DE102016123158A1 - Luminaire, multi-luminaire arrangement and method of making a luminaire - Google Patents

Abstract

The presented principle relates inter alia to a luminaire, an arrangement with a plurality of such luminaires and a method for producing a luminaire. A luminaire (1) comprises an organic light-emitting diode (2) which is set up to emit light having an effective emission surface (E). An anti-dazzle structure (3) integrated into the organic light-emitting diode (2) is arranged at least partially on the emission surface (E) and arranged to glare the organic light-emitting diode (2) for emission angles above a glare angle α. The light emitted from the organic light emitting diode (2) emerges from the lamp (1) corresponding to an effective radiating surface (F). In this case, the anti-dazzle structure (3) has at least one cell (31) with an edge (32) extending from the emission surface (E) to the emission surface (F), and the at least one section of the emission surface (F) and a portion of the Emission surface (E) as a function of a cutting line (A) at least partially encloses. The edge (32) has a height B, which is dependent on the cutting line (A) and the glare angle α.

Description

The present invention relates inter alia to a luminaire, an arrangement with a plurality of such luminaires and a method for producing a luminaire.

Area light sources such as organic light emitting diodes emit light in a wide solid angle of up to 180 °. Often, however, a defined beam guidance is desired in order to deblade the light source or to illuminate objects in a more targeted manner.

Organic light-emitting diodes are area light sources that are approximately Lambertian emitters. That is, the light emitting diodes radiate approximately with a cos ² θ characteristic, where θ denotes the emission angle. Thus, organic light emitting diodes also emit a significant amount of radiation at angles nearly parallel to an emitting surface. On the other hand, the lighting conditions, for example for office space, are normalized and regulated. For example, at angles above 60 °, a luminance must not exceed 1500 nits. In other words, a light source, for example for office lighting, must be glare-free to large emission angles.

For glare reduction of surface light sources, for example, beam-forming foils, (Jungbecker) plates or macroscopic elements such as metal sheets and reflectors are known. For example, in conventional organic light-emitting diodes, a beam-forming film is placed on the organic light-emitting diode and provided with a light-scattering layer. Such solutions usually lead to significant light losses. For example, the glare control of an organic light-emitting diode with a beam-forming film of 80% reflectivity leads to an efficiency loss of about 25%. Plates and sheets require an elaborate production and often limit the size of the design of the light sources and can also affect the aesthetics undesirable.

Another problem with efficient glare control is the duck conservation. A reduction of the entendue without self-illumination of the source is always associated with a loss of light. Entendue is due to rotationally symmetric emission through the context n ² πsin ² θ · A

• – θ = 15°, für einen Spot mit 30° Durchmesser,
• – θ = 90°, für eine Lambert’sche OLED, und
• – θ = 60°, für eine entblendete OLED mit einem Entblendungswinkel α und α = θ.

Described, where n is the refractive index (hereinafter n = 1), θ the emission angle and A the emission surface. Typical emission angles θ are, for example:

• - θ = 15 °, for a spot with 30 ° diameter,
• - θ = 90 °, for a Lambertian OLED, and
• - θ = 60 °, for a blended OLED with a glare angle α and α = θ.

In order to be able to discover a luminaire without loss, it is necessary to obtain the Entendue according to the above context. For a Lambert OLED with an emission area A of 100 cm ² , a Entendue of 314 cm ² sr. For a glare reduction to 60 °, the surface A must be increased accordingly to 140 cm ² , in order to achieve approximately the same Entendue value.

An object to be solved is to provide a luminaire or arrangement of luminaires and a method for producing the same, in which an organic light-emitting diode can be used efficiently and without glare.

This object is achieved inter alia by the subject matters of the independent claims. Further developments are the subject of the dependent claims.

In accordance with at least one embodiment, a luminaire comprises an organic light-emitting diode and an anti-glare structure integrated into the organic light-emitting diodes. The luminaire is set up to produce visible light, for example white light. Preferably, the light can be used for general lighting purposes, for example as a ceiling light or pendant light, for the lighting of a room. Possible rooms include, for example, living rooms or workrooms.

The organic light emitting diode is configured to emit light having an effective emission area. The luminaire may comprise one or more organic light-emitting diodes. Visible light, for example white light, is thereby generated in an organic layer sequence and emitted over an area of the organic light-emitting diode.

From the effective emission surface, the light generated in the organic light emitting diode is radiated. The effective emission surface may be a real boundary surface of the organic light-emitting diode, it may also be flat or curved. Likewise, the effective emission area may be a notional area corresponding to an area of the organic light emitting diode in plan view. In particular, the effective emission area is a projection of a light emitting area of the organic light emitting diode onto a plane perpendicular to a main emission direction of the organic light emitting diode. In this case, this plane cuts the organic light-emitting diode preferably in at least one point, so that this level is the organic light-emitting diodes touched from a direction opposite to the main emission direction, in particular touched tangentially.

Furthermore, the luminaire comprises a plane or curved effective radiating surface. The effective radiating surface is an area of the luminaire from which the light emitted by the luminous diode emerges from the luminaire. The effective radiating surface may be a real boundary surface of the luminaire formed by a solid material. Preferably, however, it is a fictitious surface, which results in a plan view of the lamp. The effective radiating surface is, for example, a sum of the effective emission surface of the organic light-emitting diode and a surface of the anti-glare structure, seen in plan view. In this case, the emission surface of the organic light-emitting diode and the surface of the anti-glare structure, seen in plan view, preferably do not overlap, but touch, for example.

The anti-glare structure is arranged at least partially on the emission surface of the organic light-emitting diode. The integration of the anti-glare structure on the organic light-emitting diode can be effected, for example, by arranging the anti-glare structure on the organic light-emitting diodes by injection molding or by means of a 3-D pressure. Furthermore, the anti-glare structure can be applied to the light-emitting diode, for example impressed in a surface.

The anti-glare structure is designed for the insertion of the organic light emitting diode. In particular, the anti-glare structure is provided for emission angles above a glare angle α. The anti-glare structure can be the same for all directions. The glare angle preferably relates to the main emission direction and / or to a solder to the effective emission surface of the organic light-emitting diode. At angles greater than the glare angle, no light is emitted from the organic light emitting diode. The glare angle can be a maximum of 60 °. In particular, the glare angle is between at least 20 ° and at most 60 °. For example, the glare angle is 60 °.

The anti-glare structure has at least one cell. The cell includes an edge that extends from the emission surface toward the emission surface and that at least partially surrounds at least a portion of the emission surface and a portion of the emission surface. The enclosed emission surface or emission surface depends on a cutting line. Furthermore, the edge has a height B, which is dependent on the intersection line and the glare angle α.

The cutting line has, for example, a length A, which is measured from an edge of the emission surface facing away from the edge to the edge of the facing emission surface, seen in plan view. The cutting line can be a diameter of a circle or an edge length of a rectangle or other polygonal geometries. Seen in plan view, a cutting line can be laid through the emission surface of the organic light emitting diode.

For example, the intersection line is the longest possible intersection line, relative to a particular point on the edge of the emission surface, at which point the height B of the cell is to be determined. Alternatively or additionally, the cutting line is oriented perpendicular to the location at which the height B of the cell is to be determined. Starting from this point at which the height of the cell is to be determined, the intersection line is calculated to the further intersection of this intersection line with the emission surface and on the other hand to the intersection of this intersection line with the Abstrahlflächenbegrenzung, to this point, in which the height of the cell is to be determined, borders.

In the case of the luminaire described here, the anti-glare structure integrated in the organic light-emitting diode leads to an effective glare reduction. In this case, the Entblendungsstruktur created a larger effective radiating surface, whereby a targeted Etendue magnification can be achieved. Glare-induced losses can be minimized. Thus, described here glare-free lights, compared to conventional lights with organic light emitting diodes, efficient. Furthermore, a lower overall height compared to macroscopic elements such as sheets or reflectors is possible. This allows more degrees of freedom in design and design of the lamp.

In accordance with at least one embodiment, the portion of the emission surface is surrounded all around by a lower edge of the cell. Furthermore, the portion of the radiating surface is surrounded all around by an upper edge of the cell. The edge of the cell is in cross-section perpendicular to the emission surface, ie from the upper edge to the lower edge, completely or concave in the middle. For a ratio between an area E1 of the section of the emission surface and a surface F1 of the section of the emission surface is valid with a tolerance of at most 10%: F1 = E1 / sin ² (α). The border defines a wall of the cell whose shape determines the emission surface and the emission surface. For example, the edge The cell is set up to fan out from the bottom edge to the top edge. Preferably, the edge increases in the direction away from the emission surface and in monotone or strictly monotone, as seen in cross-section. The radiating surface is larger in proportion to the emission surface (or corresponding portions thereof). The shape of the edge of the cell allows to set a minimum cell height and cell area. As a result, a component efficiency can be kept high and a component size can be further reduced.

According to at least one embodiment, the area E1 is dependent on a length A of the intersection line. For the height B of the edge applies in a direction perpendicular to the emission surface with a maximum tolerance of 10%: B = tan (90 ° - α) ∙ A. In this case, A is a length of the cut line from an edge facing away from the edge of the emission surface to the edge of the facing radiating surface, seen in plan view.

The relationship for the height of the edge applies, for example, to every longest line of intersection and along the entire circumference of the edge around the emission surface, in particular with a tolerance of at most 10% or 5% or 2% or 1% or 0.5% or exactly, within the manufacturing tolerances. This may mean that with a non-rotationally symmetric shaped emission surface, the height of the cell varies around the emission surface.

In accordance with at least one embodiment, the organic light-emitting diode has a current distribution structure. The edge of the cell extends at least in sections along the current distribution structure. Usually, the layer structure of an organic light-emitting diode comprises a current distribution structure of printed conductors, also called busbars, in order to compensate for a drop in radiation intensity from the edges to the center. The power distribution structure may comprise regular rasters, such as a honeycomb structure, or a raster of other polygons. Along the tracks, the organic light emitting diode can not emit light. By tuning the anti-glare structure or the cell to parts or the entire current distribution structure, it is possible to use regions of the organic light-emitting diode which in any case do not emit. An additional loss of light can thus be prevented or reduced.

According to at least one embodiment, as seen in plan view, the portion of the emission surface is completely within the portion of the emission surface. That is, the portion of the emission surface is surrounded by the portion of the emission surface and the edge of the cell.

In accordance with at least one embodiment, the section of the emission surface and the section of the emission surface are each circular surfaces. Both circular surfaces preferably have the same center.

In accordance with at least one embodiment, the portion of the emission surface and the portion of the emission surface are each surfaces of a uniform polygon. For example, the sections may be in the shape of a triangle, rectangle, pentagon, hexagon, etc. Preferably, the section areas have the same geometric center of gravity and are uniform polygons.

In accordance with at least one embodiment, the anti-glare structure has additional cells. In this case, the line screens are arranged in a planar manner on the emission surface to form a grid and in each case surround further sections of the emission surface and the emission surface. By arranging several cells into a grid, the size of the component can be further reduced, for example compared to a single cell.

In accordance with at least one embodiment, the cells are arranged in a regular grid on the emission surface to the grid. In this way, there is only a slight increase in a total thickness of the organic light emitting diode.

In accordance with at least one embodiment, a maximum height of the edges of the cells across the grid is constant.

According to at least one embodiment, the emitting surface of the organic light emitting diode is curved and the maximum height of the edges of the cells is dependent on a curvature of the emission surface across the grid, for example, the height of a bending radius is dependent. Organic light-emitting diodes are flexible to some extent and can be arched. This opens up further degrees of freedom for the design of luminaires.

According to at least one embodiment, an arrangement comprises a plurality of lamps of the type described above. These are arranged laterally side by side in a common plane.

By way of example, the arrangement comprises a plurality of organic light-emitting diodes which represent approximately a segmented organic light-emitting diode.

In at least one embodiment of the arrangement, the lights are mounted in a common plane. Within this level, the luminaires are arranged next to one another and preferably do not overlap one another, as seen in plan view on this level. It is possible that the lights in the arrangement and densely packed within this plane, so that only a narrow gap, for example with an average width of at most 10% or 5% of a mean diameter of the radiating surfaces, is formed between adjacent luminaires. Likewise, neighboring lights, especially radiating surfaces, in places or touch all around. Preferably, the arrangement comprises a plurality of luminaires with rectangular, circular or hexagonal radiating surfaces.

In accordance with at least one embodiment, a method for producing a luminaire comprises at least the following steps.

There is provided an organic light emitting device configured to emit light having an effective emission area. In a further step, a defibrillation structure is integrated into the organic light-emitting diode. The anti-glare structure is at least partially arranged on the emission surface. Furthermore, the anti-glare structure is set up to deblast the organic light-emitting diode for emission angles above a glare angle α.

In accordance with at least one embodiment, the anti-glare structure is applied to the organic light-emitting diode by at least one of the following methods or method steps: by injection molding, by means of a 3-D pressure and / or by impressing.

According to at least one embodiment, the anti-glare structure is at least partially coated with a reflective material. In this case, the reflectance refers to the light emitted by the organic light-emitting diode. The reflectivity in the emission region of the light-emitting diode is preferably 95% or higher. The reflective material can be applied both on one side of the anti-glare structure facing away from the organic light-emitting diode and on the opposite side.

Hereinafter, the principle presented here will be explained in more detail with reference to drawings based on embodiments. The same reference numerals indicate the same elements in the individual figures. However, there are no scale relationships shown, but individual elements can be shown exaggerated for better understanding.

Show it:

1 to 4 schematic representations of embodiments of luminaires described here.

An embodiment of a lamp 1 is in a side view in 1 shown.

The lamp 1 includes an organic light emitting diode 2 , The organic light-emitting diode 2 further comprises an organic layer structure which is in operation of the luminaire 1 emitted visible light. As the organic light emitting diode 2 represents a surface radiator, the emission takes place through a main surface 22 of the layer structure. On the main surface of the organic light emitting diode 2 is a glare-free structure 3 integrated. The anti-glare structure 3 will be on the surface 22 the organic light emitting diode 2 mounted or integrated. This can be done by different methods, for example by injection molding, 3-D printing or by imprinting.

For example, the defoaming structure may be 3 to act a mirrored injection molding mask. An injection molding mask can be separate from the organic light emitting diode 2 getting produced. In a further method steps, these can then be coated and encapsulated with a highly reflective material, such as silver. In this way, for emission wavelengths of the organic light emitting diode 2 an effectiveness of more than 95% achievable and losses can be kept low. An injection molding mask made in this way can be applied to the surface 22 the organic light emitting diode 2 glued and integrated so.

Alternatively, the anti-glare structure 3 directly on the surface of the organic light emitting diode 2 be applied. For example, a 3-D printing process allows the anti-glare structure 3 directly to the substrate of the organic light emitting diode and also to mirror.

It is also possible, the Entblendungsstruktur 3 before coating with reflective material in the substrate or the surface 22 the organic light emitting diode 2 to shape. This is possible with glass and plastics. Finally, the so-called defibrillation structure 3 be vaporized with the highly reflective material, such as silver or aluminum.

The anti-glare structure 3 includes a variety of cells 31 , Every cell 31 includes a border 32 extending to a maximum height B across the surface of the organic light emitting diode 2 extends. Further, an area of each cell 31 characterized by a cutting line. The cells 31 are in a grid 35 in a regular grid on the surface of the organic light emitting diode 2 arranged.

The anti-glare structure 3 serves to glare the organic light emitting diode 2 For Emission angle above a glare angle α. It is characterized by the structure of the individual cells 31 the glare angle α predetermined. The relationship between the glare angle α and the structure of the cells 31 will be in greater detail with respect to the 3 and 4 explained in more detail. Generally, the maximum height B cells depends 31 the anti-glare structure 3 from a length A of the cut line. About the context B = tan (90 ° -α) · A let the height B and length A for a glare angle α in a grid 35 to calculate. An example calculation is in 1B summarized in a table. This shows cells with heights B in millimeters for different cutting lines of length A, also given in millimeters. For example, this results in a grid of 60 °, a grid 35 , which is about 33% of the surface of the organic light emitting diode 2 busy. A maximum height B of one of the cells 31 the anti-glare structure 3 of 1.2 mm thus results in a cell size with a length A of the cutting line of 2 mm.

The 2A and 2 B each show plan views of embodiments of a Entblendungsstruktur 3 based on a grid 35 with circular cells 31 , 2C shows a plan view of an embodiment with a Entblendungsstruktur 3 based on a grid 35 with hexagonal cells 31 ,

The anti-glare structure 3 out 2A includes a rectangular grid 35 from each circular cells 31 , also called pixels. This is shown by the respective cells 31 the same radius or diameter and are arranged regularly to each other. Between the individual cells 31 go the edges 32 the individual cells into each other and to a certain extent form a blank space over which no light of the underlying organic light emitting diode 2 can be emitted. The cells are preferred 31 or their edges 32 arranged to each other so that they have a current distribution structure of the underlying organic light emitting diode 2 mostly cover. In this way it is possible, for example, 33% of the surface of the organic light emitting diode 2 with the power distribution structure and by the anti-glare structure 3 to cover. That's how lights are made 1 with a size of up to 50 × 50 cm ² finished and with the Entblendungsstruktur 3 entblenden. 2 B shows, for example, an embodiment with a square Entblendungsstruktur 3 ,

2C shows a further embodiment of the anti-glare structure 3 , also for example with a square base. In this embodiment, the grid comprises 35 each hexagonal cells 31 or pixels that are also equally spaced. In such a hexagonal lattice 35 For example, the cells or pixels may be arranged with less variation than, for example, in a square or circular grid. In particular, it is customary to design the current distribution structure also hexagonal, so that a hexagonal lattice 35 can cover the power distribution structure without forming larger void areas without the possibility of light emission.

In alternative embodiments, not shown, the cells may have further basic patterns or polygons. For example, the cells may have a triangular, square or pentagonal outline. Furthermore, it is conceivable that the base area of the respective cells is different across the grid and also describes different geometric figures. In this way, there is a greater freedom in the design of the lamp 1 , Furthermore, the organic light emitting diode 2 also be curved and the cells are adapted to this curvature.

3A shows an embodiment of a cell 31 the light 1 in a plan view and 3B shows the cell 31 in a sectional view.

The cell 31 As seen in plan view, a section E1 encloses an emission surface E of the organic light-emitting diode 2 , In this embodiment, the portion E1 of the emission surface E is a circular light exit surface 20 , which is, for example, planar and planar. However, this can also be curved. By several in the anti-glare structure 3 arranged cells 31 arise in this way a plurality of light exit surfaces 20 , which sum the effective emission area E of the light emitting diode 2 determine. The cells are preferably provided with a reflective material such as silver or aluminum.

Seen in plan view, each cell revolves 31 one of the light exit surfaces 20 with a constant width, so the cells 31 seen in plan view, each having a circular outer edge and a circular inner edge. Seen in plan view is through the respective cell 31 and the corresponding light exit surface 20 a section F1 of a radiating surface F of the luminaire 1 educated. The radiating surface F or its sections F1 is a flat, fictitious surface. The radiating surface F is thus due to the anti-glare structure 3 defined along edges 32 the individual cells 31 from the emission surface E or its portions E1, 20 go to the radiating surface F.

The cells 31 are concave in shape when viewed in cross section, moving in the direction away from the Emission area E, 20 the edge 32 the cell 31 continuously enlarged. For example, the cells point 31 a lower edge 33 which comes to lie in the plane of the emission surface E, and an upper edge 34 on, which comes to lie in the plane of the radiating surface F. The edge 32 is, in cross-section perpendicular to the emission surface E, from the upper edge 34 to the bottom 33 is completely concave or concave. For example, the cells point 31 Seen in cross section, each two straight sections, which by a kink 6 are separated from each other (see 4B ).

Through the cells 31 the anti-glare structure 3 is achieved that for emission angle above a glare angle α the lamp 1 is glare-free. There is no light from the lamp 1 with angles greater than the glare angle α, which is relative to a perpendicular 36 the emission area E1, 20 out of the lamp 1 measured out. This is achieved, on the one hand, by the cells each having a maximum height B and a concave edge 32 exhibit. Preferably, the maximum height B is the same for all cells. Generally, however, the height can vary from cell to cell.

In order to obtain high efficiency and low component height, the size of the sections F1 of the radiating surface and the height B of the cells depend 31 from the size and the shape of the corresponding portions E1 of the emission surface E from. For a cell 31 and a radius r _{F1 of} the emission surface F thus applies with respect to a radius v of the section E1 of the emission surface E, as a function of the glare angle α: r _F1 = r _E1 · sinα.

The circular emission surface E1 seen in plan view, 20 has a diameter D equal to twice that of r _E1 .

The maximum height B of the cells 31 results from a length A of the intersection line, wherein the intersection line lies within a plane of the emission surface E1. The length A is determined starting from a point X, at which the height of each cell 31 is to be determined. Starting from this point X, the length A extends to an opposite, furthest point of intersection of the line of intersection with an outer edge of the emission edge E1, see the point Y. Further, the length A extends from the point Y and beyond the point X to an outer edge of the respective radiating surface F1, which is located at the point X. Through the line of intersection with the outer edge of the radiating surface F1 a point Z is formed. The length L thus extends from the point Y to the point Z, that of the cell 31 opposite edge of the emission edge E to the edge of the facing radiating surface F1, seen in plan view. For height B at point X, the following applies: B = A · tan (90 ° -α).

The glare angle α is for example given by the intended use of the lamp 1 which lies approximately in an office room lighting.

In particular, the glare angle α can amount to a maximum of 60 °. In particular, the glare angle can be between at least 20 ° and at most 60 °. For example, the glare angle α is in the 3B represented cell 31 60 °. The glare angle α is determined by the length of the intersection line A and the height B of the cell 31 Are defined. Advantageously, light rays R hit the edge 32 the anti-glare structure 3 and are absorbed or reflected there when the light rays R the luminous surface 20 relative to the lot 36 at an angle greater than the glare angle α is left.

When the rays of light that hit the edge are reflected, the angle of the light beam becomes a perpendicular 36 downsized, since the edge 32 on which the light beam R is incident, not perpendicular to the illuminated area 20 runs. In particular, the edge runs 32 a cell 31 such that the angle between the illuminated area 20 and the edge 32 greater than 90 °. For example, a light beam may be on the edge several times 32 be reflected before the light beam R the cell 31 through the radiating surface F leaves. Advantageously, only light rays pass through the emission surface F of a cell whose angle to the solder 36 is equal to or smaller than the glare angle α.

In the 4A and 4B are sectional views of cells 31 shown. Furthermore, exemplary beam paths are shown, which are the anti-glare function of the cell 31 illustrate. In 4A it can be seen that the edge 32 the cell 31 seen in cross-section is formed by a single straight line section. This results in an emission limit angle of 30 ° for the radiation R, starting from a point X at a corner of the emission surface E1. By specular reflection at the reflective edge 32 However, rays with a much smaller angle, for example 22 °, can also be emitted. This can be done by the kink 6 in the margin 32 be reduced (see 4B ). Incidentally, the radiating surface F1 and the height B are set, as explained above. The determination of the emission surface E1 and the emission surface F1 and the height B is preferably carried out by simulation on the basis of the above-described optical relationships.

This patent application claims the priority of German patent application 102015120772.9 , the disclosure of which is hereby incorporated by reference.

LIST OF REFERENCE NUMBERS

1

lamp

2

organic light emitting diode

3

Entblendungsstruktur

6

kink

20

light area

22

Main surface of the organic light emitting diode

31

cell

32

edge

33

lower edge

34

upper edge

35

grid

36

solder

A

Length of the cutting line

B

Height of the cell

D

diameter

e

effective emission area

E1

Section of the effective emission area

F

effective radiating surface

F1

Section of the effective radiating surface

R

beam of light

X

Point

Y

Point

Z

Point

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 102015120772 [0064]

Claims (15)

Lamp ( 1 ) comprising: - an organic light emitting diode ( 2 ) arranged to emit light with an effective emission area (E), - one in the organic light emitting diode ( 2 ) integrated anti-glare structure ( 3 ), which is arranged at least partially on the emission surface (E), and which is adapted to glare the organic light emitting diode ( 2 ) for emission angles above a glare angle α, - an effective radiation surface (F) of the light ( 1 ), from which the of the organic light emitting diode ( 2 ) emitted light from the lamp ( 1 ), wherein - the anti-glare structure ( 3 ) at least one cell ( 31 ) with a border ( 32 ) which extends from the emission surface (E) to the emission surface (F) and at least partially surrounds at least a portion of the emission surface (F) and a portion of the emission surface (E) in dependence on a cut line (A); Edge ( 32 ) has a height B, which is dependent on the cutting line (A) and the glare angle α, and the glare angle α is a maximum of 60 °. Lamp ( 1 ) according to the preceding claim, wherein - the portion of the emission surface (E) is surrounded by a lower edge ( 33 ) of the cell ( 31 ), - the portion of the radiating surface (F) all around from an upper edge ( 34 ) of the cell ( 31 ), - the edge ( 32 ) of the cell ( 31 ), in cross-section perpendicular to the emission surface (E), from the upper edge ( 34 ) to the bottom edge ( 33 ) is concavely shaped on average, and for a ratio between an area E1 of the portion of the emission surface (E) and a surface F1 of the portion of the emission surface (F) with a tolerance of at most 10%: F1 = E1 / sin ² (α). Lamp ( 1 ) according to the preceding claim, wherein - the surface E1 depends on a length L of the line of intersection (A), and - for the height B of the edge ( 32 ) in a direction perpendicular to the emission surface (E) with a tolerance of at most 10%: H = tan (90 ° - α) · L. Lamp ( 1 ) according to one of the preceding claims, wherein - the organic light-emitting diode ( 2 ) a power distribution structure ( 21 ), and - the edge of the cell ( 31 ) at least in sections along the power distribution structure ( 21 ) runs. Lamp ( 1 ) according to one of the preceding claims, wherein seen in plan view, the portion of the emission surface (E) lies completely within the portion of the emission surface (F). Lamp ( 1 ) according to one of the preceding claims, wherein the portion of the emission surface (E) and the portion of the emission surface (F) are each circular surfaces. Lamp ( 1 ) according to one of the preceding claims, wherein the portion of the emission surface (E) and the portion of the emission surface (F) are each surfaces of a uniform polygon. Lamp ( 1 ) according to one of the preceding claims, wherein the anti-glare structure ( 3 ) other cells ( 31 ), the cells ( 31 ) grid-shaped on the emission surface (E) to a grid ( 35 ) are arranged and in each case enclosing sections of the emission surface (F) and the emission surface (E). Lamp ( 1 ) according to the preceding claim, wherein the cells ( 31 ) are arranged in a regular grid on the emission surface (E). Lamp ( 1 ) according to one of the preceding claims, wherein a maximum height (Hmax) of the edges ( 32 ) of the cells ( 31 ) over the grid ( 35 ) is constant. Lamp ( 1 ) according to one of the preceding claims, wherein the emission surface (E) of the organic light emitting diode ( 2 ) and the maximum height (Hmax) of the edges ( 32 ) of the cells ( 31 ) over the grid ( 35 ) depends on a curvature of the emission surface (E). Arrangement with several lights ( 1 ) According to at least one of the preceding claims, wherein the lights are arranged laterally side by side in a common plane. Method for producing a luminaire ( 1 ) comprising the steps: - providing an organic light-emitting diode ( 2 ) arranged to emit light having an effective emission area (E), - integrating a deblending structure ( 3 ) in the organic light emitting diode ( 2 ), which is arranged at least partially on the emission surface (E), and which is adapted to glare the organic light emitting diode ( 2 ) for emission angle above a glare angle α, wherein the glare angle α is a maximum of 60 °. Method according to the preceding claim, wherein the anti-glare structure ( 3 ) by at least one of the following process steps on the organic light emitting diode ( 2 ) is applied: - by injection molding, - by means of a 3D printing, and / or - by imprinting. Method according to one of the preceding claims, wherein the anti-glare structure ( 3 ) is at least partially coated with a reflective material suitable for the organic light emitting diode ( 2 ) has a reflectivity, in particular a reflectivity, which is higher than 95%.

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