3D printing for rocket engines is making a lot of headlines lately. In the last few weeks, we've told you about Aerojet Rocketdyne building and hot-firing a 3D-printed rocket engine and NASA's 3D-printed rocket engine injectors that perform better than welded ones. Now SpaceX has revealed details about its use of 3D printing in the SuperDraco thruster engine for the Dragon Spacecraft, as well as in one of the Falcon 9 rocket's engines.
The SuperDraco thruster engine is an advanced version of the current Draco engine that's used in SpaceX's Dragon spacecraft to maneuver in orbit and during re-entry. SuperDracos will be used on the crewed version of the next-generation Dragon Version 2 spacecraft. There, they will power the vehicle's launch escape system, which is completely integrated into the spacecraft.
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SpaceX has 3D printed and successfully hot-fired a SuperDraco engine chamber made of Inconel, a high-performance super alloy, using direct metal laser sintering (DMLS). The part was designed and built entirely in-house. (Source: SpaceX)
SpaceX says it has been working with 3D printing for almost three years to perfect the technology for flight hardware. Late last year, the company 3D printed a SuperDraco engine chamber made of Inconel, a high-performance super alloy, using direct metal laser sintering (DMLS). The part was designed and built entirely in-house. The company also successfully fired the engine chamber at full thrust, which is 16,000 lb per engine. Now, SpaceX is testing these engines in its crewed spaceflight program. Using 3D printing reduced lead-time by an order of magnitude compared to traditional machining: from first concept to first hot-fire test took slightly more than three months.
Last May, SpaceX completed qualification testing for the SuperDraco, including multiple starts, extended firing durations and extreme off-nominal propellant flow and temperatures. If necessary, each SuperDraco can be restarted multiple times. They can also deep throttle, which gives astronauts huge amounts of power as well as high precision. SpaceX said that during the hot-fire test, the SuperDraco engine was fired in two different profiles: launch escape and landing burn, and successfully throttled at thrust levels between 20% and 100%. The chamber itself was fired more than 80 times during hot-fire.
The eight engines in the Dragon Version 2 launch escape system will produce up to 120,000 pounds of axial thrust to carry astronauts to safety if an emergency occurs during launch. The launch escape system also enables astronauts to land the spacecraft, using propulsion, with the pinpoint accuracy of a helicopter. This makes the Dragon Version 2 spacecraft completely and rapidly reusable, and capable of being refueled and reflown multiple times. Later this year, SpaceX will fly SuperDracos in a demonstration of the launch escape system.
SpaceX's first 3D-printed rocket engine part already launched on the Falcon 9 rocket in January for the THAICOM 6 mission. One of the rocket's Merlin 1D engines contained a 3D-printed main oxidizer valve (MOV) body. The valve operated correctly with high-pressure liquid oxygen, withstanding high vibration and cryogenic temperatures. The printed valve body has better strength, fracture resistance, and ductility than a part made with traditional casting, as well as lower variability in material properties. It was also a lot faster to make, being printed in two days instead of several months. The valve is now qualified to fly on all Falcon 9 flights.
Without emoticons, it's hard to tell in this chat format when people are joking, Lou. I had a feeling you were being serious and humorous all at once. If you look at the changes in what's available in desktop printers over the last 2-3 years, it's been quite amazing. Metals 3D printing poses challenges that are a lot harder to solve for desktops than plastics, such as temperature and quality. So I think that's going to take a lot longer. But I bet it's going to happen sooner than some people imagine.
Ann, I was being a bit flippant, but you are probably correct. This stuff could be coming very soon. Coupling that with inexpensive and extensive electronics, and we could see some very cool hobyist stuff.
Pretty amazing, isn't it Cabe? But this isn't the first 3D printed rocket engine/reocket engine part we've reported on recently. NASA and Aerojet Rocketdyne are also in the running. Of course, they've all got much better quality equipment than what's available in desktop machines.
Lou, thanks for your comments coming from within the aerospace industry. I agree, it will be something else entirely when desktop machines can do what highly specialized aerospace-grade 3D printers are doing now. But that is the typical path in technology development so it's probably coming sooner than we expect.
Ann, this is a great use of 3D printing. These are complex parts and hard to machine. In addition, if the tooling is lost (which happened for most NASA programs over time) then it is difficult to make new copies of the engines if a future need arises. I am thinking about the time after the Challenger accident, when we could have used the Saturn V to get into space quickly. The only problem is that the program had been shut down and it would have been almost impossible to restart given the state of things. This is another advantage of 3D printing, in that you only need the CAD files.
The next thing is to print one of these on my home 3D printer. That would make a great model rocket.
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