KR100824966B1 - El device - Google Patents

Abstract

An EL(Electro Luminescence) is provided to simplify a manufacturing process and connection to an external terminal and improve a yield by minimizing an inner terminal of the EL device connected to the external terminal through a through hole. An EL device includes an ESD(ElectroStatic Discharge)(17), an insulating layer(11), a transparent electrode layer(12), a luminance layer(13), a dielectric layer(14), a rear electrode layer(15), and a noise shield layer(18). The ESD layer and the noise shield layer are electrically connected through a through hole(20) and grounded. At least one of the ESD layer and the noise shield layer and a conductive material of the through hole are integrally connected by forming the at least one of the ESD layer and the noise shield layer in a printing method and inserting the conductive material into the through hole.

Description

EL device

1 is a cross-sectional view of a conventional EL element,

2 is a cross-sectional view of an EL element according to an embodiment of the present invention.

* Explanation of symbols for main parts of the drawings

11: transparent insulating layer 12: transparent electrode layer

13: fluorescent layer 14: dielectric layer

15: back electrode layer 16: insulating layer

17: ESD layer 18: noise protection layer

20: through hole

The present invention relates to an EL element.

In the conventional EL element, the transparent electrode layer and the back electrode layer are used as two electrodes, and AC power is applied to these two electrodes. At this time, since the EL element uses the DC power source of the battery as a power source, the DC power source of the battery is transformed through the inverter, and the alternating sinusoidal AC power is applied to the electrode.

FIG. 1 shows a laminated structure and a cross-sectional view of a conventional EL element, and the EL element generally includes a transparent electrode layer 101, a light emitting layer 102, an insulating layer 103, a back electrode layer 104, and a protective layer 105. ) Is formed by lamination. An alternating current voltage 106 is applied between the back electrode layer 104 and the transparent electrode layer 101 or a direct current voltage is transformed into an alternating current-like sine wave to the inverter to apply a voltage. The laminated structure and cross-sectional view in FIG. 1 are shown to explain the EL element conveniently, and the thickness, the width, the shape, etc. of each layer may have various shapes as necessary in actual application.

The transparent electrode layer 101 may be configured in the form of a conductive transparent film, or may be configured in the form of a coating film with a conductive polymer, ITO ink, or the like, and may be formed between the transparent electrode layer 101 and the back electrode layer 104. 106 is connected. The light emitting layer (luminescent layer 102) is a layer printed by mixing a phosphor and a binder and emitting light. The insulating layer (dielectric layer) 103 serves to prevent insulation breakdown that may appear when power is applied to the transparent electrode and the back electrode and to protect the light emitting layer. The rear electrode layer (Rear Electrode, 104) is also called a metal electrode and is a layer through which electricity passes when a power source is connected to the transparent electrode layer. The protection layer 105 is a layer used to prevent the product from moisture or contamination.

In the EL element having such a configuration, the light generated from the light emitting layer 102 passes through the transparent electrode layer 101 and is irradiated to various keys of the keypad. Through the irradiated light, the user sees the keypad in a dark place. It becomes possible.

An integrated circuit (IC) or various electric / electronic elements are essentially used in various devices in which such EL elements are used, and these elements are susceptible to damage by static electricity. In particular, devices used in small devices such as mobile phones are a problem because they can be more easily damaged by static electricity.

In addition, in the conventional EL device, there is a problem in that electrical noise is generated by a sinusoidal AC power source, and an audible frequency is generated in the dielectric layer as the AC power phases alternately change.

In addition, in order to prevent noise and static electricity as described above, the EL element has a somewhat more complicated structure than the existing structure, and a simpler structure is required in connection with external terminals such as a manufacturing process and a printed circuit board. .

Accordingly, the present invention is to solve the above problems,

The present invention prevents device defects caused by static electricity and at the same time shields the outside of the EL element with an equipotential to reduce the influence of phase change of the power source, thereby reducing noise generated in the dielectric layer and the light emitting layer. The purpose is to provide.

In addition, by minimizing the internal terminal of the EL element connected to the external terminal through the through-hole, to simplify the connection to the external terminal, such as manufacturing process and printed circuit board, to provide an EL element that can improve the yield The purpose.

As an aspect for achieving the above object,

In an EL device including an ESD layer, an insulating layer, a transparent electrode layer, a light emitting layer, a dielectric layer, a back electrode layer, and an anti-noise layer, the ESD layer and the anti-noise layer are electrically connected through a through hole. An EL element is provided.

In addition, the ESD layer and the noise prevention layer provide an EL element characterized in that the ground.

Further, there is provided an EL element characterized in that a plurality of through holes exist.

In addition, a conductive material is inserted into the through hole while at least one of the ESD layer and the noise prevention layer is formed by a printing method so that at least one of the ESD layer and the noise barrier layer and the conductive material of the through hole are integrated. It provides an EL device characterized in that connected to.

Hereinafter, with reference to the accompanying drawings will be described in detail the present invention.

2 is a cross-sectional view of an EL element according to an embodiment of the present invention.

As shown, an EL element according to an embodiment of the present invention is an electrostatic discharge (17) layer, a transparent insulating layer 11, a transparent electrode layer 12, a light emitting layer 13, a dielectric layer 14 In the EL device including the back electrode layer 15 and the noise prevention layer 18, the ESD layer 17 and the noise prevention layer 18 are formed through the through-holes 20 to become an equipotential. Preferably, the ESD layer and the noise prevention layer are grounded, and a plurality of through holes may be present.

The ESD layer 17 causes static electricity generated in the device using the EL element to be discharged to the printed circuit board or the device case through the ESD layer, thereby damaging various devices used in the device by the static electricity. You can protect against. An ESD layer 17 is formed on the front surface of the transparent insulating layer 11. The material may be preferably used as the material is formed of a material having high electrical conductivity, and materials such as ITO, carbon, copper, silver, gold, and conductive polymers may be preferably used.

It is preferable that the YSD layer 17 is grounded, and as shown in the drawing, it is not only troublesome to make a separate ground terminal in front of the EL element, but also has a poor aesthetic appearance, and the ESD layer 17 When the noise protection layer 18 is electrically connected to the FPCB or the like, there are problems in that the circuit is somewhat complicated because two terminals are required for the connection to the FPCB.

In the present invention, the ESD layer and the noise prevention layer are electrically connected to each other through the through hole 20 formed in the EL element, so that the ESD layer does not have a separate terminal on the rear surface of the EL element. Terminals may be provided only at the noise suppression layer 18 located to be grounded or connected to a printed circuit board (PCB) through an FPCB.

Although the transparent insulating layer 11 is a transparent insulating layer, there is no particular limitation, but a thin film, film, or the like is preferable, and it is preferable to have excellent light transmittance. Resin such as PET, polyurethane and the like can be selected. The thickness of the transparent insulating layer is not limited, but 20 to 50 μm is preferred for ultra-thinning, and may be formed by a printing method.

The transparent electrode layer 12 may be formed on the entire surface of the lower portion of the transparent insulating layer, or may be formed by patterning a light emitting region. A transparent conductive polymer may be used as the material of the transparent electrode layer, and may be a transparent material including indium tin oxide (ITO).

The light emitting layer 13, the dielectric layer 14, and the back electrode layer 15 may be sequentially stacked below the transparent electrode layer 12. The light emitting layer may be used without limitation the light emitting material known in the art. The inorganic light emitting material is good, and an organic light emitting material may be used if necessary. The back electrode layer is not limited, but may be formed by patterning to correspond to the transparent electrode layer, or may be formed on the entire surface.

The transparent electrode layer, the light emitting layer, the dielectric layer, and the back electrode layer may be covered and insulated by the insulating layer 16.

The transparent electrode layer and the back electrode layer are driven in connection with the printed circuit board.

A noise prevention layer 18 for noise reduction is formed under the insulating layer 16. When the EL element driven by the AC power source, especially the material of the light emitting layer is an inorganic material, electric noise is generated by the characteristics of the AC power source which is the driving power source. On the other hand, the power source used in the mobile phone is a DC power source, but the mobile phone converts the DC power source into a sinusoidal wave power similar to AC through an inverter, and uses the converted sinusoidal power source. In this way, the modified sinusoidal power source used in the mobile phone also has electrical noise, and audible noise also occurs as the polarity of the dielectric layer is changed by the power source whose phase changes.

In order to reduce such noise, the present invention can shield the light emitting layer and the dielectric layer at an equipotential to reduce the influence of the phase change, thereby reducing the change in polarity of the dielectric layer and reducing the noise generated by the light emitting layer. The noise prevention layer 8 may be covered by an insulating layer and insulated. The noise prevention layer serves to block noise generated when the EL element is operated by an AC power source.

The noise prevention layer 18 is preferably configured to be located on the rear surface of the EL element, and is preferably configured to be applied to the entire rear surface of the noise blocking property. The material of the noise prevention layer 18 is not limited as long as it is a material having electrical conductivity, and a material of the transparent electrode layer, the back electrode layer, or the ESD layer may be selectively applied.

The through hole 20 is preferably formed to penetrate the insulating layer 16 as shown. The through hole is filled with a conductive material to electrically connect the YSD layer and the noise prevention layer. Preferably, the conductive material is inserted into the through hole while at least one of the YSD layer and the noise preventing layer is formed by a printing method so that at least one of the ESD layer and the noise preventing layer is integrally connected with the conductive material of the through hole. Is preferred because it is simple. Although the upper and lower lengths of the through holes are long, the illustrated thickness is exaggerated for convenience of explanation and the distance between the YSD layer and the anti-noise layer has a very slim thickness of several hundred μm to several mm, thereby penetrating through the printing method. The hole can be filled with a conductive material sufficiently. Through the above method, the through hole is integrally formed with at least one of the YSD layer and the noise prevention layer, thereby preventing stronger and reliable binding and disconnection.

Although not shown, the transparent electrode layer 12 may be electrically connected to the ESD layer and the noise prevention layer. That is, by connecting the ESD layer, the transparent electrode layer, and the noise prevention layer to the first terminal connected to the outside, the method of providing an equipotential shield effect as described above and connecting to the outside can be simplified. That is, the terminal connecting the ESD layer, the transparent electrode layer, and the noise prevention layer to the outside may be connected to one end of the driving power source of the printed circuit board. The terminal may or may not be grounded according to the circuit diagram of the printed circuit board, or may be included in the present invention.

The above embodiments are intended to describe the present invention in detail, and are not intended to limit the present invention, and thus modifications, modifications, omissions, etc. that can be applied within the scope of the technical idea of the present invention are defined by the claims. It is included in the scope of the invention.

Due to the above characteristic configuration, the following effects are provided. That is, the present invention prevents device defects caused by static electricity and simultaneously shields the exterior of the EL device at an equipotential to reduce the influence of phase change of the power source, thereby reducing noise generated in the dielectric layer and the light emitting layer. By minimizing the internal terminal of the EL element connected to the terminal, the connection between the manufacturing process and the external terminal can be simplified, and the yield can be improved.

Claims (4)

In an EL device comprising an ESD layer, an insulating layer, a transparent electrode layer, a light emitting layer, a dielectric layer, a back electrode layer, and an anti-noise layer, And the ESD layer and the noise prevention layer are electrically connected through a through hole. The EL device according to claim 1, wherein the ESD layer and the noise prevention layer are grounded. 2. An EL element according to claim 1, wherein a plurality of said through holes exist. The method according to any one of claims 1 to 3, wherein at least one of the ESD layer and the noise prevention layer is formed by a printing method, and a conductive material is inserted into the through hole, thereby forming the ESD layer and the noise prevention layer. And at least one of the conductive material of the through hole is integrally connected.

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