KR20010045812A - Discharge gas of plasma display panel - Google Patents

Abstract

PURPOSE: A discharge gas of a plasma display panel is provided which is able to produce ultraviolet rays having a wavelength longer than the wavelength of conventional ultraviolet rays to improve the energy efficiency of fluorescent material. CONSTITUTION: A mixed gas for discharging of a plasma display panel is composed in such a manner that I2 gas is added to an inert gas composition including Xe in a predetermined ratio. The pressure of the mixed gas is 300 to 500Torr. The inert gas composition includes Ne gas. The inert gas composition may contain Ar gas. The mixture ratio of the I2 gas is less than 10% of the pressure ratio of the entire mixed gas. The I2 gas emits ultraviolet rays having a longer wavelength than Xe.

Description

Discharge gas of plasma display panel

The present invention relates to a plasma display panel, and more particularly to a discharge gas.

Plasma display panels are attracting attention as the next generation display devices because they have both the vivid image quality of cathode ray tubes (CRT), various screen sizes, and the advantages of thin liquid crystal displays. Plasma display panels are generally lighter than the cathode ray tubes with the same screen size, and are light, even though large panels of 40 to 60 inches are characterized by a thickness of 10 cm or less.

In addition, the cathode ray tube or the liquid crystal display device has a problem of size limitation when simultaneously displaying a digital data image and a full motion picture, but the plasma display panel does not have such a problem. In addition, while the cathode ray tube is affected by the magnetic force, the plasma display panel is not affected by the magnetic force, thereby providing a stable image to the viewer. In addition, because each pixel is digitally adjusted, the image in the corner of the screen is not distorted, so that the image quality is superior to that of the cathode ray tube.

The plasma display panel is composed of two glass substrates coated with electrodes. The electrodes formed on the glass substrates face each other in the vertical direction, and serve as pixels at each intersection of the electrodes. The operation of the plasma display panel is almost the same as that of the home fluorescent lamp.

In the typical three-electrode surface discharge plasma display panel, as shown in FIG. 1A, the upper substrate 10 and the lower substrate 20 installed to face each other are bonded to each other. FIG. 1B illustrates a cross-sectional structure of the plasma display panel illustrated in FIG. 1A, and the lower substrate 20 is rotated by 90 ° for convenience of description.

The upper substrate 10 is a dielectric layer for coating the scan electrodes 16 and 16 'and the sustain electrodes 17 and 17' formed in parallel with each other, and the scan electrodes 16 and 16 'and the sustain electrodes 17 and 17'. And a protective film 12, wherein the lower substrate 20 is formed between the address electrode 22 and the dielectric film 21 formed on the entire surface of the substrate including the address electrode 22, and the address electrode 22. As shown in FIG. A partition 23 formed on the dielectric film 21 of the dielectric film 21, and a phosphor 23 formed on the surface of the partition wall 23 and the dielectric film 21 in each discharge cell. The upper substrate 10 and the lower substrate 20 The space between) is filled with an inert gas such as helium (He), xenon (Xe) and the like at a pressure of about 400 to 500 Torr to form a discharge region.

In general, the inert gas filled in the discharge space of the DC plasma display panel is a mixture of helium-xenon (He-Xe), and the inert gas filled in the discharge space of the AC plasma display panel is neon-Xenon (Ne-). A mixed gas of Xe) is used.

The scan electrodes 16 and 16 'and the sustain electrodes 17 and 17' are made of transparent electrodes 16 and 17 and a metal bus as shown in FIGS. 2A and 2B to increase light transmittance of each discharge cell. It consists of electrodes 16 'and 17'. FIG. 2A is a plan view of the sustain electrodes 17 and 17 'and the scan electrodes 16 and 16', and FIG. 2B is a sectional view of the sustain electrodes 17 and 17 'and the scan electrodes 16 and 16'. The bus electrodes 16 'and 17' receive a discharge voltage from an external driving IC, and the transparent electrodes 16 and 17 receive a discharge voltage applied to the bus electrodes 16 'and 17' and are adjacent to each other. It causes discharge between (16, 17). The overall width of the transparent electrodes 16 and 17 is about 300 micrometers (µm) indium oxide or tin oxide, and the bus electrodes 16 'and 17' are made of chromium (Cr) -copper (Cu) -chromium. It consists of three thin films comprised of (Cr). At this time, the width of the bus electrode 16 ', 17' lines is set to approximately one third the width of the transparent electrode 16, 17 line.

The operation of the three-electrode surface discharge type AC plasma display panel configured as described above is as shown in FIGS. 3A to 3D.

First, when a driving voltage is applied between the address electrode and the scan electrode, an opposite discharge occurs between the address electrode and the scan electrode as shown in FIG. 3A. By the opposite discharge, the inert gas injected into the discharge cell is excited and then transitions back to the ground state, and ions are generated. Some of the generated ions or quasi-excited atoms are generated. Impinge on the protective layer surface as shown in 3b. Due to the collision of electrons, electrons are secondarily emitted from the surface of the protective layer. The secondary electrons collide with the gas in the plasma state to diffuse the discharge. After the opposite discharge between the address electrode and the scan electrode is finished, opposite charge wall charges are generated on the surface of the protective layer on each address electrode and the scan electrode as shown in FIG. 3C.

When the discharge voltages having opposite polarities are continuously applied to the scan electrode and the sustain electrode, and the driving voltage applied to the address electrode is blocked at the same time, the potential difference between the scan electrode and the sustain electrode as shown in FIG. Surface discharge occurs in the discharge region on the surface of the dielectric layer and the protective layer. Due to the opposite discharge and the surface discharge, electrons present in the discharge cell collide with the inert gas inside the discharge cell. As a result, ultraviolet rays having a wavelength of 147 nm are generated in the discharge cells while the inert gas of the discharge cells is excited. Such ultraviolet rays collide with the phosphor surrounding the address electrode and the partition wall, and the phosphor is excited. The excited phosphors generate visible light, and the visible light causes an image to be displayed on the screen.

At this time, ultraviolet rays are more easily generated by the penning effect of the inert gas. The phenning effect is that the ionization reaction is further promoted by the metastable particles having a very large impact area, thereby increasing the Townsend alpha process. For example, the penning effect of the mixed gas of helium and xenon and the mixed gas of neon and xenon is as follows.

^{He * + Xe -> Xe +} + e - + He

^{Ne * + Xe -> Xe +} + e - + Ne

He and Ne are gases constituting the main components of the discharge gas, Xe is an added gas, and He ^* and Ne ^* are particles in each metastable state or particles in an excited state. The particles in this excited state have a longer collision time because their life time is longer than that of the stable particles. Thus, particles in an excited state are more likely to collide with other particles than particles in a steady state. Therefore, ionization is further promoted when present with helium and neon gas as compared with when only xenon gas is present.

However, xenon (Xe) included in the discharge gas of the conventional plasma display panel uses negative column ultraviolet light having a wavelength of 147 nanometers (nm) and positive column ultraviolet light having a wavelength of 174 nanometers (nm). Due to the excitation of the phosphor, there is a problem that the luminous efficiency of the phosphor is low. That is, the conventional discharge gas composed of helium, neon, and xenon has a low generation efficiency of ultraviolet rays generated by plasma discharge of about 6%, and a luminous efficiency of phosphors of about 26% to 28%. An increasing problem arises. The equation for calculating the energy efficiency of the phosphor is as follows.

(Emission UV wavelength of discharge gas) / (Visible wavelength of phosphor)

Equation 1 below calculates the energy efficiency of a phosphor that emits light in a conventional discharge gas.

(147-173 nm) / 550 nm = 26-28%

In addition, since the difference in wavelength between the ultraviolet rays that excite the phosphor and the visible light generated by the phosphor is large, energy corresponding to the wavelength difference is generated as heat, causing a problem of deterioration of the phosphor. In addition, there is a problem that the color purity of the phosphor is reduced by the visible light generated from the neon gas.

The present invention is to solve such a problem, the object of the present invention is to increase the energy efficiency of the phosphor by providing a discharge gas capable of generating ultraviolet light of a longer wavelength than conventional ultraviolet light.

1A and 1B illustrate a structure of a general plasma display panel.

2A and 2B illustrate structures of the scan electrode and the sustain electrode of the plasma display panel.

3A to 3D illustrate the discharge principle of the plasma display panel.

4 is a view schematically showing the structure of a plasma display panel of the present invention.

Symbol description for main parts of drawing

100: upper substrate 110: dielectric layer

120: protective film 160, 170: discharge electrode (transparent electrode)

160 ', 170': bus electrode (metal electrode) 200: lower substrate

210: lower dielectric film 220: address electrode

230: partition 240: phosphor

The present invention is characterized in that ultraviolet rays having a long wavelength can be generated by adding iodine (I ₂ ) gas to an inert mixed gas containing a conventional xenon.

The plasma display panel employing the discharge gas of the present invention is almost the same as the conventional structure. The upper substrate 100 is a dielectric layer coating the scan electrodes 160 and 160 'and the sustain electrodes 170 and 170' formed in parallel with each other, and the scan electrodes 160 and 160 'and the sustain electrodes 170 and 170'. And a protective film 120. The scan electrode includes a discharge electrode 160 made of a transparent electrode and a bus electrode 160 'made of a metal electrode, and the sustain electrode also includes a discharge electrode 170 made of a transparent electrode and a bus electrode 170' made of a metal electrode. )

The lower substrate 200 includes an address electrode 220, a dielectric film 210 formed on the front surface of the substrate including the address electrode 220, a partition 230 formed on the dielectric film 210 between the address electrodes 220, and It is composed of a phosphor 240 formed on the partition wall 23 and the dielectric film 21 in each discharge cell, the space between the upper substrate 100 and the lower substrate 200 is helium (He), xenon (Xe) The mixed gas of the inert gas including the back is filled to form a discharge region.

A mixed gas, which is a feature of the present invention, is the addition of iodine (I ₂ ) gas in a predetermined ratio to an inert mixed gas which causes plasma discharge. At this time, the pressure of the entire mixed gas is in the range of 300 Torr to 500 Torr, and the mixing ratio of the iodine gas is preferably within 10 percent (%) of the total gas mixing ratio.

The mixed gas to which the iodine gas is added is made by mixing an inert gas such as helium, neon, argon, or xenon at an appropriate ratio.

The iodine (I ₂ ) gas emits ultraviolet light with a longer wavelength than xenon (Xe) under the same conditions during plasma discharge. The penning effect of this iodine gas is as follows.

First, electrons collide with xenon to excite xenon.

^{e - + Xe -> Xe *} + e -

Alternatively, electrons collide with xenon to ionize xenon, and at the same time one electron is emitted from xenon.

^{e - + Xe -> Xe +} + 2e -

The electrons collide with the iodine gas to separate the iodine gas into iodine atoms and anions.

_{^{e - + I 2 -> I}} + I -

Xenon ions, iodine ions, and other inert gas particles collide to release excited xenon iodide and inert gas particles.

^{Xe + + I - + M -} > XeI * + M ( At this time, M = Ar, Ne, or other gas particle)

Alternatively, excited xenon and iodine gas collide to release the excited xenon iodide and iodine particles.

Xe ^* + I _2- > XeI ^* + I

The xenon iodide in the excited state is stabilized with xenon and iodine particles, and at the same time, it emits long wavelength ultraviolet rays.

XeI ^* -> Xe + I + UV

At this time, the emitted ultraviolet rays are long wavelength ultraviolet rays of about 253 nanometers (nm). The energy efficiency of the phosphor by ultraviolet rays is as follows.

253 nm / 550 nm = 46%

Therefore, the discharge gas of the present invention has about two times higher luminous efficiency of the phosphor than the conventional one.

The discharge gas of the present invention has a longer wavelength of ultraviolet rays emitted by the plasma discharge than the conventional discharge gas. Therefore, there is an effect that the energy efficiency of the phosphor is further improved than before. In addition, the difference between the ultraviolet wavelength emitted from the gas in the excited state and the visible wavelength emitted from the phosphor is reduced, thereby reducing the amount of heat generated, thereby preventing deterioration of the phosphor. Therefore, there is no need to use a short wavelength ultraviolet excitation phosphor separately, there is an advantage that can reduce the manufacturing cost. In addition, since the content of neon (Ne) gas is less than conventional, there is an effect that can prevent the reduction of color purity by the light emission of neon.

Claims (5)

In the plasma display panel, A mixed gas for discharge of a plasma display panel, wherein an iodine (I ₂ ) gas is added to an inert gas mixture containing xenon (Xe) at a predetermined ratio. The mixed gas for discharging the plasma display panel of claim 1, wherein the pressure of the mixed gas is in a range of 300 torr to 500 torr. The mixed gas for discharging the plasma display panel of claim 1, wherein the inert gas mixture includes neon (Ne) gas. The mixed gas for discharging the plasma display panel of claim 1, wherein the inert gas mixture contains argon (Ar) gas. The mixed gas for discharging of the plasma display panel of claim 1, wherein the mixing ratio of the iodine gas is within 10 percent of the pressure ratio of the total mixed gas.