RU196562U1 - CABLE CABLE LINE - Google Patents

Abstract

The invention relates to electrical products, in particular to high-voltage cable power transmission lines, mainly used for underground cable routes, and generally relates to facilitating the detection of breakdown points of cable sheaths laid in a cable line pipe. The technical result achieved by the claimed solution consists in improving the accuracy, reliability and speed of localization of places of damage to the cable in the conduit of the cable line. The claimed technical result is achieved by that they use a conduit for a cable line including a tubular body, the wall of which is made of polymer material, and equipped with a through channel for laying an electric cable along its length, and the tubular body is segmented, including combining at least two alternating longitudinal conjugated longitudinal circuits case and electrically conductive segments located along the entire length of the housing, together forming a closed rigid contour of the wall of the housing, ensuring the flow of ka through the electrically conductive segment in the direction from the inner surface of the housing to its outer surface. 9 s.p. f-ly, 2 ill.

Description

Purpose and scope

The utility model relates to electrical products, in particular, to high-voltage cable power transmission lines, mainly used for underground cable routes, and generally relates to facilitating the detection of breakdown points of cable sheaths laid in a cable line pipe.

State of the art

Known designs of conduits of cable lines, which include pipes that ensure the placement of the cable along the cable route.

In particular, at present, cable lines are widely used, which, as a means for accommodating the cable, comprise a conduit having a tubular body, in whose interior a cable is laid. The tubular conduit body can be made in the form of a single pipe or in the form of several pipes joined to each other.

So known cable line described in the journal "News of Electrical Engineering" No. 4 (82), 2013 (p. 78-83). The conduit of the cable line in question is a tubular casing containing a wall of polyethylene, intended for laying along its length, in the inner space, a power cable (6-500 kV) equipped with an external polymer sheath.

The use of a polymer tubular conduit, which has sufficient mechanical strength and resistance to environmental factors, protects the cable from mechanical damage and external influences, which improves the reliability of this cable line, and also makes it possible to use it when laying both ground and underground cable routes.

However, the design of the conduit of the cable line does not provide the ability to search for the place of damage to the outer sheath of the power cable by methods known from the prior art, based on the search and localization of the cable line along the cable using the devices used for this purpose, the place where the test current from the conductive screen of the power cable through a damaged outer shell it goes into the ground.

The output of current into the soil is prevented by the wall of the casing, made of polyethylene, which is a dielectric, not possessing the properties of electrical conductivity in the direction from its inner surface to the outer surface.

A solution is known from the prior art [RU 186701], according to which a solution is disclosed for conduit of a cable line having a tubular body, the wall of which is made of polymeric material and is made to ensure its conductive properties, making it possible for current to flow through the wall in the direction from its inner surface to outer surface, the ratio of the diameter of the inner surface of the wall of the housing to the diameter of the outer sheath of the cable is at least 1.5. The specified ratio was chosen in order to significantly reduce the heating of the soil surrounding the cable line, and the electrically conductive properties of the polymer wall of the tubular body are organized in the direction from its inner surface to the outer surface over its entire thickness, that is, in the transverse (radial) direction and can be distributed pointwise the housing, including the grouping of electrically conductive sections along an annular contour with the distribution of such sections along the length of the pipe. conduit. Based on the set of essential features, this decision can be taken as a prototype.

This solution only partially solves the problem of detecting the location of cable damage, since in order to meet the requirements for the mechanical and strength properties of the conduit, the formation of electrically conductive sections along the contour of the tubular body has its own limitations, thereby reducing the accuracy of localization of the location of damage to the cable sheath. This leads to unjustified time and labor costs, both for the actual detection of cable breakdown places, and for the elimination of identified malfunctions and renovation of these areas.

The essence of the claimed utility model

The technical problem that can be solved by implementing the utility model is the ability to test and search for the place of damage to the outer sheath of an electric cable placed in a protective tubular polymer conduit using methods based on detecting the place where current flows into the ground.

The technical result achieved by the claimed utility model is to increase the accuracy, reliability and speed of localization of cable damage points in the conduit of the cable line.

The claimed technical result is achieved by using a conduit of a cable line, including a tubular body, the wall of which is made of polymer material, and equipped with a through channel for laying along the length of the electric cable, which differs from the prototype in that the tubular body is segmented, including combining at least two alternating along an annular contour, interconnected, longitudinal housing and electrically conductive segments located along the entire length of the housing, together about azuyuschih rigid closed contour of the housing wall, with provision of current flow through the electrically conductive segment in a direction away from the casing inner surface to its outer surface.

In one of the possible embodiments of the claimed utility model, the wall of the housing is made multilayer, while the conductive properties of each layer of the housing and conductive segments in thickness correspond to the purpose of each segment.

In another possible embodiment, at least one electrically conductive segment is made in the form of an insert, with the possibility of mounting in the housing along the longitudinal side sections of the segment.

In yet another particular embodiment of the claimed utility model, at least one electrically conductive segment is made of a compound having electrical conductivity.

At the same time, according to any of the possible options for the implementation of the claimed utility model, housing and electrically conductive segments can be made of different sizes.

In one of the possible options, the inner surface of the housing is additionally provided with a coating having a reduced resistance to electric current. Whereas in another possible embodiment of the claimed utility model, the outer surface of the housing is additionally provided with a coating having a reduced resistance to electric current.

In the particular case, the casing and electrically conductive segments are made of materials with different electrical resistance. In this case, the housing segment can be made of dielectric materials.

Brief Description of the Drawings

The claimed utility model is illustrated by drawings, where:

FIG. 1 is a solution of a segmented tubular conduit of a conduit of a cable line according to a utility model, where: a) a cross section; b) longitudinal section

FIG. 2 - direction of current output in case of damage to the cable sheath of the cable line with a segmented conduit body.

It should be noted that the accompanying drawings illustrate only one of the most preferred embodiments of the utility model and cannot be construed as limiting the content of the utility model, which includes other embodiments.

Utility Model Feasibility

According to the claimed utility model, in the claimed solution, the conduit of the cable line is provided with a tubular housing made segmented and consisting of housing 1 and electrically conductive 2 segments, interconnected in the longitudinal direction along the entire length of the housing. At the same time, the segments forming the conduit body have a thickness that ensures the formation of uniform external and internal surfaces of the body of a given shape. As shown in FIG. 1 and 2 of the embodiment, the segments of the housing are single-layer. However, in possible embodiments of the claimed utility model, the tubular conduit body may be laminated. Moreover, the electrically conductive properties of each layer of the structural and electrically conductive segments in thickness correspond to the purpose of each segment.

Since one of the main tasks solved by the conduit is the possibility of using a cable line both in land and in underground cable routes using cost-effective and technologically advanced laying methods, in particular, the method of horizontal directional drilling, its casing is preferably made of materials ensuring the placement and preservation of the position of the cable in the place of passage of the cable route, as well as protecting the cable from mechanical damage and external influences during its operation. Thus, the casing and electrically conductive segments forming the conduit body together have a sufficient degree of rigidity, elasticity and chemical resistance to aggressive environments and adverse operating conditions, providing the required performance characteristics of the conduit of the cable line. At the same time, due to the use of a conduit housing wall of a polymer material, which is resistant to corrosion and mechanical stress, flexibility, lightness, and durability, the usability of the inventive cable line is increased.

The electrically conductive segments of the conduit body are made with a sufficient degree of mechanical strength and chemical resistance comparable with similar characteristics of the body segments, however, in a preferred embodiment, the materials of the body and electrically conductive segments have different electrical resistance to current. In this case, the housing segments can be made of dielectric materials, for example, thermoplastic polymeric materials. Then, as for the electrically conductive segments, materials are selected that have an electric current resistance, providing the possibility of outputting current from the inner cavity of the conduit to the outside when the outer sheath of the cable located in the cable line is damaged.

The mating structural and electrically conductive segments, according to the claimed utility model, can have a different configuration and geometric dimensions, depending on operating conditions, the configuration of the conduit body and the cable duct, as well as the cable lines (cable) located in the conduit housing, and interconnected with the formation of a single tubular contour of the housing, with the specified mechanical parameters of the conduit. At the same time, the inner surface of each segment has contact with the inner surface and the space of the tubular body, and the outer surface with the external medium (soil), ensuring the transmission of electric current through the electrically conductive segment from the inner surface of the tubular body to the outside, where the current propagates into the ground and can be detected by methods known in the art.

Since all segments of the casing, including electrically conductive ones, are longitudinally elongated along the entire length of the tubular conduit casing, the current exit to the ground can be localized with a high degree of accuracy. At the same time, the number of conductive segments and their sizes do not significantly affect the localization accuracy, they only contribute to a clearer identification of the fact of current leakage and eliminate the possibility of accidental isolation of the leakage current, for example, in the case of complex topologies of cable lines and their type (single-phase, three-phase )

In the particular case of the claimed utility model, the electrically conductive segment can be made in the form of a long insert, for the entire length of the housing, with fastening along adjacent longitudinal lateral sides of adjacent housing segments. The fastening can be carried out, for example, by performing adjacent segments by coextrusion, fastening the adjacent surfaces with glue, using mechanical fastening, for example, by attaching a tongue groove, as well as by another method of fastening adjacent segments used in the body of pipelines known from the prior art and cable lines. Preferred is the implementation of the interface between the electrically conductive segments and the housing segments in a sealed design.

As materials for performing the electrically conductive segments of the pipe, it is preferable to use polymeric materials having a specific volume resistance of not more than 10,000 Ohm⋅m. For example, composite polymer materials based on various polymers (thermo-, reacto-, elastoplastics) containing electrically conductive fillers (carbon black, graphite, carbon, metal and metallized fibers, metal powder, etc.) can be used as electrically conductive polymeric materials, or polymeric materials in which the molecules themselves or supramolecular formations have a specific conductivity. The electrically conductive segment may also contain, if necessary, and preferably in combination with the above conductive particles or fibers, initially conductive polymers such as polyacetylene, polythiophene, polyaniline or polypyrrole or ionomers containing alkali and / or alkaline earth metal ions or mixtures thereof.

Due to the placement of cable 3 (Fig. 2) in a tubular conduit, the casing wall of which is made to ensure its conductive properties, due to the presence of longitudinal conductive segments, causing the possibility of current flowing through the wall in the direction from its inner surface to the outer surface, in the inventive cable line a path is organized for the current generated in the inner space of the housing when the outer sheath of the cable is damaged, through the wall of the housing beyond.

In practice, the current output from the conduit body to the surrounding soil can be difficult due to its low electrical conductivity due to the prolonged exposure to the soil at a high working temperature of the cable. So, the temperature of the core of the high-voltage cable in normal operation reaches 90 ° C, and the temperature of its outer shell reaches 80 ° C. Heating of the soil leads to the absence or minimization of moisture content, filling the gaps between the particles of the soil and having the properties of electrical conductivity, which leads to a decrease in the electrical conductivity of the soil.

Placing the cable in an electrically conductive polymer tubular casing helps to reduce the heating temperature of the soil surrounding the cable line and, accordingly, to reduce the negative effect of heating on the electrical conductivity of the soil, the greater the greater the gap between the cable and the tubular casing, which is determined by the ratio of the diameters of the casing and the cable.

Thus, in the inventive cable line, a current path is organized from the inner space of the housing, where it enters from the surface of the cable from the damaged outer sheath, through the housing wall beyond its limits into the surrounding soil, where the current can be recorded by devices that search for the location of cable damage.

In order to combine individual sections with transverse conductive properties into a single system in order to facilitate the flow of current from the internal space of the casing beyond its limits, the casing wall can be coated with an electrically conductive material on its inner, outer surface, as well as on both its surfaces (multilayer wall).

The conduit body can be made in the form of a single pipe or in the form of several pipes joined to each other.

As an electric cable, a power cable (up to 500 kV) containing a core, a core insulation, a metal shield and an outer sheath can advantageously be used.

The cable is installed inside the tubular body, mainly ensuring contact areas (mechanical and / or electrical) of its outer shell with the inner surface of the shell.

In the General case, the conduit may also contain couplings, end caps and other (not shown), without changing the design of the segmented conduit housing according to the claimed utility model.

The device operates as follows.

When applying test current through the cable screen, the current from the damaged cable sheath 3 (Fig. 2) goes to its outer surface, then through the place of contact of the cable and the pipe, the current flows to the inner surface of the housing segment 1, from where it enters the surrounding pipe through the electrically conductive segment 2 soil where it is fixed by standard methods and devices.

The mere fact that the test current flows from the test setup connected to the cable means that the cable sheath is really damaged somewhere, and the current goes out into the ground somewhere. The place where the test current exits from the cable to the ground, fixed by instruments, will indicate the exact location of the damage along the cable line. At the same time, a segmented conduit casing allows minimizing the costs of troubleshooting, by minimizing the time and labor required to determine the exact location of the cable line cable damage and opening the conduit casing to provide access to the cable for repair.

Claims (10)

1. Conduit cable line comprising a tubular body the wall of which is made of a polymeric material, and provided with a through bore for a lining along the length of the electrical cable, characterized in that the tubular housing is segmented, comprising a combination of at least two alternating along the circular contour of the conjugate between themselves, longitudinal hull and electrically conductive segments located along the entire length of the housing, together forming a closed rigid contour of the wall of the housing, ensuring leakage electrically conductive segment of an eye through from the inner surface of the housing to its external surface. 2. The conduit according to claim 1, characterized in that the wall of the housing is multilayer, while the electrically conductive properties of each layer of the structural and electrically conductive segments in thickness correspond to the purpose of each segment. 3. The conduit according to claim 1, characterized in that at least one electrically conductive segment is made in the form of an insert, with the possibility of fastening in the housing along the longitudinal side sections of the segment. 4. The conduit according to claim 1, characterized in that the segmented tubular body is made by coextrusion of casing and electrically conductive segments. 5. The conduit according to claim 1, characterized in that at least one electrically conductive segment is made of a compound having electrical conductivity. 6. Conduit according to any one of paragraphs. 1-5, characterized in that the casing and conductive segments are made of different sizes. 7. The conduit according to claim 6, characterized in that the inner surface of the housing is additionally provided with a coating having a reduced resistance to electric current. 8. The conduit according to claim 6, characterized in that the outer surface of the housing is additionally provided with a coating having a reduced resistance to electric current. 9. The conduit according to claim 6, characterized in that the structural and electrically conductive segments are made of materials with different electrical resistance. 10. The conduit according to claim 9, characterized in that the structural segment is made of dielectric materials.

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