DE10323616A1 - Rapid connection plug or socket connector in clamping jaws technology has contact partner with region in form of clamping jaws for accommodating stripped end of line of especially multi-strand cable - Google Patents

Abstract

The rapid connection plug or socket connector enables at least one line of an especially multi-strand cable to be connected to a contact partner (1) of the plug or socket, whereby the contact partner has a region in the form of clamping jaws for accommodating the stripped end of the line. The clamping jaws are released by a movable clamp sleeve (7) to receive the cable end and compressed to fix the cable end.

Description

The invention relates to a connector or a socket of a plug connection for quick connection technology according to the characteristics the preamble of claim 1.

Quickly connectable connectors that have sockets and associated plugs are known. Rapid connection technology is understood to mean that a cable has one or more lines, the end of the individual lines being connected to associated contact partners which are arranged in the plug or the socket. The contact partners are, for example, contact pins of a plug or socket elements of a socket. Two technologies are known in the field of quick connection technology, on the one hand the insulation displacement technology and on the other hand the penetration technology. In both technologies, the ends of the lines of the cable are inserted into a wire-receiving part, fixed there in their position and penetrated by an insulation displacement contact at approximately a right angle in the insulation displacement technique, so that this insulation displacement contact reaches the core of the cable and thus establishes the contact from this to the contact partner. As a rule, the insulation displacement contact and the contact partner are formed in one piece. With penetration technology ( DE 44 18 259 C1 ) a spit is connected to the contact partner or is formed in one piece and penetrates axially into the end of the line when the end of the line is inserted into the wire-receiving part, so that the contact is established in this way.

The quick connection technology has proved its worth, so nowadays finished sets for Plugs or sockets of a plug connection are offered, the the end user only has to finish assemble with his cable. Both previously used cables were such cables that either have no shielding or, if shielding does exist is not connected to the plug or socket.

The invention is based based on a plug or socket of a plug connection for quick connection technology To be provided with regard to the connection process and the contact security is further improved.

This task is due to the characteristics of claim 1 solved.

According to the invention it is provided that the contact partner to hold the stripped end of the cable as a collet has trained area. When opened, the stripped Insert the end of the line into the collet and then the collet closed, so that stripped end of the line is arranged there contact safe. This means that the connector can be assembled without tools (assembly) possible, so for example Screw-clamp contacts can be omitted. Is the collet in the closed If the condition is spring-loaded, the Contacting due to this spring force, so that thereby the life of the connector or the sockets have reliable contact reliability. This contact security is also with interferences (like e.g. Temperature changes, vibrations and the like) are given. On Another advantage of the collet is that it is stripped Ends with different diameters can be used. that is, that only a plug or socket must be provided, too if cables are to be used, several within the cable Have lines with different diameters or different Cables are to be used whose lines are different Have diameter. By using the collets it is shortened Moreover the assembly time while automation is also possible. Become stranded wires used, can ferrules omitted. The symmetrical arrangement is particularly advantageous several collets and thus also the contact partner, which is advantageous in the transfer greater Amounts of data or signals from high frequencies.

The design is particularly advantageous a plug or socket with a conductive housing (such as a plastic housing with electrically more conductive Coating or a metal housing), the housing or is formed in several parts. Via the contacting element, which in the housing is arranged and in particular is designed as an iris spring, electrical contact is made between the shielding of the Cable (which is a shielding braid or a cable of the cable) and the housing of the plug or socket, so that after Conclude the plug connection has a continuous shield (e.g. over ground) is. This turns a plug or socket into a connector provided for transmission from particularly high data rates (up to the megabit range) per second) is suitable. So that is such a connector ethernet capable (e.g. from 1 megabit per second to a few gigabits per Second).

A constructive embodiment of a connector according to the invention, which is an industrial-grade (IP67 according to IEC60529) E-series connector according to IEC61076-2-101 that the invention is not limited is described below and explained with reference to the figures.

Show it

1a / 1b Overall and sectional views of a plug,

2 the structure of the contact partner with collet,

3 the structure of the contact carrier,

4 the structure of the adapter sleeve,

5 the structure of the receiving element,

6 the structure of the housing,

7 u. 8th Contacting elements.

In the 1a and 1b Overall views and sectional views of a plug of a plug connection are shown. The counterpart to this plug, ie the socket, can have a comparable structure and be arranged at the end of a cable; alternatively, the plug or the socket can be part of a sensor, actuator, a control unit or the like. The plug has a plurality of contact partners which are designed as plug pins at one end and, according to the invention, have the area designed as a collet at the other end. The contact partners 1 are arranged by insertion or pressing in a contact carrier, which consists of a non-conductive material. For example, the contact partners 1 be arranged symmetrically (e.g. lying on a circular path) and alternatively by injection molding the contact carrier 2 be surrounded. Furthermore, the plug has a connection element 3 with which he comes into contact with the corresponding connection element of the socket, which can be, for example, a screw connection (union nut). Following the connection element 3 , which can be or is electrically conductive, closes a contacting element 4 on. In the axial course behind it is a sealing element 5 available, which has the purpose of protecting the interior of the connector against environmental influences (in particular against moisture penetration). In the outer area of the housing of the plug, this has a further connection element 6 on, which is shown in this figure as a union nut and for fastening the sleeve 9 serves. The connector 3 and or 6 have a gripping surface with which the plug can be better handled when screwing together with the socket or when assembling with the sleeve 9 is guaranteed during assembly. There is an adapter sleeve inside the housing of the plug 7 arranged the area of the contact partner designed as a collet 1 receives and allows the collets to be opened to insert the stripped ends of the leads of the cable and to close the collets to establish contact between the contact partner and the stripped end of the lead. The adapter sleeve 7 is axially displaceable within the housing of the plug and can preferably be locked in two positions, namely in a first position in which the collets are open and in a second position in which the stripped cable ends have been inserted into the collets and now the contact force over the adapter sleeve 7 to be applied. The housing of the plug is formed in one or more parts and comprises a sleeve 9 , being inside the sleeve 9 above all the adapter sleeve 7 and the receiving element 8th are arranged for the stripped end of the line. Also inside the sleeve 9 is another contacting element 10 arranged, which is designed here as an iris spring. With this contacting element 10 the contact is established between a shield of the cable to be used and the electrically conductive housing 9 , so that continue through the connector 6 , the contacting element 4 and the connecting element 3 a corresponding contact to the socket can be established, so that continuous shielding (in particular ground connection) can be realized. This continuous shielding (ground connection) is absolutely necessary in certain applications, especially in applications with high data rates or frequencies, such as. B. Connectors that are used in Ethernet applications. Coaxial inside the sleeve 9 is a sealing element 11 arranged, which is a seal between the outer jacket of the cable to be used and the sleeve 9 realized. Furthermore, there is a deformable strain relief element 12 also coaxially within the rear end of the sleeve 9 arranged, which by inserting an actuator 13 at the end of the sleeve 9 is pressed together and thus a strain relief of the cable is produced. In 1a is the section AA and in above 1b the section BB shown through the connector.

Further detailed views of the individual elements of the connector are made with reference to the overall construction of the connector as described in 1a / 1b shown is described below.

2 shows the structure of the contact partner in different views and sections 1 with an area designed as a collet. The contact partner has a contact pin in the connection direction 1.1 which, depending on the application, can also be designed as a contact socket, hybrid contact, circuit board contact, solder contact or the like. For fastening in the contact carrier 2 is the contact partner 1 with expressions 1.2 provided, which can also have any structure in the Z direction (for example, knurling) with regard to anti-rotation protection. A surface serves as an assembly aid (stop) 1.3 , The contact partner is towards the ends of the lines 1 designed as a collet, the collet at least one spring plate 1.4 has at least one actuating bead 1.5 or the like where with the several spring slats 1.4 are arranged on a circular path and in the Z direction through slots 1.6 are separated from each other. The point P roughly defines the contact area to the stripped end of the line, while at point Q the actuation bead 1.5 the actuating force is introduced and point R indicates the clamping point of the spring plate. Furthermore, the contact partner points out 1 one of the spring slats 1.4 delimited management chamber 1.7 on, in particular a line chamber with the property D _P ≤ p _Q ≤ D _R , which with the chamfers 1.8 is provided. It is also important, especially in the event that the actuating force on the bead 1.5 Is initiated via electrically insulating materials with relatively pronounced creep and relaxation behavior that the coordinate Z _Q over the range Z _R <Z _Q <Z _P is chosen so that the spring plate 1.4 over the contacting cycle (service life) with sufficient certainty to spring back onto the stripped metallic end of the line in such a way that the required contact force at point P is approximately maintained. The spring slats shown here 1.4 The collet has the basic shape of ring segments in cross section, wherein cross sections with generally curved or polygonal contours or combinations thereof are also conceivable. Having a contact partner 1 as he is in 2 is produced, it can automatically be placed in the contact carrier in a further processing step 2 be used.

3 shows the structure of such a contact carrier 2 , which consists of an electrically non-conductive material, in particular plastic. The contact carrier 2 which can be produced, for example, in the plastic injection molding process, has one of the connecting element 3 corresponding support covenant 2.1 , a coding or an anti-rotation device 2.2 on and has mounting holes 2.3 in which the contact partner 1 defined or pressed in when the contact carrier 2 is produced as a single part. Furthermore, the contact carrier 2 another, the connecting element 6 corresponding support covenant 2.8 as well as a sealing groove or sealing surface 2.4 on. In addition, the contact carrier 2 according to the adapter sleeve 7 and the receiving element 8th guide columns 2.5 with contact surfaces 2.5 , 1 and locking elements 2.5 , 2 as well as other locking elements 2.6 and a stop surface 2.7 , These named elements of the contact carrier 2 serve to accommodate and hold the connection elements 3 and 6 and their position fixation in one end region of the sleeve 9 , The connector 3 , in particular a closed metallized or metallic connecting element, can, as in 1 shown on a plug, preferably as a union screw, or in the case of a socket, preferably as a union nut. The connection element is analogous 6 also a particularly closed metallized or metallic connection element for the sleeve 9 , like in 1 shown, is preferably designed as a union nut.

4 shows the structure of the adapter sleeve in different views 7 , the clamping chambers 7.1 the number and location of the number and location of the contact partners 1 equivalent. The clamping chambers 7.1 have a wedge-shaped or conical shape with constant or variable inclination over at least part of their longitudinal extent 7.1 , 1 , being about the clamping chambers 7.1 , depending on the position of the adapter sleeve 7 , the actuating forces for the collets of the contact elements 1 be generated. In addition, the adapter sleeve 7 one of the pillars 2.5 appropriate management area 7.2 with at least one locking element 7.2 , 1 , with the adapter sleeve 7 still stop surfaces 7.3 , a grip surface 7.4 and other stop surfaces 7.5 having.

5 shows different views of the structure of the receiving element 8th which has several center holes 8.1 through which the stripped ends of the lines are positioned precisely in the line chambers 1.7 be introduced. The center holes 8.1 have insertion funnels for easy cable routing 8.2 and mounting holes 8.3 for the isolated end areas of the cable. Furthermore, the receiving element has 8th mounting holes 8.6 with rest areas 8.6 , 1 for the locking elements 2.6 of the contact carrier 2 , A conical surface 8.4 has the function of the contacting element 10 to be fixed in the Z direction in such a way that a radial force component is generated in the direction of the plug center axis. With the groove-like depressions 8.5 it is a coding or anti-rotation against the sleeve 9 while the stop face 8.7 a path limitation for the adapter sleeve 7 represents.

6 shows in different views the structure of the housing of the plug, the sleeve being part of the housing 9 is shown. Overall, the housing of the plug does not only include the sleeve 9 , but in particular the connection elements 3 and 6 , the contacting element 4 and the sealing element 5 , The sleeve 9 , which is in particular a closed metallized (with a plastic core) or metallic sleeve, has a sealing surface 9.1 for the sealing element 5 on. There is also a connecting part 9.2 , for example a thread, for the connection element 6 available, as well as a sealing surface 9.5 for the sealing element 11 , There is also a connecting part 9.8 , for example a thread again, for the actuating element 13 available for strain relief. In addition, the sleeve has 9 at least one of the wells 8.5 of the receiving element 8th corresponding coding or anti-rotation device 9.3 , wherein this anti-rotation device is or can be with insertion bevels 9.3 , 1 , Furthermore, at least one is stop surface 9.6 present, the stop surface 9.6 is dimensioned so that when assembled together with the connecting element 6 ensures that the adapter sleeve 7 is in its lower rest position and thus the slats 1.4 the collet rests securely against the stripped end of the cable. The sleeve can also have at least one contact surface 9.4 for the contacting element 10 exhibited. The particularly conical surface 9.7 has regarding the contacting element 10 same function as the surface 8.4 on the receiving element 8th ,

In the 7 and 8th are the contacting elements 4 and 10 shown, the contacting element 4 according to 7 is designed as a corrugated flat disc and between the connecting element 3 and the connecting element 6 is arranged in the sprung state. This in 8th shown contacting element 10 is designed as an iris spring (helical spring joined to form a torus), with corresponding stamped or bent wire parts also being conceivable at this point. In the event that the sleeve 9 is produced in an injection molding or die casting process, it is conceivable to also design such spring elements designed as tool inserts, also in this sleeve 9 to be firmly integrated. That would make the sleeve 9 and the contacting element 4 and / or the contacting element 10 be formed in one piece.

• – Kontaktträger komplett: Kontaktpartner 1, Kontaktträger 2, Anschlußelement 3, Kontaktierungselement 4, Anschlußelement 6, Dichtungselement 5, Spannhülse 7, Aufnahmeelement 8,
• – Griffhülse komplett: Hülse 9, Kontaktierungselement 10; alternativ: Hülse 9 und Kontaktierungselement 10 als Einzelteile,
• – Zugentlastungselement komplett: Dichtungselement 11, Zugentlastungselement 12,
• – Betätigungselement 13.

A connector as described in the previous figures is usually assembled by the manufacturer into the following assemblies:

• - Contact carrier complete: contact partner 1 , Contact carrier 2 , Connecting element 3 , Contacting element 4 , Connecting element 6 , Sealing element 5 , Adapter sleeve 7 , Receiving element 8th .
• - Complete grip sleeve: sleeve 9 , Contacting element 10 ; alternatively: sleeve 9 and contacting element 10 as individual parts,
• - Complete strain relief element: sealing element 11 , Strain relief element 12 .
• - actuator 13 ,

To attach the above modules to the cable, proceed as follows:
The insulating jacket of the cable is cut off at the end, so that the cable cores (individual cables) and the cable shield (shielding the cable) are exposed over a defined length. Furthermore, the cable shield is cut to a certain predeterminable length and then the free ends of the cable cores are stripped over a defined length. Then the actuator 13 , the strain relief element 12 and the sealing element 11 as well as the sleeve 9 and the contacting element 10 pushed over the exposed wires and the cable shield onto the cable jacket. The adapter sleeve is attached to the "contact carrier complete" assembly 7 moved into their first locking position, causing the spring slats 1.4 the contact partner 1 change to the open state, the diameter D _{P must be} larger than the diameter of the thickest metallic conductor to be connected. The stripped wires are through the holes 8.1 to 8.3 of the receiving element 8th into the line chambers 1.7 the contact partner 1 introduced. The adapter sleeve is then attached to the "contact carrier complete" assembly 7 moved to the second locking position, causing the spring slats 1.4 the contact partner 1 are pressed onto the metallic conductors of the cores with the appropriate pretension, in order to generate the necessary contact forces. This means that the collets are closed. After that, the sleeve 9 with the contacting element 10 with the "complete contact carrier" on the connection element 6 merged up to the stop. Finally, the strain relief element 12 and the sealing element 11 via the actuator 13 with the sleeve 9 firmly connected, so that the strain relief of the cable is realized. Due to the described assembly and the electrical conductivity of the connection element 3 and 6 and the sleeve 9 and the use of the contacting elements 4 and 10 it is ensured that a continuous shielding is guaranteed when the connector is assembled. It should be mentioned that the housing of the plug (in particular the connection elements 3 . 6 and the sleeve 9 ) can also be formed in one piece or consisting of more than three parts. If a continuous electrical connection for shielding is not necessary, the contacting elements can above all 4 and 10 omitted, in which case the components of the plug involved can also consist of non-conductive material.

In the preceding description, the terms "plug" and "socket" were used in the following context:
A plug connection can consist on the one hand of a plug and a socket, which are connected by means of the quick connection technology at the end of a line and which are plugged together, screwed together or the like for electrical contacting of the cables. The part of such a plug connection which is brought together with a plug can also be referred to as a socket, socket, coupling instead of "socket". In addition, it is possible that the plug or socket is not attached to the end of a cable by means of quick connection technology , but is a fixed or detachable component of a sensor, an actuator, a device or the like. The term “plug” or “socket” thus includes all those parts that are required to make a cable plug-in. These parts are in particular around the contact elements that can be fixed in the contact carrier or are fixed, the strand holder and a housing of the plug or socket, in which the parts mentioned at the beginning are integrated, although other components (such as a union nut or a union screw for screwing a plug connection, a strain relief and others) may also be present ,

Claims (10)

Plug or socket of a plug connection for quick connection technology, in which at least one line of a multi-core cable in particular can be connected to a contact partner of the plug or socket, characterized in that the contact partner has an area designed as a collet for receiving the stripped end of the line. Plug or socket according to claim 1, characterized in that the area of the contact partner (collet) 1 ) from a sliding adapter sleeve ( 7 ) can be released for receiving the stripped ends of the line and can be compressed to fix the stripped ends of the line. Plug or socket according to claim 2, characterized in that the clamping sleeve ( 7 ) can be locked in at least two positions. Plug or socket according to one of the preceding claims, characterized in that at least the contact partners ( 1 ) and the adapter sleeve ( 7 ) are arranged in a one-part or multi-part housing of the plug or the socket. Plug or socket according to one of the preceding claims, wherein the cable has a shield, characterized in that at least one contacting element ( 10 ) is arranged in the electrically conductive housing of the plug or socket such that the contacting element ( 10 ) contact is made between the shielding of the cable and the conductive housing. Plug or socket according to claim 5, characterized in that the contacting element ( 10 ) is an iris feather. Plug or socket according to one of the preceding claims, characterized in that for guiding the stripped end of the line in the direction of the collet, at least one centering hole corresponding in position to the collet ( 8.1 ) receiving element ( 8th ) is provided. Plug or socket according to claim 7, characterized in that the center hole ( 8.1 ) an insertion funnel ( 8.2 ) and / or a location hole ( 8.3 ) connects. Plug or socket according to claim 7 or 8, characterized in that the receiving element ( 8th ) coaxially in the housing or part of the housing of the plug or socket, in particular in a sleeve ( 9 ), is arranged. Plug or socket according to claim 7, 8 or 9, characterized in that the receiving element ( 8th ) has an anti-twist device.