24th May 2017
With the recent launches of the Telkom 3S, SGDC and KOREASAT-7 satellites, plus satellites in the Iridium Next constellation, Thales Alenia Space has now sent into orbit 79 metal parts made by additive manufacturing (3D printing) and 350 polymer tube supports for chemical propulsion systems.
The story started two years ago, back in April 2015, with the first 3D-printed aluminum antenna support, sent into orbit on the TurkmenAlem MonacoSat satellite. Since then, all of the company’s telecommunications satellites use lightweight 3D-printed antenna supports and reflector fittings.
In mid-January 2017, with the successful launch of the first Iridium NEXT satellites, Thales Alenia Space also sent into orbit satellites with propulsion system tube supports, the first flight application of thermoplastic additive manufacturing.
The next step for Thales Alenia Space will be the manufacture of larger and larger parts using this process, such as dual antenna supports for a new telecom satellite, to be launched shortly. These parts measure 480 x 378 x 364 mm, a real challenge from the manufacturing standpoint. “Our development efforts are now focusing on integrating several functions in a single part, such as mechanical, thermal and radio-frequency functions,” explains Florence Montredon, Additive Manufacturing Technology Development manager at Thales Alenia Space. “The challenge lies as much in the design process as in the production technique per se.”
Additive manufacturing provides real benefits for spaceborne products. For example, it allows designing and manufacturing single-piece structures, as opposed to a conventional manufacturing approach, which entails the assembly of several different parts to form a structure. The upshot is a significant reduction in weight, along with cost savings. The tube support perfectly illustrates the ability to replace several parts by a single-piece structure, thanks to additive manufacturing, while also introducing new functions.
Additive manufacturing also means greater design freedom and the absence of tooling, which makes it the perfect technology for complex parts – with curves, holes or cavities – that are produced in small runs or on a one-off basis.