WO2009115598A1

WO2009115598A1 - Guiding device for guiding light beams, laser cutting device provided therewith and production device equipped therewith for producing a preform for fibre composite structures suitable for power flows

Info

Publication number: WO2009115598A1
Application number: PCT/EP2009/053293
Authority: WO
Inventors: Oliver Meyer; Thomas Wechs
Original assignee: Eads Deutschland Gmbh
Priority date: 2008-03-20
Filing date: 2009-03-20
Publication date: 2009-09-24
Also published as: DE102008015281A1

Abstract

The invention relates to a guiding device (20) for guiding light beams, in particular laser beams (14), comprising an optical guiding device (20) that is arranged in a light path of the laser beams (14) and which can be moved by means of solid body actuators (30) for guiding the light beams (14). The claimed guiding device (20) that can move the optical deflection device (20) by means of the solid body actuators (30) for guiding the light beams (14) has the advantage that based on the increased precision of positioning of the optical guiding device (20), a very high repetitive accuracy of the light beam path is produced.

Description

Steering device for guiding light beams, thus provided laser cutting device and provided therewith manufacturing device for producing a preform for power flow fair fiber composite structures

The invention relates to a steering device for directing light beams, in particular laser beams, with an optical deflection device which is arranged in an optical path of the light beams. Furthermore, the invention relates to a provided with such a steering device laser cutting device and advantageous uses thereof.

Such steering devices are used for example in laser scanners.

In a first variant of known laser systems, scanner systems with galvometer or galvanometer drive are used for beam deflection. A mirror is attached to an arm of a galvanometer and follows the movements of this arm. To operate such a steering device, the generation of high voltages and rapid pumping of charges is necessary to ensure a fast reaction time of the steering device. At the same time, the resulting electric fields create dangers and undesirable scattering effects in electronic assemblies.

It is also known to move a laser optics of a laser cutter with a robot system through a room. For this purpose, a laser assembly with rigid optics is attached to a movable and / or rotatable robot arm and moved from this to the desired position.

Both variants have by the mechanically moving, relatively massive, elements a limited speed and accuracy. The present invention is based on the object to provide a steering device of the type mentioned, which has an improved accuracy and speed.

This object is achieved by a steering device having the features of patent claim 1. The steering device according to the invention, in which the optical deflection device for guiding the light beams is movable by means of solid state actuators, has the particular advantage that due to the increased accuracy of the positioning of the optical deflection device, a very high repeatability of the light beam path is given.

Advantageous embodiments of the invention are the subject of the dependent claims. Advantageous uses of the steering device are the subject of the dependent claims.

The optical deflection device may comprise an optical deflection lens. Thereby, the steering device is almost independent of the power of the deflected light beams and also of the source of the light beams.

Advantageously, the optical deflection device may have a frame on which the solid state actuators act. This makes it possible to attach the optical deflection device to the solid-state actuators even if the optical deflection device and the solid-state actuators can not be directly connected to each other due to the materials used. In addition, the stability of the deflector is improved. In particular, more fragile deflection devices, for example particularly sensitive deflection lenses, can be used.

The solid-state actuators can be arranged at opposite points of the deflecting device. This makes it possible to achieve a uniform tensile and compressive loading of the optical deflection by each opposite activation of the solid state actuators. In a further embodiment, the solid-state actuators may be arranged to move the deflection device in a direction which is substantially transverse to the direction of the light rays. Thus, by shifting the optical deflection device substantially orthogonal to the propagation direction of the light beams, a deflection thereof can be achieved.

The solid-state actuators may be arranged to move the deflection device in a direction which is substantially parallel to the direction of the light rays. This makes it possible to tilt the deflection device. When using optical lenses as a deflection device, it is also possible to shift the focal point of the laser. This can in particular be done very accurately by moving the lens, in particular in a plane substantially transverse to the light beam. Such displacement movements can be performed simply and with high precision by means of the actuators.

Advantageously, the solid state actuators have piezo elements. A piezoelectric actuator can perform a change in length practically immediately by applying a voltage and at the same time generate high forces. A movement device constructed with piezoelectric elements can also be electrically controlled directly. On mechanical components can be largely dispensed with.

Advantageously, the solid-state actuators can have a plurality of actuator elements, which are arranged in series in their main expansion direction. If solid state actuators are stacked, the individual length changes add up. Thus, the deflection device can be moved over longer distances.

In a further advantageous embodiment, the solid state actuators are biased to further increase the reaction speed of the steering device.

In another aspect, the invention is directed to a laser cutter. A compact laser cutter, with cuts to be made exactly A laser cutting device is provided which is provided with the steering device according to the invention or one of its advantageous embodiments, reproducibly easily controllable and can be repeated in quick succession.

Preferably, the laser cutter is used for cutting carbon fibers. The laser cutting device is particularly preferably used in a production device for the production of preforms for power flow compatible fiber composite structures.

The invention will be explained in more detail with reference to a drawing which schematically shows an embodiment according to the invention. It shows:

1 shows a three-dimensional view of an embodiment of the steering device according to the present invention.

1 shows a deflection device 20 for a laser source 10. The laser source 10 has a laser (not shown). The laser 12 emits a laser beam 14, which is deflected by the deflector 20 to an adjustable target point 16a, 16b, 16c here.

The deflection device 20 has a Ablenkklinse 22 and a perpendicular to the Ablenklinse 22 movable collecting lens 12. The Ablenklinse 22 has a curved refractive region 24 and a substantially cylindrical mounting portion 26, which adjoins the refraction region 24.

The attachment portion 26 is connected to a frame 28. The frame 28 has the shape of a Ablenklinse 22 enclosing ring.

Solid state actuators 30 engage the frame 28. The solid state actuators 30 each have ten piezoelectric elements 32 which are composed so that their main expansion directions 34 substantially coincide. The pie Zoelemente 32 are based in the main expansion direction 34 from each other, so that the expansions or shrinkages of the piezo elements 32 add.

The solid-state actuators 30 are arranged at opposite positions on the outer surface of the frame 28 and supported on a housing, not shown.

The deflection lens 22 is substantially circular in orthogonal view of the refraction region 24. If a light beam strikes the center of this circle, it will not be deflected when passing through the deflection lens 22. However, as soon as the light beam hits the Ablenkklinse 22 away from the center, it is deflected. Thus, when the light beam does not change position, its deflection is achieved by movement of the diverter lens 22. In the exemplary embodiment, a laser beam 14 generated by the laser is deflected by the deflection lens 22. For this purpose, the deflection lens 22 is displaced by the solid-state actuators 30 essentially orthogonally to the propagation direction of the laser beam 14.

For example, the deflection lens 22 can focus the laser beam 14 on target points 16a, 16b, 16c, which are given here only as examples. The focal point of the Ablenklinse 22 can be moved purely by movement of the Ablenklinse 22 within its main extension plane. Adjustments in the direction perpendicular thereto are possible via the converging lens 12.

By shifting a suitable Ablenklinse 22 in the beam path of a laser system by means of piezoelectric actuators, the repeatability of a laser scanner can be significantly increased, resulting in new applications. If the lens is moved in the X, Y, or Z direction by piezo actuators, for example, then the focal point can be moved in space.

The piezoelectric laser beam deflection system achieves a very high precision and repeat accuracy as well as a high degree of accuracy compared to known systems. speed. As a result, cutting processes that require a stratified material removal are made possible.

The system is relatively stable to temperature fluctuations and the laser beam 14 can be repeatedly guided through the same kerf (20-50 μm wide) with high repeat accuracy. Thus, for example, the contact-free cutting of carbon fiber materials is possible.

Furthermore, the technique can be used for projection purposes. Regardless of external influences (acceleration, vibration, temperature fluctuation), a stable image can be generated.

Fig. 1 shows schematically the structure of a piezoelectric Strahlablenksystems with movable lens. The unfocused laser beam 14 is guided onto the suitably formed deflection lens 22. The Ablenklinse 22 can be moved by a cross-shaped system of the piezoelectric solid state actuators 30 in the laser beam 14 orthogonal plane. This results in a shift of the focal point, for example, to the positions 16a, 16b, 16c.

An advantage over classical beam deflection systems is that thermal expansions of the structure are automatically compensated for and that position changes result in direct dependence on voltages applied to the piezoelectric elements 32. The voltage of two piezoelectric elements 32 lying on one spatial axis should in this case be inversely proportional and the piezoelectric elements 32 should be biased in order to achieve a stable displacement. The piezo elements 32 are designed, for example, as disk-shaped piezo wheels.

The achievable displacement length can be adjusted by the number of piezoelectric disks used in the solid-state actuator 30. When a voltage is applied, very large forces are generated by the Ablenklinse 22 at high speed. Move the speed and precision to the desired position. A Nachschwingen carrier masses is thus largely avoided. Due to the fact that no mechanical components are necessary, no tolerance errors or wear occur. The scanner system is largely independent of the laser power and the beam source.

Especially due to the high repeat accuracy, such a system can be used for gradual material removal as in milling. The laser beam 14 can be repeatedly performed with great precision through a previously formed kerf.

The high beam guidance accuracy makes larger working distances possible. Thus, it is also possible to have multiple lasers operate in a limited space simultaneously.

The deflection device 20 can in principle also be used for projection systems. Since the structure is small and stable to accelerate, it can be used for example in vehicles or aircraft.

The laser is designed as a cutting laser. From the laser and the deflection device 20, a laser cutting device is thus formed, which is particularly suitable for cutting carbon fiber materials.

The laser cutting device is used as a cutting device in the production method and the production device for the production of preforms for power flow compatible fiber composite structures, which are described, shown and claimed in more detail in WO 2008/110614 A1. Reference is made to this document for further details. WO 2008/110614 A1 is incorporated herein by reference. LIST OF REFERENCE NUMBERS

10 laser source

12 condenser lens

14 laser beam

16a, 16b, 16c target point (focus point)

20 deflection device

22 Ablenklinse

24 refraction area

26 mounting area

28 frame

30 solid state factor

32 piezo element

34 main expansion direction

Claims

A steering apparatus for guiding light beams, particularly laser beams (14), comprising an optical deflector (20) disposed in an optical path of the light beams and movable to direct the light beams by means of solid state actuators (30).

2. Steering device according to claim 1, characterized in that the optical deflection device has an optical Ablenkklinse (22).

3. Steering device according to claim 2, characterized in that the Ablenklinse (22) by means of

Solid state actuators (30) is movable to a focal point on which the light beams to be guided by the Ablenkklinse (22) are focusable, selectable on one of several desired positions (16a, 16b, 16c) to relocate.

4. Steering device according to one of the preceding claims, characterized in that the optical deflection device (20) has a frame (28) on which attack the solid state actuators.

5. Steering device according to one of the preceding claims, characterized in that the solid state actuators (30) are arranged at opposite points or areas of the deflection device (20).

6. Steering device according to one of the preceding claims, characterized in that the solid state actuators (30) are arranged in a cross shape.

7. Steering device according to one of the preceding claims, characterized in that the solid state actuators (30) for movement of the deflection device (20) are arranged in a direction which is substantially transverse to the direction of the light beams (14).

8. Steering device according to one of the preceding claims, characterized in that the solid-state actuators (30) for movement of the deflection device (22) are arranged in a direction which is substantially parallel to the direction of the light beams (14).

9. Steering device according to one of the preceding claims, characterized in that the solid-state actuators (30) have piezo elements (32).

10. Steering device according to one of the preceding claims, characterized in that the solid-state actuators (30) have a plurality of actuator elements which are arranged in series in their Hauptausdehnungsrichtung.

11. Steering device according to one of the preceding claims, characterized in that the solid state actuators (30) are biased.

12. Laser cutting device, characterized by a steering device according to one of the preceding claims for steering a laser beam used for cutting.

13. Use of a laser cutting device according to claim 12 for cutting carbon fiber materials.

14. Fabrication device for producing a preform for power flow-compatible fiber composite structures, characterized by a laser cutting device according to

Claim 12 for cutting individual sliver pieces.