DE102021107412B3 - Compact adjustment mount for adjusting an optical tube - Google Patents

Abstract

Adjustment mount for holding an optical tube (1) with an optical axis (1.0), containing a monolithic carrier (2) with a mechanical axis and a first and two auxiliary mounts (3, 4) via which the optical tube (1) with the Carrier (2) is connected. By means of the first and the second auxiliary mount (3, 4), the optical tube (1) has two rotational degrees of freedom in relation to the carrier (2). In addition, the optical tube (1) has two translational degrees of freedom relative to the carrier (2), at least by means of the first auxiliary mount (3). There is a fixing unit acting in the axial direction of the mechanical axis, by means of which the first and the second auxiliary mount (3, 4) can be braced with end faces formed on the carrier (2).

Description

The invention relates to an adjustment mount with an optical tube as you generically from WO 2020/207536 A1 is known.

There are a large number of adjustment mounts, consisting of a carrier and an auxiliary mount, in which an optical component to be adjusted can be adjusted radially and then fixed. These adjustment mounts have in common that the auxiliary mount, which is rigidly connected to the optical component, can be moved relative to the mount via at least two adjustment devices guided or mounted in the mount and directly or indirectly connected to the auxiliary mount, whereby the position of the optical axis of the component is adjusted.

Due to different framework conditions and accuracy requirements, there are a large number of versions of the adjustment devices for adjustment mounts known from the prior art. In order to ensure an unconstrained adjustment in at least two directions of action that form an angle (usually 90°) with one another, the known adjustment mounts often have differently constructed holding and/or restoring devices in addition to the adjustment devices, which together allow adjustment and fixing.

To fix a set adjustment position of the auxiliary mount and thus the optical component relative to the carrier, the adjustment devices are usually mechanical, e.g. B. by lock nuts or grub screws, or by a paint .fixiert. Fixing the adjustment position z. B. via lock nuts, however, has the disadvantage that forces act in a radial direction or moments in a radial direction, which can lead to maladjustment. On the other hand, a loosening of the fixation, which can occur as a result of mechanical stress or long-term influences, can lead directly to radial play and thus also to maladjustment.

In the WO 2020/207536 A1 discloses an adjustment mount for the radial adjustment of an optical unit with an optical axis, which does not have the disadvantages described. The adjusting mount comprises a carrier, two adjustment devices which are aligned orthogonally to one another and are mounted in the carrier, and an auxiliary mount which is suspended from the adjustment devices. The adjusting devices each have a radially acting adjusting screw, via which the radial adjustment of the auxiliary mount takes place. The adjusting screws are mounted in ball joints and can carry out compensatory movements, so that unconstrained guidance is possible. To fix the adjustment position, cover elements are provided, which are fastened to the carrier on both sides and are clamped together in such a way that they clamp the auxiliary mount in the radial direction.
An arrangement of two such adjustment mounts, particularly when they are part of a common frame, is suitable for adjusting an optical tube and is also disclosed in the document. The disadvantage of such an arrangement is its complex structure, which leads to a comparatively large radial expansion of the arrangement. In addition, the arrangement contains a large number of individually manufactured components, which leads to high production costs.
For the purposes of the present description, the in the aforementioned WO 2020/207536 A1 disclosed arrangement with two adjustment mounts, an adjustment mount with two auxiliary mounts.

It is the object of the invention to provide an adjustment mount which also allows an unconstrained adjustment and subsequent fixing of an optical tube, but at the same time has a more compact and simple structure.

The object of the invention is for an alignment mount with an optical tube having an optical axis, containing a carrier having a mechanical axis, and a first and a second auxiliary mount, via which the optical tube with the carrier is spaced apart from one another in one of two ways radial planes, with the first and the second auxiliary mount leaving the optical tube with two rotational degrees of freedom (Rx, Ry) for tilting the optical axis relative to the mechanical axis, and at least the first auxiliary mount also leaving the optical tube for adjustment in the radial direction mechanical axis leaves two translational degrees of freedom (x, y), solved.

The carrier is a monolithic component with two inner end faces and there is a fixing unit acting in the axial direction of the mechanical axis, by means of which the first and the second auxiliary mount can each be clamped to the carrier with an inner end face facing one of the end faces .

It is essential to the invention that the fixing unit contains two clamping disks and at least two bolts that clamp the clamping disks to one another in the axial direction indirectly via the first and the second auxiliary mount and the carrier.

The carrier is formed in particular from an extruded profile.

In an advantageous embodiment, at least the first auxiliary mount is formed by a slotted flange with a cup cutting edge formed thereon, which is clamped onto a peripheral surface of the optical tube and is connected to the carrier via at least two actuating units in a radially forcibly guided manner.

Advantageously, the at least two adjusting units are each formed by a grub screw, each of which is guided in a radial bore formed in the carrier and bears directly against the slotted flange.

In another advantageous embodiment, at least the first auxiliary mount is formed by a flexurally elastic perforated disk, which is firmly connected to the optical tube and is connected to the carrier in a radially forcibly guided manner via at least two actuating units.

Here, too, at least two adjusting units are each formed by a grub screw, which is guided in each case in a radial bore formed in the carrier. In particular, they are in direct contact with an outer edge of the flexible perforated disk or are parallel to the flexible perforated disk on the optical tube.

In particular, there are exactly four adjusting units or exactly two adjusting units, each of which is assigned a radially symmetrically opposite return spring in one of the radial bores.

It is advantageous for the second auxiliary mount to be in the form of an O-ring which is fixed in the axial direction between the optical tube and the carrier, the O-ring lying in particular in a V-groove arranged on the optical tube.

Alternatively, it is advantageous for the second auxiliary mount to be in the form of a further slotted flange with a further cup cutting edge formed thereon, which is clamped onto the optical tube and is arranged fixedly in relation to the carrier.

A third advantageous alternative for the second auxiliary mount is its design using a further flexible perforated disk which is firmly connected to the optical tube and to the carrier.

• 1a-1f ein erstes Ausführungsbeispiel für eine Justierfassung mit einer ersten und einer zweiten Hilfsfassung in Form von radial justierbaren, geschlitzten Flanschringen mit Ringschneide,
• 2 ein zweites Ausführungsbeispiel für eine Justierfassung mit einer ersten und einer zweiten Hilfsfassung in Form von radial justierbaren biegeelastischen Lochscheiben,
• 3 Teilansicht eines ein dritten Ausführungsbeispiels für eine Justierfassung mit einer zweiten Hilfsfassung in Form eines O-Ringes,
• 4 ein viertes Ausführungsbeispiel mit einer radial justierbaren ersten Hilfsfassung mit einem geschlitzten Flanschring und einer radial nicht justierbaren zweiten Hilfsfassung mit einem weiteren geschlitzten Flanschring und
• 5 ein fünftes Ausführungsbeispiel mit einer radial justierbaren ersten Hilfsfassung mit einer biegeelastischen Lochscheibe und einer radial nicht justierbaren zweiten Hilfsfassung mit einer weiteren biegeelastischen Lochscheibe.

The invention is explained in more detail below on the basis of exemplary embodiments with the aid of drawings. Here show:

• 1a-1f a first exemplary embodiment for an adjusting mount with a first and a second auxiliary mount in the form of radially adjustable, slotted flange rings with a cup point,
• 2 a second exemplary embodiment for an adjustment mount with a first and a second auxiliary mount in the form of radially adjustable flexible perforated discs,
• 3 Partial view of a third embodiment of an adjustment mount with a second auxiliary mount in the form of an O-ring,
• 4 a fourth embodiment with a radially adjustable first auxiliary mount with a slotted flange ring and a radially non-adjustable second auxiliary mount with a further slotted flange ring and
• 5 a fifth embodiment with a radially adjustable first auxiliary mount with a flexible perforated disk and a radially non-adjustable second auxiliary mount with a further flexible perforated disk.

All versions of an adjustment mounts 0 according to the invention, including the first exemplary embodiment, are shown in FIGS 1a-1f are provided for grasping and adjusting an optical tube 1 with an optical axis 1.0.

An optical tube 1 in the sense of this description is to be understood as meaning individual or multiple optical assemblies that are held in a fixed arrangement relative to one another along an optical axis in a common, monolithic or joined casing. Specifically, it can be, for example, a collimator or a beam-expanding lens (beam expander).

The adjustment mount basically contains a monolithic carrier 2 with a mechanical axis 2.0 and a first and two auxiliary mounts 3, 4, via which the optical tube 1 is connected to the carrier 2 in one of two radial planes E spaced apart from one another.
By means of the first and the second auxiliary mount 3, 4, the optical tube 1 can be freely tilted with its optical axis 1.0 relative to the mechanical axis 2.0. For this purpose, the first and the second auxiliary mount 3, 4 are designed in such a way that the optical tube 1 has two rotational degrees of freedom Rx, Ry of a Cartesian coordinate system relative to the carrier 2. In addition, at least the first auxiliary mount 3 is designed such that the mounted optical tube 1 has two translational degrees of freedom x, y relative to the carrier 2 for adjustment in the radial direction to the mechanical axis 2.0.
Due to the remaining degrees of freedom of the two auxiliary mounts 3, 4, the optical tube 1 can inner Half of the adjustment mount 0 are adjusted so that its optical axis 1.0 deviating from the mechanical axis 2.0 of the carrier 2 is aligned or at least parallel, for example, to a beam incidence direction or another optical axis.
In addition, there is a fixing unit 9, by means of which the two auxiliary mounts 3, 4, with inner end faces 3.1, 4.1 facing one another, are fixed to the carrier
2 adjacent to the carrier 2 can be braced in the axial direction of the mechanical axis 2.0.

It is essential to the invention that the carrier 2 is formed by a monolithic component. A commercially available extruded profile, e.g. made of aluminium, magnesium, brass or an alloy of these materials, is advantageously used for this purpose, in particular one with a cross section of 80 mm x 80 mm and a diameter for the central bore of 40 mm (with the code: 80 x 80 D40 ), such as in 1a shown. This is, for example, a construction profile from a modular system from ITEM Industrietechnik GmbH with a square cross-section and a large central bore, which is actually intended to accommodate bearings or the passage of shafts, spindles and axles. The use of a monolithic component, in particular an extruded profile, as a carrier 2 for an adjustment mount 0 is new. When constructing optical devices and modules, it is also not obvious to resort to construction elements for special machine construction, since there are different tolerance requirements here. Since the carrier 2 of an adjustment mount according to the invention does not represent a reference basis for the adjustment, but only a mechanical holder for the optical tube 1 and the auxiliary mounts 3, 4, the tolerances of the carrier 2 have no influence on the adjustment result. The optical tube 1 is adjusted with its optical axis 1.0 to an incident beam or another optical axis and not to a reference base on the carrier 2. The carrier 2 formed by an extruded profile can be individually adapted for various exemplary embodiments with little effort.

To an extruded profile as a carrier 2 for the adjustment detection according to a first embodiment, shown in the 1a - 1f To adapt, it is drilled out from its two ends in the direction of its mechanical axis 2.0, which is formed here by an axis of symmetry, so that two inner end faces 2.1 that face each other and are parallel to one another arise. In 1b a section through the adjustment mount 0 is shown reduced to the carrier 2 in the form of the construction profile. Leading into the drilled areas, four radial bores 2.2 are introduced in one of the planes E, ie threaded bores which are directed in the radial direction at an angular distance of 90° to one another on the mechanical axis 2.0. Furthermore, a tangential bore 2.3 is introduced per plane E, ie a through bore which is directed tangentially to a central bore 2.5 formed in the center of the carrier 2 in one of the two drilled-out areas. In addition, four axial bores 2.4 offset from one another at an angular distance of 90° are made in the end faces 2.1. The arrangement of the various holes is also well in the 1d to recognize.

In the first embodiment shown in FIGS 1a-1f , are
the first auxiliary mount 3 and the second auxiliary mount 4 are each formed by a slotted flange 5 with a cup point 5.1 formed thereon, a clamping screw 5.2 and four adjusting units 6. In this embodiment of the adjusting mount 0, the optical tube 1 to be held must be at least in the planes E be cylindrical, where it is clamped in the cup point 5.1 along a perimeter. Compared to the second exemplary embodiment described later, it is advantageous that the clamping of the slotted flange 5 on the optical tube 1 results in a connection that can be established and released again very quickly.
The first auxiliary mount 3 and the second auxiliary mount 4 are constructed identically in this first exemplary embodiment. The slotted flange 5 is applied to the end face 2.1 and encloses the optical tube 1, with the ring edge 5.1 resting on the optical tube 1 in the plane E. The clamping screw 5.2 is screwed into the slotted flange 5 through the tangential bore 2.3, whereby a clamping force acts on the optical tube 1 along the peripheral line depending on the screwing depth. The clamping screw 5.2 is loosened for adjustment.
Due to the limited line contact between the optical tube 1 and the slotted flange 5, the optical tube 1 can be pivoted relative to the slotted flange 5 and thus relative to the carrier 2 by two rotational degrees of freedom Rx and Ry of a Cartesian coordinate system and also in a relative to the mechanical axis 2.0 deflected position of the optical tube 1 can be clamped to this. The x and y axes of the Cartesian coordinate system lie in the plane E and the z axis is aligned in the direction of the mechanical axis 2.0.
The slotted flange 5 can be displaced radially in the plane E in the x and y directions. For this purpose, a grub screw is arranged in each of the four radial bores 2.2, which out in the radial bore 2.2 represents one of the actuating units 6. The slotted flange 5 is in a radially positively guided connection with the carrier 2 via the actuating units 6 . This means that the slotted flange 5 can only be displaced radially and in a defined manner relative to the carrier by actuating the actuating unit 6 . Alternatively, the radial displacement can take place via only three grub screws arranged at equal angular distances from one another. Or there are two grub screws arranged at an angular distance of 90° from one another and a tensioned return spring resting against the slotted flange 5 is present radially opposite each other in a radial bore 2.2 then designed as a blind hole. Since a radial adjustment is also possible with the two auxiliary mounts 3, 4, the optical tube 1 and thus its optical axis 1.0 can not only be tilted within the carrier 2 but can also be shifted radially.

The first exemplary embodiment has a fixing unit 9 which, as in 1e and 1f easy to see, executed. It contains two clamping disks 9.1 and four bolts 9.2 clamping the clamping disks 9.1 indirectly via the first and the second auxiliary mount 3, 4 and the carrier 2 in the axial direction. The two clamping disks 9.1 are each on a free side of one of the two slotted flanges 5, or the slotted flange 5 and the further slotted flange 11. They have four boreholes arranged in alignment with one another, through which the four bolts 9.2, each guided in one of the axial boreholes 2.4, protrude. The four bolts 9.2 each have external threads at their ends, onto which nuts are screwed for bracing the clamping disks 9.1. When the nuts are tightened, the two slotted flanges 5 or the slotted flange 5 and the further slotted flange 11 are pressed between the clamping discs 9.1 against the end faces 2.1 on the carrier 2, whereby a set adjustment position of the optical tube 1 is achieved by an axial frictional connection of the two slotted flanges 5 or the slotted flange 5 and the further slotted flange 11 in the carrier 2 is secured. In principle, the two clamping disks 9.1 can also be clamped using only two or three bolts 9.2. In order to save radial space, the boreholes are not completely within the clamping disks 9.1, based on their cross section, but only partially. The axial bores 2.4 run correspondingly proportionally through the end faces 2.1.

A second embodiment, as a sectional view in 2 shown differs from the first embodiment only by the design of the first and the second auxiliary mount 3, 4, which is formed here by a flexible perforated disk 7 in each case. This is firmly connected to the optical tube 1 and is connected to the carrier 2 via at least two actuating units 6 in a radially forcibly guided manner. The flexible perforated disk 7 is rigid in the direction of its surface, flexible in the direction orthogonal to its surface, ie in the direction of a sheet metal thickness, and is advantageously made of sheet metal. The flexurally elastic perforated disk 7 is firmly connected to the optical tube 1 and connected to the carrier 2 via at least two actuating units 6 in a radially forcibly guided manner. As based on the first auxiliary version 3 in 2 shown, the actuating units 6 are also formed here by a grub screw, which is guided in a radial bore 2.2 formed in the carrier 2 and rests directly on an outer edge of the flexible perforated disk 7 . The directions of action of the actuating units 6 are here, as in the first exemplary embodiment, in the plane E. Here, too, four actuating units 6 or two actuating units 6, each with a radially oppositely arranged return spring, are advantageously present, particularly in connection with an embodiment of the carrier 2 as an extruded profile. Alternatively, the setting units 6, as on the second auxiliary mount 4 in 2 shown, be arranged in a plane parallel to the plane E and be arranged to act radially on the optical tube 1 . A fixing unit 9 is provided for fixing the two flexible perforated discs 7 after the adjustment, as has already been described. The two clamping disks 9.1 do not act directly on the outer edge of the flexible perforated disk 7 and press it against the carrier 2, but rather they fix the outer edge of the flexible perforated disks 7 indirectly on the carrier 2, in which they orthogonally fix the actuating units 6 that rest on it press against the carrier 2 in relation to their setting direction.

The different designs for the first and second auxiliary mount 3, 4, which each have two rotational and two translational degrees of freedom in the described exemplary embodiments of the adjustment mount, can be combined with one another as desired, so that the optical axis 1.0 of the optical tube 1 can be both tilted and moved .

In the event that the adjustment mount is only intended to enable the optical tube 1 to be tilted, the second auxiliary mount 4 is designed in such a way that it only has two rotational degrees of freedom. The first auxiliary mount 3 can then be any of the first or second auxiliary mounts 3, 4 described above.

In 3 a second auxiliary socket 4 is shown, which is formed by an O-ring 8, which is arranged between a flat surface and a V-groove, is fixed in the axial direction. It is irrelevant for the functionality whether the V-groove is formed on the optical tube 1 and the planar surface is formed on the carrier 2 or vice versa. In practice, however, it is advantageous to eliminate the V-groove on the optical tube 1 form, for example as shown, by two pre-screw rings present on the optical tube 1, with bevels facing each other.

Alternatively, the second auxiliary version 4, as in 4 shown, formed by a further slotted flange 11 with a further cup point 11.1 formed thereon, which is clamped onto the optical tube 1 and is arranged fixedly relative to the carrier 2. The grub screws and the corresponding radial bores 2.2 can then be dispensed with. The further slotted flange 11 can be designed in the same way as the slotted flange 5 .

In a further advantageous alternative, the second auxiliary mount 4, as shown in 5 shown, is formed by a further flexible perforated disc 12, which is firmly connected to the optical tube 1 and the carrier 2. The clamping disk 9.1 of the fixing unit 9 acts directly on the edge of the flexible perforated disk 12.

Reference List

0

alignment detection

1

optical tube

1.0

optical axis

2

carrier

2.0

mechanical axis

2.1

face

2.2

radial bore

2.3

tangential drilling

2.4

axial bore

2.5

central bore

3

first auxiliary version

3.1

inner face of the first auxiliary version

4

second auxiliary version

4.1

inner face of the second auxiliary mount

5

slotted flange

5.1

ring edge

6

actuator

7

flexible perforated disc

8th

0 ring

9

fuser unit

9.1

clamp washer

9.2

bolt

10

clamp plate

11

another slotted flange

11.1

another ring edge

12

another flexible perforated disc

E

radial plane

Claims (12)

Adjusting mount (0) with an optical tube (1), an optical axis (1.0) having, containing a carrier (2), a mechanical axis (2.0) having, and a first and a second auxiliary mount (3, 4) via which the optical tube (1) is connected to the support (2) in one of two radial planes (E) spaced apart from one another, the first and the second auxiliary mount (3, 4) being attached to the optical tube (1) in each case for tilting the optical axis (1.0) relative to the mechanical axis (2.0) leave two rotational degrees of freedom (Rx, Ry) and additionally at least the first auxiliary mount (3) leaves the optical tube (1) for adjustment in the radial direction to the mechanical axis (2.0) two translatory degrees of freedom (x, y), the carrier (2) being a monolithic component with two inner end faces (2.1) and a fixing unit (9) acting in the axial direction of the mechanical axis (2.0) by means of which the first and the second auxiliary ing (3, 4) each with an inner end face facing one of the end faces (2.1), can be clamped to the carrier (2), characterized in that the fixing unit (9) has two clamping discs (9.1) and at least two in the axial direction, the Clamping washers (9.1) contain bolts (9.2) that are clamped together indirectly via the first and second auxiliary mounts and the carrier (2). Adjustment detection (0) after claim 1 , characterized in that the carrier (2) is formed from an extruded profile. Adjustment detection (0) after claim 1 or 2 characterized in that at least the first auxiliary mount (3) is formed by a slotted flange (5) with a cup point (5.1) formed thereon, which is clamped onto a peripheral surface of the optical tube (1) and connected to the carrier (2) via at least two adjusting units (6) are connected in a radially forcibly guided manner. Adjustment detection (0) after claim 3 , characterized in that the at least two adjusting units (6) are each formed by a grub screw which is guided in each case in a radial bore (2.2) formed in the support (2) and bears directly against the slotted flange (5). Adjustment detection (0) after claim 1 or 2 , characterized in that at least the first auxiliary mount (3) is formed by a flexurally elastic perforated disc (7) which is firmly connected to the optical tube (1) and is radially forcibly guided to the carrier (2) via at least two adjusting units (6). connection is established. Adjustment detection (0) after claim 5 , characterized in that the at least two adjusting units (6) are each formed by a grub screw which is guided in each case in a radial bore (2.2) formed in the carrier (2) and rests directly on an outer edge of the flexible perforated disk (7). Adjustment detection (0) after claim 5 , characterized in that the at least two adjusting units (6) are each formed by a grub screw which is guided in a radial bore (2.2) formed in the carrier (2) and bears parallel to the flexible perforated disc (7) on the optical tube (1). Adjustment detection (0) after claim 6 , characterized in that exactly four adjusting units (6) are present or exactly two adjusting units (6) are present, each of which is assigned a radially symmetrically opposite return spring in one of the radial bores (2.2). Adjustment detection (0) after claim 1 or 2 , characterized in that the second auxiliary mount (4) is formed by an O-ring (8) fixed in the axial direction between the optical tube (1) and the carrier (2). Adjustment detection (0) after claim 9 , characterized in that the O-ring (8) is arranged in a V-groove on the optical tube (1). Adjustment detection (0) after claim 3 , characterized in that the second auxiliary mount (4) is formed by a further slotted flange (11) with a further cup cutting edge (11.1) formed thereon, which is clamped onto the optical tube (1) and arranged fixedly relative to the carrier (2). is. Adjustment detection (0) after claim 5 , characterized in that the second auxiliary mount (4) is formed by a further flexible perforated disc (12) which is firmly connected to the optical tube (1) and to the carrier (2).

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