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‘Dynamic Beam’ Doubles Working Speed

Laser experts from Germany and Israel are jointly testing a novel laser for industrial use at the Fraunhofer Institute for Material and Beam Technology (IWS) in Dresden, Germany. The system is based on the ‘Coherent Beam Combining’ (CBC) method, which is still new for high-power lasers. The 13-kilowatt laser can generate different energy distribution patterns particularly quickly during operation and thus process even demanding high-tech materials very precisely and quickly. The Fraunhofer researchers intend to make the innovative laser technology from Israel available to companies worldwide in the near future. Within a European network project, Fraunhofer IWS is already investigating the beam shaping, which is accelerated by a thousand times, for the first time for additive manufacturing.

The ‘Dynamic Beam’ laser from Israel has been installed at Fraunhofer IWS.. The institute is thus the first research facility worldwide to employ such a laser solution. Together with the project partner Civan Lasers, the scientists hope that the testing will provide new application scenarios. “This laser will push the limits of materials processing, for example in medical technology and aerospace,” predicts Dr. Andreas Wetzig, who heads the Cutting and Joining technology field at Fraunhofer IWS. He refers to the research project ‘ShapeAM’ within the European network program ‘M-era.Net’, in which this new laser will play a central role and which started in July 2021.

Thousand Times Faster

In use is Coherent Beam Combining, in which the ‘Dynamic Beam Laser’ from the Israeli company Civan Lasers combines tens of individual beams into a powerful laser beam with high quality. Through small phase shifts (Optical Phased Array = OPA) of the wave troughs and peaks in the partial beams, the laser can quickly generate completely different energy distribution patterns in the resulting processing laser beam: While a classic laser releases most of its energy only in the center of the beam, the system from Israel can generate energy patterns on the workpieces for instance in the form of a ring, a figure eight or a horseshoe. In principle, this was already possible in the past with beam-deflecting optics or fast oscillating mirrors. But even the fastest oscillating mirrors still need milliseconds to realign the energy patterns in the beam. The ‘Dynamic Beam Laser’, on the other hand, accomplishes this a thousand times faster, within microseconds.

This speed makes it possible for the first time to use dynamic beam shaping for additive manufacturing of metals. As part of ‘ShapeAM’, researchers are testing the new CIVAN system to achieve improved material properties. Specifically, the aim is the additive manufacturing of titanium and aluminum alloys, such as those needed for space components, implants and lightweight components for mobility. In doing so, the partners plan to use dynamic beam shaping to eliminate defects and thus achieve higher quality 3D printing results. Dr. Eyal Shekel, CEO of Civan, is excited about the project: “ShapeAM makes it possible for us to explore the benefits of dynamic beam shaping in metal additive manufacturing.” Dr. Elena Lopez, department head of Additive Manufacturing at Fraunhofer IWS, adds: “We plan to use novel beam shapes and control frequencies that are not achievable with other methods to overcome challenges in crack-sensitive materials.”

The tests at the Dresden institute are intended to determine the possibilities and limits of the ‘Dynamic Beam  Laser’. Basic tests with various beam profiles, materials and processes are initially planned. After that, the researchers will evaluate concrete applications, such as how well the system can cut, join or additively manufacture diverse workpieces from materials and material composites that are otherwise difficult to process.

‘Dynamic Beam’ Doubles Working Speed

It is already predictable that the new laser will allow faster and more precise control of the melt pool dynamics in many additive and joining processes – and not only across the surface, but also in depth. Fraunhofer IWS also expects advantages in laser cutting in terms of burr-free cuts with high edge quality – at twice the working speed compared to conventional fiber lasers.

The test phase in Dresden will show whether the new laser will also meet these expectations in practice. In any case, the quality and speed advantages that are already becoming apparent make the technology highly interesting for use in metal-working industry, medical technology and electromobility, as well as in aerospace industry.

For more information: www.iws.fraunhofer.de

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