RU2551422C1 - Cable line laying method and cable chamber - Google Patents

Abstract

FIELD: electricity.

SUBSTANCE: method of cable line laying with providing of ferromagnetic shielding includes excavation of trenches for cables of one cable line circuit, bedding the trench bottom, laying of the cable line circuit, installation of ferromagnetic screen in places of local maxima of magnetic field intensity along the cable line route. The cable chamber contains the housing, supporting structures for connecting couplings inside the housing, a front cover of the cable compartment, the housing is fitted with a well for transposition of cable screens placed from outer side of the face wall of the duct.

EFFECT: simplification of the process of construction of the cable line route and implementation of more reliable and safe power transmission to consumers.

8 cl, 19 dwg

Description

FIELD OF TECHNOLOGY

The invention relates to electrical engineering and the electric power industry and can be used for cable power lines (in trenches, in particular crossed by communications) with the requirements of sanitary and epidemiological rules and norms for the maximum permissible levels of magnetic fields (MP) of industrial frequency in residential, administrative, industrial buildings and residential areas.

BACKGROUND OF THE INVENTION

Cable lines are an alternative to overhead power lines and are usually used in places where the construction of overhead lines is impossible or difficult, in particular in urban environments. The advantages of such lines are higher resistance to various atmospheric influences, a high degree of reliability and safety during operation, which makes it possible to widely use various types of voltages in electric power supply networks.

There is a method of laying single-circuit and multi-chain cable power lines in the ground (see Panteleev E.G. Installation and repair of cable lines: Handbook of an electrician / edited by A.D. Smirnov et al. - M .: Energoatomizdat, 1990. - P. 72-78 [1], Electrical Installation Rules, 7th ed. / Approved by Order of the Ministry of Energy of Russia dated 08.07.2002 No. 204, p.147-160 [2], Oil-filled cable lines 110-500 kV high pressure. - M. : Energoatomizdat, 1984. - S.21-23 [3]). This method includes:

- digging trenches for cable line chains, applying bedding to the bottom of the trench, laying one chain or several chains of the cable line, backfilling cables, installing, if necessary, additional protection elements from mechanical damage in the form of concrete slabs or bricks. With this installation method, a cable line is constructed with a cable deepening value depending on the voltage class, ensuring their security and accessibility during maintenance. However, along the route of extended cable lines, local maxima of the magnetic field may occur, exceeding the permissible sanitary standards, in particular, at the joints of the construction lengths of the cables by means of couplings. One of the possible ways to meet the sanitary standards in terms of the magnetic field above the earth's surface is to increase the laying depth along the entire route, or to further deepen the joints of cables, which complicates the process of laying cables and maintaining the cable line. In addition, the route of the cable line can intersect with other cable lines and engineering structures, and to ensure acceptable levels of the magnetic field in these places, a significant increase in the depth of the cable is necessary, which introduces additional difficulties when laying the cable line.

To protect against the magnetic component of electromagnetic fields, shielding means [2] are used that provide acceptable levels of the magnetic field. From Pat. EP 1598911, publ. 08/22/2007 [4] it is known to use means of shielding magnetic fields when laying cable power lines. The method according to US Pat. docum. [4] includes digging trenches for cable line circuits, applying backfill to the bottom of the trench, laying one or several cable line circuits, initial backfilling of cables, installation of magnetic field shielding. In this method, the installation of a ferromagnetic shield is carried out along the cables along the entire section of the route and the depth of their penetration is not related to the voltage class of the cable line. The installation of a ferromagnetic screen over the entire portion of the cable line route complicates the construction and maintenance of the cable line.

SUMMARY OF THE INVENTION

A method is proposed for laying cable lines with an acceptable magnetic field strength above the earth’s surface without installing ferromagnetic shields over the entire section of the cable line route with an acceptable minimum depth depending on the voltage class, which varies from the lowest value for cable lines of the lower voltage class to high values for cable lines of higher voltage class. With this interconnection, it is sufficient to shield magnetic fields in areas of their local maximums that occur on separate sections of the cable line, in particular in areas where cable cables are connected by means of couplings, as well as at intersections with other cable lines and utilities, and it becomes possible cable laying with a smaller amount of deepening. The technical result of this laying method is to simplify the process of constructing a cable line route, facilitate its maintenance, as well as implement more reliable and safe energy transmission to consumers with the required cable line capacity.

The specified technical result is achieved by the fact that in the method of laying the cable line with the provision of ferromagnetic shielding, in which the development of the trench, at least for the cables of one cable line circuit is carried out, a bed is added to the bottom of the trench, at least one cable line circuit is laid , perform primary filling of the cables, install a ferromagnetic shield along the cables of the circuit, make the final filling of the trench, and install the ferromagnetic shield in places of local maximums of tension and the magnetic field of the cable line with a voltage of 10 to 500 kV, while along the entire route of the cable line, the permissible laying depth to the top of the cables is:

- 0.7-4.0 m for circuits with voltage from 10 to 20 kV, with the possibility of local reduction of the laying depth when crossing with underground utilities and when entering buildings up to 0.5 m;

- 1.0-4.0 for circuits with voltage from 24 kV to 35 kV, with the possibility of local reduction of the laying depth when crossing with underground utilities and when entering buildings up to 0.5 m;

- 1.5-4.0 m for circuits with voltage from 110 to 220 kV, with the possibility of local reduction of the laying depth when crossing with underground utilities and when entering buildings up to 0.5 m;

- 1.5-4.0 m for circuits with voltage from 330 to 500 kV, with the possibility of local reduction of the laying depth at the intersection with underground utilities and when entering buildings up to 1.0 m, subject to the development of special technical conditions.

A ferromagnetic shield is installed along the cable line route at local maximum magnetic field strengths, such as the connection points of circuit cables along the cable line route, the cable line intersecting with other cable lines, and also at the intersection with collectors and utilities. The length of these places, as a rule, is determined only by the structural dimensions of the connection or intersection sections, and only at these places screening of magnetic fields is required. At the same time, ferromagnetic screens along the entire line are not required, which facilitates their installation and maintenance of the cable line as a whole.

When laying a cable line in a trench, the development of which is carried out for at least two chains of the cable line, the chains are laid on a bed with a distance in the light between the chains depending on the mutual thermal influence and the possibility of arc damage. If necessary, for at least one circuit in the trench at the cable connection points, a cable chamber equipped with a ferromagnetic screen is mounted. This allows you to build a cable chamber with a significantly lower amount of penetration and, thus, simplify the construction of the cable line as a whole and facilitate access to service connections.

When laying the cable line, the ferromagnetic shield is formed of side and horizontal sections containing a layer of ferromagnetic material. Before backfilling of the cables of the circuit, the side sections of the screen are installed with an interval in the light between each side section and the cable of at least 0.2 m, and the cables are backfilled to the installation level of the horizontal section of the ferromagnetic screen, after which the horizontal section of the ferromagnetic screen is installed to ensure that the layers are made of ferromagnetic horizontal section material and side sections. Moreover, the installation depth of the horizontal section of the ferromagnetic screen is:

- 0.5-3.6 m for circuits with voltage from 10 to 20 kV, with the possibility of local reduction in installation depth when crossing with underground utilities and when entering buildings up to 0.3 m;

- 0.6-3.6 for circuits with voltage from 24 kV to 35 kV, with the possibility of local reduction of the laying depth when crossing with underground utilities and when entering buildings up to 0.3 m;

- 1.1-3.6 m for circuits with voltage from 110 to 220 kV, with the possibility of local reduction of the laying depth when crossing with underground utilities and when entering buildings up to 0.3 m;

- 0.5-3.3 m for circuits with voltage from 330 to 500 kV.

In this design of the ferromagnetic screen, when laying the cable line, the screen is easy to install and easy to access the cables during repair or maintenance work.

To increase the reliability of the cable line operation, in addition to installing the horizontal section of the ferromagnetic screen, a mechanical protection device is placed in the form of a reinforced concrete slab or a layer of brick, while the height of the backfill between the side sections of the ferromagnetic screen is reduced by the height of the mechanical protection means.

As an option, if necessary, before installing the side and horizontal sections of the ferromagnetic screen, a reinforced concrete tray is installed on the bedding at the bottom of the trench, a predetermined height is added to the bottom of the said concrete concrete bed, the cable cables are laid and filled up to the height of the tray, the tray is covered with a reinforced concrete slab, then the installation of the lateral and horizontal sections of the ferromagnetic screen, ensuring contact of their layers of ferromagnetic material, as mentioned above.

BRIEF DESCRIPTION OF THE DRAWINGS

The invention is illustrated by drawings, representing cable lines with the installation of a ferromagnetic screen, constructed by the claimed method.

Figure 1 - plan for installing a ferromagnetic shield on the couplings of a single-core cable from 10 to 20 kV and installation in section - figa.

Figure 2 - plan for installing a ferromagnetic shield on cable lines from 10 to 20 kV and installation in the context of - figa.

Figure 3 - installation plan of the ferromagnetic shield on the couplings of a single-core cable from 24 to 35 kV and installation in section - figa.

Figure 4 - plan for installing a ferromagnetic shield on cable lines from 24 to 35 kV and installation in section - figa.

Figure 5 - installation plan of the ferromagnetic shield on the couplings 110-220 kV, installation in section - figa, installation in section with the use of reinforced concrete tray - fig.5b.

6 is a plan for installing a ferromagnetic shield on cable lines from 110 to 220 kV and installation in section - figa.

Fig.7 is a plan for installing a ferromagnetic shield on couplings from 330 to 500 kV and installation in section - Fig.7a, 7b, 7c.

Fig. 8 is a plan for installing a ferromagnetic shield on the couplings of a three-core cable from 330 to 500 kV and installation in section - Fig. 8a.

DETAILED DESCRIPTION OF THE INVENTION

In the presented figures 1, 3, 5, 7, installation plans for connecting couplings of a cable line from 10 to 20 kV, respectively, are presented; from 24 to 35 kV; from 110 to 220 kV and from 330 to 500 kV. In the presented figures 2, 4, 6, 8, plans for installing a ferromagnetic screen on cable lines, respectively, from 10 to 20 kV; from 24 to 35 kV; from 110 to 220 kV and from 330 to 500 kV. Plant plans are provided with cross-sectional figures (1a-8a).

On the plans in the context, it is clearly seen that depending on the voltage class the conditions for laying the cable change.

When laying a cable line into the ground (Figs. 2, 4, 6 and 8), trench 1 is developed along the entire route, depending on the depth of the cable deepening corresponding to the cable voltage class. A bed 2 is applied to the bottom of the trench, the height h _{1 of} which is usually not less than 0.1 m. The bedding material may be sand or other suitable bedding material. Cables 3 are laid on the backfill 2 using appropriate technical means. Laying of cables 3 is carried out with a depth of h ₂ , providing their optimal throughput and sufficient cooling conditions. Depending on the cable voltage class, the depth to the top of the cables is 0.7-4.0 m, for cables with a voltage of 10 to 20 kV, 1.0-4.0 m for cables with a voltage of 24 kV to 35 kV, 1 , 5 m - 4.0 m - for cables with voltage from 110 kV to 220 kV and 1.5 m - 4.0 m for cables with voltage from 330 to 500 kV. In this case, for cables with voltage up to 220 kV, it is allowed to locally reduce the laying depth at the intersection with underground utilities and when entering buildings up to 0.5 m, and for cables of 330-500 kV to 1.0, subject to the development of special specifications. After that, a ferromagnetic shield is installed in separate sections along the cables along the route, where zones of elevated levels of the magnetic component of the electromagnetic field (hereinafter referred to as the magnetic field) of industrial frequency occur during the passage of electric current through the cable arise above the earth's surface. Such sections along the cables are determined by calculation or on the basis of measurements of the level of magnetic field strength.

The ferromagnetic screen is made up of two side sections 4 and a horizontal section 5, which, in turn, are made with a layer of ferromagnetic material and are installed immediately after laying the cables. The implementation of the ferromagnetic screen in this design provides its simple installation and dismantling. The side sections 4 are installed vertically on the sides of the cable 3 of the circuit, after which the primary filling of the cables is carried out, for example, they are covered with sand or sand and gravel 7 to the installation level of the horizontal section 5. Depending on the voltage class of the cables, the installation depth of the horizontal section of the ferromagnetic screen is 0.5-3.6 m for circuits with voltage from 10 to 20 kV, 0.6-3.6 for circuits with voltage from 24 kV to 35 kV, 1.1-3.6 m for circuits with voltage from 110 to 220 kV , 0.5-3.3 m for circuits with voltage from 330 to 500 kV. At the same time, for cables with voltage up to 220 kV, it is allowed to locally reduce the laying depth when crossing with underground utilities and when entering buildings up to 0.3 m. To ensure the possibility of cable transfer without damaging the screen, the side sections are installed with an interval in the light between each side section and cable not less than 0.2 m. The horizontal section 5 is installed on the side sections 4, so as to ensure contact of the layer of ferromagnetic material with layers of ferromagnetic material of the side sections with the formation of P- shaped design. If required, signal and signal protective tapes and markers (not shown) are installed.

After installing the ferromagnetic screen carry out the final filling of the trench with soil 8.

To provide additional mechanical protection after installing the side sections 4 of the ferromagnetic screen, primary filling of the cables is carried out, for example, with a sand-gravel mixture 7 to a height that is lower than the level of installation of the horizontal section 5 of the ferromagnetic screen to the thickness (height) of the used mechanical protection means. Means of mechanical protection can be made in the form of a layer of brick 6 or reinforced concrete slab 9.

When laying in one trench several chains of the cable line, as shown in figure 2, 4, 6 and 8, after driving the trench and applying backfill 2, the laying of the cable chains is carried out at a distance d ₂ in the light between the chains, taking into account their mutual thermal influence and the possibility damage by an arc. The value of d _{2 is} determined by calculation and is at least 500 mm.

On Fig shows a cross-section in the cable section of the laid double-chain cable line, where the means of mechanical protection is made of reinforced concrete slabs. Each circuit is presented in the form of three single-phase cables laid by a triangle. The chains are stacked on bedding 2 at a distance of d ₂ in the light according to the voltage class, which is determined by the methods of thermal calculation.

On the sides of the cables of each circuit on the backfill 2, lateral vertically placed reinforced concrete slabs 9 are installed at a distance of at least 0.2 m and the primary backfill of the cables is carried out with sand and gravel mixture 7 to the level of horizontal reinforced concrete slabs 9. Horizontal reinforced concrete slabs 9 are installed and outside formed protective structures establish sections 4 and 5 of the ferromagnetic screen, as described above, and then make the final filling of the trench with soil 8.

The installation of a ferromagnetic screen on the couplings is carried out according to the same scheme as described above.

If, under the conditions for laying a multi-chain cable line, it is necessary to place the couplings in the cable chamber, then in the process of laying the cables, cable chambers are installed along the cable line along with the installation of a ferromagnetic shield in the chamber in the area of the section of the couplings.

Figure 1, 3, 5, 7 shows the sections of the couplings that connect the cables along the route.

On figa and 3a shows a cross section of a cable line with additional mechanical protection in the form of a layer of brick 6 or reinforced concrete slab 9.

Due to the installation of a ferromagnetic shield in the area of the couplings 10, the depth of h ₂ for its voltage class remains the same as in the cable sections 3 along the route between the connection sections.

Mechanical protection is usually carried out in the form of a reinforced concrete slab or a layer of bricks.

Figure 1 shows a cross section on a cable section of a laid cable line, where the mechanical protection means is made in the form of a protective layer of bricks 6.

It is preferable to install ferromagnetic shield sections on top of mechanical protection means (brick or reinforced concrete slabs), in which case installation work is carried out to install the ferromagnetic shield without disconnecting the cable line.

Alternatively, one mechanical protection can be installed on a group of cable line circuits. Fig. 5c shows a cross-section of a cable line in a section of couplings of a double-chain cable line. A reinforced concrete tray 12 is installed on the sand bed 2, on the bottom of which a sand bed 2 of the required height is applied, and the cables of the chains with couplers 10 are laid. Then the cable section is initially filled with sand and gravel mixture 7 to the height of the side wall of the tray and the tray is closed with a reinforced concrete slab 9. After installing the reinforced concrete slab 9, side sections 4 and a horizontal section 5 of the ferromagnetic screen are installed outside the formed protective structure, as described above, and then produced final filling with soil 8.

The installation of a ferromagnetic screen when laying cable lines of various voltage classes increases the efficiency of cable lines laid in the ground, especially in conditions of dense urban areas. As a result, minimization of the depth of the cables is ensured, which is essential for ultra-high voltage class cables, as it leads to a decrease in the volume of earthwork and costs when laying power cable lines, as well as to simplification of monitoring and maintenance.

Reinforced concrete slabs are placed at the installation site of couplings up to 220 kV, the couplings are located directly on the plates, the connection point is protected from above and from the sides by reinforced concrete slabs, sand or gravel and sand are filled with soil. In certain places of the route, it becomes necessary to install additional equipment at the couplings, for example, boxes for the transposition of a copper screen built into the cable or measuring instruments. To install this equipment, a standard reinforced concrete communication well is installed next to the coupler. The copper shield of the 110-220 kV cable is removed from the coupling with a special cable and brought to the equipment in the well.

The method is further illustrated by laying a cable line of 500 kV in a trench using a cable chamber, which is being constructed in a cable pit.

In the places of installation of couplings 330-500 kV (Fig. 7) reinforced concrete chambers of 10.2 m in length and 7.6 m in width are being constructed.

From the prior art

[http://www.prorktant.org/index.php?topic=11556.msg53717#msg53717] [5] well-known transposition wells, which are reinforced concrete boxes placed underground. You can get into the transposition well through the hatch in its roof. The transposition box is mounted on a metal structure. In such a well, 2 transposition boxes can be placed. A known project for a serviced cable chamber for accommodating 110 kV couplings, in which a cable chamber with transposition boxes installed therein, is proposed.

A disadvantage of the known device is that it is applicable only to low voltage lines.

In accordance with the invention, there is provided a cable chamber shown in FIG. 7, which comprises a housing with at least one section, for example, two sections,

branch pipes for cable entry made in the end walls of the housing, supporting structures for couplings inside the housing,

the cable compartment overlap plate, wherein the housing is additionally provided with at least one cable screen transposition well located on the outside of the housing end wall and communicating with the cable compartment through the cable transposition channel, and the camera is additionally provided with a ferromagnetic screen, and the supporting structures are installed on the bottom of the case.

The technical result, which allows to obtain a cable chamber, is to increase the reliability and throughput of cable lines by increasing their load, since the proposed cameras make it possible to lay cable lines of high voltage class, up to 500 kV.

The presented chamber is divided by a partition along with the formation of two sections for installing the couplings of one and the second circuit separately. The internal overall dimensions of the sections are 9.7 m by 3.4 m. In the end walls of the chamber, nozzles 13 are provided for entering 330-500 kV cables and pipes for fiber optic communication lines into the chamber. Pipes for fiber-optic communication lines pass through the camera.

In the middle of the end side of the chamber, that is, between two chains of cable lines 330-500 kV, wells are attached to the chamber to accommodate equipment 14 with an internal overall size of 2.45 m by 1.3 m.

The equipment in the wells is intended for the transposition of the built-in copper shields of 500 kV cables, for measuring partial discharges in the couplings, for measuring the current in the built-in copper shields.

To access the wells 14 from the outside, hatches 15 from the surface are provided. In the wall between the equipment wells and the chamber of the couplings, nozzles 16 are provided for the passage of transposition cables.

The basis for the chamber of couplings and wells for equipment is a reinforced concrete slab measuring 16.2 m long by 7.6 m wide. The chamber and wells are made of monolithic reinforced concrete, and represent a single design. The height of the chamber is 1.55 m. The height of the wells for equipment is 2 m. The optimal depth of the base plate of the chamber is 2.5 m, however, it can vary depending on the depth at which 330-500 kV cable is suitable for the connection sleeve in this section of the route.

330-500 kV couplings are installed in the chamber in a horizontal plane on metal structures that support the coupling at the same level as the 330-500 kV cable fits the chamber, providing a straight section on the way and facilitating the installation of couplings. Couplings in adjacent phases are staggered. Between the adjacent phases of the cable 330-500 kV and, accordingly, the couplings, an interval of 0.8 m along the axes is maintained. A distance of 1.2 m is maintained between the extreme phase cable and the central partition of the chamber. The minimum distances between cables and couplings in the chamber are necessary to provide access to the couplings during their installation.

After the installation of 330-500 kV couplings is completed, the chamber is filled up with a sand-gravel mixture, covered with reinforced concrete slab 17 from above and filled up with soil to the level of the earth's surface. Thus, the chamber with couplings is maintenance free. Access to the couplings is carried out only if it is necessary to replace or dismantle them by removing the reinforced concrete slab.

Access to the wells for measurements or changes in the transposition scheme is provided at any time through hatches 15 from the surface. To ensure the safety of equipment wells, double hatches are installed on them. A lock and an alarm system are installed on the inner hatch.

Before entering the chamber, cables of 330-500 kV on both sides of the chamber are laid with a “snake” to compensate for possible movement of soil along the cable line, as well as to provide a margin of cable length for cutting in case of the need for re-installation of couplings.

The reinforced concrete chamber provides reliable protection of 500 kV couplings from mechanical damage during operation in the conditions of laying a 500 kV line without the need for a collector.

After installing the reinforced concrete slab 17, the side and vertical sections of the ferromagnetic screen are mounted. The side sections 4 are installed vertically on the sides of the chamber, after which the primary filling of the chamber is carried out to the installation level of the horizontal section 5. The horizontal section 5 is mounted on the side sections 4, so as to ensure that the layer of ferromagnetic material contacts the layers of ferromagnetic material of the side sections to form U-shaped design. After this, the final filling of the pit is made.

Due to the installation of a ferromagnetic shield in the area of the couplings, the depth of h ₂ remains the same as in the sections of cables 3 along the route between the sections of the connection.

It is preferable to install ferromagnetic shield sections on top of mechanical protection means (brick or reinforced concrete slabs), in which case installation work is carried out to install the ferromagnetic shield without disconnecting the cable line.

Claims (8)

1. The method of laying a cable line with the provision of ferromagnetic shielding, in which
carry out the development of the trench for at least the cables of one circuit of the cable line,
add to the bottom of the trench,
stack at least one cable line circuit,
primary filling of cables
install a ferromagnetic shield along the circuit cables,
make the final filling of the trench,
characterized in that
determine the location of local maxima of the magnetic field;
install a ferromagnetic shield in places of local maximums of the magnetic field of the cable line with a voltage of 10 to 500 kV, while along the entire route of the cable line, the permissible laying depth to the top of the cables is:
- 0.7-4.0 m for circuits with voltage from 10 to 20 kV, with the possibility of local reduction of the laying depth when crossing with underground utilities and when entering buildings up to 0.5 m;
- 1.0-4.0 m for circuits with voltage from 24 kV to 35 kV, with the possibility of local reduction of the laying depth when crossing with underground utilities and when entering buildings up to 0.5 m;
- 1.5-4.0 m for circuits with voltage from 110 to 220 kV, with the possibility of local reduction of the laying depth when crossing with underground utilities and when entering buildings up to 0.5 m;
- 1.5-4.0 m for circuits with voltage from 330 to 500 kV, with the possibility of local reduction of the laying depth when crossing with underground utilities and when entering buildings up to 1.0 m. 2. The method according to p. 1, in which the ferromagnetic shield is installed in the places where local maxima of the magnetic field appear, exceeding the permissible values, while the maxima appear in the places where the couplings are installed along the cable lines, in places where single-phase triangular cables are laid out in plane, including at the intersection with underground utilities and with a decrease in the laying depth at the intersection with underground utilities. 3. The method according to p. 2, in which the connecting cable line voltage of 330-500 kV is placed in a cable chamber. 4. The method according to p. 1, in which the development of a trench for cables of at least two circuits is carried out, which are laid on a bed with a distance in the light between the chains depending on the mutual thermal influence and the possibility of arc damage. 5. The method according to p. 1, in which the ferromagnetic screen is formed of side and horizontal sections containing a layer of ferromagnetic material, and before backfilling the circuitry, the side sections of the screen are installed with an interval in the light between each side section and the cable of at least 0.2 m and fill the cables to the installation level of the horizontal section of the screen, set the horizontal section of the ferromagnetic screen to ensure contact of the layers of ferromagnetic material of the horizontal section and the side sections, while
the installation depth of the horizontal section of the ferromagnetic screen is:
- 0.5-3.6 m for circuits with voltage from 10 to 20 kV, with the possibility of local reduction in installation depth when crossing with underground utilities and when entering buildings up to 0.3 m;
- 0.6-3.6 m for circuits with voltage from 24 kV to 35 kV, with the possibility of local reduction of the laying depth when crossing with underground utilities and when entering buildings up to 0.3 m;
- 1.1-3.6 m for circuits with voltage from 110 to 220 kV, with the possibility of local reduction of the laying depth when crossing with underground utilities and when entering buildings up to 0.3 m;
- 0.5-3.3 m for circuits with voltage from 330 to 500 kV. 6. The method according to claim 5, in which, before installing the horizontal section of the ferromagnetic screen, a mechanical protection means is placed in the form of a reinforced concrete slab or a layer of brick, while the height of the backfill between the side sections of the ferromagnetic screen is reduced by the height of the mechanical protection means. 7. The method according to p. 5, in which before installing the side and horizontal sections of the ferromagnetic screen, a reinforced concrete tray is installed on the bedding at the bottom of the trench, a bedding of a predetermined height is applied to the bottom of the said reinforced concrete tray, the cable cables are laid and filled up to the height of the tray, the reinforced concrete tray is closed stove. 8. A cable chamber for accommodating a cable line connector of 330-500 kV voltage, comprising a housing with at least one section,
branch pipes for cable entry made in the end walls of the housing, supporting structures for couplings inside the housing,
a cable compartment overlapping plate, characterized in that the housing is additionally provided with at least one transposition well of cable shields placed on the outside of the end wall of the housing and communicating with the cable compartment through the channel for cable transposition, while the camera is additionally equipped with a ferromagnetic screen, and supporting structures mounted on the bottom of the housing.

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