RU2022383C1 - Hermetically sealed lead-in - Google Patents

Abstract

FIELD: electrical engineering. SUBSTANCE: used in protective casing is non-detachable shell where supply cables are secured. Shell has removable lids. Multi-side connection of cables, wedge-shaped shell and reduced height of shell provide enlargement of operating capabilities. EFFECT: enlarged operating capabilities. 10 cl, 6 dwg

Description

 The invention relates to the field of electrical engineering and the electric power industry, and in particular to hermetic bushings of electrical conductors into enclosed spaces or volumes, for example, into a protective shell of a nuclear power plant with any type of reactor.

 A cable penetration is known, comprising a metal case with conductors and biological protection installed in it, hermetically flanged flanges hermetically attached to the ends, each of which limits the control cavity, modules for connecting cables located inside the protective covers installed at the two ends of the case. The casing is equipped with front glands for cable entry.

 The disadvantages of the known device: limited functional and operational capabilities, which are explained only by the front location of the glands, lead-in cables, which with the usual (normative) cavity of the location of the penetrations on the wall will lead to inconvenience, and in some cases to the impossibility of repair and maintenance work as with cable from the penetration wall (due to bent cables), and from the opposite wall (due to the dense arrangement of cables); high complexity and cost of installation and repair; due to the limited visibility and the working area for the actions of the hands and the tool with the casing disconnected, but with cables disconnected; increased cable consumption when connecting from the cable penetration wall (length consumption and bends); lack of reliability due to mechanical stresses on cables and modules for sealing cables, as well as on the place of connection of core cables during removal and installation of covers or their end caps; insufficient radiation protection in the event of longitudinal cracks in the flanges of the pressure seal, in particular in the case of a direct lumbar γ-stream; increased length and weight of the casing.

 The closest in purpose and technical essence is a device containing a metal casing, covering insulated conductors and biological protection for parts of length, hermetically connected to the ends of the flange casing, a fitting for tightness control and protective housings connected to the casing.

 The disadvantages of the known device: limited functional and operational capabilities; high complexity and cost of installation and repair; increased cable consumption when connecting the latter from the penetration wall; insufficient reliability due to mechanical stresses on cables, sealing modules, connection points of cable cores during removal and installation of covers or their end caps. When removing the covers, the packing glands tighten the cable and may break the junction. In addition, the casing presses on the cable with its mass; insufficient reliability due to possible poor-quality installation or latent defects after installation or repair work, as visibility and work area are limited for critical operations such as soldering and welding; complexity of construction and installation; increased cable length and weight.

 The purpose of the invention is improving reliability and maintainability, reducing the cost of installation, expanding functionality.

 This goal is achieved by the fact that the protective casing is made of a shell fixed to the gasket and intended for removal only in case of replacement of penetration. Through the front and side surfaces of the sheath, a multilateral supply of cables is carried out, which can be shifted in height. Free from cable entry, the planes of the sheath have openings all over the inner contour of the sheath closed by removable covers. The cables are staggered. The shell is made with biases to the end opposite to its fastening on the gasket. The height of the shell is less than the diameter of the penetration. The shell has a horizontal cross section in the shape of a polygon, oval or circle.

 The execution of the sheath, not intended for removal, through the front and side surfaces of which a multilateral supply of cables is made with their fastening, leads to the possibility of eliminating mechanical stress on the cables and the joints during installation, repair and inspection. At the same time, the multilateral supply of cables with a shift in height provides an increased clearance between the junction points of the conductors and the wires of the input cables, is sealed with an insulating module, which makes it possible to make better electrical contact between the conductors and the wires of the input cable, as well as their insulation and control of the work performed , and, therefore, increases the reliability of electrical contacts in the device. However, an increase in reliability is achieved only with removable covers covering the opening of the shell, because only if there are holes, it is possible to carry out high-quality installation, repair and inspection of the pressure seal.

 The execution of the shell with slopes to the end opposite to its fastening to the gasket also increases reliability due to ease of installation, repair and inspections, as the access and placement area of the tool and the hands of the installer increases.

 The shift of cable glands into the sheath in height with removable covers, as well as the presence of slopes on the sheath, provides good access to the contact points of the cable conductors with the conductor. Reducing the complexity of installation leads to lower costs.

 The product allows you to expand the operational capabilities of the cable gland, as the design allows for multilateral cable feed, which helps to reduce the cable feed density in front of the cable glands, ease of installation and inspection.

 Thus, the presence of a combination of features that distinguish the claimed solution from the prototype and from other known technical solutions allows us to conclude that it meets the criterion of "novelty."

 Improving reliability, reducing cost, improving maintainability, expanding functionality is provided only by a combination of features of the invention and taking into account the comparison of the claimed solution not only with the prototype, but also with other technical solutions in this technical field, we can conclude that the criterion of "significant differences" is met.

 Figure 1 shows a sealed input device, a longitudinal section; in FIG. 2 - section aa in figure 1; figure 3 - pressure seal with protective casings, the shells of which are in the form of a wedge; figure 4 is a view of B in figure 3; figure 5 is a sealed entry with protective covers having a height equal to or less than the diameter of the penetration; figure 6 is a view In figure 5.

 The device comprises a housing 1, made in the form of a metal pipe, sealed on both sides by flanges 2. Inside the housing 1 there is a biological protection element 3, in which insulated conductors (cables) are reinforced 4. At the ends the housing is closed with protective devices designed to protect the sealing units from mechanical and thermal influences and for securing the lead-in cables 5. The protective device consists of a sheath 6 fixed to the penetration and intended for removal only in case of replacement of the penetration and ennoy perimeter in the horizontal section in the form of a circle and two covers 7 connected with the shell in a plane through the sealing gasket 8 threaded connection 9. As a cable 4 with refractory mineral insulated cable and the metal shell can be used with cables KMZH magnesia insulation. Cable segments 4 are passed into the holes of the flanges 2 and are welded to the flanges with their metal sheath. Each end of the cable section 4 is cleaned from insulation and sealed on both sides in the inner space of the protective device using a ceramic-metal module 10, from which the lead of the lead-in cable 11 exits. To control the tightness of the input, there is a fitting 12 connected to the control cavity of the lead-in 13. Input of the lead-in cables is carried out through stuffing box 14, designed for sealing along the entire perimeter of the sheath 6. The cores of the cables of the sinking 4 and the cores of the input cables are reliably and tight about 15 joined by welding, brazing or other method. Heat-insulating material 16 is laid between the walls of the shell 6. Gaskets 8 and gaskets can be made of the same material in the stuffing box 14. One of such materials for thermal insulation of the shell 6 can be kaolin KN-73, which is capable of endothermic reaction at high ambient temperatures . However, during an endothermic reaction, gas is released and pressure increases in the cavity between the walls 16. To prevent rupture of the shell in the inner wall of the mounted safety valve, made in the form of plugs 17, having an external shape in a cone. The plug is installed in the conical hole of the inner wall of the sheath 6. In a horizontal section, the sheath has the shape of a polygon with multilateral mounting of glands 14 for supplying external cables. To increase the gap between adjacent pressure glands and to increase the service area, for convenience of inspection and repair of pressure glands, in particular for access of the tool during repair to places of sealing joints between the metal sheath of cable 4 and flange 2, sheath 6 is made at a height close to the diameter of the body of the penetration, and to the opposite end is made with slopes. Covers 7 are connected through gaskets 8.

 The use of a non-removable sheath in the protective casing, which allows repairing and routine maintenance not to remove the lead-in cables and not to load them with the weight and friction of the sheath itself, can dramatically reduce the complexity of installation and make work safer.

 The presence of removable covers on the shell, a multilateral cable supply, a wedge-shaped shell, as well as a decrease in the height of the shell in combination with a fixed shell allow the use of tools and devices that require space during maintenance work, to carry out better repairs and inspection, which will increase reliability and durability. Maintenance work at altitude will become safer due to greater convenience, visibility, and free space for work.

Claims (10)

 1. A SEALED INPUT, comprising a penetration consisting of a metal casing, covering insulated conductors and biological protection over parts of the length, flanges hermetically connected to the ends of the casing, fittings for tightness control, modules hermetically connecting the ends of the conductors and cores of the input cables and located in the internal space limited by protective covers, through which the cable is supplied and fixed, characterized in that, in order to increase reliability while reducing the cost of mo Tazha and maintenance and improve maintainability, expand the functionality, the protective casing contains a layer of heat-insulating material and is made of a sheath, fixed to the penetration and intended for removal only in the case of replacement of penetration, through the front and side surfaces of the sheath made a multilateral supply of cables that are shifted in height while the cable planes free from cable entry have openings around the entire inner contour of the shell closed by removable covers.  2. Input according to claim 1, characterized in that the cables are staggered.  3. Input according to claims 1 and 2, characterized in that the shell is made with slopes to the end opposite to its fastening to the penetration.  4. Input according to claims 1 and 2, characterized in that the shell has a height smaller than the diameter of the gasket.  5. Input according to claims 1 to 4, characterized in that the shell has a polygon shape in cross section on a horizontal plane.  6. Input on PP. 1 to 4, characterized in that the shell in a horizontally secant plane has an oval shape.  7. Input on PP. 1 to 4, characterized in that the shell in a horizontally secant plane has the shape of a circle.  8. The input according to claim 1, characterized in that the connection of the protective device to the housing is made in the form of several threaded connections tightening the end wall of the shell with the housing flange, a central hole is made in the wall through which the conductors pass.  9. The input according to claims 1 and 8, characterized in that the threaded connections are made inside the protective device, and the end wall of the shell ends with a pipe that covers the flange of the housing.  10. The input according to claim 1, characterized in that as a thermally insulated material used material with the ability to endothermic reaction.

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