JP2633904B2 - Gas discharge panel - Google Patents

Description

Description: TECHNICAL FIELD The present invention relates to a gas discharge type display panel (gas discharge panel), and more particularly to an electrode structure thereof.

(Prior Art) Gas discharge panels include a monochrome display and a full-color display, and a full-color display is expected to be suitable for, for example, a wall-mounted high-definition television. Hereinafter, a conventional gas discharge panel will be described using a gas discharge panel capable of full color display as an example.

As this type of conventional panel, for example, there is a panel disclosed in a document (IEICE Technical Report EID87-72 (1988) pp. 55-60). The panel disclosed in this document has a two-body structure that is rich in mass productivity and suitable for upsizing. FIG. 5 (A) is a partial perspective view showing the panel with a part cut away.

In FIG. 5A, reference numeral 11 denotes a front plate, for example, as a first substrate, 12 denotes a display anode bus, and 12a denotes a display anode. The display anode 12a is constituted by a portion of the anode bus bar 12 exposed from the insulating film indicated by reference numeral 13. 14 is a display cell spacing wall, 15 is a display discharge space (sometimes called a display cell), 16 is a phosphor, 17 is a display cathode bus, 17a is a display cathode, 17b is a pilot light cathode, and 18 is a pilot light. The discharge space, 19 is a pilot flame anode bus, and 19a is a pilot flame anode. The seed-fire anode 19a is configured by a portion of the seed-fire anode bus 19 that is exposed from the insulating film 13. Here, the display cathode buses 17 are arranged in a predetermined direction. Each display anode bus 12 is spaced from each display cathode bus 17 and is arranged in a direction perpendicular to the display cathode bus 17. The cell spacing wall 14 is a quadrangular partition wall, thereby defining a display cell 15. Reference numeral 20 denotes a priming hole, and reference numeral 21 denotes a back plate as a second substrate.
The cell is filled with a He-Xe mixed gas as a discharge gas, and when a voltage of several hundred volts is applied between the display anode 12a and the display cathode 17a, plasma discharge occurs in the cell. The phosphor 16 is excited and emitted by the ultraviolet light generated at the time of the discharge, and as a result, a color display is obtained. Note that a method of thick film printing is generally used for manufacturing this type of gas discharge panel.

Next, the structure of the electrode portion of the above-described panel will be described. FIG. 5B is an enlarged plan view schematically showing one display cell portion of the panel shown in FIG. 5A.
In the conventional panel, in order to increase the aperture ratio of the display cell, the display cathode bus 17 is embedded in the cell partition wall 14, and the display cathode 17a is configured by projecting a part of the display cathode bus 17. I was Further, the display anode 12a is arranged at a position substantially diagonally to the display cathode of the display cell so that the discharge spreads over the entire display discharge space.

By the way, in this type of gas discharge panel, it is known that the area of the cathode and the electrical resistance of the cathode greatly affect the characteristics of the panel. For example, according to the literature (Technical Report of the Institute of Television Engineers of Japan ED992, IPD113-7 (1987), pp. 37-42), a large current flows through the cathode conductor, so that when the resistance increases, the voltage drop increases. Adversely affect the operating characteristics of the device. FIG. 6 is a view showing this, and is a view showing experimental data described in the above-mentioned literature. This figure shows the results of examining the static discharge characteristics of the panel using the nickel paste of two companies, Company A and Company B, as the cathode material. The horizontal axis represents the voltage applied to the cell, and the vertical axis represents the voltage. The relationship between the two (VI characteristics) is shown by taking the current flowing through the cell on the axis. In FIG. 6, 31 is the characteristic when the cell diameter is 0.5 mm, 32 is the characteristic when the cell diameter is 0.4 mm, and 33 is the characteristic when the cell diameter is 0.3 mm. The characteristics when the paste is used and the broken lines show the characteristics when the nickel paste manufactured by Company B is used. It can be seen that a difference in discharge sustaining voltage of 10 V or more is caused only by the manufacturer of the nickel paste, and that the discharge sustaining voltage increases as the cell area decreases.

(Problems to be Solved by the Invention) However, in the conventional gas discharge panel as shown in FIG. 5, the thickness of the display cathode bus is 10 to 10 at most.
The width is about 15 μm, and its width cannot be made so large in consideration of improving the display cell density. Therefore, when an attempt is made to manufacture a large panel such as a wall-mounted television, the wiring resistance of the display cathode bus becomes very large. And the wiring resistance up to the display cell at the end of the display cathode bus cannot be ignored, and it is considered that this effect causes a remarkable difference in the light emission luminance between the two display cells.
In order to avoid luminance variation, it is conceivable to control the discharge sustaining voltage to an appropriate value for each display cell. However, a control circuit for that purpose has a complicated structure. Considering such a situation, it can be said that the lower the resistance value of the display cathode bus, the better.

Further, in the conventional gas discharge panel as shown in FIG. 5, although the projection portion is reduced to constitute the display cathode, the aperture ratio of the display cell must be reduced. The improvement was desired.

Further, in the conventional gas discharge panel as shown in FIG. 5, there is a problem that the display cathode has to be reduced in order to increase the aperture ratio of the display cell, so that the discharge current cannot be increased. .

SUMMARY OF THE INVENTION The present invention has been made in view of the above points, and accordingly, an object of the present invention is to provide a gas capable of reducing the wiring resistance of a display cathode bus, improving the aperture ratio of a display cell, and increasing the display cathode area. An object of the present invention is to provide a discharge panel.

(Means for Solving the Problems) According to the first invention of the present application, a plurality of cathode buses arranged in a predetermined direction between the first and second substrates, and separated from and orthogonal to each cathode bus. And a plurality of anode buses arranged in the direction in which each of the cathode buses and the anode buses are separated and intersect with each other, and the periphery of the vicinity thereof is defined by a rectangular partition wall made of an insulating material. A plurality of display cells each having a priming hole formed in a part thereof, wherein one of two sides provided in a direction parallel to the cathode bus among four sides of the rectangular partition wall. The cathode bus is formed in a strip shape on the side of the side that is in contact with the side and faces the inside of the display cell on one side, thereby forming a cathode of the display cell.

According to the second invention of this application, in addition to the configuration of the first invention, at least one of two sides provided in a direction orthogonal to the cathode bus among four sides of the rectangular partition wall is provided. At least a portion of the side in the height direction is a band-shaped conductor electrically connected to the cathode bus (hereinafter, also referred to as a "band-shaped first conductor" for distinction from the third invention below). The strip-shaped cathode bus and the strip-shaped first bus.
Constitutes a cathode of the display cell. And
The strip-shaped first conductor also serves as a part of a cathode of an adjacent display cell adjacent to a partition wall provided with the first conductor.

Further, according to the third invention of this application, in addition to the configuration of the above second invention, the other of the two sides provided in a direction parallel to the cathode bus among the four sides of the rectangular partition wall. The display cathode bus and the first conductive member are brought into contact with a side (a side opposite to the side provided with the cathode bus in the first and second inventions) and a surface of the other side facing the inside of the display cell. A strip-shaped conductor electrically connected to the body (hereinafter, also referred to as a “band-shaped second conductor”); the strip-shaped cathode bus, the strip-shaped first conductor, and the strip-shaped second conductor; Constitutes a cathode of the display cell. The strip-shaped first conductor also serves as a part of a cathode of an adjacent display cell adjacent to a partition wall provided with the first conductor.

(Operation) According to the first to third aspects of the present invention, a surface facing the inside of the display cell at a predetermined one of the four sides of the side wall of the display cell, that is, the cell spacing wall, is used to form a display cathode bus. Can be used for As a result, the thickness of the display cathode bus can be made significantly thicker and more uniform than conventional ones, so that the wiring resistance of the cathode bus can be extremely reduced.

Further, since the display cathode can be formed by using the wall surface of the cell spacing wall, that is, the side wall of the display cell, the cathode does not protrude toward the display cell, so that the display cathode can be obtained without lowering the aperture ratio of the cell. Obviously, a display cathode having a large area can be obtained. Further, according to the configuration of the second aspect of the invention, the area of the cathode is wider than that of the first aspect of the invention because the band-shaped first conductor is further provided. Also,
According to the structure of the third invention, the cathode area becomes wider than that of the second invention by the provision of the band-shaped second conductor. Moreover, since the first and second conductors are also formed using the space in which the display cell spacing wall is to be formed, similarly to the display cathode bus of the first invention, even if these conductors are provided. In addition, the display cell aperture ratio does not decrease.

(Embodiment) Hereinafter, an embodiment of the present invention will be described using an example of a gas discharge panel capable of performing full color display, in which display cells are arranged in a substantially grid pattern. It is to be noted that the drawings used in the following description are merely schematically shown to the extent that the present invention can be understood, and therefore, the dimensions of each component,
It should be understood that the shape and the arrangement relationship are not limited to those in the illustrated example, and various changes can be made.

First Embodiment of the First Invention First, an embodiment of the first invention (hereinafter, also referred to as a first embodiment, the same applies to the drawings) using an example in which the present invention is applied to the conventional gas discharge panel described with reference to FIG. Will be described. FIG. 1 is a diagram provided for the explanation, and is a partial perspective view showing the panel of the first embodiment focusing on one display cell portion. In this figure, the same components as those shown in FIG. 5 are denoted by the same reference numerals. Also, components shown in FIG. 5 that are considered unnecessary for the description of the invention are omitted.

In FIG. 1, reference numeral 12 denotes a display anode bus, 12b denotes a display anode, 13 denotes an insulating film, 14 denotes a display cell interval wall, 15 denotes a display discharge space (sometimes called a display cell), 16 denotes a phosphor, and 20 denotes a phosphor. Each shows a priming hole. The display anode 12
b is provided so as to be exposed to the discharge space 15 from the surface of the phosphor 16 to facilitate discharge. In the gas discharge panel of the first embodiment, one of the side walls of the display cell 15
That is, one of the two sides (portion 141 in the drawing) provided in the direction parallel to the cathode bus among the four sides of the rectangular cell spacing wall 14 is a display cathode bus 143 shown as a scanning electrode. To prevent erroneous discharge of adjacent display cells
The structure is such that the inter-cathode wall indicated by 5 is arranged so that the respective main surfaces have a back-to-back positional relationship.
Therefore, one side of the cell spacing wall (specifically, the cathode
5), a cathode bus 143a is provided in a band shape on the side of the one side facing the inside of the display cell 15. As described above, the display cathode bus 143 is formed so as to also have the role of the cell spacing wall in about half of the space where one surface of the cell spacing wall is to be formed. The thickness can be made much thicker than before, and as a result, the resistance value of the display cathode bus can be reduced.

In the panel of the first embodiment, a portion of the display cathode bus 143 which is a side wall of the display cell (143a in the drawing)
The portion indicated by () is a display cathode. For this reason, since the convex portion is unnecessary, the aperture ratio of the display cell can be improved, and the area of the display cathode can be increased.

In this panel, the height of the display cathode bus 143 (the dimension indicated by H in the drawing) corresponds to the cell spacing wall (specifically, the cathode wall 14).
5), and the width of the display cathode bus 143 (dimension w) in the drawing and the width of the cell spacing wall (specifically, the cathode wall 145) are substantially equal. . However, as the width of the display cathode bus 143 is wider, the resistance value of the display cathode bus 143 can be reduced, and these dimensions are appropriate values in consideration of the desired resistance value and restrictions imposed on the panel design. And

Embodiment of Second Invention FIGS. 2 and 3A to 3C show a gas discharge panel according to an embodiment of the second invention of the present invention (hereinafter, also referred to as a second embodiment; the same applies to the drawings). FIG. FIG. 2 is a partial perspective view showing the panel focusing on one display cell portion. FIG. 3 (A)
Is a plan view showing the panel as viewed from the front panel side, and of course, a plan view in which the components of the panel are cut out stepwise from the front panel side so that the internal structure of the panel can be understood. FIG. FIG. 3B is a cross-sectional view of the panel taken along the line II shown in FIG. 3A, and FIG. 3C is a cross-sectional view taken along the line II-II of FIG. FIG. 3 (B) and 3 (C), the hatching indicating the cross section is partially omitted in order to avoid complicating the drawings. In the case of the second embodiment, the width w _{1 of} the light-shielding mask 41 (not shown in FIG. 2), the display cathode bus 42 and the cathode
Total width w ₂ and the width of the side of the cell spacing walls close to the rear plate w ₃ and 43
The relationship between, and the _{w 1> w 2> w 3} . Therefore, the third
It should be understood that the drawing (A) is complicated.

2 and 3 (A) to 3 (C), reference numeral 41 denotes a light-shielding mask, reference numeral 42 denotes a display cathode bus which is a scanning electrode, reference numeral 42a denotes a display cathode, and reference numeral 43 denotes an electrical insulation between adjacent display cathode buses. The cathode gap wall, 44 is a part of the cell gap wall, 45 is a part of the cell gap wall, and the cell gap wall with the priming hole, 46
Denotes a phosphor, 47 denotes a display anode bus, 47a denotes a display anode, and 48 denotes a priming hole. 2 and 3
In the figure, reference numeral 51 denotes a front plate, 52 denotes an anode protection film, 53 denotes a dielectric between anodes provided for insulation between anodes and for the purpose of flattening the anode protection film, and 54 denotes a back plate.

In the gas discharge panel of the second embodiment as well, one of the side walls of each display cell, that is, the main part of one surface of the cell interval wall is constituted by the display cathode bus. The structure is as follows. To explain.

First, a planar structure will be described with reference to FIGS. 2 and 3 (A). In the four-sided cell spacing wall surrounding the display cell, of the two sides provided in the direction parallel to the cathode bus. one side (in the figure, those denoted by the W ₂₎ is the partition wall shown in the display the cathode bus 42 and the cathode between the wall 43 in the width direction is constituted by those which are arranged back to back, also W ₂ The two partitions indicated by 42c and 42d extending in a direction perpendicular to the direction are formed of a strip-shaped conductor made of the same material as the display cathode bus 42. Next, referring to FIG. 3 (B) and (C), and barrier ribs denoted by the W _2, and the partition wall shown in 42c, the structure as viewed from the side of the partition wall shown in 42d description Then, the height of the cell interval wall in the normal panel is set to h ₁
When a so called partition wall panel of the second embodiment, a portion indicated by reference numeral h ₂ is Yes constituted by the cathode forming material, portions indicated by h ₃ is composed of ordinary cell spacing wall forming material To
It has a structure in which a partition material and a cathode material are laminated. Therefore, the display cathode 42a in the case of the second embodiment has a part formed by a part 42b which is a side wall of the display cell of the display cathode bus 42, and the other part is a direction perpendicular to the display cathode bus from the display cathode bus. And a display cathode having a structure surrounding the display cell from three sides. Of course, the partitions (band-shaped conductors) indicated by 42c and 42d also have a structure that also serves as a part of the cathode of the adjacent display cell adjacent to the partition provided with the strip-shaped conductors 42c and 42d. .

On the other hand, the display anode 47 is connected to the three electrodes 42b, 4 of the display cathode 42a.
In order to keep the distance from 2c and 42d constant and to facilitate discharge, a display is provided at the center of the display cell so as to be exposed to the discharge space from the surface of the phosphor 46.

Also in the case of the gas discharge panel of the second embodiment,
Since the display cathode bus 42 is formed by using a part of the space where one surface of the cell spacing wall is supposed to be formed and also serving as the cell spacing wall, the thickness of the display cathode bus is conventionally reduced. In this case, the resistance value of the display cathode bus can be reduced.

Further, in addition to the portion of the display cathode bus 42 which is the side wall of the display cell (the portion indicated by 42b in the figure), the other side wall is also used as the display cathode, so that the area of the display cathode is the same as that of the first embodiment. It becomes possible to make it wider than in

The fact that the resistance values of the gas discharge panel and the display cathode bus of the second embodiment are reduced will be described below with reference to specific examples. For example, the literature since (ITEJ Technical Report ED992IPD113-7 (1987) P.37~42) of the cell gap walls of conventional panel disclosed in height h ₁ is is also about 230 .mu.m, manufacturing margin Taking into account, the height h ₂ of each of the display cathode bus and the display cathode of the second embodiment is 150 μm.
m. Therefore, the thickness of the display cathode bus of the panel having the conventional structure is 10 to 15 μm, while h ₂ = 150 μm.
When the panel of the example is manufactured with m, the resistance of the display cathode bus at this time is easily found to be about one-tenth that of the conventional one. The higher the height h ₂ of the display cathode bus 42 is,
The larger the width is, the more the resistance of the display cathode bus 42 can be reduced. These dimensions are set to appropriate values in consideration of the desired resistance and the restrictions imposed on the panel design.

Experimental Results Next, effects obtained by the gas discharge panel of the present invention using the gas discharge panel of the second embodiment will be described based on experimental results.

The display cell pitch (the dimension indicated by P in FIG. 3 (A)) is 1.
And 0 mm, the width (FIG. 3 (dimension shown by Medium A) w ₀₎ and a display cathode 42c extending from the bus 42 of the display the cathode bus 42, and the width of the 42d respectively 150 [mu] m, the cell gap walls the height h ₁ 250μ
m, the height h ₂ of the display cathode 42a was set to 100 μm (the same applies to the display cathode bus), and a He-Xe (5%) mixed gas was sealed in the cell at a sealing gas pressure of 200 Torr to produce a gas discharge panel of Example. did. As a gas discharge panel of a comparative example, the fifth
In the structure described with reference to FIGS. (A) and (B), the cathode bus has a width of 150 μm and a thickness of 10 to 15 μm, and the cell pitch, the height of the cell interval wall, and the sealing gas pressure are controlled. A comparative gas discharge panel similar to that of the example was prepared.

Next, the resistance of the display cathode bus of the gas discharge panels of the examples and the comparative examples was measured. The data of the resistance values of the display cathode buses of both display variations depending on the cathode material used and the printing conditions, but those of the examples always showed smaller resistance values. For example, the resistance per 10 cm of the cathode bus length of both the gas discharge panels of the example and the comparative example, which were prepared by firing this paste at a temperature of 530 ° C. using a nickel paste (trade name: 2554) manufactured by ESL, Inc. The resistance of the comparative example was 60Ω, while that of the example was 5Ω.

Further, static discharge characteristics of the panel of the example and the panel of the comparative example were examined. FIG. 4 is a characteristic curve diagram showing the result. In the figure, the one indicated by I indicates the characteristics of the example, and the one indicated by II indicates the characteristics of the comparative example. Compared with the panel of the comparative example, the panel of the example obtained a large discharge current, and it was found that when the inter-cell voltage was 280 V or more, the discharge current was about three times or more.

The numerical conditions in the above description are merely examples, and these numerical conditions are changed to appropriate values according to the design of the gas discharge panel, and the object of the present invention is achieved only by these numerical conditions. It should be understood that this is not the case.

Further, the present invention is not limited to only the above-described embodiment. In the embodiment, the display cathode is provided on one or three of the four side walls of the cell spacing wall surrounding the display cell. However, the display cathode may be provided on two or four side walls. . When provided on the four side walls, in addition to the configuration of the second invention described above, the other of the two sides provided in a direction parallel to the cathode bus 42 (see FIG. 2) among the four sides of the rectangular partition wall. (A side facing the side on which the cathode bus 42 is provided in the second invention), and a band-shaped conductor (a band-shaped second conductive layer) is formed on the other side of the surface facing the inside of the display cell. Body, not shown). Of course, the band-shaped second conductor is connected to the display cathode bus 42 and the band-shaped conductors 42c and 42d (see FIG. 2) provided in the second invention, respectively. Thus, the cathode of the display cell can be constituted by the display cathode bus 42, the strip-shaped conductors 42c and 42d, and the strip-shaped second conductor (not shown). In addition, a strip-shaped conductor
42c and 42d also serve as a part of the cathode of the adjacent display cell adjacent to the partition wall provided with the conductor. In the case where the display cathodes are provided on the four side walls to surround the display cell from all sides, the widths of the portions between the cathode wall 43 and the display cathode 42a indicated by 42b are respectively set so as not to increase the width of the cell interval wall. It is preferable to make the cathode thinner so that cathode portions corresponding to 42b are formed on both sides of the inter-cathode wall. Also, depending on the design, the side wall indicated by 42b whose main part is constituted by the display cathode bus 42 is covered with an insulating film, and the other side wall of this display cell, a portion indicated by 42c, a portion indicated by 42d, and Of course, at least one side wall of the portion facing 42b may be used as a display cathode. However, when the portion facing 42b is used as a display cathode, it is preferable that both side walls indicated by 42c or 42d be display cathodes.

Further, in the embodiment, a gas discharge panel for full color display is described as an example, but it is apparent that the present invention can be applied to a gas discharge panel for monochrome display. Further, the position where the priming hole is provided, the shape and the arrangement of the display cell, and the like are not limited to those of the embodiment, and it is apparent that various changes can be made according to the design of the panel.

(Effects of the Invention) As is clear from the above description, according to the gas discharge panels of the first to third inventions of the present application, of the four sides of the quadrangular partition wall, the relationship becomes parallel to the cathode bus 2 A display cathode bus was provided in a strip shape in contact with one of the sides facing the inside of the display cell, thereby forming a cathode of the display cell. For this reason, the thickness of the display cathode bus for the space used for forming the cell spacing wall can be made thicker and more uniform than the conventional one, so that the resistance value of the display cathode bus can be significantly reduced. Furthermore, since the cathode is formed using the wall surface of the cell spacing wall, the cathode does not protrude, so that the aperture ratio of the cell can be improved and the area of the display cathode can be increased. Therefore, it is possible to contribute to the reduction of the variation of the discharge current and the variation of the luminance for each display cell of the gas discharge panel. 2, the luminance and luminous efficiency of the display cell can be improved.

Further, in the second invention, if a display cathode is provided by using a large number of side walls of the display cell as in the third invention, the effect as a hollow cathode can be obtained, and the luminance and luminous efficiency are further improved. Of course, since the hollow cathode (the strip-shaped first conductor) also serves as a part of the cathode of the adjacent display cell, it can contribute to an increase in the aperture ratio of the display cell and can simplify the configuration. It also contributes to a reduction in panel manufacturing costs.

[Brief description of the drawings]

FIG. 1 is an explanatory view of a first embodiment of the present invention, and is a perspective view showing a gas discharge panel with a part cut away. FIG. 2 is an explanatory view of a second embodiment of the present invention. FIG. 3 (A) is a partially cutaway perspective view of the gas discharge panel, FIG. 3 (A) is a plan view of the gas discharge panel of the second embodiment partially cut away, FIGS. 3 (B) and (C). ) Is a cross-sectional view showing a part of the gas discharge panel of the second embodiment of the present invention, mainly for explaining the structure of the cathode portion. FIG. 4 is a diagram showing the panel of the embodiment and the comparative example. FIGS. 5 (A) and 5 (B) are views for explaining the structure of a conventional gas discharge panel, and FIGS. 6 (A) and 6 (B) are views for explaining the conventional and the present invention. 12 ... display anode bus, 12 b ... display anode 13 ... insulating film, 14 ... cell spacing wall 15 ... display cell, 16 ... phosphor 20 ... priming hole 141 ... cell spacing wall (display cell side wall) ) 143: Display cathode bus, 145: Inter-cathode wall 41: Light-shielding mask, 42: Display cathode bus 42a: Display cathode 42b, 42c, 42d: Part of display cathode 43: Between cathodes Wall, 44, 45: Part of the cell spacing wall 46: Phosphor, 47: Display anode bus 47a: Display anode 48 ... Priming hole 51: Front plate, 52: Anode protection film 53 ... Anode-to-anode dielectric, 54 ... Back plate.

 ──────────────────────────────────────────────────続 き Continued on the front page (72) Inventor Masanobu Ito 1-7-12 Toranomon, Minato-ku, Tokyo Oki Electric Industry Co., Ltd. (56) References JP-A-61-29037 (JP, A) JP-A 62-249334 (JP, A) JP-A-58-80241 (JP, A)

Claims (3)

(57) [Claims] A plurality of cathode buses arranged in a predetermined direction between a first substrate and a second substrate; a plurality of anode buses arranged in a direction separated from and perpendicular to the respective cathode buses; A large number of display cells in which the location where the bus bar and each anode bus intersect and intersect with each other and the vicinity thereof are defined by being surrounded by a rectangular partition wall made of an insulating material, and a priming hole is formed in a part of the partition wall. A gas discharge panel comprising: a rectangular partition wall, which is in contact with one of two sides provided in a direction parallel to the cathode bus among four sides of the rectangular partition wall, and the display cell on the one side A gas discharge panel, wherein the cathode bus bar is provided in a strip shape on a surface side facing the inside to form a cathode of the display cell. 2. A plurality of cathode buses arranged in a predetermined direction between a first substrate and a second substrate; a plurality of anode buses arranged in a direction separated from and perpendicular to each cathode bus; A large number of display cells in which the location where the bus bar and each anode bus intersect and intersect with each other and the vicinity thereof are defined by being surrounded by a rectangular partition wall made of an insulating material, and a priming hole is formed in a part of the partition wall. A gas discharge panel comprising: a rectangular partition wall, which is in contact with one of two sides provided in a direction parallel to the cathode bus among four sides of the rectangular partition wall, and the display cell on the one side The cathode bus is provided in a strip shape on a surface side facing the inside, and at least one of the four sides of the quadrangular partition wall in the height direction of at least one of two sides provided in a direction orthogonal to the cathode bus. One part is electrically connected to the cathode bus The strip-shaped conductor, the strip-shaped cathode bus and the strip-shaped conductor constitute a cathode of the display cell, and the strip-shaped conductor is adjacent to a partition provided with the conductor. A gas discharge panel, which also serves as a part of a cathode of a display cell. 3. A plurality of cathode buses arranged in a predetermined direction between the first and second substrates, a plurality of anode buses arranged in a direction apart from and orthogonal to the respective cathode buses, and a plurality of cathode buses. A large number of display cells in which the location where the bus bar and each anode bus intersect and intersect with each other and the vicinity thereof are defined by being surrounded by a rectangular partition wall made of an insulating material, and a priming hole is formed in a part of the partition wall. And a gas discharge panel comprising: abutting one side of two sides provided in a direction parallel to the cathode bus among four sides of the rectangular partition wall, and The cathode bus is provided in a strip shape on a surface side facing the inside of the display cell, and a height direction of at least one of two sides provided in a direction orthogonal to the cathode bus among four sides of the rectangular partition wall At least a part of the cathode bus and electricity The first partition is made of a band-shaped first conductor connected to the other of the four sides of the rectangular partition wall and is brought into contact with the other one of two sides provided in a direction parallel to the cathode bus, and The display cathode bus and the strip-shaped second conductor electrically connected to the strip-shaped first conductor are provided on the side of the side facing the inside of the display cell, and the strip-shaped display cathode bus and the strip-shaped display cathode bus are provided. A strip-shaped first conductor and the strip-shaped second conductor constitute a cathode of the display cell, and the strip-shaped first conductor is adjacent to a partition provided with the first conductor. A gas discharge panel, which also functions as a part of a cathode of an adjacent display cell.