DE4109863A1 - Connector for termination of screened conductors - uses conducting plastic material to connect individual screens at end of housing - Google Patents

Abstract

The screened conductors (1) are all brought into a housing (5) with an extension (7) held on a cap (13). The extension is filled with a conducting plastic material (e.g. a plastic dough with embedded metal particles) which is in electrical connection with the individual conductor screens. USE/ADVANTAGE - As electronic equipment plug. Space saving.

Description

The invention relates to a connecting element for short of shielded electrical lines with Contacts and one with an Ab Shield connectable shield connection.

Such connecting elements are as device plugs known in the area of a plurality of electrical lines is guided. To connect Shields surrounding the respective cables ting, can use solder connectors or crimp connectors be det. Such connectors create the desired ones electrical contacts between the individual Ab shieldings. The solder connectors consist of one  known embodiment of a solder ring and two Sealing rings together in a shrink sleeve are embedded. When heating, for example with a hot air gun, the sleeve and the Melt the solder ring and the sealing rings. The ge melted solder then connects to the Ab shielding as well as with in the area of the housing arranged shield connection. As a result, the ge wanted electrical contact between the shield and the shield connection.

Crimp connectors are both in one piece and in two-part embodiments available. A one piece Crimp connector consists of an essentially c- shaped molding that in the area of an outer loading border is laminated with an insulating film. in the A hanging tab is attached to the inside of the connector assigns which the shielding as well as the shielding Line. To carry out an electrical Contact of the crimp connector with the shield the connector is inserted into a tool and after an insertion of the shielded Cable and the shield connection of the connector with a force that deforms it.

Two-part crimp connectors essentially exist from a stable inner sleeve, from a hard Material is formed, and one for the inner sleeve relatively softer and therefore deformable outer sleeve. The shields are used to make a connection of the individual lines in the intended contact area relaxed. This can be done by combing out, for example or by unthreading. Then be the shields to be contacted via the inside folded sleeve, and then the outer sleeve is opened with the shield between the  Inner sleeve and the outer sleeve is located. For the electrical contacting is then the entire Arrangement pressed using a tool.

Such designs have a use in Field of an aerospace industry disadvantages. It there is a comparatively large space requirement and the connecting means used will be the device with a not inconsiderable weight. To Implementation of the mechanical deformation processes special tools are also required. Close Lich is also the number of such devices connectable lines limited and a retrofit shielded cables and a Replacement of damaged shielded cables with a considerable amount of work.

The object of the present invention is therefore a Connecting element of the type mentioned in the introduction improve that when mounting the device required workload reduced and construct tive freedom when using the connecting elements elements are enlarged. This task is fiction solved according to that in one of the shield facing area of at least partially from Housing limited interior space from the Shield electrically connected to the shield connection The compliant, electrically conductive mass is arranged is not. The housing includes all possible types of housings, such as connector housings, device housings, end houses etc.

With the help of this electrically conductive mass all shields electrically with the shield connection connected. It is possible with little work shielded in prefabricated recesses of the mass  Insert cables or recesses that are not required close in the mass area. Furthermore is also a replacement of a shielded cable simply pull the cable out of the crowd and then inserting a new cable feasible. Compared to using squeeze connectors results in a significantly reduced Space requirement, which is a much higher packing density of the lines. A necessary bear The mass can be processed with simple tools gene, so that provision of complicated Special tools are not required.

To carry out a predefinable within wide limits Deformability of the mass used is suggested conditions that the electrically conductive mass at least is plastically deformable in some areas. A particularly inexpensive way to insert and for removing electrical wiring can also be there be provided by that the electrically conductive capable mass at least in some areas from one elastically deformable material is formed.

The use of electrical applications proven insulation materials allow the crowd for a reason substrate is formed in the electrically conductive Particles are embedded. A compared to usual Be loads particularly robust embodiment is realized in that the electrically conductive Silver particles are formed.

To form the mass from an elastic material it is appropriate that the mass of a metal par silicone rubber is formed.  

For use with a variety of electrical a directions, it is proposed that the housing as Part of a connector is formed. To Er closure of other use cases is provided that the housing is formed as part of a relay receptacle is.

To reduce the number of components to be used It is suggested that the mass as a you tion element is formed, the recesses for opening has electrical lines. Hereby will use separate sealing elements avoided and thus the assembly effort is reduced.

A constructive arrangement of a separate shield conclusion is avoided in that the housing min at least partially electrically conductive is. Such an embodiment is particular particularly useful for connectors used for ver Binding of socket elements with plug elements are seen.

This makes universal usability supports that in the range of mass with both Shielded electrical wires as well shielded lines are routed.

To facilitate the insertion of cables in the Range of mass is suggested to be in the direction a longitudinal axis of the recesses, the elasticity of the Mass increasing recesses are arranged that partially enlarge the recesses.

In the drawing are embodiments according to the invention games shown schematically. Show it:  

Fig. 1 is a partially sectioned side view of a device in which the conductive Mas se are arranged in a kneadable material with me-metallic particles,

Fig. 2 is a partially sectioned side view of a connecting element in which the mass is formed from a silicone rubber, are embedded in the metallic particles,

Fig. 3 is a partially sectioned side view of a connecting element which is provided with a relief part train,

Fig. 4 is a partially sectioned side view of a connecting element, a is connected to the shielding from connectable to shielding arranged in the region of a housing interior,

5 is a partially sectioned side view of a connecting element, both shielded in the region of which are guided and unshielded cables FIG.

Fig. 6 is a sectional side view of a dung Verbin element, which is designed as a distributor and arranged in the region of a rail,

Fig. 7 is a sectional side view of a dung Verbin element with at least a portion, electrically conductive housing,

Fig. 8 shows a device according to Fig. 7 with additional Lichem strain relief,

Fig. 9 is a sectional side view of a dung Verbin element, wherein the ground is formed of a kneadable material,

Fig. 10 is a sectional side view of a dung Verbin element having a recordable by a rail mount and is seen with a connectable to the relay lines ver,

Fig. 11 is a partially sectioned side view of a connecting element according to FIG. 10 with an additional strain relief,

Is a partially sectioned side view of a connecting element in which the mass is formed from a kneadable material Fig. 12,

13 is a partially sectioned side view of a connecting element, in the region of a supported from a base tertes relay is activated is arranged FIG.

Fig. 14 is a partially sectioned side view of a connecting element which is provided with a base, a relay and an at least partially electrically conductive housing, and

Fig. 15 is a partially sectioned side view of a connecting element according to FIG. 14 with a strain relief.

Has a connecting member for the connection of shielded electrical cables (1) with a Lei device (1) connectable contact (2) and a connectable with a shield (3) of the conduit (1) shield connection (4). The contact ( 2 ) and the shielding circuit ( 4 ) are partially received by a housing ( 5 ).

In the embodiment according to FIG. 1, an essentially cup-shaped receiving element ( 7 ) is arranged in a housing interior ( 6 ) delimited by the housing ( 5 ). The receiving element ( 7 ) has a base ( 8 ) which divides the housing interior ( 6 ). The receiving element ( 7 ) limits a housing interior ( 6 ) expanding receiving space ( 9 ), in which an electrically conductive mass ( 10 ) is arranged. The mass ( 10 ) is electrically connected to the shields ( 3 ) of the lines ( 1 ) in a stripped area ( 11 ). Via with the shield connections ( 4 ) connected discharge elements ( 12 ) an electrically conductive connection to a ground connection, not shown, can be produced. The shields ( 3 ) are designed as a screen braid radially surrounding the lines ( 1 ). The mass ( 10 ) consists of a plastically deformable plasticine, in which electrically conductive particles made of a metal are embedded. In particular, the use of silver is envisaged. A particularly good conformability to the shields ( 3 ) can be achieved by using a mass ( 10 ) made of a doughy material. The shield connection ( 4 ) is connected to a shield ( 3 ) one of the electrical lines ( 1 ) via a contact element ( 35 ).

The receiving element ( 7 ) is connected to the housing ( 5 ) with a union nut ( 13 ). About a threaded housing part ( 14 ) is a mechanical connection with a plug ( 15 ).

In the embodiment according to FIG. 2, a silicone rubber is used for the mass ( 10 ), in which metallic particles are embedded to ensure adequate electrical conductivity. Particles of silver or copper are particularly suitable for this. In the area of the mass ( 10 ) recesses ( 16 ) are easily seen through which the lines ( 1 ) are inserted without a significant mechanical resistance by means of a contact tool. The housing ( 5 ) is formed in this embodiment including the union nut ( 17 ) electrically conductive. The Ge housing ( 5 ) and the shield connection ( 4 ) can therefore be constructed as a single component. The housing ( 5 ) with the electrically conductive union nut ( 17 ) is connected to an electrically conductive connector housing ( 18 ). If the mass ( 10 ) is made of an elastic material that does not have any essential plastic properties, a separate receiving element ( 7 ) is unnecessary. The mass ( 10 ) can rather be formed as a molded part and inserted into the housing interior ( 6 ) in such a way that it is held by the housing ( 5 ). The electrical connection to the ground connection is made via the connector housing ( 18 ).

In the embodiment according to FIG. 3, in addition to the components according to FIG. 2, a strain relief part ( 19 ) is provided, which in the region of an end of the housing ( 5 ) facing away from the union nut ( 17 ) is connected to the latter and a tensile load impairing the functionality avoids the electrical lines ( 1 ).

In the embodiment according to FIG. 4, a recess ( 16 ) is shown in the area of the mass ( 10 ), into which no electrical line ( 1 ) with its shield ( 3 ) is inserted. Due to the elastic or plastic properties of the mass ( 10 ), the recess ( 16 ) is closed, whereby the complete shielding is achieved and the penetration of contaminants into the housing interior ( 6 ) is avoided. The shielding circuit ( 4 ) is connected to the contact element ( 35 ) by a pin or socket contact in the area of the plug ( 15 ) with the shield 3 . The associated pin or socket contact in the mating connector is in contact with the ground connection.

In the embodiment according to FIG. 5, lines ( 1 ) provided with a shield ( 3 ) and lines formed without shielding are guided through the mass ( 10 ). Via the shield connection ( 4 ) it follows through the diverting element ( 12 ) a connection to a ground connection, not shown. To increase the elastic properties, recesses ( 20 ) are arranged in the area of the mass ( 10 ), which are arranged one behind the other in the longitudinal direction of the recesses ( 16 ) and partially widen the recesses ( 16 ).

The embodiment according to FIG. 6 shows an embodiment in which the contact ( 2 ) is designed as a the electrical lines ( 1 ) to a common potential connector ( 21 ) of a module. A housing base ( 22 ) connected to the housing ( 5 ) has a design adapted to a rail ( 23 ). The rail ( 23 ) encloses the housing base ( 22 ) in some areas and is provided to hold the device before. A marking can be arranged in the area of a projection ( 24 ). Lines ( 1 ) provided with a shield ( 3 ) and lines ( 1 ) designed without shielding are provided.

Such a mixed arrangement of lines ( 1 ) is also shown in FIG. 7. The housing ( 5 ) is designed to be electrically conductive. The area-wise electrically conductive design of the module can be realized, for example, by providing a housing of the module consisting of a non-conductor with an electrically conductive surface coating. In addition, the housing ( 5 ) is provided with a closure ( 5 a).

In the embodiment according to FIG. 8, a strain relief part ( 19 ) for relieving the lines ( 1 ) is provided in addition to the components according to FIG. 7.

The embodiment according to FIG. 9 again shows a mass ( 10 ) formed from a plastic material, which can be deformed by magnetic application. The housing interior ( 6 ) is connected to the receiving space ( 9 ) via passages ( 25 ) which are arranged in the region of the base ( 8 ). To connect the diverting element, ( 12 ) with the shields ( 3 ) a shield connection ( 4 ) arranged inside the housing ( 5 ) is provided. The housing ( 5 ) projects with its housing base ( 22 ) into the rail ( 23 ).

In the embodiment according to FIG. 10, the housing base ( 22 ) is arranged in a lateral region of a cup-shaped adapter ( 26 ) which is provided for receiving a relay ( 27 ) and z. B. via a Ge thread has a fixed mechanical connection to the housing ( 5 ). In addition to the components according to FIG. 10, the embodiment according to FIG. 11 has an additional strain relief part ( 19 ).

Fig. 12 also shows a device which is provided with an adapter ( 26 ) for receiving a relay ( 27 ). There are both with a shield ( 3 ) ver seen lines ( 1 ) as well as shield-free lines ( 1 ) in the area of the mass ( 10 ). The mass ( 10 ) is formed here from a kneadable material. Discharge elements ( 12 ) are electrically connected to the shields ( 3 ) via shield connections ( 4 ).

In the embodiment according to FIG. 13, a base ( 28 ) is provided for receiving the relay ( 27 ). The housing ( 5 ) extends with a pressure web ( 29 ) in the loading area of one side ( 30 ) parallel to a holder ( 31 ) and is connected via screws ( 32 ) to a flange ( 33 ) holding the relay ( 27 ) can be positioned in the region of a further side of the holder ( 31 ) which is arranged facing away from the side ( 30 ). In the area of the mass ( 10 ) are in turn both with a shield ( 3 ) provided lines ( 1 ) and from shielding lines ( 1 ).

The embodiment according to FIG. 14 shows essentially the same components as FIG. 13. The housing ( 5 ), the receiving element ( 7 ) and the union nut ( 13 ) are electrically conductive. In FIG. 15 the embodiment according to FIG. 14 is expanded by a strain relief part ( 19 ).

Claims (12)

1. Connecting element for connecting shielded electrical lines which are connected to contacts and have a shield connection which can be connected to a shield, characterized in that in one of the shields ( 3 ) facing an area of at least some areas delimited by the housing ( 5 ), the housing interior ( 6 ) From the shield ( 3 ) with the shield connection ( 4 ) electrically connecting compliant electrically conductive mass ( 10 ) is arranged. 2. Connecting element according to claim 1, characterized in that the electrically conductive mass ( 10 ) is formed at least in regions plastically deformable. 3. Connecting element according to claim 1, characterized in that the electrically conductive mass ( 10 ) is formed at least in regions from an elastically deformable material. 4. Connecting element according to one of claims 1 to 3, characterized in that the electrically conductive mass ( 10 ) is formed out of a base substrate, are embedded in the electrically conductive particles. 5. Connecting element according to claim 4, characterized records that the electrically conductive particles are made of silver. 6. Connecting element according to one of claims 1 to 5, characterized in that the conductive mass ( 10 ) consists of a metal-containing silicone rubber. 7. Connecting element according to one of claims 1 to 6, characterized in that the housing ( 5 ) is designed as part of a connector. 8. Connecting element according to one of claims 1 to 6, characterized in that the housing ( 5 ) is designed as part of a relay receptacle. 9. Connecting element according to one of claims 1 to 8, characterized in that the conductive mass ( 10 ) is designed as a sealing element which has recesses ( 16 ) for receiving the electrical lines ( 1 ). 10. Connecting element according to one of claims 1 to 9, characterized in that the housing ( 5 ) min is at least partially electrically conductive out. 11. Connecting element according to one of claims 1 to 10, characterized in that in the region of the mass ( 10 ) both with a shield ( 3 ) ver seen electrical lines ( 1 ) and from shield-free lines ( 1 ) are guided. 12. Connecting element according to one of claims 1 to 11, characterized in that in the direction of a longitudinal axis, the recesses ( 16 ) the elasticity of the mass ( 10 ) increasing recesses ( 20 ) are angeord net, which partially enlarge the recesses ( 16 ) ver .