RU202322U1 - CABLE WIRING DEVICE - Google Patents

Abstract

The utility model relates to electrical wiring products, namely to conduit devices for laying cable power transmission lines. The essence of the utility model is that the conduit device contains a tubular body made of a dielectric polymer material, the inner space of which forms a conduit channel for an electric cable, while in the wall of the case, electrically conductive sections are formed, made in the form of extended electrically conductive elements located along the length of the case, oriented along it and passing through the entire thickness of its wall, ensuring the possibility of electric current flow through the wall in the direction from its inner surface to the outer surface, according to the utility model extended electrically conductive elements have a height exceeding the wall thickness and are made protruding into the inner space of the tubular body to form sliding ribs designed to reduce the mustache The technical result achieved when implementing the claimed utility model is to reduce the pulling force of the electric cable into the inner space of the conduit device, which is capable of determining the location of damage to the outer sheath of the cable. 2 c.p. f-ly, 5 dwg

Description

The utility model relates to electrical wiring products, namely to conduit devices for laying cable power transmission lines.

Currently, conduit devices are widely used, which contain a tubular body made of a dielectric polymer material, in the inner space of which a cable is laid (see, for example, Zh. News of Electrotechnics No. 4 (82), 2013 (pp. 78-83 )).

The specified dielectric polymer tubular body has sufficient mechanical strength and resistance to environmental factors and provides protection of the electrical cable from mechanical damage and external influences when laying both ground and underground cable routes.

Known conduit devices containing a tubular body made of a dielectric polymer material, in the wall of which electrically conductive sections are made, allowing electric current to flow through the body wall in the direction from its inner surface to its outer surface (the so-called current search conduit pipes). With the help of the considered conduit devices, it is possible to localize the site of damage to the outer sheath of the cable placed in the tubular body by methods known from the prior art, based on finding the exit point of the test current supplied to the cable screen through the damaged outer sheath and the wall of the tubular body into the soil in contact with it. ...

For example, it is known a conduit device [RU 188229], comprising a tubular body made of a dielectric polymer material, having "point" electrically conductive sections made in the form of electrically conductive elements installed in through holes formed in the wall of the body, passing through the entire wall thickness, such as bolts, screws, rivets, wire elements and so on.

In the specified device, the accuracy of determining the location of damage to the sheath of the cable depends on the number of through holes and on their location.

Known conduit device [RU 196562], which is selected as the closest analogue.

The considered device contains a tubular body made of a dielectric polymer material, the inner space of which forms a conduit channel for an electric cable. In the wall of the case, electrically conductive sections are formed, made in the form of conductive elements (segments) located along the length of the case, oriented along it parallel to the longitudinal axis and passing through the entire thickness of its wall, which provide the possibility of electric current flow through the wall in the direction from its inner surface to the outer surface.

Due to the presence of these extended electrically conductive elements, the accuracy of determining the location of damage to the outer sheath of the cable of the device in question is increased.

However, in this conduit device, as well as in the previously considered conduit devices containing a current search conduit, no special means are provided for reducing the pulling forces of the electrical cable into the conduit of the device.

An example of these special tools can be the tools used in the conduit device [RU 2128389]. The specified device is designed to install a cable in it, but it does not provide the ability to determine the location of damage to the outer sheath of the cable. It contains a thermoplastic tubular body, on the inner surface of which irregularities made of tubular body material are formed, located in a wave-like manner and forming sliding ribs, due to which the friction force is reduced when the cable is pulled into the conduit channel and the cable is prevented from sticking to the surface of the specified channel, which leads to a decrease in forces retraction.

The technical problem, the solution of which is provided by the implementation of the utility model, is to reduce the force of drawing the electric cable into the channel of the conduit device, made with the possibility of determining the location of the damage to the outer sheath of the cable.

The essence of the utility model is that in a conduit device containing a tubular body made of a dielectric polymer material, the inner space of which forms a conduit channel for an electric cable, while conductive sections are formed in the case wall, made in the form of extended conductive elements located along the length of the case, oriented along it and passing through the entire thickness of its wall, allowing electric current to flow through the wall in the direction from its inner surface to the outer surface, according to the utility model, the extended electrically conductive elements have a height exceeding the wall thickness and are made protruding into the inner space of the tubular housing with the formation of sliding ribs designed to reduce the pulling force of the electrical cable into the conduit.

In the particular case of the utility model, the extended electrically conductive elements forming the sliding ribs are oriented along the body along its longitudinal axis.

In the particular case of the utility model, the extended electrically conductive elements forming the sliding ribs are oriented at an angle of inclination a to the longitudinal axis of the body, the value of which lies in the range 0 ° <α <90 °.

The conduit body is made of a polymer dielectric material, which has sufficient mechanical strength and resistance to environmental factors, protects the cable located in its internal space from mechanical damage and external influences when laying both ground and underground cable routes. In this case, it becomes possible to use technological and economically viable methods of laying the cable route, in particular, the method of horizontal directional drilling, during which the polymer tubular body of the cable conduit is pulled into the ground, and then the cable is pulled into it.

Due to the presence in the wall of the housing of the above-described electrically conductive elements extending throughout its entire thickness, the dielectric wall of the housing in the areas occupied by them has electrical conductivity in the direction from its inner surface to the outer surface.

Due to this, it is possible for a test current to flow through the indicated sections of the housing, entering the inner space of the housing from the damaged outer sheath of the cable, and its output into the ground in contact with the housing, and, consequently, the possibility of fixing the specified current by devices in order to localize the place of damage to the cable sheath.

In this case, since these elements are made extended and are located along the body along its length, it is easier for the current to exit into the ground immediately near the location of the damage to the cable sheath, which leads to a high accuracy in determining the location of its damage.

Due to the fact that the considered extended electrically conductive elements have a height exceeding the thickness of the housing wall, their end sections protruding into the interior space of the housing form on the inner surface of the conduit channel extended sliding ribs oriented along the housing, along the contact surfaces facing the cable, the cable slides when it is pulled into conduit.

The presence of these sliding ribs helps to reduce the frictional force when pulling the cable into the conduit and prevents the cable from sticking to its surface, which causes a decrease in the pulling force.

The number of these elongated electrically conductive elements, their orientation relative to the longitudinal axis of the body and the distribution around the circumference in the plane of the cross-section of the body can be different.

The electrically conductive elements, as well as their end portions protruding into the body, in the cross-sectional plane of the body can have various geometric dimensions and configurations, for example, have a rectangular, triangular, trapezoidal, round, figured shape and others.

The specified electrically conductive elements can be made in the form of a single extended insert element or in the form of several contacting (mechanically and electrically) extended inserts made of metal or of an electrically conductive polymer material.

In order to facilitate the exit of current from the inner space of the housing outside its limits, the outer and / or inner surface of the housing wall can be coated with an electrically conductive material (multilayer wall). In this case, the outer sheath of the cable installed in the conduit can also be coated with an electrically conductive material.

The body can be made in the form of a single pipe or in the form of several pipes sequentially docked with each other.

Elongated electrically conductive elements can be located along the length of the body with an offset from the end sections of abutting pipes, in particular, for their connection to each other by welding or by means of couplings.

The claimed device can be advantageously used for laying a power cable (voltage 0.4-500 kV) containing a core, an inner insulating sheath (insulation), a metal screen and an outer sheath.

The sliding ribs can be oriented along the longitudinal axis of the housing to form conductive segments.

The sliding ribs can also be oriented at an angle of inclination a to the longitudinal axis of the body, the value of which lies in the range 0 ° <α <90 °.

In this case, the sliding ribs can be located along the length of the body with the same angle of inclination a or be located along the length of the body with oppositely directed angles of inclination a (wavy).

With an oblique orientation of the extended electrically conductive elements forming the sliding ribs, the probability of their contact with the ground increases, regardless of which part of the body surface is in contact with the ground and the degree of deepening.

Thus, the technical result achieved during the implementation of the claimed utility model is to reduce the pulling force of the electric cable into the inner space of the conduit device configured to determine the location of damage to the outer sheath of the cable.

FIG. 1 shows a general view of the claimed device with sliding ribs oriented along the longitudinal axis of the body (cross-section); in fig. 2 - the same, side view; in fig. 3 shows a general view of the device with sliding ribs oriented obliquely to the longitudinal axis of the housing (cross-section); in fig. 4 - the same, side view; in fig. 5 shows the path of current from the damaged cable sheath through the device wall into the surrounding soil.

The device contains a tubular body 1, the wall of which is made of a dielectric polymer material. The inner space 2 of the housing 1 forms a conduit for accommodating an electrical cable 3 (see FIG. 5).

In the wall of the housing 1, there are extended electrically conductive elements 4 located along its length, the height of which exceeds the thickness of the wall of the housing 1, while the end sections of the electrically conductive elements 4 protruding into the housing 1 form sliding ribs.

The elements 4 are made, in particular, of a polymer material with electrical conductivity.

In particular, said sliding ribs 4 are oriented along the longitudinal axis of the housing 1 (Figs. 1 and 2).

In particular, said sliding ribs 4 are oriented at an angle a to the longitudinal axis of the housing 1 (Figs. 3 and 4).

The device works as follows.

Place the electric cable 3 in the housing 1, pulling it into the inner space 2 of the housing 1. In this case, the cable 3 slides along the contact surfaces of the sliding ribs 4, which helps to reduce the pulling force.

When the test current is applied along the screen of the cable 3, the current from its damaged sheath enters the inner space 2 of the housing 1 (Fig. 5) and then through the contaminated and wetted surface of the cable and the housing it enters the surface of the electrically conductive element 4 that is closest to the place of damage to the cable sheath 3.

Then the current from the damaged cable sheath 3 through the wall of the housing 1 enters the ground.

The place where the test current exits from the cable 3 into the ground, fixed by the devices, makes it possible to localize the place of damage to the sheath of the cable 3 on the cable line route.

Claims (3)

1. A conduit device containing a tubular body made of a dielectric polymer material, the internal space of which forms a conduit channel for an electric cable, while electrically conductive sections are formed in the body wall, made in the form of extended electrically conductive elements located along the length of the body, oriented along it and passing for the entire thickness of its wall, providing the possibility of electric current flow through the wall in the direction from its inner surface to the outer surface, characterized in that the extended electrically conductive elements have a height exceeding the wall thickness and are made protruding into the inner space of the tubular body to form sliding ribs, designed to reduce the pulling force of the electrical cable into the conduit. 2. The conduit device according to claim 1, characterized in that the extended electrically conductive elements forming the sliding ribs are oriented along the body along its longitudinal axis. 3. The conduit device according to claim 1, characterized in that the extended electrically conductive elements forming the sliding ribs are oriented at an angle of inclination α to the longitudinal axis of the body, the value of which lies in the range 0 ° <α <90 °.

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