The Dragon capsule, which launched aboard a Falcon 9 v1.1 rocket, is the fourth of SpaceX’s minimum of 12 resupply missions to the ISS. It was carrying 4,885 pounds of cargo, including: the RapidScat instrument, which bounces microwaves off the ocean to measure wind speeds; the Kinetic Launcher for Orbital Payload Systems, for shooting mini satellites out into space; the Bone Densitometer; and the first zero-gravity 3D printer.
The 3D printer, which is part of the 3D Printing in Zero-G Experiment, was created by Californian company Made In Space. I hadn’t heard of Made In Space before, but it seems like it’s a small startup that was created for the sole purpose of sending 3D printers into space. It sounds like the zero-gravity 3D printer is much the same as your usual on-Earth 3D printer — though it has been ruggedized to survive launch pressures, and it went through rigorous safety checks to ensure it can’t harm the astronauts aboard the ISS. In a conventional 3D printer, gravity is typically used to hold layers in place as they’re deposited — but obviously the Made In Space 3D printer can’t do that.
The first Made In Space 3D printer will use ABS thermoplastic to perform additive manufacturing using standard fused deposition modelling — i.e. building objects up layer by layer with molten plastic. The second 3D printer, which is due to go up to the ISS sometime in 2015, will be capable of “higher temperature, stronger plastics” — and perhaps most interestingly, this second printer will be an open platform that other companies and institutions can use, to carry out their own tests of 3D printing in space.
The eventual plan is to install a 3D printer on the International Space Station that can manufacture new and replacement components on an as-needed basis. Additive manufacturing, as long as it actually works in zero-gravity, is perfect for such applications; it’s faster, more efficient, and simply much easier to make the parts that you need on the ISS, rather than repeatedly defeating Earth’s gravity by burning millions of dollars of rocket fuel.
3D printing with plastic is one thing, but the ultimate goal is to perform additive manufacturing with a whole range of materials — most notably, aluminium, and other key metals used in aerospace applications. NASA has spent a lot of time over the last few years working on its additive manufacturing skills — in 2012, it successfully 3D printed a metal rocket engine part. I’m not sure if such 3D-printing-with-metal techniques, such as selective laser melting, could be carried out on the ISS due to safety and power requirements — but I suspect they’re looking into it.
Ultimately, as NASA and other space agencies move towards sending humans to the Moon, asteroids, and Mars, advanced 3D printers are likely to play a key role in humanity’s colonization of the Solar System. We’ve known for a long time that anything we can manufacture off-world — tools, machined components, rocket fuel, water — is a huge, huge step towards long-term human exploration of the cosmos. Sending large amounts of stuff up into space via rockets just isn’t workable — we either have to find another way of getting stuff into space, or we have to make the stuff outside of Earth’s gravity.
We’ll be sure to report back in a few weeks, when the first plastic widgets and doodads are manufactured aboard the ISS.