EP3851785A1 - Adjusting device with adjustable indicator element and telescopic sight with same - Google Patents

Abstract

The invention relates to an adjusting device (1) for adjusting components that can be coupled to the adjusting device (1), in particular for adjusting a reticle device of a telescopic sight (50), comprising an adjusting cap device (10) with an adjusting cap (11) which is used for mechanical actuation of the adjusting device (1) is rotatably mounted on a base part (40) by a rotary movement about an axis of rotation (A), a coupling part (42) which is designed to transmit a manipulated variable resulting from the movement of the adjusting cap (11) to a to transmit the coupling part (42) connectable component for the purpose of its adjustment, the adjusting cap (11) having a circumferential surface (12) around the axis of rotation (A) on which a scale (13) is applied, which is marked with a position mark ( 41) cooperates on the side of the base part (40), and wherein the adjusting cap device (10) has a fastening groove (20) formed along the circumference in the lateral surface (12) of the adjusting cap (11) has, in which at least one adjustable indicator element (21) is fixed, which rotates with the adjusting cap (11) relative to the base part (40) and marks a defined scale value (P1) of the scale (13). The invention also relates to a telescopic sight herewith.

Description

The invention relates to an adjusting device according to the preamble of claim 1 and a telescopic sight with such a telescopic sight according to claim 15.

Such adjusting devices are preferably used in precision mechanical devices such as optical instruments, telescopic sights and the like. For example, in DE 297 207 37 U1 describes a telescopic sight with a tubular housing tube which has tube mounts for an eyepiece and an objective (system). In this case, an optical reversing system and a reticle assigned to it are present in a central tube, which is fixedly mounted on a double tube in a mount. In addition, further lenses for correcting various image errors can also be arranged in the telescopic sight, for example achromatic lenses for correcting color errors.

An intermediate image designed by the objective in a first image plane on the objective side is shown enlarged in a second image plane on the eyepiece side. Large magnifications only allow limited fields of view, which do not allow an overview of a larger image section, especially over short distances. In order to effectively target these objects too can, the prior art provides a variable magnification, the so-called zoom. In addition, the targeted object is shown reversed and upside down in the first image plane on the objective side and must therefore be erected. A reversing system within the telescopic sight is therefore used to straighten the image.

On the outside, at least two adjustment towers (adjusting devices) are attached at circumferential intervals of 90 degrees, which have a locking ring or an adjusting cap to adjust the reticle according to the target distance and wind.

Conventionally, such a locking ring, which can be rotated by a total of about 350 °, has a fine detent in such a way that it moves one step further when turning (click adjustment), which changes the point of impact at 100 m, e.g. by 10 mm. On the outer circumference of the adjustment tower there is a scale on which the correction made can be read. Depending on the division, e.g. every second click is marked with a white line, while every tenth click is indicated by a number.

In addition, an adjusting ring is provided, through the center of which the optical path runs and which is rotatably mounted relative to the housing tube. With this adjustment ring, the positions of two lens elements of the erecting system can be adjusted along the optical path, which results in a magnification of the telescopic sight.

The telescopic sight thus has adjusting devices in the form of the two adjustment towers for adjusting the reticle and also in the form of an adjusting ring for setting the magnification. The settings are all made independently based on calculations, tables and empirical values of the shooter, which also depend on the weapon and ammunition used. This can quickly lead to errors. In addition, precise and quick changes of settings are difficult.

The aim of the invention is therefore to provide an adjusting device as well as a telescopic sight which support the adjustment of the telescopic sight by the operator and / or simplify the operation, the solution being intended to cause low mechanical complexity and low costs. In addition, the solution should remain easy and convenient to use and have a long service life.

The main features of the invention are specified in the characterizing part of claim 1 and in claim 15. Refinements are the subject of claims 2 to 14 and the description.

The invention relates to an adjusting device for adjusting components that can be coupled to the adjusting device, in particular for adjusting a reticle device of a telescopic sight, with an adjusting cap device with an adjusting cap which is rotatably mounted on a base part for mechanical actuation of the adjusting device by a rotary movement about an axis of rotation. A coupling part is designed to transmit a manipulated variable, which results from the movement of the adjusting cap, to a component that can be connected to the coupling part for the purpose of setting it. The adjusting cap has a circumferential surface around the axis of rotation on which a scale is applied which interacts with a position mark on the side of the base part, in particular in order to be able to read the position of the adjusting cap relative to the base part. According to the invention it is provided that the adjusting cap device in the outer surface of the adjusting cap has a fastening groove formed along the circumference in which at least one adjustable indicator element is fixed, which rotates with the adjusting cap relative to the base part and marks a defined scale value of the scale.

The advantage of this is that an adjusting device is created with which a fast, reliable and easily reproducible setting is ensured. It is thus possible for the one indicator element or also several of the indicator elements to be individually definable in order to be able to operate an individual ballistic curve specified by the user. The adjusting device remains compact. If possible, the indicator elements should also be clearly noticeable to the user in the dark, thus avoiding incorrect settings in the dark. Since this new functionality is completely implemented in the actuating device, it can be used as a standard assembly for a large number of different telescopic sights, in particular also as a replacement or replacement component for other actuating devices.

According to a more detailed embodiment of the adjusting device, it is provided that at least one further indicator element is fixed in the fastening groove, which rotates with the adjusting cap relative to the base part and marks a defined scale value of the scale. It is thus possible to switch quickly between two or more marked positions of the actuating device, for example if different ammunition or an optional silencer is used or if you want to switch back and forth between different shooting distances or environmental parameters.

Each of the indicator elements can preferably be arranged by sliding it along the entire circumference of the fastening groove. This enables maximum flexibility in determining the defined scale values.

In a special embodiment, each of the indicator elements is designed to be removable from the fastening groove in a non-destructive manner. The number of indicator elements can thus be freely selected by the user, in particular by adding or removing.

It is particularly favorable if the fastening groove and each of the indicator elements are arranged in an indicator plane (that is to say in particular a common plane) to which the axis of rotation is oriented perpendicularly. This is because it is advantageous that several indicator elements can be arranged in a single plane and the actuating device is compact. In particular, the adjusting device can be designed to be flat.

For a precise definition of the defined scale values, there is an optional design according to which each of the indicator elements has an indicator tip. It is preferred here that the indicator tips point in the direction of the base part, in particular parallel to the axis of rotation.

Furthermore, the design of the indicator elements can be pointer-like. As a result, the indicator elements are slim, which enables the use of numerous indicator elements or also closely spaced arrangements of two or more indicator elements.

According to a special construction, the fastening groove is either negative dovetail and each of the indicator elements has a corresponding, positive dovetail indicator base, or the fastening groove is negative T-shaped and each of the indicator elements has a corresponding, positive T-shaped indicator base. Precise guidance can be provided by these geometries and the indicator elements are secured against loss. The indicator tip is preferably aligned parallel to the alignment of the indicator base. There is an embodiment according to which the indicator tip is formed on a leg which is arranged at the free end of the indicator base protruding from the fastening groove.

Furthermore, an embodiment is to be preferred according to which the fastening groove is arranged on the side of the scale facing away from the position mark. This is because the indicator elements cannot obscure the view of the position mark and the area of the scale opposite here.

A high degree of flexibility of use and high ease of use are achieved in an embodiment according to which each of the indicator elements can be clamped firmly in the fastening groove in a force-locking manner.

The same advantages result if each of the indicator elements has a tensioning means with which the respective indicator element can be released for displacement in the fastening groove and can be clamped for fixing in the fastening groove.

The clamping means can be a screw which is screwed into the respective indicator element. This makes the construction very simple. Optionally, the screw is a grub screw. This is arranged almost concealed in the installed state and does not interfere with the reading of the scale or hinder the ease of use in any other way. The screw is preferably aligned perpendicular to the fastening groove. As a result, it can be conveniently operated from outside the fastening groove and the indicator element does not tend to slip when it is screwed tight. For the same reasons, it is preferable for the screw to be oriented perpendicular to the axis of rotation. In a special construction, the screw for fixing the respective indicator element can be screwed through this indicator element to such an extent that it comes into contact with a groove bottom of the fastening groove. The screw and thus the indicator element can thus be braced against the fastening groove. In particular, the screw can be screwed through a hole which extends through the end of the indicator base protruding from the fastening groove.

In an optional embodiment, when the clamping means is released, a clearance fit with a form fit is formed between the fastening groove and the respective indicator element. The form fit prevents the indicator element from falling off and the clearance fit enables the indicator element to be moved along the fastening groove.

Conversely, a design is to be preferred according to which, when the clamping means is firmly clamped, a positive interference fit is formed between the fastening groove and the respective indicator element. A stable definition is thus achieved.

It is optionally possible for the indicator element to be elastically deformed within the fastening groove in the clamped state. In this way, stable bracing can be achieved.

In a further development of the adjusting device, it is provided that each of the indicator elements has a visual identifier, preferably an individual letter or an individual number. For example, an individual color is also possible. This enables the user to better assign the different defined scale values.

According to an optional embodiment, the adjusting cap has a carrier element and a cap, the cap being releasably fixed on the carrier element and the fastening groove is formed between the carrier element and the cap. As a result, the indicator elements can be inserted into or removed from the groove after the cap has been loosened.

The cap preferably has a handle structure, in particular on its circumference. In addition, it can be provided that the carrier element and the cap each form a section of the lateral surface, these sections preferably being annular. Optionally, the cap can be screwed onto the carrier element in a detachable manner. This allows the user to repeatedly and reproducibly remove and re-attach the cap. It proves to be particularly advantageous if the cap is held in a force-locking manner by the respective indicator element on the carrier element when the clamping means is firmly clamped. In this way the cap is secured, either additionally or exclusively.

In a more detailed embodiment, the coupling part is designed to transmit the movement of the adjusting cap device electronically and / or mechanically to components that can be connected to the coupling part for the purpose of adjusting them.

In particular, the coupling part can be an adjusting bolt coupled to the adjusting cap device in such a way that a rotation of the adjusting cap about the axis of rotation relative to the base part causes a longitudinal displacement of the adjusting bolt along the axis of rotation. In this way, for example, you can push or pull an adjacent actuator for actuation.

The invention also relates to a telescopic sight with a tubular housing through which an optical path runs along which an eyepiece system, a reticle and an objective system are arranged, and with an adjusting device as described above and below, the coupling part in this way with the reticle is coupled that the movement of the adjusting cap for the purpose of adjusting the reticle is coupled to this. The reticle can therefore be positioned precisely and quickly in the optical path in accordance with the indicator elements. The entire adjusting device is preferably designed to be exchangeable. This means that you can quickly switch between different ammunition or silencers. The advantages of the telescopic sight also correspond to the respective optional configurations of the actuating device.

Optionally, the telescopic sight has an erecting system which is arranged along the optical path between the ocular system and the objective system, the optical path having a first image plane between the objective system and the erecting system and a second image plane between the ocular system and the erecting system. This provides an erected image for the user. This in particular by using the reverse system represents an upside-down image in the first image plane erected in the second image plane.

The reticle should be arranged in one of the first and second image planes. This makes it clear to see.

It is also preferable for the telescopic sight to have a variable magnification. This allows targets to be sighted at different distances. The variable magnification can be brought about by means of at least one lens that can be adjusted along the optical path. The variable magnification is preferably brought about by means of at least two lenses that can be adjusted along the optical path, with a correlation, preferably a mechanical correlation, between the movement of the first and second adjustable lenses.

The systems, that is to say the ocular system, objective system and inversion system, are to be understood as lens arrangements, in particular with convex lenses, concave lenses, scattering lenses, focusing lenses, achromatic lenses and / or the like.

The invention also relates to a firearm with such a telescopic sight. The advantages of the firearm correspond to the respective optional configurations of the adjusting device and the telescopic sight.

Fig. 1

eine Explosionsdarstellung einer Stellvorrichtung;

Fig. 2

eine Vergrößerungsansicht eines Indikatorelementes der Explosionsdarstellung nach Fig. 1;

Fig. 3

eine Seitenansicht der Stellvorrichtung nach Fig. 1 im Zusammenbau mit Teilschnitt;

Fig. 4

eine perspektivische Ansicht eines Zielfernrohrs mit der Stellvorrichtung nach der Fig. 1; und

Fig. 5

einen Längsschnitt durch das Zielfernrohr nach Fig. 4.

Further features, details and advantages of the invention emerge from the wording of the claims and from the following description of exemplary embodiments with reference to the drawings. Show it:

Fig. 1

an exploded view of an actuating device;

Fig. 2

an enlarged view of an indicator element according to the exploded view Fig. 1 ;

Fig. 3

a side view of the adjusting device according to Fig. 1 in assembly with partial cut;

Fig. 4

a perspective view of a telescopic sight with the adjusting device according to FIG Fig. 1 ; and

Fig. 5

a longitudinal section through the telescopic sight Fig. 4 .

In Fig. 1 one can see an adjusting device 1 in an exploded view. This adjusting device is shown in FIG Fig. 2 an indicator element 24 is shown enlarged. Finally, the adjusting device is after Fig. 1 reassembled in a side view with a partial section in the Fig. 3 shown. the Fig. 1 , 2 and 3rd are therefore described together, the same reference numbers referring to the same components. The adjusting device 1 is in particular for adjusting components that can be coupled to the adjusting device 1, in particular for adjusting a reticle device (reticle for short) of a telescopic sight 50 (see FIG Fig. 4 ) intended.

In particular, how to do this in the Fig. 1 and 3 recognizes, the adjusting cap device 10 has an adjusting cap 11, which is rotatably mounted on a base part 40 for mechanical actuation of the adjusting device 1 by a rotary movement about an axis of rotation A, this at least indirectly. A coupling part 42, in particular according to Fig. 3 is designed as an adjusting bolt 43, it is provided to transmit a manipulated variable, which results from the rotary movement of the adjusting cap 11, to a component that can be connected to the coupling part 42 for the purpose of its adjustment. The coupling part 42 is in particular an adjusting bolt 43 coupled to the adjusting cap device 10 in such a way that a rotation of the adjusting cap 11 about the axis of rotation A relative to the base part 40 causes a longitudinal displacement of the adjusting bolt 43 along the axis of rotation A.

The adjusting cap 11 has a circumferential surface 12 around the axis of rotation A, in particular in order to grip and rotate the adjusting cap 11 here. A scale 13, which interacts with a position mark 41 on the side of the base part 40, is applied to the lateral surface 12. The user can thus determine the set value on the basis of the scale value to which the position marker 41 is pointing.

Furthermore, the adjusting cap device 10 has in the jacket surface 12 of the adjusting cap 11 a fastening groove 20 formed along the circumference, which is arranged on the side of the scale 13 facing away from the position mark 41. At least one adjustable indicator element 21, here in particular four indicator elements 21, 22, 23, 24, which rotate with the adjusting cap 11 relative to the base part 40 and each have a defined scale value P1, P2, P3, P4 of the scale 13, is fixed in this fastening groove 20 to mark. The fastening groove 20 and each of the indicator elements 21, 22, 23, 24 are arranged in an indicator plane E, to which the axis of rotation A is oriented perpendicularly.

Each of the indicator elements 21, 22, 23, 24 can be arranged by sliding it along the entire circumference of the fastening groove 20 and can be individually and individually fixed, for example in order to be able to operate an individual ballistic curve specified by the user. Each of the indicator elements 21, 22, 23, 24 can also be removed non-destructively from the fastening groove 20, so that the number of indicator elements 21, 22, 23, 24 can be freely selected by the user, in particular by adding or removing. For this purpose, the fastening groove 20 is designed in a negative T-shape and each of the indicator elements 21, 22, 23, 24 has a corresponding, positive T-shaped indicator foot 26, which is received in the fastening groove 20. Instead of a form fit using a T shape, a form fit using a dovetail shape would also come into consideration. Each of the indicator elements 21, 22, 23, 24 can be clamped in a force-locking manner in the fastening groove 20.

How to look in the enlarged view of the Fig. 2 can recognize, the indicator element 24 shown there has an indicator tip 25. The indicator tip 22 is aligned parallel to the alignment of the indicator base 26. For this purpose, the indicator tip 25 is formed on a leg 32 which is attached to the free end of the mounting groove 20 (cf. Fig. 3 ) protruding indicator foot 26 is arranged. The indicator tips 25 of the indicator elements 21, 22, 23, 24 each point in the direction of the base part 40, in particular parallel to the axis of rotation A (cf. Fig. 1 and 3 ). In addition, the indicator element 24 has Fig. 2 via a visual identifier 30, which in the present case is an individual number, namely the number "4". With the exception of the individual identifier 30, the indicator element 24 shown is structurally identical to the further indicator elements 21, 22, 23 of FIG Fig. 1 and 3 .

Each of the indicator elements 21, 22, 23, 24 has a tensioning means 27 with which the respective indicator element 21, 22, 23, 24 can be released for displacement in the fastening groove 20 and can be tightened in the fastening groove 20 for fixing. The tensioning means 27 is a screw 28, in particular a grub screw, which is screwed into the respective indicator element 21, 22, 23, 24. These screws 28 are each aligned perpendicular to the fastening groove 20 and to the axis of rotation A. To fix the respective indicator element 21, 22, 23, 24, the screws 28 can be screwed through the respective indicator element 21, 22, 23, 24 to such an extent that they come into contact with a groove bottom 29 of the fastening groove 20. For this purpose, the respective indicator element 21, 22, 23, 24 has a hole 31 which extends from the end of the indicator base 26 protruding from the fastening groove 20 through the latter. The groove bottom 29 is cylindrical and flat.

When the clamping means 27 is released, there is a clearance fit with a form fit between the fastening groove 20 and the respective indicator element 21, 22, 23, 24. When the clamping means 27 is clamped, this changes to a certain extent to a positive interference fit between the fastening groove 20 and the respective indicator element 21, 22, 23, 24, in particular due to the clamping means 27 to be added to the respective indicator element 21, 22, 23, 24 , 22, 23, 24 elastically deformed in the clamped state within the fastening groove 20, at least slightly.

It can be seen that the adjusting cap 11 has a multi-part carrier element 14 and a cap 15, the cap 15 having an internal thread 18 being detachably screwed onto an external thread 19 of the carrier element 14. The cap 15 is additionally secured on the carrier element 14 by means of a screw 17. In addition, when the clamping means 27 is firmly clamped, the cap 15 is held in a force-locking manner on the carrier element 14 by the respective indicator element 21, 22, 23, 24. Both the carrier element 14 and the cap 15 each form an annular section of the lateral surface 12. The cap 15 has a handle structure 16 here.

The fastening groove 20 is formed between the carrier element 14 and the cap 15. By removing the cap 15, indicator elements 21, 22, 23, 24 can be removed or inserted, for example by detaching or hanging on the carrier element 14.

the Fig. 4 and 5 show a telescopic sight 50 with the adjusting device 1 according to FIG Fig. 1 , once from a perspective view and once as a longitudinal section. The telescopic sight 50 has a tubular housing 51 through which an optical path P extends. An eyepiece system 52, an erecting system 55, a reticle 54 and an objective system 53 are arranged in the tubular housing 51 along this optical path P. The erecting system 55 is arranged along the optical path P between the ocular system 52 and the objective system 53, the optical path P having a first image plane BE1 between the objective system 53 and the erecting system 55 and a second image plane BE2 between the ocular system 53 and the erecting system 55 . The image planes BE1, BE2 are exclusively the result of the optical rays that pass through the optical path P. An optical element can optionally be arranged in the image planes BE1, BE2. Alternatively, however, a position of the image planes BE1, BE2 in the area of a cavity is also possible. The inversion system 55 represents an upside-down image in the first image plane BE1 erected in the second image plane BE2.

The telescopic sight 50 has a variable magnification which is brought about by means of two lenses 58, 59 which can be adjusted along the optical path P, there being a mechanical correlation between the movement of the first and second adjustable lenses 58, 59. These two adjustable lenses 58, 59 are part of the inversion system 55. With the aid of a magnifying ring 57 on the side of the tubular housing 51 on which the ocular system 52 is also arranged and through which the optical path P runs, the two adjustable lenses 58 , 59 change their position along the optical path P and thus adjust the magnification. This adjustment of the two adjustable lenses 58, 59 is effected by means of a cam gear of the reversing system 55.

The adjusting device 1 sits on a stop surface on the outside of the tubular housing 51 and is provided in the present case for the distance adjustment, as a so-called height tower. Alternatively or additionally, the different lateral adjusting device for cross wind, namely the side adjustment tower 56, can also be provided by an adjusting device according to the Figs. 1 to 3 be equipped. Here, of course, a different scale would have to be provided on the lateral surface 12.

The coupling part 42 is coupled to the reticle 54 in such a way that the movement of the adjusting cap 11 is coupled to the reticle 54 for the purpose of adjusting the reticle 54. For this purpose, the entire reversing system 55, which for this purpose is seated in an inner tube 60, is pivoted within the tubular housing 51.

In the present case, the reticle 54 sits in the first image plane BE1. In contrast to this, however, the reticle 54 can also be arranged in the second image plane BE2. The reticle 54 can be a graphic representation and / or an electronic display.

The invention is not restricted to one of the embodiments described above, but can be modified in many ways.

All of the features and advantages arising from the claims, the description and the drawing, including structural details, spatial arrangements and method steps, can be essential to the invention both individually and in a wide variety of combinations.

List of reference symbols

1 Adjusting device 40 Base part 41 Position mark 10 Adjustable cap device 42 Coupling part 11 Adjustable cap 43 Set bolts 12th Outer surface 13th scale 50 Rifle scope 14th Support element 51 Tubular housing 15th cap 52 Eyepiece system 16 Handle structure 53 Lens system 17th Fastening screw 54 Reticle 18th inner thread 55 Reverse system 19th External thread 56 Side adjustment tower 57 Magnifying ring 20th Fastening groove 58 optical lens 21 Indicator element 59 optical lens 22nd Indicator element 60 Inner tube 23 Indicator element 24 Indicator element A. Axis of rotation 25th Indicator tip BE1 first image level 26th Indicator foot BE2 second image level 27 Clamping device E. Indicator level 28 screw P. optical path 29 Groove bottom P1 defined scale value 30th visual identifier P2 defined scale value 31 hole P3 defined scale value 32 leg P4 defined scale value

Claims (15)

Adjusting device (1) for adjusting components that can be coupled to the adjusting device (1), in particular for adjusting a reticle device of a telescopic sight (50), comprising: - an adjusting cap device (10) with an adjusting cap (11) which, for mechanical actuation of the adjusting device (1), is mounted on a base part (40) so as to be rotatable about an axis of rotation (A), - A coupling part (42) which is designed to transmit a manipulated variable, which results from the movement of the adjusting cap (11), to a component that can be connected to the coupling part (42) for the purpose of setting it, - wherein the adjusting cap (11) has a circumferential surface (12) around the axis of rotation (A) on which a scale (13) is applied, which interacts with a position mark (41) on the side of the base part (40),
characterized in that - The adjusting cap device (10) in the lateral surface (12) of the adjusting cap (11) has a fastening groove (20) formed along the circumference in which at least one adjustable indicator element (21) is fixed, which is with the adjusting cap (11) relative to the The base part (40) rotates and marks a defined scale value (P1) on the scale (13). Adjusting device (1) according to claim 1, characterized in that at least one further indicator element (22, 23, 24) is fixed in the fastening groove (20), which rotates with the adjusting cap (11) relative to the base part (40) and defines a Marked the scale value (P2, P3, P4) on the scale (13). Adjusting device (1) according to one of Claims 1 or 2, characterized in that each of the indicator elements (21, 22, 23, 24) can be arranged by sliding it along the entire circumference of the fastening groove (20). Adjusting device (1) according to one of the preceding claims, characterized in that each of the indicator elements (21, 22, 23, 24) can be removed from the fastening groove (20) in a non-destructive manner. Adjusting device (1) according to one of the preceding claims, characterized in that the fastening groove (20) and each of the indicator elements (21, 22, 23, 24) are arranged in an indicator plane (E) to which the axis of rotation (A) is perpendicular is. Adjusting device (1) according to one of the preceding claims, characterized in that each of the indicator elements (21, 22, 23, 24) has an indicator tip (25). Adjusting device (1) according to one of the preceding claims, characterized in that a) the fastening groove (20) has a negative dovetail shape and each of the indicator elements (21, 22, 23, 24) has a corresponding, positive dovetail indicator foot (26), or b) the fastening groove (20) has a negative T-shaped design and each of the indicator elements (21, 22, 23, 24) has a corresponding, positive T-shaped indicator base (26). Adjusting device (1) according to one of the preceding claims, characterized in that the fastening groove (20) is arranged on the side of the scale (13) facing away from the position mark (41). Adjusting device (1) according to one of the preceding claims, characterized in that each of the indicator elements (21, 22, 23, 24) can be clamped firmly in the fastening groove (20) with a force fit. Adjusting device (1) according to one of the preceding claims, characterized in that each of the indicator elements (21, 22, 23, 24) has a tensioning means (27) with which the respective indicator element (21, 22, 23, 24) can be moved in the fastening groove (20) is releasable and can be tightened to fix it in the fastening groove (20). Adjusting device (1) according to Claim 10, characterized in that the tensioning means (27) is a screw (28) which is screwed into the respective indicator element (21, 22, 23, 24). Adjusting device (1) according to one of Claims 10 or 11, characterized in that when the tensioning means (27) is released, a clearance fit with a form fit is formed between the fastening groove (20) and the respective indicator element (21, 22, 23, 24). Adjusting device (1) according to one of the preceding claims, characterized in that each of the indicator elements (21, 22, 23, 24) has a visual identifier (30). Adjusting device (1) according to one of the preceding claims, characterized in that the adjusting cap (11) has a carrier element (14) and a cap (15), the cap (15) being releasably fixed on the carrier element (14) and the fastening groove (20) is formed between the carrier element (14) and the cap (15). Telescopic sight (50) with a tubular housing (51) through which an optical path (P) runs, along which an ocular system (52), a reticle (54) and an objective system (53) are arranged, and with an adjusting device (1) according to one of the preceding claims, wherein the coupling part (42) is coupled to the reticle (54) in such a way that the movement of the adjusting cap (11) for the purpose of adjusting the reticle (54) is coupled to it.

Images