The invention concerns a plug insert for receiving at least one contact element, the plug insert comprising at least one receptacle for at least partially receiving the at least one contact element, wherein the plug insert has a plug side and a contact side which is opposite to the plug side.

Especially in the automotive industry it is desirable to tap off or feed high-frequency and/or interference-prone signals from into the vehicle bus by means of connectors customary in this field of application, such as FAKRA (specialized automotive) connectors or HSD (high speed data) connectors. It is advantageous for this when the connectors used are combined in a bus adapter.

This combination may take place in a plug insert, which provides a plug face with the usual connectors starting at the vehicle bus, so that for example peripheral devices having such a plug connection can be connected to the vehicle bus by means of the plug insert.

At the vehicle side it is advantageous to connect the plug insert electrically to a circuit board designed for this, in which case narrow positioning tolerances are needed in order to enable surface mounting on the circuit board and soldering, press-fitting, or similar joining process.

In the solutions of the prior art, and owing to the nested design of the aforementioned exemplary connector systems (FAKRA / HSD), it is sometimes not possible or very difficult to maintain the positioning tolerances of the contacts.

Moreover, the aforementioned exemplary connector systems are preferably provided with a shielding, and they likewise advantageously have a shielding when combining different connector systems in a plug insert.

Thus, the problem which the present invention proposes to solve is to create a plug insert for bringing together several shielded connectors or shielded with unshielded connectors in an overall connector, making it possible to maintain narrow positioning tolerances of the soldering pins to be soldered or the press-fit pins to be press-fitted used.

The plug insert of the kind mentioned at the start solves this problem in that in the at least one receptacle, which connects the plug side and the contact side, at least one positioning element, which is accessible from the plug side and the contact side for positioning a contact pin of the at least one contact element, is at least partially received in the at least one receptacle.

Such a positioning element according to the invention has the advantage that the soldering pins of the connectors assembled in the plug insert are guided in relation to the plug insert and fixed in their spatial position. This makes it possible to guarantee the required soldering tolerances.

In the following, inherently advantageous embodiments of the present invention shall be described. Technical features of the described embodiments may be combined in any desired manner and individual technical features may be left out, as long as the technical effect achieved by the omitted technical feature is not important.

The receptacle may be understood as an aperture in the plug insert from the plug side to the contact side. It is conceivable to accommodate the most different contact elements, such as those in the form of a plug or a bushing, in the at least one receptacle.

The positioning element may be designed for the desired geometry of the connector being received, i.e., it may have a corresponding number and size and geometry of supporting sections of the positioning element, so that the complementary geometry of the plug, especially its individual contact pins, may be held or supported by the positioning element.

Since the positioning element is accessible from the plug side and the contact side, an element being positioned may be introduced into the positioning element or mounted on it from both sides.

In one embodiment of the plug insert according to the invention, the at least one positioning element is connected by means of at least one connecting web to the receptacle. Such a connecting web has the advantage that the position of the positioning element may be established directly in relation to the plug insert.

The connecting web may preferably be connected monolithically to the receptacle, or it may be designed separately and secured with suitable means in the at least one receptacle.

In another embodiment of the plug insert according to the invention, at least one centring opening is provided in the positioning element to receive the contact pin in the at least one positioning element, wherein the at least one centring opening is designed continuous from the plug side to the contact side. A centring opening has the advantage that the position of a contact pin received therein is bounded or established along every direction perpendicular to the inserting direction.

The at least one centring opening is to be understood to the effect that it allows a centring of a contact pin about or in the desired position of the contact pin (which is within the given positioning tolerances). The position of the received contact pin or the centring opening may be arranged off-centre in the positioning element, especially if several centring openings are provided (which is the case for example with a FAKRA plug connection).

However, the at least one centring opening may also be arranged substantially centrally in the positioning element.

In one embodiment of the plug insert according to the invention, at least two connecting webs hold the at least one positioning element substantially symmetrically in the at least one receptacle. The use of two connecting webs has the advantage that the stability of the position of the positioning element in relation to the plug insert is significantly increased. Since the bracing of the at least one contact element against or in the positioning element when the at least one contact element is inserted is accompanied by a mechanical resistance, wherein the effective direction may constantly vary during the inserting process, it is advantageous to design the connecting webs symmetrically, so that the at least two connecting webs are designed for identical loading by the inserting process.

In particular in a monolithic embodiment of the plug insert with the at least one positioning element it is advantageous from a process technology standpoint to provide at least two symmetrically disposed connecting webs. The plug insert with monolithically designed positioning element may be produced for example by means of injection moulding, where during the injection moulding process a positioning element connected by means of a single connecting web to the plug insert would be less advantageous, since such a single connecting web upon removal of the injection moulding die and possible further machining (deburring) could easily break.

Since the requirements for the material of the positioning element may be different from the requirements for the material of the plug insert, the positioning element may have a material different from the plug insert or a different material composition.

Thus, the material of the positioning element may be optimized for example in terms of its electrical properties, e.g., the permittivity or its electrical resistance.

The material of the plug insert on the other hand may have advantageous mechanical properties, e.g., high breaking stress and shock resistance.

The monolithic connection between the plug insert and the positioning element may be realized for example by means of 2-shot injection moulding, also known as 2-component injection moulding. When this method is used, the plug insert could be produced in a first injection moulding step, and the positioning element in a second injection moulding step, the plug insert and the positioning element being monolithically joined together.

In a further embodiment of the plug insert according to the invention, at least one aperture is located in the circumferential direction about the at least one positioning element, wherein the aperture is designed continuous from the plug side to the contact side. The at least one aperture may be provided to receive a shielding element. Moreover, depending on the geometry of the positioning element, the at least one aperture may have different cross sections. Thus, for example, the aperture may be rectangular, N-gonal, or a segment of a circular ring.

Especially if the at least one positioning element has a rectangular cross section, the at least one aperture, preferably the apertures, may have a shape which is complementary to the outer contour of the positioning element.

The connecting webs may be joined at various positions to the rectangular (for example) positioning element, so that an aperture may extend only along one side edge of the rectangle or around one corner of the rectangle.

If the positioning element is circular in shape, the at least one aperture may have the shape of a circular ring segment. By a circular ring segment is meant a geometrical shape based on a circular ring, which is sectioned in the radial direction at two different places, starting from the centre of the circular ring.

In a further embodiment of the plug insert according to the invention, the plug insert has at least one plug-side and at least one contact-side connecting web, wherein the at least one plug-side and the at least one contact-side connecting web are offset relative to each other in the circumferential direction around the at least one positioning element and relative to each other toward the plug or contact side.

The offset of the at least one contact-side or plug-side connecting web relative to each other has the advantage that the stability of the attachment of the positioning element to the plug insert may be further increased.

In other words, in this embodiment of the plug insert the at least one plug-side connecting web protrudes into the aperture formed by the at least one contact-side connecting web, wherein the at least one connection-side connecting web protrudes into the aperture formed by the at least one plug-side connecting web.

Thus, this embodiment has two sets of connecting webs, wherein the connecting webs of the first set may be arranged on the positioning element toward the contact side, and the connecting webs of the second set on the positioning element toward the plug side.

The apertures which are formed by the contact-side connecting webs may thus be bordered at least partly by the plug-side connecting webs, and the apertures formed by the plug-side connecting webs may be bordered at least partly by the contact-side connecting webs.

In a further embodiment of the plug insert according to the invention, a receiving pocket is arranged in the receptacle for at least partial receiving of a shielding element. The embodiment of a receiving pocket has the advantage that, for example, a shielding element may be received in the receiving pocket and another shielding element is arranged at the side of the receiving pocket, so that the two shielding elements overlap.

The receiving pocket may be arranged along the inner circumference of the receptacle and open either toward the plug side or the contact side.

Likewise, the receiving pocket may be designed between the at least one connecting web and the at least one positioning element. That is, the receiving pocket may be formed on the outer circumference of the positioning element.

The receiving pocket formed on the outer circumference of the positioning element may also be open toward the contact side or the plug side.

The receiving pocket may be formed for at least a portion as a circular ring and be designed to receive a complementary shielding element, i.e., one which is a hollow cylinder for at least a portion.

In particular, the receiving pocket may be formed entirely around the inner circumference of the receptacle or the outer circumference of the positioning element, i.e., without interruption.

An outer wall of the receiving pocket may furthermore pass into a connecting web. Such a connecting web may thus be situated between the receiving pocket and the positioning element or between the receiving pocket and the inner wall of the contact chamber.

In a further embodiment of the plug insert according to the invention, the receiving pocket in one direction of extension of the receiving pocket overlaps the at least one connecting web entirely or extends beyond the at least one connecting web. If two shielding elements are received from different sides of the plug insert in this embodiment of the plug insert, this embodiment ensures an overlapping of the shielding elements.

Purely as an example, a first shielding element may be inserted from the contact side into a receiving pocket arranged on the outer circumference of the positioning element, wherein from the plug side a second shielding element having a larger diameter in the radial direction than the first shielding element is received in the receptacle, can be inserted in such a manner, until it abuts against the connecting web which joins the positioning element to the inner wall of the receptacle. Since the receiving pocket of the first shielding element may protrude in the direction of the plug side beyond the connecting web and furthermore the second shielding element may be received as far as the connecting web in the receptacle, an overlapping of the first shielding element with the second shielding element is assured.

It is likewise conceivable for the at least one connecting web to be formed continuous about the entire circumference, so that each time a receiving pocket is formed both on the plug side and on the contact side. Such receiving pockets may also be conceived as being circumferentially arranged grooves in a shoulder of the inner wall of the receptacle or the outer wall of the positioning element.

In a further embodiment of the plug insert according to the invention, an electromagnetic shielding comprising at least two shielding elements is provided, whose shielding elements are each received from either the plug side or the contact side at least partially in the at least one receptacle and form the electromagnetic shielding. The embodiment of the electromagnetic shielding in several parts, i.e., with at least two shielding elements, has the advantage that this modular layout of the electromagnetic shielding may be used in combination with the previously described embodiments of the plug insert and furthermore a continuous electromagnetic shielding is assured.

This embodiment of the present invention thus makes it possible furthermore to assure an electromagnetic shielding when several shielded connectors or shielded with unshielded connectors are assembled.

The modular electromagnetic shielding may have substantially the same geometrical dimensions as a one-piece shielding of the connector being used. Unlike the solutions of the prior art, such a modular electromagnetic shielding is not introduced into the plug insert from one side, but instead the at least two shielding elements are each received in the at least one receptacle from the plug side and the contact side, respectively.

In a further embodiment of the plug insert according to the invention, the at least two shielding elements are each arranged at least partially between the at least one positioning element and an inner wall of the at least one receptacle. Such an arrangement of the shielding elements has the advantage that the at least one contact element is fully enclosed by the shielding elements.

Preferably at least one of the at least two shielding elements may directly border on the inner wall of the receptacle, so that on the one hand the electromagnetic shielding is stabilized or secured in its position with regard to the plug insert and on the other hand the at least one receptacle can be utilized optimally to receive the at least one contact element.

The at least two shielding elements may be configured as a hollow cylinder at least partially or represent sections of a hollow cylinder which when assembled with each other yield a hollow cylinder.

In a further embodiment of the plug insert according to the invention, one end of one of the at least two shielding elements overlaps at least partially with one end of at least one other of the at least two shielding elements. Thanks to such an overlapping, a substantially complete electromagnetic shielding and interference suppression of the volume enclosed by the electromagnetic shielding is assured. The previously described electrical connectors may be located in this volume.

In a further embodiment of the plug insert according to the invention, at least one of the at least two shielding elements has at least one recess at one end in the circumferential direction, so that a toothing is formed. The recess or recesses have the advantage that a connecting web may be received therein, so that the remaining toothing, that is sections of the shielding element, may extend beyond the connecting web.

Depending on the number of the connecting webs, at least one of the at least two shielding elements may be provided with a number of recesses corresponding to the number of connecting webs.

Moreover, shielding elements provided with a toothing have the advantage that, by virtue of the mechanical engagement of the connecting web in the at least one recess, they can no longer rotate about their longitudinal axis, so that a force acting tangentially on the plug-side shielding element is not transmitted to the contact-side shielding element.

A decoupling of the rotation between the plug-side shielding element and the contact-side shielding element is already provided to a certain degree by the modular design consisting of at least two shielding elements. By a decoupling to a certain degree is meant that, given enough friction between the at least two shielding elements, a rotation might still be transmitted.

The teeth of the toothing may have a circular ring segment-shaped cross section, a rectangular cross section, an N-gonal cross section or a cross section of any other shape.

At least two shielding elements may have such a toothing, overlapping each other in forklike manner when the electromagnetic shielding is assembled and thus ensuring a gap-free shielding.

The fastening of the at least two shielding elements on or in the plug insert may be done by press-fit and/or detent geometries.

In a further embodiment of the plug insert according to the invention, the toothing of the shielding element received at least partially in the receptacle from the plug side is configured to be substantially complementary to the toothing of the shielding element received at least partially in the receptacle from the contact side. A complementary embodiment of the toothings makes it possible for the recesses of one shielding element to be covered with a tooth of the toothing of a second shielding element.

In a further embodiment, the toothings of the at least two shielding elements overlap each other at least partially. An overlapping of the toothings at least partially has the advantage that the plug insert, especially the receptacle, the at least one connecting web and the positioning element may be more simple in design. This embodiment may be chosen, for example, if despite incomplete overlapping of the two shielding elements, i.e., with free sites remaining in the electromagnetic shielding, the tolerance value for the injecting of interference signals through the free sites into the volume enclosed by the shielding elements at least partially is not exceeded.

The size of the free sites may correspond substantially to the size of the cross section of the connecting webs.

In a further embodiment of the plug insert according to the invention, a spacing exists between the toothings overlapping at least partially, which spacing is less than a material thickness of the shielding elements.

It is advantageous to keep the spacing between the overlapping regions of the shielding elements as small as possible, in order to prevent a slanting passage of electromagnetic radiation through the overlap area without impinging on a section of a shielding element.

In the following, the plug insert according to the invention shall be explained more closely with the aid of enclosed drawings. The drawings show specific exemplary embodiments of the present invention. The technical features of the individual embodiments shown may be combined with each other at will or be omitted on occasion. The same technical features or features with the same technical effect are provided with the same reference numbers.

There are shown:

Fig. 1

a plug insert with receiving contact elements from the prior art;

Fig. 2

the plug insert from Fig. 1 in a rear view;

Fig. 3a and 3b

a detail of a first embodiment of the plug insert according to the invention and the corresponding modular electromagnetic shielding in the installed state;

Fig. 4a and 4b

a detail of a second embodiment of the plug insert according to the invention in partially sectioned view and front view;

Fig. 5

the modular electromagnetic shielding in the installed state for the second embodiment of Fig. 4;

Fig. 6a and 6b

a detail of a third embodiment of the plug insert according to the invention in two partially sectioned perspective views;

Fig. 7a and 7b

the rear view of the detail from Fig. 6 and the corresponding modular electromagnetic shielding in the installed state;

Fig. 8

a cross-section through the detail shown in Fig. 6 of the plug insert according to the invention with mounted modular electromagnetic shielding of Fig. 7;

Fig. 9a and 9b

a contact element with modular electromagnetic shielding in cross section and in perspective view; and

Fig. 10

a plug insert according to the invention with mounted contact pin and modular electromagnetic shielding to be installed.

Fig. 1 shows a plug insert 1 from the prior art. This plug insert 1 has a plug side 3 and a contact side 5. The plug insert 1 depicted comprises eight receptacles 7, of which only two are provided with reference numbers for better clarity.

The receptacles 7 may receive contact elements 9. Of the eight contact elements 9 depicted, again only two are provided with reference numbers.

Fig. 1 shows that different kinds of contact elements 9 may be received in the plug insert 1. The embodiment of Fig. 1 shows seven contact elements 9, designed as FAKRA connectors 9a, and one contact element 9, designed as a HSD connector 9b.

All contact elements 9 shown in Fig. 1 have an electromagnetic shielding 11 and at least one contact pin 13 which is received in the electromagnetic shielding 11.

The contact elements 9 may be inserted from the contact side 5 into the respective receptacles 7 of the plug insert. The positioning of the contact pins 13 occurs here in the embodiment of the plug insert of the prior art that is shown in Fig. 1 only indirectly via the electromagnetic shielding 11.

Fig. 2 shows the plug insert 1 depicted in Fig. 1 in a rear view, i.e., as seen from the contact side 5.

One recognizes the receptacles 7, the depicted embodiment of the plug insert 1 from the prior art having seven FAKRA receptacles 7a and one HSD receptacle 7b. The HSD receptacle 7b differs from the FAKRA receptacle 7a merely in having a different diameter d of the receptacle 7.

The receptacles 7 of the plug insert 1 of the prior art are continuous, i.e., they extend from the contact side 5 to the plug side 3.

Fig. 3a and 3b shows a detail 15 of the plug insert 1 according to the invention, whose position in Fig. 2 is indicated by means of a dashed line.

The detail 15 of the plug insert 1 shows the base body 17 of the plug insert 1, a receptacle 7 and a positioning element 19 received in the receptacle at least partially.

The detail 15 is partially sectioned in order to afford a view inside the receptacle 7. The positioning element 19 received in the receptacle 7 is not affected by the sectioning.

The positioning element 19 is joined by means of four connecting webs 21 to an inner wall 23 of the receptacle 7. The connecting webs 21 are arranged in the first embodiment shown in Fig. 3 at the end of the positioning element 19 facing the plug side 3, that is, the plug-side end 25. A contact-side end 27 of the positioning element 19 protrudes from the receptacle 7 beyond the base body 17 of the plug insert 1 toward the contact side 5. At the contact-side end 27, the positioning element 19 is not joined to the base body 17 of the plug insert 1.

The positioning element 19 is configured as a hollow cylinder 29 and has a lateral surface 29a and a centring opening 29b. The centring opening 29b is continuous from the plug side 3 to the contact side 5.

Moreover, the embodiment of the plug insert 1 according to the invention shown in Fig. 3a and 3b has a monolithically configured edge 31 arranged toward the contact side 5, which is formed all around the circumference on the inner wall 23 of the receptacle 7.

Fig. 3b shows an electromagnetic shielding 11, which is designed as a modular electromagnetic shielding 11a.

The modular electromagnetic shielding 11 a comprises, in the embodiment shown, two shielding elements 33, where one plug-side shielding element 33a is configured substantially as a hollow cylinder 29 and a contact-side shielding element 33b is received at least partially in the plug-side shielding element 33a.

The modular electromagnetic shielding 11a shown in Fig. 3b is shown in an installed state 35, i.e., the relative position of the plug-side shielding element 33a to the contact-side shielding element 33b corresponds exactly to the relative position of the two elements 33a, 33b to each other when they are received in the receptacle 7 shown in Fig. 3a.

For better clarity, the plug insert 1 is not shown in the representation of the modular electromagnetic shielding 11a.

The plug-side shielding element 33a has a toothing 37, which comprises four teeth 39 and four recesses 41 in the embodiment shown. A tapering 42 as depicted is provided on account of the embodiment as a FAKRA connector 9a.

The contact-side shielding element 33b comprises a shielding area 43 and a base area 45.

The two shielding elements 33a, 33b form an overlap area 47, wherein the depicted embodiment of the modular electromagnetic shielding 11 a has free sites 49 where no shielding of the volume V enclosed by the shielding elements 33a, 33b is present partially.

Since Fig. 3b is shown without the plug insert 1, the position of the modular electromagnetic shielding 11a present in the installed state 35 shall now be briefly discussed.

In the installed state 35, the plug-side shielding element 33a is inserted from the plug side 3 into the receptacle 7. The four connecting webs 21 are received in the four recesses 41 of the plug-side shielding element 33a. The plug-side shielding element 33a is received far enough in the receptacle 7 so that a recess abutment surface 51 present in each recess 41 lies against a plug-side abutment surface 53 present on one of the connecting webs 21, so that the teeth 39 of the plug-side shielding element 33a are received in apertures 55 formed between the connecting webs 21.

The shielding area 43 of the contact-side shielding element 33b is received from the contact side 5 in the receptacle 7, the shielding area 43 receiving the positioning element 19 at least partly, starting with the contact-side end 27. The shielding area 43 is moved through the hollow cylinder of the positioning element 19 until an abutment surface, not shown (the top edge of the cylinder of the shielding area 43 pointing to the left in Fig. 3b), comes up against a contact-side abutment surface 57 of the connecting web 21. The contact-side abutment surfaces 57 of the connecting webs 21 are arranged facing the plug-side abutment surfaces 53 and point toward the contact side 5.

The free sites 49 shown in Fig. 3b are produced in the installed state 35 of the modular electromagnetic shielding 11a on account of the connecting webs 21, since the connecting webs 21 are located in the free sites 49 and interrupt the electromagnetic shielding 11 at these sites.

Fig. 4a and 4b show a second embodiment of the plug insert 1 according to the invention in the same detail representation 15 as the first embodiment of Fig. 3.

Unlike the first embodiment of Fig. 3a and 3b, the plug insert 1 represented in Fig. 4a and 4b has four plug-side connecting webs 21 a and four contact-side connecting webs 21 b.

The plug-side connecting webs 21 a form plug-side apertures 55a, and the contact-side connecting webs 21 b form contact-side apertures 55b. The plug-side connecting webs 21a protrude into or through the contact-side apertures 55b and the contact-side connecting webs 21 b protrude through the plug-side apertures 55a.

Fig. 4b shows the plug insert 1 of the second embodiment in a front view, where the offset 58 in the circumferential direction 59 between the plug-side connecting webs 21 a and the contact-side connecting webs 41 b is recognizable. Likewise recognizable, as already described, is that each of the connecting webs 21a, 21b protrudes into an aperture 55b, 55a and through it. For better clarity, only one plug-side aperture 55a and one contact-side aperture 55b is shown. These are each encircled by a broken line, it being noted that the contact-side aperture 55b is partly covered.

Fig. 5 shows the modular electromagnetic shielding 11a in the installed state 35, but without the plug insert 1. In the embodiment shown in Fig. 5, the modular electromagnetic shielding 11 a likewise has a plug-side shielding element 33a and a contact-side shielding element 33b, the plug-side shielding element 33a being substantially identical to the one of the first embodiment shown in Fig. 3, but the contact-side shielding element 33b likewise has recesses 41 and a toothing 37 in the second embodiment shown.

Bordering on the overlap area 47, free sites 49 are formed on both sides of the overlap area, so that in total eight free sites of the electromagnetic shielding 11 are formed in the embodiment shown.

The receiving of the plug-side shielding element 33a in the receptacle 7 of the plug insert 1 occurs analogously to the inserting of the plug-side shielding element 33a shown in Fig. 3 and has been described above.

The contact-side shielding element 33b of the second embodiment shown in Fig. 5 is introduced into the receptacle 7 from the contact side 5 so that the teeth 39 (Fig. 5 shows two teeth 39, concealing two additional teeth 39) are introduced into the contact-side apertures 55b. At the same time, the contact-side connecting webs 21 b are received in the recesses 41 of the contact-side shielding element 33b.

In the installed state 35, the connecting webs 21 a, 21 b thus extend through the free sites 49 shown in Fig. 5. Both the plug-side shielding element 33a and the contact-side shielding element 33b lie against both the plug-side connecting webs 21 a and the contact-side connecting webs 21 b.

Fig. 6a and 6b show a third embodiment of the plug insert 1 according to the invention in detail 15 in two different perspective views.

The third embodiment of the plug insert 1 has four connecting webs 21, which are for the most part concealed in the left hand figure, but are well seen in the enlargement 61 of Fig. 6b. The positioning element 19 of the third embodiment has a receiving pocket 63, which is formed between the hollow cylinder 29 and a collar wall 65 and which extends in the circumferential direction 59 and in a direction of extension 64. The cross section of the pocket is substantially U-shaped.

The connecting webs 21 of the embodiment shown in Fig. 6a and 6b pass at the plug side 3 into longitudinal struts 67 formed on the collar wall 65 and at the contact side 5 into longitudinal struts 67 formed on the inner wall 23 of the receptacle 7. The latter pass into a circumferential collar 69, while the volume V which is bounded by the connecting webs 21, the longitudinal struts 67 and the collar 69 may be called a receiving volume V_A. In this receiving volume V_A each time a tooth 39 of the plug-side shielding element 33a is received in the installed state 35. The receiving volume V_A is indicated in Fig. 7 by a dashed line. The collar 69 corresponds to the previously mentioned edge 31.

The collars 69 of the embodiments of the plug insert 1 represented in Fig. 3a and 3b, 4a and 4b and 6a and 6b serve as a limit 71 for the receiving of the respective plug-side shielding element 33a, which thrusts by its toothing 37 against the inner wall of the corresponding collar 69 oriented toward the plug side 3.

Fig. 7a and 7b show a rear view of the plug insert 1 of Fig. 6a and 6b and a modular electromagnetic shielding 11 a as seen from the contact side. The rear view shows the centring opening 29b, the hollow cylinder 29, the receiving pocket 63, the collar wall 65 and the connecting webs 21. Moreover, the receiving volume V_A and, in the upper left region, the size of the partly concealed connecting web 21 are indicated. The connecting webs 21 are partly concealed by the encircling collar 69. Moreover, Fig. 7a shows a sectioning line 73, which shall be discussed once more in Fig. 8.

Fig. 7b moreover shows the modular electronic shielding 11 a in the installed state 35, where in the third embodiment of the plug insert according to the invention a complete shielding 75 is provided, having no free sites 49.

As in the first and second embodiment of Fig. 3a and 3b and 4a and 4b, the plug-side shielding element 33a is received in the receptacle 7 such that the teeth 39 are introduced into the apertures 55 and at the same time the connecting webs 21 are introduced into the recesses 41. In the installed state 35, in the third embodiment as well, the plug-side abutment surfaces 53 of the connecting webs 21 touch the recess abutment surface 51 of the plug-side shielding element 33a (see Fig. 6b). The shielding area 43 of the contact-side shielding element 33b of the third embodiment is received in the receiving pocket 63, wherein one end 77 of the contact-side shielding element 33b in the installed state 35 extends beyond the recess abutment surface 51 of the plug-side shielding element 33a in the direction of the plug side 3.

Fig. 8 shows a cross-section 81 of the plug insert 1 according to the invention with received modular electromagnetic shielding 11a in the installed state 35. The cross section 81 occurs along the sectioning line 73 shown in Fig. 7.

Fig. 8 shows that the end 77 of the contact-side shielding element 33b is received entirely in the receiving pocket 63 and the connecting webs 21 protrude in the direction of the plug side 3. The teeth 39 of the plug-side shielding element 33a are received in the receiving volume V_A bypassing the connecting webs 21 in the direction of the contact side 5. The third embodiment shows no free sites 49 in the installed state 35 and thus affords a complete shielding 75.

All embodiments of the plug insert 1 shown thus far have a supporting collar 79, in which the plug-side shielding element 33a is received and supported at least partially. The supporting collar 79 is form-fitted to the plug-side shielding element 33a. The regions of the plug-side shielding element 33a protruding from the plug side 3 of the plug insert 1 have a geometry designed for a FAKRA connector 9a.

The third embodiment of the plug insert 1 of Fig. 8 represents a possible design for the receiving pocket 63 in the receptacle 7. Another embodiment, not shown, forms the receiving pocket 63 between the inner wall 23 (see Fig. 6) of the receptacle 7 and the positioning element 19. In the second possibility of the embodiment of the receiving pocket 63, not shown, the longitudinal strut 67 formed on the collar wall 65 (see enlargement 61 of Fig. 6) is formed in the entire circumferential direction 59.

Fig. 9a and 9b show a FAKRA connector 9a in the installed state 35 with complete shielding 75 and a cross-section 81 along the sectioning line 73 shown in Fig. 9. The shielded FAKRA connector 9a comprises one contact pin 13, which is received offset inwardly in the modular electromagnetic shielding 11a.

The cross section 81 shows that in the third embodiment as well the contact-side shielding element 33b may have a toothing 37. Moreover, it can be seen that a spacing 83 exists between the teeth 39 of the plug-side shielding element 33a and the contact-side shielding element 33b, which is less than a material thickness 85 of each of the participating shielding elements 33a, 33b. This assures a complete shielding 75.

Fig. 10 shows a plug insert 1 according to the invention with a contact pin 13 already received in the positioning element 19. As already described above, the plug-side shielding element 33a is inserted into the receptacle 7 from the plug side 3. The contact-side shielding element 33b is likewise inserted into the receptacle 7 from the contact side 5, so that in the installed state (see Fig. 9) the desired complete shielding 75 is achieved.

The plug insert 1 shown in Fig. 10 combines seven FAKRA receptacles 7a, of which only two are provided with reference numbers, and one HSD receptacle 7b.

The geometry and size of the plug insert 1 depends here on the number of combined connectors, their arrangement, and the geometry of the plug in which the individual different connectors are to be combined.

A plug insert according to the invention may thus have any given number of receptacles 7 of different size and shape and thus combine any given number of different or identical connectors in one plug insert.

List of reference numbers

1

Plug insert

3

Plug side

5

Contact side

7

Receptacle

7a

FAKRA receptacle

7b

HSD receptacle

9

Contact element

9a

FAKRA connector

9b

HSD connector

11

Electromagnetic shielding

11a

Modular electromagnetic shielding

13

Contact pin

15

Detail of the plug insert

17

Base body

19

Positioning element

21

Connecting web

23

Inner wall

25

Plug-side end

27

Contact-side end

29

Hollow cylinder

29a

Lateral surface

29b

Centring opening

31

Edge

33

Shielding element

33a

Plug-side shielding element

33b

Contact-side shielding element

35

Installed state

37

Toothing

39

Tooth

41

Recess

42

Tapering

43

Shielding area

45

Base area

47

Overlap area

49

Free site

51

Recess abutment surface

53

Plug-side abutment surface

55

Aperture

55a

Plug-side aperture

55b

Contact-side aperture

57

Contact-side abutment surface

58

Offset

59

Circumferential direction

61

Enlargement

63

Receiving pocket

64

Direction of extension

65

Collar wall

67

Longitudinal strut

69

Collar

71

Limit

73

Sectioning line

75

Complete shielding

77

End

79

Supporting collar

81

Cross section

83

Spacing

85

Material thickness

d

Diameter

V

Volume

V_A

Receiving volume