FR2794568A1 - IMPROVEMENT IN MATRIX TYPE PLASMA PANELS - Google Patents

Abstract

The invention concerns a colour plasma panel of the matrix type comprising a first faceplate or front faceplate bearing a first array of electrodes (Y'1, Y'2) and a second faceplate or rear faceplate bearing a second array of electrodes, the first and second faceplates being assembled to produce a matrix of cells defined at the intersection between an electrode of the first array and an electrode of the second array, each cell comprising a discharge zone with resist (Ep1, Ep2, ) on the colour side. The invention is characterised in that each electrode of the first array consists of at least one element (Y'1, Y'2) covering the associated discharge zones, the element being produced in a conductive transparent material and connected to a metal bus (B, B').

Description

The present invention relates to plasma panels, more particularly matrix type color plasma panels.

The plasma panels hereinafter called PAP are screens for viewing images of the flat screen type which operate on the principle of a gas discharge accompanied by an emission of light.

In the case of matrix type PAPs, two crossed electrodes, located on different substrates, are only used to define and control a discharge. Thus, as shown in FIG. 1, a matrix type PAP has two substrates or slabs 2, 3 one of which is a front slab 2, namely the slab which is on the side of the observer, and the other is a rear panel 3, namely that located opposite the observer. The first slab or front slab 2 carries a first network of electrodes generally called "line electrodes" of which only three electrodes Y1, Y2, Y3 are shown. To allow alternative operation, the line electrodes Y1 to Y3 are covered with a layer 5 of a dielectric material. The second slab or rear slab 3 comprises a second network of electrodes generally called "column electrodes" of which only five electrodes X1 to X5 are shown. The two tiles 2, 3 are made of the same material, generally glass. These slabs 2, 3 are assembled together so that the arrays of row electrodes and column electrodes are orthogonal to one another.

On the rear panel 3, the column electrodes X1 to X5 are also covered with a layer 6 of dielectric material. This layer 6 is itself covered with layers forming bands 7, 8, 9 of phosphor materials corresponding, for example, to the colors green, red and blue, respectively. The phosphor strips 7, 8, 9 are arranged parallel to the column electrodes X1 to X5 above the latter from which they are separated by the dielectric layer 6. On the other hand, the rear panel 3 also has parallel barriers 11 to the phosphor strips 7, 8, 9 and arranged between these latter. These barriers, when they have a height corresponding to the distance between the two tiles, separate each point along a line, which avoids crosstalk with the points of the neighboring columns.

The PAP is formed by assembling the front and rear tiles 2, 3 so as to produce a matrix of cells C1 to Cri. The cells are defined at the intersection between a row electrode Y1 to Y3 and a column electrode X1 to X5. Each cell has a discharge zone, the section of which corresponds substantially to so-called useful surfaces formed by the facing surfaces of the two crossed electrodes. For each cell, the discharge in the gas generates electric charges which, in the case of an alternative PAP, accumulate on the dielectric layers 5, 6 with regard to the row electrodes and the column electrodes. In the embodiment shown, this is obtained at the rear panel 3 using savings Ep1 to Epn produced in the phosphor strips 7, 8, 9, substantially in line with the surfaces of the column electrodes X1 to X5 , these savings being intended to reduce the voltages to be applied to the electrodes to obtain a discharge.

In the matrix type PAPs, the addressing voltages and the maintenance voltages are applied between the array of row electrodes and the array of column electrodes. The applied voltages, in this case, are high and require the use of networks of highly conductive electrodes deposited on the two faces and centered on the light emission of the point defined at the crossing of the two electrodes, these networks having to convey the strong currents. of discharge obtained during maintenance. Therefore, the electrodes, especially those made on the front panel, must be both fine to allow good vision but sufficiently conductive to allow maintenance currents to pass without loss. The electrodes are made of an opaque metallic material, the only one capable of carrying the discharge currents obtained. However, with this type of structure, if we want to pass a maximum of the light emitted, it is necessary to minimize the width of the electrodes on the front face, which leads to an increase in the ignition voltages of the cells and the need to turn them on in a very short time.

The object of the present invention is to propose an improvement to plasma panels of the matrix type which makes it possible to remedy the drawbacks mentioned above.

Consequently, the subject of the present invention is a matrix type color plasma panel comprising a first panel or front panel carrying a first network of electrodes and a second panel or rear panel carrying a second network of electrodes, the first and second slabs being assembled to produce a matrix of cells defined at the intersection between an electrode of the first network and an electrode of the second network, each cell comprising a discharge zone with savings on the color side, characterized in that each electrode of the first network is constituted by at least one element covering the associated discharge zones, the element being made of a transparent conductive material and connected to a metal bus.

According to one embodiment, the transparent conductive material is chosen from indium tin oxide (1T0) or tin oxide (Sn02). In addition, the element covering the discharge zones can consist of an electrode whose width is close to that of the emissive zone or the element covering the discharge zones can consist of a patch associated with each discharge zone, the patch having dimensions allowing its connection to the metal bus. The metal bus, the width of which may be very small, has a shape which allows it to conceal the light-emitting zones as a minimum.

Other characteristics and advantages of the present invention will appear on reading the description given below of various embodiments of the present invention, this description being made with reference to the attached drawings in which FIG. 1, already described , is a schematic perspective view of a matrix-type plasma panel according to the prior art, FIG. 2 is a schematic top plan view of a matrix plasma panel implementing a first embodiment of the Figure 3 is a schematic perspective view of another embodiment of a matrix type color plasma panel to which the invention can be applied, Figure 4 is a schematic top plan view showing the first embodiment of the invention implemented with the structure of Figure 3, Figure 5 is a schematic top plan view of another embodiment ion of the invention implemented in a plasma panel of the type of that of Figure 3. To simplify the description in the figures, the same elements have the same references.

We will first describe a first embodiment of the present invention with reference to Figure 2. Figure 2 refers to a matrix type color plasma panel structure as shown in Figure 1, namely a panel in which the luminophores are deposited in the form of bands 7, 8, 9 parallel to the columns and the savings Ep1, Ep2, Ep3 produced in each band are aligned. In this case, three neighboring savings Ep1, Ep2, Ep3 are used located at the same electrode-line Y'1 but in three adjacent phosphor bands 7, 8, 9 to form a trichromatic pixel P. As shown in FIG. 2, the savings Ep1, Ep2, Ep3 of the same pixel P are separated by a distance Px which corresponds substantially to a third of the step Py separating two electrode-lines (Y'1, Y'2).

As shown in Figure 2 and in accordance with the present invention, the line electrodes Y'1, Y'2 are deposited above the savings Ep1, Ep2, Ep3. They are produced by strips of a transparent conductive material which can be chosen from indium tin oxide (1T0) or from tin oxide (Sn02). In this case and as shown in FIG. 2, they have a width greater than the dimensions of the savings Ep1, Ep2, Ep3, covering a large part of the light emitting area. By way of example, for a pitch Py of approximately 900 Nm, the electrodes Y'1, Y'2 have a width of approximately 300 Nm.

As shown in Figure 2, each line electrode Y'1, Y'2 is associated with a conductive bus B, B 'made of a conductive metallic material. This bus typically has, in this case, a width of 60 to 100 Nm. On the other hand, in FIG. 2, there are shown black bands 4 produced between each electrode-line Y'1, Y'2. These black bands are part of a network called black matrix which aims to improve the contrast.

Another type of matrix color plasma panel to which the present invention can now be described with reference to FIG. 3. Referring to FIG. 3, compared with FIG. 1, we find on the rear panel 3, the column electrodes X1 to X5 covered with the dielectric layer 6, itself covered with zones B1, B2, B3 of phosphors . The strip-shaped phosphor zones are arranged substantially parallel to the column electrodes X1 to X5. The rear panel 3 also includes barriers 11 for separating the phosphor zones. As for the embodiment of FIG. 1, the zones 131, B2, B3 of phosphors are equipped with savings Ep1, Ep2, Ep3 and a pixel P have at least two neighboring savings located at the same line electrode in zones 131, B2, B3 of adjacent phosphors. In the embodiment shown, a pixel P is three-color, it therefore comprises three savings which are represented in circular form. It is obvious to those skilled in the art that a pixel can have a different number of savings and that these can have other shapes.

In the embodiment shown in FIG. 3 which relates to a PAP of so-called staggered structure, instead of two neighboring savings Ep1, Ep2 forming part of the same pixel P and located in zones 131, B2 of adjacent phosphors being separated by the pitch Px of the column electrodes X1, X2, the two neighboring savings Ep1, Ep2 are separated by a distance L which is greater than the pitch Px. In the figure, the savings Ep1, Ep2, Ep3 of the same pixel P are arranged in a triangle. This particular structure makes it possible to increase the thickness HO between the two slabs relative to that required when the savings are distant substantially from the pitch Px. This improves the light output of the panel without degrading its contrast. With this structure and as shown in FIG. 4, it is possible to use elements Y "1 a, Y" 1 b, Y "2a and Y'215 made of a transparent conductive material for the line electrodes. These elements have a width 1 making it possible to substantially cover the emissive zones Z1 of the savings Ep1, Ep2, Ep3.

In accordance with the present invention and as shown in FIG. 4, each line electrode Y "1, Y'2 consists of two rectilinear elements Y" 1a and Y "1b or Y" 2a and Y "2b connected to a conductive bus B, B 'which is positioned between the elements. One of the line electrode elements Y "1a or Y" 2b covers the savings Ep3, Ep1 of the red R and blue phosphor bands B while the other element Y "1b or Y "2b covers the savings of the green phosphor strips V. For example, for a pitch Py of 900 Nm, the bus B, B 'has a width of 60 to 100 microns and it is made of a highly conductive material, preferably a metallic material, and the elements Y "1a, Y" 1b, Y "2a, Y" 2b made of transparent conductive material have a width I of approximately 300 Nm.

In FIG. 5, another embodiment of the present invention has been represented, mainly applying to a matrix-colored PAP structure as shown in FIG. 3. In this case, each electrode-line element is constituted by a pad or pad Pa made of a transparent material such as 1'1T0, this pad substantially covering the emissive zone of each savings Ep1, Ep2, Ep3 and being connected to a conductive bus made of a metallic material B, B '.

As shown in FIG. 5, the bus B ′ has a sinusoidal shape, which makes it possible to obscure the light-emitting zone at least. The pellets or pads have a circular shape corresponding substantially to the shape of the emitting area, when the savings Ep1, Ep2 ... have a circular shape. It is obvious that they can have other shapes depending on the shape of the savings Ep1, Ep2, Ep3. The use of Pa pads or pads minimizes the proximity of 1'1T0 with the savings of the neighboring line. Other shapes can also be used for buses B, B ′ such as zigzag shapes or the like making it possible to pass the bus 131, B2 between the spares while minimizing the obscured areas.

By using electrode-line elements made of a transparent conductive material, the following advantages are obtained. Thus, the entire light-emitting area, especially the most intense around the savings, is cleared on the front panel, allowing a significant improvement in luminance and light output. On the other hand, it is possible to significantly lower the voltages required to ignite the cells. In addition, the respective positioning of the front and rear faces of the plasma panel is much less critical, which facilitates the manufacture of the panels.

Claims (8)

<B><U>REVENDICATIONS</U> </B> 1. Matrix-type color plasma panel comprising a first panel or front panel (2) carrying a first array of electrodes (Y'1, Y "1 a, Y" 1 b, Y'2, Y "2a, Y "2b) and one. second slab or rear slab (3) carrying a second array of electrodes, the first and second slabs being assembled to produce a matrix of cells defined at the intersection between an electrode of the first array and an electrode of the second array, each cell comprising a discharge zone (Z1) with savings (Ep1, Ep2 ...) on the color side, characterized in that each electrode of the first network is constituted by at least one element (Y'1, Y "1a, Y" 1b, Y '2, Y "2a, Y" 2b) covering the associated discharge zones, the element being made of a transparent conductive material and connected to a metal bus (B1, B2). 2. Plasma panel according to claim 1, characterized in that the transparent conductive material is chosen from indium tin oxide (1T0) or tin oxide (Sn02). 3. Plasma panel according to claims 1 and 2, characterized in that the element covering the discharge zones consists of an electrode whose width is equal to that of the emissive zone. 4. Plasma panel according to claims 1 and 2, characterized in that the element covering the discharge zones consists of a tablet (Pa) associated with each discharge zone, the tablet having dimensions allowing its connection to the metal bus (B1, B2). 5. Plasma panel according to any one of the preceding claims, characterized in that the metal bus (B1, B2) has a shape allowing it to obscure at least the light-emitting areas. 6. Plasma panel according to any one of the preceding claims, characterized in that the second panel carries phosphor strips (7, 8, 9) arranged parallel to the electrodes of the second network. 7. Plasma panel according to claim 6, characterized in that the phosphor strips are separated by barriers parallel to said strips. 8. Plasma panel according to claim 7, characterized in that the barriers (11) have a height corresponding to the spacing between the two slabs.