EP0201926A1 - Indirect mirror light fixture - Google Patents

Abstract

The specular lamp or lighting fixture comprises a fluorescent tube as a light bulb which is arranged largely within a channel-shaped counter-reflector. Cross-lamellae for blanking the light of the fluorescent tube out in the longitudinal direction are seated on the counter-reflector. A channel-shaped main reflector which is designed large, and whose surface is preferably matted, is situated opposite the counter-reflector. A uniform luminance in the radiation region and a compact structure are achieved with the specular lamp. The luminance does not exceed a prescribed value in a prescribed, screened region.

Description

The invention relates to an indirect mirror lamp with a counter reflector, with a lamp arranged inside the counter reflector, completely shielded from it and with an at least partially curved main reflector, which is arranged opposite the counter reflector and is larger than it.

In lighting technology, efforts are made to protect a person who is at a certain distance from the lamp from the effects of glare. So you should have no direct view of the lamp and should not be disturbed by bright reflectors. In the beam area of the luminaire there should still be sufficient brightness for the predetermined purpose. These conditions. are by a mirror lamp of the type mentioned, as z. B. in the product brochure "Object Lights" from Siemens AG, catalog 1 4.23 1982, page 3/0, is satisfactorily fulfilled. There is an indirect mirror lamp with a halogen lamp inside a counter reflector. This is arranged opposite a main reflector, from which the light beams are reflected into the area to be illuminated. Above a shielding angle - measured from the vertical - the lamp has a shielding area in which no light is emitted by the main reflector. At a viewing angle that is smaller than the shielding angle (radiation area), the lamp itself is covered by the counter reflector.

More recently, efforts have been made to achieve a low luminance even in the radiation range. One reason for this is that, for example, in the case of reflective work tables which are below the lamp, a person working there is not disturbed by a too high luminance when looking at the reflecting table.

Mirror lights of the known type have only a small luminous flux. To illuminate larger rooms evenly, a large number of these lights is necessary, which is not always economically justifiable.

The object of the invention is to provide a mirror lamp of the type mentioned with a higher luminous flux, in which the luminance in the radiation range does not exceed a predetermined value.

This object is achieved in that the lamp is a fluorescent tube and that the counter-reflector is channel-shaped and is provided with transverse slats for dimming the lamp in the longitudinal direction.

The desired high luminous flux is ensured by using the fluorescent tube. The cross blades on the counter reflector ensure that the luminance in the radiation area is low even when viewed in the longitudinal direction.

A particularly advantageous embodiment of the invention is characterized in that - seen in cross section - the main reflector consists of two circular arc parts placed one against the other and one outer part attached to each side. This measure results in a particularly low structure of the mirror lamp.

• FIG 1 eine indirekte Spiegelleuchte in Seitenansicht,
• FIG 2 ein Schnittbild quer zur Ansicht der Figur 1, und
• FIG 3 eine Spiegelleuchte mit zum Teil gerader Ausführung des Hauptreflektors.

Further advantages and refinements of the invention result from the description of the figures in connection with the subclaims. Show it:

• 1 shows an indirect mirror lamp in side view,
• 2 shows a sectional view transversely to the view of FIG. 1, and
• 3 shows a mirror lamp with a partly straight version of the main reflector.

According to FIGS. 1 and 2, a lamp 1 is arranged inside a counter reflector 3, which is designed as a channel. The lamp 1, which is designed as a fluorescent tube, is surrounded by this and completely shielded. The fluorescent tube 1 is U-shaped, that is to say it has two parallel illuminated paths, and is plugged into a base 5 at its end. The base 5 is mounted on a fastening part 7 which is fastened on the counter reflector 3. The lamp 1 is surrounded by circular transverse lamellae 9, which are arranged at a distance from one another and have a parabolic or triangular cross section which is known in the case of louvre lights.

This arrangement of counter-reflector 3 with fluorescent tube 1 is located opposite a main reflector 11. This has the shape of a groove which is slightly depressed in the area opposite the fluorescent tube 1 and is attached to a housing 13 at the side.

The main reflector 11 is mirror-symmetrical with respect to the center plane 15, which runs through the fluorescent tube 1. Seen in cross section, the main reflector 11 first has a circular arc part 17 on both sides of the center plane 15 and then an outer part, which is designed here as a parabolic arc part 19. Both circular arc parts 17 are assembled at Z. The size each circular arc part 17 is determined by a boundary beam 21, 21 ', which is emitted from a point F on the edge or outside the edge of the counter reflector 3, after reflection in point L of the circular arc part 17 takes back the same beam path (21') and with Vertical includes the shielding angle α. In Figure 2, this outermost point F is placed somewhat next to the counter reflector 3 for safety. The circular arc part 17 is thus guided up to the point L and merges there into the parabolic arc part 19. At point L, both arc parts 17, 19 have the same slope.

The focal point of the parabola on which the parabolic arch part 19 is based is located at point F, through which its main axis also runs.

Instead of the parabolic arch part 19, other, outer parts with a flat curve shape are also possible, as shown for example in FIG. 3. However, such external parts inevitably involve a more spacious design, as may be desired in exceptional cases. Such a case is e.g. B. given when the mirror lamp as a ceiling element in a predetermined grid of z. B. 1.25 m wide to be brought.

The counter reflector 3 and the main reflector 11 have the smallest possible distance A from one another in order to achieve a compact design. This distance A is dependent on the required shielding angle α and the width B of the counter reflector 3. The smallest distance A results when a light beam 23 is emitted from the left outer edge of the counter reflector 3 to point Z on the left edge of the right circular arc part 17 and from there is reflected as light beam 23 'at the shielding angle zC. With a smaller distance A, the specified value would be for the shielding angle α are exceeded. A light beam 25, which emanates in the area between the edges of the counter reflector 3, for example directly from the lamp 1, is reflected by the main reflector 11 at an angle (light beam 25 ') that is smaller than the shielding angle% Z. This configuration and arrangement of the main reflector 11 achieves a high degree of efficiency while maintaining the secondary conditions for the shielding area.

The main reflector 11 has a diffusely reflecting inner surface with a directivity (directionally reflected portion) of 20 to 40%. In the illustrated embodiment of Figures 1 and 2, z. B. with a total width G of the mirror lamp of about G = 60 cm, the directivity is about 20%. In the case of a correspondingly larger main reflector 11 with a large light exit opening, as is shown later in FIG. 3, the directivity can be increased to a value of approximately 40%. The main reflector 11 preferably has about six times the width of the counter reflector 3: G = 6B. The length E of the main reflector 11 is dependent on the lamp 1 used and should be at least equal to the width G of the main reflector 11.

Pure or purest aluminum can be used as the material for the main reflector 11. Alternatively, a plastic can be used, the reflective surface of which is coated with pure or ultra-pure aluminum. To achieve diffuse reflection, the surface of the main reflector 11 is either roughened, painted or coated. It is also possible to provide the main reflector 11 with fine holes and to deposit these with a white layer. This also results in good sound insulation. The inside of the counter reflector 3 is also made of pure or purest aluminum manufactured. It is high-gloss, that is, mirrored. The end faces of the reflectors 3, 11 can have a glossy or diffuse surface.

In Figure 3, the same components are identified with the same reference numerals as in Figures 1 and 2. Here, the two outer parts of the main reflector 11 are not curved, i.e. straight in cross-section. This gives the mirror lamp larger dimensions, but this may be desirable for aesthetic or structural reasons. The description of FIGS. 1 and 2 applies analogously to the structure and mode of operation of the mirror lamp according to FIG. 3.

Claims (8)

1. Indirect mirror lamp with a counter reflector, with an arranged inside the counter reflector, completely shielded from this lamp and with an at least partially curved main reflector, which is arranged opposite the counter reflector and is larger than this, characterized in that the lamp (1) a Is fluorescent tube, and that the counter-reflector (3) is channel-shaped and is provided with cross blades (9) for dimming the lamp (1) in the longitudinal direction. 2. Mirror lamp according to claim 1, characterized in that - seen in cross section - the outer surface of the main reflector (11) consists of two circular arc parts (17) placed against each other and one lateral part attached to it on the outside (19). 3. mirror lamp according to claim 2, characterized in that the main reflector (11) is matted and has a directivity of 20 - 40%. 4. Mirror lamp according to claim 3, characterized in that the main reflector (11) has approximately six times the width of the counter reflector (3). 5. Mirror lamp according to claim 4, characterized in that the length of the main reflector (11) is at least equal to its width. 6. Mirror lamp according to claim 5, characterized in that the length of the main reflector (11) is between 30 and 160 cm. 7. Mirror lamp according to one of claims 1 to 6, characterized in that the outer surface of the main reflector (11) to the center plane (15) which extends through the fluorescent tube is mirror-symmetrical. Reference symbol list 1 lamp as fluorescent tube 3 counter reflector 5 bases 7 fastening part 9 cross blades 11 main reflector 13 housing 15 center level 17 circular arc part 19 parabolic arch part 21, 21 'boundary beam 23, 23 'light beam 25, 25 'beam of light

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