KR101860607B1 - Shim plate device having vent-notches for air circulating under the steam generator of pressurized water reactor - Google Patents

Abstract

The present invention relates to an apparatus for preventing thermal deformation of a sliding base for supporting a reactor steam generator to prevent a vibration phenomenon of a nuclear reactor and a coupling surface between a lower surface of a skirt support of a steam generator and an upper surface of a sliding base And a plurality of vent holes formed in the radial direction on the upper surface of the shim plate and recessed circumferentially at equal intervals in the radial direction of the shim plate, Notches) to cool the sliding base and the air stagnation zone on the inner side of the skirt support through the plurality of vent notches to naturally cool the air outside the skirt support so as to prevent thermal deformation of the sliding base, A suction plate device is provided.
According to the present invention, it is possible to greatly reduce the heat transferred from the steam generator to the sliding base, thereby effectively preventing the thermal deformation of the sliding base and preventing the structural vibration of the reactor to prevent abrasive wear of the steam generator, An excellent effect that can effectively prevent wear can be obtained.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a steam generator of a pressurized water reactor,

The present invention relates to an apparatus for circulating air in a stagnated air area located below a steam generator and more particularly to a system for circulating air between a lower surface of a skirt support supporting a reactor steam generator and a lower surface Air circulation type shim plate is arranged to allow the outside air to flow into the stagnated air area inside the stay cylinder and the skirt support to naturally cool the high temperature region and to cool the high temperature region And more particularly, to an outer air intake plate unit under the reactor steam generator for effectively preventing the steam from being transferred from the steam generator to the sliding base, thereby preventing a vibration phenomenon of the reactor due to the thermal expansion deformation of the sliding base.

Generally, nuclear reactors are used in Korea, for example, Convustion Engineering (CE) System Plus 80 (Hanbit 3 & 4), Korea Standard Nuclear Power Plant (Hanols 3, 4, 5, 6 and Hanbit 5,6 And the APR1400 (Shin Gori 3 and 4, Shin Ulchin 1 and 2, UAE Nuclear Power Units 1 and 4), and 2-loop pressurized water reactor.

Generally, a reactor power plant (hereinafter simply referred to as a "reactor") is a reactor coolant system (RCS) in a containment building, as described in Korean Patent Registration No. 10-1473665, entitled "Piping Support Device for Replacement Parts of Nuclear Power Plants" Reactor Coolant System).

Such a reactor coolant system has a reactor containing a reactor and at least one heat transfer circuit connected thereto.

Each circuit includes a steam generator and at least one coolant pump that circulates the coolant between the reactor and the steam generator.

In addition, the circuit includes a pusher that keeps the temperature and pressure of the coolant constant.

The first large diameter piping or hot leg is connected to one side of the reactor and one side of the suction portion of the coolant chamber of the steam generator to contact the core in the reactor to transfer the heated coolant to the steam generator.

A circulation tube, called a cross-over leg, connects one side of the discharge section of the coolant chamber of the steam generator and one side of the swirl chamber suction section of the coolant pump.

The cold leg connects the swirling chamber of the coolant pump and the reactor. Also, the coolant cooled in the steam generator and drawn out by the coolant pump is transferred to the reactor through the circulation tube, the cold tube, and cools the core.

In such a reactor, each steam generator 1 has a substructure as shown in Fig.

That is, the steam generator 1 has a stay cylinder 10 maintained at a high temperature, and a skirt support 20 having a cylindrical structure supporting the stay cylinder 10 at a lower portion thereof.

Such a skirt support 20 is a cylindrical steel structure located on the lower side of the stay cylinder 10 and the lower surface 20a of the skirt support 20 is supported on the upper side of the sliding base 30 Is directly in surface contact with the surface (30a) and fixedly supported by a plurality of stud anchors (32).

The sliding base 30 is slidably supported on a plurality of, for example, four hemispherical sliders 42 provided on the bearing anchor plate 40 and the bearing plate 41, To accommodate the resulting thermal expansion and fine movement.

Since the steam generator 1 generates a high temperature during operation, the heat insulating material 50 for preventing the high temperature from being transmitted to the lower sliding base 30 is supplied to the stay cylinder 10 and the skirt support 20 ).

In the conventional sliding base 30, the keys 46 protruding from the posed anchor plate 40 are positioned in the keyhole 48, respectively.

In such a steam generator 1, a high temperature of 300 ° C or higher is generated in the inside of the stay cylinder 10 during operation, and this high temperature is transmitted to the lower side to thermally deform the sliding base 30.

In order to prevent this, a heat insulating material 50 is attached to the lower portion of the stay cylinder 10, but the heat insulating material 50 can not completely block the heat. The sliding base 30 is heated and thermally deformed due to various factors.

Particularly, the skirt support 20 of the steam generator 1 is a cylindrical supporting steel structure, and a stagnated air area 80 is formed inside the skirt support 20.

In this air congestion zone 80, a heat insulating material 50 of the stay cylinder 10 is positioned at the upper side, a cylindrical wall-shaped skirt support 20 is located around the air congestion zone 80, and a sliding base 30 Is disposed on the upper surface to form a closed space.

Such an air congestion zone 80 acts as a space for radiating high heat of the steam generator 1, thereby causing severe thermal deformation of the sliding base 30.

Problems related to this are described in detail below.

That is, the thermal deformation of the sliding base 30 suppresses free movement due to the thermal expansion of the sliding base 30 generated during operation of the power plant, or interferes with the surrounding structure on the upper part of the steam generator 1 , Resulting in structural vibration of the steam generator 1 and the coolant pump.

These structural vibrations cause tubular wear and vibration stress of the steam generator (1), and when operated for a long period of time, boric acid leakage occurs due to fatigue of small diameter piping with boric acid brittleness due to accumulation of boric acid.

Also, as a construction factor of the reactor piping, the final connection welding of the intermediate tube and the steam generator (1) nozzle is left as a residual load on the sliding base 30 and the pump vertical support due to welding shrinkage. As a result of this residual load, the sliding base 30 is settled by the welding shrinkage. After the installation of the steam generator 1 and after the final connection welding, a settlement usually occurs within a range of about 1 mm.

Such a settlement amount can be regarded as a residual load on the sliding base 30. The residual load increases the frictional force on the sliding base 30 at the initial stage of the reactor and hinders the sliding operation in the lateral direction.

In addition, when the sliding base 30 is thermally deformed as described above, the steam generator 1 is operated by being inclined, and the phenomenon of misalignment between components can be exhibited even after the room temperature is stopped.

As a result, if the sliding base 30 is not deformed to be horizontal, the steam generator 1 is inclined and the vibration stress of the reactor due to the deformation and interference of the reactor coolant pump and the related supporting structure of the steam generator 1 stress.

This vibration stress not only causes the tubular wear of the steam generator (1), but also causes abrasion of the interior of the reactor coolant pump and fatigue cracking caused by piping connected to the RCS system to cause fatigue cracking frequently during operation of an overseas nuclear power plant have.

When operated in this state for a long period of time, it leads to the leakage of the mechanical seal of the reactor coolant pump and the small diameter piping.

Accordingly, in the art, development of a technique capable of preventing thermal deformation of the sliding base 30 of a nuclear reactor and preventing wear of the steam generator 1 due to structural vibration of the reactor and wear of the reactor coolant system equipment This is a situation that is desperately required.

SUMMARY OF THE INVENTION It is an object of the present invention to solve the above-mentioned problems of the related art by providing an air circulation type shim plate between a lower surface of a skirt support and an upper surface of a sliding base, The present invention provides an outside air intake plate device under a reactor steam generator that substantially reduces the heat transmitted from the steam generator to the sliding base and effectively prevents thermal deformation of the sliding base.

It is another object of the present invention to provide an external air suction plate device for a lower portion of a nuclear reactor steam generator which greatly reduces the phenomenon of direct heat conduction of high heat from the skirt support under the steam generator to the sliding base, .

According to an aspect of the present invention, there is provided an apparatus for preventing thermal deformation of a sliding base supporting a reactor steam generator,
A shim plate disposed along a mating surface between the lower surface of the skirt support of the steam generator and the upper surface of the sliding base and having a plurality of anchor holes through which the stud anchors are respectively passed;
A plurality of vent notches formed to pass through the shim plate in a radial direction on the upper surface of the shim plate and recessed to allow the air outside the skirt support to flow into the air baffle area inside the sliding base and the skirt support, ; And
And at least one air vent formed in the skirt support and configured to expose an air condi- tioning zone inside the sliding base and the skirt support to the outside atmosphere of the skirt support, wherein the air outside the skirt support, through the plurality of vent notches, And the air is introduced into the stagnation zone and discharged through the ventilation hole to perform natural circulation of the air to thereby prevent thermal deformation of the sliding base.

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Preferably, the vent notches are each formed as a groove having a "V" -shaped cross section, and are formed at equal intervals in the circumferential direction between the anchor holes of the shim plate.

Further, according to the present invention, it is preferable that the vent notches are each formed as a groove having a "V" -shaped cross section, and are formed at equal intervals in the circumferential direction between the anchor holes of the shim plate and the respective anchor holes.

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Preferably, the shim plate is divided into a plurality of shim plates,

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According to the present invention, the shim plate is disposed between the lower surface of the skirt support of the steam generator and the upper surface of the sliding base, and a plurality of vent notches are formed on the upper surface of the shim plate, And the air stagnation zone inside the skirt support, and forms a natural circulation path of the air that discharges the air through at least one vent hole formed in the skirt support.

Therefore, according to the present invention, the high temperature stagnation of the air stagnation zone can be eliminated to greatly reduce the temperature, and the high heat directly conducted from the skirt support under the steam generator to the sliding base can be cooled by the cold outside air passing through the notches of the simple rate It is possible to effectively prevent thermal deformation of the sliding base and to prevent structural vibration of the reactor and consequently to effectively prevent abrasion of the tub of the steam generator and wear of the reactor coolant system.

FIG. 1 is a cross-sectional view showing a structure in which a lower surface of a reactor steam generator according to a conventional technique, in particular, a lower surface of a skirt support is in direct surface contact with an upper surface of a sliding base.
FIG. 2 is an exploded sectional view showing a structure in which a shim plate is disposed between a skirt support and a sliding base in an outside air intake plate device under a reactor steam generator according to the present invention.
FIG. 3 is an external perspective view showing a shim plate provided in an outside air suction plate device under a reactor steam generator according to the present invention.
4 is a plan view and an enlarged view showing a structure in which vent notches of the shim plate are formed at equal intervals in the circumferential direction between the anchor holes of the shim plate in the air intake plate device under the reactor steam generator according to the present invention.
FIG. 5 is a plan view showing a structure in which vent notches of a shim plate are formed at intervals between anchor holes of a shim plate and at equal intervals in the circumferential direction on the respective anchor holes in an outside air suction plate device under a reactor steam generator according to the present invention. And an enlarged view.
FIG. 6 is a cross-sectional view illustrating an operation in which a shim plate is disposed between a skirt support and a sliding base in an outside air suction plate device under a reactor steam generator according to the present invention, and air is introduced through vent notches.

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

The outer air suction plate device 100 under the reactor steam generator according to the present invention is a device for preventing the thermal deformation of the sliding base 30 supporting the reactor steam generator 1 to prevent a vibration phenomenon of the reactor.

2, the outer air suction plate device 100 under the reactor steam generator according to the present invention includes a lower surface 20a of the skirt support 20 of the steam generator and a lower surface 20a of the upper surface of the sliding base 30, And a shim plate 110 disposed along a coupling surface between the first and second plates 30a.

The structure of such a shim plate 110 is shown in detail in Fig.

That is, the shim plate 110 has an annular ring shape and is formed on the coupling surface formed between the lower surface 20a of the skirt support 20 and the upper surface 30a of the sliding base 30 And a plurality of anchor holes 112 through which the stud anchors 32 pass, are formed at regular intervals in the circumferential direction.

In addition, the shim plate 110 has a plurality of vent notches 120 on its upper surface.

As shown in enlarged view in FIG. 4, these vent notches 120 are preferably formed as grooves of a "V" -shaped cross section, respectively, and between the anchor holes 112 of the shim plate 110, Direction and the like.

The plurality of vent notches 120 are formed in a concave shape in the radial direction on the upper surface of the shim plate 110. The plurality of vent notches 120 are formed on the inner side of the sliding base 30 and the air inside the skirt support 20 And serves as an air passage for introducing air outside the skirt support 20 into the stagnation zone.

5, the bent notches 120 are formed between the anchor holes 112 of the shim plate 110 and on the respective anchor holes 112 on the anchor holes 112, Direction, and the like.

In this structure, the vent notches 120 formed on the respective anchor holes 112 expose the stud anchors 32 to the outside air, thereby moving the stud anchors 32 from the skirt support 20 to the sliding base 30 It is possible to cool the high heat that is conducted.

The outer air suction plate device 100 in the lower part of the steam generator according to the present invention includes at least one ventilation hole 140 on one side of the skirt support 20 so as to prevent the sliding base 30 and the inside of the skirt support 20 So that the air congestion zone is exposed to the outside atmosphere of the skirt support 20.

Such a ventilation opening 140 may be formed in the form of an opening formed along the periphery of the skirt support 20. Through this ventilation opening 140, a man-way through which the operator enters the inside of the skirt support 20 ).

Accordingly, the ventilation hole 140 is formed such that the air outside the skirt support 20, which has flowed into the air stagnation area through the plurality of vent notches 120, is discharged through the ventilation hole 140, do.

The outer air suction plate device 100 under the reactor steam generator according to the present invention constructed as described above is installed between the lower surface 20a of the skirt support 20 of the steam generator and the upper surface 30a of the sliding base 30 The shim support plate 20, the shim plate 110 and the sliding base 30 are integrally fixed to each other through the stud anchor 32. [

An enlarged section of the structure thus combined is shown in Fig.

That is, the outer air suction plate device 100 under the reactor steam generator according to the present invention is disposed between the lower surface 20a of the skirt support 20 of the steam generator and the upper surface 30a of the sliding base 30 A plurality of vent notches 120 are formed on the upper surface of the shim plate 110 to allow the air outside the skirt support 20 to flow into the air baffle area inside the sliding base 30 and the skirt support 20, And forms a natural circulation path of air that discharges air through at least one ventilation hole 140 formed in the skirt support 20.

In such a structure, the plurality of vent notches 120 may have a plurality of circumferentially equally spaced structures between the anchor holes 112 of the shim plate 110 and / or on the respective anchor holes 112.

In such a structure, a plurality of vent notches 120 formed between the respective anchor holes 112 serve to cool and block the heat transmitted from the skirt support 20 to the sliding base 30, The vent notches 120 formed on the hole 112 serve to cool the high heat that is conducted from the skirt support 20 to the sliding base 30 through the stud anchors 32.

In addition, according to the present invention, the air outside the skirt support 20, which is introduced through the plurality of vent notches 120 into the air condi- tioning space, is discharged through the vent 140 to form a path for natural circulation of the air, The temperature of the air stagnation zone under the stay cylinder can be greatly lowered.

Therefore, according to the present invention, it is possible to effectively prevent thermal deformation of the sliding base 30 and to prevent the structural vibration of the reactor from occurring.

Although the present invention has been described in detail with reference to specific embodiments thereof with reference to the accompanying drawings, the present invention is not limited to such specific structures. It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined in the following claims. For example, the vent notches 120 may be formed in various cross sections, e.g., "U" shapes, or other types of cross sections, rather than a "V" In addition, the shim plate may be divided into a plurality of shim plates to facilitate assembly. On the other hand, a plurality of vent notches may be formed on the lower surface of the skirt support or the upper surface of the sliding base in a radial and circumferential concave manner without using a separate shim plate. However, it is intended that the present invention cover the modifications and variations of this invention provided they come within the scope of the appended claims and their equivalents.

1: Steam generator 10: Stay cylinder
20: skirt support 20a: lower surface
30: sliding base 30a: upper surface
32: stud anchor 40: posed anchor plate
41: bearing plate
42: Slider 46: Key
48: keyhole 50; lagging
80: stagnated air area
100: the outside air suction plate unit under the reactor steam generator
110: shim plate 112: anchor hole
120: Vent Notches 140: Vents

Claims (6)

An apparatus for preventing thermal deformation of a sliding base (30) supporting a reactor steam generator (1)
Are arranged along the mating surface between the lower surface 20a of the skirt support 20 of the steam generator 1 and the upper surface 30a of the sliding base 30 and the plurality of stud anchors 32 A shim plate (110) having anchor holes (112) formed therein;
The skirt support 20 is formed so as to pass through the shim plate 110 in a radial direction on the upper surface 30a of the shim plate 110 so that air outside the skirt support 20 can pass through the sliding base 30 and the inside of the skirt support 20 A plurality of vent notches 120 recessed to form air passages into the air condi- And
At least one ventilation opening 140 formed in the skirt support 20 and configured to expose the sliding base 30 and the air congestion zone 80 inside the skirt support 20 to the outside atmosphere of the skirt support 20; So that the air outside the skirt support 20 is introduced into the air condi- tioning space 80 through the plurality of vent notches 120 and discharged through the air vent 140, Wherein the sliding base (30) is configured to prevent thermal deformation of the sliding base (30). The vane cutter according to claim 1, wherein the vent notches (120) are each formed as a groove having a V-shaped cross section, and a plurality of vent notches (120) are formed at regular intervals in the circumferential direction between the anchor holes (112) (100) of the reactor steam generator. The vent hole (112) of claim 1, wherein the vent notches (120) are each formed as a groove having a "V" shaped cross section, and between the anchor holes (112) And a plurality of the heat exchangers are formed at equal intervals in the direction of the steam generator. delete 4. The apparatus according to any one of claims 1 to 3, wherein the shim plate (110) is divided into several parts to facilitate assembly. delete

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