As 3D printed rockets, car parts and even homes begin to hit the market on Earth, L3Harris Technologies says it is aiming to leverage the International Space Station (ISS) National Laboratory in its search for durable materials to 3D print satellite components. Before 3D printed materials can be used to build more sustainable and efficient parts for spacecraft, they must be tested to ensure they can withstand the harsh environment of low Earth orbit (LEO).
Among the payloads launching on SpaceX’s upcoming 27th Commercial Resupply Services (CRS) mission is a project to test an L3Harris-designed 3D printed radio frequency (RF) circuit and various 3D printed material samples. The project is a continuation of a 2021 experiment on the ISS that collected two months of data. This time, L3Harris says it will also test photonic material for a new technology called photonic integrated circuits. Used for satellite communications and similar to computer chips, these circuits utilize light instead of electrons in conventional electronics, similar to how light carries information in fiber optic cables for phone and internet data.
“We’re excited to test the 3D printed materials for six months and compare the new results with previous ISS experiments and ground tests,” said Arthur C. Paolella, senior scientist and technical fellow with L3Harris. “The ability to 3D print materials for use in space opens up new possibilities for satellite design and construction while making spacecraft manufacturing more cost-effective and efficient.”
Eduardo Rojas, director of the Wireless Devices and Electromagnetics Laboratory at Embry Riddle Aeronautical University, and his students are assisting with the experiment. The investigation will utilize the MISSE Flight Facility (owned and operated by ISS National Lab Commercial Service Provider Aegis Aerospace) mounted to the exterior of the ISS. There, the material samples will experience the harshness of space in the ultimate test of their durability. The materials will be subjected to various conditions, including extreme temperatures and radiation, to validate their performance in the same environment where the satellites will operate.
“While we can test the durability of these materials on Earth against one or two of these factors at a time, on the ISS, we can test every potential hazard — and all at once,” Paolella said.
The results will be used to develop and refine the materials to incorporate them into satellite manufacturing, says Paolella. Photonic integrated circuits for optical communications between satellites and the ground could one day reduce the size, weight, and power of communications systems and increase the amount of data possible to transmit from satellite to satellite, he said. L3Harris continues to explore other potential space-based applications for 3D printed materials, including in-orbit manufacturing and repair.