After 20 years of iteration on the same basic additive-manufacturing technologies for metal, a new wave of innovation is emerging. Lower-cost, safer processes are replacing the old ways of doing things, offering vastly different material properties through resolution, surface quality, and design freedom.
But first, a little 3D-printing history: Since the invention of the selective laser melting (SLM) process at the Fraunhofer Institute in 1995, metal additive manufacturing has relied primarily on three processes: the first, and most common, selectively melts a cross-section of a metal powder with a laser or electron beam, layer by layer, to build up a metal object in a range of alloys. The second, a lens/directed-energy approach, blows the metal powder into the path of the laser. And in the third, a powder-bed approach, the metal powders are glued together, then sintered to achieve metal-like properties.
As transformative as these processes have been in enabling custom and complex parts, they aren’t perfect: Using metal powder for additive manufacturing means handling potentially dangerous materials, and thermal-distortion issues have seen many prints relegated to the bin of broken dreams.
Enter the new wave of metal printing with XJet, Desktop Metal, NanoCore Technologies, Markforged, 3DEO, Digital Alloys, Vader Systems, and a few more startups in stealth mode. These companies are forgoing the powder-based approach for one in which the metal powder is either encapsulated in a carrier liquid or embedded in a filament, printed into a fragile “green body,” and then sintered in a furnace to achieve final results.
XJet’s founders are the team behind Objet, the first polymer multimaterial 3D printer (now merged with Stratasys) and the first wide-format inkjet printer (acquired by HP). Calling its technology “nanoparticle jetting,” XJet essentially outfits a military-grade inkjet printer with thousands of nozzles that deposit nanoparticles of metal (or ceramic) in a liquid carrier that evaporates on impact with the support bed or preceding layer. These nanoparticles allow for a much finer resolution and a secondary support material—doing away with the dreaded support structures. Also gone are the thermal distortion and residual stress that occur during the printing and cooling of powder-bed processes. What remains is the potential for multimaterial metal 3D printing with complex gradients.
Desktop Metal, Markforged, Digital Alloys, and Vader Systems take an approach more similar to the fused deposition modeling (FDM) developed by Stratasys: extruding material from a filament onto the bed of the 3D printer. One major benefit of the FDM approach is the handling of the material feedstock, where the metal is contained within a binding material; that binding material could be a polymer coating on a filament, a pastelike slurry, a metal rod, or welding wire. Not using a powder process also opens up a greater range of materials already available in bulk, either as wire for the welding industry or those used in metal injection molding (MIM).
Markforged’s Metal X 3D printer uses atomic diffusion additive manufacturing (ADAM) with traditional MIM powders encapsulated in a polymer that is melted away during the secondary sintering process; the process creates a part with 99.7 percent density. The Metal X also has a laser sensor in the print head that feeds data back to Markforged’s cloud-based Eiger software, which enables monitoring of the part for dimensional accuracy during the build process.
Real-time feedback from a machine could be incredibly powerful for recognizing part geometries that may fail, predicting problems before they occur, and reducing waste of both material and time. This could also be fed into generative-design tools so that the software produces part designs—specifically for that process—that will not fail.
Desktop Metal also offers hardware as a service (HaaS), which means customers can secure a machine for only a few thousand dollars a month—less than the cost of a full build in many metal powder-bed machines. This lowering of the cost barrier will make metal additive manufacturing more financially viable for many industries and use cases not served by current powder-based processes.
As it turns out, lasers that melt metal are expensive. The average price of a laser-based machine starts at about $600,000 and can go up to a couple of million, not including the postprocessing equipment required. The price for these new types of metal 3D printers is closer to the $100,000 range, including postprocessing equipment—another win for the new metal upstarts.
Powder-based processes still have their place for many applications that require the laser-focused resolution, architected material properties, and design complexity that that are not yet possible in many of the new additive manufacturing technologies. Which approach is preferable depends on the right process for the application, based on material properties, resolution, design freedom, speed, and price. But the new processes do open up more options for designers and engineers to choose from—because, when it comes to metal, sometimes the situation calls for Black Sabbath and other times Pantera (but never Korn).