EP3742561A1 - Electric plug connector - Google Patents

Abstract

The invention relates to an electrical plug connection (7) made up of two components (1, 2) with electrical contacts (12) to be connected to one another in a plugging direction (4). A first component (1) is designed as a plug (10) and a second component (2) is designed as a socket (20). A latching device for mechanically securing the plug connection (7) is provided between the components (1, 2), the latching device comprising a latching element (14) held on the first component (1) and a latching recess (2) formed in the second component (2). 24) is formed, in which the locking element (14) engages. Furthermore, an actuating element (5) acting on the latching element (14) is provided for releasing the latching by lifting the latching element (14) out of the latching recess (24). According to the invention, a mechanical locking element (40) is provided on the first component (1) carrying the locking element (14), wherein the locking element (40) shows the locking element (14) lying in the locking recess (24) of the second component (2) locked in its detent position. To release the locking, the latching element (14) is to be moved relative to the locking element (40) against the insertion direction (4).

Description

The invention relates to an electrical plug connection made up of two components with electrical contacts to be connected to one another in a plugging direction. A first component of this plug connection is designed as a plug and a second component of this plug connection is designed as a socket. A latching device for mechanically securing the plug connection is provided between the components, the latching device being formed from a latching element held on the first component and a latching recess formed in the second component. When the plug connection is plugged together, the latching element engages in the latching recess and mechanically latches the plug connection to prevent unintentional loosening. The latching can be released by lifting the latching element out of the latching recess via an actuating element acting on the latching element. For this purpose, the actuating element is moved relative to the component.

Such plug connections for electrical lines are also referred to as push-pull systems and are used to simply connect a plug connection with a mechanical fuse. The locking device is implemented using a typical 90 ° undercut. The disadvantage here is that the latching device can come loose when a tensile force acts on the plug connection. This loosening takes place non-destructively, however, when loosening, tensile force acts on the components so that they do not act after they are locked again more the holding force of the mechanical safety can be achieved than in the original state.

The invention is based on the object of designing an electrical plug connection with a latching device acting between the components in such a way that loosening of the latching is prevented even in the case of large tensile forces acting on the plug connection.

According to the invention, the object is achieved in that a mechanical locking element is formed on the first component carrying the latching element, which securely locks the latching element located in the latching recess of the second component in its latching position. To cancel the locking, it is provided that the latching element is to be moved relative to the locking element. The latching element is mounted on the first component in such a way that it can be moved against the insertion direction.

With this design according to the invention it is achieved that the plug connection can only be released by axial displacement or rotation of the actuating element. With the movement of the actuating element, the locking element is released from the locking element, so that it can be deflected radially inward into a free space. The locking is canceled by the radial displacement of the locking lug of the locking element inward. Because of the axial path covered by the latching element, it is exposed from the locking element. The locking element is at an axial distance from the locking element.

The electrical connector according to the invention is designed in such a way that when the connector is subjected to a tensile load against the insertion direction, the locking element forces the latching element into the latching recess so that the latching lug of the latching element cannot lift out of the latching recess.

The latching element is preferably mounted on the first component so as to be displaceable counter to the plugging direction of the plug connection. The axial movement of the locking element in the direction of the longitudinal axis of the plug connection releases it from the locking element and can be displaced radially inward to release the locking device.

In one embodiment of the invention it is provided that a spring holds the locking element in an end position. When the plug connection is locked, the locking element is in its end position determined by a spring. In this end position, the latching element is preferably in contact with the locking element.

The locking element is designed with a contact surface facing the latching element. The contact surface is provided in particular as an inclined plane.

In a further development of the invention, the plug device has a longitudinal axis, the contact surface of the locking element with the longitudinal axis of the plug connection delimiting an angle of 20 ° to 80 °, in particular 60 °, which opens in the plugging direction. The choice of the size of the angle determines the force exerted by the lock on the latching element in the event of a tensile load on the plug connection.

The latching element advantageously has an opposing surface. The counter surface lies opposite or on the contact surface of the locking element.

The locking element is advantageously designed as a locking tongue with a locking lug. The locking recess is designed as a locking groove formed in the second component.

In a special development of the invention, the locking lug has a basic shape that is V-shaped in cross section. The cross-section of the locking recess and the cross-section of the locking lug in particular have the same, expediently identical shape.

In the latched end position of the plug connection, the cross section of the latching lug is essentially precisely shaped, in particular precisely shaped in the cross section of the latching recess.

The latching device is advantageously designed such that the latching section of the latching element engaging in the latching recess has a latching surface which, with the longitudinal axis of the plug connection, has an angle of less than 90 ° opening in the plugging direction.

Further features of the invention emerge from the further claims, the description and the drawing, in which exemplary embodiments of the invention described in detail below are shown. The advantages and features specified for the individual exemplary embodiments can be combined with one another as desired. Features of one exemplary embodiment also apply without restriction to other exemplary embodiments, even if this is not specified again in the following description.

Fig. 1

einen Schnitt durch eine gelöste Steckverbindung aus Stecker als erstes Bauteil und einer Buchse als zweites Bauteil,

Fig. 2A

eine perspektivische Darstellung eines Rings mit mehreren sich in Axialrichtung erstreckenden Rastelementen in Form von Rastzungen,

Fig. 2B

eine perspektivische Darstellung des Steckers als erstes Bauteil bestehend aus einem Grundkörper mit Steckkontakten, einem Ring mit mehreren Rastelementen sowie einem auf die Rastelemente wirkenden Betätigungselement,

Fig. 3

einen Schnitt durch eine Steckverbindung nach Fig. 1 in einer Zwischenstellung,

Fig. 4

einen Schnitt durch die Steckverbindung nach den Figuren 1 und 3 in mechanisch verrasteter Verbindungsstellung,

Fig. 5

in vergrößerter Darstellung die Einzelheit V aus Fig. 4,

Fig. 6

einen Schnitt durch ein weiteres Ausführungsbeispiel einer Steckverbindung in offener Stellung,

Fig. 7

einen Schnitt durch die Steckverbindung nach Fig. 6 in einer Zwischenstellung,

Fig. 8

einen Schnitt durch die Steckverbindung nach den Figuren 6 und 7 in mechanisch verrasteter Stellung,

Fig. 9

einen Schnitt durch ein weiteres Ausführungsbeispiel einer Steckverbindung in mechanisch verrasteter Stellung.

The drawings show in detail:

Fig. 1

a section through a detached plug connection consisting of a plug as the first component and a socket as the second component,

Figure 2A

a perspective view of a ring with several locking elements extending in the axial direction in the form of locking tongues,

Figure 2B

a perspective view of the connector as a first component consisting of a base body with plug contacts, a ring with several locking elements and an actuating element acting on the locking elements,

Fig. 3

a section through a connector Fig. 1 in an intermediate position,

Fig. 4

a section through the connector after the Figures 1 and 3 in mechanically locked connection position,

Fig. 5

the detail V in an enlarged view Fig. 4 ,

Fig. 6

a section through a further embodiment of a plug connection in the open position,

Fig. 7

a section through the connector Fig. 6 in an intermediate position,

Fig. 8

a section through the connector after the Figures 6 and 7 in mechanically locked position,

Fig. 9

a section through a further embodiment of a plug connection in the mechanically locked position.

In Fig. 1 a first embodiment of a connector 7 according to the invention is shown in the open position. A first component 1 is designed as a plug 10. A second component 2 is designed as a socket 20.

The plug 10 consists of a base body 11 which has electrical connecting pins 12. The connecting pins 12 are located within a plug sleeve 13. The plug sleeve 13 is preferably designed in one piece with the base body 11 of the plug 10.

The first component 1 carries at least one latching element 14, which interacts with a counter-latching element 23 on the second component 2. In the exemplary embodiment shown, the counter-locking element 23 is formed by a locking recess 24. The latching recess 24 is formed in the base body 21 of the second component 2, which is designed as a bushing 20. The latching recess 24 has in particular a V-shaped basic shape in cross section. In the exemplary embodiment shown, the locking recess 24 is designed as a locking groove 25. The locking groove 25 is preferably designed as a circumferential groove and has a V-shaped cross-section.

A first side wall 26a of the V-shaped cross-section of the latching recess 24 lies near the end 34 of the second component 2. The first side wall 26a lies in a plane 27 which, with a longitudinal axis 3 of the plug connection 7, opens to the socket 20 (second component 2) Angle 28a is determined. The side wall 26a of the circumferential locking groove 25 forms a cone, the tip of which lies on the longitudinal center axis 3 of the plug connection 7. The angle 28a, which is a cone angle in the exemplary embodiment shown, preferably has a size of 90 ° to 20 °, in particular a size of 60 °. The second side wall 26b of the V-shaped cross section of the latching recess 24 lies in a plane 29 which, with the longitudinal axis 3 of the plug connection 7, defines an angle 28b that opens towards the plug 10 (first component 1). The side wall 26b of the circumferential locking groove 25 forms a further cone, the tip of which lies on the longitudinal axis 3 of the plug connection 7. The angle 28b, which is a cone angle in the exemplary embodiment shown, preferably has a size of 20 ° to 60 °, in particular a size of 30 °.

The second component 2, which is preferably designed as a socket 20, has a receptacle 22 for making electrical contact with the electrical connecting pins 12 of the first component 1, which is designed as a plug 10. An annular gap 30 is formed between the receptacle 22 and the base body 21 of the second component 2 and is used to receive the plug sleeve 13 of the first component 1.

The first component 1 has a plurality of latching elements 14 distributed over the circumference of the base body 11. A latching element 14 is sufficient for the plug connection 7 according to the invention to function; Six latching elements 14 are advantageously provided over the circumference of the cylindrical base body 10, such as in particular Figure 2A shows.

The locking elements 14 are evidenced Figure 2A held on a carrier sleeve 15 which has an outer, advantageously circumferential annular flange 16. The carrier sleeve 15 is held together with the locking elements 14 on the base body 11 of the first component 1 so as to be displaceable. The carrier sleeve 15 is axially guided on the cylindrical base body 11. The carrier sleeve 15 can be displaced to a limited extent between a peripheral flange 17 and an annular shoulder 18 of the base body 11. A spring 19 is arranged between the circumferential flange 17 and the annular flange 16. The spring 19 holds the support sleeve 15 in an end position on the annular shoulder 18 of the base body 11. By means of the spring 19, the latching elements 14 held on the support sleeve 15 take an in Fig. 1 end position shown.

The carrier sleeve 15 is via an actuating element 5 from the in Fig. 1 to move the end position shown against the plugging direction 4 of the connector 7 in the direction of its longitudinal axis 3. The actuating element 5 is designed as a sliding sleeve 6 which is held displaceably on the first component 1. An annular shoulder 38 of the sliding sleeve 6 interacts with the annular flange 16 of the carrier sleeve 15.

The latching element 14 is designed as a latching tongue 44. The latching tongue 44 carries a latching lug 42 which is preferably arranged at the free end 43 of the latching tongue 44. The Latch 42 points - in relation to the cylindrical base body 11 of the plug 10 - to the outside and engages - from the inside to the outside - into the latching recess 24 on the second component 2 of the plug connection 7.

In the in Fig. 1 The end position of the latching tongue 14 shown here lies against a locking element 40. The locking element 40 is provided on the first component 1. The locking element 40 is preferably provided on the base body 11 and / or on the plug sleeve 13. The locking element 40 is arranged on the outer circumference of the base body 11 and / or the plug sleeve 13. The locking element 40 is expediently provided in one piece with the base body 11 and / or the plug sleeve 13.

In the exemplary embodiment shown, the locking element 40 is formed in the transition region between the base body 11 and the plug sleeve 13. A locking element 40 is assigned to each latching element 14. The locking element 40 rests against the locking element 14 in the end position of the latter. In the illustrated embodiment of a latching element 14 designed in particular as a latching tongue 44 with a latching nose 42, the free end 43 of the latching tongue 44 rests on the locking element 40 in the embodiment of the invention shown. As in Figure 2B shown, the locking elements 40 assigned to the latching elements 14 on the first component 1 form a common circumferential, outer annular shoulder 41. The annular shoulder 41 is in particular formed in one piece with the plug sleeve 13 and / or the base body 11.

The second component 2 designed as a bushing 20 has an in particular frustoconical insertion bevel 32. The insertion bevel 32 is formed in particular on the insertion opening 31 of the second component 2. The insertion bevel 32 interacts with a frustoconical section 33 of the first component 1. The frustoconical section 33 is composed of the circumferential annular shoulder 41 of the locking elements 40 and the latching lugs 42 resting on the locking elements 40. The lateral surface of the frustoconical section 33 is of a locking element 40 or more locking elements 40 on the one hand and composed of a locking element 14 or more locking elements 14 on the other hand. In the exemplary embodiment shown, the locking lugs 42 of the locking elements 14 form parts of the lateral surface of the frustoconical section 33.

As in Fig. 3 As shown, the first component 1 and the second component 2 are moved towards one another in the plugging direction 4 in order to join the plug connection 7. The connector sleeve 13 enters the insertion opening 31 of the second component 2 and is inserted into the annular gap 30 in the further movement in the insertion direction 4. The two components 1 and 2 are moved further towards one another in the insertion direction 4. The beveled insertion 32 of the second component 2 (socket 21) slides onto the frustoconical section 33 of the first component 1 (plug 10). During the further movement in the plug-in direction 4, the lead-in bevel 31 is pushed onto the frustoconical jacket section of the latching element 14 and displaces it axially against the plug-in direction 4 and radially inward. To accommodate the locking tongue 14 deflected radially inward, a free space 45 is formed between the locking element 40 and the annular shoulder 18 of the base body 11. The free space 45 is designed in particular as a recessed circumferential groove 46 or undercut in the cylindrical base body 11 of the first component 1.

When the inclined surface 31 runs onto the frustoconical casing section of the latching element 14, the latter is axially displaced together with the carrier sleeve 15 against the insertion direction 4 of the first component 1. The axial displacement of the locking element 14 together with the carrier sleeve 15 is limited by the peripheral flange 17 of the base body 11 of the first component 1. With the axial displacement, the locking element 14 is released from the locking element 40. The insertion bevel 31 passes over the locking element 14, which is blocked in the axial movement, until the components 1 and 2 are completely inserted into one another, as shown in FIG Fig. 4 is shown. After the locking element 14 has been driven over by the insertion bevel 31, it springs out of the free space 45 into its original position and locks the two components 1 and 2 of the connector 7 with one another.

When the latching element 14 springs back, the latching lug 42 of the latching tongue 44 engages in the latching recess 24. The first component 1 and the second component 2 are connected in a mechanically secured manner by the latching device comprising the latching element 14 and the counter-latching element 23.

The locking lug 42 is V-shaped in cross section. In particular, the locking lug 42 is adapted in cross section to the V-shaped basic shape of the locking recess 24. The cross section of the locking lug 42 engages in the cross section of the locking recess 24 with an advantageous shape. In particular, the cross section of the locking lug 42 and the cross section of the locking recess 24 are matched to one another as positive and negative.

In this in Fig. 4 The latched end position shown in the latched end position of the electrical plug connection 7 according to the invention is the latching element 14 in its end position caused by the spring 19. In this end position, the latching element 14 rests against the locking element 40 of the first component 1. In this end position, in the exemplary embodiment shown, the free end 43 of the latching tongue 44 rests on the locking element 40. In Fig. 5 the position and the interaction of the latching element 14 with the locking element 40 is shown enlarged in the enlarged view of the detail V.

One side wall 26a of the locking recess 24, which is V-shaped in cross section, is at an angle 28a to the longitudinal axis 3 of the components 1 and 2. Corresponding to the angular position of the side wall 26a to the longitudinal axis 3, the locking lug 42 is designed with a contact surface 47. The contact surface 47 lies in particular parallel to the side wall 26a of the V-shaped locking recess 24. Due to the cylindrical design of the components 1 and 2, the side wall 26a of the locking recess 24, like the contact surface 47 of the locking nose 42, forms a frustoconical outer surface. The radial outer surface 48 of the locking lug 42 adjoining the contact surface 47 is the angular position of the side wall 26b of the V-shaped locking recess 24 is formed accordingly. The radial outer surface 48 lies parallel to the side wall 26b of the V-shaped locking recess 24.

The free end 43 of the latching element 14 or the latching tongue 44 lies opposite a contact surface 50 of the locking element 40 with a counter surface 49. The mating surface 49 of the latching element 14 preferably rests against the contact surface 50 of the locking element 40.

The contact surface 50 of the locking element 40 is designed as an inclined plane 51. The contact surface 50 running around the longitudinal axis 3 forms a truncated cone with an opening angle 52 of 20 ° to 80 °. The opening angle 52 advantageously has a size of 60 °.

The inventive design of the electrical plug connection 7 ensures that in the event of a tensile load on the plug connection 7 on the ends 8, 9 ( Fig. 1 ) of the components 1, 2 of the plug connection 7 against the plugging direction 4, the locking element 40 holds the locking element 14 in the locking recess 24. In the event of a tensile load opposite to the insertion direction 4, the locking element 14 is preferably subjected to force by the locking element 40 in the locking recess 24. The latching element 14 or the latching lug 42 of the latching tongue 44 is reliably prevented from being lifted out of the latching recess 24 of the second component 2 or the socket 20 by tensile loading. If one and / or the other end 8, 9 of the components 1, 2 is pulled against the insertion direction 4, the locking element 40 will lock the locking element 24 located in the locking recess 24 of the second component 2 in its locking position. A loosening of the locking due to an increased tensile force at the ends 8, 9 ( Fig. 1 ) of the components 1, 2 of the connector 7 is prevented. To cancel the locking according to the invention, the latching element 14 must be moved axially relative to the locking element 40 against the insertion direction 4. At a z. B. effected via the sliding sleeve 6 withdrawal of the locking element 14 from the locking element 40, the locking element 14 is released for radial deflection, so that it can move radially inward into the free space 45. As a result of the axial movement opposite to the insertion direction 4, the contact surface 47 of the locking lug 42, which forms an inclined plane, slides on the side wall 26a and experiences a radially directed force inward, whereby the locking lug 42 comes free from the latching recess 24 and the locking device is released. The locking device opens. The plug 10 forming the first component 1 can be pulled out of the second component 2 forming the socket 20.

The representation of the further embodiment in FIGS Figures 6 to 8 corresponds in basic structure to those of Figures 1 to 5 . The same reference numbers are used for the same parts.

In the embodiment according to Figures 6 to 8 is a compared to the embodiment of the Figures 1 to 5 Modified coupling of the actuating element 5, designed as a sliding sleeve 6, to the carrier sleeve 15 having the locking elements 14 is provided. The annular flange 16 not only interacts with the annular shoulder 38 of the sliding sleeve 6. In the embodiment according to Figures 6 to 8 the annular flange 16 of the carrier sleeve 15 lies between the annular shoulder 38 and an inner shoulder 39. The annular shoulder 38 and the inner shoulder 39 are spaced apart in the axial direction of the sliding sleeve 6 and delimit a receiving groove 35. The annular flange 16 of the carrier sleeve 15 is held in this receiving groove 35 . As a result, the actuating element 5 designed as a sliding sleeve 6 is connected to the latching element 14 in both axial directions.

When the plug connection 7 is plugged together, the insertion bevel 31 of the second component 2 will slide onto the frustoconical section 33 of the first component 1, as described above. When the locking element 14 is axially pushed back when the insertion bevel 32 of the insertion opening 31 slides open, the sliding sleeve 6, together with the locking element 14, is axially displaced against the insertion direction 4. The axial displacement of the locking element 14 together with the carrier sleeve 15 is delimited by the peripheral flange 17 of the base body 11 of the first component 1. This intermediate position is in Fig. 7 shown.

During the further movement in the plug-in direction 4, the insertion bevel 31 passes over the locking lug 42 of the axially fixed locking element 14, the locking element 14 being displaced radially inward into the free space 45. As soon as the locking lug 42 has been axially passed, it springs radially outward from the free space 45 and engages in the locking recess 24 of the second component 2. At the same time, the locking element 14 is advantageously moved axially towards the locking element 40 by the spring 19 until the axial end position of the locking element 14 is reached. In this end position, the free end 43 of the latching element 14 advantageously rests against the contact surface 50 of the locking element 40. The locking lug 42 of the locking element 14 is held locked in the locking recess 24.

Due to the coupling of the sliding sleeve 6 in both axial directions of movement of the locking element 14, the axial movement of the locking element 14 can be visually recognized by the user via the axial position of the sliding sleeve 6. Based on the axial position of the sliding sleeve 6 in the position after Fig. 8 the user can recognize a proper latching and locking of the connector.

In the embodiment according to Fig. 9 a locking recess 24 is shown in the second component 2, which is advantageously designed as a circumferential inner locking groove 25 in the base body 21. In the embodiment according to Fig. 9 formed locking groove 25 has a U-shaped cross section. The side walls 26a 'and 26b' form annular surfaces which lie in planes which are at right angles to the longitudinal center axis 3 of the plug connection 7. The longitudinal center axis 3 of the plug connection 7 is perpendicular to the imaginary planes of the side walls 26a 'and 26b'.

The locking element 40 is designed as an outer ring 55, in particular at the end of the plug sleeve 13. The contact surface 50 provided on the locking element 40 for the free end 43 of the locking tongue 14 is at an angle 52, as shown in FIG Fig. 5 is shown. The contact surface 50 of the locking element 40 is opposite the mating surface 49 of the latching element 14; as in Fig. 5 As shown, the mating surface 49 is preferably parallel to the contact surface 50. The latching lug 42 of the latching element 14 is V-shaped in cross section, so that the side wall 26a ′ perpendicular to the longitudinal axis 3 is opposed by a contact surface 47 which is at an angle 28a to the longitudinal axis 3 like this in Fig. 5 is shown.

The functioning of the plug connection according to the embodiment Fig. 9 corresponds to the exemplary embodiments described above. To release the plug connection, the sliding sleeve 6 is moved axially against the plug-in direction 4, as a result of which the latching element 14 is axially displaced on the base body 11 counter to the plug-in direction 4. As a result, the mating surface 49 of the latching tongue 14 is released from the contact surface 50 of the locking element 40. Due to the axial movement opposite to the insertion direction 4, the contact surface 47 forming an inclined plane slides on the groove edge of the locking recess 24 and experiences a radially inward force, whereby the locking lug 42 is released from the locking recess 24 and the locking device is released. The plug connection 7 is locked as described for the other exemplary embodiments.

Claims (12)

Electrical plug connection consisting of two components (1, 2) to be connected to one another in a plug-in direction (4) with electrical contacts (12), a first component (1) as a plug (10) and a second component (2) as a socket (20) is formed, and with a locking device acting between the components (1, 2) for mechanically securing the plug connection (7), the locking device comprising a locking element (14) held on the first component (1) and one in the second component (2 ) formed latching recess (24), in which the latching element (14) engages and the plug connection (7) mechanically latches, and with an actuating element (5) acting on the latching element (14), which is used to release the latching by lifting out the latching element (14) is to be moved out of the locking recess (24),
characterized in that a mechanical locking element (40) is provided on the first component (1) carrying the locking element (14), that the locking element (40) is the locking element (14) lying in the locking recess (24) of the second component (2) locked in its latching position, and that in order to cancel the locking, the latching element (14) is to be moved relative to the locking element (40) against the plugging direction (4). Plug connection according to claim 1,
characterized in that in the event of a tensile load on the plug connection (7) against the plugging direction (4), the locking element (40) forces the latching element (14) into the latching recess (24), so that the latching element (14) is lifted out of the latching recess (24) ) is blocked. Plug connection according to claim 1,
characterized in that the latching element (14) is mounted on the first component (1) so as to be displaceable against the plug-in direction (4) of the plug-in connection (7). Plug connection according to claim 1,
characterized in that a spring (19) holds the latching element (14) in an end position and when the plug connection (7) is locked, the latching element (14) is in this end position. Plug connection according to claim 4,
characterized in that in the end position the latching element (14) rests against the locking element (40). Plug connection according to claim 1,
characterized in that the locking element (40) has a contact surface (50) facing the latching element (14) and the contact surface (50) is designed as an inclined plane (51). Plug connection according to claim 6,
characterized in that the plug-in device (7) has a longitudinal axis (3) and the contact surface (50) delimits an angle (52) of 20 ° to 80 °, in particular 60 °, opening in the plug-in direction (4) with the longitudinal axis (3). Plug connection according to claim 6,
characterized in that the latching element (14) has a mating surface (49) which lies opposite or rests against the contact surface (50) of the locking element (40). Plug connection according to claim 1,
characterized in that the locking element (14) is designed as a locking tongue (44) with a locking lug (42) and the locking recess (24) is designed as a locking groove (25) formed in the second component (2). Plug connection according to claim 1,
characterized in that the locking lug (42) has a V-shaped basic shape in cross section. Plug connection according to claim 10,
characterized in that the cross-section of the locking lug (42) engages with the exact shape in the cross-section of the locking recess (24). Plug connection according to claim 1,
characterized in that the latching section of the latching element (14) engaging in the latching recess (24) has a latching surface (47) which, with the longitudinal axis (3) of the plug connection (7), forms an angle (52) of less than in the plugging direction (4) than 90 °.

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