Titanium Powder Used to 3D Print Automotive Parts
To date, the 3D printing revolution has focused on the use of plastics – cheap printers’ feedstock and high throughput. Until now 3D printing with metal has been prohibitively expensive because of the cost of titanium powders which currently sell for $200-$400 per kilogram.
UK based company Metalysis have developed a new way of producing low-lost titanium powder, which could potentially herald a new era in additive layer manufacture that will see greater use of titanium in components across the automotive, aerospace and defence industries.
The Renishaw 3D printer, which is based at the Mercury Centre within the Department of Materials at the University of Sheffield, made the parts, demonstrating the feasibility of producing titanium components using additive layer manufacturing.
The Metalysis process is touted to be cheaper and environmentally benign compared with existing titanium production methods, such as the energy-intensive and toxic Kroll process. Currently, the manufacture of titanium powder involves taking the metal sponge produced by the Kroll process, which is then processed into ingot billets, melted into bar form and finally atomised into powder – a costly and labour-intensive four-step process.
Metalysis takes rutile and transforms it directly into powdered titanium using electrolysis, which is cost-effective and thus essential to the supply chain; the low-cost titanium powder can be used in a variety of new applications whereas previously the metal has been excessively expensive for use in mass production of lower value items.
3D printing brings further cost benefits by reducing waste because the current means of production is subtractive, as components are shaped out of metal billets, which wastes a huge amount of material. Metalysis’ low-cost titanium powder enables additive manufacturing with its metal powder, thereby reducing the quantity of material required.
Professor Iain Todd, Director of the Mercury Centre explained: “There are significant challenges to overcome in taking emerging technologies like metallic 3D printing from the lab to production, not least of which is material cost. The step-change in terms of process economics that this material breakthrough provides takes us ever closer to the time when 3D Printing of metals such as titanium is considered the norm rather than exceptional.”
In a further development, the titanium powder used to manufacture the automotive parts is also a world-first, as Metalysis has created titanium from rutile sand, a naturally occurring titanium ore present in beach sands, in one single step. The use of this inexpensive and plentiful feedstock for titanium manufacture will reduce the cost of titanium production, allowing its increased use.
University of Sheffield Vice-Chancellor, Professor Sir Keith Burnett, said: “Most people associate 3D printing with plastic parts, but, with Metalysis’ titanium powder, we have for the first time demonstrated its potential in the manufacturing of metal parts. This is potentially a significant breakthrough for the many sectors which can benefit from its low-cost production.”
In addition to titanium, Metalysis is developing tantalum powder and will use its technology to produce a wide range of specialist metals (including rare earths). Furthermore, innovative new alloys can be produced because the process is conducted in the solid state, hence metals with significantly different densities or melting points can be alloyed, says Metalysis. Metal powders created by this new process can be engineered to get particle size and distribution correct for a range of PM applications.
Dion Vaughan, CEO of Metalysis added: “Metalysis’ rutile-derived titanium powder is produced at lower cost and is suitable for 3D printing so that manufacturing metal components becomes more economical.
“The Metalysis process could reduce the price of titanium by as much as 75 per cent, making titanium almost as cheap as specialty steels. We believe that titanium made by the Metalysis process could replace the current use of aluminium and steel in many products. This world-first for a titanium 3D printed component brings us a step closer to making this a reality.”
Source: University of Sheffield