Binoculars With Eyepiece-Based Support Device

Abstract

The invention relates to a binocular telescope comprising two tubes, which are connected in an articulate fashion with a swivel hinge pivotal around a joint bending axis. With a forehead contact unit comprising a comprehensive support device the binoculars can be supported in the area of the root of the nose or the forehead of the observer. The support device is here arranged at a body of the binoculars.

Claims

1. Binoculars comprising: a first monocular tube comprising a first housing part and at least one first bridge part; a second monocular tube comprising a second housing part and at least one second bridge part, wherein the at least one second bridge part faces the at least one first bridge part; a support device arranged between the first and second monocular tubes for supporting the binoculars at the side of an eyepiece on a face of an observer, the support device comprising a forehead contact unit extending from the binoculars and arranged to support the binoculars during use against an area above an observer's nose or forehead; a swivel hinge connecting the at least one second bridge part with the at least one first bridge part, such that the first and second monocular tubes are connected in an articulate fashion at a bending axis formed by the swivel hinge, wherein between the first and second monocular tubes a symmetry plane is defined in the bending axis; and a symmetry device which is mechanically coupled via a drive connection to at least the first or at least the second monocular tube, such that the pivoting movement of the first monocular tube against the second monocular tube is transferred via the symmetry device to the forehead contact unit. such that a center of a support surface of the forehead contact unit maintains in the area of the symmetry plane during the pivoting of the first and second monocular tubes around the bending axis by the swivel hinge, and wherein a distance between the first and second monocular tubes is adjustable by mutual pivoting the first and second monocular tubes around the bending axis.

2. The binoculars according to claim 1, wherein the support device is fastened on the binoculars facing the observer.

3. The binoculars according to claim 1, wherein the forehead contact unit is arranged with its support point along the bending axis of the swivel hinge.

4. The binoculars according to claim 1, further comprising a roller-shaped central drive wherein the support device is arranged on the central drive.

5. The binoculars according to claim 1, wherein the support device is arranged along the bending axis extending between the two eyepieces, and wherein the support device is longitudinally displaceable along the bending axis.

6. The binoculars according to claim 1, wherein the support device can be removed from the binoculars.

7. The binoculars according to claim 1, wherein the forehead contact unit of the support device is rotational in reference to the binoculars.

8. The binoculars according to claim 1, wherein the forehead contact unit is axially adjustable in reference to the binoculars.

9. The binoculars according to claim 1, wherein the forehead contact unit is supported in a swaying fashion in reference to the binoculars.

10. The binoculars according to claim 1, wherein the symmetry device comprises a first adjusting element and a second adjusting element, wherein via the two adjusting elements, the support device, particularly its forehead contact unit, seen in the axial direction of the bending axis, is arranged in the area of the symmetry plane and the first adjusting element is in a drive connection with the first monocular tube or is arranged stationary thereon, and the second adjusting element is in a drive connection with the second monocular tube or is arranged stationary thereon.

11. The binoculars according to claim 10, wherein the support device comprises a base part and the base part of the support device is in a drive connection both with the first adjusting element as well as the second adjusting element.

12. The binoculars according to claim 11, wherein the first monocular tube includes a first eyepiece and defines a first eyepiece axis and the second monocular tube includes a second eyepiece and defines a second eyepiece axis, the two eyepiece axes further define an eyepiece plane extending in a parallel direction relative to the bending axis, the eyepiece plane being perpendicular to the symmetry plane, and wherein a center of the support surface of the forehead contact unit is arranged on one of the sides, facing away from the bending axis of the two eyepieces, defining the eyepiece plane.

13. The binoculars according to claim 11, further comprising an adjusting device by which the forehead contact unit is adjustable relative to the base part in the direction of a position axis and thus a distance in the direction of the bending axis between the support surface of the forehead contact unit and the base part is configured in an adjustable fashion.

14. The binoculars according to claim 13, wherein the position axis of the adjusting device shows a parallel alignment relative to the bending axis or an inclined orientation relative to the bending axis.

15. The binoculars according to claim 13, wherein the position axis of the adjusting device is arranged extending in the symmetry plane.

16. The binoculars according to claim 11, wherein a pivot arrangement is provided by which pivot arrangement the support surface of the forehead contact unit is pivotal relative to the base part and a tilt of the support surface relative to the bending axis is designed to be changeable.

17. The binoculars according to claim 11, wherein the base part comprises a support arm and the support arm along with the forehead contact unit pivotal about a swivel center located in the bending axis in a normal orientation relative to the bending axis at the binoculars.

18. The binoculars according to claim 11, wherein the first adjusting element comprises at least one partial section of a toothed wheel and a center of the toothed wheel is arranged in the bending axis.

19. The binoculars according to claim 10, wherein the second adjusting element comprises at least one partial section of an internal gear and a center of the partial section of the inner gear is arranged in the bending axis.

20. The binoculars according to claim 18, wherein between the partial section of the toothed wheel and the partial section of the inner gear a planetary gear is arranged and the planetary gear is supported rotationally at the support arm of the base part.

21. The binoculars according to claim 18, wherein the transmission ratio from the partial section of the inner gear to the partial section of the toothed wheel is 2:1.

22. The binoculars according to claim 18, wherein the first adjusting element comprises a first control lever supported pivotally in the bending axis and arranged on its side facing the forehead contact unit and the partial section of the toothed wheel and, the first adjusting lever is provided on the side opposite the partial section of the toothed wheel of the bending axis with a first operating extension which is in a drive connection with the first monocular tube.

23. The binoculars according to claim 22, wherein the second adjusting element comprises a second adjusting lever, which second adjusting lever is supported rotationally in the bending axis and is provided on its side facing the forehead contact unit with an adjusting lever arm and, if necessary, the second adjusting lever is provided on the adjusting lever arm opposite the bending axis with a second operating extension, and that the second operating extension is in a drive connection with the second monocular tube.

24. The binoculars according to claim 22, wherein the support arm of the base part is provided on its end section, distanced from the bending axis with a partial section of an inner gear and a center of the partial section of the inner gear is arranged positioned in the bending axis.

25. The binoculars according to claim 23, wherein between the partial section of the toothed wheel and the partial section of the inner gear a first planetary gear and a second planetary gear are provided and the planetary gears can be supported in a rotational fashion on the adjusting lever arm of the second adjusting lever.

26. The binoculars according to claim 25, wherein the two planetary gears are provided in the second control lever, such that they engage each other, and the first planetary gear engages the partial section of the toothed wheel and the second planetary gear engages the partial section of the inner gear.

27. The binoculars according to claim 26, wherein the two planetary gears include same number of teeth.

28. The binoculars according to claim 25, wherein the two planetary gears are arranged in a radial alignment relative to the joint bending axis behind each other at the second control lever.

29. The binoculars according to claim 25, wherein the transmission ratio from the partial section of the inner gear to the partial section of the toothed wheel is 2:1.

30. The binoculars according to claim 12, wherein the first adjusting element is formed by a first bolt with a first bolt axis and the second adjusting element by means of a second bolt with a second bolt axis and the bolt axes of both bolts each are parallel alignment relative to the bending axis.

31. The binoculars according to claim 30, wherein the first bolt is arranged on a side of the symmetry plane and distanced therefrom and the second bolt is arranged on the opposite side of the symmetry plane and distanced therefrom and the two bolts with their bolt axes are arranged in a normal alignment to the symmetry plane located in a normal plane and the normal plane shows a parallel alignment relative to the eyepiece plane.

32. The binoculars according to claim 30, wherein the two bolts with their bolt axes are arranged symmetrically relative to the symmetry plane.

33. The binoculars according to claim 30, wherein the base part of the support device, on a side of the symmetry plane and distanced therefrom, a first recess or a first penetration is provided and on the opposite side of the symmetry plane as well as distanced therefrom a second recess or a second aperture is arranged.

34. The binoculars according to claim 33, wherein the first recess or the first aperture and the second recess or the second aperture in the normal alignment to the symmetry plane are aligned in a normal plane and the normal plane shows a parallel alignment relative to the eyepiece plane.

35. The binoculars according to claim 34, wherein the first recess or the first aperture is designed as a bore.

36. The binoculars according to claim 34, wherein the second recess or the second aperture is designed as an oblong hole and the oblong hole extends in the direction of the normal plane.

37. The binoculars according to claim 35, wherein a center of the bore and a center of the oblong hole are arranged symmetrically in reference to the symmetry plane.

38. The binoculars according to claim 37, wherein the first bolt engages the first recess or the first aperture and the second bolt engages the second recess or the second aperture of the base part.

39. The binoculars according to claim 38, wherein the base part is formed in one piece and the recesses or apertures are arranged therein and also the forehead contact unit is arranged on the base part.

40. The binoculars according to the claim 30, wherein the base part comprises a first control arm with a first end section and a second end section and a second control arm with a first end section and a second end section, and the two first end sections of the control arms are connected to each other in an articular fashion and the second end section of the first control arm is connected by the first bolt forming the adjusting element and the second end section of the second control arm rests on the second bolt forming the adjusting element.

41. The binoculars according to claim 40, wherein the forehead contact unit is arranged in the area of the two first end regions of the control arms connected to each other in an articular fashion.

42. Binoculars comprising: a first monocular tube comprising a first housing part and at least one first bridge part; a second monocular tube comprising a second housing part and at least one second bridge part, wherein the at least one second bridge part faces the at least one first bridge part; a support device arranged between the first and second monocular tubes for supporting the binoculars at the side of an eyepiece on a face of an observer, the support device comprising a forehead contact unit extending from the binoculars and arranged to support the binoculars during use against an area above an observer's nose or forehead; a swivel hinge connecting the at least one second bridge part with the at least one first bridge part, such that the first and second monocular tubes are connected in an articulate fashion at a bending axis formed by the swivel hinge, wherein between the first and second monocular tubes a symmetry plane is defined in the bending axis; and a symmetry device comprising at least a first adjusting element, wherein via the first adjusting element, the support device, seen in the axial direction of the bending axis, is arranged in an area of the symmetry plane, and the first adjusting element is in a drive connection with the first monocular tube. such that a center of a support surface of the forehead contact unit maintains in the area of the symmetry plane during the pivoting of the first and second monocular tubes around the bending axis by the swivel hinge.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0057] Additional features, details and advantages of the invention are based on the wording of the claims, as well as the following description of the exemplary embodiments based on the figures.

[0058] In each case, it is shown in a very simplified, schematic illustration:

[0059] FIG. 1 is a perspective view of binoculars with a support device according to the invention;

[0060] FIG. 2 is other binoculars with a support device and a symmetry device, in a front view and in a very schematic representation;

[0061] FIG. 3 is a possible embodiment of a base part of the support device in a front view as well as in a highly schematic representation;

[0062] FIG. 4 is another possible design of the support device and the symmetry device, in a front view as well as a highly schematic representation;

[0063] FIG. 5 is the binoculars with a different embodiment of the symmetry device for the support device in a first broad position of the eyepieces, in a front view as well as a highly schematic representation;

[0064] FIG. 6 is the binoculars, including the symmetry device according to FIG. 5, in a second narrower position of the eyepieces, in a front view and a highly schematic representation;

[0065] FIG. 7 is the binoculars with another possible embodiment of the symmetry device for the support device in a first broad position of the eyepieces, in a front view as well as a largely schematic representation;

[0066] FIG. 8 is the binoculars, including the symmetry device according to FIG. 7, in a second narrower position of the eyepieces, in a front view and a largely schematic representation;

[0067] FIG. 9 is the base part of the support device with the forehead contact unit, sectioned to show a side view, as well as a largely schematic illustration.

DETAILED DESCRIPTION

[0068] First it must be stated that in the various embodiments described, identical parts are provided with the same reference characters or identical component designations, whereby the disclosures contained in the entire description can be transferred accordingly to identical parts with identical reference characters or identical component designations. Furthermore, the location information selected in the description, such as above, at the bottom, at the side, etc. is related to the respectively described and shown figure and such location information must correspondingly be transferred to the new location in case of a change in location.

[0069] The term “in particular” is understood in the following in such a way that it can be a possible more specific embodiment or more detailed specification of an object or a process step, but not necessarily a compelling, preferred embodiment of the same or a mandatory procedure.

[0070] Binoculars refer here (in German) to an optical instrument or observation device, which allows the observation of an object via two separate beam paths using simultaneously both eyes. The observer is provided here with a stereoscopic vision of a plastic, three-dimensional depth impression. The known examples of binocular are the binocular telescope, such as the field glass or the opera glass.

[0071] In principle, binoculars represent a portable telescope, generally used in a hands-free fashion. It is predominantly used in the market in a binocular design that allows objects to be monitored with both eyes via separate beam paths. The binoculars are offered in a simple lens design as a theater glass (opera glass, Galileo telescope), on the other hand as prismatic binoculars (Kepler telescope), which is also called colloquially a field glass.

[0072] According to FIG. 1, an embodiment is shown that is formed essentially from two tubes 2, 3, which are connected in an articulate fashion by a swivel hinge -SS- 4, forming binoculars -FG- 1 which in the direction of the object is followed by two lenses -OB- 6, 7 and on the observer side by two eyepieces 8, 9 and a roller-shaped central drive 10, is provided showing on its free forehead side is, comprising the mounting base -MS- 11, support profile -SP- 12, and forehead contact unit -SA- 13, the device or support device 5, wherein the forehead contact unit -SA- 13 is rotational in reference to the central drive -MT- 10 and the forehead contact unit -SA- 13, is axially adjustable compared to the binoculars -FG- 1. For comfortable and convenient contacting of the forehead contact unit -SA- 13 at the head of the observer, it may be padded and mounted swaying. Preferably, its circumferential edge at the observer side is rounded. Preferably the support device -VO- 5 is essentially designed rotationally symmetrically, wherein this can generally be referred to as a resting device or support device. The binoculars -FG- 1 can also be referred to as a binary observation device in the embodiment described above. Both tubes 2, 3 can also be called telescopes.

[0073] Binocular observation devices, such as binoculars 1, field glasses, or opera glasses, essentially include the first monocular tube 2 or the first telescope, the second monocular tube 3 or the second telescope, and the two tubes 2, 3 are connected together with the swivel hinge 4. The swivel hinge 4 can also be called a joint.

[0074] Furthermore, in FIG. 1, it is additionally shown that the first monocular tube 2 or the first telescope comprises a first housing part 14 and at least one first bridge part 15 arranged or formed thereat. The first housing part 14 contains at least the first objective lens 6 and the first eyepiece 8 and, if necessary, additional optical components are included, here. The first eyepiece 8 defines a first eyepiece axis 16 on the observer side.

[0075] The second monocular tube 3 or the second telescope comprises a second housing part 17 and at least one second bridge part 18 arranged or formed thereat. In the second housing part 17 at least the second objective lens 7 and the second eyepiece 9 and, if necessary, additional optical components are included here. The second eyepiece 9 defines a second eyepiece axis 19 on the observer side. Both eyepiece axes 16 and 19 are preferably aligned parallel to one another and jointly define an Eyepiece plane 20.

[0076] The swivel hinge 4 defines a common swivel axis, which can also be called a bending axis 21, wherein using the swivel hinge 4 the bridge parts facing each other 15, 18 of both monocular tubes 2, 3 are held to each other in a manner pivotal about the bending axis 21. This pivotability serves to set and adjust the eye distance to the respective user.

[0077] The Eyepiece plane 20 is further aligned extending in a parallel direction with regard to the common bending axis 21. Furthermore, binocular observation devices or binoculars 1 show, arranged or extending between the two tubes 2, 3, a symmetry level 22. The symmetry level 22 refers here to both eyepiece axes 16 and 19 of the two eyepieces 8 and 9. Furthermore, the symmetry level 22 is arranged extending between the two tubes 2, 3 in the joint bending axis 21. The symmetry level 22 also shows a normal alignment or a right angle alignment with regard to the Eyepiece plane 20. By the relative mutual pivotability of the two tubes 2, 3 the binocular observation device or the binoculars 1 can be adjusted to different eye distances. In the case of a level or horizontal alignment of the Eyepiece plane 20 here the symmetry level 22 is aligned perpendicular in reference thereto.

[0078] FIG. 2 shows another and, if necessary, an independent embodiment of the binocular observation device or binoculars 1 wherein, in turn, the same reference characters or component designations are used for identical parts as in the previous FIG. 1. In order to avoid unnecessary repetitions, reference is made or similarities are pointed out to the detailed description in the previous FIG. 1. For a better overview, a detailed illustration of the tubes 2, 3 as well as the two bridge parts 15, 18 connecting the swivel hinge 4 is omitted, here. The support device 5 is arranged at the eyepiece side on the binocular observation device or binoculars 1.

[0079] All the embodiments of the support device 5 described in the following can be removed from the binoculars 1 and can be reassembled. Furthermore, the forehead contact unit 13 is rotational and/or axially adjustable in reference to the binoculars 1. It is also possible to provide a swaying arrangement in reference to the binoculars 1 for the forehead contact unit 13. In the following exemplary embodiments, the forehead contact unit 13 is arranged with its support surface or support center not located in the bending axis 21 but outside thereof, aligned in the normal direction, at a distance from the tubes 2, 3, especially their eyepieces 8, 9.

[0080] In all of the exemplary embodiments described below, it is respectively provided that the support device 5, even when the two tubes 2, 3 are pivoted relative to each other, to adjust the respective eye distance, remain arranged located in the area of the symmetry level 22 or in the symmetry level 22. Furthermore, the forehead contact unit 13 is arranged in such a way with regard to the joint bending axis 21 that it is located outside the common bending axis 21 as well as, facing away from the common bending axis 21, on the side of the symmetry level 22. In this selected arrangement is a center of a support surface of the forehead contact unit 13 is arranged on the side, facing away from the joint bending axis 21, of the two eyepieces 8, 9 defining the Eyepiece plane 20. Depending on the design and form of the forehead contact unit 13 in principle, the center is respectively designed thereat in each case. The support surface of the forehead contact unit 13 can be designed in a rotationally symmetric, arched, oval or similar manner. Furthermore, the forehead contact unit 13 can in general be called a support element or a forehead support.

[0081] The design of the support device 5 shown here comprises a base part 23 and the forehead contact unit 13 arranged or formed thereat. Furthermore, a symmetry device 24 is also provided, which comprises in turn a first adjusting element 25 and a second adjusting element 26. With the two adjusting elements 25, 26 the support device 5, especially its forehead contact unit 13, remains arranged in place in the axial direction of the joint bending axis 21, seen in the area of the symmetry level 22.

[0082] The first adjusting element 25 is here arranged with the first monocular tube 2 in a drive connection or it is arranged on the monocular tube 2 in a location-fixed fashion. The second adjusting element 26 is here in a drive connection with the second monocular tube 3, or it is arranged fixed on the monocular tube 3. The mounting can occur, for example, on the respective housing part 14, 15, on the respective bridge part 15, 18 or in each case, on an individual, separate component provided for this purpose and not shown in greater detail. Here, the drive connection is understood not merely as contacting or supporting, but a coupling in a mechanical, form-fitting fashion.

[0083] The base part 23 of the support device 5 is therefore in a drive connection with the first adjusting element 25 as well as the second adjusting element 26.

[0084] The first adjusting element 25 is here formed by a first bolt 27 with a first bolt axis 28. The second adjusting element 26 is formed here by a second bolt 29 with a second bolt axis 30. Both bolt axes 28 and 30 of the bolts 27 and 29 each show respectively a parallel alignment with regard to the common bending axis 21. Furthermore, the first bolt 27 is arranged on one side of the symmetry level 22—here, at the right side—as well as distanced therefrom, with the second bolt 29 being arranged on the opposite side of the symmetry level 22—here at the left side—as well as distanced therefrom. The two bolts 27, 29 are with their bolt axes 28, 30 in a normal alignment arranged located on the symmetry level 22 as the aligned normal level 31. The normal level 31 preferably also shows a parallel alignment with regard to the Eyepiece plane 20. The two bolts 27, 29 are preferably with their bolt axes 28, 30 arranged symmetrical with regard to the symmetry level 22.

[0085] The two bolts 27 and 29 forming the adjusting elements 25 and 26 are stationary here and arranged fixed at one of the tubes 2, 3. In order to allow forming or creating a drive connection or a coupling connection between the bolts 27 and 29 and the base part 23, here in the base part 23 of the support device 5, on a side of the symmetry level 22 and distanced therefrom, a first recess 32 or a first aperture 33 is arranged or formed and on the opposite side of the symmetry level 22 and distanced therefrom a second recess 34 or a second aperture 35. The first bolt 27 engages the first recess 32 or the first penetration 33, wherein the second bolt 29 engages the second recess 34 or the second aperture 35 of the base part 23.

[0086] The first recess 32 or the first aperture 33 as well as the second recess 34 or the second aperture 35 are in each case arranged located in the normal direction on the symmetry level 22 aligned to the normal level 31. As described above, the normal level 31 shows in this exemplary embodiment a parallel alignment with regard to the Eyepiece plane 20.

[0087] The first recess 32 or the first aperture 33 is designed as a bore hole here. The first recess 32 or the first aperture 33 shows a size, which is approximately equivalent to an external dimension of the first bolt 27. Thus, a sufficiently reliable guide and positioning of the base part 23 can be achieved relative to the first tube 2. Thus, this area represents a fixed point between the base part 23 and the first tube 2. It would also be possible to form the recess 32 or the first aperture 33 as an oblong hole and the second recess 34 or the second aperture 35 as a bore hole.

[0088] In order to allow performing the pivoting movement of both tubes 2, 3 without the basic part 23 preventing this, the second recess 34 or the second aperture 35 is designed as an oblong hole. The oblong hole extends in the direction of the normal level 31, here. In addition, a center of the bore and a middle of the oblong hole can be arranged symmetrically with regard to the symmetry level 22.

[0089] Furthermore, it is also provided here that the base part 23 is formed in one piece and in it the recesses 32, 34 or apertures 33, 35 are designed or arranged. The forehead contact unit 13 can be designed like a button and also arranged or embodied on the base part 23. The layout of the base part 23 is selected here as an upside-down “T”, but a triangular shape or the like can be selected here as well.

[0090] FIG. 3 shows another and, if necessary, independent embodiment of the basic part 23 described above, wherein in turn the same reference characters or component designations are used for identical parts, as in the previous FIGS. 1 and 2. In order to avoid unnecessary repetitions, reference is made to the detailed description in the previous FIGS. 1 and 2 or pointed to. The basic structure of the support device 5 described in FIG. 2 as well as the symmetry device 24 is unchanged and is therefore not described in greater detail.

[0091] For attaching the bolts 27, 29, the sections of the base part 23 are provided, respectively seen in the direction of the bending axis 21, in a round or button-shaped manner. The base part 23 is embodied lattice-shaped with individual connection braces in an area between the bolts 27, 29 forming adjusting elements 25, 26 and the arrangement area of the forehead contact unit 13.

[0092] In the embodiments of the base part 23 described in FIGS. 2 and 3, based on the support of the base part 23 formed on the side as a fixed point, and the oblong hole formed on the other side, a slight lateral movement occurs and thus a not one-hundred percent centric alignment of the center of the forehead contact unit 13 with regard to the symmetry level 22.

[0093] FIG. 4 shows another and, if necessary, an independent embodiment of the support device 5 as well as the symmetry device 24, wherein in turn the same reference characters or component designations are used for identical parts, as in the previous FIGS. 1 to 3. In order to avoid unnecessary repetitions, reference is made to the detailed description in the previous FIGS. 1 to 3 or pointed to.

[0094] Here, the two adjusting elements 25 and 26 are also provided, which are arranged locally fixed on the respective tube 2, 3. They form fixed rotary points or support points for a base part 23-1, which due to the embodiment deviating in its basis 23 described above are provided with a separate reference character.

[0095] The two adjusting elements 25 and 26 can, e.g., again be embodied as bolts 27, 29 or pins. The base part 23-1 comprises a first control arm 36 and a separate, independent second control arm 37. The first control arm 36 is usually formed in a flat profile form and has a first end section 38 and distanced therefrom a second end section 39. Here, the second control arm 37 is also preferably formed with a flat profile design and has a first end section 40 and a second end section 41 arranged distanced therefrom. Both control arms 36, 37 are each aligned, starting with the two adjusting elements 25 and 26, extending toward one another. In the area of the forehead contact unit 13, the two first end sections 38, 40 of the control arms 36, 37 are jointly connected with one another in an articulate fashion by means of a joint arrangement which is not described in greater detail. This can, for example, be a pin or a bolt or the like. Furthermore, the second end section 39 of the first control arm 36 is supported on the first adjusting element 27 formed by the first bolt 25 in a manner that it can be swiveled or rotated about the first bolt axis 28. For this purpose, in the second end section 39 of the first control arm 36 the first recess, 32 is provided designed as a hole or as a blind hole, or the first penetration 33.

[0096] The second end section 41 of the second control arm 37 is supported on the second adjusting element 29 formed by the second bolt 26 in a manner that it can be swiveled or rotated about the second bolt axis 30. For this purpose, in the second end section 41 of the second control arm 37 the second recess 34 or the second aperture 35 is provided, which is also designed as a hole or as a blind hole.

[0097] Both control arms 36 and 37 show, starting from the recesses respectively formed in the second end section 39, 41, formed as bores 32, 34 or apertures 33, 35 the same construction length for the joint arrangement and joint connection site, not described in greater detail.

[0098] The forehead contact unit 13 is preferably connected with the center of its support surface in the area of the two first end regions 38, 40 connected to each other in an articulate fashion, to the control arms 36, 37 and projects towards the user from the base part 23-1 and thus from the side facing away from the lens 6, 7. The spatial shape of the forehead contact unit 13 can be like a mushroom, wherein the shaft may be equivalent to the support profile 12 described above.

[0099] The two adjusting elements 25, 26 or the bolts 27, 29 forming them with their bolt axes 28, 30 can in turn be arranged in the previously described normal level 31. Furthermore, the center of the support area of the forehead contact unit 13 is also arranged on the side, facing away from the bending axis 21, of the Eyepiece plane 20.

[0100] In the following paragraphs 5 to 8, additional possible embodiments of the support device 5 as well as the symmetry device 24 for the forehead contact unit 13 are shown and described, wherein in contrast to the embodiments described in FIGS. 2 to 4, a transmission arrangement deviating from this is provided. The arrangement and embodiment of tubes 2, 3 and their swiveling support in reference to each other on the joint bending axis 21 can be done analogously, as previously described in detail. Therefore, it is no longer discussed in greater detail.

[0101] Here a separate base part 23-2 is respectively provided, which comprises a support arm 42 or 42-1. The support arm 42, 42-1, by means of a pivoting arrangement or a bearing arrangement, is supported in a pivotal fashion about the common swivel center arranged located in a common bending axis 21 in a normal direction with regard to the swivel level aligned to the common bending axis 21 on the observation device or binoculars 1. Here, the bending axis 21 may at least form in sections a physical part of an axis, which can be formed by means of a bearing pin. On the end section, facing away from the pivot center of the support arm 42, 42-1, the forehead contact unit 13 is arranged or designed. This way, the support arm 42, 42-1 can be pivoted along with the forehead contact unit 13 in the swivel level. Only a freely rotating support of the support arm 42, 42-1 around the common bending axis 21 occurs, however, the swivel movement and relative positioning of the same relative to the symmetry level 22 is compulsory, as described below.

[0102] Thus, FIGS. 5 and 6 show a first possible and, perhaps independent exemplary embodiment of the symmetry device 24 for the support device 5 along with the observation device or the binoculars 1, wherein in turn, the same reference signs or component designations are used for identical parts as in the previous FIGS. 1 to 4. In order to avoid unnecessary repetitions, reference is made to the detailed description in the previous FIGS. 1 to 4 or pointed to.

[0103] Once more a first adjusting element 25-1 is provided here, comprising at least one partial section of a toothed wheel 43. A center of the toothed wheel 43 or the partial section of the toothed wheel 43 is arranged located in the common bending axis 21.

[0104] The second adjusting element 26-1 comprises at least one partial section of an internal gear 44, wherein a center of the partial section of the inner gear 44 being arranged located in the joint bending axis 21.

[0105] The first adjusting element 25-1 formed by the gear 43 or its partial section is arranged with the first tube 2 in a drive connection or is arranged fixed on this or a part thereof. The second adjusting element 26-1 formed by the inner gear 44 or its partial section is in a drive connection with the second tube 3 or is arranged fixed thereon or a part thereof. It would also be possible, in turn, to mount or arrange the two adjusting elements 25-1 and 26-1 on the respective tubes 2 and 3 to be exchanged against each other. Then the first adjusting element 25-1 would be in a drive connection with the second tube 3 and the second adjusting element 26-1 with the first tube 2. Here, a relative stationary mounting or fastening of the adjusting elements 25-1 and 26-1 is assumed on the respective tubes 2 and 3.

[0106] For transmitting the relative swivel movement of both tubes 2 and 3 in reference to each other when adjusting the eye distance to the symmetry device 24, between the partial section of the toothed wheel 43 and the partial section of the inner gear 44 a planetary gear 45 is arranged or provided.

[0107] The planetary gear 45 is rotationally supported at the support arm 42 or on a cantilever connected to the support arm 42 and can thus be pivoted like a planetary wheel, and transfer the pivoting movement between the partial section of the toothed wheel 43 and the partial section of the inner gear 44 upon the support arm 42. The gear 43 or its subsection forms the so-called sun gear here, wherein the inner gear 44 or the subsection forms the hollow wheel. The symmetry device 24 can therefore be embodied in the form of a planetary gear, or designated as such.

[0108] The transmission ratio from the partial section of the inner gear 44 to the partial section of the toothed wheel 43 is 2:1. The transmission ratio can also be defined by means of the roller diameter. Here, a roller diameter of the partial section of the inner gear 44 shows twice the value as a roller diameter of the partial section of the toothed wheel 43.

[0109] In FIGS. 7 and 8, another possible and, perhaps independent design of the support device 5 and the symmetry device 24 is shown with the observation device or the binoculars 1 wherein, in turn, the same reference characters or component designations are used for identical parts, as in the previous FIGS. 1 to 6. In order to avoid unnecessary repetitions, reference is made to the detailed description in the previous FIGS. 1 to 6 or pointed to.

[0110] In this exemplary embodiment, a transmission arrangement in the type of a planetary gear is likewise used for the formation of the symmetry device 24. Here, only the formation and design of the symmetry device 24 is discussed in greater detail, wherein the components not described in greater detail are designed analogously, as they have already been described in detail.

[0111] Once more a separate base part 23-2 is provided here, comprising a support arm 42-1. By means of a pivoting arrangement or a bearing arrangement, the support arm 42-1 is provided in a rotational fashion about a swivel center located in the common bending axis 21 of a swivel level arranged in a normal alignment with regard to the common bending axis 21 on the observation device or on the binoculars 1. The bending axis 21 can at least in sections form a physical part of an axis, which can be formed by means of a bearing pin. On the end section facing away from the pivot center of the carrier arm 42-1, the forehead contact unit 13 is arranged or designed, which is only indicated for a sake of clarity in dot-dash lines. The support arm 42-1 can thus be pivoted along with the forehead contact unit 13 in the swivel level. Only a freely rotating bearing of the support arm 42-1 occurs around the common bending axis 21, however the swivel movement and relative positioning with regard to the symmetry level 22 is compulsory, as described below.

[0112] Here a first adjusting element 25-2 comprises a first control lever 46, wherein the first control lever 46 similar to the partial section of the previously described toothed wheel 43, is also supported in a rotational fashion in the joint bending axis 21. The adjusting lever 46 also includes on the side facing the forehead contact unit 13 at least one partial section of a toothed wheel 43-1 and, if necessary, on the partial section of the toothed wheel 43-1 opposite the joint bending axis 21 a first operating extension 47. The gear 43-1 or its subsection forms the sun gear as with a planetary gear. The center of the partial section of the toothed wheel 43-1 is also arranged located in the common bending axis 21. The first operating extension 47 is in a drive connection with the first monocular tube 2 and is particularly held thereat in a fixed fashion. To do this, a screw connection, a rivet connection, a bolt connection, or the like can be provided.

[0113] A second adjusting element 26-2 comprises a second adjusting lever 48, wherein this is also supported in a rotary fashion in the common bending axis 21. The second adjusting lever 48 includes on its side facing the forehead contact unit 13 a control lever arm 49 and may comprise or show at its side opposite the control lever arm 49 in reference to the joint bending axis 21 a second operating extension 50. If the second operating extension 50 is provided, it is in a drive connection with the second monocular tube 3 and is in particular held fixed on this location. Thus, with a swivel movement of the two tubes, 2, 3 relative to one another, the swivel movement can be transmitted directly to the respective adjusting element 25-2 and 26-2 and thus to the respective adjusting lever 46, 48.

[0114] It would also be possible, to waive the arrangement or the provision of at least one operating extension 47 and/or 50. In some models of the binocular 1 it may show or comprise in the area of the bending axis 21, among other things, a battery compartment, in particular one integrated into the focusing dial, comprising a battery cover not shown in greater detail. The battery compartment and its battery cover can be installed at one of the two tubes 2 or 3 in a fixed fashion and thus it must be rotationally fixed to one of the tubes 2 or 3. For example, it would be possible to connect the first adjusting element 25-2, in particular the first control lever 46 directly to the battery compartment, in particular by fastening the adjusting element 25-2 on the battery compartment instead of the battery cover, and to waive the first actuation extension 47. Regardless of this, it would also be possible to connect the second adjusting element 26-2, in particular the second adjusting lever 48 directly to the battery compartment and to waive the second operating extension 50. In this way, when omitting at least one of the actuating extensions 47, 50 still the swivel movement can be transmitted from the respective tube 2 or 3, depending to which battery compartment it is connected to in a torque-proof fashion, to on the first adjusting element 25-2 or the second adjusting element 26-2. For example, in this exemplary embodiment the first adjusting element 25-2 with the first monocular tube 2 is in a drive connection or is arranged fixed thereon, whereby the second adjusting element 26-2 with the second monocular tube 3 is in a drive connection or is arranged fixed thereto.

[0115] The base part 23-2, here formed by the support arm 42-1, is provided at its end section, and distanced from the common bending axis 21 with a partial section of an internal gear 44-1. The center of the partial section of the inner gear 44-1 is arranged located in the joint bending axis 21.

[0116] Here, for the transmission of the pivoting movement of the two actuators 25-2 and 26-2 upon the base part 23-2 with the forehead contact unit 13 a first planetary gear 51 and a second planetary gear 52 are provided. The two planetary gears 51 and 52 are supported in a rotational fashion on the adjusting lever arm 49 of the second adjusting lever 48 and thus on the second adjusting element 26-2. Furthermore, the two planetary gears 51 and 52 are arranged between the partial section of the toothed wheel 43-1 and the partial section of the inner gear 44-1. The two planetary gears 51 and 52 are in such a manner arranged on the second adjusting lever 48 such that they are engaging each other. The first planetary gear 51 engages the partial section of the toothed wheel 43-1 and the second planetary gear 52 engages the partial section of the inner gear 44-1. Preferably, the planetary gears 51 and 52 show the same size, in particular the same number of teeth. The term “engaging each other” is understood here as a combing intervention of the gears and the sections of toothed wheel. Furthermore, the two planetary gears 51, 52 are arranged in a radial alignment with regard to the common bending axis 21 behind one another on the second control lever 48.

[0117] In this exemplary embodiment, it is also provided that the transmission ratio from the partial section of the inner gear 44-1 to the partial section of the toothed wheel 43-1 is selected with 2:1. In relation to the roller diameter, the roller diameter of the partial section of the inner gear 44-1 shows twice the value compared to the roller diameter of the partial section of the toothed wheel 43-1.

[0118] The presentation of housings and/or covers has been waived for the sake of clarity.

[0119] In all the exemplary embodiments described above, the components or component groups described below can also be used. This is shown in FIG. 7 in a simplified fashion.

[0120] For setting and adjusting the distance of the support surface of the forehead contact unit 13 from the eyepieces 8, 9 in the axial direction with regard to the bending axis 21 an adjusting device 53 may be provided. With it the forehead contact unit 13 can be adjusted relative to the base part 23, 23-1, 23-2 in the direction of a position axis 54. Thus, the distance in the direction of the joint bending axis 21 between the support surface of the forehead contact unit 13 and the base part 23, 23-1, 23-2 and thus the respective user can be individually adapted. Depending on the embodiment of the forehead contact unit 13 the position axis 54 of the adjusting device 53 may show a parallel alignment with regard to the joint bending axis 21 or an inclined orientation with regard to the joint bending axis 21. Preferably the position axis 54 of the adjusting device 53 is arranged or aligned extending in the symmetry level 22 or extending parallel thereto.

[0121] Furthermore, it would still be possible, as already described previously, to arrange the forehead contact unit 13 swaying relative to the base part 23, 23-1, 23-2. A swivel arrangement 55 is provided by which the forehead contact unit 13 can be pivoted with its support surface in its position relative to the base part 23, 23-1, 23-2. The pivoting movement can here be done only in one swing level or in a spatial manner. This depends on the selection and embodiment of the swivel arrangement 55.

[0122] The exemplary embodiments show possible design variants, where at this point it shall be pointed out that the invention is not restricted to the specifically depicted design variants, but rather also includes various combinations of the individual design variants, and based on the teaching regarding technical implementation using the present invention known to one trained in the art.

[0123] The scope of protection is determined by the claims. However, the description and the drawings are to be used to interpret the claims. Individual features or combinations of features from the shown and described various embodiments may represent independent inventive solutions. The objective underlying the independent inventive solutions can be taken from the description.

[0124] All information on value ranges in this description must be understood in such a way that they cover any and all arbitrary subsections, e.g., statement 1 to 10 shall be understood in such a way that all subsections start with a lower limit of 1 up to the upper limit of 10, i.e., all subsections start with a lower limit of 1 or more and end at an upper limit of 10 or less, e.g., 1 to 1.7, or 3.2 to 8.1, or 5.5 to 10.

[0125] For the sake of good order, it should be conclusively pointed out that some elements were partially shown in a normal manner and/or enlarged and/or reduced for better understanding of the structure.