KR100240490B1 - Honeycomb-type plasma display panel - Google Patents

Abstract

The present invention discloses a honeycomb PDP with a novel configuration.

In the conventional PDP, the partition wall and both electrodes are orthogonal to each other, so that the opposite area between the electrodes is small and the projection area of the front electrode is large, resulting in low luminance and high crosstalk between adjacent electrodes.

The problem of pore luminance was also the same for honeycomb PDPs having hexagonal pixels advantageous for pixel arrays.

In the present invention, by extending the front electrode in the lateral direction to the vertex side of the hexagonal pixel to increase the facing area while reducing the projection area greatly improves the light emission luminance, in particular, the front electrode by sharing the front electrode by sharing the front electrode The number was halved and the duty cycle of the pixel was increased.

Description

Honeycomb Plasma Display Device

1 is a cross-sectional view showing the configuration of a general PDP.

2 is a projection plane view showing the configuration of a lattice-type PDP.

3 is a projection plan view showing the configuration of a conventional honeycomb PDP.

4 is a projection plan view showing the configuration of a honeycomb PDP according to the present invention.

* Explanation of symbols for main parts of the drawings

P1, P2: front and back substrates E1, E2: front and back electrodes

B: barrier rib E3: auxiliary electrode

X: pixel (picture element)

The present invention relates to a plasma display panel (PDP), and more particularly to a honeycomb type PDP.

PDP, which is a type of flat panel display device that uses gas discharge for image display, basically has electrodes E1 and E2 intersecting each other on the front substrate P1 and the rear substrate P2 as shown in FIGS. ) And discharge gas is injected into the circumferentially discharged discharge space (V) by the partition wall (B).

On the other hand, an appropriate phosphor is coated on the electrodes E1 and E2 as necessary. The electrode E1 and E2 on the side on which the phosphor is applied are composed of a reflective and transmissive PDP depending on the application position thereof.

The PDP is driven by a matrix driving method, which sequentially scans the transverse electrode E2 and writes data to the longitudinal electrode E1, that is, addressing. It is done in such a way.

However, since the PDP does not immediately start discharging by selecting the positive electrodes E1 and E2, it is difficult to obtain high light emission luminance by the matrix driving method in which the duty time is limited because there is a time delay.

Accordingly, various auxiliary electrodes are used to trigger the discharge to start immediately or to implement the memory effect of maintaining the discharge until the next selection, and AC type PDP using wall charge is also actively developed. It is becoming.

However, the most basic thing to increase the luminance is the discharge intensity. The discharge intensity depends on the type, pressure, and potential difference of the discharge gas, but since these factors are almost impossible to adjust, mainly the opposing area between the two electrodes (E1, E2) It depends on.

However, since a high voltage of several hundred V is used in the PDP, the transparent electrode cannot be used as the electrode E1 of the front substrate P1 and the opaque metal electrode can be used.

Therefore, the projected area of the electrode E1 (the anode in the transmissive type and the cathode in the reflective type) of the front substrate P1 is preferably as small as possible, which makes it very difficult to increase the opposing area with the back electrode E2.

On the other hand, since the PDP has to inject the discharge gas after exhausting the inside, it is extremely difficult to exhaust and inject into the grid-shaped partition B partition as shown in the figure. It is preferable. However, when a gap or a hole is formed in the partition B, cross talk occurs easily between adjacent pixels during matrix driving, which causes a problem in that image quality is greatly deteriorated.

On the other hand, in order to implement a color image, different phosphors of R.G.B are applied to adjacent pixels to drive at least three R.G.B pixels in a cluster or a group to display an image.

However, in the lattice-shaped partition wall B structure as shown inevitably, the four pixels must be grouped into a group, and thus, the field-shaped "all" shape is inevitably taken. In such a field “all” pixel array, two pixels of one color are included in a group, so it is very difficult to achieve white balance. By changing the size of each pixel area or using a color filter, Various alternatives have been proposed, such as adjusting the light emission intensity or configuring one pixel with black or white pixels.

However, as shown in FIG. 3, when the partition B 'is formed in a hexagonal shape such as a regular hexagon, and the pixel X is formed in a hexagonal shape, the pixel arrangement of the RGB three primary colors is facilitated, and thus, the space efficiency of the PDP substrate and the resulting luminance of the light emitting diode It was known that it can be optimized.

Such a PDP is generally referred to as a honeycomb PDP according to its shape, which is a staggered structure similar to an article-shaped pixel array, and the back electrode E2 extends along the center line of each pixel so as to filter out one pixel. The front electrode E1 extends laterally one by one.

However, even in such a honeycomb type PDP, the projected area of the front electrode E1 is large, and there is a limitation in improving the aperture ratio and the resulting luminance.

Accordingly, it is an object of the present invention to provide a honeycomb PDP that can greatly reduce the projected area of the front electrode and reduce the number of front electrodes by half without lowering the discharge intensity.

In the present invention to achieve the above object is a honeycomb PDP in which the pixels formed in the hexagon by the hexagonal partition wall is arranged horizontally,

The front electrode in the lateral direction extends toward the vertex side of the upper or lower portion of the hexagonal pixel.

According to this characteristic, the projected area of the front electrode can be greatly reduced while maintaining the opposing area between the front electrode and the back electrode.

According to another feature of the present invention, the front electrode extends around the lower vertex of the upper row of pixels and around the upper vertex of the lower row of pixels, which means that the front electrode is shared with the upper row of pixels and the lower row of pixels, so that the number of front electrodes is increased. It is easy to drive by halving and the duty time of each pixel can be doubled.

Such specific features and advantages of the present invention will become more apparent from the following description of the preferred embodiments with reference to the accompanying drawings.

In FIG. 3, the honeycomb PDP according to the present invention is arranged laterally so that the pixels X formed in the low hexagon by the regular hexagonal partition B 'are vertically up and down. The rear electrode E2 extends in the longitudinal direction along the center line of each pixel X as in the related art so as to face the front electrode E1 one by one every other pixel.

Accordingly, the front electrode E1 extending in the lateral direction is arranged to be disposed toward the vertex side of the upper or lower portion of each pixel X according to the present invention. In this case, when the widths of the conventional electrodes E1 and E2 as shown in FIG. 3 are respectively b and the width of the pixel X is h, the opposite area between the conventional electrodes E1 and E2 is b ² The projected area of the electrode E1 is bh.

In comparison, when the opposite area b ² is maintained as in the related art, the projection area of the front electrode E1 is only 1.5625b ² due to the arithmetic calculation of the pixel X of the cube having a 60 ° vertex angle. .

The projected area of the front electrode E1 is significantly smaller than that of the conventional bh. For example, assuming that the width of the back electrode E2 is b = h / 6, the front electrode according to the present invention ( The projection area of E1) is reduced to 1.5625 / 6, i.e. only 26% of the conventional one. This increases the aperture ratio of 80% to 95% when calculated as the aperture ratio, thereby enabling a significant improvement in the luminance.

However, this calculation is invar, a front electrode (E1) the facing area between the so much higher than the center of the pixel anode electrodes (E1, E2) is sufficiently larger than the conventional b ² in accordance with the assumption that the same discharge intensity when the facing area equal obtained It is preferable to set large.

For example, in the above-described example, when the opposing area between the front electrode E1 and the back electrode E2 is set to 2 times conventional, that is, 2b ² , the projection area of the bottom electrode E1 becomes about 4b ² . Even in this case, it can be seen that the projection area is only two-thirds of the conventional art.

Meanwhile, as illustrated, the front electrode E1 extends in a width that spans the lower vertex side of the pixel X in the upper row and the upper vertex side of the pixel X in the lower row. Then, when the front electrode E1 serves as a scan electrode, for example, the pixel X in the upper column and the pixel X in the lower column can be simultaneously selected. This halves the required number of front electrodes E1 by half to facilitate the manufacture of a high pitch PDP, and each pixel X is selected as a separate electrode. It has an effect of doubling the duty time to select (X).

The reduction of the projection area and the reduction in the number of electrodes required also facilitate the arrangement of the auxiliary electrodes E3 as indicated by the dotted lines between the front electrodes E1. That is, even if the auxiliary electrode E3 is added, the aperture ratio and the light emission luminance according to the increase in the projection area are not lowered compared with the conventional ones, and the number of front electrodes is the same as in the prior art. The problem will not be caused.

The auxiliary electrode E3 is also preferably configured to span the pixels X in the upper and lower rows like the front electrode E1.

In particular, when the front electrode E1 and the auxiliary electrode E3 are provided together, both electrodes E1 and E3 may be driven to alternately operate as the scan electrode and the auxiliary electrode. For example, when the front electrode E1 acts as the scan electrode, the auxiliary electrode E3 causes the sustain discharge lamp to cause an auxiliary discharge, and when the auxiliary electrode E3 acts as the scan electrode, the front electrode E1 acts as the auxiliary electrode. It works.

Such a driving method brings about a remarkable improvement in the luminance of light emitted from the PDP of the present invention. In this case, the front electrode E1 and the auxiliary electrode E3 are merely for convenience and the functions of both are completely the same.

As described above, according to the present invention, it is possible to greatly reduce the projected area of the front electrode while increasing the opposing area between the electrodes in the honeycomb PDP, and to improve the manufacturing and driving characteristics by halving the required number of the front electrodes. It is effective to let.

Claims (3)

In a honeycomb plasma display device in which hexagonal pixels formed by hexagonal partitions are arranged horizontally so that their vertices are vertically up and down, the front electrode and the back electrode extend in the horizontal and longitudinal directions of the pixels, respectively, wherein the front electrode A honeycomb type plasma display device characterized in that it extends laterally shifted toward the vertex side of the upper or lower portion of the hexagonal pixels. The honeycomb plasma display device according to claim 1, wherein an auxiliary electrode extends laterally toward a vertex side of the lower or upper portion of the pixel where the front electrode does not extend. The method according to any one of claims 1 to 2, wherein at least one of the front electrode or the auxiliary electrode extends in a width spanning the lower vertex side of the pixels in the upper row and the upper vertex side of the pixels in the lower row. Honeycomb type plasma display device.