RU70415U1 - CONNECTING CLUTCH FOR POWER CABLE - Google Patents

Abstract

The utility model can be used to connect the ends of both multi-core and single-core power cables. The technical result achieved by the proposed utility model consists in reducing the overall dimensions of the coupling in a cross section perpendicular to the axis of the cable and increasing the reliability of its operation. The coupling includes a connector for the ends of the current-carrying core, a first layer of insulation coating covering the connector, a second layer of insulation coating covering the first layer of insulation coating, and a metal shield located on the outside of the second layer of insulation coating. The sleeve further comprises an electrically isolated transforming layer for converting an unevenly stressed electric field propagating from the connector into a uniformly stressed electric field propagating from the outer surface of the transforming layer. The transforming layer is located between the first and second layers of the insulation coating and is made of a material with a volume resistivity ρ _v from 10 ⁸ to 10 ¹² Ohm · cm at a relative dielectric constant . The transforming layer prevents the possibility of electrical breakdown between live conductors, as well as between live conductors and a metal screen.

Description

The utility model relates to electrical engineering, namely to cable accessories, and can be used to connect the ends of a multi-core or single-core power cable.

A known coupling for a power cable with insulation made of cross-linked polyethylene (RF patent No. 2190913, H02G 15/08, H02G 15/18, H02G 1/14, publ. 10.10.2002). The coupling contains a connector for live conductors and an insulator with a hole mounted on the cable. In addition, the connection sleeve is equipped with two grounding contact rings mounted on the grounding contact springs, a cable shield wire connector made in the form of two copper pressed sleeves, a transverse sealing tube formed of aluminum foil and placed on the insulator and adjacent cable sections, and a heat shrink tube mounted on the cable from the side of the cable shield wire connector. The insulator contains an electric field leveling unit made in the form of two cones and a central high-voltage electrode. The cones and the central high-voltage electrode of the electric field leveling unit are made of electrically conductive silicone rubber and / or coated with an electrically conductive composition. The insulator is made of silicone rubber. The coupling is equipped with a casing made of solid polyvinyl chloride for pouring a sealing compound into it. At least one layer of electrically conductive and one layer of electrical insulation tape and at least one additional heat-shrinkable tube are placed on the transverse sealing tube.

A known coupler smoothes out surges of electric field in the area of cable connection. However, this coupling is structurally complex due to the presence of a large number of parts, technologically difficult to manufacture and has a large material consumption. It has large overall dimensions both in the longitudinal, along the axis of the cable, and in the transverse directions. The coupling is difficult to use in tight spaces and limited installation times, which narrows the scope of its application.

Closest to the proposed connection sleeve is a known cable connection sleeve for a multicore cable, comprising a two-piece metal casing with a transverse connector line and sprue holes, covering the end sections of the cables and connections at opposite ends with their metal sheaths. Both parts of the housing are hermetically connected to each other and to the cable sheaths using solder. In addition, the coupling contains metal sleeves according to the number of current-carrying conductors, pairwise connecting the ends of the exposed conductors to each other. Each metal sleeve is enclosed in an insulating tube, for example a porcelain one, installed with the formation of a constant gap relative to the current-carrying core using centering tools made in the form of protrusions uniformly located on the inner surface of the insulating tube around its circumference. For increase

the reliability of the cable joint, it additionally contains a layer of thermal insulation, for example of varnish or PVC tape, located on each metal sleeve. In this case, the protrusions of each insulating tube are configured to interact directly with the thermal insulation layer in such a way that channels for passage of the casting compound remain between the protrusions in the circumferential direction. Each metal sleeve performs the function of a connector of the ends of the current-carrying core. A thermal insulation layer laid directly on a metal sleeve is the first insulation coating. The insulating tube covering the thermal insulation layer is the second insulating coating. Insulating tubes of all current-carrying conductors are pulled together by a bandage made of glass tape. The body cavity is filled with an insulating casting composition, which is in a liquid state at a temperature of 100 ° C and hardens after pouring.

The known cable connector is structurally simpler than the above-described connector for a power cable with XLPE insulation, and is technologically simpler to manufacture. But it has large overall dimensions in a cross section perpendicular to the axis of the cable, and low reliability, which narrows the scope of its application.

The technical result achieved by the proposed utility model consists in reducing the overall dimensions of the coupling in a cross section perpendicular to the axis of the cable; and improving the reliability of its work.

The specified technical result is achieved in that the connection sleeve for the power cable containing the connector ends of at least one current-carrying core, the first layer of insulation coating covering the connector, the second layer of insulation coating covering the first layer prevent electrical breakdowns prevented electrical breakdowns of the insulation coating, and the metal screen located on the outside of the second layer of the insulating coating further comprises an electrically insulated trans ormiruyuschy layer for converting nonuniformly intense electric field propagating from the connector, in a uniformly intense electric field extending from the outer surface transforming layer. The transforming layer is located between the first and second layers of the insulation coating, exceeds the length of the connector in length, protrudes beyond the connector with its opposite ends and is made of material with a volume resistivity ρ _v of 10 ⁸ to 10 ¹² Ohm · cm at a relative permittivity .

The transforming layer makes it possible to smooth out surges of tension, to limit the propagation zone of an unevenly stressed electric field propagating from the connector, and to convert an unevenly charged electric field to a uniformly stressed electric field propagating from the outer surface of the transforming layer. As a result, electrical breakdowns that may occur between live conductors are prevented, as well as electrical breakdowns between the live conductor and the metal screen are prevented. The overall dimensions of the coupling in the cross section perpendicular to the axis of the cable, and the material consumption of the coupling can be reduced. At the same time, the reliability of the coupler can be improved.

As the material of the transforming layer, a mixture of an elastic polymer material with a finely dispersed conductive filler can be used in the following ratio of components, wt.%:

elastic polymer material 50-97 fine conductive filler rest.

In this case, polyethylene, or polypropylene, or polyvinyl chloride can be used as an elastic polymer material.

As a finely dispersed conductive filler, metal dust or carbon black, or titanium dioxide, or barium titanate can be used. A mixture of these materials can be used, for example, a mixture of metal dust with soot or a mixture of titanium dioxide with barium titanate. It should be noted that to control the capacitive conductivity of the transforming layer, it is preferable to use materials with a proper relative permittivity of at least 150, which are possessed by titanium dioxide and barium titanate.

Example 1 of the composition of the material of the transforming layer: polyethylene - 90%, copper metal dust - 10%.

Example 2 of the material composition of the transforming layer: polypropylene - 80%, carbon black - 20%.

Example 3 of the composition of the material of the transforming layer: polyvinyl chloride - 85%, titanium dioxide - 15%.

Example 4 of the composition of the material of the transforming layer; polyethylene - 85%, barium titanate - 15%.

A plastic deformable metal tube can be used as a connector. Or, a bolt, or welded, or solder joint can be used as a connector.

The proposed cable connector can be used to connect the ends of both multi-core and single-core power cable.

The utility model is illustrated by drawings.

Figure 1 is a longitudinal section of a coupling for a power multi-core cable.

Figure 2 is a cross-sectional view of a coupler for a power multi-core cable.

Figure 3 is a longitudinal section of a coupling for a power single-core cable.

Figure 4 is a cross-sectional view of a coupler for a single-core power cable.

The coupling for the power multi-core 1 or power single-core 2 cable contains a connector 3 ends of the conductive core 4, the first 5 and second 6 layers of insulation coating and a metal shield 7. The first layer 5 of the insulation coating covers the connector 3. The second layer 6 of the insulation coating covers the first layer 5 insulation coating. The metal screen 7 is located on the outside from the second layer 6 of the insulating coating. The coupling additionally contains a transforming layer 8, smoothing out surges of the electric field propagating from the connector 3. The transforming layer 8 is located between the first 5 and second 6 layers of the insulation coating and is longer than the length of the connector 3. The opposite ends 9 and 10 of the transforming layer 8 protrude for the connector 3. In the multi-core power cable 1, the connector 3, the first layer 5 of the insulation coating, the second layer 6 of the insulation coating and the transformation layer 8 are mounted on zhdoy

current-carrying conductor 4. The metal screen 7 of the power multi-core cable 1 or power single-core cable 2 in the working position is grounded.

The coupling works as follows.

When a current passes through a current-carrying conductor 4 of a power multicore 1 or power single-conductor 2 cable, surges of the electric field occur in the area of the ends of the current-carrying conductor 4. The magnitude of the surges of the electric field depends on the size of the flowing current, dimensions and material of the connector 3, the reliability of the connection of the ends of the conductor 4, the occurrence of an electric arc, burning contact surfaces and other factors. Thus around the connector 3 is formed unevenly stressed electric field. An electrically isolated transforming layer 8, located between the first 5 and second 6 layers of the insulating coating, limits the propagation zone of the unevenly intense electric field arising near the connector 3, and converts it into a uniformly stressed electric field propagating from the outer surface of the transforming layer 8. Opposite ends 9 and 10 of the transforming layer 8, protruding beyond the connector 3, prevent the transforming flow around the unevenly stressed electric field on layer 8. The reformed uniformly intense electric field is sharply reduced as the probability of electrical breakdown between live conductors 4 and between 4 and a conductive residential earthed metallic screen 7. This increases the reliability of the coupling operation. The overall dimensions of the coupling in the cross section perpendicular to its axis, and the material consumption of the coupling can be accordingly reduced.

Claims (7)

1. A connector for a power cable comprising a connector of the ends of at least one current-carrying core, a first layer of insulation coating covering the connector, a second layer of insulation coating covering the first layer of insulation coating, and a metal shield located on the outside of the second layer insulation coating, characterized in that it further comprises an electrically isolated transforming layer for converting an unevenly stressed electric field propagating Xia from the connector, in a uniformly intense electric field extending from the outer surface transforming layer, wherein transforming layer is disposed between the first and second layers of insulating coating along the length exceeds connector length, their opposite ends favors connector and made of a material with a volume resistivity ρ _v from 10 ⁸ to 10 ¹² Ohm · cm at a relative dielectric constant

. 2. The coupling according to claim 1, characterized in that as a material for the transforming layer, a mixture of an elastic polymer material with a finely dispersed conductive filler is used in the following ratio of components, wt.%: elastic polymer material 50-97 fine conductive filler rest. 3. The coupling according to claim 2, characterized in that polyethylene, or polypropylene, or polyvinyl chloride is used as an elastic polymer material. 4. The coupling according to claim 2, characterized in that metal dust is used as a finely dispersed conductive filler. 5. The coupling according to claim 2, characterized in that soot is used as a finely dispersed conductive filler. 6. The coupling according to claim 2, characterized in that titanium dioxide is used as a finely dispersed conductive filler. 7. The coupling according to claim 2, characterized in that barium titanate is used as a finely dispersed conductive filler.