DE29518202U1 - Lighting device - Google Patents

Description

μg/cm² 4245 - KG/dk Müiler-Bore & Partner _{16 N} oven door

METAPRINT GMBH ~~ —~ —— ^lö ' ^woveraDer

Patent Attorneys · European Patent Attorneys

Graiinger Straße 2 ■ D-61671 Munich

Lighting device

The present invention relates to a lighting device according to the preamble of claim 1.

Conventional lighting devices, in particular so-called 'downlighters', in which a linear light source, such as a compact fluorescent lamp (energy saving lamp) is used, are operated in two ways. Firstly, the linear light source is installed along the reflector axis, whereby the reflector is generally rotationally symmetrical. Secondly, the linear light source is installed approximately perpendicular to the reflector axis (as shown in connection with the present invention in Fig. 1).

Both types of installation have disadvantages. When installed along the reflector axis, a rotationally symmetrical light intensity distribution is achieved, but the height of the reflector is high due to the length of the light source. When installed perpendicular to the reflector axis, the height is about 50% lower (with the same blanking angle compared to the first variant), but this arrangement of the light source leads to large deviations from the rotationally symmetrical light intensity distribution. Figure 4 shows the beam path of two light beams (highlighted in gray), whereby it can be seen that the light beam in the left part of Figure 4 has an opening angle of about twice the size compared to the right part of Figure 4. This leads to deviations from a rotationally symmetrical light intensity distribution.

Since downlighters are usually arranged in a grid pattern in practice, a rotationally symmetrical light intensity distribution is aimed for in order to evenly illuminate the plane of use.

For structural reasons, however, the second variant, with a linear light source installed perpendicular to the reflector axis, must often be used.

It is therefore the object of the present invention to create a lighting device in which an approximately rotationally symmetrical light intensity distribution can be achieved by arranging the lens-shaped light source perpendicular to the reflector axis.

This object is achieved by the features specified in the characterizing part of claim 1.

Advantageous developments of the invention are specified in the subclaims.
20

In the drawings shows:

Fig. 1 shows a cross section through a lighting device according to a first embodiment of the present invention with partial cross section;

Fig. 2 shows a cross section through a lighting device according to a second embodiment of the present invention, as well as an associated partial cross section in the right-hand part;

Fig. 3 shows a cross section through a lighting device according to a further embodiment of the present invention, with an associated partial cross section;

Fig. 4 shows a cross-section through a lighting device and schematically drawn beam paths;

Fig. 5 a schematic view of a mini-structuring in the form of grooves in a reflector wall (in planes perpendicular or parallel to the reflector axis);

Fig. 6 is a schematic view of a pot-shaped reflector, with zone-structured surface, seen from the opening side.

In the following, the present invention will be described using preferred embodiments with reference to the drawings.

In Figure 1, 1 designates a reflector of a lighting device. The pot-shaped reflector 1 consists of a base part 1a and a side part 1b and is constructed rotationally symmetrically to a reflector axis A. The inside of the reflector 1 is divided into two parts: on the one hand, a reflector surface 2 which is (aluminum) glossy mirrored and on the other hand, a partial area 3 which has a structured surface.

The partial area 3 comprises a first area 3a, which is located on the base part la of the reflector 1, and a second area 3b, which is located on the side part 1b of the reflector 1. The structured surface of the partial area 3 can, for example, be a sandblasted surface in terms of structure.

Through an opening 6 (see Fig. 4) in the transition area between the base part la and the side part lb of the reflector 1, two linear light sources 4, e.g. compact fluorescent lamps, in a flat design, are arranged next to each other symmetrically to the

Axis B is inserted. Axis B intersects reflector axis A approximately at a right angle.

An opening 5 of the reflector 1 is circular (Fig. 1 and 6) and the edge of the side part 1b of the reflector 1 is bent outwards in the area of this opening 5. A fastening hole for the reflector 1 is not shown in the drawings, but is located in the middle of the base part 1a of the reflector 1.

Figure 2 shows a further embodiment of the present invention, in which the light source 4 consists of four rod-shaped fluorescent tubes arranged in a square shape. The components that have already been described in connection with Figure 1 will not be explained further. In the right-hand part of Figure 2 it can be seen that the two fluorescent tubes of the light source 4 are arranged symmetrically to the axis B.

Figure 3 shows a further embodiment according to the invention; in this embodiment, two light sources 4 in a similar design to that in Fig. 2 are arranged next to one another symmetrically to the axis B.

Figure 4 shows the ray paths of two light beams, both of which emanate from the light source 4 and which are reflected at a point Pl or P2 on the inner surface of the reflector 1, whereby these two points Pl and P2 lie on a plane E that intersects the reflector axis A perpendicularly. Pl and P2 also lie in two planes that intersect 0 in the reflector axis A and are perpendicular to each other (partial section).

The left part of Figure 4 shows the ray path of a first light beam which emanates from the light source 4 and

·

·

• ·« • « * * •
··· • ··· • • · • · •
··· •

which is reflected on the reflector surface 2 at point Pl and then leaves the reflector 1 through the opening 5.

The right part of Figure 4 shows the ray path of a second light beam, which emanates from the light source 4 and how it was reflected on a reflective surface. The first light beam, for example, has an opening angle of approx. 35°,

while the second light beam has an opening angle of approximately 17° (the grey-shaded beam path of the second light beam shown relates to a reflector surface without structure). The reason for this deviation of the light intensity distribution from rotational symmetry is that different points (for example Pl and P2) which lie on the intersection line of the plane E which is perpendicular to the reflector axis (also rotational symmetry axis) "see" the light source 4 from different angles. This leads to different light scatterings - caused, among other things, by the dimensions of the light source and their position - which affect the light intensity distribution. The symbol ^v *' schematically indicates the beam path which is aimed for by the sandblasted surface of the partial area 3 in order to produce a beam of rays in P2 which is similar to that in Pl and thus an approximation of the desired rotationally symmetrical light intensity distribution.

This means that by structuring the surface of the reflector 1 in a partial area 3, the differences in light scattering, which are caused by the geometric dimensions and the arrangement of the light source, are compensated.

One way of forming sub-area 3 is to change the zonal reflection properties of the reflector surface. A further approximation can be achieved by areas or zones with direction-dependent scattering properties-5 . The most effective structures are those with direction-dependent

ger variable scattering width (Fig. 5, scattering angle &thetas;) , whereby

Scattering in different planes can be optimally adapted (compensated), ie an almost three-dimensional optimization can be achieved.
5

In Figure 5, as an example of such a mini-structure indentation with direction-dependent reflection properties, grooves are provided which have a depth t ₁ or t ₂ , whereby these grooves can be created, for example, by rotating a spinning tool about its axis of symmetry (for example with a profile knife). A variable scattering angle G ₁ or θ ₂ can, for example, be achieved via a variable groove depth t ₁ or t ₂ , whereby the variable groove depth can possibly be realized by eccentric rotation. A further improvement in the approximation to a rotationally symmetrical light intensity distribution can be achieved if the surface 2 is partially provided with grooves of variable depth which are perpendicular to the grooves in the partial area 3. These can, for example, be milled into the spinning tool. This enables better three-dimensional adaptation.

A schematic view from the opening side of the reflector 1 is shown in Figure 6. In the projection of the illustration, the opening 6 for the light source 4 can be seen and the partial area 3 is marked by the hatching. In the projection, the partial area 3 extends in the example in strip form over the entire diameter of the reflector 1 and runs at right angles to the arrangement of the linear light source 4. Depending on the surface structure, light sources 0 and their positioning options, the structured zone can also have other shapes and arrangements.

If in special cases a targeted asymmetry of the light intensity distribution is desired (e.g. wall illumination), this can

by an asymmetrical arrangement of the light source 4 relative to the axis B of the reflector 1, without additional changes to the shape or surface structure of the reflector 1 being necessary.
5

A lighting device comprises a pot-shaped reflector, in which a linear light source is arranged perpendicular to the reflector axis, with at least a partial area of the reflector surface having a differently structured surface. The partial area with a structured surface has a different reflectivity to the reflector surface, i.e. the partial area generates a larger and possibly differently oriented diffuse radiation or scattered radiation than the rest of the reflector surface. The reflection properties and shape of the partial area are determined by the geometric dimensions of the reflector, the shape and arrangement of the light source and by the requirements for blocking and adaptation to the rotationally symmetrical light intensity distribution. The reflector consists of a base part and a side part. Both can contain partial areas with different reflection properties.

Claims (13)

. NoMember 1395 · «» . MO!ler-Bore& Partne, Applicant: Metaprint GmbH "Lighting device" Our reference: M 4245 - kg / dk Claims 1. Lighting device with a pot-shaped reflector (1) in which a linear light source (4) can be arranged approximately perpendicular to the reflector axis (A), characterized in that at least a partial area (3) of the reflector surface (2) has a structured surface. 2. Lighting device according to claim 1, characterized in that the partial area (3) with a structured surface has a different reflectivity to the remaining reflector surface (2). 3. Lighting device according to claim 1 or 2, characterized in that the partial area (3) generates a larger and possibly differently oriented diffuse radiation or scattered radiation than the remaining reflector surface (2). 4. Lighting device according to one of claims 1 to 3, characterized in that the partial area (3) is determined by the geometric dimensions of the reflector (1), the arrangement and shape of the light source (4) and by the form of the masking and adaptation to the rotationally symmetrical light intensity distribution. 5. Lighting device according to one of claims 1 to 4, characterized in that the partial area (3) has a sandblasted surface as a structure. 6. Lighting device according to one of claims 1 to 5, characterized in that the reflector (1) is rotationally symmetrical. &Lgr;&dgr;. November "1995 » ·· . Müjler-Bor^§&igr; Pjirtpgr - 2- 7. Lighting device according to one of claims 1 to 6, characterized in that the reflector surface (2) is an aluminum-glossy surface. 8. Lighting device according to one of claims 1 to 7, characterized in that the light source (4) is linear, e.g. a compact fluorescent lamp. 9. Lighting device according to one of claims 1 to 8, characterized in that the partial area (3) extends over the bottom and side part of the reflector (1) when viewed in projection and is perpendicular to the axis of the linear light source (4). 10. Lighting device according to one of claims 1 to 9, characterized in that the structured surface of the partial area (3) is designed by grooves (Fig. 5) with different shapes, cross sections and positions. 11. Lighting device according to claim 10, characterized in that the depth (t 1 , t ₂ ) of the grooves is variable and they have a differently designed profile. 12. Lighting device according to claim 8, characterized in that the rod-shaped light sources are arranged approximately perpendicularly with respect to the reflector axis (A). 13. Lighting device according to claim 10 and 11, characterized in that the partial area (3) is distributed in a non-contiguous manner with different structures over different areas of the reflector (1).