WO2017025283A1 - Lighting assembly - Google Patents

Abstract

The invention relates to a lighting assembly, in particular a lighting surface, comprising at least one organic light-emitting diode (OLED1) having a planar layer structure on a substrate. The layer structure has a first electrically conductive conduction layer, a second electrically conductive conduction layer, and an electroluminescent functional layer arranged therebetween, which has an organic semiconducting material. The layer structure also has at least one structured layer having a line structure (1). The line structure (1) of the structured layer is arranged in accordance with a perspective image of a three-dimensional object on or near at least one of the conduction layers, selected from the first and the second conduction layers.

Description

description

Beieuchtungsanordnung

The present invention relates to a Beleuchtungsanord ^¬ tion, in particular a luminous surface.

Organic light emitting diodes, or OLEDs are thin luminous layer ^¬ components made of organic semiconducting materials, and are used for example as light-emitting surfaces for a variety of lighting applications. As a rule, an OLED comprises a layer structure comprising a substrate, a first electrically conductive line layer (eg

Indium tin oxide, chromium-aluminum-chromium (CrAlCr) or other metals and alloys) and a second likewise electrically conductive e.g. metallic conductor layer (e.g., aluminum, silver, ...). Furthermore, a passivation layer can be provided on one or both conductor layers. Between the two conductor layers is an electroluminescent functional layer with an organic semiconductive material, which can emit light as an active layer during operation of the OLED. The layers of an OLED are typically enclosed by an encapsulation and thus protected from environmental influences.

The conductivity of the conductor layers, in particular of transparent conductor layers, can be influenced and improved by further layers. For example, by additional metallic line structures (so-called

Busbars), which are introduced on or him the conductor layers, a more homogeneous luminance distribution of the OLED can be achieved. The busbars are structured layers that take on an additional power line. In doing so, The further layers are applied directly to the conductor layers or to the functional layer. However, other intermediate layers may be provided, which should be expressed by the term "near".

However, the advantages of the further structured layers and in particular of the busbars are opposed to the fact that they often unintentionally influence or change the visual impression of an OLED. Especially in the automotive sector, customers want a three-dimensional lighting surface, which consists of one or more OLEDs and implements certain design specifications. Busbars, which are mostly used for a homogenous luminance distribution, often contradict this desire. In the near future, it will not be possible to replace the currently essentially two-dimensional OLEDs with flexible, three-dimensional OLEDs. Typical OLEDs can usually bend only in a preferred direction and are thus limited for a three-dimensional design can be used. Therefore, various ^¬ dene area OLED segments are used in vie ^¬ len demos taillight for motor vehicles and to dreidimensiona ^¬ len illumination arrays arranged to achieve impression so a 3-D.

It is an object of the present invention, a lighting ^¬ arrangement, in particular a light-emitting surface, indicate the egg ^¬ NEN improved three-dimensional impression possible.

According to one embodiment includes a Beleuchtungsanord ^¬ voltage, in particular a light-emitting surface, at least one organic ^¬ specific light-emitting diode. The light-emitting diode has a laminar layer structure on a substrate. The layer structure also includes ^¬ a first electrically conductive line ^¬ layer and a second also electrically conductive Conductive layer. Between the conductor layers, an electroluminescent functional layer with an organic semiconducting material is provided. Furthermore, the layer structure has at least one structured layer with a Li ^¬ nienstruktur. The line structure of the structured

Layer is disposed in the vicinity of at least one of the conductor layers selected from the first and second conductor layers. The arrangement of the line structure takes place in accordance with a perspective image of a three-dimensional object on or in the vicinity of at least one of the line layers.

The structured layer extends at least partially over a main surface of the organic light-emitting diode. In this case, the structured layer may have one or more line structures which are connected to one another or are separated from one another. The line structures can be defined in a regular manner by geometric sections or can also have a design preset pattern or a predetermined structure. For example, the structured layer defines recesses on the conductor layers or the functional layer and, as it were, forms a frame structure with linear walls. The line structure determines the frame to a certain extent and usually has a certain height, width and elongated extent. For example, the recesses formed between the line structure can be filled with further layers and also have at least parts of the electroluminescent functional layer. The structured layer or the line structure may generally comprise a conductive, semi-conductive or non-conductive material. The arrangement and shape of the structured layer or the line structure is defined by a perspective image. The term perspective illustration is to be understood below in terms of illustrative geometry. For example, the perspective image is a projection onto a main surface of the (planar) organic light-emitting diode. Such a projection can be defined, for example, with the means of central projection. The perspective image underlying the illumination assembly images one or more three-dimensional objects or bodies onto a major surface of the organic light emitting diode. The perspective illustration can to be cut from ^¬ as defined and different mapping rules de ^¬ finishing on partial areas of the organi ^¬ rule LED. On the one hand, perspective is generally due to the convergence of image lines of parallel object lines (eg, parallel edges of a cube) at a point on the horizon of the image plane (vanishing point) and, on the other hand, through the

Smaller images are marked with increasing distance of the object from the image plane (foreshortening).

The term "major surface" of the surface character of an organic light emitting diode will hereinafter be characterized, for an organic light emitting diode is a FLAE ^¬ chenstrahler and can thus be used as light emitting area ^¬ the. In this case, a main surface curved along a preferred direction or be flat.

Using the structured layer and its line structure, a three-dimensional impression can be achieved with an organic light-emitting diode. The perspective image can be a perspective or a three-dimensional effect targeted and set according to design specifications. In contrast to conventional three-dimensional arrangements of several two-dimensional OLED segments, the three-dimensional impression is already produced with a single OLED, since the structured layer and the line structure are part of the organic light-emitting diode itself.

According to a further embodiment, the structured layer comprises at least one metal layer, in particular an electrically conductive busbar and / or an electrical supply line.

Use of an electrically conductive metal layer, wherein ^¬ game as a busbar or an electrical supply line is influenced within the organic light-emitting diode the power supply and current guide. Such structures are often provided on an organic light emitting diode and can influence the optical impression of the diode unintentionally. On the basis of the perspective image, however, such structures can be deliberately included in the design or in a three-dimensional impression of the lighting arrangement without having to provide further structures on the organic light-emitting diode or additional auxiliary structures outside the organic light-emitting diode. Furthermore, the metal structure can be used to influence further parameters of the lighting arrangement. By suitable conductivity due to the layer structure of the brightness of the or ganic ^¬ light emitting diode can for example be influenced and be involved in achieving the three-dimensional effect with.

According to a further embodiment, the line structure has at least one vanishing point. The vanishing point or even several vanishing points are a suitable means of representing lozenge geometry, in particular the central projection, in order to achieve a perspective or a three-dimensional effect. A vanishing point can also be emphasized and emphasized by further means of representation, for example by a tuned brightness or a color gradient as well as line structures of different widths.

According to a further embodiment, the organic

LED is divided into several sub-areas by means of the line structure. Each of the faces is framed at least teilwei ^¬ se and according to the perspective illustration of sections of the line structure.

In this case, the partial surfaces can be interconnected by the line structure and / or form regular geometric figures. In general, however, the sections of the line structure need not be interconnected.

The partial surfaces assist in their relative arrangement of the three-dimensional impression which is formed when viewing the illumination arrangement and is defined geometrically by the perspective Abbil ^¬ dung. The term "geometric figure" is to be understood as meaning a structure or combination of a plurality of structures comprising straight lines, rectangles, triangles, polygons and / or circles, but in principle also complicated subsets of regular or irregular geometric objects should be included.

For example, the organic light emitting diode may be classified as hexagons, different size in a multi ^¬ number of polygons. A central hexagon can define a vanishing point from which the others start Group hexagons and zoom in or out depending on the distance to the center. Another example could be the honeycomb surface of a football.

According to a further embodiment, the sections frame the partial surfaces according to regular geometric figures. In particular, the sections frame the partial surfaces according to regular plane geometric figures.

According to a further embodiment, the partial surfaces are arranged at least partially concentric with one another. In ^¬ play, the line structure is the processin ^¬ reindeer, or dictated by concentric Krei ^¬ se, the individual sections of the line structure by concentric rectangles. Due to the concentric design, for example, results in a tunnel-like perspective. By suitable definition ei ^¬ nes or more vanishing points, these sections or sub-areas can set a preferential direction of the three-dimensional effect.

In accordance with a further embodiment, the sections of the line structure become thinner or thicker in accordance with the perspective illustration along the line structure or in sections. In particular, the portions to which we ^¬ nigstens a vanishing point will be towards or away from thinner or thicker.

The three-dimensional effect achieved by the perspective arrangement of the line structure can be further supported by the thickness or width of the line structure itself. This is particularly the case when the converted lines ^¬ structure to one or more vanishing points out, that is its width tapers to the vanishing point or widened. This can also be done in sections, so that parts of the line structure produce a three-dimensional impression to or from the vanishing point.

According to a further embodiment, the partial surfaces framed by the sections have a different luminance corresponding to the perspective image and according to the line structure. In particular, the partial surfaces framed by the sections have a luminance gradient extending towards or away from the at least one vanishing point.

For example, by means of the line structure, for example in the embodiment as a metallic layer, the organic light-emitting diode can not only be divided into partial areas, but also their brightness can be influenced. This is the case in particular if the line structure or

structured layer is designed as a busbar. In this case, the brightness profile is predetermined by the line structure and can, for example, change continuously from the inside to the outside (in relation to the area of the organic light-emitting diode). The brightness transitions must not run continu ^¬ ously, but can also be carried out discreetly by the geometry of the line structure. It is also conceivable that, in turn, following the change of a bright patch to ei ^¬ ner darker patch a brighter face or vice versa.

Alternatively, brightness gradients can also be set other than directly with the line structure, for example by laterally different thickness or different conductivity of one or more (transparent) electrodes or by lateral stack variations. According to a further embodiment, the partial surfaces framed by the sections have at least one color gradient predetermined according to the perspective illustration and according to the line structure. In particular, the partial surfaces framed by the sections have at least one color gradient extending toward or away from the at least one vanishing point.

Similar to the brightness gradients in the individual partial surfaces, their colors can also be adjusted in a targeted manner and according to the perspective image. So can contribute to a three-dimensional impression of watching a Enriched color contrast, for example, by a drop sequence un ^¬ terschiedlicher complementary colors.

In accordance with a further embodiment, the illumination ^arrangement comprises at least one further organic light-emitting diode with a further planar layer structure on the substrate. In this case, each further layer structure has further first and second electrically conductive line layers. In addition, a further electroluminescent functional ^¬ layer is provided with an organic semiconducting material between the conductor layers of each further layer structure. Each further layer structure likewise has a further structured layer with a further line structure, which are arranged on or in the vicinity of at least one of the line layers selected from the first and second conductor layers of the further layer structure. The arrangement takes place in accordance with a perspective image of a three-dimensional object on or in the vicinity of at least the selected line layer. With the aid of one or more further organic light-emitting diodes, more complex illumination arrangements can be realized. In this case, the three-dimensional effect extends to the entire lighting arrangement, ie the plurality of organic light-emitting diodes and their respective line structures. In this way, for example, taillights for a power ^¬ vehicle can be achieved with three-dimensional effect.

According to a further embodiment, the organic light-emitting diodes form light-emitting diode segments of the illumination arrangement. The respective line structures of the segments are connected to one another in such a way that they form a common line structure which is arranged on or in the vicinity of at least one of the line layers in accordance with a perspective image of a three-dimensional object. The line structures of the segments may also be electrically connected, but this is not a requirement. They can also seemingly, so the visual impression to be connected.

In principle, the structured layer or the Li ^¬ nienstrukturen the individual organic light-emitting diodes can be defined independently of each other and by respective perspective Abbil ^¬ tions. However, the segments can be adjusted so aufei ^¬ Nander that they enable a greater Beleuchtungsan ^¬ order with a common line structure and a common three-dimensional effect.

The embodiments of the individual organic light-emitting diodes described above can be transferred in an analogous manner to the different segments, which can be further emphasized by an additional vote, for example, the common line structure. According to another embodiment, the segments become thinner or thicker along the common line structure according to the perspective image. In particular, the segments become thinner or thicker towards or away from a common vanishing point.

According to a further embodiment, the segments have a different luminance in accordance with the perspective illustration and according to the common line structure. In particular, the segments have a luminance gradient extending at least towards or away from the common vanishing point.

In accordance with a further embodiment, the segments have a color gradient corresponding to the perspective image and according to the common line structure. In particular, the segments have one to the common

Vanishing point towards or from this ongoing gradient on.

According to a further embodiment, the segments are individually electronically controllable.

The invention will be explained in more detail with reference to Ausführungsbeispie ^¬ len. The same, similar or gleichwirk ^¬ de elements are provided in the figures with the same reference numerals. The figures and the proportions of the elements shown in the figures with each other are not to be considered to scale. Rather, individual elements may be exaggerated in size for better representability and / or better understanding. Show it:

1 shows an exemplary illumination arrangement with an organic light-emitting diode according to the proposed principle,

FIG. 2 shows a further exemplary illumination arrangement with an organic light-emitting diode according to the proposed principle,

FIG. 3 shows a further exemplary illumination arrangement with an organic light-emitting diode according to the proposed principle,

Figure 4 shows another exemplary lighting arrangement with three organic light-emitting diodes according to the proposed principle, and

Figure 5 shows another exemplary lighting arrangement with three organic light-emitting diodes according to the proposed principle.

Figure 1 shows an exemplary lighting arrangement with an organic light emitting diode according to the proposed principle.

The figure shows schematically an organic light emitting diode OLEDl with a line structure 1 based on several busbars. The busbars divide the luminous area, so to speak the functional layer of the organic light-emitting diode OLED1, in different partial areas 2 or partial luminous areas. The busbars form on the one hand different sections 11, 12, 13, 14, which are defined by concentric rectangles and in the center of which a vanishing point 3 of the lighting ^¬ arrangement is located. Furthermore, further bus bar from ^¬ sections 15 are provided, each connecting the same corners of the kon ^¬ centric rectangles together.

In this way, a three-dimensional effect or perspective is created, which creates a tunnel-like impression towards the vanishing point 3 when the illumination ^{arrangement is} viewed. The presented structure of the line structure 1 is al ^¬ so characterized by a perspective image, which images a tunnel-like object on the two-dimensional surface of the organic light emitting diode OLEDl used.

In addition to the featured line structure 1, 12, 13, 15, the portions 11, 15 having the patterned layer un ^¬ terschiedliche thickness. When using busbars different thicknesses can be realized by a different width metal layer. To enhance the three dimensional effect can therefore be, for example, busbars ver ^¬ turns that the vanishing point 3 thinner toward or away from the vanishing point 3 are thicker (not shown).

Furthermore, other geometric figures are conceivable as concentric rectangles. For example, triangles, polygons, circles or ovals can be used.

2 shows another exemplary Beleuchtungsanord ^¬ voltage with an organic light emitting diode according to the procedure suggest ^¬ NEN principle.

In this embodiment, a three-dimensional effect is generated by differently sized hexagons 40, each surrounding partial light areas 41. A largest hexagon is included provided at a vanishing point of the lighting arrangement. Adjacent to this central hexagon are six other smaller hexagons. The other smaller hexagons are in turn surrounded by even smaller hexagons. This sequence is repeated until the resulting line ^¬ structure 1 is completed by an outer line. The individual hexagons are distorted in perspective.

To illustrate this honeycomb-shaped arrangement, the perspective image can be specified, or the pattern with- help, for example, a central projection designed ^¬ the. The line structures 1 through busbars rea ^¬ lisiert which may have according to the perspective and to the lower support alarm ^¬ wetting of the three-dimensional effect, different di ^¬ CKEN to the vanishing point or away are preferred.

3 shows another exemplary Beleuchtungsanord ^¬ voltage with an organic light emitting diode according to the procedure suggest ^¬ NEN principle.

Shown is a lighting arrangement according to the figure 1. In addition to the line structure 1, which generates the three-dimensional effect, a brightness gradient is shown. The ^¬ is set ser present so that surfaces 2 of the light-emitting diodes or ^¬ ganischen from the outside to the vanishing point 3 to go darker. The brightness gradient is essentially continuous and is based on the course of the line structure 1.

If the line structure 1 is predetermined by busbars, these can be used to conduct current through the organic light-emitting diodes or their layer structure. By the design the busbars, for example, by their height and thickness, the current density in the supply lines can be adjusted. As a result, the relevant sections of the busbars can set the Hel ^¬ ligkeit the OLED emission. In addition, individual sections of bus bars can be individually controlled electronically ^¬ to, so that in this way a brightness is adjustable.

In the present embodiment, the brightness gradient or brightness gradient based on the predetermined by the Ge ^¬ ometrie line structure 1 vanishing point 3. In the vanishing point 3, the brightness at the lowest and at an edge region of the organic light emitting diode is strongest.

Alternatively or additionally, further or other Hellig ^¬ keitsverläufe can be set. For example, at vanishing point 3, the brightness can be maximum and minimal at the edge region of organic light-emitting diode OLED1. As mentioned above, the line structure 1 is not limited to a rectangular shape and may be other geometric figures be ^¬ write, such as triangles, polygons, circles or ovals.

FIG. 4 shows a further exemplary lighting ^arrangement with three organic light-emitting diodes according to the proposed principle.

The illumination arrangement comprises a first, second and third segment OLED1, OLED2, OLED3, each segment comprising an organic light-emitting diode according to the proposed principle. The surfaces of the respective segments are quadrangular, but in the respective corners no right angles are provided. In this way, the segments to each other abge ^¬ agrees to be and already due to their surface a three- Create a single impression by the respective edges or side lines converge towards a vanishing point.

The three-dimensional effect defined by the convergence to the vanishing point of the segment surfaces can be amplified by the structured layer or the line structures 1 on the individual segments in accordance with the principles presented above. The line structures can also be adjusted in such a way that they seem to convert along a common line structure 17 to the (common) vanishing point. Furthermore, a further line structure 1 with a suitably set three-dimensional effect can be provided on each individual segment (not shown).

Furthermore, the three-dimensional effect can be amplified by ei ^¬ nen brightness gradient between the segments ^¬ to. For example, the first segment of maximum light, the second segment darker and set the third segment even dunk ^¬ ler. The brightness gradient can alternatively be in a different order from dark to light set the ^¬.

The individual segments are separated from each other by leads 16, which also represent a line structure 1 in the ^{vorgestell ¬} th sense. By appropriate placement of the leads 16, the three-dimensional effect can also be influenced.

Using additional busbars on the respective segments OLED1, OLED2, OLED3 can be adjusted as described Hel a ^¬ ligkeitsverlauf above also within the segment, so that for example, a continuous brightness variation is also possible between the segments, without there being sharp brightness transitions between the segments.

FIG. 5 shows a further exemplary lighting ^arrangement with three organic light-emitting diodes according to the proposed principle.

This embodiment also relates to a lighting arrangement of three separate segments OLED1, OLED2, OLED3. The segments themselves are rectangular or square and, similar to the embodiment shown in FIG. 1, are arranged concentrically with one another. In this case, however, not portions of the line structure 1 on an organic light emitting diodes are arranged concentrically to each other, but the framed by leads 16 segments themselves. The center of the concentric arrangement is also a vanishing point 3 of the lighting arrangement. This in turn defines a three-dimensional effect.

The individual segments OLED1, OLED2, OLED3 can be controlled individually so that different brightness are adjustable in a ^¬. The three-dimensional effect is enhanced by the un ^¬ terschiedliche brightness. Furthermore, it is conceivable ^¬ bar that the individual segments are also controlled in time sequentially, so that there is a movement effect to the vanishing point. Reference sign list

1 line structure

 11 section

 12 section

 13 section

 14 section

 15 section

 16 supply line

 17 common line structure

2 part surface

 3 vanishing point

 40 hexagon

 41 partial area

 OLED1 organic light emitting diode

OLED2 organic light emitting diode

OLED3 organic light emitting diode

Claims

claims

1. Lighting system, in particular a light-emitting surface, comprising at least one organic light emitting diode (OLED1) comprising on a sub ^¬, strat a planar layer structure wherein

- the layer structure of a first electrically conductive Lei ^¬ tung layer and a second electrically conductive layer comprises Lei ^¬ tung as well as an interposed electroluminescent functional layer with an organic ^¬ rule semiconducting material comprises,

 - The layer structure at least one structured

 Layer having a line structure (1) and

- The line structure (1) of the structured layer according to a perspective image of a three-dimensional object on or in the vicinity of at least one of the conductor layers, selected from the first and second conductor layer, is arranged.

2. The lighting arrangement according to claim 1, wherein the structured layer has at least one metal layer, in particular an electrically conductive busbar and / or an electrical supply line.

3. Lighting arrangement according to claim 1 or 2, wherein the line structure has at least one vanishing point (3).

Divided 4. Lighting arrangement according to claim 1 or 2, wherein the line structure of the organic light emitting diode (OLED1) into several partial surfaces (2), each sub-surfaces (2) at least partially and correspondingly the perspektivi ^¬ rule illustration of portions (11, 12, 13, 14, 15, 16, 17) of the line structure (1) is framed.

5. Lighting arrangement according to claim 3, wherein the sections according to regular geometric figures frame the partial surfaces (2), in particular according to regular planar geometric figures frame the partial surfaces (2).

6. Lighting arrangement according to claim 3 or 4, wherein the partial surfaces (2) are arranged at least partially concentric with each other.

7. Lighting arrangement according to one of claims 3 to 6, wherein the sections (11, 12, 13, 14, 15, 16, 17) ^¬ accordingly the perspective image along the line structure (1) are thinner or thicker, in particular to the at least a vanishing point (3) towards or from the ^¬ sem thinner or thicker.

8. Lighting arrangement according to one of claims 3 to 7, wherein the framed by the sections (11, 12, 13, 14, 15, 16, 17) partial surfaces (2) at least one corresponding to the perspective image according to the line structure (1) different luminance have, in particular at least one to the at least one vanishing point (3) out or from this progressing luminance gradients.

9. Lighting arrangement according to one of claims 3 to 8, wherein the framed by the sections (11, 12, 13, 14, 15, 16, 17) partial surfaces (2) at least one according to the perspective illustration and according to the line structure (1) extending Have color gradient, in particular at least one of the at least one Vanishing point (3) toward or away from this continuing gradient have.

10. Lighting arrangement according to one of claims 1 to 9, comprising at least one further organic light-emitting diode (OLED2, OLED3) with a further planar layer structure on the substrate, wherein

 - Each additional layer structure comprises further first and second electrically conductive line layers and a further interposed therebetween

having electroluminescent functional layer with an organic ^¬ rule semiconducting material,

 - Each further layer structure has at least one further structured layer with a further line structure (1) and

 - Each further line structure (1) corresponding to one

perspective illustration of a three-dimensional object on or in the vicinity of at least one of the Lei ^¬ processing layers selected from the first and second conductor layer of the further layer structure, angeord ^¬ net is.

11. Lighting arrangement according to claim 10, wherein

- the organic light emitting diode (OLED1) and any other organic light emitting device (OLED2, OLED3) form segments of Be ^¬ lighting arrangement and

- The line structures (1) of the segments are so unterei ^¬ mutually connected or at least appear that they form a common line structure (17), which is arranged according to a perspective image of a three-dimensional object on or in the vicinity of at least one of the conductor layers.

12. Lighting arrangement according to claim 10 or 11, wherein the segments according to the perspective image along the common line structure (17) are thinner or thicker, in particular to a common vanishing point (3) towards or away from this thinner or thicker.

13. Lighting arrangement according to one of claims 10 to 12, wherein the segments corresponding to the perspective Ab ^¬ education according to the common line structure (17) have different luminance, in particular wenigs ^¬ least one to the common vanishing point (3) out or from this continuing luminance gradients exhibit .

14. Lighting arrangement according to one of claims 10 to 13, wherein the segments have a correspondingly the perspektivi ^¬'s picture and according to the common line structure (17) extending gradient, and in particular we ^¬ nigstens one to the common view point (3) towards or away from have gradual color gradient.

15. Lighting arrangement according to one of claims 10 to 14, wherein the segments individually electronically

 are controllable.