DE10026088C1 - Sleeve insulating body has sleeve enclosing screw connector at both ends ending in elastic spouts for accommodating cable ends, openings with bungs or hose seal, field control elements - Google Patents

Abstract

The device has a screw connector enclosed by a sleeve insulating body with a sleeve enclosing the connector at both ends and ending in elastic spouts for the cable ends. Insulating sleeve openings at clamp bolts accesses are closed by insulating bungs or an elastic hose seal. A field control element is provided in each spout between the cable's outer conducting coating at each cable end and an inner conducting coating of the insulating body. The device has a screw connector (5) using a metal sleeve-shaped clamping part (5.1) with screw shafts perpendicular to the connector and cable longitudinal axes and screw-in clamp bolts (5.2) and an arrangement for reducing the electrical field strength. The screw connector is enclosed by a sleeve insulating body (8) with an insulating sleeve (8.1) enclosing the connector at both ends and ending in elastic spouts (8.2) for accommodating the cable ends. Openings (6) at the accesses to the clamp bolts formed in the insulating sleeve are closed by insulating bungs or an elastic hose seal. A field control element is provided in each spout between the outer conducting coating of the cable (1) at each cable end and an inner conducting coating (12) of the sleeve insulating body.

Description

For establishing a cable connection of power cables for nominal voltages via 1 kV to 42 kV (medium voltage) are usually similar to the range Low voltage metallic sleeve-shaped connector used. The stripped The ends of the conductors to be connected are inserted into the connector on both sides. The mechanically firm and electrically conductive connection is made by pressing a special press tool (press connector) or by screwing Screws arranged laterally in the connector (screw connector). That for them Reliable connection required torque is either with a Torque wrench or by tearing off the screw head when it is reached of the required value.

The screw connectors with tear-off screws are gaining increasing acceptance among the Users, because in contrast to the press connector for assembly, they are not special require tool. In addition, a specific screw connector can be used for several Conductor cross sections are used. One can also look inside the cross section Connect a wide range of cables with different cross sections, which is the case with the Extending existing facilities is often required.

To rebuild electrical insulation and mechanical external protection the metallic connectors and the adjacent conductor sections must be covered area with suitable insulating materials. For that exist several solutions, which basically assume that initially in the usual Way prepared cable ends the electrically conductive connection and mechanical  Fixing the two conductor ends with one of the above-mentioned metallic Ver binder is manufactured.

Over the connector and over the trailing edge of the outer conductive layer of the cable Measures to reduce the electrical field strength required as a field control or field equalization.

For this purpose, an electrically conductive one is used in the area above the connector Layer (inner conductive layer) arranged with respect to the connector and him surrounding cavities acts as a Faraday cage. In some cases the Connector also encased with a mastic-like material that has a higher permittivity (Dielectric constant) as the insulating layer of the sleeve arranged above. In the area above the settling edge of the outer conductive layer, either a funnel-shaped electrode z. B. made of a conductive plastic (field control funnel, capacitive field control) or a layer of an insulating material with higher Permittivity (refractive field control) arranged.

An insulation layer and an outer layer follow in the further construction of the sleeve insulation Conductive layer to limit the electric field.

The following descriptions are limited to four essential, more or less proven principles of construction of sleeve insulation.

First, changing sleeve: The above. Elements of the sleeve insulating body are covered by the Wrapping insulating and semi-conductive tapes. The field control via the edge of the outer conductive layer is capacitive; there is a club-shaped Winding in this area.

The advantage of this technology is that there is no parking position for the availability of the Socket elements are required before the connection.

The disadvantage is the high expenditure of time for assembly, whereby air pockets are possible that can lead to partial electrical discharges. Another disadvantage is that none Final inspection of the sleeve insulator can be carried out.  

Second, heat shrink sleeve: This is the sleeve insulating body heat shrinkable polyolefin tubing built up before installing the Connector must be placed in a parking position on one end of the cable. To equalize the field above the connector, the above. Mastics used. The Field control over the edge of the outer conductive layer is refractive. The outer The conductive layer is usually arranged by coextrusion with the one below it Insulating layer connected.

The short assembly time is a particular technological advantage.

The disadvantage here is the required parking position above the cable jacket. Of a gas flame is also required for assembly, which is used for thermal damage who can lead materials. A final test of the sleeve insulator cannot be done either.

Third, push-on sleeve: With the push-on sleeve, the sleeve insulator is made out elastic insulating materials (e.g. silicone, ethylene-propylene-diene monomer (EPDM)) mainly manufactured by the manufacturer using injection molding technology. Before assembly of the connector, it is in a parking position over the outer conductive layer on one of the pushed both cable ends. The inside diameter of the mostly tubular one Sleeve insulation body is smaller than the diameter over the wire insulation of the Cable with the smallest conductor cross section in the application area. So that becomes a permanent contact pressure in the interface between core insulation and socket insulation reached. After installing the connector, the sleeve insulator is inserted into the End position pushed back. A sliding agent, e.g. B. Silicone oil used. The field control can be capacitive or refractive. The advantages of this technology are the simple installation without a gas flame; also one The manufacturer can test the cross insulation of the socket insulation body. The main disadvantage is the parking position above the outer one Conductive layer, the cable sheath being removed from the cable in this area got to. This requires more work and the length of the parking position  extended outer protective cover. The effort when moving is high and limits the size of the area of application.

Fourth, cold shrink sleeve according to DE 39 43 296 C2: The structure of the Sleeve insulating body is similar to that of the push-on sleeve. However, it is installed before with a special device radially expanded so far that it is in a parking position can be brought over the cable jacket. After assembling the connector the expanding device is removed, the sleeve insulating body relaxes and "shrinks cold" to the end position. The device can e.g. B. be a helix, which is brought in by the manufacturer. In this case, the sleeve insulator in highly stretched state (e.g. 230%) transported and stored, resulting in a Fatigue of the elastomer and permanent stretching can result. Other manufacturers (Cossonay, CH and ABB Kabeldon, S) use tubular, longitudinally divisible support sleeves that are inserted only before assembly, what with a shorter time for overextension. In a third variant, the elastic sleeve insulator with a PE-slide Push-on aid pushed onto the cable sheath so that there is no parking position either on the outer conductive layer is required as well as the duration and degree of overstretching are minimized during assembly.

Such a from an annular arrangement of spaced apart PE sliding webs existing slide-on aid is known from DE 195 10 598 A1.

Furthermore, from DE 195 13 618 A1 is a sleeve insulating body for connecting two Cables in the medium voltage range are known, which are a press or screw connector for the connecting conductor and means for controlling the electric field in the form of Field control hoses and tapes wound in a cone shape.

DE 197 27 567 A1 describes a branch terminal for a branch cable and house connection sleeve described, in which the consisting of clamping piece and clamping screws metallic screw connector is firmly enclosed by an insulating body. There is the Insulating body made of an insulating jacket that envelops the screw connector and that on both End faces of the connector has elastic seals for receiving the cable ends and has openings at the accesses to the clamping screws, which are made by plugs Insulating material can be closed.

DE 198 20 869 A1 describes means in the form of shrinkable conical hollow bodies for Adaptation of the cross-section of insulating bushings or grommets to the cable cross-section known, which also include field control bodies.

Starting from the illustrated prior art, it is an object of the invention To develop sleeve insulators that do not require a parking position, simply too assembly, requires little insulation material and can be produced efficiently. It there must be the possibility of increasing the sleeve insulating body Reliability in operation to be subjected to a 100% test with high voltage.

An inventive solution to this problem is specified in claim 1. Developments of the invention are characterized in the subclaims.  

According to the concept of the invention, a metallic screw connector and a associated waterproof sleeve insulating body encasing the screw connector already combined by the manufacturer into a compact assembly part in such a way that the screw connector is insulating in the end areas of the sleeve body is firmly integrated.

The manufacturer prefers this assembly part as a unit-tested unit "Screw connector - sleeve insulating body" produced and in this compact form the customers shipped.

The basic structure of the socket insulator with integrated screw connector exists in that a metallic screw connector, e.g. B. in the injection molding process, with a adherent insulating jacket is wrapped, which is on both ends of the connector continues in elastic grommets to accommodate the cable ends.

At the entrances to the clamping screws for the electrical and mechanical Connection of the cables with the connector are openings in the insulating jacket brought in after removing the tear-off heads of the clamping screws Plug made of insulating material can be closed. These openings have one pronounced cylindrical or curved edge on that of the plug cover is covered concentrically.

Stopper cover and cylindrical or curved edge of the opening have on it outer and possibly parallel contact surface an adapted profile for reliable fixation of the plug, for example by snapping it into place.

The field control over the cable end can be integrated in the grommet. The introductory openings for the plugs and the plugs themselves create an interface with one electrical insulation, which is necessary for reliable operation of the sleeve is necessary and sufficient. For this purpose, the stopper receives one on the outside of the stopper cylinder refractive field control layer. After inserting the cable ends through the Spouting and screwing the cable ends in the screw connector and after Closing the screw openings with the field-controlled plugs is that  Insulation ability of the sleeve manufactured. Then the Shielding and the construction of the external mechanical protection, which is not the subject of the invention.

The sleeve insulating body constructed in this way can also be designed as a branch sleeve. It has one or more additional cable entries and one for each cable entry or two more screw holes with plugs. Unlike everyone on the market medium-voltage branch sleeves located on this principle is also a T- shaped branch can be realized, which behaves more favorably, especially in the event of a short circuit than the so-called parallel branch.

The slide-on aids can be used to insert the cable ends into the elastic grommets according to patent DE 195 10 598 A1.

Further details, features and advantages of the invention result from the following description of an embodiment with reference to the associated drawing. Show it

Fig. 1 shows a sleeve insulating body with an integrated connector in a sectional view

Fig. 2 shows a preferred embodiment of the plug as a sectional view

Fig. 3 shows the enlarged view of the edges protruding into the opening for the tear-off screw of the inner and outer conductive layer of the sleeve insulating body.

Fig. 1 illustrates the basic structure of the sleeve insulating body 8 with a centrally arranged, enclosed by the insulating jacket 8.1 Screw. 5

Leading away from the end faces of the screw connector 5 , the sleeves 8.2 connect to the insulating jacket 8.1 for the watertight reception of the cable ends. The clamping process for connecting the conductor 4 of the two cable ends in the clamping piece 5.1 takes place by means of tear-off screws 5.2 through the openings 6 .

After completion of the assembly process, the openings 6 are made of insulating material by means of the plugs 10 , cf. Fig. 2, sealed watertight.

For field control above the cable end, a field control element 9 is integrated in the grommet 8.2 . This field control element establishes the connection between the outer conductive layer of the cable 1 via the wire insulation 3 and the inner conductive layer 12 of the connector 5 or sleeve insulating body 8 . It extends over the edge of the outer conductive layer 2 .

The arrangement of the means for field control on the plug 10 is shown in Fig. 1 in conjunction with Fig. 2.

A field control layer 11 is applied to the stopper cylinder 10.1 .

The continuous formation of the outer conductive layer of the sleeve insulating body 7 also includes the plug cover 10.2 .

To ensure that the plug 10 is securely connected to the opening 6 , the opening has a pronounced cylindrical edge 6.1 against which the plug cylinder 10.1 with the field control layer 11 bears.

To ensure a reliable mechanical connection of the plug 10 with the sleeve insulating body 8 , the plug cover 10.2 is angled around the cylindrical edge 6.1 and engages in the area of the overlap of the plug cover 10.2 and the cylindrical edge 6.1 with a snap connection to the edge 6.1 .

This latching or snap connection can be supported by a clamping ring which is arranged at the level of the knob ring in the angled part of the plug cover 10.2 .

The outer diameter of the plug 10 with the field control layer 11 is at least 5% larger than the inner diameter of the opening 6 , so that the interface experiences a permanent contact pressure, which is necessary for the reliable electrical insulation.

The other dimensions in the edge area of the openings and in the throw area of the plug are designed in such a way that none are in the installed, stretched state Cavities are created at the contacting interfaces.  

For the purpose of capacitive field control, the edges 13 of the inner 12 and the outer conductive layer 7 , 7.1 of the sleeve insulating body 8 projecting into the opening 6 may be rounded or funnel-shaped, see FIG. Fig. 3. Fig. 3 shows the mentioned edges 13 of the two guide layers 7 , 12 in an enlarged section.

LIST OF REFERENCES

1

Outer conductive layer of the cable

2

Trailing edge of the outer conductive layer

3rd

Core insulation

4

ladder

5

Screw connector

5.1

Clamp

5.2

Clamping screw

6

Opening for tear-off screw

6.1

cylindrical edge

7

Outer conductive layer of the sleeve insulator

7.1

the plug cap

8th

Sleeve insulator

8.1

Insulating jacket

8.2

Spouts

9

Field control

10th

Plug,

10.1

Stopper cylinder

10.2

Stopper cap

11

Field control layer

12th

inner conductive layer

13

Edges of the inner and outer conductive layers

Claims (11)

1.Sleeve insulation body with screw connector for producing a cable connection for medium-voltage plastic cables using a metallic sleeve-shaped clamping piece with screw shafts and screw-in clamps available perpendicular to the connector and longitudinal axis of the cable and from above the screw connector to the area above the offset edge of the outer conductive layer of the cable Arranged means for reducing the electric field strength, characterized in that a metallic screw connector ( 5 ) consisting of clamping piece ( 5.1 ) and clamping screws ( 5.2 ) is firmly enclosed by a sleeve insulating body ( 8 ), wherein

• a) the sleeve insulating body ( 8 ) consists of an insulating jacket ( 8.1 ) which surrounds the screw connector ( 5 ) and which continues on the two end faces of the connector in elastic sleeves ( 8.2 ) for receiving the cable ends,
• b) openings ( 6 ) are made in the insulating jacket ( 8.1 ) at the entrances to the clamping screws ( 5.2 ) and can be closed by plugs ( 10 ) made of insulating material,
• c) in each grommet ( 8.2 ) there is a field control element between the outer conductive layer of the cable ( 1 ) at each cable end and an inner conductive layer ( 12 ) of the sleeve insulating body ( 8 ),
• d) the walls of the plug cylinders ( 10.1 ) immersed in the openings ( 6 ) have a field control and preferably have at least one refractive field control layer ( 11 ) and
• e) the surface of the plug cover ( 10.2 ) has an outer conductive layer ( 7.1 ) which is galvanically connected to the outer conductive layer of the sleeve insulating body ( 7 ).

2. sleeve insulating body with screw connector according to claim 1, characterized in that the cross section of the spout ( 8.2 ) is variable and is selected so that different conductor shapes are sealed watertight. 3. sleeve insulating body with screw connector according to claim 2, characterized in that the diameter of the grommet ( 8.2 ) is selected so that it is stretched at least 5% after assembly of the cable core with the smallest conductor cross-section of the application area. 4. sleeve insulating body with screw connector according to one of claims 1 to 3, characterized in that the openings ( 6 ) have a pronounced cylindrical or curved edge ( 6.1 ) on which the plug cylinder ( 10.1 ) with the applied field control layer ( 11 ) lies flat and this cylindrical edge ( 6.1 ) is covered concentrically by the plug cover ( 10.2 ). 5. sleeve insulating body with screw connector according to claim 4, characterized in that the pairing plug cover ( 10.2 ) and cylindrical or curved edge ( 6.1 ) of the opening ( 6 ) in the insulating jacket ( 8.1 ) has an adapted profile on its outer contact surface, which has a reliable fixation of the plug ( 10 ) and covering the opening ( 6 ). 6. sleeve insulating body with screw connector according to claim 4 or 5, characterized in that the plug cover ( 10.2 ) is angled to cover the cylindrical or curved edge ( 6.1 ) of the opening ( 6 ) in the direction of the cable axis and perpendicular to the cable axis. 7. sleeve insulating body with screw connector according to one of claims 4 to 6, characterized in that the stopper ( 10 ) in its areas stopper cylinder ( 10.1 ) and stopper cover ( 10.2 ) is completely constructed from the refractive field control material of the layer ( 11 ). 8. sleeve insulating body with screw connector according to one of claims 4 to 7, characterized in that the outer diameter of the plug ( 10 ) with the field control layer ( 11 ) is at least 5% larger than the inner diameter of the opening ( 6 ). 9. sleeve insulating body with screw connector according to one of claims 1 to 8, characterized in that for the purpose of field control in the opening ( 6 ) projecting edges ( 13 ) of the inner ( 12 ) and the outer conductive layer ( 7 , 7.1 ) of the sleeve insulating body ( 8 ) are rounded or funnel-shaped. 10. sleeve insulating body with screw connector according to one of claims 1 to 9, characterized in that the field control element ( 9 ) is integrated over the cable end in the spout ( 8.2 ). 11. sleeve insulating body with screw connector according to one of claims 1 to 10, characterized in that it is designed as a branch sleeve, one or more further cable entries and for each cable entry one or two further screw openings ( 6 ) with plugs ( 10 ) are provided.