EP4277041A1 - Locking connector and method of making the same - Google Patents

Abstract

The invention relates, among other things, to a locking plug connector (100), the plug contacts (43) of which can each be coupled to a mating plug contact of a mating plug connector along a plugging direction (SR). According to the invention, it is provided that inside the locking plug connector (100) - axially along the Seen in the plug-in direction (SR) - a terminal block (10) is arranged at a distance from the plug-in contacts (43), the terminal block contacts (11) of which - seen axially along the plug-in direction (SR) - are arranged one behind the other, the terminal block (10) allowing conductor contacts to be inserted a connecting cable to be connected to the locking plug connector (100) into the terminal block (10) along a predetermined insertion direction and the insertion direction is oriented at an angle, preferably at right angles, to the insertion direction.

Description

The invention relates to locking plug connectors with plug contacts, which can each be coupled to a mating plug contact of a mating plug connector along a plugging direction. The term locking connectors here means those that are automatically secured or can be secured manually against the locking connector being pulled away from the mating connector by means of a mechanical locking device.

For example, push-pull connectors, which are also known as push-pull connectors in German-speaking countries, are known as locking connectors. Such push-pull connectors are, for example, in the European patent specification EP 1 955 413 B1 or the German disclosure document DE 3 200 265 A1 described. Push-pull connectors automatically lock themselves when pushed onto or into a mating connector.

Other locking connectors are, for example, bayonet-based and can be locked manually using a bayonet locking device after they have been pushed onto or into the mating connector.

An advantage of the previously known locking plug connectors is an axial locking between the locking plug connector and the corresponding mating plug connector after the electrical connection between them has been established. The axial locking prevents that the plug contacts of the locking plug connector can unintentionally detach from the mating plug contacts of the mating plug connector or the locking plug connector can be unintentionally removed and the electrical connection is unintentionally interrupted.

A disadvantage of the previously known locking plug connectors, however, is that - due to the aforementioned blocking of the locking plug connector from being removed by the locking device - in the event of a high tensile force of a connecting cable attached to the locking plug connector, the mechanical connection between the plug contacts of the locking plug connector and the cable connections of the connecting cable is very heavily loaded and the connection cable may be torn off from the plug contacts and the locking plug connector may be destroyed.

The invention is based on the object of further developing a locking connector of the type described with a view to particularly high mechanical resilience.

This object is achieved according to the invention by a locking connector with the features according to claim 1. Advantageous embodiments of the locking connector according to the invention are specified in the subclaims.

It is then provided according to the invention that in the interior of the locking plug connector - viewed axially along the plug-in direction - a terminal block is arranged at a distance from the plug-in contacts, the terminal block contacts of which - seen axially along the plug-in direction - are arranged one behind the other, the terminal block allowing the insertion of conductor contacts with the locking plug connector to be connected Connection cable into the terminal block along a predetermined insertion direction and the insertion direction is oriented at an angle, preferably at right angles, to the insertion direction.

A significant advantage of the locking connector according to the invention is the great mechanical stability at high tensile forces. If a connecting cable on the locking connector is pulled axially against the insertion direction, the tensile forces can be absorbed efficiently by the terminal block, because the insertion direction of the conductor contacts of the connecting cable into the terminal block is angular, preferably at right angles, to the insertion direction and thus the axial pulling direction of the connecting cable is arranged.

With a view to axial guidance of the connecting cable and a targeted axial alignment of any tensile forces of the connecting cable, it is considered advantageous if a guiding and/or fastening device, in particular in the form of an eyelet, is arranged at the end of the locking connector remote from the plug contacts allows the connecting cable to be guided and/or fixed and the connecting cable to be axially aligned at the remote end. A guided axial alignment of the connecting cable can advantageously ensure not only the mentioned axial alignment of the tensile forces of the connecting cable, but also a minimal space requirement in the radial direction, so that locking plug connectors and their connecting cables can be arranged particularly close to one another.

Preferably, the terminal block with its circuit board-side terminal block contact connections is on one inside The circuit board arranged on the locking connector is soldered or pressed in.

It is advantageous if cable-side terminal block contact connections of the terminal block are accessible radially from the outside and enable the conductor contacts of the connecting cable to be inserted manually from the outside.

A housing of the locking plug connector preferably has a through slot, the longitudinal direction of which extends along the plug-in direction and enables manual attachment of the conductor contacts of the connecting cable to the terminal block from the outside.

The housing of the locking plug connector preferably has a further through slot, the longitudinal direction of which extends along the plug-in direction and enables the conductor contacts of the connecting cable to be screwed or loosened on the terminal block from the outside.

A radially outer section of the terminal block preferably extends radially outwards through the through-slot or the further through-slot.

The locking plug connector preferably has a front sub-module, viewed in the plug-in direction, in which the plug-in contacts are arranged, and a rear sub-module, seen in the plug-in direction, in which the terminal block and the circuit board are arranged.

The front sub-module and the rear sub-module are preferably connected to one another in a tensile manner by a positive connection.

The rear sub-module preferably comprises a shell-shaped lower housing part and a shell-shaped upper housing part, which alone or with further housing parts form a rear housing part of the rear sub-module.

The terminal block and the circuit board are preferably mounted on the shell-shaped lower housing part.

The through slot and/or the further through slot are preferably arranged in the shell-shaped upper housing part.

The shell-shaped lower housing part and/or the shell-shaped upper housing part together with the front sub-module preferably form an axial tension lock, which enables the rear sub-module to be rotated relative to the front sub-module about an axis of rotation coaxial with the plug-in direction. The angle of rotation is preferably at least 30 degrees.

It is advantageous if the shell-shaped lower housing part and/or the shell-shaped upper housing part has at least one radially tapering (constricting) engagement region, which engages in a circumferential groove or in a ring segment-shaped (trough-like) recess in the front sub-module and thereby the axial train protection or at least one Part of the train protection. The engagement in the circumferential groove or the ring segment-shaped (trough-like) recess in the front sub-module advantageously enables the aforementioned rotation about the axis of rotation coaxial with the insertion direction.

Each of the plug contacts is preferably soldered to a solder connection on the circuit board using a connecting wire.

Each of the latter solder connections is preferably connected to a terminal block contact of the terminal block via a conductor track of the circuit board.

The solder connections are preferably located on the circuit board on a fictitious line, which in turn is parallel to the plugging direction.

On the circuit board, viewed in the plug-in direction, a shield contact spring is preferably attached to the circuit board between the terminal block and the plug contacts, specifically on the circuit board side facing away from the terminal block, the shield contact spring connecting one of the terminal block contacts of the terminal block to a coaxial shield contact of the front sub-module.

An identification chip is preferably arranged on the circuit board, preferably separated from the plug contacts by the terminal block, which identifies the locking plug connector or an external device connected to the terminal block by means of the connecting cable.

An electrical contact of the identification chip is preferably soldered or pressed to a conductor track of the circuit board, the latter conductor track also being connected to both one of the plug contacts and one of the terminal block contacts.

The invention also relates to a method for producing a locking plug connector, in particular one as described above, the plug contacts of which can each be coupled to a mating plug contact of a mating plug connector along a plugging direction.

According to the invention, it is provided that in the interior of the locking plug connector - seen axially along the plug-in direction - a terminal block is arranged at a distance from the plug-in contacts, the terminal block contacts of which - seen axially along the plug-in direction - are arranged one behind the other, the terminal block allowing the insertion of conductor contacts with the locking plug connector connecting connection cable into the terminal block along a predetermined insertion direction and the insertion direction is oriented at an angle, in particular at right angles, to the insertion direction.

With regard to the advantages of the method according to the invention and its advantageous embodiments, reference is made to the above statements in connection with the locking connector according to the invention and its advantageous embodiments.

Fig. 1-9

Verfahrensschritte im Rahmen der Herstellung von in den Figuren 10 bis 15 gezeigten Ausführungsbeispielen für erfindungsgemäße Verriegelungssteckverbinder,

Fig. 10-12

ein Ausführungsbeispiel für einen erfindungsgemäßen Verriegelungssteckverbinder in verschiedenen dreidimensionalen Ansichten,

Fig. 13

die Verdrehbarkeit eines hinteren Teilmoduls des in den Figuren 10-12 gezeigten Verriegelungssteckverbinders näher im Detail, und

Fig. 14-15

ein weiteres Ausführungsbeispiel für einen erfindungsgemäßen Verriegelungssteckverbinder.

The invention is explained in more detail below using exemplary embodiments; show by way of example

Fig. 1-9

Process steps as part of the production of in the Figures 10 to 15 shown embodiments for locking connectors according to the invention,

Fig. 10-12

an exemplary embodiment of a locking connector according to the invention in various three-dimensional views,

Fig. 13

the rotatability of a rear sub-module in the Figures 10-12 locking connector shown in more detail, and

Fig. 14-15

a further embodiment of a locking connector according to the invention.

For the sake of clarity, the same reference numbers are always used in the figures for identical or comparable components.

In connection with the Figures 1 to 9 A method for producing exemplary embodiments of locking connectors 100 according to the invention is described below as an example, as shown in FIGS Figures 10 to 13 or 14 to 15 are shown in more detail in different representations.

The Figure 1 shows a terminal block 10, which has a plurality of terminal block contacts 11, which are arranged linearly on a fictitious line and - axially along the plugging direction SR of the locking plug connector 100 (cf. Figures 10-15 ) - are arranged one behind the other. Each of the terminal block contacts 11 has a circuit board-side terminal block contact connection 11a and a cable-side terminal block contact connection 11b. The terminal block 10 can advantageously be a screw terminal block or an insulation displacement terminal block.

The Figure 2 shows the terminal block 10 after it has been mounted on the front 21 of a circuit board 20. It can be seen that the circuit board-side terminal block contact connections 11a extend to the back 22 of the circuit board 20, so that they can be soldered to or pressed into the conductor tracks of the circuit board 20 that are present there but are not shown for reasons of clarity.

The Figure 2 also shows a shield contact spring 30, which is attached to the back 22 of the circuit board 20 and is electrically connected there to a shield conductor track, not shown, of the circuit board 20.

The Figure 3 shows a three-dimensional view from above of the terminal block 10 after it has been attached to the front 21 of the circuit board 20. In addition, the Figure 3 Recognize through holes 24, which enable connecting wires, not shown, to be pushed through or through so that they can each be contacted with a contact connection 25, for example solder connection or press-fit connection, on the back 22 of the circuit board 20, for example soldered or pressed into it.

The Figure 4 shows the back 22 of the circuit board 20 in a three-dimensional representation. It can be seen that the solder connections 25 lie on a fictitious line L, which is parallel to the plugging direction SR of the locking connector 100 (see Figures 10-12 ) are arranged. Each of the solder connections 25 is connected to an individually assigned terminal block contact 11 of the terminal block 10 via a conductor track, not shown, of the circuit board 20.

The Figure 5 shows internal components of a front sub-module 40 in the Figures 10 to 13 locking connector 100 shown in more detail. A first sleeve part 41a can be seen, into which a plug contact carrier 42 is inserted. The plug contact carrier 42 carries a large number of plug contacts, which are marked with the reference number 43. A connecting wire 50 is connected to each of the plug contacts 43, the circuit board-side connection 51 of which passes through - as shown in other figures an assigned through hole 24 in the circuit board 20 is pushed through and soldered to an assigned solder connection 25 on the back 22 of the circuit board 20.

The Figure 6 shows the arrangement according to Figure 5 after a second sleeve part 41b has been placed on the first sleeve part 41a and connected to it, preferably by a positive connection, for example a latching connection. The two sleeve parts 41a and 41b are preferably made of metal or at least of conductive material so that they can together form a coaxial shield contact 41 in the front sub-module 40.

The shape and the inner diameter of the coaxial shield contact 41 are preferably selected such that when the front section of the circuit board 20, viewed in the plug-in direction SR, is inserted into the coaxial shield contact 41, the shield contact spring 30 is electrically contacted with the coaxial shield contact 41 and thus an electrical connection between the coaxial shield contact 41 and the shield contact spring 30 and subsequently also one of the terminal block contacts 11 of the terminal block 10 is ensured.

The Figure 7 shows the related to the Figures 5 and 6 Components described after they have been inserted into a housing 44 of the front sub-module 40. It can be seen that the connecting wires 50 and their circuit board-side connections 51 protrude from the rear of the housing 44 so that soldering to the circuit board 20 is possible.

In addition, the shows Figure 7 that the housing 44 is preferably equipped with a circumferential groove 45, which in the exemplary embodiment shown, it rotates in a ring and is rotationally symmetrical. The function of the circumferential groove 45 will be explained in more detail below.

The Figure 8 shows the terminal block 10 and the circuit board 20 after it has been inserted into the housing 44 of the front sub-module 40. The shield contact spring 30, which is in the Figure 8 cannot be seen in more detail, is connected to the coaxial shield contact 41 through the spring action of the shield contact spring 30.

In the Figure 8 It can also be seen that the circuit board-side connections 51 of the connecting wires 50 each pass through an assigned through hole 24 (cf. Figure 3 ) have been passed through the circuit board 20. After the connecting wires 50 have been passed through, their circuit board-side connections 51 are each connected to an assigned solder connection 25 (cf. Figure 4 ) soldered to the back 22 of the circuit board 20.

The Figure 9 shows the arrangement according to Figure 8 , after a shell-shaped lower housing part 60 has been attached to the housing 44 of the front sub-module 40. The shell-shaped lower housing part 60 supports the circuit board 20 downwards and fixes its position.

The Figure 9 also shows that the shell-shaped lower housing part 60 has a radially tapering engagement region 61 which engages in the circumferential groove 45 of the housing 40.

The Figure 10 shows the arrangement according to Figure 9 , after a shell-shaped upper housing part 70 has been mounted on the shell-shaped lower housing part 60. For assembly is preferred A latching or snap connection is provided in the two housing parts 60 and 70.

The upper housing part 70, the lower housing part 60, the circuit board 20, the terminal block 10 and the shield contact spring 30 form components of a rear sub-module 80 of the locking connector 100, as shown in the Figures 10-13 is shown.

The shell-shaped upper housing part 70 is also equipped with a radially tapering engagement area, which is in the Figure 10 is no longer recognizable; This radially tapering engagement area also projects into the groove 45 of the housing 44, so that the tapering engagement areas of the upper housing part 70 and the lower housing part 60 together with the groove 45 in the housing 44 form a positive connection, which provides axial tension protection between the front sub-module 40 and the rear sub-module 80 is guaranteed.

Since, in the exemplary embodiment shown, the groove 45 rotates through a rotation angle of 360 degrees and the radially tapering engagement areas of the rear sub-module 80 engage in the circumferential groove 45 in the front sub-module, the rear sub-module 80 can move relative to the front sub-module 40 by a position coaxial with the insertion direction The axis of rotation can be rotated, theoretically by 360 degrees; However, the angle of rotation is limited by the length of the connecting wires 50.

Alternatively, it can be provided that the groove 45 does not rotate through 360 degrees, but only through a predetermined maximum angle of, for example, 45 degrees. Of course, in such a configuration, the radially tapering engagement areas must be adapted accordingly; for example, instead of this, only a radially inwardly projecting nose could be provided which engages in the groove 45 and is pushed back and forth in the groove 45 when the rear sub-module 80 is rotated relative to each other. In the latter variant, the groove walls would form stops that limit the angle of rotation of the relative rotation. Several such annular grooves, each of which rotates at 45 degrees, for example, can also be arranged rotationally symmetrically and each of these annular grooves can be assigned a radially inwardly projecting nose in the rear sub-module 80.

The Figure 10 Furthermore, it can be seen that the shell-shaped upper housing part 70 has a through slot 71, the longitudinal axis of which is aligned parallel to the plugging direction SR of the locking plug connector 100. Operating elements 11c of the terminal block 10 preferably extend through the through-slot 71, which ensures that they are accessible from the outside to the operator and can be easily operated by screwing and/or other operations, such as pressing or the like.

The Figure 11 shows the locking connector 100 according to Figure 10 in another three-dimensional representation. It can be seen that in the shell-shaped upper housing part 70 there is also a further through slot 72, the longitudinal direction of which is also aligned parallel to the plug-in direction SR and thus runs parallel to the longitudinal direction of the through slot 71.

Through the further through slot 72, the cable-side terminal block contact connections 11b of the terminal block 10 are accessible from the outside, so that conductor contacts of a connection cable, not shown, can be inserted into the terminal block contacts 11 or removed from them again by the user.

The Figure 12 shows another three-dimensional representation of the locking connector 100 according to Figures 10 and 11 more in detail. The plug contacts 43 can be seen, which are preferably arranged parallel to one another and each run parallel to the plugging direction SR of the locking plug connector 100.

In addition, it can also be done in the Figure 12 You can clearly see that the controls 11c of the terminal block 10 extend radially outwards, so that they are easily accessible and can be easily operated from the outside. Also shows the Figure 12 Again in another view, the terminal block contacts 11 are accessible from the outside through the further through slot 72, so that conductor contacts of a connection cable, not shown, can be inserted manually from the outside.

For reasons of space, it is advantageous if the cable-side terminal block contact connections 11b are located within the rear sub-module 80, i.e. do not protrude from it - unlike the operating elements 11c of the terminal block 10.

The Figures 10 to 12 also show a guiding and/or fastening device 110 in the form of an eyelet, which is arranged at an end of the locking plug connector 100 that is remote from the plug contact 43. The guiding and/or fastening device advantageously enables the connecting cable, not shown, to be guided and/or fixed, so that at least in the end region of the locking plug connector 100 an axial alignment of the connecting cable with respect to the plugging direction SR is ensured. Such an alignment ensures - seen in the radial direction - a minimal space requirement, so that many locking connectors 100 of the type described are very close to one another can be arranged. The one guiding and/or fastening device 110 can provide guidance alone, for example when the connecting cable is inserted through it, or together with other aids (not shown), such as cable ties or the like.

The Figure 13 shows the already in connection with the Figures 9 and 10 mentioned rotatability of the rear sub-module 80 relative to the front sub-module 40 about an axis of rotation coaxial with the plug-in direction SR. The rotation of the rear sub-module 80 is ensured by the described design of the two housing parts 60 and 70 with their tapering engagement areas and the corresponding matching groove 45 in the housing 44.

The angle of rotation through which the rear sub-module 80 and the front sub-module 40 can be rotated is - as mentioned - limited by the length of the connecting wires 50. It is therefore advantageous if these are dimensioned in such a way that the rear sub-module 80 can be rotated by at least 30°, preferably up to 45°, relative to the front sub-module 40.

The ability to rotate advantageously allows the front sub-modules 80 to be aligned so that no mechanical blockage occurs with an adjacent locking connector 100 when the connecting cable is connected.

In order to ensure a basic alignment or basic alignment of the rear sub-module 80 relative to the front sub-module 40, reference markings 101 and 102 are preferably provided which mark this position as a reference. The sub-module 80 can then be rotated relative to this basic orientation until it is adjusted by stops or the length of the connecting wires 50 predetermined maximum rotation angle is reached or a further reference marking indicating this maximum rotation angle indicates this.

In order to prevent the operator from rotating the rear sub-module 80 too much around the front sub-module 40 and causing the connecting wires 50 to tear off, stops or the like are preferably provided - as already explained - which limit such rotation. As already mentioned, it can be provided that the groove 45 does not rotate through 360 degrees, but only through a smaller maximum angle of, for example, 45 degrees. Alternatively or additionally, other types of stops can also be provided.

The Figure 14 shows a further exemplary embodiment of a locking connector 100 according to the invention, the shell-shaped upper housing part 70 being shown in accordance with Figure 10 has been removed to allow a view into the interior of the rear sub-module 80.

It can be seen that in the exemplary embodiment according to Figure 14 An identification chip 120 is arranged on the circuit board 20, which identifies the locking connector 100 as such or an external device connected to the terminal block 10 by means of a connecting cable, not shown.

With regard to the arrangement of the identification chip 120, it is considered advantageous if it is separated from the front sub-module 40 by the terminal block 10.

The Figure 15 shows for the exemplary embodiment according to Figure 14 a particularly advantageous embodiment of the circuit board 20. It can be seen that on the circuit board 20 preferably a Ypsilon-branched conductor track 130 is present, which connects a ground connection of the identification chip 120 to one of the terminal block contacts 11 and an associated plug contact 43 of the locking plug connector 100 that carries ground potential.

With the in the in the Figures 1 to 15 Locking plug connectors 100 shown can advantageously also have a light source, such as a light-emitting diode, arranged on the circuit board 20, which, for example, indicates that the locking plug connector 100 has been electrically connected to a mating plug connector.

With the in the in the Figures 1 to 15 Locking connectors 100 shown, the shell-shaped lower housing part 60 and the shell-shaped upper housing part 70 can be advantageously produced by a 3D printing process or an injection molding process.

With those in the Figures 1 to 15 Locking connectors 100 shown can advantageously be push-pull connectors (push-pull connectors) or bayonet-based locking connectors.

Finally, it should be mentioned that the features of all of the exemplary embodiments described above can be combined with one another in any way to form further other exemplary embodiments of the invention.

All features of subclaims can also be combined with each of the subordinate claims, each alone or in any combination with one or other subclaims, in order to obtain further other exemplary embodiments.

Claims (15)

Locking plug connector (100), the plug contacts (43) of which can each be coupled to a mating plug contact of a mating plug connector along a plugging direction (SR), characterized in that - Inside the locking connector (100) - seen axially along the plug-in direction (SR) - a terminal block (10) is arranged at a distance from the plug-in contacts (43), the terminal block contacts (11) of which - seen axially along the plug-in direction (SR) - are arranged one behind the other are, - wherein the terminal block (10) enables conductor contacts of a connection cable to be connected to the locking plug connector (100) to be inserted into the terminal block (10) along a predetermined insertion direction and - The insertion direction is oriented at an angle, preferably at right angles, to the insertion direction. Locking connector (100) according to claim 1,
characterized in that
At the end of the locking plug connector (100) remote from the plug contacts (43), a guiding and/or fastening device (110), in particular in the form of an eyelet, is arranged, which guides and/or fixes the connecting cable and one in the plugging direction (SR ) allows axial alignment of the connecting cable at the remote end. Locking connector (100) according to one of the preceding claims,
characterized in that
the terminal block (10) with its circuit board-side terminal block contact connections (11a) is soldered or pressed onto a circuit board (20) arranged inside the locking connector (100). Locking connector (100) according to one of the preceding claims,
characterized in that
Cable-side terminal block contact connections (11b) of the terminal block (10) are accessible radially from the outside and enable the conductor contacts of the connecting cable to be inserted manually from the outside. Locking connector (100) according to claim 4,
characterized in that - a housing (44) of the locking plug connector (100) has a through slot (71), the longitudinal direction of which extends along the plug-in direction (SR) and enables the conductor contacts of the connecting cable to be attached manually to the terminal block (10) from the outside, and - The housing of the locking plug connector (100) has a further through slot (72), the longitudinal direction of which extends along the plug-in direction (SR) and enables the conductor contacts of the connecting cable to be screwed or loosened on the terminal block (10) from the outside. Locking connector (100) according to claim 4 or 5,
characterized in that
a radially outer section of the terminal block (10) extends radially outwards through the through-slot (71) or the further through-slot (72). Locking connector (100) according to one of the preceding claims,
characterized in that
the locking plug connector (100) has a front sub-module (40), viewed in the plug-in direction (SR), in which the plug-in contacts (43) are arranged, and a rear sub-module (80), seen in the plug-in direction (SR), in which the terminal block (10) and the circuit board (20) are arranged. Locking connector (100) according to claim 7,
characterized in that
the front sub-module (40) and the rear sub-module (80) are connected to one another in a tensile manner by a positive connection. Locking connector (100) according to one of the preceding claims 7 to 8,
characterized in that - the rear sub-module (80) comprises a shell-shaped lower housing part (60) and a shell-shaped upper housing part (70), which alone or with further housing parts form a rear housing part of the rear sub-module (80), - The terminal block (10) and the circuit board (20) are mounted on the shell-shaped lower housing part (60). Locking connector (100) according to claim 9,
characterized in that
the through slot (71) and/or the further through slot (72) are arranged in the shell-shaped upper housing part (70). Locking connector (100) according to one of the preceding claims 9 to 10,
characterized in that
the shell-shaped lower housing part (60) and the shell-shaped upper housing part (70) form an annular, radially tapering engagement area in the area of the interface to the front sub-module (40), which engages in a circumferential groove (45) in the front sub-module (40) and forms an axial train protection, which enables the rear sub-module (80) to be rotated relative to the front sub-module (40) about an axis of rotation coaxial with the plug-in direction (SR), preferably by a rotation angle of at least 30 degrees. Locking connector (100) according to one of the preceding claims 2 to 11,
characterized in that - each of the plug contacts (43) is soldered to a solder connection (25) on the circuit board (20) by means of a connecting wire (50), - wherein each of the latter solder connections (25) is connected to a terminal block contact (11) of the terminal block (10) via a conductor track of the circuit board (20) and - The solder connections (25) on the circuit board (20) lie on a fictitious line (L) that is parallel to the plug-in direction (SR). Locking connector (100) according to one of the preceding claims 2 to 12,
characterized in that - On the circuit board (20) viewed in the plug-in direction (SR), a shield contact spring (30) is attached to the circuit board (20) between the terminal block (10) and the plug-in contacts (43), namely on the circuit board side facing away from the terminal block (10). (22), - wherein the shield contact spring (30) connects one of the terminal block contacts (11) of the terminal block (10) to a coaxial shield contact (41) of the front sub-module (40). Locking connector (100) according to one of the preceding claims 2 to 12,
characterized in that - An identification chip (120) is arranged on the circuit board (20), preferably separated from the plug contacts (43) by the terminal block (10), which has the locking plug connector (100) or an external one connected to the terminal block (10) by means of the connecting cable facility identified, - wherein an electrical contact of the identification chip (120) is soldered or pressed to a conductor track of the circuit board (20) and - The last-mentioned conductor track is also connected to both one of the plug contacts (43) and one of the terminal block contacts (11). Method for producing a locking plug connector (100), in particular one according to one of the preceding claims, the plug contacts (43) of which can each be coupled to a mating plug contact of a mating plug connector along a plugging direction (SR),
characterized in that - Inside the locking connector (100) - seen axially along the plug-in direction (SR) - a terminal block (10) is arranged at a distance from the plug-in contacts (43), the terminal block contacts (11) of which - seen axially along the plug-in direction (SR) - are arranged one behind the other are, - wherein the terminal block (10) enables conductor contacts of a connection cable to be connected to the locking plug connector (100) to be inserted into the terminal block (10) along a predetermined insertion direction and - The insertion direction is aligned at an angle, in particular at right angles, to the insertion direction (SR).

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