ultraSURFACE – Achievements

The use of multi-beam optics is already state of the art for laser structuring to increase the throughput of the process. But due to the high demands on the position accuracy of each spot (usually within single digit micrometres), these processes are limited to flat and non-tilted surfaces as well to very small scanning angles from the laser scanner. Curved or tilted surfaces and large scanning angles distort the spot array (cf. Figure 1) and the required position accuracy of spots on the work piece is not achievable anymore. Therefore, a spot position control unit is designed and realized within ultraSURFACE to allow the manipulation of the x-, y- and z position of the individual beam foci on the work piece.

Figure 2 shows the concept for the multi-beam optics: A diffractive optical element (DOE) splits the incoming laser beam into several beams. The beams are identical in size and power and only differ in their angle relative to the incoming beam. A telecentric relay optics focuses the beam into an intermediate focus some distance behind the relay optics. Due to the telecentricity of the relay module, the central rays of the beams propagate parallel to each other behind the relay. A mask may be placed behind the relay to block unwanted diffraction orders but is not required as the DOE can be designed in such a way that only desired diffraction orders are created. A spot position control unit, placed in front of/behind/around the intermediate focus allows to vary the lateral position (x,y) of each beam and to defocus each beam. A change in x- and/or y-position of the beam after the spot position control unit directly corresponds to a change in x- and/or y-position on the work piece. The ratio between the position changes depends on the ratio of the focal lengths of the relay optics and the focusing lens. Furthermore, defocussing will move the focal plane of the beam relative to the focal plane of the focusing optics. Thus, the focus position of each beam can be controlled in x-, y- and z-direction. A second relay optics images the DOE into the entrance aperture of the laser scanner. An F-Theta lens behind the scanner focuses the beams onto the work piece.

According to the application requirements, the multi-beam optics should create a 2x2 beam array with a beam separation of 5 mm on the work piece. Relays for multi-beam optics usually have high demands regarding a minimal distortion of the relay to achieve constant beam separations between the relay optics. However, for a square 2x2 beam array, distortion influences all beams equally and is therefore not a critical aberration. This allows for a two lens design based on commercially available standard lenses (cf. Figure 3). 

Spot Position Control Unit

The demands for the spot position control unit stem from the process (i.e. what kind of curvature or surface tilt needs to be compensated) as well as the optical design of the remaining multi-beam optics (e.g. distortion of the beam array for large scanning angles). With the chosen setup, each beam can deviate up to ±380 µm laterally from its target position and focus shifts of up to ±1 mm are required to keep the focus of each beam on the work piece for tilted surfaces (cf. Figure 1). Note that the required compensation for each individual beam is different so a global compensation is not possible.

Focus shifters

Focus shifters are part of most laser scanners and usually consist of two lenses where one lens is fixed and the other can be moved along the optical axis. The shift of the lens introduces defocus to the beam, moving the focal plane behind the f-theta lens further away from or closer to the lens. The challenge for the spot position control unit within ultraSURFACE is that each beam needs its own focus shifter without interfering with the other beams (cf. Figure 4). Therefore a miniaturised solution must be found that is small enough to avoid interference with other focus shifters or the other beams (e.g. blocking them out). While in principle the beam distance between the relay optics is a free parameter, the goal is to keep it as small as possible.

The optical design of the focus shifter is shown in Figure 5.  Each focus shifter consists of two commercially available lenses grinded down to an outer diameter of 6 mm. By moving the first lens ±5 mm along the optical axis of the beam, a total focus shift of 7.2 mm or a symmetrical shift of ±3.6 mm can be achieved for each individual beam

The mechanical design of the focus shifter is shown in Figure 6. Commercially available, high dynamic linear stages are used to move the first lens in the desired position while the second lens is held in place.

Extensive tests of the focus shifters showed, that the strong permanent and electromagnets within neighbouring linear stages heavily influence each other while moving. Thus, an updated design for the focus shifters was developed that increases the distance between the linear stages by arranging the stages in a star shape (cf. Figure 7). To avoid inductive effects from the strong and changing magnetic fields within the mechanical parts, the focus shifters were made out of polyether ether ketone (PEEK) – a readily machinable polymer (cf. Figure 8+9).

x-y-control unit

While the whole spot array can be laterally moved over the work piece with the laser scanner, the lateral movement of single beams relative to the spot array is not state of the art for multi-beam optics. The lateral position of a beam in the focal plane of the focusing lens is directly related to the lateral position of each beam between the first and the second relay module. Therefore, by laterally shifting a beam between the two relay modules, the beam is also laterally shifted in the focal plane of the focusing lens. The ratio between these lateral shifts is the ratio of the focal lengths of the f-theta lens and the second relay module.

To realise such a lateral shift, a plane-parallel glass plate can be placed in the beam path (cf. Figure 10). Tilting the glass plate results in a lateral shift of the beam after the glass plate. The direction of a beam is not altered by a plane-parallel glass plate. If the glass plate can only be rotated around one axis, two glass plates per beam are required to adjust each beam in x- and y-direction.

The optical design of the x-y-control unit is shown in Figure 11. Fused silica glass plates with outer dimensions of 8x8x15 mm³ were chosen based on the remaining optical design and the restrictions from the mechanical design (see below). Note that in contrast to the concept in Figure 10, neighbouring plates are not rotated around the same axis but around perpendicular axes. This allow for larger glass plates and larger tilt angles without collisions between neighbouring plates. Additionally, this allows to position the motors for the rotation closer to each other making the system more compact. With the maximum rotation angle of the motors of ±11.4°, each beam can be laterally shifted in each direction by ±900 µm before the second relay lens and ±450 µm on the work piece.

A 3D drawing of the mechanical design is shown in Figure 9. The glass plates are mounted on galvanometers to allow fast tilts synchronous with the laser scanner. The minimal distance between the two glass plates for a single beam (49 mm) is restricted by the size of the galvanometers.

Figure 13 shows the mounting of a single glass plate on the galvanometer. The complete x-y-control unit is depicted in Figure 14 and a close up of the first row of glass plates is shown in Figure 15.

Figure 16 shows the complete optical design for the multi-beam optics. The folding of the beam path with the two mirrors is only exemplarily. The actual folding is based on the available space in the optics head.

The mechanical design for the Multi-Beam optics was developed and manufactured. The optics was successfully assembled and characterized and meet the requirements for laser structuring. Thus the Multi-Beam optics was integrated in the 5-axis laser machine tool to process parts of the end-users. 3D capability could be demonstrated on simple geometries. The optics can be used as a prototype for product development.