DE3731416A1 - Illuminating device of a structure which can be looked through - Google Patents

Abstract

The illuminating device of a cross wire (cross hair, reticle) (19) in a target scope (optical sight) consists of a light-collecting, luminescent body (18) which is designed in such a manner that it emits visible radiation in a concentrated manner near the cross hair (19). For this purpose, the luminescent body (18) has collecting surfaces (20, 21) for collecting ambient radiation and radiation coming from the object. The collected radiation is passed to the mounting edge (22) and the radiation which is emitted there illuminates the cross hair (19) in a grazing manner (Figure 4). <IMAGE>

Description

The invention relates to a lighting device a structure to be foreseen according to the generic term of claim 1.

Foreseeable structures in the form of crosshairs and Graticules are commonly used in observation and Target devices, e.g. in diopters, telescopes, Ent rangefinders and microscopes. The company Denkreuz can take many forms, it can consist of crossed wires that are within a Carrier ring are clamped, it can continue to photolithographic path through chemical etching as made by galvanoplastic processes be. Parts are called reticules, with foreseeable structures on a carrier are brought. Examples of such structures are in the book: Naumann, Schröder; Components of the Op tik; 4th edition, page 427 shown. With observation and target devices in which imaging optics are used find to magnify objects to the eye it is particularly advantageous to offer the thread  cross or the reticle in the place of a Arrange intermediate image and the bracket of the company cross or graticule as a field boundary to use.

So that the structure to be foreseen by the observer is good can be recognized, it must stand out from the background take off, i.e. there must be a certain contrast between the image of the object to be observed and the image of the crosshair or the reticle be there. To maintain this contrast even with bad ones To maintain lighting conditions are for lighting from crosshairs or graticules auxiliary light source len known. In the book: Naumann, Schröder; Construction elements of optics; 4th edition; Page 428 is one of the Illumination of a reticle by a Lamp on the side shown. The brightness this lamp is due to current change, aperture or Gray filter set so that the eye is not ge is dazzled.

A lamp as an auxiliary light source has the disadvantage that on the observation and target devices a Ge Housing for the lamp must be attached that the Power supply of this lamp also in the device is housed, or that a disturbing connection an external power supply is required is. Furthermore, the brightness of the lamp must be constant the ambient brightness, or the brightness of the Object image are adjusted to dazzle the To avoid eye.  

Noctilucent graticules are also known, where the structure is etched into a glass plate and with a pigment from e.g. Titanium dioxide and bandage is filled in medium. The appears in daylight Structure dark and in the dark it rises, caused by the lighting with an auxiliary light source, bright from the dark background.

The invention has for its object a Be lighting device of a structure to be foreseen to create that independent of an energy ver supply works and saves space and is inexpensive be used in observation and target devices can.

This object is achieved by the kenn Drawing features of claim 1 solved.

The advantages achieved with the invention exist especially in that the proposed lighting the optimal contrast between the Image of the object and the image of the structure to be foreseen structure itself, since the irradiated light guide performance always proportional to the environment or the ob Brightness is that the lighting continues is maintenance free and an almost unlimited life has duration.

Exemplary embodiments are based on the drawing explained in more detail  

It shows

Fig. 1 is a Diopterbe inventive lighting,

Fig. 2 is an illumination of a Fadenkreu zes in section,

Fig. 3, the reticle of FIG. 2 in the view III-III,

Fig. 4 shows a sighting telescope,

Fig. 5 shows another scope.

In Fig. 1, an illumination is shown a diopter with means of light-collecting and luminescent body 1. A diopter is a device for determining a target line, the diopter forming a visual aperture by means of an aperture. When aiming, this aperture limits the field of view and serves as a rear sight. Between the diaphragm and the object, an annular grain 2 is attached, the center of which must be brought into line with the object. The luminescent body 1 is also the Fas solution of the ring grain 2 , it is positioned by two screwed sleeves 3 and 4 . The shape of the luminescent body 1 is selected so that it acts as a light collector and the energy radiated from the object or from the environment concentrates on the narrow surface 5 again. In the invention, the photoluminescence is used, that is, the energy supplied to an atomic system is converted into radiation energy without the intermediate stage of thermal energy. The emitted radiation has the same or a longer wavelength than the exciting radiation. For example, a luminescent layer or a luminescent body can result in an emission in the visible spectral range by UV radiation. One differentiates between fluorescence and phosphorescence. With fluorescence, the light phenomenon quickly subsides after excitation by radiation, with phosphorescence, the light phenomenon slowly subsides. It is essential to the invention that the lighting of a structure to be foreseen, which in FIG. 1 is the ring grain 2, is carried out by means of a luminescent body 1 which collects the object and the ambient radiation. The radiation that is which produces an incident light in the luminescent body 1 is guided by total reflection within the Kör pers 1 and at the narrow face 5 coupled. So there is a grazing lighting device of the ring grain 2 , which is coated matt black and thus has a very high degree of reflection even with the grazing light.

The object to be targeted is observed through the diaphragm of the diopter and the target point of the object must be aligned with the center of the diaphragm and with a crosshair 7 ( FIG. 2) attached between the diaphragm and the object in the vicinity of the diaphragm. So that this crosshair 7 stands out from the object, a fiction, contemporary lighting of the crosshair 7 is also advantageous. The crosshair 7 is - as shown in FIGS. 2 and 3 - integrated in a luminescent body 8 . The luminescent body 8 consists of light-collecting plastic, which is sold under the trade name "LISA plastic". So that the surface of the luminescent body 8 , which faces the observer, does not appear dazzling, the luminescent body 8 is screwed to the shading panel 9 , which at the same time gives it the required stability and with which it is fastened, for example, to a gun barrel . It is also possible to dispense with the shading aperture 9 and to shape the luminescent body by 8 so that it alone achieves the required stability. In order to avoid disturbing radiation or glare, surfaces of the luminescent body 8 can also be covered entirely or partially with a layer. The crosshair 7 is embedded in the luminescent body 8 in such a way that the collected radiation emerges from the narrow surface 10 and illuminates the crosshair 7 in a grazing manner. In order to collect as much object radiation as possible, the luminescent body 8 is funnel-shaped and the outer surface 12 also serves to collect the ambient radiation.

In Figs. 1 to 3, examples are shown in which no imaging optics are used. However, the invention is also particularly advantageously applicable in target telescopes, as exemplified in FIGS . 4 and 5. A lens 13 is fastened to a tube 15 by means of a mount ring 14 . An eyepiece 16 is constituted by a ring nut 17 Ver pressed to a luminescent body 18, which is interposed between the Verschraubring 17 and the tube 15 and in which a reticle is integrated 19th The luminescent body by 18 is shaped so that it collects as much ambient radiation as possible by means of the outer surface 20 and as much object radiation as possible with the curved surface 21 , and that the radiation generated in the luminescent body 18 leads to the socket edge 22 of the cross hair 19 and leaves there concentrated. The inner surface 23 is coated here in such a way that no light radiation emerges from the inner surface 23 and the light radiation is reflected back into the luminescent body 18 .

FIG. 5 shows another scope with an inventive lighting. As in FIG. 4, a lens 24 is fastened in a tube 26 by means of a mount ring 25 . An eyepiece 27 is connected to an intermediate piece 29 by a screw ring 28 . In order to form the collecting surface of the luminescent body 30 very large and to optimize the Lichtlei device, it is tubular in the example shown and fixed with the aid of screws, not shown, with the intermediate piece 29 and the tube 26 . The tubular luminescent body 30 is open on the object side and holds a reticle 31 on the image side. The intermediate body 29 acts simultaneously as a field diaphragm at the location of an intermediate image. The frame of the reticle 31 is a circular opening of the luminescent body 30 , into which the reticle 31 is glued and on the surface 32 sen the collected light is concentrated.

The partial decoupling of the collected radiation can e.g. due to bumps on the surface of the lumi nescent body, through sharp-edged corners or caused by narrow edges. Form and the surfaces of the luminescent bodies chosen so that the collected radiation only on site the lighting point can emerge in a concentrated manner.  

In versions not shown, the line plate or the crosshair can not be taken from the luminescent body, but the reticle or the crosshair have its own version or be clamped between two bodies, both bodies can be luminescent. In Figs. 1 to 5 only target devices are shown, the invention is also to other monitoring devices, such as at range finders, telescopes, microscopes and micro applicable to detect a Conceivable structure in low light conditions. An area of application is also the contactless edge probing for workpiece or tool measurement, in which the measuring points of the workpiece or tool image are brought into line with a target mark. In order to separate the structure to be foreseen particularly well from the background radiation, it can be advantageous to make it highly reflective, or to form it from luminescent material or to coat it with luminescent material. Thus, designs are also conceivable in which no separate graticule is required, but rather the luminescent body is shaped in such a way that the structure to be foreseen is introduced into an area of this body, so that visible radiation is coupled out to this structure. The structure to be foreseen can be introduced into the luminescent body as a depression, which may be filled with a pigment made of titanium dioxide.

Additional radiation can be used to collect radiation Tools such as Mirror arrangements used will.  

For the interior lighting of reticles, it may be before geous when the edge up to a gap - is mirrored - for coupling of radiation. Total reflection thus results in uniform and complete illumination of the lines on the reticle.

Claims (13)

1. Illumination device of a structure to be foreseen in an observation or target device, characterized in that a luminescent body ( 1 , 8 , 18 , 30 ) of the observation or target device is designed such that it absorbs ambient and / or object radiation, and that radiation for illuminating the structure to be foreseen ( 2 , 7 , 19 , 31 ) on surfaces ( 5 , 10 , 22 , 32 ) or edges of the luminescent body ( 1 , 8 , 18 , 30 ) is coupled out. 2. Lighting device according to claim 1, characterized in that the luminescent body ( 1 , 8 , 18 , 30 ) is the frame of the structure to be foreseen ( 2 , 7 , 19 , 31 ). 3. Lighting device according to claim 1, characterized in that the luminescent body ( 1 , 8 , 18 , 30 ) has a large collecting area ( 12 , 20 , 21 ) and that the collected radiation to narrow areas ( 5 , 10 , 22 , 32nd ) or edges near the structure to be foreseen ( 2 , 7 , 19 , 31 ) and is coupled out there. 4. Lighting device according to claim 3, characterized in that the surfaces ( 5 , 10 , 22 , 32 ) or edges for coupling out the radiation are roughened. 5. Lighting device according to claim 1, characterized in that the luminescent body ( 18 , 30 ) is part of a telescopic sight. 6. Lighting device according to claim 5, characterized in that the structure to be foreseen is a crosshair ( 7 , 19 ). 7. Lighting device according to claim 5, characterized in that the structure to be foreseen is a reticle ( 31 ). 8. Lighting device according to claim 6 or 7, characterized in that the frame edge of the crosshair ( 19 ) or the graticule ( 31 ) is surrounded by the luminescent body ( 18 , 30 ) and the radiation is guided to this frame edge and coupled out there. 9. Lighting device according to claim 7, characterized characterized that the edge of the graticule, except for a gap for coupling radiation, is mirrored. 10. Lighting device according to one of the preceding claims, characterized in that the luminescent body ( 1 , 8 , 18 , 30 ) consists of a material with a refractive index greater than 1.55, the emitted radiation has a maximum in the visible wavelength range. 11. Lighting device according to claim 1, characterized characterized that the luminescent body is provided with the structure to be foreseen, so that visible radiation on the structure is coupled. 12. Lighting device according to claim 11, characterized characterized that the structure as a depression is introduced into the luminescent body. 13. Lighting device according to claim 11, characterized characterized in that the recess with a Pig ment is filled out.