RU233071U1 - HERMETIC CABLE PENETRATION FOR THE SHELL OF A NUCLEAR POWER PLANT - Google Patents

Abstract

The utility model relates to passing electrical communications through the walls of power units of nuclear power plants. The technical result is the creation of a cable penetration that has increased versatility due to the possibility of using the same lead biological protection elements for any number of electrical conductors in the penetration module. For this purpose, the cable penetration comprises a metal cylindrical body with intra-body biological protection elements that are made in the form of two identical extruded lead screens in the form of chord-truncated cylinders, the cross-sectional area of each of which is greater than half the cross-sectional area of the module, wherein the said truncated cylinders are installed in series in the middle part of the module with their cylindrical surface adjacent to the inner surface of the tubular body of the module and with a shift in the axial direction with the formation of a gap between them, the value of which is not less than two permissible bending radii of electrical conductors, wherein the truncated cylinders are located relative to the longitudinal axis of the module so that they block the cross-section of the tubular body of the module from the free passage of radioactive radiation and/or radioactive particles. 4 pts. f-ly, 2 ill.

Description

The utility model relates to the field of equipment used for the hermetically sealed passage of electrical communications into a zone with ionizing radiation separated by a hermetically sealed wall, for example, for the passage of high-voltage and low-voltage electrical power circuits, low-voltage control circuits through concrete walls with metal cladding of the hermetic shell of power units of nuclear power plants.

As an element of the support system, the penetration must ensure the conduction of the appropriate power supply and the output of control electrical signals, while the penetration must perform safety functions to prevent or limit the spread of radioactive substances released during accidents beyond the boundaries of the accident localization zone, and must also limit the release of ionizing radiation beyond the boundaries of the accident localization zone (biological protection).

The prior art discloses a device for hermetically sealed passage of electrical communications into a zone with ionizing radiation separated by a hermetically sealed wall, which contains a cylindrical body with conductors (cables) hermetically secured at its ends, protective casings and biological protection elements made in the form of thickened bottoms of casings with channels through which the passage cables are released to the outside (RU 2249892 C2, H02G 3/22, 10.04.2005).

The disadvantages of this device are the lack of control over the tightness of the passage and an insufficient degree of protection from ionizing radiation.

Also known is a penetration adopted as the closest analogue (RU 2579155 C1, H02G 3/22, 10.04.2016), used in the method of transmitting electric energy by means of cables, wires, bundles of various designs in sealed systems, including for the hermetic entry of electrical conductors through a protective shell in nuclear power plants. The description of the said method discloses the implementation of a penetration (hermetic entry) in the form of a hollow metal housing with flanges with openings fixed to its ends, while inside the housing there are radiation protection elements with channels made of electrical insulating tubes according to the number of electrical conductors, and insulating feed-through modules protruding from the outside and from the inside of the flange are fixed in the flange openings, and in the internal free space of the housing around the conductors there are bioprotection elements, in particular in the form of lead disks. The penetration is equipped with a unit for monitoring the tightness of the entry during operation.

This technical solution generally eliminates the disadvantages of the above-mentioned known device for the hermetic passage of electrical communications, but there are other disadvantages associated with the fact that lead elements for the intra-modular biological protection screen are difficult to mechanically process in precise dimensions due to the plasticity and viscosity of lead, therefore, it is difficult to manufacture elements according to the size of the modules and the electrical conductors passing inside, for example, due to the need to drill precise holes in the elements for them.

The technical problem that the utility model is aimed at solving is the creation of a cable penetration for the hermetic passage of electrical communications into an area with ionizing radiation, which allows for reliable protection from radiation and has a more universal design, while achieving a reduction in the labor intensity of its manufacture.

The technical result, the achievement of which is ensured by the proposed utility model, is the creation of a cable penetration that has increased versatility due to the possibility of using the same lead elements of biological protection for any number of electrical conductors in the penetration module, while simultaneously reducing the labor intensity of its manufacture.

The specified technical result is achieved in that in a hermetic cable penetration for a nuclear power plant shell containing a metal cylindrical body with intra-body biological protection elements, a leakage control device and end flanges, penetration modules located inside the said cylindrical body, each of which consists of a tubular module body in which electrical conductors are located, sealed using seals, and intra-modular biological protection elements fixed in the module, wherein the said cylindrical body is designed with the possibility of hermetically welding to the metal lining of the said shell, and the end flanges have sealed passages for the said modules, the intra-modular biological protection elements are made in the form of two identical extruded lead screens in the form of cylinders truncated along a chord, the cross-sectional area of each of which is greater than half the cross-sectional area of the module, wherein the said truncated cylinders are installed in series in the middle part of the module with their cylindrical surface adjacent to the inner surface of the tubular body module and with a shift in the axial direction with the formation of a gap between them, the size of which is not less than two permissible bending radii of electrical conductors, and the truncated cylinders are located relative to the longitudinal axis of the module so that they block the cross-section of the tubular body of the module from the free passage of radioactive radiation and/or radioactive particles.

Moreover, the mentioned truncated cylinders can be fixed in the module body by means of external compression of the module body with a radial press in the area of their installation.

Moreover, the module seals can be made of heat-resistant and radiation-resistant polymer material, in particular, polyetheretherketone or polysulfone.

The utility model is illustrated by figures showing:

Fig. 1 - general view of the passage in section,

Fig. 2 - intra-modular biological protection element in the form of a lead screen.

The penetration contains a metal cylindrical body 1 with internal body elements 2 of biological protection, which are made in the form of a set of lead and polymer plates, with openings for the passage of tubular bodies of penetration modules 5, located inside the cylindrical body 1. The lead plates are intended for protection against gamma and X-ray radiation, the polymer plates - for protection against neutrons.

The housing 1 is also provided with a leak-tightness control device 3 and end flanges 4. Each of the penetration modules 5 has a tubular housing in which electrical conductors 7 are located, sealed with seals 6, and intra-modular biological protection elements 8, fixed in the module.

Elements 8 are made in the form of two identical extruded lead screens in the form of chord-truncated cylinders, the cross-sectional area of each of which is greater than half the cross-sectional area of module 5, wherein said truncated cylinders are installed sequentially in the middle part of module 5 with their cylindrical surface adjacent to the inner surface of the tubular body of module 5 and with a shift in the axial direction with the formation of a gap between them, the value of which is not less than two permissible bending radii of electrical conductors 7. At the same time, the truncated cylinders are located relative to the longitudinal axis of module 5 so that they block the cross-section of the tubular body of module 5 from the free passage of radioactive radiation and/or radioactive particles.

The cylindrical body 1 is designed with the possibility of hermetically welding to the metal lining 10 of the shell 9 of the nuclear power plant, and the end flanges 4 have sealed passages for modules 5.

The intra-modular elements 8 of biological protection in the form of truncated cylinders can be fixed in the housing of the module 5 by means of external compression of this housing with a radial press in the area of their installation.

The seals of the 6th module can be made of a heat-resistant and radiation-resistant polymer material, for example, polyetheretherketone or polysulfone.

To confirm the preservation of the tightness, the body 1 of the passage is under excess gas pressure (for example, nitrogen 2.5 atm), which is controlled using the tightness control device 3, for example, in the form of a pressure gauge in the indicator status.

The use of the utility model allows to simplify the design of the penetration and the process of its manufacture, including lead elements of biological protection, which can be manufactured by extrusion and obtain a profiled screen of any length. In this case, no mechanical processing of these elements is required. In addition, due to the possibility of using the same elements of biological protection for any number of electrical conductors in the penetration module, the versatility of the penetration design increases. At the same time, due to the production of lead screens in the form of cylinders truncated along the chord, installed with the overlap of the cross-section of the tubular body of the module, the penetration also ensures high reliability of protection from radioactive radiation.

Claims (5)

1. A hermetic cable penetration for a nuclear power plant enclosure, comprising a metal cylindrical body with intra-body biological protection elements, a leak test device and end flanges, penetration modules located inside said cylindrical body, each of which consists of a tubular module body in which electrical conductors are located, sealed using seals, and intra-module biological protection elements fixed in the module, wherein said cylindrical body is designed with the possibility of hermetically welding to the metal lining of said enclosure, and the end flanges have sealed passages for said modules, characterized in that the intra-module biological protection elements are made in the form of two identical extruded lead screens in the form of chord-truncated cylinders, the cross-sectional area of each of which is greater than half the cross-sectional area of the module, wherein said truncated cylinders are installed in series in the middle part of the module with their cylindrical surface adjacent to the inner surface of the tubular module housings and with a shift in the axial direction with the formation of a gap between them, the size of which is not less than two permissible bending radii of electrical conductors, and the truncated cylinders are located relative to the longitudinal axis of the module so that they block the cross-section of the tubular housing of the module from the free passage of radioactive radiation and/or radioactive particles. 2. A passage according to item 1, characterized in that the said truncated cylinders are fixed in the module body by means of external compression of the module body with a radial press in the area of their installation. 3. A penetration according to item 1 or 2, characterized in that the module seals are made of a heat-resistant and radiation-resistant polymer material. 4. A passage according to item 3, characterized in that the seals are made of polyetheretherketone. 5. A passage according to item 3, characterized in that the seals are made of polysulfone.