KR20030052448A - Display for using organic thin film electroluminescence device - Google Patents

Abstract

The present invention relates to a display using an organic thin film electroluminescence (EL) device, comprising: a transparent insulating substrate; A transparent electrode deposited on a transparent insulating substrate; An organic electroluminescent device deposited on top of the transparent electrode on which the transparent electrode is deposited; A sealing cap which seals the organic electroluminescent device such as an insulating substrate and forms a sealing space; A polymer matrix attached to a position opposite to the organic electroluminescent element at a lower portion of the sealing cap in the sealing space and including a moisture absorbent absorbing moisture; And an organic electroluminescent thin film display facing the organic electroluminescent device and formed on the polymer matrix, or using a porous polymer matrix having pores in the polymer matrix. The absorption function is improved to prevent deterioration due to moisture, which prevents the generation of dark spots in which the organic electroluminescent device does not emit light, thereby increasing display brightness and improving lifetime.

Description

DISPLAY FOR USING ORGANIC THIN FILM ELECTROLUMINESCENCE DEVICE}

The present invention relates to a display using an organic thin film electroluminescence device, and in more detail, an alkali metal film is deposited on a polymer matrix on a display to cause chemical reaction between alkali metals and moisture, The present invention relates to a display using an organic thin film electroluminescent device in which the moisture absorption function of the polymer matrix is improved by using a porous polymer compound to allow the introduced moisture particles to move from the surface of the polymer matrix to the inside.

The electroluminescence phenomenon has been actively applied to specific fields such as lighting and rear light source since its discovery, but its field of use has been extremely limited due to problems in brightness and lifespan. Electroluminescent devices are faster in response than light-receiving devices such as LCDs, which are currently being spotlighted as flat panel displays, and because they are self-luminous, they have a wide viewing angle, excellent brightness, excellent visibility, and no backlight. I can make it. In addition, the structure is simple, easy to manufacture during production, low power consumption is possible as a promising next-generation flat panel display. Electroluminescence is largely classified into inorganic electroluminescence and organic electroluminescence according to the type of material used as the light emitting layer. Inorganic electroluminescence requires the driving voltage to be high to emit light with high brightness. Therefore, research has been conducted on organic electroluminescence that can lower the driving voltage.

In addition, the organic thin film electroluminescent device has an advantage in that the organic thin film constituting the electroluminescent device can be formed to have an extremely thin thickness.

However, in spite of the above advantages, the organic thin film electroluminescent device using organic thin film materials is easily affected by moisture present in the area around the organic electroluminescent display device, and thus there is a problem such as lifespan, which causes certain limitations in use. Do it. For example, moisture that penetrates through the interface between the light emitting layer and the electrode interferes with the injection of the electrode, causes dark spots that do not emit light, and causes corrosion of the electrode, thereby limiting its use. Black spots grow and do not emit as deterioration progresses. Therefore, a technique for removing or preventing moisture has been developed by sealing the organic electroluminescent device to prevent such deterioration and to prevent corrosion of the electrode.

1 is a cross-sectional view of a general organic thin film electroluminescent device. Referring to FIG. 1, the organic thin film electroluminescent device 200 deposits a transparent electrode (ITO electrode: anode: 215) on a transparent substrate 210 and an organic electroluminescent layer 223 made of an organic electroluminescent material. ) And an organic electroluminescent laminate 220 laminated in the order of the counter electrode (cathode: 225).

In order to prevent the organic thin film electroluminescent device configured as described above from being corroded and deteriorated by the moisture in the air, the sealing cap for sealing the organic electroluminescent laminate 220 is adhered to the transparent substrate 210 by using an adhesive. It is possible to isolate the polymer matrix from the atmosphere, and the organic thin film electric field to absorb the moisture penetrating into the sealing cap is provided with a polymer matrix that is formed opposite the organic electroluminescent laminate 220 in the sealing cap to absorb moisture A light emitting device is constructed to be used in a display.

The polymer matrix is formed by mixing CaO and BaO with the base polymer to form a film. At this time, the absorbent exposed to the front of the polymer matrix has an effect of removing moisture, while the absorbent particles located inside the polymer film transfer moisture to the inside of the polymer film. Moisture absorption is impaired. Therefore, the effect of absorbing moisture is reduced, causing the electrode to corrode and deteriorate to generate black spots.

Accordingly, an object of the present invention is to solve the problems of the prior art, the water absorbed in the polymer matrix by using a film deposited on the polymer matrix with an alkali metal having excellent reactivity with water reacts with the alkali metal. Improve the reaction function of the polymer matrix with water,

In addition, to provide a display using an organic thin film electroluminescent device to create a path through which moisture can move using a porous polymer matrix to increase the water absorption capability of the absorbent in the polymer matrix.

The above object is a display using an organic thin film electroluminescent device according to the present invention, a transparent insulating substrate; A transparent electrode deposited on a transparent insulating substrate; An organic electroluminescent device deposited on top of the transparent electrode on which the transparent electrode is deposited; A sealing cap which seals the organic electroluminescent device such as an insulating substrate and forms a sealing space; A polymer matrix attached to a position opposite to the organic electroluminescent element at a lower portion of the sealing cap in the sealing space and including a moisture absorbent absorbing moisture; And, it can be achieved by providing a display using an organic electroluminescent thin film, characterized in that the alkali metal thin film is formed on the polymer matrix facing the organic electroluminescent device,

Transparent insulating substrates; A transparent electrode deposited on a transparent insulating substrate; An organic electroluminescent device deposited on top of the transparent electrode on which the transparent electrode is deposited; A sealing cap that seals the organic electroluminescent device such as an insulating substrate to form a sealing space; And an organic electroluminescent thin film attached to a lower portion of the sealing cap in a sealed space, the organic electroluminescent device being attached to a position opposite to the organic electroluminescent device and including a moisture absorbent absorbing moisture and having a porous polymer matrix having pores formed therein. It can be achieved by providing

In addition, a transparent insulating substrate; A transparent electrode deposited on a transparent insulating substrate; An organic electroluminescent device deposited on top of the transparent electrode on which the transparent electrode is deposited; A sealing cap which seals the organic electroluminescent device such as an insulating substrate and forms a sealing space; A porous polymer matrix attached to a position opposite to the organic electroluminescent element at a lower portion of the sealing cap in the sealing space and including an absorbent absorbing moisture and having pores formed therein; And, it can be achieved by providing a display using an organic electroluminescent thin film, characterized in that the alkali metal thin film is formed opposite to the organic electroluminescent device and formed on the polymer matrix.

1 is a cross-sectional view of a general organic thin film electroluminescent device.

2 is a cross-sectional view of one embodiment of a display using an organic thin film electroluminescent device according to the present invention.

3 is a cross-sectional view showing the structure of a polymer matrix used in a display using an organic electroluminescent device according to the present invention.

4 is a cross-sectional view showing the form of a porous polymer compound film.

The present invention will be more clearly understood from the following description, in comparison with the prior art, with reference to the accompanying drawings.

2 is a cross-sectional view of one embodiment of a display using an organic thin film electroluminescent device according to the present invention. Referring to Figure 2,

The display 100 using the organic thin film electroluminescent device deposits the transparent electrode 15 on the transparent and flat transparent substrate 10 and the transparent substrate 10, and the organic thin film 23 made of the organic electroluminescent material and the opposite surface. The organic electroluminescent laminate 20 laminated in the order of the electrode 25, a sealing cap 30 is fixed to the transparent substrate 10 by using an adhesive 80 and seals the organic electroluminescent laminate 20, Argon formed in the sealing cap 30 and formed of a polymer compound matrix 40 disposed to face the organic electroluminescent laminate 20, and formed in the space formed by the sealing cap 30 and the transparent substrate 10. Fill inert gas such as gas.

The organic thin film 23 emits light by applying a negative voltage to the counter electrode 25 of the organic electroluminescent laminate 20 and applying a positive voltage to the transparent electrode 15. Electrons are injected into the counter electrode 25 and holes are injected into the transparent electrode 15. In general, since the energy barrier on the cathode side is high, it is difficult to inject electrons, so diode characteristics having rectification in the flow of current appear. The carriers of electrons and holes produce negative and positive flaons, respectively, by interacting with phonons in the organic material, and each generated flaon moves to the opposite electrode, where the negative and positive flaons bind to each other. To form. At this time, the flaon-excitation emits light to stabilize the ground.

The organic electroluminescent laminate 20 may be formed through the following process. The organic thin film 23 and the counter electrode 25 are subjected to a photolithography and a wet etching process by using a vacuum deposition technique on the transparent substrate 10 on which the transparent electrode 15 and the wiring (not shown) forming the anode are formed. Are continuously formed to form the organic electroluminescent laminate 20 on the transparent substrate 10. The organic thin film 23 has a two-layer structure including a hole transport layer made of diamine derivative (TPD), an electron transport layer made of tris (8-quinolinol) aluminum, and a light emitting layer. The counter electrode 25 is made of magnesium and indium.

The sealing cap 30 is adhered to the transparent substrate 10 with an adhesive 80 such as an UV-curable epoxy resin to form an airtight space therein to isolate the organic electroluminescent laminate 20 from the atmosphere, thereby thinning the organic thin film 23. ) Can be preserved and a stable inert gas is injected into the sealed space to prevent the organic thin film 23 from contacting with oxygen or moisture. The polymer matrix 40 is formed to face the organic electroluminescent laminate 20 in a sealed space and attached to the sealing cap.

The polymer matrix 40 is a means for absorbing moisture injected from the outside of the display 100 to prevent deterioration and corrosion of the organic thin film 23, and adding an absorbent such as CaO or BaO to the base polymer. Form. However, the absorbed water reacts with the absorbent on the surface of the polymer matrix 40 by the base polymer and does not react with the absorbent inside the polymer matrix 40, thereby limiting the amount of absorbed moisture. . Therefore, in order to improve the function of absorbing moisture, an alkali metal having good reactivity with water is deposited on the surface of the polymer matrix 40.

3 is a cross-sectional view showing the structure of a polymer matrix used in a display using an organic electroluminescent device according to the present invention. Referring to Figure 3,

The polymer matrix 40 is formed by depositing an alkali metal 42 such as lithium on the polymer compound film 41 and the polymer compound film 41 that absorb moisture by including a moisture absorbent. Then, an adhesive 43 such as a UV curable epoxy resin is applied to a surface opposite to the surface on which the alkali metal 42 is deposited so that the polymer matrix 40 is fixed to the sealing cap 30. When the moisture contained in the atmosphere penetrates into the sealing cap 30, the polymer compound film 41 absorbs the moisture. The moisture is transferred into the polymer compound film 41 by the base polymer of the polymer compound film 41. If it does not, water is present on the surface. Therefore, the alkali metal 42 having good reactivity with water is deposited on the surface of the polymer compound film 41 so that the moisture formed on the surface reacts with the alkali metal 42 so that more moisture is added to the polymer compound film 41. To be absorbed.

4 is a cross-sectional view showing the form of a porous polymer compound film. Referring to FIG. 4, the polymer compound film according to the present invention has a path through which moisture penetrates into the polymer compound film 41 and is blocked by the base polymer, so that moisture is not easily absorbed, thereby forming water only on the surface of the polymer compound film. Since it is possible to secure a path for the moisture to reach the moisture absorbent inside so that more moisture can be absorbed in the polymer compound film (41).

Securing a path through which moisture penetrates into the polymer compound film 41 may be achieved by using the porous polymer compound film 41 ′.

The polymer compound film and the porous polymer compound film 41 'are prepared by dissolving a copolymer polymer containing a fluorine element such as PVDF-HFP (polyvinylidene difluoride-hexafluoropropylene) in an acetone solution. DBP (dibutyl phthalate) having a high vaporization temperature and a pore-forming body are injected and stirred to form a mixed solution, and then, an appropriate amount of the absorbent particles 52 such as CaO and BaO is added again to disperse well. Then, the mixed solution is coated on a flat glass substrate with a predetermined thickness, and then heated to about 50 ° C. to remove the acetone solution as a solvent, thereby obtaining a polymer compound film 41 including a moisture absorbent 52 and a pore-forming agent. When the polymer compound film 41 is placed in a Soxlet apparatus and the pore forming agent is extracted at 80 ° C., the pores 53 are formed in the place where the pore forming agent was, and the path through which the moisture can move is formed. Porous polymeric compound film 41 'is produced.

The pores generated in the porous polymer compound film 41 'is preferably formed to a size of about 1 ~ 10㎛. If the pore size is smaller than 1 μm, the flow path of moisture does not become large enough to transfer water, and the effect of the porous polymer compound film 41 ′ is reduced. If the pore size is larger than 10 μm, the porous polymer compound film The porous polymer compound 41 'can be easily broken by the water migration path generated by the pores at 41'. Therefore, the moisture absorption ability is poor and does not help to improve the lifetime of the organic thin film electroluminescence.

Since the main purpose of the display 100 using the organic electroluminescent device according to the present invention is to have a polymer matrix 40 having an excellent absorption function, the alkali metal 42 is deposited on a general polymer compound film 41 to obtain moisture. The absorption function may be improved, and the water absorption function may be improved by using the porous polymer compound film 41 ′. In addition, the alkali metal 42 may be deposited on the porous polymer compound film 41 ′ to improve the water absorption function.

The display using the organic electroluminescent device according to the present invention has a wider viewing angle, a faster response time, and a self-luminous form, compared to a light-receiving element such as a liquid crystal display. Easy to manufacture In addition, since the backlight is not required, the display can be manufactured to be extremely thin, and low power consumption is possible.

In addition, pores are formed in the polymer matrix used as the moisture absorbent to allow moisture to move along the pores so that the particles in the polymer matrix can absorb the moisture, and deposit an alkali metal such as lithium on one side of the polymer matrix. The polymer matrix absorbs water, and the water on the surface of the polymer matrix reacts with alkali metals, improving the water absorption function of the polymer matrix to prevent deterioration due to water, and thus preventing black light from emitting to the organic electroluminescent device. Prevents the creation of dark spots, increasing display brightness and improving lifetime.

While the preferred embodiments of the present invention have been described using specific terms, such descriptions are for illustrative purposes only, and it is understood that various changes and modifications may be made without departing from the spirit and scope of the following claims. Should be done.

Claims (5)

Transparent insulating substrates; A transparent electrode deposited on the transparent insulating substrate; An organic electroluminescent device deposited on top of the transparent electrode on which the transparent electrode is deposited; A sealing cap sealing the organic electroluminescent element like the insulating substrate to form a sealing space; A polymer matrix attached to a lower portion of the sealing cap in the sealing space to face the organic electroluminescent device and including a moisture absorbent to absorb moisture; And A display using an organic electroluminescent thin film, characterized in that an alkali metal thin film is formed opposite to the organic electroluminescent device and formed on the polymer matrix. Transparent insulating substrates; A transparent electrode deposited on the transparent insulating substrate; An organic electroluminescent device deposited on top of the transparent electrode on which the transparent electrode is deposited; A sealing cap sealing the organic electroluminescent element like the insulating substrate to form a sealing space; And The organic electroluminescent thin film is attached to a lower portion of the sealing cap in the sealing space, the organic electroluminescent device is attached to a position opposite to the organic electroluminescent device, and includes a porous polymer matrix having pores formed therein and including a moisture absorbent. display. Transparent insulating substrates; A transparent electrode deposited on the transparent insulating substrate; An organic electroluminescent device deposited on top of the transparent electrode on which the transparent electrode is deposited; A sealing cap sealing the organic electroluminescent element like the insulating substrate to form a sealing space; A porous polymer matrix attached to a lower portion of the sealing cap in the sealing space to face the organic electroluminescent device, the absorbent absorbing moisture, and having pores formed therein; And A display using an organic electroluminescent thin film, characterized in that an alkali metal thin film is formed opposite to the organic electroluminescent device and formed on the polymer matrix. The method according to claim 1 or 3, The alkali metal thin film is a display using an organic electroluminescent thin film, characterized in that the lithium. The method of claim 2 or 3, The pore size is a display using an organic electroluminescent thin film, characterized in that more than 1㎛ 10㎛.