KR100607250B1 - Plasma Display Panel of In-Bus Structure - Google Patents

Abstract

The present invention improves the structure of the bus electrodes in the plasma display panel of the in-bus structure to reduce the line resistance of the bus electrodes. In addition, the present invention relates to a plasma display panel which can improve driving margin and brightness and increases efficiency due to heat generation.

The present invention as described above includes a scan transparent electrode and a sustain transparent electrode formed in a discharge region, and a scan bus electrode and a sustain bus electrode formed on the scan transparent electrode and the sustain transparent electrode. Each of the bus electrode and the sustain bus electrode is connected to the scan auxiliary electrode and the sustain auxiliary electrode in a non-display area, and the scan auxiliary electrode and the sustain auxiliary electrode are formed on the partition wall.

In addition, the transparent electrode is formed in each of the discharge region is characterized in that it is formed long to the non-discharge region.

The transparent electrode may be formed on the scan auxiliary electrode and the sustain auxiliary electrode.

Further, the position of the bus electrode is d / h when the distance from the center of the discharge region of the pair of transparent electrodes to the center of the bus electrode is d, and the distance between both ends of the pair of transparent electrodes is h / 8 < Provided is an in-bus plasma display panel characterized by satisfying d < h / 4.

Line resistance, non-display area, scan auxiliary electrode, sustain auxiliary electrode

Description

Plasma Display Panel of Inverse Structure

1 is a perspective view showing the structure of a typical plasma display panel.

FIG. 2 is a plan view illustrating in detail a structure of a transparent electrode and a bus electrode of a plasma display panel having a conventional in-bus structure. FIG.

3 is a plan view illustrating in detail a transparent electrode and a bus electrode structure of an in-bus plasma display panel according to a first embodiment of the present invention;

<Explanation of symbols for the main parts of the drawings>

300a ₁ , 300a ₂ , 300b ₁ , 300b ₂ : transparent electrode 310a, 310b: bus electrode

320a, 320b: auxiliary electrode

The present invention relates to a plasma display panel (hereinafter referred to as PDP), and more particularly to a plasma display panel having an in-bus structure.

In general, PDP is a display device that displays characters or graphics by using light emitted from plasma generated during gas discharge, and is suitable for large-sized, colorable at CRT level, and has a wide viewing angle. There is a lot of unique advantages that are attracting attention as the next generation large display device.

1 is a perspective view showing the structure of a general plasma display panel.

As shown in FIG. 1, a general PDP includes a front substrate 122 and a back substrate 124 made of transparent glass facing each other in parallel with an interval of 100 μm to 200 μm. In addition, a discharge space 128 is formed between the front substrate 122 and the rear substrate 124 by the partition walls 126 and 126 that are parallel to each other.

Here, the front substrate 122 is a display surface, and a plurality of transparent electrodes 200 are arranged side by side on the rear surface of the front substrate 122. The transparent electrode 200 is divided into a scan electrode and a sustain electrode and extends in parallel to each other at a thickness of approximately several hundred nm by deposition of ITO, tin oxide (SnO), or the like.

In the transparent electrode 200, a bus electrode 210 made of metal narrower than each electrode width is formed in close contact with each other. These bus electrodes 210 serve to increase conductivity between electrodes as auxiliary electrodes of the transparent electrode 200.

In addition, the dielectric layer 130 is formed to a thickness of about 20 ~ 30μm to cover the transparent electrode 200 and the bus electrode 210, the MgO layer 132 made of magnesium oxide (MgO) in contact with the dielectric layer 130 It is laminated to a thickness of approximately several hundred nm.

On the other hand, the rear substrate 124 is formed with a partition wall 126 to maintain a distance from the front substrate 122 to secure the discharge space.

The partition walls 126 are formed to be parallel to each other so that the longitudinal direction thereof extends in a direction orthogonal to the transparent electrode 200 by using a thick film printing technique, so that a width of 50 μm and a space of 400 μm are provided. Here, the width and spacing of the partition wall 126 can be changed to appropriate values depending on the size of the PDP or the number of pixels.

Further, an address electrode 220 made of aluminum (Al) or an aluminum alloy is formed between the partition walls 126 and 126 adjacent to each other, that is, at the bottom of the discharge space 128. The address electrode 220 is formed to have a thickness of approximately 100 nm in a direction orthogonal to the longitudinal direction of the transparent electrode 200. The address electrode 220 is not limited to Al or Al alloy, but can be made of a suitable metal or alloy such as Cu or Au having high reflectance.

On the address electrode 220, a phosphor film 136 is applied to a thickness of 10 ~ 30μm is formed as a light emitting layer.

In addition, the front substrate 122 and the rear substrate 124 are sealed, the discharge space 128 is exhausted, and then the moisture of the surface of the MgO layer 132 is removed by baking. Subsequently, an inert mixed gas containing 3 to 7% of Ne and Xe gas is injected into the discharge space 128 to form a PDP.

In the PDP configured as described above, a unit light emitting region at the intersection of the transparent electrode 200 composed of the scan electrode and the sustain electrode and the address electrode 220 is defined as one pixel cell. The phosphor is excited to emit light. That is, in each pixel cell, light emission is controlled by selecting, maintaining, and erasing the light emission discharge of the pixel cell by applying the voltage between the electrodes.

2 is a plan view illustrating in detail a transparent electrode and a bus electrode structure of a conventional in-bus structure. As shown in the figure, the in-bus structure refers to a structure in which each bus electrode 210 formed on the transparent electrode 200 is disposed close to the discharge gaps facing each other to narrow the gap.

The in-bus structure has a strong electric field, which causes strong discharge, thereby improving discharge efficiency. In addition, brightness is improved and jitter characteristics are also improved.

In the conventional in-bus structure, since the bus electrodes 210a and 210b are formed in the discharge space, the aperture ratio is lowered. Accordingly, the bus electrodes 210a and 210b have a very narrow line width L of the bus electrodes 210a and 210b in order to increase the aperture ratio.

As such, since the line width L of the bus electrode of the in-bus structure is formed to be narrow, a problem arises in that the total line resistance increases. As a result, driving margin and luminance are lowered, and efficiency due to heat generation is also reduced.

Accordingly, the present invention is to solve the above problems and to improve the structure of the bus electrode in the plasma display panel of the in-bus structure to reduce the line resistance of the bus electrode. In addition, an object of the present invention is to provide a plasma display panel which can improve driving margin and brightness and increases efficiency due to heat generation.

The plasma display panel of the in-bus structure according to the present invention for achieving the object of the present invention is a scanning bus formed on the transparent electrode for scanning and sustain transparent electrode formed in the discharge region and the transparent electrode for scanning and the transparent electrode for sustain In the plasma display panel including an electrode and a sustain bus electrode, each of the scan bus electrode and the sustain bus electrode is connected to the scan auxiliary electrode and the sustain auxiliary electrode in a non-display area, and the scan auxiliary electrode and the sustain auxiliary electrode are supported. The electrode is characterized in that formed on the partition wall.

In addition, the transparent electrode is formed in each of the discharge region is characterized in that it is formed long to the non-discharge region.

The transparent electrode may be formed on the scan auxiliary electrode and the sustain auxiliary electrode.

Further, the position of the bus electrode is d / h when the distance from the center of the discharge region of the pair of transparent electrodes to the center of the bus electrode is d, and the distance between both ends of the pair of transparent electrodes is h / 8 < It is more preferable to satisfy d <h / 4.

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

3 is a plan view showing in detail the structure of the transparent electrode and the bus electrode of the plasma display panel of the in-bus structure according to the present invention. As shown, the distance between the two ends of two adjacent pairs of the scanning transparent electrode 300a ₁ and the sustaining transparent electrode 300b ₁ , that is, the length of the cell, is defined as h, and the bus electrode is formed from the center of the discharge region. The distance to the center of 310a, 310b is defined as d.

At this time, the positions of the bus electrodes 310a and 310b positioned on the transparent electrodes 300a ₁ and 300b ₁ satisfy the following Equation 1.

h / 8 <d <h / 4

That is, the distance d from the center of the discharge region to the center of the bus electrodes 310a and 310b is preferably smaller than h / 4, which is larger than h / 8, from the center of the discharge region.

The in-bus structure refers to a structure in which the bus electrodes 310a and 310b formed on the transparent electrodes 300a ₁ and 300b ₁ are disposed close to the discharge gaps facing each other to narrow the gap.

Since the in-bus structure has a strong electric field and strong discharge, the discharge efficiency is improved. In addition, brightness is improved and jitter characteristics are also improved.

The transparent electrodes 300a ₂ and 300b ₂ are formed long to the non-discharge region, and the transparent electrodes 300a ₂ and 300b ₂ are the scan auxiliary electrodes 320a and the sustain auxiliary electrodes 320b formed on the partition wall 126. Is formed on the phase.

In this case, each of the scan auxiliary electrode 320a and the sustain auxiliary electrode 320b is connected to each other in the non-display area with the scan bus electrode 310a and the sustain bus electrode 310b.

As such, the scan auxiliary electrode 320a and the sustain auxiliary electrode 320b connected to the scan bus electrode 310a and the sustain bus electrode 310b are formed on the partition wall so that the scan bus electrode 310a is not reduced in aperture ratio. And the line width of the sustain bus electrode 310b can be maintained. Therefore, there is no increase in the line resistance, which leads to a decrease in driving margin and brightness, and also decreases efficiency due to heat generation.

In this case, the scan auxiliary electrode 320a and the sustain auxiliary electrode 320b are connected to the scan bus electrode 310a and the sustain bus electrode 310b in the non-display area so that the scan auxiliary electrode 320a and the sustain auxiliary electrode 320b are reset for discharge in the entire subpixel. This is to facilitate the process, address process and sustain process.

As such, the present invention described above compensates for the increase in overall line resistance due to the narrow line width L in the conventional in-bus structure. Therefore, driving margin and brightness are improved, and efficiency due to heat generation also increases.

As such, the technical configuration of the present invention described above can be understood by those skilled in the art that the present invention can be implemented in other specific forms without changing the technical spirit or essential features of the present invention. Therefore, the above-described embodiments are to be understood as illustrative and not restrictive in all respects, and the scope of the present invention is indicated by the appended claims rather than the detailed description, and the meaning and scope of the claims and All changes or modifications derived from the equivalent concept should be interpreted as being included in the scope of the present invention.

As described above, the present invention improves the structure of the bus electrodes in the plasma display panel of the in-bus structure to reduce the line resistance of the bus electrodes. In addition, the driving margin and brightness can be improved, and the efficiency due to heat generation is also increased.

Claims (4)

A plasma display panel comprising: a scan transparent electrode and a sustain transparent electrode formed in a discharge region; and a scan bus electrode and a sustain bus electrode formed in the scan transparent electrode and the sustain transparent electrode. The scan bus electrode and the sustain bus electrode are connected to each other in the non-display area with the scan auxiliary electrode and the sustain auxiliary electrode, and the scan auxiliary electrode and the sustain auxiliary electrode are formed on the partition wall. Plasma display panel of in-bus structure. The method of claim 1, The transparent electrode is formed in each of the discharge region, the plasma display panel of the in-bus structure, characterized in that formed to extend to the non-discharge region. The method of claim 1, And the transparent electrode is formed on the scan auxiliary electrode and the sustain auxiliary electrode. The method of claim 1, The position of the bus electrode is d when the distance from the center of the discharge region of the pair of transparent electrodes to the center of the bus electrode is d, and the distance between both ends of the pair of transparent electrodes is h, h / 8 <d <h / 4 The plasma display panel of the in-bus structure, characterized in that to satisfy.

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