EP0419331A1 - Shielded casing for EMI RFI protection - Google Patents

Abstract

1. The invention relates to a shielding chassis for the protection, against the effects of electromagnetic radiation, of an electrical circuit placed inside this chassis. 2. This chassis is provided with an opening 30 serving for the passage of a shielded connector part 15A with a view to its coupling to a complementary connector part 15B which, disposed opposite this opening, inside the chassis, is fixed to a circuit board 13. The chassis 11 is further provided with a conductive, elastic, non-metallic element 35 which, fixed around the opening 30, comes into contact with the shielding element 19 of the part 15A connector and allows stray currents generated by electromagnetic radiation to flow to the earth without passing inside the chassis. 3. Application to the technique of connecting electronic equipment used to process information.

Description

The present invention relates to a shielding chassis for the protection, against the effects of electromagnetic radiation, of an electrical circuit placed inside this 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 measurement recorders or electronic circuits operating by pulses, for example, are particularly sensitive to the disturbing effects caused by electromagnetic radiation which are generated by other electrical circuits which are not part of these assemblies. This is why each of these electrical assemblies, in order to be protected against this parasitic radiation, is generally placed inside a metal frame which serves both as a mechanical support and as a shield for this electrical assembly. Most often, for various reasons, a single electrical assembly is placed inside the same shielding chassis. Thus, for example, a peripheral device, such as a disk drive, intended to be connected to a central processing and control unit is housed in a shielding frame different from that in which this is located. central unit, this way of operating allowing the operator, when this peripheral device becomes faulty, to proceed quickly to the replacement of this device, without thereby causing a prolonged stop of operation of this central unit. The electrical connection between this peripheral device and this central unit is then ensured by means of a screened conductive cable which, fixed at one of its ends to the own electrical circuits of this device, is provided, at its other end, a shielded connector which allows this cable to be connected to the electrical circuits of this central unit. Since this central unit usually consists of one or more printed circuit boards fitted with electronic components, this shielded connector is, in general, of the type which has been described and represented in the patent of the United States of America n ° 4 337 989, this connector being made up, on the one hand of a first part of connector which, fixed to the end of the screened conducting cable, comprises an insulating body provided housings in which are inserted contact elements of a first type (for example female), these elements being connected to the conductors of the cable, this insulating body being coated with a shielding element electrically connected to the shielding sheath of this cable, on the other hand from a second connector part which, fixed to one of the faces of a circuit board of the central unit, comprises an insulating body provided with housings in which are inserted contact elements d '' 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 each other, these contact elements of the second type being connected és the circuits of the circuit card. The insulating body of this second connector part, which is mounted on the circuit board so that its coupling face is perpendicular to the plane of this board, is coated, on its face opposite to that which is in contact with this card, as well as on its two lateral faces which are adjacent to its coupling face, of a metal cover which, projecting from the ends of the contact elements which start from this coupling face, makes it possible to form a cavity in which can be engaged the first part of the connector. This cover, which thus ensures correct guiding of this first connector part during this engagement, also serves as shielding for the contact elements. For this purpose, this cover is provided with metal tabs which are fixed on conductive areas formed on one of the faces of the circuit card, these conductive areas themselves being electrically grounded. When the assembly constituted by this circuit board and this second connector part is placed inside a metal shielding chassis, this grounding is obtained by simply connecting these conductive zones to the metal parts which, mounted at inside this chassis, are provided to support this assembly. So that the first connector part, which is mounted at the end of the shielded conductive cable, can be coupled to this second connector part, this chassis is naturally provided with an opening opposite which the second connector part is positioned. , this opening having dimensions greater than those of this first connector part, which allows the operator to conveniently perform, without being hindered, the coupling of these two connector parts. Furthermore, the metal cover which covers the second connector part is further provided with elastic conductive fingers which, when the first connector part is coupled to this second connector part, come into contact with the shielding element of this first part. Under these conditions, it is understood that, when these two connector parts are coupled to each other, this shielding element and the cable shielding sheath are both earthed, through, successively , elastic fingers, metal cover, conductive areas of the circuit card, metal parts for fixing this card to the chassis and finally, conductors which normally connect this chassis to earth. This way of doing things naturally requires that the circuit card comprises, in addition to the usual conductors used for the transmission of electrical signals or for the application of electrical potentials of given values, particular conductive zones which allow the shielding cover to on the one hand to be firmly fixed on this card, on the other hand to be electrically connected to the chassis. However, the presence of these conductive zones has the drawback of requiring a relatively large space on the surface of the card, which leads either to significantly increase the dimensions of this card, or to greatly increase the density of the other conductors implanted. on this one. In addition, these conductive areas, which are located close to these other conductors, present the risk of being involuntarily brought into contact with them and thus causing short-circuits. In addition, the conductive portion of the circuit which is constituted by the shielding element of the first connector part, the elastic fingers, the metal cover, the conductive zones and the metal parts for fixing the card to the chassis, has substantially the form of a loop which is located almost entirely inside the chassis. As a result, the high frequency parasitic electric currents which arise in the cable shielding sheath, under the action of electromagnetic radiation which prevails outside the chassis, generate, when they pass through this conductive portion for s '' flow normally towards the earth, an electromagnetic radiation which is all the more important as the area of the loop constituted by this conductive portion is larger and that the frequency of these parasitic currents is higher. This electromagnetic radiation which is generated inside the chassis by this conductive portion then risks seriously disturbing the electrical circuits that this chassis was supposed to protect.

The present invention overcomes the drawbacks of the prior art and proposes a shielding chassis capable of effectively ensuring the protection, against external electromagnetic radiation, of an electrical circuit which, placed inside this chassis, is connected to a shielded conductive cable outside this chassis, via a connector comprising two complementary parts, one of which, shielded, is fixed to one end of the cable and the another, placed inside the chassis, is connected to this electrical circuit. This effective protection is ensured even in the case where this other connector part is itself coated with a shielding cover connected to the chassis by means of a circuit portion extending inside this chassis.

More specifically, the present invention relates to a shielding chassis intended to ensure the protection, against external electromagnetic radiation, of at least one electrical circuit placed inside this chassis, this chassis being connected to earth and being provided with '' at least one opening for the passage of a first shielded connector part fixed to one end of a shielded electrical cable, so that this first part can be coupled to a second connector part which, complementary to said first part, is connected to said electrical circuit and is placed, inside said chassis, opposite this opening, this chassis being characterized in that it is further provided with an elastic conductive connecting element which is fixed on this chassis so to be moved by the first connector part before the end of the movement made by this first part when it is engaged da ns said opening to be coupled to said second connector part, the displacement undergone by this connecting element allowing the latter to come to bear, under the effect of the elastic deformation undergone, on the shielding element of this first connector part, so that the parasitic currents induced by said electromagnetic radiation pass directly from said shielding element to said chassis without penetrating inside this chassis.

• - la figure 1 est une vue en coupe montrant un châssis de blindage réalisé selon l'invention et à l'intérieur duquel est placé un circuit électrique destiné à être raccordé, par l'intermédiaire d'un connecteur blindé, à un câble électrique blindé placé à l'extérieur de ce châssis,
• - la figure 2 est une vue en élévation du châssis de blindage qui a été représenté sur la figure 1, cette vue étant destinée à montrer la forme de l'élément de liaison conducteur élastique qui équipe ce châssis,
• - la figure 3 est une vue en coupe montrant la position occupée par l'élément de liaison conducteur élastique du châssis de blindage lorsque les deux parties du connecteur blindé sont accouplées l'une à l'autre,
• - la figure 4 est une vue en coupe partielle montrant un châssis de blindage de l'art antérieur, cette vue étant destinée à illustrer la manière dont un rayonnement électromagnétique peut être produit, par une portion conductrice de circuit, à l'intérieur du châssis de blindage, et
• - la figure 5 est une vue montrant une autre forme sous laquelle peut se présenter l'élément de liaison conducteur élastique qui équipe le châssis de blindage représenté sur la figure 1.

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 sectional view showing a shielding frame produced according to the invention and inside which is placed an electrical circuit intended to be connected, via a shielded connector, to a shielded electrical cable placed outside this chassis,
• FIG. 2 is an elevation view of the shielding chassis which has been shown in FIG. 1, this view being intended to show the shape of the elastic conductive connecting element which equips this chassis,
• FIG. 3 is a sectional view showing the position occupied by the elastic conductive connecting element of the shielding frame when the two parts of the shielded connector are coupled to each other,
• - Figure 4 is a partial sectional view showing a shielding frame of the prior art, this view being intended to illustrate the manner in which electromagnetic radiation can be produced, by a conductive portion of the circuit, inside the frame shielding, and
• FIG. 5 is a view showing another form in which the elastic conductive connecting element which is fitted to the shielding chassis shown in FIG. 1 may appear.

In order to better understand the principles of construction and the advantages of the armor frame produced according to the invention, we will first recall, with reference to FIG. 4, the way in which, in the prior art, the protection is produced of an electrical circuit against the effects of electromagnetic radiation, this circuit being placed inside a shielding frame and being connected, via a shielded connector, to a shielded electrical cable placed at the exterior of this chassis. The shielding frame 10 which has been partially represented in FIG. 4 essentially consists of a metal case 11 closed at its upper part by a removable cover 12 which can be removed in order to allow access to the interior of the housing. This box contains an electrical circuit which, in the embodiment shown in FIG. 4, is established on a printed circuit board 13 and is intended to be connected to a shielded electrical cable 14 via a shielded connector 15 As can be seen in FIG. 4, this connector 15, which is of the type which has been described and represented in the aforementioned patent of the United States of America No. 4,337,989, comprises two parts, one 15A is fixed to one end of the shielded cable 14 and the other 15B of which is mounted on one of the faces of the circuit card 13. The connector part 15A, which has also been shown in FIG. 1, comprises, as can be seen with reference to this last figure, an insulating body 16A, of parallelepiped shape, provided with housings in which are inserted contact elements 17, of female type, which are connected to the electrical conductors 18 of the cable bl indie 14. The insulating body 16A is coated with a shielding element 19 which, as shown in FIG. 4, is in contact with the metallic shielding sheath 20 of the cable 14. The connector part 15B which is represented on the FIG. 4 comprises an insulating body 16B which is provided with housings into which are inserted contact elements 21, of the male type, these contact elements protruding on a coupling face 22 of the insulating body 16B and being established so as to be brought into contact with the contact elements 17 of the connector part 15A when these two parts are coupled to each other. This insulating body 16B is mounted on the circuit card 13 so that its coupling face 22 is perpendicular to the plane of this card. In the example illustrated in FIG. 4, the circuit card 13 is arranged horizontally and, consequently, the insulating body 16B, which is mounted on the upper face of this card, is placed in a position in which its face coupling 22 is vertical. The contact elements 21 pass entirely through the insulating body 16B and, thus projecting from the face 23 of this body which is opposite to the coupling face 22, are extended by portions which are bent at right angles so as to be engaged in holes in the card 13 to be soldered to conductors carried by this card. FIG. 4 also shows that the insulating body 16B is coated, on its upper face and on its two vertical lateral faces which are adjacent to the coupling face 22, with a metal cover 25. This cover, which has, in a direction perpendicular to the figure plane, a U-shaped cross section overturned, extends beyond the ends of the contact elements 21 which start from the coupling face 22 and thus defines a cavity 26 which, intended to receive the connector part 15A, ensures the correct guiding of this connector part when the latter is engaged in this cavity to be coupled to the connector part 15B. The cover 25 is provided, at its lower part, with metal tabs 27 which are fixed, by means of screws or by welding, on conductive zones 28 of the circuit board 13, and which allow this cover to be held firmly attached to this card. When the assembly constituted by the circuit card 13 and the connector part 15B is placed inside the chassis 10, these conductive zones 28 are themselves fixed on metal parts 29 which, integral with the housing 11, are provided to maintain and support this set. Because the housing 11, which serves as a shield for this assembly, is normally connected to earth, it can then be seen that the metal cover 25 is also earthed, via the tabs 27, of the conductive zones 28 , metal parts 29 and the housing 11. So that the connector part 15A, which is mounted at the end of the shielded conductive cable 14, can be coupled to the connector part 15B, the housing 11 is naturally provided with a opening 30 in front of which is positioned this connector part 15B. It can be seen, in FIG. 4, that this opening 30 has dimensions greater than those of the connector part 15A, so that this opening does not hinder the passage of this connector part and allows the operator to carry out conveniently the coupling of the two connector parts 15A and 15B. Furthermore, the continuity of the shielding between the two connector parts 15A and 15B is ensured by elastic conductive fingers which form part of the metal cover 25, these fingers, one of which 31 has been shown in FIG. 4, being formed on the edges of the cover which are located near the open end of the cavity 26 and being folded inwards of this cavity, as indicated in the figure, so as to come to be applied on the shielding element 19 of the connector part 15A which has been introduced into this cavity. Under these conditions, it is understood that, when the two connector parts 15A and 15B are coupled to each other, the shielding sheath 20 of the cable 14 and the shielding element 19 of the part 15A are both earthed, successively by means of elastic fingers 31, metal cover 25, tabs 27, conductive zones 28, metal parts 29 and box 11. However, if the box 11 and the shielded cable 14 which is connected to the electrical circuit contained in this box are in a region where electromagnetic radiation is produced by other circuits or devices placed outside this box , these radiations induce, in the shielding sheath 20 of this cable, parasitic electric currents which circulate in the direction indicated by arrows in FIG. 4, in order to flow towards the earth. It can be seen in FIG. 4 that these parasitic currents necessarily flow in a portion of the circuit located entirely inside the housing 11, this portion of the circuit comprising the part of the shielding element 19 which has been introduced into this housing , the elastic fingers 31, the metal cover 25, the tabs 27, the conductive areas 28 and the metal parts 29. This portion of the circuit, when crossed by these parasitic currents, then generates electromagnetic radiation which is all the more more important than the surface of the loop constituted by this portion of circuit is larger and that the frequency of these parasitic currents is higher. This electromagnetic radiation, which is thus generated inside the housing 11 by this portion of circuit, then risks seriously disturbing the electrical circuits of the circuit card 13.

The shielding frame produced according to the invention does not have this drawback. As can be seen in Figure 1, this chassis, which has great similarities to that of Figure 4, consists of a housing 11 closed by a cover 12 and containing an electrical circuit formed on a circuit board 13. This circuit is intended to be connected to a shielded electrical cable (not shown), of the type shown in FIG. 4, via a connector made up of two parts, one of which 15A, is fixed to one end of this cable, and the other 15B of which is mounted on the circuit board 13. The connector part 15A is similar to that which has been described above. In the embodiment illustrated in FIG. 1, the connector part 15B comprises an insulating body 16B having a recess 26 dimensioned so as to allow the connector part 15A to be engaged with a small clearance in this recess, the bottom of it constituting the coupling face of the connector part 15B. The contact elements 21, of the male type, which protrude on this coupling face 22, are established so as to be brought into contact with the contact elements 17 of the connector part 15A when these two parts 15A and 15B are coupled to each other. The contact elements 21, which pass entirely through the insulating body 16B, protrude from the face 23 of this body which is opposite to the coupling face 22 and are extended by conductive portions which are bent at right angles so as to be able be connected to the conductors of the card 13. Figure 1 shows that the connector part 15B is positioned so that its recess 26 is located opposite the opening 30 of the housing 11, the fixing of this connector part on the card 13 being produced in a known manner, for example by means of screws 32 which, engaged in holes in the card 13, are screwed into corresponding threaded housings of the insulating body 16B. The opening 30 is made so as to have dimensions greater than those of the cross section of the connector part 15A, so that this part can pass without being obstructed by this opening to be coupled to the connector part 15B. This characteristic appears moreover in FIG. 2 in which the position occupied in the opening 30 by the outline of the cross section of the connector part 15A is represented by a dashed line 33 when the latter is coupled to the connector part 15B, this line 33 being naturally situated inside the contour formed by the edge 34 of the opening 30.

However, as can be seen with reference to FIGS. 1 and 2, the housing 11 is provided with a non-metallic elastic conductive connecting element which, in the example described, is in the form of a membrane 35 , this membrane being fixed on this housing, around the opening 30, so as to come into contact with the shielding element 19 of the connector part 15A when the latter is coupled to the connector part 15B. In the embodiment illustrated in FIGS. 1 and 2, the membrane 35 is kept applied to the wall of the housing which is close to the opening 30, by means of a hollow plate 36 which is fixed to the housing 11 at the using rivets 37. This membrane 35 is provided with a central opening 38 which, like the opening 30, is rectangular in shape, but has dimensions smaller than those of the cross section of the connector part 15A, this opening 38 being indeed limited by an edge 39 which, as shown in FIG. 2, is located inside the contour formed by the line 33 representative of the position occupied, in opening 30, by this cross section. Under these conditions, when the connector part 15A is engaged in the opening 30 to be coupled to the connector part 15B, the portion of this membrane which, around the opening 38, is located on the path followed by this part 15A connector is pushed back into the housing by this connector part and thereby undergoes bending. However, since the membrane 35 is elastic, this portion tends to resume its original shape and it therefore comes to be applied, as can be seen in FIG. 3, to the shielding element 19 while ensuring contact pressure all around this shielding element, that is to say on the four faces of this element. Therefore, the shielding element 19 is connected to earth via the membrane 35 and the housing 11. It is then understood that if the housing 11 and the shielded cable 14 which is connected to the electrical circuit contained in this box is located in a region where electromagnetic radiation prevails, the parasitic electric currents which are induced by this radiation in the shielding sheath 20 of this cable circulate, as indicated by the arrows represented in FIG. 3, passing successively through the shielding element 19, the membrane 35 and the housing 11, to finally flow towards the ground. These parasitic currents, which therefore do not circulate in any portion of the circuit located inside the housing 11, are not likely to generate electromagnetic radiation inside this housing.

dans laquelle r désigne la résistivité électrique du matériau constitutif de la membrane 35 et S représente le produit de l'épaisseur de cette membrane par la longueur de la ligne 33, cette longueur étant celle du contour de la section droite de la partie de connecteur 15A. Dans le cas où la longueur de cette ligne 33 est sensiblement égale à 50 mm, cette résistance est, compte tenu des valeurs de r et de L mentionnées plus haut, au plus égale à 0,12 ohm pour une membrane ayant une épaisseur de 1 mm.The material which is used to make the membrane 35 is a non-metallic elastic conductive material, that is to say a conductive material which, not being composed entirely of metal, has a significantly higher mechanical flexibility than that of a metal or a metal alloy. This material consists of a conductive elastomer, that is to say an elastomer in which metallic conductive particles have been incorporated, for example silver, gold, nickel or aluminum, the percentage, in volume, of these conductive particles in this elastomer generally being between 30% and 70%. In the example described, this elastomer preferably consists of a silicone rubber loaded with fine flakes or fine spherical granules of nickel or aluminum, this conductive elastomer having an electrical resistivity not exceeding 0.2 ohm-cm and one elongation at break less than 300%. Furthermore, the thickness of the membrane 35 is between 0.5 and 3 mm, the value preferably adopted being practically equal to 1 mm. It should also be indicated that, to facilitate the passage, through the central opening 38 of the membrane 35, of the connector part 15A, without requiring great efforts on the part of the operator, this opening 38 is dimensioned so that the distance D which separates its edge 39 from the line 33 representative of the position occupied, in the opening 30, by the cross section of this connector part, is at most equal to 3 mm. It should also be noted that, as can be seen with reference to FIG. 2, the opening 30 of the housing 11 is dimensioned so that its edge 34, which is situated outside the contour formed by this line 33 , is at a very small distance L from this contour, this distance L being in fact at most equal to 3 mm. Under these conditions, the portion of the membrane 35 which is between the edge 34 and the line 33 and which is taken by the parasitic electric currents to go from the shielding element 19 to the housing 11, has an electrical resistance whose value R is given by the well known expression:
R = r $\frac{\text{L}}{\text{S}}$

in which r denotes the electrical resistivity of the material constituting the membrane 35 and S represents the product of the thickness of this membrane by the length of the line 33, this length being that of the contour of the cross section of the connector part 15A . In the case where the length of this line 33 is substantially equal to 50 mm, this resistance is, taking into account the values of r and L mentioned above, at most equal to 0.12 ohm for a membrane having a thickness of 1 mm.

It should also be noted that, although in the embodiment illustrated in Figures 1 and 3, the connector part 15B has been established so as to prevent the shielding element 19 of the connector part 15A is connected to the earth by means of the metal parts 29, the housing 11 which has been shown in these two figures 1 and 3 can also be used to protect, against the effects of electromagnetic radiation, the circuits of a card to circuits 13 which would be provided with a connector part 15B similar to that which is shown in FIG. 4. In this last embodiment, the shielding element 19 of the connector part 15A is then connected to the housing 11, on the one hand via a circuit portion which, located inside this housing, comprises, as we saw above, the elastic fingers 31, the metal cover 25, the tabs 27, the conductive zones 28 and the metal parts 29, on the other hand via the portion of the membrane 35 which is between the edge 34 and the line 33. It should however be noted that the portion of the circuit which is located at the interior of the housing has, due to its relatively large length and the reduced section of the fingers 31 and the tabs 27, an electrical resistance of the order of 0.03 ohm. This portion of the circuit also has an impedance due to the inductance resulting from the loop made by the parasitic electric currents, this impedance having a value substantially equal to 0.1 ohm when the frequency of these currents is 10 megahertz and a value close to 1 ohm when the frequency of these currents is 100 megahertz. Since the frequency of these currents is generally greater than 10 megahertz, it can therefore be seen that this portion of the circuit has a total impedance greater than 0.11 ohm. However, in this case, the membrane 35 is made of a silicone rubber loaded with fine particles of nickel or aluminum and having an electrical resistivity at most equal to 0.01 ohm-cm. Under these conditions, the portion of the membrane 35 which is between the edge 34 and the line 33 has, taking into account the numerical values indicated above, an electrical resistance at most equal to 0.006 ohm, this portion of the membrane thus having an impedance which is at least 20 times weaker than that of the circuit portion located inside the housing. As a result, the high frequency parasitic currents which are induced in the shielding sheath of the cable 14 by the electromagnetic radiation prevailing outside the housing 11, practically do not pass through the portion of the electrical circuit formed by the fingers 31, the cover 15, the tabs 27, the conductive zones 28 and the metal parts 29, and that these parasitic currents, in order to reach the housing 11 and flow towards the earth, mainly pass through the membrane 35. Consequently, no electromagnetic radiation is present. is generated inside the housing 11 by these parasitic currents.

It may happen that it is necessary to connect to the electrical circuit of the circuit card 13, not just one, but several shielded electrical cables. In the case where the parts of connectors which are fixed to one end of each of these electric cables differ from each other, in particular by their dimensions or their shapes, it is then essential that the housing 11 is provided with several openings , each of these openings being established so as to leave a passage allowing each of these connector parts to be introduced inside the housing to be coupled to a complementary connector part. In a more particularly advantageous embodiment, these openings can be located on the same face of the housing. This has been shown, by way of example, in FIG. 5 where one 40 of the enclosure plates of the housing 11 is provided with three openings 30A, 30B and 30C, one of which, 30A, is of rectangular shape, of which another, 30B, is circular, and of which the last 30C, is of square shape, these three shapes corresponding to the shapes of the straight sections of the connector parts intended to be engaged in these openings. In the case where these openings are relatively close to one another, it may be advantageous to provide, for these three openings, not three, but only one membrane 35 of elastic conductive material, this membrane being dimensioned so as to extend , when it is fixed to the enclosure plate 40, on all of these three openings, this membrane 35 being itself provided with three openings 38A, 38B, 38C centered, each respectively, on each of the openings 30A, 30B and 30C of the plate 40, in a manner similar to that which is represented in FIG. 2.

It should also be noted that, because the conductive membrane 35 has elastic properties, the opening 38 of this membrane can be produced without requiring rigorous machining tolerances, the only condition necessary for the application of this membrane all around of the shielding element 19 being in fact that the edge 39 of this opening is located inside the contour formed by the line 33 which represents the position occupied, in this opening, by the cross section of this shielding element. As a result, the circuit card 13 can be mounted inside the chassis 10 without requiring precise positioning, provided, however, that the condition which has just been stated is observed.

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. Shielding chassis intended to protect, against external electromagnetic radiation, at least one electric circuit placed inside this chassis (10), this chassis being connected to earth and being provided with at least an opening (30) for the passage of a first shielded connector part (15A) fixed to one end of a shielded electrical cable (14), so that this first part (15A) can be coupled to a second connector part (15B) which, complementary to said first part, is connected to said electrical circuit and is placed, inside said chassis, opposite this opening (30), this chassis being characterized in that it is further provided with '' an elastic conductive connecting element (35) which is fixed on this chassis so as to be moved by the first connector part (15A) before the end of the movement made by this first part when the latter is engaged in said opening to be coupled to this second connector part, the displacement undergone by this connecting element allowing the latter to come to bear, under the effect of the elastic deformation undergone, on the shielding element (19) of this first connector part (15A), so that the parasitic currents induced by said electromagnetic radiation pass directly from said shielding element to said chassis without penetrating inside this chassis. 2. Shielding frame according to claim 1, characterized in that the elastic conductive connecting element (35) is non-metallic. 3. Shielding frame according to claim 2, characterized in that the non-metallic elastic conductive connecting element (35) consists of a membrane (35) of elastic conductive material, this membrane, fixed all around the opening (30 ) of the chassis, being provided with a central opening (38) having practically the same shape as that of the contour (33) of the cross section of the first connector part (15A), but of dimensions smaller than those of the shape of this outline. 4. Shielding frame according to claim 3, characterized in that the membrane (35) is made of a conductive elastomeric material having an electrical resistivity at most equal to 0.2 ohm-centimeters. 5. Shielding frame according to claim 4, characterized in that the conductive elastomeric material is a silicone rubber containing conductive metallic particles, the percentage, by volume, of these particles in this material being between 30% and 70%. 6. Shielding frame according to claim 5, characterized in that the conductive metal particles consist of fine particles of silver, gold, nickel or aluminum. 7. Shielding frame according to claim 6, characterized in that the thickness of the membrane (35) is between 0.5 and 3 millimeters. 8. Shielding frame according to claim 7, characterized in that the opening (30) of this frame is dimensioned so that its edge (34) is located at a distance (L), at most equal to 3 mm, d a line (33) representing the position occupied, in this opening (30), by the outline of the cross section of the first connector part (15A) when the two connector parts (15A and 15B) are coupled together . 9. Shielding chassis according to claim 8, in which the second connector part (15B) is coated with a metal cover (25) which, connected to this chassis (10) via a conductive circuit portion ( 27, 28, 29) extending inside this chassis, is established to be brought into contact with the shielding element (19) of the first connector part (15A) when the latter is coupled to said second connector part (15B), this chassis being characterized in that the membrane (35) is made of a conductive elastomer material having a thickness at least equal to 1 mm and having an electrical resistivity at most equal to 0.01 ohm- centimeter. 10. Shielding frame according to any one of claims 3 to 9, characterized in that the central opening (38) of the membrane (35) is dimensioned so that its edge (39) is located at a distance ( D), at most equal to 3 mm, of a line (33) representing the position occupied, in the opening (30) of the chassis, the outline of the cross section of the first connector part (15A) when the two connector parts (15A and (5B) are coupled together.

Images