KR0142023B1 - Color plasma display device - Google Patents

Abstract

The present invention discloses a color PDP having a novel configuration.

Since the color PDP is important to improve the luminous luminance, the conventional electronic color PDP equipped with an auxiliary power station is difficult to meet the white balance and achieve high definition.

In the present invention, the discharge cells constituting the pixel are divided into one discharge cell extending over the full width and two discharge cells extending by dividing the discharge cells so that the white balance can be easily satisfied. As it can be used as an auxiliary electrode of the discharge cell, the light emission luminance is improved with a simple structure.

Description

Color Plasma Display Device

1 is a plan view showing the configuration of the color PDP of NHK,

2 is a conceptual diagram showing the configuration of the pixels of the present invention color PDP;

3 is a plan view showing the configuration of the present invention color PDP;

4 is a perspective view thereof,

5 is a block diagram for explaining a driving method of the color PDP of the present invention.

Explanation of symbols used in the main part of the drawing

R, G, B: discharge cell

AR, AG, AB: anode

K1, K2Kn-1: (odd) cathode

K2: K2n L: (even) cathode

M: auxiliary cell

L: black matrix

N: node

X, Xn: pixel

The present invention relates to a color plasma display device (PDP).

PDP, which is a typical discharge display device, has various excellent features as a flat panel display device, and its use area is gradually being widened. In particular, the development of color PDP as a wall-mounted TV or a portable terminal has been actively developed. In the case of sequential scanning, color PDP has a 1/3 selectable time compared to black and white PDP. Is focused on.

1 shows a so-called field-shaped color PDP of NHK as an example of a conventional color PDP.

In this configuration, the four discharge cells R, G, and B are grouped by one pixel by the partition wall V, and one auxiliary electrode C is provided for each of the two anodes A. In (C), the priming charge is supplied to the discharge cells R, G, and B on both sides, so that the main discharge occurs quickly by the selection of the positive electrode A and the negative electrode K, thereby driving voltage. In order to improve the light emission luminance, the discharge duration during the selectable time of the discharge cells R and G. B is extended.

On the other hand, the blue light emitting phosphor has a lower luminance than the red or green-green fruit, so in this configuration, two blue discharge cells (B) are provided in one pixel, thereby satisfying the white balance of the entire screen. Becomes difficult. In addition, since the density of the electrode to be installed on the substrate is increased by the provision of the auxiliary electrode C, there is a problem that it becomes difficult to configure the display device.

In view of such a conventional problem, an object of the present invention is to provide a color PDP that is easy to satisfy the white balance and has a simple structure.

In order to achieve the above object, the color PDP according to the present invention is a color plasma display device that constitutes one pixel by gripping a discharge cell of three colors of red, green, and blue, each pixel having a height corresponding to a part of the height of the pixel. And a discharge cell of one color having a width extending over the full width of the pixel, and a discharge cell of two remaining colors each having a height corresponding to the remaining height of the pixel and a width obtained by dividing the full width of the pixel.

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

In FIG. 2, one pixel X of the color PDP according to the present invention is composed of set discharge cells R, G, and B, and the blue discharge cells b having low luminance have the full width of the pixel X; It extends over W and has a predetermined width W3 and height h2. The red and green discharge cells R and G have a height H1 excluding the height H2 of the blue discharge cell B from the pixel height H, and the widths W1 and W2 are the pixels X. It has the widths W1 and W2 divided by the full width W. Preferably, since the auxiliary cells described below are positioned between the red discharge cells R and the green discharge cells G, the widths W1 and W2 of the red and green discharge cells R and G and the widths of the auxiliary cells M are determined. The sum is the full width W of the pixel X.

Thus, by dividing each discharge cell R, G, and B in one pixel X, it is easy to adjust the luminance difference of each discharge cell R, G, and B. FIG. That is, by adjusting the height H2 of the blue discharge cell B to the pixel height H, the area ratio of the blue discharge cell B to the green and red discharge cells R and G can be adjusted. The area ratio between the green and red discharge cells R and G can be adjusted by adjusting the widths W1 and W2. In the case of using a general phosphor, the area between the green and red discharge cells (R, G) is preferably about the same, and the area of the blue discharge cells (B) is 1.5 to 2 times that of the other discharge cells (R, G). In this way, by controlling the area of each discharge cell (R, G) relatively, the light emitting area can be adjusted, and thus the white balance can be satisfied very easily.

Such a color PDP of the present invention preferably has a configuration as shown in FIGS. 3 and 4.

In the drawing, each of the discharge cells R, G, and B is partitioned by the partition walls VR, VG, and VB, and the positive and negative electrodes AR, AG, AB, and the cathodes are disposed up and down of each of the discharge cells R, G, and B. K1 and K2) are disposed to face each other in a matrix.

Here, the odd-numbered negative electrode K1 at the upper side of the figure passes through the lower portions of the red and green discharge cells R and G, and the lower-numbered negative electrode K2 passes only the blue discharge cell B. FIG.

On the other hand, the anodes (AR, AG, AB) are responsible for one of the three discharge cells (R, G, B), respectively, the anodes (AR, AG) responsible for the red discharge cell (R) and the green discharge cell (G). It extends to the center of the said discharge cell R, G, and passes through the outer side of the blue discharge cell B, respectively. The anode AB, which is responsible for the blue discharge cell B, passes between the red and green discharge cells R and G and passes through the center of the blue discharge cell B.

Preferably, the auxiliary cell M is formed by the two partition walls VR and VG between the red and green discharge cells R and G so that the anode AB in charge of the blue discharge cell passes through the auxiliary cell M. . According to a preferred driving method of the present invention to be described later, the anode (AB) of the blue discharge cell (B) also serves as a secondary electrode for the red and green discharge cells (R, G), accordingly, both sides of the bono cell (M) A priming hole H is formed in each of the partition walls VR and VG, and priming particles generated when the anode AB of the blue discharge cell B functions as an auxiliary electrode are formed in the priming hole H. Through the two discharge cells (R, G) are supplied.

On the other hand, when at least one of the red or green discharge cells (R, G) and the blue discharge cell (B) are selected at the same time, the main discharge voltage or more between the upper cathode (K1) and the anode (AB) of the blue discharge cell (B) A voltage is applied to generate a discharge between the two. In order to prevent abnormal light emission, it is preferable that a light shielding layer L made of an insulator such as black is applied to the upper surface of the auxiliary cell M. For this reason, it is preferable that the anodes AR and AG of the red and green discharge cells R and G are covered with an insulating layer in a portion passing through the blue discharge cell B. FIG.

In such a configuration, the red walls and the green discharge cells R and G receive charged priming particles from the auxiliary cell M, but the blue discharge cells B do not. In addition, since the blue discharge cell B is long left and right, the anode AB passes through the center, and therefore, it is preferable to include a node N in which the area of the anode AB is enlarged. According to such a statement, the discharge area of the blue discharge cell B is enlarged to cause rapid and large intensity discharge, thereby obtaining sufficient light emission luminance.

The color PDP of the present invention described above is preferably driven evenly alternately, which will be described below with reference to FIG.

In FIG. 5, only one column of the pixels X1 and Xn is shown. In the discharge cells R, G and B of each pixel X1 and Xn, three anodes AR, AG and AB and an odd number are shown. The second and even second cathodes K2n-1 and K2n intersect.

First, the red discharge cells R and the green discharge cells G are driven when the odd-numbered cathodes K1 and K2n-1 are selected. In this case, the anode AB of the blue discharge cell B is used as an auxiliary electrode and a predetermined non-discharge voltage is applied thereto. The priming particles generated thereby move to the red and green discharge cells (R, G) through the priming hole (H), so that the discharge can be started quickly at a low voltage when data is written through the corresponding anodes (AR, AG). .

On the other hand, the blue discharge cell B is driven when the even-numbered cathodes K2 and K2n are selected. That is, when data is written into the positive electrode AB of the blue discharge cell B when the even-numbered negative electrodes K2 and K2n are selected, discharge occurs in the blue discharge cell B and emits light. At this time, since the node N having an enlarged area is formed in the anode AB, a discharge of sufficient intensity is newly generated.

Thus, according to the present invention, it is possible to easily correct the luminance difference of the three types of red and green discharge cells R, G, and B by simple adjustment, thereby enabling the implementation of a color PDP having sufficient white balance and luminous luminance.

In addition, since all electrodes are arranged in a pixel, the structure is not excessively dense even in the configuration of a high-definition screen, and the data electrode and the auxiliary electrode can be used as the same electrode even without a separate auxiliary electrode, thereby simplifying the structure and driving. .

Accordingly, the present invention has the effect of providing a high-quality color PDP at a low manufacturing cost.

Claims (9)

In a color plasma display device that forms a pixel by grouping discharge cells of red-green-blue three emission colors, each pixel has a height that corresponds to a portion of the height of the pixel and a width extending over the full width of the pixel. And a discharge cell of two remaining colors each having a discharge cell and a height corresponding to the remaining height of the pixel and a width obtained by dividing the full width of the pixel. The color plasma display device of claim 1, wherein the discharge cells extending the full width of the pixel are blue discharge cells. The color plasma display device of claim 2, wherein the area of the blue discharge cells is 1.5 to 2 times the remaining discharge cells. The color plasma display device of claim 1, wherein an auxiliary cell is formed between the divided two discharge cells, and a priming hole is provided in a partition wall between the two discharge cells and the auxiliary cell. The color plasma display device of claim 5, wherein a light shielding layer is formed on the auxiliary cell. 2. The color of claim 1, wherein an odd-numbered cathode passes through the divided two discharge cells, an even-numbered cathode passes through the full-width discharge cells, and an anode passes through each of the three discharge cells. Plasma display element. The color plasma display device according to any one of claims 4 to 6, wherein an anode passes through the auxiliary cell of the full width discharge cell. The color plasma display device of claim 7, wherein an anode passing through the auxiliary cell is used as an auxiliary electrode when the odd numbered cathode is selected, and a data electrode is selected when the odd numbered cathode is selected. 8. The color plasma display device of claim 7, wherein a node having an enlarged area is formed at a portion where the anode passes through the discharge cell of the full width.