JPH11126561A - Gas discharge panel - Google Patents

Abstract

(57) Abstract: An object of the present invention is to provide a gas discharge panel, such as a PDP, capable of achieving good discharge efficiency while suppressing power consumption during driving. SOLUTION: On a front panel glass 21, a pair of display electrodes 22 and 23 (X electrodes 22 and Y electrodes 23) are respectively connected to a plurality of electrode limbs X1, X2 or Y1, Y2, Y.
3 to form a fork. And Y1 and X2
The gap between (X2 and Y2) is the first discharge gap 3 of about 20 μm.
9. A gap between Y1 and X1 (X2 and Y3) is a second discharge gap 40 of about 40 μm.
During the sustain discharge, discharge is performed in the second discharge gap 40.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a gas discharge panel used for a display device or the like, and more particularly, to a gas discharge panel.
Regarding DP.

[0002]

2. Description of the Related Art In recent years, expectations for a high-quality, large-screen display device represented by a high-definition television have been increased, and a CRT, a liquid crystal display (hereinafter, referred to as an LCD), a plasma display panel (Plasma Display P).
Anel, hereinafter referred to as PDP) has been researched and developed for each display device. Each of such display devices has the following features.

[0003] CRTs are excellent in resolution and image quality, and have been widely used in televisions and the like. However, when the screen is enlarged, the depth size and weight tend to increase, and it is important to solve this problem. From this, it is considered that it is difficult to produce a CRT having a large screen exceeding 40 inches. On the other hand, LC
D has low power consumption compared to a CRT, has excellent performance of small size and light weight, and is now widely used as a computer monitor. However, LCDs cannot emit light and display on the screen, so if the screen is enlarged, the display becomes thin and difficult to see,
Technical problems such as a tendency that the gradation level and the color tone are easily disturbed at the top and bottom of the screen are likely to occur. Further, in the case of increasing the screen size, it is considered that it is necessary to positively solve the disadvantage that the viewing angle unique to LCD is narrow.

[0004] On the other hand, the PDP uses a CRT as described above.
Unlike LCDs and LCDs, they are relatively lightweight and are advantageous for realizing a large screen. In addition, they have a merit that they consume less power while being driven by a self-luminous display. Therefore, at the present time when a next-generation display device is required, research and development for increasing the size of a gas discharge panel such as a PDP are being actively promoted, and products exceeding 50 inches are already being developed. Has arrived.

[0005] Such a PDP is classified into a DC (direct current) type and an AC (alternating current) type due to the difference in the driving method. Among them, the AC type is considered suitable for enlargement of the screen, and this is becoming common.

[0006]

By the way, today it is desired to develop electric products with as low power consumption as possible for various purposes, and it is expected that gas discharge panels such as PDPs will have low power consumption during driving. Has been sent. In particular, gas discharge panels such as PDPs, in which power consumption tends to increase due to the recent trend of larger screens and higher definition, cannot neglect measures for this power consumption. In order to meet this demand, it is necessary to improve the discharge efficiency, which largely affects the performance of the PDP.

[0007] In gas discharge panels such as PDPs, the technical problem of suppressing power consumption by improving the discharge efficiency as described above still has room for improvement.

[0008]

SUMMARY OF THE INVENTION The present invention has been made in view of the above-mentioned problems, and has an object to appropriately reduce power consumption.
An object of the present invention is to provide a gas discharge panel such as a PDP having a high-performance display function by securing excellent discharge efficiency. The above object is achieved by disposing a plurality of cells filled with discharge gas in a matrix between a pair of opposed plates, and forming a pair of display electrodes on the opposed surface of the plate. In a gas discharge panel that is arranged to extend in the row direction while straddling, two types of discharges, a first discharge gap and a second discharge gap wider than the first discharge gap, are provided between the pair of display electrodes. This can be realized by providing a gap.

More specifically, when the discharge gas pressure is P and the discharge gap is d, the first discharge gap is the minimum discharge start voltage in the Paschen curve showing the relationship between the Pd product and the start discharge voltage. Or the gap corresponding thereto, and the second discharge gap includes a gap corresponding to a gap where the discharge efficiency is maximized in a discharge efficiency curve indicating a relationship between the Pd product and the discharge efficiency. realizable.

In this manner, when power is supplied to the display electrodes, discharge is started at a lower voltage value in the first discharge gap than in the prior art, and the luminous efficiency of the PDP is improved. Further, after the discharge is started, the sustain discharge is efficiently performed in the second discharge gap, and a good display is possible. In the gas discharge panel as described above, specifically, one display electrode is branched into first and second electrode limbs, the other display electrode is inserted between the electrode limbs, and the first electrode limb is provided. A gap between the second display electrode and the other display electrode is a first discharge gap, and a gap between the second electrode limb and the other display electrode is a second discharge gap or a pair of display electrodes. Both branches into electrode limbs, the electrode limb of the other display electrode is inserted between the first and second electrode limbs of one display electrode, the first electrode limb of one display electrode and the other display electrode The gap between the electrode limb of the first discharge gap, the gap between the second electrode limb of one display electrode and the electrode limb of the other display electrode is a second discharge gap by a gas discharge panel. realizable. In this case, in addition to the above effects, it is also possible to perform good address discharge while preventing crosstalk.

Further, according to the present invention, the gap between the pair of display electrodes has a plurality of gap values in a direction perpendicular to the plane of the gas discharge panel, and the plurality of gap values include the first discharge gap and the second gap. This can be realized by providing a gas discharge panel including a gap value corresponding to each of the discharge gaps. This makes it easy to provide the first and second discharge gaps in a limited space, which is advantageous in producing a high-definition cell.

Further, according to the present invention, in at least one of the pair of display electrodes, one or more projections are formed for each cell at the edge of the electrode facing the other display electrode. There is a gap corresponding to the first discharge gap between the second display electrode and the other display electrode, and a gap corresponding to the second discharge gap is formed between the other display electrode and a portion other than the portion where the protrusion is formed. This can be realized by using an existing gas discharge panel.

In this way, the present invention can be realized only by making a slight improvement after the display electrode is manufactured in the conventional manner, and an excellent effect can be obtained in terms of the manufacturing cost.

[0014]

BEST MODE FOR CARRYING OUT THE INVENTION

<First Embodiment> FIG. 1 is a partial sectional perspective view of an AC surface discharge type PDP according to a first embodiment. In the figure, the z direction is P
The xy plane in the thickness direction of the DP corresponds to a plane parallel to the PDP plane. As shown in the figure, the configuration of the present PDP is roughly divided into two units, a front panel 20 and a back panel 26.

The front panel glass 21 serving as a substrate of the front panel 20 is made of soda lime glass. On the surface of the front panel glass 21 facing the back panel 26, the electrode limbs X1, X2 or Y1, Y2, Y
3 and a pair of fork-type display electrodes 22, 2 respectively.
3 (X electrode 22, Y electrode 23) is stretched in the x direction, and
Each electrode limb is Y1, X1, Y2, X
2, Y3 are alternately arranged. Here, it is assumed that the X electrode 22 operates as a scanning electrode at the time of an address discharge, which is common to the embodiments. Display electrode 2
The overall views of 2, 23 will be shown later.

On the surface of the front panel glass 20 on which the display electrodes 22 and 23 are arranged, a dielectric layer 24 made of lead oxide glass is coated. by this,
The display electrodes 22 and 23 are buried in the dielectric layer 24. On the surface of the dielectric layer 24, a protective layer 25 made of magnesium oxide (MgO) is further coated.

A back panel glass 27 serving as a substrate of the back panel 26 is also manufactured in the same manner as the front panel glass 21. A plurality of address electrodes 28 are provided on the surface facing the front panel 20 in the y direction. The display electrodes 22 and 23 of the front panel 20 form a grid-like electrode arrangement pattern at regular intervals in the z direction. Address electrode 28
A dielectric film 29 made of the same material as the dielectric layer 24 is formed on the surface of the back panel glass 27 on which the address electrode 28 is wrapped, and is adjacent to the surface of the dielectric film 29. A plurality of partitions 30 having a certain height and thickness are formed along the y-direction in accordance with the interval between the two address electrodes 28. Side wall of partition 30 and dielectric film 29
Of the phosphor layers 31 and 3 corresponding to each color of RGB
Either of 2 and 33 is applied.

The protective layer 25 on the front panel 20 and the top of the partition 30 on the back panel 26 are bonded to each other with sealing glass. Then, a discharge gas containing a rare gas is filled in each space partitioned by the plurality of partition walls 30, and each space becomes a strip-shaped discharge space 38 long in the y direction. In this discharge space 38, a pair of display electrodes 22 and 23
(Here, electrode limbs X1, X2, Y1, Y2, and Y3) and areas each including a crossing point of one address electrode 28 include cells 11, 12, 13, and 14 for screen display.
(To be described later). Are formed so as to be arranged in a matrix with the x direction as a row direction and the y direction as a column direction, so that in this PDP, each cell 11,.
The matrix can be displayed by blinking.

During driving, each of the electrodes 22, 23, 28
, Two types of discharges are performed. One is an address discharge for controlling ON / OFF of lighting of the cells 11,.
And the address electrode 28 is supplied with power. The other is a sustain discharge (surface discharge) that directly contributes to the screen display of the PDP, and is performed by supplying power between the X electrode 22 and the Y electrode 23.

FIG. 2 shows the display electrode pattern of the present PDP as z
It is a top view when looking down from a direction. Here, illustration of the partition 30 is omitted to avoid complication of the drawing.
Each of the regions obtained by dividing the discharge space 38 by a broken line is the cell 1
1, 12, 13, and 14. Y1 and X correspond to cell 11 (cell 12) which is one of such cells.
1, Y2, X2, Y3 (Y'1, X'1, Y'2, X '
2, Y'3), each electrode limb is set to a size of about 20 μm in width, and the discharge gap between adjacent electrode limbs is one of the following two values. Set to take a value.

That is, one of the two values is:
The gap value of the first discharge gap 39 existing in the gap between X1 and Y2, Y2 and X2 (Y'1 and X'1, Y'2 and X'2), and is set to about 20 μm. First discharge gap 39
Is set for the purpose of keeping the discharge starting voltage lower than before. Another value is Y1 and X1, X2 and Y
3 (Y'1 and X'1, X'2 and Y'3), which is the gap value of the second discharge gap 40, which is set to about 40 μm. The second discharge gap 40 is set as a gap for ensuring high luminous efficiency after the start of discharge. The reason why the respective gap values of the first discharge gap 39 and the second discharge gap 40 are selected will be described later.

Note that two cells 11 adjacent in the y-direction
The gap 35 between the cells 12 (cells 13 and 14), that is, the gap between the Y electrode legs Y3 and Y'1 is set to about 120 μm. According to the present PDP having the above configuration, power supply is started to the display electrodes 22 and 23 during the discharge period, and a pulse is applied. At this time, surface discharge (start discharge) is started in the first discharge gap 39, and the first discharge gap 39 is about 20 μm.
, The discharge starting voltage is lower than before. Thereby, power consumption at the time of starting discharge of the PDP is effectively suppressed.

When the start discharge is started, the discharge is performed not only in the first discharge gap 39 but also in the second discharge gap 40, and good luminous efficiency can be obtained by sufficient sustain discharge. As described above, the PDP of the present embodiment uses each discharge gap existing between the plurality of electrode limbs X1,... According to the start discharge and the sustain discharge. Also, in the dielectric layer 24, for example, corresponding to the cell 11, one more Y electrode limb Y1, Y2, Y3 is provided than the X electrode limb X1, X2, so that the X electrode limb X2, etc. The risk of generating crosstalk with the Y electrode limb Y1 ′ of the adjacent cell 12 is suppressed. As a result, the X electrode 22 which also functions as a scanning electrode is protected by the Y electrode 23.

Such a PDP is manufactured as follows. (Method of Manufacturing PDP of First Embodiment) i. Preparation of Front Panel 20 On a surface of a front panel glass 21 made of soda lime glass having a thickness of about 2 mm, a conductive material containing silver as a main component is used. Electrode limb X1, X2 or Y1, Y2, Y3
Of the display electrodes 22 and 23 having a fork shape.
For the display electrodes 22 and 23, known methods such as a screen printing method and a photo etching method can be applied.

Next, a lead-based glass paste is coated on the entire surface of the front panel glass 21 to a thickness of about 20 to 30 μm on the display electrodes 22 and 23, and baked to form the dielectric layer 24. Next, a protective layer 25 made of magnesium oxide (MgO) having a thickness of about 1 μm is formed on the surface of the dielectric layer 24 by vapor deposition or CVD (chemical vapor deposition).

Thus, the front panel 20 is completed. ii. Manufacture of back panel 26 On a surface of a back panel glass 27 made of soda lime glass having a thickness of about 2 mm, a conductive material containing silver as a main component is applied in stripes at regular intervals by a screen printing method. An address electrode 28 having a thickness of about 5 μm is formed.
Here, in order to manufacture a high-definition television of a 40-inch class, two adjacent address electrodes 2 are used.
8 is set to about 0.2 mm or less.

Subsequently, a lead-based glass paste is applied to a thickness of about 20 to 30 μm over the entire surface of the back panel glass 27 on which the address electrodes 28 are formed, and is baked to form a dielectric film 29. Next, a partition 30 having a height of about 100 μm is formed on the dielectric film 29 between the two adjacent address electrodes 28 using the same lead-based glass material as the dielectric film 29. The partition walls 30 can be formed by, for example, repeatedly screen-printing a paste containing the above-described glass material and then firing the paste.

After the partition 30 is formed, the red (R) phosphor, the green (G) phosphor, and the blue (B) phosphor are formed on the wall surface of the partition 30 and the surface of the dielectric film 29 exposed between the partitions. A fluorescent ink containing any of the bodies is applied, and dried and fired to form phosphor layers 31, 32, and 33, respectively. Here, examples of phosphor materials generally used for PDPs are listed below.

Red phosphor; (Y _x Gd _1-x ) BO ₃ : Eu ³⁺ green phosphor; Zn ₂ SiO ₄ : Mn blue phosphor; BaMgAl ₁₀ O ₁₇ : Eu ³⁺ (or B
aMgAl ₁₄ O ₂₃ : Eu ³⁺ ) Thus, the back panel 26 is completed.

Although the front panel glass 21 and the back panel glass 27 are made of soda lime glass, this is an example of a material, and other materials may be used. Further, the dielectric layer 24 and the protective layer 25 are not limited to the above materials, and the materials may be appropriately changed. Similarly, for the display electrodes 22 and 23, for example, a material can be selected to be a transparent electrode having good transparency. Such selection of each material may be similarly performed in each embodiment as far as possible.

Iii. Completion of PDP The produced front panel 20 and back panel 26 are bonded together using sealing glass. Thereafter, the inside of the discharge space was degassed to a high vacuum (8 × 10 ⁻⁷ Torr), and Ne-Xe was added thereto at a predetermined pressure (here, 2000 Torr).
The PDP is completed by filling a discharge gas having a composition of (5%).

The discharge gas is also He gas
-Xe system or He-Ne-Xe system can be used. Further, this PDP manufacturing method is different in the shape and structure of the display electrode formed for each PDP in each embodiment, but is generally common in other parts. Therefore, a method of manufacturing a PDP in each of the following embodiments will mainly be described with respect to features relating to display electrodes.

In this embodiment, the Y electrode limb is (n +
1) As an example of a combination of a book and X electrode limbs, cell 1
1,..., Three Y electrode limbs and two X electrode limbs are shown, but n is an arbitrary natural number, for example, two Y electrode limbs and X electrode limb. The limb may be a single combination. The present invention is not limited to this, and the first and second discharge gaps can be secured for each of the cells 11,..., And further, an electrode that does not cause crosstalk between the cell 11 and the adjacent cell 12 Any combination of the number of limbs may be used. For this purpose, it seems desirable that the number of X electrodes and the number of Y electrodes corresponding to one of the cells 11,... Be different.

In the embodiment, the gap 35 between the cells 11 and 12 adjacent in the y direction is set to about 120 μm. However, the electrode limb is increased toward the boundary between the cells 11 and 12, thereby improving the luminous efficiency. You may do so. in this case,
If cross talk does not occur in the cells 11 and 12 by causing electrode limbs having different polarities to be adjacent to each other, for example, the cell 1
The gap 35 between 1 and 12 may be eliminated.

Further, in this embodiment, an example is shown in which the widths of the X electrode limb and the Y electrode limb are similarly made.
In order for the electrode limb to function well as a scanning electrode, the X
The electrode limb may be made as wide as about 1.5 to 3 times the width of the Y electrode limb, so that sufficient capacitance for address discharge may be ensured. AC surface discharge type P
In the DP, power is generally supplied by applying several to several tens of pulses to the display electrode during the discharge period.
In the present embodiment, the electrode limb Y2 or Y′2 of the Y electrode 23 is further replaced with the other electrode limb Y1, Y3 or Y′1,
An electrode independent of Y'3 is used to supply power to the electrode limb (here, Y2 or Y'2) directly involved in the starting discharge, for example, only in the first few pulses of the discharge period, and thereafter, the electrode involved in the sustain discharge. Power may be supplied only to the limb (here, Y1, Y3 or Y'1, Y'3).
By doing so, discharge is performed in the first discharge gap only at the beginning of the discharge period in which the number of charge particles is small in the discharge space (the amount of priming charged particles is small), and no discharge is performed in the first discharge gap thereafter. Efficiency is improved.

As a measure for further improving the light emission luminance, for example, as shown in the plan view of FIG.
Of the electrode limb Y3,
If the discharge area of Y′1 is increased, a sustain discharge having a larger scale can be obtained. In this case, the Y electrode limb Y3,
If a black layer made of a metal material such as black aluminum or black zinc is formed on the surface of the front panel glass 20 of Y′1 on the side thereof, the display electrodes 22 and 23 reflect external light and float white on the screen. Is prevented, and the contrast at the time of driving the PDP is improved. Note that such a black layer can be applied to a display electrode of a PDP according to another embodiment.

<Second Embodiment> FIG. 4 is a partial cross-sectional perspective view of an AC surface discharge type PDP according to a second embodiment. This PDP has almost the same structure as the PDP of the first embodiment as a whole, but has a structure in which the display electrodes 22 and 23 are stacked in the thickness direction (z direction) of the PDP instead of having electrode limbs. Have.

That is, the PD around the display electrode shown in FIG.
As shown in the P sectional view, the X electrode 22 and the Y electrode 23
It has a two-stage structure consisting of first layers 221 and 231 and second layers 222 and 232 along the direction. Further, the width of the second layers 222 and 232 is smaller than that of the first layers 221 and 231, thereby securing a discharge gap having a plurality of gap values between the display electrodes 22 and 23. That is, in the present embodiment, the first discharge gap 43 exists between the first Y electrode layer 231 and the first X electrode layer 221, and the second discharge gap 43 exists between the second Y electrode layer 232 and the second X electrode layer 222. There are 44.

The specific size of each of the display electrodes 22 and 23 is such that the first layers 221 and 231 have a width of about 40 to 80 μm and a thickness of about 300 nm or less.
32 is about 20 μm in width and about 500 nm to 5000 nm in thickness
(5 μm). In the figure, the first discharge gap 4
3. The second discharge gap 44 is set to about 20 μm and about 40 μm, respectively, as in the first embodiment. Such display electrodes 22 and 23 can be formed by forming each layer by repeating a screen printing method a plurality of times and then firing.

According to the present PDP having the above configuration, power supply to the display electrodes 22 and 23 is started during the discharge period,
When a pulse is applied, a start discharge is first performed by a discharge starting voltage in the first discharge gap 43, and then a second discharge gap 4
At 4, a sustain discharge is performed with a sustain voltage. This PDP
However, the same effects as in the first embodiment can be obtained by the respective voltage values. However, in the present embodiment, the first discharge gap 43 is provided between the pair of display electrodes 22 and 23.
And the second discharge gap 44 exists,
There is a feature that the space for the existence of the cells 3 and 44 can be relatively suppressed, and it is easy to realize even a fine cell.

In this embodiment, the second layers 222, 2
32 is wider than the first layers 221 and 231. However, the first layer and the second layer are formed to have the same width, and the layers are stacked with a certain amount of displacement, thereby forming the first discharge gap and the first discharge gap. Two discharge gaps may be provided. Further, the display electrode is not limited to such a two-stage structure.
23, a discharge gap having a plurality of gap values including a first discharge gap and a second discharge gap in the z-direction may be used. As shown, the X electrode 22 has a simple single-layer structure, and only the Y electrode 23 has a laminated structure including the first layer 233 and the second layer 234, so that the first discharge gap 45 and the second discharge gap 46 are X-shaped. It may exist between the electrode 22 and the Y electrode 23.

As shown in the cross-sectional view of the PDP around the display electrode in FIG. 7, for example, the first layer 221 and the second layer 222 of the X electrode 22 may be separated in the z direction. Then, the second layer 234 of the Y electrode 23 and the second layer 222 of the X electrode 22 become a display electrode with the second discharge gap 48 interposed therebetween due to the dielectric layer 24 therebetween. In this case, the capacitance around the X electrode 22 increases, so that the X electrode 22 can be favorably operated. One of the first discharge gaps 47 is formed by the first layer 22.
1 and 233 are secured.

Further, in addition to the two-stage structure described above, the display electrodes 22 and 23 may have an X-electrode 22 and a Y-electrode 23 as shown in FIG.
3, 224 or 235, 236, respectively, with a triangular cross-section, each facing slope 223, 235
May be made to coincide with the first discharge gap 49, and the apex between the X electrode 22 and the Y electrode 23 may be made to coincide with the second discharge gap 50. In this case, the first discharge gap 49
Many discharge gaps related to sustain discharges other than the above can be made to exist, and discharge efficiency is improved. Such a display electrode also
It can be formed by repeating the screen printing many times, laminating, and firing.

As shown in the cross-sectional view of the PDP in FIG. 9, the opposing slopes 223 and 235 are curved surfaces 225 and 23, respectively.
It may be 7. Thereby, while the first discharge gap 53 is secured, the value of the discharge gap related to the sustain discharge below the second discharge gap 52 increases, so that the start discharge and the sustain discharge can be performed more effectively. Become. When it is difficult to manufacture the display electrodes 22 and 23 having the triangular cross-section as described above, first, as shown in a PDP cross-sectional view of FIG. By cutting some of the corners of the display electrodes 22 and 23, cut surfaces 227 and 239 are provided respectively. In this case, the cut surfaces 227, 23
The cut amount is adjusted so that the shortest gap 9 and the gap between the opposing surfaces 226 and 238 become the first discharge gap 53 and the longest gap between the cut surfaces 227 and 239 becomes the second discharge gap 54.
The cut surfaces 227 and 239 can be formed by forming the X electrode 22 and the Y electrode 23 and then chamfering by a known over-etching process.

Third Embodiment In the second embodiment, an example is shown in which a gap having a plurality of gap values is provided for a pair of display electrodes in the thickness direction (z direction) of the PDP panel. In the present embodiment, a plurality of discharge gaps including a first discharge gap and a second discharge gap exist along a front panel 20 plane (xy plane) between a pair of display electrodes.

Specifically, as shown in FIG. 11 which is a partial perspective view of the AC surface discharge type PDP according to the third embodiment,
A pair of X electrodes 22 and Y electrodes 23 (each having a width of about 20 μm)
m) is made to have a single layer structure. The display electrodes 22 and 23 have triangular protrusions 228 and 240 in regions corresponding to the insides of the cells 11 and 13 as shown in FIG.
(Having a height of about 10 μm) so as to face each other. A first discharge gap 55 is secured between the tips of the projections 228 and 240, and a second discharge gap 56 is secured between the display electrodes 22 and 23 other than the projections 228 and 240. Note that the projections 228, 240
Is larger than the size of the display electrodes 22 and 23.

According to the present PDP having the above-described configuration, during the discharge period, the power supply to the display electrodes 22 and 23 is started, and when a pulse is applied, first, a start discharge by the discharge start voltage is caused in the first discharge gap 55. Occur. Protrusion 228,
By providing the display electrodes 240 on the display electrodes 22 and 23, the amount of electricity is concentrated on these tips, so that the discharge start voltage is effectively reduced and the start discharge is positively generated. In addition, since the first discharge gap 55 exists at the gap between the tips of the protrusions 228 and 240, other discharge gaps are used for the sustain discharge, and the discharge gap including the second discharge gap 56 has a good size. Sustain discharge is performed.

Furthermore, the present embodiment has an advantage that the display electrode having the projections 228 and 240 can be patterned at a time by, for example, a screen printing method and can be easily manufactured. This is advantageous for cost reduction in manufacturing. In this embodiment, the protrusions 228, 240
Of the pair of display electrodes 22 and 23 is opposed to each other. However, as shown in the plan view of the PDP electrode pattern in FIG. Only (only X electrode 22 in the figure) protrusion 22
9, a first discharge gap 57 is provided between the tip of the protrusion 229 and the display electrode (the Y electrode 23 in the figure), and a second discharge gap 58 is formed between the display electrodes 22 and 23. May be present.

Further, the shape of the projection is not limited to a triangle. For example, as shown in FIG. 14, the projections 241 and 260 having a parabolic outer edge may be used to obtain the first discharge gap 59 and the second discharge gap 60. Further, in the present embodiment, an example has been described in which the tips of the projections are aligned with the positions where the display electrodes 22 and 23 face each other. However, the positions of the tips of the two projections are slightly shifted from each other, and the height of the projections is adjusted to the first height. The first discharge gap may be longer than half of the two discharge gaps (that is, the height of the protrusion is twice as long as the second discharge gap).

Further, the number of protrusions may be increased as appropriate according to the size of the cell, or the shape of only a specific protrusion may be changed. <Embodiment 4> The present PDP has substantially the same structure as that shown in the cross-sectional perspective view of FIG. 11, but as shown in the plan view of the electrode pattern of the PDP of FIG. An X electrode 22 and a Y electrode 23, which are display electrodes, are arranged in parallel and opposed to each other, and are electrically insulated at substantially the center of each of the cells 11 and 13 so as to fit inside each of the cells 11 and 13. Electrode 6 made of conductive material
1 is provided.

FIG. 16 is a sectional view of the present PDP. The display electrodes 22 and 23 are formed to have a thickness of about 5 μm and a width of about 20 μm, and the intermediate electrode 61 has a thickness (z direction) of about 5 μm × width (y direction) of about 2 in the approximate center between the display electrodes 22 and 23.
It is formed in a rectangular parallelepiped shape of 0 μm × length (x direction) of about 20 μm. Accordingly, in the present embodiment, the intermediate electrode 61
621 between the X electrode 22 and the intermediate electrode 6
The sum (10 μm + 10 μm) of the gap 622 with 1 is the first discharge gap 62, and the gap between the pair of display electrodes 22 and 23 is the second discharge gap (about 40 μm) 63. The bottom surface 611 of the intermediate electrode 61 facing the front panel glass 20 is connected to the display electrode 2 facing the intermediate electrode 61.
The height is set substantially the same as the upper surfaces 221 and 231 of the display electrodes 22 and 23 so that the discharge gap between the electrodes 2 and 23 is not interrupted. Such an intermediate electrode 61 can be manufactured by a screen printing method, similarly to the display electrodes 22 and 23.

According to the present PDP having the above configuration, power supply to the display electrodes 22 and 23 is started during the discharge period,
When the pulse is applied, the capacitance near the position where the X electrode 22 and the Y electrode 23 face the intermediate electrode 69 via the dielectric layer 24 relatively increases, and even if the starting voltage is low, the first electrode 22 and the Y electrode 23 have the first capacitance. Discharge easily occurs in the discharge gap 62. When the start discharge is generated in this manner, a sustain discharge is then generated in the second discharge gap 63. At this time, since the discharge is performed over a wide opposing region of the display electrodes 22 and 23, a sustain discharge of a good scale can be performed, which can improve the luminous efficiency of the PDP.

In the present embodiment, the position of the bottom surface 611 of the intermediate electrode 61 is changed to the upper surface 261 of the display electrodes 22 and 23,
The height of the display electrode 242 is adjusted to prevent the second discharge gap 63 from being interrupted by the intermediate electrode 61. For example, as shown in the cross-sectional view of the PDP in FIG. , 23 as long as the thickness of the intermediate electrode 61 can be made sufficiently small to secure the second discharge gap 63.

With respect to the setting of the first discharge gap, the intermediate electrode may be disposed substantially at the center between the pair of display electrodes.
Attention should be paid to the risk that the firing voltage may increase. Furthermore, the shape of the intermediate electrode is not limited to a rectangular parallelepiped as in the present embodiment, but may be, for example, an elliptical body with its major axis direction parallel to the x direction.

The size range of the intermediate electrode is not limited to the size of the embodiment, but it is desirable that the intermediate electrode can be separated from the vicinity of the partition 30 to some extent in order to avoid crosstalk with cells adjacent in the x direction. . <Fifth Embodiment> FIG. 18 is a PDP sectional view around a display electrode according to a fifth embodiment.

The structure of the display electrodes of the present PDP and the arrangement pattern thereof are basically the same as the two-stage structure according to the second embodiment, except that the first layer of the display electrodes is replaced by the second layer. The difference is that it is made of a material having a high resistance value. This makes it difficult for the discharge in the first discharge gap to participate in the sustain discharge after the start discharge, so that the discharge efficiency can be further improved. The details are as described below.

In general, a gas discharge panel such as a PDP is driven by alternately repeating charging and discharging of display electrodes at regular intervals. The time required for charging or discharging the load capacity of the gas discharge panel slightly varies depending on the load capacity of the gas discharge panel and its driving circuit.
It is set to 1 μSec from Sec. However, when the display electrode has a resistance equal to or more than a certain value, the charging time becomes longer, so that it takes time to start discharging, and the time during which discharging is maintained becomes shorter.

FIGS. 19 and 20 show temporal changes in voltage and current when the electric resistance is low (about 10 Ω or less) and when the electric resistance is high (about 120 Ω), respectively. According to these figures, during the charging time (period 1) until the first discharge occurs irrespective of the level of the electric resistance, the phases of the voltage and the current are almost the same, but once the pair of display in the dielectric layer is displayed. When the discharge generated between the electrodes reaches a sustain discharge in the discharge space (referred to as a space discharge in this case), it becomes difficult for the current to rapidly flow when there is an electric resistance. Accordingly, the time required for charging becomes longer, and as a result, the time during which space discharge is maintained becomes shorter than when the electric resistance is low. This is because, in FIG. 20, the phase of the voltage waveform and the current waveform are shifted in the period (period 2) after the start of the space discharge as compared with the period 2 in FIG. 19, and the number of peaks is also reduced. I can see.

Here, if a material having a high resistance value is used in a region where positive discharge is desired only at the start of discharge, and a material having a low resistance value is used in a region where sustain discharge is desired to be continuously performed after the start of discharge, the type of discharge may vary. The discharge area can be changed. The present embodiment utilizes this. The specific configuration of the present embodiment is as follows. Display electrode 2 having a two-stage structure as in the second embodiment
2 and 23, the first layers 261 and 242 of the X electrode 22 and the Y electrode 23 are made of a high resistance material (about several tens kΩ / □) of an oxide conductor mainly composed of Ca and Mg. I have. This makes it possible to generate a start discharge in the first discharge gap 64 only at the beginning of the discharge period. Also, after starting the discharge, the second layer 222 having a low resistance value,
This is positively performed in the second discharge gap 65 between the first and second 232, so that a good sustain discharge can be performed. As described above, in the present embodiment, the sustain discharge in the second discharge gap 65 by the second layers 222 and 232 is much more likely to occur than the start discharge in the first discharge gap 64 by the first layers 261 and 241. ing.

Note that the resistance value can be adjusted by changing the amount of oxygen contained in the oxide conductor.
In addition, as a high resistance material other than the above, ITO having a small thickness can be considered. Further, the above effect can be obtained to some extent at a resistance value of several hundred Ω / □ or more,
A resistance value of several tens kΩ / □ is desirable because a clear effect can be obtained.

As a variation of this embodiment, for example, instead of having the first layer have a high resistance value, FIG.
1, a resistor 243 may be provided between the first layer 231 and the second layer 232 of the Y electrode 23, and the Y electrode 23 may be energized from the second layer 232 side. As yet another variation, the plan view showing the arrangement pattern of the display electrodes in FIG. 22 shows the configuration around the display electrodes 22 and 23 in the third embodiment in detail, and the protrusion 260
Shows a state in which a resistor 262 is inserted in the bottom portion of FIG.
As a variation of the fifth embodiment, the first and second discharge gaps may be made to exist using the protrusions as described above.

<Setting of discharge gap of PDP and composition of discharge gas (filled gas)> As a feature of the present invention, a first discharge gap and a second discharge gap are present between a plurality of display electrodes. Here, prior to manufacturing the PDP of each of the above-described embodiments, a method of specifically determining the values of these discharge gaps will be described. i. Discharge gap and discharge gas composition When considering the discharge gap of multiple display electrodes suitable for each of the start discharge and the sustain discharge, simultaneously consider that the characteristics of the discharge greatly depend on the composition of the discharge gas (filled gas). There is a need to. Therefore, it is desirable to first narrow down the components of the discharge gas to some extent. As an example, here, a general Ne-Xe-based discharge gas is used,
The ratio of Xe in the Ne-Xe-based discharge gas was considered in parallel with the discharge gap.

Regarding the discharge gas and the discharge gap, P is generally determined by the filling gas pressure P (Torr) and the discharge gap d (cm).
It is related to each other as a d product ("Electronic Display Device", Ohmsha, 1984,
See pages 113 to 114). Therefore, this Pd product is calculated as a function of the firing voltage Vf and the discharge efficiency (relative value).
A range in which an appropriate Pd product can be obtained was selected from the characteristics indicated by each function, and thereby the Xe ratio in the discharge gas and the discharge gap were determined.

The specific Pd product was determined by measurement according to the following method. ii. Measurement of Discharge Starting Voltage and Discharge Efficiency for Pd Product In a vacuum chamber, an AC surface discharge type PDP model (the discharge gap between a pair of display electrodes is 40 μm, 60 μm, 90 μm) having the same driving method as the PDP of the present invention. Are mounted, and an aging circuit (applied pulse is set to 20 kHz) from outside the vacuum chamber.
The P model can be driven. Further, a gas cylinder is connected from the outside of the vacuum chamber via a gate valve so that the discharge gas can be sealed in the vacuum chamber at a predetermined pressure at an appropriate time. At the time of measurement, Xe
Were divided into 2%, 5%, and 10%, and a PDP model was prepared in each case, and driven while appropriately changing the sealed gas pressure P (that is, changing the Pd product). Illustration of these experimental devices is omitted.

Subsequently, the timing at which the PDP model started to emit light after the start of driving was detected using a luminance meter, and the applied voltage at that time was recorded as a discharge starting voltage Vf. In this way, a function curve having the discharge starting voltage Vf on the vertical axis and the Pd product on the horizontal axis is produced, and Pasche (Pasche) which is known as a curve showing the relationship between the Pd product and the discharge starting voltage Vf.
n) A curve was obtained.

On the other hand, after the discharge sustaining voltage Vm becomes a state in which the discharge shifts to the sustaining discharge (a state in which the value measured by the luminance meter becomes almost constant), the applied voltage value is gradually lowered to stop the light emission. The value was recorded as the applied voltage value when the test was performed. Then, a relative value of the discharge efficiency is calculated using each of the discharge sustaining voltages Vm, a function curve is created with the relative value of the discharge efficiency on the vertical axis and the Pd product on the horizontal axis, and the relationship between the Pd product and the discharge efficiency is calculated. The obtained curve (discharge efficiency curve) was obtained. The value of each discharge efficiency was calculated from the following equation 1 from the discharge sustaining voltage Vm, the discharge current I, the luminance L, and the light emitting area S. [Equation 1] Discharge efficiency η = π · SL / (Vm · I) The Paschen curve is a downward curve, the discharge efficiency curve is an upward curve, and both curves are the minimum value of the discharge starting voltage in the direction of each curve. It has a peak of Vf _min or the maximum value of discharge efficiency. The value range of the Pd product that is considered to be appropriate in actual production of the PDP is determined by focusing on the value of the Pd product corresponding to each peak. Therefore, how clearly the peak appears in the curve is the first point in determining the Pd product.

It should be noted that the Paschen curve and the discharge efficiency curve having such shapes can be obtained by using a discharge gas other than the Ne—Xe discharge gas. It is also known that, for a multi-component discharge gas such as a Ne—Xe-based gas, both of the above curves can be obtained, for example, for the partial pressure (P _Xe ) of the Xe gas in the discharge gas. iii. Measurement Results FIG. 23 shows the Paschen curves obtained as described above, and FIG. 24 shows the discharge efficiency curves. In each figure,
(A), (b) and (c) each have an Xe ratio of 5%, 1
0% and 2%.

When the Xe ratio is 5%, its Paschen curve diagram (a) shows that the Pd product near Vf _min is 1-5.
Includes relatively sharp curves in the range of (Torr · cm)
It can be seen that a clear peak further falls in the range of 2 to 4 (Torr · cm). The range of the Pd product corresponding to the peak can be further narrowed down to 2.5 to 3.5 (Torr · cm). Moreover, the discharge start voltage Vf near the peak is lower than 200V.
Such a curve can be seen almost similarly in the Paschen curve diagram (b) in the case where the Xe ratio is 10%, but in this case, the range of the Pd product corresponding to the peak is a slightly smaller value (1 to 1).
About 3 Torr · cm).

On the other hand, FIG. 2 shows a discharge efficiency curve when the Xe ratio is 5%.
In FIG. 4A, the Pd product corresponding to the periphery including the peak of the curve is in the range of 4 to 12 (Torr · cm), and the clear peak is further in the range of 6 to 10 (Torr · cm). . Looking only at the position very close to the peak,
The range falls within the range of 7 to 9 (Torr · cm).
Further, the curve has a value of approximately 2.8 or more from a wide range of Pd products of 4 to 12 (Torr · cm), and its maximum value reaches about 3. On the other hand, when the Xe ratio is 10
%, The peak at this time reaches a maximum of about 3.5 in a range of approximately 3 to 10 (Torr · cm) according to the discharge efficiency curve diagram 24 (b). P corresponding to this peak
The d product seems to be in the range of about 4 to 7 (Torr · cm).

As described above, when the Xe ratio is 5% or 10%
In the case of, since each peak of the Paschen curve and the discharge efficiency curve can be relatively clearly confirmed, it is possible to easily select the range of each Pd product for both the discharge starting voltage Vf and the discharge efficiency, Its specific value can be determined. Further, in the case of these Xe ratios, since the values of the Pd products corresponding to the respective peaks of the Paschen curve and the discharge efficiency curve are not so large, for example, for securing the first discharge gap and the second discharge gap, respectively. Space can be reduced.

When the Xe ratio is 2%, as shown in the Paschen curve diagram (c), the shape of the peripheral curve including the peak is within the range of about 4 to 6 (Torr · cm) of the Pd product. Draw a gentle curve. Therefore, it is difficult to determine a clear peak position for the discharge starting voltage Vf.
Further, since the entire curve curves in the range of the Pd product having a relatively large value, the value of the Pd product corresponding to the peak also increases. On the other hand, also in the discharge efficiency curve diagram 24 (c), the value of the Pd product corresponding to the peak position is larger than the case where the Xe ratio is 5% or 10% (almost 12%).
-20 (Torr · cm)).

As described above, when the value of the product of the discharge starting voltage Vf and each Pd for the discharge efficiency is greatly increased, the discharge gas pressure P and the discharge gap d also need to be kept considerably large. This hinders the fabrication of fine cell PDPs and is considered less desirable. iv. Determination of discharge gap and Xe ratio As described above, Ne-Xe that can be used favorably
Xe ratio in the composition of the system discharge gas is 5%
Alternatively, a case of 10% is considered appropriate. Then, either the case where the Xe ratio is 5% or the case where the Xe ratio is 10% is selected.
Many e-Xe-based discharge gases have an Xe ratio of about 5%. Therefore, in this case, P
It is considered that a discharge gas having an Xe ratio of 5% is suitable for producing DP.

That is, as described above, the discharge starting voltage V
P suitable for the minimum value Vf _{min of} f (and the first discharge gap)
According to the range corresponding to the vicinity of the peak of the Paschen curve, the d product is as follows in the order of the desired range. Pd product; 2.5 to 3.5, 2 to 4, 1 to 5 (Torr.
cm) Instead of this Pd product, the partial pressure P of the Xe gas in the discharge gas
Expressed as a P _Xed product by _Xe , the order of the desired range is approximately as follows. Here, it is assumed that P = 20P _Xe .

[0074] P _Xe d product; 0.12～0.18,0.10
-0.20, 0.05-0.25 (Torr · cm) The range of the Pd product suitable for the discharge efficiency (and the second discharge gap) is according to the range corresponding to the vicinity of the peak of the discharge efficiency curve. , In the order of the desired range:

Pd product; 7-9, 6-10, 4-12 (T
Expressed in orr · cm) P _Xe d product of this Pd product, substantially as follows in order of desired range. P _Xe d product; 0.35～0.45,0.30～0.50,0.
20 to 0.60 (Torr · cm) As a result of considering the range of these Pd product values, in the embodiment of the present invention, the value of the Pd product suitable for the discharge starting voltage is set to 4,
The value of the Pd product suitable for the discharge efficiency was set to 8 respectively. Specifically, the discharge gas pressure P is set to 2000 Torr.
On the other hand, the first discharge gap is set to 20 μm (20 × 1
0 ⁻⁴ cm) and the second discharge gap is 40 μm (40 × 10 ⁻⁴ c).
m).

It should be noted that Xe
It was found from another experiment that in the case of containing, the two curves showed the same tendency as the Ne—Xe-based discharge gas.

[0077]

As described above, according to the present invention, in a gas discharge panel such as a PDP, luminous efficiency is improved by securing a discharge gap in accordance with each of a start discharge and a sustain discharge in a display electrode. And good discharge efficiency can be obtained.

[Brief description of the drawings]

FIG. 1 is a partial cross-sectional perspective view of a PDP according to a first embodiment.

FIG. 2 is a plan view showing an arrangement pattern of display electrodes according to the first embodiment.

FIG. 3 is a plan view showing an arrangement pattern of display electrodes in a variation of the first embodiment.

FIG. 4 is a partial sectional perspective view of a PDP in a second embodiment.

FIG. 5 is a PDP cross-sectional view around a display electrode in the second embodiment.

FIG. 6 is a PDP sectional view around a display electrode in a variation of the second embodiment.

FIG. 7 is a PDP sectional view around a display electrode in a variation of the second embodiment.

FIG. 8 is a PDP sectional view around a display electrode in a variation of the second embodiment.

FIG. 9 is a PDP sectional view around a display electrode in a variation of the second embodiment.

FIG. 10 is a PDP sectional view around a display electrode in a variation of the second embodiment.

FIG. 11 is a partial cross-sectional perspective view of a PDP according to a third embodiment.

FIG. 12 is a plan view showing an arrangement pattern of display electrodes according to a third embodiment.

FIG. 13 is a plan view showing an arrangement pattern of display electrodes in a variation of the third embodiment.

FIG. 14 is a plan view showing an arrangement pattern of display electrodes in a variation of the third embodiment.

FIG. 15 is a plan view showing an arrangement pattern of display electrodes according to a fourth embodiment.

FIG. 16 is a PDP around a display electrode in Embodiment 4.
It is sectional drawing.

FIG. 17 is a PDP sectional view around a display electrode in a variation of the fourth embodiment.

FIG. 18 is a PDP around a display electrode in the fifth embodiment.
It is sectional drawing.

FIG. 19 is a graph showing a change with time of an applied current and an applied voltage when a resistance value of a display electrode is low.

FIG. 20 is a graph showing a change with time in applied current and applied voltage when the resistance value of the display electrode is high.

FIG. 21 is a PDP sectional view around a display electrode in a variation of the fifth embodiment.

FIG. 22 is a plan view showing an arrangement pattern of display electrodes in a variation of the fifth embodiment.

FIG. 23 is a graph showing a characteristic (Paschen curve) of a discharge starting voltage with respect to a Pd product. FIG. 23A is a Paschen curve when the Xe ratio in the discharge gas is 5%. FIG. 23B shows that the Xe ratio in the discharge gas is 10%.
It is a Paschen curve in the case of. FIG. 23C is a Paschen curve when the Xe ratio in the discharge gas is 2%.

FIG. 24 is a graph showing a characteristic (discharge efficiency curve) of discharge efficiency with respect to a Pd product. FIG. 24A is a discharge efficiency curve when the Xe ratio in the discharge gas is 5%. FIG.
4 (b) is a discharge efficiency curve when the Xe ratio in the discharge gas is 10%. FIG. 24C is a discharge efficiency curve when the Xe ratio in the discharge gas is 2%.

[Explanation of symbols]

11, 12, 13, 14 cell 20 front panel 22 display electrode (X electrode) 23 display electrode (Y electrode) 24 dielectric layer 28 address electrode 39, 41, 43, 45, 47, 49, 51, 53, 5
5, 57, 59, 62, 64, 66, 71 First discharge gap 40, 42, 44, 46, 48, 50, 52, 54, 5,
6, 58, 60, 63, 65, 67, 72 Second discharge gap

 ──────────────────────────────────────────────────の Continuing on the front page (72) Yoshiki Sasaki 1006 Kadoma Kadoma, Osaka Prefecture Inside Matsushita Electric Industrial Co., Ltd. (72) Masatoshi Kudo 1006 Kadoma Kadoma Kadoma City, Osaka Matsushita Electric Industrial Co., Ltd. (72) Inventor Masaki Aoki 1006 Kazuma Kadoma, Osaka Pref. Matsushita Electric Industrial Co., Ltd. (72) Inventor Hidetaka Higashino 1006 Odaka Kazuma Kadoma, Osaka Pref. Matsushita Electric Industrial Co., Ltd. Matsushita Electric Industrial Co., Ltd.

Claims (43)

[Claims] A plurality of cells filled with a discharge gas are arranged in a matrix between a pair of plates provided to face each other, and a pair of display electrodes are provided on a surface of the plate facing the plurality of cells. In a gas discharge panel that is disposed extending in the row direction in a state of straddling, a first discharge gap and a second discharge gap wider than the first discharge gap between the pair of display electrodes. A gas discharge panel having a discharge gap. 2. When the discharge gas pressure is P and the discharge gap is d, the first discharge gap is defined by a Paschen curve indicating the relationship between the Pd product and the starting discharge voltage, at or near the local minimum of the discharge starting voltage. Wherein the second discharge gap includes a gap corresponding to a maximum discharge efficiency in a discharge efficiency curve showing a relationship between a Pd product and a discharge efficiency. 2. The gas discharge panel according to 1. 3. One of the display electrodes branches into first and second electrode limbs, the other display electrode is inserted between the electrode limbs, and a gap between the first electrode limb and the other display electrode is provided. Is a first discharge gap, and a gap between a second electrode limb and the other display electrode is a second discharge gap.
A gas discharge panel as described. 4. The gas discharge panel according to claim 3, wherein outer edges of the first and second electrode limbs extend to near a boundary between cells adjacent in the column direction. 5. A pair of display electrodes are both branched into electrode limbs, an electrode limb of the other display electrode is inserted between the first and second electrode limbs of one display electrode, and The gap between one electrode limb and the electrode limb of the other display electrode is a first discharge gap, and the gap between the second electrode limb of one display electrode and the electrode limb of the other display electrode is a second discharge gap. 3. The gas discharge panel according to claim 2, wherein the gas discharge panel is a gap. 6. An outer edge of an electrode limb closest to a cell adjacent in a column direction in the arranged electrode limbs extends to a vicinity of a boundary between the adjacent cells. A gas discharge panel as described. 7. The first electrode limb of the one display electrode,
The gas discharge panel according to claim 5, wherein power is supplied through a resistor. 8. A gap between the pair of display electrodes has a plurality of gap values in a direction perpendicular to the plane of the gas discharge panel, and includes a first discharge gap and a second discharge gap in the plurality of gap values. 3. The gas discharge panel according to claim 2, wherein each of the gas discharge panels includes a corresponding gap value. 9. A display device according to claim 1, wherein at least one display electrode of the pair of display electrodes has a side surface facing the other display electrode in a direction perpendicular to the plane of the gas discharge panel. 9. The gas discharge panel according to claim 8, wherein the gas discharge panel is formed in a crab. 10. The display device according to claim 1, wherein at least one of the display electrodes is formed in multiple stages in a direction perpendicular to a plane of the gas discharge panel.
10. The gas discharge panel according to claim 9, further comprising an electrode step for forming a first discharge gap with the other display electrode, wherein the electrode step is formed of a resistor. 11. At least one display electrode comprises a first conductive member and a second conductive member, and the first conductive member and the second conductive member are arranged in a direction perpendicular to a panel plane of the gas discharge panel. Arranged in a state separated from each other, there is a first discharge gap between the other display electrode and the first conductive member,
9. The gas discharge panel according to claim 8, wherein a second discharge gap exists between the other display electrode and the second conductive member. 12. The gas discharge panel according to claim 11, wherein a resistor is provided between the first conductive member and the second conductive member. 13. At least one display electrode of a pair of display electrodes, one or more projections are formed for each cell at an electrode edge end facing the other display electrode, and the projection and the other projection electrode are formed. A gap corresponding to the first discharge gap exists between the display electrodes, and a gap corresponding to the second discharge gap exists between a portion other than the portion where the protrusion is formed and the other display electrode. The gas discharge panel according to claim 2, wherein: 14. The projection according to claim 13, wherein at least a root portion is formed of a resistance material.
A gas discharge panel as described. 15. A plurality of cells filled with a discharge gas are arranged in a matrix between a pair of plates provided to face each other, and a pair of display electrodes are provided on a plurality of cells on opposite surfaces of the plate. In a gas discharge panel that is disposed to extend in the row direction in a straddling state, an intermediate electrode is disposed in a state of being electrically insulated in a gap between the pair of display electrodes, and is provided between the intermediate electrode and the display electrode. A gas discharge panel comprising a first discharge gap and a second discharge gap wider than the first discharge gap between the display electrodes. 16. When the discharge gas pressure is P and the discharge gap is d, the first discharge gap is defined by a Paschen curve indicating the relationship between the Pd product and the start discharge voltage, at or near the minimum discharge start voltage. And wherein the second discharge gap includes a gap corresponding to a maximum discharge efficiency in a discharge efficiency curve indicating a relationship between a Pd product and a discharge efficiency. 16. The gas discharge panel according to 15. 17. The product of the charged gas pressure and the discharge gap is 1 to 5
17. The gas discharge panel according to claim 2, wherein the first discharge gap is set to (Torr.cm). 18. The product of the charged gas pressure and the discharge gap is 2 to 4
17. The gas discharge panel according to claim 2, wherein the first discharge gap is set to (Torr.cm). 19. The product of the charged gas pressure and the discharge gap is 2.5 to
17. The gas discharge panel according to claim 2, wherein the first discharge gap is set to 3.5 (Torr.cm). 20. A sealed gas containing an Xe component, wherein a product of a partial pressure of the Xe gas in the sealed gas pressure and a discharge gap is 0.02 to 0.10.
17. The gas discharge panel according to claim 2, wherein the first discharge gap is set to (Torr.cm). 21. A sealed gas containing an Xe component, wherein a product of a partial pressure of the Xe gas in the sealed gas pressure and a discharge gap is 0.04 to 0.08.
17. The gas discharge panel according to claim 2, wherein the first discharge gap is set to (Torr.cm). 22. A sealed gas containing an Xe component, wherein the product of the partial pressure of the Xe gas in the sealed gas pressure and the discharge gap is 0.05 to 0.07.
17. The gas discharge panel according to claim 2, wherein the first discharge gap is set to (Torr.cm). 23. The product of the charged gas pressure and the discharge gap is 4 to 12 (T
The gas discharge panel according to claim 2 or 16, wherein the second discharge gap is set so as to be orr · cm). 24. The product of the charged gas pressure and the discharge gap is 6 to 10 (T
The gas discharge panel according to claim 2 or 16, wherein the second discharge gap is set so as to be orr · cm). 25. The product of the charged gas pressure and the discharge gap is 7 to 9 (To
17. The gas discharge panel according to claim 2, wherein the second discharge gap is set to be equal to (rr · cm). 26. A sealed gas containing an Xe component, wherein the product of the partial pressure of the Xe gas in the sealed gas pressure and the discharge gap is 0.1 to 0.3.
17. The gas discharge panel according to claim 2, wherein the second discharge gap is set so as to be (Torr.cm). 27. A sealed gas containing a Xe component, wherein the product of the partial pressure of the Xe gas in the sealed gas pressure and the discharge gap is 0.15 to 0.25.
17. The gas discharge panel according to claim 2, wherein the second discharge gap is set so as to be (Torr.cm). 28. A sealed gas containing an Xe component, wherein a product of a partial pressure of the Xe gas in the sealed gas pressure and a discharge gap is 0.16 to 0.20.
17. The gas discharge panel according to claim 2, wherein the second discharge gap is set so as to be (Torr.cm). 29. A plurality of cells filled with a discharge gas are arranged in a matrix between a pair of plates provided to face each other, and first, second, and third cells are formed on opposing surfaces of the plates. In a gas discharge panel in which the display electrodes are arranged in a row direction so as to extend over a plurality of cells, a first discharge gap exists between the first and second display electrodes, and the first and third display electrodes are provided. Where there is a second discharge gap wider than the first discharge gap between the display electrodes, during driving, power is supplied to the first and second display electrodes at the beginning of the discharge sustain period, A gas discharge panel, wherein power is supplied to the first and third display electrodes throughout the discharge sustaining period. 30. Assuming that the discharge gas pressure is P and the discharge gap is d, the first discharge gap is defined by a Paschen curve indicating a relationship between a Pd product and a start discharge voltage, at a minimum or near the minimum discharge start voltage. And wherein the second discharge gap includes a gap corresponding to a maximum discharge efficiency in a discharge efficiency curve indicating a relationship between a Pd product and a discharge efficiency. 30. The gas discharge panel according to 29. 31. The display device according to claim 31, wherein the first, second, and third display electrodes are all branched into a plurality of electrode limbs, and the electrode limbs of each display electrode are arranged so as to be inserted into each other in a fixed arrangement. The gas discharge panel according to claim 30, characterized in that: 32. A front cover plate and a back plate are arranged to face each other, a plurality of cells in which discharge gas is sealed between the two plates are arranged in a matrix, and a pair of cells are provided on one surface of the two plates. In a gas discharge panel in which a display electrode is disposed in a row direction so as to extend over a plurality of cells, and a dielectric layer is disposed on the display electrode, A gas discharge panel comprising two types of discharge gaps, one discharge gap and a second discharge gap wider than the first discharge gap. 33. Assuming that the discharge gas pressure is P and the discharge gap is d, the first discharge gap is defined by a Paschen curve indicating the relationship between the Pd product and the starting discharge voltage, at or near the minimum value of the discharge starting voltage or its vicinity. And wherein the second discharge gap includes a gap corresponding to a maximum discharge efficiency in a discharge efficiency curve indicating a relationship between a Pd product and a discharge efficiency. 33. The gas discharge panel according to 32. 34. One display electrode branches into first and second electrode limbs, the other display electrode is inserted between the electrode limbs, and a gap between the first electrode limb and the other display electrode is provided. 34. The gas discharge panel according to claim 33, further comprising a first discharge gap, and a second discharge gap between a second electrode limb and the other display electrode. 35. A pair of display electrodes are both branched into electrode limbs, an electrode limb of the other display electrode is inserted between the first and second electrode limbs of one display electrode, and The gap between one electrode limb and the electrode limb of the other display electrode is a first discharge gap, and the gap between the second electrode limb of one display electrode and the electrode limb of the other display electrode is a second discharge gap. The gas discharge panel according to claim 33, wherein the gas discharge panel is a gap. 36. A gap between a pair of display electrodes has a plurality of gap values in a direction perpendicular to a plane of the gas discharge panel, and includes a first discharge gap and a second discharge gap in the plurality of gap values. 34. The gas discharge panel according to claim 33, comprising a corresponding gap value. 37. At least one display electrode includes a first conductive member and a second conductive member wider than the first conductive member, wherein the first conductive member and the second conductive member are connected to each other. The second discharge gap is provided between the other display electrode and the first conductive member, and the second display gap is disposed between the other display electrode and the first conductive member in a direction perpendicular to the plane of the gas discharge panel. The gas discharge panel according to claim 33, wherein a first discharge gap exists between the gas discharge panel and the member. 38. A gas discharge panel having a plurality of display electrodes, a first polar electrode and a second polar electrode, which are parallel to each other and form a discharge gap for matrix display, corresponds to one cell for matrix display. A gas discharge panel, wherein the number of first polar electrodes and the number of second polar electrodes are different. 39. Among the plurality of display electrodes corresponding to the one cell, display electrodes having polarities not involved in data writing are arranged at both ends of the cells in the column direction of the matrix. 39. The gas discharge panel according to claim 38. 40. A display electrode disposed at both extreme ends of one cell and a display electrode on an adjacent cell side in the column direction are closely adhered or have a very small gap in parallel with the column direction of the matrix. 40. The arrangement of claim 39, wherein
A gas discharge panel as described. 41. In a gas discharge panel having a plurality of display electrodes of a first polarity electrode and a second polarity electrode which are parallel to each other and form a discharge gap for matrix display, display electrodes of the same polarity are arranged in a column direction of the matrix. A gas discharge panel, which is disposed at both extreme ends of the cell. 42. Among the plurality of display electrodes corresponding to the one cell, display electrodes having polarities not involved in data writing are arranged at both extreme ends of the cells in the column direction of the matrix. 42. The gas discharge panel according to claim 41. 43. A display electrode disposed at both extreme ends of one cell and a display electrode on an adjacent cell side in the column direction are closely attached or very small in parallel to the column direction of the matrix. 43. The arrangement of claim 42, wherein
A gas discharge panel as described.