DE19826548A1 - Lighting arrangement - Google Patents

Abstract

The present invention relates to a lighting fixture (2) comprising a base body (4) in which profiled bodies (5) are formed from a translucent material and are spaced apart by cavities (6). Each of the profiled bodies (5) bears a luminous member (7) for diffusing light in the corresponding profiled body (5). The light is further transmitted internally from the profiled body (5) to an emission surface of the base body (4), wherein said light reaches the emission surface according with a maximal range of radiation angle so as to prevent an observer from being dazzled. The luminous member (7) used in this invention can be a flat fluorescent tube.

Description

The present invention relates to a lighting arrangement according to the preamble of Claim 1, in particular a lighting arrangement in lights, screens etc. can be used.

Lighting arrangements of the type described in the preamble of claim 1 used for example as luminaire covers. It is already known Covers with trained on the side facing a lamp of the lamp and protruding profile bodies for light control of the light of the lamp used to reduce the beam angle of light rays to reduce glare limit a viewer. GB-A-1365507 proposes the Form profile body in the form of truncated pyramids, which of the base body protrude from the cover, the upper boundary surfaces of the truncated pyramids are coated with an opaque material. In US-A-3,351,753 also a cover with the form of truncated pyramids Profiled bodies proposed, but in this case the side surfaces of the Truncated pyramids and the spaces between the truncated pyramids with a opaque material are coated.

A suitable light control is achieved by these known covers limit the beam angle of the light rays: due to the opaque Areas of the cover, however, reduce the efficiency of the lamp. In the AT A-301/87 was therefore a cover for lights with pyramid-like Profiled bodies proposed on the side of the lamp facing the lamp Base body of the cover are arranged in a matrix and one to the emission surface the cover have parallel upper boundary surface, the entire cover is made of a crystal-clear material.

The individual glass profile bodies of this cover known from AT-A-301/87 are designed so that the lamp of the lamp on the upper boundary surface the individual profile body emitted light from the profile bodies to the emission surface the coverage is forwarded and there within a predetermined maximum Beam angle range is emitted. However, since this form of covers preferably used in conjunction with elongated fluorescent lamps Coupling the light emitted by the lamp used in the glass profile body Cover problems because the lamp naturally doesn't just cover the top Boundary surfaces of the individual profile bodies, but also the (translucent)  Side flanks of the truncated pyramid-shaped profile bodies are irradiated with light. However, this means that the desired maximum radiation angle to avoid the Glare to a viewer can not be easily complied with because of the Light emitted not only inside the individual profile body to the lamp Emission area of the cover directed, but also on the side surfaces of the Profile body is reflected or broken.

The present invention is therefore based on the object Lighting arrangement with profile bodies formed in a base body create, on the one hand, the previously described light coupling into the individual Profile body facilitated and on the other hand a high optical efficiency, preferably with sufficient glare control.

This object is achieved according to the present invention by a lighting arrangement solved with the features of claim 1. The sub-claims describe preferred Embodiments of the present invention, which in turn to a possible rational and serial producibility of the invention Lighting arrangement or the best possible optical efficiency with contribute to the best possible glare control.

According to the present invention, the is on each profile body lighting arrangement according to the invention (in particular on the upper Boundary surface of each profile body) a light means attached, which light in radiates the corresponding profile body. The profile body consist of a translucent material and conduct inside that emitted by the light means Light towards the emission surface of the lighting arrangement, where the light of the light means is emitted. The individual profile bodies are preferably designed such that the lighting arrangement at any point its emission area the light the light means within a predetermined maximum radiation angle range of for example, 60 ° -70 ° to dazzle a viewer from being too flat to avoid emitted light.

The individual profile bodies can, for example, be truncated pyramids or oblong in Be formed in the form of strips. A diffuse light source, for example luminous layer of organic or inorganic semiconductor materials in question, wherein in these semiconductor materials by applying an electrical voltage Electroluminescence is excited.  

The profile body of the lighting arrangement according to the invention are in the Main body of the cover formed recesses separated from each other, these Wells can be particularly V-shaped. The flanks of these depressions or the side flanks of the profile body can be straight or curved. Advantageously the side flanks of the profile body are mirrored on their inside, so that the light is completely reflected within the profile body. The same effect can be achieved by a Design of the individual profile body can be achieved in such a way that depending on the Refractive index of the profile body the light on the inside of the side flanks Profile body only falls under a totally reflective angle.

According to a preferred embodiment, the individual profile bodies are in one Film formed, which is attached to a support of a lamp, in particular is stuck on.

The advantage of the present invention is that the profile body applied light means the light source for the corresponding lighting arrangement represent. Are the light means in the form of luminescent layers, can accordingly, a very flat lighting arrangement can be realized. Since the Light means are applied directly to the profile body occurs in the invention Lighting arrangement in practice the problem of Coupling of light does not occur. Since a lamp with the invention Lighting arrangement without lamp and without lamp holders is not Lamp change required. Such a lamp has depending on the used light sources have a long service life.

The lighting arrangement according to the invention can in particular in combination with one or more flat fluorescent lamps are used as light sources serve and rest directly on the upper boundary surfaces of the profile body. On in this way the advantages of the present invention described above can be combined with the Advantages of such fluorescent lamps, such as. B. flat design and consistently high Luminance, can be combined.

The invention is explained in more detail below on the basis of preferred exemplary embodiments described.

Fig. 1 is a perspective view schematically shows a luminaire with an inventive illumination arrangement in the form of a cover,

FIGS. 2a and 2b show cross-sectional views of the lighting arrangement according to a first and second embodiment of the present invention,

Fig. 3 shows a perspective view of a preferred embodiment of the illumination assembly of the present invention, wherein 3 show two different variants are shown in Fig.

FIGS. 4a and 4b are enlarged views of a profile body of the lighting arrangements shown in Fig. 2a and 2b for illustrating the beam path within this profile body, and

FIGS. 5a and 5b show cross-sectional views of the lighting arrangement according to a third and fourth embodiment of the present invention.

Fig. 1 showed a perspective view of an elongate luminaire, in which the lighting arrangement of the invention is used as a cover. As can be seen from FIG. 1, a lighting arrangement or cover 2 is held in a housing 9 in the luminaire 1 in such a way that the emission surface of the cover 2 is directed downward. The emission surface of the cover 2 is preferably flat. The cover 2 and the profile bodies formed therein (and not visible in FIG. 1) are designed such that light is emitted from the emission surface of the cover 2 at any point P only within a certain maximum radiation angle (cut-off angle) γ _max . The emerging light beams accordingly limit a cone jacket 3 . The relationships shown in FIG. 1 with respect to point P apply analogously to all other points on the emission surface of the lamp cover 2 .

Fig. 3 showed a top perspective view of a preferred embodiment of a lighting arrangement or cover 2 of the invention. More specifically, Fig. 3 shows a plan view of the side facing the luminaire housing surface of the cover 2. The cover 2 has a plurality of profile bodies 5 which are formed on or in a base body 4 of the cover 2 . The individual profile bodies 5 are spaced apart from one another by depressions 6 . As shown in FIG. 3, the profile bodies 5 can have the shape of truncated pyramids or elongated strips, for example. If the profile bodies 5 are designed in the form of truncated pyramids, the profile bodies 5 can be arranged evenly in rows and rows, ie in a matrix-like manner, so that the depressions 6 form a grid between the individual truncated pyramids 5 . If the profile bodies 5 are strip-shaped, they are preferably arranged parallel to one another, so that the recesses arranged between them also run parallel to one another.

FIGS. 2a and 2b show exemplary cross-sectional views of the illumination arrangement according to the invention along the illustrated in Fig. 3 dash-dotted line. The side flanks of the individual profile bodies are designed differently in FIGS. 2a and 2b.

The exemplary embodiments shown in FIGS. 2a and 2b have in common that the individual profile bodies 5 are separated by recesses 6 which run essentially in a V-shape. The side flanks of the individual profile bodies 5 drop relatively steeply. On the underside of the base body 4 , which represents the emission surface of the cover 2 , there is an essentially plane-parallel section which essentially does not influence the beam path and is formed in that the individual V-shaped incisions 6 are not completely up to the underside of the base body 4 can be pulled.

The profile body 5 are preferably made in one piece with the base body 4 from a translucent material. The entire base body 4 including the profile body 5 can be made of acrylic glass, for example. Advantageously, however, the base body 4 can also be designed in the form of a translucent plastic film in which the individual profile bodies 5 are designed analogously to the known glass profile body embodiment. This plastic film is then simply attached to a rectangular support of the lamp, for example glued on. The use of the plastic material makes it easier to manufacture the base body 4 and to form the profile body 5 in the base body 4 .

According to the present invention, a light means 7 is now attached to each profile body 5 . The light means 7 is preferably formed by a relatively thin luminescent layer which is applied directly to the upper boundary surface of each profile body 5 and can have a thickness of <1 mm. Each light means 7 emits light directly into the interior of the corresponding profile body 5 . The profile bodies 5 are preferably designed such that the light is completely reflected on the inside of their side flanks and is guided to the underside of the base body 4 , ie to the emission surface of the cover 2 . Furthermore, the individual profile bodies 5 fulfill geometrical framework conditions in order to be able to maintain the maximum radiation angle γ _max shown in FIG. 1. The luminous layer 7 can, for example, consist of an inorganic or organic semiconductor material and can be applied to the individual profile bodies 5 by screen printing.

As shown in Fig. 2a, the side flanks of the profile body 5 or the V-shaped recesses 6 can run straight. Instead, however, the curved or curved course of these side flanks shown in FIG. 2b is also possible.

As has already been mentioned, organic or inorganic semiconductor materials, for example, can be used as light means 7 for the profile bodies 5 shown in FIGS . 2a and 2b. Depending on the material used, these materials are made to glow by applying a direct or alternating voltage (electroluminescence). Corresponding electroluminescent foils or plates are already known.

For example, the light means 7 can be formed by an electroluminescent luminescent layer with luminescent crystals arranged in a dielectric, electrical saving being applied to the luminescent layer via ITO electrodes (indium tin oxide) to excite the electroluminescence. Such electroluminescent luminescent layers can have a thickness of <1 mm. Furthermore, a polymer film can be used as the luminescent layer, to which an electrical voltage is likewise applied via ITO electrodes. When the electrical voltage is applied, positive charge carriers (holes) and negative charge carriers (electrons) are injected, these different charge carriers recombining while emitting light beams. The polymer film can for example consist of PPV and have a thickness of <1 µm. An arrangement of light-emitting layers arranged one above the other can also be used as the luminescent layer, each of which emits light of different wavelengths, so that overall white light is emitted by the luminescent layer. In general, according to the present invention, light means which emit diffuse light are preferably used.

As has already been explained above, the individual profile bodies must adhere to certain geometric framework conditions, so that - as shown in FIG. 1 - 2 light beams from the emission surface of the lighting arrangement or cover to avoid glare to an observer only in the range 0 ° <γ _max be emitted. These geometric conditions are the material of the profile body 5 as well as the selected maximum beam angle (off angle) γ _max depends in particular on the refractive index of the optical means shown in Fig. 2 2, the index of refraction. An angle of 60 ° is preferably selected as the maximum radiation angle γ _max . In general, however, maximum radiation angles γ _max in the range 60 ° -70 ° are sufficient.

The geometrical framework conditions for the profile body used in each case are to be explained in more detail below with reference to FIGS. 4a and 4b. FIGS. 4a and 4b show 2D projections in FIGS. 2a and 2b profile body 5 shown applied thereon with phosphor layers 7.

As shown in FIG. 4a, light rays are emitted from the luminescent layer 7 into the interior of the corresponding profile body 5 . These rays can leave the profile body 5 without reflection on the side flanks 8 of the profile body 5 , which is indicated in FIG. 4a by the left beam path. However, it is also possible that certain light rays emitted by the luminescent layer 7 are reflected on a side flank 8 of the profile body 5 and only then emitted on the underside of the profile body 5 , which is indicated in FIG. 4a by the right beam path. In any case, the light rays emitted by the luminous layer 7 are refracted twice, namely once at the interface between the luminous layer 7 and the profile body 5 and a second time at the underside of the profile body 5 when the light rays leave the profile body 5 and are emitted again . It is assumed below that n _L denotes the refractive index of the luminous layer 7 and n _S the refractive index of the structure block or profile body 5 .

The light control within the profile body 5 or the light emission from the profile body 5 should essentially meet two conditions. Firstly, no emitted from the light emitting layer 7 in the profiled element 5 light beam is to be broken out of the profile body 5 side, ie the light beams of the light-emitting layer 7 are either emerge or without reflection at the side edges 8 of the profile body 5 at the bottom of the profile body 5 but at the Side flanks 8 of the profile body 5 are totally reflected. Furthermore, no light beam should leave the lower surface of the profile body 5 at an angle that is greater than a desired maximum radiation or cut-off angle γ _max . Advantageously, this maximum radiation angle γ _{max is} 60 °, in order to achieve optimal glare control, for example when using the lighting arrangement for room lighting.

As has already been explained above, the light beams emitted by the luminous layer 7 are refracted upon transition into the profile body 5 depending on the refractive index n _{L of} the luminous layer 7 and the refractive index n _{S of} the structure block or profile body 5 . According to the law of refraction, there is the following relationship between the angle of incidence β and the angle of reflection δ:

In general, light rays are refracted towards the solder when transitioning into an optically denser medium, while the light rays are refracted away from the solder during transition into an optically thinner medium. In the present case, this means that the light beams emitted by the luminous layer 7 for n _S <n _L are refracted into the structure block or profile body 5 , ie towards the solder, while the light beams for n _S <n _{L are} refracted away from the solder will.

If n _S <n _L , from a certain maximum angle of incidence β _{max there is} a total reflection of the light beam emitted by the luminous layer 7 at the interface with the profile body 5 , where:

This means that in this case, rays impinging on the boundary layer to the profile body 5 , which include an angle of incidence between β _max and 90 ° to the solder, are totally reflected.

Accordingly, the angle δ can have the following maximum value according to the formula (1):

Of course, the above considerations also apply to the refraction of the light rays on the underside of the profile body 5 , but in this case it must be taken into account that n = 1 applies to the refractive index n of the air.

As has already been explained above, light rays incident on the inner surfaces of the side flanks 8 of the profile body 5 are to be totally reflected. This can be achieved, for example, by (opaque) mirroring of the inner surfaces of the side flanks 8 , so that no light rays can be broken out of the profile body 8 laterally. Instead, however, a total reflection analogous to the formula (2) given above can be achieved if it is ensured that the light rays strike the side faces 8 at an angle s at which, according to the law of reflection, the light rays are completely in the optically denser profile body 5 are reflected, ie the light rays must strike at an angle ε <ε _min , where:

Depending on the previously explained requirements, the geometric dimensions of the profile body 5 shown in FIGS. 4a and 4b can now be calculated, these dimensions being dependent in particular on the predetermined refractive indices n _L and n _S and the desired maximum masking angle β _max . In this case, according to Fig. 4a and 4b assumed that the structural element or of the profile body 5 is arranged symmetrically with respect to the y-axis and the x-axis 5 forms the underside of the profile body. Furthermore, the profile body 5 is designed in such a way that the side flanks 8 are inclined outwards from top to bottom. In the following, y _h denotes the height of the profile body 5 , 2x _i the width of the upper boundary surface and 2x _a the width of the lower boundary surface of the profile body 5 .

With regard to the profile body shape shown in FIG. 4 a, in addition to the values for x _i , x _a and y _h , the inclination angle α of the side flanks 8 of the profile body 5 is of particular interest. Due to the desired total reflection on the side flanks 8 of the profile body 5 , the following condition for the angle of inclination α results from evaluating the known relationships specified above:

Since the light rays not reflected in the profile body 5 from the side flanks 8 should emerge on the underside at a maximum with the predetermined angle γ _max , the following relationships also result:

A suitable inclination angle α can be determined from the formulas (5) - (7) and a desired value x _{i can be} specified. Depending on this, the height y _{h of} the profile body 5 can finally be determined according to the following equation:

In principle, the same procedure is possible for the profile body profile shown in FIG. 4b. However, due to the curved shape of the side flanks 8 of the profile body 5, it is assumed that the side flanks 8 run according to a predetermined function f (x), ie the following applies:

y = f (x) for all | x | <x _i (9).

It is assumed in the following that suitable values for x _i and y _h are specified in addition to the course f (x) and that only the value x _{a is} to be determined as a function thereof.

The following condition results from the requirement regarding total reflection on the side flanks 8 of the profile body 5 :

The following conditions result for the anti-glare conditions of the light beams reflected on the side flanks 8 of the profile body 5 :

Finally, the following conditions result for the anti-glare conditions with regard to the light rays passing through the profile body 5 without reflection on the side flanks 8 :

Depending on the predefined values for x _i and y _h , the likewise predefined function f (x) for all x is now | x | <x _i under consideration of the conditions (10) - (12) given above until a value for x _{a is} found which fulfills the condition according to formula (13).

Fig. 5a and Fig. 5b show further embodiments of the present invention, wherein a flat fluorescent lamp is used as light source or light means 7.

Flat fluorescent lamps are the latest developments in the area of panel spotlights. With reference to FIG. 5a, such flat fluorescent lamps comprise a body 11 made of a translucent or transparent material, in particular a glass body, the interior 9 of which is filled with a certain gas, e.g. B. Xenon is filled. Into the glass body 2 arranged electrodes 10 is applied a suitable voltage U _0, which excites the gas molecules in the inner space 9 of the glass body. 2 When these excited gas molecules decay, a short-wave UV radiation arises, which is converted into visible light and emitted with the aid of a corresponding phosphor 15 , with which the emission surface of the glass body 2 is coated. The efficiency of the radiation generation can also be improved in that an insulation 13 is arranged between the discharge or interior 9 of the glass body 2 and at least one of the electrodes 10 and / or a specifically selected pulsed voltage U _{0 is} applied.

Such fluorescent lamps can because of their flat design and their uniform and high luminance in different areas of application Use, especially as a backlight for (LCD) screens.

According to an embodiment of the present invention, it is provided that at least one such flat fluorescent lamp is used as the light means 7 for the profile body 5 of the lighting arrangement 2 . In particular, a correspondingly small flat fluorescent lamp 7 can be applied to the upper boundary surface of a profile body 5 . For clarity, however, 5b embodiments are shown in Fig. 5a and Fig. Shown, wherein such flat fluorescent lamp as a common light emitting means 7 is used for a plurality of profile-members 5 and is arranged directly on the upper boundary surfaces of the corresponding profile body 5.

As shown in FIG. 5 a, the glass block grid structure according to the invention (cf. FIG. 3) with a base body 4 made of a translucent material and several (for example pyramid-like) profile bodies 4 formed in the base body 4 , which are spaced apart from one another by depressions 6 , arranged directly behind the emission or light exit surface of the flat fluorescent lamp 7 . In order to solve the problem of light incident laterally on the side flanks of the profile body 5 , the fluorescent layer 15 attached in the glass body 11 of the flat fluorescent lamp 7 corresponding to the recesses 6 between the profile bodies is provided in accordance with the embodiment shown in FIG. 5a to interrupt that the light emitted by the fluorescent lamp from the fluorescent layer 15 is converted into visible light and emitted only at those areas where the upper boundary surfaces of the profile body 5 abut the emission surface of the fluorescent lamp 7 . This can be achieved, for example, by attaching a grid-like, opaque layer 12 to the emission surface of the glass body 11 , in particular by gluing or printing, so that the upper boundary surfaces of the profile body 5 cover the spaces between the grid made of the aforementioned opaque material 12 and lie directly on the emission surface of the glass body 11 . In this way it is ensured that the visible light emitted by the phosphor layer can only enter the upper boundary surfaces of the profile body 5 .

The efficiency of the lighting arrangement 2 can be further improved by coating the entire light exit surface of the flat fluorescent lamp 7 with a material which is known to the person skilled in the art and which reflects UV light. A corresponding lighting arrangement is shown in FIG. 5b, wherein this layer 14 , which reflects the UV light, is arranged in particular between the phosphor layer 15 and the light exit or emission surface of the flat fluorescent lamp 7 . Otherwise, the structure of the lighting arrangement shown in FIG. 5b corresponds to that of the lighting arrangement shown in FIG. 5a.

The embodiments shown in Fig. 5a and Fig. 5b can also be modified such that the glass body 11 of the flat fluorescent lamp 7 is formed in the area of the light outlet in such a way that it itself has the structure of the glass block grid, ie the profile body 5 (and the base body 4 ) are formed in one piece with the glass body 2 of the flat fluorescent lamp 7 in this case.

The profile bodies 4 of the exemplary embodiments shown in FIGS . 5a and 5b also advantageously have the properties already explained above with regard to the most effective light control and glare control.

In addition to the above, it should be noted that the lighting arrangement according to the invention can be used, for example, for backlighting screens, and the efficiency and glare reduction can be improved in particular by assigning a profile body 4 to each pixel or pixel of the screen.

Furthermore, the profile body 5 can also be designed, for example, in such a way that its "glare-free angle" γ _{max is} 90 °, in which case it can be ensured that the entire radiation can emerge from the envelope surrounding the corresponding light means 7 in order to increase the efficiency increase. This applies in particular to light means 7 in the form of electroluminescent lamps, the substrate of which is applied to glass plates as a carrier material, since in such electroluminescent lamps up to 50% of the light radiation generated usually enters the glass plates so flat that it can no longer escape due to total reflection.

Finally, the lighting arrangement according to the invention can also be used, for example, in signal systems or their signal lights, such as, for. B. traffic lights or brake lights are used, in which case the profile body 5 should be designed to protect road users, etc., such that their glare angle γ is _max 30 °.

Claims (31)

1. Lighting arrangement ( 2 ), with light means ( 7 ) for emitting light, with a base body ( 4 ), and with in the base body ( 4 ) formed profile bodies ( 5 ) made of a translucent material, which are spaced apart by depressions ( 6 ) and direct the light emitted by the light means ( 7 ) to an emission surface of the base body ( 4 ) and emit it there, characterized in that on each profile body ( 5 ) there is a light means ( 7 ) which emits light into the corresponding profile body ( 5 ) emits. 2. Lighting arrangement according to claim 1, characterized in that the light means ( 7 ) emits diffuse light in the corresponding profile body ( 5 ). 3. Lighting arrangement according to claim 1 or 2, characterized in that each light means ( 7 ) in the form of a luminescent layer is applied to the upper boundary surface of the corresponding profile body ( 5 ). 4. Lighting arrangement according to claim 3, characterized in that each luminescent layer ( 7 ) has a thickness <1 mm. 5. Lighting arrangement according to one of the preceding claims, characterized in that the light means ( 7 ) are designed such that they emit light when an electrical voltage is applied. 6. Lighting arrangement according to claim 5, characterized in that the light means ( 7 ) have an organic or inorganic semiconductor material as the light-emitting material. 7. Lighting arrangement according to claim 6, characterized in that the light means ( 7 ) have a polymer material as the light-emitting material. 8. Lighting arrangement according to claim 1 or 2, characterized in that the light means ( 7 ) comprise at least one flat fluorescent lamp which is arranged on the upper boundary surface of the profile body ( 5 ). 9. Lighting arrangement according to claim 8, characterized in that a flat fluorescent lamp is arranged as light means ( 7 ) on each profile body ( 5 ). 10. Lighting arrangement according to claim 8 or 9, characterized in that the flat fluorescent lamp ( 7 ) has a body ( 11 ) with a light emission surface, which comprises an interior filled with certain gas molecules ( 9 ), in which the gas molecules by applying an electrical voltage Can be excited and release UV radiation when they decay, and that the flat fluorescent lamp ( 7 ) has a fluorescent layer ( 15 ) arranged adjacent to the light emission surface, which converts the UV radiation released when the gas molecules decay into visible light, so that the visible light is emitted through the light emission surface in the corresponding profile body ( 5 ). 11. Lighting arrangement according to claim 8 and 10, characterized in that the flat fluorescent lamp as a common light means ( 7 ) on the upper boundary surface of a plurality of profile body ( 5 ) is attached, and that light limiting means ( 12 ) are provided to the emission of visible light from ensure the phosphor layer ( 15 ) only in the corresponding profile body ( 5 ). 12. Lighting arrangement according to claim 11, characterized in that the light limiting means on the light emission surface of the flat fluorescent lamp ( 7 ) arranged opaque layer ( 12 ) with light outlet openings, the light outlet openings being arranged such that each light outlet opening is covered by a corresponding profile body. 13. Lighting arrangement according to one of claims 10-12, characterized in that the light emission surface of the flat fluorescent lamp ( 7 ) has the profile body ( 5 ), wherein the profile body ( 5 ) are integrally formed with the light emission surface. 14. Lighting arrangement according to one of claims 10-13, characterized in that a UV light reflecting layer ( 14 ) is arranged between the phosphor layer ( 15 ) and the light emission surface of the flat fluorescent lamp ( 7 ). 15. Lighting arrangement according to one of the preceding claims, characterized in that the profile body ( 5 ) are elongated in the form of strips and parallel to each other. 16. Lighting arrangement according to one of claims 1-14, characterized in that the profile body ( 5 ) in the form of a truncated pyramid and are arranged such that they are spaced apart from one another by lattice-like recesses ( 6 ). 17. Lighting arrangement according to one of the preceding claims, characterized in that the depressions ( 6 ) between the profile bodies ( 5 ) are substantially V-shaped. 18. Lighting arrangement according to one of the preceding claims, characterized in that the profile body ( 5 ) have lateral flanks ( 8 ) which extend from the respective light means ( 7 ) to the base body ( 4 ) inclined outwards. 19. Lighting arrangement according to claim 18, characterized in that the lateral flanks ( 8 ) are straight or curved. 20. Lighting arrangement according to claim 18 or 19, characterized in that each profile body ( 5 ) is designed such that the light emitted into its interior of the corresponding light means ( 7 ) is completely reflected within the profile body ( 5 ) on the side flanks ( 8 ) becomes. 21. Lighting arrangement according to claim 20, characterized in that the side flanks ( 8 ) of each profile body ( 5 ) are mirrored on their inside opaque. 22. Lighting arrangement according to one of the preceding claims, characterized in that the profile body (5) emit light from the light means (7) via a substantially flat emission surface of the base body (5). 23. Lighting arrangement according to claim 22, characterized in that the profile body ( 5 ) are designed such that they emit the light of the light means ( 7 ) within a certain maximum radiation angle range (γ _max ) with respect to the surface normal of the emission surface of the base body ( 4 ). 24. Lighting arrangement according to claim 23, characterized in that the maximum radiation angle (γ _max ) is 60 ° to 70 ° with respect to the surface normal of the emission surface of the base body ( 4 ). 25. Lighting arrangement according to claim 23, characterized in that the maximum radiation angle (γ _max ) is 90 ° with respect to the surface normal of the emission surface of the base body ( 4 ). 26. Lighting arrangement according to claim 23, characterized in that the maximum radiation angle (γ _max ) is 30 ° with respect to the surface normal of the emission surface of the base body ( 4 ). 27. Lighting arrangement according to one of the preceding claims, characterized in that the base body ( 4 ) is formed by a plastic film made of translucent material. 28. Use of a lighting arrangement ( 2 ) according to one of the preceding claims in a luminaire ( 1 ), the luminaire having a housing ( 9 ) which holds the lighting arrangement ( 2 ), the base body ( 4 ) also serving as a cover for the luminaire ( 1 ), and the light means ( 7 ) attached to the profile bodies ( 5 ) of the lighting arrangement ( 2 ) serve as the light source of the lamp ( 1 ). 29. Use of a lighting arrangement ( 2 ) according to one of the preceding claims in a screen, the lighting arrangement serving to illuminate the screen. 30. Use according to claim 29, characterized in that each profile body ( 5 ) of the lighting arrangement ( 2 ) is assigned to a pixel of the screen. 31. Use of a lighting arrangement ( 2 ) according to one of the preceding claims in a signal lamp, the light means ( 7 ) attached to the profile bodies ( 5 ) of the lighting arrangement ( 2 ) serving as the light source of the signal lamp ( 1 ), and wherein the profile body ( 5 ) of the lighting arrangement are designed such that they emit the light within a specific maximum radiation angle range (γ _max ) of 30 ° with respect to the surface normal of the emission surface of the base body ( 4 ) of the lighting arrangement ( 2 ).