KR100998620B1 - Hoist driving apparatus for nuclear reactor - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a reactor hoist drive for transferring a dismantling and tightening tensioner or driver tool for fastening the head of a reactor pressure vessel to the top of the stud. The present invention is a monorail 200 hypothesized on top of the reactor pressure vessel; A circumferential transfer part 310 moved along the monorail 200; A guide rail 330a coupled to the transfer part 310 and attached to the monorail 200 in a radial direction, and a roller 331 assembled to the guide rail 330a to perform a rolling action, and a hoist ( 300 is composed of a conveying body 330 to which the assembly is coupled and a conveying body moving means for conveying the conveying body 330. The present invention can transfer the stud tensioner 100a or the driver tool 100b to the top of the stud 10 by transporting the hoist 300 assembly in the circumferential or / and radial direction of the track 201.

Reactor, Reactor, Hoist, Radial, Transfer, Circumferential Transfer

Description

HOIST DRIVING APPARATUS FOR NUCLEAR REACTOR}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a reactor hoist drive for transferring a dismantling and tightening tensioner or driver tool for fastening the head of a reactor pressure vessel to the top of the stud.

Currently, commercial nuclear power plants are operated for a period of 12 to 18 months or longer to generate electricity, and then shut down at scheduled shutdowns for maintenance, maintenance and / or refueling. During a shut down during regular refueling, about one third of the spent fuel assembly in the core of the reactor pressure vessel needs to be replaced with a new fuel assembly, and the remaining fuel assembly is repositioned within the core. There is a need.

In other shutdown procedures, the fuel assembly may remain within the core but must be exposed. Fuel assemblies may contain rich uranium or other fissile material.

Therefore, workers working around pressure vessels must be protected from excessive radiation exposure. Each step of shutdown, whether it is an important policy or not, should be carried out as quickly and safely as possible to maintain a short shutdown period.

After checking or repairing the pressure vessel or refueling, the pressure vessel should be sealed to allow the plant to resume power generation. Shutdown plans are generally allotted for at least about 10 hours, and move stud-tight fixtures to the high radioactive environment around the reactor pressure vessel in the reactor building, and provide stud nuts to securely seal the head of the reactor pressure vessel. Five or more operators are required to operate the equipment around the pressure vessel flange to tension and then remove the tensioning equipment from the reactor building.

In commercial power plants (which typically include the simultaneous use of several multiple stud tensioners), the tensioning step requires more than two hours and may extend to radiation above 500 millimetres.

In general, the reactor pressure vessel is sealed with 54 studs. Therefore, after disassembling all 54 studs, inspecting the pressure vessel, repairing, or refueling, the 54 vessels must be assembled again to seal the pressure vessel.

The stud is mounted in a fastening hole provided around the flange of the vessel head and is screwed into the edge flange of the pressure vessel. Stud tensioning mechanism is used to compress the seal between the vessel head and the vessel flange and to tension the stud. The seal is squeezed when the stud tension is released because the nut on the vessel stud is rotated under the stud to tighten tightly.

The vessel studs and attached nuts are removed from the reactor vessel at the beginning of the fuel change cycle. The stud tensioning mechanism is again used to compress the seal between the vessel head and the vessel flange. The stud nut is then loosened several times to keep it loose after the stud tensioning mechanism is released.

Once the tension applied to all studs is removed, the studs and attached nuts are removed from the flange of the reactor pressure vessel. The vessel head then rises over the reactor vessel.

The stud tensioning device has several devices for engaging the top of the vessel stud on the nut flask device such that the stretching force extends the stud. Usually the pressure generated by the operation of the hydraulic cylinder raises the top of the vessel stud against the top face of the vessel head, and the nut acts to squeeze the seal between the reactor vessel flange and the vessel head.

As described above, in order to open and restore the reactor pressure vessel, the bolts fastened to the studs are disassembled to separate the head of the pressure vessel, and fuel replacement or necessary work is performed. Of course, when necessary, the studs are fastened to the flange to reseal the head of the pressure vessel.

However, this series of work processes are conducted in a narrow space with studs and above all in a high radioactive environment, so the daily radiation irradiation allowance does not allow sufficient working time. Is very long and heavy, and it is difficult to tilt the studs transversely or obliquely due to the interference of the fastened studs, and the space between the studs is so narrow that it is difficult to install workers or tools and instruments, and the heavy chain studs The equipment or apparatus must be used for disassembly and coupling, but it is not easy to attach and detach the equipment and apparatus, the disassembly and tightening must be performed to prevent the stud from being damaged, and the disassembly and tightening force of the stud must be physically and accurately transmitted to seal the pressure vessel head. Comprehensive consideration of points, etc. The stud tensioner and driver tool approached the tensioner and driver tool in the manner of lifting up and down from the top of the stud.

The characteristics of the reactor stud tensioner and driver tool proposed by the inventors are raised and lowered in the longitudinal direction of the stud by the hoist, and the stud tensioner and driver tool is mounted directly on the stud or supports studs disposed adjacent to the target stud. It is used as a means.

This can meet the operating conditions and working environment of the stud tensioner and driver tool as described above, the life of the stud and the handling and durability of the equipment.

The present invention seeks to propose a reactor hoist drive for transferring stud tensioners and driver tools to the top of the studs as described above.

It is an object of the present invention to provide a reactor stud transfer hoist drive for transferring a tensioner or driver tool for fastening or disassembling the stud to open or close the head of the reactor pressure vessel to the top of the stud.

As a means for implementing the hoist drive device for a reactor according to the object of the present invention,

A monorail installed on top of the reactor pressure vessel;

A circumferential transfer part moved along the monorail;

A conveying body coupled to the circumferential conveying part, the conveying body including a guide rail attached to the monorail in a radial direction, a roller assembled to the guide rail to roll, and coupled to a hoist assembly;

It is characterized by consisting of a conveying body moving means for conveying the conveying body.

The hoist for transporting the tensioner and driver tool for the reactor stud fastening and disassembly according to the invention to the top of the stud can move along the annular track of the monorail hypothesized on top of the reactor pressure vessel and move radially of the annular track. This makes it easy and convenient to operate the tensioner and driver tool in the limited space.

Hereinafter, with reference to the accompanying drawings for the reactor hoist driving apparatus according to the present invention will be described in detail.

Referring to Figures 1 and 2, Figure 1 illustrates a stud tensioning operation by connecting a stud tensioner to the hoist to an annular track (hereinafter referred to as "monorail") hypothesized by a support on top of the reactor pressure vessel. FIG. 2 is a working example in which a driver tool is connected to a hoist to perform separation and fastening of studs.

In the drawings, reference numeral 2 is a reactor pressure vessel flange, 2a is a fastening hole provided along the circumference of the flange, 10 is a stud inserted into the fastening hole, and 3 is a pressure vessel head. 11 is a thread to which the tension nut is fastened during the stud tensioning operation, 12 is a nut to seal the head of the pressure vessel, and 13 is a thread provided to the stud for fastening the stud to the flange.

3 and 5, FIGS. 3 and 4 are side and front views illustrating a state in which the hoist 300 according to the present invention is mounted on the monorail 200, and FIG. 5 is a reactor hoist according to the present invention. As an example of a plan view of the driving device, the hoist driving device 300a (see FIGS. 1 to 3) is coupled to the monorail 200, and the circumferential feeder 310 moves along the track of the monorail 200. A radial conveying part 320 having a guide rail 330a fixed in the radial direction of the monorail 200, a conveying body 330 assembled to the radial conveying part 320 and conveyed in a radial direction, and The hoist assembly 400 coupled to the conveying body 330 and a conveying means 340 for conveying the conveying body 330.

6A and 6B, FIG. 6A is a sectional view showing main parts of the circumferential conveyance as viewed along the line AA of FIG. 5, and FIG. 6B is a sectional view showing the principal part of the radial conveyance of the hoist driving apparatus for the reactor according to the present invention. FIG. 7 is a cross-sectional view illustrating main parts taken from a state in which a hoist assembly is coupled to a transfer body 330 of the present invention.

The circumferential feed part 310 is driven rollers 312a, 312b and driven rollers 313a, 313b, drive rollers 312a, 312b and driven rollers 313a, 313b as shown in FIG. 6A. The first driving motor 315 for providing rotational force to the idling gears 314a and 314b and the driving rollers 312a and 312b, which are connected to each other, and grounded to the surface of the track 201 of the monorail 200. The first frame 317 to which the idling roller 316 is attached, and the second frame 319 disposed to be spaced apart from the first frame 317 as shown in FIG. 6B are disposed on the main frame 318. The second frame 319 is provided with upper and lower idling rollers 318a and 318b which are in contact with the upper and lower surfaces of the monorail 200, respectively.

The driving rollers 312a, 312b and driven rollers 313a, 313b are both provided with rollers for rolling action and gears for transmitting power, and two driving rollers 312a, 312b and driven rollers 313a. ) 313b is connected by idling gears 314a and 314b.

The driving rollers 312a and 312b are connected to the sun gear 315a attached to the first driving motor 315 so that the sun gear 315a, the driving rollers 312a and 312b and the idling roller 316 and driven rollers 313a and 313b are rotated.

The driving rollers 312a, 312b and driven rollers 313a, 313b are located on the upper surface of the track 201 of the monorail 200, and are driven by any one of the first driving motors 315. Can move along the circumferential direction.

The first and second frames 317 and 319 are fixed to the main frame 318. The first frame 317 is spaced apart by a predetermined distance and moves in the circumferential direction along the track 201 of the monorail 200 by the rolling action of both driving rollers 312a and 312b and driven rollers 313a and 313b. do.

In addition, the first and second frames 317 and 319 are smoothly transported from the track 201 when the frame is transported in the circumferential direction in the track 201, and a guide roller 316a for preventing play during transportation. ) Is further attached to abut the side of the track 201.

The radial conveying part 320 is moved to the pair of guide rails 330a and the pair of guide rails 330a which are spaced apart by a predetermined distance in the radial direction of the annular monorail 200 below the main frame 318. It is composed of a conveying body 330 is possibly coupled.

The guide rail 330a has a predetermined length, and a pair of rollers 331 are assembled on the upper and lower surfaces of the guide rail 330a so that the conveying member 330 is a guide rail 330a. You can move along.

The conveying body 330 is conveyed by a moving means for conveying the conveying body 330 in the radial direction.

The transfer means 330 is supported by the main frame 318 rotatably at both ends between the second drive motor 332 and the guide frame 319a fixed on the main frame 318 The screw 333 is assembled with the transfer member 330, and a power transmission means for transmitting the power of the second driving motor 332 to the screw 333.

The power transmission means is achieved by providing a planetary gear in the screw 333 that meshes with the sun gear 332a coupled to the second drive motor 332.

Therefore, the hoist 300 assembly is assembled to the transfer body 330 to be transferred in the radial direction of the monorail 200 when the second driving motor 332 is rotated.

On the other hand, the first and second drive motors 315 and 332 described above are controlled by a cable from a remote location, preferably a servo motor driven by a pulse value of the voltage.

The operation of the hoist driving apparatus for the reactor according to the present invention configured as described above will be described.

When the power is supplied to the first drive motor 315 at a remote location, the driving rollers 312a and 312b engaged with the sun gear 315a of the first drive motor 315, the idling rollers 314a and 314b, and As the driven rollers 313a and 313b rotate, the main frame 318 is transported along the track 201 of the monorail 200 (the main frame moves in the circumferential direction of the monorail).

One of the first driving motors 315 attached to the first frame 317 may be configured to drive the main frame 318 in the clockwise direction and the other driving motor in the counterclockwise direction. .

When the second driving motor 332 is driven, the transfer member 330 assembled to the screw 333 moves in the radial direction while the screw 333 rotates by the power transmitted from the sun gear 332a.

Therefore, the hoist 300 assembly assembled to the conveying body 330 can move in the radial direction.

As described above, the reactor hoist driving apparatus according to the present invention can transfer the hoist 300 along the annular track 201 corresponding to the flange 2 of the pressure vessel of the reactor, and the hoist 300 radius Direction so that the stud tensioner 100a or driver tool 100b suspended from the hoist 300 can be accurately positioned above the stud 10 as shown in FIGS. 1 and 2.

1 is a layout view illustrating the working state of the stud tension and nut disassembly and tightening tensioner for sealing the head of the reactor pressure vessel;

FIG. 2 is a layout view illustrating a working state of a driver tool for handling the fastening and disassembly of a stud for closing the head of the reactor pressure vessel. FIG.

3 and 4 is a side view and a front view illustrating a state in which the hoist mounted on the monorail according to the present invention,

5 is a plan view of a hoist driving apparatus for a reactor according to the present invention;

Figure 6a is a cross-sectional view of the main portion illustrating the circumferential transfer portion of the present invention as seen from A-A of FIG.

Figure 6b is a cross-sectional view seen from the front of the hoist drive device for reactors according to the present invention,

7 is a cross-sectional view of main parts taken from the front of the conveying body is coupled to the hoist assembly according to the present invention.

<Explanation of symbols for the main parts of the drawings>

1: reactor 2: flange

2a: tightening hole 3: pressure vessel head

10: stud 11: tension screw

12: stud nut 13: stud tightening screw

100a: tensioner 100b: driver tool

200: monorail 201: track

310: circumferential feed section 312a, 312b: drive roller

313a, 313b: driven roller

314a, 314b, 316, 318a, 318b, 332b: idling gear

315: first drive motor 316a: guide roller

317: first frame 318: main frame

319: second frame 319a: guide frame

320: radial transfer unit 330: conveying body

330a: guide rail 331: roller

332: second drive motor 332a: sun gear

333: Screw

Claims (4)

A monorail 200 installed above the reactor pressure vessel; Idling gear connecting driving rollers 312a, 312b and driven rollers 313a, 313b, driving rollers 312a, 312b and driven rollers 313a, 313b to move along the monorail 200. Idling driven in contact with the surfaces of the tracks 201 of the monorail 200 and respective first drive motors 315 for providing rotational force to the 314a and 314b and the driving rollers 312a and 312b. A circumferential feeder 310 to which a roller 316 is attached to the first frame 317; Coupled to the circumferential transfer portion 310, in the radial direction of the monorail 200 A conveying body 330 having an attached guide rail 330a, a roller 331 assembled to the guide rail 330a, and having a rolling function, and to which a hoist 300 assembly is coupled; The second driving motor 332 coupled to the main frame 318 and the both ends are rotatably supported by the main frame 318 to convey the conveying body 330, the conveying body 330 The assembled screw 333 and the hoist drive device for a nuclear reactor, characterized in that consisting of the transfer unit 330 moving means connected to transmit the power of the second drive motor 332 to the screw 333. delete delete delete

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