KR102592739B1 - Leak measurement system for reactor coolant system - Google Patents

Abstract

Provides a nuclear reactor cooling system leakage measurement system. The nuclear reactor cooling system leak measurement system includes a first pipe through which leaked fluid flows through a pressure relief valve of the reactor cooling system; A condensate collection tank in which condensate based on the leaked fluid is collected; a second pipe installed to communicate between the first pipe and the condensate collection tank; a pressure release tank in communication with the first pipe, condensing vapor based on the leaked fluid and collecting the condensate; an initial leak monitoring unit installed on the first pipe to initially monitor leakage of the leaking fluid from the first pipe; a first valve installed on the first pipe and blocking the flow path of the first pipe to measure the leaked fluid; It includes a third pipe branched from the first pipe and installed to communicate with the first pipe and the second pipe, wherein the third pipe is configured to supply the condensate water to an inlet area branched from the first pipe. It includes an expansion pipe part extending from the first pipe to reinforce the collection, and a communication pipe part extending from the expansion pipe part and communicating with the second pipe.

Description

Leak measurement system for reactor coolant system}

The present invention relates to a nuclear reactor cooling system leak measurement system.

Nuclear power plants are equipped with safety relief valves to prevent over-pressurization of the reactor coolant system. The pressure relief valve installed directly in the reactor coolant system may leak reactor coolant if the valve's airtightness deteriorates. The leakage amount of reactor coolant is strictly controlled to ensure safe operation of the reactor. If the amount of leakage exceeds a certain level during normal operation of a nuclear power plant, the reactor must be manually stopped for safety reasons.

In addition, in nuclear power plants, a pipe is formed behind the valve outlet, and this pipe is connected to a pressure relief tank provided to collect condensate. The pressure relief tank not only collects leaks but also performs the function of condensing a large amount of vapor released when the pressure relief valve is normally opened. At this time, the size of the pressure relief tank must be sufficient to condense a large amount of steam. On the other hand, the amount of leakage that occurs when the valve is closed is very small compared to the amount of steam released when the valve is open, so it is difficult to quickly measure the amount of leakage flowing into a large-capacity pressure release tank, and the resolution of water level changes in the tank is poor. There is a problem with the reliability of measurement being low. In addition, even if a minute leak that does not affect the safety of the nuclear reactor occurs, if the leak amount cannot be measured at a certain time, it is treated as an unidentified leakage, and accordingly, the nuclear power plant must be manually stopped according to operating instructions. there is.

Korean Patent Publication No. 10-2011-0020515

The problem that the present invention aims to solve is that, in addition to the large-capacity pressure relief tank, a separate condensate collection tank is provided to collect a small amount of leakage, and in the case of a small leak, it is possible to quickly determine whether the operating instructions are violated, thereby enabling manual shutdown of the nuclear power plant. The purpose is to provide a nuclear reactor cooling system leakage measurement system that can prevent and operate power plants economically.

In addition, we provide a nuclear reactor cooling system leakage measurement system that can contribute to safe operation of the power plant by reducing the burden on operators to take action in the event of a leak, as it is possible to quickly identify whether the operating guidelines have been violated in the event of a microleak.

In addition, even if minute vapor leaks, it can be completely condensed through the condenser and condensation heat exchanger, so it provides a nuclear reactor cooling system leakage measurement system that can accurately measure the amount of leakage.

In addition, a reactor cooling system leakage measurement system equipped with bypass piping and rupture means can relieve pressure when the valve is opened while the downstream piping is isolated for leakage measurement, thereby maintaining the power plant in a safe state. It is provided.

In addition, with the introduction of a leakage measurement system, operators can immediately respond when a leak occurs, enabling real-time monitoring of the status of the power plant, enabling safe operation of the power plant, and improving the economic feasibility of the power plant by preventing manual shutdown. It provides a cooling system leak measurement system.

The problems of the present invention are not limited to the problems mentioned above, and other problems not mentioned will be clearly understood by those skilled in the art from the description below.

A nuclear reactor cooling system leak measurement system according to an aspect of the present invention for achieving the above problem includes a first pipe through which leaked fluid flows through a pressure relief valve of the reactor cooling system; A condensate collection tank in which condensate based on the leaked fluid is collected; a second pipe installed to communicate between the first pipe and the condensate collection tank; a pressure release tank in communication with the first pipe, condensing vapor based on the leaked fluid and collecting the condensate; an initial leak monitoring unit installed on the first pipe to initially monitor leakage of the leaking fluid from the first pipe; a first valve installed on the first pipe and blocking the flow path of the first pipe to measure the leaked fluid; It includes a third pipe branched from the first pipe and installed to communicate with the first pipe and the second pipe, wherein the third pipe is configured to supply the condensate water to an inlet area branched from the first pipe. It includes an expansion pipe part extending from the first pipe to reinforce the collection, and a communication pipe part extending from the expansion pipe part and communicating with the second pipe.

In addition, the initial leak monitoring unit performs a temperature value measurement and detects whether the leaking fluid is leaking based on whether the temperature value is measured above a preset value, and the first valve is configured to detect leakage of the leaking fluid from the initial leak monitoring unit. Based on the detection, a locking operation is performed to measure the leaked fluid, and the leaked fluid flows into the third pipe based on the locking action of the first valve.

In addition, it is provided on the communication pipe of the third pipe and further includes a condensation module for condensing leakage vapor based on the leakage fluid based on a heat exchange method.

Additionally, the condensate collection tank is provided to collect the condensate in an amount of 3 to 10 liters/min per hour.

In addition, the condensate collection tank includes a pressure value measuring unit that measures the pressure value of the leaking fluid, a temperature value measuring unit that measures the temperature value of the leaking fluid, and a real-time level value of the condensate filled therein. Includes a real-time water level measurement unit.

In addition, it further includes a fourth pipe installed to communicate the condensate collection tank and the pressure release tank, and an isolation valve to block communication of fluid on the fourth pipe, wherein the fourth pipe is connected to the condensate collection tank. A flow measuring unit is provided to measure the flow rate of the condensate flowing into the pressure relief tank, and the condensate collection tank independently measures the water level value of the condensate in real time based on the fluid communication blocking of the isolation valve.

In addition, the nuclear reactor cooling system leakage measurement system includes the first pipe, a 1-1 pipe that is one side of the first valve and a side from which the third pipe branches, and the pressure release tank that is the other side of the first valve. It includes a 1-2 pipe on the side facing, and the second pipe is installed to communicate between the 1-1 pipe of the first pipe and the condensate collection tank.

In addition, in a first state in which the first valve blocks the flow path of the first pipe to measure the leaked fluid, and the pressure release valve is opened to prevent overpressure in the reactor cooling system, the reactor cooling system In an overpressure discharge state that satisfies the second state in which the leaked fluid is discharged, the leaked fluid moves to the 1-2 pipe via the 1-1 pipe, the third pipe, and the second pipe.

In addition, on the second pipe, it prevents fluid movement to the 1-2 pipe in normal times, but is opened to the pressure of the leaking fluid in the overpressure discharge state, thereby allowing the leaked fluid to move to the 1-2 pipe. A leak prevention body is provided.

In addition, the leak prevention member is a disk-shaped body, and when the pressure of the leak fluid is applied, at least a part of the leak prevention member ruptures, thereby allowing the leak fluid to move to the 1-2 pipe.

A nuclear reactor cooling system leakage measurement system according to another aspect of the present invention for achieving the above object is a nuclear reactor cooling system leakage measurement system, comprising: a first pipe through which leaked fluid flowing through a pressure relief valve of the reactor cooling system flows; a condensate collection tank that communicates through the first pipe and collects condensate based on the leaked fluid; a pressure relief tank in which the vapor based on the leaked fluid is condensed and the condensate water is collected; a second pipe installed to communicate between the condensate collection tank and the pressure release tank; and a flow measuring unit for measuring the flow rate of the fluid passing through the second pipe, wherein the second pipe has a bent portion bent in a loop shape between the condensate collection tank and the flow measuring unit, and the condensate collection tank and the flow measuring unit include a flow measuring unit for measuring the flow rate of the fluid passing through the second pipe. The tank and the bent portion are provided in a fluid-filled state in which fluid is normally filled inside the condensate collection tank. When condensate based on the leaked fluid flows into the condensate collection tank through the first pipe, the condensate is collected by hydrostatic pressure. The internal fluid passes at least through the flow measurement unit through the bent portion, and the flow measurement unit measures the amount of leakage of the nuclear reactor cooling system by measuring the flow rate of the fluid passing through the bend.

Additionally, when the pressure relief valve is opened in the fluid filling state, vapor based on the leaked fluid flows into the pressure release tank along with the condensate via the condensate collection tank and the bent portion.

According to the nuclear reactor cooling system leak measurement system of the present invention as described above, the following effects are achieved or more.

The present invention is equipped with a separate condensate collection tank in addition to the large-capacity pressure relief tank to collect small amounts of leakage. In the case of microleakage, it is possible to quickly determine whether the operating instructions are violated, thereby preventing manual shutdown of the nuclear power plant and maintaining the power plant. It is possible to provide a nuclear reactor cooling system leakage measurement system that can be operated economically.

In addition, since it is possible to quickly identify whether operating guidelines are violated in the event of a micro-leak, it is possible to provide a reactor cooling system leak measurement system that can contribute to the safe operation of the power plant by reducing the operator's burden of taking action in the event of a leak.

In addition, even if minute vapor leaks, it can be completely condensed through the condenser and condensation heat exchanger, so it is possible to provide a nuclear reactor cooling system leakage measurement system that can accurately measure the amount of leakage.

In addition, a reactor cooling system leakage measurement system equipped with bypass piping and rupture means can relieve pressure when the valve is opened while the downstream piping is isolated for leakage measurement, thereby maintaining the power plant in a safe state. can be provided.

In addition, with the introduction of a leakage measurement system, operators can immediately respond when a leak occurs, enabling real-time monitoring of the status of the power plant, enabling safe operation of the power plant, and improving the economic feasibility of the power plant by preventing manual shutdown. A cooling system leak measurement system can be provided.

Figure 1 is a block diagram showing the configuration of a nuclear reactor cooling system leak measurement system according to an embodiment of the present invention.
FIG. 2 is a configuration diagram showing the configurations according to FIG. 1.
Figure 3 is a configuration diagram showing the configuration of a nuclear reactor cooling system leak measurement system according to another embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the attached drawings. The advantages and features of the present invention and methods for achieving them will become clear by referring to the embodiments described in detail below along with the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below and may be implemented in various different forms. The present embodiments are merely intended to ensure that the disclosure of the present invention is complete and to provide common knowledge in the technical field to which the present invention pertains. It is provided to fully inform those who have the scope of the invention, and the present invention is only defined by the scope of the claims. Like reference numerals refer to like elements throughout the specification.

Referring to Figures 1 and 2, the nuclear reactor cooling system leak measurement system 100 according to an embodiment of the present invention includes a nuclear reactor cooling system 50, a pressure release valve 55, a first pipe 110, and a first valve. (112), condensate collection tank (120), second pipe (130), pressure release tank (140), third pipe (160), condensation module (170), flow measurement unit (181), isolation valve (182) Includes.

Here, the third pipe 150 includes an expansion pipe portion 161 and a communication pipe portion 162. The condensate collection tank 120 includes a pressure value measurement unit 121, a temperature value measurement unit 122, and a real-time water level measurement unit 123.

The first pipe 110 receives leaked fluid through the pressure relief valve of the reactor cooling system 50. The condensate collection tank 120 collects condensate based on the leaked fluid.

In addition, the second pipe 130 is installed to communicate between the first pipe 110 and the condensate collection tank 120. The pressure release tank 140 is in communication with the first pipe 110, condenses vapor based on the leaked fluid, and collects the condensed water.

The initial leak monitoring unit 111 is installed on the first pipe 110 and initially monitors leakage of the leaking fluid from the first pipe 110. The first valve 112 is installed on the first pipe 110 and serves to block the flow path of the first pipe 110 to measure the leaking fluid.

Meanwhile, the third pipe 150 is branched from the first pipe 110 and is installed to communicate with the first pipe 110 and the second pipe 130. The expansion pipe portion 161 of the third pipe 150 extends from the first pipe 110 to reinforce the collection of condensate in the inlet area branching from the first pipe 110.

The communication pipe part 162 of the third pipe 150 extends from the expansion pipe part 161 and communicates with the second pipe 130. The initial leak monitoring unit 111 measures the temperature value and detects whether the leaking fluid is leaking based on whether the temperature value is measured above a preset value.

In addition, the first valve 112 performs a locking operation to measure the leaked fluid based on the leak detection of the leaked fluid by the initial leak monitoring unit 111. The leaked fluid flows into the third pipe 150 based on the locking operation of the first valve 112.

The condensation module 170 is provided on the communication pipe portion 162 of the third pipe 150 and condenses leakage vapor based on the leakage fluid based on a heat exchange method.

Here, the condensate collection tank 120 is provided to collect the condensate at a rate of 3 to 10 liters/min per hour. The pressure value measuring unit 121 of the condensate collection tank 120 measures the pressure value of the leaked fluid.

The temperature value measurement unit 122 of the condensate collection tank 120 measures the temperature value of the leaked fluid. The real-time water level measuring unit 123 of the condensate collection tank 120 measures the water level value of the condensate filled therein in real time.

Meanwhile, the fourth pipe 180 is installed to communicate with the condensate collection tank 120 and the pressure release tank 140. The isolation valve 182 serves to block communication of fluid on the fourth pipe 180.

The flow rate measurement unit 181 of the fourth pipe 180 measures the flow rate of the condensate flowing from the condensate collection tank 120 to the pressure release tank 140.

The condensate collection tank 120 independently measures the water level value of the condensate in real time based on the blocking of the fluid communication of the isolation valve 182.

Meanwhile, the 1-1 pipe 1101 of the first pipe 110 is one side of the first valve 112 and corresponds to a portion where the third pipe 150 branches. The first-second pipe section 1102 of the first pipe 110 is the other side of the first valve 112 and corresponds to the side facing the pressure release tank 140.

The second pipe 130 is installed to communicate with the 1-1 pipe 1101 of the first pipe 110 and the condensate collection tank 120.

Regarding the measurement of leaked fluid, the nuclear reactor cooling system leak measurement system according to an embodiment of the present invention is a device in which the first valve 112 blocks the flow path of the first pipe 110 to measure the leaked fluid. It can be in state 1.

In addition, the pressure relief valve may be opened to prevent overpressure of the reactor cooling system 50, resulting in a second state in which the leaked fluid is discharged from the reactor cooling system 50.

In the overpressure discharge state that satisfies the first state and the second state, the leaked fluid passes through the first pipe 1101, the third pipe 150, and the second pipe 130. It moves to the 1-2 pipe (1102).

On the second pipe 130, fluid movement to the 1-2 pipe 1102 is prevented in normal times, but by being opened to the pressure of the leaking fluid in the overpressure discharge state, the leaked fluid is prevented from flowing into the 1-2 pipe. A leak prevention body 131 is provided to allow movement to (1102).

Here, the leak prevention body 131 is a disk-shaped body, and when the pressure of the leaking fluid is applied, at least part of it ruptures, thereby allowing the leaking fluid to move to the 1-2 pipe 1102.

Below, the description will be based on the above-described embodiment, focusing on parts with technical features.

Referring to FIG. 3, the nuclear reactor cooling system leak measurement system 100 according to another embodiment of the present invention has a first pipe 110 in which leaked fluid flows through the pressure release valve of the reactor cooling system 50. do.

In addition, the condensate collection tank 120 is communicated through the first pipe 110, and condensate water based on the leaked fluid is collected. Pressure relief tank 140 condenses vapor based on the leaked fluid and collects the condensed water. The second pipe 130 is installed to communicate between the condensate collection tank 120 and the pressure release tank 140.

The flow measurement unit 181 is provided to measure the flow rate of fluid passing through the second pipe 130. The second pipe 130 has a bent portion 1301 bent in a loop shape between the condensate collection tank and the flow rate measurement unit.

The condensate collection tank 120 and the bent portion 1301 are provided in a fluid-filled state in which fluid is normally filled therein. The condensate collection tank 120 is configured such that when condensate based on the leaked fluid flows into the condensate collection tank 120 through the first pipe 110, the fluid inside is moved to the bent portion 1301 by hydrostatic pressure. It passes through at least the flow measurement unit 181.

Here, the flow measurement unit 181 is capable of measuring the amount of leakage of the reactor cooling system 50 by measuring the flow rate of the fluid passing through. That is, when the pressure release valve is opened in the fluid filling state, the vapor based on the leaked fluid passes through the condensate collection tank 120 and the bent portion 1301 along with the condensate to the pressure release tank ( 140).

Although embodiments of the present invention have been described with reference to the above and the attached drawings, those skilled in the art will understand that the present invention can be implemented in other specific forms without changing the technical idea or essential features. You will understand that it exists. Therefore, the embodiments described above should be understood in all respects as illustrative and not restrictive.

50: Reactor cooling system
55: Pressure release valve
110: 1st pipe
120: Condensate collection tank
130: Second pipe
140: Pressure release tank

Claims (10)

As a nuclear reactor cooling system leak measurement system,
a first pipe through which leaked fluid flows through the pressure relief valve of the reactor cooling system;
A condensate collection tank in which condensate based on the leaked fluid is collected;
a second pipe installed to communicate between the first pipe and the condensate collection tank;
a pressure release tank in communication with the first pipe, condensing vapor based on the leaked fluid and collecting the condensate;
an initial leak monitoring unit installed on the first pipe to initially monitor leakage of the leaking fluid from the first pipe;
a first valve installed on the first pipe and blocking the flow path of the first pipe to measure the leaked fluid; and
It includes a third pipe branched from the first pipe and installed to communicate with the first pipe and the second pipe,
The third pipe is,
an expansion pipe extending from the first pipe to reinforce collection of the condensate in an inlet area branching from the first pipe;
A nuclear reactor cooling system leak measurement system comprising a communication pipe extending from the expansion pipe and communicating with the second pipe. According to paragraph 1,
The initial leak monitoring unit,
By measuring the temperature value, it detects whether the leaking fluid is leaking based on whether the temperature value is measured above the preset value,
The first valve is,
Based on the leakage detection of the leakage fluid by the initial leakage monitoring unit, a locking operation is performed to measure the leakage fluid,
The third pipe is,
A nuclear reactor cooling system leak measurement system in which the leaked fluid flows in based on the locking operation of the first valve. According to paragraph 2,
A nuclear reactor cooling system leak measurement system provided on the communication pipe of the third pipe and further comprising a condensation module for condensing leaked vapor based on the leaked fluid based on a heat exchange method. According to paragraph 2,
The condensate collection tank is,
A nuclear reactor cooling system leak measurement system provided to collect the condensate in an amount of 3 to 10 liters/min per hour. According to paragraph 3,
The condensate collection tank is,
A pressure value measuring unit that measures the pressure value of the leaked fluid,
A temperature value measuring unit that measures the temperature value of the leaked fluid,
A nuclear reactor cooling system leak measurement system comprising a real-time water level measurement unit that measures the water level of the condensate filled inside in real time. According to clause 5,
A fourth pipe installed to communicate with the condensate collection tank and the pressure release tank,
It further includes an isolation valve to block communication of fluid on the fourth pipe,
The fourth pipe is provided with a flow measuring unit that measures the flow rate of the condensate flowing from the condensate collection tank to the pressure release tank,
A nuclear reactor cooling system leakage measurement system, wherein the condensate collection tank independently measures the water level value of the condensate in real time based on the isolation valve's blocking of communication with the fluid. According to clause 6,
The reactor cooling system leakage measurement system is,
The first pipe is,
A 1-1 pipe on one side of the first valve and on the side where the third pipe branches off,
The other side of the first valve includes a 1-2 pipe that faces the pressure release tank,
The second pipe is,
A nuclear reactor cooling system leak measurement system installed to communicate between the 1-1 pipe of the first pipe and the condensate collection tank. In clause 7,
A first state in which the first valve blocks the flow path of the first pipe to measure the leaking fluid, and
In an overpressure discharge state that satisfies a second state in which the pressure relief valve is opened to prevent overpressure of the reactor cooling system, and the leaked fluid is discharged from the reactor cooling system,
The leakage fluid is moved to the 1-2 pipe via the 1-1 pipe, the 3rd pipe, and the 2nd pipe. As a nuclear reactor cooling system leak measurement system,
a first pipe through which leaked fluid flows through the pressure relief valve of the reactor cooling system;
a condensate collection tank that communicates through the first pipe and collects condensate based on the leaked fluid;
a pressure relief tank in which the vapor based on the leaked fluid is condensed and the condensate water is collected;
a second pipe installed to communicate between the condensate collection tank and the pressure release tank; and
It includes a flow measurement unit for measuring the flow rate of fluid passing through the second pipe,
The second pipe is formed with a bent portion bent in a loop shape between the condensate collection tank and the flow measurement unit,
The condensate collection tank and the bent portion are provided in a fluid-filled state in which fluid is normally filled inside,
The condensate collection tank is,
When condensate based on the leaked fluid flows into the condensate collection tank through the first pipe, the fluid inside passes at least the flow measurement unit through the bent portion due to hydrostatic pressure,
A nuclear reactor cooling system leakage measurement system in which the flow measurement unit measures the amount of leakage of the nuclear reactor cooling system by measuring the flow rate of the fluid passing through. According to clause 9,
When the pressure relief valve is opened in the fluid filling state, vapor based on the leaked fluid flows into the pressure release tank through the condensate collection tank and the bend along with the condensate, a nuclear reactor cooling system leak measurement system. .