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  • Hey it's me Destin, welcome back to Smarter Every Day

  • I love rockets

  • If you've been around this channel, you know that about me

  • and today is like the best day ever

  • because we're going to learn how to build rockets.

  • Just down the road from Huntsville, Alabama

  • there's a city named Decatur.

  • And in that city, there is a rocket factory owned by

  • a company called United Launch Alliance,

  • and that factory has been cranking out incredibly reliable

  • rockets for years.

  • Because these orbital rockets have some of the

  • same technologies in them as ballistic missiles,

  • the knowledge about how to build them is protected.

  • In the United States we have a set of regulations called ITAR

  • International Traffic in Arms Regulations

  • Because of ITAR, nobody's going to let you walk

  • into a rocket plant with a camera and film things.

  • They can't risk that stuff getting out and breaking the law.

  • So there has to be an incredible amount of trust

  • between the parties that want to film things, and the people that own the plant.

  • Thankfully, I was given the opportunity to build that trust

  • with ULA, when I went and watched the launch of

  • the Parker Solar Probe, and I met the CEO of ULA on the launchpad.

  • If you haven't heard of this guy, Tory Bruno,

  • then you're in for a treat.

  • He's a legitimate rocket scientist who know his stuff inside and out.

  • It was at this launch that Tory and I built trust with each other.

  • Like, this guy is the real deal.

  • The tour we're about to go on has never been done on the internet,

  • Tory literally takes us right up to the line of what he can show us,

  • and all along the way he's answering my technical questions,

  • and he's letting me explore the factory.

  • So here we go, let's take the first ever online tour of

  • the United Launch Alliance rocket factory in

  • Decatur, Alabama, with the CEO of ULA.

  • Tory Bruno.

  • Okay, we've got Tory, mic'd up now, -Hi!

  • and you're gonna show me the rockets that are - Yes, yeah

  • fabricated at this facility? What do we have?

  • Okay, so we've got an Atlas V on the side,

  • this is kind of our workhorse, and it's in the

  • five meter payload fairing configuration.

  • So that's what we're talking about here,

  • it also has its SRB's on the side, which is sort of its

  • maximum lift version.

  • When it's got all five of those, we call it the beast.

  • - And this is the Delta IV Heavy, and this is what

  • you--thank you again, for letting me -Yeah, of course

  • participate, or at least see the Parker Solar Probe

  • Yeah, that was fun huh

  • -And that's fabricated here in Decatur?

  • Yes, yeah so three core rocket, you know literally

  • literally three rockets kind of bolted together,

  • and it is our largest rocket; it's physically the largest rocket

  • in the world right now,

  • and it is what we used for Parker Solar Probe.

  • -And this is what I want to talk about, -Yeaaaaah

  • this is Vulcan, and this rocket has never flown.

  • Never flown, not yet.

  • And you're going to see, the first flight vehicle hardware

  • in the factory being fabricated when we go in there today.

  • -Today -Yeah

  • Okay! -So this is our brand new rocket,

  • you can think of it as kind of a derivative of those

  • two in a way, so it'll be large

  • 5.4 meter diameter, so a little bit bigger than Delta,

  • it can take six SRB's, it's a huge cavernous payload volume for

  • the spacecraft, and this rocket has 30% more lift capability

  • than this big three-core monster.

  • -So when you say six SRB's...

  • Six of them, yeah. -And that's just to get out of the Earth's gravity well

  • Yes, right, exactly.

  • -Can we go see the stuff?

  • Yeah, let's go see it.

  • Okay, we're at a rocket factory, let's do it.

  • -We're gonna peel off to the right here Okay

  • Okay I'm seeing the grid here

  • Yeah, so this is a barrel section from the booster over your head,

  • actually from an Atlas.

  • And I'm going to walk you down to the end of the factory where

  • this first gets made; it's the first thing we do

  • Raw stock comes in the back door,

  • gets machined, puts this curve in it,

  • and then we'll walk you all the way through to a completed version.

  • -That's awesome

  • Okay, so there's something unique about the north Alabama area here,

  • correct me if I'm wrong, but there's a little triangle:

  • there's a nuclear power station,

  • there's a steel mill,

  • -Yes

  • and there's also a rocket factory like in a triangle.

  • -That's true And then you got a river running between them

  • -Yup

  • and so you can bring in steel, you can make a rocket

  • using the power from the nuclear plant, -Yes

  • is that why you're here?

  • That's part of why we're here, but it's

  • also because of the talent that we have here with

  • University of Alabama and the other Alabama universities

  • and the technician programs they have here;

  • you just get an awesome workforce.

  • And with the river, which is only a mile from here

  • down Red Hat Road, we have the dock for our rocket

  • ship, so we can transport our rockets out to the launchpad.

  • This is the rocketship Tory's talking about;

  • ya see? Says so right on the side: "Rocketship.

  • Rocketship navigates its way through several rivers

  • up to the Mississippi River, down to the Gulf of Mexico,

  • and then it heads to whatever pad the rockets will launch from.

  • You should come back sometime and do the ship.

  • Yeah, I should ride on the ship. Is that a thing? -Yeah

  • Can you do that? -Yes that is a thing

  • Okay we're getting on a golf cart, and

  • we have to cut cameras because we're going to pass

  • uh, not "secret stuff", but things we can't film.

  • Right? -Right

  • Okay, cutting the camera off

  • Ok we're on the golf cart, and I've obtained permission

  • to film straight up so you can't see "that"

  • which is pretty neat.

  • Ok so,

  • I can't talk about that right now, can I

  • No, we can't show it to you, but I can tell you what it is

  • That's a Delta payload fairing

  • so one of the smaller versions of the Delta's payload fairing

  • and then you're passing by a heat shield here that would

  • protect the RS-68 engine,

  • from its own plume during flight.

  • Ok... this is almost emotional.

  • I mean, you know what it's like to sit in class and study

  • this stuff, -Oh yeah, sure

  • and then...

  • cause you went to Cal Poly right?

  • Right.

  • Yeah, so this is me looking at all the stuff I've learned about

  • and finally getting to see it.

  • It's on thing to see it on the pad, but uh

  • it's almost like a holy experience.

  • Yeah well, you're inside where it's actually happening,

  • where it all gets put together.

  • Okay I'm starting to get the smell of the machine shop,

  • the manufacturing, the cooling oil, -Yep

  • smell. -You got it

  • It's my understanding you're about to show me how to

  • build a rocket from scratch.

  • Yes I am.

  • Okay, excellent, so we're going to the door, right?

  • Yes we are

  • Okay this is what I wanted to see, here at ULA:

  • This is the door.

  • I can't even get--it's a wide angle lens--so that's the door

  • where the material comes in, right? -Right

  • That's where the raw aluminum plate and other materials come in,

  • and then this is the receiving area,

  • and as they move that way turn into a rocket.

  • So we're about to build a rocket by going

  • that way in the plant.

  • Exactly.

  • -Okay, I'm game let's do this.

  • Alright let's do it.

  • And this is an active manufacturing facility,

  • so you're just going to have to deal with the audio,

  • there's a lot of tools running.

  • Yeah, sorry about that, but, ya know, building rockets.

  • It's good

  • Oh wow, that is...

  • that is really--can I go touch that?

  • Yeah yeah, absolutely.

  • This is a very, very expensive, piece--is that aluminum or stainless?

  • -That's aluminum Aluminum

  • Yeah

  • -And is that fabricated here locally?

  • -That's imported? No, yeah we buy that from a supplier

  • and then it's shipped here, comes in through the big door,

  • if you will--and then we machine it down,

  • we're going to remove, more than two thirds of the material

  • while retaining about ninety percent of the strength

  • -in certain dimensions, right?

  • And I will show you that, yeah

  • -Okay, got it

  • So this is our raw material, and uh, we're going to go

  • make a rocket.

  • Okay.

  • And so, all this is aluminum? That is a-- -All this is aluminum

  • That's a unique dimension, you normally don't see

  • plates of aluminum that wide and that long.

  • No, so this is actually made especially for us in these dimensions,

  • so that we can turn them into the barrel; the propellant

  • tanks of the rocket itself.

  • -Okay, so, so you're tooling up an entire foundry of some type

  • or a mill, a rolling mill. -A rolling mill.

  • Okay, gotcha

  • So I'm going to show you a couple of different things

  • before we get to the machine,

  • so starting here with the raw stock of 7000-series aluminum

  • it'll eventually become a round rocket barrel,

  • this is just after machining, and I wanted to point this out to you,

  • because, this is our old style of grid that we machine in

  • called an isogrid, and you're familiar with what an isogrid is--

  • -Isogrid, yes

  • Right? So we have isentropic properties when we do the stress analysis,

  • and you can see the triangular patterns in there.

  • That's not actually the ideal pattern for a rocket barrel,

  • but it is what the analytical tools--the finite element analysis tools available to us

  • when we designed the Atlas and Delta in the nineties,

  • were available to us, and that's why we have that pattern.

  • Vulcan will be better, because the tools are better and you'll see the difference

  • when we walk down the line.

  • -I have never thought about that

  • So literally because in the nineties the FEA analysis could

  • solve a triangle easily, -Yes

  • that's why the isogrid is a triangle.

  • -Exactly I would've never thought that

  • so, so basically if I understand correctly,

  • you--can I touch this?

  • Yeah, touch if you want.

  • I'm going to ask you that every time -Yeah, that's alright

  • So basically because you can compute the force coming

  • in one member, -Yep

  • to a node and the forces coming out the other member

  • that's how you arrived at isogrid.

  • Exactly.

  • -Okay, fantastic

  • Yeah it's sort of an interesting thing,

  • in the real world, how the engineering tools that are available,

  • dictate the kind of designs that we use.

  • Got it. What's your safety factor on flying here?

  • Oh, so it depends on what part of the rocket we're talking about,

  • anything that would be pressurized when people are around,

  • it has a higher safety factor

  • than what is not, but the factors we work with in

  • flight are anywhere from 1.1, to never really higher than 1.25.

  • Got it, yes. I mean it's very different than like,

  • designing a railroad car where your factor of safety might be

  • 7 or 8.

  • Oh no, yeah.

  • And a factor of safety is, if you can compute the stress

  • that the thing will break at, you design it to 1.1 times that

  • Right, 10% more load carrying capability, and really a factor of safety

  • is really a factor of ignorance.

  • You have a factor of safety because you're not truly

  • sure what might happen to it in the field,

  • so you give yourself just a little bit more.

  • And you talked about rail,

  • big tractors are another one;

  • we have big factors of safety like 7 times, 12 times,

  • when we do rockets, we like to keep it closer to like

  • just 10%, maybe 20%, cause we can't afford the weight.

  • Got it, because every every 1000th of an inch that you put in this webbing here,

  • over the course of a huge part like this,

  • you're talking tons on the whole rocket.

  • Yes

  • -Okay

  • Exactly, and this is a booster plate, and so

  • every seven pounds of that costs me a pound of spacecraft.

  • -So how long does it take to machine that?

  • You have the tools here to machine this isogrid.

  • Yeah this is about a two day operation altogether.

  • Is this curled like a potato chip in this direction,

  • or in this direction?

  • In the long direction.

  • -In the long direction

  • And you're going to see that operation as we walk

  • to the other end. -Nice

  • That's what the twenty-five-ton brake presses are for.

  • Yeah, cause if you're curling along the long direction,

  • you require a tremendous amount of force,

  • and you have to have alignment to keep it straight during the bend.

  • Exactly -Okay

  • Is that a pressure vessel? I mean would that hold pressure

  • or would there be a liner on the inside?

  • It is a pressure vessel, but actually on the booster

  • because it's liquid propellant, most of the pressure

  • is at the bottom just coming from hydraulic head.

  • We only have a few PSI of gas on top

  • to keep the propellant down against the outlet feeding

  • it into the engine.

  • Got it.

  • This is not something I expected to see.

  • These guys are--they appear to be putting--are they washing?

  • What are they doing?

  • They are. So the first thing that happens to those big plates,

  • is we plane them--we make them flat--and so these

  • guys are going over an operation that's just been done,

  • they're cleaning it up, they're looking for any

  • imperfections, and what you're going to see in the factory

  • that I think is really cool; you know we're building rockets

  • we're at the pinnacle of technology, and you're going to see

  • high tech robotic operations, but mixed in

  • you're going to also see craftsmanship,

  • with people who are very skilled, and have great attention to detail

  • like these guys. They're going to go over every inch of that thing

  • and make sure that the automated machine that

  • planed it, didn't leave any features we don't want.

  • So if like a piece of the tool broke or something like that -Exactly

  • Shattered, whatever.

  • Yeah so, are these your fly-cutters here?

  • Yeah, basically end mills, some of them are side mills,

  • but yes.

  • Gotcha, am I allowed to look at this fly cutter?

  • Yeah yeah, go ahead, sure.

  • -Wow

  • Isn't that cool?

  • I love machining

  • It's a secret passion of mine

  • Yeah me too

  • So you went to Alabama, right?

  • -I did

  • So do you guys do a lotta sorta machine shop time in your engineering degree?

  • -Not a whole lot, but we do take a class or two,

  • for my undergrad I did that.

  • But my dad had an old lathe and mill in the garage

  • when I was growing up.

  • -Cool Yeah that's cool stuff

  • The other thing I'll share with you,

  • you can see all that flow down there,

  • we actually recover all these chips

  • so even though we're going to take the majority

  • of the material away by machining it off--subtractive manufacturing--we

  • capture all of it, we send it right back to the supplier

  • and it comes back to us in a plate a month later.

  • -That's awesome

  • That, is that coolant?

  • That's coolant but it's mostly water.

  • Mostly water, so it's capturing the chips.

  • That's a tremendous amount of water flow!

  • Yeah, well, chips are heavy.

  • [Both chuckle]

  • It's hard to get a scale for that.

  • It's hard to get a scale for that, but that is a lot of fluid.

  • Oh, there's a whole river of coolant there.

  • -Oh yeah, you can see it

  • Are you looking for places where the tooling broke?

  • No we're looking for chips or,

  • debris that might be on it,

  • we only have about a 5000th of a thickness,

  • -Right

  • So, a small chip would be outside of the tolerance zones.

  • -Right

  • Thank you very much, my name's Destin.

  • -Jeff Nice to meet you Jeff.

  • Nice to meet you

  • That's cool, the human story is what's really cool

  • to me, that's amazing.

  • -Me too

  • Here's one that, uh, I think this guy's actually running.

  • So you can see way down there where the cutting head is,

  • These are actually the plates for Vulcan flight two,

  • -Really the second Vulcan that'll go.

  • So you know what we outta do is we outta, like,

  • steal you a chip down there, so you'll have a chip from the Vulcan rocket when it goes to space.

  • -Can I, can I stick on in my pocket?

  • Yeah.

  • -Ok, I'm gonna-- It's a little sharp, be careful.

  • -I'll be careful, I'll take a little one

  • Nothing to see here

  • It's okay, you be careful.

  • A chip from Vulcan, here's your chip.

  • Guard it with your life.

  • -Alright we're in trouble but don't tell anybody

  • We're in trouble but don't tell anybody,

  • Tory Bruno said it was okay if I stuck a chip in my pocket.

  • So,

  • these machine are CNC, correct?

  • Yes.

  • Okay and, are these specially made machines, or

  • because usually you, you don't plane a surface that -They were, yeah

  • wide. -No, generally when you're in this kind of factory

  • you're going to see tooling that comes from big tooling manufacturers,

  • but it has been designed especially for this application.

  • so all of this is custom stuff.

  • -Really

  • -So for example, the head here it probably

  • normal, but the ways on the machine,

  • this is incredibly long for a mill.

  • Yes, exactly, very very long, and very large.

  • -Gotcha Very, ya know, big width.

  • That lets us do more than one plate at a time.

  • -So if one of these machines go down,

  • what does that do to you?

  • That would be a big impact, but fortunately we have more than one,

  • so we would always still have the other machines running.

  • And so what would happen is we'd get it fixed

  • and then we would catch up on an off-shift.

  • -Because I've kept up with your launch record,

  • and you always meet schedule,

  • is it because you have redundancy built in to

  • this part of the process?

  • That is part of it. So yes, this factory was actually built

  • with the idea in mind of building as many as forty rockets a year,

  • and so we have so much capacity, it's easy for us

  • to kind of make up for little challenges like that along the way,

  • cause nowadays you fly maybe twelve or fifteen times a year tops.

  • -Right, okay. So you're not at capacity.

  • No, not even close.

  • -But you want to be, this is a commercial for that.

  • Yes we do, yeah we do.

  • Okay so that moment right there where Tory Bruno is

  • joking about the capacity of his rocket plant;

  • it reminds me of a very specific moment in an audio book I love called Seveneves.

  • Now the beautiful thing about Smarter Every Day being

  • sponsored by Audible, is I can use moments like that

  • to go to Nashville and introduce you to someone

  • I've been wanting to meet for a really long time.

  • Okay so we're going to drive a couple hours away,

  • and we're going to meet a lady named Mary Robinette Kowal.

  • She was the narrator for Seveneves by Neil Stephenson,

  • and she did an amazing job, listen to the first line of the book:

  • "The moon blew up without warning, and for no apparent reason."

  • Let's go talk to Mary Robinette about this book.

  • What a cool place to meet someone for the first time.

  • I'm Destin, you doing alright?

  • Yeah I'm doing great, nice to meet you! -Good to meet you, you doing ok?

  • Okay, this is Mary Robinette Kowal -Hi!

  • who is an amazing narrator of audio books.

  • -Thanks You are!

  • I've spent, like, well over twelve hours with you,

  • mostly in a tractor but that's another story,

  • but, the book that I want to tell people about is called "Seveneves"

  • by Neil Stephenson. And this looks like it was a challenging book to narrate.

  • It was more than a little bit challenging,

  • it's, uh, technically completely accurate,

  • it's got this huge international cast,

  • so basically something hits the moon--they never figure out what it is

  • shatters it, and that causes them to have to get off the planet

  • real darn fast, because pieces of the moon are going to start raining down,

  • and causing destruction for five thousand years.

  • Mass destruction -Mass destruction!

  • This is why I wanted to do it on this video,

  • because Tory Bruno is talking about building more rockets,

  • but you've also written a book yourself,

  • Calcu--

  • You've written many books, but there's one

  • in particular that's similar to Seveneves,

  • "The Calculating Stars", yeah I slam an asteroid into

  • Washington, D.C. in 1952 which kicks off the space program, fast!

  • Also building a lot of rockets, a lot fast. -A lot of rockets

  • There you go, so go get one of these two books,

  • she's kind of downplaying that a little bit

  • you've won the Hugo Award, the Locus Award, and the Nebula.

  • That is correct.

  • For that book, that's a big deal to win all three. -It's three

  • Go get her books,

  • [URL]

  • Which one would you recommend?

  • Seveneves.

  • Seveneves? I'm going to recommend your book

  • even though I haven't read it,

  • I'm guessing its' going to be amazing

  • It's called?

  • "The Calculating Stars" -The Calculating Stars

  • Okay, that's it, let's go back and build more rockets with Tory Bruno.

  • Here we go:

  • Yeah so if anybody needs their own personal rocket,

  • Tory's your guy.

  • Oh yeah, just let me know.

  • So you remember we were looking at isogrids down there

  • and we were looking at those Delta panels,

  • so if you look at this panel that's being machined,

  • you can see that they're rectangles.

  • So this is an orthogrid,

  • which is not symmetric, but we're able to do that now,

  • because the engineering analysis tools are better.

  • And so Vulcan switches to orthogrid, takes about half

  • the amount of time to manufacture,

  • and these panels will actually be stronger.

  • so as I look along the orothogrid

  • here, so

  • you're gonna break it along the long side

  • so this is gonna be a really long skinny

  • potato chip looking thing. -Exactly

  • So what happens when you're breaking along that line?

  • Because you have a section in the middle of the webbing

  • That's gonna have the most stress

  • Yes

  • But along the longitudinal webbing

  • you're gonna have, it's gonna be difficult there.

  • So actually the way the break process works

  • is we'll bring it in flat,

  • and as we break it, we're moving just a small amount of material each time

  • and we roll the part in and out,

  • so the amount of strain and work hardening that we get

  • is actually very uniform across that width

  • -Okay. Got it.

  • But the issue that you brought up is one of the reasons

  • why that's done by people. It's a hand operation.

  • So there's no CNC on the curving of the brake press,

  • it's all craftsmanship. -Really? That's amazing.

  • So, so these are Vulcan?

  • Yes, these are Vulcan panels

  • these panels are going to space.

  • -Wow, it's got a lubricant on it, it feels like.

  • From the machining; from the machining process. -Got it.

  • -And so, the orthogrid, just looking at it,

  • the webbing looks thinner, so it looks like it's much more light-weight.

  • It is, yes.

  • Are you allowed to tell me a percentage?

  • I can't give you the number yet, -Okay

  • ask me next year. -Okay, I'll do that

  • But it is absolutely lighter weight and stronger than the old isogrid design.

  • And it takes half as long to make.

  • -Why does it take less time to make?

  • You can see how much simpler that pattern is,

  • So the CNC machine has more straight runs in a simpler pattern,

  • and it just... it's that much faster to machine.

  • So those are fancy space saw horses?

  • Yes they are, yeah.

  • [Both chuckle]

  • So these are the panels that have been machined,

  • they've been cleaned up a little bit.

  • And they're getting ready to go into these

  • 25-ton brake presses, bump presses in order to

  • potato chip them, up into a curve.

  • -Okay, those presses right there?

  • Those presses right there.

  • -Okay, so I'm noticing that there's no hydraulic pressure in the center of the press,

  • There's just a really... it's a strong back. -Right

  • It's a strong back.

  • -What is the technical term for it?

  • Strong back. -Is it really?

  • Yeah! -Okay, awesome

  • So, so, can I look at this and then look at that?

  • Absolutely. -Okay am I allowed to walk over there?

  • Yeah.

  • So you can see that these guys actually have

  • a little bit of curvature along their length;

  • we're going to actually take that out.

  • That helps up form the curvature along this axis,

  • more evenly.

  • So it's sort of an intermediate manufacturing step, if you will.

  • -Is it done on purpose, or is it a function of stress relief?

  • It is done on purpose. -Oh okay, gotcha.

  • Of course this is, again, isogrid. -Isogrid, got it.

  • So this is Atlas V?

  • Right. -Okay

  • So at some point you have internal stresses

  • in the material. -Yes

  • Do you have an oven here to anneal?

  • No, we let them do what's called "artificial aging of aluminum,"

  • so 7000 series will do that,

  • so we're going to put a certain amount of work hardening in here,

  • and we like that--we actually like the properties that gives us

  • and then what the--sort of--room temperature artificial aging

  • does, is even that out for us.

  • So we're entering the space of--I notice you're saying hello to everyone;

  • people know you, don't they?

  • Yeah, oh yeah. -That's cool

  • So, we're entering the area where we've got this tooling here,

  • that's holding this stuff. These are the guys--oh they're actually doing something now.

  • Yeah, so that's a, you know that's a skirt

  • and they've just manufactured it, just put the curve into it,

  • we can walk over there; we'll let them finish what they're doing

  • we can talk to them if you like. -Okay. Yeah that'd be great

  • This is a finished part here? That's Vulcan. -Yes. Vulcan flight hardware right here,

  • It takes five of these to make a complete barrel,

  • for a methane tank, and then another five on top of that

  • will be the liquid Oxygen tank.

  • And we're going to show you friction stir welding

  • which is how these are joined.

  • -Gotcha.

  • Alright, so here is our two 25-ton bump presses.

  • So this big beam in the center is very very stiff,

  • that's why it's so tall, because the hydraulics are on the edges.

  • And what the technicians are going to do--our craftsmen--are going

  • to take one of these big, flat panels on these roller carts,

  • and they literally have patterns that are pre-formed,

  • that we've made, and they're going to roll them in and out,

  • and have that knife edge come down and hit it,

  • and slowly, potato chip it up,

  • while they're matching it to the physical pattern,

  • until they have it just right,

  • and so we saw all this high-tech computer computer controlled machining down there,

  • now this is pure craftsmanship where they're going to do it by eye and by pattern,

  • and achieve very tight tolerances in doing so.

  • -Do you have any plans to computer control this in the future?

  • No, this is a process that you will always get

  • better results doing it by hand.

  • That's amazing! So, oh I didn't even think about

  • having to hold the material as it comes out.

  • -Exactly, yeah.

  • Let's walk down and you'll see one,

  • they're working on that one right there.

  • -Okay

  • That's a skirt, which is why it's short.

  • Hey guys!

  • So, so one question I have Tory is,

  • as they lift the part,

  • obviously it's being supported by the top,

  • it's going to deflect. -Yes

  • So how do they know if they--oh it's pressing now. -Yeah, so you can watch.

  • -And you'll see.

  • See now, they're lifting it a little bit.

  • Bumping it again.

  • So now they're making another adjustment,

  • and they're going to bump it again.

  • This is all done by eye and by hand.

  • You could do this with a, sort of a remote controlled operation,

  • but you could not get the same lightweight tanks out of that,

  • you'd have to work with much thicker pieces of metal,

  • and you wouldn't have as high a performing rocket.

  • So I notice, she's looking with her eyes,

  • she's operating--is she operating the press with her foot?

  • -Yes

  • She's operating the overhead crane, -Yes

  • and also that-- -She has what's called a "walk along" or a "creeper,"

  • just like you would have, say, on your truck,

  • to tighten a fence or to get yourself out of a ditch,

  • she's doing all three things at once,

  • while watching the curvature she's creating in this part.

  • She is fully engaged.

  • Oh yes.

  • That's amazing.

  • Don't look at us, don't let us distract you--

  • should we go away? We're distracting them. -Yes yeah

  • Let's go let's go let's go

  • Yeah we don't want to have the uh, "Destin and Tory Discrepancy Report" on that.

  • [Both Laugh]

  • And here's finished product.

  • And this is all for Atlas,

  • as you can tell by seeing the isogrid,

  • and then we're going to walk down the aisle and

  • we're going to show you how these get joined together

  • into a tube.

  • --the welding? Oh! I almost forgot

  • Yeah we want to go to chem processing, right?

  • -Oh yeah, is this where stuff is anodized? Yeah

  • Let's go it, yeah yeah yeah.

  • Okay, so now we're in one of the world's largest plating facilities,

  • or chemical processing facilities,

  • where we're going to etch the panels down,

  • so that we have a very consistent high quality known surface,

  • and then we'll anodize them, which is plating

  • to create a very thick oxide layer,

  • to give the aluminum corrosion resistance and a little bit of hardness.

  • -Oh that is a very specific tool there.

  • Yes it is.

  • -To hold that part.

  • Yup

  • You know all this, Destin, but this is sort of,

  • classic, bare aluminum and it automatically forms

  • its own Oxide layer right away, which is why it's sort of white in color,

  • but we don't get very good corrosion resistance naturally,

  • especially from a 7000-series aluminum,

  • because it's not very thick.

  • And it tends to be porous, and so that's why we anodize it.

  • -That's bad for fatigue, right?

  • Yes, yes, very bad.

  • So we can get a phenomenon called stress corrosion cracking for example

  • If we allow corrosion to be present in these kinds of materials.

  • So is this the chemical milling process before you anodize?

  • No that will all happen inside the booths we're gonna take you to.

  • This is really for cleaning

  • because we're gonna - you know there's a lot of machining activity, there's a lot of chemicals that are going to be involved.

  • And so we like to have a known condition when it goes in and out of the tanks.

  • And this particular dome is in here to be inspected.

  • Look at that!

  • Yeah.

  • So what am I looking at?

  • So you're looking at us rinsing and washing a ring, before it comes further down to this booth which is actually an inspection booth.

  • Gotcha!

  • So this is pre-anodization.

  • Yes

  • So just to connect the parts, we made the part down there. Pulled it up on this crane, pulled it over here,

  • Brought it over there and inspected it one more time

  • We're going to take it down there and clean it.

  • We're going to inspect it, and then we're going to go around where you can't see right now and anodize it.

  • and we're going to drop it off the other side?

  • and then when it's all done, it'll come down the other side.

  • Gotcha.

  • So this is like the rainbow arc of anodization!

  • Yes it is! Yeah.

  • Ok, cool.

  • So Shannon, what's your role here?

  • So, I work on the commercial crew hardware, -Okay

  • I'm in the production engineering group, so I work with the design team and the technicians,

  • to interpret the drawings, and make sure they're building it correctly.

  • Give them all the procedures and processes they need.

  • -What kind of engineer are you?

  • So I'm in the production engineering group,

  • so manufacturing engineering.

  • How's it going?

  • That's the thing about working at ULA,

  • you never know when the CEO is going to walk in on you while you're cleaning the floor.

  • [Both laugh]

  • So you said Sulfuric Acid to do the etching?

  • Yes, and that's part of the plating, so anodization always

  • uses, typically one of three acids,

  • you use Sulfuric, you use Chromic acid, or other organic acids,

  • so that's part of it,

  • because that releases the Oxygen in the bath,

  • some of it bubbles off, but the rest of it ends up attaching to the material,

  • creating that corrosion resistant layer.

  • -So this is a vat that you would dip the part into?

  • Yes, in fact here we are.

  • Here's our Sulfuric Acid anodization,

  • so there's a part in there right now that's going to sit there for a prescribed amount of time,

  • it's heated, and then we're passing current through it

  • because ultimately this is actually a plating process.

  • See, here's our DI (deionized) tap water rise,

  • that we were talking about.

  • Yeah.

  • So you literally put the part in there and you give it a shower.

  • Give it a shower!

  • -That's awesome!

  • Holy cow, that's intimidating.

  • -Yeah

  • -That's intimidating... Keep your hands out of there.

  • [Both laugh]

  • We'll plate, we'll rinse, we'll plate again,

  • we'll clean, then it goes out where you were before, for inspection.

  • Here's what they look like when they come out,

  • so you can see that sort of characteristic green/bronze

  • color of an anodized aluminum surface.

  • And as they naturally age it'll become more and more bronze,

  • so when you see an Atlas rocket on the pad,

  • and you look at the booster, it has that very distinctive bronze color,

  • this is why, because of what we just looked at here.

  • Maybe we'll just let you peek over the edge, would you like to?

  • -Yeah that'd be great.

  • So at this point we've finished plating, cleaning, and inspecting,

  • and here are the panels, lowered down from where we took that last shot.

  • -And now what?

  • Now they're going to get friction stir welded together into barrels,

  • forming the body of the rocket, and the propellant tanks.

  • -So one question I have about this next step, is

  • when you weld something, usually you tack it together all around the perimeter

  • before you do the final welding, because the heat will draw it up

  • -Right So how do you account for that here?

  • So we fixture it, we hold it in place mechanically, because the

  • interesting thing and the reason you want to do a friction stir welding

  • is because you don't melt any material.

  • In conventional welding, you bring the parts together,

  • and then as you say, you tack them to hold them,

  • and then you fill in that gap with filler material

  • that you've melted.

  • It fuses to the parent material

  • melting it a little bit too, and then you get a heat-affected zone,

  • and that entire weld joint has different mechanical properties

  • than the original material.

  • But when you friction stir weld, you never melt anything.

  • You bring the parts tightly together,

  • and you bring a head that spins, and literally stirs the material together as it moves.

  • That gives you a stronger joint, which means you can

  • thin down the entire part, and get a much lighter weight

  • higher performance structure.

  • -So what is the head made out of, that can withstand the higher temperatures?

  • So the heads are always made out of tool steel,

  • high strength materials that can stand that

  • over and over and over

  • we're welding aluminum so we just need that difference.

  • -So the melting point of aluminum is so much lower than the head

  • -Yes of the tool part...

  • and it never quite melts.

  • It gets warm, it gets a little soft, because of the heat generated through the friction,

  • but we never actually erase all of its mechanical properties,

  • like you do with a classic, conventional fusion weld,

  • you literally melt the material.

  • And I'm not allowed to film this, and I'm not allowed to film that...

  • -Nope

  • What if I peek over there, can I peek...? -You can peek

  • Peek over there, but it was blocked out

  • so people couldn't see that.

  • So now, those big plates that you saw machined and you saw bent,

  • and you saw anodized, have to get friction stir welded

  • together into a barrel to form an Atlas booster,

  • or in the case of what you see over there

  • right now is the Vulcan first flight liquid oxygen tank.

  • -That's it, okay so that is the first vertical assembly of Vulcan.

  • -Right, and so that tank will go to space,

  • and it will lift the Astrobotic Peregrine Lander back to the moon,

  • which is our first mission on Vulcan.

  • -Really? -Yeah.

  • I didn't know you had a lunar mission. -Yeah yeah, that's our first mission.

  • That's awesome, okay! -Yeah it's super cool we're really excited about that.

  • -Yeah

  • So what you're seeing here, is uh,

  • five--these are actually Atlas, but for the version that's Vulcan,

  • five of those big panels that start out flat and thick,

  • machined down, they're fixtured up in there,

  • and if you look right there you can see that sort of bright aluminum stripe that runs up it,

  • that is a completed friction stir weld.

  • -And you have a rotary stage at the bottom that's

  • turning it, and so you have the weld on one side. -Right, cause we're going to do

  • one, two, three--it takes five of those panels to make a Vulcan, so

  • we've gotta do five, we've got to do all of those welds.

  • -Wow So we'll rotate it, then we'll do another one,

  • rotate it, do another one.

  • And over there is a finished Atlas barrel, if you'd like to

  • kinda see what it looks like. -That would be great, yeah.

  • So these are friction stir welds?

  • Yeah, so this is an Atlas tank, and by the way you can--maybe it's a little hard to see

  • from down on the ground, but this is a lot smaller than that big beast over there.

  • -Right.

  • And so here's our classic isogrid pattern--

  • -What's our diameter on Atlas?

  • So Atlas is a little bit closer to 3.8 meters,

  • and this is a 5.4 meter diameter rocket on Vulcan.

  • -Got it So even just a little bit bigger than Delta.

  • -That's a lot more volume payload.

  • Oh yeah, yeah so r², you know the math.

  • -Yeah, so like, it's better to order one large pizza than two medium pizzas,

  • -That's right and so when you have a large rocket,

  • you get more than just two small rockets.

  • -You got it. That's the easiest way to say that.

  • Okay, so this is a friction stir weld?

  • -So here's a friction stir weld, so you can feel that.

  • -Yeah, you can feel where it heated up and grew a little bit.

  • -Yeah.

  • We just bring these parts tightly together,

  • we bring a head down that spins very very fast,

  • it heats it, softens it, stirs it together without ever melting it,

  • and we just run all the way down the length of the barrel,

  • and that's how we join them together, and we get a stronger part, and a lighter rocket.

  • -But do you do that on both sides?

  • I guess my question is, do you have a tool on the outside, and the inside?

  • -Yes, you have to react against something,

  • so there is such a thing as a self-reaction friction stir weld,

  • and I'll show you that too, -Okay

  • but for these parts yeah, you have to react it against

  • so you don't just push the material through.

  • -Gotcha

  • So now, we're going to look at a different friction stir welding process called "circumferential",

  • cause we're going to attach a dome or a barrel,

  • self reacting friction stir welding, where we don't have

  • to have something holding the part up from behind.

  • -It seems like that would be difficult though, because like

  • when you have a hammer and you're hitting something on an anvil,

  • You know, it squishes and molds the metal together against the anvil. -Yes, right

  • But if you're just pushing, how does it not just push out the other side?

  • -Well it has to do with how we fixture it,

  • and some very clever things in the friction stir weld head,

  • which is why I'm not going to let you film it.

  • I can't film it? -No.

  • Okay...

  • You cannot look at that part at the end of this big assembly up there, that's the weld head.

  • -Which part can I not look at? Yeah this guy right up here,

  • so the end of that. -That part I can't look at?

  • Don't look at that. -Okay, got it. [Both laugh]

  • -A little video magic

  • This is why we're taking your card.

  • -This is why you're taking my card, because of ITAR.

  • It seems like you would be more prone to fracture on the back side.

  • -You are, there are some..."tricks and techniques" to making this work well,

  • especially a self-reacting process like this one, where you don't have any support,

  • to uh, you know protect that joint.

  • -And what's the advantage of doing that?

  • You can, seal a tank? It's like when you sew a pillow together,

  • that last stitch is important, but you have to do it from outside the pillow.

  • -One of the things we have to deal with is, when you come around,

  • because of the way that head works, you actually leave a terminal hole.

  • So where you terminate, there's a hole that penetrates the tank,

  • that we then have to later seal up as well.

  • But it's worth doing that, because this process is so fast.

  • -This tooling here holds, everything... So a big tank like the tube we just filmed

  • would come all the way down here, where

  • where we would either have a dome or a ring,

  • that would then get the friction stir weld to put it all together.

  • -On the circumference? On the circumference.

  • -Got it, so there's two different operations:

  • there's a longitudinal friction stir weld, and there's a circumferential one--

  • -Exactly Okay friction stir weld.

  • In fact you can see a dome over there that's being set up for its

  • attachment. -So that's a smaller tank, so would that be oxygen?

  • Yeah that's Atlas, that's just the dome.

  • That's just the dome attached to its ring, it'll get attached to a big long barrel.

  • -Gotcha, sounds good.

  • Okay! Alright and--there's an X-Ray booth to X-Ray joints,

  • and then there's also a uh,

  • a pressure booth where small bottles get pressurized,

  • and then outside this building there's a booth where we put pressure and fluid in the big tanks

  • to make sure everything seals, just like any kind of normal pressure vessel process.

  • -So this is, humans know how to make pressure vessels,

  • so you build it, you weld it, you seal it, and then you take it up to a certain pressure

  • above what you think it's going to see, and then that tests it and you come back down

  • and then you fly it.

  • You got it.

  • [DESTIN VOICEOVER] After the booster's assembled, the plumbing is installed,

  • the insulation is applied as necessary, and the rocket engines are mounted.

  • We weren't able to film details about the engines themselves,

  • But they're made offsite by a variety of different sources.

  • [ON-SITE DESTIN] It's really interesting being able to peek inside and see

  • the isogrid and understand where we started with the plate.

  • -Yeah That's pretty fascinating.

  • Alright so we built the booster, now we're going to talk about the second stage of that rocket.

  • -Okay The part that goes to space.

  • So the technology we had before that we walked through,

  • was aluminum; rigid structures, very high performance.

  • but on a booster, you could afford seven kilograms of inner mass before it costs you

  • a kilogram of spacecraft--on the upper stage it's literally one-to-one.

  • So we switched to an even higher performance technology,

  • so now we're going to walk the Centaur line; our very high performance upper stage.

  • We use stainless steel-- -To be clear, the Centaur is like,

  • it's like the tractor, it's the heartbeat of American space kind of, right?

  • -Yeah yeah, so it is in fact the highest performance upper stage ever flown,

  • it is the last stage of the rocket that takes the spacecraft, all the way into space

  • and into its destination orbit. -Gotcha, okay.

  • Alright so this is a gore(?),

  • and these are kinda fun, these are gonna be resistance welded,

  • you can't friction stir weld them because the material is too thin,

  • and shaped into a dome--and you can touch this if you want, Destin.

  • That's it.

  • Oh my goodness.

  • And that's a pressure vessel? -That's a pressure vessel.

  • And it's going to be huge, -Okay I had no idea, I--

  • it'll be over 3 meters in diameter, 40ft long.

  • -So, I can just tell you this, like,

  • I've done the math to say, if I have a certain thickness pressure vessel,

  • it'll be this much weight, but it's a totally different thing to actually feel it.

  • -Oh yeah It's like uh...

  • It's just nothin', it's nothin'... -Nothing there, nothing there.

  • That's amazing, ok I can understand.

  • -Half the thickness of a dime. Wow, okay,

  • -Yeah That's incredible!

  • So, you put these together in a sphere?

  • We'll put those together in a dome, and then there will be a cylindrical section that's almost 40 feet long,

  • and then another dome on the bottom.

  • So this stuff comes in in big coil rolls, almost like you would buy sheet steel,

  • you know at Home Depot or something.

  • And then we stretch it, and then we cut it into those shapes,

  • and even as thin as that is, we'll actually machine it still, kinda honing it,

  • to get even just a little bit thinner than we can buy it.

  • So these are sharp edges so be careful.

  • They came off a big roll, and we've laid it out, we've cut it,

  • we're gonna stretch it, -It's all stainless steel?

  • Stainless steel. -So these are--are they called mandrels, or

  • no not mandrels, what are these called?

  • These are dyes.

  • -Yeah so these are dyes, and they're going to be used to stretch it and cut it

  • for those gore(?) shapes that you saw for a dome. -Okay

  • That really gives you a sense of how little material and the margins you're playing with here.

  • -Yeah. And then we didn't talk about it, but uh,

  • the 5-meter composite payload fairing for Atlas used to be made in Switzerland

  • by a company called Ruag,

  • they're going to make the Vulcan 5-meter payload fairing,

  • and so I asked them--this is another one of those strategic business partnerships,

  • to take their factory out of Switzerland, and it's actually on the other side of that wall.

  • -Really, so you brought the factory to America? Brought the factory to America.

  • And there was enough volume there that they were totally on board.

  • -Yeah.

  • One of the strategies for having a very succesful first flight on Vulcan,

  • is to fly it before you fly it.

  • -With parts from Atlas?

  • You got it. So lots of the technologies on Vulcan could be flown on Atlas,

  • and so we'll slowly start bringing them into Atlas over the next year,

  • we'll fly Vulcan payload fairings on Atlas,

  • We'll fly a lot of the same technology you just saw, pretty much everything but the BE-4 engine,

  • will have flown on Atlas at least once before we try it out on Vulcan.

  • -Gotcha. I notice you have pictures of the commercial crew all over the walls here.

  • Yes, yeah so we're flying people, that's a whole other game,

  • you know, 135 in a row is, we're very proud of that

  • but...

  • when it's a person up there, when you can shake hands with the payload,

  • you know, talk to them and meet their friends and relatives,

  • it's a whole other thing.

  • And so they've been to the factory many times, to see their rocket,

  • and it means a lot to my employees to know them,

  • and to know that we're flying people, and so we're just that much more careful,

  • and we have pictures of them everywhere to sort of remind us,

  • you know that's Sunny, and that's Nicky. -Sunny's amazing isn't she

  • Yeah, yeah. -She really is.

  • Here is, sort of the, completed product.

  • Stainless steel, you can see, just look at that. -I didn't ask, I'm allowed to touch, right?

  • You can touch it, yeah. -Okay.

  • Okay, is that machined after it's welded?

  • -Before, yeah before. Before, okay.

  • So you make a groove maybe. -Yeah

  • Gotcha. -And we actually plane the whole surface.

  • So as thin as that was, what you saw over there, we actually plane it and thin it out just

  • a little bit more; we want it a little thinner than you can buy it.

  • -Really

  • The cool thing about Centaur is, you know a booster... is typically 80% mass fraction.

  • And... most upper stages get, 85-ish.

  • Centaur is around 90, so literally the highest performance upper-stage ever.

  • Okay, so we saw the dome, that's the cylindrical tank that the dome will be fitted to.

  • One on the top, one on the bottom,

  • and the one on the bottom is where the engine will be.

  • -Is this the same thickness metal we're talking about?

  • It is, yeah so that giant thing you're looking at, 40ft long, half the thickness of a dime

  • You see all the rings? That's all tooling, so that we can support that shape,

  • so it doesn't just collapse on its own.

  • And when we actually put the domes on it, we'll have to grab it at either end and stretch it,

  • or pressurize it depending on where it is in the factory.

  • -Oh okay so, it's the opposite of a bulk(?) buckling problem.

  • You have hoop stress and you have ring stress. Ring stress is the issue here.

  • -Exactly, exactly. Okay

  • Wait, am I saying that right? Axi--okay.

  • So you have axial stress and you have ring stress, ring stress is the problem here.

  • -So you could think of it as a longitudinal buckling problem if you want,

  • because the weight of the structure itself would overcome the stiffness,

  • and it would--you'd start with a hoop and it would just kinda buckle like this on the top and fold in.

  • -Gotcha, awesome. But we have the same friction stir welding idea there?

  • No, so this material is so thin that you cannot friction stir weld it.

  • So this is all done with resistance arc welding instead, and on Centaur III,

  • which is what we fly on Atlas today,

  • this is a labor-intensive operation. 180,000 welds,

  • they're all setup by hand,

  • so it takes many many hours and quite a bit of time to build this sort of "Ferrari" of an upper-stage.

  • -Yeah. Vulcan will be robotic and automated.

  • -Really, that's amazing.

  • Dome on the front, dome on the back, tank,

  • the engine--well there's not a dome on the back, that's where the engine goes.

  • -So there will actually be a dome, so that you have a sump to collect propellant in

  • to draw it into the engine, so you don't waste as much propellant,

  • and what you can't see on the inside is a bulkhead, to separate

  • the liquid oxygen and the liquid hydrogen from one another.

  • -Got it.

  • So, where are the engines at, are they here?

  • -Uhhhhh... let's see.

  • Have we got an RL10 open out of a crate that we could show him?

  • -We're gonna go upstairs. Okay--oh! Yeah so, we're gonna--

  • so there's a final assembly that gets done in a clean room. -Okay

  • And that's the best place, so we'll look down, you'll see a whole bunch of them,

  • they'll be engines, that'll be better.

  • Okay, so this is the final assembly area for Centaur,

  • this is a clean room, that's why we're up here,

  • the people down there who are on break right now would be in bunny suits.

  • So you're looking at the business end, those red covers are on the bottom of the nozzle of the,

  • RL10 rocket engine.

  • And you can see that you have a standard configured one with a single engine,

  • -Right there Right there, but to its left you see a dual.

  • -Okay, that's strange.

  • That Centaur will carry astronauts to space.

  • -That one will? That one will.

  • -That's amazing Yeah

  • -That's a pretty big deal, so how do you--I mean that changes everything about how you operate

  • the thing. Have you ever flown a dual-engine Centaur?

  • We have, but it's been decades.

  • -Really? And so this is reintroducing a,

  • kind of a historic but one configuration we haven't done recently.

  • -So this right here, I'm seeing, that's Mars 2020 right there?

  • Yeah

  • -So that's the Centaur that's going to take Mars 2020 to Mars?

  • Yes it is, yes it is.

  • -So you do the bulk of the heavy lift or the, I guess the "far push" you could say,

  • with Centaur.

  • We do, yeah so the booster's job is to get you into space, typically depending on the payload

  • but typically you're not quite orbital at the end of first stage burn,

  • and then Centaur will take you orbital, bring you to your parking orbit,

  • and then once you're lined up correctly with, you know the right sort of argument, of

  • perigee, then it will send you off on the final burns to get you lined up for wherever you're going,

  • and in this case it's interplanetary missions, so we're going out to Mars.

  • -So, the brains that drives the Centaur, where is that at?

  • Are you integrating GNC at this point?

  • We are. So on the back end of that is a flight controls computer,

  • and you know inertial measurement sensor and other sensors,

  • uh rate sensors that are the guidance system; they're always attached to the upper stage

  • obviously because if you attached them to the booster and it separated,

  • you would've lost your brains.

  • So they're always up here.

  • Okay, final assembly.

  • -It is and I'm not--so yeah this is, this is the big show, right?

  • This is the big show, we call this the "great hall of rockets", because as you can see,

  • There's rockets way down there and they just keep going all the way to that big roll-up door,

  • they're in final assembly, and when they get to that door,

  • They roll outside, down to the Rocketship, and off to the launchpad.

  • -So, this gentleman over here is doing final assembly on a rocket?

  • He is absolutely doing that, yes he is.

  • -That's amazing, and so wow just having a person for scale is pretty impresive there.

  • Yep. -That's amazing, so what are we looking at?

  • These are Deltas on this side of the aisle, and Atlas on this side,

  • and way down there we'll walk you back down there, but Vulcan will start

  • at the far end of the Delta line and slowly work its way down,

  • eventually replacing Delta entirely.

  • -So Delta and Atlas are being phased out, correct? Yes, yes.

  • So do you know the number of missions you have left for each one?

  • I do!

  • -Okay, are you allowed to talk about it?

  • No. -Okay. [Both Laugh]

  • So the last question I asked Tory was very interesting,

  • and before I show you that though, I want to say, you should be following this guy on Twitter.

  • He has a legitimate, technical engineering answer for everything he's asked.

  • He's very engaged in the space community, it is legitimately fun to watch Tory Bruno

  • interact on Twitter. So there's that.

  • Now if you're into space, you know that I didn't ask two things in this video.

  • I didn't talk about engines very much, and I also didn't ask about Tory Bruno's

  • competitors. I did that; that's over on the second channel.

  • He gave me really good answers, if you want to hear what Tory Bruno thinks about

  • those two things, go to the second channel, link in the video description,

  • also a link to Tory Bruno's Twitter.

  • Okay, let's get back to the last question I asked Tory on this tour.

  • I have noticed that there's not a lot of stuff in this plant that's going to low Earth orbit.

  • -That's correct And,

  • and uh, that's intentional?

  • Yes, our specialty are the higher-energy, more difficult orbits,

  • things like Mars 2020, an interplanetary mission. -Right, and that's...

  • Literally right there, yeah, but we don't call it Mars 2020, here.

  • -What do you call it? We call it Mars 2020...20,

  • -Why would you do that? Because it's our 20th trip to Mars.

  • -Really? That's amazing Mhm

  • -That's impressive! So your job is to get it there, Yes.

  • And then what happens with the payload at that point?

  • So it'll re-enter, it'll come down to the surface of Mars, as you mentioned it's a rover.

  • We really set it on its way, so Centaur is no going to go all the way with it to Mars,

  • we're going to put that energy in, as an escape velocity here at Earth,

  • greater than "1c3", as we say in the technical world,

  • and then that will carry it all the rest of the way,

  • it will establish its own orbit and land.

  • -That's impressive, that's what I like about Tory, he knows his stuff.

  • So thank you very much for this tour! -Oh yeah, you're welcome.

  • This was absolutely incredible,

  • I've lived near this plant my entire life; well I guess it hasn't been here my entire life.

  • But as long as it's been here, I've lived near this plant and always wanted to come inside, so

  • thank you very much for extending your flight and giving us this tour, this was amazing.

  • I'm glad you came by.

  • Thank you so much! -You bet

  • Super duper thank you, for watching this video.

  • It's a long video, but it's so special. I mean I've loved rockets forever,

  • Always have, always will, and this is like rockets and manufacturing--the Venn diagram right there that sweet spot,

  • this is what this is for me, it's wonderful.

  • So thank you for watching this video. If you feel like this type of video earned your subscription,

  • one way you can signal that to me is by subscribing. You can click on the subscribe button

  • and there's a little notification bell; if you click that, it'll notify you when I upload, and that'll encourage

  • me to do more stuff like this.

  • Big thanks to ULA and Tory Bruno, you trusted me with your rocket factory,

  • so thank you very much!

  • Also, you can support on Patreon, if you're into that

  • sort of thing. I've got something coming up in

  • the near term, that the Patrons have made happen,

  • and it's fantastic.

  • audible.com/smarter or text the word "smarter" to 500-500,

  • I recommend "Seveneves" or Mary Robinette's book "The Calculating Stars",

  • Yeah, that's about it!

  • I'm just really happy, and very grateful, and thank you for being here with me.

  • That's it. I'm Destin, you're getting Smarter Every Day. Have a good one, bye.

Five...

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火箭是如何製造的(火箭工廠之旅--聯合發射聯盟)--每天更聰明 231 (HOW ROCKETS ARE MADE (Rocket Factory Tour - United Launch Alliance) - Smarter Every Day 231)

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    林宜悉 發佈於 2021 年 01 月 14 日
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