Cost-effective titanium forming
20 Oct 2012
Titanium as a material offers excellent properties, though it is costly and time-consuming to form. Fraunhofer researchers are now giving this multi-purpose metal another chance. They are presenting an economical forming technology for car exhaust systems at the EuroBlech trade fair from 23 to 27 October in Hannover, Germany.
To all intents and purposes, nothing stands in the way of titanium in terms of becoming a first-choice industrial material. It is a practically unlimited resource; it is stable and lightweight, but also extremely malleable as well as corrosion and temperature resistant. Nevertheless, this white silver lustrous metal remains in the shadows of steel, chrome, nickel and aluminum when it comes to manufacturing.
The reason for this is that efficient metal forming processes such as deep drawing or hydroforming can only be used in a very limited way. ''Titanium tends to adhere to the forming tools. This leads to major damage which can cause components to fail in the worst case. This effect is amplified by the extremely high temperatures of up to 800 °C, at which titanium has to be formed'', explains André Albert, group leader for media based forming technologies at the Fraunhofer Institute for Machine Tools and Forming Technology IWU in Chemnitz, Germany.
Premiere at EuroBlech
In collaboration with his colleagues at the Fraunhofer Institute for Surface Engineering and Thin Films IST in Braunschweig, Germany, he has developed a new technology for hydroforming titanium car exhaust systems at elevated temperatures. This new method enables forming to be undertaken in a single process stage. Researchers are now presenting the initial results of the joint project at the EuroBlech trade fair (Hall 11, Booth B06) from 23 to 27 October in Hannover, Germany.
Up until now, a minimum of three stages were necessary utilising intermediate heat treatments which partially required processing at different locations. The scientists have now developed a process and custom tool which can withstand temperatures of over 800 °C. ''Forming titanium at room temperatures leads to severe cold work hardening of the processed pipe. In order to prevent cracking, the metal requires frequent treatment by means of recrystallisation processes. This leads to extremely complex multi-stage forming processes which are not economically viable in large-volume production of exhaust systems. This microstructural change can be avoided at extremely high temperatures'', explains Albert.
The approximately 1.40 x 1.20 meter forming tool is manufactured from high-performance materials such as nickel-base alloys which remain stable at temperatures over 800 °C without oxidising. A special coating, just a few micrometers thick prevents titanium from adhering to the tool, which can lead to component cracking and severe damage to the surface.