EP4054017A1 - Electrical socket - Google Patents

Abstract

The invention relates to an electrical socket (10) with a housing (14) which has a plug receptacle (28) and a cable receptacle (36), contact springs (30) being arranged in the plug receptacle (28) which are connected to associated plug contacts of a plug connector can be contacted and each electrically connected to a wire connection element (32), and having a wire receiving part (38) which can be inserted together with a data transmission cable (12) into the cable holder (36) and positioned on the wire connection elements (32) for receiving the wires of the data transmission cable (12 ), and having at least one strain relief member (78, 80) reciprocally movable between a release position and a strain relief position. In order to simplify handling of the socket (10) and to reduce the number of individual parts required for this, the at least one strain relief part (78, 80) can be inserted into the cable holder (36), with the cable holder (36) being released in the release position and dips into the cable holder (36) in the strain relief position and, during the transition from the release position to the strain relief position, shifts the wire receiving part (38) from a pre-assembly position to a final assembly position and fixes it in the final assembly position, with it being in the release position and in the strain relief position via a detachable latching connection , which has several locking stages in the strain relief position, can be fixed on the housing (14).

Description

The invention relates to an electrical socket with a housing that has a plug receptacle for inserting a plug connector and a cable receptacle for inserting a data transmission cable, with several contact springs being arranged in the plug receptacle, which can be contacted by assigned plug contacts of the plug connector and can each be electrically connected to a wire connection element , and with a wire receiving part that can be inserted into the cable receptacle together with the data transmission cable and positioned on the wire connection elements for receiving the wires of the data transmission cable, and with at least one strain relief part that can be moved back and forth between a release position spaced apart from the data transmission cable and a strain relief position that rests on the data transmission cable.

Such an electrical socket is used in particular in communications and data transmission technology. The socket interacts with a corresponding plug connector. Through the interaction, a detachable electrical connection can be established, for example, between two data transmission cables. The electrical socket has a plug receptacle in which several contact springs are arranged. A corresponding connector can be inserted into the connector receptacle, with the contact springs arranged in the connector receptacle being able to be contacted by associated plug contacts of the connector. The contact springs are each electrically connected to a wire connection element. The wires of a data transmission cable can be connected to the wire connection elements. For this purpose, the electrical socket on a wire receiving part that receives the wires of the data transmission cable and together with the data transmission cable in a Cable receptacle of the electrical socket can be inserted and positioned on the wire connection elements, so that an electrical connection can be made between the wire connection elements and the wires of the data transmission cable. The data transmission cable can have 2, 4, 6 or 8 wires, for example.

To relieve the strain on the data transmission cable, the electrical socket usually has at least one strain relief part that can be moved back and forth between a release position in which the strain relief part is at a distance from the data transmission cable and a strain relief position in which the strain relief part rests on the data transmission cable. With the aid of the at least one strain relief part, external forces and moments acting on the data transmission cable can be intercepted in order to avoid undesired mechanical loading of the connection between the wires of the data transmission cable and the wire connection elements of the socket.

Snap-in connections between the wire receiving part and the housing are often used to secure the position of the wire receiving part in the housing. Such snap-in connections are, for example, from DE 100 51 097 C2 known. This publication proposes a U-shaped additional part for fixing the wire receiving part in the housing, which has two side walls aligned parallel to one another and which are connected to one another via a rear wall. On their upper side, the side walls carry an inwardly directed guide edge and on their lower side, the side walls carry inwardly directed guide rails. The additional part can be pushed laterally onto the housing of the plug connector, with the inwardly directed guiding edges contacting a bevel of the wire receiving part that is complementary to the guiding edges, so that the wire receiving part is displaced in the direction of the wire connection elements when the additional part is pushed onto the housing and is in a final assembly position is specified on the wire connection elements. In addition, the attachment has two flexible jaw parts. After sliding the additional part on the housing, the jaw parts form a cable support behind the housing. The jaw parts can be locked with a strain relief part, which is designed like a clamp. The strain relief part surrounds the rear of the data cable protruding from the cable holder and makes it possible to absorb external forces and moments acting on the data transmission cable.

From the EP 3 229 325 A1 an electrical socket is known in which a cover is pivotably mounted on the housing. A pivoting movement of the cover slides the wire receiving part in the direction of the wire connection elements. The cover can be snapped onto the housing to secure the position of the wire receiving part. A cable support is arranged on the back of the cover facing away from the housing, on which the data cable protruding from the cable holder can be fixed by means of a clamp-like strain relief part surrounding the data transmission cable in order to absorb external forces and moments acting on the data transmission cable.

A similarly designed electrical socket is from DE 10 2015 008 632 A1 known. In this socket, too, a pivotable cover is articulated on the housing, which forms a position lock for the wire receiving part. A cable support protruding from the rear of the cover interacts with a strain relief part which can be moved from a release position spaced apart from the data transmission cable into a strain relief position adjacent to the data transmission cable in order to absorb external forces and moments acting on the data transmission cable.

With the electrical sockets explained above, positioning the wire receiving part on the wire connection elements and producing a strain relief for the data transmission cable requires several work steps that make handling the sockets more difficult when connecting the data transmission cable. In addition, connecting the data transmission cable to the sockets is time consuming and requires a significant number of individual parts that negatively affect the size of the sockets.

From the CN 202651467 U an electrical socket is known in which a core receiving part can be inserted into a cable receptacle together with a data transmission cable fixed thereto in order to initially assume a pre-assembly position. An insertion wedge can then be inserted perpendicularly to the direction of insertion of the wire receiving part into the cable holder, the wire receiving part being pushed by the insertion wedge into a final assembly position in which the wires of the data transmission cable fixed to the wire receiving part each contact a wire connection element. In order to be able to insert the core receiving part into the cable receptacle, it is necessary for the slide-in part to assume a position separate from the housing of the socket, since otherwise the wire receiving part would be impeded by the slide-in part. After inserting the core receiving part, the slide-in wedge must be pushed completely into the cable receptacle so that the core receiving part reaches its end position.

From the DE 10 2011 051 951 A1 and the US 2012/0135633 A1 electrical plug connectors are known with a housing that has a cable receptacle for inserting a data transmission cable, and with a strain relief part that can be moved back and forth between a release position spaced apart from the data transmission cable and a strain relief position that rests on the data transmission cable. The strain relief part can be inserted into the cable holder, releasing the cable holder in the release position and dipping into the cable holder in the strain relief position.

The object of the present invention is to further develop an electrical socket of the type mentioned at the outset in such a way that it is easier to handle when connecting a data transmission cable and, on the one hand, the number of individual parts required for this is reduced in order to enable the socket to be produced inexpensively with a small size allow, and on the other hand a strain relief function for different diameters of the data transmission cable is realized.

This object is achieved by an electrical socket with the features of patent claim 1.

In the electrical socket according to the invention, the at least one strain relief part not only has the function of absorbing external forces and moments acting on the data transmission cable in order to avoid undesired mechanical stress on the connection of the individual wires of the data transmission cable to the wire connection elements of the socket, but also the at least one Strain relief part also has the function of moving the wire receiving part inserted into the cable holder together with the data transmission cable from a pre-assembly position into a final assembly position and fixing it in the final assembly position, in which the wires of the data transmission cable contact the wire connection elements of the socket. The at least one strain relief part can be inserted into the cable holder, releasing the cable holder in the release position, so that in a first step the wire receiving part can be inserted into the cable holder together with the data transmission cable without being impeded by the strain relief part. The core receiving part can assume a pre-assembly position in the cable receptacle, in which it is at a rather small distance from the core connection elements. The at least one strain relief part can then be moved from its release position into its strain relief position, in which it dips into the cable receptacle. During the transition from the release position to the strain relief position, the wire receiving part is pushed by the at least one strain relief part into its final assembly position, in which the wires of the data transmission cable make contact with the wire connection elements. If the at least one strain relief part assumes its strain relief position, it secures the core receiving part in the final assembly position and at the same time absorbs external forces and moments acting on the data transmission cable.

The handling of the electrical socket according to the invention when connecting a data transmission cable is therefore very simple. The production of a strain relief and the positioning of the wire receiving part in its final assembly position takes place simultaneously during the same work step, namely during the movement of the strain relief part from the release position into the strain relief position. Only a few individual parts are therefore required to secure the wire receiving part and to produce a strain relief. This permits cost-effective production and enables the electrical socket to be small in size.

The at least one strain relief part can be fixed in the release position and in the strain relief position on the housing. This further simplifies handling of the electrical socket when connecting a data transmission cable, since the at least one strain relief part can be fixed in the release position on the housing together with the data transmission cable in the cable receptacle before the wire receiving part is inserted. As a result, the at least one strain relief part can assume a predefined position when the wire receiving part is inserted together with the data transmission cable into the cable seat. After inserting the wire receiving part together with the data transmission cable into the cable receiving area, the at least one strain relief part can be moved into its strain relief position and fixed again on the housing in this position.

According to the invention, the at least one strain relief part can be detachably latched to the housing in the release position and in the strain relief position. The at least one strain relief part is thus fixed to the housing via a releasable latching connection, the latching connection having a plurality of latching steps for the at least one strain relief part in the strain relief position of the at least one strain relief part. This enables a strain relief function to be implemented for different diameters of the data transmission cable.

It is advantageous if the at least one strain relief part has a thrust surface which, during the transition of the at least one strain relief part from the release position to the strain relief position, contacts a contact surface of the core receiving part assigned to the thrust surface in order to apply a shearing force to the core receiving part. If the at least one strain relief part is moved from the release position into the strain relief position, it exerts a shearing force on the core receiving part in that the shearing surface of the strain relief part contacts a contact surface of the core receiving part assigned to the shearing surface. Under the effect of the shearing force, the core receiving part is moved from its pre-assembly position to its final assembly position, in which the cores of the data transmission cable each contact a core connection element, so that an electrical connection is established between the cores of the data transmission cable and the core connection elements of the electrical socket.

The thrust surface can have a curved geometry, for example. As a result, the force-displacement diagram can be optimized, ie the at least one strain relief part can exert different shear forces on the contact surface of the wire receiving part by providing a curve geometry on its way from the release position to the strain relief position.

The core receiving part can be inserted together with the data transmission cable in an insertion direction into the cable receptacle of the plug connector. It is advantageous if the thrust surface of the at least one strain relief part forms a wedge surface aligned obliquely to the insertion direction of the wire receiving part. The at least one strain relief part thus acts in the manner of a wedge thrust on the core receiving part, which can be subjected to a shearing force via the wedge surface and the associated contact surface.

The at least one strain relief part is preferably movably mounted on the housing of the electrical socket.

It is favorable if the at least one strain relief part is mounted in a linearly displaceable manner on the housing of the electrical socket. In such an embodiment of the invention, the at least one strain relief part can be inserted in a straight line into the cable receptacle.

In order to simplify the insertion of the at least one strain relief part into the cable receptacle and the transition of the at least one strain relief part from the release position to the strain relief position and to reduce the risk of the at least one strain relief part jamming during the transition from the release position to the strain relief position, in a preferred Configuration of the invention arranged on the at least one strain relief part and on an inside of the cable holder interacting with each other, in particular complementary to each other configured guide elements.

The guide elements are preferably designed as guide grooves and guide ribs, the guide grooves being designed to complement the guide ribs and the guide ribs being slidably received in each case by a guide groove.

In a preferred embodiment of the invention, the direction of movement of the at least one strain relief part is aligned perpendicularly to the direction of insertion of the core receiving part.

It is favorable if the at least one strain relief part has a locking surface against which the wire receiving part rests in the final assembly position. The locking surface secures the wire receiving part in its final assembly position. The wire receiving part is thus held immovably in its final assembly position.

The locking surface is favorably aligned perpendicular to the direction of insertion of the wire receiving part.

In the strain relief position, external forces and moments acting on the data transmission cable can be absorbed by the at least one strain relief part. To this end, it is advantageous if the at least one strain relief part has a strain relief surface that can be placed against the data transmission cable on its end face. The strain relief part can exert a pressing force on the data transmission cable via the strain relief surface when the strain relief part assumes its strain relief position.

In an advantageous embodiment of the invention, the strain relief surface is designed in the shape of an arc, in particular in the shape of a circular arc.

In order to be able to move the at least one strain relief part easily from its release position into its strain relief position, in a preferred embodiment of the invention the at least one strain relief part has at least one tool contact element for contacting an auxiliary tool for moving the strain relief part from the release position into the strain relief position. Pliers can be used as an auxiliary tool, for example, or a screwdriver, for example, which can be positioned with its tip on the tool contact element in order to exert a force on the strain relief part so that it is moved from the release position into the strain relief position.

The at least one tool contact element can be designed, for example, in the form of an elevation, a depression, an opening, or for example in the form of an end surface of the strain relief part, in particular in the form of a flat end surface.

A particularly cost-effective production of the electrical socket can be achieved in that the at least one strain relief part consists of a plastic material.

In a preferred embodiment of the invention, the electrical socket has two strain relief parts. The two strain relief parts can each be moved from a release position, in which they do not impede the insertion of the core receiving part together with the data transmission cable into the cable receptacle, into a strain relief position in which they dip into the cable receptacle and intercept external forces and moments acting on the data transmission cable.

It is advantageous if the two strain relief parts can each be inserted into the cable receptacle through an opening in the housing. In such an embodiment of the invention, the housing of the electrical socket has openings in the area of the cable holder, through which the strain relief parts can be inserted into the cable holder.

It is of particular advantage if the two strain relief parts are opposite one another and accommodate the data transmission cable between them in the strain relief position. The two strain relief parts can be moved in opposite directions from their release position to their strain relief position, i.e. the two strain relief parts can be moved towards one another during the transition from the release position to the strain relief position in order to receive the data transmission cable arranged in the cable holder in the strain relief position between them and from to apply a pressing force to opposite sides. The two strain relief parts can be moved simultaneously from their release position into their strain relief position, preferably with the help of an auxiliary tool, for example parallel-closing pliers, which engage with their jaws on an end face of a strain relief part. While moving out of her Release position in their strain relief position, the strain relief parts move the wire receiving part from the pre-assembly position to the final assembly position. If the strain relief parts assume their strain relief position, they set the wire receiving part in the final assembly position.

It is of particular advantage if the two strain relief parts are configured identically. This makes it possible to further reduce the manufacturing cost of the socket according to the invention.

Figur 1:

eine perspektivische Darstellung einer elektrischen Steckbuchse mit einem angeschlossenen Datenübertragungskabel;

Figur 2:

eine perspektivische Darstellung der elektrischen Steckbuchse aus Figur 1, wobei zwei Zugentlastungsteile ihre Freigabestellung einnehmen und ein Aderaufnahmeteil vor einer Kabelaufnahme positioniert ist und die freien Enden der Adern des Datenübertragungskabels vom Aderaufnahmeteil aufgenommen werden;

Figur 3:

eine perspektivische Darstellung des Aderaufnahmeteils aus Figur 2 mit den darin aufgenommenen freien Enden der Adern des Datenübertragungskabels;

Figur 4:

eine Schnittansicht der elektrischen Steckbuchse aus Figur 1, wobei die beiden Zugentlastungsteile ihre Freigabestellung einnehmen und das zusammen mit dem Datenübertragungskabel in die Kabelaufnahme eingeführte Aderaufnahmeteil eine Vormontagestellung einnimmt;

Figur 5:

eine Schnittdarstellung entsprechend Figur 4, wobei die beiden Zugentlastungsteile eine erste Zwischenstellung zwischen ihrer Freigabestellung und ihrer Zugentlastungsstellung einnehmen und das Aderaufnahmeteil eine Position zwischen der Vormontagestellung und einer Endmontagestellung einnimmt;

Figur 6:

eine Schnittdarstellung entsprechend Figur 4, wobei die beiden Zugentlastungsteile eine zweite Zwischenstellung zwischen ihrer Freigabestellung und ihrer Zugentlastungsstellung einnehmen und das Aderaufnahmeteil seine Endmontagestellung einnimmt;

Figur 7:

eine Schnittdarstellung entsprechend Figur 4, wobei die beiden Zugentlastungsteile ihre Zugentlastungsstellung einnehmen und das Aderaufnahmeteil in seiner Endmontagestellung festlegen;

Figur 8:

eine erste perspektivische Darstellung eines der beiden Zugentlastungsteile der elektrischen Steckbuchse aus Figur 1;

Figur 9:

eine zweite perspektivische Darstellung des Zugentlastungsteils aus Figur 8;

Figur 10:

eine teilweise aufgebrochene perspektivische Darstellung der elektrischen Steckbuchse aus Figur 1, wobei die beiden Zugentlastungsteile ihre Freigabestellung einnehmen;

Figur 11:

eine vergrößerte Darstellung von Detail X aus Figur 10;

Figur 12:

eine teilweise aufgebrochene perspektivische Darstellung der elektrischen Steckbuchse aus Figur 1, wobei die beiden Zugentlastungsteile ihre Zugentlastungsstellung einnehmen;

Figur 13:

eine vergrößerte Darstellung von Detail Y aus Figur 12.

The following description of a preferred embodiment of the invention is used in connection with the drawing for more detailed explanation. Show it:

Figure 1:

a perspective view of an electrical socket with a connected data transmission cable;

Figure 2:

a perspective view of the electrical socket figure 1 , wherein two strain relief parts assume their release position and a wire receiving part is positioned in front of a cable seat and the free ends of the wires of the data transmission cable are received by the wire receiving part;

Figure 3:

a perspective view of the wire receiving part figure 2 with the free ends of the wires of the data transmission cable received therein;

Figure 4:

Figure 12 shows a sectional view of the electrical socket figure 1 , wherein the two strain relief parts assume their release position and the core receiving part inserted into the cable receptacle together with the data transmission cable assumes a pre-assembly position;

Figure 5:

a sectional view accordingly figure 4 , wherein the two strain relief parts occupy a first intermediate position between their release position and their strain relief position and the wire receiving part occupies a position between the pre-assembly position and a final assembly position;

Figure 6:

a sectional view accordingly figure 4 , wherein the two strain relief parts assume a second intermediate position between their release position and their strain relief position and the wire receiving part assumes its final assembly position;

Figure 7:

a sectional view accordingly figure 4 , wherein the two strain relief parts take their strain relief position and set the wire receiving part in its final assembly position;

Figure 8:

a first perspective view of one of the two strain relief parts of the electrical socket figure 1 ;

Figure 9:

a second perspective view of the strain relief figure 8 ;

Figure 10:

a partially broken perspective view of the electrical socket figure 1 , wherein the two strain relief parts take their release position;

Figure 11:

an enlarged view of detail X figure 10 ;

Figure 12:

a partially broken perspective view of the electrical socket figure 1 , wherein the two strain relief parts take their strain relief position;

Figure 13:

an enlarged view of Detail Y figure 12 .

In the drawing, an advantageous embodiment of an electrical socket according to the invention is shown schematically, which is assigned the reference numeral 10 in its entirety. A multi-core data transmission cable 12 is connected to the electrical socket 10 .

The electrical socket 10 has a substantially cuboid housing 14 with a plug connection side 16 and a cable connection side 18 facing away from the plug connection side 16. Extending from the plug connection side 16 to the cable connection side 18 are a housing top 20 and a housing bottom 22 as well as a first housing longitudinal side 24 and a second Housing long side 26.

A plug receptacle 28 is arranged on the plug connection side 16 in the form of a cavity in which a plurality of contact springs 30 positioned next to one another in a row are arranged. A plug connector of complementary configuration can be inserted into the plug receptacle 28, with the contact springs 30 being able to be contacted by associated plug contacts of the plug connector. Such connectors are known per se to those skilled in the art and therefore do not require any further explanation here.

The contact springs 30 arranged in the plug receptacle 28 are each connected to a wire connection element 32 via electrical connection elements which are known per se and are therefore not shown in the drawing to provide a better overview. The wire connection elements 32 are positioned in the housing 14 . In the exemplary embodiment shown, they are held on a printed circuit board 34 , protruding from the printed circuit board 34 in the direction of the cable connection side 18 . The wire connection elements 32 are designed as insulation displacement/clamping contacts. Alternatively, the wire connection elements 32 could be designed as piercing contacts, for example.

A cable receptacle 36 is arranged on the cable connection side 18 and is also designed as a hollow space. In the cable holder 36 can Wire receiving part 38 are inserted in an insertion direction 40. The insertion direction 40 is aligned parallel to a longitudinal axis 42 of the housing 14 . The wire receiving part 38 has a central passage opening 44 through which the exposed wires 46, 48, 50, 52, 54, 56, 58, 60 of the data transmission cable 12 can be passed. On its front side 62, the wire receiving part 38 has a number of receiving channels 64 corresponding to the number of wires 46 to 60, with each individual wire 46 to 60 positioned in a receiving channel 64 and by means of known and therefore in the drawing to achieve a better overview not shown clamping elements can be clamped in the respective receiving channel 64.

Relative to the longitudinal axis 42, the housing 14 has an upper housing opening 66 and a lower housing opening 68 opposite this at the height of the cable receptacle 36. An upper housing web 70 is arranged between the upper housing opening 66 and the cable connection side 18, via which the two housing long sides 24 and 26 are connected to one another, and between the lower housing opening 68 and the cable connection side 18 there is a lower housing web 72, via which the two housing long sides 24 and 26 are connected to each other. The upper housing web 70 has an upper locking lug 74 facing the upper housing opening 66, and the lower housing web 72 has a lower locking lug 76 facing the lower housing opening 68.

The upper opening 66 in the housing forms an access for a first strain relief part 78 which can be inserted into the cable receptacle 36 via the upper opening 66 in the housing. The direction of movement of the first strain relief part 78 runs perpendicularly to the insertion direction 40 of the wire receiving part 38. In a corresponding manner, the lower housing opening 68 forms an access for a second strain relief part 80, which can be inserted into the cable receptacle 36 via the lower housing opening 68. The direction of movement of the second strain relief part 80 is also aligned perpendicularly to the insertion direction 40 of the wire receiving part 38 and the direction of movement of the first strain relief part 78 opposite.

The two strain relief parts 78, 80 are of identical design. They each have a flat end surface 82, 84, with the two end surfaces 82, 84 facing away from one another and each forming a first tool contact element on which an auxiliary tool can be placed in order to insert the two strain relief parts 78, 80 into the cable receptacle 36. A pair of parallel-closing pliers, for example, can be used as an auxiliary tool, the pliers jaws of which can each be placed against one of the end faces 82, 84.

On their end faces 86, 88 facing one another, the two strain relief parts 78, 80 each have an arcuate strain relief surface 90, 92 which can be applied to the data transmission cable 12 in order to absorb external forces and moments acting on the data transmission cable 12.

A push surface 94 , 96 adjoins the strain relief surfaces 90 , 92 in the direction of the wire connection elements 32 and forms a wedge surface 98 or 100 oriented obliquely to the insertion direction 40 of the wire receiving part 38 .

Facing the first longitudinal side 24 of the housing, the two strain relief parts 78 and 80 each have two first guide ribs 102, 104. Facing the second longitudinal side 26 of the housing, the two strain relief parts 78 and 80 each have two second guide ribs 106 , 108 . The first guide ribs 102, 104, like the second guide ribs 106, 108, interact with complementary guide grooves 110, which are formed in the cable receptacle 36 and which receive the guide ribs 102, 104, 106, 108 in a form-fitting and sliding manner.

On their rear sides 112, 114 facing the housing webs 72, 74, the first strain relief part 78 and the second strain relief part 80 each carry a plurality of first latching projections 116, which are arranged at a small distance from the strain relief surfaces 90, 92, and a plurality of second latching projections 118, which are at a small Distance to the end faces 82, 84 are arranged.

On their front sides 120, 122 facing the wire receiving part 38, the two strain relief parts 78, 80 each have a flat locking surface 124, 126, which is aligned perpendicular to the insertion direction 40 of the wire receiving part 38 and extends from the respective thrust surface 94 or 96 to the end surface 82 or 84 extends.

On their end surfaces 82 and 84, the two strain relief parts 78, 80 each have a recess 128, 130, which forms a second tool contact element for contacting an auxiliary tool, in particular for contacting the tip of a screwdriver, which is inserted into the recess 128 or 130 can, in order to move the respective strain relief part 78, 80 in the direction of the data transmission cable 12.

Between the depression 128, 130 and the rear side 112 or 114, the two strain relief parts 78, 80 each have an opening 132 or 134, which extends from the end surface 82, 84 to the strain relief surface 90, 92.

On their rear side 112, 114, the two strain relief parts 78, 80 have a semi-cylindrical recess 136 which is accessible from the end face 82 or 84, respectively.

To connect the data transmission cable 12 to the electrical socket 10, the cores 46 to 60 of the data transmission cable 12 can be exposed in a first step. The exposed wires 46, 60 can then through the central passage opening 44 of the wire receiving part 38 are passed through and each clamped in a receiving channel 64. End sections of the exposed wires 46, 60 which protrude laterally from the wire receiving part 38 can then be severed.

In a further work step, the wire receiving part 38 can be inserted together with the data transmission cable 12 into the cable seat 36 so far that the wire receiving part 38 assumes a pre-assembly position arranged at a small distance from the wire connection elements 32 . This will be off figure 4 clear.

The two strain relief parts 78, 80 initially take a figure 4 shown release position, in which they release the cable holder 36, so that the wire receiving part 38 can be moved into the pre-assembly position without being hindered by the strain relief parts 78, 80. In their release position, the strain relief parts 78, 80 are releasably latched to the housing 14 by means of the first latching projections 116 and the latching lugs 74, 76. This is in particular from the Figures 10 and 11 clear.

After the wire receiving part 38 has been moved into the pre-assembly position, the strain relief parts 78, 80 can be removed from their in figure 4 shown release position in figure 7 shown strain relief position are moved, wherein they can be releasably locked in the strain relief position by means of the locking lugs 74, 76 and the second locking projections 116 with the housing 14 (see Figures 12 and 13 ) and exert oppositely directed clamping forces on the data transmission cable 12 by means of the strain relief surfaces 90, 92, in order thereby to intercept external forces and moments acting on the data transmission cable 12. In order to shift the strain relief members 78, 80 from their release position to their strain relief position, the jaws of parallel closing pliers known per se (not shown in the drawing) can be applied to the end surfaces 82, 84.

When the strain relief parts 78, 80 are moved from their release position to their strain relief position, the thrust surfaces 94, 96 each slide along a contact surface 138 or 140 of the wire receiving part 38, which is assigned to the thrust surfaces 94, 96, so that the wire receiving part 38, starting from its in figure 4 shown pre-assembly in its in the figures 6 and 7 shown final assembly position is shifted, in which the wire connection elements 32 each contact one of the wires 46 to 60 of the data transmission cable 12 and thereby establish an electrical connection between the wires 46 to 60 of the data transmission cable 12 and the wire connection elements 32. During the transition from their release position to their strain relief position the strain relief parts 78, 80 are moved perpendicularly to the insertion direction 40 of the wire receiving part 38, and the wedge-type interaction of the thrust surfaces 94, 96 and the contact surfaces 138, 140 moves the wire receiving part 38 in the insertion direction 40 from the pre-assembly position into the final assembly position. This is in particular from the Figures 5 and 6 clear.

In the strain relief position, the locking surfaces 124, 126 of the strain relief parts 78, 80 rest against the rear side of the wire receiving part 38, so that the wire receiving part 38 is fixed in its final assembly position. This is made out in particular figure 7 clear.

The two strain relief parts 78, 80, which dip into the cable receptacle 36, thus make it possible on the one hand to absorb external forces and moments acting on the data transmission cable 12, and on the other hand the wire receptacle part 38 can be moved from the pre-assembly position to the final assembly position by means of the strain relief parts 78, 80 be moved and fixed in the final assembly position.

If wire receiving part 38 is to be removed from cable receiving part 36 together with data transmission cable 12, an auxiliary tool, for example inserting the tip of a screwdriver, can be inserted into rear recesses 136 of the strain relief parts 78, 80 the latching connection between the second latching projections 118 and the latching lugs 74, 76 can be released. The second latching projections 118 can be released from the housing-side latching lugs 74, 76 by elastic deformation of the strain relief parts 78, 80 in the region of their rear sides 112, 114. The elastic deformability of the strain relief parts 78, 80 in the area of the rear sides 112, 114 is made possible by the provision of the openings 132, 134. After the latching connection between the second latching projections 116 and the housing-side latching lugs 74, 76 has been released, the strain relief parts 78, 80 can be moved back into their release position, so that the first latching projections 116 latch with the housing-side latching lugs 74, 76. The wire receiving part 38 can then be pulled out of the cable receptacle 36 together with the data transmission cable 12 counter to the insertion direction 40 .

Claims (15)

Electrical socket with a housing (14) which has a plug receptacle (28) for inserting a plug connector and a cable receptacle (36) for inserting a data transmission cable (12), a plurality of contact springs (30) being arranged in the plug receptacle (28) which can be contacted by assigned plug contacts of the plug connector and are each electrically connected to a wire connection element (32), and having a wire receiving part (38) which can be inserted together with the data transmission cable (12) into the cable receptacle (36) and positioned on the wire connection elements (32) for receiving the cores (46, 48, 50, 52, 54, 56, 58, 60) of the data transmission cable (12), and with at least one strain relief part (78, 80) which is spaced between a release position spaced apart from the data transmission cable (12) and a release position on the data transmission cable ( 12) adjacent strain relief position can be moved back and forth, characterized in that the at least one strain relief part (78, 80) can be inserted into the cable holder (36), in the release position it releases the cable holder (36) and in the strain relief position it dips into the cable holder (36) and during the transition from the release position to the strain relief position the core holder part (38) from a pre-assembly position shifted into a final assembly position and fixed in the final assembly position, wherein the at least one strain relief part (78, 80) can be fixed in the release position and in the strain relief position on the housing (14), the fixing of the at least one strain relief part (78, 80) on the housing ( 14) via a detachable latching connection which, in the strain relief position of the at least one strain relief part (78, 80), has a plurality of latching stages for the at least one strain relief part (78, 80). Electrical socket according to Claim 1, characterized in that the at least one strain relief part (78, 80) has a thrust surface (94, 96) which, during the transition of the at least one strain relief part (78, 80) from the release position into the strain relief position, forms one of the thrust surfaces ( 94, 96) associated contact surface (138, 140) of the wire receiving part (38) makes contact in order to apply a shearing force to the wire receiving part (38). Electrical socket according to Claim 2, characterized in that the thrust surface (94, 96) forms a wedge surface (98, 100) aligned obliquely to the insertion direction (40) of the wire receiving part (38). Electrical socket according to Claim 1, 2 or 3, characterized in that the at least one strain relief part (78, 80) is mounted on the housing (14) in a linearly displaceable manner. Electrical socket according to one of the preceding claims, characterized in that on the at least one strain relief part (78, 80) and on an inside of the cable receptacle (36) there are guide elements (102, 104, 106, 108, 110) which interact with one another and are in particular designed to be complementary to one another are. Electrical socket according to one of the preceding claims, characterized in that the direction of movement of the at least one strain relief part (78, 80) is aligned perpendicularly to the insertion direction (40) of the core receiving part (38). Electrical socket according to one of the preceding claims, characterized in that the at least one strain relief part (78, 80) has a locking surface (124, 126) against which the wire receiving part (38) rests in the final assembly position. Electrical socket according to Claim 7, characterized in that the locking surface (124, 126) is aligned perpendicularly to the insertion direction (40) of the core receiving part (38). Electrical socket according to one of the preceding claims, characterized in that the at least one strain relief part (78, 80) has a strain relief surface (90, 92) that can be placed against the data transmission cable (12) on its end face (86, 88). Electrical socket according to Claim 9, characterized in that the strain relief surface (90, 92) is designed in an arc shape. Electrical socket according to one of the preceding claims, characterized in that the at least one strain relief part (78, 80) has at least one tool contact element (82, 84, 128, 130) for contacting an auxiliary tool for moving the at least one strain relief part (78, 80). the release position to the strain relief position. Electrical socket according to one of the preceding claims, characterized in that the electrical socket (10) has two strain relief parts (78, 80). Electrical socket according to Claim 12, characterized in that the two strain relief parts (78, 80) can each be inserted through an opening (66, 68) in the housing (14) into the cable receptacle (36). Electrical socket according to Claim 12 or 13, characterized in that the two strain-relief parts (78, 80) lie opposite one another and, in the strain-relief position, receive the data transmission cable (12) between them. Electrical socket according to Claim 12, 13 or 14, characterized in that the two strain relief parts (78, 80) are of identical design.

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