Maximum Material Thickness
Mild steel
Stainless steel
Aluminium
Copper
Brass
Titanium
1"
1"
1"
.38"
.38"
.16"
Maximum Sheet Size
5 feet in width & 10 feet in length.
Accuracy
Positioning deviation Pa
0.05 mm / 0.00196 inch
Maximum position range Ps-max
0.07 mm / 0.00275 inch
Smallest possible increment
.001 mm / 0.000039 inch
The positioning accuracy specifications are based on the entire workinging length. The positioning accuracy is approved at the Trumpf production facility in accordance with VDI/DGQ 3441.
Burr Height Example
30 µm at a sheet thickness
of 3 mm / 0.12 in.
Extended material range
The TruLaser 1030 Edition not only cuts stainless steel and mild steel, but also processes highly reflective non-ferrous metals such as copper and brass. As the TruDisk laser is relatively immune to back-reflections, copper can be processed using nitrogen. As a result, the conductivity of this material is retained.
TruDisc 6001
A Solid-State Laser
The laser active medium is a thin crystal disk made from Yb:YAG (Ytterbium-endowed yttrium aluminum garnet). The disk laser is pumped with the help of diode lasers. The laser beam is generated in the crystal disk and leaves the cavity through a hole at the center of the parabolic mirror.
The TruDisk can be used in pulsing mode as well as in CW mode thanks to its diode pumped simulation.
1 Deflection mirror
2 Parabolic mirror
3 Output coupling mirror
4 Decoupled laser beam
5 Pump laser beam
6 Rear mirror
7 Crystal disk, laser active
medium
8 Cavity
Advantages of the solid state laser:
■ Very good beam shape due to a small opening angle with a small beam waist.
■ High levels of efficiency.
■ High beam quality.
■ No laser gas required.
■ Beam guidance through a laser light cable.
■ Low power consumption.
■ Free of wear parts.
■ Maintenance-free.
Nanojoints vs Microjoints
Regardless of the geometric intricacies of your components, nanojoints enable a dependable and resource-efficient machining process. This technology leads to enhanced productivity, superior part quality, and simplified component extraction, thanks to minimal attachment within the scrap framework. Often, there's no need for post-processing. In contrast, microjoints affix the component to the scrap framework using a tab spanning the entire sheet thickness. This frequently results in visible damage to contours, necessitating time-consuming component refinishing. Removing parts is more challenging with thin sheet thicknesses and nearly impossible with mid-range sheet thicknesses when using microjoints.
All Fiber Trumpf TruLaser 1030
