EP0403371A1 - Electrical connector for connecting a shielded multiconductor cable to an electrical unit which is inside a frame - Google Patents

Abstract

1. The invention relates to an electrical connector for connecting a shielded multiconductor cable to an electrical assembly enclosed within a chassis. 2. This connector comprises two parts (10 and 11), one of which (10), connected to an electrical assembly (18) enclosed inside a chassis, is fixed so as to appear through a opening made in an enclosure plate (20) of this chassis, while the other part (11) is fixed to the end of a shielded multiconductor cable (32). This part (11) is provided, on at least one of its lateral faces (42, 43), with a sheet (50) which is connected to the cable shielding sheath (32) and which, during the coupling of the two parts (10 and 11) comes into contact with the conductive plate (20), thus ensuring the continuity of the shielding for protecting electrical circuits against the effects of external electromagnetic radiation. 3. Application to the technique of connecting electronic equipment used to process information.

Description

The present invention relates to an electrical connector for connecting a shielded multiconductor cable to an electrical assembly placed inside a chassis.

In the technique of construction of electronic equipment used for telecommunications and, more particularly, for information processing, there is a wide use of more or less complex electrical assemblies which, such as electrical recorders or electronic circuits operating by pulses for example, are particularly sensitive to the disturbing effects caused by electromagnetic radiation generated by other electrical circuits external to these assemblies. This is why these electrical assemblies, in order to be protected against this parasitic radiation, are generally enclosed inside a metal frame which serves both as mechanical support and as a shield for the electrical assembly.

The electrical assemblies which, enclosed in these frames, consume electrical energy, are usually supplied by electrical generators which are designed to deliver electrical currents whose voltage, current and / or frequency characteristics must meet well-defined conditions to allow these assemblies to function properly. Some of these electric generators, such as those which deliver direct voltages of a few tens of volts for example, can be housed inside the same chassis as that which accommodates the consumer assembly which is supplied by these generators. On the contrary, other generators, such as those which are known by the name of inverters for example, cannot take place inside the chassis in which the consumer assembly is located which they must supply, for the reason that these generators are often the source of relatively high high frequency electromagnetic radiation and therefore require solid shielding which makes them particularly heavy and bulky. In addition, these generators due to the relatively high electrical voltages - of the order of a few hundred volts - which reign inside them, require careful electrical insulation and their insertion, inside the chassis containing the assembly to be supplied, could prove to be dangerous for the persons responsible for intervening, during maintenance operations, on this apparatus, if, for any reason, these generators had an insulation fault. Since each of these generators is placed in a chassis different from that in which the consumer assembly to be supplied is located, it is therefore necessary, to ensure the electrical connection between a generator and this assembly, to use a multiconductor cable shielded whose conductive wires are used to establish the essential connections between the electrical circuits of the generator and those of the consumer assembly, and whose shielding sheath is connected to the two chassis containing this generator and this consumer assembly. In order to allow this shielded multiconductor cable to be easily disconnected from one or the other of these two chassis, in particular with a view to replacing a faulty generator or consumer assembly by another generator or another together consumer, we used in the prior art, shielded connectors of the type which has been described and represented in the patent of the United States of America No. 3,904,265, this connector being made up of two parts of connector, the first of which, integral with a chassis, comprises an insulating body provided with housings into which are inserted contact elements of a first type (for example female), these contact elements being connected to the circuits of a generator assembly or of the consumer assembly contained in this chassis, and the second of which, fixed to one end of the multiconductor cable, comprises an insulating body provided with housings in which elements are inserted contact elements of a second type (for example male) intended to be brought into contact with the contact elements of the first type when these two connector parts are coupled to one another, these contact elements of the second type being connected to the conductive wires of the multiconductor cable. The insulating body of the first connector part is provided with a first shielding element which, made of a conductive material, is electrically connected to the metal frame. Similarly, the insulating body of the second connector part is provided with a second shielding element which, also made of a conductive material, is electrically connected to the shielding sheath of the cable.

These two shielding elements are profiled so as to fit one into the other during the coupling of the two connector parts, this which ensures continuity of the shielding between the multiconductor cable and the metal frame.

In an electrical connector of this kind, it is necessary that the various component parts of the connector are machined and adjusted with great precision in order to allow, when coupling the two parts of the connector, on the one hand to the contact elements , which are relatively small, to be able to be brought into contact with each other under a mechanical pressure of determined value, on the other hand for the shielding elements to fit into one another with a clearance as reduced as possible. As a result, not only the manufacture of such a connector, which requires perfect positioning of the various component parts with respect to each other, proves to be particularly long and costly, but the repeated operations of connection and disconnection of the two parts of the connector, which require relatively large mechanical forces due to the interlocking of the two shielding elements, eventually, in the long run, causing misalignments of the contact elements, which naturally risks causing these elements to deteriorate contact and thus lead to a rapid decommissioning of the connector.

The present invention overcomes these drawbacks and proposes an electrical connector which, intended to allow the connection of a shielded multiconductor cable to an electrical assembly (generator or consumer of energy) enclosed within a metal frame, ensures the continuity of the shielding between this cable and this chassis, without requiring expensive shielding elements and requiring relatively high mechanical forces during the coupling and uncoupling operations of the two parts of this connector.

More specifically, the present invention relates to an electrical connector allowing a multiconductor cable provided with a shielding sheath to be electrically connected to an electrical assembly placed inside a metal chassis, this connector being made up of a part of a first connector part comprising an insulating body provided with contact elements of a first type capable of being electrically connected to said electrical assembly, this body being intended to be secured to said chassis, inside thereof, opposite an opening made in a enclosure plate of this chassis, on the other hand of a second connector part comprising an insulating body having a coupling face intended to be brought at least close to the insulating body of said first part when these two parts are coupled to each other, the body of the second part also having faces adjacent to said coupling face, the latter body insulator being provided with housings into which are inserted contact elements of a second type intended to be connected to the contact elements of said first connector part when these two parts are coupled to each other, these contact elements of second type being electrically connected to the conductors of said screened cable, said connector being characterized in that the insulating body of said second connector part is provided, on the u at least of said adjacent faces, of a sheet of conductive material connected to the shielding sheath of said screened cable, this sheet having a flexible part extending substantially towards said first connector part when the latter is coupled to said second part connector, this flexible part having a length such that, when these two connector parts are coupled to one another, it is able to be in elastic contact with said enclosure plate and thus to ensure the continuity of the shielding of electrical circuits against the effects of external electromagnetic radiation.

• - La figure 1 est une vue en perspective montrant un connecteur électrique établi selon l'invention pour assurer le raccordement d'un câble multiconducteur blindé à un ensemble électrique enfermé à l'intérieur d'un châssis, ce connecteur étant équipé de pièces de blindage établies selon une première forme de réalisation,
• - La figure 2 est une vue en perspective, avec parties éclatées, montrant la constitution de la partie de connecteur qui, sur la figure 1, est fixée à l'une des extrémités du câble multiconducteur blindé,
• - La figure 3 est une vue en coupe, suivant un plan passant par une ligne indiquée par 3.3 sur la figure 1, montrant la position occupée par les différentes pièces du connecteur lorsque les deux parties de ce connecteur sont désaccouplées,
• - La figure 4 est une vue en coupe, suivant un plan passant par une ligne indiquée par 3.3 sur la figure 1, montrant la position occupée par les différentes pièces du connecteur lorsque les deux parties de ce connecteur sont accouplées,
• - La figure 5 est une vue en perspective, montrant un autre connecteur réalisé selon l'invention, mais plus particulièrement adapté au cas où le câble multiconducteur blindé présente une section de forme circulaire,
• - La figure 6 est une vue en coupe, montrant un connecteur dont les pièces ûe blindage sont établies selon une deuxième forme de réalisation,
• - La figure 7 est une vue en coupe, montrant un connecteur dont les pièces de blindage sont établies selon une troisième forme de réalisation, et
• - La figure 8 est une vue en coupe, montrant un connecteur dont les pièces de blindage sont établies selon une quatrième forme de réalisation.

The present invention will be better understood and other objects, details and advantages thereof will appear better in the following description, given by way of nonlimiting example and with reference to the appended drawings in which:

• - Figure 1 is a perspective view showing an electrical connector established according to the invention for connecting a shielded multiconductor cable to an electrical assembly enclosed within a chassis, this connector being fitted with shielding parts established according to a first embodiment,
• FIG. 2 is a perspective view, with exploded parts, showing the construction of the connector part which, in FIG. 1, is fixed to one of the ends of the shielded multiconductor cable,
• FIG. 3 is a sectional view, along a plane passing through a line indicated by 3.3 in FIG. 1, showing the position occupied by the different parts of the connector when the two parts of this connector are uncoupled,
• FIG. 4 is a sectional view, along a plane passing through a line indicated by 3.3 in FIG. 1, showing the position occupied by the different parts of the connector when the two parts of this connector are coupled,
• FIG. 5 is a perspective view showing another connector produced according to the invention, but more particularly suitable for the case where the shielded multiconductor cable has a circular cross section,
• FIG. 6 is a sectional view showing a connector, the shielding parts of which are established according to a second embodiment,
• FIG. 7 is a sectional view showing a connector, the shielding parts of which are established according to a third embodiment, and
• - Figure 8 is a sectional view showing a connector whose shielding parts are established according to a fourth embodiment.

The connector which is shown in Figure 1 comprises two connector parts 10 and 11 which can be coupled to each other in a manner which will be indicated later. The connector part 10 comprises an insulating body 12, having the shape of a parallelepiped whose width e is relatively small compared to its length L and its height h. Thus, in the example described, this height h is substantially equal to five times the value of the width e. This body 12 is made of an insulating material having high mechanical strength and excellent electrical insulation for the contact elements, such as, for example, the acetal resin sold commercially under the name of "Delrin" (registered trademark) or else polycarbonate. commercially sold under the name of "Makrolon" (registered trademark). The insulating body 12 is provided with housings 13, of cylindrical shape, which, passing through the mass of this body, each open onto the two parallel faces 14 and 15 of this body which have for dimensions the values e and h indicated above. In FIG. 1, only the face 14, which constitutes the coupling face of the connector part 10 is visible, while the face 15, which is located at the rear of the part 10, as can be seen. understand by referring to Figure 3, is not visible.

In each of the housings 13 of the insulating body 12 is inserted a contact element of the type which, in FIG. 3, is designated by the reference 16. In the example illustrated by FIG. 3, each of the contact elements which are inserted into these housings 13 is of the female type and has a recessed part 30. As can be seen in FIGS. 3 and 4, each contact element 16 is connected, at its end situated on the side of the face 15, to a sheathed conductive wire 17 which establishes the electrical connection between this contact element and an electrical apparatus 18. It will be considered that this electrical apparatus is normally enclosed inside a metal frame which has been partially represented in FIG. 1, this chassis, designated by the reference 19, serving both as a mechanical support and as a shield for this apparatus.

The chassis 19, which is of parallelepipedal shape, comprises enclosure plates which ensure the delimitation of the interior space of this chassis. One, 20, of the four vertical enclosure plates of this chassis is pierced with a rectangular opening 21 opposite which is disposed the part of the connector 10, this connector part being placed inside the chassis 19 and being made integral with this chassis by means of fixing of known type (not shown). The position of the connector part 10 is such that its coupling face 14 is flush with or slightly exceeds the plane of the enclosure plate 20, which allows the connector part 11 which is located outside the chassis 19 to be able to be connected to the connector part 10, in a manner which will be explained later.

As can be seen in FIG. 2, the connector part 11, which is exploded in this figure, comprises an insulating body 22, of parallelepiped shape, having substantially the same width e and the same height h as those of the insulating body 12 of the connector part 10, this insulating body 22 thus having two faces having each for dimensions e and h. Only one, 27, of these two faces is visible in FIG. 2. The other face, designated by the reference 23 in FIG. 3, constitutes the coupling face of the connector part 11, this face of coupling 23 being intended to come into contact, or at least in the immediate vicinity, of the coupling face 14 of the connector part 10 when these two parts 10 and 11 are coupled to one another. FIG. 2 shows that the insulating body 22 has four faces 40, 41, 42 and 43 which are adjacent to the coupling face 23 and two of which, 42 and 43, are oriented vertically in the figure, each of these two faces having for dimensions h and M, M denoting the length of the insulating body 22. In the position illustrated by FIG. 2, the faces 40 and 41 are, respectively, the upper face and the underside of the insulating body 22. This insulating body 22 is made of an insulating material similar to that which constitutes the insulating body 12 of the connector part 10. FIGS. 2 and 3 show that the insulating body 22 is provided, on its coupling face 23, with hollow insulating plugs 24, in number equal to that of the housings 13 of the insulating body 12, these hollow plugs being intended to engage each one respectively in each of these housings 13 during the coupling of the parts 10 and 11. Each of these plugs 24 is pierced with a cylindrical cavity eu 25 in which engages, during the introduction of the plug into a housing 13, the contact element 16 which is located in this housing. Each cylindrical cavity 25 communicates with a housing 26 which, from the coupling face 23, crosses the mass of the insulating body 22 to open on the face 27 of this body which is opposite to the coupling face 23. This housing 26 is used to receive a contact element 28 ending in a rod 29 which, extending along the axis of the cylindrical cavity 25, is introduced into the recessed part 30 of the contact element 16 during the coupling the two connector parts 10 and 11. Each contact element 28 is connected, at its end situated next to the face 27, to each of the conducting wires 31 of a shielded multiconductor cable 32 (FIG. 1), the assembly of these conductive wires being disposed inside a shielding sheath 33 made of an electrically conductive material, this sheath itself being enclosed within an envelope 34 of insulating material. The connector part 11 which is shown in FIG. 2 further comprises two insulating covers 35 and 36 which, provided removable, can be assembled to one another by means of screws 37. These two covers 35 and 36, which are each provided with a curved tab 38 which can be engaged in a stirrup 39 formed by molding on the insulating body 22, are intended to protect the end portion of the shielded multiconductor cable 32 on which the connector part 11, ensuring, as can be understood from FIG. 3, a reinforcement of the mechanical rigidity of this terminal portion, which reduces the risks of separation of the cable 32 and the connector part 11 during repeated operations of coupling and uncoupling of this part with the connector part 10. In addition, these two covers, which are arranged on either side of this terminal portion of the cable 32, as seen in Figure 3 , prevent, when assembled together, that the stripped end of the shielding sheath 33 of this cable does not undergo, during handling of this cable, deformations capable of causing involuntary contacting of the conducting wires 31 with each other by means of this sheath 33.

Figures 3 and 4 allow to understand that, during a coupling operation of the two connector parts 10 and 11, each of the hollow plugs 24 of the part 11 engages respectively in the free space of each of the housings 13 of part 10, that is to say in the region of the housing which is not occupied by the contact element 16 which is in this housing, while, simultaneously, each of the rods 29 respectively penetrates into each of the recessed parts 30 of the contact elements 16. In order to reduce the effort necessary for this operation, while ensuring good electrical contact between each of these rods 29 and each of these contact elements 16, the housings 13, the plugs 24 and the contact elements 16 are dimensioned so as to provide a small clearance between each housing and each hollow plug inserted in this housing and between each hollow plug and each contact element 16 introduced in this fi che hollow. On the contrary, the hollowed out parts 30 and the rods 29 are produced in such a way that the introduction of a rod 29 into a hollowed out part 30 takes place with a slight friction of the surfaces of these parts which are brought into contact. It can be observed, by comparing FIGS. 3 and 4, that, at the end of the coupling operation of the two connector parts 10 and 11, the coupling faces 14 and 23 of these two parts are in the immediate vicinity one from the other.

In order to avoid involuntary uncoupling of the two connector parts 10 and 11, for example under the action of vibrations generated, during operation, by the apparatus 18 which is enclosed inside the chassis 19, these two parts are provided with a locking device constituted, in the example described, by a hooking lug 45 (FIG. 1) which, made of a material similar to that constituting the insulating body 22, is fixed, in a flexible manner, to the upper face 40 of this body 22, this tab 45 being provided with an opening 46 into which engages, when the two connector parts 10 and 11 are coupled to each other, a lug 47 formed by molding on the upper face of the connector part 10. The tab 45 is integral with an actuating tongue 48 which, when the two connector parts 10 and 11 are coupled to each other, allows the operator to lift tab 45 to release the lug 47 of the opening 46 and thus free the connector part 11 so that it can then be uncoupled from the part 10. Another locking device, similar to that which has just been described, is also provided on the underside 41 of the connector part 11.

E représentant la valeur du module d'élasticité du matériau constituant la feuille 50 et  l'angle (indiqué sur la figure 4) que forme la face latérale 42 avec le plan tangent Q àla portion 56 de la partie flexible 53 qui est contiguë à la portion terminale 55 de cette partie flexible. Dans le mode de réalisation qui est illustré sur la figure 4, cet angle  a une valeur voisine d'une vingtaine de degrés, de sorte que la valeur de sin  est pratiquement égale à 0,4. La force G avec laquelle la partie flexible de la feuille 50 est appliquée sur la plaque d'enceinte 20 doit avoir une valeur suffisante pour permettre d'assurer un bon contact entre cette feuille 50 et cette plaque 20. Cependant il convient que cette force ne dépasse pas une certaine valeur limite au-dessus de laquelle l'opération d'accouplement des deux parties de connecteur 10 et 11 se révèlerait difficile pour l'opérateur. Afin de répondre à ces conditions, on s'arrange pour que la valeur de cette force G, exprimée en newtons, reste, préférentiellement, comprise entre 0,02b et 0,12b, b représentant la dimension, exprimée en millimètres, de l'extrémité 54 de cette feuille. C'est ainsi que, dans l'exemple décrit, cette feuille 50 est réalisée en acier et présente ainsi un module d'élasticité pratiquement égal à 25 000 daN/mm². En outre, cette feuille a une épaisseur pratiquement égale à 0,1 mm et une largeur b (figure 2) pratiquement égale à 45 mm, tandis que la partie flexible 53 de cette feuille a une longueur pratiquement égale à 16 mm. Il faut également signaler que, dans l'exemple qui est illustré par la figure 4, le déplacement f subi par l'extrémité 54 de la partie flexible 53 est sensiblement égal à 4,5 mm. Dans ces conditions, la force avec laquelle cette extrémité est appliquée sur la plaque d'enceinte 20 a pour valeur :

soit pratiquement : G = 1,5 Newton.Figures 1 and 2 also show that the side face 42 of the insulating body 22 of the second connector portion is coated with a sheet 50 which, made of an electrically conductive material, is provided with a recess 51 in which can be engaged, when the cover 35 is removed, the stirrup 39 which protrudes on this face 42. The recess 51 is dimensioned such that the engagement of the stirrup 39 in this recess is effected with a very low clearance, so that the sheet 50 cannot move on the face 42 on which it has been applied. Furthermore, this sheet 50 is chosen to be thin enough so that, once applied to the face 42, it does not hinder the introduction, into the stirrup 39 of this face, of the curved tab 38 of the cover 35, this introduction, which aims to secure the cover 35 with the insulating body 22, further having the effect of preventing the release of the sheet 50 of this stirrup. The sheet 50, which has thus been positioned on the lateral face 42, has a free part 52 which, from the face 27 of the insulating body 22, extends beyond this body, that is to say at right of the body 22 shown in FIG. 3, so as to take place, in the interior space between the two insulating covers 35 and 36, against the internal face of the cover 35. This free part 52 is electrically connected to the shielding sheath 33 of the cable 32, this connection operation, carried out by welding, being carried out, either after the sheet 50 has been engaged, by its recess 51, in the stirrup 39 of the face 42, or, on the contrary, before this sheet is engaged in this recess. The sheet 50 which has been engaged in this stirrup also has a flexible part 53 which, as can be seen in FIG. 3, extends along the insulating body 22, to the left of it, that is to say substantially in the direction of the first connector part 10, when the second connector part 11 is positioned with a view to being coupled to this first connector part. In the embodiment illustrated in FIG. 3, this flexible part 53 has, near its end 54, an end portion 55 which has been slightly bent, in a direction having the effect of moving this end 54 away from the plane P of the lateral face 42, this terminal portion 55 forming with this plane P an angle B̂ less than eighty ten degrees. In a more particularly advantageous embodiment, this angle B̂ has a value practically equal to forty five degrees. Furthermore, as can be understood with reference to FIGS. 3 and 4, the flexible part 53 has a length such that, when the connector part 11 is moved to be coupled to the connector part 10, the end portion 55 of this flexible part comes into contact with the enclosure plate 20 a little before the coupling operation of the two connector parts is completed. During this movement, as the coupling faces 14 and 23 of the two connector parts are brought closer to each other, this end portion 55 is constrained, after having contacted the enclosure plate 20, to slide on the external face of this plate, in a direction tending to move it away from the opening 21, which has the effect of flexing the flexible part 53, as can be seen in FIG. 4. In Consequently, at the end of the coupling operation, the end 54 of the flexible part 53 is applied to the enclosure plate 20 with a force whose intensity is all the more important as the bending undergone by this flexible part 53 is larger. It has been found, by designating by a the length, by b the width and by e the thickness of this flexible part 53, that when this flexible part underwent a bending such that its end 54 was displaced by a distance f relative to at its original position, the force G with which this end was applied to the speaker plate 20 was given substantially by the expression:

E representing the value of the modulus of elasticity of the material constituting the sheet 50 and the angle (indicated in FIG. 4) that forms the lateral face 42 with the tangent plane Q to the portion 56 of the flexible part 53 which is contiguous with the terminal portion 55 of this flexible part. In the embodiment which is illustrated in FIG. 4, this angle a has a value close to around twenty degrees, so that the value of sin est is practically equal to 0.4. The force G with which the flexible part of the sheet 50 is applied to the enclosure plate 20 must have a value sufficient to make it possible to ensure good contact between this sheet 50 and this plate 20. However, this force should not not exceed a certain limit value above which the coupling operation of the two connector parts 10 and 11 would prove difficult for the operator. In order to meet these conditions, it is arranged that the value of this force G, expressed in newtons, remains, preferably, between 0.02b and 0.12b, b representing the dimension, expressed in millimeters, of the end 54 of this sheet. Thus, in the example described, this sheet 50 is made of steel and thus has a modulus of elasticity practically equal to 25,000 daN / mm². In addition, this sheet has a thickness practically equal to 0.1 mm and a width b (FIG. 2) practically equal to 45 mm, while the flexible part 53 of this sheet has a length practically equal to 16 mm. It should also be noted that, in the example which is illustrated in FIG. 4, the displacement f undergone by the end 54 of the flexible part 53 is substantially equal to 4.5 mm. Under these conditions, the force with which this end is applied to the enclosure plate 20 has the value:

or practically: G = 1.5 Newton.

It can be observed that, with a force of this value, the contact between the sheet 50 and the enclosure plate 20 is well ensured, and this all the more so as the friction exerted by the end 54 of this sheet, during operations of coupling and uncoupling of the two connector parts 10 and 11 has the effect of cleaning the zone of this plate 20 which is subjected to this friction, by freeing it of traces of insulating material which can form on this zone, these traces which may be, for example, traces of oxides. Thus, the sheet 50 achieves excellent continuity between the shielding sheath 33 of the cable 32 and the enclosure plate 20 which participates in the shielding of the metal frame 19. Furthermore, as can be seen in FIG. 1, the terminal portion of the sheet 50 can be provided with notches 57 which, practiced at regular intervals and oriented in a direction perpendicular to the end of this terminal portion, allow a better distribution of the contact force along this end.

The conductive sheet 50 can naturally be made of a conductive material, other than steel, capable of undergoing small elastic deformations and of resuming its initial shape after the disappearance of the bending force. Thus, for example, this sheet could be made of a copper alloy with beryllium. In this case, the thickness of this sheet is practically equal to 0.2 mm.

In order to further improve the continuity of the shielding between the shielding sheath 33 of the cable 32 and the enclosure plate 20, the lateral face 43 of the insulating body 22 is also provided, as can be seen in FIGS. 2, 3 and 4 , of a sheet of conductive material 60, this sheet being analogous to the sheet 50 and being mounted in a similar manner to that of the latter sheet.

It is useful to note that, when the two connector parts 10 and 11 are coupled, the connector part 11 tends to be moved away from the enclosure plate 20 under the action of the forces exerted on the terminal portions sheets 50 and 60. However, since these two connector parts are made integral with one another by at least one of the locking devices which have been described above, these two parts are not likely to decouple for as long that these locking devices have not been released by the operator.

In the embodiments which are represented in FIGS. 1 and 2, the upper 40 and lower 41 faces of the insulating body 22 each have a width e which is relatively small, this width being close to five millimeters in the example described. Consequently, the surface of each of these two faces is relatively small and, therefore, it is not necessary to provide these faces with sheets of conductive material, the sheets 50 and 60 being in fact sufficient to ensure the continuity of the shielding of electrical circuits against the effects of external electromagnetic radiation. On the contrary, in other embodiments, such as that which is illustrated in FIG. 5 for example, the insulating body 22 may have a shape in which the four faces 40, 41, 42 and 43 which are adjacent to the face coupling of this body each have non-negligible dimensions, that is to say at least equal to fifteen millimeters for example. In this case, to obtain effective protection against the disturbing effects of external electromagnetic radiation, it is necessary to provide each of these four faces with a sheet of conductive material, some of these sheets, such as that which is designated by the reference 80 in Figure 5, which can be cut so as to leave uncovered the locking devices which are provided on the faces on which these sheets are arranged. The electrical connector which is shown in FIG. 5 is more particularly intended for ensuring the connection of a shielded multiconductor cable having a circular section.

It should also be noted that the terminal portion 55 of each of the sheets of conductive material may have a shape different from that which is shown in FIGS. 1 to 5. Thus, in the embodiment which is illustrated in the figure 6, the sheet 50 which is mounted on the face 42 of the connector part 11 comprises, near its end 54, an end portion 55 which is folded back so that its cross section has practically the shape of a U, this U having two branches 70 and 71 oriented substantially in a direction parallel to the plane of the face 42, these two branches being joined by a base 72 which, when the two connector parts 10 and 11 are coupled comes into contact with the plate pregnant 20.

In the embodiment which is illustrated in FIG. 7, the terminal portion 55 of the sheet 50 has a cross section which also has the shape of a U, but with this difference that the two branches 70 and 71 of this U are oriented substantially in a direction perpendicular to the plane of the face 42. It can be seen, in FIG. 7, that the branch 70, which is the furthest from the end 54 of the sheet 50, is in fact folded almost four- twenty-ten degrees relative to the rest of this sheet, and that the branch 71, which is parallel to this branch 70, comes into contact with the external face of the enclosure plate 20 when the two connector parts 10 and 11 are coupled .

In the embodiment which is illustrated in FIG. 8, the terminal portion 55 of the sheet 50 has a cross section which has substantially the shape of a V, this V having two branches 70 and 71 which form an angle Ĉ between them whose value is between 60 ° and 75 °. In addition, the branch 71 which is closest to the end 54 of this sheet 50, forms with the enclosure plate 20, when the two connector parts 10 and 11 are coupled, an angle D̂ whose value is included between 15 ° and 25 °.

Of course, the invention is in no way limited to the embodiments described and illustrated which have been given only by way of example. On the contrary, it includes all the means constituting technical equivalents of those described and illustrated, considered in isolation or in combination, and used in the context of the claims which follow.

Claims (10)

1. Electrical connector allowing a multiconductor cable (32) provided with a shielding sheath (33) to be electrically connected to an electrical assembly (18) placed inside a metal frame (19), this connector being constituted, on the one hand, by a first connector part (10) comprising an insulating body (12) provided with contact elements of a first type (16) capable of being electrically connected to said electrical assembly (18), this body being intended to be secured to said chassis, inside of it, opposite an opening (21) formed in an enclosure plate (20) of this chassis, on the other hand of a second connector part (11) comprising an insulating body (22) having a coupling face (23) intended to be brought at least close to the insulating body (12) of said first part when these two parts (10 and 11) are coupled to each other, the insulating body (22) of this second part further having faces (40, 41, 42, 43) adjacent to said coupling face (23), the latter insulating body (22) being provided with housings (26) into which are inserted contact elements of a second type (28) provided for being connected to said first type contact elements (16) when the two connector parts (10 and 11) are coupled, these second type contact elements (28) being electrically connected to the conductors (31) of said shielded cable (32), said connector being characterized in that the insulating body (22) of said second connector part is provided, on at least one (42) of said adjacent faces, with a sheet ( 50) of conductive material connected to the shielding sheath (33) of said shielded cable, this sheet having a flexible part (53) extending substantially towards said first connector part (10) when the latter is coupled to said second part connector (11), this flexible part e (53) having a length such that, when these two connector parts are coupled to each other, it is capable of being in elastic contact with said enclosure plate (20) and thus ensuring continuity protective shielding of electrical circuits against the effects of external electromagnetic radiation. 2. An electrical connector according to claim 1, characterized in that the flexible part (53) of the sheet of conductive material (50) has, near its end (54), an end portion (55) which is folded, relative to the remainder of this flexible part, in a direction having the effect of tending to move this end (54) away from the plane (P) of the face (42) on which this sheet (50) is fixed. 3. Electrical connector according to claim 2, characterized in that, when the two connector parts (10 and 11) are uncoupled, the end portion (55) of the flexible part (53) of the sheet of conductive material (50) forms , with the plane (P) of the face (42) on which this sheet is fixed, an angle (B̂) whose value is practically equal to forty five degrees. 4. An electrical connector according to any one of claims 2 and 3, characterized in that the flexible part (53) of the sheet of conductive material (50) has a portion (56) which is contiguous with the end portion (55) of this flexible part and which, when the two connector parts (10 and 11) are coupled, forms, with the face (42) on which this sheet (50) is fixed, an angle (Â) whose value is close to d 'about twenty degrees. 5. Electrical connector according to claim 1, characterized in that the flexible part (53) of the sheet of conductive material (50) has, near its end (54), an end portion (55) which is folded so that its cross section has practically the shape of a U, the base (72) of which comes into contact with the enclosure plate (20) when the two connector parts (10 and 11) are coupled. 6. An electrical connector according to claim 1, characterized in that the flexible part (53) of the sheet of conductive material (50) has, near its end (54), an end portion (55) which is folded so that its cross section has practically the shape of a U of which one (71) of the branches is applied to the enclosure plate (20) when the two connector parts (10 and 11) are coupled. 7. Electrical connector according to claim 1, characterized in that the flexible part (53) of the sheet of conductive material (50) has, near its end (54), an end portion (55) which is folded so that its cross section has practically the shape of a V whose branches (70, 71) form an angle between them (Ĉ) whose value is between 60 ° and 75 °, the branch (71) closest to said end (54) forming with the enclosure plate (20) , when the two connector parts (10 and 11) are coupled, an angle (D̂) whose value is between 15 ° and 25 °. 8. An electrical connector according to any one of claims 1 to 7, characterized in that the sheet of conductive material (50) has, near its end (54), an end portion (55) which, when the two parts connector (10 and 1) are coupled, is applied to the speaker plate (20) with a force whose value, expressed in newtons, is between 0.02b and 0.12b, b representing the dimension, expressed in millimeters, from said end (54) of the sheet. 9. An electrical connector according to any one of claims 1 to 8, characterized in that the sheet of conductive material (50) is made of a copper alloy with beryllium. 10. An electrical connector according to any one of claims 1 to 9, characterized in that the insulating body (12) of its first part (10) is integral with the frame (19) containing the electrical assembly (18).

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