DE4403297A1 - Device for deflecting optical rays - Google Patents

Description

The invention relates to a device for deflection kung optical rays, preferably for distraction of laser beams, with a drivable rota tion body arranged mirror surfaces.

It is known in the prior art for realization tion of the deflection of laser beams, which a con continuous radiation deflection for larger angles and require high deflection speed, rotato rically driven polygon mirrors to use. The disadvantage is that the extreme manufacturing this mirror expended to extraordinarily high Ko leads. In addition, the known poly gon mirror the freedom of tilt of the individual Mirror segments with respect to the axis of rotation are not ge be guaranteed.

Are still from the field of microtechnology Deflecting mirror arrangements for optical rays be  knows who hung on torsion bands Can tilt mirror surfaces around an axis of rotation or where the mirror surfaces at the end of movable Chen tongue structures are arranged. For derar systems become electrostatic, piezzoelek trical or electrothermal drives are used, which are generally functionally integrated with the mechanics are.

With such arrangements beamables are admittedly can be realized by ± 10 °, the associated However, mirror surfaces are only in the area between 50 × 50 µm² to 500 × 500 µm² can be produced. As very problematic with the previously known Systems the dynamic behavior. With high fre the achievable deflection angle dra dra stisch from, because the accelerated movement of the Mirror surface necessary forces through the chosen drive principles are no longer applied that can. There are also vibration modes which lead to warping of the mirror surfaces. Around a safe movement of the mirror surfaces also To enable higher frequencies, their mass must be be drastically reduced, what for a given game gel area only by reducing the thickness is possible. However, this leads to an increased Formation of vibrations on the mirror surface che and thus to malfunctions.

The invention is based on the object Specify radiation deflection system that has a high Ab steering frequency at large deflection angles and for large ones Mirror surfaces allow freedom of tilting  the individual segments with respect to the axis of rotation performs and can be manufactured inexpensively.

According to the invention the problem is solved by devices that the in claims 1 to 7 specified features.

The arrangement according to the invention is particularly notable the following advantages:

• - Realization of high deflection frequencies also for relatively large light beam diameters,
• - Manufacture of mirror surfaces with high pre precision,
• - Inexpensive manufacture in mass production tion, because in micromechanics the advantageous Technologies of batch processes in microelectronics can be used
• Freedom of tilting of the segments relative to one another,
• - High reflectivity of the mirror surfaces the intended materials.

The invention is based on Exemplary embodiments explained in more detail. In the zuge show proper drawing:

Fig. 1 and 2 according to the invention before direction, the mirror surfaces are located in the rotary body in a recess, and

Fig. 3 and 4 according to the invention before direction, the mirror surfaces are at a sastruktur when mounted on the rotary body Me.

In the arrangement shown in FIGS . 1 and 2, the base body 1 contains a recess 1.1 which is larger in its dimensions than the disk-shaped rotary body 2 . The rotary body 2 consists of a single-crystalline material, preferably silicon, and contains a centrally arranged polygonal recess 2.1 . The deepening 2.1 is laterally limited by crystal planes of the rotary body 2 , which represent the mirror surfaces 2.2 . On the top of the Rota tion body 2 there is an annular, seg mented hard magnetic layer 2.3 , the center of which define the axis of rotation of the rotary body 2. The base body 1 , in the recess 1.1 of which the rotary body 2 is located, is on the top by a cover plate 3 hermetically sealed from glass. On this cover plate there is a ring magnet 4 and a number of coils 3.1 pairs with integrated flux guide 3.2 . On the underside of the base body a Gegenpolma gnet 5 is arranged.

A further embodiment of the device according to the invention is shown in FIGS . 3 and 4. Here, a polyhedral mesa structure 2.4 is arranged centrally on the disk-shaped rotating body 2 . The mesa structure 2.4 is laterally delimited by crystal planes of the rotating body 2 , which represent the mirror surfaces 2.2 . On the top of the rotating body 2 there are annular hard magnets 2.3 , the center of which define the axis of rotation of the rotating body. The base body 1 , in the recess 1.1 of the rotary body 2 , is in turn hermetically closed at its top by a cover plate 3 .

In both versions, the rotating body 2 is held in suspension by the segments of the hard magnetic material on its upper side, by the force of the ring magnet 4 , the counter-pole magnet 5 and by the magnetic field of the coils 3.1 in the recess of the base body 1 . The ring-shaped design of the magnets forces the centering of the rotating body 2 . By suitable control of the coil pairs 3.1 arranged on the base body 1 , a magnetic field is generated via the flux-conducting layers 3.2 , which causes a torque in cooperation with the hard magnetic segments on the rotary body 2 . The rotary body 2 can be set in a multi-pole arrangement in a wobble-free rotational movement.

A falling on a mirror surface 2.2 of the Rotationskör pers 2 light beam can be deflected by the rotation movement of the mirror surface about an axis of rotation up to an angle of approximately 60 °. The device according to the invention allows very high speeds, because the self-centering magnetic bearing prevents friction effects almost completely and unbalances can be minimized.

Reference list

1 basic body
1.1 recess
2 rotating bodies
2.1 deepening
2.2 mirror surfaces
2.3 hard magnetic layer
2.4 Mesa structure
3 cover plate
3.1 Coil pairs
3.2 Flow directors
4 ring magnet
5 opposite pole magnet

Claims (7)

1. Device for deflecting optical rays, preferably for deflecting laser beams, with a drivable rotating body ( 2 ) arranged th mirror surfaces ( 2.2 ), characterized in that the rotating body ( 2 ) consists of single-crystal material, the mirror surfaces ( 2.2 ) through the crystal planes are formed and are arranged rotationally symmetrically. 2. Device according to claim 1, characterized in that the rotary body ( 2 ) is designed as a disc-shaped body having a centric cal recess ( 2.1 ) in which the mirror gel surfaces ( 2.2 ) are. 3. Device according to claim 1 or 2, characterized in that the recess ( 2.1 ) has a polygonal cross-section and the mirror surfaces ( 2.2 ) are inclined benenscharen at the angle of defined crystals. 4. The device according to claim 1, characterized in that the rotary body ( 2 ) consists of monocrystalline material, on which a polygonal mesa structure is arranged centrally, on which the mirror surfaces ( 2.2 ) are located. 5. Device for deflecting optical rays, preferably for deflecting laser beams, with surfaces arranged on a rotating body ( 2 ) ( 2.2 ), characterized in that the mirror surfaces ( 2.2 ) are arranged on a magnetically mounted rotary body ( 2 ). 6. Device according to one of claims 1 to 5, characterized in that

• - The rotary body ( 2 ) is in a base body ( 1 ) with a recess ( 1.1 ),
• - segments of hard magnetic material are arranged in a ring on the rotating body ( 2 ),
• - There is a ring magnet ( 4 ) above the rotating body ( 2 ),
• - Below the rotating body ( 2 ) there is a Ge pole magnet ( 5 ) and
• - Above the counter pole magnet ( 5 ) coil pairs ( 3.1 ) with flux guide pieces ( 3.2 ) are arranged.

7. The device according to claim 6, characterized in that the base body ( 1 ) is hermetically sealed with a plate.