JPH06347587A - Incore seal test plug - Google Patents

Abstract

PURPOSE:To enable simply withdrawing an incore test plug from an incore monitor flange and confirm leakage from a metal 'O' ring seal part safely, surely and simply without adversely affecting to the core. CONSTITUTION:The plug has a sleeve 21 attached attachably and detachably to a flange 19 of an incore monitor measuring neutron flux in a reactor, a shaft 22 inserted free of up and down movement in this sleeve 21, and a flexible packing 24 connecting tightly between this shaft 22 and the sleeve 21. The upper part of this packing 24 and the shaft 22 are connected.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a metal "O" ring between the incore monitor housing and the incore monitor housing for replacing the incore monitor flange for supporting the lower end of a neutron measuring tube (incore monitor) in a boiling water reactor. The present invention relates to an in-core seal test plug that checks for leaks from the seal.

[0002]

2. Description of the Related Art Generally, in a boiling water reactor, in order to keep the neutron flux in the reactor in an appropriate distribution state during operation,
A rod-shaped in-core neutron measuring tube, that is, an in-core monitor is inserted between the fuel assemblies to monitor the distribution state of neutron flux.

In this in-core monitor, the head is fitted into the intersection of the upper lattice plate in the furnace by utilizing the extension force of the spring installed at the upper end of the in-core monitor, and the lower end of the in-core monitor has a seat for abutting support. It is installed by being joined to the formed flange through an "O" ring. The seat of this flange is mirror-finished so that it will be in close contact with the lower end of the in-core monitor to prevent reactor water from leaking. It is necessary to replace the ring etc.

During such replacement of the in-core monitor flange, the inside of the reactor pressure vessel and the in-core monitor guide tube are temporarily shut off to prevent the reactor water from being discharged. In this case, after replacing the in-core monitor flange and the "O" ring, it is necessary to confirm the presence or absence of leakage from the metal "O" ring seal part. This work is to install the seal member inside the in-core monitor guide tube. It is troublesome because it is removed or removed, or a water pressure supply port is installed, and since it takes a long time, the worker may be exposed to radiation.

In order to solve such a problem, there is one disclosed in Japanese Patent Publication No. 4-22477 by the present applicant. Since the above-mentioned work is a place where the radiation concentration is relatively high even in the nuclear power plant, it is required to supply the test jigs and tools capable of performing the work more quickly.

[0006]

However, the in-core seal test plug disclosed in Japanese Examined Patent Publication No. 4-224477 releases high water pressure from the water pressure supply port and loosens the nut after confirming the presence or absence of leak, but high water pressure ( For example, 10
When pressurized at 0 kg / cm ² or more), the packing deformed into a bellows shape may not be restored to the original cylindrical shape.

In this case, since the in-core seal test plug cannot be pulled out from the in-core monitor flange, the sleeve is removed and the shaft is pushed up to wait until the packing is restored to the original cylindrical shape, or the shaft is returned. While pushing up and down
It was necessary to restore the packing to its original tubular shape by giving an impact.

The present invention has been made in view of the above circumstances, and an object thereof is to provide an in-core seal test plug which can be easily pulled out from the in-core monitor flange.

Another object of the present invention is to:
When replacing the in-core monitor flange, it is possible to safely, reliably, and easily check for leaks from the metal "O" ring seal between the in-core monitor housing and the in-core monitor flange without adversely affecting the core. It is to provide an in-core seal test plug that can.

[0010]

In order to solve the above-mentioned problems, the in-core seal test plug according to the present invention has the following features.
A sleeve that is detachably attached to the flange of the in-core monitor that measures the neutron flux in the reactor, a shaft that is vertically movably inserted in the sleeve, and a fluid-tight connection between the shaft and the sleeve. An in-core seal test plug having a flexible packing, a water pressure supply port for applying water pressure to a metal "O" ring seal portion provided on the sleeve, and a pressure port, and the upper part of the packing and the shaft are coupled to each other. It was done.

Further, the upper part of the packing and the shaft may be connected by an upper screw. Further, the lower part of the packing and the sleeve may be connected by a lower screw.

[0012]

In the present invention having the above-mentioned structure, since the upper part of the packing and the shaft are connected to each other and the shaft is pushed up, the packing deformed into a bellows shape can be stretched, and the original packing can be easily and quickly performed. It can be returned to a tubular shape, and the in-core seal test plug can be easily pulled out from the in-core monitor flange.

Further, it is preferable that the upper part of the packing and the shaft are connected by an upper screw. Further, it is preferable that the lower part of the packing and the sleeve are connected by a lower screw.

[0014]

Embodiments of the present invention will be described below with reference to the drawings. FIG. 3 is a longitudinal sectional view showing a main part of a nuclear reactor to which the in-core seal test plug according to the present invention is applied. Figure 3
As shown in FIG. 2, a core support plate 13 is horizontally provided on a shroud 12 which is integrated with the core 10 and the pressure vessel 11 containing the cooling water, and the pressure vessel located below the core support plate 13 is provided. An in-core monitor housing 14 is fixed to the bottom 11 a of the through-hole 11 by penetrating. At the upper part of the incore monitor housing 14, the incore guide tube 1 is provided.
5 are provided so as to penetrate the core support plate 13.

An incore monitor 16 is removably fitted into the upper end opening 15a of the incore guide tube 15.
The upper portion of the in-core monitor 16 is inserted below the intersection of the upper lattice plate 17. At the lower end of the in-core monitor housing 14, an in-core monitor flange 19 having a seat for contacting and supporting is provided with a metal “O” ring seal portion 20.
Are connected through. The in-core monitor 16 is inserted between the fuel assemblies 18 and monitors the distribution state of neutron flux.

As described above, the in-core monitor flange 1
Reference numeral 9 is for preventing leakage of reactor water, and in order to purify oxides and the like adhering to the surface thereof, the in-core monitor flange 19 and the metal "O" ring seal portion 20 are regularly replaced.

The in-core seal test plug of this embodiment is used to check for a leak in the metal "O" ring seal portion 20 after performing this replacement work.
The in-core monitor flange 19 is mounted from the lower end as shown in FIG.

In the in-core seal test plug, a shaft 22 is incorporated in the center of a sleeve 21, and a nut 23 for pulling down the shaft 22 is screwed onto the lower end of the shaft 22.

The upper stage of the sleeve 21 and the upper end of the shaft 22 protruding from the sleeve 21 are liquid-tightly connected by a packing 24 made of a flexible material. This packing 24
The packing 24 is placed at several points in the axial direction of the
A ring 25 that suppresses expansion in the radial direction is disposed.

A water pressure supply port 26 is opened in the sleeve 21 below the in-core monitor flange 19, and a pressure port 27 is opened in the vicinity of the metal "O" ring seal portion 20. The “O” ring 28 is provided so that water pressurized downward from the shaft 22 does not leak.

The upper part of the packing 24 and the shaft 22 are connected by an upper screw 30, and an "O" ring 29 is provided so that upwardly pressurized water does not leak from the contact surface between the inner peripheral surface of the packing 24 and the shaft 22. It is provided. The lower part of the packing 24 and the upper end of the sleeve 21 are connected by a lower screw 31. Therefore, the shaft 22, the packing 24, and the sleeve 21 are connected by the upper and lower screws 30 and 31 of the packing 24.

Next, the operation of this embodiment will be described.
In the in-core seal test plug having the above-described structure, when the nut 23 is rotated, the shaft 22 is lowered, and the packing 24 is assisted by the ring 25.
As shown in (3), it is deformed into a bellows shape and is pressed against the inner surface of the in-core monitor housing 14.

In this state, when water pressure is applied to the water pressure supply port 26 provided on the side surface of the sleeve 21 of the in-core seal test plug, this water pressure is supplied to the inside of the in-core monitor housing 14 through the pressure port 27 and the metal "O". Since the ring seal portion 20 is pressurized, the presence or absence of leak can be confirmed from there.

After confirming the presence or absence of this leak, the water pressure supply port 2
Even if the water pressure is released from 6 and the nut 23 is loosened, when the pressure is increased by a high water pressure (for example, 100 kg / cm ² or more), the packing 24 deformed into a bellows shape may not be restored to the original cylindrical shape. When pushing up the shaft 22,
Since the upper screw 30 of the packing 24 is pulled up to the shaft 22 and one lower screw 31 of the packing 24 is coupled to the sleeve 21 fixed to the in-core monitor flange 19, the packing 24 deformed in a bellows shape is stretched vertically. Be done.

Therefore, the packing 24 is easily returned to the original tubular shape in a short time and becomes thinner than the inner diameter of the in-core monitor flange 19, so that the in-core monitor flange 19 can be easily performed.
Can be pulled out from.

Even if the lower screw 31 is not provided, when the shaft 22 is pushed up, the upper screw 30 of the packing 24 is
Is pulled up to the shaft 22, but the packing 24
Since the lower part of the inner core is deformed into a bellows shape, the same effect as the lower screw 31 can be obtained by the frictional resistance with the in-core monitor housing 14, and it easily returns to the original cylindrical shape in a short time, and the inner diameter of the in-core monitor flange 19 Since the packing 24 becomes thinner, it can be easily pulled out from the in-core monitor flange 19.

The present invention is not limited to the above embodiment, but various modifications can be made. For example, the upper screw 30 of the above embodiment can exhibit the same effect even if it is connected by a pin connecting means or a connecting means such as a dovetail groove.

[0028]

As described above, according to the in-core seal test plug of the present invention, after the in-core monitor flange and the metal "O" ring seal part are exchanged, they are inserted into the in-core monitor flange and the packing is expanded. After letting
By applying water pressure from the water pressure supply port, a leak from the metal “O” ring seal portion between the in-core monitor housing and the in-core monitor flange can be surely and easily confirmed.

Further, by connecting the upper part of the packing and the shaft, the packing deformed into a bellows shape can be stretched by pushing up the shaft, and the packing can be easily returned to the original cylindrical shape in a short time. The in-core seal test plug can be easily pulled out from the monitor flange.

Therefore, since the replacement work of the in-core monitor housing can be carried out quickly in a short time, the radiation exposure amount of the worker can be reduced, and the replacement work is simple, and other excellent effects can be obtained.

[Brief description of drawings]

1A and 1B are a longitudinal sectional view and an end view showing a state in which an embodiment of an in-core seal test plug according to the present invention is attached to an in-core monitor housing.

FIG. 2 is a vertical cross-sectional view showing a state in which the packing of the in-core seal test plug of this embodiment is deformed and sealed.

FIG. 3 is a vertical cross-sectional view showing a main part of a nuclear reactor to which an in-core seal test plug according to the present invention is applied.

[Explanation of symbols]

 10 core part 11 pressure vessel 12 shroud 13 core support plate 14 incore monitor housing 15 incore guide tube 16 incore monitor 17 upper lattice plate 18 fuel assembly 19 incore monitor flange 20 metal “O” ring seal part 21 sleeve 22 shaft 23 nut 24 Packing 25 Ring 26 Water pressure supply port 27 Pressurization port 28 “O” ring 29 “O” ring

Continuation of front page (51) Int.Cl. ⁵ Identification code Office reference number FI technical display location 8908-2G G21C 17/02 GDB E

Claims (3)

[Claims] 1. A sleeve detachably attached to a flange of an in-core monitor for measuring a neutron flux in a nuclear reactor, a shaft vertically movably inserted in the sleeve, and a space between the shaft and the sleeve. An in-core seal test plug having a flexible packing that is liquid-tightly connected, and a hydraulic pressure supply port and a pressurizing port that are provided on the sleeve to apply a hydraulic pressure to the metal “O” ring seal part, and An in-core seal test plug characterized by being combined with the above shaft. 2. The in-core seal test plug according to claim 1, wherein the upper portion of the packing and the shaft are connected by an upper screw. 3. The in-core seal test plug according to claim 1, wherein the lower portion of the packing and the sleeve are connected by a lower screw.