DE102012016788A1 - Polygon type laser scanner used in material processing field, has deflecting mirror whose mirror surface is three-dimensionally shaped such that laser beam is periodically guided along single or multiple curved scanning paths - Google Patents

Abstract

The scanner has a rotary propelled deflecting mirror (7) through which an incident laser beam (4) is guided periodically along a scanning path (10) in a machining plane. The mirror surface (8) of the deflecting mirror is three-dimensionally shaped such that the laser beam is periodically guided along the single or multiple curved scanning paths. The deflecting mirror is disc or cylindrical-shaped. The mirror surface is a free-form surface. The mirror surface has the curvature which changes periodically in the direction of rotation.

Description

Technical application

The present invention relates to a laser scanner with a rotationally driven deflection mirror, through which an incident laser beam is guided periodically along a scanning path in a working plane. The invention also relates to the design of the deflection mirror of such a laser scanner.

In material processing methods with laser radiation scanner systems with movable mirrors are also used for guiding the laser radiation, also referred to as galvanometer scanner. These mirrors direct the radiation over the workpiece so that the desired processing path is scanned at the desired speed with the laser beam. This method finds application possibilities in almost all material processing methods of laser technology. The movement is no longer purely linear, but is superimposed with another type of movement. As a result, the respective processing location is repeatedly traversed by the laser beam (spatial modulation), which, depending on the parameterization, brings advantages for the process control. For local modulation of the laser power, the deflecting mirrors are moved at very high frequency in some applications so that closed contours such as, for example, Lissajous figures are scanned periodically with the laser beam.

State of the art

A periodic deflection of the laser radiation in a laser scanner, in order thereby to guide the laser beam multiply in a short time over a processing location, can take place, for example, by rotation of a so-called polygon mirror. Such a polygon mirror has n mirror surfaces, which are arranged in the form of a polygon. This is schematically illustrated in the cross-sectional view of such a polygon mirror in FIG 1 to recognize. In this figure is the polygon mirror 1 with nine mirror surfaces 2 shown. The mirror surfaces 2 are formed on the lateral surface of a cylindrical mirror body. The polygon mirror 1 is driven by a very high speed motor around the axis of rotation 3 set in rotational motion and thereby directs the incident laser beam 4 so that he turns every n-fold a straight line 5 scans in the working plane. However, with such a polygon mirror, the laser beam can only lead on straight tracks.

Galvanometer scanners are currently used for the periodic generation of a single or multiple curved scanning path. These usually consist of two mirror elements which can be tilted about mutually perpendicular axes of rotation, which are each driven separately. By suitable control can thereby lead the incoming laser beam on arbitrarily curved scanning paths. However, due to physical limitations, such galvanometer scanners can not achieve sufficiently high periodic scan frequencies as are needed for higher process speeds in material processing.

The object of the present invention is to provide a laser scanner which allows a deflection or guiding a laser beam periodically along a curved scanning path with high frequency.

Presentation of the invention

The object is achieved with the laser scanner according to claim 1. Claim 9 indicates a specifically designed for use in the laser scanner deflection mirror. Advantageous embodiments of the laser scanner and the deflecting mirror are the subject of the dependent claims or can be found in the following description and the embodiments.

The proposed laser scanner has a rotationally driven deflection mirror, through which an incident laser beam is periodically guided along a scanning path in the working plane. A rotationally driven deflecting mirror here is to be understood as meaning a mirror which, during the operation of the laser scanner, executes several complete revolutions about an axis of rotation which runs through a center of the mirror body. The mirror surface of this deflecting mirror is shaped in such a way that the laser beam is periodically guided on a single or multiple curved scanning path due to the rotation. The mirror surface is preferably a free-form surface.

The proposed laser scanner therefore has, in a manner similar to a polygon scanner, a rotationally driven deflecting mirror. However, the deflecting mirror is not composed of flat mirror surfaces, but has a continuous or more composite mirror surfaces that are not flat but curved shaped. The mirror surface (s) are shaped such that an incident laser beam which strikes the surface at a certain angle is deflected during the rotation of the mirror to the desired single or multiple curved scanning path, ie a two-dimensional scanning path. By appropriate design of the Three-dimensional shape of the mirror surface (s) can thereby different contours such as, circles, 8-shaped contours or the like are generated periodically as a scanning path. The generated contour is determined by the surface curvatures of the mirror surface (s) of the proposed deflection mirror or laser scanner.

With the proposed laser scanner and the associated deflection mirror can be very high local modulation frequencies as well as produce a polygon scanner. However, in contrast to a polygon scanner, the proposed laser scanner allows the generation of arbitrarily two-dimensionally shaped periodic scanning paths. Furthermore, the proposed embodiment of the laser scanner also very advantageously allows operation with high laser power, since the mirror surface of the deflection mirror can be made insensitive to high radiation intensities.

Preferably, the deflection mirror has a disk-shaped or cylindrical body, through the lateral surface of which the mirror surface is formed. Due to the rotational symmetry of such a body, it can be driven at high speed about its axis of rotation. A possible imbalance due to the particular shape of the mirror surface can be corrected by providing or attaching additional material or removing material on the end faces of the disc or cylindrical body. This may be necessary if very high speeds are to be achieved during the rotation of the deflection mirror.

The suitable three-dimensionally shaped mirror surface of the deflecting mirror can be produced, for example, by milling of a corresponding disk-shaped or cylindrical body. Such milling operations can nowadays be carried out with very high precision, for example with a five-axis milling machine whose precision is sufficient for the present application. The three-dimensionally shaped lateral surface produced in this way is then suitably polished, for example by means of laser polishing, and then provided with a suitable reflective coating.

By suitable choice of the three-dimensional shape of the mirror surface of the deflecting mirror, 3D machining on the workpiece or beam shaping (eg focusing) of the laser beam can be achieved within certain limits. By sufficiently large height differences of the different areas of the mirror surface of the focus of the laser beam is moved in the working plane, whereby the desired 3D processing can be achieved. Furthermore, it is possible to make the focusing optics for the laser beam correspondingly adjustable in the beam direction with a drive, so that a corresponding shift of the focus can also be achieved thereby. This technique can also be used, for example, to compensate for an undesired periodic shift of the focus due to the shape of the mirror surface during the rotation of the deflection mirror. The focusing optics is thereby moved synchronously with the rotation of the deflection mirror.

The proposed laser scanner can be used in all applications in which a laser beam is to be guided periodically on a single or multiple curved scanning path in a working plane. This applies above all to areas of application in material processing with laser radiation. Such a laser scanner can be used, for example, in the removal, soldering, welding or structuring of workpieces or workpiece material. Similar processing methods can also be found in medical technology, in which the proposed laser scanner can also be used. Of course, the laser scanner can also be used in other areas, for example in areas of metrology, in which a region to be measured has to be scanned with laser radiation. In typical applications, the proposed laser scanner is moved over the workpiece by a higher-level axis system in order to enable the macro movement required for processing larger areas.

Brief description of the drawings

The proposed laser scanner and the associated deflecting mirror will be briefly explained again by means of embodiments in conjunction with the drawings. Hereby show:

1 a schematic cross-sectional view of a polygon scanner according to the prior art;

2 an example of a laser scanner according to the present invention in a schematic representation;

3 an example of the angle of inclination of the mirror surface of the proposed deflection mirror in dependence on the arc path of the rotating deflection mirror;

4 Examples of scanning paths, as they can be generated periodically with the proposed laser scanner;

5 a section along AA 'through the mirror body of 2 ; and

6 Further examples of scanning paths, as they can be generated periodically with the proposed laser scanner.

Ways to carry out the invention

1 shows a schematic representation of an example of a polygon scanner according to the prior art, as it has already been explained in more detail in the introduction to the description. Although such a polygon scanner can generate high modulation frequencies, the laser beam can only be periodically guided on a straight-line scanning path.

2 shows a schematic representation of an example of a laser scanner according to the present invention, wherein the deflection mirror is shown in cross section. The deflection mirror 7 is also rotating around the axis of rotation 3 driven by the mirror body. The deflection mirror 7 has a cylindrical mirror body whose lateral surface as a mirror surface 8th is trained. The mirror surface 8th is a free-form surface used to periodically create the desired curved scan paths 10 is formed in the working plane. The mirror surface 8th has in this example a curved shape that repeats periodically over the circumference of the mirror body. This is indicated in the figure by the wavy cross-sectional shape with the hatched areas. 5 shows a section along AA 'the 2 in which the different inclination of the mirror surface 8th the deflecting mirror 7 to the direction of the axis of rotation 3 can be seen in the plane perpendicular to the direction of rotation. The angle of the mirror surface 8th to the axis of rotation may vary in the circumferential or rotational direction, for example, sinusoidal. Other variations are of course possible.

With a suitable embodiment of the three-dimensional shape of this mirror surface 8th can a through a laser 6 on the mirror surface 8th directed laser beam 4 during rotation of the deflecting mirror 7 around its axis of rotation 3 during a complete rotation several times on a single or multiple curved scanning path 10 be guided in the processing level. The motor drive for the rotation of the deflection mirror 7 around the axis of rotation 3 is not shown in this figure. However, the figure shows schematically a focusing optics 9 that the incoming laser beam 4 focused on the working plane. As indicated by the double arrow, this focusing optics 9 in the propagation direction of the laser beam 4 be moved by a. For example, motor drive to edit a workpiece with a non-planar surface shape by appropriate displacement of the focus, which is moved for processing relative to the laser scanner. Also a compensation of a possible due to the surface shape of the mirror 8th generated periodic shift of the focus can be achieved by appropriate counter-movement of the focusing optics 9 be compensated.

By forming the mirror surface 8th As a free-form surface, with such a deflecting mirror, if the free-form surface is designed appropriately, almost any single or multiple curved, preferably self-contained scanning paths in the processing surface can be periodically traversed. 3 shows a simple example of an embodiment of such a mirror surface. In the figure, the dependence of the angle of inclination of the mirror surface in the plane perpendicular to the circumferential direction relative to the axis of rotation is plotted against the sheet path l of the rotating mirror body, as in 2 is indicated. The inclination of the mirror surface in the circumferential direction can run in a comparable manner. In addition to the sinusoidal shape shown here, of course, any other periodic pitch gradients can be used, as they are required for the respective desired Abtastfigur.

4 shows three examples of scanning paths 10 , a circular path and two Lissajous figures, as they can be generated with the proposed laser scanner. 6 shows three more examples, an example of a scanning path 10 in the form of a circle with discontinuous deflection, an example of a scanning path 10 with any continuous contour and an example of a scan path 10 with any, discontinuous contour. The six examples each show a top view of the working plane.

Such figures can be produced in the proposed laser scanner and associated deflection mirror also by juxtaposition of n mirror surfaces along the circumference of the deflecting mirror similar to a polygon scanner, in which case the individual mirror surfaces are designed to be curved accordingly.

LIST OF REFERENCE NUMBERS

1

polygon mirror

2

plane mirror surfaces

3

axis of rotation

4

laser beam

5

straight-line scanning path

6

laser

7

deflecting

8th

mirror surface

9

focusing optics

10

curved scanning path

Claims (9)

Laser scanner with a rotatory driven deflection mirror ( 7 ), through which an incident laser beam ( 4 ) periodically along a scanning path ( 10 ) is guided in a working plane, characterized in that the mirror surface ( 8th ) of the deflection mirror ( 7 ) is shaped so that the laser beam ( 4 ) periodically on a single or multiple curved scanning path ( 10 ) to be led. Laser scanner according to claim 1, characterized in that the deflecting mirror ( 7 ) has a disk-shaped or cylindrical body, through the lateral surface of which the mirror surface ( 8th ) is formed. Laser scanner according to claim 1 or 2, characterized in that the mirror surface ( 8th ) is a freeform surface. Laser scanner according to one of claims 1 to 3, characterized in that the mirror surface ( 8th ) in a plane perpendicular to a direction of rotation of the deflecting mirror ( 7 ) about a rotation axis ( 3 ) an angle with respect to the axis of rotation ( 3 ) which changes periodically in the direction of rotation. Laser scanner according to one of claims 1 to 3, characterized in that the mirror surface ( 8th ) in a plane perpendicular to a direction of rotation of the deflecting mirror ( 7 ) has at least one curvature which changes periodically in the direction of rotation. Laser scanner according to one of claims 1 to 5, characterized in that the mirror surface ( 8th ) is shaped so that the laser beam ( 4 ) on a self-contained scanning path ( 10 ) to be led. Laser scanner according to claim 6, characterized in that the self-contained scanning path ( 10 ) is a Lissajous figure. Laser scanner according to any of claims 1 to 7, characterized in that the laser scanner (a focusing optical system 9 ) for generating a focus of the laser beam ( 4 ) in the region of the working plane, wherein the focusing optics ( 9 ) is connected to a drive through which the focusing optics ( 9 ) can be adjusted to shift the focus. Deflection mirror, which is designed for a laser scanner according to one of the preceding claims.

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