KR20230141058A - Decontamination bypass device of reactor vessel and decontamination method - Google Patents

Abstract

A decontamination bypass device for nuclear reactor vessels is provided for excluding reactor vessels that do not require decontamination from systematic decontamination. The decontamination bypass device includes a frame including a first hole and a second hole; A first connection part installed in the first hole and including a first fastening member for fastening to the first inlet of the nuclear reactor; a second connection part installed in the second hole and including a second fastening member to be fastened to the first outlet of the nuclear reactor; and a first bypass line located inside the frame and connecting the first connection portion and the second connection portion to each other, wherein the decontamination agent provided to the first inlet of the nuclear reactor is supplied to the first connection portion and the first bypass line. It goes out to the first outlet through the pass line and the second connection.

Description

Decontamination bypass device of reactor vessel and decontamination method}

The present invention relates to a decontamination bypass device and method for decontamination of a nuclear reactor vessel.

System decontamination refers to the decontamination of the reactor coolant system (RCS) piping, which consists of a closed circuit located within the nuclear power plant containment building, with the goal of reducing radiation exposure to radiation workers and reducing radioactive waste during nuclear power plant decommissioning work. Specifically, system decontamination operates a pump connected to the coolant piping of the nuclear reactor to circulate decontamination water (i.e., decontamination water containing a high concentration of chemicals including an oxidizing agent) along the coolant piping. Decontamination water can reduce the radiation dose by desorbing the radioactive concentration and oxides contained in the slurry inside the coolant pipe.

Meanwhile, the target of system decontamination is the internal surfaces that come into contact with coolant, such as the reactor vessel, steam generator, pressurizer, and coolant pump. Decontamination water circulates throughout the entire system decontamination target, and the circulated decontamination water is collected and decontaminated (or reprocessed). However, because the decontamination water circulates throughout the entire system decontamination object, it also circulates inside the reactor vessel where decontamination is not necessary. Due to the high radiation dose of oxides inside the reactor vessel, the radioactivity concentration of liquid waste that must be reprocessed increases and a large amount of oxide sludge is generated.

The problem to be solved by the present invention is to provide a decontamination bypass device for nuclear reactor vessels to exclude reactor vessels that do not require decontamination from systematic decontamination.

Another problem to be solved by the present invention is to provide a decontamination method for excluding reactor vessels that do not require decontamination from systematic decontamination.

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.

One aspect of the decontamination bypass device for a nuclear reactor vessel of the present invention for achieving the above object includes a frame including a first hole and a second hole; A first connection part installed in the first hole and including a first fastening member for fastening to the first inlet of the nuclear reactor; a second connection part installed in the second hole and including a second fastening member to be fastened to the first outlet of the nuclear reactor; and a first bypass line located inside the frame and connecting the first connection portion and the second connection portion to each other, wherein the decontamination agent provided to the first inlet of the nuclear reactor is supplied to the first connection portion and the first bypass line. It goes out to the first outlet through the pass line and the second connection.

The first fastening member may be connected to the frame by a first flexible hose. The first fastening member may be moved in a direction away from or closer to the frame by the first moving member. The first fastening member includes a body connected to the first moving member, a protrusion that is formed to protrude from the body and has a slope that is inserted into the inner surface of the first inlet of the nuclear reactor, and a buffer formed in the slope. do.

The decontamination agent exiting the first outlet passes through a system decontamination skid containing an ion exchange resin, and radioactive contaminants in the decontamination agent may be collected by the ion exchange resin. The frame further includes a third hole and a fourth hole, a third connection part installed in the third hole and including a third fastening member for fastening to the second inlet of the nuclear reactor, and in the fourth hole. A fourth connection part is installed and includes a fourth fastening member for fastening to the second outlet of the nuclear reactor, and a second bypass line located inside the frame and connecting the third connection part and the fourth connection part to each other. Includes more. The decontamination agent passing through the system decontamination skid exits to the second outlet through the second inlet, the third connection portion, the second bypass line, and the fourth connection portion, and the decontamination agent exiting the second outlet is Again, the system decontamination skid is provided.

One aspect of the decontamination bypass device for a nuclear reactor vessel of the present invention for achieving the above other problems is to remove the internal structure from the nuclear reactor including the first inlet and the first outlet, and to remove the internal structure and the coolant system connected to the reactor. A system decontamination skid is connected to the pipe, and a decontamination bypass device is installed in the reactor, wherein the decontamination bypass device includes a frame including a first hole and a second hole, and installed in the first hole and the second hole. 1 A first connection part including a first fastening member for fastening with the inlet, a second connection part installed in the second hole and including a second fastening member for fastening with the first outlet, and located inside the frame, It includes a first bypass line connecting the first connection and the second connection to each other, wherein the system decontamination skid provides a decontamination agent to the first inlet of the reactor, and the decontamination agent provided to the first inlet is the The decontamination agent exits the first outlet through the first connection, the first bypass line, and the second connection, and passes through a systematic decontamination skid.

The frame further includes a third hole and a fourth hole, and the decontamination bypass device includes a third connection part installed in the third hole and including a third fastening member for fastening to the second inlet of the nuclear reactor. , a fourth connection part installed in the fourth hole and including a fourth fastening member for fastening to the second outlet of the nuclear reactor, and a second connection part located inside the frame and connecting the third connection part and the fourth connection part to each other. It further includes a bypass line, and the decontamination agent passing through the system decontamination skid exits the second outlet through the second inlet, the third connection, the second bypass line, and the fourth connection, and the decontamination agent passes through the system decontamination skid. The decontamination agent discharged to the second outlet is supplied again to the system decontamination skid.

Specific details of other embodiments are included in the detailed description and drawings.

The decontamination bypass device for a nuclear reactor vessel according to some embodiments of the present invention has one or more of the following effects.

By using a decontamination bypass device for a nuclear reactor vessel according to some embodiments of the present invention, reactor vessels that do not require decontamination can be excluded from systematic decontamination. Therefore, it is possible to prevent the radioactivity concentration of liquid waste that must be reprocessed from increasing and to prevent large amounts of oxide sludge from being generated.

1 is a diagram for explaining a system related to a decontamination bypass device for a nuclear reactor vessel according to some embodiments of the present invention.
Figure 2 is a cross-sectional view illustrating a decontamination bypass device for a nuclear reactor vessel according to some embodiments of the present invention.
FIGS. 3A and 3B are diagrams for explaining the frame, first connection, second connection, third connection, and fourth connection of the decontamination bypass device of FIG. 2.
FIG. 4 is a diagram specifically illustrating a portion of the decontamination bypass device of FIG. 2.
Figure 5 is a flow chart for explaining a decontamination method according to some embodiments of the present invention.
Figures 6 and 7 are intermediate stage diagrams for explaining step S230 of Figure 5.
Figure 8 is a diagram for explaining steps S240 to S260 of Figure 5. In other words, it is a drawing to explain the decontamination agent circulation flow (F1).
Figure 9 is a diagram for explaining the decontamination agent circulation flow (F2).

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.

1 is a diagram for explaining a system related to a decontamination bypass device for a nuclear reactor vessel according to some embodiments of the present invention.

In Figure 1, the primary system of a nuclear power plant is shown, and the primary system is equipment/equipment related to the nuclear reactor 90 that produces nuclear energy.

Specifically, during normal operation, the first coolant pump (RCP1) supplies coolant to the nuclear reactor 90 through the first inlet (IN1). The nuclear reactor 90 heats the coolant to a high temperature using heat generated through nuclear fission. Heated coolant is delivered to the first steam generator (SG1) through the first outlet (OUT1). Similarly, the second coolant pump (RCP2) supplies coolant to the nuclear reactor 90 through the second inlet (IN2). The nuclear reactor 90 heats the coolant to a high temperature using heat generated through nuclear fission. The heated coolant is delivered to the second steam generator (SG2) through the second outlet (OUT2). The steam generated by the steam generator (SG1 or SG2) is delivered to the steam turbine in the secondary system and used to produce electricity.

On the other hand, during system decontamination, as shown in FIG. 1, the internal structures inside the nuclear reactor 90 are removed. A decontamination bypass device 100 is installed inside the nuclear reactor 90. The decontamination bypass device 100 includes a first bypass line 161 directly connecting the first inlet (IN1) and the first outlet (OUT1) of the nuclear reactor 90, a second inlet (IN2), and a second outlet ( It includes a second bypass line 162 directly connected to OUT2).

In addition, a full system decontamination skid (FSDS) 80 is connected to the coolant system pipes 91 and 92 connected to the nuclear reactor 90.

The system decontamination skid 80 provides decontamination agent to the coolant system pipes 91 and 92, and can collect radioactive contaminants contained in the decontamination agent that circulates and returns to the coolant system pipes 91 and 92. For example, the system decontamination skid 80 includes an ion exchange resin, and radioactive contaminants can be captured by the ion exchange resin.

By using the decontamination bypass device 100, the reactor vessel 90 that does not require decontamination can be excluded from the systematic decontamination target. Therefore, it is possible to prevent the radioactivity concentration of liquid waste that must be reprocessed from increasing and to prevent large amounts of oxide sludge from being generated.

The structure of the decontamination bypass device 100 will be described in detail using FIGS. 2 to 4 . Figure 2 is a cross-sectional view illustrating a decontamination bypass device for a nuclear reactor vessel according to some embodiments of the present invention. FIGS. 3A and 3B are diagrams for explaining the frame, first connection, second connection, third connection, and fourth connection of the decontamination bypass device of FIG. 2. For convenience of explanation, the first bypass line and the second bypass line are omitted. FIG. 4 is a diagram specifically illustrating a portion of the decontamination bypass device of FIG. 2. Figure 4 is a shape viewed from IV in Figure 2.

Referring to Figures 2 to 4, the decontamination bypass device 100 includes a frame 105, a first connection part 110, a second connection part 120, a third connection part 130, a fourth connection part 140, It includes a first bypass line 161 and a second bypass line 162.

The frame 105 may be an octagonal pillar, but is not limited thereto. For example, it could be a circular pillar or a square pillar. The structure of the frame 105 can be of any shape that can support the other members 110, 120, 130, 140, 161, and 162.

In FIG. 3A, the frame 105 has a solid shape, and in FIG. 3B, the frame 105 has a frame shape. The solid-shaped frame 105 is relatively heavy but can be stronger, and the frame-shaped frame 105 is relatively light. The shape of the frame-shaped frame 105 can be implemented in various shapes other than that shown in FIG. 3B.

A first hole, a second hole, a third hole, and a fourth hole are formed in the frame 105.

The first connection portion 110 is installed in the first hole of the frame 105 and includes a first fastening member 119 to be fastened to the first inlet IN1 of the nuclear reactor 90. The second connection portion 120 is installed in the second hole of the frame 105 and includes a second fastening member 129 to be fastened to the first outlet OUT1 of the nuclear reactor 90. The third connection portion 130 is installed in the third hole of the frame 105 and includes a third fastening member 139 to be fastened to the second inlet IN2 of the nuclear reactor 90. The fourth connection portion 140 is installed in the fourth hole of the frame 105 and includes a fourth fastening member 149 to be fastened to the second outlet OUT2 of the nuclear reactor 90.

The first bypass line 161 is located inside the frame 105, and is connected to the first connection part 110 (i.e., the first fastening member 119) and the second connection part 120 (i.e., the second fastening member 129). )) are connected to each other. The second bypass line 162 is located inside the frame 105, and is connected to the third connection part 130 (i.e., the third fastening member 139) and the fourth connection part 140 (i.e., the fourth fastening member 149). )) are connected to each other.

Since the structure and operation of the first to fourth connection parts 110 to 140 are substantially the same, the description will focus on the first connection part 110. What has been explained using the first connection part 110 can be equally applied to the second connection part 120, the third connection part 130, and the fourth connection part 140.

The first connection part 110 includes a first fastening member 119, a first flexible hose 118, and a first moving member 115.

The first fastening member 119 is formed to protrude from the body 111 connected to the first moving member 115 and the body 111 and is inserted into the inner surface of the first inlet IN1 of the nuclear reactor 90. It includes a protrusion 112 having a slope formed thereon. Since a slope is formed, it can be inserted/fixed along the inner surface of the first inlet IN1. Although not separately shown, an absorber (see 112a in FIG. 6) may be formed on the surface of the slope. The buffering agent may be, for example, a rubber material coated on the slope, but is not limited thereto. The buffering agent makes sealing possible and ensures rigidity.

The first flexible hose 118 connects the first fastening member 119 and the frame 105.

The first moving member 115 moves the first fastening member 119 in a direction away from or closer to the frame 105. The first moving member 115 may be, for example, an air cylinder, but is not limited thereto. The first moving member 115 can move the first fastening member 119 in all directions and attach it to the inner surface of the first inlet IN1 of the nuclear reactor 90. The first moving member 115 can move the first fastening member 119 in the rearward direction to separate it from the inner surface of the first inlet IN1 of the nuclear reactor 90.

As shown in FIG. 4 , a plurality of first moving members 115 may be formed around the protrusion 112 on the body 111 .

Below, a decontamination method according to some embodiments of the present invention will be described using FIGS. 5 to 9.

Figure 5 is a flowchart for explaining a decontamination method according to some embodiments of the present invention. Figures 6 and 7 are intermediate stage diagrams for explaining step S230 of Figure 5. Figure 8 is a diagram for explaining steps S240 to S260 of Figure 5. In other words, it is a drawing to explain the decontamination agent circulation flow (F1). Figure 9 is a diagram for explaining the decontamination agent circulation flow (F2).

Referring to FIGS. 1 and 5, the internal structure is removed from the nuclear reactor 90 (S210).

Next, the system decontamination skid 80 is connected to the coolant system pipes 91 and 92 connected to the nuclear reactor 90 (S220).

Next, the decontamination bypass device 100 is installed in the nuclear reactor 90 (S230).

Specifically, the decontamination bypass device 100 includes a frame 105 including first to fourth holes, and a first fastening member 119 installed in the first hole and fastened to the first inlet IN1. ), a first connection portion 110 including a second connection portion 120 including a second fastening member 129 installed in the second hole and fastened to the first outlet OUT1, and a third hole. A third connection part 130 including a third fastening member 139 installed and fastened to the second inlet (IN2), and a fourth fastening member installed in the fourth hole and fastened to the second outlet (OUT2) The fourth connection part 140 including (149), the first bypass line 161 located inside the frame 105 and connecting the first connection part 110 and the second connection part 120 to each other, frame 105 ) It is located inside and includes a second bypass line 162 that connects the third connection part 130 and the fourth connection part 140 to each other.

The decontamination bypass device 100 is placed inside the nuclear reactor 90, for example by a polar crane. As shown in FIG. 6, the first connection portion 110 is positioned to correspond to the first inlet IN1. Likewise, the second connection part 120, the third connection part 130, and the fourth connection part 140 are positioned to correspond to the first outlet (OUT1), the second inlet (IN2), and the second outlet (OUT2).

As shown in FIG. 7, the first moving member 115 pushes the first fastening member 119 so that the protrusion 112 of the first fastening member 119 contacts the inner surface of the first inlet IN1. (i.e., the first fastening member 119 and the first inlet IN1 are fastened). As the first fastening member 119 moves in the forward direction, the first flexible hose 118 stretches.

Referring again to FIG. 5, the system decontamination skid 80 provides decontamination agent to the first inlet IN1 of the nuclear reactor (S240). The decontamination agent provided to the first inlet (IN1) flows out to the first outlet (OUT1) through the first connection part 110, the first bypass line 161, and the second connection part 120 (S250). The decontamination agent exiting the first outlet (OUT1) passes through the system decontamination skid 80 (S260) [refer to the decontamination agent circulation flow (F1) in FIG. 8].

Subsequently, the system decontamination skid 80 provides decontamination agent to the second inlet IN2 of the reactor. The decontamination agent provided to the second inlet (IN2) flows out to the second outlet (OUT2) through the third connection part 130, the second bypass line 162, and the fourth connection part 140. The decontamination agent that went out to the second outlet (OUT2) returns to the system decontamination skid (80) (refer to the decontamination agent circulation flow (F2) in FIG. 9).

As shown in F1 of FIG. 8 and F2 of FIG. 9, the decontamination agent circulates through the primary system (excluding the reactor 90) multiple times, so that the decontamination agent contains radioactive contaminants. As this decontaminant passes through the ion exchange resin in the system decontamination skid 80, radioactive contaminants are captured by the ion exchange resin.

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.

100: Decontamination bypass device 105: Frame
110: first connection 111: body
112: protrusion 115: first moving member
118: first flexible hose 120: second connection part
130: third connection 140: fourth connection
161: first bypass line 162: second bypass line

Claims (9)

A frame including a first hole and a second hole;
a first connection part installed in the first hole and including a first fastening member to be fastened to the first inlet of the nuclear reactor;
a second connection part installed in the second hole and including a second fastening member to be fastened to the first outlet of the nuclear reactor; and
It is located inside the frame and includes a first bypass line connecting the first connection part and the second connection part to each other,
A decontamination bypass device for a nuclear reactor vessel, wherein the decontamination agent provided to the first inlet of the nuclear reactor exits the first outlet through the first connection, the first bypass line, and the second connection. According to clause 1,
The first fastening member is connected to the frame by a first flexible hose. According to clause 2,
A decontamination bypass device for a nuclear reactor vessel, wherein the first fastening member is moved in a direction away from or closer to the frame by a first moving member. According to clause 3,
The first fastening member is
A body connected to the first moving member,
a protrusion formed to protrude from the body and having a slope that fits into the inner surface of the first inlet of the nuclear reactor;
A decontamination bypass device for a nuclear reactor vessel comprising a buffer formed in the slope. According to clause 1,
The decontamination agent exiting the first outlet passes through a system decontamination skid containing an ion exchange resin,
A decontamination bypass device for a nuclear reactor vessel, wherein radioactive contaminants in the decontamination agent are collected by the ion exchange resin. According to clause 5,
The frame further includes a third hole and a fourth hole,
A third connection part installed in the third hole and including a third fastening member for fastening to the second inlet of the nuclear reactor;
A fourth connection part installed in the fourth hole and including a fourth fastening member for fastening to the second outlet of the nuclear reactor;
A decontamination bypass device for a nuclear reactor vessel further comprising a second bypass line located inside the frame and connecting the third connection portion and the fourth connection portion to each other. According to clause 6,
The decontamination agent passing through the system decontamination skid exits to the second outlet through the second inlet, the third connection, the second bypass line, and the fourth connection,
A decontamination bypass device for a nuclear reactor vessel, wherein the decontamination agent exiting the second outlet is supplied back to the system decontamination skid. In a nuclear reactor including a first inlet and a first outlet, removing the internal structure,
Connecting a system decontamination skid to the coolant system pipe connected to the nuclear reactor,
A decontamination bypass device is installed in the nuclear reactor, wherein the decontamination bypass device includes a frame including a first hole and a second hole, and a first fastening member installed in the first hole and fastened to the first inlet. A first connection part including a first connection part, a second connection part installed in the second hole and including a second fastening member for fastening to the first outlet, and located inside the frame and the first connection part and the second connection part. Includes a first bypass line connecting to each other,
The system decontamination skid provides a decontamination agent to a first inlet of the reactor,
The decontamination agent provided to the first inlet exits the first outlet through the first connection, the first bypass line, and the second connection,
A decontamination method comprising passing the decontamination agent exiting the first outlet through a systematic decontamination skid. According to clause 8,
The frame further includes a third hole and a fourth hole,
The decontamination bypass device includes a third connection portion installed in the third hole and including a third fastening member for fastening to the second inlet of the nuclear reactor, and a second outlet of the nuclear reactor and installed in the fourth hole. It further includes a fourth connection part including a fourth fastening member to be fastened, and a second bypass line located inside the frame and connecting the third connection part and the fourth connection part to each other,
The decontamination agent passing through the system decontamination skid exits to the second outlet through the second inlet, the third connection, the second bypass line, and the fourth connection,
A decontamination method comprising providing the decontamination agent that exited the second outlet to the systematic decontamination skid.

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