RU2572824C2 - Modular sealed entry of electric conductors through protective shell - Google Patents

Abstract

FIELD: electricity.

SUBSTANCE: invention relates to the area of electric engineering and electrical power engineering, and more specifically to design of sealed entries; it may be used in different technical and process electrical installations and machines, for example at nuclear power plants. Modular sealed multilinear entry comprises a set of hollow metal sections A joined by two sections into a module by a metal tube with one or two terminated cables passing through it inside the module section with sealed current feedthroughs passing through bushing insulators reinforced with a common cartridge clamp and an opening for remote check-up of inner volume hermeticity and further passage of current feedthroughs covered by a thermally shrinkable tube, from module cartridges inside side conduits, which pass hermetically through intermediate bushes inside openings of entry flanges coupled in a sealed way with a covering tube filled with an element of biological shielding and protective housings, inside which from the side of "clean area" there are unions for remote hermeticity control in each modular entries.

EFFECT: invention allows increase in reliability and expanded functionalities.

6 cl, 6 dwg

Description

The invention relates to electric power devices and can be used to transfer electrical energy through cables, wires, bundles of various designs in sealed systems with fire resistance, seismic resistance and radiation protection, for example, in nuclear power plants, chemical reactors, test benches and other similar objects and construction facilities.

A device is known for passing electric conductors (the invention according to the application 2656406 / 24-07, class H01B 17/26) into the sealed area of nuclear power plants, containing an insulating multichannel element located in the embedded pipe coaxially with electrical conductors, bushing insulators mounted on flanges on both sides embedded pipe.

The disadvantage of this device is the element-wise assembly in a protective shell, the lack of constant tightness control, the possibility of moisture entering the device and at the same time there is a decrease in electrical parameters, the complexity of installation and dismantling.

The closest in technical essence to the device claimed in this application is the sealed entry of electrical conductors through a protective sheath (RU 2322717 C1).

The sealed entry according to this patent contains a metal case, inside of which ceramic tubes with conductors with a flexible insert passing inside them are reinforced in a cement mixture, bushing insulators, hermetically connected to flanges welded hermetically at the ends of the case, and hermetic housings.

Some improvements in the electromechanical characteristics of the pressure seal are achieved by:

- filling under excessive pressure of the internal free space of the housing with dry nitrogen, SF6 gas and their mixture;

- the inner space of the housing around the conductors is filled with powder of ceramic insulating material;

- application of insulation from high-temperature organics to ceramic conductors from current-carrying conductors inside a pressure lead or ceramic core insulation is used;

- development (broadening) of the ends of bushing insulators inside the pressure seal.

The disadvantages of the closest analogue is the following:

- the internal volume of the metal housing of the sealed input is not used effectively when passing electrical conductors;

- the use of a cement-sand mixture as a reinforcing element of ceramic tubes and as radiation protection inside the sealed volume of bushings reduces the electrical insulation properties of ceramic bushings during operation and reduces the reliability of bushings in general;

- violation of the integrity of their own factory insulation of conductors of electrical conductors during installation also reduces the electrical characteristics of the inputs.

Thus, the aim of the claimed invention is to increase reliability and increase the functionality of sealed bushings (hermetic leads).

The claimed invention allows to sharply increase the number of conducted electrical conductors in the blocks of sealed inputs. The use of a block constructive solution of inputs allows for the autonomous use of each of the blocks, equipped with an individual leak tightness control system, in the event of a malfunction in one of the blocks, it becomes possible to switch electrical conductors from the faulty block to the backup block while maintaining the operability of the entire block tight input as a whole. The invention allows to increase the reliability of the pressure glands, to increase their radiation (biological) protection and fire resistance, to increase the electrical and mechanical strength due to the fact that the electrical conductors inside the blocks along the entire length of the pressure gland do not have gaps or violations of their own factory electrical insulation of the conductors.

In addition, in the claimed device, it becomes possible to significantly increase the number of electrical conductors without increasing the overall dimensions of existing structures, devices for passing electrical circuits into sealed rooms or volumes with normal atmospheric pressure.

The indicated technical results are achieved in that a sealed block input of electrical conductors through a protective sheath containing a set of hollow metal tubular sections combined in two sections into a block by means of an internal central metal pipe (central pipeline) with one or more cables passing inside it can be technically implemented that have undergone installation cutting inside sections of the unit with hermetic transmission of electrical conductors in their own insulation of cores through bushings tori, reinforced with the common clip of the section of the block in the form of a circle or rectangle, mounted perpendicularly, parallel to or at any angle of the axis of the input block, respectively, with an opening for remote checking the tightness of the intra-block volume with the subsequent passage of electrical conductors and a tightness test tube covered by a heat-shrinkable tube from the section blocks inside the side pipelines, which through the intermediate sleeves hermetically pass inside the holes of the input flanges, hermetically connected to intercepts a metal input tube filled with biological protection element and protective casings within which the part of the "pure zone" fittings are remote leakage control in each of the sealed entry blocks.

Sections are the main structural elements of the block and are formed during assembly work with mechanical connection (welding) of the holder of the block with the central and side pipelines of the block. When connecting the clips of the block with the central pipeline, a sealed volume of the block is formed, the tightness of which is monitored during operation.

Depending on the purpose determined by passing control power conductors through the pressure seal, the clips of the blocks may have a circle, a rectangle, and another shape in cross section.

Depending on the tasks set, the clips of blocks can be composite, i.e. in the constructive solution, they may simultaneously include ferrule elements having a cross section from the above series.

The orientation of the clip in the input design can be varied:

- perpendicular to the axis of entry,

- parallel to the input axis,

- at an arbitrary angle to the input axis.

All fire hazardous areas of the input sealing are located inside the containment during operation, and the annular gap between the pipeline and the cable bundle located in it at the outlet of the input flange is sealed to the calculated length by the cold hardening sealant.

Further, the claimed invention is illustrated by drawings, in which:

In FIG. 1 shows a General view of the block hermetic input of electrical conductors (BGVEP) through a protective sheath.

In FIG. 2 shows the design of a typical block and the layout of blocks inside a sealed block input.

In FIG. 3 shows the design of a separate type unit.

In FIG. 4 is a view AA of FIG. one.

In FIG. 5 shows the design of a separate input unit BGVEP with a mounting pad for insulators located parallel to the axis of the input.

In FIG. 6 shows the construction of a two-unit sealed input BGVEP with a mounting pad for insulators located parallel to the axis of the input (option 2).

The main specification of the elements of the block tight input contains the following elements:

1 - embedded pipe input,

2 - metal input housing,

3 - input casing,

4 - fitting for tightness control of a separate input unit,

5 - input flange,

6 - mounting ring input

7 - biological protection (lead) of a separate input unit,

8 - biological protection (cement),

9 - electrical conductors in the block section,

10 - clip block

11 - bushing block insulator,

12 - fastening of the input casing,

13 - sections of input blocks,

14 - the place of connection of the input conductors with consumer cables in the casings,

15 - the intermediate sleeve of the hermetic fastening of pipelines with electrical wiring to the input flange,

16 - pieces of metal pipes, inside of which a factory-made cable passes (central pipeline),

17 - sections of metal pipes, inside which the conductors pass after passing and sealing in bushing insulators, hermetically fixed in the clips of the blocks (side pipelines),

18 - place of sealing of electrical conductors with a cap of the bushing,

19 - the place of fastening of the fittings for injection of cement-sand mortar into the internal volume of the input (sprues),

20 - air gap

21 - air vents when pouring the internal volume of the input cement-sand mixture.

Block hermetic input of electrical conductors through a protective sheath (Fig. 1) contains, for example, a package of 6 metal blocks (Fig. 2), connected coaxially and rotated among themselves in a certain sequence and enclosed inside a pipe (2)) with a reinforcing element biological protection (8).

The design of a separate input unit No. 1 is shown in FIG. 2. The block consists of two sections, inside of which are placed the clips (10) with bushing insulators (11) with the electrical conductors hermetically passing inside them (9) in the primary factory insulation of the cores.

The internal volumes of the input sections are hermetically connected to each other by a central pipeline (a piece of metal pipe, inside which a factory-made cable passes (16)) with one or more cables located inside, with their mounting cuts at the section inlet, electrical conductors (9) after sealing on the bushing insulators reinforced with a clip (10) of the block are located in the lateral pipelines (17) hermetically connected to the section of the block.

In the lateral pipeline (17) from the clean zone side, together with the electrical conductors, there is a tightness test tube in the unit sections.

In FIG. Figure 3 shows the design of a separate typical block, where the section consists of two symmetric parts (half sections), combined into a single unit during assembly work.

The input assembly is carried out in the following sequence.

The central pipeline (16) is hermetically connected to the half sections of the input unit No. 1, while inside the central pipeline (16) a cable or more has already passed through, the ends of which are installed at the entrance to the half sections, before insulation of the conductors. The ends of the electrical conductors are passed through bushing insulators (11) of the cage (10) of the block. The clips come closer to contact with half sections of the central pipeline on both sides of the block and the joint is sealed by laser welding along the contact line.

At the outlet of the bushing insulators (11), the conductors in the sealing place are freed from insulation and hermetically connected by soldering, laser welding with the cap of the bushing (11), the other fittings of which are also hermetically connected to the section holder.

After sealing, the sectional conductors emerging from the section chamber are grouped, covered by a heat-shrink tube, and together with the block tightness test tube, are passed further into the side pipeline (17) from the clean zone side. Similarly, installation is carried out on the other side of the unit. Further, biological protection elements (7) are mechanically fixed on the outer end surfaces of the unit sections.

At nuclear facilities with a wide shell wall thickness of 1,500 mm for entering diameters of 194 mm and consisting of 6 blocks, the distance between sections of block No. 1 is approximately 920 mm.

The assembly of subsequent blocks No. 2, 3, 4, 5, 6 is carried out in a similar manner, but the distance between the sections of the blocks (13) changes, and the lengths of the central and side pipelines of the blocks with cables and cable bundles passing inside them change accordingly.

Next, the design and centering of the package of 6 input blocks is carried out, their alignment is checked, the blocks are placed on the basis of one in another, that is, block No. 2 is placed coaxially in block No. 1, block No. 3 is placed coaxially in block No. 2, etc. ., but at the same time, for the input of 6 blocks, the angle between the pipelines with the cables of the neighboring blocks will be 60 ° (Fig. 4), then the formed package of blocks is mechanically fixed using the laser spot welding method.

Entrance flanges are installed on the protruding ends of the side pipelines and through the intermediate bushings (15) a tight connection of the flanges to the side pipelines (17) of the cables is carried out.

Then, a metal pipe (metal input case (2)) of the input case is installed on a centered package of 6 blocks and a tight connection is made by laser welding of the body (2) with the input flange (5) on both sides of the input.

Through the sprues (19) using the air outlet in the metal housing (2) of the inlet, fine-dispersed cement mortar or cold hardening sealant is injected into the inner annular volume of the inlet until it is completely filled, followed by sealing of the technological holes in the inlet body.

On sections of pipelines protruding from the input flanges on both sides of the input, the annular gap is sealed between the intermediate sleeve (15) and the pipe and cable by injection of a non-combustible cold hardening sealant to a certain depth.

After that, on the mounts (12), sealed input covers are installed on both sides and the input assembly is completed.

In FIG. Figure 5 shows the construction of a separate BGVEP unit with a mounting pad (clip (10)) of a rectangular shape for insulators, insulator modules, parallel to the input axis.

In FIG. Figure 6 shows the construction of a two-unit sealed inlet of БГВЭП with a mounting pad (clip (10)) of a rectangular shape for insulators, insulation modules, also parallel to the axis of the input.

The main advantages of the newly developed block hermetic input of electrical conductors through a protective sheath (claimed invention):

- A block version of a sealed electric power device has been developed, which allows to fully utilize its internal sealed volume for the passage of electrical conductors. In known sealed bushings, the possibility of carrying out the maximum number of electrical conductors in a structure is limited by the diameter of the input flange and its useful mounting area. So, for bushings with a diameter of flanges of 194 cm, the maximum number of conductive control cable conductors is 144 units, while the useful mounting area of the flange is about 200 cm ² ;

- in the developed inputs, containing for example 6 blocks, the mounting area of the casing of the blocks is 600 cm ² , while the casing of the block in section is a circle and is structurally installed in the block perpendicular to the axial line of the sealed input. When used in the form of rectangular-section block holder and constructively installed in parallel to the sealed unit input axis Useful block mounting surface sealingly input increases up to 900 cm ^2. The excess in assembly areas is 4.5 times, which allows technologically ensuring the passage of about 700 electrical conductors in newly developed bushings. There is the possibility of planning and creating backup blocks in the inputs;

- tightness control is provided in each sealed input unit. In case of loss of tightness, violation of electrical insulation, breakage of the conductor in any sealed input unit, this unit is muffled, the necessary switches are made to the backup unit and the sealed input remains operational, that is, planned failures of 1, 2 can be allowed in assessing the reliability of the sealed inputs etc. depending on the degree of redundancy of the airtight entry. Currently, with the appearance of such violations of tightness, violations of electrical insulation, etc. for sealed bushings in operation now, it becomes inoperative, labor-intensive and complicated dismantling of the bush and installation of a new pressure seal is required with increased operating costs;

- the constructive solution of the block tight input allows for various purposes to create block inputs with the number of blocks from 1 to 10 or more depending on the thickness of the protective sheath, the type of conductors being passed through, the type of clip used: a block in the form of a mounting surface of a circle or a rectangular shape;

- when the number of blocks is 1-3 units, the design of a block sealed input for transmitting electrical conductors to a voltage class of 0.4-10 kV is technically implemented;

- when the number of blocks is from 1 to 10 or more, using input clips in the form of a circle or a rectangle, the control, control, and alarm circuits pass through the sealed input of electrical conductors, while the number of transmitted electrical conductors in control cable circuits can reach 900 units;

- the exclusion from the internal volume of the hermetic input of the reinforcing cement-sand mixture allows to increase the electromechanical characteristics of the insulating input elements;

- reinforcement with a cement-sand mixture of the outer surfaces of pipelines with cables, blocks, radiation protection elements (lead disks), the internal volume of sealed bushings increases their mechanical strength and seismic resistance;

- sealing with non-combustible sealant of cold hardening of the annular gap at the ends of pipelines with cables emerging from the input flanges increases the fire safety of the products;

- during the construction of new nuclear power units, it becomes possible to reduce the diameter of the embedded elements in the shell of the blocks, as well as the possible reduction by several times the number of embedded elements, thereby dramatically increasing the reliability of the entire NPP unit as a whole;

- the use of block hermetic input of electrical conductors through the protective sheath allows to obtain a significant economic effect at nuclear facilities.

Claims (6)

1. Block hermetic input of electrical conductors through a protective sheath, characterized in that it contains a set of sections of the unit, combined in two sections into a block by means of a central pipeline with cables passing inside it with hermetic transmission of electrical conductors through passage insulators, reinforced with a common clip, installed with a hole for remote control of the tightness of the internal volume followed by the passage of electrical conductors and tubes of the fittings of the control seal In particular, from sections of the block inside the side pipelines that pass through the intermediate sleeves tightly inside the holes of the input flanges, hermetically connected to the enclosing metal input housing filled with a biological protection element, and protective housings, inside of which from the “clean zone” side there are fittings for remote tightness control each of the tight entry blocks. 2. Input according to claim 1, characterized in that the total clip has the shape of a circle. 3. Input according to claim 1, characterized in that the clip has the shape of a rectangle. 4. The input according to claim 1, characterized in that the clip is installed perpendicular to the axis of the input. 5. Input according to claim 1, characterized in that the clip is installed parallel to the axis of the input. 6. The input according to claim 1, characterized in that all fire-hazardous zones of the input sealing are located inside the containment during operation, and the annular gap between the pipeline and the cable inside it, the cable at the outlet of the input flange, is sealed to the calculated length with cold-hardening sealant.

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