DE3615597A1 - Voltage-resistant connecting element for medium-voltage cables - Google Patents

Abstract

Voltage-resistant plug connections are gaining ever greater significance. Particularly stringent requirements are placed on the dielectric strength in confined conditions in switching installations. While sleeves which can be shrunk by heat using heat shrinkage technology are used for covering connecting elements which must be destroyed when a connection is released, the object exists here of developing a voltage-resistant connecting element having reusable components. In this case, an insulating body 1 is used as a prefabricated push-on element which is subject to prestressing and is pushed onto a cable end 2. An open attachment 11 on the insulating body is used for connection to a bushing 5. A crimping cable lug 3, which terminates the cable end 2, is located inside the insulating body 1. By means of its connecting tab 31, the crimpling cable lug 3 produces the connection to the connecting element 4, which consists of a threaded pin 42 and a connecting nut 43. A contact retaining ring 6 which is embedded in the insulating body 1 is used for fixing the insulating body. The dielectric strength is achieved in that the insulating body 1, which is subject to prestressing, is pushed not only onto the cable end 2 but also onto the bushing 5. <IMAGE>

Description

The invention relates to a voltage-resistant connection element for Medium voltage cable according to the preamble of claim 1.

It is known to have voltage-proof plug connections with electrical to provide conductive outer walls, making them as contact apply safely. However, this has the disadvantage that the inner live connecting parts can be controlled electrically have to. Overall, such constructions are relative on maneuverable to manufacture. This was one of the reasons why tension-proof to produce closing elements in so-called heat shrink technology. The dielectric strength essentially shrinks insulating materials. Such components are in the Usually unsolvable and, if they are to be solved, must open get cut.

After further development of this heat shrinking technique, it is known to produce the insulating body for the connecting element from a removable elastomeric part (brochure "Fully Insulated Connection Systems 6-30 kV" from Raychem, NOM 001 3/84). The live connection element is covered with a heat-shrinkable hose, which must also be cut when the connection is released. In addition, a heat source (usually flame) must be used during assembly due to the heat-shrinking components.

The invention is therefore based on the object of a connection to develop element of the kind described above, its  Dielectric strength is achieved by components that are neither heat sources are still exposed during dismantling must be destroyed.

This object is achieved by the in the characteristics of Claim 1 specified combination of design features solved.

The advantages achieved by the invention are that prefabricated slide-on elements to achieve the required Have dielectric strength used, the appropriate Prestress and with special sealing surfaces in the joint are rich in the implementation and cover cap.

Training and further developments of the subject matter of claim 1 are the See subclaims.

The use of a test voltage adapter is particularly important here to emphasize (claim 4). The associated bolt can be take the cap into the connector nut or into the plug and / or threaded socket of the plug are screwed so that the test voltage can be easily applied. Here too Dielectric strength is guaranteed because on the one hand the the insulating body covering the bolt sealingly with the second Approach of the insulating body surrounding the connection element is connected and on the other hand the length of the adapter to the Test voltage is matched.

Embodiments of the invention are shown in drawings represents and are explained in more detail below. Show it

Fig. 1 shows a connection element for a medium cable cross-section in side view, in section

Fig. 2 shows a connection element for a larger cable cross-section in side view, in section

Fig. 3 is a test voltage adapter in side view, in section. According to FIG. 1, a cable end 2 is inserted into an insulating body 1 that is closed in a remote section with a field control body 21 . The field control body 21 contains a capacitively acting field control funnel 22 . On the bare conductor end 23 , a compression cable lug 3 is pushed and pressed with the conductor. The compression cable lug has a connecting lug 31 , the bore of which serves to receive a connecting element 4 . The connecting element 4 consists of a threaded pin 42 and a connecting nut 43 . The connecting nut has the task of fixing the connecting lug 31 . The counterpart to the connecting element 4 is a bushing 5 , which has a socket-like recess 51 for receiving the threaded pin 42 . The guide 5 is in the form of a cone. A first open attachment 11 encloses the entire cone of the feedthrough 5 when plugged in. At the transition of the first open extension 11 to the actual insulating body 1 , the latter is provided with an annular bulge 15 . This bulge serves to receive a contact holding ring 6 . This is pressed into the bulge 15 , for example after the manufacture of the insulating body 1 . The outer diameter and the outer rounding of the contact retaining ring are matched with the bulge 15 such that the contact retaining ring 6 abuts the bushing 5 in the inserted state of the insulating body 1 and fixes the insulating body 1 in this position. At the same time a contact between the current-carrying threaded pin 42 and the socket-like recess 51 from the bushing 5 is made. The contact retaining ring 15 has a height which is dimensioned such that the press cable shoe 31 is inserted at right angles to the feed-through axis 52 . A second open extension 12 is used to apply a test voltage to the connecting element 4 . In the normal case, the second open attachment 12 is closed with a cover cap 7 . The voltage resistance is achieved in this area in that the sealing surface between the open extension 12 and the cap 7 has annular beads 13 on the outside of the open extension 12 , for which purpose the cover 7 has corresponding corresponding de recesses on the inside.

According to FIG. 2, the contact holding ring 6 has a lower height than according to FIG. 1 because the cable end 2 has a larger cross section, which also includes a correspondingly dimensioned press cable shoe 31 . The connecting element 4 is in this case made in one piece and consists of a cylindrical pin 44 with a threaded shoulder 45 to the side of the bushing 5 . On the side facing away from the bushing 5 , the connection element is designed as a plug and / or threaded bushing 46 . The open set 12 has in the area of the cover cap 71 on the inside of annular beads 14 which engage in corresponding corresponding recesses in the cover cap 71 .

Finally, Fig. 3 shows the use of a Prüfspannungsadapters. 8 Its essential components are a bolt 81 which is screwed into the connecting nut 43 . The bolt is connected to a cable lug 82 . The test voltage adapter 8 is enclosed by an insulating body 9 which is formed in the region of the second open extension 12 so that it can be fixed in a sealing manner on the ring-shaped beads 13 .

Claims (6)

1.Volt-proof connection element for medium-voltage cables, with a hollow cylindrical insulating body with two open approaches and a corresponding bushing, with a cable end inserted into the insulating body, which is terminated with a cable lug with a connecting lug, with the connecting element which, on the one hand, engages in a bore in the connecting lug and on the other hand by a first open approach with a bush-like recess which is provided with an outer cone, form-fit ver is bindable and with a second open approach of the insulating body which is closed with a cover cap, characterized in that the insulating body ( 1 ) as a pre-assembled slide-on element is formed, which is initially pushed onto the field control body ( 21 ) with the cable end ( 2 ), and that an extension ( 11 ) on the side facing the bushing ( 5 ) has an annular bulge ( 15 ) in which surface r a the connection element ( 4 ) surrounding the contact holder ring ( 6 ) is embedded, the outer diameter and the rounding of the contact holder ring ( 6 ) are matched to the dimensions of the bulge of the insulating body ( 1 ) such that the contact holder ring ( 6 ) is inserted Condition bumps against the bushing ( 5 ), and that a further set ( 12 ) on the side facing away from the bushing ( 5 ) has inner or inner annular beads ( 13 or 14 ) which fit into corresponding recesses in the cover cap ( 7 or 71 ). 2. Connection element according to claim 1, characterized in that it consists of a threaded pin ( 42 ) in the bush-like recess ( 51 ) of the bushing ( 5 ), and that the contact retaining ring ( 6 ) is dimensioned in such a height that that the cable lug ( 3 ) at right angles to the bushing axis with a threaded pin on the Ge ( 42 ) inserted connecting nut ( 43 ) can be screwed. 3. Connection element according to claim 1, characterized in that it is designed as a one-piece part, which for connection to the socket-like recess ( 51 ) of the implementation ( 5 ) has a cylindrical pin ( 44 ) with a threaded shoulder ( 45 ) and on the is formed with a plug and / or threaded bushing ( 46 ) facing away from the bushing. 4. Connection element according to one of claims 1 or 2, characterized in that the bolt ( 81 ) of a test voltage adapter ( 8 ) with the cover cap removed ( 7 ) in the connecting nut ( 43 ) or in the plug and / or threaded socket ( 46 ) can be screwed in, and that the bolt ( 81 ) is covered by an insulating body ( 9 ) and is formed on the side facing the approach of the insulating body ( 1 ) in such a way that the insulating body ( 9 ) in the inner or outer annular beads ( 13 or 14 ) of the approach ( 12 ) is fixed. 5. Connection element according to one of claims 1 to 4, characterized in that the bolt ( 81 ) including its insulating body ( 9 ) is dimensioned in length according to the level of the test voltage to be applied, the bolt ( 81 ) with a cable lug ( 82nd ) is completed. 6. Connection element according to one of claims 1 to 5, characterized in that the insulating body ( 1 and 9 ), the field control body ( 21 ) and the cover cap ( 7 ) are made of a stretchable, insulating elastomer.