KR102162013B1 - A bottom nozzle of Nuclear Fuel Assembly formed spiral type flow hole - Google Patents

Abstract

The present invention relates to a lower end fixture of a nuclear fuel assembly formed with a spiral flow path, and more particularly, a flow path is formed in a spiral shape and overlapped between neighboring flow paths to complicate the cooling water flow path, thereby improving the efficiency of filtering foreign matter. Each of the inlet and outlet portions in which the coolant inflow and outflow is performed is to maximize the size of the lower end fixture of the nuclear fuel assembly in which a spiral flow path hole is formed so as to prevent the coolant pressure drop from dropping.
To this end, in the lower end fixture of the nuclear fuel assembly forming a plurality of passage holes, the passage hole is formed while rotating in a spiral direction in the height direction of the lower end fixture, and the passage hole is formed by rotating an elliptical perforation means. It provides a lower end fixture of a nuclear fuel assembly formed with a spiral flow path hole, characterized in that made while rising in the height direction of the lower fixture.

Description

A bottom nozzle of Nuclear Fuel Assembly formed spiral type flow hole

The present invention relates to a lower end fixture of a nuclear fuel assembly having a spiral channel hole, and more particularly, a nuclear fuel having a spiral channel hole that prevents a decrease in the flow rate of coolant by preventing a drop in coolant pressure while increasing foreign matter filtering efficiency. It relates to the lower fixed body of the aggregate.

A nuclear reactor is a device to use the thermal energy generated from nuclear fission as power by artificially controlling the chain fission reaction of fission materials.

Nuclear fuel used in a nuclear reactor is manufactured by molding enriched uranium into cylindrical pellets of a certain size and then loading a number of pellets into a fuel rod, and after these multiple fuel rods form a nuclear fuel assembly and are loaded into the core of the nuclear reactor. Combustion takes place through nuclear reactions.

Referring to FIG. 1, in general, a nuclear fuel assembly includes a plurality of fuel rods disposed in the axial direction, a plurality of support grids 30 provided in the transverse direction of the fuel rods to support the fuel rods, and the support grids 30 and fixed. It is to support the upper and lower ends of the guide tube 20 and the guide tube 10 and the measurement tube 20 inserted in the center of the plurality of guide tubes 10 and support grid 30 constituting the assembly It consists of an upper fixing body 40 and a lower fixing body 50.

The fuel rods constituting the nuclear fuel assembly are made up of approximately 200 or more, and each fuel rod is charged with enriched uranium formed into pellets of a certain size.

The upper fixture 40 and the lower fixture 50 are for supporting the upper and lower ends of the guide tube 10, respectively, and the upper fixture 40 is applied to the water pressure of the coolant flowing through the lower portion of the nuclear fuel assembly. As a result, a plurality of elastic bodies are provided to prevent the nuclear fuel assembly from being lifted, and function to press and fix the upper end of the nuclear fuel assembly.

The lower end fixture 50 fixes the lower end of the guide tube 10 and forms a hole into which the guide tube 10 and the measurement tube 20 are inserted, and a plurality of flow path holes through which cooling water is supplied.

With reference to FIGS. 2A and 2B, the lower fixing member 50 will be described in detail.

A guide hole 51 and a measurement hole 52 to which the guide tube 10 and the measurement tube 20 are connected, respectively, and a flow path hole 53 that is a cooling water passage hole are formed in the lower fixing body 50.

With this configuration, the coolant flows into the fuel rod region through the flow path hole 53 and cools heat generated from the fuel rod while passing between the fuel rods.

At this time, when the coolant flows into the fuel rod region through the passage hole 53, foreign substances remaining in the cooling water also enter the fuel rod region in the same path as the coolant.

In other words, various types of foreign matter flowing with the coolant during the operation of the reactor pass through the flow path hole 53 and flow into the area where the fuel rod of the nuclear fuel assembly is located, and can be caught between the fuel rod and the fuel rod or between the support grid and the fuel rod at the bottom of the nuclear fuel assembly. will be.

When a relatively large-sized foreign material flows into the fuel rods like coolant through the flow path hole 53, the foreign matter vibrates to the adjacent nuclear fuel rod cladding tube, thereby mechanically abrading the nuclear fuel rod cladding tube, thereby damaging the cladding tube.

As such, the types of foreign substances that can damage the nuclear fuel rod are very diverse, such as metal pieces after cutting, debris generated during welding, bolts, nuts, nails, and hacksaw pieces.

If the cladding tube of the nuclear fuel rod is damaged, the nuclear reaction products generated by the nuclear reaction of the nuclear material in the fuel rod leak out of the fuel rod cladding tube and contaminate the cooling water with radioactive materials, and the contaminated coolant circulates through the primary cooling system of the nuclear power plant. Pollute the whole.

In order to prevent this problem, the flow path 53 is designed in various shapes, such as a mesh shape, to filter foreign substances generated in the nuclear reactor.

However, conventionally, the design of the flow path hole 53 to increase the foreign matter filtering efficiency does not facilitate the flow of the cooling water due to a drop in the pressure of the cooling water, and the design of the flow path hole 53 to prevent the pressure drop of the cooling water is effective for filtering foreign matter. There is a problem with this falling.

Republic of Korea Publication No. 2000-0061665

The present invention has been conceived to solve the above problems, and an object of the present invention is to increase the efficiency of filtering foreign matter by forming a flow path hole in a spiral shape, and the inlet portion and the outlet portion of the flow path hole through which cooling water flows in and out It is intended to provide a lower end fixture of the nuclear fuel assembly that forms a spiral flow path hole that prevents the pressure drop of the cooling water by making the diameter gradually expand from the part to make the cooling water flow smoothly.

The present invention is to achieve the above object, in the lower end fixture of the nuclear fuel assembly forming a plurality of passage holes, the passage hole is formed while rotating in a spiral direction in the height direction of the lower end fixture, the passage hole Provides a lower end fixture of a nuclear fuel assembly having a spiral flow path hole, characterized in that the elliptical perforation means is rotated and raised and lowered in the height direction of the lower end fixture.

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In addition, it is preferable that the inlet portion of the flow path hole through which the coolant flows in and the outlet portion of the flow path hole through which the cooling water flows are gradually expanded from the middle portion of the flow path hole.

In addition, it is preferable that the flow path holes overlap adjacent flow path holes.

The lower end fixture of the nuclear fuel assembly in which the spiral flow path hole is formed according to the present invention has the following effects.

First, by forming the passage hole in a spiral shape, it is possible to increase the efficiency of filtering foreign matter.

That is, since the flow path hole is formed in a spiral shape, turbulence such as a eddy current may occur in the process of passing the foreign material through the flow path hole, thereby improving the filtering efficiency of the foreign material.

Particularly, as spaces overlap each other between adjacent flow path holes and the flow path holes overlap each other, turbulence in the flow path hole may occur more severely, so that foreign matter can be collected more effectively.

Second, the outlet portion of the channel hole through which the coolant flows in and the outlet portion of the channel hole through which the coolant exits are formed to be gradually expanded from the middle portion of the channel hole, so that the sizes of the inlet portion and the outlet portion can be maximized.

Accordingly, there is an effect of preventing the pressure from dropping during the inflow and outflow of cooling water.

1 is a view showing a general nuclear fuel assembly
Figure 2a is a perspective view showing a lower end fixture of a nuclear fuel assembly according to the prior art
2B is a plan view showing the lower end of the nuclear fuel assembly according to the prior art
3 is a plan view showing a lower end fixture of a nuclear fuel assembly having a spiral flow path hole according to a preferred embodiment of the present invention.
4 is a perspective view showing a main part of a lower end fixture of a nuclear fuel assembly forming a spiral flow path according to a preferred embodiment of the present invention
5 is a side cross-sectional view showing a main part of a lower end fixture of a nuclear fuel assembly forming a spiral flow path according to a preferred embodiment of the present invention
6 is a side view showing a main part of a structure corresponding to a channel hole of a lower end fixture of a nuclear fuel assembly having a spiral flow path according to a preferred embodiment of the present invention
7 is a plan view showing a main part of a structure corresponding to a flow path hole of a lower end fixture of a nuclear fuel assembly having a spiral flow path according to a preferred embodiment of the present invention;
FIG. 8 is a view taken in the direction A of FIG.

Terms and words used in the present specification and claims are not limited to the usual or dictionary meanings, and the inventor is based on the principle that the concept of terms can be appropriately defined in order to explain his or her invention in the best way. It should be interpreted as a meaning and concept consistent with the technical idea of the present invention.

Hereinafter, a lower end fixture (hereinafter, referred to as a'lower fixture') of a nuclear fuel assembly having a spiral flow path according to a preferred embodiment of the present invention will be described with reference to FIGS. 3 to 8.

The lower stationary body 100 has a flow path hole 200 formed in a spiral shape to increase the efficiency of filtering foreign substances, and prevents a drop in the cooling water pressure when the cooling water passes, so that the cooling water flows smoothly.

Accordingly, both the cooling water flow and the foreign matter filtering efficiency can be improved.

The lower fixed body 100 forms a flow path hole 200 through which cooling water flows.

At this time, the flow path hole 200 is formed in a spiral shape in the height direction of the lower fixture, as shown in FIGS. 3 and 4.

As the flow path hole 200 is formed in a spiral shape as described above, turbulence such as a vortex phenomenon may occur when the cooling water passes, thereby increasing the efficiency of filtering foreign substances.

The flow path hole 200 may be composed of an inlet part 210, an intermediate part 220, and an outlet part 230 from the inflow direction of the coolant, wherein the flow path hole 200 has an elliptical perforation means, etc. It is made in the form of a perforated spiral hole.

A plurality of such flow path holes 200 are formed on the lower fixing body 100 and are formed to overlap between adjacent flow path holes 200.

As the spiral flow path holes 200 are overlapped with each other, the flow path of the flow path hole 200 has a very complex shape.

As described above, the shape of the flow path hole 200 is formed in a spiral shape, but partially overlaps with the adjacent flow path hole 200, so that the flow path hole 200 provides a complex configuration to generate a vortex when the coolant flows.

Accordingly, when the cooling water flows, foreign substances contained in the cooling water can be effectively filtered.

A more detailed look at the shape of the flow path hole 200 is as follows,

In order to form the flow path hole 200 on the lower fixing body 100, as described above, the elliptical perforation means is rotated and raised and lowered in the height direction of the lower fixing body 100. FIG. 6 shows a spiral flow path hole 200 It is a structure that was created by forming ).

As can be seen through this, it can be understood that the flow path hole 200 forms a spiral in the upper and lower directions of the lower fixing body 100.

At this time, the inlet portion 210 and the outlet portion 230 into which the cooling water 200 is introduced are located above and below the drawing (FIG. 5), and the inlet portion 210 and the outlet portion 230 are shown in FIG. 6. As can be seen through, each of the intermediate portions 220 of the flow path hole 200 is gradually enlarged and formed.

Accordingly, even if a eddy current occurs in the middle part 220 of the flow path hole 200, the size of the inlet part 210 and the outlet part 230 is maximized, so that the pressure drops when the coolant passes through the flow path hole 200. Does not occur.

In particular, as can be seen through FIGS. 6 and 7, the inlet 210 and the outlet 230 of the flow path hole 200 are the inlet 210 and the outlet 230 of the adjacent flow path hole 200. Since they are partially overlapped with each other, the sizes of the inlet 210 and the outlet 230 are further maximized.

Accordingly, a pressure drop does not occur during the inflow and outflow of the coolant, so that the coolant flow rate does not drop.

Meanwhile, the middle portion 220 of the flow path hole 200 also overlaps the middle portion 220 of the neighboring flow path hole 200.

8 is a view showing the structure shown in FIG. 6 from one side. As the intermediate portion M of the structure corresponding to the intermediate portion 220 of the flow path 200 is formed convexly to both sides, the flow path hole ( The intermediate part 220 of 200 means that the intermediate part 220 of the adjacent channel hole 200 overlaps with each other.

As shown in FIG. 7, the middle portion 220 of the flow path hole 200 is a structure M of the flow path hole 200 adjacent to the structure M corresponding to the middle portion 220 of the flow path hole 200. It can be understood that the middle portion 220 of the flow path hole 200 overlaps each other as it indicates that it overlaps with (M).

With such a configuration, the cooling water flows into the flow path hole 200 and the middle part 200 through the inlet 210, and then passes along the complicated flow path hole path. Is filtered.

Thereafter, the coolant is discharged from the middle portion 220 of the flow path hole 200 through the enlarged outlet portion 230.

As described so far, the lower stationary body of the nuclear fuel assembly in which the spiral flow path hole is formed according to the present invention has a configuration in which the flow path hole is formed in a spiral shape and the cooling water flow path between neighboring flow path holes is overlapped. The outlet size was maximized.

Accordingly, it is possible to maximize the efficiency of filtering foreign substances while maintaining the cooling water flow rate as it is.

In the above, the present invention has been described in detail with respect to the described embodiments, but it is obvious to those skilled in the art that various modifications and modifications are possible within the scope of the technical idea of the present invention, and it is natural that such modifications and modifications fall within the scope of the appended claims.

100: lower fixed body 200: euro hole
210: inlet 220: middle
230: outlet M: middle of the structure

Claims (4)

In the lower end fixture of the nuclear fuel assembly forming a plurality of flow path holes,
The channel hole,
It is formed while rotating in a spiral direction toward the height of the lower fixture.
The flow path hole is a lower end fixture of a nuclear fuel assembly forming a spiral flow path hole, characterized in that formed while the elliptical perforation means is rotated and raised in the height direction of the lower end fixture. delete The method of claim 1,
A lower end fixture of a nuclear fuel assembly having a spiral channel hole, characterized in that the inlet portion of the channel hole through which the cooling water flows and the outlet portion of the channel hole through which the coolant flows out are gradually expanded from the middle portion of the channel hole. The method of claim 1 or 3,
The flow path hole is a lower end fixture of the nuclear fuel assembly forming a spiral flow path hole, characterized in that the overlapping between adjacent flow path holes.

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