JPH09102280A - Face discharge type ac plasma display panel - Google Patents

Abstract

PROBLEM TO BE SOLVED: To reduce the effective area of discharge by replacing a part of a cathode film with a discharge inert film, and to improve contrast by reducing the maintenance discharge currents per pulse and increasing the maintenance discharge currents. SOLUTION: An MgO pattern 4a, which functions as a discharge cathode, is made on a discharge inert film 11. Therefore, the discharge inert film 11 fronts on the discharge space only at the gap section between the MgO patterns 4a, and the MgO pattern 4a is made on the gap inside each pair of maintenance discharge electrodes across a dielectric layer 3 and a discharge inert film 11. Here, in the region where discharge inert material is arranged on the surface, this does not cause discharge easily even by voltage application, and the MgO pattern 4 causes discharge with relatively lower voltage. This way, the maintenance discharge current per pulse is reduced and the maintenance discharge pulses are increased by reducing the effective area of the discharge, whereby contrast is improved, and wrong discharge between adjacent line is prevented.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to power saving and contrast improvement of a surface discharge type AC plasma display panel and suppression of erroneous discharge between adjacent cells.

[0002]

2. Description of the Related Art FIG. 5 is a technical report EID-9 of the Institute of Electrical Communication.
2-86, pp. FIG. 7 is a partial structural diagram of a conventional surface discharge type plasma display panel shown in 7-12 (1993.1). In the figure, 1x and 1y are a pair (X-Y) of sustain discharge electrodes made of a transparent conductive film, 2x and 2y are a pair of bus electrodes for supplying a voltage to the sustain discharge electrodes 1x and 1y, and 3 is a bus electrode. Is a uniform dielectric layer covering 4 and 4 is a uniform MgO vapor deposition film functioning as a discharge cathode, and 5 is a front glass substrate on which 1, 2, 3 and 4 described above are mounted. 6 is an address electrode intersecting the sustain discharge electrode 1 at a right angle,
Reference numeral 7 is a barrier rib (hereinafter referred to as a partition) that partitions each address electrode 6, and 8 _R , 8 _G , and 8 _B are red, green, and blue phosphors formed on the wall surfaces of the address electrode 6 and the partition 7, respectively. Reference numeral 9 is a rear glass substrate on which the above 6, 7 and 8 are mounted. By contacting the top of the barrier rib 7 with the MgO vapor deposition film 4, a discharge space surrounded by the address electrode 6 and the phosphor formed on the wall surface of the barrier rib 7 and the magnesium oxide (hereinafter referred to as MgO) vapor deposition film 4 is formed. Is formed, and the discharge space is Ne.
It is filled with a mixed gas of + Xe.

The drive sequence of the above surface discharge plasma display is roughly as follows. Line-sequential address discharge: The Y-side sustain discharge electrode 1y is line-sequentially scanned, and a signal corresponding to image data is output to the address electrode 6 in synchronization with this, so that 1 is generated between the sustain discharge electrode 1y and the address electrode 6. Mg in the vicinity of the Y electrode 1y of the cell that causes AC discharge twice and emits light in the drive sequence immediately after
Accumulate wall charges on the O surface. XY sustain discharge: sustain discharge electrode 1x,
By applying an AC pulse for sustain discharge at least once during 1y, X- is written in the cell written in the driving sequence.
The sustain discharge between Y is generated by the number of pulses. Full-area write discharge: A bias sufficient to cause X-Y discharge regardless of the presence or absence of wall charge is applied between the sustain discharge electrodes 1x and 1y on the entire surface of the panel. Full erase discharge: Sustain discharge electrodes 1x, 1y on the entire panel
When an erase pulse is applied during this period, wall charges unnecessary for the next drive sequence are erased. Each phosphor 8 _R , 8 _G , 8
_{When B} receives the ultraviolet light emitted during the discharge process, it emits each fluorescent color red, green, and blue. Thus, a desired color image is obtained.

[0004]

Now, the improvement of the contrast on the display will be described as the first problem. The conventional surface discharge type plasma display panel is configured as described above, and only the discharge cells selected in writing (hereinafter, appropriately called cells) emit light in the driving sequence, but unconditionally all cells in the driving sequence. Emits light. Therefore, even in the OFF cell which is not selected, it has some emission intensity due to the discharge of the driving sequence,
This is one of the factors that deteriorate the display contrast. First, since the contrast is the ratio between the white level and the black level, consideration will be given to lowering the black level or raising the white level as a measure for improving the contrast.

As a measure for improving the contrast, in order to lower the black level, it is conceivable to reduce the discharge current for full writing / erasing in the drive sequence as compared with the sustain discharge current in the drive sequence. However, any discharge in the drive sequence is mainly performed between XY, and the voltage applied between the sustain discharge electrodes 1x and 1y is necessarily higher in the drive sequence than in the drive sequence. Therefore, it can be said that this improvement measure is difficult in principle. Next, as another measure for improving the contrast, in order to raise the white level, it is possible to increase the number of sustain discharge pulses in the drive sequence. However, simply increasing the number of pulses causes a new problem that the power consumption of the sustain discharge increases in proportion, and also causes the temperature of the plasma display panel to rise.
Therefore, it is necessary to reduce the cell current flowing in one sustain discharge in inverse proportion to the number of pulses. The most effective cell current reduction method under the conventional panel structure shown in FIG. 5 is to reduce the sustain discharge area by forming the sustain discharge electrodes 1x and 1y in advance to have a narrow electrode width. Unless the electrode widths of the bus electrodes 2x, 2y are also thinned at the same time, the ratio of the shaded portions of the bus electrodes 2x, 2y to the light emitting area increases, and the brightness visually perceived by the viewer of the plasma display decreases. However, since the electrode widths of the bus electrodes 2x and 2y are originally set to a level that does not hinder the pattern formation yield of the electrodes in order to suppress the ratio of the shaded portions, it is necessary to reduce the line width. There is little room. According to the above examination, under the conventional panel structure shown in FIG. 5, it is difficult to take the contrast improvement measure without increasing the power consumption of the sustain discharge.

Next, as a second problem, suppression of erroneous discharge between adjacent cells will be described. The conventional surface discharge type plasma display panel is constructed as described above, and the partition between the adjacent cells is only the partition 7, and the nth sustain discharge electrode pair and the (n + 1) th sustain discharge electrode pair. There is no partition that physically separates the space between and. Therefore, there is a risk that an erroneous discharge may occur in the gap between adjacent sustain discharge electrode pairs (for example, between 1y _n and 1x _{n + 1} ). Regarding the prevention of the erroneous discharge, the gap between the adjacent sustain discharge electrode pairs is set to the internal gap (for example, 1x _n and 1 y) of the sustain discharge electrode pairs.
₍ between _n ) and sufficiently large. That is, the longer the discharge path, the more the address electrode 6
It utilizes the property that discharge is unlikely to occur because it is easily affected by the electric field due to.

Here, the number of pixels is 480 with a diagonal of about 21 inches.
Assuming x640 display panels, an example of each dimension will be described below. Adjacent sustain discharge electrode pair pitch: 0.675 mm Gap between adjacent sustain discharge electrode pairs: 0.22 mm Address electrode 6 pitch: 0.225 mm Sustain discharge electrode pair internal gap: 0.075 mm Bus electrode 2x, 2y width: 0.075 mm Discharge Depth of space (between MgO film 4 and bottom of phosphor 8):
However, there is a limit to widening the gap between the adjacent sustain discharge electrode pairs when the pitch of the adjacent sustain discharge electrode pairs is reduced in order to increase the definition of the plasma display panel. Alternatively, it is conceivable to narrow the width of the sustain discharge electrode pair 1x, 1y, but this is accompanied by the problem of lowering the emission brightness, so excessive thinning is not appropriate. Therefore, for example, if the pitch between adjacent sustain discharge electrodes is 0.3 mm, the dimensional distribution that is reasonable in pattern formation is as follows. Sustain discharge electrode (1x, 1y) width: 0.075 to 0.1 m
m sustain discharge electrode pair internal gap: 0.05 mm bus electrode (2x, 2y) width: 0.05 mm adjacent sustain discharge electrode pair gap: 0.05 to 0.1 mm where the gap between adjacent sustain discharge electrode pairs is 0 Since it is less than 0.1 mm, the erroneous discharge between the adjacent lines described above frequently occurs under this condition. Therefore, there is a limit in advancing high definition only by adjusting the dimensions under the conventional panel structure of FIG.

The present invention has been made to solve the above problems, and an object thereof is to obtain a surface discharge type AC plasma display capable of improving contrast while suppressing an increase in power consumption of sustain discharge. .

Another object of the present invention is to obtain a surface discharge type AC plasma display capable of coping with high definition without causing erroneous discharge between adjacent lines even if the gap between the adjacent sustain discharge electrode pair is narrowed. To do.

[0010]

In order to achieve the above object, the surface discharge type AC plasma display of the invention according to claim 1 is arranged parallel to the inner surface of one of the pair of glass substrates. A plurality of pairs of discharge sustaining electrodes arranged in proximity, a dielectric layer covering the electrode pairs, a cathode film formed on the upper surface of the dielectric layer, and the electrode pairs on the inner surface of the other rear glass substrate. In a surface discharge type AC plasma display panel having barrier ribs partitioning a discharge space in an orthogonal direction and address electrodes arranged between the barrier ribs to selectively emit light in a unit light emitting region, in the discharge space, A part of the cathode film formed on the exposed upper surface of the dielectric layer is replaced with an insulating film made of a discharge inactive material.

Further, the surface discharge type A of the invention according to claim 2
The C-type plasma display includes a plurality of pairs of discharge sustaining electrode pairs arranged in parallel and closely on the inner surface of one front glass substrate of a pair of glass substrates, a dielectric layer covering the electrode pairs, and the dielectric layer. An insulating film made of a discharge inactive material that uniformly covers the upper surface, a cathode film pattern formed on the upper surface of the insulating film, and a discharge space defined in the direction orthogonal to the electrode pair on the inner surface of the other rear glass substrate. A surface discharge type AC plasma display panel having barrier ribs, address electrodes arranged between the barrier ribs to selectively emit light in the unit light emitting regions, and phosphors of a predetermined emission color on the inner wall surface of the discharge space. And forming a cathode film pattern on an insulating film made of a discharge inactive material formed on the upper surface of the dielectric layer exposed to the discharge space to limit a discharge region. .

Further, the surface discharge type A of the invention according to claim 3
The C-type plasma display includes a plurality of pairs of discharge sustaining electrode pairs arranged in parallel and closely on the inner surface of one front glass substrate of a pair of glass substrates, a dielectric layer covering the electrode pairs, and the dielectric layer. A cathode film that uniformly covers the upper surface, an insulating film pattern that is formed on the upper surface of the cathode film and is made of a discharge inert material, and a discharge space is defined on the inner surface of the other rear glass substrate in the direction orthogonal to the electrode pair. A surface discharge type AC plasma display panel having barrier ribs, address electrodes arranged between the barrier ribs to selectively emit light in the unit light emitting regions, and phosphors of a predetermined emission color on the inner wall surface of the discharge space. A discharge region is limited by forming an insulating film pattern made of a discharge inactive material on the cathode film formed on the upper surface of the dielectric layer exposed to the discharge space. To.

Further, the surface discharge type A of the invention according to claim 4
The C-type plasma display is characterized in that the cathode film pattern of the surface discharge type AC plasma display panel panel according to claim 2 is a cathode film pattern formed by a lift-off method.

Further, the surface discharge type A of the invention according to claim 5
In the C type plasma display, the insulating film pattern made of the discharge inactive material of the surface discharge type AC type plasma display panel panel according to claim 3 is an insulating film pattern made of the discharge inactive material formed by a lift-off method. Is characterized by.

Further, the surface discharge type A of the invention according to claim 6
The cathode type pattern formed on the upper surface of the dielectric layer of the surface discharge type AC type plasma display panel according to claim 2 is a sustain discharge electrode pair inner gap. Is a cathode film pattern formed in a strip shape in the upper part of the electrode in the direction of the sustain discharge electrode pair.

The surface discharge type A according to the invention of claim 7
The C-type plasma display is a surface discharge type AC-type plasma display panel according to claim 2, wherein the cathode film pattern formed on the upper surface of the insulating film made of the discharge inactive material on the upper surface of the dielectric layer is formed between the barrier ribs defining the discharge space. Is a strip-shaped cathode film pattern on the upper surface of the insulating film made of the discharge inactive material, or a cathode film pattern formed in a cell shape above the internal gaps of each sustain discharge electrode pair.

Further, the surface discharge type A of the invention according to claim 8
In the C-type plasma display, the insulating film pattern made of a discharge inactive material formed on the upper surface of the cathode film on the upper surface of the dielectric layer of the surface discharge AC-type plasma display panel according to claim 3, is formed between adjacent sustain discharge electrode pairs. It is characterized in that the insulating film pattern is formed in a strip shape in the upper part of the gap in the pair of sustain discharge electrodes.

Further, the surface discharge type A of the invention according to claim 9
In the C type plasma display, the material forming the cathode film of the surface discharge type AC type plasma display panel according to claim 1, 2, or 3 is MgO, and the material forming the insulating film made of a discharge inactive material is Al ₂ It is characterized by being O ₃ or TiO ₂ .

[0019]

BEST MODE FOR CARRYING OUT THE INVENTION Embodiment 1. First Embodiment FIG. 1 is a partial structural diagram of a surface discharge type AC plasma display panel showing a first embodiment of the present invention. In the figure, 11 is a discharge inactive film that uniformly covers the upper surface of the dielectric layer made of a material having a work function higher than that of MgO forming the cathode film, and 4a is a discharge inactive film 11 formed by a lift-off method or the like. It is a MgO pattern formed on the upper surface and functioning as a discharge cathode. Other configurations are the same as the conventional configuration shown in FIG. Discharge inactive film 1
In addition to having a work function higher than that of MgO, the material of No. 1 needs to satisfy the following requirements. (1) Insulating material, (2) Thermal history of post-process (4
Chemically stable at 50 ° C level, (3) Mg
Having thermal expansion coefficient close to O, (4) it is difficult suffer sputtering, taking into account the (to close to the discharge plasma space) these _{requirements, SiO 2, Al 2 O 3} , Ti
Three materials of O ₂ were selected as candidates. Then, under the conventional panel structure of FIG. 5, the function as a discharge inactive film was confirmed at a practical level by substituting the above three materials for the MgO vapor deposition film 4. Various dimensions of the discharge cell of the test sample are described below. Adjacent sustain discharge electrode pair pitch: 0.675 mm Gap between adjacent sustain discharge electrode pairs: 0.22 mm Address 6 electrode pitch: 0.225 mm Sustain discharge electrode pair internal gap: 0.075 mm Bus electrode (2x, 2y) width: 0. 075 mm Depth of discharge space (distance between various discharge inactive films and bottom of phosphor 8): 0.1 mm All discharge inactive films were formed by a vacuum deposition method.
The test results of the discharge inert film including the reference data of MgO are shown below.

[0020]

[Table 1]

As a result of the preliminary test, the SiO ₂ discharge inactive film had a poor adhesion to the MgO film, and was therefore excluded from the candidates for the test. As shown in Table 1, Al ₂ O ₃ and Ti
It has been found that O ₂ requires a voltage higher than the discharge start voltage of MgO just to maintain discharge, and thus can sufficiently function as a discharge inactive film. Thus, the discharge inert film 11 of FIG. 1 showing the first embodiment of the present invention is formed with Al ₂ O 3.
It was decided to apply a vapor deposition film of _{3 or} TiO ₂ . The discharge inactive film 11 itself is a solid vapor deposition film, but since the MgO pattern 4a which functions as a discharge cathode is formed thereon, the discharge inactive film 11 is discharged only in the gap portion between the MgO patterns 4a. It is exposed to space.
Here, the MgO pattern 4a is formed above the respective sustain discharge electrode pair internal gaps with the dielectric layer 3 and the discharge inactive film 11 being separated from each other. Further, the pattern width of the MgO pattern 4a is set to 0.3 mm, and the other dimensions are set to be the same as the above-mentioned test sample of the discharge inactive film.

Even when exposed to the discharge space, in the region where the discharge inactive material is arranged on the surface, discharge does not easily occur even when a voltage is applied. On the other hand, in a region having MgO on its surface, discharge can be generated at a relatively low voltage. Therefore, by setting the applied voltage to a predetermined value, it becomes possible to discharge only the region having MgO on the surface.
By replacing a part of the cathode surface exposed to the discharge space with a discharge inert film without changing the dimensions of the sustain discharge electrodes 1x, 1y and the bus electrodes 2x, 2y, the effective area of discharge is reduced by one pulse. It is possible to improve the contrast while reducing the sustain discharge current per hit, increasing the number of sustain discharge pulses, and suppressing an increase in power consumption of sustain discharge. According to the test results, it was confirmed that the sustain discharge current in the first embodiment is reduced by about 10% as compared with that in the conventional example.

Embodiment 2 FIG. Second Embodiment FIG. 2 is a partial structural view of a surface discharge type AC plasma display panel showing a second embodiment of the present invention. Here, the MgO pattern 4b that functions as a discharge cathode is formed in a strip shape on the upper surface of the discharge inactive film 11 in the discharge space between the partition walls 7.
Other configurations are the same as those in FIG. In the figure, MgO pattern 4
The width of b was 0.1 mm. In the conventional panel structure shown in FIG. 5, the MgO surface region involved in the discharge is determined mainly by the physical barrier ribs of the barrier ribs 7.
It had a width of 15-0.2 mm. According to the structure of the second embodiment, since the MgO pattern width is narrowed to the discharge area of 0.1 mm, the sustain discharge current can be reduced. The effect of making it possible to improve the contrast while suppressing an increase in the power consumption of the sustain discharge is the same as that described in the first embodiment. According to the test results, it was confirmed that the sustain discharge current in the second embodiment was reduced by about 35% as compared with that in the conventional example.

Embodiment 3. Third Embodiment FIG. 3 is a partial structural diagram of a surface discharge type AC plasma display panel showing a third embodiment of the present invention. Here, the MgO pattern 4c which functions as a discharge cathode is arranged in a cell shape above each sustain discharge electrode pair internal gap on the upper surface of the discharge inactive film 11 in the discharge space between the partition walls 7. Is the same as that of FIG. The effect of making it possible to improve the contrast while suppressing an increase in the power consumption of the sustain discharge is the same as that described in the first embodiment. According to the test results, the sustain discharge current when the cell size was designed to be 0.3 mm × 0.09 mm was almost halved compared to the conventional example. As described above, according to the structure of the third embodiment, the sustain discharge current can be freely reduced by the MgO pattern design.

Embodiment 4 Fourth Embodiment FIG. 4 is a partial structural diagram of a surface discharge type AC plasma display panel showing a fourth embodiment of the present invention. In the first, second, and third embodiments described above, the surface of the dielectric layer 3 is uniformly covered with the discharge inactive film 11, and the specific MgO patterns 4a, 4b, and 4c are provided on the upper surfaces thereof.
However, even if the layer structure is changed so that the surface of the dielectric layer 3 is uniformly covered with the MgO vapor deposition film 4 and the discharge inactive film pattern is formed on the upper surface, the discharge inactive film is formed. The sustain discharge current can be freely reduced by designing the film pattern. In the figure, a strip-shaped insulating film pattern 11a made of a discharge inactive material is formed on the upper surface of the cathode layer 4 on the upper surface of the dielectric layer 3 above the gap between adjacent pairs of sustain discharge electrodes. The insulating film pattern 11a is formed by a lift-off method. In the first, second, and third embodiments, the MgO patterns 4a, 4b, and 4c are formed by the lift-off method, but at this time, MgO is vapor-deposited on the resist pattern. Therefore, heating the substrate during the MgO vapor deposition is not appropriate in order to facilitate the resist stripping in the subsequent step. However, from the viewpoint of the life of the cathode, it is considered important to make MgO into a <111> oriented film, and for that purpose, it is appropriate to heat the substrate during MgO vapor deposition. The effect of making it possible to improve the contrast while suppressing an increase in the power consumption of the sustain discharge is the same as that described in the first embodiment. According to the fourth embodiment, Mg
The above resist pattern is not yet formed during O vapor deposition, and the substrate heating is not restricted, so that it is possible to obtain a good quality <111> orientation film.

Embodiment 5 In the fifth embodiment, the following dimensions in FIG. 1 showing the first embodiment are set as follows. Adjacent sustain discharge electrode pair pitch: 0.3 mm Gap between adjacent sustain discharge electrode pairs: 0.05 mm Address electrode 6 pitch: 0.1 mm Sustain discharge electrode pair internal gap: 0.05 mm Bus electrode (2x, 2y) width: 0. 05 mm Depth of discharge space (between various discharge inactive films and bottom of phosphor 8): 0.1 mm Width of MgO pattern 4a: 0.15 mm Gap between adjacent sustain discharge electrodes and sustain discharge electrode in the above setting values The internal gap is the same value. If the electrode dimensions are set similarly in the partial structure diagram of the conventional panel shown in FIG. 5, the probability of erroneous discharge occurrence in the gap between adjacent sustain discharge electrode pairs (for example, between 1y _n and 1x _{n + 1} ) is increased. , Sustain discharge electrode pair internal gap (eg, 1x _n
And 1y _n ), the probability is the same as that of the sustain discharge. However, according to the fifth embodiment, since the discharge inactive material 11 is arranged with a width of 0.15 mm between adjacent lines, the path length of erroneous discharge is 0.15 mm, and the path length of normal sustain discharge is 0.15 mm. The value is three times as large as that of 05 mm, it is possible to eliminate the occurrence of erroneous discharge, and it is possible to deal with higher definition.

[0027]

As described above, according to the first aspect of the present invention, by replacing a part of the cathode film, which functions as the cathode of the discharge exposed to the discharge space, with the discharge inactive film, the discharge can be effectively performed. The area can be reduced to reduce the sustain discharge current per pulse, and the number of sustain discharge pulses can be increased (while suppressing the power consumption of the sustain discharge) to improve the contrast. Even if the gap between the discharge electrode pair is narrowed, erroneous discharge between adjacent lines does not occur, and it is a surface discharge type A that can cope with high definition.

According to the second aspect of the present invention, the discharge region is limited by forming the cathode film pattern on the insulating film made of the discharge inactive material formed on the upper surface of the dielectric layer exposed to the discharge space. By doing so, it is possible to reduce the sustain discharge current per pulse and increase the number of sustain discharge pulses (while suppressing the power consumption of the sustain discharge), and at the same time, to improve the definition, the adjacent sustain discharges can be improved. Even if the gap between the electrode pairs is narrowed, an erroneous discharge between adjacent lines does not occur, and a surface discharge type AC plasma display capable of coping with higher definition can be obtained.

According to the third aspect of the invention, an insulating film pattern made of a discharge inactive material is formed on the cathode film formed on the upper surface of the dielectric layer exposed to the discharge space to form a discharge region. By limiting, the sustain discharge current per pulse can be decreased and the number of sustain discharge pulses can be increased (while suppressing the power consumption of the sustain discharge) to improve the contrast, and for the sake of higher definition, the adjacent sustain Even if the gap between the discharge electrode pairs is narrowed, erroneous discharge between adjacent lines does not occur, and it is a surface discharge AC that can deal with higher definition.
Type plasma display can be obtained.

According to the invention described in claim 4, in addition to the effect of the surface discharge type AC plasma display panel panel described in claim 2, the cathode film pattern is formed by the lift-off method. As a result, it is possible to obtain a surface discharge type AC plasma display in which the discharge region can be accurately limited.

According to the invention of claim 5, in addition to the effect of the surface discharge type AC plasma display panel panel of claim 3, an insulating film pattern made of a discharge inactive material is formed by a lift-off method. With such a configuration, the discharge region can be accurately defined, and a surface discharge AC plasma display having a cathode film orientation advantageous in terms of discharge life can be obtained.

According to the sixth aspect of the present invention, the cathode film pattern formed on the upper surface of the insulating film made of the discharge inactive material formed on the upper surface of the dielectric layer exposed to the discharge space is provided with each sustain discharge electrode. By limiting the discharge region as a cathode film pattern formed in a strip shape in the pair of sustain discharge electrodes in the upper part of the inner gap, the sustain discharge current per pulse is reduced and the number of sustain discharge pulses is increased ( The contrast can be improved (while suppressing the power consumption of sustain discharge), and even if the gap between adjacent sustain discharge electrode pairs is narrowed for higher definition, erroneous discharge between adjacent lines does not occur and high definition is achieved. Discharge AC that can deal with
Type plasma display can be obtained.

According to the seventh aspect of the invention, the discharge space is defined by the cathode film pattern formed on the upper surface of the insulating film made of the discharge inactive material formed on the upper surface of the dielectric layer exposed to the discharge space. The discharge region is defined as a strip-shaped cathode film pattern on the upper surface of the insulating film made of a discharge inactive material between the barrier ribs or as a cathode film pattern formed in a cell shape above each sustain discharge electrode pair internal gap. As a result, the sustain discharge current per pulse can be reduced and the number of sustain discharge pulses can be increased (while suppressing the power consumption of the sustain discharge) to improve the contrast, and for the sake of high definition, the adjacent sustain discharge electrodes can be improved. To obtain a surface discharge type AC plasma display capable of dealing with high definition without causing false discharge between adjacent lines even if the gap between the pair is narrowed. It can be.

Further, according to the invention of claim 8, the insulating film patterns made of the discharge inactive material formed on the upper surface of the dielectric layer exposed on the discharge space and formed on the upper surface of the cathode film are adjacent to each other. By limiting the discharge region as an insulating film pattern formed in a strip shape in the direction of the sustain discharge electrode pair above the gap between the sustain discharge electrode pairs, the sustain discharge current per pulse is reduced and the number of sustain discharge pulses is reduced. Contrast can be improved by increasing the number (while suppressing the power consumption of sustain discharge), and erroneous discharge between adjacent lines does not occur even if the gap between adjacent sustain discharge electrode pairs is narrowed for higher definition, It is possible to obtain a surface discharge type AC plasma display capable of coping with higher definition.

According to the invention of claim 9, in addition to the effect of the surface discharge type AC plasma display panel of claim 1, 2, or 3, the material forming the cathode film is MgO, and The material forming the insulating film made of an active material is Al ₂ O ₃ or TiO ₂ , so that the cathode film required in the manufacturing process and the insulating film made of an inactive material can have an adhesive force. AC plasma display can be obtained.

[Brief description of the drawings]

FIG. 1 is a surface discharge type AC showing first and fifth embodiments of the present invention.
FIG. 3 is a partial structural view of a type plasma display panel.

FIG. 2 is a partial structural diagram of a surface discharge type AC plasma display panel showing a second embodiment of the present invention.

FIG. 3 is a partial structural diagram of a surface discharge type AC plasma display panel showing a third embodiment of the present invention.

FIG. 4 is a partial structural diagram of a surface discharge type AC type plasma display panel showing a fourth embodiment of the present invention.

FIG. 5 is a partial structural view of a conventional surface discharge type AC plasma display panel.

[Explanation of symbols]

1x, 1y A pair of (X-Y) sustain discharge electrodes 2x, 2y A pair of (X-Y) bus electrodes 3 Dielectric layers 4a, 4b, 4c MgO vapor deposition film pattern 5 Front glass substrate 6 Address electrode 7 Partition wall (barrier rib) 8 _R , 8 _G , 8 _B Red, green, blue phosphor 9 Rear glass substrate 11 Discharge inactive film 11a Discharge inactive film pattern

Claims (9)

[Claims] 1. A plurality of pairs of discharge sustaining electrode pairs arranged in parallel and closely on an inner surface of one front glass substrate of a pair of glass substrates, a dielectric layer covering the electrode pairs, and an upper surface of the dielectric layer. To form a cathode film, a partition on the inner surface of the other rear glass substrate that defines a discharge space in the direction orthogonal to the electrode pair, and between the partitions to selectively emit light in the unit light emitting regions. And a part of the cathode film formed on the upper surface of the dielectric layer exposed to the discharge space in the surface discharge type AC plasma display panel having the address electrode of FIG. A surface discharge type AC plasma display panel characterized by: 2. A plurality of pairs of discharge sustaining electrode pairs arranged in parallel and closely on the inner surface of one front glass substrate of the pair of glass substrates, a dielectric layer covering the electrode pairs, and an upper surface of the dielectric layer. An insulating film made of a discharge inert material that uniformly covers the
A cathode film pattern formed on the upper surface of the insulating film, barrier ribs that partition a discharge space in the direction orthogonal to the electrode pairs on the inner surface of the other rear glass substrate, and unit light-emitting regions that are respectively arranged between the barrier ribs and select unit light emitting regions Is a surface discharge type AC plasma display panel having an address electrode for selectively emitting light and a phosphor of a predetermined emission color on the inner wall surface of the discharge space, the dielectric layer upper surface being exposed to the discharge space. A surface discharge type AC plasma display panel, characterized in that a cathode film pattern is formed on an insulating film made of a discharge inactive material to limit a discharge region. 3. A plurality of pairs of discharge sustaining electrode pairs arranged in parallel and closely on the inner surface of one front glass substrate of the pair of glass substrates, a dielectric layer covering the electrode pairs, and an upper surface of the dielectric layer. A cathode film that evenly covers the cathode film, an insulating film pattern formed on the upper surface of the cathode film and made of a discharge inactive material, and a partition wall that defines a discharge space in the direction orthogonal to the electrode pair on the inner surface of the other rear glass substrate. And a surface discharge AC type AC plasma display panel having address electrodes arranged between the barrier ribs to selectively emit light in a unit light emitting region, and a phosphor of a predetermined emission color on the inner wall of the discharge space. A surface discharge characterized in that an insulating film pattern made of a discharge inactive material is formed on the cathode film formed on the upper surface of the dielectric layer exposed to the discharge space to limit the discharge region. AC type plasma display panel. 4. The surface discharge type AC plasma display panel panel according to claim 2, which has a pattern of a cathode film formed by a lift-off method. 5. The surface discharge type AC type plasma display panel according to claim 3, wherein the surface discharge type AC type plasma display panel has a pattern of an insulating film made of a discharge inactive material formed by a lift-off method. 6. A cathode film pattern formed on an upper surface of an insulating film made of a discharge inactive material on an upper surface of a dielectric layer is formed in a band shape in a direction of a sustain discharge electrode pair above an inner gap of each sustain discharge electrode pair. The surface discharge type AC type plasma display panel according to claim 2, which is a cathode film pattern. 7. The cathode film pattern formed on the upper surface of the insulating film made of the discharge inactive material on the upper surface of the dielectric layer is formed in a strip shape on the upper surface of the insulating film made of the discharge inactive material between the partition walls partitioning the discharge space. 3. The surface discharge type AC plasma display panel according to claim 2, wherein the surface discharge type AC type plasma display panel is a formed cathode film pattern or a cathode film pattern formed in a cell shape above each sustain discharge electrode pair internal gap. 8. The insulating film pattern made of a discharge inactive material formed on the upper surface of the cathode film on the upper surface of the dielectric layer is formed in a band shape in the direction of the sustain discharge electrode pair above the gap between the adjacent sustain discharge electrode pairs. 4. The surface discharge type AC type plasma display panel according to claim 3, wherein the surface discharge type AC type plasma display panel is a formed insulating film pattern. 9. The material forming the cathode film is MgO,
The material forming the insulating film made of a discharge inactive material is Al
The surface discharge AC type plasma display panel according to claim 1, 2 or 3, wherein the surface discharge type AC plasma display panel is ₂ O ₃ or TiO ₂ .