RU2255387C1 - Containment leaks cleaner - Google Patents

Abstract

FIELD: nuclear power engineering; power projects using multilayer containments.

SUBSTANCE: proposed leaks cleaner designed to prevent escape of radioactive and otherwise contaminated materials into surrounding atmosphere in case of accidents has convector with air draft shaft mounted in its top, filter with draft tube, and passage disposed above heated surface of convector and communicating interlayer space of containment; the latter accommodates power unit with heat loop coupled with convector; novelty is that air draft shaft incorporates heat-transfer channels whose bottom ends communicate through valves with passage and top ones, with filter; heat-transfer channels are disposed above heating surface of convector for drying out leaks and building up natural convective draft affording escape of leaks over channels from interlayer space of containment.

EFFECT: enhanced safety of nuclear power station due to reduced emission of contaminated materials into atmosphere during above-design accidents.

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 [Margulova T.Kh. Nuclear power plants. M .: Higher school, 1974, p.324].

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, i.e. with part of the substances leaked from the inner shell into the inter-shell space (inter-shell cavity). An active ventilation system is connected to the inter-shell space by channels with fittings, it directs leaks through the filter into the atmosphere and creates a vacuum in the space 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 power sources at nuclear power plants, reliable localization and cleaning of leaks is not provided, because overpressure occurs in the inter-shell space, and leaks through leaks in the outer shell of the untreated enter the atmosphere.

Also known is a leakage purifier from the power unit’s containment containing a filter with an exhaust pipe and a nozzle connecting the filter to the intershell [Proceedings of the Fifth International Topical MeetingOn Reactor Thermal Hydraulics NURETH-5, volume IV, pp.1235-1241, USA, American Nuclear Society, 1992]. The cleaner works without the use of electricity.

The disadvantage of this cleaner is the lack of a special heat exchanger for heating leaks. Therefore, its use is limited to localization systems with internal metal shells. With a reinforced concrete inner shell, there is no leakage heating, and as a result, the natural draft necessary to overcome the filter resistance is not created in the cleaning system.

In addition, the disadvantage of a cleaner without a leak heater, which would drain the leaks, is to moisten the filter material with a droplet aerosol (fog) formed in the inter-shell space during leaks from the inner shell containing water vapor. Humidification increases the resistance and reduces the filtering properties of the material.

The closest analogue to the claimed invention is a leakage cleaner from a protective shell containing a convector over which an air traction shaft is installed, a filter with an exhaust pipe and a penetration located above the heated surface of the convector, connected to the inter-shell cavity of the protective shell, inside which a power unit with a thermal circuit is installed, associated with the convector [SU 1829697 A1, CL G 21 C 9/00, publ. 06/09/1995].

The disadvantage of the technical solution proposed in the analogue [SU 1829697 A1, class G 21 C 9/00, publ. 06/09/1995], it is that in the case of a blackout of the main drive of gas-blowing units, overcoming the filter resistance is not due to natural traction, but due to an additional steam-powered installation, specially created for driving gas blowers.

The steam power plant is a multi-element active device, which reduces the structural reliability of the purifier and adversely affects the safety performance of nuclear power plants.

The objective of the invention is to increase the reliability of the leakage cleaner from the protective shell through the use of heat transfer channels that create a natural convection draft in the cleaner, which allows leakage to be pushed through the filter and released into the atmosphere.

The solution to this problem is achieved by the fact that in the known cleaner of leaks from the protective shell containing a convector, above which an air draft shaft is installed, a filter with an exhaust pipe, and a penetration located above the heated surface of the convector, connected to the inter-shell cavity of the protective shell, inside which a power unit with the thermal circuit associated with the convector, new is that heat transfer channels are installed in the air traction shaft, the lower ends of which are connected via valves Nena with the sinking, and the top filter, wherein the heat transfer channels disposed on the surface of a heating convectors, with drainage of leaks and to create a natural convection traction providing output leaks through the channels from the intershell cavity.

The invention is illustrated by drawings:

in FIG. 1 schematically shows a leakage cleaner from a containment;

in FIG. Figure 2 shows a diagram of the distribution of pressure of a medium in an inter-shell cavity.

The leakage cleaner from the protective shell is connected to the protective shell, which includes the inner 1 and outer 2 shells defining the intershell cavity 3. Under the shell is a power unit that has a reactor 4 and steam generators 5 with steam pipelines 6 for supplying steam to the convector 9 and pipelines 7 for returning condensate to the steam generators 5. In the inter-shell cavity 3, the pipelines 6 and 7 have protection 8 against leakage of the high-potential coolant from the pipelines 6 and 7 into the inter-shell cavity 3.

Convectors 9 are air condensers that are installed around the perimeter of the outer 2 shell. The heated surface of the convector 9 receives energy from a high-potential coolant of one of the power unit circuits. For the convector 9 shown in Fig. 1, the heated surface is a set of heat transfer tubes that serve as an air condenser for the steam coming from the steam generator 5 and return the condensate again to the steam generator 5. Condensate returns by gravity, i.e. due to natural convection due to the excess of the elevation of the convector 9 over the steam generator 5.

The convector 9 has an inlet at the bottom and an outlet for atmospheric air at the top. At the inlet and outlet of the convector 9, the lower and upper gates 10 are mounted.

At the exit of each convector 9 above its upper part (by air), air traction shafts 11 are also mounted.

Air traction shafts are curved along the contour of the dome 12 of the outer 2 protective sheath and in the upper part are connected by the output air collector 13 with the deflector 14. The collector 13 with the deflector 14 provides the air passing the purifier convectors 9 to the atmosphere. From atmospheric effects, the traction shafts 11 are closed by a domed roof 15.

The intake of atmospheric air to the surface of the convector 9 heated by steam is organized from below through the input collector 16 common for convectors, mounted concentrically on the cylindrical part of the reinforced concrete outer 2 protective sheath. The inlet manifold 16 has intake holes 17 for the passage of atmospheric air in the lower wall.

The heat transfer channels 18, used for heating leaks, are placed in the traction shafts 11 above the heated surface of the convector 9.

The lower ends of the heat transfer channels 18 through the valves 19 are introduced through the penetrations 20 in the outer shell 2 into the inter-shell cavity 3. The upper ends of the heat transfer channels 18 are fixed in the collector 21. A filter 22 is installed on the collector 21 for cleaning leaks from radioactive substances leaked into the inter-shell cavity 3. The filter 22 is equipped with a chimney 23, through which the cleaned leaks go into the atmosphere.

The proposed cleaner leakage from the protective shell for its work does not require the supply of energy from an external source. The movement of all media in the purifier occurs under the influence of gravitational forces, i.e. natural circulation, developing due to the supply of thermal energy from the power unit.

Figure 1 also shows the active ventilation system of the cavity 3, which includes the inlet 24 and outlet 25 nozzles with valves 26 and 27 and an electric fan 28 with a filter 29.

The proposed cleaner of leaks from the protective shell works as follows. In normal operation of the reactor installation, the valves 19 are in the closed position. The heat transfer channels 18, convector 9, collector 21, filter 22 and exhaust pipe 23 are constantly in a heated state due to heating from a small amount of atmospheric air passed through the leaks of the gates 10. The air receives heat from the steam discharged from the steam generators 5 to the convectors 9. The warmed state of the mass of all elements of the purifier ensures that the leakage purifier is in constant readiness for work after opening the valves 19.

In the design operating modes of the power unit, the valves 26 and 27 are open, and the vacuum in the inter-shell cavity 3 is determined by the operation of the active ventilation system, namely the electric fan 28.

In case of emergency leaks from the thermal circuits of the power unit in the volume of the inner 1 shell, the pressure increases and leaks of radioactive medium leak through cracks in the inner shell 1 into the intershell 3, where the active ventilation system maintains a vacuum and directs leakages to the filter 29.

If there is a failure in the operation of the active ventilation system, for example, due to the interruption of the power supply to the electric fan 28 in the inter-shell cavity 3, excessive pressure occurs. To eliminate this phenomenon, a passive leakage cleaning system is turned on, namely, the valves 19 are opened and the valves 26 and 27 are closed. The shutters 10 open when they are switched off. The opening of the gate 10 causes a rapid increase in air flow through the convectors 9, which automatically increases the steam flow from the steam generators 5 to the convectors 9. Atmospheric air, having received heat in the convectors 9, passing through the air draft shafts 11, heats the heat transfer channels 18 and the leaks in them. Due to the heating of leaks in the heat transfer channels 18, the drip moisture contained in the leaks is drained and the leaks are overheated. The temperature of the medium in the air heat transfer channels 18, in the filter 22 and in the exhaust pipe 23 is higher than in the surrounding atmosphere, which creates a constant leakage and rarefaction in the intershell 3 with respect to atmospheric pressure. Due to the creation of rarefaction in the inter-shell cavity, an unorganized escape of leaks through the outer 2 shell into the environment without purification on the filter 22 is eliminated, i.e. environmental pollution is prevented by nuclides from a nuclear power plant.

In the purifier, direct contact of the heat transfer channels 18 with the high potential coolant of the power unit circuits (in this case, with the steam of the second circuit of the reactor installation) is excluded. The heat-transferring channels 18 are heated by atmospheric air, which excludes an emergency pressure increase in the inter-shell cavity 3 and the outer shell 2 is loaded with internal pressure higher than the design pressure when the heat-transferring channels 18 are loose and the heat-transfer pipes of the convector 9 are loose.

P_(K). Высотное расположение точек A, B, C, D, E, F, G, K показано на фиг.1.The work of the cleaner to create a vacuum in the inter-shell cavity 3 is illustrated by the pressure distribution diagram (Fig. 2) in the equipment elements of the leak cleaner P _(ABCD) , the inter-shell cavity P _(GDE) and the atmosphere P _(AKF) , which shows that due to the heating of the leaks in the heat transfer channels 18, the pressure P _(GDE) in the inter-shell cavity 3 is lower than the pressure in the atmosphere P _(AKF) . The design parameter for the selection of technical and structural characteristics of the equipment of the proposed leak cleaner, i.e. the surface of the heat transfer channels, fittings, filter and exhaust pipe is the following condition: the pressure P _(G) at the upper point of the intershell 3 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 altitude location of points A, B, C, D, E, F, G, K is shown in Fig. 1.

A leak cleaner with heat transfer channels creates a vacuum in the inter-shell cavity when the active ventilation system fails and prevents the outer shell from loading with internal pressure if leaks occur in the heat transfer channels and convector heat transfer tubes.

The technical result of the invention is to increase the safety of a nuclear power plant in the event of excess accidents occurring with the loss of power sources due to the prevention of accidental emissions into the atmosphere due to the reliability of the process of maintaining rarefaction in the intershell space.

Claims (1)

A cleaner of leakages from the protective shell, comprising a convector above which an air draft shaft is installed, a filter with an exhaust pipe and a penetration located above the heated surface of the convector, connected to the inter-shell cavity of the protective shell, inside which an energy unit with a thermal circuit connected to the convector is installed, characterized in that heat transfer channels are installed in the air draft shaft, the lower ends of which are connected to the penetration by valves and the upper ends with a filter, while heat transfer e channels are arranged over a heating surface, with the convector draining leakages and create natural convection traction providing output leaks through the channels from the intershell cavity.

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