KR102539328B1 - System and method for draining nuclear chemical and volume control system - Google Patents

Abstract

The present invention relates to a drainage system and a drainage method for a chemical and volume control system for efficiently discharging system water of a chemical and volume control system.
According to an embodiment of the present invention, as the procedure for draining the coolant system water is simplified and a plurality of manual valves are replaced with automatic valves, multiple operations are simplified to reduce human errors that frequently occur when the coolant system water is discharged. There are possible effects.
In addition, according to an embodiment of the present invention, by forcibly recovering the coolant system water through the forced drain pump, it is possible to quickly recover the entire amount of the coolant system water introduced into the coolant system and a plurality of circulation lines and drain lines, Compared to the drainage method, the discharge time of the coolant system water can be shortened, so the work time can be shortened and the maintenance cost can be reduced.
In addition, according to an embodiment of the present invention, when the coolant system water is discharged, the entire amount of the coolant system water is recovered and reused in the reactor drain tank, so that not only can a large amount of liquid waste generated during gravity drainage be remarkably reduced, but also chemical (boric acid) : Boric acid) has the effect of reducing the cost of expensive coolant system water.

Description

Chemical and volume control system drainage system and drainage method {SYSTEM AND METHOD FOR DRAINING NUCLEAR CHEMICAL AND VOLUME CONTROL SYSTEM}

The present invention relates to a drainage system and a drainage method for a chemical and volume control system for efficiently discharging system water of a chemical and volume control system.

Nuclear power plants usually consist of systems with more than 100 individual functions. These are largely divided into a nuclear steam supply system centered on a nuclear reactor, a turbine that receives this steam and turns a generator, a generator system, and other auxiliary facilities.

Here, the nuclear reactor has a function to utilize nuclear energy in real life by adjusting a large amount of energy instantaneously released during a nuclear explosion to be gradually released. It is a device made to be used for various purposes, such as producing radioactive isotopes and plutonium, or forming radiation fields.

Meanwhile, in the safety system reflected in the nuclear power plant, a certain flow rate is formed between the Chemical & Volume Control System (hereinafter referred to as CVCS) and the coolant system (hereinafter referred to as RCS) during normal operation of the power plant. System operation to secure the safety of the power plant is in progress.

Here, as shown in FIG. 1, the RCS is sent to the Volume Control Tank (VCT) through the RCS Letdown system connected to Loop 1B, and the RCS collected here is sent to the loop of the RCS by the charging pump. It is sent back to RCS through the charging system connected to 1A.

Meanwhile, in order to disassemble and inspect the control valve, which also performs a key function in the CVCS, during the maintenance period of nuclear power plants, the system water is drained in the isolated state of the system section for the relevant work valve, and maintenance is performed according to the prescribed procedures and conditions. .

At this time, the stock quantity maintenance (pressurizer level control) control valve of the RCS, where disassembly and inspection is mainly performed, is V515 (L/D ISO.VV), V516 (L/D ISO.VV), V523 (L/D ISO.VV), V526(L/D C/V BYPASS VV), 110Q(L/D CTRL BYPASS VV), 110P(L/D CTRL VV), 201P(L/D BACK PR CTRL BYPASS VV), 201Q(L/D PR CTRL VV ) are provided as a total of 8 control valves and are designed to secure the safety of RCS and CVCS.

However, in the case of the conventional coolant system drainage system, there are the following problems when considering the section system isolation and recovery period and the safety and economy of power plant operation.

First, for disassembly and inspection of the CVCS control valve, it is possible to start the next work after completely draining the system water. Human error factors occur frequently.

Second, after section system isolation, drainage of the system tree proceeds with natural drainage using gravity. At this time, as the gravity drainage time is delayed due to the complicated structure and shape of the system piping, delayed cases of starting work frequently occur.

Third, CVCS system water is sent to the sump installed in the power plant without re-sulfurization of expensive system water with chemicals (boric acid: boric acid) added. Therefore, a lot of liquid waste is generated, which causes a lot of waste processing. There is a problem that cost and manpower must be input.

Korean Registered Patent No. 10-0584835 (registration date: 2006. 05. 23)

Accordingly, the present invention has been devised from the foregoing background, and an object of the present invention is to simplify the procedure for draining the coolant system water and replace a plurality of manual valves with automatic valves, thereby simplifying multiple operations and It is to reduce human errors that frequently occur during discharge.

In addition, an object of the present invention is to quickly recover the entire amount of the coolant system water introduced into the coolant system and a plurality of circulation lines and drain lines by forcibly recovering the coolant system water through a forced drain pump, and compared to the existing gravity drain method, the coolant system water It is to shorten the discharge time and shorten the working time.

The object of the present invention is not limited thereto, and other objects not mentioned will be clearly understood by those skilled in the art from the description below.

In order to solve this problem, an embodiment of the present invention provides a first circulation line CL1 connected to the outlet circulation line L of the coolant system 10 when the coolant system water of the nuclear reactor is discharged, and the first circulation line CL1. A second circulation line CL2 connected to the line CL1, a third circulation line CL3 and a fourth circulation line CL4 connected to the second circulation line CL2, respectively, and the third circulation line A circulation line (CL) into which coolant system water flows from the outlet side circulation line (L) of the coolant system (10) including a fifth circulation line (CL5) connected to (CL3); A first drain line DL1 connected to the fifth circulation line CL5 and a second drain line DL2 connected to the first drain line DL1, wherein the coolant flow from the circulation line CL A drain line (DL) through which the inlet is discharged; a reactor drain tank (T) connected to the second drain line (DL2) and storing coolant system water discharged through the drain line (DL); The first separation valve (IV1) installed at the end of the first circulation line (CL1), the second separation valve (IV2) installed at the end of the third circulation line (CL3), and the fourth circulation line ( A third isolation valve (IV3) installed at the end of CL4) and a fourth isolation valve (IV4) installed at the end of the second drain line (DL2), but when the coolant system water of the nuclear reactor is discharged, the circulation line (CL) and a separation valve (IV) closed so that coolant system water does not flow through the drain line (DL); A first drain valve DV1 installed in the first circulation line CL1, a second drain valve DV2 installed in the second circulation line CL2, and installed in the fifth circulation line CL5. a third drain valve (DV3) and a fourth drain valve (DV4) installed on the first drain line (DL1), but when the coolant system water of the nuclear reactor is discharged, the circulation line (CL) and the drain line ( a drain valve (DV) opened so that the coolant system water is discharged to the reactor drain tank (T) through DL); A first circulation valve (CV1) installed between the first separation valve (IV1) and the first drain valve (DV1), the second circulation line (CL2), the third circulation line (CL3) and and a second circulation valve (CV2) installed at an end of the fourth circulation line (CL4) and connecting the second circulation line (CL2), the third circulation line (CL3), and the fourth circulation line (CL4). circulation valve (CV); a forced drain pump (EP) installed at an end of the fifth circulation line (CL5) to forcibly drain the coolant system water injected into the coolant system (10) to the reactor drain tank (T); and the forcibly drained coolant system water installed between the forced drain pump EP and the first drain line DL1 through the first drain line DL1 and the second drain line DL2 to the reactor drain tank. It provides a drainage system of a chemical and volume control system including; a drain connection line (DH) to be introduced into (T).

In addition, one embodiment of the present invention, in the method of draining the coolant system water through the drainage system of the chemical and volume control system, (a) opening a plurality of control valves installed in the coolant system (10); (b) opening the first circulation valve (CV1), the second circulation valve (CV2), the first drain valve (DV1) and the second drain valve (DV2); (c) closing the first separation valve (IV1), the second separation valve (IV2), the third separation valve (IV3), and the fourth separation valve (IV4); (d) installing the forced drainage pump (EP) at an end of the fifth circulation line (CL5); (e) connecting the circulation line (CL) and the drain line (DL) by installing the drain connection line (DH) between the forced drain pump (EP) and the first drain line (DL1); and (f) opening the third drain valve DV3 and the fourth drain valve DV4 to discharge the coolant system water of the coolant system 10 through the forced drain pump EP to the reactor drain tank T ) Provides a drainage method of a chemical and volume control system, characterized in that it comprises a; forcibly draining.

According to an embodiment of the present invention, as the procedure for draining the coolant system water is simplified and a plurality of manual valves are replaced with automatic valves, multiple operations are simplified to reduce human errors that frequently occur when the coolant system water is discharged. There are possible effects.

In addition, according to an embodiment of the present invention, by forcibly recovering the coolant system water through the forced drain pump, it is possible to quickly recover the entire amount of the coolant system water introduced into the coolant system and a plurality of circulation lines and drain lines, Compared to the drainage method, the discharge time of the coolant system water can be shortened, so the work time can be shortened and the maintenance cost can be reduced.

In addition, according to an embodiment of the present invention, when the coolant system water is discharged, the entire amount of the coolant system water is recovered and reused in the reactor drain tank, so that not only can a large amount of liquid waste generated during gravity drainage be remarkably reduced, but also chemical (boric acid) : Boric acid) has the effect of reducing the cost of expensive coolant system water.

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

1 is a system summary diagram showing a chemical & volume control system and a reactor coolant system of a Korean standard nuclear power plant.
FIG. 2 is a system summary diagram showing the reactor coolant system of FIG. 1 .
3 is a system summary diagram showing a drainage system of a chemical and volume control system according to an embodiment of the present invention for draining the coolant system water of the coolant system of FIG. 1.
4 is a view showing a forced drainage pump according to an embodiment of the present invention.
5 is a flow chart of a drainage method of a chemical and volume control system according to an embodiment of the present invention.

Hereinafter, some embodiments of the present invention will be described in detail through exemplary drawings. In adding reference numerals to components of each drawing, it should be noted that the same components have the same numerals as much as possible even if they are displayed on different drawings. In addition, in describing the present invention, if it is determined that a detailed description of a related known configuration or function may obscure the gist of the present invention, the detailed description will be omitted.

Also, terms such as first, second, A, B, (a), and (b) may be used in describing the components of the present invention. These terms are only used to distinguish the component from other components, and the nature, order, or order of the corresponding component is not limited by the term. When an element is described as being “connected,” “coupled to,” or “connected” to another element, that element is directly connected or connectable to the other element, but there is another element between the elements. It will be understood that elements may be "connected", "coupled" or "connected".

1 is a system summary diagram showing a chemical & volume control system and a reactor coolant system of a Korean standard nuclear power plant.

FIG. 2 is a system summary diagram showing the reactor coolant system of FIG. 1 .

3 is a system summary diagram showing a drainage system of a chemical and volume control system according to an embodiment of the present invention for draining the coolant system water of the coolant system of FIG. 1.

4 is a view showing a forced drainage pump according to an embodiment of the present invention.

5 is a flow chart of a drainage method of a chemical and volume control system according to an embodiment of the present invention.

The drainage system 20 of the chemical and volume control system according to an embodiment of the present invention is installed in the coolant system 10 of a nuclear power plant to quickly and efficiently discharge coolant system water. It can be installed in a Korean standard nuclear power plant.

Hereinafter, each configuration of the present invention will be described in detail through an example in which the drainage system 20 of the chemical and volume control system of the present invention is applied to a Korean standard nuclear power plant.

As shown in these figures, the drainage system 20 of the chemical and volume control system according to an embodiment of the present invention, when the coolant system water of the nuclear reactor is discharged, the outlet side circulation line (L) of the coolant system 10 and A first circulation line CL1 connected thereto, a second circulation line CL2 connected to the first circulation line CL1, a third circulation line CL3 connected to the second circulation line CL2, and a second circulation line CL3 connected to the second circulation line CL2. A circulation line including a fourth circulation line (CL4) and a fifth circulation line (CL5) connected to the third circulation line (CL3), into which coolant system water flows from the outlet circulation line (L) of the coolant system (10). (CL); A first drain line DL1 connected to the fifth circulation line CL5 and a second drain line DL2 connected to the first drain line DL1 are included, and coolant system water flows in from the circulation line CL. Discharged drain line (DL); a reactor drain tank (T) connected to the second drain line (DL2) and storing coolant system water discharged through the drain line (DL); The first separation valve IV1 installed at the end of the first circulation line CL1, the second separation valve IV2 installed at the end of the third circulation line CL3, and the fourth circulation line CL4. A third isolation valve (IV3) installed at the end and a fourth isolation valve (IV4) installed at the end of the second drain line (DL2), but when the coolant system water of the nuclear reactor is discharged, the circulation line (CL) and drain an isolation valve (IV) closed so that the coolant system water is not leaked through the line (DL); The first drain valve DV1 installed in the first circulation line CL1, the second drain valve DV2 installed in the second circulation line CL2, and the third drain valve DV2 installed in the fifth circulation line CL5. Including the drain valve DV3 and the fourth drain valve DV4 installed in the first drain line DL1, but when the coolant system water of the nuclear reactor is discharged, the coolant system water is passed through the circulation line CL and the drain line DL. a drain valve (DV) opened to be discharged to the reactor drain tank (T); The first circulation valve (CV1) installed between the first separation valve (IV1) and the first drain valve (DV1), the second circulation line (CL2), the third circulation line (CL3), and the fourth circulation line (CL4) A circulation valve (CV) including a second circulation valve (CV2) installed at an end of the ) and connecting the second circulation line (CL2), the third circulation line (CL3), and the fourth circulation line (CL4); A forced drain pump (EP) installed at an end of the fifth circulation valve (CL5) to forcibly drain the coolant system water injected into the coolant system 10 to the reactor drain tank (T); and the forced drained coolant system water installed between the forced drain pump (EP) and the first drain line (DL1) flows into the reactor drain tank (T) through the first drain line (DL1) and the second drain line (DL2). It is characterized by including a; drain connection line (DH) to be.

First, the circulation line CL is connected to the outlet circulation line L of the coolant system 10 when the coolant system water of the nuclear reactor is discharged, and the coolant system water flows in from the outlet circulation line L of the coolant system 10. do.

The circulation line CL includes the first circulation line CL1 to the fifth circulation line CL5.

First, the first circulation line CL1 is connected to the outlet side circulation line L of the coolant system 10 when the coolant system water of the nuclear reactor is discharged, and the coolant system water flows in from the coolant system 10 .

As described above, the coolant system 10 may be the coolant system 10 of the Korean standard nuclear power plant.

In addition, a first drain valve DV1 is installed at the inlet side of the first circulation line CL1, and a first isolation valve IV1 is installed at the outlet side. The first drain valve DV1 and the first isolation valve IV1 are installed. ) Between the first circulation valve (CV1) is installed.

Here, another circulation line may be connected to the outlet side of the first circulation line CL1.

Subsequently, the second circulation line CL2 is connected to the first circulation line CL1 so that when the coolant system water of the nuclear reactor is discharged, the coolant system water flows in from the first circulation line CL1.

One end of the second circulation line CL2 is connected to the first circulation line CL1, the other end is connected to the second circulation valve CV2, and a second drain valve DV2 is installed.

Also, the third circulation line CL3 has one end connected to the second circulation valve CV2 so as to be connected to the second circulation line CL2, and a second isolation valve IV2 is installed at the other end, which is the outlet side. .

Here, another circulation line may be connected to the outlet side of the third circulation line CL3.

Then, the fourth circulation line CL4 is connected to the second circulation line and the third circulation line, so that one end is connected to the second circulation valve CV2 and the third separation valve IV3 is connected to the other end, which is the outlet side. installed

Here, the outlet side of the fourth circulation line CL4 may be connected to other circulation lines.

The fifth circulation line CL5 has one end connected to the third circulation line CL3 and a forced drain pump EP installed at the other end.

In addition, a third drain valve DV3 is installed in the fifth circulation line CL5.

Subsequently, one side of the drain line DL is connected to the circulation line CL, and the other side is connected to the reactor drain tank T, so that the coolant system water supplied from the circulation line CL is transferred to the reactor drain tank T. emit with

The drain line DL includes a first drain line DL1 and a second drain line DL2.

The first drain line (DL1) is connected to the fifth circulation line (CL5) through the drain connection line (DH) and the forced drain pump (EP), more specifically, one end is connected to the drain connection line (DH) and the other end The end is connected to the second drain line DL2 so that the coolant system water introduced from the drain connection line DH flows into the second drain line DL2.

A fourth drain valve DV4 is installed in the first drain line DL1.

In addition, the second drain line DL2 has one side connected to the first drain line DL1 and the other end connected to the reactor drain tank T so that the coolant system water supplied from the first drain line DL1 is transferred to the reactor drain tank. (T).

Subsequently, the reactor drain tank T of the present invention is connected to the second drain line DL2 to store coolant flow water discharged through the drain line DL.

In addition, the reactor drain tank T is connected to a nitrogen supply line NL, and a nitrogen supply valve NV is installed in the nitrogen supply line NL.

The nitrogen supply valve (NV) removes the nitrogen pressure in the reactor drain tank (T) to reduce the inflow resistance of the coolant system water flowing into the reactor drain tank (T).

All of the coolant system water introduced into the reactor drain tank T is recovered through the reactor drain tank T and reused through purification and boric acid injection processes.

As such, in one embodiment of the present invention, when the coolant system water is discharged, the entire amount of the coolant system water is recovered and reused in the reactor drain tank, so that not only can a large amount of liquid waste generated during gravity drainage be remarkably reduced, but also chemicals (Boric Acid: Boric acid) has the effect of reducing the cost of expensive coolant system water.

On the other hand, the separation valve IV according to an embodiment of the present invention prevents the coolant system water from flowing out to other circulation lines through the circulation line CL and the drain line DL when the coolant system water of the nuclear reactor is discharged. (CL) and drain line (DL) are closed.

The separation valve (IV) includes the first separation valve (IV1) to the fourth separation valve (IV4).

First, the first separation valve IV1 is installed at the end of the first circulation line CL1.

When the coolant system water is discharged, the first separation valve IV1 closes the outlet side end of the first circulation line CL1 so that the coolant system water does not flow to another circulation line (not shown) through the first circulation line CL1. shut down

That is, when the coolant system water is discharged, the first separation valve IV1 prevents the coolant system water from flowing out to other circulation lines and allows the coolant system water to flow into the second circulation line CL2.

Also, the second separation valve IV2 is installed at the end of the third circulation line CL3.

When the coolant system water is discharged, the second separation valve IV2 closes the outlet side end of the third circulation line CL3 so that the coolant system water does not flow to another circulation line (not shown) through the third circulation line CL3. shut down

That is, when the coolant system water is discharged, the second isolation valve IV2 prevents the coolant system water from flowing out to other circulation lines and allows the coolant system water to flow into the fifth circulation line CL5.

Subsequently, the third isolation valve IV3 is installed at the end of the fourth circulation line CL4.

The third separation valve IV3 closes the outlet side end of the fourth circulation line CL4 so that the coolant system water flows into the drain line DL through the fifth circulation line CL5 when the coolant system water is discharged.

That is, the third separation valve IV3 prevents coolant system water from flowing into other circulation lines through the fourth circulation line CL4.

And, the fourth separation valve (IV4) is installed at the end of the second drain line (DL2).

When the coolant system water is discharged, the fourth separation valve IV4 closes the outlet side end of the second drain line DL2 so that the coolant system water introduced from the first drain line DL1 is discharged to the reactor drain tank T. shut down

As described above, in one embodiment of the present invention, as the separation valve (IV) installed at the outlet end of the circulation line (CL) and the drain line (DL) is provided, when the coolant system water is discharged, each circulation line (CL and The entire coolant system water can be recovered by preventing the coolant system water from flowing out to other circulation lines through the drain line (DL).

Subsequently, the drain valve DV according to an embodiment of the present invention is opened so that the coolant system water is discharged to the reactor drain tank T through the circulation line CL and the drain line DL when the coolant system water is discharged. .

The drain valve DV includes a first drain valve DV1 to a fourth drain valve DV4. First, the first drain valve DV1 is installed in the first circulation line CL1.

The first drain valve DV1 is installed in the first circulation line CL1 and opens the first circulation line CL1, so that when the coolant system water is discharged, the coolant system water introduced into the first circulation line CL1 is discharged into the second circulation line CL1. Let it flow into the circulation line (CL2).

Also, the second drain valve DV2 is installed in the second circulation line CL2.

The second drain valve DV2 is configured to allow the coolant system water introduced from the first circulation line CL1 to the second circulation line CL2 to flow into the third circulation line CL3 and the fourth circulation line CL4. Open the circulation line (CL2).

Also, the third drain valve DV3 is installed in the fifth circulation line CL5 and opens the fifth circulation line CL5 when the coolant system water is discharged.

That is, the third drain valve DV3 is opened when the coolant system water is discharged, and the coolant system water flowing into the fifth circulation line through the first circulation line CL1 and the second circulation line CL2 flows into the drain line DL. The fifth circulation line CL5 is opened so that it flows out.

Next, the fourth drain valve DV4 is installed in the first drain line DL1 and opens the first drain line DL1 when the coolant system water is discharged.

That is, the fourth drain valve DV4 is opened when the coolant system water is discharged so that the coolant system water introduced from the drain connection line DH flows into the reactor drain tank T via the second drain line DL2. Line DL1 is opened.

Subsequently, a circulation valve (CV) according to an embodiment of the present invention is installed in the circulation line (CL), and this circulation valve (CV) includes a first circulation valve (CV1) and a second circulation valve (CV2). do.

First, the first circulation valve CV1 is installed in the first circulation line CL1.

That is, the first circulation valve CV1 is disposed between the first separation valve IV1 and the first drain valve DV1 so that the coolant system water of the first circulation line CL1 flows into the second circulation line CL2. It is open.

And, the second circulation valve (CV2) is installed at the ends of the second circulation line (CL2), the third circulation line (CL3), and the fourth circulation line (CL4), the second circulation line (CL2) and the third circulation line (CL3) and the fourth circulation line (CL4) are connected.

The second circulation valve CV2 is opened when the coolant system water is discharged so that the coolant system water introduced from the second circulation line CL2 flows into the third circulation line CL3 and the fourth circulation line CL4.

Meanwhile, the isolation valve (IV), the drain valve (DV) and the circulation valve (CV) according to an embodiment of the present invention may be composed of automatic valves. As such, the isolation valve (IV), the drain valve (DV) and the circulation valve Since (CV) is made of an automatic valve, one embodiment of the present invention has the effect of improving work efficiency and shortening work time.

Subsequently, the forced drain pump EP is installed at the end of the fifth circulation line CL5 to forcibly drain the coolant system water injected into the coolant system 10 to the reactor drain tank T.

The forced drain pump (EP) is installed at the outlet side end of the circulation line (CL), and the coolant system water injected into the coolant system (10) is discharged to the reactor drain tank (T) through the circulation line (CL) and the drain line (DV). Forced drainage with

Describing the structure of the forced drain pump (EP) in more detail, the forced drain pump (EP) is a pressure gauge installed at the inlet side to which the fifth circulation line (CL5) is connected and measuring the pressure of the incoming coolant system water ( PG); and a confirmation window (W) installed on the outlet side to which the first drain line DL1 is connected and for checking the flow rate of the drained coolant system water.

As such, the forced drain pump (EP) of the present invention is provided with a pressure gauge (PG) and a confirmation window (W), so that the pressure and flow rate of the coolant system water can be checked, and the forced drain pump (EP ) can be controlled.

Subsequently, the drain connection line (DH) is installed between the forced drain pump (EP) and the first drain line (DL1), and the coolant system water forcibly drained by the forced drain pump (EP) flows into the drain line (DL). Connect the forced drain pump (EP) and the drain line (DL) as much as possible.

This drain connection line (DH) may be made of a metal flexible hose (Metal Flexible Hose) to facilitate installation, for example.

On the other hand, in the drainage system 20 of the chemical and volume control system according to an embodiment of the present invention, a water level gauge ( WG);

The water level gauge (WG) is connected to the reactor drain tank (T) through the water level gauge connection line (WGL) and detects the level of the coolant system water drained to the reactor drain tank (T) when the coolant system water is forcibly drained. In the embodiment, since the water level gauge (WG) is provided, overflow of coolant system water drained into the reactor drain tank (T) can be prevented in advance.

On the other hand, in the drainage method 30 of the chemical and volume control system of the present invention, in the method of draining the coolant system water through the drainage system 20 of the chemical and volume control system described above, (a) the coolant system 10 Opening a plurality of control valves installed in; (b) opening the first circulation valve (CV1), the second circulation valve (CV2), the first drain valve (DV1) and the second drain valve (DV2); (c) closing the first isolation valve (IV1), the second isolation valve (IV2), the third isolation valve (IV3), and the fourth isolation valve (IV4); (d) installing a forced drainage pump (EP) at the end of the fifth circulation line (CL5); (e) installing a drain connection line (DH) between the forced drain pump (EP) and the first drain line (DL1) to connect the circulation line (CL) and the drain line (DL); and (f) forcibly draining the coolant system water of the coolant system 10 to the reactor drain tank T through the forced drain pump EP by opening the third drain valve DV3 and the fourth drain valve DV4. It is characterized by including;

First, step (a) is a step of opening a plurality of control valves installed in the coolant system 10 .

Referring to FIG. 2, in step (a), V515, V516, V523, V526, 110Q, 110P, 201P are recovered so that all of the coolant system water of the coolant system 10 is recovered through the drainage system 20 of the chemical and volume control system. , This is the step of opening a total of 8 valves of 201Q.

In step (b), when the coolant system water is drained, the coolant system water of the coolant system 10 flows into the first circulation line CL1 to the fifth circulation line CL2, and This is the stage in which the second circulation valve (CV2), the first drain valve (DV1), and the second drain valve (DV2) are opened.

In step (c), the coolant system water is discharged to the outlet end of each of the first circulation line CL1, the third circulation line CL3, the fourth circulation line CL4, and the second drain line DL2. This is the stage in which the first separation valve (IV1), the second separation valve (IV2), the third separation valve (IV3), and the fourth separation valve (IV4) are closed.

Meanwhile, in step (d), the forced drain pump EP is installed at the end of the fifth circulation valve CL5.

Here, step (d) includes: (d-1) installing a forced drain pump (EP) at the end of the fifth circulation valve (CL5); (d-2) installing a pressure gauge (PG) for measuring the pressure of the coolant system water flowing into the inlet side of the forced drain pump (EP); (d-3) installing a confirmation window (W) for checking the flow rate of the drained coolant system water on the outlet side of the forced drain pump (EP);

Subsequently, step (e) is a step of installing a drain connection line (DH) between the forced drain pump (EP) and the first drain line (DL1) so that the circulation line (CL) and the drain line (DL) are connected. am.

That is, in step (e), the coolant system water introduced into the circulation line CL from the coolant system 10 flows into the drain line DL and is discharged to the reactor drain tank T, the circulation line CL This is the step in which the drain line DL is connected.

Subsequently, in step (f), after opening the third drain valve DV3 and the fourth drain valve DV4, the coolant system water of the coolant system 10 is pumped into the reactor drain tank T through the forced drain pump EP. This is the step of forced drainage.

On the other hand, the drainage method 30 of the chemical and volume control system according to an embodiment of the present invention, between steps (e) and (f), (g) in the reactor drain tank (T), the reactor drain tank ( A step of installing a water level gauge (WG) for measuring the level of the coolant system water discharged to T); is further included.

As described above, according to the embodiment of the present invention, as the procedure for draining the coolant system water is simplified and a plurality of manual valves are replaced with automatic valves, multiple operations are simplified to frequently discharge the coolant system water. It has the effect of reducing human errors that occur.

In addition, according to the embodiment of the present invention, by forcibly recovering the coolant system water through the forced drain pump (EF), the coolant system water introduced into the coolant system 10 and the plurality of circulation lines (CL) and drain lines (DL) As the entire amount can be quickly recovered, the discharge time of the coolant system water can be shortened compared to the existing gravity drainage method, thereby reducing work time and reducing maintenance costs.

In addition, according to an embodiment of the present invention, when the coolant system water is discharged, the entire amount of the coolant system water is recovered and reused in the reactor drain tank (T), so that not only can a large amount of liquid waste generated during gravity drainage be remarkably reduced, but also chemical (Boric Acid) has the effect of reducing the cost of expensive coolant system water to which boric acid is added.

In the above, even though all the components constituting the embodiment of the present invention have been described as being combined or operated as one, the present invention is not necessarily limited to these embodiments. That is, within the scope of the object of the present invention, all of the components may be selectively combined with one or more to operate.

In addition, terms such as "comprise", "comprise" or "have" described above mean that the corresponding component may be inherent unless otherwise stated, so excluding other components is not recommended. It should be interpreted that it may further include other components. All terms, including technical or scientific terms, have the same meaning as commonly understood by a person of ordinary skill in the art to which the present invention belongs, unless defined otherwise. Commonly used terms, such as terms defined in a dictionary, should be interpreted as consistent with the meaning in the context of the related art, and unless explicitly defined in the present invention, they are not interpreted in an ideal or excessively formal meaning.

The above description is merely an example of the technical idea of the present invention, and various modifications and variations can be made to those skilled in the art without departing from the essential characteristics of the present invention.

Therefore, the embodiments disclosed in the present invention are not intended to limit the technical idea of the present invention, but to explain, and the scope of the technical idea of the present invention is not limited by these embodiments. The protection scope of the present invention should be construed according to the following claims, and all technical ideas within the equivalent range should be construed as being included in the scope of the present invention.

10: coolant system
20: Drainage system of chemical and volume control system
30: Drainage method of chemical and volume control system
CL: circulation line
CL1: 1st circulation line
CL2: 2nd circulation line
CL3: 3rd circulation line
CL4: 4th circulation line
CL5: 5th circulation line
CV: circulation valve
CV1: 1st circulation valve
CV2: 2nd circulation valve
DL: drain line
DL1: 1st drain line
DL2: 2nd drain line
DV: drain valve
DV1: 1st drain valve
DV2: 2nd drain valve
DV3: 3rd drain valve
DV4: 4th drain valve
DH: drain connection line
EP : Forced drain pump
IV: Isolation valve
IV1: 1st separation valve
IV2: 2nd separation valve
IV3: 3rd separation valve
IV4: 4th separation valve
L: Outlet circulation line
T : Reactor drain tank
PG: pressure gauge
W: confirmation window
WG : water level
WGL: water level connection line

Claims (4)

A first circulation line CL1 connected to the outlet side circulation line L of the coolant system 10 when the coolant system water of the nuclear reactor is discharged, and a second circulation line CL2 connected to the first circulation line CL1 and a third circulation line CL3 and a fourth circulation line CL4 respectively connected to the second circulation line CL2, and a fifth circulation line CL5 connected to the third circulation line CL3. Including, a circulation line (CL) into which the coolant system water flows from the outlet side circulation line (L) of the coolant system (10);
A first drain line DL1 connected to the fifth circulation line CL5 and a second drain line DL2 connected to the first drain line DL1, wherein the coolant flow from the circulation line CL A drain line (DL) through which the inlet is discharged;
a reactor drain tank (T) connected to the second drain line (DL2) and storing coolant system water discharged through the drain line (DL);
A first separation valve (IV1) installed at the end of the first circulation line (CL1), a second separation valve (IV2) installed at the end of the third circulation line (CL3), and the fourth circulation line ( A third isolation valve (IV3) installed at the end of CL4) and a fourth isolation valve (IV4) installed at the end of the second drain line (DL2), but when the coolant system water of the nuclear reactor is discharged, the circulation line (CL) and a separation valve (IV) closed so that coolant system water does not flow through the drain line (DL);
A first drain valve DV1 installed in the first circulation line CL1, a second drain valve DV2 installed in the second circulation line CL2, and installed in the fifth circulation line CL5. a third drain valve (DV3) and a fourth drain valve (DV4) installed on the first drain line (DL1), but when the coolant system water of the nuclear reactor is discharged, the circulation line (CL) and the drain line ( a drain valve (DV) opened so that the coolant system water is discharged to the reactor drain tank (T) through DL);
A first circulation valve (CV1) installed between the first separation valve (IV1) and the first drain valve (DV1), the second circulation line (CL2), the third circulation line (CL3) and the and a second circulation valve (CV2) installed at an end of the fourth circulation line (CL4) and connecting the second circulation line (CL2), the third circulation line (CL3), and the fourth circulation line (CL4). circulation valve (CV);
a forced drain pump (EP) installed at an end of the fifth circulation line (CL5) to forcibly drain the coolant system water injected into the coolant system (10) to the reactor drain tank (T); and
The reactor drain tank ( Including; Drain connection line (DH) to be introduced into T);
A water level gauge (WG) installed in the reactor drain tank (T) to measure the level of coolant system water discharged into the reactor drain tank (T); and
The forced drain pump (EP),
a pressure gauge (PG) installed at the inlet side to which the fifth circulation line (CL5) is connected and measuring the pressure of the incoming coolant system water; and
a confirmation window (W) installed on the outlet side to which the first drain line (DL1) is connected and for checking the flow rate of the drained coolant system water;
Drainage system of chemical and volume control system, characterized in that it comprises a.
delete delete In the method of draining the coolant system water through the drainage system of the chemical and volume control system according to claim 1,
(a) opening a plurality of control valves installed in the coolant system (10);
(b) opening the first circulation valve (CV1), the second circulation valve (CV2), the first drain valve (DV1) and the second drain valve (DV2);
(c) closing the first separation valve (IV1), the second separation valve (IV2), the third separation valve (IV3), and the fourth separation valve (IV4);
(d) installing the forced drainage pump (EP) at an end of the fifth circulation line (CL5);
(e) connecting the circulation line (CL) and the drain line (DL) by installing the drain connection line (DH) between the forced drain pump (EP) and the first drain line (DL1); and
(f) The third drain valve DV3 and the fourth drain valve DV4 are opened to discharge the coolant system water of the coolant system 10 to the reactor drain tank T through the forced drain pump EP. Forced draining to;
Drainage method of chemical and volume control system, characterized in that it comprises a.

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