RU2248632C1 - Containment leaks decontaminating device - Google Patents

Abstract

FIELD: nuclear power engineering; nuclear power plants USING multilayer containment.

SUBSTANCE: proposed decontaminating device designed for use where power failure is possible to limit escape of contaminated materials emitted during beyond-design basis accidents into atmosphere has filter with exhaust pipe and branch pipe one of whose ends communicates with interlayer space of containment that accommodates power unit with heat circuits, and convector connected by means of heat-carrying agent inlet and outlet to heat circuit; novelty is that other end of branch pipe communicates with bottom ends of convector heat-transfer channels and top ends of the latter communicate with filter.

EFFECT: enhanced safety of nuclear power stations.

1 cl, 2 dwg

Description

The invention relates to the field of nuclear energy, and in particular to localizing safety systems, and can be used in devices that maintain vacuum in the premises of industrial facilities containing environmentally harmful substances, in the event of failure at these facilities of ventilation systems that require electricity for their work .

In nuclear energy, devices are widely used to prevent radioactive contamination of the environment and localization of accident products, consisting of a double protective shell above the power unit (for example, a reactor installation) and an active ventilation system with filters [see Book Margulova T.Kh. “Nuclear Power Plants”, p. 344, 1978 Moscow. Graduate School].

The inner shell is a localizing barrier to the bulk of the radioactive substances released during the accident, the outer shell, together with the active ventilation system and filters, limits the spread of radioactive substances with leaks (leaks), i.e. with a part of substances leaked from the inner shell into the inter-shell cavity (inter-shell space). The ventilation system is connected with the inter-shell cavity by channels with fittings, it directs leaks through the filter and creates a vacuum in the cavity between the shells in relation to the pressure in the atmosphere. Dilution prevents leakage through the outer shell. In the event of a failure of the ventilation system, for example, in an accident with the loss of all sources of power supply at nuclear power plants, reliable localization and cleaning of leaks is not provided, because excessive pressure occurs in the inter-shell cavity, and leaks through the leaks of the outer shell enter the atmosphere.

The closest technical solution to the proposed one is a leakage cleaner from a protective shell containing a filter with an exhaust pipe, a pipe one end of which is connected to the inter-shell cavity of the protective shell, inside which a power unit with thermal circuits and a convector connected through an input and output for the heating coolant to the thermal contour [see USSR Author's Certificate No. 1829697, IPC G 21 С 9/00 of 05/08/1991].

Protective sheaths may have leaks. Therefore, in case of possible emergency leaks in the reactor installation, leading to an increase in the pressure of the medium in the volume of the inner shell, leaks of the radioactive vapor-gas medium from the inner shell into the inter-shell cavity occur. In the inter-shell cavity there is an increase in pressure above atmospheric. Part of the leaks passes through the filter, but another part of them enters the environment through leaks in the outer shell, i.e. without being cleaned on filters.

The present invention describes a new independent active ventilation system, which, when the nuclear power plant is de-energized, must turn on in order to remove leaks from the inter-shell cavity. For the operation of this system, at least a heat exchanger, a steam generator, a turbine and a gas blower are used, that is, many complex devices, some of which have mechanical drives, therefore this system is insufficient, reliable in case of an accident and difficult to operate.

In addition, the disadvantage of the system under consideration is the moistening of the filter material with a droplet aerosol (fog) formed in the inter-shell cavity during leaks from the inner shell containing water vapor. Humidification increases the resistance and reduces the filtering properties of the material.

The objective of the invention is to simplify the design and increase the reliability of the purifier in case of failure of the active ventilation system by creating conditions under which the process of filtering the vapor-gas medium from the inter-shell cavity was carried out without the use of mechanical drives and the filter was not wetted.

This object is achieved in that in the known cleaner of leaks from the protective shell containing a filter with a chimney, the pipe one end of which is connected to the inter-shell cavity of the protective shell, inside which a power unit with thermal circuits and a convector connected via an input and output for the heating coolant to thermal circuit, new is that the second end of the pipe is in communication with the lower ends of the heat transfer channels of the convector, and the upper ends of the heat transfer channels of the convector scheny filter.

The connection of the second end of the pipe to the lower ends of the conveying channels of the convector provides overheating and drainage of the leaks and the creation of natural convection, allowing without the use of mechanisms to remove leaks from the inter-shell cavity and create a vacuum in it.

The invention is illustrated by drawings, where:

figure 1 shows a diagram of the proposed cleaner leaks from the protective shell;

figure 2 is a plot of the pressure of the medium in the inter-shell cavity.

The cleaner of leaks from the protective shell, Fig. 1, is designed to clean leaks from the inner 1 of the shell of the power unit in the inter-shell 2, limited by the outer shell 3. In the space of the inner shell there is a power unit with thermal circuits, having a reactor 4 and a steam generator 5 with pipeline 6 for supplying steam to the convector 7 of the purifier and a pipe 8 for returning condensate to the steam generator 5. The convector 7 is installed on the outside of the outer 3 shell. The convector 7 has channels 9 that transfer heat from the steam to the leaks. The lower end 10 of the heat transfer channels 9 of the convector 7 is connected to the pipe 11 with a valve 12, which, through a penetration 13 made in the outer 3 shell, communicates the intershell cavity 2 with the channels 9 of the convector 7. The upper end 14 of the heat transfer channels 9 is connected to the filter 15, which in turn, it is connected to the exhaust pipe 16. A pipe 6 for supplying steam is connected to the convector 7 to its input 17 for supplying a heating coolant, and a pipe 8 for returning condensate to the steam generator 5 is connected to the output 18 of the convector 7.

Figure 1 schematically shows one convector 7. The leak cleaner may have several convectors, the inputs of which are individually connected to the intershell cavity, and the outputs are combined when connected to the input part of the filter 15.

Figure 1 also shows the active ventilation system of the intershell 2, which includes the inlet 19 and outlet 20 nozzles with valves 21 and 22, an electric fan 23 and a filter 24.

The proposed cleaner of leaks from the protective shell works as follows.

In normal operation of the reactor installation, the valve 12 is in the closed position. The channels 9 of the convector 7 are in a heated state due to the steam entering in a small amount from the steam generator 5 into the annular space of the convector 7. The heated state of the mass of the tubular of channels 9 ensures that the leak cleaner is always ready for operation after opening valve 12.

In the design modes of operation of the power unit, the valves 21 and 22 are open, and the vacuum in the intershell 2 is determined by the operation of the active ventilation system.

In case of emergency leaks from the thermal circuits of the power unit in the volume of the inner 1 shell, the pressure rises and leakage of the radioactive medium from the inner 1 shell into the inter-shell cavity 2, where the active ventilation system maintains a vacuum in case of its operation and directs the leaks to the filter 24.

If during emergency leaks there was a failure in the active ventilation system, for example, due to the interruption of the power supply to the electric fan 23, overpressure occurs in the inter-shell cavity 2. To eliminate this phenomenon, the valve 12 is opened and the valves 21 and 22 are closed. Due to the fact that the convector 7 is kept in a constant heated state, the passive cleaner is quickly turned on. Due to the heating of leaks in the heat transfer channels 9, the drip moisture contained in the leaks is drained and overheated. The temperature of the medium in the channels 9, in the filter 15 and in the exhaust pipe 16 is higher than in the surrounding atmosphere, and the density, respectively, is lower than in the atmosphere, which creates a constant vacuum in the inter-shell cavity 2 with respect to atmospheric pressure. Due to the creation of rarefaction in the inter-shell cavity, an unorganized escape of leaks through the outer 3 shell into the environment without purification on the filter is eliminated, i.e. environmental pollution is prevented by nuclides from a nuclear power plant.

The work of the purifier to prevent leaks through the outer shell into the atmosphere is illustrated by the pressure distribution diagram (Fig. 2) in the elements of the equipment of the leak purifier, the inter-shell cavity and the atmosphere, showing that due to the natural convection arising from the heating of the leaks, the pressure p _(GE) in the inter-shell cavity 2 lower than atmospheric pressure p _(AF) . The design parameter for the selection of technical and structural characteristics of the equipment of the proposed leak cleaner, i.e. The channels of the convector, fittings, filter and exhaust pipe are the following conditions: the pressure P _(G) at the upper point of the intershell cavity G is less than or equal to the pressure in the surrounding atmosphere at the same height P _(K) , i.e. P _(G) ≤ P _(K) . The high-altitude location of points A, B, C, D, E, F, G, K is shown in figure 1.

The proposed device in relation to the previously known has a new positive property, it maintains a vacuum in the inter-shell cavity in case of failure of the active ventilation system.

The technical and economic effect consists in increasing the safety of nuclear power plants (or other facilities) due to a decrease in the value of accidental untreated emissions during excess accidents and ensuring the compactness of the sanitary protection zone of a nuclear power plant.

Claims (1)

A cleaner of leakages from the protective shell, comprising a filter with a chimney, a pipe, one end of which is connected to the inter-shell cavity of the protective shell, inside which a power unit with thermal circuits is installed, and a convector connected through an input and output for the heating coolant to the thermal circuit, characterized in that the second end of the pipe is in communication with the lower ends of the heat transfer channels of the convector, and the upper ends of the heat transfer channels of the convector are in communication with the filter.

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