KR100469241B1 - Organic Electroluminescence Device for eliminating static electricity - Google Patents

Abstract

SUMMARY OF THE INVENTION The present invention provides an organic EL device for removing static electricity, wherein an organic light emitting layer is formed at a position where a plurality of first and second electrodes each intersect each other on a substrate has a light emitting area and seals the organic light emitting layer. An organic EL device having a seal cover, comprising: a conductive discharge path formed on one side of an upper portion of the substrate and grounded on one side of the organic EL device to discharge static electricity generated in or outside the device; When the substrate or seal cover of the device is conductive, a discharge path is simply formed of a conductive material and grounded. If the substrate or seal cover is non-conductive, the conductive discharge is connected to the conductive shield plate formed on one side of the substrate or seal cover. The static electricity is discharged through the furnace to minimize the influence of the electrostatic discharge of the organic EL element.

Description

Organic electroluminescence device for eliminating static electricity

The present invention relates to an electrostatic discharge (hereinafter, ESD) of an organic EL element.

The organic EL device is a device that emits light when electrons and holes are paired and extinguished when electric charge is injected into the organic film formed between the electron injection electrode (cathode) and the hole injection electrode (anode). In addition, the device is characterized in that the power consumption is relatively low.

In general, since the thickness of the organic EL element is very thin, about 200 nm, it can be easily destroyed by an external strong electric shock. Strong electrical shock can be caused to EL elements by ESD. In general, static electricity can be easily formed by friction, and the voltage at this ESD ranges from thousands to tens of thousands of volts.

Devices or systems that are exposed to ESD can destroy or cause some form of degradation. Spark-type discharges can cause interfering electromagnetic pulses over a wide frequency band, causing system disturbances, or even destroying the system completely, making it inoperable.

Such ESD generally provides the cause of thermal breakdown, dielectric breakdown, metal melting, etc.

Thermal breakdown is concentrated when the ESD pulse is applied and the heat is not spread, and the temperature coefficient of the resistance of this part becomes negative so that even if the current is shunted, thermal runaway occurs and the junction is shorted. It is a phenomenon.

Dielectric breakdown is the breakdown of insulation and breakdown of the insulation when the voltage across the dielectric is more than the characteristics of the dielectric.Metalization Melt is a phenomenon in which the temperature of the device is increased by ESD, causing the metal to melt or the junction line to fall. to be.

Accordingly, an object of the present invention is to provide a conductive discharge path around an organic EL device or a module in a product or system equipped with the organic EL device, and to protect the organic EL device from ESD. have.

1 is a schematic diagram of an electrostatic elimination organic EL device according to the present invention;

2a to 2c show a first embodiment according to the present invention according to the conceptual diagram of FIG.

3 is a schematic diagram of an electrostatic eliminating organic EL device according to the present invention;

4a to 4c show a first embodiment according to the present invention according to the conceptual diagram of FIG.

* Explanation of symbols for main parts of the drawings

1, 10: substrate 2, 50: seal cover

3: sealing agent 4: element layer

5: conductive discharge furnace 5-1, 50-1: conductive shield plate

20: first electrode 30: organic light emitting layer

40: second electrode 20-1, 40-1, 70-2: electrode line

70 conductive pattern 70-1 contact line

80: sealing agent

The organic EL device for removing static electricity according to the present invention for achieving the above object is characterized in that the organic light emitting layer is formed at a position where a plurality of first and second electrodes each formed on the substrate cross each other to form a light emitting area In an organic EL device having a seal cover for sealing the organic light emitting layer, a conductive pattern is formed and grounded on one side of the upper portion of the substrate to discharge static electricity generated inside or outside the device on one side of the organic EL element. An electroconductive discharge furnace is provided.

A conductive pattern is further formed on one side of the upper substrate, and when the seal cover is conductive, the conductive pattern is formed to contact the seal cover.

The conductive discharge path is formed to be connected to the conductive pattern in a tab region that is connected to an external module for driving the organic EL element, or is formed outside the organic EL element to be connected to the conductive seal cover.

A conductive pattern is further formed on one side of the upper portion of the substrate, and when the seal cover is non-conductive, the conductive pattern is formed to be in contact with the conductive shield plate.

The conductive discharge path is formed by being connected to the conductive pattern in a tab region that is connected to an external module for driving the organic EL element, or is formed outside the organic EL element by being connected to the shield plate.

The action according to the characteristics of the present invention is to provide a conductive discharge path inside or outside the organic EL element. When the substrate or seal cover is conductive, the discharge path is simply formed of a conductive material and grounded. In the case of non-conductive, the influence of the electrostatic discharge of the organic EL device can be minimized by allowing the electrostatic discharge to escape through the conductive shield plate formed on one side of the substrate or the seal cover and the conductive discharge path connected to the shield plate.

Other objects, features and advantages of the present invention will become apparent from the following detailed description of embodiments taken in conjunction with the accompanying drawings.

A preferred embodiment of the electrostatic elimination organic EL device according to the present invention will be described with reference to the accompanying drawings.

First embodiment

1 is a schematic diagram of an electrostatic elimination organic EL device according to the present invention.

As shown in Fig. 1, the organic EL element includes an element layer 4 formed on the substrate 1, a seal cover 2 which is sealed by a sealing agent 3 to protect the element layer 4; When the substrate 1 or the seal cover 2 is conductive, the substrate 1 or the seal cover 2 includes a conductive discharge path 5 connected to the substrate 1 or the seal cover 2.

As shown in Fig. 1, a suitable method for protecting an organic EL element from electrostatic discharge (hereinafter, ESD) is to provide a conductive discharge path 5 around the organic EL element to quickly dissipate static electricity.

In order to quickly dissipate static electricity, grounding the organic EL element as shown in Fig. 1 simply provides a way for the charge to move to or from the earth.

2A to 2C are first embodiments according to the present invention according to the conceptual diagram of FIG. 1, and FIG. 2A is a plan view of an organic EL device for eliminating static electricity according to the present invention, and FIGS. 2B and 2C are respectively shown in FIG. 2A. Figure 1 shows one end along the direction of Ⅰ-Ⅰ '.

As shown in FIGS. 2A to 2C, the organic light emitting layer 30 is formed at positions where the first electrodes 20 and the second electrodes 40 each formed on the substrate 10 intersect with each other to emit light. In an organic EL device having a region and a seal cover 50 in which the organic light emitting layer 30 is sealed by a sealing agent 80, when the seal cover 50 is conductive, one side of the organic EL device is provided. The present invention provides a conductive discharge path that is connected to the seal cover 50 and discharges static electricity through the ground for electrostatic discharge generated outside or inside the device.

As shown in FIG. 1, the conductive discharge path is directly connected to the conductive seal cover 50 and formed outside the organic EL element. The conductive discharge path contacts the ground line to discharge static electricity. By doing so, static electricity flowing through the surface of the conductive substrate 10 or the seal cover 50 can be removed to the ground.

When the static electricity is discharged to the conductive seal cover 50 side, as described above, a conductive discharge path may be formed of a conductive material and contacted with the ground wire.

In addition, when the substrate 10 is conductive, the conductive discharge path is directly connected to the substrate 10 and formed outside the organic EL element. The conductive discharge path contacts the ground line to discharge static electricity.

In forming the conductive discharge path, it is much more effective to form the conductive discharge path by forming the conductive pattern 70 inside the substrate 10. A discharge path is formed in a predetermined region on the substrate 10 to be connected to the conductive pattern in a tab region by forming a pattern made of a conductive material that is not in contact with the electrode of the device, or as shown in FIG. The static electricity generated in the substrate 10 is discharged to the outside of the device through an external discharge path directly connected to the conductive seal cover 50.

Therefore, the conductive pattern 70 is formed to contact the conductive seal cover 50 by forming a portion of the conductive seal cover 50 on one side of the upper portion of the substrate 10, and at least a portion of the sealing portion and the region is formed. The conductive pattern 70 is formed to be shared.

In addition, the conductive pattern 70 is formed only in a partial region of the substrate to be in electrical contact with the conductive seal cover 50, so that the conductive pattern 70, the conductive seal cover 50, and an external conductive discharge path are connected to the ground. The static electricity generated from the substrate 10 side is discharged to the outside through the path of.

The conductive pattern 70 is formed at a corner of the upper portion of the substrate so as to be in electrical contact with the conductive seal cover 50, and is formed in a tab region and connected to ground, as shown in FIG. 1. The static electricity generated from the substrate 10 side is discharged to the outside through a discharge path connected to the seal cover 70 outside the organic EL element.

For example, the electrode 20 of the device may be formed in a tab region for electrically connecting the electrode lines 20-1 and 40-1 connected to the external module of the organic EL device and the electrodes 20 and 40 of the device. And the conductive pattern 70 is formed so as not to contact with 40. And a line connected to the contact line 70-1 at one side of the contact line 70-1 connected to the conductive pattern 70 and an electrode line 20-1, 40-1 connected to an external module. A conductive discharge path made of 70-2 is formed to discharge the static electricity quickly by connecting the conductive discharge path to ground.

FIG. 2C is the same as that of FIG. 2B, and the auxiliary electrode 90 is further formed in the predetermined region on the first electrode 20 and the predetermined region on the sealing agent 80.

Second embodiment

3 is a schematic diagram of an electrostatic eliminating organic EL device according to the present invention.

As shown in FIG. 3, the organic EL element includes an element layer 4 formed on the substrate 1, a seal cover 2 sealed by a sealing agent 3 to protect the element layer 4; When the substrate 1 or the seal cover 2 is non-conductive, the conductive shield plate 5-1 surrounding the substrate 1 or a part of the seal cover 2, the conductive shield plate 5-1, It is comprised including the conductive discharge furnace 5 connected.

The conductive discharge path 5 is formed in a tab region that connects to an external module for driving the organic EL element or, as illustrated, to be electrically connected to the substrate 1 or the seal cover 2. Is formed on the outside.

As shown in Fig. 3, when the organic EL element is grounded to provide a conductive discharge path 5 around the organic EL element to quickly dissipate the static electricity, the path for the electric charge can simply move to or from the earth. To provide.

4A to 4C are a first embodiment according to the present invention according to the conceptual diagram of Fig. 3, and Fig. 4A is a plan view of the electrostatic elimination organic EL element according to the present invention, and Figs. 4B and 4C are respectively shown in Fig. 4A. One end surface along the II-II 'direction is shown.

As shown in FIGS. 2A to 2C, the organic light emitting layer 30 is formed at positions where the first electrodes 20 and the second electrodes 40 each formed on the substrate 10 intersect with each other to emit light. In an organic EL device having a region and a seal cover 50 for sealing the organic light emitting layer 30 with a sealing agent 80, when the substrate 10 or the seal cover 50 is non-conductive, the substrate Or a conductive shield plate 50-1 surrounding a part of the seal cover, and a conductive discharge path connected to and grounded with the conductive shield plate 50-1 to discharge static electricity flowing through the non-conductive substrate or seal cover. It is composed.

When the substrate 10 or the seal cover 50 is non-conductive, the organic EL element is surrounded by the conductive shield plate 50-1 so as not to flow toward the organic EL element during electrostatic discharge. By doing so, the static electricity flowing through the surface of the non-conductive substrate 10 or the seal cover 50 can be removed to the ground.

As shown in FIG. 3, the conductive discharge path is connected to the conductive shield plate 50-1 and formed outside the organic EL element, and is simple as described above when static electricity is discharged to the seal cover 50 side. In this case, the shield plate 50-1 and the conductive discharge path may be formed of a conductive material to contact the ground line.

In addition, when the substrate 10 is non-conductive, a conductive shield plate 50-1 is formed on one side of the substrate 10 so that the conductive discharge path is connected to the conductive shield plate 50-1 so that the outside of the organic EL element is connected to the conductive shield plate 50-1. It may be formed in contact with the ground wire.

In forming the conductive discharge path, it is much more effective to form the conductive discharge path by forming the conductive pattern 70 inside the substrate 10. A discharge path is formed in a predetermined region on the substrate 10 to be connected to the conductive pattern in a tab region by forming a pattern made of a conductive material that is not in contact with the electrode of the device, or as shown in FIG. The static electricity generated in the substrate 10 is discharged to the outside of the device through an external discharge path directly connected to the conductive shield plate 50-1.

Therefore, the conductive pattern 70 is formed on one side of the upper portion of the substrate 10 to be in contact with the conductive shield plate 50-1, and at this time, the conductive pattern 70 is formed by sharing a region with at least a portion of the sealing portion.

The conductive pattern 70 is formed only in a portion of the substrate so as to be in electrical contact with the conductive shield plate 50-1, and then passes through the conductive pattern 70, the conductive shield plate 50, and the conductive discharge path. The static electricity generated from the substrate 10 side is discharged to the outside.

In addition, the conductive pattern 70 is formed at a corner of the upper portion of the substrate so as to be in electrical contact with the conductive shield plate 50-1, and is formed in a tab region and is connected to ground. As described above, the static electricity generated from the substrate 10 side is discharged to the outside through another discharge path formed in the outside of the organic EL element by being connected to the shield plate 50-1.

For example, the electrode 20 of the device may be formed in a tab region for electrically connecting the electrode lines 20-1 and 40-1 connected to the external module of the organic EL device and the electrodes 20 and 40 of the device. And the conductive pattern 70 is formed so as not to contact with 40. And a line connected to the contact line 70-1 at one side of the contact line 70-1 connected to the conductive pattern 70 and an electrode line 20-1, 40-1 connected to an external module. A conductive discharge path made of 70-2 is formed to discharge the static electricity quickly by connecting the conductive discharge path to ground.

FIG. 4C is the same as that of FIG. 4B, and the auxiliary electrode 90 is further formed on the upper predetermined region of the first electrode 20 and the upper predetermined region of the sealing agent 80.

The organic EL device for eliminating static electricity according to the present invention as described above has the following effects.

If the substrate or seal cover of the device is conductive, a discharge path is simply formed of a conductive material and grounded. If the substrate or seal cover is non-conductive, a conductive shield plate formed on one side of the substrate or seal cover, and the shield plate, The effect of electrostatic discharge of the organic EL element is minimized by allowing static electricity to escape through the connected conductive discharge furnace.

In addition, a conductive pattern is further formed on the substrate to be in contact with the conductive seal cover or the conductive shield plate, and a conductive discharge path connected to the conductive pattern is formed together in the tab region of the external module for driving the device. By minimizing this, the influence of the electrostatic discharge of the organic EL element is minimized.

Those skilled in the art will appreciate that various changes and modifications can be made without departing from the spirit of the present invention.

Therefore, the technical scope of the present invention should not be limited to the contents described in the embodiments, but should be defined by the claims.

Claims (7)

An organic EL device having an organic light emitting layer formed at a position where a plurality of first electrodes and a second electrode formed on a substrate cross each other, each having a light emitting region, and having a seal cover for sealing the organic light emitting layer, And an electroconductive discharge path having a conductive pattern formed on one side of the substrate and grounded at one side of the upper surface of the organic EL element to discharge static electricity generated from the outside or the inside of the element. delete The organic EL device of claim 1, wherein a conductive pattern is further formed on one side of the upper portion of the substrate, and the conductive pattern is formed to contact the seal cover when the seal cover is conductive. 2. The conductive discharge path of claim 1, wherein the conductive discharge path is formed in a tab region connected to an external module for driving the organic EL element to be connected to the conductive pattern or is formed outside the organic EL element to be connected to the conductive seal cover. An organic EL device for removing static electricity, characterized in that. delete The organic material of claim 1, wherein a conductive pattern is further formed on one side of the upper portion of the substrate, and when the substrate or the seal cover is non-conductive, the conductive pattern is formed to contact the conductive shield plate. EL element. 2. The conductive discharge path of claim 1, wherein the conductive discharge path is formed in a tab region that is connected to an external module for driving the organic EL element to be connected to the conductive pattern or is formed outside the organic EL element to be connected to the shield plate. An organic EL device for eliminating static electricity, characterized in that.