DE9109267U1 - Indirect mirror light - Google Patents

Description

G U 6 8Ut

Siemens AG

Indirect mirror light
5

Technical area

The invention relates to an indirect mirror light, consisting of a housing that accommodates a main reflector for mounting on or installation in a ceiling, as well as a channel-shaped counter-reflector that is open towards the main reflector and that accommodates a tubular illuminant in the form of at least one fluorescent lamp, in which the counter-reflector has cross slats on the side of the main reflector that are aligned perpendicularly to the illuminant axis and that are arranged at predetermined intervals along the length of the illuminant, and in which the counter-reflector arrangement consisting of counter-reflector, illuminant including lamp holders and cross slats is arranged below the housing opening, fastened to housing-side brackets.

Underlying state of the art

Indirect mirror lights of this type are known, for example, from the literature reference EP 0 201 926 Bl. With such mirror lights, it is possible to not only prevent undesirable reflected glare on essentially vertical surfaces of work equipment, such as screens, with a high luminous flux for illuminating a relatively large radiation area, but also to reduce undesirable reflected effects on essentially horizontal reflective surfaces, such as the surface of desks and work tables.

The beam angles to be observed for office workplace luminaires to the vertical between 50° and 60 lead to the

Jae/May / 26.07.91
3AO 01 01

Housings that accommodate the main reflector, the height of which, given the width of the main reflector, requires a ceiling installation depth that is often not available.

The requirements to be taken into account with regard to freedom from glare can then be achieved with a relatively low main reflector and thus also a correspondingly reduced height of the housing accommodating the main reflector if, as shown in the literature reference GM 86 03 794, the counter-reflector arrangement comprising the counter-reflector, the tubular lamp including lamp holders and cross slats is suspended downwards from the main reflector.

Disclosure of the invention

The invention is based on the object of developing an indirect mirror light of the latter type in such a way that it can be optimally adapted to different illumination conditions with regard to its beam characteristics while maintaining the required freedom from glare.

This object is achieved according to the invention by the features specified in claim 1.

The invention is based on the knowledge that, given a given main reflector and a given counter-reflector arrangement, the beam characteristics of the lamp can be changed or adjusted in a simple manner by making the housing-side brackets to which the counter-reflector arrangement is attached adjustable in length.

Further adjustment options are advantageously also provided by the counter-reflector arrangement being additionally attached to the brackets so that it can pivot about a horizontal axis parallel to the lamp axis and/or the brackets being additionally attached to the housing so that they can be adjusted or moved horizontally across the lamp axis.

01 02

G 136 8Dt

Appropriate embodiments of the object according to claim 1, optionally in conjunction with the features of claims 2 and 3, are specified in the further claims 4 to 12.

Short description of the drawing

In the drawing, the figures used to explain the invention in more detail
10

Fig. 1 shows a schematic representation of an indirect mirror light with adjustable asymmetric beam characteristics in cross section,

Fig. 2 shows a schematic representation of an indirect mirror light designed as a climate light with adjustable

symmetrical beam characteristics in cross section, Fig. 3 the schematic representation of another indirect mirror light with adjustable symmetrical beam characteristics in cross section, Fig. 4 the indirect mirror light according to Fig. 3 in longitudinal section,

Fig. 5 the indirect mirror light according to Fig. 3 in cross section with details explaining its preferred dimensioning,

Fig. 6 shows an enlarged cross-section of the counter-reflector arrangement of the indirect mirror light according to Fig. 5 with further design information,

Fig. 7 shows the schematic representation of the indirect mirror light according to Figures 3 to 6 for three preferred different distances of the counter-reflector arrangement from the housing opening,

Fig. 8 to 10 show the light distribution curves in the C0-180° plane corresponding to the preferred different distances of the counter-reflector arrangement from the housing opening in the indirect mirror light according to Fig. 7.

01 03

Best way to carry out the invention

The embodiments of indirect mirror lights shown in Figures 1 to 7 are designed for ceiling installation. However, such lights can also be placed on a ceiling with their housing in the same way.

The indirect mirror light shown in cross section according to Fig. 1 has a housing 1 inserted into the ceiling opening DO of a ceiling DE with a main reflector 20 inserted into the housing 1. The main reflector 20 is dimensioned here for an asymmetrical beam characteristic and has an involute-like cross section. Below the housing opening 1.2 and thus below the main reflector 20, a counter-reflector arrangement is arranged on rod-shaped holders 6. The counter-reflector arrangement 30 consists of a channel-shaped counter-reflector 3, which accommodates a tubular illuminant 5, as well as cross slats A, which are aligned perpendicular to the illuminant axis and distributed over the length of the illuminant 5 at predetermined intervals and span the opening of the counter-reflector 3 on the side of the main reflector 20 in an arc shape. The lamp 5 is a U-shaped fluorescent lamp, the lamp axis of which is designated Ax.

To set a desired beam characteristic of the indirect mirror light according to Fig. 1, there are basically three different ways of adjusting the reflector arrangement 30, either individually or in combination, with regard to the main reflector. Firstly, the rod-shaped holders 6 are designed to be variable in length, so that the reflector arrangement 30 can be changed in terms of its distance H from the housing opening 1.2. Furthermore, the reflector arrangement 30 is attached to the lower end of the holders 6 so that it can pivot about a horizontal axis parallel to the lamp axis Ax. Finally, the holders can be adjusted horizontally on the housing transversely to the lamp axis Ax Jae/May / 18.09.91

09 01

G1368Dt

or moved. These three adjustment options are indicated by arrows in Fig. 1. The variable length of the brackets 6 can be achieved, for example, by a telescopic design. The fastening of the brackets 6 on the side of the housing 1 can also be implemented mechanically, for example by a lockable slide guide.

As can also be seen from Fig. 1, the counter-reflector 3 of the counter-reflector arrangement 30 has a roof-like recess 31 in the middle of its base, the roof edge 32 of which lies in a central plane M, which divides the counter-reflector 3 into two mutually mirror-symmetrical channel halves. To illustrate the adjustment options of the counter-reflector arrangement 30, in addition to the reflector arrangement 30, two different adjustment positions are shown in broken lines in Fig. 1, which, in contrast to the counter-reflector arrangement 30, are designated 30' and 30". In the counter-reflector arrangement 30', the distance H relative to the housing opening 1.2 is increased and at the same time the reflector arrangement 30' is pivoted slightly to the right on the brackets 6. The reflector arrangement 30" is provided at a distance H from the housing opening 1.2 that is greater than the corresponding distance of the reflector arrangement 30, but smaller than the corresponding distance of the reflector arrangement 30'. Here, the reflector arrangement 30' is pivoted slightly to the right relative to the reflector arrangement 30 and, in addition, the entire arrangement with the brackets 6 is shifted to the right towards the center of the housing 1.

The embodiment of an indirect mirror light, also shown in cross-section in Fig. 2, is intended for a symmetrical beam characteristic and at the same time represents a climate-controlled version. The main reflector 2, which is mirror-symmetrical to a central plane S, has two concavely curved partial reflectors 21. For the climatically conditioned

3AO 01 05

For ventilation, longitudinal slots 23 are provided on the one hand between the partial reflectors 21 and the side walls 1.1 of the housing 1 close to them and on the other hand between the adjacent edges of the partial reflectors 21. The rod-shaped holders 6, which are adjustable in length, are arranged with their axes in the center plane S. If the beam characteristics are limited to a symmetrical beam characteristic, a pivoting design for fastening the reflector arrangement 30 at the lower end of the holders 6 can be dispensed with.

A representation of another embodiment of an indirect mirror light corresponding to Fig. 2, in which special air slots can be dispensed with, is shown in Fig. 3. The main reflector 2 is also designed as a mirror image of the center plane S, but in contrast to the main reflector according to Fig. 2, it can be made in one piece. The concave curvature of one reflector half 22 is designed here as a circular arc with the radius R and the circle center M. The distance H of the reflector arrangement 30 from the housing opening 1.2 is selected here via the holders 6, the length of which can be changed, so that the beam angle ϑ shown in Fig. 3 is larger than would be necessary for the illumination of the main reflector 2. In other words, the distance H can also advantageously be selected to be so large that the light emitted by the lamp 5 also contributes to brightening the ceiling DE in the vicinity of the housing 1. The ratio of height h to width b of the housing 1 is desirably relatively small and has a value in the range 1/8 to 1/12.

As the longitudinal section of the indirect mirror light according to Fig. A shows, the counter-reflector arrangement 30 is attached to one of the brackets 6 on the front side of the counter-reflector 3. The Dulux lamp, which is held in a socket 50 inside the counter-reflector 3 and represents the tubular light source 5, is arranged in the area of the transverse slats A,

3AO 01 06

G 1 36 8OE ^

7 ,;.-,. ^: -.. '' ■ - ■: which have an equal mutual distance a.

Structural details of the indirect mirror light according to Figures 3 and 4, which represents a preferred embodiment, can be seen in Figures 5 and 6.

In the representation of the indirect mirror light according to Fig. 5, which corresponds to Fig. 3, a beam si is entered which, starting from the right edge point F of the main reflector 2, touches the right outer edge of the counter-reflector 3 as a tangent at point B and intersects the center plane S at point D. In relation to the distance H of the counter-reflector arrangement 3 from the housing opening 1.2, this results in an angle between the beam si and the vertical or the center plane S which is equal to the radiation angle ^S 8^~. The radiation angle lf~ thus becomes larger the smaller the distance H is chosen between the counter-reflector arrangement 30 and the housing opening 1.2.

Furthermore, a free beam s2 is shown in Fig. 5, which is reflected at point T of the left reflector half 22 to the counter-reflector 3. The beam s2 is then reflected at the counter-reflector 3 at points C and A and from there is emitted into the center of the right tube of the lamp 5. This beam guidance naturally applies in the opposite direction as well and makes it clear that a beam emanating from the lamp axis Ax2 of the right tube of the lamp 5 is emitted around the lamp 5 to the main reflector 2 with the help of the counter-reflector 3. In other words, the cross-sectional contour of the counter-reflector 3 is designed in such a way that practically no light emerging from the lamp 5 is reflected back into the lamp 5 by the counter-reflector 3 in an undesirable manner. The beam s2 is aligned parallel to the beam si, and thus also represents a limiting beam of the radiation area. The angle to the horizontal is also specified for the beam s2. This is the shielding angle β, which indicates the area in which the

3AO 01 07

indirect mirror light practically no longer emits any light. As already mentioned in the introduction, the beam angle &ogr; for office work lights is 50° to 60° and the shielding angle /3 is accordingly AO ⁰ to 30°.

The reflector halves 22 of the main reflector 2 have a circular arc contour which can change into a straight section at the small distance from the center plane S given by the point T. In this way it is ensured that the light beam striking the main reflector 2 at the radiation angle ϳ always has the same reflection angle tA in the area between the point T and the center of the main reflector at the location of the center plane S. The bisector w between the incident beam s2 and its reflection at the point T passes through the center point M of the circular arc with the radius R, which determines the circular arc contour of the left reflector half 22.

The structural design of the counter-reflector 3 is shown in Fig. 6, which is an enlarged view of the counter-reflector arrangement 30 according to Fig. 5. As can be seen in Fig. 6, the light source 5, which represents a U-shaped fluorescent lamp, has a light source axis Ax that runs in the middle of the connecting plane containing the two lamp axes AxI and Ax2 as boundary lines. The counter-reflector 3 is mirror-symmetrical to the center plane M, which in the embodiment coincides with the center plane S and divides the counter-reflector 3 into two channel halves. Each of the two channel halves consists of two circular arcs Kl and K2 in its cross-sectional contour. The circular arc Kl with the smaller radius begins in the area of the roof edge 32 of the roof-like recess 31 and then merges into the circular arc K2 with the larger radius, which extends to the outer edge of the counter-reflector 3. The circle center MKl of the circular arc Kl is the intersection of the bisector w2 of the beam s2 incident at point A and reflected from there to the light source 5 with the perpendicular L2 dropped on the tangent t at point E. Jae/May / 18.09.91

10 01

G 1 3 6 8 EN

In the same way, the circle centre MK2 of the circular arc K2 is obtained by the intersection of the bisector wl of the ray s2 incident at point C and reflected from there to point A with the perpendicular Ll to the ray s2 at point B.

Fig. 7, which corresponds to the representation according to Figures 3, 5 and 6, the counter-reflector arrangement 30 is specified for three preferred different distances Hl, H2 and H3 to the housing opening 1.2. At the distance Hl of the counter-reflector arrangement 30, the light distribution curve LVKl shown in Fig. 8 results, which has a narrow beam characteristic and at which the shielding angle P = 40°.

At the distance H2 of the counter-reflector arrangement 30, as shown in the diagram in Fig. 9, a light distribution curve LVK2 results which has a narrow, wide beam characteristic. The shielding angle β here is = 30°.

At the distance H3 of the counter-reflector arrangement 30 from the housing opening 1.2, the light distribution curve LVK3 shown in the diagram in Fig. 10 is finally obtained, which can be described here as wide beam and where the shielding angle is < 30°.

3AO 01 09

Claims (12)

G 1 36 8OE ..., _ ,. &iacgr;&ogr; ■ Protection claims 1. Indirect mirror light, consisting of a housing containing a main reflector for mounting on or installation in a ceiling, as well as a channel-shaped counter-reflector open towards the main reflector, which contains a tubular light source in the form of at least one fluorescent lamp, in which the counter-reflector on the side of the main reflector has cross slats aligned perpendicular to the lamp axis, which are distributed over the length of the lamp at specified intervals and in which the counter-reflector arrangement consisting of counter-reflector, light source including lamp holders and cross slats is attached to housing-side brackets and arranged below the housing opening, characterized in that the holders (6) are designed to be variable at least in their length determining the distance (H, H1, H2, H3) of the counter-reflector arrangement (30, 30', 30") from the housing opening (1.2). 2. Indirect mirror light according to claim 1, characterized in that the counter-reflector arrangement (30, 30', 30") is pivotably attached to the brackets (6) about a horizontal axis parallel to the lamp axis (Ax). 3. Indirect mirror light according to claim 1 or 2, characterized in that the brackets (6) are attached to the housing (1) so that they can be adjusted or moved horizontally across the lamp axis (Ax). 02 01 G 1 3 6 8 OE 4. Indirect mirror light according to one of the preceding claims, characterized in that the concavely curved cross-sectional contour of the main reflector (20) has an involute-like course. 5. Indirect mirror light according to claim 1 or 2, characterized in that the main reflector (2) consists of two identical reflector halves (22) which are at least partially concavely curved in their cross-sectional contour and which are arranged in mirror image to a center plane (S) containing the lamp center axis (Ax). 6. Indirect mirror light according to claim 5, characterized in that longitudinal slots (23) serving to guide the air are provided for climatic ventilation on the one hand between the reflector halves representing the partial reflectors (21) and the side walls (1.1) of the housing (1) close to them and on the other hand between the adjacent edges of the partial reflectors (21). 7. Indirect mirror light according to claim 5 or 6, characterized in that the mutually mirror-image cross-sectional contours of the reflector halves (22) or partial reflectors (21) have, in a first approximation, a flat circular arc shape. 8. Indirect mirror light according to one of the preceding claims, characterized in that the channel-shaped counter-reflector (3) has a roof-like recess (31) in its cross section in the middle of the base, that the counter-reflector (3) is mirror-aligned to a central plane (M). 3Al 02 02 W tU 3 b BUt is symmetrical, in which both the roof edge (32) of the recess (31) and the lamp axis (Ax) parallel thereto of the lamp (5) arranged above the recess (31) in the counter reflector (3) lie. 9. Indirect mirror light according to one of the preceding claims, characterized in that the cross-sectional contour of the counter-reflector (3), based on one of the two gutter halves divided by the central plane (M), starting from the roof edge (32) of the recess (31), is a first circular arc (Kl), to which a second circular arc (K2) adjoins up to the gutter edge, that the second circular arc (K2) has a larger radius than the first circular arc (Kl) and both circular arcs (Kl, K2) merge into one another at a point (E) of the same gradient and that the radii of the two mutually associated circular arcs (Kl, K2) are dimensioned such that the light emanating from the lamp (5) and reflected at the counter reflector (3) is radiated as completely as possible past the lamp (5) to the main reflector (30). 10. Indirect mirror light according to one of the preceding claims, characterized in that the ratio of height (h)/width (b) of the cross-sectional contour of the housing (1) with the main reflector (2) is 1/8 to 1/12 and the variable distance (H) of the counter-reflector arrangement (30) from the housing opening (1.2) = the width (b) of the housing (1) and that furthermore the optimal minimum distance (H) of the counter-reflector arrangement (30) from the housing opening (1.2) is given when the main reflector (2) occupying the housing opening (1.2) is illuminated by the illuminant (5) over its full width. 02 03 11. Indirect mirror light with a cross-sectional contour of the main reflector that is mirror-symmetrical to the center plane according to one of claims 1, 2, 4 to 10, characterized in that at a predetermined distance (H) of the reflector arrangement (30) from the housing opening (1.2), based on a cross-sectional plane, the angle that the beam (si) passing through the edge point (F) of the main reflector (2) and touching the outer near edge of the counter reflector at point (B) as a tangent encloses with the center plane (S) is the radiation angle ( Tf) . 12. Indirect mirror light according to one of the preceding claims, characterized in that the light source (5) is a U-shaped fluorescent lamp, 11