RU97013U1 - CONNECTING CLUTCH FOR POWER CABLE - Google Patents

Abstract

The coupling (1) for the power cable (2) relates to electrical engineering and can be used to connect the ends of a single-core power cable, as well as to connect the ends of each phase of a multiphase power cable. The coupling (1) contains a connector (3) of the ends of at least one current-carrying core (4), which is sequentially covered by the first layer (5) of an insulating coating of elastic polymer material, an electrically insulated transforming layer (6) based on an elastic polymer material , the second layer (7) of the insulating coating of elastic polymer material and a metal screen (8). The electrically isolated transforming layer (6) is longer than the length of the connector (3), protrudes beyond the connector (3) with its opposite ends (9), (10), has the shape of a hollow cylinder with opposite ends (9), (10) in the form of hollow truncated cones 55-65 mm long, the generators of which form an angle from 6 ° to 8 ° with the longitudinal axis of the cable. The transforming layer (6) is made of a material with a relative dielectric constant ε of at least 22, in which the ratio of the longitudinal component of the complex conductivity tensor to the transverse component is 10-12. 4 cp, 2 ill.

Description

The inventive utility model relates to electrical engineering and can be used to connect the ends of a single-core power cable, as well as to connect the ends of each phase of a multiphase power cable.

A known cable connection sleeve (see patent RU No. 2284620, IPC H02G 15/08, published September 27, 2006), including a cable cutting unit, a cable end sealing assembly, an isolated cable splice with interfacial space between them, a sealing element and a heat-shrinkable fitting the tube. When sealing the ends of the cable, two cuffs were used sequentially superimposed on one another, one of which is made of an oil-resistant polymer material, and the other is made of a polymer material with non-linear electrical characteristics. A single insulating spacer is introduced into the interphase, having the form of a cylindrical rod with at least three deep segmented recesses elongated in the longitudinal direction of its length. The sealing element of the interfacial space is made of a two-layer pipe, the first outer layer of which is made of heat-shrinkable material with an underlayer of adhesive material, and the inner layer has the shape of a cylinder with a cut along its longitudinal axis, tightly adjacent to the first layer of heat-shrinkable material with an underlayer of adhesive and made, like a spacer made of fusible material.

The disadvantages of the known cable connector are technological difficulties in production (vulcanization of polyethylene) and installation (the need for heat treatment), as well as insufficient reliability, due to the impossibility of changing its size, following a change in cable size, during heating and cooling during operation due to the properties of heat shrinkable cross-linked polyethylene products. In addition, the known coupling has a high material consumption, due to the need to use additional adhesive and sealing elements. This narrows the scope of its application.

Known coupling for a single-core cable with insulation made of cross-linked polyethylene (see patent RU No. 62300, H02G 15/18, published March 23, 2007), containing a sleeve connecting the cores of two cables, a polymer sleeve, smoothing the electric field along the sleeve, an element, leveling the electric field at the cut-off screen of the connected cables, a two-layer heat-shrinkable tube with an inner insulating layer and an external electrically conductive one for insulating the sleeve, an aluminum foil screen, a second sleeve for connecting Ia shield, an outer heat-shrinkable polymer tube, the sealant layers located under the outer heat-shrinkable tube. The element leveling the electric field strength is made in the form of a cable installed on the insulation with approaching the steps of the screens of a two-layer heat-shrinkable polymer tube with an external layer equalizing the electric field strength and an external insulating one.

The disadvantages of the known cable joint are technological difficulties in the production (vulcanization of polyethylene) and installation due to the need for heat treatment, as well as insufficient reliability, due to the impossibility of changing its size, following the change in cable size, during heating and cooling during operation from -for the properties of heat-shrinkable products from cross-linked polyethylene.

Known cold-seated connector for a power cable (see US patent No. 7498515, IPC H02G 15/08, published 03.03.2009), containing a connector ends of a current-carrying core, which is sequentially applied to the first layer of insulating coating of silicone rubber, a semiconductor layer conducting metal an element conducting a metallized layer and an outer protective layer.

Known coupler has the ability to change its size, after changing the dimensions of the cable, during heating and cooling during operation. However, in the known coupling, the degree of electric field is reduced using only the physical properties of the material.

Known coupler for power cable (see patent RU No. 70415, IPC H02G 15/08, published January 20, 2008), coinciding with the claimed technical solution for the largest number of essential features and adopted as a prototype. 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 with a relative permittivity ε = 15-30. The transforming layer prevents the possibility of electrical breakdown between live conductors, as well as between live conductors and a metal screen.

A known coupler smoothes out surges of electric field in the area of cable connection. In a known clutch, the degree of electric field is reduced using only the physical properties of the material. With this approach, it is not possible to achieve optimal effective values of the maximum rms electric field strength in the insulation, which reduces the reliability of the coupling, especially in overload conditions.

The task that the claimed technical solution solves was the development of such a coupling for the power cable, which would have increased reliability in operation.

The problem is solved in that the connection sleeve for the power cable contains a connector of the ends of at least one current-carrying core, which is sequentially covered by a first layer of insulation coating of elastic polymer material, an electrically isolated transforming layer of elastic polymer material, a second layer of insulation coating of elastic polymer material and metal screen. The electrically insulated transforming layer is longer than the length of the connector, protrudes beyond the connector with its opposite ends, has the shape of a hollow cylinder with opposite ends in the form of hollow truncated cones 55-65 mm long, which form an angle of 6 ° to 8 ° with the longitudinal axis of the cable. The electrically isolated transforming layer is made of a material with a relative dielectric constant ε of at least 22, for the material of the transforming layer the ratio of the longitudinal component of the complex conductivity tensor to the transverse component is 10-12.

Improving the reliability of the coupling is achieved both due to certain physical characteristics of the material of the transforming layer and certain physical characteristics of the insulating layers that allow the use of cold shrinkage, and due to a certain geometric configuration of the transforming layer, which, along with the physical properties of the material, provides the optimal values of the maximum rms tension of the quasistationary electric field in isolation.

As a material for an electrically isolated 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 - 50-95 fine conductive filler - the rest.

As an elastic polymer material, ethylene propylene or silicone rubber can be used.

As a finely dispersed conductive filler, metal dust or soot with certain geometric particle sizes can be used.

In the event that the indicated geometric dimensions of the transforming layer (the length of the truncated cones and the angles of the generators) go beyond the corresponding intervals, it is not possible to achieve optimal values of the maximum rms electric field strength in the coupling insulation.

The same will happen if the relative permittivity ε of the composite material of the transforming layer is less than 22.

The inventive utility model is illustrated in the drawing, where:

figure 1 shows a longitudinal section of a coupling for a power single-core cable;

figure 2 - shows a cross section along aa of the coupling for the power single-core cable shown in figure 1.

The coupling 1 for the power single-core cable 2 (see Fig. 1, Fig. 2) comprises a connector 3 of the ends of the current-carrying core 4, a first layer 5 of an insulating coating, an electrically isolated transforming layer 6 for converting an unevenly stressed electric field propagating from the connector 3, into a uniformly intense electric field propagating from the outer surface of the layer, and thereby smoothing out surges of the electric field propagating from connector 3, the second layer 7 of insulating about the coating and the metal shield 8. 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 of the insulation coating. An electrically insulated control layer 6 is located between the first insulation coating layer 5 and the second insulation coating layer 7 and is longer in length than the connector 3. The metal shield 8 is located on the outside of the second insulation coating layer 7. The electrically insulated control layer 6 has the form of a hollow cylinder with opposite ends 9, 10 protruding beyond the connector 3, in the form of hollow truncated cones with a length of 55-65 mm. Generators of hollow cones make an angle of 6 ° to 8 ° with the longitudinal axis 11 of cable 2. The electrically insulated control layer 6 is made of a material with anisotropic electrical conductivity. Anisotropy is characterized by a predetermined ratio between the longitudinal, parallel to the axis 11, and the transverse components of the complex conductivity tensor. Namely, the material of the electrically isolated control layer 6 has a ratio of the longitudinal component of the complex conductivity tensor to the transverse component equal to 10-12, while the electrically isolated control layer 6 is made of a material with a relative dielectric constant ε of at least 22.

As the connector 3 can be used plastically deformable metal tube, or bolted, or welded joint.

As a finely dispersed conductive filler, carbon black with a particle size of the order of (0.02-0.05) microns can be used. A mixture of materials may be used, for example a mixture of metal dust with soot.

The inventive coupling 1 operates as follows. When the current passes through the current-carrying conductor 4 of the power single-core cable 2, surges in the electric field occur in the zone of connection of the ends of the current-carrying conductor 4. The magnitude of surges in the electric field depends on the size of the current flowing, the size and material of the connector 3, the reliability of the connection of the ends of the current-carrying conductor 4 arc, burning contact surfaces and other factors. Thus around the connector 3 is formed unevenly stressed electric field. An electrically insulated control layer 6, located between the first insulation coating layer 5 and the second insulation coating layer 7, limits the propagation zone of an unevenly charged electric field arising near the connector 3 and converts it into a uniformly stressed electric field propagating from the outer surface of the control layer 6. The opposite ends 9 and 10 of the control layer 6, protruding beyond the connector 3, prevent the flow of unevenly charged electric field p the regulating layer 6. In a uniformly transformed electric field, the probability of electrical breakdown between the current-carrying conductor 4 and the grounded metal screen 8. is sharply reduced. This increases the reliability of the coupling 1.

Example 1 of the composition of the material of the regulatory layer 6, wt.%:

ethylene propylene rubber - 90

copper metal dust - 10.

Example 2 of the composition of the material of the regulatory layer 6, wt.%:

ethylene propylene rubber - 75

soot - 25.

Example 3 of the composition of the material of the regulatory layer 6, wt.%:

silicone rubber - 80

carbon black 20.

Example 4 of the composition of the material of the regulatory layer 6, wt.%:

silicone rubber - 95

copper metal dust - 5.

All conclusions regarding the geometric configuration of the transforming layer and the dielectric properties of the material from which this layer is made are based on a series of calculations using a special application package.

Claims (5)

1. A connector for a power cable, comprising a connector for the ends of at least one current-carrying core, which is sequentially covered by a first layer of insulation coating of elastic polymer material, an electrically isolated transforming layer based on elastic polymer material, and a second layer of insulation coating of elastic polymer material and a metal screen, wherein the electrically isolated transforming layer is longer than the length of the connector, protrudes beyond the connector its opposite ends, it has the shape of a hollow cylinder with opposite ends in the form of hollow truncated cones 55-65 mm long, the generators of which form an angle of 6 to 8 ° with the longitudinal axis of the cable, and is made of a material with a relative permittivity ε of at least 22, which the ratio of the longitudinal component of the complex conductivity tensor to the transverse component is 10-12. 2. The coupling according to claim 1, characterized in that as a material for an electrically isolated 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  50-95 fine conductive filler  rest 3. The coupling according to claim 2, characterized in that ethylene-propylene or silicone rubber is used as the 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.