KR101977341B1 - Integrated Reactor Installation Pressurizer System with Surge Lines - Google Patents

Abstract

The present invention relates to a pressurizer system for an integrated nuclear reactor including a surge line, capable of forming a sufficient separation space for reducing heat loss from a pressurizer without being installed by being extended lengthwise toward the pressurizer or a coolant circulation flow path. To achieve the purpose of the present invention, the pressurizer system for an integrated nuclear reactor comprises: a lower housing having an accommodation space with a predetermined depth as the upper part of a surge line is open, wherein the lower housing also includes an inlet of a predetermined length, connected to the bottom of the accommodation space; an upper housing covering the accommodation space of the lower housing and forming an inlet of a predetermined diameter corresponding to the inlet of the lower housing; and a flow path forming member inserted into the accommodation space and forming a flow path for a coolant flowing into the surge line through the inlet to be gradually mixed by passing through the accommodation space.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an integrated reactor pressurizer system,

The present invention relates to a pressurizer system for an integrated nuclear reactor with a throat tube, and more particularly, to a pressurizer system for an integrated nuclear reactor, To a pressurizer system of an integral nuclear reactor having a thruster.

A pressurizer is configured to maintain a pressurized state above a saturation pressure in order to prevent the coolant from boiling in the core. Recently, an integrated reactor in which such a pressurizer is installed inside a reactor vessel has been developed.

In the integrated reactor, the main components of the reactor are installed in the reactor vessel (pressure vessel), and there is an advantage that the radioactive material such as the coolant can be prevented from flowing out to the outside even if an accident such as an earthquake occurs, There is a structural problem that the heat lost from the pressurizer to the reactor coolant circulation channel is increased. Therefore, various attempts have been made to reduce the heat loss of the pressurizer in the integrated reactor.

[0004] Japanese Patent Application Publication No. 0872513 discloses a milling tube (hereinafter, referred to as patent document) for reducing the heat loss of a pressurizer in an integrated nuclear reactor.

The jamming pipe disclosed in the above patent document is formed in the form of a cylindrical pipe having a certain length from the upper portion barrel of the upper guide structure to the upper and lower sides in the longitudinal direction so that the jamming between the pressurizer and the reactor coolant circulation channel The coolant is mixed sequentially and / or progressively when the overturning phenomenon occurs, thereby reducing the heat loss of the pressurizer.

However, in the case of the above-described journalling tube, in order to exhibit a sufficient heat loss reduction performance between the coolant circulation channel and the pressurizer, the above-mentioned journaling tube must be formed long in the vertical direction and then a plurality of compartment- As a result, the heat exchanging area contacting the inner and outer sides of the cooling pipe circulation channel and the inner side of the pressurizer is widened. As a result, As the heat is transferred, the heat loss reduction efficiency becomes poor.

Therefore, it is required to develop a pressurizer system of an integrated reactor having an improved throttle tube so as to be able to form a sufficient isolation space for reducing the heat loss of the pressurizer without being extended to the side of the pressurizer or the coolant circulation flow path.

KR10-0872513 B1 (Dec. 01, 2008) KR10-0272726 B1 (Aug. 29, 2000) KR10-0354172 B1 (Sep. 12, 2002) KR10-0383817 B1 (Apr. 30, 2003)

SUMMARY OF THE INVENTION Accordingly, it is an object of the present invention to provide a pressurizer system for a nuclear power reactor capable of reducing the heat loss of a pressurizer without extending the pressurizer or the coolant circulation conduit. Which is capable of forming a sufficient isolation space for the reactor.

According to an aspect of the present invention, there is provided an integrated reactor pressurizer system including: a lower housing having an upper opening and a receiving space having a predetermined depth, the lower housing having a predetermined length of inlet and outlet communicating with a lower surface of the receiving space; An upper housing having an inlet and an outlet having a predetermined diameter corresponding to the inlet and outlet while covering the receiving space of the lower housing; And a flow path forming member inserted in the receiving space to form a flow path so that the coolant flowing into the inside of the pushing tube through the inlet and outlet is gradually mixed with each other via the receiving space, An insertion body having a cylindrical shape and having a predetermined length up and down; An upper receiving portion formed at an upper portion of the insertion body to have a predetermined depth; A lower receiving portion formed at a lower portion of the insertion body to have a predetermined depth; A plurality of penetrating portions formed at predetermined intervals along the outer surface of the insertion body to penetrate the inner and outer sides of the upper and lower receiving portions; And a pair of latching portions formed to protrude by a predetermined length along upper and lower outer sides of the insertion body.

The present invention is characterized in that the diameter of the penetration portion is 1/4 to 2/4 of the inner side diameter of the upper and lower receiving portions.

The present invention is further characterized in that an auxiliary pipe having a predetermined diameter between the lower housing and the flow path forming member and separating the receiving space in the vertical direction is further provided.

In addition, according to the present invention, the auxiliary pipe includes a cylindrical auxiliary pipe body having a hole communicating with the upper pipe and the lower pipe; An oil passage partition plate protruding to a predetermined width along an inner center portion of the auxiliary pipe body; And a plurality of through holes formed at predetermined intervals so as to pass through the passage partition plate vertically.

The diameter of the plurality of through holes is formed to be relatively smaller than the diameter of the through hole.

According to the present invention, a sufficient flow path for sequentially mixing the coolant can be formed in the accommodation space without being extended to the side of the pressurizer or the coolant circulation flow path, whereby the coolant can be sequentially and progressively So that the heat loss on the pressurizer side is reduced.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a view showing an example of an integral nuclear reactor in which a threshing tube is installed according to the present invention; FIG.
FIG. 2 is a perspective view showing an example of a pressurizer system of an integral nuclear reactor having a threshing tube according to the present invention. FIG.
Figure 3 is an exploded perspective view of Figure 2;
Fig. 4 is a sectional view of Fig. 2; Fig.
5 is a view showing an example of a lower housing according to the present invention.
6 is a view showing an example of an upper housing according to the present invention.
7 is a view showing an example of a flow path forming member according to the present invention.
FIG. 8 is a view showing an example of a flow of a coolant formed through a pressurizer system of an integral nuclear reactor having a throttle according to the present invention. FIG.
9 is a view showing an example of an auxiliary tube according to the present invention.
FIG. 10 is a view showing an example of a milling tube provided with the auxiliary pipe according to FIG. 9; FIG.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

An object of the present invention is to provide a pressurizer system of an integral nuclear reactor having a push-in pipe or a push-in pipe capable of sufficiently forming an isolation space for reducing heat loss of a pressurizer without being installed elongated toward a circulating flow path of a coolant.

1, a reactor core 1 having a predetermined size, a reactor core 2 positioned at an inner lower portion of the reactor vessel 1, an inner core 2 of the reactor vessel 1, A coolant circulation flow path 3 located in the upper part of the reactor vessel 1 and a steam generator 4 installed in a side space of the coolant circulation flow path 3; A coolant pump 5 for circulating a coolant on the reactor vessel 1, a dome-shaped pusher 6 installed to cover the upper portion of the reactor vessel 1, and a heater 7 installed inside the pusher 6 A plurality of pushing pipes 8 are provided so that the coolant circulating flow path 3 and the pressurizing device 6 communicate with each other.

At this time, a plurality of installation holes 6B are formed in the heat insulating plate 6A for partitioning between the coolant circulating flow path 3 and the presser 6, and a plurality of the installation holes 6B are inserted into the plurality of installation holes 6, .

2 and 3, the jamming tube 8 according to the present invention includes a lower housing 10, an upper housing 20, and a flow path forming member 30, 8 will be described.

The lower housing 10 is fixed to the installation hole 6B of the presser 6 while a receiving space having a predetermined size is formed therein so as to insert a passage forming member 30 to be described later.

4 and 5, the lower housing 10 includes a housing main body 11 having an upper opening and a receiving space 11A having a predetermined depth formed therein, An inlet and an outlet 12 protruding downward so as to have a predetermined diameter on the bottom surface of the housing main body 11 so as to communicate with the accommodation space 11A to allow the coolant to flow in and out, (13).

At this time, the flange portion 13 is formed to be relatively larger than the diameter of the installation hole 6B formed in the heat insulating plate 6A, whereby the flange portion 13 is formed when the extension pipe 8 is inserted into the installation hole 6B, The flange 13 and the heat insulating plate 6A are welded together or the clamping tube 8 is welded to the heat insulating plate 6A 6A).

When the jamming tube 8 is assembled to the heat insulating plate 6A using the fastening member, a plurality of through holes (not shown) are formed along the flange portion 13 so as to insert the bolts assembled through the heat insulating plate 6A .

The upper housing 20 is configured to be positioned on the upper portion of the lower housing 10 so as to cover the opened accommodation space 11A of the lower housing 10. [

6, the upper housing 20 includes a housing main body 21 having a cylindrical shape and having a predetermined length up and down, an inlet / outlet 22 formed so as to pass through the inside of the housing main body 21 vertically, And a flange portion 23 formed to protrude a predetermined width along a lower outer surface of the housing main body 21.

The flange portion 23 is formed to have a diameter corresponding to the housing main body 11 of the lower housing 10 so that the upper housing 20 is seated on the lower housing 10 and then the flange portion 23 And the lower housing 11, and are integrally fixed to each other.

According to the above-described configuration, the coolant introduced into the lower housing 10 is not leaked into the gap between the lower housing 10 and the upper housing 20 without providing a separate sealing member, thereby ensuring airtightness .

The coolant at the side of the pressurizer 6 flows into the coolant circulation flow path 3 through the inlet 22 of the upper housing 20 or the coolant at the coolant circulation flow path 3 flows toward the pressurizer 6 .

The flow path forming member 30 is inserted into the receiving space 11A of the lower housing 10 to form a flow path through which the coolant flows.

As shown in FIGS. 3 and 7, the flow path forming member 30 includes a cylindrical insertion body 31 having an upper and a lower length, A lower receiving portion 33 formed to have a predetermined depth in a lower portion of the insertion body 31 and a lower receiving portion 33 formed to extend through the upper and lower receiving portions 32, A plurality of penetrating portions 34 formed at predetermined intervals along the outer surface of the insertion body 31 and a pair of engaging portions 35 formed to protrude by a predetermined length along upper and lower outer surfaces of the insertion body 31 So that a partition P having a predetermined thickness is formed between the upper and lower receiving portions 32 and 33 of the insertion body 31. [

At this time, the diameter D1 of the penetrating portion 34 is formed to be 1/4 to 2/4 of the inner side diameter D2 of the upper and lower accommodating portions 32 and 33, The coolant flowing into the receiving portions 32 and 33 passes through the penetrating portion 34 having a relatively small diameter so that the coolant stays in the upper and lower accommodating portions 32 and 33 for a predetermined time and then passes through the penetrating portion 34 And gradually moved to the next space.

When the flow path forming member 30 is inserted between the lower housing 10 and the upper housing 20, the latching part 35 is tightly fixed to the inner surface of the lower housing 10 and the upper housing 20 The latching part 35 may be formed so as to have a predetermined depth along the upper and lower outer peripheries of the insertion body 31 instead of being protruded to a predetermined width outside the insertion body 31. [

As a result, the coolant circulating flow path 3 and the coolant on the side of the pressurizer 6 are mixed with each other through a predetermined step, so that the heat energy on the side of the pressurizer 6 is transmitted to the coolant circulating flow path 3 unnecessarily, Is prevented from being generated.

Hereinafter, the coolant flows from the coolant circulation channel 3 side to the pressurizer 6 with reference to FIG. 8, for example.

The coolant toward the coolant circulation flow path 3 flows into the space A formed by the lower accommodating portion 33 of the flow path forming member 30. [

Then, the coolant in the space A passes through the plurality of through-holes 34 formed through the inside and outside of the lower accommodating portion 33 between the inner surface of the accommodating space 11A and the outer surface of the flow path forming member 30 And then flows into the B space formed in the second row.

The coolant introduced into the B space flows into the C space through a plurality of penetration portions 34 formed through the inside and outside of the upper accommodating portion 33 and then flows through the inlet and outlet 22 of the upper housing 20 The coolant on the side of the coolant circulation flow path 3 flows toward the pressurizer 6 as the coolant flows to the pressurizer 6, and the heat energy is transmitted.

When the coolant on the side of the pressurizer 6 flows toward the coolant circulation flow path 3, heat energy is transferred in the order of the C space, the B space, and the A space in the reverse order.

As a result, the coolant on the side of the coolant circulation flow path 3 or the pressurizer 6 sequentially passes through the spaces A, B, and C and is gradually mixed, thereby reducing the heat loss of the pressurizer 6. [

The coolant flows sequentially through spaces A, B, and C formed by the accommodation space 11A and the flow path forming member 30. However, in order to further reduce the heat loss on the side of the pressurizer 6, 11A and the outer surface of the flow path forming member 30 may further include an auxiliary pipe 40 for further dividing the inner flow path.

As shown in FIG. 9, the auxiliary pipe 40 includes a cylindrical auxiliary pipe main body 41 having a hole communicating with the top and the bottom, And a plurality of through holes 43 formed at predetermined intervals so as to pass through the flow dividing plate 42 vertically.

10, when the auxiliary pipe 40 is inserted into the receiving space 11A of the lower housing 10, the inner surface of the receiving space 11A and the outer surface of the flow path forming member 30 The B space formed in the upper and lower spaces is divided into the B1 space and the B2 space so that the coolant flows sequentially along the spaces A, B1, B2, and C, and is gradually mixed.

At this time, the diameter D3 of the through hole 43 is formed to be relatively smaller than the diameter D1 of the through hole 34 formed in the flow path forming member 30, thereby passing through the through hole 34, Or the coolant introduced into the B2 space is delayed for a predetermined time when flowing into the opposite space, the heat loss is further reduced.

As described above, according to the present invention, a sufficient flow path for sequentially mixing the coolant can be formed in the accommodation space without being extended to the side of the pressurizer or the coolant circulation flow path, whereby the coolant flows sequentially And gradually flows to be mixed with each other, so that heat loss on the side of the pressurizer is reduced.

Although the preferred embodiments of the present invention have been disclosed for illustrative purposes, those skilled in the art will appreciate that various modifications, additions and substitutions are possible, without departing from the scope and spirit of the invention as disclosed in the accompanying claims. It is to be understood that the scope of the present invention should not be construed as being limited only by the appended claims and should not be construed as limiting the scope of the present invention to those of ordinary skill in the art. It will be very self-evident.

1: Reactor vessel 2: Reactor core
3: coolant circulation flow path 4: steam generator
5: coolant pump 6: pressurizer
6A: Insulating plate 6B: Mounting hole
7: heater 8:
10: lower housing 11: housing body
11A: accommodation space 12: inlet / outlet
13: flange portion 20: upper housing
21: housing body 22: inlet / outlet
23: flange portion 30: flow path forming member
31: insertion body 32: upper receiving portion
33: lower receiving portion 34: penetrating portion
35: latching portion 40: auxiliary tube
41: auxiliary tube main body 42: flow path partition plate
43: Through hole D1: Diameter of penetration part
D2: Diameter of upper and lower receiving part
D3: diameter of penetrating hole P:

Claims (5)

A pressurizer system for an integral nuclear reactor in which a cooling pipe (8) for reducing the heat loss of the pressurizer (6) is provided between a coolant circulation channel (3) and a pressurizer (6)
The jarring tube (8)
A lower housing 10 having a receiving space 11A having an open top and a predetermined depth and having an inlet / outlet 12 of a predetermined length communicating with the bottom of the receiving space 11A;
An upper housing 20 having an inlet / outlet 22 of a predetermined diameter corresponding to the inlet / outlet 12 while covering the accommodation space 11A of the lower housing 10; And
The coolant introduced into the accommodating space 11A and flowing into the inside of the pushing tube 8 through the inlet and outlet 12 and 22 is gradually mixed with the accommodating space 11A A flow path forming member (30);
Lt; / RTI >
The flow path forming member (30)
An insertion body 31 having a cylindrical shape and having a predetermined length vertically;
An upper receiving portion 32 formed at an upper portion of the insertion body 31 to have a predetermined depth;
A lower receiving portion 33 formed at a lower portion of the insertion body 31 to have a predetermined depth;
A plurality of penetrating portions 34 formed at predetermined intervals along the outer surface of the insertion body 31 so as to penetrate the inner and outer sides of the upper and lower receiving portions 32 and 33; And
A pair of latching portions 35 protruding along the upper and lower outer sides of the insertion body 31 by a predetermined length;
Wherein the pressurizer system includes a pressurizing system for pressurizing the reactor.
The method according to claim 1,
The diameter (D1) of the penetrating portion (34)
Wherein the inner diameter D2 of the upper and lower accommodating portions 32, 33 is 1/4 to 2/4 of the inner side diameter D2 of the upper and lower accommodating portions 32, 33.
The method of claim 2,
Between the lower housing 10 and the flow path forming member 30,
Wherein the auxiliary pipe (40) is further provided with an auxiliary pipe (40) having a predetermined diameter and partitioning the accommodation space (11A) in the vertical direction.
The method of claim 3,
The auxiliary pipe (40)
An auxiliary tube main body 41 of cylindrical shape in which an opening communicating with the upper side and the lower side is formed;
A flow path partition plate (42) protruding a predetermined width along an inner center portion of the auxiliary pipe main body (41); And
A plurality of through holes (43) formed at predetermined intervals so as to pass through the passage partitioning plate (42) vertically;
Wherein said pressurizer system comprises a pressurizing system for pressurizing the reactor.
The method of claim 4,
The diameter (D3) of the plurality of through holes (43)
Is smaller than the diameter (D1) of the penetrating portion (34).

Images