DE4225386A1 - Fluorescent lamp lighting unit - has apertured light stop projecting inwards from one side of light exit opening - Google Patents

Abstract

The lighting unit has a compact fluorescent tube (1) with a high light output intensity, enclosed by a symmetrical reflector (2,3) with a light exit opening (4) perpendicular to the longitudinal centre plane of the lighting unit. An apertured light stop (5) projects inwards from one side of the light exit opening (4) perpendicular to the longitudinal centre plane, for obtaining an asymmetrical light distribution curve. The light stop (5) may be provided by an apertured plate, or by an opaque area of the lamp glass fitted across the light exit opening (4). ADVANTAGE - Simple modification of light distribution curve.

Description

The invention relates to a spotlight according to the preamble of the main claim.

Preferably direct spotlights with symme light intensity distribution curves in the C0-180 plane and the C90-270 level are widely known. As a light medium-sized light sources such as metal are used for this steam lamps, e.g. B. of the type HQI-T or HQI-TS or halogen incandescent, but also linear light sources with one light-emitting lamp part up to about 25 cm in length, such as e.g. B. compact fluorescent lamps or lamps of the type SDW-T, into consideration. These light sources are given in a Distance partially enveloped by a reflector in front preferably with respect to the in the direction of the longitudinal axis of the Light source running C90-270 level mirror image symmetry is trained. This results in a symmetri cal luminous intensity distribution curve in the perpendicular C0-180 level. With an appropriate design of the end face The spotlight also applies to the luminous intensity Division in the C90-270 level approximately analog.

Such spotlights with essentially symmetri light intensity distribution curves can be used successfully a number of lighting tasks especially then be used if the illuminated area is sufficient is illuminated at a great distance. But there are also Known use cases in which precisely this symmetry the luminous intensity distribution curve of considerable disadvantage is, so that the use of such spotlights lighting reasons is not possible. So one can Spotlight of this type, for example, usually not as  Wallwashers are used. If the spotlights luminaire close to the wall and approx forth perpendicular to the wall surface to be illuminated is arranged already results in the wall area in front of the the free emission of the lamp takes effect, a very sharp light-dark contrast. This will still be reinforces that in the subsequent illuminated wall rich inadmissibly high luminance levels occur. With wide geometric distance from the spotlight then the luminance decreases very quickly. This results in this case in addition to the annoying light-dark contrast an unreasonable luminance distribution. Spotlights with essentially symmetrical light distribution cannot be used in such applications, instead, spotlights with one in the ent speaking C-plane asymmetrical light distribution curve can be used. Both for the manufacturer as well however, it is desirable for the user to use a beam ler luminaire available, which at identi structure and similar external appearance without the restrictions mentioned for a variety of Lighting tasks with different lighting technology requirements can be used.

A number of possibilities are possible for the expert in lighting technology known, spotlights of the aforementioned Art to convert so that they are asymmetrical Show luminous intensity distribution curves. So you could The reflector is not symmetrical but asymmetrical design. Since the reflector is an essential function and also the structure and dimensions of the emitters luminaire is directly a determining element this possibility in the present case. It would exist also the possibility of the light intensity distribution curve there by changing that one the relative position of the light source adjustable to the reflector. The  Similar solutions are used for street lights, but also ro occasionally symmetrical recessed ceiling lights agile. This solution is because of the because of the necessary design of the lamp holder and against also the reflector is relatively expensive to construct. Unless the lamp is rotationally symmetrical this solution also does not allow any adjustment of the Luminous intensity distribution curve in different C levels.

The invention is therefore based on the object for Spotlight of the type described above a white tere embodiment to create that allows without a major intervention in the luminaire structure with a symmetrical light distribution curve equipped spotlight with simple means and inexpensively converting into a spotlight that optionally an asymmetrical one in different C-levels Luminous intensity distribution curve.

In a spotlight of the type mentioned this task according to the invention in the characteristics of Main claim described features solved.

Studies have shown that these manufacturing tech nisch very simple solution surprisingly also light technically meets the requirements. One in the lights aperture inserted appears first to the Lighting technicians as a suitable means, the ent influence the speaking luminous intensity distribution curve, but still compared to other known solutions as we less useful, since it is expected that such a Blen de significantly reduces the lighting efficiency. At Appropriate aperture design can be used as a night master the perceived quality to the extent that the advantages of an easily convertible lamp by far prevail. This is especially true when the bezel  according to a further development of the invention sig is formed, so z. B. according to another further education of the invention is designed as a pinhole.

For spotlights, the one the light outlet opening have covering cover glass, the aperture can according other developments of the invention as a partial area be finished glass, which compared to the remaining surface of the cover glass on average one has lower transmittance. All of these continue Formations make it possible, even when grazing sideways Incidence of light a softer transition in the light / dark Create zone of illuminated area. At the same time leaves the luminance increases even with a light source Radiation intensity in the light closest to the light reduce the illuminated area to a permissible level ren, where then also the lower luminance per se not so anymore in areas far away from the light deviates significantly that these surface areas as not appear sufficiently illuminated. In other words, it is possible with one of the simplest means Luminaire arrangement with the area to be illuminated illuminates the side grazing light by essentially leveled luminance distribution an appropriate and to achieve appealing lighting.

Further advantages of the invention result from the following description of exemplary embodiments hand of the drawing to be explained in more detail. It shows:

Fig. 1 in a three-dimensional representation Invention designed according spot light in its essential details,

Fig. 2 is a schematic cross-sectional view of the spot light of FIG. 1,

Fig. 3 shows schematically a typical application example for a spotlight according to Fig. 1 and

Fig. 4 compared in a diagram, the respective luminance distribution for a spotlight without or with a diaphragm in the use case shown in Fig. 3.

The reflector light schematically illustrated in Fig. 1, a compact fluorescent lamp as the light source 1, al so in this case, a line-shaped light source with rela tively short light-emitting length. Other comparable linear light sources, such as B. SDW-T lamps or line-shaped halo gene lamps. As such, punctiform light sources of high radiation intensity, such as metal halide lamps of the type HQI-T or HQI-TS or halogen incandescent lamps, could also be used.

With a relative distance to the light source 1 , a partially enveloping reflector 2 is provided, the bezüg Lich the longitudinal axis of the spotlight or the light source 1 with its spherical surfaces is formed symmetrically. The end faces of the spotlight can, as shown in Fig. 1 simplified, be designed as plane Seitenre reflectors 3 . But they can also be curved, inclined surfaces against the light source 1 . The outer edges of these reflectors 2 , 3 together form the boundary for a light exit opening 4 of the beam lamp, through which the light emitted by the light source 1 is partly directly, partly reflected via the reflector surfaces 2 , 3 .

In this respect, the spotlight shown in Fig. 1 is a conventional lamp. Because of the described design of the reflector surfaces 2 , 3 , this radiator has essentially symmetrical luminous intensity distribution curves both in the C0-180 plane perpendicular to the longitudinal axis of the lamp and in the perpendicular C90-270 plane.

This symmetrical cal luminosity distribution curve, which is predetermined for this type of radiator per se, with respect to one of the C-planes mentioned, can be transformed through a diaphragm 5 , which is arranged from a reflector edge into the light exit opening 4 , into a desired radiator characteristic with an asymmetrical luminous intensity distribution curve. The arrangement of the aperture 5 on a long side of the spotlight - as shown in Fig. 1 preference, - causes a one-sided shielding the free radiation of the light source 1 in the C0-180 plane. If, on the other hand, the diaphragm 5 is arranged , as shown schematically in FIG. 1 by a hatched area 51 , starting from one of the end faces and extending into the light outlet opening 4 , an asymmetrical deformation of the light distribution curve in the C90 is achieved in an analogous manner -270 level. The diaphragm 5 can simply be designed as a flat sheet metal reflecting in the interior of the luminaire or - as indicated in FIG. 1 - can be designed as a perforated diaphragm.

The same function can also be realized in spotlights whose light exit opening is covered by a closing glass. In this case, the function of the diaphragm 5 can be fulfilled by a correspondingly arranged partial surface of the cover glass, which on average has a lower transmittance than the other surface of the cover glass. With this definition it should be included that such a partial surface is produced by coating or printing on the end glass in this area. If necessary, different patterns can be generated so that the cover glass remains partially translucent even in this partial area. The integrating property of such patterns of locally reflecting raster elements or the like results in a more or less strong shielding of the light source 1, averaged over the entire partial area. Similar effects can also be achieved, however, by matting the corresponding partial areas by etching or sandblasting their surface, and by increasing the surface roughness by increasing the degree of reflection of the partial area treated in this way compared to the untreated area of the end glass.

To clarify the lighting function, the spotlight according to FIG. 1 is shown schematically in cross section in FIG. 2, different light rays that are essential for the light distribution characteristic of the lamp being indicated. A first light beam S 1 , grazing the outer edge of the reflector 2 , is placed tangentially on the side of the light source 1 pointing in the direction of the light exit surface. This light beam S 1 is thus the boundary beam that emerges from the spot lamp without reflection, provided that no aperture 5 is provided. In a glare-free spotlight, this first light beam S 1 , in other words, indicates the light exit angle from which the free emission of the light source 1 begins. A second light beam S 2 is tangentially placed on the light source 1 from the other side in such a way that it also grazes the outer edge of the reflector 2 . The water second light beam S 2 thus characterizes the angle at which the full free emission of the light source 1 is given in a spotlight luminaire without a lateral screen 5 .

The two other light rays shown in FIG. 2, S 3 and S 4 are also placed tangentially to the light source 1 corresponding to the first light beam S 1 and the second light beam S 2 , but each graze the inner edge of the diaphragm 5th The third light beam S 3 thus designates the angle from which the free emission of the light source 1 begins, provided the side panel 5 is seen before. At the exit angle of the fourth light beam S 4 , the full free radiation of the light source 1 is then sufficient even when shielded by the blen de 5 .

In Fig. 3 an application is schematically shown for the lamp described with reference to FIGS . 1 and 2 above. The lamp is arranged with its longitudinal axis parallel to and relatively close to a wall surface 7 , the light exit surface 4 of the lamp being approximately perpendicular to the wall surface 7 . The light beams S 1 to S 4 described with reference to FIG. 2 are shown and illustrate the incidence of light on the illuminated wall surface, which becomes more and more streaking as the distance from the spotlight increases.

In FIG. 4, in a graph in two curves 81 and 82 reproduced luminance distributions on the wall surface 7 of the illustrated in Fig. 3 the application. The luminance distribution according to curve 81 applies to a spotlight with a symmetrical light distribution curve, ie without a side diaphragm 5 . In contrast, a spotlight with an asymmetrical luminous intensity distribution curve, that is to say with a lateral diaphragm 5 , results in a luminance distribution according to curve 82 . As expected, the luminance distribution in the case of a radiator characteristic with a symmetrical luminous intensity distribution curve shows a very rapid and pronounced increase in luminance as soon as the free emission of the light source 1 begins, which is limited by the first light beam S 1 . Even before the full free emission of the light source 1 characterized by the second light beam S 2 has an effect, a luminance maximum with impermissibly high luminance values is reached. With increasing distance from the spotlight, the luminance drops rapidly towards the lower part of the wall. This distribution curve 81 thus illustrates that the unshielded spotlight on the illuminated wall surface 7 creates a very sharply delineated light-dark zone in the transition to the illuminated surface. To reinforce this effect, an inadmissibly high luminance occurs in the illuminated area directly adjacent to it. Wall areas lying further down, on the other hand, appear dark again due to the high luminance differences.

The curve shape 82 , which reproduces the lighting conditions through a beam light with an asymmetrical luminous intensity distribution curve, shows the leveling function of the side diaphragm 5 very clearly. The unbearably high luminance maximum does not occur here. Naturally, the luminance also drops here in the direction of the distant wall parts further away from the spotlight lamp, but overall a much more uniform luminance distribution can be achieved. Even if - depending on the design of the panel 5 - egg ne certain impairment of the lighting efficiency is to be accepted, however, the overall lighting on the wall surface 7 corresponds technically to the requirements for more uniform lighting. In the transition of the light / dark zone can be created in particular by the design of the aperture as a pinhole or as a partially permeable aperture, a softer transition that is visually perceived as pleasant. Because of the more uniform lighting, a luminance is still achieved even when the wall is remote from the light, which is not so low compared to the higher luminance in wall parts near the light that these wall parts which are remote from the light are felt to be too dark.

Claims (6)

1. Spotlight with a point or line-shaped light source of high radiation intensity and a reflector partially enveloping the light source, symmetrical to the C90-270 level of the spotlight and a perpendicular to this C-plane, limited by the edge surfaces of the reflector light outlet opening, characterized in that in order to achieve an asymmetrical light distribution curve of the spotlight in a predetermined C-plane, a diaphragm ( 5 ) projecting from a limitation of the light exit opening ( 4 ) which is predetermined by a reflector edge is provided and extends perpendicularly to the predetermined C-plane. 2. Spotlight according to claim 1, characterized in that the diaphragm ( 5 ) is partially translucent. 3. Spotlight according to claim 2, characterized in that the diaphragm ( 5 ) is designed as a flat pinhole. 4. Spotlight according to claim 2, characterized in that a light exit opening ( 4 ) covering the end glass is provided and the diaphragm ( 5 ) is formed as a partial surface of this end glass, which in comparison to the remaining surface of the end glass from an average has lower transmittance. 5. Spotlight according to claim 4, characterized in that the diaphragm ( 5 ) we kende partial surface of the end glass is at least partially coated. 6. Spotlight according to claim 4, characterized in that the diaphragm ( 5 ) we kende partial surface of the end glass compared to the rest of the surface caused by etching or sandblasting, larger surface roughness.