DE102022004924B3 - Cable connection device and extension cable - Google Patents

Abstract

The invention relates to a cable connection device (10) for electrically connecting the wires (12) of a first and second data transmission cable (11, 141) to a first and a second cable connection device (19, 119) which have a housing (20) and a wire fixing part (40, 70), wherein each wire fixing part (40, 70) comprises a plurality of wire receiving channels (47, 48, 49, 50, 73, 74, 75, 76), and wherein each cable connection device (19, 119) comprises a connection contact (100) with two end regions (108, 118) on which a wire connection element (102, 112) is arranged. The invention also relates to an extension cable (200), on the front end regions of which a first and second cable connection device (19, 119) is arranged. For a simple and secure electrical connection between the wires (12) of the data transmission cables (11, 141) to be connected in a cost-effective embodiment, it is proposed that the connecting contact (100) of the first cable connection device (19) connects the first wires (12) of the first and second data transmission cables (11, 141) and the connecting contact (100) of the second cable connection device (119) connects the second wires (12) of the first and second data transmission cables (11, 141), wherein the connection of the wires (12) of the data transmission cables (11, 141) is brought about by directly joining the first and second cable connection devices (19, 119).

Description

The invention relates to a cable connection device for electrically connecting the wires of a first data transmission cable to the wires of a second data transmission cable with a first and a second cable connection device according to the preamble of independent claim 1 and an extension cable according to claim 10.

Such cable connection devices are used in particular in single-pair Ethernet connections (SPE) for transmitting data and energy via two-wire data transmission cables. In contrast to known eight-wire Ethernet connections, single-pair Ethernet connections (SPE) enable the transmission of signals via the Ethernet protocol using only one twisted pair of wires with transmission rates of 10 Mb/s to 1 GBit/s. This leads to material savings, which particularly favors industrial use. At the same time, SPE enables energy transmission with power of up to 50 watts at a temperature-dependent current load of 2 to 3.5 A or 4 to 7 A simultaneously with signal and data transmission.

An SPE data transmission cable has exactly two wires. Each wire consists of an electrical conductor that is covered by a wire insulation, whereby the wires are twisted together to form a wire pair. The electrical conductor can be designed as a stranded conductor made of, for example, seven or nineteen stranded individual wires or as a solid conductor. For short transmission distances of up to around 20 m, data transmission cables with stranded conductors are often used, which are characterized by high flexibility. For longer transmission distances, solid conductors are preferred, as their compact cross-section means they have lower attenuation.

To protect the wire pair against crosstalk of signals from and to wire pairs of adjacent data transmission cables, the wire pair can be surrounded by a pair shield, whereby this pair shield can be designed, for example, as a conductive foil strip that is wound around the wire pair.

The wires of the data transmission cable are surrounded by a cable sheath made of an insulating material. A cable shield in the form of a conductive braided shield is often arranged between the wire sheath and the wire pair, which is optionally surrounded by a pair shield. This cable shield protects the signal current flowing through the wires of the data transmission cable from disruptive radiation that can affect the data transmission cable from the outside. Sources of such external interference include, for example, radiation from cell phones, cell phone masts or neighboring incompletely shielded or unshielded data transmission arrangements in the form of connectors.

In typical applications, such two-core data transmission cables are laid in cable ducts inside buildings, with the front end areas of the data transmission cables being fitted with suitable connection components, such as SPE connectors or SPE junction boxes, after installation. Such connection components are known to the expert, for example, from the EN 10 2019 131 596 B3 or from the EN 10 2020 117 772 A1 known. In the event of a subsequent change/expansion of the aforementioned network infrastructure, it becomes necessary to extend the data transmission cables that have already been laid by connecting additional data transmission cables. This is possible, for example, by using additional connection components in the form of connectors and junction boxes, but is very complex. Therefore, the use of simple, intuitively connectable cable connection devices makes sense for these applications.

The WO 2022 150 388 A1 discloses a cable connection device 10 with a central connector housing 11, which has a cable receiving area 114, 115 at its front end areas 111, 112 for receiving the cable sheaths of the data transmission cables 1 to be connected, wherein the cable receiving areas 114, 115 open in the direction of the middle part 113 of the connector housing 11 into wire receiving channels 117 for receiving the wires 4 of the data transmission cables 1. A stop element 118 limits the maximum insertion depth of the wires 4 into the wire receiving channels 117. Two slots 116 extend vertically over the entire length of the middle part 113 for receiving two connection contacts 12, the end areas of which are provided with piercing contacts (IPCs) 122, 123 for electrically connecting the connection contacts 12 to the wires 4. The insertion of the connecting contacts 12 into the slots 116 provided for this purpose and the subsequent pressing of the connecting contacts 12 into the openings of the wire receiving channels 117 with the wires 4 arranged therein by means of the press covers 13 rotatably mounted in the joints 1130 causes the piercing contacts 122, 123 arranged at the end regions of the connecting contacts 12 to penetrate through the wire insulation of the wires 4 and then cut into/penetrate the inner conductors of the wires 4. The position of the press cover 13 relative to the connector housing 11 is secured by engaging the locking projection 119 in the complementary opening 136, 137 of the press cover 13. The disadvantage is the difficult handling required to connect the data transmission cables. The proposed solution requires the simultaneous actuation of the two press covers 13 relative to the connector housing 11 while maintaining the position of the wires 4 in the wire receiving channels 117 in order to avoid jamming/tilting of the connection contact 12 in the slots 116.

From the DE 20 2014 104 353 U1 A cable connector for connecting two cables is known, which has a central connector housing 3 with two connecting contacts 5 arranged therein for electrically connecting the wires 6 of the cables to be connected. On the top and bottom of the central connector housing 3, two wire receiving channels 313, 314 extend over the entire length of the cable connector for receiving two wires 6 arranged next to one another. The two connecting contacts 5 are positioned between the wire receiving channels 313, 314, with the front end regions of the connecting contacts 5 provided with wire connection elements 511 protruding into the wire receiving channels 313, 314. In addition, sealing elements 52 are provided which seal the connecting contacts 5 to the connector housing 3. Two identical cover parts 4 are arranged on the top and bottom of the connector housing 3 and can be rotated relative to the connector housing 3 via a joint 41 designed as a film hinge. To create the cable connection, the wires 6 are inserted into the wire receiving channels 313, 314 provided for this purpose. Folding the two cover parts 4 in the direction of the connector housing 3 causes the wire connection elements 511 to penetrate through the insulation of the wires 6 and into the wire inner conductors, thus creating an electrical connection between the wires 6 of the cables to be connected. The position of the cover parts 4 relative to the connector housing 3 is secured by the locking projections 32 engaging behind the complementary openings 430 of the cover parts 4. The solution presented allows a quick and easy connection between two cables. Due to the design of the wire connection elements 511 as piercing contacts, this proposal is limited to the connection of cables with stranded conductors. This design is unsuitable for connecting cables with a solid wire as the inner conductor, which are used primarily for longer transmission distances. The cover parts 4, which are rotatably connected to the connector housing 3 by means of film hinges, place high demands on the choice of material and on the injection molding tool.

The EN 10 2010 019 050 A1 shows a device for connecting two wires 400 with a wire insulation 420 and a wire inner conductor 410, which consists of a U-shaped base housing 100, a connecting contact 200 and a wire receiving housing 300. The wire receiving housing 300 is arranged via the pins 310 on the complementary recesses 110 of the base housing 100. The one-piece connecting contact 200 is firmly connected to the base housing 100 and has wire connection elements 210 in the form of insulation displacement contacts or alternatively piercing contacts 580 on its end areas facing the wires to be connected. The wire receiving housing 300 contains two wire receiving covers with wire receiving guides 350 that can be rotated by means of film hinges. To connect the wires 400, these are inserted into the wire receiving guides 350 according to 2 introduced and then pressed together with the rotatably mounted wire receiving covers of the wire receiving housing 300 in the direction of the base housing 100. This causes the wire connection elements 210 to penetrate and penetrate the wire insulation 420 of the wires 400 and to cut into the inner conductors 410. The position of the rotatably mounted wire receiving covers of the wire receiving housing 300 in the base housing 100 is secured by the locking projections 120 engaging behind the complementary openings 320 of the base housing 100. The proposed device enables two wires to be easily connected for current transmission. The lack of a fixation of the wires 400 in the wire receiving housing 300 is disadvantageous, as this makes the wire connection process more difficult. Connecting a plurality of wires requires a corresponding amount of space for a plurality of such devices.

The EN 10 2010 022 970 A1 discloses, according to paragraph [0001], a cable connection device 10 for electrically connecting two electrical lines 16, 34 with two electrically insulating housing halves (12, 44), in each of which a frame-shaped connecting contact 14 is arranged, which has a total of four insertion and cutting slots 64 in the sense of an insulation displacement contact (IDC) on its front end areas. The joining of the two housing halves 12, 44 to form the housing 42 with the inserted lines 16, 34 leads to a total of eight contact points, which advantageously enable a safe and solid electrical connection between the lines 16, 34 without the need for a separate cutting tool [0013]. The limitation of the proposed cable connection device 10 to the connection of two lines 16, 34 has a disadvantage. The connection of two cables with a plurality of wires of a data transmission cable requires a plurality of such cable connection devices with a disadvantageous space requirement.

The object of the present invention is therefore to further develop a generic cable connection device in such a way that it enables a simple and secure electrical connection between the wires of the data transmission cables to be connected in a cost-effective design and an advantageous application of cable connection devices according to the invention on an extension cable.

This object is achieved according to the invention in a generic connector with the features of patent claim 1.

In a particularly preferred embodiment, the cable connection devices can be detachably connected to one another.

It has proven particularly advantageous if the housing and the wire fixing part of the cable connection devices are made as a single piece from an insulating plastic. In unshielded applications, this reduces the number of parts required for the cable connection device when connecting unshielded data transmission cables.

In an advantageous embodiment, a metallic conductive material is provided for the housing of each cable connection device and an insulating plastic for the wire fixing part. In shielded applications, the metallic housing shields the cable connection device against unwanted interference signals.

For a cost-optimized design of a cable connection device according to the invention, it is advisable to design the housings of the cable connection devices identically.

For effective protection of the cable connection device, it is advantageous if the housings of the cable connection devices, after immediate assembly, form a shield housing that is almost closed in the circumferential direction and extends over the entire length of the cable connection device.

The arrangement of a shield connection part on the housing of the cable connection device enables the electrical connection of the metallic housing with the cable shield of the data transmission cable to be connected.

In a preferred embodiment, the wire connection elements of the connecting contacts are designed as insulation displacement contacts (IDC). This enables secure contacting of wires with different diameters.

It proves to be advantageous if the wire connection elements at the end areas of the connecting contacts form an angle β to the axes of the wire guide channels. This improves the defined penetration of the edges of the wire connection elements through the wire insulation into the inner wire conductor.

In an advantageous embodiment, the wire connection elements at the end regions of the connecting contacts have an angle β of 45° to the axes of the wire guide channels.

It is particularly advantageous if the connecting contacts of the two cable connection devices are identical. This leads to further cost savings.

In order to specifically optimize the transmission quality of the cable connection device, it can be provided that the wire connection elements arranged at the end regions of the connection contacts are spaced apart from one another in the X direction.

In an alternative design, the wire connection elements can be designed as piercing contacts (IPC).

It is particularly advantageous if the cable connection devices have a mechanical coding for each other. In this way, a clearly defined connection is achieved between the two cable connection devices.

The arrangement of a strain relief element on the cable connection devices enables, by means of a fixing of the cable, an effective protection of the electrical connections between the wire connection elements and the inner wire conductors against external mechanical stresses, for example against tensile and/or bending stresses of the data transmission cables to be connected.

In an application according to the invention, the front end regions of a data transmission cable are assembled with the cable connection devices of a cable connection device in the sense of an extension cable, wherein both cable connection devices are designed such that they can each be connected to a further cable connection device according to the invention to form a cable connection device according to the invention at each of the two ends of the extension cable.

Alternatively, it is possible to assemble a first connecting cable with the first cable connection devices on both front cable ends and to assemble a second connecting cable with the second cable connection devices. The combination of the first and second connecting cables easily produces an extension cable.

In a further advantageous embodiment, it can be provided that the first and second cable connection devices are designed identically. This leads to further effective cost savings.

• 1: eine perspektivische Ansicht der Kabelverbindungsvorrichtung in einer ersten vorteilhaften Ausführung;
• 2: eine perspektivische Ansicht der Kabelverbindungsvorrichtung aus 1 nach der Art einer Explosionszeichnung;
• 3: eine weitere perspektivische Ansicht der Kabelverbindungsvorrichtung nach der Art einer Explosionszeichnung aus 1;
• 4: eine perspektivische Ansicht der ersten Kabelanschlussvorrichtung aus 1;
• 5: eine perspektivische Ansicht der ersten Kabelanschlussvorrichtung nach der Art einer Explosionszeichnung aus 4;
• 6: eine Draufsicht der ersten Kabelanschlussvorrichtung aus 4;
• 7: eine Schnittansicht der ersten Kabelanschlussvorrichtung aus 6;
• 8: eine weitere Schnittansicht der ersten Kabelanschlussvorrichtung aus 6;
• 9: eine perspektivische Ansicht des Aderfixierteils mit Verbindungskontakt der ersten Kabelanschlussvorrichtung aus 4;
• 10: eine perspektivische, teilweise aufgebrochene Ansicht des Aderfixierteils mit Verbindungskontakt der ersten Kabelanschlussvorrichtung aus 9;
• 11: eine perspektivische Ansicht des Verbindungskontakts aus 5;
• 12: eine Draufsicht des Verbindungskontakts aus 11;
• 13: eine perspektivische Ansicht des Aderfixierteils mit Verbindungskontakt der zweiten Kabelanschlussvorrichtung aus 3;
• 14: eine teilweise aufgebrochene Draufsicht des Aderfixierteils mit Verbindungskontakt der zweiten Kabelanschlussvorrichtung aus 13;
• 15: eine perspektivische Ansicht eines Verlängerungskabels mit montierten Kabelanschlussvorrichtungen aus 3;

The following description of advantageous embodiments of the invention serves to explain in more detail in conjunction with the drawing.
Show it:

• 1 : a perspective view of the cable connection device in a first advantageous embodiment;
• 2 : a perspective view of the cable connection device of 1 in the manner of an exploded view;
• 3 : another perspective view of the cable connection device in the manner of an exploded view from 1 ;
• 4 : a perspective view of the first cable connection device of 1 ;
• 5 : a perspective view of the first cable connection device in the manner of an exploded view of 4 ;
• 6 : a plan view of the first cable connection device from 4 ;
• 7 : a sectional view of the first cable connection device from 6 ;
• 8th : another sectional view of the first cable connection device from 6 ;
• 9 : a perspective view of the wire fixing part with connection contact of the first cable connection device from 4 ;
• 10 : a perspective, partially broken away view of the wire fixing part with connection contact of the first cable connection device from 9 ;
• 11 : a perspective view of the connection contact from 5 ;
• 12 : a top view of the connection contact from 11 ;
• 13 : a perspective view of the wire fixing part with connection contact of the second cable connection device from 3 ;
• 14 : a partially broken away top view of the wire fixing part with connection contact of the second cable connection device from 13 ;
• 15 : a perspective view of an extension cable with mounted cable connection devices from 3 ;

In the 1 to 14 a first advantageous embodiment of a cable connection device according to the invention is shown schematically and is designated overall by the reference numeral 10. According to the 1 to 3 the cable connection device 10 consists of a first cable connection device 19 and a second cable connection device 119, which have a housing 20, a connection contact 100, a shielding part 120 and a strain relief element 130, wherein a wire fixing part 40 is arranged in the first cable connection device 19 and a wire fixing part 70 is arranged in the second cable connection device 119.

According to the 2 the data transmission cable 11, 141 to be connected to the cable connection devices 19, 119 has two wires 12. Each wire 12 consists of an electrical conductor 14 which is covered by a wire insulation 13, whereby the wires 12 are twisted together and form a wire pair. The electrical conductor 14 is designed as a solid conductor, for example. Alternatively, stranded conductors made of, for example, seven or nineteen individual wires twisted together can be used. The wire pair formed from the wires 12 is surrounded by a shielding film 15 and the cable sheath 17. Between the cable sheath 17 and the shielding film 15 there is also a shielding braid 16 which in the exemplary embodiment has been folded back over the cable sheath 17.

The 3 discloses the cable connection devices 19, 119 with the data transmission cables 11, 141 fixed therein and to be connected in the state before the immediate assembly to establish the electrical connection between the data transmission cables 11, 141. For better understanding, the cable connection device 19 assumes a position rotated by 180° about the axis 18 relative to the cable connection device 119. The cable 11, 141 is fixed to the housing 20 by means of the strain relief element 130, wherein the shield element 120 establishes an electrical contact with the cable shield 16. The wires 12 of the data transmission cable 11, 141 are located in the wire receiving channels 47, 48 of the wire fixing part 40 and in the wire receiving channels 73, 74 of the wire fixing part 70. End regions of the wires 12 protruding beyond the front sides 41, 71 of the wire fixing parts 40, 70 have already been removed, for example with a suitable side cutter.

The detachable joining of the cable connection devices 19, 119 in direction Y according to 2 causes an electrical connection between the first and second wires 12 of the data transmission cables 11, 141 to be connected, wherein the housings 20 are arranged in accordance with the 1 form a shield housing 140 which is almost closed in the circumferential direction and extends over the entire length of the cable connection device 10.

The 4 to 8 show the first cable connection device 19 consisting of the housing 20, the wire fixing part 40, the connecting contact 100, the shielding part 120 and the strain relief element 130 with the data transmission cable 11 arranged therein. The strain relief element 130, which is rotatably mounted on the hinge pin 33 via its hinge opening 133, is located according to the 4 in its release position, in which the data transmission cable 11 is released. After the wires 12 have been inserted into the wire guide channels 47, 48 of the wire fixing part 40 and the cable shield 16 folded back over the cable sheath 17 has been pressed into the contact tabs 124 of the shield part 120, the strain relief element 130 can be rotated from its release position, which releases the data transmission cable 11, into its fixing position, which fixes the data transmission cable 11 to the housing 20, the position of the strain relief element 130 being secured by engaging behind a locking projection 137 behind the locking projection 37 of the housing 20. The majority of the locking projections 137 of the strain relief element 130 enables data transmission cables with different cable diameters to be fixed to the housing 20. This is particularly evident from the 8th clearly.

The housing 20 is according to 5 designed as a U-shaped cover and has a cover plate 21 from which the side walls 22, 23 rise. The contact ribs 24, 25 serve to secure the position of the wire fixing part 40, 70 in the housing 20. The side walls 22, 23 have two cutouts 26 in which locking projections 27 are arranged, which in cooperation with the complementary locking recesses 30 in the recesses 29 of the housing 20 of the second cable connection device 119 produce a detachable connection between the cable connection devices 19, 119. The recesses 28 create the free space for the realization of the detachable connection between the housings 20 of the cable connection devices 19, 119. The shoulders 31 and the recesses 26, 29 are dimensioned such that by detachably joining the cable connection devices 19, 119 in the direction Y according to 2 the housings 20 form a shield housing 140 which is almost closed in the circumferential direction by an interlocking of the side walls 22, 23.

A cable receptacle 32 for receiving the data transmission cable 11 and a receiving space 34 with a hinge pin 33 for rotatably supporting the strain relief element 130 are arranged on the front end region 36 of the housing 20. Such arrangements are known to the person skilled in the art, for example from EN 10 2019 131 596 B3 known.

A sleeve 38 extends from the cover surface 21 of the housing 20 and forms a firm connection to the shield part 120 after passing through the complementary through-opening 125 of the shield part 120, for example by means of rivets. The housing 20 can be designed as a zinc die-cast part, for example.

The shielding part 120 has a U-profile-like cross-section that is open at the top and has a base area 121 from which the side walls 122, 123 rise, which lead into four inwardly curved contact tongues 124 that serve to make a force-fitting contact with the cable shield 16. The base area 121 is penetrated centrally by a through-opening 125 that serves to attach the shielding part 120 to the housing 20 as already described. Tinned brass or spring bronze can be used as an example of a material.

The strain relief element 130 is designed as an arcuate clamp and extends longitudinally between the end faces 131, 132. The joint opening 133, which is provided with a lateral opening 134 and is arranged at its end region facing the housing 20, surrounds the joint pin 33 for rotatable mounting of the strain relief element 130 relative to the housing 20. The strain relief element 130 is mounted by a snap-in connection between the joint opening 133 with temporary widening of the lateral opening 134 via the joint pin 33. A clamping rib 136 is arranged on the inner surface 135 surrounding the cable sheath 17 in order to achieve a defined fixing of the data transmission cable 11 to the housing 20. The strain relief element 130 can be manufactured from a plastic, for example a PC, using an injection molding process.

The 9 and 10 The wire fixing part 40 shown extends as a cuboid-like solid body between the end faces 41, 42. It is limited in width by the surfaces 43, 44 and in the height is limited by the surfaces 45, 46 and has a total of four wire guide channels 47, 48, 49, 50 which extend between the end faces 41, 42. The wire guide channels 47, 48 serve to accommodate the wires 12 of the first data transmission cable 11, which is fixed to the first cable connection device 19. After the cable connection devices 19, 119 have been joined together, the wire guide channels 49, 50 at least partially enclose the wires 12 of the second data transmission cable 141, which is fixed to the second cable connection device 119.

Two connecting pins 52, 53 extend from the bottom surface of the recess 51 provided for receiving the connecting contact 100, which penetrate the complementary through-openings 107, 117 of the connecting contact 100 to secure the position of the connecting contact 100 in the wire fixing part 40. The position can be secured, for example, by deforming the pins 52, 53 with local heating of the areas to be deformed. The arrangement of the connecting contact 100 in the recess 51 is such that the wire connection elements 102, 112 assume a central position in relation to the wire guide channels 48, 50. This is shown in 12 clearly.

The recesses 56, 57, 58 are provided for receiving the complementary wire guide elements 79, 80, 81 of the wire fixing part 70 when the two cable connection devices 19, 119 are joined together. The recesses 54, 55 arranged in the wire receiving channels 47, 49 serve as a free space for immersing the wire connection elements 102, 112 of the connection contact 100 arranged in the wire fixing part 70. Three wire guide elements 59, 60, 61 extend vertically from the wire guide channel 48 and serve to guide the wire 12 in the wire fixing part 40. The six crimp ribs 62 arranged in the wire guide elements 59, 60, 61 and offset from one another in the longitudinal direction enable the fixing of wires 12 with different insulation diameters.

The wire guide channel 47 provided for guiding the first wire 12 of the first data transmission cable 11 is closed in the circumferential direction in the area 46. The adjacent half-open wire guide channel 48 with the wire guide elements 59, 60, 61 serves to accommodate the second wire 12 of the first data transmission cable 11. When the cable connection devices 19, 119 are joined together, the complementary geometry of the wire fixing part 70, which is defined by the surfaces 89, 90, engages in the shoulder defined by the surfaces 63, 64.

The 11 and 12 disclose the connection contact 100, which consists of a connection region 101, from the end regions 108, 118 of which the wire connection elements 102, 112 rise in the vertical direction, wherein the wire connection elements 102, 112 are designed as insulation displacement contacts. Each wire connection element 102, 112 has two contact posts 103, 104, 113, 114, which are spaced apart from one another by slots 105, 115, wherein the slots 105, 115 open at their free end regions facing the wires 12 to be connected into the insertion surfaces 106, 116 in the sense of catch funnels for the insertion of the wires 12 to be connected and at the end regions facing the connection region 101 into the through openings 107, 117.

The wire connection elements 102, 112 are arranged parallel to one another, but form an angle β with the wire guide channels 47, 48, 49, 50, 73, 74, 75, 76, which in this embodiment has a value of 45°. In addition, the wire connection elements 102, 112 have an offset X in the direction of the wire guide channels 47, 48, 49, 50, 73, 74, 75, 76, the size of which depends on the transmission requirements. In the example shown, the offset X has a value of 0.5 mm. The connection contact 100 can be made from a spring bronze, for example.

The 13 and 14 The wire fixing part 70 shown is, with the exception of the recesses 77, 78 and 91, constructed essentially mirror-symmetrically across the mirror plane SE to the wire fixing part 40, so that when the cable connection devices 19, 119 are joined together, the wire guide elements 79, 80, 81 engage in the complementary recesses 56, 57, 58 of the wire fixing part 40. The cuboid-shaped base body extends in the longitudinal direction in an equivalent manner to the wire fixing part 40 between the end faces 71, 72 and has a total of four wire guide channels 73, 74, 75, 76 extending between the end faces 71, 72. The recesses 77, 78 form a free space for receiving the wire connection elements 102, 112 of the connecting contact 100 of the cable connection device 19 arranged in the wire fixing part 40. The fixing of the connecting contact 100 in the wire fixing part 70 takes place in the same way as in the wire fixing part 40 by means of two deformable pins 92, 93 which rise from the bottom surface of the recess 91. The wire guide channel 73 provided for guiding the first wire 12 of the second data transmission cable 141 is closed in the circumferential direction in the area 89. The adjacent half-open wire guide channel 74 with the wire guide elements 79, 80, 81 serves to receive the second wire 12 of the second data transmission cable 141.

The wire fixing parts 40, 70 can be made from an insulating plastic, for example from a PC, by injection molding.

The wire fixing parts 40, 70 are fixed in the housing 20 using means known to those skilled in the art, for example by means of locking or snap-in connections. Alternatively, a material connection between the wire fixing part 40, 70 and the housing 20 is also possible, for example by means of an adhesive connection.

According to the 1 to 4 The electrical connection between the data transmission cables 11, 141 is established by means of a cable connection device 10 according to the invention in the following steps.

In the first step, the front end of the data transmission cable 11 is prepared for connection to the cable connection device 19. This includes removing the cable sheath 17 over a suitable length, folding back the exposed cable shield 16 over the remaining cable sheath 17 and exposing the wires 12 by removing an optional shielding foil 15.

In the second step, the first cable connection device 19 is assembled with the data transmission cable 11 prepared in the previous step, whereby the strain relief element 130 assumes its release position according to 4 To do this, the first wire 12 passes through the wire guide channel 47, which is completely closed in the area 46. The second wire 12 of the first data transmission cable is pressed into the adjacent wire guide channel 48, which is open at the top, whereby the crimping ribs 62 of the wire guide elements 59, 60, 61 ensure that the wire 12 is secured in position by at least partially digging into the wire insulation 13. The two wires 12 of the first data transmission cable 11 are spaced apart by a distance T. This is evident from the 7 clearly. In this state, the wires 12 protrude beyond the front surface 41 of the wire fixing part 40.

The data transmission cable 11 is positioned in such a way that when the cable sheath 17 is pressed into the shield part 120 with the cable shield 16 folded back, a secure, force-fit contact is made with the four contact tongues 124. The length of the cable shield 16 is dimensioned such that it does not protrude into the free space 34 for the strain relief element 130. In the next step, the data transmission cable 11 is secured to the housing 20 by rotating the strain relief element 130 from its release position to its securing position securing the data transmission cable 11, with the locking projection 137 of the strain relief element 130 engaging behind the complementary locking projection 37 of the housing 20. This is evident from the 8th visible.

Finally, the wires 12 protruding beyond the front surface 41 are shortened as shown in 4 .

The assembly of the second cable connection device 119 with the front end of the second data transmission cable 141 takes place in an equivalent manner to the first cable connection device 19. The first wire 12 of the second data transmission cable 141 passes through the wire guide channel 73, which is completely closed in the area 89. The second wire 12 of the second data transmission cable 141 is pressed into the adjacent wire guide channel 74, which is open at the top, with the crimp ribs 82 of the wire guide elements 79, 80, 81 securing the position of the wire 12. The two wires 12 of the second data transmission cable 141, like the wires 12 of the first data transmission cable 11, are spaced apart by a distance T in this state, with the wires 12 initially protruding beyond the front surface 71. After the data transmission cable 141 has been secured by the strain relief element 130, the protruding wires 12 are also shortened to the end face 71.

The direct joining of the two cable connection devices 19, 119 assembled with the data transmission cables 11, 141 in accordance with the 1 to 3 to the cable connection device 10 causes the wire connection elements 102, 112 of the connection contacts 100 to penetrate through the wire insulation 13 of the wires 12 and into the wire inner conductors 14. This causes the electrical connection of the first wire 12 of the first data transmission cable 11 to the first wire 12 of the second data transmission cable 141 and the electrical connection of the second wire 12 of the first data transmission cable 11 to the second wire 12 of the second data transmission cable 141.

In the 15 a second advantageous embodiment of a cable connection device according to the invention is shown schematically in the use of an extension cable and is assigned the reference number 200 in its entirety. The first front end region of the data transmission cable 11 is fitted with a first cable connection device 19 and the second front end region of the data transmission cable 11 is fitted with a second cable connection device 119. The combination of a plurality of such extension cables 200 enables an easy-to-implement application-specific Cable extension by the customer, for example on construction sites.

Claims (10)

Cable connection device for electrically connecting the two wires (12) of a first data transmission cable (11) to the two wires (12) of a second data transmission cable (141) with a first and a second cable connection device (19, 119), each of which has a housing (20) and a wire fixing part (40, 70), wherein each wire fixing part (40, 70) comprises a plurality of wire receiving channels (47, 48, 49, 50, 73, 74, 75, 76), and wherein each cable connection device (19, 119) comprises a connection contact (100) with two end regions 108, 118, wherein a wire connection element (102, 112) is arranged at each end region (108, 118) of the connection contact (100), wherein the connection contact (100) of the first cable connection device (19) has the first wires (12) of the first and second data transmission cables (11, 141), wherein the connecting contact (100) of the second cable connection device (119) connects the second wires (12) of the first and second data transmission cables (11, 141), and wherein the connections of the wires (12) of the two data transmission cables (11, 141) are brought about by a direct joining of the first with the second cable connection device (19, 119). Cable connection device according to Claim 1 , characterized in that the housing (20) and the wire fixing part (40, 70) are made in one piece from an insulating plastic. Cable connection device according to Claim 1 , characterized in that the housing (20) consists of a metallically conductive material and the wire fixing part (40, 70) consists of an insulating plastic. Cable connection device according to Claim 3 , characterized in that a shield connection part (120) for connection to the cable shield (16) of the data transmission cable (11, 141) is arranged on the housing (20). Cable connection device according to one of the preceding claims, characterized in that the wire connection elements (102, 112) are designed as insulation displacement contacts. Cable connection device according to one of the preceding claims, characterized in that the wire connection elements (102, 112) at the end regions of the connecting contacts (100) have an angle β to the axes of the wire receiving channels (47, 48, 49, 50, 73, 74, 75, 76). Cable connection device according to one of the preceding claims, characterized in that the connecting contacts (100) are identical. Cable connection device according to one of the preceding claims, characterized in that the two cable connection devices (19, 119) have a mechanical coding (26, 29) with respect to one another. Cable connection device according to one of the preceding claims, characterized in that a cable strain relief element (130) is provided on the cable connection device (19, 119). Extension cable (200) with a first cable connection device (19) at the first end region of the data transmission cable (11) and with a second cable connection device (119) at the second end region of the data transmission cable (11), wherein both cable connection devices (19, 119) are designed such that they can each be connected to a further cable connection device to form a cable connection device according to one of the preceding claims at each of the two ends of the extension cable (200).

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