FR2548469A1 - Device for connecting and aligning conductors arranged in ribbons - Google Patents

Abstract

The invention relates to a device for connecting and aligning a bundle of ribbon conductors 24 with electrodes 21 carried by a substrate 20. The object of the invention is to arrange, on the device, alignment test tracks 28, 30, 47, the alignment being achieved when there is electrical continuity between the various test tracks. The invention applies particularly to the connection of electrodes carried by the plates (strips) of a display screen having matrixed access to electronic control circuits.

Description

CONNECTION AND ALIGNMENT DEVICE
CONDUCTORS PROVIDED IN TABLECLOTH
The invention relates to a device for connecting and aligning a bundle of stranded wires with the corresponding conductive tracks carried by a substrate.

The invention applies more particularly to liquid crystal display devices with screen with matrix access. Such screens include conductive tracks placed horizontally called rows and conductive tracks placed vertically called columns. The number of intersection points between the rows and the columns determines the maximum resolution of the image that can be obtained. The constant increase in this resolution leads to an ever-increasing number of rows and columns for the same screen area. To fix an order of magnitude, the conductive tracks can have a width of 250 m and be separated by a distance of the same order, their thickness being less than 1 m. Display devices with matrix access generally include connected display screens control electronics installed 5L: '. a printed circuit through elastomeric connectors. These allow the realization of conne :: - ions at steps much lower than those made by mechanical systems
The connection between the conductive tracks carried by a substrate and a bundle of conductive wires arranged in a sheet or other tracks supported by a printed circuit, for example via a connector, poses serious problems when the number of conductors increases and their size decreases. In the case of display screens, the conductive tracks of the screen are connected to their control circuits by means of a connector comprising a bundle of conductors arranged in a sheet on an insulating material. The connection consists in making each track electrically conductor of the screen with the corresponding conductor placed on the printed circuit; a certain pressure, obtained by a spring, ensures the rigidity of the assembly.

 Optical and mechanical processes, long and complicated, must be implemented first to align the conductors of the various elements, then to maintain these alignment conditions during the bringing together and the tightening of these elements. Finally, alignment becomes practically impossible if the conductive tracks are made of transparent material such as, for example, indium oxide.

 In order to overcome these drawbacks, the present invention provides a connection and alignment system which quickly and simply ensures that the conductors of the different elements are placed in a row by electrical detection of the continuity between two corresponding conductors placed on the different elements.

 The invention therefore relates to a device for connecting and aligning at least one layer of conductors with electrodes deposited on a substrate, said conductors having to occupy a determined position with respect to said electrodes, the electrical connections between the conductors and the electrodes being provided by a connector, the device comprising means for detecting the positioning of the electrodes relative to the conductors, characterized in that said detection means comprise at least one test track associated with said conductors and at least one test track associated with said conductors electrodes, said tracks having electrical continuity when said positioning is carried out, this continuity being detected by a detection element.

The invention will be better understood and other advantages will appear from the following description and the appended figures, among which:
- Figure 1 shows a connection system of conductors arranged on two elements, according to the known art;
FIG. 2 represents a connection system according to the invention:
- Figures 3 and 4 show variants of connection systems according to the invention.

 Figure 1 shows a connection system of conductors arranged on two elements, according to the known art. We have chosen to represent the connection system of a glass substrate 1 which can be one of the plates supporting one of the networks of electrodes of a display screen with matrix access. The element 10 symbolizes the rest of the display screen comprising, for example, a layer of liquid crystal inserted between the blade 1 and another blade 11 supporting the other array of electrodes of the screen. Conductors 2 are etched on the substrate 1 on the side of the element 10. They are arranged parallel to each other and are regularly spaced.

In order for an incident light ray to the substrate 1 to be able to access the screen liquid crystal layer, it is necessary that the conductors 2 are transparent. They can consist of a layer of indium oxide. A double-sided printed circuit 3 is placed under the element 10 and supports elements 4 forming part of electronic circuits for controlling the screen.

It is understood that the electrical contacts between the internal face of the printed circuit 3 and the conductors supported by the blade 11 are easily achievable. On the other hand, the connections between the conductors 2 of the substrate 1 and the conductors 5 which correspond to them on the printed circuit must be provided by means of a connector 6. The ends of the conductors 5 are etched at the same pitch as the conductors 2 and are located opposite these conductors. The connector 6 is generally constituted by an elastomer body 7 which is encircled according to its largest dimension of conductive tracks 8 isolated from each other and parallel to the conductors 2 and 5. The space separating the tracks 8 between them is of the same order of magnitude as the width of these tracks. The pitch of the connection tracks is generally chosen to be lower than that of the conductors to be connected. This has several advantages: the positioning of the connector relative to the conductors to be connected does not need to be rigorous and the risks of short circuits between conductors are thus avoided. A second connector 9 playing the same role as the connector G can be provided at the other end of the conductors 2. A slight tightening exerted on the assembly, as indicated by the arrows, ensures the electrical contact of the different parts. The connector bodies being made of elastomer slightly deform under the effect of tightening ensuring the effectiveness of the contact. However, it is imperative to align the conductors of the substrate with those of the printed circuit. This operation is quite delicate, especially if the substrate is not transparent and therefore does not allow visual alignment.

 Figure 2 is an exploded view of a connection system of conductors arranged on several elements, according to the invention. We have chosen to represent, as in FIG. 1, the connection system of a blade supporting one of the networks of electrodes of a display screen with matrix access. It is indeed in this area that the problem of the quality of connection systems arises acutely, especially when the number of electrodes in the networks tends to increase and the dimensions to decrease. Figure 2 is a top view of a blade 20 supporting an array of etched electrodes 21 which are located on the face opposite to that shown in the figure. The electrodes 21 may be reflective or transparent according to the known art of display screens. They are rectilinear and arranged parallel to each other. It is assumed that they must be connected to elements carried by a printed circuit 38 via conductors 24 and 25. This arrangement is particularly sought in the case of smectic liquid crystal screens with matrix access where a heating current must pass through the electrodes of one of the networks of the matrix. The printed circuit 38 comprises a part 22 supporting the conductors 24 and a part 23 supporting the conductors 25. In FIG. 2, the blade 20, the connectors 26 and 27 are shown side by side as well as the parts 22 and 23 of the circuit printed 38 to simplify the drawing and its understanding. In fact, the connectors 26 and 27 are located under the blade and on the parts 22 and 23 so as to ensure the electrical connection between the electrodes 21 and the corresponding conductors 24 and 2, as shown in FIG. 1. The width of the conductors 24 and 25 is substantially equal to the width of the electrodes 21. The pitch of these conductors is equal to the pitch of the electrodes 21. The connection between the electrodes 21 and the conductors 24 and 25 is produced by connectors 26 and 27 for example of the type described above. As mentioned above, the pitch of the tracks carried by the connectors is less than the pitch of the electrodes 21 and of the conductors 24 and 25 in order to ensure safe and effective contacts.

In order to ensure correct relative positioning of the electrodes and the conductors, the invention proposes to etch test tracks on the blade 20 and on the parts 22 and 23 of the printed circuit 38. The test tracks are composed of the conductors 28 and 29 on part 22, conductors 32 and 33 on blade 20 and conductors 30 and 31 on part 23 of printed circuit 38. The average distance separating track 28 (respectively 30) from conductor 24 (respectively 25) closest is equal to the average distance separating the track 32 from the nearest electrode 21. I1 is the same for the test tracks 29, 31 and 33 relative to the electrode and to the closest conductors. All the test tracks being parallel to the conductors 24 and 25 as well as to the electrodes 21, the different elements shown in Figure 2 will be properly assembled when there is electrical continuity between tracks 28, 3C and 32 on the one hand and 29, 31 and 33 on the other. The continuity of the test tracks can be detected by an element indicating the passage of an electric current. To this end, a power source 34 in series with a lamp 35 (or a vibrator) connected in series with the tracks 23, 30 and 32 can perform this function. Likewise the power source 36 and the element 37 confirm the continuity of the test tracks 29, 31 and 33.

 One can note which theoretically it is enough of only one set of tracks test tracks (28, 30 and 32) to ensure the assembly of the various elements.

 However, it should be avoided that the electrical continuity between the tracks 28 and 30 is not ensured by one of the electrodes 21. This can be achieved by two sets of tracks I test, each set preferably being placed on each side of the electrode group 21. With such an arrangement, the assembly will be correctly performed if electrical continuity is detected at the same time for its two sets of test tracks. tAnother provision can also be implemented: one can do ex. so that the distance separating the test tracks from the nearest electrode 21 is clearly greater than the pitch of these electrodes in order to avoid any possible error.

 To allow more precise alignment t of the electrodes 32 with the corresponding conductors 24 and 25, the etchings of the test tracks carried by the parts 22 and 23 can be made less wide than the test tracks carried by the blade 20. For example, the .ar? e.ur of tracks 28, 29, 30 and 31 will be half the width of the electrodes 21. This makes it possible to achieve alignment with an accuracy at least equal to the half-pitch of the electrodes 21.

 Always polish to allow greater accuracy in alignment, the width of the test pis-es can be significantly less than the width of the electrodes 32. For example, the width of the tracks 28, 30, 32 and 29, 31, 33 can be between five times smaller than the width of the electrodes 21 and of the conductors 24 and 25. In general, the thinner the test tracks relative to the electrodes and conductors, the better the alignment accuracy. But it is also necessary that the width of the test tracks is greater than the pitch of the tracks of the connectors 26 and 27.

 For clarity of description, two power sources 34 and 36 have been shown, although a single source is sufficient as well as a single detection element to detect the continuity of the two sets of test tracks. Such a system is represented in FIG. 3 which takes up the basic arrangement revealed by FIG. 2 and where the same references represent the same elements. The tracks 30 and 31 are short-circuited by a conductor 42 and between the ends A and B of the tracks 28 and 29 there is a power source in series with a detection element 41. When the alignment of the electrodes 21 with the corresponding conductors 24 and 25 will be produced, the source 40 will deliver a current which will pass through the detection element 41 via the tracks 28, 32, 30, 42, 31, 33 and 29 and thanks to the connectors 26 and 27 .

 It is within the scope of the invention to detect the alignment by test tracks having a different configuration. One can for example use a polarizing device constituted by a bar shape given to the test tracks. This is shown in Figure 4 which shows a connection system of conductors of the type described in the previous figures and where the same references designate the same elements. In view of FIG. 4, it can be understood that the power source 45 can only deliver a current which will pass through the detection element 46 (for example a lamp) only when the series circuit formed from the source 45, from the element 46 and test tracks will be closed. To do this, there must be electrical continuity of the tracks 28, 47 and 30 via the connectors 26 and 27. The track width characteristics set out above also apply in the case of FIG. 4. For avoid any risk of misalignment, it is necessary that the offset d of the bar 48 is greater than the width of the electrodes 21.

 The alignment system according to the invention makes it possible to make connections between sets of conductors in a simple and efficient manner. It is particularly recommended when connecting the electrodes of a display screen to their control electronics.

Claims (8)

 1. Device for connecting and aligning at least one ply of  conductors (24, 25) with electrodes (21) deposited on a substrate (20),  said conductors having to occupy a determined position with respect to  to said electrodes, the electrical connections between the conductors and the  electrodes being provided by a connector (26, 27), the device comprises  providing means for detecting the positioning of the electrodes relative to  to conductors, characterized in that said detection means com  take at least one test track (28) associated with said conductors and at least one test track (32) associated with said electrodes, said tracks  having electrical continuity when said positioning is real  read, this continuity being detected by a detection element (41).  2. Connection and alignment device according to claim 1,  characterized in that said connector comprises a body of material  deformable (7) surrounded by conductive tracks (8) whose pitch is less than  not of said electrodes (21) and of said conductors (24, 25).  3. Connection and alignment device according to claim 2,  characterized in that said body is made of elastomer.  4. Connection and alignment device according to any one of  Claims 1 to 3, characterized in that the distance separating the said  test tracks (28, 30, 32) of conductors (24, 25) or electrodes (21)  adjacent is significantly greater than the pitch of said conductors or  of said electrodes.  5. Connection and alignment device according to any one of  Claims 1 to 4, characterized in that test tracks (28 to 33) are  provided on each side of the conductors (24, 25) and electrodes (21) to  connect.  6. Connection and alignment device according to any one of  Claims 1 to 5, characterized in that at least one of the test tracks  has a key.  7. Connection and alignment device according to claim 6,  characterized in that the coding has a heel-shaped (48).  8. Connection and alignment device according to any one of claims 1 to 7, characterized in that the width of the test tracks is less than the width of the conductors and of the electrodes to be connected, and greater than the pitch of the tracks of the connector.