Our mission is to advance production technology, making it not only digitally connected, but also even more economical, precise and future-proof. We want to make manufacturing – including its upstream and downstream processes – more efficient. In doing so, we will help build the industrial world of tomorrow. We are the market and technology leader in machine tools and lasers for industrial manufacturing, and are shaping almost every sector with our innovations. Our software solutions are paving the way for the smart factory, and we are facilitating high-tech processes in industrial electronics.
TRUMPF was founded in 1923 as a series of mechanical workshops, and has since developed into one of the world's leading companies for machine tools, laser technology, and electronics for industrial applications. In the 2019/20 fiscal year, the company generated a turnover of 3,487.7 million euros with 14,325 employees.
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Poster + Pitch
Dr. Sabrina Vogt, TRUMPF Laser- und Systemtechnik GmbH, GERMANY
Mr. Marco Göbel, TRUMPF Laser- und Systemtechnik GmbH, GERMANY
Mr. Florian Hermann, TRUMPF Laser- und Systemtechnik GmbH, GERMANY
Laser Metal Deposition (LMD) is an often-used technology for high quality repairs, wear- and corrosion protection as well as modifications on existing parts. With build-up rates of up to 500 cm³/min this technology can be used for fast, near net shape build-ups for e.g. applying optimized structural reinforcements to increase functionality or resistance to high local stress loads. A new variant of the well know LMD process is the High-Speed Laser Cladding, enabling very high feed rates between 100-500 m/min and locally adjusted layer thicknesses between 50-300 µm per layer.
Using High-Speed Laser Cladding, a laser beam is melting powder particles, which are fed coaxially into the laser beam, before these particles hit the substrate. Using a laser as heat source, heat input into workpiece can be minimized and fast thermo cycles can be achieved. This allows for a very low dilution of additive into workpiece – typically < 10µm – and high feed rates between 100-500 m/min. Layers generated by this process can be locally adjusted in thickness between 50-300 µm per layer. Since each layer is metallurgically bonded to the substrate or the layer before, multi layers or multi-material approaches are feasible. This feature can be used to achieve functionally graded material or to apply metallurgically bond coatings on hard-to-weld alloys such as cast iron.
By use of the afore mentioned unique process features, new and in properties tailored coating systems become feasible. High-Speed Laser Cladding is already used for a broad range of applications: wear resistant layers on small valves, corrosion resistant coatings for very long shafts used in hydraulic systems, etc. Even additive manufacturing of rotational symmetric geometries – such as seal lips or a shoulder on a shaft – is feasible.
For automotive industry LMD and High-Speed Laser Cladding are already being investigated for a broad range of applications. In the presentation we will highlight use cases from R&D and future production: the coating of brake discs is addressed by use of the High-Speed Laser Cladding.
The presentation we will show recent results for the afore mentioned use cases, using new system technology and process parameters. Additionally, potential key figures related to production costs and -time are discussed, if LMD or High-Speed Laser Cladding technology is implemented into an automotive production environment for brake discs.
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