EP1586137A1 - Connecteur enfichable pour cables - Google Patents

Connecteur enfichable pour cables

Info

Publication number
EP1586137A1
EP1586137A1 EP03785805A EP03785805A EP1586137A1 EP 1586137 A1 EP1586137 A1 EP 1586137A1 EP 03785805 A EP03785805 A EP 03785805A EP 03785805 A EP03785805 A EP 03785805A EP 1586137 A1 EP1586137 A1 EP 1586137A1
Authority
EP
European Patent Office
Prior art keywords
plug
socket
cable
insulation displacement
contact
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Withdrawn
Application number
EP03785805A
Other languages
German (de)
English (en)
Inventor
Othmar Gaidosch
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
Hirschmann Electronics GmbH and Co KG
Hirschmann Electronics GmbH
Original Assignee
Hirschmann Electronics GmbH and Co KG
Hirschmann Electronics GmbH
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Priority claimed from DE10323614A external-priority patent/DE10323614A1/de
Application filed by Hirschmann Electronics GmbH and Co KG, Hirschmann Electronics GmbH filed Critical Hirschmann Electronics GmbH and Co KG
Publication of EP1586137A1 publication Critical patent/EP1586137A1/fr
Withdrawn legal-status Critical Current

Links

Classifications

    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01RELECTRICALLY-CONDUCTIVE CONNECTIONS; STRUCTURAL ASSOCIATIONS OF A PLURALITY OF MUTUALLY-INSULATED ELECTRICAL CONNECTING ELEMENTS; COUPLING DEVICES; CURRENT COLLECTORS
    • H01R9/00Structural associations of a plurality of mutually-insulated electrical connecting elements, e.g. terminal strips or terminal blocks; Terminals or binding posts mounted upon a base or in a case; Bases therefor
    • H01R9/03Connectors arranged to contact a plurality of the conductors of a multiconductor cable, e.g. tapping connections
    • H01R9/031Connectors arranged to contact a plurality of the conductors of a multiconductor cable, e.g. tapping connections for multiphase cables, e.g. with contact members penetrating insulation of a plurality of conductors
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01RELECTRICALLY-CONDUCTIVE CONNECTIONS; STRUCTURAL ASSOCIATIONS OF A PLURALITY OF MUTUALLY-INSULATED ELECTRICAL CONNECTING ELEMENTS; COUPLING DEVICES; CURRENT COLLECTORS
    • H01R13/00Details of coupling devices of the kinds covered by groups H01R12/70 or H01R24/00 - H01R33/00
    • H01R13/648Protective earth or shield arrangements on coupling devices, e.g. anti-static shielding  
    • H01R13/658High frequency shielding arrangements, e.g. against EMI [Electro-Magnetic Interference] or EMP [Electro-Magnetic Pulse]
    • H01R13/6591Specific features or arrangements of connection of shield to conductive members
    • H01R13/65912Specific features or arrangements of connection of shield to conductive members for shielded multiconductor cable

Definitions

  • connector and cable connection technology An important trend in connector and cable connection technology is the permanent electrical connection between insulated electrical conductors and the corresponding contact elements of connectors, devices, device boxes, sensor-actuator modules, circuit board modules, etc. as rational as possible, i.e. to manufacture with a minimum of time and money. An important requirement here is to carry out this connection process manually as flawlessly as possible without the use of auxiliary tools.
  • the main contact technologies are insulation displacement technology, penetration technology, collet technology and spring contact technology.
  • Another very important trend, which is derived more from general technical development, is to miniaturize connectors and other cable connection devices - as a rule with at least the same performance characteristics. In this context, one of the most important solderless electrical connections is the insulation displacement connection.
  • Plugs or sockets of a plug connection for quick connection technology consist of several assemblies. These include at least one housing consisting of metal or a metallizable housing in order to achieve a shielding effect at the end of the cable.
  • a shielding of the cable can be connected to the housing, while the individual line cores of the multi-core cable in particular can be connected to a contact partner of the plug or the socket by means of insulation displacement contacting.
  • such a known socket or plug has various disadvantages. On the one hand, it is necessary to widen the shielding braid of the cable that forms the shielding, on the one hand to distribute the multiple cable cores arranged coaxially within the shielding braid into a holder, the cutting inside the holder Terminal contacting is made using insulation displacement terminals.
  • a cone element For contacting the shielding braid with the housing, a cone element is provided, over which the expanded shielding braid must be arranged over a large area and pressed together when being assembled with a counterpart of the cone element.
  • the assembly effort of such a plug or socket is not only high, but also prone to errors, since the shielding braid generally consists of very thin individual wires, which are often cut, especially by inexperienced users during assembly, when the outer sheath surrounding the shielding braid of the cable must be removed to expose the braid. There is therefore a risk that the shielding braid will be injured or, in the worst case, be completely eliminated, so that no or insufficient electrical connection to the housing of the plug or socket will be established via the cone element and thus no or insufficient shielding will be provided.
  • the invention is therefore based on the object of providing a shielded socket or a shielded plug of a plug connection for quick connection technology by means of insulation displacement contacting, in which the electrical connection between the shielding of the cable and at least one housing part of the plug or the socket is of simple design, can be produced safely is and can be assembled with little effort.
  • a separate contacting element which establishes the electrical connection between the housing and the shield when assembling the plurality of assemblies of the plug or the socket.
  • a separate contacting element thus becomes part of the plurality of assemblies and can either be placed over the shielding of the cable, which is designed as a shielding braid, after the shielding braid has been exposed.
  • the end of the cable prepared in this way is then assembled with the other modules in order to contact the plug or socket and to complete. This is in one operation without the shielding mesh having to be treated further (for example, there is no widening compared to the known prior art) in order to produce the continuous shielding.
  • the contacting element is inserted into one of the assemblies of the plug or the socket and then the cable with the exposed shielding braid is inserted, so that this automatically makes contact between the shielding braid of the cable and the housing of the plug or socket for the purpose of shielding.
  • the contacting element is designed as an iris spring, which, due to its shape, makes it possible for the electrical connection between the shielding braid and, coaxially inward in the direction of the shielding braid and, depending on the design, axially and / or coaxially outward in the direction of the housing to manufacture the housing.
  • An iris spring also has the advantage that it can be compressed within certain limits and thus on the one hand compensates for tolerances and on the other hand the contact forces are maintained over the service life of the plug or socket due to the spring action.
  • cables with shields in which at least one conductor core is used as a shield or ground connection.
  • Such cables which may also have a shielding braid in addition to a cable core as a shield have application in network technology with certain bus systems.
  • continuous shielding from the cable via the plug connection e.g. from a plug to a socket or from a plug or socket to a sensor, actuator, device or the like
  • the shielding of the cable is at least one of several line wires and the electrical connection between a housing part of the plug or the socket and a contact partner takes place via a contacting element.
  • the line wire used for the shielding is contacted with the contact partner and, in addition, a connection is established between this contact partner and the housing of the plug or socket for the purpose of shielding.
  • a plug or socket for quick connection technology in insulation displacement contact is particularly advantageous if the individual contact partners are arranged symmetrically, since this is particularly advantageous for the transmission of high data rates or high signal frequencies.
  • An example of such a symmetrical arrangement is a 5-pin connector, in which a middle contact partner is arranged and coaxially with the other contact partners around this middle contact partner (which can also be more than four or less than four contact partners) are arranged.
  • the contact partners have special shapes and arrangements, from which a great compactness of the plug structure (or the structure of the socket) results. Because only with this configuration and arrangement of the insulation displacement contacts of the contact partner and the arrangement of the insulation displacement terminals in the associated contact carrier and strand holder, the compact design and even more the arrangement of a middle contact partner is made possible.
  • Embodiments of the connector according to the invention to which the invention is not limited, however, and for example also for sockets, device sockets, sensor actuators.
  • FIG. 1a, 1b, 1c overall, sectional and detailed views of a first embodiment of a plug
  • FIG. 2 shows several views of the design of a contact partner
  • 3 shows a view of a contact carrier for receiving the contact partners
  • FIGS. 4a, 4b show different views of a stranded wire holder for receiving the ends of the line wires and the insulation displacement terminals in the area in which the insulation displacement contacting takes place
  • FIG. 5 and 6 views of contacting elements, FIG. 7 part of the housing of the plug, FIG. 8 a contacting element for establishing an electrical connection between the housing of the plug and at least one, preferably the middle contact partner.
  • Figures 9 to 1 1 overall, sectional and detail views of a further embodiment of a connector.
  • the exemplary embodiment relates to a 5-pin, industry-standard (IP 67 according to IEC 60529) E-series plug of a plug connection according to IEC 61076-2-101 with quick-connectable insulation displacement terminals and axial cable outlet in a particularly compact design.
  • the plug can be assembled by the user without the help of tools. There is no need to strip or pinch the wires before the insulation piercing terminals penetrate.
  • the connector can optionally be built in a shielded version with electrically plated-through metallic or metallized housing parts, whereby the cable shield can be connected to the housing particularly simply and quickly in the sense of quick assembly.
  • the plug of such a connector is interplay with the socket, among other things. suitable, Ethernet signals, i.e. Transfer data rates up to 100 Mbit / s.
  • a solution is shown at the central pole with regard to its contact with the metallic housing.
  • FIG. 1 a shows the assemblies required for the assembly of the plug - partly also shown in their individual parts - and individual parts in an exploded view:
  • Housing (grip sleeve) complete sleeve 9 and contacting element 8; alternatively, the sleeve 9 and the contacting element 8 can also be provided as individual parts; Strain relief element complete: sealing element 10 (for example a hose or O-ring) and strain relief element 11;
  • the actuating element 12 serves to press or release the strain relief element 11 and the sealing element 10 against the sheath of the cable, which is shown in this figure 1a as a perforated screw.
  • the cable shown in FIG. 1 b itself is multi-core and has a shield 15 (shielding braid) lying under a cable jacket 14, which surrounds a plurality of conductor cores 16 with a diameter “D”, the conductor cores 16 comprising the core insulation 16.1 and the metallic conductor 16.2 (for example a stranded wire or a solid wire), but the cable structure described is not mandatory.
  • the connector shown in Figure 1a includes:
  • An electrical contact element 1 (see also FIG. 2) which is designed in the connection direction of the plug as contact pin 1.1, but depending on the application can also be designed as a contact socket, hybrid contact, circuit board contact, solder contact or the like.
  • the contact element 1 is provided with features 1.2 which, if required, can also have a structure in the longitudinal direction with respect to protection against rotation (for example knurling).
  • Surface 1.3 serves as an assembly aid (stop) and to absorb the insulation displacement forces.
  • the contact element 1 is designed as an insulation displacement terminal with the insulation displacement flanks 1.4, the insulation displacement slot 1.5 in between with the width “s” and the insertion bevels 1.6, which on the one hand have a centering effect with respect to the wire core and on the other hand reduce the penetration force.
  • ring segments are only a special embodiment of the general case, according to which the cross sections of the insulation displacement flanks 1.4 have a curved shape, for example elliptical.
  • Polygonal cross-sections are also conceivable for this, with an L-shape (for a simple insulation displacement clamp) or a C or U shape (for a double insulation displacement clamp) being of particular interest in this case.
  • Insulation clamps with such curved or polygonal flank cross sections have the great advantage in terms of a compact design that they are the same Spring stiffness has significantly smaller dimensions in the spring direction than insulation displacement connectors with flat flanks.
  • the orientations of the boundary surfaces of the insulation displacement slot 1.5 corresponding to the dimension "h", the insertion bevel (1.6) and the insulation displacement flanks 1.4 with respect to the axes "aa” or “Bb” (cf. FIG. 2, section BB) over the longitudinal extent of these partial areas are at least partially constant and / or at least partially variable.
  • This orientation can, for example on dimension "s" parallel to axis "aa”, such as on dimension "u” parallel to axis "bb”, or have an orientation between these two borderline cases.
  • the dimension "h” along these boundary surfaces can also be designed to be at least partially constant and / or at least partially variable, thereby optimizing the penetration force characteristic.
  • FIG. 3 shows a contact carrier 2 consisting of an electrical insulation material with a support collar 2.1 corresponding to the connecting element 3, a coding or anti-rotation device 2.2 and receiving bores 2.3 in which the contacts 1 are fastened or pressed in in a defined position.
  • these receiving bores 2.3 are provided with contact surfaces 2.9.
  • the mounting hole 2.3 (the middle mounting hole here as an example), the contact of which must be electrically connected to the metallic housing of the plug, is optional.
  • an additional concentric receiving bore 2.4 which serves to receive or fasten the contacting element 13 for the shield.
  • the contact carrier 2 has a support surface 2.5, a receiving or fastening groove 2.6 and a through slot 2.10. Furthermore, the contact carrier 2 has a further support collar 2.7 corresponding to the connection element 6, a sealing groove or surface 2.8, a guide surface 2.1 1, a further coding or anti-rotation device 2.12 and a stop surface 2.13.
  • connection element in particular a closed metallized or metallic connection element with a knurled grip surface 3, which is shown in FIGS. 1a, 1b and 1c as a screw cap and serves to screw the plug to an associated socket (not shown here).
  • a contacting element 4 which is shown as a spring washer (see also FIG. 5), which makes the electrical contact between the connecting elements 3 and 6.
  • a sealing element 5 is present, which is shown in Figure 1 b as an O-ring.
  • a further connecting element, in particular a closed metallized or metallic connecting element, which forms a further part of the housing of the plug, with a knurled grip surface 6 is shown in FIGS. 1a, 1b and 1c as a union nut.
  • FIGS. 4a and 4b show in different views and sections a strand holder 7 made of an electrical insulation material with conductor chambers 7.1 in which the respective conductor cores are received and positioned in a defined manner for the purpose of contacting the associated insulation displacement terminals.
  • the conductor chambers 7.1 are funnel-shaped on the side of the conductor entry with circumferential lead-in chamfers or curves 7.7.
  • the basic shape of the conductor chamber 7.1 initially has a constant cross-section with the basic dimensions “m * n” (see FIG. 4a).
  • the conductor chamber tapers on one side via a deflection bevel 7.4 to a cross section which corresponds to the corresponds to the respective end of the line wire in such a way that it is positioned in the xy projection sufficiently precisely with respect to the insulation displacement terminal that the y coordinate of the wire core 16.2 is, with sufficient certainty, smaller than the y coordinate of the insulation displacement slot with respect to the electrical contact.
  • This positioning also causes the insulation displacement connector to penetrate the end of the wire, which is also a P in the longitudinal direction.
  • the chamber dimension "m” must be determined so that the xy projection of the metallic conductor also crosses the insulation displacement slot with sufficient certainty. Due to the fact that the diameter of the metallic conductor is necessarily smaller than the core diameter "D", one can be achieve reliable contacting even under the condition "m ⁇ 2D". At the end of the conductor chamber 7.1 there is also a stop 7.6 which ensures that a live line conductor cannot protrude from the conductor chamber 7.1. At the same time this stop 7.6 causes that the insulation displacement also takes place in the z-direction.
  • the cross section of the conductor chamber 7.1 has flat surfaces throughout the width dimension "n", it tapers at the ends defined by the dimension "m” either to an approximately curved one , in particular semicircular form 7.1.1, or to an approximately polyg on-shaped, in particular V-shaped shape 7.1.2 out. Of course, these ends can also have the same shape. This shape can also be maintained in the same way or in a similar manner via the deflection bevel 7.4 up to the stop 7.6.
  • These tapers are particularly important in the case of cable cores with a smaller diameter than the chamber width "n", and when deflecting such cable cores they center them in the central plane of the conductor chamber 7.1.
  • one or more, in particular two, deflection ribs are located within the conductor chamber 7.1 7.2 and one or more, in particular two, deflection ribs 7.3 offset about the z-axis.
  • These deflection ribs 7.2 and 7.3 are provided with relatively flat bevels 7.2.1 and 7.3.1 in the direction of the conductor insertion, which prevents the conductor wires from getting caught and the frictional forces when
  • the deflection ribs 7.2 and 7.3 along these bevels in their (xy) cross-section have further bevels 7.2.2 and 7.3.3 which, similar to the chamber taper 7.1.1 and 7.1.2, especially with regard to thinner conductor wires have a centering effect.
  • the slopes 7.2.2 and 7.3.3 each depending on the number and distribution of the deflection ribs 7.2 and 7.3 across the chamber width “n”, they can have a variable inclination along the z-axis, as is the case, for example, with the bevel 7.3.3.
  • the stop 7.6, the deflection slope 7.4 and the deflection ribs 7.3 and 7.2 are distributed over the z-axis in such a way that the insertion of the conductor wire into the conductor chamber 7.1 is possible with relatively little effort.
  • Another important part of the conductor chamber 7.1 is the guide surface 7.5, whose function it is To lead insulation piercing flanks 1.4 and above all to prevent their evasion in the spring direction when entering the conductor wire.
  • the extension of the guide surface 7.5 in the z direction is at least as long as the depth of penetration of the insulation displacement terminals and preferably ends on the lower surface of the deflection rib 7.2.
  • the deflection rib 7.3 is located approximately halfway up this penetration depth means that the conductor wire is touched by the insulation displacement connector at least once, possibly twice in the z direction, which leads to an increase in the reliability of the contact.
  • the heddle holder 7 Corresponding to the guide surface 7.5, the heddle holder 7 has openings 7.5.1 in the direction of the insulation displacement terminals, as a result of which the insulation displacement terminals can penetrate into the corresponding conductor chambers 7.1.
  • the outer contour of this opening 7.5.1 reproduces the outer contour of the insulation piercing either over its entire circumference or only over parts thereof (for example if the insulation displacement flanks 1.4 are to be guided or supported at specific points), the remaining sections, so to speak, "air"
  • the xy projection of the inner contour of the opening 7.5.1 taking into account the draft angles required in the tool, on the one hand, with the projection of the chamber limitation 7.4.1, which is based on the Deflection bevel 7.4 extends up to the deflection rib 7.2, on the other hand, this inner contour is at least correct with the lower side edge
  • the stranded wire holder 7 has further openings 7.8 on each conductor chamber 7.1, the number of which corresponds to the number of the deflection ribs 7.3, with the special feature that their contour is larger, taking into account the draft angles required in the tool, is preferably the same as the xy projection of the deflection ribs 7.3.
  • the openings 7.8 are not so large that the thinnest conductor wire to be connected can be pushed through them, as a result of which the stop 7.6 would lose its meaning.
  • the conductor chambers 7.1 or the entire strand holder 7 can be arranged in a very high functional density in a particularly simple manner along the longitudinal axis
  • Further features of the stranded wire holder 7 are the coding or anti-rotation lock 7.9, the guide surface 7.16 and the stop surface 7.15, which are important in connection with the contact carrier 2.
  • the groove 7.10 serves to receive or guide the contacting element 13.
  • the groove-like depressions 7.11 also represent a coding or an anti-rotation device for the sleeve 9.
  • the surfaces 7.12 are laughing handles on which the Strand holder 7 can be pulled out of the contact carrier 2.
  • the strand holder 2 is pressed, indirectly via the sleeve 9, with the aid of the connecting element 6 into the contact carrier 2 equipped with insulation displacement clamps.
  • the test hole 7.14 which has a conical shape over part of its length, is used by the user to determine whether the diameter of the conductor wires present are suitable for the conductor chambers 7.1 of the stranded wire holder 7.
  • the conical (or alternatively also planar) surface 7.17 has the function of fixing the contacting element 8 in the z direction in such a way that a radial force component is generated in the direction of the plug center axis, ie towards the cable shield.
  • FIG. 5 shows the contacting element 4 required for continuous shielding between the connecting element 3 and the terminating element 6.
  • the contacting element 4 is adapted to the contact contours of the connecting elements 3 and 6 and is preferably designed as a disk.
  • a contacting element 8 is shown in FIG. 6, which is shown in this figure as an iris spring (helical spring that can be detachably or non-releasably joined). Corresponding stamped or wire-bent parts would also be conceivable for this.
  • the sleeve 9 were produced in an injection or die-casting process, such spring elements, designed as tool insert parts, could also be integrated into this sleeve 9 (“one-piece solution”).
  • the contacting element 8 is necessary for the electrical contact between the shielding of the cable and the housing of the plug (here the sleeve 9) in order to implement a continuous shielding
  • the iris spring is particularly advantageous because it can be pushed over the shielding of the cable without tools and to compensate for tolerances leaves.
  • a sleeve 9 in particular a closed metallized or metallic sleeve with a sealing surface, is a further component of the housing of the plug
  • the sleeve 9 has at least one of the depressions 7.11 corresponding coding or anti-rotation device 9.3 with insertion bevels 9.3.1 and possibly with at least one contact surface 9.4 for the contacting element 8.
  • the sleeve 9 has pressure surfaces 9.6.
  • the conical (or alternatively also planar) surface 9.7 has the same function with respect to the contacting element 8 as the surface 7.17 on the strand holder 7.
  • a contacting element 13 is shown in FIG.
  • This contacting element 13 has at least one fastening element 13.2 provided with a fastening or contacting loop 13.1 (or vice versa), wherein the contacting loop 13.1 is resilient in particular on the central contact element 1 and for this purpose makes an electrical contact.
  • a fixing web 13.3, a spring plate 13.4 and a contacting surface 13.5 are provided, via which the electrical connection to the metallized or metallic housing of the plug is produced.
  • the spring plate 13.4 and the contacting surface 13.5 are designed such that the respective contact element 1 is not electrically connected to the housing of the plug, but rather directly to the cable shield 15 or to the contacting element 8.
  • the cable jacket 14 is cut off at the end, so that the line wires 16 and the cable shield 15 are exposed over a defined length; furthermore, the cable shield 15 is cut to a certain length.
  • the strain relief element 11 and the sealing element 10 are firmly connected to the sleeve 9 via the actuating element 12.
  • the assembly so assembled on the cable side is assembled with the "contact carrier complete” via the connecting element 6; during this process, the insulation displacement connectors are pressed into the respective line wires 16, which in turn are fixed in position in the conductor chambers 7.1, so that the electrical contact between a line wire and the associated contact pin 1.
  • the contacting elements 4 and 8 are used for electrical contacting from the shield 14 of the cable via the conductive areas of the housing of the plug to the actuating element 3, so that after contacting the plug with the associated socket or Alternatively, or in addition to this, the contact can be made from the shield 14 of the cable via the contact element 13 to a contact partner 1. In this way, for example given a continuous ground connection.
  • FIGS. 9a and b and 10 and 11 show overall, sectional and detailed views of a further exemplary embodiment of a plug.
  • the plug shown in these figures differs from that in FIG. 1 in that here the strand holder 7 consists of the parts strand holder 7a (see FIG. 10) and clamping part 7b (see
  • stranded wire holder 7a has only one fixed deflection rib in the conductor chamber, the function of the second rib being taken over here by the resilient lamellae of the tensioning part 7b projecting into these chambers.
  • These slats with regard to the cable core thus not only fulfill a deflecting function, but also a fastening function.

Abstract

La présente invention concerne une connecteur mâle ou femelle constitué de plusieurs parties individuelles ou plusieurs modules (1 à 5), appartenant à une connexion enfichable à raccordement rapide, les modules (1 à 5) comprenant au moins un boîtier en métal ou métallisable. Au moins un fil conducteur (6.3) d'un câble (6) notamment à plusieurs conducteurs, peut être connecté à un partenaire de contact (1.1) du connecteur mâle ou femelle au moyen d'une connexion autodénudante, le câble (6) présente une protection, et le connecteur mâle ou femelle est conçu pour être connecté à la protection lors de l'assemblage des modules (1 à 5). Selon l'invention, un élément de contact séparé sert à établir la connexion électrique entre le boîtier et la protection lors de l'assemblage des modules (1 à 5).
EP03785805A 2003-01-23 2003-12-12 Connecteur enfichable pour cables Withdrawn EP1586137A1 (fr)

Applications Claiming Priority (5)

Application Number Priority Date Filing Date Title
DE10302711 2003-01-23
DE10302711 2003-01-23
DE10323614 2003-05-26
DE10323614A DE10323614A1 (de) 2003-01-23 2003-05-26 Kabelsteckverbinder
PCT/EP2003/014157 WO2004066447A1 (fr) 2003-01-23 2003-12-12 Connecteur enfichable pour cables

Publications (1)

Publication Number Publication Date
EP1586137A1 true EP1586137A1 (fr) 2005-10-19

Family

ID=32773158

Family Applications (1)

Application Number Title Priority Date Filing Date
EP03785805A Withdrawn EP1586137A1 (fr) 2003-01-23 2003-12-12 Connecteur enfichable pour cables

Country Status (4)

Country Link
US (1) US7416448B2 (fr)
EP (1) EP1586137A1 (fr)
JP (1) JP2006513543A (fr)
WO (1) WO2004066447A1 (fr)

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CA207230S (en) * 2021-01-29 2022-09-16 Belden Deutschland Gmbh Connector [electricity]

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JPS6326941Y2 (fr) * 1981-07-10 1988-07-21
US5091606A (en) * 1988-04-25 1992-02-25 Peter J. Balsells Gasket for sealing electromagnetic waves filled with a conductive material
US4857015A (en) * 1988-07-01 1989-08-15 Molex Incorporated Evironmentally sealed grounding backshell with strain relief
JPH0449484U (fr) * 1990-08-31 1992-04-27
US5011440A (en) * 1990-09-10 1991-04-30 Lee Chun Te Wire connector
JPH0922746A (ja) * 1995-07-05 1997-01-21 Keyence Corp 電気機器の結線構造、端子構造および結線装置
US5586910A (en) * 1995-08-11 1996-12-24 Amphenol Corporation Clamp nut retaining feature
EP0886343A2 (fr) * 1997-06-19 1998-12-23 Itt Manufacturing Enterprises, Inc. Boítier de terminaison pour connecteur électrique
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Also Published As

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JP2006513543A (ja) 2006-04-20
US20060205251A1 (en) 2006-09-14
US7416448B2 (en) 2008-08-26
WO2004066447A1 (fr) 2004-08-05

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