JPH0462741A - Plasma display panel - Google Patents

Abstract

PURPOSE:To increase the contrast on the entire surface of a display surface, and to improve visibility of a display screen by providing a shade for covering and hiding a part of display electrode lead out to the outside of a display region, to the display surface, in an opposed gap of a pair of substrates. CONSTITUTION:A partition 19 made of glass of low melting point colored black is extended not only in a display region E1, but also from the region E1 to the vicinity of a sealing glass 31, so as to provide the partition on a region E2 on the outside of the display region E1. The region E1 is partitioned into a unit emission region (g) correspondent to each phosphor 28, while an address electrode 22 lead out from the region El to the outside is partially covered. An exposed area of the address electrode 22 to a display surface 10 is reduced, and the turning of the light to the region E1 due to irregular reflection at the electrode 22 is reduced thereby. The contrast of the entire display surface is increased, and the visibility of a display screen can be improved.

Description

[Detailed Description of the Invention] [Summary] Regarding a plasma display panel whose display area is a part of the surface of a transparent substrate, the visibility of the display screen is improved by increasing the contrast of the entire display surface including the display area and its surroundings. In order to improve the performance of the display, a light shield is provided in the opposing gap between the pair of substrates to cover at least a portion of the display electrodes led out to the outside of the display area from the display surface.

[Industrial application field]

The present invention relates to a plasma display panel (FDP) in which a part of the surface of a transparent substrate serves as a display area.

FDP is superior in terms of brightness among flat display devices, and its use is expanding to include office automation equipment and the like.

Along with this, it is desired to improve the visibility of display screens.

[Conventional technology]

A dot matrix display type PDP that displays characters and figures by a combination of dots (pixels) that emit light is
A pair of glass substrates are arranged facing each other with a predetermined gap, the periphery of the glass substrates is sealed to form a discharge space, and each discharge cell defined at or near each intersection of the electrode group arranged in a grid is selected. The battery is configured to cause a discharge.

Usually, in an FDP, the display area is provided avoiding the vicinity of the sealing part where discharge becomes unstable due to gas release from the sealant.

Furthermore, the display area must be provided avoiding vent holes for evacuating the discharge space and filling with discharge gas after sealing. In other words, in an FDP, the display area is a portion of the glass substrate surface excluding the peripheral portion thereof.

On the other hand, the electrodes are led out from the display area to the ends of the glass substrate for connection with the drive circuit.

Incidentally, surface discharge type FDPs have been known in the past, in which electrodes for selecting display dots and phosphors that emit light by discharge are provided on the glass substrate on the back side, making it possible to display multiple colors. In a surface discharge type FDP, partition walls are provided that partition the discharge space into unit light emitting areas corresponding to each phosphor.

[Problem to be solved by the invention]

When providing metal electrodes on the glass substrate on the display surface side, a thin film method is used that allows the electrode width to be made small in order to suppress a decrease in display brightness as much as possible.

On the other hand, the electrodes provided on the back glass substrate are formed by a thick film method, which is advantageous in terms of manufacturing cost, and are generally made of silver (A
It is formed using a so-called silver paste whose main component is g).

However, the surface of the electrode made of silver paste became white due to oxidation during firing, which was particularly noticeable around the display area.

For this reason, conventional FDPs have a problem in that the overall contrast of the display surface is low and the visibility of the display screen is poor.

In order to solve this problem, it is possible to paint the surface of the glass substrate on the display side with black paint around the display area, but according to this, when installing an exterior cover on the FDP, the aesthetic appearance will be reduced. If the painted area is covered so as not to damage the display area, the size of the window of the exterior cover will be limited to the display area, and the paint film on the exterior surface will easily peel off, and it will also increase the number of man-hours required to manufacture the PDP. It is disadvantageous.

In view of the above-mentioned problems, the present invention aims to improve the visibility of the display screen by increasing the contrast of the entire display surface including the display area and its surroundings.

Moreover, the invention of claim 2 aims to improve the visibility of the display screen without increasing the number of manufacturing steps.

CIII! Means for Solving] In order to solve the above-mentioned problem, the PDP 1 according to the invention of claim 1 has a pair of substrates 11 and 21 as shown in FIG.
A light shielding body 19 is provided in the opposing gap 30 to cover at least a portion of the display electrode 22 led out to the outside of the display area E1 from the display surface 10.

The PDP I according to the invention of claim 2 has a dark partition wall 19 on the substrate 11 on the display surface 10 side for partitioning the display area E1 in the display surface 10, and has display electrodes 22 on at least the substrate 21 on the back side. In the plasma display panel 1, the partition wall 19 is provided extending to an area E2 outside the display area E1.

[For production]

The light shield 19 provided in the opposing gap 30 between the pair of substrates 11.21 covers at least a portion of the display electrode 22 led out to the outside of the display area E1 from the display surface 10.

The dark-colored partition wall 19 extends to a region E2 outside the display region E1, and prevents the display electrode 22 from being exposed to the display surface 10.

〔Example〕

Embodiments of the present invention will be described below with reference to the drawings.

FIG. 1 is a plan view of a PDP 1 according to the present invention, and FIG. 2 is an enlarged plan view of the AA section surrounded by the two-dot chain line in FIG.
FIG. 3 is a sectional view of the cylinder taken along arrows 1--2 in FIG. 1. FIG. 4 is a sectional view taken along line IV--IV in FIG.

3 and 4, the PDP 1 includes a glass substrate 11 on the display side, a glass substrate 21 on the back side, a glass substrate 1
1, a transparent electrode 12 and a lotus electrode 15 extending in the X (horizontal) direction, a dielectric layer 17 made of low melting point glass, and MgO
A protective film 18 consisting of an X-direction wall 19a and a Y-direction wall 19b.
a lattice-shaped partition 19 consisting of an address electrode 22 and a partition 25 extending in the Y (vertical) direction on the inner surface of the glass substrate 21;
Fluorescent material 28 provided in a predetermined arrangement pattern between each address electrode 22 and partition wall 25, and glass substrate 1
1.21, and the internal discharge space 30 is filled with a mixed gas of neon and xenon, for example. The bus electrode 15 is formed by patterning a metal thin film having a three-layer structure of chromium-copper-chromium, and supplements the conductivity of the transparent electrode 12 made of a NESA film having a high resistance value.

The transparent electrode 12 and the helical electrode 15 are led out to the vicinity of the end of the glass substrate 11, and the address electrode 22 is also led out to the vicinity of the end of the glass substrate 21.
A connection is made to an external drive circuit (not shown).

The partition wall 19 is formed by screen printing a low melting point glass paste mixed with a black pigment and firing the paste.

Further, the address electrodes 22 are formed by a thick film method in which, after forming the partition walls 25, a silver paste is screen printed and baked at a predetermined temperature.

In FIGS. 3 and 4, the upper surface of the glass substrate 11 is the display surface 10, and the area facing each phosphor, that is, the area within the range where the transparent electrode 12 group and the address electrode 22 group are facing, is displayed. This becomes area E1.

In the PDP 1, an address discharge cell for selecting each phosphor 28 is defined at the intersection of the transparent electrode 12 and the address electrode 22, which face each other with a discharge space 30 in between. Main discharge cells for display, which cause selected phosphors 28 to emit light, are defined in opposing parts.

The phosphors are excited and emit light by ultraviolet light generated by surface discharge in the main discharge cell.

As best shown in FIGS. 1 and 2, bulkhead 19
is not only within the display area El (the area surrounded by the dashed line in FIG. 1), but also from the display area E1 to the sealing glass 31.
It extends to the vicinity of the display area E1 and is also provided in an area E2 outside the display area E1, and divides the display area E1 into unit light emitting areas g corresponding to each phosphor 28, and
It partially covers the address electrodes 22 led out from the.

As a result, the exposed area of the address electrodes 22 with respect to the display surface 10 is reduced, and the wraparound of light to the display area E1 due to diffuse reflection on the address electrodes 22 is reduced, and the overall coi-last within the display surface 10 is increased. Display visibility is improved.

According to the embodiment described above, the partition wall 19 that divides the unit light emitting area g is extended to the vicinity of the sealing glass 31, so a special process for providing a light shielding member that hides the address electrode 22 is not necessary. , the visibility of the display can be improved with the same number of manufacturing steps as the conventional method.

According to the embodiment described above, the address electrode 22 is hidden in the area E2 by the partition wall 19 made of low-melting glass colored black, so there is no change over time such as peeling that may occur when applying paint. It is possible to stabilize the discharge characteristics.

In the above-described embodiment, the partition walls 19 with the same pattern were provided in the display area E1 and the area E2, but in the area E2, a black low-melting glass layer was provided over the entire surface instead of in a grid pattern, and the address electrodes 22 were You may choose to hide it completely.

In the above-described embodiment, the color of the partition wall 19 is black, but other dark colors such as deep green, navy blue, brownish brown, etc. may be used.

In the above-described embodiment, the address electrodes 22 are hidden by the partition walls 19 provided on the glass substrate 11 on the display surface side.
A light shielding body may be provided on top of the light source.

〔Effect of the invention〕

According to the present invention, the contrast of the entire display surface including the display area and its surroundings can be increased, and the visibility of the display screen can be improved.

According to the invention of claim 2, the visibility of the display screen can be improved without increasing the number of manufacturing steps.

A plan view showing the big picture, Figure 3 is a sectional view taken along the ■-■ arrow in Figure 1; FIG. 4 is a sectional view taken along the line TV-rV in FIG. 1.

In the figure, 1 is an FDP (plasma display panel), 10 is a display surface, 11.21 is a glass substrate (substrate), 19 is a partition (light shield), 22 is an address electrode (display electrode), El is a display area, E2 is the outer area.

[Brief explanation of drawings]

Claims (2)

[Claims] (1) Opposing gap (30) between a pair of substrates (11) (21)
A plasma characterized in that a light shielding body (19) is provided inside the display area (E1) to cover at least a part of the display electrode (22) led out to the outside of the display area (E1) from the display surface (10). display panel. (2) The display surface (
10) that partitions the display area (E1) in the dark-colored partition wall (1
9), and has a display electrode (22) on at least the back side substrate (21).
), wherein the partition wall (19) extends to an area (E2) outside the display area (E1).