KR102790946B1 - Method of water blocking in drain pipe of essential service water in nuclear power plant - Google Patents

Abstract

The present invention relates to a method for sealing a drainage pipe of primary side equipment cooling water of a nuclear power plant, the drainage pipe including an inverted T-shaped pipe, the inverted T-shaped pipe including a first pipe extending vertically and having an inspection opening provided above ground; and a second pipe extending horizontally underground and connected to the first pipe, the method including the steps of: injecting a liner, which expands by fluid injection, into the first pipe through the inspection opening in a first bent shape; lowering the liner so that at least a part of the liner is positioned in the second pipe in the first shape; and sealing the drainage pipe by injecting a fluid into the liner so that the liner is positioned on the second pipe in a second unfolded shape.

Description

{Method of water blocking in drain pipe of essential service water in nuclear power plant}

The present invention relates to a method for draining a drainage pipe of primary side equipment cooling water of a nuclear power plant.

The drainage pipes for the primary equipment cooling water (ESW) of nuclear power plants are safety-grade structures and require periodic inspection and maintenance according to the Nuclear Safety Act.

Most of the drainage pipes are buried underground, and seawater always remains in them due to the influence of the water head on the drainage side due to the cross-design according to the power plant design concept.

In order to inspect or repair a drainage pipe, it is necessary to cut off the inflow of seawater depending on the water head on the drain side.

Korean Patent Publication No. 2010-0026599 (Published on March 10, 2010)

Accordingly, the purpose of the present invention is to provide a method for draining a drainage pipe of primary side equipment cooling water of a nuclear power plant.

The above object of the present invention is achieved by a method for sealing a drainage pipe of a primary side equipment cooling water of a nuclear power plant, wherein the drainage pipe includes an inverted T-shaped pipe, and the inverted T-shaped pipe includes a first pipe having an inspection port provided above ground and extending vertically; and a second pipe extending horizontally underground and connected to the first pipe, the method comprising: a step of injecting a liner, which expands by fluid injection, into the first pipe through the inspection port in a first bent shape; a step of lowering the liner so that at least a part of the liner is positioned in the second pipe in the first shape; and a step of sealing the drainage pipe by injecting a fluid into the liner so that the liner is positioned on the second pipe in an unfolded second shape.

The above first form may be a bracket shape, and the above second form may be a straight shape.

The above-mentioned water body is connected to the weight body through a connecting body having a plurality of joints, and in the above-mentioned injection step, the weight body can be positioned above the water body.

The above weight may include a plurality of wheels that can rotate in contact with the inner surface of the first pipe.

The above-mentioned connecting body may include a connecting rod connected to the weight body through a first joint; and a fixed part connected to the water level body and connected to the connecting rod through a second joint.

The above connecting rod may include a first connecting rod connected to the first joint; and a second connecting rod having one end connected to the first connecting rod through a third joint and the other end connected to the second joint.

The above first joint can be connected to the weight body so as to be eccentric within the first pipe.

The above connector may further include a rotation guide that guides the first joint to rotate toward the center of the first pipe during the lowering step.

According to the present invention, a method for draining a drainage pipe of primary side equipment cooling water of a nuclear power plant is provided.

Figure 1 illustrates a drainage pipe to which a water leveling method according to the present invention is applied.
Figure 2 illustrates a water level measuring device used in a water level measuring method according to one embodiment of the present invention.
Figure 3 is a plan view of a weight in a water leveling device used in a water leveling method according to one embodiment of the present invention.
Figures 4 to 7 sequentially illustrate a method of ordering according to one embodiment of the present invention.

The present invention will be described in more detail with reference to the drawings below.

The attached drawings are merely examples illustrated to more specifically explain the technical idea of the present invention, and therefore the idea of the present invention is not limited to the attached drawings. In addition, the attached drawings may have exaggerated sizes and spacings, etc., in order to explain the relationship between each component.

The present invention can be applied particularly to the case of the APR 1400 nuclear power plant type that requires blocking of seawater flowing back into the seawater residue according to the design characteristics.

Figure 1 illustrates a drainage pipe to which a water leveling method according to the present invention is applied.

The ESW drainage pipes, which are the target of the secondary water treatment, are mostly located underground and connect the heat exchanger building (CCW) and the circulating water drainage pipe (CWDC).

The ESW drainage system is provided with an inverted T-shaped pipe. The inverted T-shaped pipe includes a first pipe extending vertically and a second pipe extending horizontally. The first pipe includes an inspection port located above ground.

In the present invention, “vertical” includes an angle of 80 degrees to 100 degrees, and “horizontal” includes an angle of +10 degrees to -10 degrees. In addition, the term “located on the ground” of an inspection hole includes a case where an end of the inspection hole is located on the ground, or an end of the inspection hole is accessible or exposed from the ground, such as by removal of a cover.

Referring to Figures 2 and 3, a water level measuring device used in the water level measuring method is described.

FIG. 2 illustrates a water level measuring device used in a water level measuring method according to an embodiment of the present invention, and FIG. 3 is a plan view of a weight in a water level measuring device used in a water level measuring method according to an embodiment of the present invention.

The water level measuring device (1) includes a weight body (10), a water level measuring device (20), and a connecting body (30).

The weight body (10) is provided as a plurality of I-shaped structures as shown in FIGS. 2 and 3, and includes a connecting ring (11) at the top and a wheel (12) at the side. In other embodiments, the shape of the weight body (10) can be modified in various ways.

The one-piece structure is joined by welding, etc., and can be made of stainless steel, etc. The weight of the weight body (10) is not limited thereto, but can be 100 kg to 300 kg.

The connecting link (11) is located at the center of the weight (10), and the wheel (12) is provided so that when the weight (10) enters the first pipe, it comes into contact with the inner surface of the first pipe and rotates.

The water level body (20) is designed to be deformed by the injection of fluid. As shown in (a) of Fig. 4, when some of the fluid is removed, it is in a bent state, and when sufficient fluid is injected, it becomes an elongated cylindrical shape as shown in Fig. 2. That is, the water level body (20) is deformed between a bent shape and a straight shape depending on the degree of fluid injection.

The fluid supplied to the water supply body (20) may be a gas or a liquid, and air or water may be used.

Although not shown, the water purifier (1) may further include a configuration capable of supplying and recovering fluid to the water purifier (20).

The connector (30) includes a connecting rod (311, 312), a fixed part (321), a joint (331, 332, 333), and a rotation guide (341).

The first connecting rod (311) is connected to the weight body (10) through the first joint (331), and the second connecting rod (312) is connected to the first connecting rod (311) through the third joint (333). The fixed part (321) is connected to the water level body (20) and is connected to the second connecting rod (312) through the second joint (332).

The fixed part (321) can have various shapes such as a rod shape, an elongated plate shape, or a circular plate shape.

The rotation guide (341) connects the weight (10) and the first connecting rod (311). The first joint (331) is positioned eccentrically to the center of the first pipe, and the rotation guide (341) is positioned closer to the center of the first pipe than the first joint (331).

The rotation guide (341) may include a turnbuckle.

The joints (331, 332, 333) may adopt a conventional configuration that rotatably connects two components.

The ordering method according to the present invention will be described with reference to FIGS. 4 to 7 below.

Figures 4 to 7 sequentially illustrate a method of ordering according to one embodiment of the present invention.

First, as shown in Fig. 4, the water separator (1) is inserted into the first pipe through the inspection hole. The water separator (1) is positioned so that the water separator (20) is located at the bottom, and the water separator (20) is bent with some of the fluid removed. The insertion of the water separator (1) can be performed by connecting a crane to the connecting ring (11). Even if seawater is located in the second pipe due to the weight of the weight body (10), the water separator (20) can stably reach the second pipe.

The wheel (12) of the weight body (10) rotates while in contact with the inner wall of the first pipe during the injection process, thereby preventing damage to the first pipe and guiding the downward movement of the water separator (1).

Next, as shown in FIGS. 5 and 6, the water level measuring device (1) is lowered further so that at least a part of the water level measuring body (10) is positioned in the second pipe.

The water level sensor (20) is naturally positioned in the first pipe partly due to the bent shape of the water level sensor (20) and the joints (331, 332, 333) of the connecting body (30). This process is described in more detail as follows.

When the lower part of the water level gauge (20) is positioned inside the second pipe and a space is created in which the lower part of the water level gauge (20) can move, the water level gauge (20) tilts due to its own weight and the bent shape. In this state, when the water level gauge (20) is lowered further, the lower part of the water level gauge (20) comes into contact with the second pipe and the joints (331, 332, 333) rotate.

At this time, the first joint (331) is prevented from rotating outward by the rotation guide (341) and rotates inward, that is, so that the third joint (333) moves to the center of the first pipe. Due to the inward rotation of the first joint (331) and the tilting of the water level sensor (20), the second joint (332) and the third joint (333) rotate so that the water level sensor (20) lies down within the second pipe, as shown in Fig. 6.

Next, as shown in Fig. 7, a fluid is applied to the radiator (20) to expand the radiator (20) into a straight line. The radiator (20) is provided so as to be in close contact with the inner surface of the second pipe in the expanded state, so that the second pipe is radiated.

Afterwards, the seawater inside the drain pipe is drained and inspection or maintenance is performed. After the inspection or maintenance is completed, the fluid is removed from the water stopper (20) to make it into a hook shape again, and the water stopper (1) is removed from the drain pipe.

The above-described examples are examples for explaining the present invention, and the present invention is not limited thereto. Those skilled in the art to which the present invention pertains will be able to implement the present invention by making various modifications thereto, and therefore the technical protection scope of the present invention should be defined by the appended patent claims.

Claims (8)

In a method for draining a primary cooling water drainage pipe of a nuclear power plant,
The above drainage pipe includes an inverted T-shaped pipe,
The above inverted T-shaped conduit is,
A first pipe extending vertically and having an inspection hole provided on the ground; and
It includes a second pipe extending horizontally underground and connected to the first pipe.
A step of introducing a first bent shape of a water-filled body that expands by fluid injection into the first pipe through the inspection port;
A step of lowering the water leveler so that at least a part of the water leveler is positioned in the second pipe in the first form;
A step of injecting a fluid into the above-mentioned water body and positioning the above-mentioned water body on the second pipe in the expanded second form to thereby drain the drainage pipe,
The above-mentioned order is,
It is connected to the weight body through a connecting body with multiple joints,
A method in which the weight is positioned above the water level body in the above injection step. In the first paragraph,
The above first form is a bracket shape, and the above second form is a straight shape. delete In the second paragraph,
A method wherein the weight body comprises a plurality of wheels that can rotate in contact with the inner surface of the first pipe. In paragraph 4,
The above connector is,
A connecting rod connected to the above weight body through a first joint;
A method comprising a fixed member connected to the above-mentioned water body and connected to the above-mentioned connecting rod through a second joint. In paragraph 5,
The above connecting rod is,
A first connecting rod connected to the first joint; and
A method comprising a second connecting rod, one end of which is connected to the first connecting rod through a third joint and the other end of which is connected to the second joint. In Article 6,
A method in which the first joint is connected to the weight body so as to be eccentric within the first pipe. In Article 6,
The above connector is,
A method further comprising a rotation guide that guides the first joint to rotate toward the center of the first pipe in the lowering step.