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Laser metal deposition as an additive manufacturing method

Laser metal deposition (LMD)

Laser metal deposition is a generative manufacturing method for metals. Internationally, it is generally known as "laser metal deposition", abbreviated to LMD. People also talk about "direct metal deposition" (DMD) or "direct energy deposition" (DED). The process is easy to explain. The laser creates a weld pool on the component surface. Metal powder is automatically added via a nozzle. Beads that are welded together are formed, resulting in structures on existing base bodies or entire components. The process is used in industries such as the aviation and aerospace industry, energy technology, petrochemicals, the automotive industry, as well as medical technology. TRUMPF customers benefit from a wide range of lasers and laser systems, process expertise, and services for numerous applications. This means LMD technology can also be combined with laser welding or laser cutting.

Higher build rates

Laser metal deposition creates rough and very fine structures – both with high build rates in comparison to other additive processes.

Material range

Several powder containers can be used in the process, which enables you to develop custom alloys to suit your requirements. Sandwich structures can be created by combining different materials.


Laser metal deposition enables 3D structures to be applied to existing, uneven surfaces, meaning changes to geometry can easily be made.

Simple change of materials

Laser metal deposition makes it possible to change between different materials in a work process with ease.

The laser metal deposition process explained briefly

Process diagram - laser metal deposition

First of all, the laser beam heats up the workpiece locally, creating a weld pool. Fine metal powder is sprayed directly into the weld pool from a nozzle in the processing optics. It melts there and combines with the base material. A layer of approx. 0.2 to 1 millimeter remains. If required, numerous layers can be built upon each other. Argon is often used as the shielding gas. To apply lines, areas, and shapes, the automatically controlled processing optics move over the workpiece. An intelligent sensor system ensures that the layer thickness is even everywhere at all times.

The areas of use are as diverse as the technology itself

Laser metal deposition is more than 3D printing. The diverse areas of application of this innovative manufacturing method range from the coating and repair of components, to joining processes such as the bridging of gaps, right up to the generation of complete components with total creative freedom.

High-speed laser metal deposition (HS-LMD) – coating at high process speeds

High-speed laser metal deposition (HS-LMD) accelerates laser metal deposition significantly. The powdery filler material already comes into contact with the laser light above the weld pool; the laser light heats it almost to the melting point on its way to the component. The particles therefore melt in the weld pool more quickly, and the energy is utilized much more efficiently. This means that the HS-LMD procedure achieves surface rates of over 250 square meters per minute. This is a significant increase compared to "normal" laser metal deposition, as this procedure achieves up to 40 square meters per minute. In addition, much thinner layers can be achieved (thicknesses of 30 to 300 µm). TRUMPF has already been successful in using this procedure, developed and patented by the Fraunhofer Institute for Laser Technology, in series production.

Coating for a durable product

Structures can easily be applied by laser metal deposition to reinforce components locally or to adapt them in terms of geometry. The component underneath can be made of more cost-effective materials. Components can be upgraded or protected against strong mechanical or chemical stresses with a protective layer against corrosion and wear. In comparison to conventional processes such as plasma transferred arc welding or thermal spraying, the workpiece is only subject to low thermal stresses during laser metal deposition, meaning that there is a low risk of distortion. LMD is also much more cost effective due to its high degree of automation and reproducibility.

Generating with freedom

Laser metal deposition opens up wide-ranging design freedom in the individual manufacture of components, above all in comparison to generic press molds. Using laser metal deposition with filler material, completely new structures can be formed, or the shape and surface of existing components can be modified. Large components which do not fit in the build chamber of a 3D printer can also be completely generated in this way.

Repair – for reuse rather than waste

Expensive components with high production costs can easily be repaired using laser metal deposition with filler material, meaning that the part or tool is back in use again fast. In this way, you not only save time from any long procurement and delivery times, but also money. This is due to the fact that it is much more cost effective to repair a component than to buy a new one when it comes to expensive materials such as nickel-based alloys. Design changes can also be made on the component. In comparison to alternative processes such as patching, during which metal plates are attached to the faulty areas, plasma transferred arc welding or classic TIG welding, LMD creates low thermal stresses and is very precise – which guarantees an excellent level of reproducibility.

Welding with filler material – say goodbye to gaps

Laser metal deposition with filler material can also be used as a joining process for welding components that are unsuitable for laser welding. Due to LMD, relatively large gaps can be bridged and components can be welded tightly without any time-consuming preparations. During laser metal deposition, uniform, tight seams are created, which generally require less post-processing. The coaxial powder feed also makes the joining process three dimensional and independent of direction in comparison to wire welding. Different materials such as steel and cast aluminum can also be joined, for batteries for electric motors for example.


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