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 Powder Bed - LASERTEC SLM by DMG MORI
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Selective Laser Melting in Powder Bed

LASERTEC SLM: Additive Manufacturing in powder bed

Highlights
  • Up to 12.8 x 12.8 x 15.7 in. build volume
  • Single-, Dual- or Quad-Laser
  • rePLUG powder module for fast material change 
  • CELOS X: Consistent software solution
  • Open system: Individual adjustment of all parameters
Technical data
Max. X-axis travel
11.8 in.
Max. Y-axis travel
11.8 in.
Max. Z-axis travel
13.8 in.
Min. Layer thickness
0.0012 in.
Min. Focus diameter
0.0031 in.
Laser power standard
600 W
Control & software
  • CELOS: The App-based control and operating system
  • Smart Key for different user settings
  • 21,5” Touch Screen mit CELOS
Max. X-axis travel
Max. Y-axis travel
Max. Z-axis travel
Min. Layer thickness
Min. Focus diameter
Laser power standard
 LASERTEC 12 SLM by DMG MORI
LASERTEC 12 SLM
4.9 in.
4.9 in.
7.9 in.
0.0008 in.
0.0014 in.
200 W
 LASERTEC 30 SLM
LASERTEC 30 DUAL SLM
11.8 in.
11.8 in.
13.8 in.
0.0012 in.
0.0031 in.
600 W

Metallic 3D printing at high precision

Selective laser melting (SLM) is based on the so-called powder bedding process. In a build chamber whose size varies depending on the machine, metal powder is deposited layer by layer onto a build plate and melted in a highly localized fashion, based on a CAD model. With each layer, the plate holding the part is lowered, allowing it to gradually grow in height. Once the building process is complete, the unmelted powder is suctioned off and then prepared for reuse. Increasing adoption of the technology has already led to a wider range of materials being available, including various steels and aluminum, cobalt chrome and nickel alloys, as well as copper and titanium.

The size of the build chamber permitting, multiple workpieces can be produced simultaneously. This method of 3D printing becomes even more productive when multiple lasers are used simultaneously. The precision of powder bed machines depends on various factors, including the laser’s focal diameter, the material used, the layer thickness, and the structure of the component. A focal diameter of 80 µm can, with steels, for example, achieve a web width of 0.15 mm. With aluminum, it’s 0.3 mm. Selective laser melting can also achieve extremely fine structures, such as internal cooling channels in tools. Where even higher accuracy is required, specific areas of the component can be post-processed using conventional methods.

The right powder bed machine for every application

DMG MORI’s range of powder bed machines includes the LASERTEC 12 SLM, which features a build volume of 125 × 125 × 200 mm. It has a focal diameter of just 35 µm, allowing for the creation of extremely fine structures. The LASERTEC 30 DUAL SLM has a build volume of 300 × 300 × 350 mm and is equipped with two lasers. As a result, productivity increases by up to 80 percent. With both models, rePLUG makes material switchover fast and uncomplicated. The powder module makes zero-contamination changeover possible in under two hours.

Selective Laser Melting: a quick summary

How does selective laser melting work?

How does selective laser melting work?

With selective laser melting, a component is built up in a powder bed. This means that powder is deposited onto a build plate, where a laser then melts the material based on a CAD model. This process is performed layer by layer, gradually building up a component over time.

What metal powders are available for the powder bedding process?

What metal powders are available for the powder bedding process?

Specialist manufacturers can produce a variety of metal alloys in powder form. Crucial to this process is ensuring that these metal powders have a homogeneous particle size. The size of each metal particle is microscopic, ranging from 15 to 45 µm.

What are the advantages of laser melting?

What are the advantages of laser melting?

Selective laser melting is notable for the high degree of freedom regarding the geometry of workpieces and the high density of the material — around 99.9 percent.