Move Over Plastic: Desktop 3D Printing in Metal and Ceramics

3D Printing Metal and Ceramics

These spur gears – seen here with a euro cent coin for scale – have been produced in stainless steel to a space standard of quality using nothing more than an off-the-shelf desktop 3D printer. Credit: TIWARI Scientific Instruments

These spur gears – seen in the image above with a euro cent coin for scale – have been produced in stainless steel to a space standard of quality using nothing more than an off-the-shelf desktop 3D printer.

ESA-supported startup TIWARI Scientific Instruments in Germany has developed a technique allowing low cost 3D printing using a variety of metals and ceramics. Ordinarily producing precision parts in such high-performance materials would be costly in both time and money, but the company can instead shape them using standard 3D printing techniques.

TIWARI’s ‘Fused Filament Fabrication’ (FFF) print process uses thermoplastic filaments that are embedded with particles of the metal or ceramic the part is to be made from. Once the printing is finished, the part – known as a ‘green body’ – is put through a thermal treatment to eliminate the plastic, leaving behind a metal or ceramic item.

3D Printed Bottle Opener

This working bottle opener has been 3D printed in stainless steel to a space standard of quality using nothing more than an off-the-shelf desktop 3D printer. Credit: TIWARI Scientific Instruments

“Once this plastic-containing body goes through this treatment then what is left behind is pure metal or ceramic,” explains ESA non-metallic materials and processes engineer Ugo Lafont. “The result is high-quality parts with very good physical properties. So this cheap, simple technique can offer us additional part manufacturing capability for space applications with an expanded pallet of materials.”

Test parts made using the FFF process in stainless steel and titanium metals, as well as aluminia ceramic and silicon carbide ceramics underwent a full-scale campaign of non-destructive and destructive testing at the Materials and Electrical Components Laboratory of ESA’s ESTEC technical center in the Netherlands, assessing their added value and suitability for space.

3D Printed Aluminia Parts

These parts – seen here with a euro cent coin for scale – have been produced in aluminia ceramic to a space standard of quality using nothing more than an off-the-shelf desktop 3D printer. Credit: TIWARI Scientific Instruments

One surprise has been that the parts possess enhanced mechanical performance compared to their conventionally made equivalents – for instance, stainless steel can be elongated to a previously unachievable 100% without breaking.

TIWARI is a startup hosted at ESA’s Business Incubation Centre Hessen & Baden-Württemberg in Germany, specializing in instruments for thermal characterization of materials as well as 3D printing of high-performance metals and ceramics.

“Desktop 3D printers have become cheaper and cheaper in recent years and there’s been a lot of interest in mixing in materials with traditional print stock,” explains company founder Siddharth Tiwari. “But our company’s particular focus has really been on understanding the process thoroughly and investigating the kind of thermal and mechanical properties we can achieve.

3D Printed Silicon Carbide Filter

This filter – seen here with a euro cent coin for scale – has been produced in silicon carbide to a space standard of quality using nothing more than an off-the-shelf desktop 3D printer. Credit: TIWARI Scientific Instruments

“So this test campaign with ESA was part of our strategic planning from the start, to help commercialize the technology. At a time when other companies are still speculating about the properties achievable with 3D printed parts we have tested and qualified not one but four separate materials.

“This means we’ve ended up with a database no other company possesses, thanks to being able to make use of ESA resources – which otherwise would have cost many tens of thousands of euros. And the fact that our parts make the grade for space helps us in terrestrial markets too.”

The collaboration between the ESA and TIWARI on the testing and evaluation of the 3D printed parts has been facilitated by ESA’s Technology Transfer and Patent Office.

“We hope to offer an affordable solution to a market often put off by the high prices associated with additive manufacturing,” adds Siddharth Tiwari. “Our company offers one of the best price-to-performance ratio in the market, and we have launched an online estimation tool allowing customers to check how much the customized parts they require will cost.”     

7 Comments on "Move Over Plastic: Desktop 3D Printing in Metal and Ceramics"

  1. Will these materials be made available to the 3d printing hobbyist?

    • I highly doubt that it would work out or be cost effective. You’d need highly specialised equipment for phase 2 of the manufacturing process to fuse the materials before the plastic melts.

  2. Benoît Côté | November 26, 2020 at 2:29 pm | Reply

    Typo: it’s “palette” in “with an expanded pallet of materials.”

  3. This was clearly not a space standard of journalism. What in the world is “space standard?” If you mean aerospace standards then say that, and it might be nice if you specify which aerospace standards to which you are referring.

  4. The Virtual Foundry has been doing this since 2014. They currently have 14 products in their store. http://www.TheVirtualFoundry.com

  5. That’s interesting but I have to admit that some composite materials are reliable as metal if not even more. Anisoprintig technology https://anisoprint.com/ is already used by large industrial manufactures worldwide. I found some impressive examples of this technology on the internet.

  6. How do the metal/ceramic particles bond to each other if the plastic is removed? This is akin to putting them in water and evaporating off the water, unless the second part of the process is at an extremely high temperature/pressure or both. While it is possible to print it with a normal printer, the article is misleading because it doesn’t outline that to complete the process a forge is required (with specialised materials/or manufacturing methods) to ensure the metal fuses together before it’s plastic support melts. There would be very few hobbiests or makers with access to a forge and less still who could manufacture in this way.

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