RU2077100C1 - Stuffing arrangement for electric lines - Google Patents

Abstract

FIELD: electrical engineering; passing cables through walls of pressurized rooms of nuclear power stations. SUBSTANCE: stuffing arrangement has package with modules hermetically sealed in its ends provided with electrical conductors connected to external circuit components; stuffing arrangement is installed in embedded part of wall or steel containment and sealed at ends of package; wall of the latter under embedded part has hole; package ends are double-walled structures; their internal walls are joined together by means of pipes; provided in external walls coaxially with pipes are holes whose diameter is smaller than inner diameter of pipes accommodating modules provided with sealed plugs of connectors at ends embedded in holes of external walls; one of package ends carries connections running to device checking tightness inside pipes and space between them; cable conductors are connected to detachable contacts of connector sockets. EFFECT: improved reliability, reduced space requirement, facilitated servicing and repairs. 1 dwg

Description

 The invention relates to electrical engineering and can be used to ensure tight passage of cables through walls and overlap of sealed rooms of nuclear power plants (NPPs).

 A device is known for introducing electrical conductors into the contaminated zone of a nuclear reactor through a reinforced concrete wall with metal cladding, comprising a metal housing connected to the wall with insulating elements located inside it, through which electrical conductors and flanges located at the ends of the housing with connecting elements, from the sealed metal side facing, there is a flange made in the form of a disk with curved edges facing the first flange, while the additional flange is rigidly connected to the metal lining (1).

 The disadvantages of this design is the increase in the size of the input due to the installation of an additional flange.

 Also known is a penetration, which is a welded cylindrical body, into the end walls of which pipes are welded, with electrical conductors placed in them, forming modules and sealed by soldering through ceramic insulators (2).

 The disadvantage of this design is, firstly, the use of soldering copper wires with a shell of a pressure isolator, in which an electrochemical pair is formed, which is destroyed by current, during soldering, it is possible to burn wires and cause embrittlement of copper, which can lead to depressurization of the penetration, and disruption of electrical circuits due to wire breakage in the burnout.

 In addition, the connection of external cables to the conductors of the modules is carried out directly on the penetration method by soldering, followed by the protection of the joints with heat-shrinkable tubes, which causes considerable difficulties, since when wiring the cable cores into several modules, binding to the place where the cable was cut remains.

 Also known is the penetration of electrical communications installed in the embedded element of the wall or steel shell, comprising a housing hermetically connected to the embedded element at the ends of the latter with the formation of a cavity between the housing and the embedded element, hermetically sealed in the flanges of the pipe body, in which the electrical conductors integrated into the modules are located equipped at the ends with means of connection with elements of the external circuit, and a pipe installed in one of the flanges, communicating with the cavity between the pipes for of the connections with a control device tightness (3).

 The objective of the invention is to increase the reliability, compactness, operational comfort and maintainability of the sinking.

 The technical result is the provision of tightness control separately for the main parts of the housing, including embedded elements, the introduction of sealed electrical connections.

 This result is achieved by the fact that the housing under the embedded element is made with a hole, and its flanges are with double walls, the internal of which are connected hermetically sealed in them between the pipes, and holes are formed in the outer walls coaxially to the pipes with a diameter smaller than the inner diameter of the pipes, while Means of connection with the elements of the external circuit are made in the form of sealed plugs located at the ends of the modules, fixed in the holes of the outer walls of the flanges and sockets with removable contacts to which the elements are connected an additional circuit, and in the flange of the casing with a nozzle an additional nozzle is installed, communicating with the cavities inside the pipes for connection with a tightness control device.

 The drawing shows a structural diagram in accordance with the invention.

 The housing 1 is enclosed in a mortgage element (pipe) 2 and sealed at the ends of the element, for example, by welding, and on the site the housing is leaky, the flanges of the housing 1 are double and consist of inner walls 3 and 4 and outer 5 and 6, inner walls 3 and 4 are tightly interconnected by pipes 7, and holes are made coaxially with the pipes 7 in the outer walls, modules (electrical conductors) 8 are enclosed inside the pipes 7, provided with sealed plugs 9 of electrical connectors at the ends, which are sealed by welding into the holes of the walls 5 and 6, pipes 10 and 11 are welded into walls 4 and 6, respectively, to control the tightness carried out by pressure switches 12 and 13, and the cavity of the pipes 7 (cavity a) is connected to the fitting 14, the cavity between the pipes and under the insert 2 (cavity b) nipples 15, biological protection can be placed in the form, for example, of lead rings 16, worn on conductors 8 (protection in cavity a) and in the form of cast-iron shot 17, filled in cavity b, external electrical cables 18 and 19 with wires spaced on plug-in contacts of 20 electrical outlets s (e.g., can be used sockets type SOG 27 GE0364.241 connectors. TU).

 The proposed device operates as follows. The current is transmitted through cables 18 of the station, cut into wires; Further, the current is transmitted through electrical connectors, consisting of sockets 20 with removable contacts and plugs 9; through the wires of the modules 8 and through the elements described above, including the cables 19 of the station. The required level of insulation resistance in electrical connectors during operation, including room decontamination modes by liquids, is provided, for example, by heat-shrinkable tubes installed on moisture-splash-proof connectors and lead-in cables (heat-shrinkable tubes are not shown in the drawing).

 The possibility of undocking the electrical connectors allows you to control the state of the electrical elements of both the tunnel itself and the station circuits.

 Tightness is ensured by a thick-walled penetration case 1, welded seals 9 and welded seams connecting its body 1 with the embedded element 2 into its end walls 5 and 6. As a result of this welding, taking into account that the body 1 is leaking on the length L, a cavity b is formed, having an outlet through the pipe 10, allowing to pressurize the cavity with gas using the fitting 15. The cavity a is filled with gas at the factory through the pipe 11 with the fitting 14. The tightness of the penetration during operation is monitored by schyu pressure sensors 12 and 13.

Improving reliability is ensured by the fact that:
a) in addition to the assembly welds at the nuclear power plant, all other elements of the penetration sealing are performed at the factory. Checking the seams performed at the nuclear power plant can be carried out through the existing standard cavity monitoring system 6 using the signaling device 13;
b) the design excludes the sealing of copper wires by soldering because of the danger of burnout and electrical damage.

The increase in compactness is ensured by the fact that:
a) the nozzles 10 and 11 are led out through the end of the penetration, where the fittings 14 and 15 and pressure indicators 12 and 13 are also located, and the electrical signals from them can be transmitted via a standard cable 19. Thus, there is no additional space for the location of the penetration tightness control system required (a system for monitoring the tightness of existing penetrations is deduced for the dimensions of penetration by pipelines with manometers);
b) electrical connectors are used that provide a higher installation density than pressure insulators.

 The increase in operational conveniences is determined by the small volume of work at nuclear power plants and the convenience of their implementation during the installation of excavation and during its operation.

This is ensured by the fact that:
a) cable cutting and connection of wires with removable contacts can be carried out on the assembly table;
b) electrical connectors are used, which make it easy to verify the correctness of the connection of the station's electrical circuits to the tunneling and correct the error at the assembly site of the installation of cable terminations 18 and 19. This is facilitated by the use of sockets 20 with removable contacts, which make it possible to extract individual contacts together with the wires connected to them ;
c) continuous separate monitoring of the tightness of the cavities a and b is performed, allowing to limit the search for the depressurization site.

 Increasing the maintainability of penetration is associated with the possibility of repair by replacing individual failed elements without removing the housing 1 of the penetration from the embedded pipe 2. Repair requiring the most laboriousness - replacing the module consists in disconnecting all electrical connectors, cutting off the welds of the forks 9 of the defective module and replace it with a conditional one and, after necessary checks, set the undocked parts to their normal position. From the described it can be seen that the most complex repair does not require a violation of the integrity of the mounted elements of the electrical circuits supplied to the sinking.

Claims (1)

 Electrical communications penetration, installed in the embedded element of the wall or steel shell, containing the housing, hermetically connected to the embedded element at the ends of the latter with the formation of a cavity between the housing and the embedded element, hermetically sealed in the flanges of the pipe body, in which the electrical conductors equipped with modules at the ends by means of connection with elements of the external circuit, and a pipe installed in one of the flanges, communicating with the cavity between the pipes for connection with the device tightness control, characterized in that the housing under the embedded element is made with a hole, its flanges are with double walls, the inside of which are connected by tubes hermetically sealed in them, and holes with a diameter smaller than the inner diameter of the pipes are formed coaxially with the pipes in the outer walls, this means of connection with elements of the external circuit is made in the form of sealed plugs located at the ends of the modules, fixed in the holes of the outer walls of the flanges, and sockets with removable contacts, to which s external circuit elements, wherein in the housing flange with an additional pipe conduit communicating with the cavities inside the pipe for the connection with the leakage control.