KR102180187B1 - Steam discharging nozzle and steam discharging system having the same - Google Patents

Abstract

An object of the present invention is to provide a steam discharging nozzle capable of increasing residence time of steam flowing into a water tank without providing additional power, and a steam discharging system including the same. The steam discharging nozzle, which discharges the steam discharged from a nuclear power plant through the water tank comprises: a first discharging nozzle discharging steam flowing into the inside; and a second discharging nozzle supported by the first discharging nozzle to discharge the steam through a water tank, and rotating when the steam is discharged from the first discharging nozzle to generate forced convection in the water tank.

Description

Steam discharging nozzle and steam discharging system including the same TECHNICAL FIELD [STEAM DISCHARGING NOZZLE AND STEAM DISCHARGING SYSTEM HAVING THE SAME}

The present invention relates to a steam discharge nozzle and a steam discharge system including the same, and more particularly, to a steam discharge nozzle for discharging steam discharged from a nuclear power plant environment, and a steam discharge system including the same.

In general, in a reactor pressurizer provided in a nuclear power plant environment, steam discharge inside the system is required according to the conditions inside the reactor coolant system. At this time, the steam discharged from the reactor pressurizer flows into the reloading water tank through the pressurizer safety discharge valve.

The vapor emission technology of such a nuclear power plant environment has already been disclosed by Korean Patent Application Publication No. 10-2005-0108530 (Containment Building Fuel Reloading Water Tank, 2005.11.17.). The above disclosed patent includes a technology for discharging steam through the reloading water tank by introducing a speeder into the reloading water tank.

However, in the conventional steam release technology, the residence time of the steam flowing into the reloading water tank may be insufficient. Accordingly, a thermal layer may be generated in the reloading water tank, and fatigue damage may occur. Accordingly, there is a continuing demand for a technology for increasing the residence time of the steam.

Korean Patent Laid-Open Publication No. 10-2005-0108530 (Container building fuel reloading water tank with bulkheads, 2005.11.17.)

An object of the present invention is to provide a steam discharge nozzle and a steam discharge system including the same, which can increase the residence time of the steam flowing into the water tank without providing additional power.

The steam discharge nozzle according to the present invention is a steam discharge nozzle that allows steam discharged from a nuclear power plant to be discharged through a water tank, wherein the first discharge nozzle discharges the steam introduced into the inside, and the steam discharge nozzle is supported by the first discharge nozzle. And a second discharge nozzle that rotates when the vapor is discharged from the first discharge nozzle and generates a forced convection inside the water bath.

At least one fan may be provided in the second discharge nozzle to increase the residence time of the steam by generating forced convection inside the water tank.

The first discharge nozzle has a cylindrical shape and communicates with the first inlet area and the first inlet area through which the steam is first introduced by a partition wall disposed at a distance from the bottom surface therein. A second inlet region may be introduced, a plurality of first discharge holes may be arranged in a sidewall of the first inlet region, and a plurality of second discharge holes may be arranged in a sidewall of the second inlet region.

The diameter of the second discharge hole may be smaller than the diameter of the first discharge hole so that steam having a mutually uniform pressure is discharged in the first and second inlet regions.

The height of the second inflow area may be provided lower than that of the first inflow area by an upper block.

The second discharge nozzle is provided to have a cylindrical shape with an opening formed on one surface thereof, and the first discharge nozzle is inserted into the connector, and an inlet portion passing through the inlet forming a path through which the steam flows into the first discharge nozzle on the upper surface Can be formed.

A third discharge hole is arranged on the side wall of the second discharge nozzle so that the steam discharged from the first discharge nozzle is discharged toward the water tank, and the third discharge hole is formed to be inclined toward the side of the second discharge nozzle. So that the second discharge nozzle rotates when the vapor is released.

On the other hand, the steam discharge system according to the present invention is connected to a nuclear power plant and the nuclear power plant to form a path through which the steam discharged from the nuclear power plant is transferred to the water tank, and the steam discharge pipe is connected to the discharge pipe inside the water tank. And a steam discharge nozzle configured to discharge into the water tank, wherein the steam discharge nozzle includes a first discharge nozzle for discharging steam introduced into the inside, and the first discharge nozzle is supported so that the steam is discharged through the water tank. And a second discharge nozzle that rotates when the steam is discharged from the first discharge nozzle and generates forced convection inside the water tank.

In the steam discharge nozzle and the steam discharge system including the same according to the present invention, as the amount of steam increases, heat transfer between the jetted steam and the coolant in the water tank becomes active, thereby improving the steam cooling effect and reducing the pressure of the containment by the steam.

In addition, the steam discharge nozzle and the steam discharge system including the same according to the present invention generate forced convection to promote mixing between the upper and lower parts of the water tank, thereby preventing the formation of a thermal layer in the tank.

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

1 and 2 are schematic diagrams of a vapor release system according to the present embodiment,
3 is a perspective view schematically showing a steam discharge nozzle according to the present embodiment,
4 is an exploded perspective view schematically showing a steam discharge nozzle according to the present embodiment,
5 is a schematic cross-sectional view of a steam discharge nozzle according to the present embodiment,
6 is a cross-sectional view schematically showing discharge holes of the first and second half-filling nozzles according to the present embodiment,
7 is an operation diagram schematically showing the operation of the steam discharge system according to the present embodiment.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. However, this embodiment is not limited to the embodiments disclosed below, but may be implemented in various forms, only this embodiment makes the disclosure of the present invention complete, and the scope of the invention is given to those of ordinary skill in the art. It is provided to be fully informed. The shapes of elements in the drawings may be exaggerated for a more clear explanation, and elements indicated by the same reference numerals in the drawings mean the same elements.

1 and 2 are schematic diagrams of a vapor emission system according to the present embodiment.

1 and 2, the steam discharge system 1000 according to the present embodiment is connected to the reactor pressurizer 10, and the steam discharged from the reactor pressurizer 10 is provided to the reloading water tank 20. Make it possible.

However, this is for explaining the present embodiment and is not limited to the application of the steam release system 1000 to the reactor pressurizer 10, and the steam release system 1000 is applied to various nuclear power plant facilities including the reactor pressurizer 10 As a result, steam can be discharged smoothly.

This steam discharge system 1000 includes a discharge pipe 30 forming a discharge path of the steam from the reactor pressurizer 10 to the reloading water tank 20, that is, the water tank 20a. The discharge pipe 30 is formed by connecting at least one or more pipes so that the steam provided from the reactor pressurizer 10 is provided to the water tank 20a. At this time, the discharge pipe 30 is connected to the upper portion of the reactor pressurizer 10, and a pressurizer safety discharge valve 40 may be provided on the discharge pipe 30 of the steam.

Meanwhile, a steam discharge nozzle 100 is connected to one end of the discharge pipe 30. The steam discharge nozzle 100 may be provided in the form of a sprinkler, and allows steam to be discharged toward the cooling water stored in the water tank 20a.

Hereinafter, a steam discharge nozzle according to the present embodiment will be described in detail with reference to the accompanying drawings. However, for the above-described components, detailed descriptions are omitted and the same reference numerals are assigned to describe them.

3 is a perspective view schematically showing a steam discharge nozzle according to the present embodiment, and FIG. 4 is an exploded perspective view schematically showing a steam discharge nozzle according to the present embodiment. And Figure 5 is a cross-sectional view schematically showing a steam discharge nozzle according to the present embodiment, Figure 6 is a cross-sectional view schematically showing the discharge holes of the first and second discharge nozzles according to the present embodiment.

3 to 6, the vapor discharge nozzle 100 according to the present embodiment includes a first discharge nozzle 200 and a second discharge nozzle 300.

The first discharge nozzle 200 is provided in a cylindrical shape. In addition, an inlet part 210 connectable to the discharge pipe 30 is formed on the upper surface of the first discharge nozzle 200. The inlet 210 is drawn from the upper surface of the first discharge nozzle 200 so as to have a smaller diameter than the upper surface of the first discharge nozzle 200. In addition, the first discharge nozzle 200 may have an inner shape in a "J" shape.

To this end, a partition wall 220 spaced apart from the bottom surface is provided inside the first discharge nozzle 200. The partition wall 220 may bisect the interior of the first discharge nozzle 200. Accordingly, the partition wall 220 allows vapor flowing into the first discharge nozzle 200 through the inlet 210 to be provided to one side region of the partition wall 220 (hereinafter, referred to as a first inlet region). In addition, the vapor passing through the first inlet region 200a through the lower side of the partition wall 220 is provided to the other region of the partition wall 220 (hereinafter, referred to as a second inlet region). In this case, a block 221 extending from the partition wall 220 is provided above the second inflow area 200b so that the height of the second inflow area 200b is set lower than the height of the first inflow area 200a.

Thus, the steam flowing into the first discharge nozzle 200 through the inlet 210 is discharged through the first discharge hole H1 formed in the first inlet region 200a. In addition, the residual steam is discharged through the second discharge hole H2 formed in the second inlet region 200b.

Here, a plurality of first discharge holes H1 are provided. The plurality of first discharge holes H1 are arranged in the first inflow region 200a in the height direction of the first discharge nozzle 200 and may be provided to have a plurality of rows. And the second discharge hole (H2) is provided in plurality. The plurality of second discharge holes H2 are arranged in the second inlet region 200b in the height direction of the first discharge nozzle 200 and may be provided to have a plurality of rows.

At this time, the diameter of the second discharge hole H2 may be formed to be narrower than the diameter of the first discharge hole H1. That is, the pressure inside the second inlet region 200b is relatively lower than the pressure in the first inlet region 200a. This is because the residual steam is provided to the second inlet area 200b after some steam is discharged through the first inlet area 200a. Accordingly, the diameter of the second discharge hole H2 may be formed to be narrower than the diameter of the first discharge hole H1 so that the uniform vapor can be discharged to the outside from the entire area of the first discharge nozzle 200.

Meanwhile, the second discharge nozzle 300 is supported by the first discharge nozzle 200. The second discharge nozzle 300 rotates based on the steam injected from the first discharge nozzle 200 and allows the steam to be injected toward the cooling water in the water tank 20a.

This second discharge nozzle 300 is provided in a cylindrical shape. At this time, the second discharge nozzle 300 has an opening formed on the bottom surface, and a connector 310 into which the inlet 210 is inserted is formed on the upper surface. Accordingly, the first discharge nozzle 200 may be inserted into the second discharge nozzle 300, and the inlet part 210 passes through the connector 310 to be exposed outside the second discharge nozzle 300. I can. In this case, the length of the second discharge nozzle 300 may be shorter than the length of the first discharge nozzle 200 so that the lower region of the first discharge nozzle 200 can be exposed to the outside.

In addition, a third discharge hole H3 is formed in the sidewall of the second discharge nozzle 300. The third discharge hole H3 is provided in plural. The plurality of third discharge holes H3 are arranged in the height direction of the second discharge nozzle 300 and may be provided to have a plurality of rows. At this time, the plurality of third discharge holes H3 are formed to have an inclination toward the side of the second discharge nozzle 300, so that when steam is injected from the first discharge nozzle 200 disposed inside, separate power It is provided to be able to rotate without supply.

In addition, a plurality of fans 320 are formed in the upper region of the second discharge nozzle 300. The plurality of fans 320 are provided to have a shape extending from the second discharge nozzle 300 and rotate together with the second discharge nozzle 300 when the second discharge nozzle 300 is rotated.

The plurality of fans 320 guides the steam discharged to the cooling water in the downward direction of the second discharge nozzle 300 and simultaneously generates forced convection in the water tank 20a.

That is, as the steam is discharged from the first discharge nozzle 200, the second discharge nozzle 300 rotates and discharges the steam outward, and at this time, the inside of the water tank 20a according to the rotation of the plurality of fans 320 Forced convection occurs.

Accordingly, the steam discharge nozzle 100 prevents the formation of a thermal layer in the water tank 20a by generating forced convection inside the water tank 20a even if separate power is not supplied, and the steam stays inside the water tank 20a. It has the advantage of increasing the time to play.

Hereinafter, with reference to the accompanying drawings to be described in detail the operation of the steam discharge system according to the present embodiment. However, for the above-described components, detailed descriptions are omitted and the same reference numerals are assigned to describe them.

7 is an operation diagram schematically showing the operation of the steam discharge system according to the present embodiment.

As shown in FIG. 7, the steam discharge system 1000 according to this embodiment is connected to the reactor pressurizer 10 so that the steam discharged from the reactor pressurizer 10 is conveyed toward the water tank 20a. Accordingly, the steam discharge system 1000 may maintain a state in which the steam discharge nozzle 100 is accommodated in the cooling water inside the water tank 20a.

Thereafter, the steam from the reactor pressurizer 10 is provided to the inlet 210 through the pressurizer safety discharge valve 40. Accordingly, the first discharge nozzle 200 discharges steam from the first inlet region 200a and the second inlet region 200b. At this time, the second discharge hole H2 of the second inlet region 200b is formed to be narrower than the first discharge hole H1, so that relatively even steam is discharged outside the first discharge nozzle 200.

At this time, the second discharge nozzle 300 disposed outside the first discharge nozzle 200 rotates with respect to the first discharge nozzle 200 based on the steam discharged from the first discharge nozzle 200 to discharge steam. Let this happen. At this time, the second discharge nozzle 300 is stably rotated by the third discharge hole H3 provided to have a lateral inclination, and the vapor is discharged to the outside of the second discharge nozzle 300.

Here, the plurality of fans 320 formed on the second discharge nozzle 300 rotate together with the second discharge nozzle 300. Accordingly, the steam discharged from the second discharge nozzle 300 is conveyed toward the side and downward of the second discharge nozzle 300, and the residence time of the steam may be increased. In addition, as the fan 320 rotates, forced convection occurs inside the water tank 20a, and thus there is an advantage of preventing the occurrence of a thermal layer that causes fatigue damage.

As described above, in the steam discharge nozzle and the steam discharge system including the same according to the present invention, as the amount of steam increases, the heat transfer between the jetted steam and the coolant in the water tank becomes active, thereby improving the steam cooling effect and reducing the pressure of the containment by the steam. have.

In addition, the steam discharge nozzle and the steam discharge system including the same according to the present invention generate forced convection to promote mixing between the upper and lower parts of the water tank, thereby preventing the formation of a thermal layer in the water tank.

One embodiment of the present invention described above and illustrated in the drawings should not be construed as limiting the technical idea of the present invention. The protection scope of the present invention is limited only by the matters described in the claims, and those of ordinary skill in the technical field of the present invention can improve and change the technical idea of the present invention in various forms. Therefore, such improvements and changes will fall within the scope of the present invention as long as it is apparent to those of ordinary skill in the art.

1000: steam release system
10: reactor pressurizer 20: reloading water tank
20a: water tank 30: discharge pipe
40: pressurizer safety release valve 100: steam discharge nozzle
200: first discharge nozzle 300: second discharge nozzle

Claims (8)

In the steam discharge nozzle to discharge the steam discharged from the nuclear power plant through the water tank,
A first discharge nozzle for discharging steam flowing into the interior; And
A second discharge nozzle supported by the first discharge nozzle to allow the steam to be discharged through the water tank, rotate when the steam is discharged from the first discharge nozzle, and generate a forced convection inside the water tank,
The first discharge nozzle
A second inlet that has a cylindrical shape and communicates with the first inlet region through which the steam first flows in and the first inlet region by a partition wall spaced apart from the bottom surface from the inside, so that the steam flows in from the first inlet region Have an area,
On the sidewall of the first inflow area
A plurality of first discharge holes are arranged and formed,
On the sidewall of the second inflow area
A vapor discharge nozzle in which a plurality of second discharge holes are arranged.
The method of claim 1,
In the second discharge nozzle
A steam discharge nozzle provided with at least one fan for increasing the residence time of the steam by generating forced convection inside the water tank.
delete The method of claim 1,
The diameter of the second discharge hole is
A steam discharge nozzle that is provided smaller than the diameter of the first discharge hole to discharge steam having a mutually uniform pressure in the first and second inlet regions.
The method of claim 1,
The height of the second inflow area is
A vapor discharge nozzle provided lower than the first inlet region by a block located at an upper portion.
The method of claim 1,
The second discharge nozzle
It is provided to have a cylindrical outer shape with an opening formed on one side, and the first discharge nozzle is inserted into the inside, and a connection hole through which an inlet portion that forms a path through which the steam flows into the first discharge nozzle is formed on the upper surface. Nozzle.
The method of claim 6,
On the side wall of the second discharge nozzle
A third discharge hole is arranged so that the steam discharged from the first discharge nozzle is discharged toward the water tank,
The third discharge hole is
The vapor discharge nozzle is formed to be inclined toward the side of the second discharge nozzle so that the second discharge nozzle rotates when the steam is discharged.
Nuclear power plant equipment;
A discharge pipe connected to the nuclear power plant to form a path through which steam discharged from the nuclear power plant is transferred to the water tank; And
It includes a steam discharge nozzle connected to the discharge pipe inside the water tank to discharge the steam to the water tank,
The vapor discharge nozzle
A first discharge nozzle for discharging steam flowing into the interior,
A second discharge nozzle supported by the first discharge nozzle to allow the steam to be discharged through the water tank, rotate when the steam is discharged from the first discharge nozzle, and generate a forced convection inside the water tank,
The first discharge nozzle
A second inlet that has a cylindrical shape and communicates with the first inlet region through which the steam first flows in and the first inlet region by a partition wall spaced apart from the bottom surface from the inside so that the steam is introduced from the first inlet region Have an area,
On the sidewall of the first inflow area
A plurality of first discharge holes are arranged and formed,
On the sidewall of the second inflow area
A vapor discharge system in which a plurality of second discharge holes are arranged.

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