DE20310475U1 - A lighting device has main and secondary reflectors with the lamp partly projecting into the main reflector to reduce height - Google Patents

Abstract

A lighting device comprises an electrically lit medium, main reflector (3) through which the light (2) partly projects (4) and a rotationally symmetric concave secondary reflector (5). Preferably a shield tube partly surrounds the light.

Description

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Lighting device

The present invention relates to a lighting device with an electric light source, a primary reflector, an approximately rotationally symmetrical, concave secondary reflector and preferably a blanking tube partially surrounding the electric light source.

Such lighting devices, which are available on the market in a wide variety of designs, have the advantage over older lighting devices having a single concave reflector that the primary reflector prevents direct view into the light source without causing a significant deterioration in the efficiency of the lighting device, as would be the case, for example, with a non-reflective masking of the light source.

What is problematic in this context is that the arrangement of the primary reflector beneath the electric lamp inserted into a socket results in a relatively large overall height of the lighting device compared to its horizontal dimension.

The object of the invention is to provide a generic lighting device according to the preamble of claim 1 with favorable lighting properties and a compact design.

This is achieved according to the invention in that the preferably flat primary reflector has an opening into which the electric light source partially projects.

The technical and economic advantage of the lighting device according to the invention is the versatility resulting from the low construction height. The height of the lighting device is essentially determined by the height of the vertically arranged electrical light source including the socket.

An advantageous embodiment of the invention results from the fact that the height of the lighting device is a maximum of 1/3 of the diameter of its approximately circular underside. This allows, for example, the lighting device according to the invention to be installed flush in false ceilings with a small vertical distance from the room height, as can be found in many public buildings.

A further advantageous embodiment of the invention results from the fact that the electric light source is approximately rod-shaped. Compared to a bulb-shaped light source, for example, this has the advantage that a smaller opening is required on the primary reflector. The rod-shaped light source is advantageously conductively contacted at one end by a socket and protrudes with the other, free rod end partially into the opening of the primary reflector.

A further advantageous embodiment of the invention results from the fact that the lighting device has a blanking tube that partially bypasses the electric lamp and the light-emitting area of the electric lamp is arranged outside the blanking tube and outside the primary reflector. This prevents a view of all areas of the electric lamp that do not emit light.

In a further advantageous embodiment of the invention, the secondary reflector consists of exactly one convergent inner region near the socket and exactly one convergent outer region, the curvature of which is different, with a defocusing region, for example in the form of a dome-shaped facet band or a roughened surface, being arranged between the inner and outer regions of the secondary reflector. The inner region reflects the incident light in the form of convergent spread radiation, while the outer region reflects convergent cross radiation. By illuminating the entire radiation region twice, a very uniform, structureless illumination without color images on the working plane can be achieved. The radiation that occurs from the electric light source between the inner and outer regions on the secondary reflector is reflected almost perpendicularly onto the working plane. To avoid over-illumination (center tip), which is undesirable in terms of lighting technology, parallel incident rays are widened by the defocusing region, for example by about 2 x 20 degrees. If the defocusing area is designed in the form of domes, these can be machined into the printing tool for the secondary reflector without gaps using a specially made milling cutter. Depending on the design of the secondary reflector, the defocusing area could also be located entirely in its inner or outer area, at least where incident radiation emerges from the underside of the lighting device at approximately a right angle after being reflected from the defocusing area.

A further advantageous embodiment of the invention results from the fact that the lighting device is only translucent in a circular ring-shaped area on its approximately circular underside. This allows an aesthetically pleasing and technically advantageous illumination of the usable area. The circular ring-shaped area is advantageously provided with a UV filter glass pane. An embodiment of the invention in which the width of the circular ring-shaped translucent area is less than 1/4, preferably about 1/6, of the diameter of the circular underside of the lighting device is extremely aesthetically pleasing and technically advantageous.

The lighting device advantageously has a blanking tube which partially surrounds the electric lamp and partially blanks the electric lamp. The blanking of the electric lamp advantageously takes place over an angular range of approximately 0 degrees to approximately 50 degrees, in a coordinate system with the vertical longitudinal axis of the electric lamp as the Z axis and the center of the light-emitting area as the coordinate origin. The inner end of the lamp arranged in a socket is therefore at approximately φ = 0 degrees and the free, outer end at approximately φ = 180 degrees. As a result, the inner part of the lamp in the area of the socket is blanked out, while only a small part of the emitted light is lost.

A further advantageous embodiment of the invention results from the primary reflector blocking the electric lamp in an angle range of approximately 130 degrees to approximately 180 degrees, starting from the vertical longitudinal axis of the electric lamp in the area of the socket. This blocks out the outer area of the electric lamp, whereby again only a fraction of the radiation emitted by the electric lamp is lost.

A further advantageous embodiment of the invention results from the fact that rays emanating from the electric light source in an angle range of approximately 50 degrees to approximately 100 degrees, starting from the vertical longitudinal axis of the electric light source in the area of the socket, emerge from the lighting device through the light-permeable area after a single reflection on the secondary reflector. As a result, the majority of the radiation emitted by the light source is available for illuminating the usable area, which results in an economically advantageous high level of efficiency. In a further advantageous embodiment of the invention, rays emanating from the electric light source in an angle range of approximately 100 degrees to approximately 130 degrees measured from the vertical longitudinal axis of the electric light source, emerge from the lighting device through the light-permeable area after a single reflection.

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at the primary reflector and subsequent single reflection at the secondary reflector through the light-permeable area of the lighting device. This leads to a further increase in the efficiency of the lighting device according to the invention.

A further advantageous embodiment of the invention results from the fact that rays emanating from the electric light source in an angle range of approximately 70 degrees to approximately 80 degrees, starting from the vertical longitudinal axis of the electric light source in the area of the socket, emerge from the lighting device through the translucent area after a single reflection at the defocusing area. This prevents the center peak mentioned at the beginning, which results in a luminance on the usable area that is advantageous in terms of lighting technology. A further advantageous embodiment of the invention results from the fact that from an angle of reflection γ > 50 degrees to the vertical longitudinal axis, the luminance is less than 1000 cd/m ^2. This makes the lighting device according to the invention particularly suitable for office use, although according to the standard this value only has to be met from γ = 65 degrees.

Further advantages and details of the invention are explained in more detail with reference to the following description of the figures.

Fig. 1 is a vertical central section through an embodiment of a

lighting device according to the invention,

Fig. 2a, 2b, 2c Paths of light rays in embodiments of an inventive

appropriate lighting device and

Fig. 3 shows the light distribution curve of an embodiment of a

lighting device according to the invention.

Fig. 1 shows a lighting device 1 according to the invention with an electric light source 2, a primary reflector 3, which has an opening 4, a secondary reflector 5 with an inner region 6 and an outer region 7. A defocusing region 8 is arranged between the two regions 6, 7. The rod-shaped electric light source 2 (in the exemplary embodiment a halogen incandescent lamp or metal halide lamp) is partially blocked out by a blocking tube 9. The inner end 14 of the light source is inserted into a socket 13, whereby a conductive connection is established with a voltage source (not shown). The outer end 15 of the electric light source 2 partially projects into an opening 4 arranged on the primary reflector 3. The electric light source 2 is thus completely blocked out except for its light-emitting region 16.

hidden. The underside 10 of the lighting device 1 is only translucent in a circular ring-shaped region 11 over a width R ₂ -Ri, which can be covered by a clear UV filter. The lighting device 1 according to the invention is attached to a ceiling 20 by means not shown in detail. It can be seen that the height H of the lighting device 1 is approximately the same as the height H _L m + H _F of the electrical lamp 2 arranged vertically along the longitudinal axis 12 including the socket 13. The ratio between the height H of the lighting device 1 and the diameter D of its approximately circular underside 10 is approximately 1/3.

Fig. 2a shows the course of selected rays based on the cross section according to Fig. 1, whereby for reasons of clarity, the designation of the structural parts of the lighting device 1 already explained in Fig. 1 has been omitted. It can be seen that rays which emanate from the lighting device 2 at an angle Cp ₁ = 45 degrees measured in a coordinate system with the origin in the center of the light-emitting region 16 of the electrical lighting device 2, where the angle φ = 0 degrees corresponds to the vertical longitudinal axis Z, emerge from the lighting device 1 after being reflected once at the inner region 11 of the secondary reflector 5 through the translucent region 11 on the underside 10 of the lighting device 1. Rays which emanate from the electrical lighting device 2 at an angle φ ₂ = 98 degrees emerge from the lighting device 1 according to the invention after being reflected once at the outer region 7 of the secondary reflector 5 through the translucent region 11 on the underside 10 of the lighting device 1. Thus, all rays in an angular range Δφ ₂ = cp ₂ -cpi emerge from the lighting device 1 after a single reflection at the secondary reflector 5. Furthermore, it can be seen that rays with an angle greater than cp ₃ = 135 degrees up to an angle φ ₄ = 180 degrees enter the interior of the primary reflector 3 and thus cannot emerge from the lighting device 1 according to the invention. This results in the electrical lighting means 2 being blocked out in an angular range Δφ ₄ = φ ₄ -φ ₃ by the primary reflector 3.

Fig. 2b shows that light rays which emanate from the electric light source 2 in an angular range Δφ ₁ = φ 1 - φ ₀ are blocked by the blocking tube 9. It can also be seen that light rays with an angle between φ ₂ and φ ₃ emerge from the lighting device 1 through the translucent region 11 on the underside 10 of the lighting device 1 after being reflected once on the primary reflector 3 and once on the secondary reflector 5. This applies to all rays in an angular range Δφ ₃ = φ ₃ -φ ₂ .

Fig. 2c shows that light rays which emerge from the light source 2 at an angle between approximately φ ₅₂ = 80 degrees and approximately cp ₅₁ = 73 degrees emerge from the light device 1 approximately perpendicularly to the underside 10 of the light device 1 after being reflected once at the defocusing region 8. The exit angle γ is defined as the angle between the emerging rays and an axis 21 perpendicular to the underside 10 of the light device 1. The defocusing region 8 has the task of expanding the rays striking it to a certain angular range, for example 2 × 20 degrees, and thus preventing an undesirably high light intensity for small angles γ. Otherwise, a radiation concentration in the center (γ -> 0 degrees) would result, which would lead to very high illuminances. The defocusing region 10 is designed in a manner known per se, for example as a dome facet band or as a roughened region.

The lighting device 1 according to the invention has, in addition to the attractive design of a narrow light exit opening and the advantageous technical feature of a very low construction height, which results in versatile use, excellent lighting properties. As can be seen from Fig. 2a, 2b, 2c, the inner region 6 of the secondary reflector 5 provides a convergent spread radiation and the outer region 7 of the secondary reflector 5 provides a convergent cross radiation. By illuminating the entire radiation area twice, it is possible to achieve very uniform lighting without color images or undesirable images of the light source 2 on the working plane. The light distribution is also rotationally symmetrical and has a hundredth angle of approximately 2 x 50 degrees. From an angle γ > 50 degrees, the luminance of the lighting device 1 is below 1000 cd/m ² , as can be seen from Fig. 3. According to the legal regulations on the use of lighting devices in the workplace, this value only has to be complied with from an angle γ > 65 degrees. Also evident is the absence of a so-called center peak of the light distribution curve at an angle γ « 0 degrees.

In all figures and in the figure description, the representation or description of construction details that are familiar to the expert has been omitted.

Claims (15)

1. Lighting device with an electric lamp, a primary reflector, an approximately rotationally symmetrical, concave secondary reflector and preferably a blanking tube partially surrounding the electric lamp, characterized in that the preferably flat primary reflector ( 3 ) has an opening ( 4 ) into which the electric lamp ( 2 ) partially projects. 2. Lighting device according to claim 1, characterized in that the height (H) of the lighting device ( 1 ) is approximately the same as the height (H _LM + H _F ) of the vertically arranged electric lamp ( 2 ) including the socket ( 13 ). 3. Lighting device according to one of claims 1 or 2, characterized in that the height (H) of the lighting device ( 1 ) is a maximum of 1/3 of the diameter (D) of its approximately circular underside ( 10 ). 4. Lighting device according to one of claims 1 to 3, characterized in that the electric lighting means ( 2 ) is approximately rod-shaped. 5. Lighting device according to claim 4, characterized in that the electric lighting means ( 2 ) is conductively contacted at one end ( 14 ) by a socket ( 13 ) and projects with the other, free end ( 15 ) into the opening ( 4 ) of the primary reflector ( 3 ). 6. Lighting device according to claim 5, characterized in that it has a blanking tube ( 9 ) partially surrounding the electric lighting means ( 2 ) and the light-emitting region ( 16 ) of the electric lighting means ( 2 ) is arranged outside the blanking tube ( 9 ) and outside the primary reflector ( 3 ). 7. Lighting device according to one of claims 1 to 3, characterized in that the secondary reflector ( 5 ) consists of exactly one convergent inner region ( 6 ) and exactly one convergent outer region ( 7 ), the curvature of which is different, wherein a defocusing region ( 8 ) is arranged between the inner and the outer region ( 6 , 7 ) of the secondary reflector ( 5 ). 8. Lighting device according to one of claims 1 to 7, characterized in that the lighting device ( 1 ) is translucent on its approximately circular underside ( 10 ) only in an annular region ( 11 ). 9. Lighting device according to claim 8, characterized in that the width (R ₂ -R ₁ ) of the annular light-permeable region ( 11 ) is smaller than 1/4, preferably about 1/6, of the diameter (D) of the circular underside ( 10 ). 10. Lighting device according to one of claims 1 to 9, characterized in that it has a blanking tube ( 9 ) partially surrounding the electric lighting means ( 2 ), and the blanking tube ( 9 ) blanks the electric lighting means ( 2 ) over an angular range (Δφ ₁ ) of approximately 0 degrees to approximately 50 degrees, starting from the vertical longitudinal axis (Z) of the electric lighting means ( 2 ) in the region of the socket ( 13 ). 11. Lighting device according to one of claims 1 to 10, characterized in that the primary reflector ( 3 ) blocks the electric lighting means ( 2 ) in an angular range (Δφ ₄ ) of approximately 130 degrees to approximately 180 degrees, starting from the vertical longitudinal axis (Z) of the electric lighting means ( 2 ) in the region of the socket ( 13 ). 12. Lighting device according to one of claims 1 to 11, characterized in that rays emanating from the electric lighting means ( 2 ) in an angular range (Δφ ₂ ) of approximately 50 degrees to approximately 100 degrees, starting from the vertical longitudinal axis (Z) of the electric lighting means ( 2 ) in the region of the socket ( 13 ), emerge from the lighting device ( 1 ) through the light-permeable region ( 11 ) of the latter after being reflected once at the secondary reflector ( 5 ). 13. Lighting device according to one of claims 1 to 12, characterized in that rays emanating from the electric lighting means ( 2 ) in an angular range (Δφ ₃ ) of approximately 100 degrees to approximately 130 degrees, starting from the vertical longitudinal axis (Z) of the electric lighting means ( 2 ) in the region of the socket ( 13 ), emerge from the lighting device through the light-permeable region ( 11 ) after a single reflection at the primary reflector ( 3 ) and a subsequent single reflection at the secondary reflector ( 5 ). 14. Lighting device according to one of claims 1 to 13, characterized in that rays emanating from the electric lighting means ( 2 ) in an angular range (Δφ ₅ ) of approximately 70 degrees to approximately 80 degrees, starting from the vertical longitudinal axis (Z) of the electric lighting means ( 2 ) in the region of the socket ( 13 ), emerge from the lighting device ( 1 ) through the light-permeable region ( 11 ) after being reflected once at the defocusing region ( 8 ). 15. Lighting device according to one of claims 1 to 14, characterized in that from an angle of reflection γ > 50 degrees to the vertical longitudinal axis (Z) the luminance (L) is less than 1000 cd/m ² .