The Rocket engines carrying Us to Space. The SLS RS-25. (The space shuttle main engine).
There are few rockets more iconic than theRS-25, also known
as the Space Shuttle main engine. Even though it’s been around in some form since
the 1970s, it’s been improved and upgraded several times, making it the most efficient
liquid fuel rocket engine going today. And now the RS-25 is going to see a new
chapter in its history, working to carry NASA’s new Space Launch System back to
deep space, beyond Earth orbit.
When you really think about it, the principle of a rocket is
actually pretty simple. Use a combustible fuel to blast out a jet of hot gas
through a nozzle. Rockets take advantage of Newton’s third law, you know, for
every action, there’s an equal and opposite reaction. As material is fired out
the back of the rocket at supersonic speeds, the rocket receives a force,
pushing it in the opposite direction. Unlike jet engines, which need to bring
in oxygen from the atmosphere to create the combustion, rockets carry their own
oxidizer, so they can even work in the vacuum of space where there is no
oxygen. Rockets aren’t pushing against anything, they’re throwing material out
the back so fast that they move in the opposite direction.
There are many different kinds of rockets out there on the
market. There are the small sounding rockets that can follow a parabolic
trajectory, reaching a high altitude and then returning to Earth. And then
there are the enormous, multi-staged rockets like the Atlas or Ariane capable
of lifting tonnes of satellite into low Earth orbit and beyond. Of course,
there’s everything in between, from many different manufacturers across many
different nations. There are fewer kinds of rocket engines, though.
You’ll see the same
engine attached to different sizes of rockets. Some of these engines have been
used continuously for decades, like the Russian RD-180 engine, which is used
for Russian and even American launches. Others are relatively brand new like
SpaceX’s Merlin engine, which has already been through many iterations,
carrying Falcon rockets into space. And the even newer Blue Origin BE-4.
Today I want to talk about an iconic rocket engine, the
mighty RS-25, the Space Shuttle’s main engine. Let’s look at its history,
capabilities and how it’ll see a whole new chapter by helping to push Space
Launch Systems rockets into orbit and beyond. You might have problems with the
space shuttle program, and disagree with NASA’s plans for the Space Launch
System, but the RS-25is an incredible piece of space hardware, there’s not much
out there that stacks up to it in pure power and efficiency. As the Apollo Era
was winding down, NASA began investigating the technologies it would be using
for its next step in space flight: the space shuttle.
While the mighty
Saturn V was a beast for hurling heavy cargo deep into the cosmos, the space
shuttle was seen as a reusable vehicle that would make spaceflight a routine
experience. It turns out, spaceflight wasn’t ready to be routine, but NASA
didn’t know that yet, balancing the various requirements from different stakeholders.
During the design process, the shuttle went through many variations.
There was a time that the space shuttle could have had 12
sea level booster engines and then 3 orbiter engines, fixed wings versusdelta
wing, but they finally settled on the modern design with the space shuttle
orbiter attached to the huge external fuel tank with its solid rocket boosters.
When it came to the
engines, several new technologies were being considered, like an expanding
nozzle that would operate more efficiently at different altitudes and
high-pressure engines that would use the fuel more efficiently to produce
thrust. When the initial contracts for the Space Shuttle were awarded in 1969 -
yes, work on the Space Shuttle began back when the first astronauts were
landing on the Moon - NASA requested engine proposals that matched the
capabilities they had been studying, with the ability to throttle the engine,
expanding nozzles, and a very high-pressure combustion chamber. The contract
was awarded to Aerojet to produce the space shuttle main engine, the RS-25.
The company later
merged in 2013 with Pratt& amp; Whitney Rocketdyne to become Aerojet
Rocketdyne, which I think is about the coolest name fora rocket company. The
space shuttle was equipped with threeRS-25 engines which were fed by liquid
oxygen and hydrogen from the huge orange external fuel tank. Together with the
twin solid rocket boosters, the space shuttle’s 2,000 tonnes or 4.4 million
pounds would be carried into orbit. Each shuttle would be capable of
delivering27,500 kilograms or 60,600 pounds of cargo to low-Earth orbit. The
exact thrust of the RS-25 is actually a little difficult to pin down. The
engine was designed to be throttled, so that it could change the total amount
of engine power from 67% to 109% of its power rating. In an emergency, it could
probably hit 111%. At sea level, and at 100% thrust, each engine could generate
380,000 pounds of thrust (or 1,670 kilonewtons).
And in a vacuum, they could produce 470,000pounds of thrust
or 2,090 kilonewtons. But like I said, the rockets could be throttled up beyond
100%, which I know sounds kind of crazy, but 100% was the original spec, while they
were able to get the engine power higher through improvements and modifications
over the engine’s development lifetime. Need some kind of comparison? The
SpaceX Merlin engine produces 845 kilonewtons or 190,000 pounds of thrust,
rising to 914 kilonewtons or 205,500 pounds of thrust when it reaches the
vacuum of space. That’s why the Falcon 9 has the name, it carries 9 Merlin
engines.
The Falcon Heavy has 27 of them. Over the course of the
shuttle program, there were a total of 46 RS-25 engines used. And together,
they successfully lifted off the space shuttle 135 times. One RS-25 did fail on
a 1985 mission with Challenger, but the shuttle was still able to get to orbit
and complete its mission with the one failed engine. And there were a handful
of times when leaks and sensors connected with the engines led to a launch
delay. And then, one year later Challenger was destroyed along with its
7-astronaut crew during launch.
The mishap was traced back to the o-rings that helped attach
the solid rocket boosters. Just to give you a sense of scale, each
RS-25measures 4.3 meters tall and the nozzle is 2.4 meters in diameter. It’s
about the size of a compact car. There are four turbopumps that pull in liquid hydrogen
and liquid oxygen from the main fuel tank, and force them into the combustion
chamber at high pressure. Inside the combustion chamber, the fuel and oxidizer
are mixed together and ignited. Beneath this is the huge nozzle, where the hot
gases are expelled at 13 times the speed of sound. The RS-25 is known as staged
combustion engine, where turbine exhaust is captured and fed back into the
engine.
This makes for higher performance, but also higher pressure
and more danger. During its initial development, NASA had a rough time getting
the RS-25 to handle the pressure and forces involved. This is one of the key
differences from other engines on the market, like the SpaceX Merlin, which is
open-cycle. It’s less powerful pound for pound than the RS-25, but you get the
benefits of lower cost and higher production rates. Each Falcon Heavy will
almost have as many Merlin engines in it than the number of RS-25s that were
ever built.
The end of the shuttle program would have been the end of
the RS-25 engine, but it’s gotten a new lease on life with NASA’s Space Launch
System. I’m going to talk all about how the RS-25fits in, but first I’d like to
thank: Howard Amos Bjørn Karlsen Epyx911Jonathan Stein Anders The odorsen And
the rest of our 802 patrons for their generous support. If you love what we’re
doing and want to get in on the action, head over to patreon.com/universe today.
Once the shuttle
program wrapped up, NASA was ordered to keep the fleet’s workforce employed
developing the Ares rockets for the Constellation program. This transitioned to
the Space Launch System, which would give NASA heavy lift capabilities again,
enabling missions past low-Earth orbit, to the Moon, asteroids, and beyond. In
its initial Block 1 design, SLS will be capable of lofting 70 metric tonnes to
low-Earth orbit, and the final Block II configuration will be able to carry 130
metric tonnes.
In fact, it could end up being even more powerful than the
Saturn V, making it the most powerful rocket ever built - until the SpaceX BFR
becomes operational. And much of this depends on using the RS-25engines for the
central core of the Space Launch System’s first stage, since they have 16 left
over from the space shuttle days. Unlike the space shuttle, the SLS will be equipped
with 4 RS-25s, together contributing 9,000 kilonewtons or 2 million pounds of
thrust to the system.
These will be joined
by twin solid rocket boosters for a total of 32,000 kilonewtons or 8 million pounds
of thrust. As part of the upgrade to SLS, NASA engineered an entirely new
engine controller to match the engine with the new rocket. At the end of 2017,
NASA wrapped up a 400-secondtest of its new RS-25 controller. This was the
eighth test of the year so far and the sixth using this new controller.
There’s already been a successful test in2018 with more to
come. If all goes well, the RS-25 will see its return to flight when the first
SLS rocket blasts off with Exploration Mission-1, now scheduled for 2019 (or
maybe even 2020). Unlike the reusability of the shuttle, though, the core stage
of SLS will be destroyed after launch, including its RS-25s. Once they use up
the initial group of left over engines, they’ll need to get more from Aerojet
Rocketdyne. While the RS-25 engines were developed and built for the shuttle
fleet, and now SLS.
They have been upgraded several times, with the total power
output updated to 105% by the end of the shuttle program. SLS should get to
109% and they think they can push the engines to 111%. Normally this would mean
a decline in their reusability, but these engines won’t be reused, so they
might as well be driven to the max. Each mission using the Space Launch System is
going to cost US taxpayers $500 million to $1 billion dollars.
A launch on the SpaceX Falcon Heavy is going to cost a mere
$90 million in comparison; although it won’t have the raw launch capacity of
the SLS. Each RS-25 probably cost NASA around $60 million. That much money will
get you a flight on a Falcon 9. So I think there’s a pretty important argument to
have about the cost effectiveness of the SLS, and developing a rocket system
that gets destroyed with every launch, now that SpaceX and Blue Origin are
demonstrating reusability.
But I’ve really got to admire the power and capability of
the RS-25, and the creativity and workmanship that went into it. It’ll go down
in the history books as one of the most important and impressive rocket engines
ever built. And I can’t wait to see it fly again. How do you feel about the
RS-25, the space shuttle and the Space Launch System. Did you want me to
compare this engine with the more modern reusable rockets from SpaceX and Blue
Origin? Let me know your thoughts in the comments. Want more space news, I’m
now writing a weekly email newsletter that highlights many of the big stories
that happened this week. It’s quick, easy to digest, with lots of amazing
pictures and videos. You can find out more and sign up by going to
universetoday.com/newsletter In our next episode I continue my series on the
discoveries made by space missions. What did NASA’s Curiosity Rover discover?
That’s next time. And finally, here’s a playlist
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