's compressed on the top and snapping can occur on the bottom
when tension is at work. That's right. All sounds very confusing. But if you just,
all you got to do is like put your hand out and look at it. Right.
You know. And so, or if you take and push down on your hand or on your hand.
Right. You know what I'm saying? Sure. Like that. Yeah. Like that.
The whole thing becomes very, very evident when you look at a beam bridge. Right. The most basic
form of a bridge. Like if you dropped a log over a river. Right. And this thing,
this article used the example of like taking a pair of milk crates and putting like a two by four
across them. Right. Let's do that. If you put like a bowling ball on a bowling ball stand so it
doesn't roll around. Yeah. That'd be awkward. On top of the, on top or right in the middle of your
two by four, which makes up your beam bridge deck. Right. You're going to see that it bows.
And what you're seeing is that on the top it's being compressed on the bottom. It's being tensed.
Right. Yeah. And what you've just done is add a load to that bridge. And there's two kinds of
loads to start out with. There's a dead load, which is the weight of the bridge and all of its
materials combined. Yeah. And then there's a live load, which is say like the cars and the people
and the trains and everything that, that add the extra weight while they're moving across it and
everything. Yeah. And as you add this extra load, first of all, the bridge is already dealing with
its dead load. Yeah. It's got to hold that up. That's job number one for a bridge. Yeah. Like
if you had a 300 foot two by four and two milk crates, it's going to sag in the middle just
naturally. Right. And it might even break. And there have been bridges that have been built that
where the guy forgot to carry the one or whatever and they couldn't stand up under their own weight
and they collapsed from their own weight. They collapsed from the dead load. So job number one
of a bridge is to support its own weight. Job number 1.1 is to support all of the live load,
the traffic that goes across it as well. That's right. And the two ways that you're going to do
this to counteract tension and compression are dissipation and transference force. Yeah. Or
transferring the force. So with dissipation, you spread out that force equally. You spread out
over a wide area and with transferring, you move the area of weakness to an area of strength.
Right. Which is pretty simple. Yeah. They're kind of tough to distinguish sometimes. Yeah. You
know what I mean? But for example, the best example of dissipation is the arch, which we'll
talk about how that works in a second. Yeah. But suspension bridges are best at transferring the
tension and compression forces. That's right. So if you're talking about a beam bridge,
that most basic kind, the other thing they're going to do to make it stronger, of course, is use
back in the old days to use wood, then later iron, and then steel. Right. Maybe some concrete mixed
in. Yeah. But the size of the beam is going to be really important. Like the height of the beam
is important because the top is going to experience stress. The bottom is going to
experience stress. In the middle, not as much. So a good eye beam. Right. A good tall eye beam
is what you want. Yeah. And I didn't realize that that's why eye beams are made like eye
beams until just now. It makes perfect sense. Because the center of like the deck or the beam
or whatever, any kind of beam is going to experience the least amount of compression or
tension. It's really the top or the bottom. Yeah. So you don't have to put quite as much
material into the center of the beam as you do the top and the bottom to prevent buckling and
snapping. That's right. So with the beam bridge, you're going to add what's called a truss
to make it stronger. We'll talk about trusses more, but it's basically a triangulated strength.
And you'll see a truss if you've ever seen like a train bridge, like you see a truss on top.
Or like in areas where they get a lot of snow, roof supports will frequently be trusses.
Yeah. And that's a three truss on top, we already said. And if it's underneath,
then it is the deck truss. Right. And you can have both, but usually like with the railroads,
you'll see like that top truss. Not the same as a trestle. That's different. Right. That's like
a like a roller coaster. You know, so after this break, why don't we talk more about truss bridges?
Nice.
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So Chuck, no joke, trusses are one of my favorite things now.
It's pretty neat.
After doing some research into them, I'm like, I love trusses.
You're a truss guy.
Yeah. And it's because they're so elegant and simple. They're elegantly simple, basically.
So I saw this really great explanation where it was on Make Magazine and I think it was called Ask Make, How Do Trusses Work? Pretty straightforward.
And it basically had a really great graphic of using popsicle sticks, right?
Okay.
Let's say you make a square out of popsicle sticks and you join the popsicle sticks together at the corners where the ends all meet.
Yeah, a little Elmer's Paste, maybe.
Makes sense.
Uh-huh.
Seems pretty supportive, right?
Yeah.
But when you press down on any one of those joints, which is where the load's going to be centered or distributed most.
Yeah.
Remember the ends?
The square shifts to the side and all of a sudden you have a rhombus.
Well, a rhombus is inherently less structurally sound than a square, which is why you very rarely see rhombuses in architecture.
Right.
With a triangle, when you press down at any one of the joints, it distributes that compression or tension directly through the center of the beam.
Yeah.
So the triangle stays totally rigid.
And when you add the more triangles you add, the more support you have.
So they're like basically like as far as the shape goes, the superconductor of transferring or distributing compression or tension.
Yeah.
That's a good way to put it.
And that's why when you see that train trestle and that has that truss on top, it's got all those beautiful diagonal pieces of metal.
Right.
And it's not just for looks, even though it is cool looking.
No.
One of the other great things about a truss is that they're, you know, it's like just three steel beams or three whatever aluminum beams.
They're just three pieces of metal, usually, fixed together.
And that's the other key that I left out.
They have to be connected at the ends, equally distributed from each end, right?
So let's say you drill a hole to rivet one side of the truss to another or one end of the truss to another end.
The other end has to be equally far away.
Right.
Do you see what I'm saying?
Yeah, yeah.
Okay.
They wouldn't just be like, oh, I'll just drill that other one wherever.
So anyway, you have to, the place where the truss sides joined together has to be on the ends.
And then, but one of the things that it allows for is for wind to blow through it easily.
Oh, sure.
That's a huge point about trusses.
Yeah.
They're not solid in that they don't, they don't put up a lot of resistance to when they allow it to flow through, which is really kind of what you want.
We'll see when you're building bridges.
Yeah.
I think even the covered bridges have, it's more of a lattice type thing on the sides, right?
Yes.
It's not solid, is it?
That'd be dumb.
The bridge?
Yeah.
Yeah, they're solid.
I thought the walls were usually like a lattice, so wind could pass through now.
And they had a, that had a roof and like a lattice-y side.
Is that right?
Yeah, maybe there's all kinds.
Yeah.
I think those are just to keep the rain off.
Oh yeah.
That's what you said earlier.
You keep shooting down the, the theory of the structure.
But anyway, trusses rock, I guess, is what I'm trying to say.
Yes.
There's your T-shirt.
Trusses rock.
So, are we at arches?
Did we say that they frequently use trusses to support beam bridges?
Yeah.
Okay.
Arches.
Now, when we say a bridge is an arch bridge, the deck is not some big hill that you drive
over.
The deck is flat.
The arch is underneath.
Right.
Yeah.
Yeah.
So, you can have a single arch if your span isn't along, or you can have a big one with
like six or eight arches.
Although, I've seen, I think there are like short arch bridges that actually do go up and
down.
Oh, sure.
You know, like a-
I mean, there's natural arch bridges, like rock formations or like that.
Yeah.
And that's why they're still standing.
There's, there's, there's a bridge that forms like a perfect circle.
So, like when, when you see it reflected in the water, it just looks like a circle.
Oh, neat.
Isn't that neat?
Yeah.
Arch bridges are pretty cool too.
They're no trusses, but they're beautiful in their own way.
Yeah, that's true.
So, the arch is obviously semi-circular.
And like you said, if it meets the water and reflects nicely.
Fully circular.
Fully circular.
And the entire form is going to divert weight onto what are called abutments.
And this is what takes on the pressure.
It's like, I mean, if it's just a single arch, those abutments are probably going to be part
of the earth on one side or the other.
Yeah.
And the whole point of an abutment is when you press down on an arch or when, you know,
gravity pushes down on it or it's compressed, that force goes downward and it makes the
sides of the arch go out.
Those abutments press inward so that the force of compression just goes straight down through
the arch circle, the semi-circle, and into the earth or into the ground or whatever.
Yeah.
And the arch, what I thought was interesting, it's really all about fighting that compression.
There isn't a lot of tension that comes into play with an arch bridge.
I think the tension grows more and more possible when the degree of the arch grows.
Oh, okay.
Yeah.
So that could come into play.
It can, but for the most part, when you're building an arch, you have to worry about
compression more than tension.
Gotcha.
Yeah.
So there's stylistically and artistically design-wise, there are all kinds of arches,
Baroque arches, Renaissance arches, Roman arches.
They were, the Romans built, you know, arch bridges that are still standing today.
Yeah.
Have you been to Rome?
Yeah.
Man, it's just like you're walking along and all of a sudden, you look to your left
and there's like a 2,000-year-old aqueduct, you know, 1,500-year-old arch just sitting
there.
Yeah.
I remember the first time I went to Europe coming back and being sort of like bummed out,
you know, because we were walking along and then there's the Burger King, you know.
Yeah.
This house is 200 years old and we're like, she could have Rome.
I know my house is like 80 years old and it seems super old.
Yeah.
Nothing.
Not by Roman standards.
No.
You know, a little drafty in those 1,000-year-old apartments.
Yeah.
But it's so neat though because I mean, like, there's so much old surviving stuff that not
all of it's even meant to be preserved.
Some of it's just like, just there.
It's not like a part of a park or an historic exhibit.
It's just part of the city, you know?
Yeah.
I've heard other tourists complaining about how dirty Rome is and I'm always just like,
come on.
They're focusing on the wrong part.
It's been around for a long time.
Yeah.
Oh yeah, that too.
Yeah.
And also, yeah, don't be stupid and just look around you.
Like they're complaining in front of a 2,000-year-old fountain.
I didn't notice it was particularly dirty.
I mean, it wasn't any more dirty than like New York or anything.
Yeah.
Any other big city?
I agree.
But the thing with the arch though, very stable once you get it built, but the building
process is tricky because until you connect those two ends, that's what gives it its strength.
So until that happens, it's a little dicey.
Yeah.
Oh yeah.
Got to have some scaffolding going on.
Yeah.
And they used to build wood scaffolds and supports to hold the thing and then you just
would build it in.
Yeah, that makes sense.
Now they use suspension cables.
Like I think the biggest arch bridge on the planet is West Virginia's New River Gorge
Bridge.
That thing is unbelievable.
It really is.
And what's cool is when you look at it, it uses the cliff walls or the walls of the gorge
as the abutments.
Beautiful stuff.
Super strong.
And that's where we're going to talk about that in our base jumping.
I know.
That's the fact that ties these two podcasts together.
Yeah.
That's where they have bridge day.
Talk about elegantly simple.
So suspension bridges for my money are where it's at.
I think they deserve their own episode.
Oh yeah?
I'm pretty much, they're that complex.
This is just the briefest overview of bridges in general, but especially with suspension
bridges it feels like there's just so much going on with those things.
Yeah, I agree.
I mean, Kim Burns did like an eight hour long documentary on the Brooklyn Bridge alone.
Yeah, that's true.
He's a deep diver.
He really is.
We're over of you guys.
With a giant helmet to go over his giant haircut.
He does have pretty big hair doesn't he?
All right, so suspension bridges, we mentioned of course Golden Gate Bridge and the Brooklyn
Bridge.
This is when you have your deck, your roadway is suspended by cables between, can be a number
of them, but two, at least two tall towers that are supporting all of this weight and
compression is pushing down, traveling up through those cables and transferring all
that compression through all those lovely cables.
Right, so I mean another way to look at it is exactly what it sounds like.
The bridge is suspended from cables, right?
Yeah.
But if you really start looking into what it's doing, it's not just holding these things
up.
What's going on is there's a transfer of that natural compression of the deck up through
the lines, up through the cables, up to the towers, which like you said, send them down
to the earth, right?
So the towers that hold the bridge up are at the same time distributing or dissipating
the forces of compression that are trying to pull the bridge down into the water below
it.
Yes.
And the tension you also have to deal with as well, and apparently you deal with that
using another part of the structure of suspension bridges, which are called anchorages.
Yeah.
Now that's just what the towers connected to at the base, right?
No.
So it's like...
Oh, the anchorages is like the abutment, essentially.
Yes.
Yeah, yeah.
On the left and right.
They're like a suspension bridges abutment, whereas as you get closer to the middle of
the bridges, that's where the towers are.
But on the very ends, like say where the roadway hits the bridge, you're going to have a massive
piece of rock or massive piece of concrete, and those are the anchorages.
And you have horizontal cables that distribute the compression from the bottom of the bridge
to the anchorages, and those transfer those into the earth.
Yeah.
And you might also, depending on the size of your suspension bridge, have to have that
below deck truss as well to help stiffen the deck.
And if you have a 4,000 foot bridge, you're going to have all kinds of trusses and decks
and cables.
And I think I finally figured out what it is about bridges that I love is that the structural
design that it needs to be strong also happens to be beautiful.
You know what I mean?
Like the way the cables are arranged, it's not like they're like, oh, this looks great.
It's like, well, it has to be like this.
But it also happens to be very striking.
Like Grace Jones.
You know what I mean?
Yeah, absolutely.
So suspension bridges are your favorite, huh?
I like them because they have so much going on.
I like trusses because they're so elegantly simple, and they're just tough as nails.
There's a bridge for everyone, I think.
There really is.
The cable stayed bridge, and we should say that suspension bridges, when you think of
a suspension bridge, you probably think of the Golden Gate Bridge or something like that,
right?
Yeah.
Just a classic suspension bridge.
Two towers, two anchorages, lots of suspension cables, it's a suspension bridge.
And you think, well, then they're probably pretty new.
Wrong.
Suspension bridges have been found in various forms for hundreds of years at least.
And apparently the Inca were masters at building rope suspension bridges out of woven grass.
Crazy, man.
Yeah.
1500s.
They discovered the Spanish conquistadors stumbled upon these and were like, what in
the world is going on here?
Right.
Because the smart Europeans didn't figure this out for another like a few hundred years
after that.
That's right.
The Inca still have one of these bridges intact.
It spans 90 feet, and they remake it every year as part of a three-day festival.
Oh, really?
Nice.
Yeah, which is why it's still intact.
Because a woven grass rope bridge doesn't last all that long necessarily.
Even though when it's fresh and new, it's strong.
Yeah.
As an expiration date.
Right.
You're saying.
But apparently as we'll learn, all bridges have an expiration date.
Ooh.
All right.
Well, we'll take a break then with that tease and talk about the cable stayed bridge and
then how you might die on a bridge one day.
Hey, I'm Lance Bass, host of the new iHeart podcast, Frosted Tips with Lance Bass.
The hardest thing can be knowing who to turn to when questions arise or times get tough
or you're at the end of the road.
Okay.
I see what you're doing.
Do you ever think to yourself, what advice would Lance Bass and my favorite boy bands
give me in this situation?
If you do, you've come to the right place because I'm here to help this.
I promise you.
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Seriously.
I swear.
And you won't have to send an SOS because I'll be there for you.
Oh, man.
And so my husband, Michael.
Um, hey, that's me.
Yep.
We know that Michael and a different hot sexy teen crush boy band are each week to guide
you through life step by step, not another one, kids, relationships, life in general
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And so tell everybody, everybody about my new podcast and make sure to listen so we'll
never, ever have to say bye, bye, bye.
Listen to Frosted Tips with Lance Bass on the iHeart Radio app, Apple podcast or wherever
you listen to podcasts.
I'm Mangesh Atikular and to be honest, I don't believe in astrology, but from the moment
I was born, it's been a part of my life in India.
It's like smoking.
You might not smoke, but you're going to get secondhand astrology.
And lately I've been wondering if the universe has been trying to tell me to stop running
and pay attention because maybe there is magic in the stars if you're willing to look for
it.
So I rounded up some friends and we dove in and let me tell you, it got weird fast.
Tantric curses, major league baseball teams, canceled marriages, K-pop.
But just when I thought I had a handle on this sweet and curious show about astrology,
my whole world came crashing down.
Situation doesn't look good.
There is risk to father.
And my whole view on astrology, it changed.
Whether you're a skeptic or a believer, I think your ideas are going to change too.
The Skyline Drive and the I Heart Radio App, Apple Podcast, or wherever you get your podcasts.
All right, so we're on to your favorite, my friend, the super sleek, modern looking cable
stayed bridge, which is actually, actually, actually has been around since World War II.
Yeah, but the idea, which is still modern.
The idea came from a dude named Faust Vanchick.
Yeah, man.
And he was a contemporary of Kepler and Brahe, and he basically came up with the first design
for a cable stayed bridge back in the 16th century.
So what's the nuts and bolts of this thing?
So basically, it is a rather than two towers, like a suspension bridge uses, a cable stayed
bridge uses one tower.
Well, not always.
There's plenty of them that have more than one, but okay.
But for a particular span of bridge, there's one tower supporting that one span, right?
So it's basically, you can't use it for as long of a span as a suspension bridge.
Right.
But if you have a slightly shorter span and you don't want to spend quite as much money
and you don't want as many wires up there and everything, you can go with the cable
stayed bridge, so you have one, usually one tower holding up all the cables and the cables
can either all connect to one point, which is called a radial pattern, right?
So it's like all these different cables are connecting on the bridge deck at different
points, but they're all connecting at about a single point on the tower.
Again, architecturally lovely.
Very neat looking.
And then another way that you can do it is in a parallel pattern.
So they're connected at different points on the deck and they connect at different points
on the tower.
And that's the case with the Erasmus Bridge, which I think is the most beautiful bridge
in the world, in Holland.
Oh, wow.
Wow, that didn't surprise me.
I mean, look at that thing.
Look at that.
Pow.
Oh, yeah.
That's something else.
Yeah.
I wish you guys could see this.
It doesn't look like a very Dutch, though.
No, it looks very...
It's like the New Holland, I guess.
Yeah.
New Amsterdam.
I'm just picturing Holland, I think of wooden windmills.
Oh, and tulips and stuff like that.
Yeah.
Sure.
Yeah, this is modern Holland for sure.
It looks like something that would be in Sydney.
Australia.
Yeah.
Well, they have great bridge, too.
They do.
Maybe that's what I'm thinking.
Living...
Are you done with those?
Yeah, I was going to say another design for cable-stayed bridge looks a lot like a sailboat.
With the tower standing straight up, and then on each side, cable's going down at a diagonal
from it to make it look like a sailboat sail and mast.
And again, for structural integrity more than anything.
Living bridges?
Sure.
Well, I guess we should say cable-stayed bridges are...
They can't be as long as suspension bridges, but they can be pretty long.
Yeah.
Like up to close to 3,000 feet.
But that's what I'm saying.
If you have a shorter span and you don't want to use as many materials and hence you spend
as much money, cable-stayed bridge is a great alternative.
Yeah.
I wonder when cities...
I wonder what the considerations are.
Money...
I would guess money first and foremost.
Money what you'd probably is best for the land, but I also bet that architecture comes
into play like how it looks in the cityscape, don't you think?
Yeah.
Like usually a city will have some sort of...
Will accept several designs, competing designs, and then probably, well, like in Atlanta's
case with the 17th Street Bridge, goes with the cheapest one, and then half of it falls
down onto traffic later, like a couple years later.
Did that happen?
Yeah.
When?
Like two years ago.
Really?
Yeah, man.
It was a big deal.
Like four in the morning or five in the morning, but like when you're walking on the bridge,
you know the side stuff?
One whole side fell over onto 75 below, onto the connector right below.
Yeah, I kind of remember that.
But it's an ugly bridge to begin with, really, and dude, if you're listening, the guy who
designed it, I'm sorry, I don't mean to insult your work, but I...
Do better.
The city could have done better, I think.
I think what it came down to, I'm sure, was...
All of these are beautiful, but we're just going to spend the money on this one.
Right.
Or whoever got the biggest kickback, or wherever that came from, not to be cynical.
Living bridges?
Yeah, we were talking about that.
If you go to Northern India to the, here we go, the Meghalaya region.
I think that was good.
All right, close enough.
They have something pretty remarkable, and they're called living bridges, and what they
did was, it's so rainy there that all of their natural bridges were having a hard time staying
intact because of all the moisture.
Yeah, from monsoon season.
Yeah, and that's, you know, you can't have a natural bridge with that much water.
So they said, why don't we take these tree roots and grow them out of the ground and
span a river over the course of years, and years, and years, and then basically plant
it on the other side into the ground, and this is now a natural tree root bridge.
Right, it's like giant living bonsai, like they were training roots to go a certain way,
and they would take a tree, a felled tree, and split it in half, and use that as the
guide.
Yeah.
Right, it's like the structure, so they were building an arch, but they weren't making
an arch.
Like sort of a temporary bridge.
Exactly, and they let the roots grow along that, and like they would plan these things
out, or they do plan these things out over the course of like a decade, and I get the
impression it's the whole town's responsibility, at least some people in the town's responsibility
to make sure that if you see your roots starting to go down in the wrong place, you just pluck
it up and put it back on that felled log that's guiding it across the way.
Yeah, it's pretty neat, like it requires patience obviously, but it also, I imagine
just once a day, someone walks down and's like, yep, looking good, and then just walks
away again.
Pets the bridge says, keep growing, I'll walk across you in 10 years buddy, and apparently
those things can last up to 50 years, or the largest one that they have up to 100 feet,
which is 30 meters for our friends in India.
Crazy.
And it can bear the weight of 50 people.
And last up to 500 years, not 50.
That's what I said.
Oh, I thought you said 50.
I said 50 people.
Well, it's crazy, like you got to Google these things.
Yeah, they're very pretty.
Very pretty.
It looks very dark crystal-y.
Oh, yeah, totally.
You know what I mean?
But they're not unsettling at all, like the dark crystal, which by the way, if you're
ever in Atlanta, sometimes people say, hey, I'm coming to Atlanta, what should I do?
Go to the Center for Papertary Arts and just look at their free exhibit, which includes
a full-size skexie.
It's terrifying.
Yeah, they have all, we've talked about this before, they have Emmett Otter on display
as well.
Oh yeah, that's right, yeah.
For me, that was pretty magnificent.
Oh, it meant a lot for Emmett Otter to meet you too.
They're doing actually, I saw it was just at the Museum of the Moving Image in Queens.
Oh yeah, I saw you post something about that.
Yeah, they have a Mad Men exhibit right now, which is pretty neat, but they, I was not there
in time for the Jim Henson one, they're putting that in place, I think for later.
Oh, it's coming?
It's coming.
Well, it's good, you didn't miss it yet.
Well, yeah, I'll just go back.
We went to the Yoko Ono exhibit at MoMA, awesome.
She's something else.
Dude, she's got a pretty cool mind.
She had this one display and it was titled Three Spoons and it was just four spoons in
a row.
It wasn't three?
No.
I love that stuff.
So I recommend that as well.
I'm not a fan of her music though.
I actually got turned on to her music in the listening room there, classic Ono band.
It's crazy man.
It is weird stuff, but I kind of like it.
I mean, she's definitely one of the most like original thinkers out there.
And she's been at it for a while, like a lot of the stuff went back to the 60s, like the
early 60s.
Yeah, and talk about weathering criticism and still just being like, screw you, I'm
Yoko Ono.
I don't care what you say.
Well, she was exonerated too recently.
Remember Paul McCartney came out and said like, it was not Yoko Ono that broke up the
Beatles and stopped saying that.
It just took them like 50 years to come out and say it.
She's like, would it kill you?
You've told me privately many times, but we'll press release.
Just tweet it.
All right.
So we talked about compression and tension being the two main forces.
There are quite a few other forces, dozens even, that can act on a bridge in a negative
way.
And the scariest one for my money is torsion.
If you've ever seen the video, it's a very famous video of the bridge.
What is it?
The Tacoma?
The Tacoma Narrows Bridge.
Tacoma Narrows Bridge when it looks like a wet noodle twisting in the wind.
Yeah, it was 1940.
It's nuts.
The footage of this whole thing just undergoing this destruction that kept just going on and
on and on.
And finally the bridge just comes down.
Yeah.
The craziest part is when you're watching it, you just think, oh man, look at that thing.
It's nuts.
Thank God there's no one on it.
And then you see like a dude walking on it in a car.
Yeah.
A guy ran.
There was a dog.
There was one car in there and there was a dog trapped in the car.
Some guy ran and got the dog.
Oh, he did?
Yes.
Pretty great heroic stuff.
Then later on.
I don't know if it was the same guy and another guy or just two completely new guys.
They're just walking along it.
This is after a whole section has fallen into the river, but the section they're walking
on is still swaying.
It's like, get away from the bridge.
Step back from the bridge, man.
So that's torsion at work.
Yeah.
And that's a big problem that designers of suspension bridges face because you have a
deck that's being held from, it's being held off by cables, right?
It's not like fixed to anything below it necessarily.
Yeah.
It's being suspended.
So just like on like a rope bridge or something like that, it sways very easily, right?
Yeah.
Those towers are strong, but it's not directly connected to those towers.
So if you have a swaying bridge in between them and the thing is swaying back and forth,
but if one side starts to sway over the other side, then all of a sudden you have an opposing
circular force and that's torsion.
And that can basically rip the bridge in two, which is shear.
Yeah.
Well, that's the other awful thing that can happen.
It can just snap, well, not snap, I guess, but just break into two parts.
Yeah.
Well, I mean, snapping is the result of compression.
Yeah.
So shearing would be what it's called technically.
Yeah, exactly.
So the same span of bridge has the two opposing forces acting on it at once in opposite directions
and it goes, it makes that terrible sound.
If you want to combat torsion, many ways to do this, you're probably going to have a
deck truss going on to help out.
Truss saves the day.
Deck truss saves the day.
So you're going to have, you're going to do wind tunnel tests if it's a modern bridge
beforehand.
Well, you're going to make a model.
Yeah.
And do tests and see how does wind affect this bridge and what do we need to do?
But the thing is, with the Tacoma Narrows Bridge in particular, they did tests.
They had that thing rated with standing winds up to 120 miles an hour, but the winds that
day that brought it down were only 40 miles an hour.
And for a long time they were like, what happened?
And somebody said, you know what it was?
It was mechanical resonance.
It was, yeah, the deck truss was not sufficient for the span.
That was part of it.
And the way that the wind hit it and the angle caused the final thing, like you just mentioned,
resonance, which is sort of, it's a vibration basically that gets out of hand.
So resonance to me, I think, deserves its own podcast too.
It's awesome.
Everything, especially anything that we build from an airplane to a bridge to a watch, it
has a certain frequency where it will really pick up force, really absorb force.
It'll run through it, right?
So let's say that your bridge has a resonance that's like at a frequency of 10.
That's probably a totally ridiculous number that I just said, but let's say it's 10, right?
And then let's say that wind comes at it at 40 miles an hour at just the right angle
and it makes it sway at a frequency of nine.
Well that bridge is going to be, it's just going to sit there and sway.
Not a big problem.
If that wind hits it at just the right angle at just the right speed and it starts swaying
at 11, it's still not quite a problem.
But if it gets it just right and it starts it swaying at 10, all of a sudden those sways
are going to become more and more pronounced because all that energy is flowing through
at its maximum potential, at its freest flow because it's hitting the bridge at its natural
resonance, right?
Yeah.
And that's what caused the Tacoma Narrows Bridge to come down because once that thing
starts going, there's no coming back from it.
Oh yeah, well you can see it happening, it gets worse and worse.
Exactly, and that's because it hit it at just the right frequency.
Yeah, they liken it in the article, which I think is pretty down to earth of a snowball
rolling downhill.
Exactly, it just keeps getting worse and worse and you can't stop it.
But isn't that bizarre that a bridge has a natural resonance, a natural frequency?
I don't think so.
I would assume it would vibrate.
Yeah, it did not occur to me at all and I was talking to Adam about this too.
And I was like, so I saw that building designers, bridge designers, they will fine tune like
a structure so that it resonates at a frequency that it's probably never going to encounter
from an earthquake or from winds or whatever.
I'm like, how do you do that?
And apparently it comes down to the building materials you use, the shapes you use to form
the structure, the way you join those shapes together.
And you can basically say, I'm giving this building a frequency of 1.5, whereas I know
all of the wind in the area and the ground movement from an earthquake is going to make
it vibrate at a frequency of 7.
So it'll be fine.
Yeah, and one way, like you said, they can do that is by not having like one, like shortening
the sections of the deck, let's say, and that way the vibration when you have these overlapping
plates and smaller sections, it's going to create enough friction to disrupt that frequency.
Right, it'll change the frequency that the bridge is moving at.
But I mean, and not just bridges too, you have to take into account like airplanes, right?
You can't use engines on airplanes that create vibrations at a frequency that's at the natural
resonance of the airplane body, or else the airplane body is going to come apart just
from turning the engines on.
Yeah, could you imagine seeing the airplane wing starting to flap like harder and harder?
Right, but apparently the more common thing when you have a disaster or a catastrophe
from a mechanical resonance problem, it's like one bolt is like, I can't take it anymore
and stops, and then that leads to a cascade of failures that ultimately has the bridge
coming down.
Yeah.
Interesting.
I think that's fascinating.
I had no idea that you had to worry about frequencies and vibrations.
I mean, I get like-
Maybe that's why all the bridges you've built have collapsed.
They collapsed pretty easy.
Well, if you've ever heard the old-
They go down like a French boxer.
I don't know what that means.
I don't need it.
But it was a Glass Joe reference.
Remember him?
Mike Tyson's punch out?
Oh, no.
What's that one of the guys?
The first guy on your counter.
He says-
He was French, Glass Joe.
Oh, gotcha.
He said the Glass Joll, and he went down just like a sack of potatoes.
So easy.
Man.
Well, which was it?
A sack of potatoes or a French boxer?
He was both.
He went down like a sack of French potatoes.
Yes.
A French fries.
Right.
My bridges go down like a French boxer, but Glass Joe, the French boxer, went down like
a sack of potatoes.
Gotcha.
Ergo, my bridges go down like a sack of potatoes.
If you've ever heard the old wives tale that like an army marching across a bridge in
step can cause enough vibration to take down that bridge, it's true.
That could happen.
Yep.
So in wartime-
If they do it at the right frequency, right?
Yeah, in wartime, they will break step, in other words, their rhythm isn't all the same
to avoid that scenario.
There was a bridge disaster I saw on that Time Magazine slideshow where that happened.
There were a pair of skywalk bridges inside the Hyatt Regency, Kansas City, hotel in
the lobby.
They were just like raised bridges going through the lobby, and they collapsed in 1981 and killed
like a bunch of people, like 30-something people.
People marching?
Dancing.
Oh.
They were dancing on the skywalk.
And you think like up to today or yesterday when I started researching this, right?
Like I just thought that's weight or pressure or something, like if everybody's dancing,
it never occurred to me that the rhythm had something to do with it.
Oh, really?
Yeah, I'd always heard that.
Well, you're far more advanced than I am in structural engineering, my friend.
Beyond that, it's just always heard that even a bunch of kittens walking across could cause
that, and the reason they said kittens, of course, is so it has nothing to do with weight.
Right, because kittens don't weigh nothing.
And consequently, I think Lionel Richie had to change the name of that song because of
the accident.
I think originally it was...
Hello?
Oh, what a feeling when you're dancing on the skywalk, and he had to change it to ceiling
and everyone was like, that's weird, you can't dance on a ceiling, but it rhymes.
It's like, yeah, but nobody ever died from dancing on the ceiling.
I guess the final thing we should mention is that weather, obviously, will play a big
impact.
We already talked about wind, but over the years, the materials they use and the design
has gone in to take account things like wind and what, sun damage?
I don't know what else.
I think the freeze thaw cycle is huge.
Yeah, I guess, sure.
It's salt exposure, if it's going over like a salty body of water.
Yeah, that makes sense.
Yeah, there's a lot of things that are trying to bring a bridge down.
Nature abhors a bridge, basically, as much as a vacuum.
I've got one.
Which got?
There's probably around 630,000 bridges in the U.S. alone, because there were 617,935
in the 2002 census, and they were adding them at about 1,000 a year, maybe 900 a year.
That's just the U.S.
The world's longest bridge, completed in 2010, the Dan Yang Kun Shan Bridge.
I think I've seen pictures of that.
It serves as a railway bridge for the Beijing and Shanghai Railway.
It's 102-mile-long bridge.
That's nutty.
Over water.
I'm a big fan of cities with multiple water bridges.
Sure.
Well, that's why you liked Pittsburgh.
Pittsburgh, Portland, Budapest.
Yeah.
I'm a big fan.
Atlanta doesn't, you know, we have bridges, but it's not like, you have to go to the Chattahoochee
River or the lakes.
Nobody goes to the Chattahoochee, you know?
What?
Sure.
I got one more thing.
I want to shout out to PBS's Build It Big website, which is like beyond 90s, as far
as websites go, but it was extremely helpful in understanding the forces that work on bridges,
different types of bridges, different specific bridges, great website.
And thanks to Adam, I guess.
You got some information from him.
Yeah, thanks, Adam.
Was he into talking to you about it, or was he on the other end going, oh my God, Josh,
shut up.
I'm watching Tim and Eric.
He was into talking about it.
I figured he would be.
Yeah.
And I actually have to shout out to Yumi, too, because I told her we were building bridge
or, well, we were talking about bridges.
She sent me a bunch of stuff on popsicle bridges.
Apparently, there's an Indiegogo for the world's strongest or Canada's strongest popsicle
bridge.
Wow.
Yeah.
They're trying to build that?
Yes.
And they have like six grand already for out of popsicle sticks.
Good for them.
So that's everybody getting shouted out to all over the place in this one, huh?
Yeah.
That's nice stuff.
Bam.
If you want to know more about bridges, you can type that word into the search bar at
HowStuffWorks.com, and since I said search bar, it's time for listener mail.
I'm going to call this.
I got a couple of street gang responses we'll read over the next couple of shows.
Here's one.
I had to write in about your street gangs episode as it was interesting and pertains
to my job.
Short version is that I work for a hospital-based program, and we see every gunshot wound victim
in stab wound victim who comes through, which is about four to five hundred a year, and
about 10% of those are gang involved.
You guys have mentioned how you found the number of gangs to be hard to believe, but
I think you may be thinking of street gangs as one entity that has strict borders and
lots of people.
In my experience, larger gangs will sometimes incorporate smaller gangs, and sometimes larger
gangs will split off into many, many smaller groups.
People go in and out of gangs and are sometimes affiliated with more than one.
We have about at least 70 in our city alone, and a substantial amount of those have less
than 20 members.
They're like mini gangs.
Gotcha.
Not super gangs.
Not super gangs.
According to this paper on street gangs in Boston, 18% of the gangs in the city have
less than 10 members, and 34% have 10 to 19 members.
While the numbers you gave seem shockingly high, they also seem to be in step with the
current climate, and that is from Ariana.
What city did she say?
You know?
I don't see that.
I don't think she said.
I don't know if it was Boston, or if she just referenced Boston.
Well, thanks a lot, Ariana.
We appreciate that email, and yeah, keep them coming.
We want to know more about gangs.
I just had the impression the whole time that one way or another, we were officially or unofficially
misinformed.
Maybe.
Also, let us know who's the coolest, famous person you've ever met.
You can tweet to us at syskpodcast.
You can join us on facebook.com slash stuff you should know.
You can put it in an email to stuffpodcast.howstuffworks.com, and as always, join us at our home on the
web, stuffyoushouldknow.com.
Stuff You Should Know is a production of iHeart Radio.
For more podcasts from iHeart Radio, visit the iHeart Radio app.
Apple podcasts are wherever you listen to your favorite shows.
Hey, I'm Lance Bass, host of the new iHeart podcast, Frosted Tips with Lance Bass.
Do you ever think to yourself, what advice would Lance Bass and my favorite boy bands
give me in this situation?
If you do, you've come to the right place because I'm here to help.
And a different hot, sexy teen crush boy bander each week to guide you through life.
Tell everybody, everybody about my new podcast and make sure to listen so we'll never ever
have to say bye-bye-bye.
Listen to Frosted Tips with Lance Bass on the iHeart Radio app, Apple podcast, or wherever
you listen to podcasts.
I'm Munga Chauticular, and it turns out astrology is way more widespread than any of us want
to believe.
You can find it in Major League Baseball, international banks, K-pop groups, even the
White House.
But just when I thought I had a handle on this subject, something completely unbelievable
happened to me and my whole view on astrology changed.
Whether you're a skeptic or a believer, give me a few minutes because I think your ideas
are about to change too.
Listen to Skyline Drive on the iHeart Radio app, Apple podcast, or wherever you get your
podcasts.