DE102018114306A1 - "Lattice support device for optical gratings, in particular for reproducible lattice change for the tunability of the Dyes laser" - Google Patents

Abstract

The invention relates to a grating support device (1) for optical gratings, comprising a grating holder (2) mounted on a basic body (3), the grating holder (2) being designed to receive an optical grating, and the basic body (3) and grating holder (2) can be assembled on top of each other along a central assembly axis (M). The base body (3) is mounted in a laser device, and the lattice holder (2) is relative to a surface plane (A) of the base body (3) extending in an x and a y direction with a first (5) and a second (6) and a third (7) bearing point on the base body (3). The relative position of the lattice holder (2) to the surface plane (A) of the base body (3) is adjustable on the lattice holder (2), and the lattice holder (2) is connected to the base body (3) with a magnetic connection. The invention further relates to a laser device with such a lattice support device (1).

Description

According to the preamble of claim 1, the invention relates to a grating support device for optical gratings, comprising a grating holder mounted on a base body, the grating holder being designed to accommodate an optical grating, and the base body and grating holder being assembled one on top of the other along a central assembly axis, the base body in a laser device is mounted.

In practice, optical gratings are used to tune the wavelengths in lasers, especially in dye lasers.

Such optical gratings are based on selected areas of application or wavelength ranges by means of their physical properties, for. B. the grid line spacing, which limits the range of tunability of the optical grating.

Dye lasers in particular require a large wavelength tuning range, which means that the technical properties of a single optical grating are not sufficient to operate the dye laser efficiently. With dye lasers, for example, optical gratings with a groove density of 1800 L / mm, 2400 L / mm and 3000 L / mm are used.

Another factor in the use of optical gratings is the so-called Wood's Anomaly, which occurs particularly in the application in which the laser resonator works with grazing incidence over a grating and has a very small line width, for example when the grazing incidence with a first grating a mirror or a second grating is reflected back into the resonator via the first grating. In these cases, Wood's Anomaly means that the resonator oscillates in an undesired polarization at certain critical wavelengths.

This unwanted polarization is always different z. B. with grids with a groove density of 1800 L / mm, 2400 L / mm and 3000 L / mm. In particular, this leads to the need to change the optical gratings in the laser system when tuning through a large wavelength range.

In known lattice girder devices, the lattices are individually manually clamped on a lattice girder and each is adjusted. Such a grid change takes a lot of time and effort.

In particular, assembly involves the risk of damaging the highly sensitive gratings and thus negatively influencing the efficiency of the entire laser.

Furthermore, precise knowledge of laser technology is required for the calibration of the optical gratings, so that mostly external service providers carry out the adjustment.

A further development of this system is a pre-assembly of the grids on a pre-adjusted lattice girder, whereby the crucial adjustment in the laser is not omitted.

In addition to the optical grids which are individually arranged individually on grating supports, grating support devices are known on which a plurality of optical grids are mounted in an already ideally adjusted position. These lattice girder devices then automatically move the desired lattice into the working position. The optical gratings are arranged on lattice girders, either on a turntable as a positioning element or on slides that can be moved linearly to the base body.

In practice, it has been found that the manual and individually fitted lattice support devices are very time-consuming to assemble and calibrate. In addition, the longer it takes to assemble, the greater the risk of damage to the optical grating. An external service provider may also have to make the adjustment.

The automated lattice girder devices solve the problems of the manual lattice girder device as far as possible, but are limited to a number of lattice girders that can be fitted in the system. Furthermore, the systems require more space than the manual systems and are more prone to malfunction than manual systems due to the mechanics. In addition, such systems are expensive to manufacture and maintain.

It is therefore the object of the invention to provide a lattice support device for optical gratings which reduces the deficits shown and, in particular, enables a reproducible lattice change with minimal assembly effort and an unlimited number of lattice holders.

According to the invention, this is solved by a lattice girder device according to the features of independent claim 1.

The lattice support device according to the invention comprises a lattice holder that is adjustable relative to a surface plane of the base body that extends in an x and a y direction and that is mounted at three points. Furthermore, the relative position of the grid holder to that in x and y Direction extending surface level of the base body adjustable on the grid holder. The base body and the lattice holder are mounted on top of each other along a central assembly axis and held against each other with a magnetic connection and fixed in the bearing.

In particular, the changing of the lattice holder is improved by the lattice support device according to the invention, because the relative position of the lattice holder to the surface plane of the base body on the lattice holder itself is set and its setting is retained even when it is dismantled. In practice, this means that the grid holder reproducibly assumes the set position during any number of assembly processes and that a grid holder that has been adjusted does not have to be readjusted.

A particularly advantageous embodiment of the mounting is when in particular the first bearing fixes the lattice holder in an x or a y direction relative to the base body against a translatory movement parallel to the surface plane of the base body. The second bearing point advantageously fixes the lattice holder relative to the base body against rotation about the first bearing point in a plane parallel to the surface plane of the base body. The third bearing point preferably fixes the lattice holder relative to the base body against a tilting movement around the first bearing point out of a plane parallel to the surface plane of the base body. Such an advantageous embodiment supports the inventive idea of reducing the assembly effort in the simplest way, since the grating holder can be completely adjusted in its position with only a small number of bearing points in accordance with the requirements of the laser device or the optical grating, and the adjustment only must be done once.

In particular, it is advantageous if the first bearing point comprises a hemispherical elevation and an opposite bearing for receiving the elevation, which includes the hemispherical elevation at at least three points on the circumference of the elevation. This advantageously provides a separable bearing point which fixes the lattice holder relative to the base body against translational movement parallel to the surface plane of the base body in the x or y direction.

It is even more advantageous if the bearing opposite the elevation is designed as a circular opening, so that the bearing opposite the elevation only rests on a radius of the elevation. In particular, the edge of the circular opening is made of material that is harder than the surrounding material to protect the opening.

Furthermore, it can be advantageous if the elevation is designed as a ball arranged in an opening made of a material that is harder than the surrounding material. In particular, the manufacture of the bearing point is simplified.

In a further preferred embodiment, the second bearing point has adjustment means which adjust the angle of inclination of the lattice holder around the first bearing point in the x direction relative to the surface plane of the base body extending in the x and y direction, which the positional adjustment of the lattice holder relative to the surface plane of the Basic body favors.

It is also advantageous for the position adjustment if the third bearing point has adjustment means which adjust the angle of inclination of the lattice holder around the first bearing point in the y direction relative to the surface plane of the base body extending in the x and y direction.

It can be particularly advantageous for the position adjustment of the lattice holder relative to the surface plane of the base body if the second bearing comprises a first adjustment screw accommodated in the lattice holder and an opposite bearing arranged on the base body for receiving one end of the adjustment screw, the end of the bearing of the adjusting screw at least two points around the circumference of the adjusting screw. It is even more advantageous if the bearing lying opposite the first adjusting screw is designed as two dowel pins arranged on the base body and running parallel to one another, which form a groove for receiving the adjustment screw, and in particular the dowel pins are pressed into a groove in the base body.

Furthermore, it is advantageous for the positional adjustment of the lattice holder relative to the surface plane of the base body if the third bearing comprises a second adjusting screw accommodated in the lattice holder and an opposite, flat bearing area arranged on the base body for supporting one end of the adjusting screw. This embodiment can be improved if the bearing area on the base body is made of a material that is harder than the surrounding material.

In particular, the adjusting screws can be rounded in the advantageous embodiments of the invention, in particular in order not to damage the surface of the base body. For the manufacture, the rounded ends of the adjusting screws can advantageously be balls into which the adjusting screws are pressed, or the balls are pressed into the adjusting screws.

It is particularly beneficial if the magnetic fastening means are arranged within an imaginary triangle formed from the three bearing points in the surface plane of the base body and / or the lattice holder. This prevents the grid holder from accidentally leaving its adjusted position.

In particular, it can be advantageous if the grating holder has a receiving area for optical grids on the surface facing away from the base body, so that the optical grids can be connected to the grating holder in an ideal area. It is even better if the receiving area is designed as a groove which encloses the grid on at least two sides. Ideally, the receiving area can also have a reservoir for fastening means for producing a cohesive connection between optical gratings and grating holder in the receiving area or specifically in the groove.

Lattice holders and / or base bodies can advantageously be produced from aluminum.

Further advantageous embodiments of the invention result from the following description of the figures and the dependent subclaims.

• 1 Seitenansicht einer erfindungsgemäßen Gitterträgervorrichtung mit einem auf einem Grundkörper montierten Gitterhalter,
• 2 Ansicht der zum Grundkörper gerichteten Oberfläche des Gitterhalters,
• 3 Ansicht der zum Gitterhalter gerichteten Oberfläche des Grundkörpers,
• 4 Ansicht der vom Grundkörper abgewandten Oberfläche des Gitterhalters und
• 5 Ansicht der vom Gitterhalter abgewandten Oberfläche des Grundkörpers.

Show it:

• 1 Side view of a lattice support device according to the invention with a lattice holder mounted on a base body,
• 2 View of the surface of the lattice holder facing the base body,
• 3 View of the surface of the base body facing the lattice holder,
• 4 View of the surface of the grid holder facing away from the base body and
• 5 View of the surface of the base body facing away from the lattice holder.

In the different figures of the drawing, the same parts are always provided with the same reference symbols.

In the following description, it is claimed that the invention is not limited to the exemplary embodiments and not to all or more features of the described combinations of features, but rather each individual partial feature of the / each exemplary embodiment is also detached from all other partial features described in connection with it and also in combination with any features of another embodiment of importance for the subject of the invention.

1 shows a lattice girder device according to the invention 1 , there is the grid holder 2 on a basic body 3 along a central assembly axis M assembled on top of each other. An example is in 1 the basic body 3 with one foot 4 connected to which the main body 3 is mounted in a laser device, not shown. It is beneficial if the main body 3 a central hole in particular 21 has, through which a screw can be passed, with which the base body 3 on a holder, in 1 the foot, for example 4 , is connected. This hole 21 is particularly in the 3 and 5 to recognize.

In 2 and 3 are the first depository 5 , the second depository 6 and the third depository 7 shown with which the grid holder 2 as in 1 and 8th relative to a surface plane A of the basic body 3 , which extends in an x and a y direction, on the base body 3 is stored and the relative position of the grid holder 2 to the surface plane A of the basic body 3 on the grid holder 2 is adjustable.

Especially in 4 and 5 are fasteners according to the invention 8th visible with which the grid holder 2 with a magnetic connection against the body 3 held and fixed in storage. In particular, the magnetic fasteners 8th within one of the three storage locations 5 . 6 and 7 formed imaginary triangle in the surface plane A of the basic body 3 and / or the grid holder 2 arranged.

As in 4 and 5 shown, the magnetic fasteners can advantageously 8th in holes in the grid holder 2 and / or base body 3 be formed, in particular the magnetic fasteners 8th on the to the grid holder 2 facing surface of the base body 3 educated.

In 2 and 3 are advantageous versions of the bearings 5 . 6 and 7 shown. In particular the first depository 5 that advantageous the grid holder 2 relative to the body 3 against a translational movement parallel to the surface plane A of the basic body 3 that are in x and y Direction extends in x or y Direction is fixed in 3 to recognize.

It is particularly advantageous if the first depository 5 , as in 3 shown, an at least hemispherical elevation 9 and as in 2 an opposite bearing 10 to start the survey 9 includes. The hemispherical elevation is advantageous 9 at least three points along the scope of the survey 9 through the opposite bearing 10 locked in.

In particular, this is opposite to the survey 9 lying storage 10 , as in 2 pictured, a circular opening 11 , An optional improvement is that the edge 12 of storage 10 or the circular opening 11 is formed from material harder than the surrounding material.

The survey is advantageous 9 in particular as a ball arranged in an opening 13 and in particular made of a material that is harder than the surrounding material.

Furthermore, in the 2 and 3 an advantageous design of the second bearing 6 who the grid holder 2 relative to the body 3 against twisting around the first bearing 5 in a plane parallel to the surface plane A of the basic body 3 fixed to recognize.

It is particularly advantageous if the second bearing 6 furthermore in particular adjustment means 14 which has the angle of inclination of the grid holder 2 around the first depository 5 in x -Direction relative to the surface plane A of the basic body 3 that are in x and y Direction.

Conveniently, the second depository 6 also one in the grid holder 2 first adjusting screw picked up 15 and one on the base 3 arranged opposite storage 16 for receiving one end of the adjusting screw 15 include, the bearing the end of the adjusting screw 15 at at least two points on the circumference of the adjusting screw 15 includes. In particular, it is opposite the first adjusting screw 15 lying storage 16 as two on the body 3 arranged, parallel dowel pins 16 trained who, as in 3 illustrates a groove for receiving the adjusting screw 15 form. These dowel pins can in particular in a groove in the base body 3 be pressed in.

Also in 2 and 3 the third bearing point is shown in particular 7 who the grid holder 2 relative to the body 3 against a tilting movement around the first bearing 5 from a plane parallel to the surface plane A of the basic body 3 fixed out. Auxiliary is on the representation of the surface level A in 1 directed.

In particular, the third depository 7 advantageously also like the bearing 6 adjusting 14 have, but, unlike the special version of the bearing 6 , the angle of inclination of the grid holder 2 around the first depository 5 in the y direction relative to the surface plane A that are in x and y Extends in the direction of the base body 3 to adjust.

As with the advantageous design of the second bearing 6 can also be the third depository 7 preferably one in the grid holder 2 picked up second adjusting screw 17 exhibit. The third depository 7 has in this advantageous embodiment with a second adjusting screw 17 especially one on the base body 3 arranged, opposite, flat storage area 18 , shown in 3 , to support one end of the adjusting screw 17 , This storage area 18 is advantageously on the base body 3 made of a material that is harder than the surrounding material.

Especially for the advantageous versions with adjusting screws 15 and or 17 the ends of the adjustment screws may be rounded. The rounded end of the adjusting screws is preferred 15 and or 17 one ball each in the ends of the adjusting screws 15 and or 17 is pressed.

For the inclusion of an optical grating (not shown), as in 1 and 4 , the grid holder 2 advantageously a recording area 19 on the to the main body 3 have formed opposite surface. In particular, this recording area 19 be designed as a groove which encloses the grid on at least two sides. In a preferred embodiment there is a reservoir in the receiving area or specifically in the groove 20 for fasteners for creating a material connection between the optical grating and grating holder 2 educated.

In particular, the grid holder 2 and the main body 3 made of aluminium.

To illustrate the invention, a grid change or a grid holder change is possible in a possible embodiment variant according to the 1 to 5 described in more detail below.

In practice, the grating is advantageously changed in such a way that the optical grids are each on a grating holder 2 are pre-assembled and pre-adjusted and manually on the base body 3 to be assembled.

The assembly process of the grid holder is simplified 2 on the base body 3 by magnetic attraction, which the grid holder 2 on the base body 3 fixed easily replaceable by the three-point storage according to the invention.

To the advantages of the lattice girder device according to the invention 1 the three-point mounting is explained below using a practical adjustment example.

At the beginning, a correspondingly desired number of optical gratings is preassembled on grating holders, e.g. B. three optical gratings, in particular with 1800 L / mm, 2400 L / mm and 3000 L / mm groove density, each on a lattice girder. The grating holder is for holding optical grids 2 trained, in particular with a separate receiving area 19 , in which in particular a reservoir 20 for fasteners, e.g. B. adhesive, is formed. This allows a cohesive connection of the grid holder 2 and optical gratings are generated.

The following steps only have to be done once for the respective optical grating or grating holder 2 be performed.

A grid holder 2 comes with a pre-assembled optical grille on the base plate 3 assembled. Here is the grid holder 2 only in three places on the base plate 3 stored. At this point, the optical grating is not yet effectively aligned with the laser system.

The first depository 5 , especially a ball bearing, is a fixed point on the base plate 3 and limits translational movement parallel to the surface plane A of the basic body 3 that are in x and y Direction extends in x or y Direction one. The grid holder 2 at this point the assembly can only be parallel to the surface level A of the base body rotate and / or relative to this about the pivot point of the first bearing 5 , especially a ball 13 tend.

The second depository follows 6 determined, this can in particular adjustment 14 , e.g. B. a first adjusting screw 15 , exhibit. The second depository is determined 6 by the angle of inclination of the grid holder 2 around the first depository 5 in x -Direction relative to the surface plane A of the basic body 3 that are in x and y Direction extends, is set. The second depository also includes 6 conveniently means to the grid holder 2 relative to the body 3 against twisting around the first bearing 5 in a plane parallel to the surface plane A of the basic body 3 to prevent. Hence the second depository 6 after determining the angle of inclination of the grid holder 2 around the first depository 5 in x -Direction relative to the surface plane A of the basic body 3 that are in x and y Direction extends, determined.

Finally, by means of an advantageous third adjustment means 14 , e.g. B. a second adjusting screw 17 , at the third depository 7 the second angle of inclination of the grid holder 2 around the first depository 5 in the y direction relative to the surface plane A of the basic body 3 that are in x and y Direction extends. The lattice holder is advantageous 2 through the third depository 7 relative to the base body against a tilting movement around the first bearing point 5 from a plane parallel to the surface plane A of the basic body 3 fixed out.

If the bearing points are determined or adjusted as described, the grille holder or the optical grille is adjusted and can be removed. The set adjustment is retained. Every time this lattice girder on the main body 3 is installed, it assumes the adjusted position.
This adjustment process can be repeated with any number of grating holders with the same or different optical grids. In this example, at the end of the entire adjustment process, there are three lattice holders that have been pre-adjusted in accordance with the requirements of the optical grating 2 Including optical grating with 1800 L / mm, 2400 L / mm and 3000 L / mm groove density before and can be reproducibly changed any number of times in practical use without readjustment, thereby creating a high level of tunability of the laser.

The invention is not limited to the exemplary embodiments shown and described, but also encompasses all embodiments having the same effect in the sense of the invention. It is expressly emphasized that the exemplary embodiments are not restricted to all features in combination; rather, each individual partial feature can also have an inventive meaning in isolation from all other partial features. Furthermore, the invention has not yet been limited to the combination of features defined in claim 1, but can also be defined by any other combination of specific features of all the individual features disclosed overall. This means that basically every single feature of claim 1 can be omitted or replaced by at least one single feature disclosed elsewhere in the application.

LIST OF REFERENCE NUMBERS

1

Girder device

2

Mounting

3

body

4

foot

5

First depository

6

Second depository

7

Third depository

8th

Magnetic fasteners

9

Hemispherical elevation

10

Storage opposite the hemispherical elevation

11

Circular opening

12

Edge of the bearing opposite the hemispherical elevation

13

Bullet

14

adjusting

15

First adjustment screw

16

Bearing opposite the first adjusting screw, dowel pins 16

17

Second adjustment screw

18

storage area

19

reception area

20

reservoir

21

Central hole in the body

A

surface plane

M

mounting axis

X

Extension direction x the surface level of the base body

Y

Extension direction y of the surface plane of the base body

Claims (10)

Lattice support device (1) for optical gratings, comprising a grating holder (2) mounted on a basic body (3), the grating holder (2) being designed to receive an optical grating and the basic body (3) and grating holder (2) along a central assembly axis ( M) can be mounted on top of one another, the base body (3) being mounted in a laser device, characterized in that the grid holder (2) is relative to a surface plane (A) which extends in an x and a y direction Base body (3) with a first (5), a second (6) and a third (7) bearing point is mounted on the base body (3) and the relative position of the grid holder (2) to the surface plane (A) of the base body (3 ) is adjustable on the grid holder (2), and the grid holder (2) is connected to the base body (3) with a magnetic connection. Lattice support device (1) Claim 1 , characterized in that the second bearing point (6) has adjusting means (14) which adjust the angle of inclination of the lattice holder (2) around the first bearing point (5) in the x direction relative to the surface plane (A) of the base body (3). Lattice support device (1) Claim 1 or 2 , characterized in that the third bearing point (7) has adjustment means (14) which adjust the angle of inclination of the lattice holder (2) around the first bearing point (5) in the y direction relative to the surface plane (A) of the base body (3). Lattice support device (1) according to one of the Claims 1 to 3 , characterized in that the second bearing point (6) comprises a first adjusting screw (15) received in the lattice holder (2) and an opposite bearing (16) arranged on the base body (3) for receiving one end of the adjusting screw (15), wherein the bearing (16) encloses the end of the adjusting screw (15) at at least two points on the circumference of the adjusting screw (15). Lattice support device (1) according to one of the Claims 1 to 4 , characterized in that the third bearing point (7) has a second adjusting screw (17) accommodated in the lattice holder (2) and an opposite, planar bearing area (18) arranged on the base body (3) for supporting one end of the adjusting screw (17) includes. Lattice support device (1) Claim 4 or 5 , characterized in that the end of the adjusting screws (15, 17) is rounded. Lattice support device (1) Claim 6 , characterized in that the rounded end of the adjusting screws (15, 17) is a ball into which the adjusting screw (15, 17) is pressed, or a ball is pressed into the adjusting screw (15, 17). Lattice support device (1) according to one of the Claims 1 to 7 , characterized in that the magnetic connection with magnetic fastening means (8) arranged within an imaginary triangle formed from the three bearing points (5 to 7) in the surface plane (A) of the base body (3) and / or the grid holder (2) are generated. Lattice support device (1) Claim 8 , characterized in that the magnetic fastening means (8) are formed in bores in the grid holder (2) and / or in the base body (3). Laser device with a lattice support device (1) according to one of the Claims 1 to 9 ,

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