KR100866598B1 - Electro luminance element printed matter and manufacturing method thereof - Google Patents

Abstract

An electro luminescence element printed product and a manufacturing method thereof are provided to simplify the manufacturing process by printing a pattern electrode layer on a dielectric layer of the previously manufactured electro luminescence substrate with a printed pattern. An EL substrate(10) is formed by successively laminating a optical transmission substrate, a transparent electrode layer, an EL substrate, and a dielectric layer(19). A pattern electrode layer(20) laminated and printed with a conductive ink material to have a predetermined shape on the dielectric layer is included in the EL element printed product. The pattern electrode layer is laminated and printed by using an inkjet printing method and a screen printing method.

Description

EL element printed product and its manufacturing method {Electro Luminance element printed matter and manufacturing method

1 is a simplified cross-sectional view of a conventional EL device printed product,

2 is a simplified perspective view of an EL device printed product according to the present invention;

3 is a cross-sectional view taken along line III-III of FIG. 2;

4 is a manufacturing process block diagram of an EL device printed product according to the present invention;

5 and 6 are cross-sectional views of an EL device printed product according to another embodiment of the present invention.

* Explanation of symbols for the main parts of the drawings

10: EL substrate 13: Reinforcement layer

17 EL layer 19 dielectric layer

20: pattern electrode layer 21: protective layer

The present invention relates to an EL element printed product and a manufacturing method thereof.

Electro Luminance elements (hereinafter referred to as "EL elements") are widely used as light sources for keypads of various display devices and mobile phones and as light sources for advertising media.

Recently, the EL device has been developed a technology for printing the EL device in a predetermined pattern on a thin film substrate using a screen printing technique.

In the pattern printing of the EL element by the screen printing technique, after placing a plate (not shown) corresponding to the pattern on the substrate 110, as shown in FIG. 1, the lower electrode layer 120 and the dielectric layer 130 constituting the EL element ) And screen printing the ink of the EL layer 140 and the upper electrode layer 150.

By the way, in the conventional pattern printing method of an EL element, all the laminated structures such as the lower electrode layer, the dielectric layer, and the EL layer and the upper electrode layer are laminated printed by the screen printing technique by plate making, so that printing with the same EL element pattern is performed. Although it is suitable for mass production of products, there is a problem that it is not suitable for mass production of printed products having various EL device patterns suitable for small quantity production of various kinds.

In addition, the conventional pattern printing method of the EL element is to make a small amount of printed products having the EL element pattern in the home or office as needed, or to separately produce small quantities and small quantities of banners and flyers having the EL element pattern in terms of cost. There was a problem that was impossible.

 Accordingly, it is an object of the present invention to provide an EL device printed product and a method of manufacturing the same, which can significantly reduce its manufacturing cost when producing a large quantity of small quantity EL devices.

According to the present invention, there is provided an EL device printed product comprising: a light transmissive substrate, and an EL substrate prepared by sequentially laminating a transparent electrode layer, an EL layer, and a dielectric layer on the light transmissive substrate; And a pattern electrode layer laminated and printed with a conductive ink material to have a predetermined shape on the dielectric layer.

Here, the laminated printing of the pattern electrode layer is preferably laminated printing using an inkjet printing method or a screen printing method.

In addition, it is effective that the ink material of the pattern electrode layer includes a low-temperature curing or UV-curable photoinitiator as the conductive ink material.

In the above EL substrate, a reinforcing layer of a resin material is laminated on the light transmissive substrate, and the transparent electrode, an EL layer, and a dielectric layer are laminated on the reinforcing layer.

In addition, it is more effective that the protective layer of the resin material is laminated coated, printed or laminated on the pattern electrode layer.

On the other hand, the above object is, according to another field of the present invention, EL device printed product manufacturing method comprising the steps of: preparing an EL substrate in which a transparent electrode layer, an EL layer and a dielectric layer are sequentially stacked on a light transmissive substrate; It is also achieved by an EL device printed product manufacturing method comprising the step of laminating printing a pattern electrode layer with a conductive ink material to have a predetermined shape on the dielectric layer.

Here, the laminated printing of the pattern electrode layer is preferably laminated printing using an inkjet printing method or a screen printing method.

In addition, it is effective that the ink material of the pattern electrode layer includes a low-temperature curing or UV-curable photoinitiator as the conductive ink material.

In the above EL substrate, a reinforcing layer of a resin material is laminated on the light transmissive substrate, and the transparent electrode, an EL layer, and a dielectric layer are laminated on the reinforcing layer.

In addition, it is more effective that the protective layer of the resin material is laminated coated, printed or laminated on the pattern electrode layer.

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

Fig. 2 is a simplified perspective view of an EL element printed product according to the present invention, and Fig. 3 is a sectional view taken along line III-III of Fig. 2. As shown in these figures, the EL element printed product 1 according to the present invention includes an EL substrate 10 prepared in advance and a pattern electrode layer 20 printed on the dielectric layer 19 of the EL substrate 10 to be described later. It includes.

The EL substrate 10 is prepared in advance by laminating the transparent electrode layer 15, the EL layer 17, and the dielectric layer 19 on the light transmissive substrate 11 in order.

The substrate 11 may be made of various light transmissive materials. For example, the substrate 11 may be made of a material such as transparent paper, a transparent resin film, or glass.

The transparent electrode layer 15 is formed of a transparent conductive ink material made of silver of conductive fine particles, or in addition to conductive gold, zinc, graphite, copper, ITO, carbon, carbon nanotubes, conductive polymers, and combinations thereof. It may be formed by a transparent conductive ink material made of water, and various materials may be used without departing from the spirit of the present invention.

In this case, the ink material of the transparent electrode layer 15 may include a UV-curable photoinitiator according to a wavelength band so that the transparent electrode layer 15 may be cured by a relatively low-temperature UV curing method. Of course, the transparent electrode layer 15 may be cured by various curing methods in a range that does not damage the substrate 11 by the curing temperature, such as a natural curing method or a low temperature thermal curing method.

The transparent electrode layer 15 is electrically connected to an external power source (not shown). Here, as shown in FIG. 5, the reinforcement layer 13 is formed between the substrate 11 and the transparent electrode layer 15 by using an insulating resin material, whereby the ink for forming the transparent electrode layer 15 into the substrate 11 is absorbed. At the same time, the stacking performance between the substrate 11 and the ink material such as the transparent electrode layer 15 can be enhanced. In addition, the lamination performance between the substrate 11 and the ink material such as the transparent electrode layer 15 may be enhanced by plasma treatment, corona treatment, chemical treatment, or the like. In addition, the substrate 11 and the transparent electrode layer 15 may be purchased by using a substrate already coated with a conductive material such as a transparent film or transparent glass coated with ITO.

It is preferable that the EL layer 17 is formed of a luminescent ink material and also contains a UV-curable photoinitiator in accordance with the wavelength band in the ink material. By this, the EL layer 17 can be cured by comparatively low temperature UV curing. Of course, the EL layer 17 can also be cured by various curing methods in a range that does not damage the substrate 11 by the curing temperature such as a natural curing method or a low temperature thermal curing method. The EL layer 17 emits light when electric charges are distributed in the dielectric layer 19 by the current flowing through the transparent electrode layer 15 and the pattern electrode layer 20.

The dielectric layer 19 may be formed of an ink material made of barium titanate. In this case, the ink material of the dielectric layer 19 may also include a UV-curable photoinitiator according to a wavelength band, and the dielectric layer 19 may be formed by a relatively low-temperature UV curing method. It is desirable to allow) to be cured. Of course, the dielectric layer 19 may also be cured by various curing methods in a range that does not damage the substrate 11 by the curing temperature, such as a natural curing method or a low temperature thermal curing method. In addition, the material of the dielectric layer 19 may also use various ink materials including the barium titanate, which serve as a dielectric, so long as the gist of the present invention is not impaired. In this dielectric layer 19, electric charges are distributed when a current flows through the transparent electrode layer 15 and the pattern electrode layer 20.

As such, the EL substrate 10 having the transparent electrode layer 15, the EL layer 17, and the dielectric layer 19 laminated or coated on the light-transmissive substrate 11 in this order is fabricated in advance to print the pattern electrode layer 20. It is provided as an original of the printed product 1 for.

On the other hand, the pattern electrode layer 20 laminated on the EL substrate 10 is printed on the back surface of the dielectric layer 19 of the EL substrate 10 prepared in advance so as to correspond to the printing pattern using an ink material of a conductive material. 19) printed on the bottom surface. Here, the planar shape of the pattern electrode layer 20 is printed corresponding to a desired printing pattern, and may have various letters, symbols, images, and the like.

The pattern electrode layer 20 is printed by a conductive ink material made of silver of conductive fine particles, or in addition to conductive gold, zinc, graphite, copper, ITO, carbon, carbon nanotubes, conductive polymers, and combinations thereof. It can be printed by a conductive ink material consisting of.

At this time, the laminated printing of the pattern electrode layer 20 is preferably laminated printing using a direct or digital printing method, such as inkjet printing, in addition, it can be laminated printing using a relatively easy printing method, such as screen printing.

In addition, it is preferable to include the UV-curable photoinitiator in the ink material of the pattern electrode layer 20 in accordance with the wavelength band so that the pattern electrode layer 20 can be cured by low temperature UV curing and relatively low temperature thermal curing. Of course, it may be cured without including the UV photoinitiator. The pattern electrode layer 20 is electrically connected to an external power source (not shown).

In this case, as shown in FIG. 6, a protective layer 21 of a transparent resin material may be laminated on the outer surface (the lower surface of the drawing) of the pattern electrode layer 20 to protect the pattern electrode layer 20, etc. A bus electrode (not shown) may be additionally printed on the electrode layer 15 and the pattern electrode layer 20 for smooth connection of external supply power.

The manufacturing process of the EL element printed product 1 according to the present invention will be described.

The manufacturing of the EL element printed product 1 according to the present invention comprises the steps of preparing an EL substrate 10 (S01) and a pattern electrode layer on the dielectric layer 19 of the EL substrate 10, as shown in FIG. It consists of a step S02 of printing 20 sequentially.

The step (S01) of preparing the EL substrate 10 is made in advance by laminating or coating the transparent electrode layer 15, the dielectric layer 19, and the EL layer 17 on the light-transmissive substrate 11, in advance, as it is. May be used, or may be appropriately cut according to the size of the printed product (1).

Here, as shown in FIG. 5, the reinforcement layer 13 is formed between the substrate 11 and the transparent electrode layer 15 by using an insulating resin material, whereby the ink for forming the transparent electrode layer 15 into the substrate 11 is absorbed. At the same time, the stacking performance between the substrate 11 and the ink material such as the transparent electrode layer 15 can be enhanced. In addition, the lamination performance between the substrate 11 and the ink material such as the transparent electrode layer 15 may be enhanced by plasma treatment, corona treatment, chemical treatment, or the like.

Meanwhile, in the step (S02) of printing the pattern electrode layer 20, the pattern electrode layer 20 is laminated and printed in a predetermined print pattern on the dielectric layer 19 of the EL substrate 10 by using an inkjet or screen printing technique. By curing.

In this case, as shown in FIG. 6, a protective layer 21 of a transparent resin material may be laminated on the outer surface (the lower surface of the drawing) of the pattern electrode layer 20 to protect the pattern electrode layer 20, etc. A bus electrode may be additionally printed on the electrode layer 15 and the pattern electrode layer 20 for smooth connection of an external power supply.

The EL device printed product 1 according to the present invention manufactured by such a process has an EL substrate in a region corresponding to the pattern electrode layer 20 when a current flows when power is supplied to the transparent electrode layer 15 and the pattern electrode layer 20. (10) As the electric charge is distributed in the dielectric layer 19, the EL layer 17 in the region corresponding to the pattern electrode layer 20 emits light.

The light emitted from the EL layer 17 is emitted to the outside through the light transmissive substrate 11 while maintaining the pattern shape of the pattern electrode layer 20, so that the observer can visually observe a predetermined printed pattern that emits light.

As described above, the EL element printing product according to the present invention can easily produce an EL element printing product simply by printing the pattern electrode layer in the form of a corresponding printing pattern on the dielectric layer of the EL substrate prepared in advance.

Thereby, there is provided an EL element printed product and a manufacturing method thereof that are not only suitable for producing a large quantity of a printed product having the same EL element pattern but also for producing a large quantity of a printed product having various EL element patterns.

In addition, since an EL substrate can be purchased and a pattern electrode layer can be printed according to a desired pattern as required, a small amount of printed products having an EL element pattern can be produced in a small office, or a banner or advertisement sheet having an EL element pattern can be used. Easy to produce separately and in small quantities.

In addition, since only the pattern electrode layer needs to be printed on the EL substrate prepared in advance, a printed matter having an EL light emitting pattern can be obtained easily and inexpensively.

As described above, according to the present invention, there is provided an EL device printed product and a method of manufacturing the same, which can be easily produced in production of a large quantity of small quantity EL devices and that can significantly reduce its manufacturing cost.

Claims (10)

In the EL element printing product, A light-transmissive substrate, and an EL substrate previously prepared by sequentially stacking a transparent electrode layer, an EL layer, and a dielectric layer on the light-transmissive substrate; And a pattern electrode layer laminated with a conductive ink material to have a predetermined shape on the dielectric layer. The method of claim 1, The laminated printing of the pattern electrode layer is an EL device printed product, characterized in that the laminated printing using an inkjet printing method or a screen printing method. The method of claim 1, The ink material of the pattern electrode layer is a conductive ink material, a low-temperature hardened or UV-curable photoinitiator comprising an EL device printing product. The method of claim 1, A reinforcing layer of a resin material is laminated on the light transmissive substrate of the EL substrate, and the transparent electrode, the EL layer, and a dielectric layer are laminated on the reinforcing layer. The method of claim 2, And a protective layer of a resin material is laminated coated, printed or laminated on the pattern electrode layer. In the EL device printing product manufacturing method, Preparing an EL substrate on which a transparent electrode layer, an EL layer, and a dielectric layer are sequentially stacked on the light transmissive substrate; And laminating a patterned electrode layer with a conductive ink material so as to have a predetermined shape on the dielectric layer. The method of claim 6, The laminated printing of the pattern electrode layer is an EL device printed product manufacturing method characterized in that the laminated printing using an inkjet printing method or a screen printing method. The method of claim 6, The ink material of the pattern electrode layer is a conductive ink material, a low-temperature curing or UV-curable photoinitiator manufacturing method characterized in that it comprises an EL device printing product. The method of claim 6, A reinforcing layer of a resin material is laminated on the light transmissive substrate of the EL substrate, and the transparent electrode, the EL layer and the dielectric layer are laminated on the reinforcing layer. The method of claim 7, wherein A method of manufacturing an EL device printed product, characterized in that a protective layer of a resin material is laminated coated, printed or laminated on the pattern electrode layer.

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