KR101141778B1 - Nuclear fuel transfer tube blind flange clamping device - Google Patents

Abstract

PURPOSE: An apparatus for clamping a flange blocking a nuclear fuel transfer pipe is provided to minimize radiation doses since a flange blocking a nuclear fuel transfer pipe is opened and closed rapidly using a clamping device. CONSTITUTION: A fastening flange(10) is combined with an outer circumferential surface of an end portion of a nuclear fuel transfer pipe penetration sleeve(11). A blocking flange(20) is closely connected with the fastening flange. A clamping device combines the fastening flange with the blocking flange closely. A first clamping portion(31) is inserted into a part of the outer circumferential surface of the blocking flange and the fastening flange. A second clamping portion is inserted into the rest of the outer circumferential surface of the blocking flange and the fastening flange. A compression coupling member presses and couples first and second clamping portions.

Description

Nuclear fuel transfer tube blind flange clamping device

The present invention relates to a shut-off flange clamping device of a nuclear fuel transport pipe, and more particularly, to a shut-off flange clamping device of a nuclear fuel transport pipe which can open and close a shut-off flange of a nuclear fuel transport pipe quickly by using a clamping means and minimize radiation dose. It is about.

The shutoff flange of the nuclear fuel transport pipe is installed to maintain the pressure boundary on the containment side of the fuel transport pipe, which serves as a passage for transferring fuel between the containment building and the fuel building in the nuclear power plant.

1 to 3 schematically show the structure of a conventional blocking flange. In the conventional blocking flange, a plurality of bolts 7 are used to fasten the blocking flange 3 to the fixed flange 2 fixed to the nuclear fuel transfer pipe through sleeve 8.

The shutoff flange 2 of the nuclear fuel transport pipe 1 serves as a pressure boundary of the containment vessel during the output operation of the nuclear power plant and should be removed to provide a passage for transporting fuel during the reload of the nuclear fuel. Since the conventional blocking flange 3 is fastened using a plurality of bolts 7 to the fixed flange 2, the operator is exposed to the high radiation area for a long time during the installation and removal of the blocking flange (3). Therefore, the radiation exposure dose is increased.

The removal process of the conventional blocking flange 3 is as follows. To remove the fuel feed pipe blocking flange (3) of the nuclear power plant, first check that the fuel transfer system upender is up and the radiation is shielded. After connecting the chain block hook (4) provided separately to the lifting ring (5) of the blocking flange (3) to maintain only three bolts and nuts fastened to the blocking flange (3) at intervals of 120 degrees and the rest (in Figure 1) Unpack and store in a designated box.

Remove the remaining bolt (7) while lifting the weight of the blocking flange (3) using the chain block hook (4). At this time, since the contaminated water remaining in the fuel transport pipe may flow out, great care should be taken. After moving horizontally along the guide rails (6) to a position accessible to the containment ceiling crane (not shown), replace the blocking flange (3) from the chain block hook (4) to the overhead crane hook (Operating) Store up to Floor).

The blocking flange 3 is shielded by lead and stored at a designated place to complete the removal process. The installation sequence of the blocking flange 3 is performed in the reverse order of the removal process.

Therefore, in order to remove and install the conventional blocking flange, the operator is exposed to radiation for a long time, so it is required to be able to open and close it quickly.

The present invention has been made in view of the above-described matters, the fuel transfer pipe to improve the work efficiency by enabling the quick opening and closing of the shut-off flange for opening and closing the nuclear fuel transport pipe, the operator to minimize the radiation exposure dose An object of the present invention is to provide a blocking flange clamping device.

The shutoff flange clamping device of the nuclear fuel transport pipe according to the present invention for achieving the above object, is coupled to the outer peripheral surface of the end portion of the nuclear fuel transport pipe through sleeve, the fixed flange through the center; An outer circumferential surface is formed in a shape corresponding to the outer circumferential surface of the fixed flange, the plate-shaped blocking flange is in close contact with the fixed flange; And a clamping means for tightly coupling the fixed flange and the blocking flange, wherein the clamping means includes a first clamping portion fitted to the outer circumferential surface of the fixed flange and the blocking flange, and the rest of the fixed flange and the blocking flange. And a second clamping part fitted to an outer circumferential surface and a pressure fastening member configured to press and fasten the first clamping part and the second clamping part to each other.

Here, a first inclined surface is formed on the fixed flange along its outer circumferential surface, and a second inclined surface is formed on the blocking flange along its outer circumferential surface, and the first and second clamping parts correspond to the first and second inclined surfaces. It is preferable that three inclined surfaces were formed.

Here, it is preferable that an airtight O-ring is inserted between the fixed flange and the blocking flange.

Here, the pressure fastening member, the bolt and nut for bolting the first and second clamping portion; And a lever rotatably coupled to the first and second clamping portions, a through portion penetrating through the first and second clamping portions, an extension extending from one end of the through portion, and a nut coupled to the through portion. It is preferable that it consists of.

Here, a first through hole is formed in the first clamping part, a lifting lug is coupled to the first through hole, and both ends of the lifting lug are fixed together with the blocking flange.

Here, a second through hole is formed in the second clamping part, and a support hole is formed at a point corresponding to the second through hole in the fixing flange, and passes through the second through hole so as to support the second clamping part. It is preferable to further include a support member inserted into and supported by the support hole.

Here, the outer circumferential surface of the fixed flange and the blocking flange is annular, the first clamping portion is fitted to the upper semicircle of the fixed flange and the blocking flange, the second clamping portion in the lower half circle of the fixed flange and the blocking flange It is preferable to fit.

The shutoff flange clamping device of the nuclear fuel transfer pipe according to the present invention enables to open and close the shutoff flange for opening and closing the nuclear fuel transfer pipe quickly, thereby improving the work efficiency and providing the effect of minimizing the radiation dose to the operator.

1 is a schematic conceptual diagram of a structure of a conventional fuel transfer pipe blocking flange;
2 is a cross-sectional view of a conventional fuel transfer pipe blocking flange structure;
Figure 3 is a front view of the conventional fuel transfer pipe blocking flange,
4 is a cross-sectional view of the nuclear fuel transfer pipe blocking flange according to the embodiment of the present invention;
5 is a front view of a blocking flange according to an embodiment of the present invention;
6 and 7 are excerpts of the first clamping portion employed in the embodiment of the present invention;
8 and 9 are excerpts of the second clamping portion employed in the embodiment of the present invention;
FIG. 10 is an enlarged view of a portion “A” of FIG. 5.

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

First, referring to FIG. 4, the blocking flange clamping apparatus of the nuclear fuel transport pipe according to the embodiment of the present invention includes a fixed flange 10, a blocking flange 20, and a clamping means.

The stationary flange 10 is coupled to the outer peripheral surface of the end portion of the nuclear fuel transfer pipe through sleeve 11, the central portion thereof is penetrated. In this embodiment, the fuel transfer pipe through sleeve 11 is formed in an annular shape, and the fuel transfer pipe 13 is inserted therein. The stationary flange 10 is also formed in an annular shape on the outer peripheral surface of the end portion of the nuclear fuel transfer pipe through sleeve (11).

The blocking flange 20 is a portion that is in close contact with the fixed flange 10, the outer peripheral surface is made of a shape corresponding to the outer peripheral surface of the fixed flange 10, unlike the fixed flange 10 in a plate shape Is done.

The shut-off flange 20 serves as a pressure boundary of the containment vessel during the output operation of the nuclear power plant, and serves as a passage for removing fuel when the nuclear fuel is reloaded.

The clamping means is provided to closely couple the fixed flange 10 and the blocking flange 20, and fasten the blocking flange 20 to the fixed flange 10, and quickly from the fixed flange 10 It is prepared to separate.

The clamping means includes a first clamping portion 31, a second clamping portion 32, and a pressure fastening member.

The first clamping portion 31 is a member that is fitted to the outer peripheral surface of the fixed flange 10 and the blocking flange 20, in the present embodiment the first clamping portion 31 is a fixed flange 10 and It is fitted in the upper semicircle of the blocking flange (20).

As shown in FIG. 4, in the present embodiment, the fixed flange 10 is formed with a first inclined surface 12 along its outer circumferential surface, and the blocking flange 20 has a second inclined surface 21 along its outer circumferential surface. ) Is formed. In addition, a third inclined surface 316 corresponding to the first and second inclined surfaces 12 and 21 is formed in the first clamping part 31. The third inclined surface 316 of the first clamping part 31 presses the fixed flange 10 and the blocking flange 20 to improve the fastening force transmitted to the fixed flange 10 and the blocking flange 20 and The first clamping part 31 may be easily inserted into the fixed flange 10 and the blocking flange 20.

6 and 7, the first clamping portion 31 is fastened to the semi-circular portion into which the fixed flange 10 and the blocking flange 20 are fitted and to the second clamping portion 32 at both ends of the semi-circular portion. The first pressure contact portion 311 is formed.

A first fastening hole 312 is formed in the first pressure-contacting part 311 so as to be fastened to the second clamping part 32 and the bolt 41, and one side is opened adjacent to the first fastening hole 312. Open holes 313 are formed. In addition, an insertion groove 314 connected to the opening hole 313 is formed in the first pressure contact part 311. The opening 313 and the insertion groove 314 is provided for the operation of the lever 42 to be described later.

In addition, the first clamping part 31 is formed with a first through hole 315 to which the lifting lug 60 is coupled. 6 and 7, in the present embodiment, the first through hole 315 is formed at the upper end of the semi-circular portion of the first clamping portion 31. As shown in FIG.

The second clamping part 32 is fitted to the remaining outer circumferential surfaces of the fixed flange 10 and the blocking flange 20. In the present embodiment, the second clamping part 32 is fitted to the lower semicircle of the fixed flange 10 and the blocking flange 20.

Like the first clamping part 31, the second clamping part 32 includes a third inclined surface 316. First and second inclined surfaces 12 and 21 are formed in the fixed flange 10 and the blocking flange 20, respectively, along the outer circumferential surface thereof, and the second clamping portion 32 is formed in the first and second inclined surfaces 12 and 21. In response to 21), a third inclined surface 316 is provided.

The second clamping part 32 is press-fitted by the first clamping part 31 and the pressure fastening member described later. At this time, the third inclined surface 316 formed on the first and second clamping parts 31 and 32. The effective transmission of the fastening force to the fixed flange 10 and the blocking flange 20.

8 and 9, like the first clamping part 31, the second clamping part 32 has a semicircular portion into which the fixed flange 10 and the blocking flange 20 are fitted, and both ends of the semicircular portion. The second pressing contact portion 321 is fastened to the first clamping portion 31.

A second fastening hole 322 is formed in the second pressure-contacting part 321 to fasten the first clamping part 31 and the bolt 41, and is adjacent to the second fastening hole 322 to open the opening. A third fastening hole 323 is formed in communication with 313. The third fastening hole 323 is provided for the operation of the lever 42 together with the opening hole 313 and the insertion groove 314.

In addition, a second through hole 325 is formed in the second clamping part 32. 4 and 5, in the present embodiment, the second through hole 325 is formed at the lower end portion of the semi-circular portion of the second clamping portion 32.

The pressure fastening member is provided to press fasten the first clamping part 31 and the second clamping part 32 to each other. The pressure fastening member includes a bolt 41, a nut 411, and a lever 42.

The bolt 41 is inserted through the first and second fastening holes 312 and 322 formed in the first and second pressure contact parts 311 and 321 and the first and second clamping parts 31 and 32 using a nut 411. Bolting.

The lever 42 includes a through part 421, an extension part 422, and a nut 423.

The through part 421 penetrates through the third fastening hole 323 and the opening hole 313 as a part penetrating the first and second clamping parts 31 and 32. The extension part 422 extends from one end of the through part 421. A nut 423 is fastened to a lower end of the through part 421.

The lever 42 inserts the penetrating portion 421 into the opening 313 of the second clamping portion 32 and loosely fastens the nut 423 to the lower end of the penetrating portion 421. 2 Close the pressure contact portion (311, 321) to each other. At this time, the extension part 422 is inserted through the open part of the opening hole 313. When the first and second pressure-contacting parts 311 and 321 contact each other, the extension part 422 is rotated and inserted into the insertion groove 314, and then the first and second clamping parts 31 and 32 are tightened by tightening the nut 423. ) Comes in close contact.

On the other hand, the shut-off flange clamping device of the nuclear fuel transfer pipe according to the present embodiment further includes an airtight O-ring 50, the lifting lug 60, and the support member 70.

As shown in FIG. 4, the airtight O-ring 50 is disposed between the fixed flange 10 and the blocking flange 20. The airtight O-ring 50 prevents radiation contaminants from leaking between the fixed flange 10 and the blocking flange 20. In this embodiment, two airtight O-rings 50 are provided concentrically. Of course, the number can be variously changed.

The lifting lug 60 is provided to hold and move the blocking flange 20 when the blocking flange 20 is separated from the fixed flange 10.

As shown in FIG. 5, the lifting lug 60 is formed in a “∩” shape, and both ends thereof are coupled to the first through hole 315 formed in the first clamping part 31. In addition, both ends of the lifting lug 60 is fixed together with the blocking flange (20). When the blocking flange 20 is removed, after the clamping of the first and second clamping parts 31 and 32 is released, the lifting flange 60 of the first clamping part 31 is lifted when the blocking flange 20 is removed. 20 is configured to be transported together. As a method of fixing the lifting lug 60 to the blocking flange, various methods such as welding may be used.

The support member 70 is provided to support the second clamping portion 32 to the fixed flange 10. The support member 70 is composed of a support piece 71 of a "∪" type and a nut member 72 respectively inserted into a portion extending vertically from the support piece 71.

As described above, a second through hole 325 is formed in the second clamping part 32, and a support hole 326 is formed at a point corresponding to the second through hole 325 in the fixed flange 10. Is formed. Specifically, both ends of the support piece 71 penetrates through the second through hole 325 and is inserted into the support hole 326 to be fixed, and a thread is formed in the support piece 71 so that the nut member 72 is formed. Combined with.

When the second clamping portion 32 is fitted to the fixed flange 10 and the blocking flange 20, the support member 70 supports the second clamping portion 32, and the nut member 72 Tightening or loosening can adjust the height of the second clamping portion (32).

Therefore, it is not necessary to install a separate support on the bottom to support the second clamping portion 32, the height of the second clamping portion 32 through the support member 70 when fastening with the first clamping portion 31 Can be adjusted.

In addition, when the blocking flange 20 is to be removed, the second clamping portion 32 is fixed by the support member 70 in a state where the clamping of the first and second clamping portions 31 and 32 is released. Since it is supported in the state 10), when the separation of the blocking flange 20, a separate support for supporting the second clamping portion 32 is not necessary.

As such, the shutoff flange clamping device of the nuclear fuel transport pipe according to the embodiment of the present invention, the fastening and closing the fixed flange 10 and the blocking flange 20 by using the clamping means to ensure the stability of the operator in the high-radiation work zone do.

In addition, since the time required for the replacement work of the blocking flange 20 is shortened, it is possible to shorten the critical process during the nuclear power plant planning and maintenance period, thereby improving the utilization rate of the nuclear power plant.

In addition, the third inclined surface 316 of the first and second clamping parts 31 and 32 presses the first and second inclined surfaces 12 and 21 formed on the fixed flange 10 and the blocking flange 20 to effectively tighten the clamping force. The first and second clamping parts 31 and 32 pressurize the entire outer circumferential surface of the first and second clamping parts 31 and 32 using the lever 42 and the bolt 41 to fix the flange 10. And the effect of reliably sealing the boundary of the blocking flange 20.

In addition, since the support member 70 supporting the second clamping part 32 does not need to provide a separate support stand, the installation and removal process of the blocking flange 20 is simplified, and the second clamping part 32 is Since it is supported by the fixing flange 10 by the support member 70 it is possible to prevent the safety accident of the operator due to the falling accident of the second clamping portion (32).

In addition, it is possible to minimize the safety and convenience of the operator, such as the radiation exposure dose can actively cope with the notification on the radiological protection that is further strengthened.

As mentioned above, although the preferred embodiment of the present invention has been described in detail, the present invention is not limited to the above embodiment, and many various modifications may be provided without departing from the scope of the present invention. Therefore, the true technical protection scope of the present invention will be defined by the technical spirit of the appended claims.

10 ... Flanged flange 11 ... Nuclear fuel feed pipe through sleeve
12 ... 1st slope 13 ... Nuclear fuel transfer pipe
20 ... Blocking flange 21 ... Second slope
31 ... 1st clamping part 311 ... 1st press contact part
312 ... First fastener 313 ... Open hole
314 ... Insertion groove 315 ... First through hole
32 ... 2nd clamping part 321 ... 2nd pressing contact part
322 ... 2nd fastener 323 ... 3rd fastener
325 ... 2nd through hole 326 ... support hole
41 ... bolt 411 ... nut
42 ... Lever 421 ... Penetration
422 ... extension 423 ... nut
50 ... Airtight O-Ring 60 ... Salvage Lug
70 ... support member 71 ... support
72 ... Nut member

Claims (7)

A stationary flange 10 coupled to the outer circumferential surface of the end portion of the nuclear fuel transfer pipe through sleeve 11 and having a central portion penetrated therethrough;
An outer circumferential surface is formed in a shape corresponding to the outer circumferential surface of the fixed flange 10, and a plate-shaped blocking flange 20 that is tightly coupled to the fixed flange 10; And
It includes a clamping means for closely coupling the fixed flange 10 and the blocking flange 20,
The clamping means is fitted to the first clamping portion 31 fitted to a part of the outer peripheral surface of the fixed flange 10 and the blocking flange 20, and the other outer peripheral surface of the fixed flange 10 and the blocking flange 20. And a second clamping part (32), and a pressure clamping member for pressing and fastening the first clamping part (31) and the second clamping part (32) to each other. The method of claim 1,
A first inclined surface 12 is formed in the fixed flange 10 along its outer circumferential surface, and a second inclined surface 21 is formed in the blocking flange 20 along its outer circumferential surface.
The first and second clamping portion (31,32) is a flange clamping device of the nuclear fuel pipe, characterized in that the third inclined surface (316) corresponding to the first and second inclined surface (12, 21) is formed. The method of claim 1,
An airtight O-ring (50) is inserted between the stationary flange (10) and the blocking flange (20) blocking flange clamping device of the nuclear fuel transport pipe. The method of claim 1,
The pressure fastening member,
Bolts 41 and nuts 423 bolting the first and second clamping parts 31 and 32; And
A through part 421 rotatably coupled to the first and second clamping parts 31 and 32 and penetrating the first and second clamping parts 31 and 32 and one end of the through part 421. Blocking clamping device of the nuclear fuel transport pipe, characterized in that consisting of a lever (42) having an extension portion (422) extending from, and the nut (423) coupled to the through portion (421). The method of claim 1,
A first through hole 315 is formed in the first clamping part 31, and a lifting lug 60 is coupled to the first through hole 315, and both ends of the lifting lug 60 are formed. Blocking clamping device of the nuclear fuel transport pipe, characterized in that is fixed with the blocking flange (20). The method of claim 1,
A second through hole 325 is formed in the second clamping part 32, and a support hole 326 is formed in the fixed flange 10 at a point corresponding to the second through hole 325.
In order to support the second clamping portion 32, further comprising a support member 70 which passes through the second through hole 325 and is inserted into and supported by the support hole 326. Shut-off flange clamping device. The method of claim 1,
The outer circumferential surfaces of the fixed flange 10 and the blocking flange 20 are annular,
The first clamping part 31 is fitted to an upper semicircle of the fixed flange 10 and the blocking flange 20, and the second clamping part 32 is the fixed flange 10 and the blocking flange 20. Shut-off flange clamping device of the nuclear fuel transport pipe, characterized in that inserted into the semi-circle of the lower side.

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