KR20040025451A - Plasma display panel using Kr-Ne-Xe mixture as discharge gas - Google Patents

Abstract

PURPOSE: A plasma display panel is provided to achieve improved luminous efficiency and color temperature, while reducing a power consumption. CONSTITUTION: A plasma display panel is characterized in that the plasma display panel uses, as a discharge gas, the mixture of Krypton-Neon-Xenon based gases, wherein the Xenon gas is added at the ratio of 2vol% to 8vol% to the Krypton-Neon based gases. The Krypton gas is mixed at the ratio of 50vol% to 70vol% in the mixture of the Krypton-Neon based gases.

Description

Plasma display panel using Krypton-Neon-Xenon-based discharge gas {Plasma display panel using Kr-Ne-Xe mixture as discharge gas}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a plasma display panel, and more particularly, to a krypton-neon-xenon which can improve luminous brightness and efficiency and simultaneously reduce power consumption by using xenon gas added to a krypton-neon mixed gas as a discharge gas. The present invention relates to a plasma display panel to which a discharge gas of a system is applied.

Recently, as the expectation for high-quality large-screen televisions increases, development of display devices suitable for the CRT, liquid crystal displays, and plasma display panels (hereinafter referred to as PDPs) in each display field is progressing.

CRT is excellent in terms of resolution and image quality, but it is not suitable for large screens of 40 inches or more in terms of weight and volume depending on the size of the screen. In addition, although LCD has excellent characteristics with low power consumption and driving voltage, there are technical difficulties in making a large screen, and a narrow viewing angle and slow response speed remain problems to overcome.

On the other hand, PDP is thin and light, it is advantageous in response speed and viewing angle, and above all, it is easy to make a big screen, and 63-inch products have already been developed.

PDP is largely divided into DC type and AC type, but AC type is the mainstream.

In a typical AC surface discharge type PDP, a front substrate and a rear substrate are arranged in parallel, and discharge gas is enclosed in a discharge space divided by a partition wall. A display electrode is provided on the front substrate, and a dielectric layer and a protective layer are stacked below, and a phosphor layer made of an address electrode, a partition wall, and an ultraviolet-excited phosphor of red, green, or blue is provided on the rear substrate.

As the composition of the discharge gas, a mixed gas system of helium (He), neon (Ne), and xenon (Xe), or a mixed gas system of neon (Ne) and xenon (Xe) is generally used. In consideration of restraining below, it sets to the range of about 100-500 Torr normally.

The emission principle of PDP emits visible light by exciting the phosphor by vacuum ultraviolet (Vacuum Ultra Violet) formed by the gas discharge generated by applying a voltage to the electrode, and converts the discharge energy into ultraviolet It is difficult to obtain high luminance due to low efficiency and low efficiency of converting ultraviolet light into visible light.

For example, in a PDP with a helium (He) -xenon (Xe) or neon (Ne) -xenon (Xe) -based gas composition, only about 2% of electrical energy is used for ultraviolet radiation, and the emitted ultraviolet rays are finally visible light. Only 0.2% is converted. The cause of such low UV generation efficiency is due to self-absorption of the discharge gas in the ground state during PDP discharge.

Therefore, in a discharge panel including a PDP, a technique for improving light emission brightness and efficiency and reducing power consumption is required.

In addition, in order to obtain good image quality in the PDP, it is important to adjust the white balance by improving not only the luminance but also the color temperature.

The present invention has been made to solve the above problems, discharge of krypton (Kr) -neon (Ne) -xenon (Xe) system that can improve the light emission brightness, efficiency and color temperature while reducing power consumption An object of the present invention is to provide a plasma display panel to which a gas is applied.

1 is a graph showing the luminance characteristics of a plasma display panel according to the present invention.

2 is a graph showing the luminous efficiency characteristics of the plasma display panel according to the present invention.

3 is a graph showing power consumption characteristics of the plasma display panel according to the present invention;

4 is a graph showing color temperature characteristics of the plasma display panel according to the present invention;

In the plasma display panel to which the krypton-neon-xenon-based discharge gas of the present invention is applied to achieve the above object, 2 vol% to 8 vol% of xenon (Kr) -neon (Ne) -based mixed gas is used. Xe) It is characterized by using what added gas as discharge gas.

Here, the krypton gas occupies 50 vol% to 70 vol% in the krypton-neon mixed gas.

Hereinafter, the characteristics of the plasma display panel to which the discharge gas composition according to the prior art is applied and the plasma display panel to which the discharge gas composition of the present invention is applied will be described in comparison with experiments.

1 to 3 are graphs showing characteristics such as brightness, luminous efficiency and power consumption of a plasma display panel to which the discharge gas composition of the present invention is applied.

Experimental conditions are as follows.

Set the encapsulation pressure to 300, 400 and 500 Torr with the discharge voltage applied at 220V, and then add 2vol% to 8vol% of xenon (Xe) gas into the mixed gas of krypton-neon system to measure the characteristics of PDP. It was. At this time, the volume specific gravity of the krypton gas is 60 vol%.

First, as shown in FIGS. 1 and 2, the higher the encapsulation pressure, the better the luminance and the luminous efficiency. The reason is that the higher the encapsulation pressure, the more excimers of xenon and krypton gas are formed during discharge, resulting in vacuum ultraviolet rays. This is because the phosphor excitation efficiency of is increased, so that the luminance and the efficiency are improved.

In addition, as the amount of xenon gas added in the krypton-neon mixed gas increases, the brightness and luminous efficiency decreases by the penning effect to about 2 vol% to 4 vol% of xenon. Therefore, the brightness and efficiency are increased because xenon excimer does not have a self absorption phenomenon.

In addition, as shown in FIG. 3, it can be seen that as the encapsulation pressure is higher and the amount of the xenon gas is increased, the power consumed decreases.

The higher the encapsulation pressure and the larger the xenon gas with the larger atomic radius, the more three-body collision occurs, resulting in more excitation reactions that cause ultraviolet light emission than the ionization reaction. If the ionization reaction occurs less, the current flowing during the driving of the PDP element is reduced, thereby reducing the power consumption.

4 is a graph illustrating color temperature characteristics of the plasma display panel according to the present invention, and experimental conditions are the same as those applied to FIGS. 1 to 3.

As shown in FIG. 4, it can be seen that as the amount of xenon gas added increases, the color temperature value is improved because, as described above, the vacuum ultraviolet rays formed by the xenon gas increase simultaneously with the decrease of the visible light emitted from the neon gas. to be.

Table 1 shows the experimental results of the brightness, luminous efficiency, power consumption and color temperature characteristics of the plasma display panel having a conventional gas composition and the plasma display panel having neon, krypton and xenon gas compositions of the present invention.

Here, the composition of the discharge gas applied to the plasma display panel according to the prior art is Xe 4%, Ne 25%, He 71%, the gas encapsulation pressure is 500torr, the applied voltage when measuring the brightness and efficiency is 220V.

Composition of discharge gas Luminance (cd / m ² ) Luminous Efficiency (lm / W) Power Consumption (W) Color temperature ( ^o K) 4% Xe -25% Ne-He bal., 500torr (conventional) 360 0.6113 5.06 6220 6% Xe-60% Kr-Ne bal., 500torr 493 1.9940 2.00 6740

As shown in Table 1, it can be seen that as a result of applying the discharge gas composition of the present invention, improved characteristics can be obtained in all characteristics such as light emission luminance, light emission efficiency, power consumption, and color temperature than the plasma display panel using the conventional discharge gas composition.

As described above, the plasma display panel to which the krypton-neon-xenon-based discharge gas of the present invention is applied has the following effects.

By adding a xenon gas having a larger atomic radius than these in the krypton-neon mixed gas, the amount of vacuum ultraviolet light emission can be increased to realize high brightness, and at the same time, the light emission efficiency can be improved.

In addition, due to the addition of xenon gas exhibits an excellent luminous efficiency than the conventional plasma display panel at the same discharge voltage has the advantage of reducing the power consumption.

Claims (2)

A plasma display panel comprising a plasma display panel comprising a discharge gas of adding 2vol% to 8vol% of xenon (Xe) gas to a krypton (Kr) -neon (Ne) -based mixed gas. 2. The plasma display panel of claim 1, wherein the krypton gas occupies 50 vol% to 70 vol% of the krypton-neon mixed gas.