EP1952418A1

EP1952418A1 - Plasma display provided with an array of concentrators

Info

Publication number: EP1952418A1
Application number: EP06807689A
Authority: EP
Inventors: Jean-Philippe Browaeys
Original assignee: Thomson Licensing SAS
Current assignee: THOMSON LICENSING
Priority date: 2005-11-24
Filing date: 2006-10-31
Publication date: 2008-08-06
Also published as: FR2893719A1; TW200721227A; WO2007060081A1; US20100214196A1

Abstract

Display comprising a front plate (5), an array of optical concentrators (7), which operate by reflection, and an array of plasma discharge cells (10) capable of emitting light through the front plate (5) and the concentrators (7), in which each plasma discharge cell (10) is optically coupled to at least one concentrator (7). According to the invention, the concentrators are fastened to one and the same layer (6) which incorporates electromagnetic screening means. The manufacture of the display is thus simplified.

Description

The invention relates to an image display panel comprising a front panel, a network of optical concentrators, and an array of plasma discharge cells able to emit light through said front panel and concentrators of said network, where each plasma discharge cell is optically coupled to at least one concentrator.

Documents EP1526561, JP11-260269 and JP64-010544 describe such a panel, where the concentration of light is ensured, in particular, by lenses; it is therefore concentrators by refraction. Other documents describe the application of reflective concentrators to display panels other than plasma panels, for example US6504981 and US5598281, or to plasma panels, for example US2004 / 108980.

In the document EP1526561, the network of concentrators comprises on the one hand a lens array, on the other hand by a network of diaphragms. The diaphragms are formed by holes in an opaque layer that is also used for contrast enhancement. A disadvantage of this network of concentrators is that it requires an alignment of the holes of the opaque contrast enhancement layer on the optical axis of the lenses, which is a problem during the manufacture of the panel. Another disadvantage lies in the production of two plates (referenced 120 and 123) of different index having complementary curved faces so as to form the lens array; such an embodiment is complex and problematic. Finally, in the case where the maintenance electrodes are positioned between these plates as in FIGS. 3 and 4 of this document, it can be seen that the thickness of the dielectric layer (layer referenced 123) above the maintenance electrodes increases. as one moves away from the landfill initiation edge, resulting in a decrease in electrical capacitance as one moves away from this boot edge, which is contrary to obtaining a good light output of landfills, as taught in WO2004-001786.

An object of the invention is to solve one or more of the aforementioned drawbacks. For this purpose, the subject of the invention is an image display panel comprising a front panel, an optical concentrator network, and an array of plasma discharge cells able to emit light through said front panel and concentrators of said network, wherein each plasma discharge cell is optically coupled to at least one concentrator, and wherein each concentrator proceeds by reflection. The light emission of the panel cells is adapted in a manner known per se to visualize the images. The concentrators of the panel proceed by reflection, unlike the concentrators described in EP1526561 which, being formed of lenses, proceed by refraction. Thanks to the use of concentrators by reflection advantageously avoids the alignment constraints between the lenses and the diaphragms of these lenses, as in EP1526561. Generally, each concentrator includes a light input section, a light output section, and reflective sidewalls that are delimited by the input section and the output section. The sidewalls of each concentrator are reflective for the light that is emitted by a cell and which enters said concentrator through the input section. The rays coming out of each concentrator passed through it either directly without reflection or, on the contrary, after one or more reflections on its side walls.

According to a first variant, the reflective side walls of the concentrators are formed by the interface between two transparent materials of different optical indices, and the shape of these walls and the difference between these optical indices are adapted so that the rays of light emitted which strike said walls from the interior of said concentrator and its input section are reflected by total internal reflection on said walls. According to a second preferred variant, the reflective sidewalls are metallized. Any ray of light emitted striking these walls from inside said concentrator is then reflected on these walls.

Each plasma discharge cell of the panel is optically coupled to at least one concentrator via its input section. All the sidewalls of concentrators are not necessarily reflective; in the case of a panel comprising cells divided into rows and / or columns, each concentrator may be common to all the cells of the same row or column; this concentrator then comprises two opposite reflecting side walls, the other two side walls of this concentrator being offset at the ends of the line or column, and not necessarily reflective; the input section of the concentrator is then optically coupled to a plurality of cells; in this configuration, each cell of the line "sees" therefore only two portions of opposite reflective walls of this concentrator.

Even in the case where each plasma discharge cell is optically coupled to a plurality of concentrators, each concentrator may also be common to several cells. According to the invention, the concentrators are integral with the same layer. The network of concentrators is preferably formed in a sheet of transparent plastic material, for example by thermoforming. Such a process is particularly economical. In order to obtain concentrators whose side walls are reflective, this plastic sheet is metallized, before or after forming. Generally, all input sections of the concentrators are coplanar and form the inner face of the concentrator layer, and all output sections of the concentrators are coplanar and form the outer face of the concentrator layer, facing the observer of the concentrator layers. images to display. According to the invention, the concentrator layer comprises electromagnetic shielding means. In this case, it is the concentrator layer itself that integrates the electromagnetic shielding means; an additional layer is advantageously avoided, especially for the shielding; then simplifies the manufacture of the panel. For example, in the concentrator layer, conductors are integrated between the concentrators. As a conductor, metallized plastic fibers can be used. If the network of concentrators is formed in a transparent plastic sheet, to obtain such shielding means, for example, it is applied in the gaps between the concentrators a conductive plastic resin, for example charged with conductive particles. To further obtain a black contrast enhancement network, the black pigment resin is also loaded. Preferably, the concentrator layer is integrated with the slab before itself, for example analogously to the electromagnetic shielding plastic layer described for example in the document EP0917174: this layer is then bonded to a glass plate which forms walls to the cells of the panel. Another thin glass plate may be deposited on this layer of concentrators, in a manner similar to that described in document EP0908920: the layer of concentrators is then interposed between two glass plates which form part of the front slab; thanks to the integration of the concentrator layer to the front slab, either at the periphery or at the heart of this slab, the distance between these concentrators and the panel cells is reduced, which advantageously reduces any parallax defects between concentrators and panel cells.

Conversely, in a more conventional manner, the front slab can be interposed between the cell network and the concentrator layer. Thus, the concentrator layer is applied to the side of the front slab which is opposite to the one where the cell array is located. Preferably, the reflective sidewalls of the concentrators are metallized. Generally, the metallized layer is such that the reflective sidewalls of the concentrators of the network are electrically connected to each other. Thus, the metallization layer advantageously has a dual function of reflection and electromagnetic shielding.

According to a variant, the panel further comprises an electromagnetic shielding layer which is conductive, which is arranged on said outer face of the concentrator layer, and which comprises holes corresponding to said output sections, for the passage of the light emitted by cells. Such a conductive layer may be obtained by depositing a metal such as aluminum by vacuum evaporation followed by chemical or electrochemical etching to drill holes in the deposit. Such a conductive layer may also serve as a contrast layer capable of absorb the ambient light. Anodizing treatment of the metal layer makes it possible, for example, to obtain such an absorbent layer. Alternatively, all the output sections of the concentrators being coplanar and forming the outer face of the concentrator layer, the panel comprises a contrast layer which is adapted to absorb ambient light, which is disposed on said outer face of the layer. concentrators, and which includes holes corresponding to said output sections, for the passage of light emitted by the cells. This contrast layer thus provides means capable of absorbing ambient light striking the layer of concentrators between said concentrators. Thanks to the concentrators, the contrast layer can be applied over a large area without loss of luminance for the panel, which makes it possible to very substantially improve the contrast in ambient light when viewing images. Preferably, the concentrator layer itself comprises means capable of absorbing the ambient light striking said layer between said concentrators. These light absorbing or light-masking means form what is generally referred to as a black contrast enhancement network in ambient light. Thanks to the concentrators, the surface available for applying this black network without loss of light is much greater than in the prior art, which makes it possible to very substantially improve the contrast in ambient light during the image display. In this case, it is the concentrator layer itself which integrates the means capable of absorbing the ambient light; an additional layer is advantageously avoided, especially for contrast; then simplifies the manufacture of the panel. If the network of concentrators is formed in a transparent plastic sheet, to obtain such absorption means, an absorbent plastic resin, for example filled with black pigment, is applied, for example, in the spaces between the concentrators. Preferably, for each concentrator, the light output section has a surface area smaller than that of the input section. This leads to a concentration effect. Preferably, to obtain the concentration effect, the reflective sidewalls of each concentrator are turned towards its inlet section: this means that the normal at any point of said reflective walls intersects this inlet section passing through the interior. concentrator, or, failing that, is parallel to this input section.

Preferably, the reflective sidewalls of each concentrator have a shape adapted so that any ray of light emitted which penetrates through its inlet section, which is reflected at least once by said sidewalls, and which emerges from said concentrator by its section output at an emission angle greater than the emission angle of this beam at the inlet of the concentrator. This advantageously widens the angular distribution of the emission intensity.

The definition of the shape of the reflective sidewalls includes that of the depth of the concentrators, i.e. the distance between the inlet section and the outlet section of these concentrators; it also includes the shape and the surface of these sections whose edges delimit these walls. Preferably, the reflective sidewalls of each concentrator are two to two symmetrical with respect to a plane oriented in a direction normal to the panel, or the reflective sidewalls have an axis of symmetry.

In the case of a previously mentioned concentrator which is common to all the cells of the same line or of the same column of a panel, this concentrator then comprises two opposite reflective side walls and symmetrical with respect to a plane parallel to said line or column. In the case of rectangular or square entry and exit sections, there is generally a first pair of opposed sidewalls that are symmetrical with respect to a first plane, and a second pair of opposed sidewalls that are symmetrical with respect to a first plane. second plane, perpendicular to the first. According to a first preferred variant, each of the two lines of intersection of the side walls with any cutting plane of this wall which is oriented in a direction normal to the panel and which is perpendicular to said plane of symmetry or, in the case of the axis of symmetry, with any cutting plane passing through said axis of symmetry, forms a line or a parabola whose axis is in said normal direction. Such forms make it possible to optimize the concentration effect. In the case of walls having an axis of symmetry, these reflective side walls then form a cone or a paraboloid.

According to a second preferred variant, each of the two lines of intersection of the side walls with any cutting plane of this wall which is oriented in a direction normal to the panel and which is perpendicular to said plane of symmetry or, in the case of the axis of symmetry, with any cutting plane passing through said axis of symmetry, is inscribed in the surface bounded by:

- On the one hand, a line joining the common point to said intersection line and to said input section and the point common to said intersection line and said output section; on the other hand, a parabola whose axis is approximately parallel to the line joining the latter common point and the point common to the other intersection line, symmetrical with the preceding one, and to said input section, and whose focus coincides approximately with the point common to this other line of intersection and to said exit section. The parables thus defined are called "CPC parabolas". The inscription in this surface here includes the contours of this surface. Preferably, each of the two lines of intersection of said side walls with the cutting plane coincides approximately with this parabola "CPC". Note that the normal to each parabola of type "CPC" in said section plane, at the point of common point E, E 'of this dish and the edge of the input section of said concentrator, is perpendicular to said plane of symmetry or said axis of symmetry.

The side walls then form a "CPC" ("compound parabolic concentrator" in English), which optimizes the concentration efficiency.

The extreme radius of such a concentrator is defined as follows: this extreme radius belongs to said cutting plane; it is defined as the radius which passes on the one hand by the common point at the edge of the inlet section of the concentrator and a first line of intersection of the reflective side walls of this concentrator with this sectional plane, and, secondly, by the point common to the exit section and a second line of intersection of the walls with this cutting plane, which is symmetrical to the first with respect to said plane of symmetry or to said axis of symmetry.

The book entitled "High Collection Nonimaging Optics", WT. Welford & R. Winston, Academy Press, Inc. 1989, precisely defines the shape of the sidewalls of a CPC type concentrator, as well as its depth and the ratio of the surfaces of the inlet and outlet sections; see especially paragraph 3 of chapter 4 of this book. If 2a 'is the distance between two opposite edges of the output section of a concentrator of this type CPC in the previously defined section plane, if 2a is the distance between two opposite edges of the input section still in this plane of cutting, if θ _max is the angle of the extreme radius with respect to the direction normal to the panel, these three parameters are linked by the relation: a = a '/ sin θ _max . The depth L of the concentrator, that is to say the distance between the inlet section and the outlet section, is expressed by the equation: L = (a + a ') cos θ _max . In practice, the rays of the emitted light have an emission limit angle θjj _m , due, in particular, to the index n _d of material of the front slab and the concentrator; we have sin θ _lim = 1 / n _d . Preferably, the geometry of the concentrators is adapted so that θ _max = θ _lim , which makes it possible to limit the losses of light emitted.

Preferably, each plasma discharge cell is optically coupled to a plurality of concentrators, preferably to at least four concentrators. These concentrators are then preferably joined so that their input sections cover the entire emitting surface of the panel. For the manufacture of the panel, it thus advantageously avoids the alignment constraints during the application of the concentrator layer on the front panel. It is thus possible to use layers of concentrators that are less thick. Finally, by increasing the density of concentrators, we achieve a tighter mesh of electromagnetic shielding conductors and therefore a more efficient shielding. Preferably, none of the dimensions of the inlet section of the concentrators is greater than 100 μm, which further improves the electromagnetic shielding.

Generally, the panel according to the invention also comprises a rear slab, which is arranged relative to the front slab so as to arrange between the front and rear slabs a space comprising said plasma discharge cells. The panel preferably comprises a network of barriers delimiting, at least in part, said cells. Preferably, the rear panel comprises an array of addressing electrodes distributed so that each cell is traversed by an addressing electrode. Preferably, the front panel comprises two networks of maintenance electrodes which are distributed so that each cell is traversed by an electrode of each maintenance network. Preferably, each cell is positioned at a crossing of an addressing electrode and an electrode of each maintenance network. Preferably, the walls of the cells, in particular the rear slab and the barriers, are covered with phosphors able to emit visible light under the excitation of the plasma discharges. Within each cell, it is therefore the phosphors that emit light in the direction of the input section of the at least one concentrator to which this cell is optically coupled. The invention will be better understood on reading the description which follows, given by way of nonlimiting example, and with reference to the appended figures in which:

- Figure 1 is a cross-sectional view of a plasma panel according to one embodiment of the invention; FIG. 2 is a top view of the panel of FIG. 1, in which the contrast enhancement network has been made slightly transparent only to reveal the network of the underlying cells;

FIG. 3 is a simplified perspective view of the front slab and its network of concentrators of the panel of FIG. 1; FIG. 4 is a simplified perspective view of the front panel of the panel of FIG. 1, with a variant of the network of concentrators, in which each concentrator is common to a line of cells of the panel;

FIGS. 5 to 8 illustrate variants of the shape of the intersections of a plane of normal cut with the side walls of a concentrator for a panel according to the invention: form "CPC" for FIGS. 5 and 6, truncated "CPC" form for FIG. 7, trapezoidal shape inscribed in a "CPC" shape for Figure 8; FIG. 9 illustrates the layout of a "CPC" type parabola between an input section and an output section of a concentrator according to the variant of FIGS. 5 and 6.

With reference to FIGS. 1 and 2, the panel according to the invention comprises a rear slab 1, a front slab 5 and a network of barriers 3, 31 delimiting between the slabs of the plasma discharge cells 10.

The rear panel 1 comprises an array of X address electrodes distributed so that each cell 10 is traversed by an addressing electrode. This array of addressing electrodes is covered with a dielectric layer 2. The front panel comprises two networks of maintenance electrodes Y _AS , Y _s which are distributed in such a way that each cell 10 is traversed by an electrode of each maintenance network. Each maintenance electrode Y _AS , Y _s comprises a transparent part (in dashed lines in the figure) and an opaque part for distributing the current (solid line in the figure). These networks of maintenance electrodes are covered with a dielectric layer 4 and a very thin layer of secondary electron protection and retro-emission, generally based on magnesia (not referenced in the figure). In this panel, each cell 10 is positioned at a crossing of an address electrode X and an electrode of each maintenance network Y _AS , Y _s . Finally, in each cell, the bottom corresponding to the rear slab and the sides of the barriers corresponding to the side walls are covered with a layer of phosphors, able to emit visible light, here red, green or blue, under the excitation UV radiation from plasma discharges. In FIG. 2, the plasma discharge cells have been distinguished according to their emission color: 10 _R for red, 10 _G for green, and 10 _B for blue; in FIG. 1, the generic reference 10 has been indicated to designate a cell independently of its emission color. One of the faces of the front plate 5 thus supports the maintenance electrode arrays and the dielectric layer 4; according to the invention, the other face of this slab supports a layer 6 concentrators 7 operating by reflection. Each concentrator 7 comprises a square entry section 71 of light, a square exit section 73 of light, and reflective sidewalls 72 which are delimited by the entry section 71 and the exit section 73. In order to to obtain the desired concentration effect, the surface of the output section 73 is smaller than that of the input section 71. In the embodiment described, each cell 10 is optically coupled to a plurality of concentrators 7, via the input section 71 of these concentrators. An advantage to such an arrangement is to reduce the thickness of the layer 6 concentrators and limit the alignment constraints when applying the layer 6 concentrators on the front panel. In the embodiment described, the reflective sidewalls 72 of the concentrators are metallized. Any ray of light emitted striking these walls from inside a concentrator is then reflected on these walls. The rays coming out of each concentrator passed through it either directly without reflection or, on the contrary, after one or more reflections on its side walls. In the embodiment described, the reflective sidewalls 72 of the concentrators are flat and form trapezoids as shown in Figure 3; the reflective side walls of each concentrator are turned towards its inlet section 71: this means that the normal at all points of the reflecting walls 72 intersects this inlet section 71 through the interior of the concentrator.

Since the area of the outlet sections 73 is smaller than that of the inlet sections 71, it is seen that the area available for a contrast layer between these outlet sections 73 is larger than in the prior art, allowing very substantially improve the contrast in ambient light when viewing images by the panel.

Referring to Figure 3, each concentrator 7 of the layer 6 thus forms a truncated cone of square section, which therefore comprises two perpendicular planes of symmetry, which are oriented in a normal direction. With reference to 1, the emitting surface of each cell, which corresponds to the phosphor layer in this cell, is optically coupled with the input section of several concentrators 7 via the transparent front plate 5. In the embodiment described in FIGS. 1 to 3, the gaps between the concentrators are filled with absorbent and conductive resin, so as to form a network 9 serving both to improve the ambient light display contrast and electromagnetic shielding. To manufacture the plasma panel according to the invention, one starts from a plasma panel known from the prior art. In addition, a layer 6 of concentrators is prepared. By compression molding a sheet of transparent thermoformable polymeric material, such as PMMA (polymethylmethacrylate), is formed in this sheet an array of cone trunks, as previously defined. Then the entire sheet is metallized, on the side of the exit sections, masking these exit sections: the reflective walls of the concentrators are thus obtained. In the gaps formed by molding between the concentrators, a resin filled with black pigment and conductive particles is applied, which forms a network of conductors arranged between the concentrators. This provides an absorbent and conductive grating 9 which serves both for contrast enhancement and for electromagnetic shielding. Compared to the prior art, it avoids the application of a specific layer for contrast in ambient light, called "black network". It also avoids the alignment constraints of the holes in this layer as in EP1526561. It should be noted that the metallization itself participates advantageously in the electromagnetic shielding.

The layer 6 of concentrators thus obtained is assembled to the front panel 5 of the plasma panel, with the aid of an adhesive adapted to obtain the optical coupling between the cells of the panel and the inlet sections 71 of the concentrators 7. Plasma panel according to the invention thus obtained provides a network of concentrators without constraint on the thickness of the dielectric layer which covers the maintenance electrodes. We can thus adapt the thickness of this layer according to other constraints, in particular to improve the light output of the discharges.

Panel cells are typically distributed in vertical columns and horizontal lines. All the cells of the same column generally have the same emission color, that is to say the same phosphor. FIG. 4 represents an alternative embodiment of the panel according to the invention which has just been described: each concentrator 7 'of the layer 6' is common to all the cells of the same column and has a single plane of symmetry oriented in a direction perpendicular to the panel and parallel to this column. A display panel is obtained whose angle of view is, thanks to the shape of the concentrators, enlarged here only in a horizontal plane. Preferably, all the cells of the same column are optically coupled to a single concentrator. As the horizontal dimension of the cells is generally much smaller than their vertical dimension, the network of vertical conductors arranged between the cells is sufficient to provide efficient electromagnetic shielding.

According to a preferred variant shown in FIGS. 5 and 6, the reflective sidewalls of the concentrators are of the "CPC" type. more precisely in this case, the intersection of the side walls 72 'of each concentrator 7 "" with a cutting plane perpendicular to any plane of symmetry of the concentrator forms a parabola of CPC type; in the case of concentrators having an axis of symmetry, this cutting plane then passes through this axis; the detail of the characteristics of the plot of a parabola of the CPC type is represented in FIG. 9, where the points E and E 'represent the edges of the inlet section of the concentrator, the points F and F' represent the edges of the section of exit, where the parabola which follows the line of the line F'E 'has focus point F and as axis a line parallel to F'E passing by F, where the parable that follows the line of the line FE has as focal point F 'and as a straight line parallel to FE' passing through F '. One property of such parables "CPC" is that, in the plane of section, the tangent at the point of each parabola which is situated at its intersection with the entrance section, here at point E and E ', is parallel to the direction normal, so here perpendicular to the plans of the input and output sections. The advantage of the dish shape "CPC" of this section of the concentrator is to provide an optimal concentration efficiency for the rays that are emitted by the cells with an emission angle less than or equal to the angle θ _max that an extreme radius EF 'or E'F does with the normal direction to the panel. According to other variants such as that shown in FIG. 7, the reflective lateral walls 72 "of the concentrators have an intermediate shape between the plane shape 72 '" represented in FIG. 8 and the shape "CPC" previously described and represented in FIGS. 5, 6 and 9; more precisely in this case, the intersection of the side walls 72 "of each concentrator 7" with a cutting plane perpendicular to any plane of symmetry of this concentrator (or passing through its axis of symmetry) is inscribed in the limited area by the line EF and the parabola "CPC" passing through the points E and F, and in the surface limited by the line E'F 'and the parabola "CPC" passing through the points E' and F '; these limits, straight and parabolic, are considered as inscribed in these surfaces. Such so-called "intermediate" forms are advantageously simpler to manufacture than "CPC" forms, while providing quite acceptable performance.

The present invention has been described with reference to a plasma panel for coplanar maintenance electrode image display; it is obvious to one skilled in the art that it can apply other plasma panels, without departing from the scope of the claims below.

Claims

An image viewing panel comprising a front plate (5), a reflection-based network of optical concentrators (7), and an array of plasma discharge cells (10) adapted to emit light through said plate. front slab (5) and concentrators (7) of said array (6), wherein each plasma discharge cell (10) is optically coupled to at least one concentrator (7), characterized in that said concentrators are integral with a same layer (6) which comprises electromagnetic shielding means.

2. Panel according to claim 1 characterized in that each concentrator (7) comprises a light input section (71), an output section (73) of light, and reflective side walls (72) which are delimited by said inlet section (71) and said outlet section (73).

3. Panel according to claim 2 characterized in that said reflective side walls concentrators are metallized.

4. Panel according to claim 2 or 3, characterized in that said output section (73) of light has a lower surface than that of said input section.

5. Panel according to claim 4 characterized in that the reflective side walls (72) of each concentrator (7) have a shape adapted so that any ray of light emitted which enters through its input section (71), which is reflected at least once by said side walls (72), and which emerges from said concentrator (7) by its outlet section (73) emerges at an emission angle greater than the emission angle of this ray to the input of this concentrator.

6. Panel according to any one of claims 4 or 5, characterized in that said reflective side walls (72) of each concentrator are two to two symmetrical with respect to a plane oriented in a direction normal to the panel, or in that said reflective sidewalls (72) have an axis of symmetry.

7. Panel according to claim 6 characterized in that each of the two lines of intersection of said side walls with any cutting plane of this wall which is oriented in a direction normal to the panel and which is perpendicular to said plane of symmetry or, in the case of the axis of symmetry, with any cutting plane passing through said axis of symmetry, forms a line or a parabola whose axis is in said normal direction.

8. Panel according to claim 6 characterized in that each of the two lines of intersection of said side walls with any cutting plane of this wall which is oriented in a direction normal to the panel and which is perpendicular to said plane of symmetry or, in the case of the axis of symmetry, with any cutting plane passing through said axis of symmetry, is inscribed in the surface limited by:

on the one hand, a line joining the common point (E; E ') to said intersection line and to said inlet section (71) and the common point (F; F') to said intersection line and at said output section (73);

- on the other hand, a parabola whose axis is approximately parallel to the line joining the latter common point (F; F ') and the common point (E'; E) to the other intersection line, symmetrical to the previous one, and at said input section (71), and whose focus (F ', F) coincides approximately with the point common to this other intersection line and said output section (73).

9. Panel according to any one of the preceding claims characterized in that said layer (6) of concentrators comprises means adapted to absorb the ambient light striking said layer between said concentrators.

10. Panel according to any one of the preceding claims characterized in that said layer (6) of concentrators (7) is integrated with the slab before itself (5).

11. Panel according to any one of the preceding claims characterized in that each plasma discharge cell (10) is optically coupled to a plurality of concentrators (7).