Aerospace AMAM for Space

ESA and Fraunhofer show 3D printing and milling of the Athena X-ray observatory’s optic bench

Stay up to date with everything that is happening in the wonderful world of AM via our LinkedIn community.

Twin robotic arms work together as part of a project to construct what will be the largest, most complex object ever 3D printed in titanium: a test version of the 3-m diameter ‘optic bench’ at the heart of ESA’s Athena X-ray observatory.

The first multi-axis robotic arm builds up each new layer of metal using a laser to melt titanium powder. The second robotic arm then immediately cuts away any imperfections using a cryogenically cooled milling tool. The bench itself is placed on a slowly moving 3.4-m diameter turntable.

“ESA has teamed up with Germany’s Fraunhofer Institute for Material and Beam Technology for this exploratory activity,” explains ESA materials and processes engineer Johannes Gumpinger. “The final design of Athena’s optic bench is still to be decided, but if it will be built in titanium then its size and complexity is such that it could not be built in any other way.”

Due to launch in 2031, ESA’s Athena mission will probe 10 to 100 times deeper into the cosmos than previous X-ray missions, to observe the very hottest, high-energy celestial objects. The mission requires entirely new X-ray optics technology, with stacks of ‘mirror modules’ arranged carefully to capture and focus high-energy X-rays.

The optic bench aligns and secures around 750 mirror modules in a complex structure with many deep pockets that tapers out to a maximum height of 30 cm. Its overall shape needs to be precise down to a scale of a few tens of micrometers – or thousandths of a centimeter.

“The optic bench’s complexity requires each addition to be milled immediately after printing,” comments André Seidel, overseeing the project at the Fraunhofer Institute for Material and Beam Technology. “Any subsequent modification could risk introducing contamination, weakening the space-quality titanium.

Athena X-ray observatory
This is a prototype 3D-printed and partly machined test item, to investigate methods of producing complex metal parts for space. Note: this image was added to this article on May 31st, 2020.

“Similarly, the entire process has been designed to minimize any risk of contamination. The titanium powder is swept into the laser using the noble gas argon that also prevents any contamination with air. And the milling tool is kept cool using liquid carbon dioxide that evaporates as it warms up, preventing any harmful deposition on the freshly-laid metal surface.”

Precision sensors immediately detect any out of tolerance elements for milling or more extensive repair – including milling away for reprinting. Smaller segments have been manufactured so far, with a 1.5-m diameter demonstrator optic bench set to follow. The full-scale 3-m bench is expected to take about a year to produce.

“It will be a huge task, taking a lot of time and energy,” adds Johannes. “But if we manage it, it will be the largest titanium object ever 3D printed – and the process will be available to manufacture other large parts, potentially in other metals.”

The project is being supported through ESA’s Technology Development Element as part of the Agency’s Advanced Manufacturing initiative, harnessing novel materials and processes for the space sector.

Last month more than 150 experts from all across Europe met at ESA’s technical heart in the Netherlands to share the latest results from ESA Advanced Manufacturing projects covering topics including 3D printing and the latest composite materials as well as friction stir-welding.

Composites AM 2024

746 composites AM companies individually surveyed and studied. Core composites AM market generated over $785 million in 2023. Market expected to grow to $7.8 billion by 2033 at 25.8% CAGR. This new...

Davide Sher

Since 2002, Davide has built up extensive experience as a technology journalist, market analyst and consultant for the additive manufacturing industry. Born in Milan, Italy, he spent 12 years in the United States, where he completed his studies at SUNY USB. As a journalist covering the tech and videogame industry for over 10 years, he began covering the AM industry in 2013, first as an international journalist and subsequently as a market analyst, focusing on the additive manufacturing industry and relative vertical markets. In 2016 he co-founded London-based VoxelMatters. Today the company publishes the leading news and insights websites and, as well as VoxelMatters Directory, the largest global directory of companies in the additive manufacturing industry.

Related Articles

Leave a Reply

Your email address will not be published. Required fields are marked *

Back to top button
Close Popup
Privacy Settings saved!
Privacy Settings

When you visit any web site, it may store or retrieve information on your browser, mostly in the form of cookies. Control your personal Cookie Services here.

These cookies are necessary for the website to function and cannot be switched off in our systems.

Technical Cookies
In order to use this website we use the following technically required cookies
  • wordpress_test_cookie
  • wordpress_logged_in_
  • wordpress_sec

Decline all Services
Accept all Services


Join our 12,000+ Professional community and get weekly AM industry insights straight to your inbox. Our editor-curated newsletter equips executives, engineers, and end-users with crucial updates, helping you stay ahead.