UltraGRAIN controls the grain structure of metallic components directly within the additive process. The international ICON research project of the Fraunhofer-Gesellschaft, Germany, conducted with Australian partners, has shown that microstructures can be adjusted locally and in a targeted manner during laser-based metal deposition. The project involved Fraunhofer Institute for Material and Beam Technology IWS, Fraunhofer Institute for Additive Manufacturing Technologies IAPT, and RMIT University in Melbourne. Funded through the Fraunhofer ICON program and by Australian partners, the consortium developed a scalable approach for industrial applications. The project concluded on February 25, 2026, with a final partner meeting in Dresden.
At the heart of UltraGRAIN lay a central question in additive manufacturing: How can components be produced so that their internal structure matches the intended function? The project demonstrates a practical path to no longer leaving microstructures to the process itself but instead defining them precisely where strength, service life, or load-bearing capacity matter most. For industrial users, this opens new degrees of freedom in the design of additively manufactured metal components.
UltraGRAIN first used ultrasound to influence grain formation, then shifted to pulsed-laser excitation. This method operates without contact, works with any geometry, and suits industrial environments. Pulsed laser-induced direct melt-pool excitation can be integrated into existing systems for laser-based directed energy deposition (DED-LB).
It scales far better than conventional ultrasonic methods and remains stable even for complex geometries. In demonstrator components, the project achieved a reduction in the size of up to 75 percent. This capability enables, for the first time, the direct creation of microstructurally and functionally optimized zones during the manufacturing process. “We deliberately chose a solution that works in industry,” explains Jacob-Florian Mätje, main contact for the project and research assistant at Fraunhofer IWS. “Laser-based excitation allows us to set microstructures precisely where they make a real difference to component performance.”
A key distinguishing feature of UltraGRAIN lies in the close integration of laser processing, simulation, design methodology, and materials development. Fraunhofer IWS integrated pulsed laser-induced melt pool excitation into real DED-LB systems and validated the technology under industry-relevant conditions. Fraunhofer IAPT developed methods for segmentation, path planning, and parameter assignment for components with locally varying microstructures. RMIT University complemented the project with multiscale modeling, simulation-based process design, and optimization concepts in the sense of integrated computational materials engineering.
UltraGRAIN connects digital models and real manufacturing into a continuous approach. The close coupling of simulation-based process design and additive manufacturing accelerates transfer into industrial applications and strengthens international collaboration in advanced manufacturing.
UltraGRAIN’s results are relevant for industries that demand high mechanical performance and long component service life. These include mechanical engineering, aerospace, energy technology, turbomachinery, automotive manufacturing, and tool and mold making. Companies benefit from components whose microstructure aligns precisely with load and function. This approach reduces material use, extends service life, and improves the overall property profile of the component. UltraGRAIN has demonstrated that the build process can enable precise adjustment of this microstructure.
Image – The international research project demonstrated that microstructures and grain structures can be adjusted locally and in a targeted manner during laser-based directed energy deposition. Electron backscatter diffraction (EBSD) orientation maps show the differences between (left) without and (right) with pulsed-laser-induced melt pool excitation.
For more information:
Fraunhofer Institute for Material and Beam Technology IWS
https://www.iws.fraunhofer.de/en.html
