DE102004005370B4 - Electrical device with a housing and an OLED display element and method for its production - Google Patents

Abstract

electrical Device with a housing (2) and at least one OLED display element (1), wherein the electrical device has a power supply or with a power supply is connected or connectable, and the substrate for the OLED display element (1) at least partially formed by the housing (2) of the electrical device is, wherein between a housing surface (2) and the housing surface (2) nearest Layer of the OLED display element (1) a barrier layer (7) is arranged, characterized that the nearest Layer of the OLED display element (1) an electrode layer (8) and the barrier layer (7) is silicon oxynitride.

Description

The The invention relates to an electrical device with a housing and an OLED display element and a method for its production with the features mentioned in the preambles of claims 1 and 11 WO 03/041080 A2.

Increasingly are a variety of electrical devices, such as mobile phones, with a display element based on organic light-emitting diodes (OLED display element) fitted. It is under an electrical device each Device understood, which has a power and / or power supply or with a connected or connectable, wherein the mode of action of equipment at least partially based on the utilization of the provided electricity based.

Around to integrate an OLED display element into an electrical device, it is known first the OLED display element on a substrate, for example a glass substrate, form and arranged on the substrate OLED display element to install in a subsequent step in the housing of the electrical device and connect to the power supply. This is an adaptation of the OLED display element to the shape of the electrical device, in particular then when the electrical device no flat surfaces has, problematic. Thus, when using non-planar housing surfaces often cavities, which the handiness of the device clearly can reduce.

Another disadvantage is that the production time of an electrical device with an OLED display element by the necessary mechanical and electrical connection of OLED display element and electrical device leads to a relatively high production time, which means a cost disadvantage. DE 19840772 C1 discloses a display device in the form of a liquid crystal display device in which connection wires can be inserted and positioned in a manner which is easy to handle by machine. However, the contacting takes place here later, ie after the display device.

Additionally disadvantageous affects the use of a flat glass substrate, on which the display is built into an electrical device before installation is, insofar from, as the substrate a significant proportion on the total weight of the display forms.

In WO 03/041080 A2 becomes a housing of the type mentioned above, for described a container on the surface of an OLED display element can be applied. A part of the housing can be used as a substrate for the OLED display element may be formed. From this document goes does not indicate how the OLED display element is applied to the housing becomes.

It is known that OLED display elements are sensitive to oxygen and moisture and a corresponding protective layer is required to improve the service life. In DE 69911524 T2 describes a method by which the application of barrier layers can prevent oxygen and moisture from entering the cathode layers and the light-emitting layers of display elements. These barrier layers comprise two polymer layers and an inorganic oxide or nitride layer interposed between the polymer layers.

The space and weight saving integration of a display element in an electrical device is off US 2002-01 07 044 (Matsushita Electric Industrial Co.) and JP 2000-193947 (Canon Inc.). A disadvantage of the above-described devices, however, is that the display must first be built on a substrate and subsequently installed in a device, whereby a relatively high production time is required.

It is therefore an object of the present invention, a device of the above mentioned type with at least one OLED display element, in which an OLED display element particularly space and weight saving can be integrated. In particular, three-dimensional, i.e. not even display formats are possible. Furthermore is It is an object of the invention to provide a method for producing an electrical equipment specify with at least one OLED display element, which is a less number of manufacturing steps than the known methods according to the prior art, in particular a subsequent mechanical and electrically connecting the OLED display element and the housing of the electrical device avoids.

These Tasks are achieved by the features in the characterizing part of claim 1 (device claim) and claim 11 (method claim) in cooperation with the characteristics in the upper term. Preferred embodiments of the invention are in the subclaims contain.

For this purpose, an electrical device is provided with a housing and at least one OLED display element, wherein the electrical device has a power supply or is connected or connectable to a power supply, and Substrate for the OLED display element is at least partially formed by the housing of the electrical device, wherein between a housing surface and the housing surface nearest layer of the OLED display element, a barrier layer is disposed, wherein the nearest layer of the OLED display element is an electrode layer and the barrier layer of silicon oxynitride consists.

In a preferred embodiment of the Invention is the substrate for the OLED display element completely through the case, preferably through the outside of the housing of the electrical device educated. This means that the OLED display element directly on the case of the electrical device applied or manufactured, without previously on an extra provided for it Substrate to be applied. This will be advantageous the use of a substrate (usually a glass substrate) on which applied according to the prior art, the OLED display element first is saved. Thus, the housing surface provides the substrate for the OLED display element represents.

Surprisingly was found to be a direct application of an OLED display element on a housing surface, itself if this has a non-planar surface, by use the ink jet printing technique for applying the (polymeric) emitter molecules is possible.

It is according to the invention thereby provided the housing area, on which the OLED display element is to be arranged, in such a way to treat or structure, as for the production and function an OLED display element is advantageous. So is in a preferred variant a surface structuring for fixing an ink drop (polymer ink) on the case, the Application of barrier layers against oxygen and moisture and / or the application of metal layers for charge injection into the OLED structure etc. provided.

In a further, preferred embodiment is the driver electronics for the OLED display element inside the housing of the electrical device arranged, wherein the connecting line between driver electronics and OLED display element the casing penetrates. Preferably, the connection line between Driver electronics and OLED display element a plug on.

The inventive method for producing an electrical device with a housing and at least one OLED display element, wherein at least a part of the Electrode layers and the emitter layer of the OLED display element directly on the housing surface of the equipment be applied, is characterized in that in advance the contacts for contacting the electrode layers with the driver electronics of the OLED display element are introduced into the housing, wherein the contacts penetrate the housing and with the outside the housing is finally formed and subsequently the electrode layers directly onto the contacts be applied. As a result, advantageously, a subsequent connection avoided the OLED display element with the driver electronics, which the production time of the device according to the invention can be significantly reduced can.

At the inventive method becomes at least a part of the layers of the OLED display element, i.e. the anode layer, the cathode layer and the emitter layer, directly on the housing surface of the electrical device applied. In a particularly preferred embodiment, the electrode layers (Anode and cathode layer) and the emitter layer of the OLED display element Completely on the housing surface of the electrical device, applied without prior use of an additional substrate. This means that the housing surface as Substrate (carrier) for the OLED display element is used.

To The state of the art for OLED displays Ribbon cable used, for example, in a passive matrix OLED display element at one end using soldering techniques the cathode or anode lines of the OLED display element are connected. On the other side of the connecting line is a plug for connection provided with the driver electronics. By a direct application the anode or Kothodenschicht on the previously integrated into the housing connector or on the previously integrated connection line can be an afterthought soldering step be saved. For this purpose, preferably the anode layer is directly on the contact for contacting the anode layer (with the driver electronics) of the OLED display element applied by thermal evaporation. The cathode layer is preferably directly on the contact for contacting the cathode layer (with the driver electronics) of the OLED display element by thermal Vaporizing and / or RF sputtering applied. Furthermore, it is intended before applying the first layer of the OLED display element on the housing surface one Barrier layer, which preferably consists of silicon oxynitride, applied. This barrier layer is intended to be the OLED display element especially against oxygen and moisture, which is the lifetime of the OLED display element can reduce protect.

One particular advantage of the invention is the increased freedom in device design by the geometrical adaptation of the display element to the mold of the electrical device. It is possible according to the invention in a particularly simple manner, the shape the display element even with three-dimensionally shaped housings of Shape of the housing of the electrical device adapt. Another advantage of the invention is the weight reduction of the device, which due to the saving of conventionally for display generation required Substrates enabled becomes. Another advantage of the invention is a cost reduction which by saving the substrate, by saving the mechanical and electrically connecting the OLED display element and housing as well by saving a soldering step for connecting OLED display and driver electronics or OLED display and plug connection can be achieved.

The Invention will be explained in more detail with reference to an embodiment. It demonstrate:

1 an electrical device with an OLED display element in a perspective view, wherein the housing of the electrical device has a non-planar shape,

2 to 9 the steps for producing a device according to the invention in a schematic, sectional representation, in detail:

2 the housing of an electrical appliance in a sectional view,

3 the device after insertion of the anode and cathode contact,

4 the device after introducing a barrier layer,

5 the device after application of the anode layer,

6 the device after application of a hole transport layer,

7 the device after application of the emitter layer,

8th the device after applying the transparent cathode layer and

9 the device after applying a second barrier layer.

1 illustrates the principle of the invention with reference to a design example in which a simple display element 1 on the case 2 a mobile phone is applied. The housing 2 is three-dimensionally shaped and the display element 1 follow this form.

To make the top of the cellphone, a polycarbonate-based plastic is molded by standard techniques such as injection molding or thermoforming. In the area where the display element 1 are to be located, become wells 3 as well as holes 4 according to 2 brought in.

In a next step, copper contacts are inserted into the holes of the housing such that the contacts terminate smoothly with the top of the housing bottom and so far from the bottom of the housing 2 stand out that a simple plug connection with commercially available plug contacts is possible. These contacts 5 . 6 serve later for contacting the anode or cathode ( 3 ).

In a next step, a silicon oxynitride layer is used as a barrier layer 7 against oxygen and moisture by RF sputtering applied in a layer thickness of 500 nm. Laser ablation makes this barrier layer 7 removed on the electrical contacts ( 4 ).

In a next step, the anode layer 8th educated. For this purpose, a 300 nm thick nickel layer is generated by thermal evaporation from a tungsten boat using a shadow mask ( 5 ).

In a next step, a hole transport layer is formed 9 made of Baytron P ^® by ink jet printing technology as a 70 nm thick layer. Subsequently, the device is annealed at 90 ° C ( 6 ).

In a next step becomes an emitter layer 10 applied from a light-emitting polymer by means of inkjet printing technology, eg "SuperYellow" from Covion was used in a layer thickness of 90 nm as LEP material ( 7 ).

In a next step, a transparent cathode layer 11 applied. The cathode 11 consists of one 12 nm thick calcium layer, a 20 nm thick barium layer and is applied by thermal evaporation. The cathode 11 is through a 300 nm thick

1

OLED display element

2

Housing / housing surface

3

deepening

4

penetration of the housing

5

anode contact

6

Katodenkontakt

7

barrier layer

8th

First Electrode / anode layer

9

Hole transport layer

10

emitter layer

11

Second Electrode / cathode

12

barrier layer

Indium tin oxide (ITO) layer produced by RF sputtering using a mixed target (90% In ₂ O ₃ ; 10% SnO ₂ ) in an O ₂ / Ar gas mixture ( 8th ). In a final step, the barrier layer becomes 12 applied over the entire display element ( 9 ).

By the inventive design of electrical device with an OLED display element, the use of a glass substrate, a subsequent electrical and mechanical connection of OLED display element and housing as well The Kontatkierung of anode / cathode and connecting line / plug by soldering be saved. Furthermore, by the direct application of a OLED display element on the housing of an electrical device the Adaptation of the display element to non-planar housing forms allows in a particularly simple manner.

Claims (18)

Electrical device with a housing ( 2 ) and at least one OLED display element ( 1 ), wherein the electrical device has a power supply or is connected or connectable to a power supply, and the substrate for the OLED display element ( 1 ) at least partially through the housing ( 2 ) of the electrical device is formed, wherein between a housing surface ( 2 ) and the housing surface ( 2 ) nearest layer of the OLED display element ( 1 ) a barrier layer ( 7 ), characterized in that the nearest layer of the OLED display element ( 1 ) an electrode layer ( 8th ) and the barrier layer ( 7 ) consists of silicon oxynitride. Apparatus according to claim 1, characterized in that the substrate for the OLED display element ( 1 ) completely through the housing ( 2 ) of the electrical device is formed. Device according to one of claims 1 or 2, characterized in that the OLED display element ( 1 ) on the outside of the housing ( 2 ) is arranged. Device according to one of claims 1 to 3, characterized in that the driver electronics for the OLED display element ( 1 ) is arranged inside the housing, wherein the connecting line between the driver electronics and OLED display element ( 1 ) the housing ( 2 ) penetrates. Apparatus according to claim 4, characterized in that the connecting line between the driver electronics and OLED display element ( 1 ) has a plug. Device according to one of claims 1 to 5, characterized in that the emitter layer ( 10 ) of the OLED display element ( 1 ) consists of polymeric organic phosphors. Device according to one of claims 1 to 6, characterized in that the housing surface ( 2 ) nearest electrode layer the anode layer ( 8th ) and the electrode layer removed from the housing surface, the cathode layer ( 11 ) trains. Device according to one of claims 1 to 7, characterized in that the anode layer ( 8th ) of nickel with a layer thickness of 300 nm and the cathode layer ( 11 ) consists of 12nm calcium / 20nm barium / 300nm indium tin oxide. Device according to one of claims 1 to 8, characterized in that above the cathode layer ( 11 ) a barrier layer ( 12 ) is arranged. Device according to claim 9, characterized in that the barrier layer ( 12 ) consists of silicon oxynitride. Method for producing an electrical appliance with a housing ( 2 ) and at least one OLED display element ( 1 ), wherein at least a part of the electrode layers ( 8th . 11 ) and the emitter layer ( 10 ) of the OLED display element ( 1 ) directly onto the housing surface ( 2 ) of the electrical device, characterized in that in advance the contacts ( 5 . 6 ) for contacting the electrode layers ( 8th . 11 ) with the driver electronics of the OLED display element ( 1 ) in the housing ( 2 ), the contacts ( 5 . 6 ) the housing ( 2 ) penetrating and with the outside of the housing ( 2 ) and subsequently the electrode layers ( 8th . 11 ) directly on the contacts ( 5 . 6 ). Method according to claim 11, characterized in that the electrode layers ( 8th . 11 ) and the emitter layer ( 10 ) of the OLED display mentes ( 1 ) completely on the housing surface ( 2 ) of the electrical device are applied. Method according to one of claims 11 or 12, characterized in that prior to the application of the first electrode layer ( 8th ) a barrier layer ( 7 ) on the housing surface ( 2 ) of the electrical device is applied. Method according to one of claims 11 to 13, characterized in that the barrier layer ( 7 ) is applied by RF sputtering. Method according to one of claims 11 to 14, characterized in that the anode layer ( 8th ) directly on the contact ( 5 ) for contacting the anode layer ( 8th ) with the driver electronics of the OLED display element ( 1 ) is applied by thermal evaporation. Method according to one of claims 11 to 15, characterized in that the cathode layer ( 11 ) directly on the contact ( 6 ) for contacting the cathode layer ( 11 ) with the driver electronics of the OLED display element ( 1 ) is applied by thermal evaporation and / or RF sputtering. Method according to one of claims 11 to 16, characterized in that the emitter layer ( 10 ) is applied by ink jet printing. Method according to one of claims 11 to 17, characterized in that on the of the housing surface ( 2 ) more distant electrode layer ( 11 ) a barrier layer ( 12 ) is applied.