KR19990017000A - Color plasma display panel - Google Patents

Abstract

A color plasma display panel comprising: a color plasma display panel having upper and lower glass substrates, wherein the lower substrate is made of a metal material and formed on the lower substrate, an address electrode formed on the insulating layer, It is composed of a dielectric layer covering the address electrode, and a lower structure formed with a partition wall and a phosphor layer formed on the dielectric layer, reflecting the progress of the chief ray to the lower substrate during discharge of the PDP to improve the brightness and lower the metal substrate It is used as a substrate to maximize the heat dissipation effect.

Description

Color plasma display panel

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a color plasma display panel, and more particularly, to a substructure of a color plasma display panel that uses a panel substrate as a metal substrate to improve heat transfer in the panel and thus increase heat dissipation effect.

In general, a color plasma display panel drives a pixel by forming a sustain electrode and an address electrode in a matrix form between an upper glass substrate and a lower glass substrate, and generates a discharge between the electrodes to form an image using ultraviolet rays generated therein. Display element.

1 is a view showing a unit cell cross-sectional structure of a general color plasma display panel.

Referring to FIG. 1, a general color plasma display panel forms a pair of sustain electrodes 11 having a constant width and height on the same surface of the upper glass substrate 10, and the dielectric layer 12 on the sustain electrodes 11. Is formed using a printing method, and has an upper structure in which the dielectric protection layer 13 is formed on the dielectric layer 12 formed on the sustain electrode 11, and has a predetermined width and height on the lower glass substrate 14. In order to form the address electrode 15 and to prevent crosstalk between adjacent cells, the barrier rib 16 is formed.

An inert gas is filled between the upper structure and the lower structure to form a discharge region 18.

The operation of the color plasma display panel configured as described above is as follows.

First, when a driving voltage is applied to the sustain electrode 11, a discharge occurs in the discharge region 18 on the surface of the dielectric protective layer 13 to generate ultraviolet rays 19.

Color display is performed as the fluorescent material of the surrounding phosphor 17 is excited by the generated ultraviolet light 19.

That is, xenon mainly contains helium (He) as an inert mixed gas filled with a pressure of about 400 to 500 torr in the discharge cell while accelerating the space charges present in the discharge cell by an applied driving voltage. 147 nm ultraviolet rays are generated when the inert gas is excited by colliding with a phenning mixed gas to which (Xe), neon (Ne) gas and the like are added.

Visible light is generated when the ultraviolet rays 19 collide with the phosphor layer 17 surrounding the address electrode 15 and the partition 16.

The manufacturing method of the color plasma display panel comprised in this way is as follows.

First, a sustain electrode 11 as an upper electrode is formed on the upper glass substrate 10.

At this time, the sustain electrode 11 uses a transparent electrode deposited with indium oxide or tin oxide and a bus electrode made of a conductive metal.

Subsequently, in order to generate wall charges to lower the driving voltage, a dielectric paste is printed on the sustain electrode 11 to form the dielectric layer 12, followed by drying and firing.

The dielectric layer 12 is a low melting glass material mainly composed of lead oxide.

Next, the dielectric protective layer 13 is formed to prevent damage to the dielectric layer 12.

In this case, the dielectric protective layer 13 uses magnesium oxide and is formed by electron beam deposition.

Subsequently, the address electrode 15 is formed on the lower glass substrate 14.

When the address electrode 15 is formed, the partition wall 16 is formed on the lower glass substrate 14 to prevent color mixing between adjacent discharge cells.

Here, a typical technique for forming the partition wall 16 is by a thick film printing method. The partition wall 16 is not formed by an etching method, but is simply a method of printing a partition material on a predetermined area several times.

In addition, in the thick film printing method, a paste obtained by mixing a ceramic powder with an organic binder solvent or the like is printed and dried 10 times using a screen mask, and then dried at 450 ° C. to 700 ° C. to form a partition 16.

At this time, the thickness of the partition wall printed once is 13 µm to 15 µm, and the thickness of the entire partition wall is 130 µm to 150 µm.

Subsequently, a phosphor 17 is formed on the address electrode 15 and the partition 16.

When the upper and lower substrates thus formed are sealed with the sealant, a sealed space is formed.

At this time, the upper / lower structure seals the discharge gas into the space sealed by the sealant. The panel sealed through the hole by combining a hole (not shown) and a gas injection glass tube (not shown) drilled in the lower edge portion thereof. When evacuating the negative air and evacuating it, the degree of vacuum is usually about 10 ^-6 to 10 ^-8 torr.

The gas is injected by the gas injector and the glass tube is sealed with heat to form a panel in which the discharge gas is completely sealed.

The color plasma display panel configured as described above has a problem that the visible light is discharged to the lower substrate during discharging, and thus the luminance is lowered and the thermal conductivity of the glass is low.

The present invention has been made to solve the problems according to the prior art, an object of the present invention is to reflect the progress of the visible light to the lower substrate when discharging the lower substrate using a metal substrate to improve the brightness and heat radiation effect The present invention provides a color plasma display panel.

1 is a view showing a unit cell cross-sectional structure of a general color plasma display panel;

2 is a diagram illustrating a unit cell cross-sectional structure of a color plasma display panel according to the present invention.

＊ Explanation of symbols on main parts of drawing

20: upper glass substrate 21: sustain electrode

22 dielectric layer 23 dielectric protective layer

24 lower glass substrate 25 insulating layer

26 dielectric layer 27 address electrode

28: partition 29: phosphor layer

30: discharge area 31: ultraviolet

A color plasma display panel according to the present invention is characterized in that, in a color plasma display panel having an upper and lower glass substrate, a pair of sustain electrodes formed on the upper substrate, a dielectric layer formed on the sustain electrode, and a dielectric layer formed on the dielectric layer An upper structure having a dielectric protective layer formed thereon, the lower substrate comprising a metal substrate, an insulator layer formed on the lower substrate, an address electrode formed on the insulator layer, a dielectric layer covering the address electrode, and on the dielectric layer It is composed of a bottom structure formed with the formed barrier ribs and the phosphor layer to reflect the visible light traveling to the lower substrate during discharge to improve the brightness and to facilitate heat dissipation of the panel by the high thermal conductivity of the metal itself.

Hereinafter, a preferred embodiment of a color plasma display panel according to the present invention will be described with reference to the accompanying drawings.

2 is a diagram illustrating a unit cell cross-sectional structure of a color plasma display panel according to the present invention.

Referring to FIG. 2, the color plasma display panel according to the present invention forms a pair of sustain electrodes 21 having a predetermined width and height on the same surface of the upper substrate 20, and forms a dielectric layer on the sustain electrodes 21. 22 is formed by a printing method, an upper structure in which a dielectric protection layer 23 is formed on the dielectric layer 22 formed on the sustain electrode 21, a lower metal substrate 24, and the metal substrate 24. An insulator layer 25 is formed on the insulator layer, an address electrode 27 is formed on the insulator layer 25, the address electrode 27 is covered with a dielectric layer 26, and the dielectric layer 26 is formed on the insulator layer 25. In order to prevent crosstalk between cells adjacent to the barrier ribs 28, the barrier ribs 28 are formed, and the barrier ribs 28 and the barrier ribs 28 are formed under the phosphor structure 29.

Here, the metal substrate 24 uses a metal having a similar thermal expansion coefficient to that of the insulator layer 25 and the dielectric layer 26. A metal having a thermal expansion ratio of 20 × 10 ⁻⁸ / ° C. to 100 × 10 ⁻⁸ / ° C. is used. do.

In addition, the metal substrate 24 may use titanium (Ti) metal having almost no thermal expansion at about 500 ° C.

The operation of the color plasma display panel configured as described above is as follows.

First, when a driving voltage is applied to the sustain electrode 21, surface discharge occurs in the discharge region 30 on the surface of the dielectric protective layer 23 to generate ultraviolet rays 31.

Color display is performed as the fluorescent material of the surrounding phosphor layer 29 is excited by the generated ultraviolet rays 31.

That is, xenon mainly contains helium (He) as an inert mixed gas filled with a pressure of about 400 to 500 torr in the discharge cell while accelerating the space charges present in the discharge cell by an applied driving voltage. 147 nm ultraviolet rays are generated when the inert gas is excited by colliding with a phenning mixed gas to which (Xe), neon (Ne) gas and the like are added.

As the ultraviolet rays 31 collide with the phosphor layer 29 surrounding the address electrode 27 and the partition wall 28, red, green, and blue (R, G, B) visible light is generated in all directions.

The visible light portion generated in all four directions is spread toward the metal substrate 24.

In this case, since the lower substrate is made of metal, the visible light reflected to the lower substrate is reflected.

In addition, heat is generated during discharge, and the surface temperature of the panel rises to about 80 ° C., which lowers the lifetime of the panel and the reliability of the product. Therefore, existing products have a structure in which a metal aluminum heat sink is attached to the back of the panel and heat is radiated from the panel by reflecting heat of the heat sink by the heat radiating fan.

The present invention uses a metal substrate to further improve heat transfer in the panel.

Therefore, when the color plasma display panel is discharged, the visible light may reflect the progress of the lower substrate to increase luminance and improve heat dissipation of the panel.

In the color plasma display panel according to the present invention, since the lower substrate is composed of a metal substrate, the visible light is reflected to the lower substrate during discharge of the color plasma display panel, thereby increasing luminance and using a metal substrate having excellent thermal conductivity. There is an effect to facilitate.

Claims (4)

A color plasma display panel having upper and lower substrates; A lower substrate made of the metal substrate; An insulator layer formed on the lower substrate; And And a address electrode formed on the insulator layer. The method of claim 1, The metal substrate is a color plasma display panel using a metal having a thermal expansion rate of 20 × 10 ^-8 / ℃ to 100 × 10 ^-8 / ℃. The method of claim 1, The metal substrate is a color plasma display panel using titanium (Ti). In a color plasma display panel having an upper substrate and a lower substrate, The lower substrate is formed of a metal substrate, the insulating layer formed on the lower substrate; An address electrode formed on the insulating layer; A dielectric layer covering the address electrode; And And a partition wall and a phosphor layer formed on the dielectric layer.