CZ308670B6 - Hermetic zone long-term heat removal system - Google Patents

Abstract

The hermetic zone long-term heat removal system contains a cold circuit and a hot circuit. The cold circuit comprises a supply pumping station (1) on the one hand connected to the refrigerant source of the cold circuit and on the other hand to a filter (2) connected to the main pumping station (3) which is connected via an inlet shut-off valve (4) with a turbine (5) and subsequently through the cold circuit of the cooler (6) and from there through the outlet shut-off valve (7) with the source of the cold circuit refrigerant. The hot circuit comprises a hot circuit pump (8) connected at its outlet via a hot circuit of a cooler (6) to a shower (9) in the hermetic zone (10) and at its inlet via a mechanical screen (11) to a source of hot circuit refrigerant. The main pumping station (3) is also connected to the inlet of the hot circuit pump (8) for mixing the cold circuit refrigerant into the hot circuit refrigerant by the primary after cooling branch (19a).

Description

Long-term heat removal system from the hermetic zone

Field of technology

The invention relates to a system for the long-term removal of heat from a hermetic zone in the event of a severe accident at a nuclear power plant

Prior art

Efforts to constantly increase the safety of nuclear power plants and the experience of accidents that have already been overcome lead to a sophisticated typology of failures and accidents, which are described as predictable and are standardized in some way. For these events, usually on a smaller scale, systems are solved, which are implemented in the technological equipment of the power plant already in the project of the nuclear power plant itself.

For cases of a major accident at a nuclear unit, which are beyond the management of standard emergency means, the current legislation requires the operator of the nuclear facility to take such measures that will prevent or mitigate the consequences of severe accidents. A set of measures has been defined for the solution of severe accidents and one of these measures is the creation of a new functionally and energetically autonomous system of long-term effective heat removal from the hermetic zone, the so-called containment. The requirement for creating such a system is that the pressure vessel of the reactor affected by the severe accident is externally cooled by water flowing into the reactor shaft from a pool formed on the floor of the hermetic zone. The heated water evaporates and steam escapes into the space of the hermetic zone, which gradually pressurizes it and overheats the building structure. If this condition is not solved, there is a risk of violating the integrity of the hermetic zone by a pressure exceeding the safety limit of the building structure. It is therefore necessary to prevent the space from being pressurized to the safety limit and to keep the pressure in the hermetic zone low.

There are various technical solutions and proposals for methods of heat dissipation from these spaces. However, there is a difference in the design and connection of components, where a steam turbine is often used as a source of energy, or the circulation of coolant in the primary circuit is not separated.

The long-term method of heat removal is solved by the document PV 2019-166, describing the system of long-term heat removal from the hermetic zone, containing a cold circuit and a hot circuit. The cold circuit comprises a feed pumping station for supplying refrigerant to the cold circuit on the one hand connected to the refrigerant source and on the other hand to the refrigerant filter which is connected to the main pumping station to create refrigerant movement which is connected via a shut-off valve to the turbine and via radiator and shut-off valve with cold circuit refrigerant source. The hot circuit comprises a hot circuit refrigerant pump connected at the outlet via a radiator with a shower located in the hermetic zone and at the inlet via a mechanical screen with a hot circuit refrigerant source. The main disadvantage of this system is the high water temperature at the inlet to the hot circuit coolant pump. In a situation where the supply of a sufficient volume of water to the cold circuit is not ensured, the inlet may be flooded and the emergency cooling may malfunction prematurely.

The essence of the invention

It is an object of the present invention to provide such a system for long-term heat removal from the hermetic zone which overcomes the above-mentioned disadvantages of the prior art.

The above-mentioned shortcomings are largely eliminated by the system of long-term heat removal from the hermetic zone containing the cold circuit and the hot circuit, where the cold circuit comprises a feed pumping station on one side connected to the cold circuit refrigerant source and on the other

- 1 CZ 308670 B6 side with a filter which is connected to the main pumping station, which is connected via an inlet shut-off valve to the turbine and subsequently via a cold cooler circuit and thence via an outlet shut-off valve with a cold circuit refrigerant source, and the hot circuit contains a hot pump. connected at its outlet via the hot circuit of the radiator with a shower located in the hermetic zone and at its inlet via a mechanical screen with a source of refrigerant hot circuit, the essence of which consists in that the main pumping station is further connected to the pump inlet by means of the primary aftercooling branch hot circuit to mix the cold circuit refrigerant into the hot circuit refrigerant.

In a preferred embodiment, the cold circuit further comprises a primary cold circuit aftercooling branch discharged from the inlet of the filter to the cold circuit refrigerant source and / or a secondary cold circuit aftercooling branch discharged from the outlet of the main pumping station to the cold circuit refrigerant source.

In another preferred embodiment, the hot circuit comprises a secondary aftercooling branch of the hot circuit, led from the hot circuit outlet of the cooler to the pump inlet.

Explanation of drawings

The invention will be further illustrated by the figure, where Fig. 1 is a circuit diagram of a long-term heat dissipation system according to the invention.

Examples of embodiments of the invention

The long-term heat removal system from the hermetic zone of the present invention, shown in Figure 1, includes a cold circuit and a hot circuit.

The cold circuit comprises a feed pumping station 1 connected on the one hand to the refrigerant source of the cold circuit and on the other hand to a fine dirt filter 2, which is connected to the main pumping station 3, which is connected via an inlet shut-off valve 4 to the turbine 5 and subsequently via the cold cooler circuit 6 and outlet shut-off valve 7 with a cold circuit refrigerant source, whereby the circuit is closed.

The hot circuit comprises a hot circuit pump 8, connected at its outlet via the hot circuit of the cooler 6 to a shower 9 located in the hermetic zone 10 and at the inlet via a mechanical screen 11 with a source of coolant of the hot circuit.

The main pumping station 3 is further by means of a primary after-cooling branch 19a of the hot circuit, comprising a shut-off valve 20a. connected to the inlet of the hot circuit pump 8, whereby the refrigerant of the hot circuit entering the pump 8 is cooled down to a state which guarantees its correct function.

The coolant source of the cold circuit is, for example, the pool 12 of the cooling tower 13 and the coolant is preferably water.

The cold circuit can be provided with a sludge branch 14 led from the fine dirt filter 2 to the sludge tank 15. If the sensors located in the filter 2 detect its fouling, automatic rinsing and drainage of dirt into the sludge tank 15. The sludge branch 14 is provided with a sludge valve 16.

The cold circuit is preferably provided with one or two aftercooling branches 17a and 17b of the cold circuit. The primary aftercooling branch 17a of the cold circuit connects the inlet to the fine dirt filter 2 with the coolant source of the cold circuit. Secondary aftercooling branch 17b

- 2 CZ 308670 B6 of the cold circuit connects the output from the main pumping station 3 with the coolant source of the cold circuit. Both of these branches 17a, 17b can be put into operation by means of the control valves 18a, 18b at the moment when the coolant temperature of the cold circuit is above a predetermined value.

The source of the cooling of the hot circuit is the bottom part of the hermetic zone 10, preferably containing water with an admixture of boric acid, which flows into it from the shower 9.

In the presented exemplary embodiment, the turbine 5 and the pump 8 form one compact unit with a common rotor system, i.e. a turbo pump.

The hot circuit is preferably provided with a secondary aftercooling branch 19b of the hot circuit comprising a shut-off valve 20b. led from the outlet of the hot circuit of the cooler 6 to the inlet of the pump 8. This solves the limited capacity of the coolant in the hermetic zone 10, which is insufficient for long-term heat dissipation. Without this aftercooling branch, the critical temperature would be exceeded in the order of hours.

The connection of the individual components mentioned above is made by means of hoses or pipes.

The principle of operation of the long-term heat removal system from the hermetic zone according to the invention is as follows by way of example.

Cold water is taken from the pool 12 under the cooling tower 13 of the power plant, respectively from the wells of the fan cooling towers 13 by means of the pump station feeder 1 and is transported through a water filter 2 ensuring the required water quality to the main pump station 3. Both pump stations 1 and 3 they contain pumping units with thermal diesel drive. The pressurized water is led from the main pumping station 3 to the entrance to the hermetic zone 10 of the reactor block. Subsequently, it is fed to the turbine 5 of the hydrodynamic pumping unit and the waste water from the turbine 5 of the hydrodynamic unit is then led to the cold circuit of the heat exchanger or cooler 6, where it takes thermal energy from the pumped liquid of the hot circuit and heated from the hermetic zone 10. it returns to the pool 12 below the cooling tower 13 or to the wells of the fan cooling towers 13. The hot circuit pump 8 sucks a hot mixture of water and boric acid from the floor of the hermetic zone 10, filters it through a mechanical screen 11 and discharges it to the heat exchanger heat circuit. respectively coolers 6, and further to the sprinkling system, i.e. showers 9, located inside the hermetic zone 10, where it provides the desired cooling effect of important components of the hermetic zone 10 of the reactor.

The system according to the invention is fully autonomous, independent of the technological equipment of the nuclear reactor and of the external energy source, in particular the electrical supply. An exception is the components of the system, which are located outside the hermetic zone and are freely available even in the conditions of a severe accident, even if only for a limited time, such as refueling for thermal engines, etc.

The system of long-term heat removal from the hermetic zone according to the invention is intended primarily for nuclear power plants with light water reactors of the VVER type.

- 3 CZ 308670 B6

Claims (3)

PATENT CLAIMS 1. A system of long-term heat removal from the hermetic zone, comprising a cold circuit and a hot circuit, where - the cold circuit comprises a feed pumping station (1) connected on the one hand to the refrigerant source of the cold circuit and on the other hand to a filter (2) which is connected to the main pumping station (3) which is connected via an inlet shut-off valve (4) with a turbine (5) and subsequently via a cold cooler circuit (6) and thence via an outlet shut-off valve (7) with a cold circuit refrigerant source, and - the hot circuit comprises a hot circuit pump (8) connected at its outlet via a hot circuit of a cooler (6) to a shower (9) located in the hermetic zone (10) and at its inlet via a mechanical screen (11) to a hot circuit refrigerant source, characterized with that - the main pumping station (3) is further connected by means of the primary after-cooling branch (19a) of the hot circuit to the inlet of the hot circuit pump (8) for mixing the cold circuit refrigerant into the hot circuit refrigerant. The long-term heat removal system according to claim 1, characterized in that the cold circuit further comprises a primary cold circuit aftercooling branch (17a) discharged from the inlet of the filter (2) to the cold circuit coolant source, and / or a secondary aftercooling branch (17b). ) of the cold circuit, discharged from the outlet of the main pumping station (3) to the coolant source of the cold circuit. Long-term heat dissipation system according to claim 1 or 2, characterized in that the hot circuit comprises a secondary aftercooling branch (19b) of the hot circuit, discharged from the hot circuit outlet of the cooler (6) to the inlet of the pump (8). 1 drawing