CH622345A5 - Ancillary unit on a binocular telescope with a small base - Google Patents

Description

The invention relates to an additional device on a double telescope with a small base, for measuring the spatial image distance with two parallel collimators, in the image plane of which graticules are arranged with marks that appear bright when viewed at a certain distance.

In spatial image rangefinders, it is known that the viewer is presented with a spatial image of the target area together with a movable measuring mark that appears spatially in the field of view or an immobile, staggered series of measuring marks. The measured value is taken from the depth comparison of the measurement target and measurement mark. Such devices, which are also called stereo telemeters, have two mirrors spaced apart from one another in the horizontal direction, which guide the light beams arriving from the measurement object through a lens system to eyepiece mirrors, which feed the light beams back to the viewer's eye and for this purpose at their mutual distance the viewer's eye relief can be adjusted. Through the eyepieces, the viewer can see the picture of the landscape in front of them. At the same time, however, he also sees the stereoscopic images of a number of brands attached as slides in the image planes, also as spatial images, projected into the landscape. By means of suitable movements of the instrument, he can use the stereoscopic image of a spatial image of the object to be measured

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622 345

Allow the mark to collapse approximately and compare the apparent distance of the object with the apparent distance of the marks until he finds the mark whose apparent distance best matches that of the object. The brand images appear as a road leading into the distance 5 with milestones next to which the corresponding distances are given. Instruments with such marks are called fixed-scale rangefinders.

If you think of the two steroscopic single images Ul of a mark not attached at a fixed mutual distance, but in such a way that they can be moved against each other, you get the impression that the spatial image of these marks constantly changes its distance from the observer. Such a brand image can thus be set so that its apparent distance corresponds to that of the object to be measured, and the distance can be read directly on the adjusting device. It doesn't matter whether you move the two brand images or the two landscape images against each other. You either have a 2o stereoscopic range finder with a moving mark or one with a moving image. Regardless of this, the observer with fixed objects (objects in the country) has the impression that the brand image is moving, with moving targets (ships, airplanes) that they are moving. 25th

The so-called multiple wandering mark became known to increase the measuring accuracy. It usually consists of two intersecting rows of marks, at the intersection of which is the somewhat larger measuring mark. The secondary brands,

which are at different distances serve to obtain the spatial impression if only the target can be seen in the landscape against the background consisting of water or sky.

The eyepieces are also provided with a special device which makes it possible to adapt their distance to the eye distance 35 of the observer.

The aim of the invention is to create an additional device with which double telescopes of small base, in particular binoculars, can be readjusted in such a spatial image rangefinder as simply as possible. 40

According to the invention, the additional device is designed as an attachment that can be placed on the telescope body, in which the collimators are connected to one another via a connecting body and are placed in front of the two objectives of the double telescope, the collimator openings being smaller than the objective openings of the double telescope and the distance acting as a measuring basis Collimator axes is approximately equal to the distance between the optical axes of the objectives of the double telescope.

The most important feature of the invention lies in the fact that 50 the superimposition of the terrain image with the stereoscopic distance marks already takes place in front of the objectives of the double telescope, in particular the field glasses, as a result of which measurement errors result from the inevitable mechanical looseness of the field glasses parts and from the angle changes of the optical axes the two telescopes do not occur with each other when they are bent around a joint to adapt to the distance between the eyes. In addition, it is particularly insensitive to temperature-related measurement errors.

Advantageously, two jacket tubes that can be placed on the objective frames of the telescope body are provided, which have mutually facing openings through which the connecting body is guided, which in turn is connected via spring wires or the like. is movably supported in the jacket tubes.

The result of this is that, for example, each binocular 65 can be readjusted particularly quickly and easily into a spatial image rangefinder by simply placing the additional device on the lens mountings of the binoculars and, at the same time, by adjusting the distance between the binoculars' telescope lenses by kinking about the central axis of the binoculars the optical axes of the additional device can also be adapted to the observer's eye relief.

Advantageous further developments result from the drawing, in which i.a. some embodiments are shown.

1 shows the known principle of a distance measurement in two-eyed vision,

2 shows the principle of the spatial image rangefinder, FIG. 3 shows the front view of an additional device according to the invention placed on a field glasses,

4 shows the same, but with a different eye relief, FIG. 5 shows a section along the line V - V of FIG. 4,

6 shows an image presented to the observer when it is implemented with a “fixed scale”,

7 shows the construction of the left and right mark reticle,

8 the imaginary arrangement in the field for the construction of a “fixed scale”,

9 shows an advantageous embodiment of the collimators, in which the same graticules are provided for the left and right collimators,

10 shows a corresponding branding arrangement in the field, FIG. 11 shows the associated branding,

12 shows a further advantageous exemplary embodiment of an additional device according to the invention,

13 shows a section along the line XIII-XIII of FIG. 12, FIG. 14 shows an exemplary embodiment with light-emitting diodes for brightening the field of vision,

15 shows an exemplary embodiment with a glass cuboid carrying the collimators,

16 shows a section along the line XVT-XVI of FIG. 15, FIG. 17 shows a line mark image for the measurement with a “traveling mark”,

18 shows a rangefinder for the measurement with “hiking mark”,

19 shows a section along the line XIX-XIX of FIG. 18, FIG. 20 shows an additional device according to the invention, in which four identical mirror prisms for multiple reflection of light rays which emanate from lamps illuminating the field of view of the reticle are attached to a glass cuboid,

21 shows a rangefinder attachment with a hiking mark and inside reading,

22 is a front view of this,

23 shows a rangefinder attachment with a hiking mark in which the collimator and illumination beam path is broken by half-cube prisms,

24 is a section along the line XXIV-XXIV of FIG. 23,

25 shows the optical part of an attachment with a fixed scale and alignment prisms using pentagon prisms with cemented collimator lenses and reticules and

Fig. 26 is the front view.

In two-eyed vision, the two different retinal images of the left and right eyes cause depth perception, which is dependent on the size of the angle of convergence w of the eyes when fixing an object at distance E (Fig. 1). The specialist literature states that on average, a two-eyed observer is still able to distinguish distances for which the difference in the convergence angle Icoj — co2l = dœ is at least 10 arc seconds. Based on the theorems of geometric optics and the consideration of FIG. 1, this limit angle is dco = 10 "=

20600

- rad, the

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Base b and the magnification V of the double telescope used for the observation:

1. The greatest distance Emax, which the average person can still distinguish from infinite, is Emax = 2.06 X IO4 X V X b

All objects that are farther than Emax appear on one level, so their distance cannot be determined using the convergence angle.

2. The still distinguishable distance dE between two objects within Emax depends on the absolute distance E and is dE;

E2

The size dE is also the smallest measurement error to be expected.

For orientation about the possible use distance of the front attachment, the table below shows both Emax and dE for some distances both for a free-eyed person and for a person watching with binoculars.

Measuring distance in meters

Smallest measurement error of free-eyed observers with field glasses

V = lx, b = 0.066m V = 7x, b = 0.12m dE% of E dE% of E

50

1.84 m =

3.68%

0.14 m =

0.28%

100

7.35 m -

7.35%

0.58 m =

0.58%

250

45.96 m =

18.38%

3.61 m =

1.44%

500

183.82 m =

36.76%

14.45 m =

2.89%

750

413.60 m =

55.15%

32.51 m =

4.33%

1000

735.29 m =

73.53%

57.79 m =

5.78%

1250

1148.90 m =

91.91%

90.30 m =

7.22%

1500

m =

130.03 m =

8.67%

2000

m =

231.16 m =

11.56%

E

1360 meters

17304 meters

From this it can be seen that the attachment is suitable for all hunting distances up to 400 meters and for military use up to 2000 meters, i.e. for infantry weapons.

The distance measurement is based on the following consideration. If the observer is offered markers at a known distance for comparison with the spatial image of the terrain to be measured, he is able to indicate the distance of unknown terrain points with corresponding accuracy. An explanatory example is shown in FIG. 2, the observer and the terrain being shown viewed from above. The objective distance of the field glasses is the measuring base b. The distance of the room and the tower must be determined. To solve the task, appropriately labeled boards are set up in the terrain at distances of 100 m, 200 m, 300 m and 400 m. The convergence angles (ü associated with the individual objects are drawn in. The observer who is capable of spatial vision is then able to indicate the distances sought with corresponding accuracy. This accuracy increases when more measuring marks are provided at a smaller distance and reaches its maximum when the distance between the measuring marks is reduced to the smallest still distinguishable distance dE given at the beginning in point 2. The great accuracy is bought with a large number of measuring marks, which make the field of view confusing.

This disadvantage can be avoided if only one measuring mark is placed in the field, which, however, can be moved to any distance, its labeling continuously indicating the actual distance from the observer. The 5 measuring person brings the measuring mark to the same distance as the terrain point to be measured and reads the distance.

The first method described is called room image measurement with a "fixed scale", the latter room image measurement with "hiking mark".

10 In both methods, it does not matter whether the distance marks are actually set up in the terrain or whether the observer is offered stereoscopic images of such marks at the same time as the terrain. As is well known, such spatial marks can be faked by arranging two collimators rigidly connected to one another in front of the objectives of a double telescope and attaching appropriately constructed brand images to the image planes of the collimator objectives.

FIGS. 3 to 5 show a range finder accessory according to the invention together with a field glasses 20. The two field glasses 1 can be bent around the joint 3, whereby the eyepiece distance can be adjusted to the eye distance of the observer. FIG. 3 shows a field glasses set for wide eye relief and FIG. 4 for narrow eye relief. A medium setting is selected in FIG. 5. The field glasses lenses 2 are shown here cut horizontally, as well as part of the additional device. The rangefinder attachment consists of two collimators 4 which are essentially parallel to one another and which are rigidly connected to one another by a connecting body formed by connecting rods 5. The distance b of the collimator axes from one another is the measurement base and corresponds approximately to the mean objective distance of the field glasses. There are graticules 7 in the image plane of the collimator lenses 6, which are advantageously designed as telephoto lenses. The distance marks attached to them, the arrangement of which is known per se and will be described later, are transparent on an opaque ground.

In this exemplary embodiment, 4o illuminating lenses 8 are arranged in front of the reticle in order to intensify the illumination of the brand image. The connection of the double collimator with the field glasses is made here by four spring wires 9. Two of the wires connect like wheel spokes a collimator 4 with a jacket tube 10 attached to the corresponding lens barrel. The connecting rods 5 protrude 45 through two opposite, sufficiently large openings 11 of these jacket tubes 10. This type of fastening does not affect the buckling ability of the field glasses.

When looking through the binoculars, the parts of the binocular lenses 2 that remained uncovered convey the terrain image into which the spatial image of the distance marks appear when the collimators 4 are much smaller in diameter. 6 shows, as an example, in simplified form an image presented to the observer when executed with a “fixed scale”.

55 If the eyepiece distance is changed by kinking the field glasses, the measuring scale remains unchanged since the measuring base does not change. Even slight changes in the adjustment in the binoculars have no influence on the measurement result, because changes in depth perception that occur affect the terrain and the projected distance scale equally qualitatively and quantitatively. If both connecting rods 5 are made of the same material, there is also temperature independence, since in the event of temperature fluctuations due to the same length change (both rods do not change the angle of convergence, the basic change that occurs and the measurement result associated with it are linear, however, only in size moved by fractions of a percent.

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Fig. 7 shows the construction of the left and right markers. The two axially parallel collimators 41, 4 r, which are firmly connected to one another, are arranged in front of the objectives of the field glasses body 1; the reticules 71, 7 r are located in the image plane of the collimator objectives 61, 6 r. The 5 two collimator lenses have the same focal length fk. The measurement base is b. Assuming the connecting line of the collimator objective as the axis of abscissa and the symmetry m as the axis of ordinate, the terrain points have the coordinates P, (x “E,), P2 (x2, E2). io

The connecting lines of the point Pj and P2 with the center points of the collimator lenses indicate the location of the mark images (pi) i, (pi) r and (p2) |, (p2) r on the reticules, which are the same when viewed through the double telescope spatial effects result like the brands set up in P and P2. From this construction arises arithmetically for the point P (x, E)

the abscissa on the left reticle ...

- * R)

(E),

I)

the abscissa on the right graticule ...

The construction of a “fixed scale” is based on an imaginary arrangement in the field (Fig. 8). The distance marks are arranged within the field of view corresponding to the field glasses. The coordinates (x, 30 E) can be taken from this and the left and right graticules drawn using Formula I). Arranging the scale in the form of a zigzag line results in the dash mark image shown in FIG. 6.

The reticle for the left and right collimators 35 are generally different from one another. The accuracy of the distance measurement depends on the dimensionally accurate manufacture of the two graticules. With collimator lenses of short focal length, which are desirable because of the small size of the attachment, the limit of manufacturing accuracy is soon reached.

It is therefore advantageous to use a solution that requires the same graticule for the left and right collimators. This eliminates dimensional errors.

As can be seen from FIG. 9, the following result as conditions: 45

1. The two collimator lenses have different focal lengths (fk) i = £ (fk) r

2. The measuring points in the field lie on a straight line that corresponds to the equation:

E =

f. -fr b - K

• x +

f. + fr b - K

55

is sufficient, where K is the constant distance between the corresponding left and right marks.

FIG. 10 shows a corresponding branding arrangement in the field and FIG. 11 shows the branding image.

The exemplary embodiment shown in FIGS. 3 to 5 represents the basic structure of an attachment with a fixed scale. It can be modified and improved several times, as shown for example in FIGS. 12 and 13, the two halves of the field glasses body 1 with the joint 3 are only shown in Fig. 12. In the section shown in FIG. 13 along the line XIII-XIII of FIG. 12, only the objectives 2 are visible from the field glasses. As in the exemplary embodiment according to FIGS. 3 to 5, the two collimators m are connected to one another via a connecting body which in this exemplary embodiment is box-shaped and thus forms a housing 12 in which the collimators are installed. Two-part telephoto lenses are provided as collimator lenses 6 in order to reduce the overall length. The reticules 7 are illuminated by two electric lamps 13. This artificial lighting makes it possible to keep the cross-section of the collimators small, which means that the shading of the binocular lenses is less. So that the field glasses can still be bent, the cross-section of the collimators is not circular, but rectangular. The width remains the same, but the thickness of the attachment is reduced.

To adjust the range finder, two prisms 14, 15 which can be displaced in the direction of the collimator axes and have a small refractive angle are provided between the collimator objective 6 and the reticle 7. By moving the prism 15, the refractive edge of which runs horizontally, the left and right scale images can be made to coincide in height. It is used to correct the height error, which, if too large, can prevent the spatial impression. With the prism 14, the refractive edge of which is perpendicular, the distance calibration is carried out. The prisms are shifted with screw spindles 16, 17. For the sake of completeness, the batteries 18 required for the power supply of the lamps 13 and the push-button switch 19 required for switching on the power supply are also shown.

Another exemplary embodiment is shown schematically in FIG. 14. In a collimator housing 12 forming the connecting body, mirror lenses 20 are provided as collimator lenses. Two LEDs 21, 22 of different colors are used for lighting. A light guide rod or glass fiber bundle 23, 24 leads from each diode behind the reticules 7 and illuminates them via mirror 25. By using two diodes with different colors, you are able to choose the more favorable color of the measuring marks for day and twilight observation. The adjustment of the height and distance according to here takes place by vertical displacement of a lens 28 or horizontal displacement of a lens 29, which must be regarded as part of the collimator objectives.

FIGS. 15 and 16 show a very compact exemplary embodiment in which all optical parts are firmly glued to one another and in which the connecting body is likewise designed as a housing 12 in which a glass cuboid 30 forming a double collimator is installed, on the polished, long one Side surfaces of both the collimator lenses 6 and the reticle 7 are glued. In addition, lighting prisms 31 are also cemented. As a result, the adjustment is already fixed during manufacture. This optical block is loosely inserted into the housing 12 together with lamps 32 and a battery 33.

The exemplary embodiments described so far relate to attachments for measurement with a fixed distance scale. Devices for the measurement with "hiking mark" have a simpler line mark image, as shown in FIG. 17. A main mark 101, which is used for the measurement, is generally sufficient. For the better spatial impression, you usually arrange a few more brands that appear at a different distance. The marks 102 appear closer, the marks 103 further than the main mark 101. In principle, any exemplary embodiment can be used as a device with a “hiking mark”, provided an adjustment option is provided for the distance and the adjustment member position can be read off on a scale. Devices with an internal reading, whose field of view can be seen from FIG. 17, are advantageous. In addition to the main measurement mark 101 and the auxiliary measurement marks 102 and 103, the pointer 35 is also applied to one of the graticules.

622 345

The distance can be read immediately on a distance graduation 34 which has passed with the setting of the distance, without having to set the glass down.

The rangefinder shown in FIGS. 18 and 19 is set up for measurement with a hiking mark. The structure essentially corresponds to that of FIGS. 15, 16. Two square rods 36, 37 made of glass are firmly connected to a glass prism 38. The two collimator objectives 6 are cemented onto the square rod 36 and the two reticules 7 onto the square rod 37. The height error can be eliminated by moving the prism 15 via a strut 39 with a screw 40. The spatial displacement of the entire brand image is changed by the longitudinal displacement of the prism 14. The adjusting spindle 42, which adjusts the prism 14 via a strut 41, carries an adjusting knob 43 with a distance division 44. After the main marker has been brought to the same distance as the terrain point to be measured by adjusting the adjusting knob 43, the distance 44 is read from the distance division. The lamps 13, the housing 12 and the field glasses lenses 2 correspond to the previous exemplary embodiments.

Figures 20 to 22 show two further examples. To ensure that the overall height remains as small as possible, the optical axis of the collimators is broken one or more times by suitable mirror prisms.

In Fig. 20 four identical mirror prisms 47 are cemented to a glass block 46, the long side surfaces of which are polished, as are the two collimator lenses 6 and the reticules 7. The light rays emanating from the lamp 13 are reflected four times and pass through the collimator lenses 6 in the same direction and in the same direction as the incident beam. The cuboid surfaces do not need to be mirrored, since total reflection occurs here, but the reflecting surfaces of the mirror prisms 47 do. A device 48 is provided in the device for measurement with a “mark”, which is measurably displaceable by a micrometer screw 49. The distance is read directly from a graduation 50.

FIGS. 21 and 22 schematically show a rangefinder attachment with a “hiking mark” and inside reading, which provides the field of view shown in FIG. 17. Each of the two collimators consists of a rhomboid prism 51, 52 with cemented collimator objective 6 and reticle 7. Both prisms are connected to one another by gluing to form a rigid block. A glass scale 53 with a distance scale 54 is mechanically connected via an angle 55 to the displaceable lens 48, which is also shown in the exemplary embodiment according to FIG. 20. The micrometer screw 49 does not need to have a division here. The measured distance can be read in the left field of view of the field glasses.

The attachment with the “hiking mark” according to FIGS. 23 and 24 has, in addition to the low overall height, the advantage of the low weight and long focal length collimator lenses. The half-cube prisms 58 with cemented collimator objectives 6 are glued to the porro prisms 57 serving as lighting prisms, which in turn are fastened in the housing. The reticules 71 and 7 r are glued to the prisms 57. The beam path runs in two horizontal planes, as can be seen from the front view in FIG. 24. The light beams emerging from the lamp 13 to the left and right are made convergent by the condenser lenses 56. After the deflection by 180 °, they shine through the graticules 71, 7 r, pass through the horizontally displaceable adjusting lens 48 and, after reflection on the mirror surface of the half-cube prism 58, leave the attachment through the collimator lenses 61 and 6 r. The reading of the position of the adjusting lens 48 on the division 44 gives the distance.

In the range finder attachment with a fixed scale, shown in FIGS. 25 and 26, the folded beam path runs in only one plane. Only the optical parts are shown. Each prism block consists of a pentagon prism 59, a cemented 22'h ° prism 60, which supports the reticle 7, and a collimator lens 6. The cemented surface between the prisms 59 and 60 is silver-permeable. The light rays of a light source, not shown here, penetrate the reticules 71 and 7 r. About half the amount of light enters the pentagon prism 59, is reflected on the fully silvered prism surface and leaves it in a horizontal direction. After passing through the adjusting wedge 14, the light rays penetrate into the opposite prism 59 and, after being reflected twice, are again guided in half through the collimator lens 6 into the field glasses. The distance adjustment is carried out by moving the glass wedge 14 horizontally.

For the sake of completeness,

that the mirror prisms can be replaced by equivalent mirrors in all exemplary embodiments.

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Claims (22)

622 345 PATENT CLAIMS 1. Additional device on a double telescope with a small base, for measuring the spatial image with two parallel collimators, in the image plane of which graticules are arranged with marks that appear bright when viewed at a certain distance, characterized in that the additional device is designed as an attachment that can be placed on the telescope body (1) , in which the collimators (4) are connected to one another via a connecting body (5, 12, 30, 36, 37, 46, 51, 52) and are placed in front of the two objectives (2) of the double telescope, the collimator openings being smaller than the objective openings of the double telescope and the distance of the collimator axes acting as a measuring base is approximately equal to the distance of the optical axes of the objectives of the double telescope. 2. Additional device according to claim 1, characterized in that two jacket tubes (lé) which can be placed on the lens mounts of the telescope body (1) are provided, which have mutually facing openings (11) through which the connecting body is guided, which in turn has resilient struts ( 9) is movably mounted in the casing tubes (10). 3. Additional device according to claim 1 or 2, characterized in that the connecting body (30; 36, 37; 46) together with the collimators (6,7) is housed in a housing (12). 4. Additional device according to claim 1 or 2, characterized in that the connecting body is formed by a housing (12) carrying the collimators (6, 7). 5. Additional device according to one of claims 1 to 4, characterized in that the effective cross section of the collimator openings is substantially rectangular (Fig. 12). 6. Additional device according to one of claims 1 to 5, characterized in that telephoto lenses are provided as collimator lenses (6, 20). 7. Additional device according to one of claims 1 to 6, characterized in that mirror lenses (20) are provided as collimator lenses. 8. Additional device according to one of claims 1 to 7, characterized in that the same graticules (7) are provided for both collimators and the two collimator lenses (6) have a different focal length. 9. Additional device according to one of claims 1 to 8, characterized in that a glass cuboid (30, 46) carrying the collimators and in particular arranged in a housing (12) is provided as the connecting body. Auxiliary device according to claim 9, characterized in that on the one hand the collimator lenses (6) and on the other hand the graticules (7) are cemented onto the ends of the glass cuboid (30, 46). 11. Additional device according to claim 9, characterized in that the reticle (7) and the collimator lenses (6) on the glass cuboid (46) are cemented offset from one another, the reticle (7) and the collimator lenses (6) opposite each other on the glass cuboid mirror prisms (47) are cemented. 12. Additional device according to one of claims 1 to 8, characterized in that mirror prisms (47) are provided, through which the collimator axes are broken several times. 13. Additional device according to one of claims 1 to 12, characterized in that for the distance adjustment or correction and / or height correction optical micrometers, in particular between the reticules (7) and the collimator lenses (6), light-refractive prisms (14, 15) Small calculation are provided, which are adjustable in a holder on a threaded spindle (16, 40, 42). 14. Additional device according to claim 13, characterized in that the prisms between two mutually spaced square bars (36,37) are arranged, with one Square rod (36) the collimator lenses (6) and on the other square rod (37) the graticules (7) are arranged. 15. Additional device according to one of claims 1 to 12, characterized gekennzeichflet that a lens (48) is provided for distance adjustment or correction, which is adjustable in a plane perpendicular to the collimator axes. 16. Additional device according to claim 13 or 14, characterized in that the threaded spindle (42) serving for distance adjustment is provided with an adjusting knob (43). 17. Additional device according to one of claims 13 to 16, characterized in that a distance division indicating the measured distance is provided (44). 18. Additional device according to one of claims 13 to 17, characterized in that a distance scale (54) is provided which is reflected in the image field. 19. Additional device according to one of claims 5, 17 or 18, characterized in that the connecting body consists of two rhomboid prisms (51, 52) arranged one above the other with a cemented-on collimator objective (6) and reticle (7), and the two rhomboid prisms (51, 52) together are glued to a rigid block, the lens (48), which can be adjusted by means of a threaded spindle or a micrometer screw (49), being firmly connected via an angle (55) to a glass measuring rod (53) carrying the distance scale (54), which is connected to the image the associated reticle (7) through which a rhomboid prism (52) lies in the beam path of one collimator lens (6). 20. Additional device according to one of claims 1 to 19, characterized in that for illuminating or illuminating the reticle light bulbs or photodiodes (13, 21, 22, 32) with an associated power source (18, 33) and one connected in series therewith Switches (19, 26) are provided. 21. An additional device according to claim 20, characterized in that mirrors (25, 31) deflecting the beam path from the incandescent lamps (21, 22, 32) onto the reticle are arranged in front of the reticle (7). 22. Additional device according to claim 20 or 21, characterized in that differently colored light bulbs (21, 22) are provided which can be selected by means of a switch (27) arranged in the housing (12).