Aachen, Germany – Up until now, it was not possible to use selective laser melting (SLM) on copper alloys. Now, however, research scientists at the Fraunhofer Institute for Laser Technology (ILT) here have solved the technical problems that prevented this by enhancing the technique. The new method opens up new possibilities, for example, in plastics processing.
|Tool insert with internal cooling channels made of Hovadur (R) K220 produced using the SLM technique. Courtesy: Fraunhofer Institute for Laser Technology ILT|
Rapid manufacturing is making triumphant progress in industrial production as it enables digitized design engineering data to be directly and quickly translated into workpieces. In this context, SLM is particularly suitable for producing metal components of complex shapes that cannot be manufactured using conventional technology or can only be produced at very high cost. In the InnoSurface project, which is funded by the German Federal Ministry of Economics and Technology (BMWi), a research team at Fraunhofer ILT has succeeded in modifying the SLM process to make it suitable for copper materials.
In SLM, the workpiece is built up layer by layer on a platform from powder material. Basically, the process functions like a printer working in three dimensions. Directed by the computer-generated design data for the planned workpiece, the metal powder is deposited in layers and then melted at the required points by a laser beam. As a result, it bonds with the already produced part of the object. Material tests have shown that steel or light-metal components produced in this way exhibit the same mechanical properties as conventionally produced parts.
Owing to the high thermal conductivity of copper and copper alloys, however, it has not been possible up to now to use SLM on these materials. Although copper has a lower melting point than steel, it also exhibits lower laser light absorption and higher heat dissipation. As a result, the melting track interrupts, and tiny balls of molten metal form. This creates cavities and thus reduces the density of the component.
“To compensate for the high heat dissipation and the low laser light absorption by the copper during the melting process, we use a 1000-watt laser instead of the 200-watt laser that is currently the norm in SLM,” said project manager David Becker.
To achieve satisfactory results, he chose a laser that produces a particularly even beam profile. Meanwhile Becker and his team modified the entire installation to prevent the high energy input from causing disruptions. For example, they changed the inert gas control system and the mechanical equipment,
“Tests with the copper alloy Hovadur K220 are already showing excellent results,” Becker continued, “with workpiece density reaching almost 100 percent.” The technique is therefore ready for industrial use.
It is the high thermal conductivity of copper and its alloys that makes them suitable for many applications. Inserts of these materials in steel injection molding tools for the manufacture of plastic parts ensure rapid heat removal at critical points. SLM makes it possible to integrate conformal cooling channels in these copper inserts to carry a coolant such as water. Cycle times and warping are reduced by fast and even cooling of the entire tool.
In the near future, the research scientists intend to go a step further and process not only copper alloys but also pure copper to make dense components. The thermal conductivity of pure copper is almost twice as high as Hovadur K220, making for an interesting challenge.
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