DE3728798A1 - Device for receiving, amplifying and transmitting light rays or heat rays - Google Patents

Abstract

A device for receiving, amplifying and transmitting light rays or heat rays consists of a pick-up and discharging device (10) which is connected via a multiplicity of ray conductors (18; 32) to a ray collecting device (34) which is connected via a multiplicity of ray conductors (35) to ray utilisation bodies (23). In this way, it is achieved that light rays or heat rays emitted from a source or rays emitted from a ray collecting device can be transmitted with low losses even over large distances (Fig. 1, 2 and 3). <IMAGE>

Description

The invention relates to a device for collecting, Amplify and transmit light or heat rays.

DE-OS 28 14 962 is a lighting device known in the case of a spotlight, a light collector device is connected upstream with one or more flexible arms are provided, each with a light guide ter included and at the end with a light head are provided. The light guides are plastically deformed plastic or metal hoses. The Collecting device has the output of the radiator Distance surrounding leaving an air gap, funnel-shaped housing, in which one the radiator assigned lens is housed in their Focal point is a connection for one or more light guides is arranged.

DE-AS 22 37 379 is a lighting device known with electric lamp whose luminous flux in the Entrance of a main light guide is directed through which it to a light distribution head with reflector provided in it ting surfaces. The reflective Surfaces divide the luminous flux and reflect it in Auxiliary light guides that illuminate its partial luminous fluxes head which guide him in the room to be illuminated to distribute. The light reflecting surfaces are in the Light distribution head on a pyramid and / or pyrami the frustum-shaped hollow body provided in the light distribution head is firmly attached. That forms Material of the light distribution head the hollow body. The Auxiliary light guides are rod-shaped and ring-shaped. Furthermore, one of the number of secondary light guides speaking number of light reflecting surfaces provided be. The hollow body has flat surfaces, one part of the area determined by the size of the plane  Luminous flux supplied straight through the light distribution Let the head through and feed it to a light head. The The main light guide is also divided into several individual light guides divided over which the light reflecting surfaces light of different colors can be supplied can.

DE-AS 25 59 278 is a device for directed Light emission with one light and one Described body having light emission surface, the the area exposed to the light is larger than that is light-emitting surface. A light gathering and distribution ling body with a curved surface is to the light-emitting end face adjacent and aligned arranged and on the side facing away from this end face Provide side with a curved surface. The light up taking body is made of fluorescent plastic material with a light-collecting and distributing body combi made of a cylindrical rod, a ball, a reflector or the like. The light collecting and distributing bodies take the imitated light and releases it in a limited directional range and concentrates the light into an adjustable one Beam.

The invention is based on the object to improve the mentioned facility so that from a Source of outgoing light or heat rays or from one Beam trap also emits outgoing beams transmit long distances with little loss can be.

The invention solves this problem by the in the mark of claim 1 contained features.

The configuration of the beams is particularly advantageous  Pick-up and delivery device from a variety of square cones that taper conically in the direction of the beam fen. If the rays are to be parallelized, it is expedient, the square cones in the beam direction Upstream collecting lens, so that a mixed beam parallel lizer is formed. In this case, the mixing beam parallelizer one more ray concentration tration device upstream, the burning point (s) assigned to the input end of the beam line is.

The square cones can also form a hemisphere, their lying on the cut surface of the hemisphere, also concentrate hemispherical radiation exit surface arranged to the hemispherical outer surface and with is connected to the input ends of the beam conductors.

The above Mixed beam parallelizer can also have a hole plate upstream with a variety of beam conductors be into which the parallelized rays can be introduced are.

The radiation collecting device advantageously consists of a hollow body, in the outer wall lens is attached are arranged, the focal points in the center of the hollow body pers are concentrated. This is particularly advantageous Design of the hollow body as a removable cube, in the six or more side surfaces of the converging lenses are used, the output ends of which with the Radiation receiving and delivery device connected Beam guides are assigned while on the edge surfaces of the hollow cube the entrance ends of the to the rays Utilizing beam guides are arranged.

The invention is based on the schematic Drawing of exemplary embodiments explained. Show it:  

Fig. 1 is a Mischstrahlaufnahme- -abgabevorrich and processing means for parallelizing and focusing the beam,

Fig. 2 is a the Mischstrahlparallelisator in Fig. 1 vorschaltbare perforated plate having a plurality of a Strahlenkonzentrations- and -abgabevor direction leading beam conductors,

Fig. 3 is a biconcave lens for prescreening before the Mischstrahlparallelisator in Fig. 1 with a leading to a radiation beam utilization body conductor,

Fig. 4 is a vorschalt Mischstrahlparallelisator the bare ring lens having a plurality of bodies to wetting Strahlennut leading beam conductors,

Fig. 5 is a Strahlenaufnahme- and dispensing apparatus similar to Fig. 1 in the form of a hemisphere in a sectional view,

Fig. 6 is a plan view of FIG. 5,

Fig. 7 is a Strahlenkonzentrations- and Verteilvor direction in FIG. 2 in an enlarged Dar position quantitative be construed together with the divergent incoming radiation into a focal point,

Fig. 8 shows the device according to FIG. 7, but only the radiation decreasing beam conductors,

Fig. 9 similarly shows a further embodiment of a radiation distributor body concentration- and Fig. 8, but with the inner concave mirrors as the outer walls,

Fig. 10 shows another embodiment of a radiation concentration and distribution device in top view, consisting of a rigid tube with biconvex lenses lined up which are incident to the concentration of an associated parallel four concentric biconvex focal points are provided in the beam respectively,

Fig. 11 is a sectional view along line 11-11 in Fig. 10,

Fig. 12 shows a further embodiment of a radiation concentration and delivery device, Lich similarity to that in FIGS. 10 and 11, but which is designed as a rigid hollow mirror tube

Fig. 13 is a sectional view along line 13-13 in Fig. 12, in which the concentration is shown by diverging beams,

Fig. 14 a beam utilization body as a solid body made of glass or plastic.

In the drawing is a device for collecting, Amplify and transmit light or heat rays shown using a plurality of beam conductors a radiation collecting device, which is connected via several beam conductors on radiation use bodies or heads connected.

In Fig. 1, the radiation receiving and -abgabevor direction consists of a glass, metal or plastic body 10 , which is composed of a plurality of square, conical cones 11 lying one against the other, which taper conically in the direction of the rays and which are divergent but concentrated Deliver rays to an underlying bicon lens 12 , from which the rays emerge in parallel into a housing 13 which carries both the body 10 and the biconvex lens 12 . The housing 13 is provided with an external thread 14 at the lower end. A concave mirror 15 can be inserted into the lower end of the housing 13 by means of a screw ring 16 , in the focal point 17 of which the parallel rays are concentrated. In the inserted state of the concave mirror 15 , the input end of at least one beam guide 18 , which is radially inserted into the housing and whose function is described below, lies at the level of its focal point 17 .

Instead of the concave mirror 15 , a biconvex lens 19 can also be inserted into the lower end of the housing 13 by means of the screw ring 16 , through which the parallel rays of the mixed-beam parallelizer formed by the cones 11 and the biconcave lens 12 are concentrated in one focal point 20 , which the Input end 21 is assigned to at least one beam guide 22 , the output end of which is connected to a ring-shaped or spherical glass body 23 , which here is either spherical section-shaped but can also be cylindrical-section-shaped, such that the diverged beams introduced into body 23 are emitted in parallel to the outside will.

FIG. 4 shows a ring lens 24 , the individual focal points 25 of which are each assigned to a beam guide 26 , of which four beam guides are shown in FIG. 4, each beam guide being connected to a radiation use body 27 which is shown only once. This radiation use body 27 can be a prism or a blunt cone that emits the beams in a divergent manner.

In FIGS. 5 and 6, a hemispherical glass, metal or plastic body 28 is shown which forms a semi-sphere which consists of a plurality of conically tapered to the center of the ball glass, metal or plastic bodies 29th The inner radiation exit surfaces of the glass, metal or plastic body 29 form a hemispherical surface 28 a , which is arranged concentrically with the hemispherical outer surface of the glass, metal or plastic body 28 and its center and connected to the input ends of a plurality of beam conductors 30 . It can be seen that here too, the rays incident from various radiation sources, such as daylight and / or artificial light, are refracted at the surfaces of the tapered cones 29 and are concentrated towards the inner spherical surface before they enter the beam guides 30 and, as follows described, to be continued.

An essential embodiment of the invention will now be described in connection with FIG. 2. A perforated plate 31 can be seen there, which can also be used in the lower end of the housing 13 by means of the screw ring 16 . As a result, the parallelized beams can be incident on the input ends of the beam guides 32 inserted into the holes 33 of the perforated plate 31 . The beam guides 32 transmit the beams in a divergent manner to a beam concentration and distribution device 34 , from which they are emitted by means of further beam guides 35 to beams which can be of any design, for example as in 23 in FIG. 3 and in 27 in FIG. 4 This radiation concentration makes it possible to emit the beams to radiation use bodies over relatively great distances by means of beam guides 35 inserted at the cube edges, which are known in the art and therefore do not need to be described in detail.

In Fig. 7, the radiation concentration and Abgabevor direction 34 is shown in greater detail. In this top view four of six beam conductors 32 a , 32 b , 32 c and 32 d are shown, which divergently emit the beams at six biconvex lenses at right angles to one another, four of which with 40 a, 40 b, 40 c, 40 d are designated. Through these biconvex lenses, the beams are parallelized and transmitted to one smaller biconvex lens arranged coaxially with the six biconvex lenses, four of which are again designated 41 a, 41 b, 41 c and 41 d . These inner lenses 41 a to 41 d concentrate the rays on their common focal point 42 . It can be seen that the housing 43 forming the support of the lenses can consist of a sheet metal body, of plastic or the like and is spherical. However, the spherical shape is immaterial for the operation of the device. The body could also be in the form of a cube. What is decisive is the concentric arrangement of the outer and inner lenses described with respect to the concentration point 42 in order to ensure the highest possible energy concentration. With the reference numerals 40 e and 41 e those two outer and inner lenses are shown in dashed lines, which are net angeord parallel to the plane of the drawing in the device.

Fig. 8 shows a similar top view of the device as in Fig. 7, but with the difference that only the elements which discharge the rays, namely four of a total of eight beam conductors 45 a , 45 b , 45 c and 45 d , are shown with their ends protruding into the device at eight corner points are arranged at the same distance from the concentration point 42 and receive the rays emanating from this concentration point and transmit them to the radiation use bodies described above.

The embodiment of a beam concentration and delivery device shown in FIG. 9 differs from the embodiment in FIGS . 7 and 8 in that it is designed as a hollow body 50 , which in the present case is cube-shaped, the six sides of which form internal concave mirrors, four of which are designated 51 a, 51 b, 51 c, 51 d . In the focal points of the six concave mirrors, six beam conductors are introduced, four of which can be seen at 52 a, 52 b, 52 c, 52 d . Its inner end runs flat with the concave mirror surface. Beam guides lead away from the eight blunt corners of the cube-like hollow body 50 , four of which can be seen at 55 a, 55 b, 55 c and 55 d . The inner ends of the beam conductors are arranged at equal distances from one another from the concentration point which is not visible in the present case. As described, the captured rays are directed to the radiation usage bodies. In the present case, the housing 50 can also consist of glass, metal or plastic.

In Figs. 10 and 11 is a radiation concentration or dispenser 60 illustrates that of a rigid tube having one behind the other four sides are arranged at equal intervals focal agents 61 a, 61 b, 61 c and is 61 d, where this sequence nor a plurality of further Focus formers can be increased. These individual focal point formers 61 a to 61 d , as can be clearly seen in FIG. 11, consist of biconvex lenses 62 a , 62 b , 62 c and 62 d which are arranged at 90 ° to one another and which concentrate parallel rays 63 on the common focal point 64 . As a result, a chain of focal points 64 is formed within the tube 60 , as illustrated in FIG. 10, a beam guide 65 being passed through this chain of focal points, the ends of which are held concentrically in an end plate 66 which closes the tube 60 .

In the embodiment in FIGS. 12 and 13, the difference to the embodiment in FIGS. 10 and 11 is only in the fact that instead of the four biconvex lenses, four concave mirrors 70 are provided, each one at the same time one after the other in equal intervals switched cross-sectional levels are arranged. These concave mirrors are assigned nipples 71 , into which, as in FIG. 9, beam guide ends are inserted, through which the rays are fed to the concave mirrors 70 . The concave mirrors 70 concentrate the supplied beams on the focal points lying on their half-radius, which in turn are designated 64 here. The device also consists of a rigid tube 75 of any material, the end of a beam guide 72 passing through focal points 64 being held in end plates or caps inserted into the ends of tube 75 and of which, as in Fig. 10 a cap 76 can be seen.

Fig. 14 illustrates a beam utilization body 80 which is made as a solid body made of transparent glass or plastic. This radiation usage body serves as a lighting fixture in the form of a cube, of which six spherical spherical surfaces are designated as 80 a, 80 b, 80 c, 80 d, 80 e and how internal concave mirrors work. Beam guides 83 are introduced into the focal point 82 of these concave mirrors, the ends of which run approximately flat with the concave mirror surface, the axis of the beam guides again being directed towards the focal point in the center of this lamp body. The focal point emits its radiation to the entire body, the rays being reflected in a variety of ways and in different directions, so that the entire body is effective as a luminous element.

Claims (11)

1. Device for collecting, amplifying and transmitting light or heat rays, characterized in that the receiving and dispensing device ( 10 ; 28 ; 40 ) via a plurality of beam conductors ( 18 ; 30 ; 32 ) connected to a beam collecting device ( 34 ) is, which is connected via a plurality of beam conductors ( 35 ) to radiation utilization bodies ( 23 , 27 ). 2. Device according to claim 1, characterized in that the receiving and dispensing device consists of a plurality of square cones ( 11 ; 29 ) which taper conically in the beam direction. 3. Device according to claim 2, characterized in that the square cone ( 11 ) together with a upstream in the beam direction biconvex lens ( 12 ) form a mixed beam parallelizer. 4. Device according to claim 3, characterized in that the mixed beam parallelizer is a perforated plate ( 31 ) with a plurality of beam conductors ( 32 ) is switched on. 5. Device according to claim 3, characterized in that the mixed beam parallelizer is a radiation concentration device ( 15 ; 19 ; 24 ) connected upstream, the focal point (s) ( 17 ; 20 ; 25 ) associated with the input end of the beam guide ( 18 ; 22 ; 26 ) is. 6. Device according to claim 5, characterized in that the radiation concentration device consists of at least one concave mirror ( 15 ). 7. Device according to claim 5, characterized in that the radiation concentration device consists of at least one biconvex lens ( 19 ). 8. Device according to claim 5, characterized in that the radiation concentration device consists of an annular lens ( 24 ). 9. Device according to claim 2, characterized in that the quadrangular cone (29) form a half-sphere whose lying on the cut surface of the hemisphere, also hemispherical beam exit surface (28 a) arranged concentrically with the hemispherical outer surface (28 b) and to the input ends of the Beam conductor ( 30 ) is connected. 10. The device according to claim 1, characterized in that the radiation collecting device ( 34 ) consists of a hollow or solid body made of metal, glass or plastic, in the outer wall collecting lenses ( 36 ) are arranged, the focal points in the center ( 37 ) of the hollow or full body are concentrated. 11. The device according to claim 10, characterized in that the hollow body consists of an expandable cube, in the side surfaces of which the collecting lenses ( 36 ) are inserted, to which the output ends of the beam conductors ( 18 ; 22 ; 26 ; 30 ; 32 ) are assigned, while the input ends of the beam guides ( 35 ) leading to the radiation utilization bodies are arranged on the edge surfaces of the hollow cube.