FR2556113A1 - Transmission panel for a visual display device and method of manufacture - Google Patents

Abstract

A panel for a visual display device is an optical and electrical transmission panel which consists essentially of a plate 5 which is transparent from one face to an opposite face, containing electrically conducting elements 8 distributed in the said plate and each extending from one to the other of the said faces, without electrical contact between them. The plate is formed of optical fibres each oriented from one to the other face and between which the said electrically conducting elements are distributed. It further comprises a network 10 of electrical conductors on one of the faces of the said plate, the density of the electrically conducting elements 8 in the latter being such that there exists at least one such element in electrical contact with the said conductor for each network pitch 10.

Description

TRANSMISSION PANEL FOR DEVICE
VISUALIZATION AND MANUFACTURING METHOD
The present invention relates to the design and production of panels having conductive properties from both an optical and an electrical point of view, which are intended to be used, in particular, for ensuring the transmission of information in display devices.

As will be understood hereinafter, these panels make it possible, in particular, to detect the location of traces shown on an image, more particularly by contact on the displayed image, but-however this application is not limiting although it is especially advantageous.

 According to the invention, an optical and electrical transmission panel, intended in particular to equip display devices, is essentially constituted by an optically transparent plate from one face to an opposite face, containing electrically conductive elements distributed in said plate and each extending from one to the other of said faces, without electrical contact between them.

 In a particular embodiment, generally preferred, the plate is made up of optical fibers which are each oriented from one to the other of the faces and between which said electrically conductive elements are distributed. In such a panel, it is understood that the optical fibers ensure the transmission of a light image from one to the other of the faces of the plate. The panel can therefore advantageously be placed in front of a screen on which an image appears which an observer can examine as it is reformed on the outside of the panel. At the same time, the conductive elements can be used to transmit backwards. of the panel of the information given on the front, in the form of electrical contacts provided from the outside with conductive elements of the panel, possibly by connecting different conductive elements of the same panel to each other.

 The location of such contact points on the image often constitutes particularly interesting information, which can advantageously be obtained by using a particular embodiment of the panel according to the invention, in which this panel comprises a network of electrical conductors produced or attached to one of the faces of said plate, the density of the electrically conductive elements in the latter being such that there is at least one such element in electrical contact with said conductors for each pitch of the network.

Such a network can be designed and arranged in any known manner in neighboring techniques in which conductive networks are used in connection with location information, the conductors being regularly arranged along coordinate axes and in association with electrical means. processing to identify the position of contact points between 'es ~ conductors by their coordinates along these axes-.
We will now describe in more detail a particular embodiment of the invention which will make it easier to understand its essential characteristics and advantages, it being understood however that this embodiment is chosen by way of example and that it is not in no way limiting. Its description is illustrated by the appended drawings in which - FIG. 1 schematically illustrates a panel according to the invention in its application in combination with a display device - FIG. 2 shows a view in partial section of this panel - The Figure 3 illustrates in more detail an embodiment of such a panel made from optical fibers.

- Figure 4 illustrates a variant of the embodiment of Figure 3.

- Figure 5 shows a display device according to the invention incorporating a transmission panel as above.

 We see in Figure 1 a display device which is shown in the particular case in the form of a cathode ray tube 1, terminated by a screen 2. We know that in such a device, the displacement of the deflection plates of the cathode beam , under the control of a video signal from an electronic assembly 3, makes it possible to produce on the screen 2, a bright image traced by the beam.

 A panel according to the invention is arranged outside the cathode ray tube 1, just in front of the screen 2. This panel 4 essentially consists of a plate 5, optically transparent, through which an observer can examine the image formed on screen 2.

In general, any transparent material may be suitable for this purpose, whether it is in particular a more or less traditional mineral glass, or an organic glass, that is to say a material transparent plastic. In the particular case of the figure, the plate 5 is limited by two opposite faces, namely an anterior face 6 and a posterior face 7, which are both plane and parallel to each other. However, this form is in no way limiting. One could just as easily provide, for example, that the rear face follows the convex shape of the screen 2.

 In the panel 4, as illustrated in FIG. 2, the plate 5 is crossed by electrically conductive elements 8 which are flush with the two faces 6 and 7 individually. These elements are illustrated in the form of strands of metal wire, distributed throughout the plate 5, the transparent mass of which is electrically insulating against them.

The distribution can be random or regular, depending on the manufacturing method used. The density of these strands as a whole is relatively low, at least low enough so that in practice the individual wires do not touch each other and that, on the other hand, the mass of the plate retains its transparency function despite their presence optical.

 On its rear face 6, the plate 5 carries a network of electrical conductors, which can be seen in FIG. 2, the tabs 9, making it possible to ensure their electrical connection with the outside, and more particularly here with the electronic assembly. 3. This network 10 can advantageously be formed, directly on the plate 5, by the usual techniques of printed circuits. In the case shown, it is a network of orthogonal conductors, comprising a frame 11 of conductors parallel to each other and a channel 12 of conductors parallel to each other and perpendicular to the previous ones. Each conductor extends without interruption from one edge of the plate 5 to the opposite edge, being connected on each edge to one of the lugs 9. On the other hand, the conductors are contactless within the network, which is why they are separated by an insulating layer at the location of the nodes where a conductor of the frame crosses a conductor of the chain.

The techniques for producing such networks in printed circuits are known per se.

 The electronic assembly 3 is designed and constructed, also in itself known, for processing the electrical signals coming from the network 10 in order to deduce therefrom location information, defining the coordinates of a point activated on this network. Such activation can be caused by any electrical contact provided on the front face of the plate 5, with the conductive elements.

 For example, if the front face of the plate 5 is touched with the finger or a conductive stylus of sufficiently large section, the electrical contact is established between juxtaposed strands of the conductive elements. The electrical connection is then also established between conductors of the network 10 which are in contact respectively with these strands and which are normally isolated from one another. The panel according to the invention therefore makes it possible to detect the position of the place touched with the finger for example and to use the corresponding location information by the electronic assembly 3.

 It will be noted that the same panel can just as easily be used in the opposite direction, for retransmitting on the front face of the plate, in electrical form, information provided by the electronic assembly 3 via the conductive network 10.

 An optical and electrical transmission panel such as that which has just been described can be produced in a particularly simple manner from a mass of transparent, insulating material, into which the conductive elements are introduced.

It is possible, for example, to drill bores through the plate, preferably perpendicular to its faces, in order to place the conductive elements therein, or to drown the conductive elements in an organic resin during molding,
However, to be particularly simple, the previous embodiment will not always be - the best suited for particular applications. It is more often preferred to constitute the transparent mass of the plate 5 from optical fibers as illustrated in FIG. 3. This represents a detail of the plate seen in section and considerably enlarged. We see optical fibers distributed in a hexagonal network. The individual hexagonal shape of the fibers comes from the manufacturing method, taking into account the pressing directions applied during compaction, as will be understood below.

 It will be noted here that the manufacture of such agglomerates of optical fibers is in itself known.

There are even commercially available transparent plates made up of optical fibers and designated by the English term "face-plates". Compared to them, the panel plate according to the invention is essentially distinguished by the additional presence of electrical conductors through the plate.

 According to a conventional manufacturing method in the field of optical fibers, the assembly is therefore obtained by spinning fibers individually constituted by a core 21 and an envelope 22 made of different vitreous materials, that of the envelope having an index of lower refraction, and by compacting individual fibers. Hot compaction allows the fibers to be bonded together by sintering the glassy material of the envelopes. Optionally, the connection between the fibers can also be ensured by an additional intermediate vitreous phase. If the bond is obtained essentially by heating without significant pressure, the fibers retain their circular shape.

If on the other hand, without adding significant proportions of intermediate vitreous phase, a pressure is applied along the three axes of a hexagon, the hexagonal sections of FIG. 3 are obtained.

 The conductive elements are incorporated into the material of the plate 5 during its manufacture. In the case of Figure 3, each conductive element consists of an optical fiber 23 of a particular type. In addition to the vitreous materials of neighboring fibers, it comprises a conductive coating 24 formed on the core of the fiber. This conception is of course only an example. Such a conductive coating can also be formed on the outside of the fiber by a conductive enamel. The advantage is that the fiber constituting a conductive element according to the invention exhibits the same behavior as the optical fibers which surround it during the spinning and compacting operations. In particular, conductive enamels made up of the same composition can be used. base as the vitreous material of the envelopes of the fibers, added with a significant proportion of a metal such as silver. But we will also be able to obtain equivalent results by constituting the conductive elements of any suitable electrically conductive material, most often metallic, insofar as their presence at the desired density does not unduly affect transparency.

 FIG. 3 also illustrates a particularly advantageous distribution of the conductive elements in all of the fibers. The entire plate is made by agglomeration of clusters of seven fibers each, a central fiber constituting the conductive element and six exclusively transparent fibers surrounding it.

 FIG. 4 illustrates in a variant the section of a portion of plate as it would be obtained from optical fibers and conductive elements individually made up of metal wires of section significantly smaller than the fibers. These wires 25 are each housed in the center of a group of three optical fibers 26 of circular section.

 We have just described embodiments of the plate 5 where the conductive elements are regularly distributed in the middle of the optical fibers.

In other variants, it could also be a random distribution. But it should be noted that in the case of a regular distribution, there is an advantage in having the conductors of the network 10 in connection with this distribution. Thus, for a distribution of the conductive elements according to a triangular mesh or hexagonal mesh network, es
conductors of the network 10 will no longer be oriented in two perpendicular directions as illustrated in FIG. 2, but in two directions at 60 degrees from each other; let-x-and Y in figure 3.

The electronic assembly 3 can easily be designed to transform into rectangular coordinates the
location information obtained from plate 5 - according to the corresponding inclined retentions.

In the foregoing description, it did not seem necessary to give detailed figures on the dimensions of the various constituent elements in relation to each other. We can however cite the following example:
Optical fibers -: diameter 100 microns before compaction Conductive coating: 5 to 10 microns thick Density of the conductive elements: 1 fiber out of 6
Fiber density ---; after compaction: 200 per mm plate thickness: 3 mm
Network conductors in 1/3 mm steps
Rather than a metallic coating applied to the fibers rendered electrically conductive, an enamel containing 75% by weight of silver and formed, in the same way, is used to constitute the vitreous material of the envelope of these fibers. enamel composition than for other fibers. On the face of the plate which remains exposed to the outside, the conductive coating thus obtained is protected, in section of the fiber, by a crown of a deposit of corrosion-resistant metal produced by electrolytic means.

 Anyway, a certain number of particularities have been brought out on what can be obtained by means of the panel according to the invention. This has among its advantages, that of allowing a high resolution in the definition of a light image and in that of the electrical contacts by the conducting elements, to avoid the errors of para-lax in the transmission of the light images, possibly be able to ensure vacuum or gas tightness. In electrical transmission, operation by direct contact on the external face of the panel makes it possible to avoid the problems of interference caused by a command by capacitive effect. In optical transmission, moreover, we generally find all the advantages of known optical fiber panels of the "face-plates" type.

 Indeed, we wanted to illustrate only a certain number of possibilities offered by the invention in the use of the panel. It can also be emphasized that the same panel as that described above with a transparent plate made of optical fibers, can be designed to allow an enlargement or a reduction of the light image or to transmit optical or electrical information according to any desired route.

 Furthermore, the display devices comprising such a panel may include a light source of any known type as illustrated above by a cathode ray tube. However, in particular embodiments of the invention, the light source can itself be carried by the panel and produced by suitable layers formed on the rear face.

 The display device shown schematically in Figure 5 illustrates an example, where the light source is of the electroluminescent layer type. The components of a display panel with an electroluminescent layer, which are known in themselves, are then integrated and combined with an embodiment of the panel according to the invention which has already been described, with its localization means.

So, we find on the representation of the
Figure 5, where the layers are shown spaced from each other for convenience of understanding, an electroluminescent layer 31 between two layers of orthogonally crossed conductors. The lower layer is shown at 32, separated by an insulating layer 33 from the electroluminescent layer 31.

Above the latter, the network of conductors directed in a direction perpendicular to those of the layer 32 is also separated from the electroluminescent layer by an insulating layer 34, but it is directly constituted by one of the series of conductors of the network allowing location detection of the top panel. This network comprises the layer of conductors 35 which has just been mentioned and a layer of perpendicular conductors 36, carried by the internal face of the plate 37, the latter corresponding to the plate 5 of FIG. 2.

 All of the constituent layers are enclosed between the plate 37 and a support plate 30. The latter may be made of glass or any other suitable material. On it can be made one or more of the previous layers. It can be chosen, in terms of material and thickness, to take charge of most of the mechanical strength desirable for the assembly.

 For the location of the points touched on the external surface of the plate 37 (which is here the upper face) the electronic assembly 38 uses at 39 the signals coming from the two layers of crossed conductors 35 and 36. The information controlling the formation of an image by excitation of the electroluminescent layer 31, are produced at 40 and transmitted to the two series of conductors 32 and 35. The orders are produced by a programming device as a function of the location information determined at 39. The common layer of conductors 35 also always makes it possible to ensure a precise correspondence between the points touched on the external face of the transmission plate 37 and the points on or off at the level of the electroluminescent device.

 Naturally, the invention is in no way limited by the features which have been specified in the foregoing or by the details of the particular embodiments chosen to illustrate the invention. All kinds of variations can be made to the particular embodiments which have been described by way of example and to their constituent elements without thereby departing from the scope of the invention. The latter thus includes all the means constituting equivalents.

Claims (15)

 1. Optical and electrical transmission panel for display device, characterized in that it essentially consists of a plate (5) transparent from one face to an opposite face, containing electrically conductive elements (8) distributed in said plate and each extending from one to the other of said faces, without electrical contact between them.  2. Panel according to claim I, characterized in that said plate is formed of optical fibers each oriented from one to the other face and between which are distributed said electrically conductive elements.  3. Panel according to claim 2, characterized in that said electrically conductive elements consist of optical fibers having a conductive coating (24).  4. Panel according to claim 2 or 3, characterized in that the optical fibers are agglomerated together by sintering individual fibers.  5. Panel according to any one of claims 2 to 4, characterized in that said plate consists of hexagonal clusters of six insulating optical fibers surrounding a conductive element.  6. Panel according to any one of claims 1 to 5, characterized in that it further comprises a network (10) of electrical conductors on one of the faces of said plate, the density of the electrically conductive elements ( 8) in the latter being such that there is, at least, such an element in electrical contact with; said conductor for each step of the network (10).  7. Panel according to claim 6, characterized in that said network comprises a frame (11) and a chain (12) of conductors in two different directions, isolated from each other at the nodes of the network.  8. Panel according to claim 7, characterized in that said directions are oriented parallel to those of a regular distribution network of the conductive elements (8) in the plate.  9. Display device, characterized in that it comprises a panel according to any one of claims 1 to 8, for the observation of an image on a screen.  10. Device according to claim 9, comprising a panel according to claim 6, 7 or 8, characterized in that it further comprises electrical means connected to the conductors of said network to determine the location of an electrical contact ensured with at least one element or between consecutive elements of said plate, on the face opposite to that which carries said network.  11. Device according to claim 10, characterized in that it comprises a display device with an electroluminescent layer integrated with said panel on the face of the plate carrying said network of conductors.  12. Device according to claim II, characterized in that the display device comprises a layer of control conductors common with said network.  13. A method of producing an optical and electrical transmission panel according to any one of claims 1 to 7, characterized in that said plate is obtained by simultaneous spinning and compacting of the optical fibers with electrically conductive elements distributed randomly or regular among the optical fibers, said plate then being cut along sectional faces of the optical fibers.  14. A method of producing a panel according to any one of claims 1 to 7, characterized in that the conductors consist, by filling with a conductive material, holes previously drilled through a plate of transparent material.  15. A method of producing a panel according to any one of claims 1 to 7, characterized in that said plate is obtained by molding a transparent material, in particular an organic resin, around the tensioned conductive wires, said wires then being cut along the faces of the plate.