KR102135636B1 - An union structure of an upper wrench of a reactor upper structure lifting equipment and lower wrench - Google Patents

Abstract

The present invention relates to a structure for fastening upper and lower wrenches of a reactor upper structure lifting equipment and, more specifically, to a structure for fastening upper and lower wrenches of a reactor upper structure lifting equipment, capable of making the upper and lower wrenches fastened only in one direction and substantially and stably maintaining the confinement of a fastening pin by using a locking sleeve. To achieve the purpose, the structure includes: a lower wrench including a hollow duct and a fastening pin formed on the inner surface to protrude towards the duct; a hollow upper wrench lifted in the lower wrench and including a fastening groove opened towards the fastening pin; and a locking sleeve lifted in the upper wrench and including a locking groove opened towards the fastening pin combined with the fastening groove. The upper wrench includes an elongated slot penetrated towards the locking sleeve and formed in a longitudinal direction of the upper wrench, and the locking sleeve includes an indication bar exposed to the outside of the upper wrench through the slot, thereby the position of the locking sleeve being capable of being recognized in the upper wrench.

Description

An union structure of an upper wrench of a reactor upper structure lifting equipment and lower wrench}

The present invention relates to a fastening structure of an upper wrench and a lower wrench of a nuclear reactor upper structure lifting mechanism, and more specifically, a nuclear reactor upper structure so that the fastening of the upper and lower wrenches of the nuclear reactor upper structure lifting mechanism can be firmly and stably maintained. It relates to the fastening structure of the upper and lower wrenches of the lifting mechanism.

Reactor vessels in nuclear power plants, reactor vessels, reactor heads, upper guide structures (UGS), core support barrels (CSBs), lower support structures (LSSs) Structure). Nuclear power plants will disassemble and assemble nuclear reactors for planned preventive maintenance. In the process of disassembling and assembling the reactor, the upper guide structure of the reactor is lifted by the lifting mechanism for refueling and is mounted on the storage.

As shown in Figures 1 and 2, the lifting mechanism is a spreader 10 for lifting, a cylindrical column 20 connected to the spreader 10 and provided on the outer periphery of the upper portion, into the cylindrical column 20 It includes an upper wrench 30 that is inserted and provided with a handle portion 31 on one side, and a lower wrench 40 that is connected to the upper wrench 30 and one side and the other side is connected to the lifting bolt B. The lifting mechanism provided as described above is moved to the upper portion of the reactor to match the upper guide structure S of the reactor and the center line. Thereafter, the upper wrench 30 is inserted into the cylindrical column 20 to connect to the lower wrench 40, and the lower wrench connected to the upper wrench 30 by rotating the handle portion 31 of the upper wrench 30 ( 40) and the lower wrench 40, the lifting bolt (B) is rotated to be fastened with the upper guide structure (S) of the nuclear reactor. The cylindrical column 20 is installed on the outer three places of the lifting mechanism and the upper end is connected to the spreader 10 and lifted by the spreader 10.

On the other hand, as shown in Figure 4, the inside of the lower wrench 40, the fastening pin 41 is installed, the upper wrench 30 is inserted into the lower wrench 40 and then hooked to the fastening pin 41 As it becomes possible, the combination of the upper wrench 30 and the lower wrench 40 is completed. To this end, a guide groove 32 for inserting the fastening pin 41 and a fastening groove 33 for fastening the fastening pin 41 are formed at a lower end of the upper wrench 30. With this configuration, the operator inserts the upper wrench 30 into the lower wrench 40 to guide the fastening pin 41 to the guide groove 32 and rotate the upper wrench 30 to fasten the pin 41 By being positioned in the fastening groove 33, fastening of the upper wrench 30 and the lower wrench 40 is achieved.

However, the fastening structure of the upper and lower wrenches according to the prior art as described above has the following problems.

First, since the portion where the upper wrench 30 and the lower wrench 40 are fastened to each other is located inside the lower wrench 40, it is difficult for an operator to visually check the fastening portion. As described above, the conventional fastening structure of the upper wrench 30 and the lower wrench 40 is difficult for an operator to visually check the fastening part, so even if the fastening of the upper wrench 30 and the lower wrench 40 is not made accurately, Overlooked, there is a problem that a safety accident may occur due to separation of the upper wrench 30 and the lower wrench 40. For example, as shown in Figure 4, the fastening pin 41 of the lower wrench 40 may not be completely inserted into the fastening groove 33 of the upper wrench 30, and thus the upper wrench 30 and the lower wrench ( When the lifting mechanism is lifted in an incompletely fastened state, the upper wrench 30 may be detached from the lower wrench 40. As described above, a safety accident may be caused to the worker in the process of departure of the upper wrench 30 and the lower wrench 40, and the upper wrench 30 and the lower wrench 40 may be attached to any one of the lifting points. When the separation occurs, as the lifting mechanism is tilted to one side and the lifting balance is broken, there is a problem that deformation may occur in the superstructure S itself. Furthermore, there is a problem that the reactor components may be damaged because they cannot be seated in place due to interference with the surrounding structures during lifting of the superstructure S.

Second, in the conventional fastening structure of the upper wrench 30 and the lower wrench 40, since the formation of the fastening groove 33 is made in both directions based on the fastening pin 41, as shown in FIG. There is a risk of errors, ie carelessness or confusion.

Republic of Korea Registration No. 10-1537475

The present invention has been devised to solve the above problems, and the object of the present invention is to prevent the fastening pin from being detached from the fastening groove by restraining the fastening pin coupled to the upper wrench from above, and outside the upper wrench. The purpose of the present invention is to provide an upper wrench and a lower wrench fastening structure of a nuclear reactor upper structure lifting mechanism so that a worker can visually check whether the upper and lower wrenches are correctly engaged by allowing the position of the locking sleeve to be grasped.

The present invention, in order to achieve the above object, the hollow (中空) is formed with a pipe, the inner side of the lower wrench formed with a fastening pin protruding toward the pipe; A hollow upper wrench that is elevated inside the lower wrench and has a fastening groove opened toward the fastening pin; And a locking sleeve which is elevated inside the upper wrench, and has a locking groove formed toward a fastening pin coupled to the fastening groove, and penetrated toward the locking sleeve in the upper wrench, but in the height direction of the upper wrench. A slot is formed, an indicator bar exposed to the outside of the upper wrench through the slot is formed in the locking sleeve, so that the position of the locking sleeve is recognized inside the upper wrench, thereby lifting the upper structure of the reactor. It provides the fastening structure of the upper and lower wrenches of the mechanism.

At this time, the fastening groove is composed of an access groove part opened toward the fastening pin, a guide groove part formed along the outer circumferential surface of the upper wrench from the access groove part, and a restraining groove part bent downward from the guide groove part desirable.

delete

At this time, the height of the slot is preferably the locking groove corresponds to the lifting distance of the locking sleeve for restraining and releasing the fastening pin.

The upper and lower wrench fastening structures of the nuclear reactor upper structure lifting mechanism according to the present invention constitute separate locking sleeves to cover and fasten the fastening pins coupled to the fastening grooves of the upper wrench. Accordingly, even if an external force due to vibration or the like occurs in the wrench, the fastening pin in the fastened groove can be firmly coupled without being separated from the fastening groove, so that the fastening force of the upper wrench and the lower wrench can be stably and firmly provided. There is.

In addition, the upper wrench and lower wrench fastening structure of the reactor's upper structure lifting mechanism constitutes an indicator bar on the locking sleeve, and the indicator bar is exposed outside the upper wrench, so that the operator can check whether the upper wrench and the lower wrench are fastened through the position of the indicator bar. It was made to be able to confirm with the naked eye. Accordingly, there is an effect that the operator can easily grasp whether or not the upper wrench and the lower wrench are fastened.

1 is a view showing a lifting mechanism of a nuclear reactor superstructure according to the prior art.
2 is a view showing a cylindrical columnar constituting the lifting mechanism of the reactor superstructure according to the prior art.
3 is a view showing a main part of a state in which the lifting bolts constituting the lifting mechanism of the reactor upper structure according to the prior art are fastened to the upper structure.
4 is a view showing a main portion of the coupling structure between the upper and lower wrench constituting the lifting mechanism of the nuclear reactor superstructure according to the prior art.
5 is a perspective view showing an upper wrench and a lower wrench fastening structure of a nuclear reactor upper structure lifting mechanism according to a preferred embodiment of the present invention.
6 is a perspective view showing a locking sleeve of an upper wrench and a lower wrench fastening structure of a nuclear reactor upper structure lifting mechanism according to a preferred embodiment of the present invention.
7A and 7B are cross-sectional views showing before and after locking sleeves fasten the fastening pins in the fastening structure of the upper and lower wrenches of the reactor upper structure lifting mechanism according to the preferred embodiment of the present invention.
8A and 8B show a state in which the locking sleeve is constrained to the upper wrench before and after the locking sleeve is restrained in the fastening structure of the upper and lower wrenches of the reactor upper structure lifting mechanism according to the preferred embodiment of the present invention. It is a cross section.

The terms or words used in the specification and claims are not to be construed as being limited to ordinary or lexical meanings, and the inventor is based on the principle that the concept of terms can be properly defined in order to best describe his or her invention It should be interpreted in a sense and concept consistent with the technical idea of the present invention.

Hereinafter, the fastening structure of the upper and lower wrenches of the reactor upper structure lifting mechanism according to the preferred embodiment of the present invention with reference to the accompanying Figures 5 to 8b (hereinafter referred to as'fastening structure of the upper and lower wrenches') Will be explained.

The fastening structure of the upper and lower wrenches ensured that the fastening between the upper and lower wrenches was stable and robust. In addition, the fastening structure of the upper wrench and the lower wrench was made to allow the operator to visually confirm the fastening between each other.

The fastening structure of the upper wrench and the lower wrench includes a lower wrench 100, an upper wrench 200, a locking sleeve 300, and a flow prevention pin 400, as shown in FIG. 5.

The lower wrench 100 is configured to be equipped with a lifting bolt (see FIG. 1) to be coupled to the upper structure (see FIG. 1) of the nuclear reactor, and is disposed inside the cylindrical column (see FIG. 1). The lower wrench 100 is made of a hollow tube, and the inner diameter of the lower wrench 100 may be any size as long as the upper wrench 200 can enter and exit. The lower end of the lower wrench 100 having such a configuration is provided so that the lifting bolt B can be installed, and the upper end of the lower wrench 100 is provided to allow the upper wrench 200 to enter and exit. It is preferable that the upper end portion of the lower wrench 100 forms a guide portion 110 in the form of an expansion tube for guiding the entrance of the upper wrench 200. A fastening pin 120 protruding toward the conduit of the lower wrench 100 is formed on the inner surface of the lower wrench 100. The fastening pin 120 is a coupling medium for coupling the lower wrench 100 and the upper wrench 200 to each other through fastening with the upper wrench 200.

The upper wrench 200 is coupled to the lower wrench 100 by being fastened to the fastening pin 120 of the lower wrench 100. As the upper wrench 200 is fastened to the lower wrench 100, an operator can lift the upper structure of the nuclear reactor by lifting the upper wrench 200 using the spreader 10. The upper wrench 200 is preferably formed in a hollow cylindrical opening toward the lower wrench 100. A lug 210 for lifting the upper wrench 200 is formed at an upper end of the upper wrench 200. The lug 210 may enable the lifting operation to be stably and easily performed when the upper wrench 200 is lifted. The lower end of the upper wrench 200 is opened, and the locking sleeve 300 is formed inside the upper wrench 200. A fastening groove 220 for fastening with the fastening pin 120 is formed at a lower end of the upper wrench 200 as shown in FIG. 5. The fastening groove 220 is preferably composed of an access groove portion 221, a guide groove portion 222, and a restraining groove portion 223. The access groove 221 serves as an entrance for guiding the fastening pin 120 to the restraining groove 223, and is opened in the longitudinal direction of the upper wrench 200 from the lower end of the upper wrench 200. The guide groove 222 is configured to guide the fastening pin 120 inserted through the access groove 221 to the restraining groove 223, and is formed along one circumferential direction of the upper wrench 200 from the access groove 221. do. The guide groove 222 is formed only in one direction based on the access groove 221. Accordingly, by rotating the upper wrench 200 on the fastening pin 120 of the lower wrench 100, it is possible to prevent a human error of the operator when combined. The restraining groove 223 is a configuration in which the fastening pin 120 is restrained, and is bent downward from the guide groove 222. The restraining groove 223 may restrain the fastening pin 120 by closing the access groove 221 unlike the opening. A pair of handles 230 are formed at the upper end of the upper wrench 200.

5, a slot 240 and a flow prevention hole 250 are formed in the upper wrench 200. The slot 240 is a through hole through which the indicator bar of the locking sleeve 300, which will be described later, is exposed out of the upper wrench 100, and provides a lifting path of the indicator bar. The slot 240 is formed in the form of a long hole in the longitudinal direction of the upper wrench 200. The flow prevention hole 250 is a configuration in which the flow prevention pin 400 for preventing the flow of the locking sleeve 300 inside the upper wrench 200 is inserted. The flow prevention pin 400 is inserted through the flow prevention hole 250 to constrain the flow of the locking sleeve 300 so that the movement of the locking sleeve 300 within the upper wrench 200 can be constrained. Detailed description thereof will be described later. The flow prevention hole 250 is provided in plural in the height direction of the upper wrench 200 and is preferably two. Two flow prevention holes 250 are provided to constrain movement according to the position of the locking sleeve 300 in the interior of the upper wrench 200. For convenience of explanation, the upper flow prevention hole 250 is referred to as an upper hole 251, and the lower flow prevention hole 250 under the upper hole 251 is referred to as a lower hole 252.

The locking sleeve 300 serves to prevent the upper wrench 200 coupled to the fastening pin of the lower wrench 100 from coming off. The locking sleeve 300 covers the fastening pin 120 inserted in the restraining groove part 223 of the upper wrench 200 to block the fastening pin 120 from being released upward from the restraining groove part 223. will be. The locking sleeve 300 is configured to be elevated inside the upper wrench 200 as shown in FIG. 5. As shown in FIG. 6, an intermittent hole 310 is formed on the outer circumferential surface of the upper end of the locking sleeve 300. The intermittent hole 310 is formed to allow the flow prevention pin 400 to be inserted, and is formed to correspond to the flow prevention hole 250. In the lower portion of the intermittent hole 310, an indicator bar 320 is formed to protrude toward the outside of the locking sleeve 300. The indicator bar 320 is provided as a handle for elevating the locking sleeve 300 and is configured to allow an operator to grasp the position of the locking sleeve 300. A locking groove 330 is formed at a lower end of the locking sleeve 300. The locking groove 330 is configured to bind the fastening pin 120 from above, and is opened toward the bottom of the locking sleeve 300. The inner diameter of the locking groove 330 may be any size as long as the fastening pin 120 can be accommodated. On the other hand, the height of the slot 240 is preferably the locking groove 330 corresponds to the lifting distance of the locking sleeve 300 for restraining and releasing the fastening pin 120.

The flow prevention pin 400 serves to constrain the up and down movement of the locking sleeve 300 inside the upper wrench 200. The flow prevention pin 400 is inserted into the intermittent hole 310 of the locking sleeve 300 through the flow prevention hole 250 of the upper wrench 200, as shown in Figure 5, the movement of the locking sleeve 300 It can be bound.

Hereinafter, the fastening process between the upper and lower wrenches according to the fastening structure of the upper and lower wrenches of the upper structure lifting mechanism of the nuclear reactor having the above-described configuration will be described with reference to FIGS. 7A to 8B.

The worker lowers the upper wrench 200 to the pipeline of the lower wrench 100 using the lifting equipment. At this time, the fastening pin 120 of the lower wrench 100 is inserted into the access groove 221 of the upper wrench 200. Thereafter, the operator rotates the upper wrench 200 in one direction. The upper wrench 200 is rotated while the guide groove 222 is guided along the fastening pin 120. Thereafter, when the fastening pin 120 corresponds to the restraining groove 223, the operator lifts the upper wrench 200 to couple the upper wrench 200 to the lower wrench 100 as shown in FIG. 7A.

On the other hand, Figure 7a is the locking sleeve 300 is the state before the fastening pin 120, Figure 8a is the locking sleeve 300 is moved inside the upper wrench 200 by the flow prevention pin 400 You are bound. The worker lifts the locking sleeve 300 and locks the flow prevention pin 400 through the upper hole 251 in a state where the intermittent hole 310 of the locking sleeve 300 corresponds to the upper hole 251 of the upper wrench 200. By inserting into the intermittent hole 310 of the sleeve 300, the locking sleeve 300 is in a state where movement is constrained at the position before the fastening pin 120 is constrained. At this time, the indicator bar 320 is located in the upper portion of the slot 240, the operator can easily recognize the position and state of the locking sleeve 300 through the position of the indicator bar with the naked eye.

Next, the operator pulls the flow prevention pin 400 from the intermittent hole and the upper hole 251 to lower the locking sleeve 300 in a state in which the locking sleeve 300 is restrained. At this time, the operator can utilize the instruction bar 320 as a handle. The lowered locking sleeve 300 covers the fastening pin 120 as shown in FIG. 7B, precisely the fastening pin 120 is accommodated in the locking groove 330 of the locking sleeve 300, and the locking sleeve ( 300) is in a state in which the fastening pin 120 is restrained using its own weight. At this time, the intermittent hole 310 of the lowered locking sleeve 300 corresponds to the lower hole 252 of the upper wrench 200. In addition, since the indicator bar 320 of the locking sleeve 300 is located at the lower end of the slot 240, the operator can easily recognize the state and position of the locking sleeve 300 with the naked eye.

As shown in Figure 8b, the operator inserts the flow prevention pin 400 into the intermittent hole 310 of the locking sleeve 300 through the lower hole 252 of the upper wrench 200. As the flow prevention pin 400 constrains the locking sleeve 300, the locking sleeve 300 covering the fastening pin 120 is not lifted upward even though movement of the wrench is caused by external force. do. Accordingly, the fastening force of the upper wrench 200 and the lower wrench 100 may be further increased, and such fastening force may be stably maintained.

Next, the operator connects the spreader to the lug 210 of the upper wrench 200 to lift the upper structure of the reactor.

As described so far, the fastening structure of the upper wrench and the lower wrench of the reactor upper structure lifting mechanism according to the present invention allows the fastening groove fastening direction of the upper wrench to be made in only one direction, and the upper wrench is removed from the fastening pin using a locking sleeve. It was made to prevent. Accordingly, the fastening structure between the upper and lower wrenches of the upper structure and the lower wrench of the lifting mechanism for the upper structure of the nuclear reactor strengthens the fastening force between the upper and lower wrenches, and the firm fastening force can be stably maintained.

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

100: lower wrench 110: guide
120: fastening pin 200: upper wrench
210: lug 220: fastening groove
221: access groove 222: guide groove
223: restraint groove 230: handle
240: slot 250: flow prevention ball
251: upper hole 252: lower hole
300: locking sleeve 310: interrupter
320: indicator bar 330: locking groove
400: flow prevention pin

Claims (4)

A hollow pipe is formed, the inner surface has a lower wrench formed with a fastening pin protruding toward the pipe;
A hollow upper wrench that is elevated inside the lower wrench and has a fastening groove opened toward the fastening pin; And
It includes a locking sleeve that is raised in the interior of the upper wrench, and has a locking groove opened toward a fastening pin coupled to the fastening groove,
A slot of a long hole is formed in the height direction of the upper wrench through the upper sleeve of the upper wrench, and an indicator bar exposed to the outside of the upper wrench through the slot is formed in the locking sleeve. A fastening structure of the upper and lower wrenches of the reactor upper structure lifting mechanism, characterized in that the position of the locking sleeve can be recognized. According to claim 1,
The fastening groove,
Lifting the upper structure of the nuclear reactor, characterized in that it comprises an entrance groove opened toward the fastening pin, a guide groove formed along the outer circumferential surface of the upper wrench from the entrance groove, and a restraining groove bent downward from the guide groove. The fastening structure of the upper and lower wrenches of the instrument. delete The method according to claim 1 or 2,
The height of the slot is the fastening structure of the upper and lower wrenches of the reactor upper structure lifting mechanism, characterized in that the locking groove corresponds to the lifting distance of the locking sleeve for restraining and releasing the fastening pin.

Images