WO2016166209A1

WO2016166209A1 - Lighting arrangement and method for producing a lighting arrangement

Info

Publication number: WO2016166209A1
Application number: PCT/EP2016/058221
Authority: WO
Inventors: Thorsten VEHOFF; Kilian REGAU; Stefan Seidel
Original assignee: Osram Oled Gmbh
Priority date: 2015-04-15
Filing date: 2016-04-14
Publication date: 2016-10-20
Also published as: DE102015105756A1; DE112016001761A5

Abstract

The invention relates to a lighting arrangement comprising an organic light emitting diode (OLED1) having a layer structure on a substrate (S). The layer structure has an anode and a cathode and a functional layer arranged there between (FS). The anode furthermore has an anode supply lead (A1) and the cathode has a cathode lead (K). At least one of the electrode leads (EL), chosen from the anode lead (A1) and the cathode lead (K), comprises a notch structure (KORR). The notch structure (KORR) is configured to adjust a resistance (R_KORR) of at least one of the electrode leads (EL).

Description

description

Illumination arrangement and method for producing a lighting arrangement

The invention relates to a lighting arrangement and a method for producing a lighting arrangement. With the method, illumination arrangements described here can be produced in particular so that all features disclosed for the illumination arrangement are also disclosed for the method and vice versa.

Organic light emitting diodes (OLEDs) are electronic devices thin film ^¬ of organic semiconducting materials, and are used for a variety of lighting applications. FIG. 5A schematically shows a typical structure of an OLED. The illustrated OLED comprises a substrate S with a first electrically conductive metallic conductor layer MSI, for example of indium tin oxide, chromium-aluminum-chromium (CrAlCr) or metals and alloys, and with a second likewise electrically conductive metallic conductor layer MS2, for example of aluminum. Further, on the at least one of the line ^¬ layers MSI, MS2, a passivation PA be provided. An organic layer stack FS, also referred to below as functional layer, is located between a cathode coating KA and the first line layer MSI. The layers are encapsulated by an encapsulation VK and thus protected from environmental influences. The first and second conductor layers and the cathode coating KA serve as electrode leads EL in order to supply the OLED with electric current. For example, the first and second conduction layers become anode conduction used while the cathode coating KA serves as a cathode feed line. The electrode leads can be divided into sections which are still located on the substrate of the OLED or OLED segment itself and those sections which lie outside the actual OLED on the

Electrode leads, which are typically part of an OLED based lighting arrangement. Then via the electrode leads EL contact is made to other components such as a current regulator (not shown).

For lighting applications, it is advantageous that OLEDs represent surface radiators. Light is generated directly in the surface and not as with other surface light sources via optical fibers by means of side or direct coupling in the

Distributed area. This makes it possible to divide the luminous area into segments separated from one another, which can be addressed independently of one another. An example is shown in FIG. 5B. Shown is a BL LEVEL ^¬ processing arrangement, which has two concentric circular Segmen ^¬ te OLED1, OLED2 includes that are framed by the ring structures Rl, R2, R3. The first segment OLED1 is provided with a first anode lead AI and has a cathode terminal K. The second segment is provided with a second OLED2 Anodenzulei ^¬ tung A2 and has the same cathode terminal K as the first segment OLED1. However, other Kontak ^¬ tions, for example, with separate cathode leads and more than two segments also conceivable.

In practice, the Leuchtflächenendesign and the size of a lighting arrangement are specified by the customer. This means that the electrode leads EL also in length and Geometry are predetermined and are essentially based on design specifications. Due to the segmentation, the segments OLED1, OLED2 in FIG. 5B can be operated, for example, concentrically with the same current density, for example in order to achieve the same brightness. Even if segments OLED1, OLED2 are used with the same layer structure, the segments OLED1, OLED2 have different voltages during operation at the connection contacts AI, A2. This is due to different resistance values of the current paths in the electrode leads EL, which are effectively connected in series to the actual OLEDs. 6A and 6B veran ^¬ illustrate this fact.

FIG. 6A schematically shows the structure of the lighting arrangement according to FIG. 5B. Shown are the first and second segment OLED1, OLED2 and their electrode leads EL, ie the cathode lead K and the first and second Anodenzulei ^¬ tions AI, A2. Shown are also sections of Elekt ^¬ rodenzuleitungen A1 +, A2 +, which are still on the respective substrate of the light-emitting diodes or segments OLED1, OLED2 itself and such sections AI-, A2-, which are located on the electrode leads outside.

In the example shown, the electrode leads EL essentially differ from each other by their length. Accordingly, the electrode leads EL have different internal resistances. Below is with RAI inner ^¬ resisted the first anode lead AI and RA2, the internal resistance of the second anode lead AI called. The arrangement of Figure 6A can thus be represented by an equivalent circuit, as shown in Figure 6B. The internal resistances RAI, RA2 which are generally different as described above are the actual segments OLED1, OLED2 connected in series. The internal resistance of the cathode ^¬ line is neglected here and not shown.

In a lighting arrangement as shown in Figure 5B to OLED1, OLED2 to Errei ^¬ Chen, different voltages required egg ne same brightness both segments. This is made clear by the equivalent circuit diagram described above. If, conversely, both segments OLED1, OLED2 were used cost-effectively on a common driver, ie in parallel in contrast to FIG. 6B (connecting AI and A2), then the supply voltage would be the same, but the currents would be divided differently. On the other hand, this leads to different brightnesses and, as a consequence, to different aging of the segments.

This could be avoided by providing a separate current regulator for each segment to set the required voltage. This then leads to increased electronics costs, space requirements on the board and wiring costs. Finally, each segment has its own electric ^¬ denzuleitungen EL would have to be connected to the corresponding current regulators. This also leads to increased space requirements, more complex flexible printed circuit boards and more complex routing on the segments OLED1, OLED2. Another solution is to connect external balancing resistors to the electrode leads EL and then operate the lighting assembly with a single current regulator. However, this is also associated with increased costs and requires a precise adjustment of the resistance values. In addition, each segment used needs despite everything a se ^¬ parate anode lead and a dedicated contact point on the OLED. It is an object of the invention to provide a lighting device and a method for producing a lighting arrangement, which allow a cost-effective and simpler structure.

This object is achieved by a lighting device and a method for producing a lighting arrangement having the features of the independent claims. Particularly advantageous embodiments of the invention are described in the dependent claims.

According to one embodiment, a lighting ^arrangement comprises at least one organic light-emitting diode. The light-emitting diode furthermore has a layer structure which is located on a substrate. The layer structure comprises an anode and a cathode and a functional layer arranged therebetween. The functional layer is an organic layer stack. Furthermore, the anode has an anode feed line and the cathode has a cathode feed line. The anode feed line and the cathode feed line form the electrode feed lines of the lighting arrangement. At least one of the electrode leads selected from the anode lead and the cathode lead has a notched structure. In this case, the notch structure is set up and / or designed to set a resistance of at least one of the electrode leads.

During operation of the lighting arrangement, the electrode leads are connected to a voltage source, such as a current regulator, which supplies the organic light-emitting diode with an operating voltage. Depending on the voltage applied, a specific current flows through the electrodes of the organic light-emitting diode, and depending on this, a specific brightness is established. Also, within a production line by moving in principle ^¬ chen organic light emitting diodes provides a different radiation characteristic of the produced organic light emitting diodes due to manufacturing tolerances. With the aid of the notch structure, the resistance in the electrode lead or in a plurality of electrode leads can be adjusted and under standard conditions a predetermined brightness of the organic light-emitting diode can be achieved. In this way, manufacturing tolerances in the terminal adapted to the production of the organic light-emitting diode in a measurement state ^¬ the. This is inexpensive and allows a simpler structure. The notch structure may in particular also be located outside the organic light-emitting diode, that is to say, for example, in a lateral direction at a distance from the functional layer. The lateral directions are as ^¬ in those directions that are parallel to a Haupterstreckungsebe- ne of the substrate. Between the notch structure and the functional layer, there may be a portion of the electrode lead which is free of indentation structures. Can by the distance between Einkerbungsstruktur and functional layer ensures ^¬ that that the functional layer is not damaged during the production of the An ^¬ kerbungsstruktur.

The designation of anode and anode feed line and cathode and cathode feed line are to be regarded as interchangeable in the context of this application. Alternatively, they designate a first and second electrode or first and second electrode leads. Thus, the terms anode and cathode always refer to the underlying current direction, which is just reversed in technical and physical direction. Also in this sense, the terms interchangeable or from the term the current direction depends. In other words, the notch structure may be provided on each of the electrode leads as well as a plurality. In a further embodiment, the illumination arrangement comprises at least one further organic light-emitting diode. In this case, each further organic light-emitting diode has a further layer structure on a further or the same substrate. The further layer structure also has a further anode and a further cathode. The further anode has a further anode feed line and the further cathode has a further cathode feed line. The further layer structure has a further functional layer arranged between the further anode and the further cathodes.

At least one of the electrode feed lines, selected from the anode feed line, the at least one further anode feed line, the cathode feed line and the further cathode feed line, has the notch structure. The notching structure is configured to equalize the resistances Elect ^¬ clear supply lines to each other.

A lighting arrangement of the present type is usually produced according to design specifications of a customer so that the geometry of the electrode leads is predetermined and not further variable. With the help of the notch structure, it is possible to achieve an alignment of the resistances of the electrode leads and thus also to adapt the supply voltage for the organic light-emitting diode and the at least one further organic light-emitting diode to one another.

In this case, the notching structure can be produced in one process step after completion of essential parts of the lighting system. be recognized. Thus, in a measuring station, the Be ^¬ lighting arrangement under normal conditions, that is to say a given voltage or current strength of a Stromreg ^¬ coupler can be adjusted. By providing the notch structure on one or more of the electrode leads, the voltage can be equalized so that equal voltages result at rated current. Alternatively, the configuration of the notch structure can also be based on simulations or calculations. This is also useful when the geometry and thus the resistance of the

Electrode leads are known to a sufficient accuracy by the design specification. Then the setting of the resistors can be realized without or in addition to specially provided measuring stands.

The notch structure allows a simpler and thus less expensive construction of the lighting arrangement. On the organic light-emitting diodes themselves, the number of contacts can be saved, it results in a simpler design and additional costs can be saved by separate current regulator. Even outside the organic light emitting separate contacts may be provided, but a Taste ^¬ neinsparung by eliminating a current regulator is also possible optional. The increase in resistance can be made such that the Einkerbungsstruktur is almost not visible in the final design of the lighting arrangement Be ^¬ due to the low resistance values. The production of the indentation structure can be incorporated within established production processes of illumination arrangements based on organic light-emitting diodes, without these processes having to be substantially changed. Thus, the production of the notch structure can be planned without significantly increased production costs. According to a further embodiment, the cathode feed line and the further cathode feed lines are connected in such a way that they form a common cathode feed line. At least one of the electrode feed lines, selected from the anode feed line, the at least one further anode feed line, the cathode feed line and the further cathode feed line, has the notch structure. The indentation structure is also configured to match resistances of the electrode leads to one another.

According to a further embodiment, the Einkerbungsstruktur is adapted at least to approximate a resistance of the anode lead ^¬ a further resistor of the at least one further anode lead.

According to a further embodiment, the indentation structure is provided on the anode feed line selected from the anode feed line or at least one further anode feed line. In this case, the anode lead is selected, which has the lowest resistance compared to the other anode leads.

The notch structure usually leads to an increase in the internal resistance of an electrode lead. For this

Why has the choice of anode lead of least resistance to the internal resistance to moving ^¬ chen. The notch structure may be provided on a plurality of electrode leads, and accordingly changes their internal resistance in an analogous manner. According to a further embodiment, the Einkerbungsstruktur is at least a laser cutting, in particular meh ^¬ reren laser cuts provided. The laser cuts are made in a material of at least one of the electrode leads.

According to a further embodiment, the notch structure comprises at least one recess in the material of one of the electrode leads. For example, the recess or a plurality of recesses can be implemented in the context of a mask process in a lithographic process.

According to a further embodiment, the electrode leads each have an electrode layer structure. The electrode layer structure comprises at least a first and a second line layer. For example, the first Lei ^¬ tung layer a coating of indium tin oxide or chromium aluminum chromium (CrAlCr) and the second conductor layer a metal ^¬ metallic, electrically conductive layer such as aluminum. According to a further embodiment, the first

and / or the second conductive layer on the at least one La ^¬ serschnitt.

According to a further embodiment, the first and / or the second conductive layer has the recess.

In accordance with a further embodiment, the anode feed lines, selected from at least the anode feed line and from at least one further anode feed line, are connected in parallel by means of a compensating element.

According to one embodiment of a method for producing a lighting arrangement, first an organic LED provided. The organic light-emitting diode has a layer structure which is arranged on a substrate. The layer structure in this case comprises an anode and a Ka ^¬ Thode and a functional layer disposed therebetween. In this case, the anode has an anode feed line and the cathode has a cathode feed line. Furthermore, at least one resistor of one of the electrode leads, selected from the anode lead and the cathode lead, is set. The adjustment is made by providing a notch structure in at least one of the electrode leads.

In operation, the lighting arrangement is connected via its electrode leads to a voltage source such as a Stromreg ^¬ ler, which supplies the organic light emitting diode with an operating voltage. Depending on the adjacent

Voltage flows through the electrodes of the organic light-emitting diode, a certain current and it turns depending on a certain brightness. Also, within a production line by moving in principle ^¬ chen organic light emitting diodes provides a different radiation characteristic of the produced organic light emitting diodes due to manufacturing tolerances. With the aid of the notch structure, the resistance can be set in the electrode lead or in a plurality of electrode leads, and under standard conditions a predetermined brightness of the organic light-emitting diode can be achieved. In this way, manufacturing tolerances can be adapted following the production of the organic light-emitting diode in a measuring stand. This is inexpensive and allows a simpler structure. According to a further embodiment of the method, one or more further organic light emitting diodes are bereitge ^¬ represents. Each additional organic light emitting device in this case comprises egg ^¬ NEN further layer build-up on another substrate. The further layer structure has a further anode and a further cathode. The further anode comprises a further anode feed line and the further cathode another Katho ^¬ denzuleitung. The further layer structure is arranged between the white ^¬ direct anode and the cathode. Furthermore, an alignment of resistances of the electrode feed lines, which is selected from the anode feed line, the at least one further anode feed line, the cathode feed line and the further cathode feed line, takes place. This is done by means of the A ^¬ kerbungsstruktur.

Alternatively, the cathode lead and each of the other cathode leads may be connected to a common cathode lead. Furthermore, the resistances of the electrode leads, which are selected from the anode lead, the at least one further anode lead and the common cathode lead, are then matched. This is also done by means of the notch structure.

According to a further embodiment of the method, the notch structure is introduced by means of at least one laser cut, in particular a plurality of laser cuts, into a material of one of the electrode feed lines.

According to a further embodiment of the method, the indentation structure is introduced by means of at least one recess in a material of one of the electrode leads. According to a further embodiment of the method, the adjustment of the resistance of an electrode lead takes place by adjusting the resistance so that the organic light-emitting diode has a predetermined brightness during operation under standard conditions. In this way it is possible even after the egg ^¬ tual production of organic light-emitting diode to normalize a lighting arrangement to a standard characteristic and compensate tolerances. The invention will be explained in more detail with reference to Ausführungsbeispie ^¬ len. Show it:

Figure 1A and Figure 1B is a schematic representation of a

Embodiment of a lighting arrangement according to the proposed principle,

Figure 2 measuring characteristics of an embodiment of a

Lighting arrangement according to the proposed principle,

Figure 3A and 3B embodiments of Einkerbungs ^¬ structures according to the proposed principle,

Figure 4A and Figure 4B is a schematic representation of a

Embodiment of a lighting arrangement with a compensation element according to the proposed ^¬ nen principle,

FIG. 5A and FIG. 5B show an exemplary embodiment of a lighting arrangement from the prior art, and Figure 6A and Figure 6B is a schematic representation of a

Embodiment of a lighting arrangement of the prior art. Figures 1A and 1B show a schematic representation of an embodiment of a lighting arrangement according to the proposed principle. FIG. 1A shows two organic light-emitting diode segments OLED1 and OLED2. These are arranged on a common substrate S. In this exemplary embodiment, the two organic light-emitting diode segments OLED1, OLED2 are located on the common substrate S.

The organic light emitting diodes OLED1, OLED2 comprise a layer structure FS and each have a cathode KA and an anode (not shown). The respective cathodes are connected to ^¬ tels a cathode feed line K. Furthermore, the anode of the first organic light emitting diode OLED1 is provided with a first anode lead AI. The anode AN2 of the second organic light emitting diode OLED2 African is provided with a second Anodenzulei ^¬ tung A2. It can further be seen from FIG. 1A that the electrode leads EL, that is to say the first and second anode leads AI, A2, have regions A1 +, A2 + which are located on a first region S1 of the substrate S. Further towards areas Al, A2, K- are present, constitute the Elektrodenzu ^¬ lines EL, S are led out to the organic light emitting diodes from the area Sl of the substrate and, for example, a layer sequence comprising first and second conductor layer ^¬ MSI, MS2 comprise. In operation, the electrode leads EL are connected to one or more current regulators, thus supplying a supply voltage. The geometry and the dimensions of the electrode leads EL are generally predetermined by the design of the illumination ^arrangement and by customer requirements. For these reasons, the individual electrode leads EL generally have a different length or width. Because of these differences, the electrode leads EL, such as the two anode leads AI, A2, have different internal resistances. The lighting arrangement shown in FIG 1A illustrates a segmented luminous surface is, which are always connected together in this example, that is, the first and second organic light emitting device OLED1, OLED2 are always ^¬ together switched on. In contrast to the representation in FIG. 1A, a cathode contact and an anode contact would also be sufficient for this purpose. In the illustrated concentric arrangement of both segments OLED1, OLED2, a current regulation and control of the organic light emitting diodes with the same current density takes place. Since the organic light-emitting diodes usually have the same production characteristics as stack data, in most cases even being produced together in the same production, the segments nevertheless have different supply voltages in operation. This is due to the different internal resistance values of the electrode lead EL or the current paths to the electrodes of the segments OLED1, OLED2 described above.

FIG. 1B further illustrates this observation. The first and second organic light emitting diode OLED1, OLED2 are, so to speak, connected in series with the respective internal resistances. This is shown schematically in the figure by an equivalent circuit diagram. The first anode lead AI is replaced by a first internal resistance RAI and the second anode supply line A2 represented by a second internal resistance RA2.

To equalize the internal resistances in the anode supply lines Al and A2 a Einkerbungs ^¬ structure CORR is on the first anode lead AI, ie the shorter total length in the anode lead, is applied. This can be done with the aid of laser ^¬ cuts, which are introduced into the material of the anode feed line. The Einkerbungsstruktur CORR has fect the ef- to change the current path within the first anode lead AI such that the internal resistance increased by ei ^¬ NEN value R_KORR. The exact geometry and arrangement of one or more laser cuts determines the value of the compensation resistance. Further details will be explained below in connection with FIGS. 3A and 3B.

With the help of the correction resistor R_KORR, the two organic light-emitting diodes OLED1, OLED2 can be operated with the same brightness and the same voltage. This makes it possible to provide the supply of the two segments OLED1, OLED2 cost-effective to a driver or current regulator.

The effects of the notching structure KORR and the correction resistor set with it are shown by way of example in FIG. Figure 2 shows different builds character istics ^¬ an embodiment of a Beleuchtungsanord ^¬ voltage according to the principle proposed. The illustration shows on the left side the illumination arrangement based on FIG. 5B with the indentation structure KORR in the first anode lead AI. The Einkerbungsstruktur CORR was pre ^¬ taken by several laser cuts in the anode lead material. The left side shows the anode potential and the right side the luminance over the illumination device element. ment. The anode potential is nearly constant over the orga ^¬ African LEDs OLED1, OLED2. Differences are discernible in the region of the electrode lead EL, in particular in the region of the notch structure KORR, which, as described above, leads to an additional correction resistor and thus to an additional voltage drop. The luminance over the illumination arrangement element is almost constant over large parts of the segments and in particular in the comparison between the segments OLED1, OLED2.

FIGS. 3A and 3B show exemplary embodiments of notching structures KORR according to the proposed principle. Shown are various plan views of a, b, c a ^¬ Anodenzu conduit th with differently designed Lasereinschnit- are provided. The reference symbol d shows a side view of a notch structure KORR in an anode feed line. Figure 3B shows an alternative Einkerbungs ^¬ structure CORR, which has a recess in the layers of the anode lead. This is done using a mask process during lithography. In principle, the notch structure KORR may be provided in the areas A1 +, A2 + or in the areas AI-, A2-. In both cases, however, the indentation structure is not an external resistor, which is connected to an electrode lead, but an integral part of the illumination arrangement.

The electrode leads EL are constructed on the material of the actual organic light-emitting diodes, as explained in connection with FIG. 5A. The Elektrodenzu- lines EL also comprise a layered structure on Ba ^¬ sis of the substrate S. Accordingly, a coating of the first and second wiring layer MSI, MS2, for example, Indium tin oxide, chromium-aluminum-chromium (CrAlCr) or aluminum arranged on the substrate S.

In the plan view the a Einkerbungsstruktur CORR 2, 3, 4, and 5 comprises sev- eral notches 1, the sides are cut in the material of the electrode lead EL alternately from various ^¬ those. A current flow is thereby forced to a wel ^¬ lenartige trajectory when the flow through the notch structure limited part of the electrode feed line EL has to flow through. In this way, the resistance is he ^¬ increased. In the top view b, the notches 1 to 5 and 6 to 10 are arranged opposite one another, so that a limited part of the electrode feed line EL remains on the axis. This area corresponds to a constriction for the flowing current, which in turn corresponds to an increase in the resistance. Top view c shows trapezoidal notches 11 and 12 which, similar to plan view b, define a constriction for the flowing stream. This is accomplished by cutting parts 13 and 14 so that little or no current can flow there. Again, this leads to an increase in resistance.

It can be seen from the side view d that the notches of the indentation structure KORR extend through the first and second line sheath MSI, MS2 to the substrate S, but do not cut through the latter. Furthermore, it is possible that the notches of the indentation structure KORR only partially cut. The exact geometry is usually specified by the process and which correction resistor R_KORR is ultimately to be set. Supporting suitable geometries of the indentation structure KORR arise from simulations. FIG. 3B shows a side view e of an electrode feed line EL with a notch structure KORR, which has a cutout 15 in the second line layer MS2. This is carried out at play ^¬ using a mask process during Li thografie. Similarly as in the embodiments of Figure 3A, the current flow is hereby amended ^¬ changed in a way that leads to an increase in resistance. Thus, a wiring layer made of aluminum is playing particularly well to conduct current in ^¬, while a coating of Indiumzinno- oxide has a lower conductivity. Due to the savings from ^¬ 15 of the stream is deflected such that it extends partially through the first conductive layer, for example of indium tin oxide or chromium-aluminum-chromium (CrAlCr), which in turn leads to an increased resistance.

Figures 4A and 4B show a schematic representation of an embodiment of a lighting arrangement with a compensation element AE according to the proposed principle. With the aid of the indentation structure KORR, the correction resistor R_KORR is set in the lighting arrangement. This makes it possible to provide a compensation element AE between the first and second anode supply lines AI, A2, so that the entire lighting arrangement can be operated with only one external anode contact. The anode contact A is connected to a current regulator together with the cathode contact C. Figure 4B shows a equivalent circuit diagram of the so he ^¬ followed parallel connection of the first and second organic light emitting segments. The parallel connection, both segments can be operated kostengüns ^¬ tig at a driver and thus set a common supply voltage. Due to the matching internal resistances through the indentation structure KORR, the supply current will be split equally so that there is hardly any brightness difference between the two segments OLED1, OLED2. This also has the further advantage that both organic light-emitting diodes age in a similar manner. Furthermore, the common power controller can save wiring and space on the board and reduce electronics costs. Additional space on the contact strip, more complex flexible ^circuit boards and an elaborate routing to the organic

Light-emitting diodes can also be omitted.

It is the priority of the German patent application DE

102015105756.5, the disclosure of which is hereby incorporated by reference.

The invention is not limited by the description based on the embodiments of these. Rather, the invention encompasses every new feature as well as every combination of features, which in particular includes any combination of features in the patent claims, even if this feature or this combination itself is not explicitly stated in the patent claims or exemplary embodiments.

Reference sign list

1 notch

2 notch

3 notch

4 notch

5 notch

6 notch

7 notch

8 notch

9 notch

10 notch

11 notch

12 notch

13 trapezoidal notch

14 trapezoidal notch

15 recess

A anode feed

AI anode feed

Al region of the anode feed line

A1 + area of the anode feed line

A2 anode feed

A2 range of the anode feed line

A2 + range of anode lead

ALU metallic layer

FS functional layer

K cathode feed

KA cathode

MSI first conductor layer

MS2 second conductor layer

OLED1 segment, organic light emitting diode

OLED2 segment, organic light emitting diode

PA passivation Rl ring

R2 ring

R3 ring

RAI resistance

RA2 resistance

S substrate

Sl area of the substrate

VK encapsulation

Claims

claims

1. Lighting device comprising an organic Leuchtdi ^¬ ode (OLED1) comprising a layer structure on a sub- strate (S), wherein

the layer structure comprises an anode and a cathode and has a functional layer (FS) arranged therebetween,

the anode has an anode lead (AI) and the cathode has a cathode lead (K),

- At least one of the electrode leads (EL) selected from the anode lead (AI) and the cathode lead (K) has a notch structure (KORR), and

- The notching structure (KORR) is arranged to set a resistance (R_KORR) at least one of the Elektrodenzulei ^¬ tions (EL).

2. Lighting arrangement according to claim 1, comprising at least one further organic light emitting diode (OLED2), wherein - each further organic light emitting diode another

Layer structure on a further substrate (S), comprising,

the further layer structure has a further anode and a further cathode,

the further anode has a further anode feed line (A2) and the further cathode has a further cathode feed line (K),

- The further layer structure one between the other

Anode and the cathode arranged further functional ^¬ layer (FS),

at least one of the electrode leads (EL) selected from the anode lead (AI), the at least one further anode lead (A2), the cathode lead (K) and the further cathode lead has the notch structure (KORR), and

- The notching structure (KORR) is set up, ^¬ states of the electrode leads (EL) Chen to each other chen.

The lighting assembly of claim 2, wherein the cathode lead and the further cathode lead are connected to form a common cathode lead

Form and (K) wherein at least one of the Elektrodenzulei ^¬ obligations (EL) selected from the anode lead (AI), the at least one further anode lead (A2) and the common cathode terminal (K) the Einkerbungsstruktur

(KORR).

4. Lighting arrangement according to claim 2 or 3, wherein the notching structure (KORR) is adapted to equalize a resistance (RAI) of the anode lead (AI) to another resistor (RA2) of the at least one further anode lead (A2).

5. Lighting arrangement according to one of claims 2 to 4, wherein the notch structure (KORR) at least on the anode lead, selected from the anode lead (AI) or at least one of the further anode leads (A2), is provided, which in comparison to the other anode leads lowest resistance (RAI, RA2).

6. Lighting arrangement according to one of claims 1 to 5, wherein the notch structure (KORR) at least one La ^¬ serschnitt, in particular a plurality of laser sections, in a Ma ^¬ material of one of the electrode leads (EL).

7. Lighting arrangement according to one of claims 1 to 6, wherein the notch structure (KORR) at least one savings ^¬ savings in the material of one of the electrode leads (EL).

8. Lighting arrangement according to one of claims 1 to 7, wherein the electrode leads (EL) each have a Elekt- rodenschichtaufbau comprising at least a first and ei ^¬ ne second conductive layer (MSI, MS2).

9. Lighting arrangement according to claim 8, wherein the first

and / or the second conductor layer (MSI, MS2) said at least ^¬ a laser cut.

10. Lighting arrangement according to claim 8, wherein the first and / or the second line layer (MSI, MS2) has the Ausspa ^¬ tion.

11. Lighting arrangement according to one of claims 2 to 10, wherein the anode feeders selected at least from

Anode lead (AI) or from at least one other anode lead (A2), are connected in parallel by means of a compensation element (AE).

12. A method for producing a lighting arrangement, comprising the steps:

Providing an organic light-emitting diode (OLED1),

comprising a layer structure on a substrate (S), the layer structure comprising an anode and a cathode and a function layer arranged therebetween

(FS), wherein the anode has an anode lead (AI) and the cathode has a cathode lead (K), - Setting at least one resistor (R_KORR) of an electrode lead (EL) selected from the anode lead (AI) and the cathode lead (K) by a notching structure (KORR) in one of the electrode leads is provided.

13. The method according to claim 11, comprising the steps:

- providing one or more further organic light emitting diodes (OLED2), each additional organic light emitting device comprises a further layer structure on a fur ^¬ direct substrate (S), the further layer structure comprises a further anode, and a further cathode additional anode another anode lead ( A2) and the further cathode another cathode terminal (K), the further layer structure comprises a further disposed between the anode and the cathode further radio ^¬ tion layer (FS), and

- Matching resistances of the electrode leads

(EL) selected from the anode lead (AI), the at least one further anode lead (A2), the cathode lead and further cathode lead by means of the notch structure (KORR).

14. The method of claim 11 or 12, wherein the bung Einker- structure (CORR) using at least one laser ^¬-section, in particular more Laserschitte, in a mate rial ^¬ one of the electrode leads (EL) is introduced.

15. The method according to claim 11 or 12, wherein the notch structure (KORR) is introduced by means of at least one recess in a material of one of the electrode leads (EL). Method according to one of claims 11 to 14, wherein the setting of the resistance of an electrode lead (EL) by the resistor is adjusted so that the organic light-emitting diode (OLED1) in operation under Normbedin ^¬ conditions a predetermined brightness.