FR2465329A1 - Connector for flat cable - has contact forks with slits accommodating conductors when cable is pushed down - Google Patents

Abstract

The connector has an insulating body (2) with chambers (1) containing contacts (5,6). The contacts are identical and each consists of a contact pin at one end and two forks (7,8) with two slits (9,10) at the other end. The planes of the forks are inclined to the straight axis of the insulating body. The flat cable (50) sits in a guide channel (26) in a cable holder (25) and is inclined at the same angle as the planes of the forks. Each slit in the forks accommodates one conductor in the flat cable when the latter is pushed down -- i.e. when the holder is pushed down onto the insulating body.

Description

The present invention, made in the framework of the Division of
Cannon connectors, relates to a connector for ribbon cable and relates, more particularly, to a connector whose pins with insulation displacement contacts are at a different pitch from that of the conductors of the ribbon cable to be connected, the arrangements proposed by the invention allowing to use such a cable directly without making any modification to the connector while retaining the configuration of the ribbon cable.

 In the electronic industry, ribbon cables and connectors with self-stripping contacts are commonly used to make the interconnections. Such cables are in the form of flat tapes formed by the juxtaposition of metal conductors embedded in a flexible insulating material, spaced from one another at a pitch corresponding to that of the insulation-displacement contacts of the connectors. These contacts are often constituted by a fork with two teeth whose spacing. is such that if pressure is exerted on the ribbon cable, each fork pierces the insulation surrounding the conductor which corresponds to it, cuts this insulator and bites the material of the conductor itself thus ensuring good electrical contact and good mechanical behavior of the driver between the teeth of his fork.

The advantages of this type of interconnection are numerous and we can cite, among others with respect to connection methods by welding or coiled connections, the reduction in space and weight necessary for interconnection, the flexibility of use, rapid implementation, easy handling, these advantages obviously resulting in a reduction in costs.

 However, given its electronic applications, interconnection by ribbon cable must be made with elements of small dimensions. Thus the diameter of the conductors of the ribbon cable is of the order of 3/10 of a millimeter, the pitch of these conductors and of the contacts of the connector being, for example, 1.27 mm. It therefore appears essential that the dimensions are sufficiently rigorous, in particular as regards the pitch of the conductors and of the contacts, so that the interconnection takes place without problem and in a reliable manner. This is the reason why specific connectors have been created to respond to the use of ribbon cables.

 However, long before this new type of cable appeared on the market, there were already miniature connectors, generally rectangular in shape, with a single row or double row of pins, the size of which is very close to that of new connectors for ribbon cables.

These connectors, which have been widely proven and have indisputable qualities, are still widely used. In addition, the part of their pins intended for the connection which was intended for welding or to receive a coiled connection can also be in the form of contacts arranged for self-stripping of the conductors to be connected so as to allow the use of ribbon cables.

 However, a problem then arises because the pitch of the connection pins of these rectangular connectors is different from that of the conductors of the ribbon targets; thus, for example, the pitch of the contacts of a row male in this type of connector is 2.76 mm while it is 1.38 nun between the contacts of two different rows in the case of a connector with double row of pins. So we see that, even in the most favorable use hypothesis where we would connect two neighboring conductors of the cable on two neighboring contacts belonging to each of the two rows of pins, there would be a difference of 0.1 min (1.38 min - 1.27 mu). This difference cumulated with the differences also existing for the other conductors of the cable, it appears obvious that direct interconnection by self-stripping contacts and ribbon cable is impossible with miniature rectangular connectors.

However, as it is interesting that these connectors can be easily connected to other connectors having their pins at the pitch of ribbon cables, provision has been made which make it possible to adapt the pitch of the pins of the rectangular connectors and that of the conductors of the targets. in tablecloth. This is how more or less complex devices, manually or automatically, cut the insulation separating the conductors of the ribbon cable and, these made free relative to each other, separate the conductors and put them in step with the contacts. of the connector. Other provisions consist in associating these mime contacts with an adapter which reduces the pitch of said contacts to that of the conductors of the ribbon cable. These provisions are expensive, often complicated and always go against the advantage which brings the use of ribbon cable, namely the quick connection in a single operation of all the conductors of that. *
The object of the invention is therefore to alleviate such drawbacks in a simple and economical manner by confining itself to presenting the ribbon cable at an appropriate angle at an angle, at a suitable angle, to adopt a particular arrangement for said contacts and to provide a cable clamp and its cover arranged so that they catch up with the bias of the ribbon cable inside the connector and bring the part of this outer cable to the connector so that it is normally in the axis of this one.

To this end, the invention provides a miniature rectangular connector with a double row of self-stripping contacts which have, in their part used for stripping and connecting the cabal, an offset with respect to the axis of the rest of the pin. connection and its housing in the connector This offset of the self-stripping contacts is used so that the contacts of the same row of the connector have all their offset forks oriented in the same direction and so that, in the other row, the forks are arranged at 1800 with respect to the first ones and are also oriented in the same direction but opposite to the previous one.Moreover, each contact of one or the other of the rows of connecting pins is mounted in its housing so that the he axis of its double fork forms a certain angle - in this case 230 - with respect to the vertical axis of the connector. The combination of these two provisions makes it possible to use, with ribbon cables, connectors widely known for the reliability of their characteristics but whose housings receiving the connection pins are at a pitch of 2> 76 mm. while the conductors of the sheet-like cells are generally at a pitch of 1.27 mm. Indeed, to wire such a connector, it suffices to present the target in a bias ply, at an angle of 230, and each conductor is then in the axis of a contact fork alternately belonging to one or more other of the two rows of connector pins.

 However, if these provisions provide a solution as regards the adaptation of the pitch of the conductors of the ribbon cables with that of the contacts of certain common types of connectors, it remains to overcome the disadvantage which results from the bias presentation of the cable. on the contact field. Indeed, this bias is also found in the part of the cable external to the connector and the fact that this part is not in the axis of the connector can, in certain cases, constitute a discomfort. To remedy this, the invention plans to use a cable clamp and a cover connected together by a hinge. The cable clamp has conduits which pass right through it and are used individually to introduce and guide each conductor of the target in the form of a sheet when it is placed opposite the contacts before connection. The cable clamp also includes zones whose particular reliefs impose judicious bending on the flat cable which catches its bias and brings it back in the axis of the connector. On its side *, the cover has raised and recessed areas complementary to the previous ones which have the purpose of wedging the cable according to its bends and of holding it firmly so that the mechanical forces which it may undergo outside the connector are not reflected not on the contacts established in the connector.

The various objects and characteristics of the invention will now be detailed in the description which follows, given by way of nonlimiting example, with reference to the appended figures which represent:
- Figure 1, a simplified end view of a miniature rectangular connector of known type having two rows of housings for connection pins;
- Figures 2 and 3, large-scale perspective views of a model of male and female connection pins used by the invention;
- Figure 4, a view similar to that of la.figure I but with a number of housings equipped with their connection pins;
- Figure 5, a view of the internal part of the cable clamp for the introduction of the conductors of the ribbon cable in their contacts and the housing thereof;
- Figure 6, a partially cutaway and sectional view of the various means used when connecting a ribbon cable but prior to connection;
- Figure 7, a view similar to that of Figure 6 but after the connection of the ribbon cable on the connector contacts;
- Figure 8, a perspective view of the cable clamp and its cover as proposed by the invention
- Figure 9, a perspective view of the elements of Figure 8 after closing the cover on the ribbon cable and the cable clamp;
- Figure 10, a perspective view of the various folds imposed on the ribbon cable the cable clamp and its cover.

 We will begin the description by first referring to Figure 1 which illustrates in a simplified manner the end view of a miniature rectangular connector of known type and, in particular, the housings I of the insulator 2 of this connector. As can be seen, these housings are arranged in two rows; the distance 3 - or not - between two dwellings in the same row is 2.76 min while it is half, or 1.38 mm for step 4 between two dwellings belonging respectively to the one and the other rows. However, for reasons, inter alia, of cost, continuity of supply, manufacture of this type of connector, there can be no question of modifying these steps to bring them to values of 1.27 mm (and 2, 54 mm) which correspond to the pitch of the ribbon cable conductors.

Provision is therefore made, in the invention, to keep the insulators 2 such as that appearing in FIG. I but to use connection pins having self-stripping contacts whose configuration allows them to be placed in the housings 1 so that their pitch corresponds to that of the conductors of the ribbon cables.

These connection pins are the object of Figures 2 and 3, the pin of Figure 2 having a male plug 5, the pin of Figure 3 having a complementary female socket 6. It goes without saying that, in the same housing 2, only plug pins 5 or socket pins 6 are fitted
Depending on whether they are male or female connectors. However, it will be noted that the part of these pins used for the self-stripping contact is identical in the two figures. It consists of two similar forks 7 and 8 which each provide between their two teeth a slot 9 or 10 ensuring the cutting of the insulation of a flat cable conductor, then housing and contact with this same conductor according to a method well known which will not be described. Similarly, will not be described the role of the flange 11 which is used, in a conventional manner, to maintain the spindle in its housing 1 (FIG. 1) thanks to the action of elastic tabs of retention 12 as illustrated by FIG. 6. It will be noted, however, that the pin has on the sides two symmetrical lugs 11 ′ originating from the cutting of the stamping support strip whose width slightly greater than the diameter of the cavity of the insulation of the connector makes it possible to obtain a mechanical tightening preventing any rotation of this pin after insertion into the cavity in a special position which will be described later. It will also be noted that the semicircular edge 13 is at the same level as the bottom of the slits 9 and 10 so that, when the stripped conductor is at the bottom of the corresponding slit, the neighboring part of the ribbon cable rests on the edge 13 as will be seen more easily in FIG. 4. It will also be noted that the slot 9 or 10 is not in the axis of the spindle but offset relative to this axis for reasons which will be explained now.

 Referring to FIG. 4, it can be seen that certain housings 1 of the insulator 2 have been fitted with pins such as those of FIGS. 2 and 3, only the rear part provided for the contact being visible in the figure.

Two arrangements have been made with regard to the positioning of these pins: they are all placed so that the plane which passes through the axis 14 of the slots 9 and 10 of each pair of contacts 7 and 8 forms an angle - in this case 230 - with the plane which passes along the axis 15 of the connector; moreover, in the same row, all the contacts 7 and 8 are located on the same side with respect to the axis 16 of their own pins but, in the upper row, they are offset to the right with respect to the axis 16 while that, in the lower row, they are offset to the left with respect to this same axis.

 Given that the axes of the housings 1 - corresponding moreover to the axes 16 - are separated by a distance 3 (firuge 1) of 2.76 mm, it can be seen that the distance 17 separating the axes 18 and 19 from the slots of the contacts d '' the same row is equal to 2.76 mm x cosine of 239, or 2.54 mm. The same applies to the distance 20 which corresponds to the distance separating the axes 19 and 21 from the slots of two contacts each belonging to a different row since this distance results from the center distance (FIG. 1) equal to 1.38 mm x cosine of 23, which gives the dimension 20 a value of 1.27 mm.

It can therefore be seen that the fact of adopting the two arrangements described above makes it possible to obtain contacts having their self-stripping slots at a pitch identical to that of the conductors of the ribbon cable currently most used, while retaining the same type of contact whether for one or the other row of the connector. Indeed, during the description of Figures 2 and 3, it was noted that the slots 9 and 10 of the contacts were in a plane which was offset relative to a parallel plane passing through the longitudinal axis of the connection pin. We find this difference between these two planes in Figure 4; it corresponds, for each contact, to the distance 22 between the axis 23 of the slot of the two forks 7 and 8 of a contact and the axis 24 of the rest of the connection pin secured to this dreary contact. contact slots allows to leave free the part located to the right of the semicircular shank 13 (see also Figures 2 and 3). This part is used for the passage of the neighboring conductor, through the flat screen, of the one whose own contact ensures connection. In this way, not only are the contacts in step with the conductors of the ribbon cable, but they have a configuration which makes it possible to accommodate each conductor of the ribbon cable without it ever touching any other contact than that which strips and connects it.

 In order for its conductors to be arranged along the axes 18, 19, 21, 23 (as well as the similar axes of the other contacts), the ribbon cable must be presented at an angle in the connector, at an angle OL (FIG. 4) of 230.

To do this, the cable clamp 25 of Figures 5; 6, 7, 8 and 9 comprises conduits 26 which pass right through it and whose diameter corresponds to that of the conductors provided with their insulating sheath, the pitch of these conduits being the same as that of the conductors of the ribbon cable. It is therefore very easy to introduce these conductors into the conduits 26 and then to push the cable until it comes out of the length necessary for the cabling in chain of several connectors or else leave the cable slightly recessed with respect to the outputs. conduits 26 in order to avoid any untimely short-circuit. However, these conduits 26 are formed in the insulating material at an angle of 23 relative to the axis of the connector. We see that thus, after introduction into the conduits 26, the conductors of the ribbon cable are each in the axis of the slots of a connector contact fork and are ready for self-connection operation. We are then in the situation which is illustrated by FIG. 6; this is a side view of the connector and the cable clamp, the latter being cut along the axis of a conduit 26 at the level of a contact fork 7 and 8. This section of the cable clamp 25 shows internal arrangements which we will examine in relation to FIG. 5. A wall 27 constitutes the bottom which abuts against the rear face 28 of the connector. It comprises, at the level of each contact fork 7 or 8, an opening blind 29 (see also Figure 5) whose width and length correspond to the size of a contact fork so as to be able to provide housing but also guidance. The depth of each blind opening 29 is intended to be related to the ultimate position occupied by the contacts 7 and 8 at the end of the connection operation (FIG. 7). It will be noted that the two openings 29 corresponding to the two contact forks of the same connection pin form between them, in the insulating material, a stud 30 sized to abut against the insulating sheath of the conductor 31 on the space separating the two forks 7 - 8 of the contact.

 As an indication, it will also be noted that FIG. 5 is a view of the cable clamp after turning over, that is to say that in the connection position of FIG. 6, the openings 32 and 33 cooperate with the contacts not shown. of the housing 34 of FIG. 4 and the openings 35 and 36 with the contacts also not shown of the housing 37. It is, moreover, for the same reason of reversal that the dotted lines 38 and 39 corresponding to the outer edges of the flat cable are oriented symmetrically with respect to the axes 14, 18 of FIG. 4.

Under these conditions, returning to FIG. 6, it can be seen that the connection operation consists in exerting sufficient force on the cable clamp 25 in the direction of arrow 40 so that all the conductors 31 of the cable in sheet are simultaneously stripped and establish a metallic contact with the corresponding forks 7 and 8. We are then in the situation illustrated by FIG. -7 in which the wall 27 abuts against the rear face 28 of the connector.

 As regards the cable itself, it is at an angle relative to the axis of the connector as illustrated in FIG. 8. In this figure, it can be seen that the cable clamp 25 has a cutout delimited by a bottom 41 and two walls 42 and 43 intended to cooperate respectively with the faces 44, 45, 46 of the cover 47. The latter is made integral with the cable clamp 25 by means of a flexible hinge 48. In this cutout, there is in relief a pyramidal ramp 49, the cover 47 of which includes the female imprint. This pyramid ramp 49 has three identical free faces which have the role of imposing on the ribbon cable 50 a bending which eliminates its bias position and brings it back in the axis of the connector. Indeed, the cable 50 is manually folded between the walls 42 and 43, then the cover 47 is closed until the faces 51 and 52 come into contact with the faces 53 and 54 of the cable clamp.

 The "closed" position of the cover 47 is illustrated in FIG. 9 and we can clearly see the lower part 55 of the ribbon cable which lies at an angle with respect to the axis of the connector while the upper part 56, wedged by the cover is normally arranged along this axis. Such an angular catching-up of the position of the cable is therefore due to the bending to which the cable is subjected when it is trapped against the faces of the pyramidal ramp 49 (FIG. 8) by the female imprint of this ramp made in the cover 47 at when the latter is folded back on the cable clamp 25.

For clarity, FIG. 10 shows the perspective view of the portion of cable having been subjected to folding after it has been removed from the cable clamp. We recognize the parts 55 and 56 visible in Figure 9 and lton clearly distinguishes the areas 57 and 58 which are applied by the cover against the bottom 41 (Figure 8) and the areas 59, 60 and 61 that the same cover traps against the three faces of the ramp 49 and the ribbon cable of which has retained the profile.

 It remains obvious that the foregoing description has been given only by way of nonlimiting example and that other variants can be envisaged without departing from the scope of the invention.

Claims (8)

1 - Ribbon target connector in which the housings intended to receive the connection pins with contacts in the form of a self-stripping fork are regularly spaced from one another1 in one or more rows, at a pitch different from that of the conductors of the cable in sheet form, said connector being characterized in that the axis of the slot of the self-stripping fork of each contact of at least one row is offset from the common axis of the corresponding connection pin and the housing of this pin in the connector, the contacts of this row of the connector all having their offset fork oriented on the same side with respect to said common axis, each pin being arranged in its housing so that the plane passing through the axis of the slot of the auto fork stripping forms an angle with the plane passing through the vertical axis of the connector, this angle having the appropriate value so that the conductors of the ribbon cable are individually in the axis of a self-stripping fork slot. 2 - connector for ribbon cable according to the first claim, characterized in that the angle formed by the plane passing through the axes of the slot of each contact fork and the plane passing through the vertical axis of the connector has a value whose cosine is equal to the ratio of the pitch of the ribbon cable conductors with the pitch of the pin housings in the connector. 3 - Connector for ribbon cable according to the first claim 1 in which a cable clamp is used to simultaneously strip and connect all the conductors of the ribbon cable and a cover to prevent the tensile forces undergone by the cable are transmitted to the conductors connected to the contacts of the connector, said connector being characterized in that the cable clamp comprises conduits which pass right through it, the number of these conduits, their diameter and their corresponding distance between axes respectively to those relating to the conductors of the ribbon cable, these conduits being parallel to each other and arranged in the same plane perpendicular to the slots of the contact forks of the connector, the longitudinal axis of said conduits forming an angle with the vertical axis of said connector defined in the second claim.  4 - connector for ribbon cable according to the third claim, characterized in that the face of the cable clamp intended to cooperate with the contact forks of the connector has blind openings whose dimensions and locations are provided to provide accommodation contact forks during and after the stripping and connection operation of the cable conductors, said openings orthogonally cutting said conduits. 5 - Connector for ribbon cable according to the third claim, characterized in that the cable clamp comprises on the rear part opposite to that cooperating with the contact forks of the connector, a cut in the general shape of "U" whose width corresponds to that of the ribbon cable, said cutout serving as a housing for a pyramidal ramp whose base is secured to a wall of the cutout while its top is close to the other wall of the cutout.  6 - connector for ribbon cable according to the fifth claim, characterized in that the three free faces of the pyramid ramp are intended to receive the ribbon cable on which they impose bends at angles corresponding to those formed by said three faces , these folds intended to eliminate the angular position relative to the axis of the connector occupied by the cable at the outlet of said conduits and to bring it into a position where this axis and its own merge. 7 - connector for ribbon cable according to the third and fifth claims, characterized in that the cover has an imprint corresponding hollow to the reliefs of said pyramid ramp so as to subject the cable to bending by forcing it against the faces of said ramp when closing the cover on the cable clamp.  8 - Connector for ribbon cable according to the first claim comprising at least two rows of connection pins with contacts in the form of a self-stripping fork1 characterized in that the contacts of the same row of the connector all have their offset offset fork of the same category with respect to said common axis of the connection pin but on the side opposite to the orientation of the self-stripping fork offset from the contacts of the other row of the connector.