KR20010067319A - Plasma display device - Google Patents

Abstract

PURPOSE: To provide plasma display unit that can prevent brightness from lowering even by making density and precision higher. CONSTITUTION: AC driving type plasma display unit is equipped with a first panel composed of the first substrate, an electrode group consisting of a plurality of electrodes and a protection layer, and a second panel composed of the second substrate, a fluorescent layer and barrier ribs, the said paired electrodes facing each other comprise (A) the first trunk line 12A, (B) the second trunk line 12B extending in parallel to the said first trunk line 12A, (C) the first branch electrode 13A extending between barrier ribs 25 from the first trunk line 12A toward the second trunk line 12B until before it and (D) the second branch electrode 13B extending in parallel to the first branch electrode 13A between barrier ribs 25 from the second trunk line 12B toward the first trunk line 12A until before it; and cause a discharge between the pair of the first and second branch electrodes 13A and 13B.

Description

Plasma display {PLASMA DISPLAY DEVICE}

The present invention relates to an AC driven plasma display device.

As an image display device replacing the mainstream cathode ray tube (CRT), a flat panel (flat panel type) display device has been studied in various ways. As such a flat display device, a liquid crystal display (LCD), an electroluminescence display (ELD), and a plasma display device (PDP) can be exemplified. Among them, plasma displays have advantages such as large screens and wide viewing angles, relatively excellent resistance to environmental factors such as temperature, magnetism and vibration, and long life. In addition, application to large information terminal for public use is expected other than home wall hangings TV.

The plasma display device applies a voltage to a discharge cell containing a rare gas, and excites the phosphor layer in the discharge cell with vacuum ultraviolet rays generated by glow discharge in the rare gas. V) a display device that obtains light emission by That is, each discharge cell is driven on a principle similar to a fluorescent lamp, and discharge cells are usually assembled in hundreds of thousands of orders to form one display screen. Plasma display devices are roughly classified into direct current driving type (DC type) and alternating current driving type (AC) according to a voltage application method to a discharge cell, and each has one end. The AC plasma display device can be formed in a stripe-shaped partition wall which separates discharge cells in the display screen, and is therefore suitable for high definition. Furthermore, since the surface of the electrode is covered with a dielectric material, the electrode is difficult to wear and has an advantage of long life.

A typical structural example of a conventional AC plasma display device is shown in FIG. This AC plasma display device belongs to a so-called three-electrode type, and discharge is mainly generated between the pair of discharge holding electrodes 113. In the AC plasma display device shown in Fig. 6, the front panel 10 and the rear panel 20 are joined to each other at their periphery. Light emission of the phosphor layer 24 on the rear panel 20 is observed through the front panel 10.

The front panel 10 is formed on the transparent first substrate 11 and the first substrate 11 in a stripe shape, and has a pair of discharge sustaining electrodes 113 made of a transparent conductive material and a discharge sustaining electrode 113. The bus electrode 112 formed of a material having a lower electrical resistivity than the discharge sustaining electrode 113, the bus electrode 112, the discharge sustaining electrode 113, and the first substrate ( A dielectric layer 14 formed on the dielectric layer 14 and a protective layer 15 formed on the dielectric layer 14.

The rear panel 20 is formed on the second substrate 21, the address electrodes (also called data electrodes) 22 formed on the second substrate 21 in a stripe shape, on the address electrodes 22 and the second substrate 21. On the dielectric film 23 formed on the dielectric film 23 and the insulating barrier rib 25 extending in parallel with the address electrode 22 in the region between the adjacent address electrodes 22 and the dielectric film 23. And the phosphor layer 24 formed on the side wall surface of the partition wall 25 from the surface. The phosphor layer 24 is composed of a red phosphor layer 24R, a green phosphor layer 24G, or a blue phosphor layer 24B, and these various phosphor layers 24R, 24G, and 24B are arranged in a predetermined order. Formed. 6 is an exploded perspective view, and in fact, the top of the partition 25 on the rear panel 20 is in contact with the protective layer 15 of the front panel 10. A region where the pair of discharge sustaining electrodes 113 and the address electrodes 22 positioned between the adjacent partition walls 25 overlap each other corresponds to the discharge cells. A rare gas is enclosed in each of the spaces surrounded by the adjacent partition wall 25, the phosphor layer 24, and the protective layer 14.

The direction in which the discharge sustaining electrode 113 extends and the direction in which the address electrode 22 extends form an angle of 90 °, and the pair of discharge sustaining electrodes 113 and the phosphor layers 24R emitting three primary colors, An area in which one pair of 24G and 24B) overlaps corresponds to one pixel. Since glow discharge occurs between each pair of discharge sustaining electrodes 113, this type of plasma display device is called " surface discharge type ". In each discharge cell, the phosphor layer excited by irradiation of vacuum ultraviolet rays generated by glow discharge in the rare gas exhibits a unique light emission color according to the type of phosphor material. Then, a vacuum ultraviolet ray having a wavelength corresponding to the kind of the rare gas enclosed is generated.

The arrangement relationship between the discharge sustaining electrode 113, the bus electrode 112, and the partition wall 25 in the conventional plasma display device shown in FIG. 6 is schematically shown in FIG. 7. The area surrounded by the dotted line corresponds to one pixel. Moreover, in order to clarify each area | region, the diagonal line was attached. The appearance of each pixel is generally square. Each pixel is divided into three compartments (cells) by the partition wall 25, and one of the three primary colors R, G, and B emits light from each compartment. When the outer dimension of each pixel in L _0, the dimension of each compartment is slightly smaller dimensions than _{(L 0/3) × (} L 0). Thus, in each pair of discharge sustain electrodes 113, the length of the portion (113A) of the discharge sustain electrode 113 contributing to the discharge is slightly shorter than (L _0/3).

In the conventional plasma display device, an example in which the arrangement of the discharge sustaining electrode 113, the bus electrode 112, and the partition wall 25 is modified is schematically shown in FIG. This modification is disclosed in Japanese Patent Laid-Open No. 9 (1997) -167565. In this modification, the discharge sustaining electrode 113 extends from each of the pair of bus electrodes 112 toward the other bus electrode.

By the way, in the plasma display apparatus, the request of the high density and high definition of a pixel is increasing. In order to cope with such a demand, the value of the external dimension L ₀ of one pixel is inevitably reduced. As a result, according to a pair of discharge sustain electrodes 113, the length of the portion contributing to the discharge [approximately (L _0/3)] is shortened, the discharge area is reduced, the plasma display apparatus that the brightness is reduced A problem arises.

Accordingly, an object of the present invention is to provide a plasma display device capable of coping with high density and high definition, and to sufficiently secure the length of a portion contributing to the discharge at a pair of discharge holding electrodes even if the size of one pixel is small, that is, An object of the present invention is to provide a plasma display device capable of preventing a decrease in luminance even by high density and high definition.

FIG. 1 is a view schematically showing the arrangement relationship between a pair of opposing first electrodes and a partition wall in the plasma display device of Embodiment 1 of the present invention.

2 is a conceptual exploded perspective view of the plasma display device of Embodiment 1 of the present invention.

FIG. 3 is a view schematically showing the arrangement relationship between a pair of opposing first electrodes and a partition wall in the plasma display device of Embodiment 2 of the present invention.

4 (A) and 4 (B) are diagrams schematically showing the light emission states of glow discharge in a discharge cell.

5 (A) and 5 (B) are diagrams schematically showing the light emission states of the glow discharges in the discharge cells.

6 is a conceptual exploded perspective view of a conventional plasma display device.

FIG. 7 is a diagram schematically illustrating a layout relationship between a pair of opposing first electrodes and a partition wall in a conventional plasma display device.

8 is a view schematically showing a modification of the arrangement relationship between a pair of opposing first electrodes and a partition wall in a conventional plasma display device.

AC drive plasma display device of the present invention for achieving the above object,

(a) a first substrate; An electrode group composed of a plurality of electrodes formed on a first substrate, a first panel composed of the electrode group and a dielectric layer formed on the first substrate, and

(b) a second substrate; A phosphor layer formed above the second substrate; A second panel which extends at a predetermined angle from an extending direction of the electrode and is formed of partition walls formed between adjacent phosphor layers;

To have,

The opposite pair of electrodes,

(A) the first main wiring,

(B) a second main wiring extending in parallel with the first main wiring,

(C) a first branch electrode extending between the adjacent partition walls from the first main wiring to the second main wiring and to the front of the second main wiring, and

(D) Between the adjacent partition walls, the second branch electrode extending from the second main wiring toward the first main wiring and immediately before the first main wiring, facing the first branch electrode. Composed,

Discharge is generated between the first branch electrode and the second branch electrode.

For convenience, a plurality of electrodes formed on the first substrate is referred to as "first electrode", and an electrode group composed of a plurality of first electrodes is referred to as "first electrode group".

The AC-driven display device (hereinafter referred to as "plasma display device") of the present invention is disposed so that the first panel and the second panel face each other as if the dielectric layer and the phosphor layer face each other, and the direction in which each main wiring extends. Each partition wall extends in a predetermined angle (for example, 90 °), and a rare gas is enclosed in each space surrounded by the dielectric layer, the phosphor layer, and the pair of partition walls, and the phosphor layer is an opposite pair. It emits light by being irradiated with vacuum ultraviolet rays generated by alternating glow discharge in a rare gas generated between branch electrodes of. An area in which one first electrode (a pair of paired first and second main wirings and a pair of first and second branch electrodes) and a pair of partition walls overlap each other corresponds to one discharge cell. .

In the region sandwiched between the pair of partition walls, when N ₁ is the number of first branch electrodes extending from the first main wiring and N ₂ is the number of second branch electrodes extending from the second main wiring, N _1. = N _{2 may be} 1, when n is an integer of 1 or more, N ₁ = 2-n-1 and N ₂ = 2n, or N ₁ = N ₂ = 2n.

In the plasma display device of the present invention, the first branch electrode and the second branch electrode extend to face each other, but the interval between the first branch electrode and the second branch electrode is preferably a predetermined interval, and further, a constant interval. It is further more preferable to be. The planar shape of the first and second branch electrodes may be generally rectangular (that is, the first branch electrode and the second branch electrode may be in a straight shape), and may be zigzag (for example, bent like a dog's hind legs). Combination, combination of " S &quot;, bow-shaped combination, arbitrary curve combination). In the latter case, in order to prevent the occurrence of abnormal discharge between the first branch electrode and the second branch electrode, it is preferable that the opposing portions of the first and second branch electrodes have no corners. In the plasma display device of the present invention, the distance between the first branch electrode and the second branch electrode can be essentially any value, but is 1 × 10 ^-4 m or less, preferably 5 × 10 ^-5 m Hereinafter, it is more preferable that it is 4x10 <^-5> m or less, Furthermore, it is preferable that it is 2.5x10 <^-5> m or less preferably. The minimum value of the distance between the first branch electrode and the second branch electrode may be set to an interval at which insulation breakdown does not occur between the first branch electrode and the second branch electrode.

In the plasma apparatus of the present invention, the pressure of the rare gas enclosed in the space surrounded by the dielectric layer, the phosphor layer and the pair of partition walls is 1 × 10 ² Pa (0.001 atm) to 5 × 10 ⁵ Pa (5 atm), preferably Preferably it is 1 * 10 <^3> Pa (0.01 atmosphere) to 4 * 10 <^5> (4 atmosphere). When the distance between the first branch electrode and the second branch electrode is less than 5 x 10 ^-5 m, the pressure of the rare gas in each space is not less than 1.0 x 10 ² Pa (0.001 atmosphere) and 3.0 x 10 ⁵ Pa ( 3 atmospheres) or less, preferably 1.0 × 10 ³ Pa (0.01 atmospheres) or more 2.0 × 10 ⁵ Pa (2 atmospheres) or less, more preferably 1.0 × 10 ⁴ Pa (0.1 atmospheres) or more 1.0 × 10 ⁵ Pa (1 Atmospheric pressure) or less, and by setting it as such a pressure range, the fluorescent substance layer is irradiated by vacuum ultraviolet rays generated by the cathode glow in the rare gas, and within such a pressure range, the plasma display device is increased as the pressure is higher. As a result of the reduction in the sputtering rate of the various members, the lifetime of the plasma display device can be extended.

Further, in the plasma display device of the present invention, in order to prevent occurrence of abnormal discharge from the corner portion (corner portion) of the first branch electrode tip portion or the corner portion (corner portion) of the second branch electrode tip portion, It is preferable that the tip portion and the tip portion of the second branch electrode have no angle or are rounded. In the plasma display device of the present invention, the abnormal discharge between the tip of the first branch electrode and the second main wiring is prevented, or the abnormal discharge between the tip of the second branch electrode and the first main wiring is prevented. For this purpose, the distance between the first branch electrode and the second branch electrode is L ₁ , the distance between the first main wiring and the second branch electrode tip, or the distance between the second main wiring and the first branch electrode tip is L ₂ . When doing so, it is preferable to satisfy L ₁ <L ₂ .

The 2nd electrode group comprised from the some 2nd electrode may be formed on the 1st board | substrate, and may be formed on the 2nd board | substrate. In the former case, the second electrode is formed on the dielectric layer through an insulating film, and forms a predetermined angle (eg, 90 °) with the direction in which the second electrode and each main wiring extend. In the latter case, the second electrode is formed on the second substrate and forms a predetermined angle (for example, 90 °) with the direction in which the second electrode and each main wiring extend, and the phosphor layer is the second electrode. It is formed above.

It is preferable that the conductive material constituting the first and second main wirings and the conductive material constituting the first and second branch electrodes have different configurations. The first and second main wirings function as bus electrodes in the conventional plasma display device. The first and second main wirings can typically be composed of a metal material, for example, Ag, Al, Ni, Cu and Cr, or Cr / Cu / Cr laminated film. In the plasma display device of the reflective type, the first and second main wirings formed of such a metal material or a laminated film reduce the transmitted light of visible light passing through the first substrate and passing through the first substrate, thereby reducing the brightness of the display screen. Since it may be a factor, it is preferable to form as thin as possible in the range from which the electric resistance value required for a 1st electrode is obtained. As the method for forming the first and second main wirings, the vapor deposition method, the sputtering method, the screen printing method, the sandblast method, the plating method, and the lift-off method can be appropriately selected depending on the conductive material to be used.

The conductive material constituting the first and second branch electrodes differs depending on whether the plasma display device is transmissive or reflective. In the transmissive plasma display device, since the light emission of the phosphor layer is observed through the second substrate, it does not cause any problem whether the conductive materials constituting the first and second branch electrodes are transparent or opaque, When forming on a board | substrate, it is preferable that a 2nd electrode is transparent. In the reflective plasma display device, since the light emission of the phosphor layer is observed through the first substrate, it is no problem whether the conductive material constituting the second electrode is transparent or opaque when the second electrode is formed on the second substrate. Although it does not cause, it is preferable that the first and second branch electrodes are transparent. The term " transparent or opaque " is attributable to the light transmittance of the conductive material in the light emission wavelength (visible broad region) inherent to the phosphor material. In other words, if the light emitted from the phosphor layer is transparent, the conductive material constituting the first and second branch electrodes can be said to be transparent. As the opaque conductive material, materials such as Ni, Al, Au, Ag, Al, Pd / Ag, Cr, Ta, Cu, Ba, LaB ₆ and Ca _0.2 La _0.8 CrO ₃ may be used alone or in combination as appropriate. Examples of the transparent conductive material include ITO (Indium-Stone Oxide) and SnO ₂ . As the method for forming the first and second branch electrodes, a deposition method, a sputtering method, a screen printing method, a sandal blasting method, a plating method, and a lift-off method can be appropriately selected depending on the conductive material to be used. That is, the first and second branch electrodes having a predetermined pattern may be formed using a suitable mask or screen, or after the conductive material layer is formed on the entire surface, the conductive material layer is patterned to form the first and second branches. Two electrodes may be formed.

In the plasma display device of the present invention, since the dielectric layer is formed, direct contact of ions and electrons to the first and second branch electrodes is prevented. As a result, wear of the first and second branch electrodes can be prevented. The dielectric layer has not only a function of accumulating wall charges, but also a function of limiting excess discharge current and a function of maintaining a discharge state. In the reflective plasma display device, the material constituting the dielectric layer is required to be transparent since light emission from the phosphor layer is observed through the first substrate. For example, low melting glass is used as the material.

In the plasma display device of the present invention, the protective layer is preferably formed on the dielectric layer. The material constituting the protective layer can be selected from magnesium oxide (MgO), magnesium fluoride (MgF ₂ ) and calcium fluoride (CaF ₂ ). Among them, magnesium oxide is a preferred material having high secondary electron emission rate, low sputtering rate, high light transmittance in the emission wavelength of the phosphor layer, low discharge start voltage, and the like. The protective layer may be a laminated structure composed of at least two kinds of materials selected from the group consisting of the above materials.

As a constituent material of the first substrate and the second substrate, soda glass (Na ₂ O · CaO · SiO ₂ ), borosilicate glass (Na ₂ O · B ₂ O ₃ · SiO ₂ ), and fosterite (2MgOSiO ₂ ) And lead glass (Na ₂ O. PbO. SiO ₂ ) can be exemplified. The constituent materials of the first substrate and the second substrate may be the same or different from each other.

The plasma display device of the present invention is a so-called surface discharge type plasma display device. When the second electrode is formed on the second substrate, when the function as the dielectric film of the phosphor layer is insufficient, a dielectric film may be formed between the second electrode group and the phosphor layer. As the constituent material of the dielectric film, low melting glass or SiO ₂ can be selected.

The phosphor layer is composed of a phosphor material selected from the group consisting of a phosphor material emitting red light, a phosphor material emitting green light, and a phosphor material emitting blue light, and is formed above the second substrate. In the case where the second electrode is formed on the second substrate, specifically, for example, a phosphor layer (red phosphor layer) made of a phosphor material emitting red light is formed above the second electrode and emits green light. A phosphor layer (green phosphor layer) made of phosphor material is formed above another second electrode, and a phosphor layer (blue phosphor layer) made of phosphor material emitting blue light is formed above another second electrode, Three phosphor layers which emit these three primary colors are formed into one set and formed in a predetermined order. In the case where the second electrode is formed on the first substrate, a red phosphor layer, a green phosphor layer, and a blue phosphor layer are formed on the second substrate, and these three phosphor layers are formed into one set, according to a predetermined order. Formed. One pixel includes a region in which one first electrode (combination of paired first and second main wirings and paired first and second branch electrodes) and a set of phosphor layers emitting three primary colors overlap each other. Corresponds to The red phosphor layer, the green phosphor layer and the blue phosphor layer may be formed in a stripe form or may be formed in a lattice form. The phosphor layer may be formed in a region where the discharge sustaining electrode and the address electrode overlap. When the red phosphor layer, the green phosphor layer and the blue phosphor layer are formed in a stripe shape and when the second electrode is formed on the second substrate, one red phosphor layer is formed above one second electrode, One green phosphor layer is formed above one second electrode, and one blue phosphor layer is formed above one second electrode. When the red phosphor layer, the green phosphor layer and the blue phosphor layer are formed in a lattice form, the red phosphor layer, the green phosphor layer and the blue phosphor layer are formed in a predetermined order above one second electrode.

In the case where the second electrode is formed on the second substrate, the phosphor layer may be directly formed on the second electrode, or may be formed on the second electrode and on the side surfaces of the partition wall. The phosphor layer may be formed on the dielectric film formed on the second electrode, or may be formed on the dielectric film formed on the second electrode and on the side surfaces of the partition wall. In addition, the phosphor layer may be formed only on the side surface of the partition wall. "The phosphor layer is formed above the second electrode" is a concept including all the various embodiments described above. The material constituting the dielectric film can be selected from low melting glass and silicon oxide, and the dielectric film can be formed by screen printing, sputtering, or vacuum deposition. In some cases, a protective layer made of magnesium oxide (MgO), magnesium fluoride (MgF ₂ ) or calcium fluoride (CaF ₂ ) may be formed on the surfaces of the phosphor and the partition wall.

As the phosphor material constituting the phosphor layer, a phosphor material having high quantum efficiency and low saturation with respect to vacuum ultraviolet rays can be appropriately selected from conventionally known phosphor materials. Since the plasma display device is used as a color display, the color purity is close to the three primary colors defined by NTSC, the white balance when the three primary colors are mixed is well achieved, and the afterglow time is short, It is preferable to combine phosphor materials whose residual times are about the same. As a phosphor material emitting red light by irradiation with vacuum ultraviolet rays, (Y ₂ O ₃ : Eu), (YBO ₃ Eu), (YVO ₄ : Eu), (Y _0.96 P _0.60 V _0.40 O ₄ : Eu _0.04 ), [(Y, Gd) BO ₃ : Eu], (GdBO ₃ : Eu), (ScBO ₃ : Eu), and (3.5MgO.0.5MgF ₂ .GeO ₂ : Mn). Examples of phosphor materials emitting green light by irradiation with vacuum ultraviolet rays include (ZnSiO ₂ : Mn), (BaAl ₁₂ O ₁₉ : Mn), (BaMg ₂ Al ₁₆ O ₂₇ : Mn), (MgGa ₂ O ₄ : Mn), (YBO ₃ : Tb), (LuBO ₃ : Tb) and (Sr ₄ Si ₃ O ₈ Cl ₄ : Eu) can be exemplified. Examples of phosphor materials emitting blue light by irradiation with vacuum ultraviolet rays include (Y ₂ SiO ₅ : Ce), (CaWO ₄ : Pb), CaWO ₄ , YP _0.85 V _0.15 O ₄ , (BaMgAl ₁₄ O ₂₃ : Eu), ( Sr ₂ P ₂ O ₇ : Eu) and (Sr ₂ P ₂ O ₇ : Sn) can be exemplified. As a method of forming the phosphor layer, a thick film printing method, a method of spraying phosphor particles, a method of adhering an adhesive substance on a preliminary forming of the phosphor layer, attaching the phosphor particles, and a photosensitive phosphor paste And a method of patterning a phosphor layer by developing an exposure and photosensitive phosphor paste layer, and a method of removing unnecessary portions by sandblasting after forming a phosphor layer on the entire surface.

The partition wall may be configured to extend in parallel with the second electrode in a region between one second electrode and another second electrode adjacent to each other. That is, it is possible to have a structure in which one second electrode extends between the pair of partition walls. In some cases, the partition wall may include a first partition wall extending in parallel with the main wiring in an area between one main wiring and another main wiring adjacent to each other, and an area between one second electrode and another second electrode adjacent to each other. In this configuration, the second partition wall extending in parallel with the second electrode (that is, in a lattice shape) can be configured. Such lattice-shaped partition walls have been conventionally used in DC plasma display devices, but can also be applied to the AC plasma display device of the present invention. The partition wall may have a manza structure.

As a constituent material of a partition, a conventionally well-known insulating material can be used, For example, the material which mixed metal oxides, such as alumina, with the low melting glass which is widely used can be used. As the formation method of a partition, the screen printing method, the sandblasting method, the dry film method, and the photosensitive method can be illustrated. In the screen printing method, an opening is formed in a screen portion corresponding to a portion where a partition wall is to be formed, and the partition-forming material on the screen is passed through an opening having an squeeze to form a second substrate or a dielectric film (hereinafter, these are generally used). And a barrier rib forming material layer on the second substrate or the like, followed by firing or sintering or sintering the barrier rib forming material layer. In the dry film method, a photosensitive film is laminated on a second substrate or the like, the photosensitive film at the predetermined portion of the partition formation is removed by exposure and development, and the partition formation material is embedded in the opening formed by the removal. It is a method of baking or sintering. The photosensitive film is burned and removed by firing or sintering, and the partition forming material embedded in the opening remains to form the partition. The said photosensitive method is a method of forming a barrier rib material layer which has photosensitivity on a 2nd board | substrate etc., and patterning this material layer by exposure and image development, and then baking or sintering. The sand blasting method is a layer of material for forming a partition on a second substrate or the like, for example, by a screen printing method or by a roll coater, doctor blade or nozzle-spray coater. After forming and drying, the area | region in which a partition is to be formed in a partition formation material layer is masked with a mask layer, and the exposed part of a partition formation material layer is removed by the sandblasting method. By making the partition wall black, a so-called black matrix can be formed to obtain a high contrast of the display screen. As a method of blackening a partition, a method of forming a light absorption layer such as a photosensitive silver paste or a low reflection chromium layer on the top of each partition and a method of forming a partition using a color resist material colored in black will be exemplified. Can be.

Rare gases enclosed in spaces are required to meet the following requirements.

(1) In terms of prolonging the lifetime of the plasma display device, it should be chemically stable and capable of setting a high gas pressure.

② From the viewpoint of high brightness of the display screen, the radiation intensity of vacuum ultraviolet ray should be large.

③ The wavelength of vacuum ultraviolet rays emitted should be long from the viewpoint of improving energy conversion efficiency from vacuum ultraviolet rays to visible rays.

④ In terms of power consumption reduction, the discharge start voltage should be low.

Rare gas contains He (wavelength of resonance line = 58.4nm), Ne (wavelength of resonance line = 74.4nm), Ar (wavelength of resonance line = 107nm), Kr (wavelength of resonance line = 124nm) and Xe (wavelength of resonance line = 147nm) do. These rare gases may be used alone or in combination, but a mixed gas which is expected to lower the discharge start voltage due to the Penning effect is particularly useful. As such a mixed gas, Ne-Ar mixed gas and He-Xe mixed gas can be illustrated. Of these rare gases, Xe having the longest resonance wavelength is preferable because it emits strong vacuum ultraviolet rays having a wavelength of 172 nm.

Here, the light emission state of the glow discharge in the discharge cell will be described with reference to FIGS. 4A, 4B, 5A and 5B. In Fig. 4A, the light emission state in the case of performing direct current glow discharge in a discharge tube filled with a rare gas is schematically shown. From the cathode to the anode, the Aston arm A, the cathode glow B, the cathode arm (Crookes arm) (C), the negative glow (D), and the Faraday arm ( E), positive light (F) and positive glow (G) appear in this order. In the alternating glow discharge, since the cathode and the anode repeat the inversion at a predetermined frequency, the positive column F is located at the center portion between the electrodes, and the Faraday arm part E and the negative glow D are located at both sides of the positive column F. It is thought that the negative electrode arm C, the negative glow B and the Aston arm A appear symmetrically in this order. The state shown in Fig. 4B is seen when the distance between the electrodes is long enough, such as a fluorescent lamp.

If the distance between the electrodes is shortened, the length of the bright column F is reduced. If the distance between the electrodes is further reduced, as shown in Fig. 5A, the positive pole F is lost, the negative glow D is positioned at the center between the electrodes, and the negative electrode arm C is located at both sides of the negative glow D. It is considered that the negative glow B and the aston arm A appear symmetrically in this order. The state shown in FIG. 5A is a state which arises when the space | interval of an electrode is around 1 * 10 <^-4> m. In the plasma display device of the present invention, since the pair of first branch electrodes and the second branch electrodes for maintaining the discharge are arranged in parallel, the negative glow is a dielectric layer covering the first or second branch electrodes corresponding to the cathode. It is formed in the spatial region near the surface portion of the.

When the spacing of the electrodes is less than 5 x 10 ^-5 m, as shown schematically in FIG. 5 (B), the negative electrode glow B appears in the center between the electrodes, and the Aston arm portion is formed on both sides of the negative electrode glow B. It is assumed that A) appears. In some cases, there may be some negative glow. In the plasma display device of the present invention, since the pair of first branch electrodes and the second branch electrodes for maintaining the discharge are arranged in parallel, the cathode glow covers the dielectric layer covering the first or second branch electrodes corresponding to the cathode. It is formed in the spatial region near the surface portion of the. As described above, the first branched electrodes and the second have a distance between the electrode 5 × 10 ^- less than 5m, and the pressure in the area 1.0 × 10 ² Pa (0.001 atm) at least 3.0 × 10 ⁵ Pa (3 atm) By the following, it becomes possible to use the negative glow as a discharge mode. Therefore, as a result of achieving high AC glow discharge efficiency, high luminous efficiency and high luminance can be obtained in the plasma display device.

In the plasma display device of the present invention, the first branch electrode and the second branch electrode face each other and extend from the main wiring. The external shape of each pixel is generally square, and each pixel is divided into three compartments (cells) by partition walls, and one color of three primary colors (R, G, B) is emitted from each compartment, but the external dimensions of each pixel When L is set to ₀ , the length of the portion contributing to the discharge in the pair of branch electrodes becomes a value close to L ₀ . That is, compared with the conventional plasma display device, the length of the portion contributing to the discharge can be made about three times, resulting in an enlargement of the discharge region. Therefore, the present invention can prevent occurrence of a problem that the luminance of the plasma display device is lowered.

Hereinafter, the present invention will be described with reference to the drawings.

Embodiment 1

Embodiment 1 relates to the plasma display device of the present invention. The conceptual exploded perspective view of the plasma display device of Embodiment 1 is shown in FIG. This plasma display device has a front panel 10 and a rear panel 20. The front panel 10 includes, for example, a first electrode group made of glass, a first electrode group composed of a plurality of first electrodes formed on the first substrate 11, a first electrode group, and a first electrode group. 1 consists of a dielectric layer 14 formed on the substrate 11, and a protective layer 15 is formed on the dielectric layer 14. The dielectric layer 14 is made of SiO ₂ or low melting glass, and the protective layer 15 is made of magnesium oxide (MgO).

The rear panel 20 includes, for example, a second substrate 21 made of glass and a plurality of second electrodes (also called address electrodes or data electrodes) 22 formed in a stripe shape on the second substrate 21. And a partition wall 25 formed between the phosphor layer 24 formed above the second electrode 22 and the adjacent second electrode 22. The dielectric film 23 is formed on the second electrode 22 and the second substrate 21. A partition wall 25 made of an insulating material is formed on the dielectric film 23 and is formed in a region between adjacent second electrodes 22 and extends in parallel with the second electrodes 22. The phosphor layer 24 is formed on the sidewall surface of the partition wall 25 from the dielectric film 23. Each phosphor layer 24 is composed of a red phosphor layer 24R, a green phosphor layer 24G, and a blue phosphor layer 24B. These phosphor layers 24R, 24G, and 24B are arranged in a predetermined order. It is formed along.

2 is an exploded perspective view, and in the actual plasma display device, the top of the partition 25 on the rear panel 20 is in contact with the protective layer 15 on the front panel 10 side. In addition, the front panel 10 and the rear panel 20 are disposed to face each other such that the protective layer 15 and the phosphor layer 24 face each other, and are bonded to each other through a seal layer (not shown) at the periphery. have. A pair of first main wirings 12A and 12B, a pair of branch electrodes 13A and 13B extending from these main wirings 12A and 12B, and a second member located between two adjacent partition walls 25 The region where the two electrodes 22 overlap is equivalent to the discharge cell. In addition, the pair of first main wiring 12A, the second main wiring 12B, the first branch electrode 13A, and the second branch electrode 13B are formed of phosphor layers 24R, 24G, and 24B of three primary colors. The overlapping area corresponds to one pixel. In the space formed by the front panel 10 and the rear panel 20, for example, a Ne-Xe mixed gas (e.g., Ne 50%-Xe 50% mixed gas) is 8 x 10 ⁴ Pa (0.8). Sealed at a pressure of atmospheric pressure). That is, the rare gas is enclosed in the space enclosed by the adjacent partition 25, the phosphor layer 24, and the protective layer 15. As shown in FIG.

The arrangement relationship between the pair of opposing first electrodes and the partition wall 25 is schematically shown in FIG. 1. Incidentally, diagonal lines are attached to clarify each area. The pair of opposing first electrodes includes (A) the first main wiring 12A, (B) the second main wiring 12B extending in parallel with the first main wiring 12A, and (C) the adjacent partition wall ( The first branch electrode 13A extending from the first main wiring 12A to the second main wiring 12B and immediately before the second main wiring 12B between the first main wiring 12A, and (D) the partition wall. Between the 25 and the partition walls 25, from the second main wiring 12B to the first main wiring 12A, and immediately before the first main wiring 12A, The second branch electrode 13B extends facing each other. The first electrode group is an assembly of the first main wiring 12A, the second main wiring 12B, the first branch electrode 13A, and the second branch electrode 13B. In Embodiment 1, the 1st branch electrode 13A and the 2nd branch electrode 13B are substantially rectangular, and the 1st branch electrode 13A and the 2nd branch electrode 13B extend in parallel with each other. Moreover, the 1st main wiring 12A and the 2nd main wiring 12B extend in parallel, and the predetermined | prescribed which the direction in which these main wiring 12A, 12B extends, and the direction in which the partition 25 extends are formed. The angle of is 90 degrees, for example.

As shown in FIG. 1, the interval between the first branch electrode 13A and the second branch electrode 13B is L ₁ , the interval between the first main wiring 12A and the tip of the second branch electrode 13B, or When the interval between the second main wiring 12B and the tip of the first branch electrode 13A is set to L ₂ , L ₁ <L ₂ is satisfied. In the first embodiment, and ^{_{specifically, L 1 = 5 × 10 -5}} m (50㎛) and ^{L2 = 8 × 10 -5 m (} 80㎛).

In FIG. 1, the area enclosed by the dotted line corresponds to one pixel. The outer shape of each pixel is square, and each pixel is divided into three compartments (cells) by the partition wall 25, and one of three primary colors R, G, and B is emitted from each compartment. External dimensions of the first pixel, when the L _0, the dimension of each compartment (L _0/3) × slightly smaller than (L _0). Therefore, in the pair of branch electrodes 13A and 13B, the lengths of the portions 13A 'and 13B' of the branch electrodes 13A and 13B that contribute to the discharge are close to (L ₀ ).

Each branch electrode 13A, 13B is formed on the first substrate 11, and is formed of a transparent conductive material called ITO. As the conductive material constituting the first main wiring 12A and the second main wiring 12B, a material having a lower electrical resistivity than that of ITO, for example, a chromium / copper / chromium laminated film is used. The line widths of the first and second main wirings 12A and 12B are as narrow as possible so as not to damage the luminance of the display screen (upper surface of the first substrate 11 in FIG. For example, it is 50 micrometers wide.

The second electrode group is an assembly of second electrodes 22 formed in a stripe shape on the second substrate 21. Each second electrode 22 is made of, for example, silver or aluminum, and contributes to the start of discharge together with the first and second branch electrodes 13A and 13B, and is generated from the phosphor layer 24. The light emission is reflected on the display screen side, thereby contributing to the improvement of the brightness of the display screen. Each phosphor layer 24 is composed of a red phosphor layer 24R, a green phosphor layer 24G, or a blue phosphor layer 24B, and the phosphor layers 24R, 24G, and 24B emitting these three primary colors are one set. And formed on the second electrode 22 in a predetermined order.

Next, an example of the AC glow discharge operation of the plasma display device having the above configuration will be described. First, for example, a pulse voltage higher than the discharge start voltage V _bd is applied to all the first main wirings 12A for a short time. As a result, discharge occurs, wall charges are generated on the surface of the dielectric layer 14 near one branch electrode due to dielectric polarization, wall charges are accumulated, and the discharge start voltage is clearly lowered. After that, while applying a voltage to the second electrode (address electrode) 22, a voltage is applied to one of the main wirings included in the cell which is not displayed, thereby allowing the second electrode 22 and one of the branch electrodes to be separated. The discharge is generated to erase the accumulated wall charges. This erase discharge is performed in turn on each of the second electrodes 22. On the other hand, no voltage is applied to one main wiring included in the cell to be displayed. Thus, the accumulation of wall charges is maintained. Thereafter, by applying a predetermined pulse voltage between all the pair of main wirings 12A and 12B, the discharge starts between the pair of branch electrodes 13A and 13B in the cell where the wall charges have accumulated, and the discharge cell is started. The phosphor layer excited by irradiation of vacuum ultraviolet rays generated by glow discharge in the rare gas exhibits a specific emission color according to the phosphor material. The phases of the discharge holding voltages applied to one main wiring and the other main wiring are shifted by half a period, and the polarities of the electrodes are reversed in accordance with the frequency of alternating current.

Another example of the AC glow discharge operation of the plasma display device having the above configuration will be described. First, erasing discharge is performed to the telephone station in order to initialize all the pixels, and then discharge operation is performed. The discharge operation is divided into an address period for generating wall charges on the surface of the dielectric layer 14 by the initial discharge and a discharge sustain period for holding the discharge. In the address period, a pulse voltage lower than the discharge start voltage V _bd is applied to one selected main wiring and the selected second electrode 22. The overlapping region between one main wiring to which the pulse voltage is applied and the second electrode 22 is selected as the display pixel, and wall charges are generated due to dielectric polarization on the surface of the dielectric layer 14 in this overlapping region, and the wall Charges accumulate. In the subsequent discharge sustain period, the discharge sustain voltage V _sus lower than V _db is applied to the pair of main wirings 12A and 12B. When the sum of the wall charge (V _w ) induced by the wall charge and the discharge holding voltage (V _sus ) is greater than the discharge start voltage (V _bd ) (that is, V _w + V _sus > V _bd ), the discharge This is initiated. The phases of the discharge sustain voltage (V _sus ) applied to one main wiring and the other main wiring are shifted by a half cycle from each other, and the polarities of the electrodes are inverted according to the frequency of the alternating current.

In the discharge cell in which the alternating glow discharge is maintained, the vacuum ultraviolet rays radiated by excitation of the rare gas generated in the space are irradiated to excite the phosphor layer 24, thereby obtaining light emission of a unique color according to the phosphor material.

In the plasma display device of the present invention, since the length of the electrode contributing to the discharge (that is, the length of the opposing portions of the pair of branch electrodes 13A and 13B) is longer than that of the conventional plasma display device, the area of the discharge region is reduced. Compared with the conventional three-electrode AC plasma display device shown in Figs. 6 to 8, it is possible to greatly increase the brightness of the display screen.

Hereinafter, the manufacturing method of the plasma display device of Embodiment 1 is demonstrated. In the following description, the first substrate 11, all the structures formed thereon, the second substrate 21, or all the structures formed thereon may be referred to as "gas" in any step of the manufacturing method. .

The front panel 10 can be manufactured as follows. First, the ITO layer is formed on the entire surface of the first substrate 11 by, for example, sputtering, and the ITO layer is patterned in a stripe pattern by photolithography and etching techniques to thereby form the first and second branch electrodes. 13A and 13B can be formed. Next, a chromium / copper / chromium laminated film is formed on the entire surface of the substrate by, for example, sputtering, and the chromium / copper / chrome laminated film is patterned by photolithography and etching techniques, thereby forming the first and second notes. The wirings 12A and 12B can be formed. One end of the first branch electrode 13A and the first main wiring 12A are polymerized with each other, and one end of the second branch electrode 13B and the second main wiring 12B are polymerized with each other. It is. Thereafter, a dielectric layer 14 having a thickness of approximately 10 mu m is formed on the entire surface of the substrate. Then, a protective layer 15 made of MgO having a thickness of approximately 0.6 mu m is formed on the dielectric layer 14. The dielectric layer 14 can be formed by, for example, forming a low melting glass paste layer on the entire surface of the substrate by a screen printing method and firing or sintering the low melting glass paste layer. The protective layer 15 can be obtained, for example, by forming a magnesium oxide layer on the entire surface of the dielectric layer 14 by an electron beam deposition method. The front panel 10 can be completed by the above process.

The rear panel 20 can be manufactured as follows. First, the silver paste may be printed on the second substrate 21 in a stripe shape by, for example, a screen printing method, and the second electrode 22 may be formed by firing or sintering. Next, a low melting glass paste layer is formed on the entire surface of the substrate by a screen printing method, and the dielectric film 23 is formed by firing or sintering the low melting glass paste layer. Thereafter, the low-melting-point glass paste is printed on the dielectric film 23 above the region between the adjacent second electrodes 22 by, for example, a screen printing method, and the partition walls 25 are formed by firing or sintering. Form. The height of the partition 25 may be, for example, 1 × 10 ⁻⁴ m (100 μm) to 2 × 10 ⁻⁴ m (200 μm). Subsequently, the phosphor slurry of three primary colors is printed one by one, and the phosphor layers 24R, 24G, and 24B are formed by firing or sintering. The rear panel 20 can be completed by the above process.

Next, the plasma display device is assembled. First, a real layer (not shown) is formed in the periphery of the rear panel 20 by screen printing, for example. Next, the front panel 10 and the rear panel 20 are bonded to each other and baked or sintered to cure the real layer. Next, after evacuating the space formed between the front panel 10 and the rear panel 20, the Ne-Xe mixed gas (for example, Ne 50%-Xe 50% mixed gas) is subjected to a pressure of 8 x 10 ⁴ Pa. (0.8 atm) to seal the space and complete the plasma display. If the front panel 10 and the rear panel 20 can be joined in a chamber filled with a Ne-Xe mixed gas at a pressure of 8 x 10 ⁴ Pa (0.8 atm), the exhaust process and the filling of the Ne-Xe mixed gas and It is also possible to omit the sealing step.

Embodiment 2

Embodiment 2 is a variation of Embodiment 1. The second embodiment differs from the first embodiment in that the arrangement relationship between the first electrode and the partition wall 25 is schematically shown in FIG. 3, and thus, the front end portion of the first branch electrode 13A and the second branch electrode 13B. The tip of is at the point that the angle is rounded. The planar shape of the first branch electrode 13A and the second branch electrode 13B is rectangular in macroscopic view. Except for this point, the plasma display device of the second embodiment can have the same structure and configuration as the plasma display device of the first embodiment, and thus detailed description thereof will be omitted.

As mentioned above, although this invention was demonstrated according to embodiment, the plasma display apparatus of this invention is not limited to these embodiment. The details of the configuration, constituent materials and manufacturing method of the plasma display device can be appropriately changed, selected, and combined. A second electrode group composed of a plurality of second electrodes may be formed on the first substrate. That is, the second electrode may be formed on the dielectric layer 14 through an insulating film, and may have a predetermined angle (for example, 90 °) with the direction in which the second electrode and each main wiring extend. .

In the plasma display device of the present invention, since the first branch electrode and the second branch electrode extend from the main wiring so as to face each other, the length of the electrode portion contributing to the discharge can be sufficiently long. Therefore, since the discharge region can be enlarged, it is possible to prevent the occurrence of a problem that the luminance of the plasma display device is lowered despite the simple configuration.

Claims (8)

(a) a first substrate; An electrode group composed of a plurality of electrodes formed on a first substrate, a first panel composed of the electrode group and a dielectric layer formed on the first substrate, and (b) a second substrate; A phosphor layer formed above the second substrate; A second panel extending at a predetermined angle from the direction in which the electrode extends and comprising partition walls formed between adjacent phosphor layers; An AC drive plasma display device having: The opposite pair of electrodes, (A) the first main wiring, (B) a second main wiring extending in parallel with the first main wiring, (C) a first branch electrode extending between the adjacent partition walls from the first main wiring to the second main wiring and to the front of the second main wiring, and (D) Between the adjacent partition walls, the second branch electrode extending from the second main wiring toward the first main wiring and immediately before the first main wiring, facing the first branch electrode. Composed, And a discharge display between the first branch electrode and the second branch electrode. The method of claim 1, And a planar shape of the first branch electrode and the second branch electrode is generally rectangular. The method of claim 1, A front end portion of the first and second branch electrodes, the angle of which is missing or rounded plasma display device. The method of claim 1, The distance between the first branch electrode and the second branch electrode is L ₁ , the distance between the tip portion of the first main wiring and the second branch electrode, or between the tip portion of the second main wiring and the first branch electrode. A plasma display device that satisfies L ₁ <L ₂ when the interval of is set to L ₂ . The method of claim 1, And a distance between the first branch electrode and the second branch electrode is less than 5 × 10 ⁻⁵ m. The method of claim 1, And a conductive material constituting the first and second main wirings and a conductive material constituting the first and second branch electrodes are different from each other. The method of claim 6, And a conductive material constituting the first and second branch electrodes is transparent to light emitted from the phosphor layer. The method of claim 1, And a second electrode group including a plurality of second electrodes is formed on the second substrate, and the phosphor layer is formed above the second electrode.