KR102280895B1 - Integrated type passive cooling system of nuclear power plant - Google Patents

Abstract

The present invention relates to an integrated passive cooling system for a nuclear power plant, a nuclear reactor building, an auxiliary building located on the side of the reactor building, and an upper portion of the auxiliary building, and a heat exchange fluid required for a reactor building cooling system and a steam generator auxiliary water supply system and a cooling water tank accommodating the cooling water tank, the cooling water tank having an accommodation space divided into at least three zones, a supplementary water tank occupying an upper space of the accommodation space, an auxiliary water supply tank formed at a lower position than the supplementary water tank, and a building cooling water tank It is a passive cooling system that improves the efficiency of the operation of the cooling water commonly used by each cooling system and increases the stability in case of an accident.

Description

Integrated type passive cooling system of nuclear power plant

The present invention relates to a passive cooling system of a nuclear power plant, and more particularly, to a cooling system for efficient operation of a heat exchange fluid used in a cooling system of a nuclear reactor building and an auxiliary water supply system of a steam generator.

The heat generated during nuclear power generation is cooled by a coolant, and it is common to use water as the coolant, and it has been found to be excellent in economy and safety. As a technology using water as a coolant, there are a light-water reactor and a heavy-water reactor, and in Korea, a pressurized light-water reactor is mainly operated as the light-water reactor.

A pressurized light water nuclear power plant has a reactor system that sends heat generated by nuclear fission to a steam generator for heat exchange, and a turbine/generator system that uses the steam generated from the steam generator to turn the turbine and then reduces it to water and circulates it back to the steam generator. is divided into In general, the coolant in the reactor system is heated to about 320 degrees Celsius in the reactor and pressurized to about 153 atmospheres to prevent boiling.

On the other hand, a virtual accident is considered in the design of a general nuclear power plant. In the event of a coolant loss accident in which the reactor coolant leaks out of the system, radioactive materials are discharged along with high-temperature and high-pressure steam from within the reactor building, which causes the temperature and pressure rises rapidly. At this time, a cooling system such as a reactor building spray system (water tank, pump, pipe, nozzle, valve, etc.) is provided to control the rising temperature and pressure, but power supply is essential for the operation of such a cooling system, and when power is lost There is a problem in that the operating time is limited and the use of the cooling system is limited because it is difficult for an operator to access when an accident occurs.

In addition, the auxiliary water supply system is a system that maintains the water level of the steam generator so that the reactor cooling system can be switched from a high temperature standby state to a stop state when an accident occurs in a nuclear power plant and the main water supply system cannot be operated. By condensing and recovering the steam generated in the steam generator, it is used to remove the decay heat of nuclear fuel. The conventional auxiliary water supply system performed a heat removal function using a condensate storage tank and an auxiliary water pump, but since this is also an active system, there is a problem of concern when power is lost.

As described above, the cooling system used in the conventional nuclear power plant has a problem in that the operational reliability of the system is lowered as an active device is used, and the operational efficiency is lowered because each system is operated individually.

Registered Patent Publication No. 10-1382256 (2014.04.01. Registered) Unexamined Patent Publication No. 10-2019-0067426 (registered on June 17, 2019)

The present invention relates to an integrated passive cooling system for a nuclear power plant, in which a cooling system of a nuclear reactor building and an auxiliary water supply system of a steam generator are configured as a passive system, and cooling water used in both systems is provided. is intended for

As an integrated passive cooling system of a nuclear power plant, it is located in a nuclear reactor building, an auxiliary building located on the side of the reactor building, and an upper part of the auxiliary building, and a cooling water tank that accommodates a heat exchange fluid required for the reactor building cooling system and the steam generator auxiliary water supply system. and the cooling water tank, the accommodation space is divided into at least three zones, and a supplementary water tank occupying an upper space of the accommodation space, and an auxiliary water supply tank and a building cooling water tank formed at a position lower than the supplementary water tank.

Preferably, the cooling water tank includes a water level control unit capable of transferring a heat exchange fluid by providing a pipe and a valve connecting the supplementary water tank and the auxiliary water supply tank or the supplementary water tank and the building cooling water tank.

Preferably, the reactor building cooling system may discharge heat inside the reactor building to the heat exchange fluid of the building cooling water tank by a heat exchanger located inside the reactor building, and the steam generator auxiliary water supply system is located inside the auxiliary water supply tank. The steam generated from the steam generator is converted into condensate by the located heat exchanger.

Preferably, the water level control unit automatically transfers the heat exchange fluid according to the level of the heat exchange fluid inside the auxiliary water supply tank or the building cooling water tank.

Preferably, the supplementary water tank includes an inlet that can be filled with a heat exchange fluid from the outside.

Preferably, the supplementary water tank includes an outlet for discharging the heat exchange fluid therein, and the outlet section is connected to a pipe provided with a valve to transfer the heat exchange fluid to a space outside the cooling water tank.

According to the present invention, even in the event of an accident in which power supply is impossible, cooling of a nuclear reactor building and supply of auxiliary water supply are possible quickly and stably, thereby improving the stability of the power plant.

In addition, since the use of active equipment is minimized, the reliability of the system operation is improved, and the cooling water of the supplementary water tank can be supplied to the external water source by the fire engine, so that it can be cooled for a long time.

In addition, since the reactor building cooling system and the auxiliary water supply system share the supplementary water tank while keeping the cooling water in separate spaces, when a problem occurs in each system, it does not affect the systems, increasing stability and improving the convenience of actions after an accident. do.

In addition, the cooling water required for each system can be freely distributed from one supplementary water tank, and the cooling water can be supplied quickly according to the cooling water consumption rate of each system, so efficient operation is possible.

In addition, the cooling water in the supplementary water tank can be used for various purposes within the nuclear power plant facility.

1 shows a cooling system according to an embodiment of the present invention.
2 is an enlarged view of a cooling water tank according to an embodiment of the present invention.
3 is a view showing a state of charging the cooling water of the supplementary water tank in the cooling system according to the embodiment of the present invention.

Specific structural or functional descriptions presented in the embodiments of the present invention are only exemplified for the purpose of describing embodiments according to the concept of the present invention, and the embodiments according to the concept of the present invention may be implemented in various forms. In addition, it should not be construed as being limited to the embodiments described herein, and should be understood to include all modifications, equivalents, and substitutes included in the spirit and scope of the present invention.

The terms used herein are used only to describe specific embodiments, and are not intended to limit the present invention. The singular expression includes the plural expression unless the context clearly dictates otherwise.

Hereinafter, the present invention will be described with reference to the accompanying drawings. In the description of the present invention, when it is determined that the description of a related known function or configuration may unnecessarily obscure the gist of the present invention, the description thereof is omitted.

1 shows a cooling system 100 according to an embodiment of the present invention. The cross-sections of the reactor building 110 , the auxiliary building 120 , and the cooling water tank 130 are conceptually shown, and the relative positions and operating relationships of each component are expressed.

Referring to FIG. 1 , the cooling system 100 according to an embodiment of the present invention is located on the side of the nuclear reactor building 110 in a shape surrounding the nuclear reactor building 110 and the nuclear reactor building 110 in which the upper part is formed in a dome shape. It may include an auxiliary building 120 that does. In addition, it is located in the upper part of the auxiliary building 120, and includes a cooling water tank 130 for accommodating the heat exchange fluid required for the reactor building cooling system and the steam generator auxiliary water supply system. In this case, it is preferable to use water (cooling water) as the heat exchange fluid.

Since the cooling water tank 130 is located above the auxiliary building 120 , the heat exchange fluid can be transferred into the building by the water head difference. It is preferable that the height at which the cooling water tank 130 is located has a suitable height that can supply the heat exchange fluid to the required place using the head difference. Since the upper part of the auxiliary building 120 also corresponds to the upper region of the outer peripheral surface of the reactor building 110 , the cooling water tank 130 can supply a heat exchange fluid into the reactor building. It is a passive type that can be operated even when power is lost, so operation reliability can be increased.

Referring to FIG. 2 , a detailed view of the cooling water tank 130 is shown. The shape of the cooling water tank 130 is shown as a rectangular cross section, but is not limited thereto.

The reactor building cooling system is a system that cools the reactor building by transferring heat inside the reactor building to the heat exchange fluid as the heat exchanger operates in the event of a nuclear accident, and the heat exchange fluid absorbing heat is recovered in the cooling water tank. In addition, the steam generator auxiliary water supply system is a cooling system that removes the decay heat of the core by condensing the steam generated from the steam generator during a nuclear accident and recovering it as condensed water.

The reactor building cooling system and the steam generator auxiliary water supply system include a cooling water tank 130 for accommodating a heat exchange fluid. The cooling water tank 130 may include a horizontal partition wall separating the inner accommodating space vertically and a vertical partition wall vertically separating the lower accommodating space separated by the horizontal partition wall again. Accordingly, the accommodation space of the cooling water tank 130 may be divided into three zones.

In this case, the upper accommodating space may be referred to as a supplementary water tank 131 , and the two lower accommodating spaces may be referred to as a building cooling water tank 133 or an auxiliary water supply tank 132 depending on functions.

The cooling water tank 130 may include a water level adjusting unit 150 connecting the supplementary water tank 131 and the building cooling water tank 133 or the supplementary water tank 131 and the auxiliary water supply tank 132 . The water level control unit 150 includes a pipe 151 and a valve 152 . Accordingly, the heat exchange fluid filled in the supplementary water tank 131 can be freely transferred to the building cooling water tank 133 or the auxiliary water supply tank 132 . Since the supplementary water tank 131 is formed at a higher position than the building cooling water tank 133 or the auxiliary water supply tank 132, the heat exchange fluid is transferred by the water head difference.

The valve 152 of the water level control unit 150 may be automatically operated in conjunction with the level of the heat exchange fluid in the building cooling water tank 133 or the auxiliary water supply tank 132 , and thereby the building cooling water tank 133 or the auxiliary water supply tank 132 . The tank 132 may maintain a stable water level. In addition, although not shown in the drawings, the cooling system 100 may include a water level adjusting unit connecting the building cooling water tank 133 and the auxiliary water supply tank 132 . In the cooling water tank 130 , the supplementary water tank 131 , the auxiliary water supply tank 132 , and the building cooling water tank 133 are connected to each other by the water level control unit 150 to freely exchange heat exchange fluid, so that the reactor The heat exchange fluid can be quickly supplied according to the consumption amount of the heat exchange fluid in the building cooling system or the steam generator auxiliary water supply system.

The building cooling water tank 133 receives the heat exchange fluid required in the reactor building cooling system. The heat exchanger 140 of the reactor building cooling system is located inside the reactor building 110 , and the heat exchange fluid in the building cooling water tank 133 circulates through the heat exchanger 140 and heats the inside of the reactor building 110 . absorb

The auxiliary water supply tank 132 accommodates the heat exchange fluid required for the steam generator auxiliary water supply system. The heat exchanger 141 is located inside the auxiliary water supply tank 132 , and the steam transferred along the pipe from the steam generator 160 is condensed through the heat exchanger 141 and recovered as condensed water.

The supplemental water tank 131 has an inlet through which a heat exchange fluid can be supplied, and the inlet is connected to a pipe 153 including a valve 154 to become a passage through which an external water source is supplied by a fire engine or the like. Referring to FIG. 3 , a state in which coolant is filled in the supplementary water tank 131 through a vehicle that supplies coolant is illustrated.

In addition, the supplemental water tank 131 may include an outlet for discharging the heat exchange fluid. The outlet portion may be connected to a pipe 155 including a valve 156 to supply a heat exchange fluid to a place where a water source is required inside the nuclear reactor building 110 or auxiliary building 120 (or nuclear fuel building). For example, cooling water may be supplied in an emergency to the spent fuel storage tank 180 located inside the auxiliary building 120 (or nuclear fuel building).

Since cooling water may be supplied by connecting pipes to other facilities as well as the reactor building 110 or the auxiliary building 120 , the cooling water contained in the supplementary water tank 131 may be utilized for various purposes.

In the present invention, the transfer of the cooling water is a passive system that does not require a separate power source since everything is driven by the head difference, except when the heat exchange fluid is supplied to the cooling water tank 130 .

The present invention described above is not limited by the above-described embodiments and the accompanying drawings, and it will be apparent to those skilled in the art that various substitutions, modifications, and changes are possible without departing from the technical spirit of the present invention.

100: cooling system according to an embodiment of the present invention
110: reactor building
120; auxiliary building
130: cooling water tank
131: replenishment tank
132: auxiliary water tank
133: building cooling water tank
140: reactor building internal heat exchanger
141: auxiliary water supply tank internal heat exchanger
150: water level control unit
151: plumbing
152: valve
153: inlet pipe
154: inlet valve
155: outlet pipe
156: outlet valve
160: steam generator
170: reactor
180: spent fuel storage tank

Claims (6)

An integrated passive cooling system for a nuclear power plant, comprising:
nuclear reactor building;
an auxiliary building located on the side of the reactor building; and
It is located on the upper part of the auxiliary building and includes a cooling water tank for accommodating the heat exchange fluid required for the reactor building cooling system and the steam generator auxiliary water supply system,
The cooling water tank,
It is divided into at least three zones by a horizontal bulkhead that vertically separates the receiving space of the heat exchange fluid and a vertical bulkhead that vertically separates the lower part of the receiving space separated by the horizontal bulkhead,
The upper space of the accommodating space is composed of a supplementary water tank, and each space of the separated lower part of the accommodating space is composed of an auxiliary water supply tank and a building cooling water tank,
It is composed of a pipe and a valve connecting the supplementary water tank, the auxiliary water supply tank, and the building cooling water tank, and a water level adjusting unit for automatically transferring the heat exchange fluid according to the heat exchange fluid level inside the auxiliary water supply tank or the building cooling water tank and
The replenishment tank is
An inlet portion capable of filling the heat exchange fluid from the outside and an outlet portion capable of discharging the heat exchange fluid therein, wherein the outlet portion is connected to a pipe equipped with a valve to transfer the heat exchange fluid to the spent fuel storage tank,
The reactor building cooling system is
The heat inside the reactor building may be discharged to the heat exchange fluid of the building cooling water tank by a heat exchanger located inside the reactor building,
The steam generator auxiliary water supply system,
A cooling system, characterized in that the steam generated in the steam generator is converted into condensed water by a heat exchanger located inside the auxiliary water supply tank. delete delete delete delete delete

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