KR20170039083A - Containment cooling system, and containment and reactor pressure vessel joint cooling system - Google Patents

Abstract

The present invention relates to a containment cooling system and a combined cooling system of a containment vessel and a reactor pressure vessel, the containment vessel cooling system comprising an internal heat exchanger (1), a riser pipeline (2), a polling pipeline (3) The isolation valves 4 and 5, the cooling water tank 6, and the air-cooled condenser-cooler 7 are connected. The combined cooling system of the containment vessel and the reactor pressure vessel includes the containment vessel cooling system and the reactor pressure vessel cooling system. The cooling system provides long-term and effective cooling to the containment vessel and the reactor pressure vessel simultaneously without the need to provide external power in the event of an accident, so that, under the condition that there is no artificial interference and no external cooling measures in the event of an accident, Ensure that reactor pressure vessels are always in safe condition.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a containment vessel cooling system,

The present invention relates to containment vessel cooling systems for nuclear safety and thermal hydraulics, and more particularly to a combined cooling system of containment vessels and reactor pressure vessels.

Containment vessels and reactor pressure vessels are important safety barriers to prevent leakage of radioactive materials in the event of an accident at a nuclear power plant. In the event of a major accident such as a LOCA or MSLB, the temperature and pressure of the nuclear storage containment vessel are rapidly increased due to the entry of a large amount of steam, If the range is exceeded, the containment vessel may be broken and the radioactive material may leak; At the same time, the core is severely dewatered and the cooling capacity is greatly reduced. Once the core is melted, the melt can melt down to the lower sealing head of the pressure vessel, and if the lower sealing head receives excessive heat load and melts through, , The integrity of the containment vessel is seriously threatened and leakage of the core melt can be caused. Therefore, in order to ensure the safety of the nuclear power plant, it is necessary to install a specialized system for cooling the containment vessel and reactor pressure vessel.

At present, design methods of cooling system for double concrete containment vessel and reactor pressure vessel are presented.

The proposed method for the concrete containment vessel is mainly provided with a heat exchanger inside and uses the difference in height between the external water tank and the internal heat exchanger to derive the amount of heat in a natural circulation manner, (CS Byun, DW Jerng, NE Todreas, et al. Conceptional design and analysis of a semi-passive containment cooling system for a large concrete containment. Nuclear Engineering and Design, 2000,199: 227-242; SJ Cho, BS Kim, MG Kang, et al. The development of passive design features for the Korean Next Generation Reactor.Nuclear Engineering and Design, 2000, 201: 259-271; SW Lee, WP Baek, SH Chang.Assessment of passive containment cooling concepts for advanced pressurized water reactors.Ann.Nucl.Energy, 1997, 24 (6): 467-475). Thus, in designing the above-described containment container heat quantity derivation system, there is one major problem in all, that is, it can be ensured that the temperature and pressure of the containment vessel do not exceed the design criterion within a certain time, The maximum amount of time that can be provided is 72 hours. If this time is exceeded, the water in the water tank is exhausted and the system becomes ineffective. After 72 hours, the system may re-activate after external water has been injected into the water tank by external power. In order to extend the cooling time in the absence of artificial interference, the volume of the water tank must be increased, and the increase in the volume of the water tank greatly increases the effect of the earthquake.

Public Numbers CN201681637, CN203366760U, CN202887747U; As shown in the patent documents such as CN103632736A, CN102163469A, and CN103310856A, the reactor external cooling system proposed for the reactor pressure vessel almost simultaneously adopts both active and manual water injection systems. However, the above-described reactor external cooling system has a common drawback that the utilization rate of the cooling water is relatively low. If the water in the lower reactor water tank is not artificially turned off in the water pump or passive system, the water injection system continues to inject water (water flow rate is small or large) and water floods from the reactor water tank It causes waste. Thus, in order to ensure a sufficient cooling time, the water tank of the manual cooling system described above in the absence of artificial interference must store a large amount of water, which greatly increases the volume of the water tank. If the water injection volume is small, the water level in the reactor water tank can be lowered, and even the reactor pressure vessel can not be completely submerged and the reactor pressure vessel can not be sufficiently cooled, which may threaten the integrity of the reactor pressure vessel. Therefore, in order to provide continuous cooling of the reactor pressure vessel without further loss of cooling water, artificial cooling systems (active or passive systems) must be subjected to continuous control or start-stop operations, It creates a great difficulty in operation.

In addition, the above-mentioned measures are proposed for double concrete containment vessels or reactor pressure vessels, both of which are mutually independent. However, in the event of a major accident, the containment vessel and the reactor pressure vessel must be cooled simultaneously, and if the two systems operate independently, the condensate produced in the internal heat exchanger is lost.

It is an object of the present invention to provide a containment vessel cooling system that does not need to provide external power, consumes less cooling water, and can realize long-term cooling in the containment vessel.

It is a further object of the present invention to provide a combination of a containment vessel and a reactor pressure vessel to provide both long term and effective cooling to containment vessels and reactor pressure vessels in the event of an accident, Cooling system.

The containment vessel cooling system of the present invention comprises an internal heat exchanger, a riser pipeline, a polling pipeline, an isolation valve, a cooling water tank and an air-cooled condenser-cooler, wherein the internal heat exchanger is located in an upper space close to the sidewalls in the innerlayer concrete containment The cooling water tank and the internal heat exchanger are connected to each other through a rising pipe line and a polling pipe line to constitute a closed circuit and the cooling water tank and the internal heat exchanger are connected to each other through a cooling circuit Cooling unit is a case-less heat exchanger, which is located inside a cooling water tank. An air-cooled condenser-cooler is installed so as to be inclined. A part of the heat transfer pipe of the air-cooled condenser-cooler is disposed in a water space, - The air side inlet of the cooler is located near the bottom of the side wall of the water tank And the air side outlet of the condenser-cooler is formed at a position close to the upper surface of the sidewall of the water tank, and through the pipeline Air-cooled condensing-The upper sealing head of the cooler communicates with the annular space consisting of the inner layer concrete containment vessel and the outer concrete containment vessel.

In the containment vessel cooling system of the present invention,

1. A watertight sealing device is connected to the side wall of the cooling water tank, the upper connection pipe of the watertight sealing device communicates with the steam space of the cooling water tank, the lower connection pipe communicates with the water space of the cooling water tank, Is bridged by a pipeline;

2. Rising pipelines and polling pipelines may further include valves with internal and external valves.

A combined cooling system of a containment vessel and a reactor pressure vessel of the present invention includes a containment vessel cooling system and a reactor pressure vessel cooling system; The containment vessel cooling system includes an internal heat exchanger, a riser pipeline, a polling pipeline, an isolation valve, a cooling water tank, and an air-cooled condenser-cooler, wherein the internal heat exchanger is located in an upper space close to the side wall in the innerlayer concrete containment, The cooling water tank and the internal heat exchanger are connected to each other through a rising pipe line and a polling pipe line to constitute a closed circuit, and the cooling water tank and the internal heat exchanger are connected to each other through an air cooling type condenser-cooler Cooled condenser-chiller is arranged to be inclined, a part of the heat transfer pipe of the air-cooled condenser-cooler is disposed in the water space, the other part is disposed in the vapor space, and the condensation- The air inlet of the cooler is located near the bottom of the side wall of the water tank And the air side outlet of the condenser-cooler is formed at a position close to the upper surface of the side wall of the water tank and communicates with the air-cooled condenser-cooler through the pipeline, Condensing-communicating with the annular space consisting of the upper sealing head of the cooler, the inner layer concrete containment vessel and the outer concrete containment vessel; The reactor pressure vessel cooling system includes a water storage tank, a pressure equalizing tube, a water inlet, a water isolation tank, a control valve, a communicating tube, a condensate collecting tank, a water storage tank and an exhaust pipe, The reactor pressure vessel is located in the reactor water tank, and the condensate collector is connected to the lower portion of the internal heat exchanger through the communication pipe. And the condensate collecting tank connects the reservoir tank, the control tank, and the isolation tank in order through the pipeline.

The combined cooling system of the containment vessel and the reactor pressure vessel of the present invention,

1. The upper end of the pressure balance tube is located in the vapor space of the water storage tank and the lower end relative position is higher than the upper edge of the reactor pressure vessel;

2. The upper end of the water inlet is connected to the lowest point of the water storage tank and the lower end is lower than the lower edge of the pressure equalizing pipe;

3. The drain at the bottom of the water inlet represents "S" type;

4. A control valve is installed in the water inlet;

5. The upper portion of the water storage tank may communicate with the condensate collection tank through an exhaust pipe, and the lower portion of the water storage tank may be provided with a blow-down valve.

In the event of a major accident such as LOCA, MSLB, etc., the present invention can simultaneously provide long-term cooling to the containment vessel and the reactor pressure vessel so that the containment vessel and the reactor pressure vessel are always in a safe state. The system can implement the following effects.

(1) In case of an accident, natural circulation can be achieved through the difference in density between the single-phase water and the gas-water mixture without artificial interference between the internal heat exchanger and the water tank.

(2) Air Cooling Condensation-The natural circulation of air can be realized between the cooler and the outside atmosphere, so that the amount of heat in the water tank can be immediately discharged, the operation time of the heat quantity deriving system can be prolonged, If less than the heat exchange output of the condenser-chiller, the system can achieve long-term cooling of the containment vessel.

(3) The air-cooled condenser-chiller can cool water and steam in the cooling water tank at the same time, thereby drastically reducing the consumption of cooling water and increasing the utilization rate of cooling water, thereby greatly reducing the water storage amount in the cooling water tank.

(4) The air-cooled condenser-cooler cools water in the cooling water tank to lower the temperature of the water, thereby increasing the density difference in the rising and polling pipelines, increasing the natural circulation driving force, increasing the cooling water flow rate in the internal heat exchanger , It is possible to more effectively derive the amount of heat in the containment vessel by improving the heat exchange output of the heat exchanger.

(5) The water sealing device is installed to prevent the cooling water tank from being contaminated by the external environment, and automatically open when the pressure in the water tank is large, thereby preventing the cooling water tank from being broken due to the excessive pressure.

(6) The external cooling system of the reactor can realize full manual operation to sink the pressure vessel, and the water replenishment amount can realize automatic control by using the pressure balance pipe without artificial interference and control.

(7) The design of "S" type can effectively prevent reverse flow of gas phase and water phase, prevent vibration of flow rate, and stabilize water injection amount.

(8) The passive reactor external cooling system has a high utilization rate for cooling water, no wasted waste, and drastically reduces the amount of cooling water consumed under the same cooling time as the conventional manual technique, .

(9) The design of the isolation water tank effectively prevents the steam generated by boiling in the reactor water tank from flowing back to the water tank, ensuring that the system operates stably.

1 is a schematic view of a containment vessel cooling system of the present invention.
2 is a schematic diagram of a combined cooling system of a containment vessel and reactor pressure vessel of the present invention.

BRIEF DESCRIPTION OF THE DRAWINGS FIG.

First Embodiment

1, the containment vessel cooling system according to the present invention mainly includes an internal heat exchanger 1, a riser pipeline 2, a polling pipeline 3, an isolation valve 4, an isolation valve 5, (6), and an air cooling type condenser-cooler (7). The inner heat exchanger is located in an upper space close to the side wall in the inner layer concrete containment vessel 12; The cooling water tanks are located outside the outer layer concrete containment vessel 13 and their relative positions are higher than the internal heat exchanger and connected to the internal heat exchanger through the rising piping and the polling pipeline respectively to constitute a closed circuit; An air-cooled condenser-cooler is a case-less heat exchanger which is located inside the cooling water tank and is installed to be inclined. A part of the heat transfer tube is disposed in the water space and the other part is disposed in the steam space, By cooling the steam, the consumption of cooling water is significantly reduced, the continuous operation time of the heat quantity derivation system is greatly extended, and the long-term cooling of the containment vessel is realized; The air side inlet 9 of the condenser-cooler is formed at a position near the bottom of the side wall of the water tank and communicates with the outside air atmosphere through the pipeline and the lower sealing head of the air-cooled condenser-cooler; The air side outlet (10) of the condenser-cooler is formed at a position close to the upper surface of the side wall of the water tank, and is connected to the upper sealing head of the air-cooled condenser-cooler through a pipeline and to the annular condenser- Communicate the space.

The internal heat exchanger improves the heat transfer efficiency by using a highly efficient reinforced heat transfer tube such as an outer fin tube (Fin-Tube), an integral pin fin, or the like; The external air-cooled condenser-cooler uses a highly efficient, heated tube such as an inner fin tube, an inner ribbed tube, etc. to improve heat transfer efficiency and reduce the volume of the heat exchanger.

Rising pipelines and polling pipelines are equipped with internal isolation valves and external isolation valves (4, 5) to prevent leakage of radioactive material due to pipeline failure in manual heat extraction systems.

A water seal device (8) is connected to the side wall of the cooling water tank to isolate the cooling water tank from the external environment during non-operation, thereby preventing the water in the water tank from being contaminated and clogging the pipeline; In case of an accident, the cooling water tank is heated by the working material (pressure), so that the pressure rises and ruptures the water sealing device so that the cooling water tank is communicated with the outside atmosphere through the water sealing device. The upper connection pipe of the water sealing device communicates with the steam space of the cooling water tank, the lower connection pipe communicates with the water space of the cooling water tank, and the upper and lower connection pipes are bridged by the pipeline.

The top of the outer layer concrete containment dome serves to guide the air flow between the double containment vessels so that air flows from the air-cooled condenser-cooler inlet through the air-cooled condenser-cooler and air- By configuring the natural circulation of the atmospheric environment and air, there is provided an exhaust port 11 for providing a sufficient air flow rate to the air-cooled condenser-cooler.

The containment vessel cooling system of the present invention is a manual containment vessel heat quantity deriving system, and when operated alone, its operation principle is as follows. When the main pipe of the reactor is broken or the main engine is ruptured, a large amount of steam is released into the containment vessel and mixed with the air in the containment vessel to raise the temperature and pressure in the containment vessel. When the pressure in the containment container reaches a certain threshold value, the pressure sensor in the containment vessel sends a high pressure signal to the main control room of the power plant to start the containment calorie derivation system. When the containment heat quantity deriving system is activated, water in the cooling water tank flows into the internal heat exchanger 1 through the polling pipeline 3, is gradually heated to raise the temperature, and the water in the polling pipeline and the risen pipeline Air circulation type condenser-chiller is activated after introducing the amount of heat in the containment vessel to the cooling water tank so that the internal temperature of the cooling water tank 6 is raised, and air is supplied to the air side of the condenser- Cooler air side outlet 10 from the inlet 9 to the air-cooled condenser-cooler 7 and proceeding to sufficient heat exchange and then flows out of the condenser-cooler air side outlet 10 and flows through the inner layer concrete containment vessel 12 and the outer layer concrete containment vessel 13, And finally discharged to the atmosphere from the exhaust port 11 to realize the natural circulation of the air and take the amount of heat in the cooling water tank.

Since the amount of steam injected into the containment vessel at the initial stage of the accident is relatively large, the temperature in the containment vessel may be raised very quickly and the amount of heat introduced into the cooling water tank from the internal heat exchanger may be higher than the heat exchange output of the air- When the pressure in the water tank is higher than the open pressure of the water sealing device 8, the water sealing device is automatically opened so that the cooling water tank 6 is opened Directly discharges the pressure in the atmosphere, and after discharging the pressure, the water seal is rebuilt to isolate the cooling water tank (6) from the external environment.

 During an accident, the amount of steam injected into the containment vessel gradually stabilizes or decreases with time. At this time, the amount of heat that the internal heat exchanger introduces into the cooling water tank is equal to or less than the heat exchange capacity of the air-cooling type condenser-cooler 7 and the air-cooling type condenser-cooler 7 effectively cools and / Condensation proceeds to prevent the consumption of cooling water, to achieve long-term cooling of the containment vessel, and to greatly improve the safety of the containment vessel.

Second Embodiment

Referring to FIG. 2, the combined cooling system of the containment vessel and the reactor pressure vessel of the present invention comprises mainly two parts of the containment vessel cooling system and the reactor pressure vessel cooling system. The structure of the containment vessel cooling system is as described in the first embodiment.

The reactor pressure vessel cooling system described above mainly includes a water storage tank 14, a pressure balance pipe 15, a water inlet 16, a water isolation tank 17, control valves 18 and 24, a communicating pipe 19, A water tank 20, a reactor pressure vessel 21, a condensate collecting tank 22, a water storage tank 23, an exhaust pipe 25 and a blowdown valve 26 . The water storage tank is located above the isolation water tank and both are connected to the pressure balance pipe through the water inlet. The isolation water tank and the reactor water tank are connected through the communicating pipe. The reactor pressure vessel is located in the reactor water tank, Is located below the internal heat exchanger and connects the reservoir tank, the control valve and the isolation tank in order through the pipeline.

The upper end of the pressure equalizing tube is located in the vapor space of the water storage tank and the lower end relative position is higher than the upper edge of the reactor pressure vessel. When the system is in the standby state, there is no water in the tube, It is guaranteed to always sink into the water.

The upper end of the water inlet is connected to the lowest point of the water storage tank, and the lower end is lower than the lower edge of the pressure equalizing pipe.

When the drain hole leaks to the water surface, the air enters the water storage tank through the water inlet pipe, and the gas-liquid two phase flows backward in the tube. In order to increase the water injection resistance and to prevent the flow vibration, The lower outlet is designed as "S" type.

The isolation water tank is a small water tank. In case of an accident, the water in the water tank should be always kept in a cooled state to prevent steam generated by boiling in the water tank below the reactor from entering the water storage tank.

The control valve is installed in the water inlet, the control valve is turned off when the system is in the standby state, the isolation water tank is in the state of no water, the control valve is opened in case of an accident, It is injected into the water tank and flows into the reactor water tank through the communicating tube to sink the reactor pressure vessel.

In order to prevent the water in the condensate collecting tank from flowing smoothly into the reservoir tank and causing the two-phase reverse flow phenomenon to occur in the pipeline, the upper portion of the reservoir tank communicates with the condensate collector through the exhaust pipe; In the lower part of the water tank, a blowdown valve is installed and water is injected into the condensate collecting tank periodically to wash the condensate collecting tank, the storage tank and the related pipeline, the water is discharged through the blowdown valve to ensure smooth communication of the circuit, .

In this embodiment, the containment vessel cooling system is a passive containment calorie derivation system, and the reactor pressure vessel cooling system is a passive reactor external cooling system. The manual containment calorie derivation system and the passive reactor external cooling system can operate together or can operate alone. When the manual containment calorie derivation system is operated alone, the control valve is in the off state, and the condensate generated from the internal heat exchanger is collected in the condensate collecting tank and stored in the storage tank. When the manual containment calorie derivation system and the passive reactor external cooling system work together, the control valve opens and the condensate flows into the isolation tank from the reservoir tank and participates in the cooling of the reactor pressure vessel, thereby saving water in the water storage tank And the volume of the water storage tank can be effectively reduced.

When the manual containment calorie derivation system and the passive reactor external cooling system work together, the working principle is as follows. When the main pipe in the reactor is broken or the main engine is ruptured, a large amount of steam enters the containment vessel and mixed with air in the containment vessel to raise the temperature and pressure in the containment vessel; At the same time, the core can cause melting of the core due to a large amount of dehydration, the melt of the core can be melted down to the bottom sealing head of the pressure vessel, and when the bottom sealing head receives excessive heat load and melt through occurs, The integrity of the system. Water must be injected into the reactor lower water tank 20 in order to prevent the melt of the core from melting through the lower sealing head of the pressure vessel. At this time, the manual containment calorie derivation system and the passive reactor external cooling system must be operated simultaneously.

When the system is started, the water in the cooling water tank flows into the internal heat exchanger 1 through the polling pipeline 3, gradually heated to raise the temperature, and the water in the polling pipeline and the risen pipeline The natural circulation is generated so that the amount of heat in the containment vessel is introduced into the cooling water tank so that the temperature of the cooling water tank 6 is raised and then the air-cooling type condenser-chiller is operated and the air is introduced into the air- Cooled condenser-cooler 7 to perform sufficient heat exchange and then flows out from the air side outlet 10 of the condenser-cooler and flows into the annular condenser-cooler 7 through the annular condenser- Passes through the space and finally is discharged to the atmosphere from the exhaust port 11 to realize the natural circulation of the air and takes the amount of heat in the cooling water tank.

The condensed water generated on the surface of the internal heat exchanger 1 is collected in the condensate collecting tank 22 and enters the isolation water tank 17 through the water storage tank 23 and the control valve 24, Is mixed with the water flowing through the water inlet pipe (16) from the storage tank (14) and becomes the cooling water of the reactor pressure vessel (21). When the water level of the isolation water tank 17 is higher than the horizontal position where the bottom side communication pipe 19 is located, water flows into the reactor water tank 20 from the isolation water tank 17 through the communication pipe 19, ). Since the isolation water tank 17 and the reactor lower water tank 20 are communicating pipe structures, the water level between them is balanced. When the water level in the isolation water tank 17 does not exceed the lower portion of the pressure balance pipe 15, the cooling water injected into the isolation water tank 17 from the water storage tank 14 is rapidly reduced until it stops.

The surface of the reactor pressure vessel 21 in a high temperature state continuously heats the cooling water in the reactor lower water tank 20 and the temperature of the water in the reactor lower water tank 20 becomes higher, do. At this time, however, the broken part of the main pipe still injects steam into the containment vessel. After the steam is condensed on the surface of the heat exchanger 1, the condensed water is collected in the condensate collecting tank 22 and continuously injected into the lower reactor water tank 20 to cool the surface of the reactor pressure vessel 21, When the amount of the condensed water on the surface of the vessel (1) is larger than the amount of water injected into the isolated water tank (17), the condensed water is stored in the water storage tank (23).

Since the amount of steam injected into the containment vessel is relatively large at the beginning of the accident, the temperature in the containment vessel is raised very quickly, and the amount of heat introduced into the cooling water tank from the internal heat exchanger may be higher than the heat exchange output of the air- When the pressure of the water tank is higher than the open pressure of the water seal device 8, the water seal device is automatically opened so that the cooling water tank directly pressurizes the atmosphere And after discharging the pressure, the water sealing device is rebuilt to isolate the cooling water tank 6 from the external environment. Further, since the amount of condensed water on the surface of the internal heat exchanger 1 is large (the condensed water is generated mainly by the evaporation of the water in the reactor water tank and the mass condensation of the steam jetted from the damaged water tank), the condensed water is continuously injected into the isolation water tank 17 The water in the water storage tank 14 is almost not consumed except that it is injected into the isolation water tank 17 for the first time since the lower end of the pressure balance pipe 15 is always assuredly sunk.

During the event of an accident, the amount of steam injected into the containment vessel gradually stabilizes or decreases over time. At this time, the amount of heat that the internal heat exchanger introduces into the cooling water tank is equal to or less than the heat exchange capacity of the air-cooled condenser-cooler 7 and the air-cooled condenser-cooler 7 effectively cools the remaining water in the cooling water tank 6, Condensation proceeds to prevent the consumption of cooling water, realize long-term cooling of the containment vessel, and greatly improve the safety of the containment vessel. When the evaporation amount of the water in the reactor lower water tank 20 is larger than the condensation collection amount, the water level is lowered due to the evaporation and becomes lower than the lower end of the pressure equalizing pipe 15, The water storage tank 14 recovers the infusion of water until the water re-sinks the lower end of the pressure balance pipe 15. [ This repetition ensures that the reactor pressure vessel 21 is always in a sinking state without artificial interference.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the general inventive concept as defined by the appended claims. It should be understood that the present invention is not limited thereto.

Claims (9)

An enclosure cooling system comprising an internal heat exchanger, a riser pipeline, a polling pipeline, an isolation valve, a cooling water tank and an air-cooled condenser-
The internal heat exchanger is located in the upper space near the side wall in the inner layer concrete containment vessel,
The cooling water tank and the internal heat exchanger are connected to each other through a rising pipe line and a polling pipe line to constitute a closed circuit,
The air-cooled condenser-chiller is a case-less heat exchanger, which is located inside the cooling water tank, and the air-cooled condenser-chiller is installed so as to be inclined, and a part of the heat transfer tube of the air- ,
The air side inlet of the condenser-cooler is formed at a position near the bottom of the side wall of the water tank and communicates with the outside air atmosphere through the pipeline and the lower sealing head of the air-
The air side outlet of the condenser-cooler is formed at a position close to the upper surface of the side wall of the water tank. The upper sealing head of the air-cooled condenser-cooler and the annular space made of the inner layer concrete containment vessel and the outer concrete containment vessel are connected Wherein the containment vessel cooling system comprises: The method according to claim 1,
A watertight sealing device is connected to the side wall of the cooling water tank, the upper connection pipe of the watertight sealing device communicates with the steam space of the cooling water tank, the lower connection pipe communicates with the water space of the cooling water tank, Line by bridge connection. 3. The method according to claim 1 or 2,
Characterized in that the riser pipeline and the polling pipeline are equipped with valves on the inside and outside. A containment vessel cooling system and a reactor pressure vessel cooling system;
The containment vessel cooling system includes an internal heat exchanger, a riser pipeline, a polling pipeline, an isolation valve, a cooling water tank, and an air-cooled condenser-cooler, wherein the internal heat exchanger is located in an upper space close to the side wall in the innerlayer concrete containment, The cooling water tank and the internal heat exchanger are connected to each other through a rising pipe line and a polling pipe line to constitute a closed circuit, and the cooling water tank and the internal heat exchanger are connected to each other through an air cooling type condenser-cooler Cooled condenser-chiller is arranged to be inclined, a part of the heat transfer pipe of the air-cooled condenser-cooler is disposed in the water space, the other part is disposed in the vapor space, and the condensation- The air inlet of the cooler is located near the bottom of the side wall of the water tank And the air side outlet of the condenser-cooler is formed at a position close to the upper surface of the side wall of the water tank and communicates with the air-cooled condenser-cooler through the pipeline, Condensing-communicating with the annular space consisting of the upper sealing head of the cooler, the inner layer concrete containment vessel and the outer concrete containment vessel;
The reactor pressure vessel cooling system includes a water storage tank, a pressure equalizing tube, a water inlet, a water isolation tank, a control valve, a communicating tube, a condensate collecting tank, a water storage tank and an exhaust pipe, The reactor pressure vessel is located in the reactor water tank, and the condensate collector is connected to the lower portion of the internal heat exchanger through the communication pipe. And the condensate collecting tank is connected to the reservoir tank, the control tank and the isolation tank in sequence through a pipeline, and the associated cooling system of the reactor pressure vessel. 5. The method of claim 4,
Wherein the upper end of the pressure equalization tube is located in the vapor space of the water storage tank and the lower end relative position is higher than the upper edge of the reactor pressure vessel. 5. The method of claim 4,
Wherein the upper end of the water inlet is connected to the lowest point of the water storage tank and the lower end is lower than the lower edge of the pressure equalizing tube. 5. The method of claim 4,
Characterized in that the drainage port at the bottom of the water inlet has an "S" shape. 5. The method of claim 4,
Characterized in that a control valve is installed in the water inlet. 5. The method of claim 4,
Characterized in that the upper part of the reservoir tank communicates with the condensate collecting tank through an exhaust pipe and the blowdown valve is provided below the reservoir tank.

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