KR0128524Y1 - Electroluminescence element - Google Patents

Abstract

The present invention discloses an improved electroluminescent device.

In the conventional electroluminescent device, a black insulating film 57 is applied to the back electrode 55 in order to improve large contrast. Accordingly, insulation breakdown of the second insulating film 54 occurs, and reflected light passes through a plurality of boundary layers. The contrast was reduced due to the diffuse reflection.

In the present invention, in order to prevent this, contrast can be improved by forming a black matrix 1 such as a black insulating film between R, G, and B phosphors forming the color filter 56.

Description

Electroluminescent element

1 is a partially enlarged view showing the main part of the EL device according to the present invention,

(a) is a partially enlarged view which shows the state before black-matrix exposure.

(b) is the partial enlarged view which shows the state after black-matrix washing | cleaning.

2 is a cross-sectional view showing a general electroluminescent element.

* Explanation of symbols for main parts of the drawings

1 black matrix 50 glass panel

51 transparent electrode 56 color filter

The present invention relates to an electroluminescent device, and more particularly, to an electroluminescent device capable of improving contrast.

In general, a flat panel display device is classified into a liquid crystal display (LCD), a fluorescent display (Vaccum Fluorecent), a plasma display panel (Plasma Display panel) and an electroluminescent device (Electro Luminesence), etc. In addition to being a self-luminous element, its thickness is generally used as a backlight of a liquid crystal display device.

As shown in FIG. 2, the electroluminescent device is applied to the glass panel 50, the transparent electrode 51 applied to the upper surface of the glass panel 50, and the upper portion of the transparent electrode 51. The phosphor 53 is insulated from the first insulating film 52, and the back electrode 55 positioned above the phosphor 53 and separated from the second insulating film 54.

Such a configuration is the basic structure of the electroluminescent element for monochrome display, and the color filter 56 in which the R, G, and B phosphors are sequentially arranged between the glass panel 50 and the transparent electrode 51 for color display. Is positioned, and a black insulating film 57 is coated on the inner surface of the back electrode 55 to improve contrast. In addition, an auxiliary electrode 58, which is a metal material having higher conductivity than the conductivity of the transparent electrode 51, is formed on the transparent electrode 51.

In the electroluminescent device, when a predetermined signal is applied to the transparent electrode 51, an electric field is formed between the transparent electrode 51 and the rear electrode 55 to cause the phosphor 53 of the portion to which the signal is applied to emit light. The light of the emitted phosphor 53 passes through the glass panel 50 and is transmitted to the entire surface to perform a predetermined display. At the time of color display, this light passes through the color filter 56, and a predetermined color is displayed by a normal false color method.

In this case, the contrast decreases as the light transmittance is lowered by the color filter 56. Therefore, the black insulating film 57 is applied to the back electrode 55 to select the light reflected by the glass panel 50 to improve the contrast. Will improve. In other words, the black insulating film 57 is formed in a matrix shape that is the same as the transparent electrode 51, and the light reflected therebetween can be selected.

However, when the black insulating layer 57 is applied to the back electrode 55 to improve the contrast, the second insulating layer 54 and the black insulating layer 57 are brought into contact with each other to cause the breakdown of the second insulating layer 54. There is this. In addition, since the light reflected by the black insulating film 57 must pass through a plurality of boundary layers in order to pass through the glass panel 50, diffuse reflection is generated here, resulting in less contrast.

Accordingly, an object of the present invention is to prevent the dielectric breakdown of the second insulating film by applying a black insulating film to the back electrode in order to improve the contrast of the electroluminescent device, as well as a difficult reflection path as the reflected light passes through the plurality of boundary layers. It is to provide an electroluminescent device which can prevent the contrast from being lowered.

In order to achieve the above object, the present invention is characterized in that a black matrix such as a black insulating film is formed between R, G, and B phosphors forming a color filter.

Hereinafter, exemplary embodiments of the present invention will be described with reference to the accompanying drawings.

1 is a partially enlarged view showing the main part of the EL device according to the present invention, in which the color filter 56 and the transparent electrode 51 in which R, G, and B phosphors are sequentially arranged on the glass panel 50. The black matrix 1 is apply | coated in between.

The black matrix 1 is formed through a conventional photo lithography process. Referring to this, the black matrix 1 is first coated on the color filter 56 and the transparent electrode 51.

The coated black matrix 1 is dried and exposed to an ultraviolet light source (not shown) in the direction of the glass panel 50 to expose only portions located between the phosphors. When the photosensitive part is cured and cleaned, only the remaining uncured part is cleaned, leaving the black matrix 1 between the phosphors.

Next, after the color filter 56 is formed with the black matrix 1 formed, as shown in FIG. 2, the auxiliary electrode 58, the first insulating layer 52, the phosphor 53, and the second insulating layer 54 are formed. ) And the back electrode 55 is formed on the top.

The electroluminescent device configured as described above applies a signal to the transparent electrode 51 so that the light reflected from the back electrode 55 when the phosphor 53 emits light passes through the color filter 56, wherein the black matrix 1 is described above. As a result, interference between R, G, and B phosphors is prevented, thereby improving color purity. In other words, when the R, G, and B phosphors are blocked, color mixing does not occur in this portion, thereby improving color purity, that is, contrast.

At this time, even when light is scattered while passing through the boundary layer formed by the first and second insulating layers 52 and 54 and the phosphor 53, the R, G and B may be caused by the black matrix 1 during the final transmission of the glass panel 50. Accurate selection of the phosphor improves color purity.

As described above, the present invention has an advantage of improving contrast by forming a black matrix on the color filter.

Claims (1)

R, G, and B phosphors are interposed between the glass panel 50, the transparent electrode 51 applied to the upper surface of the glass panel 50, and the transparent electrode 51 and the glass panel 50. Is disposed on the color filter 56, the phosphor 53 which is coated on the transparent electrode 51 and insulated by the first insulating film 52, and on the phosphor 53. In the electroluminescent device having the back electrode 55 isolated from the second insulating film 54, the contrast between the R, G, and B phosphors constituting the color filter 56 is improved. An electroluminescent element characterized by forming a black matrix (1).