JP5448654B2 - Fixing mechanism of drain drainage strainer - Google Patents

Description

  The present invention relates to a drain drainage strainer fixing mechanism.

  As shown in FIG. 6, in a nuclear power plant nuclear reactor, a reactor vessel PV is provided in the reactor containment vessel W, and a reactor cavity CV is provided above the reactor vessel PV. ing. The nuclear reactor cavity CV is filled with boric acid water when the nuclear fuel is changed during the periodic inspection. The purpose of adding boric acid water is to open the reactor vessel PV lid when loading and unloading the nuclear fuel into the reactor vessel PV. This is to reduce exposure.

In a specific nuclear fuel exchange operation, first, boric acid water is supplied into the reactor cavity CV. At this time, boric acid water is supplied from both the drain d and the reactor vessel PV into the reactor cavity CV. The boric acid water is supplied from the reactor vessel PV to the reactor cavity CV by opening the lid of the reactor vessel PV, and then gradually raising the water level in the reactor vessel PV. Take the method of supplying water.
When boric acid water is filled in the reactor cavity CV, the nuclear fuel is transferred through the fuel replacement canal T penetrating the reactor containment vessel W. That is, the nuclear fuel is transferred between the reactor vessel PV and the spent fuel pit in the boric acid water.
When the transfer of the nuclear fuel is completed, the boric acid water in the reactor cavity CV is drained through the drain D, and after the lid is attached to the reactor vessel PV, the reactor is operated.

  Such a reactor cavity CV is contaminated by activated impurities contained in boric acid water stretched in the reactor cavity CV at the time of nuclear fuel exchange. Cleaning of the cavity (hereinafter referred to as cavity decontamination) is performed twice per periodic inspection.

The cavity decontamination work is performed according to the following procedure.
Prior to the cavity decontamination work, a process of carrying in or out nuclear fuel is performed, so boric acid water is stretched in the reactor cavity CV. For this reason, before starting the cavity decontamination operation, an operation of removing boric acid water from the reactor cavity CV is performed.
When the boric acid water in the reactor cavity CV is completely drained, the worker enters the reactor cavity CV, and the strainer is attached to the opening (drain port) of the drain d by the worker.
Then, the reactor cavity CV is cleaned (decontaminated) using a decontamination brush and pure water by an operator.
When the cavity decontamination work is completed, boric acid water is filled in the reactor cavity CV before the nuclear fuel is carried in, but before the boric acid water is filled, the strainer attached to the drain outlet of the drain d is , Removed by workers.

Here, before the decontamination work, the strainer is attached to the drainage port because the waste generated in the decontamination work passes from the drainage port through the drain d into the reactor cavity CV. This is to prevent entry into the system that supplies and discharges water.
The reason why the strainer is removed every time after the cavity decontamination work is completed is that the strainer cannot be fixed to the drain and cannot be left in the drain.
If the strainer that cannot be fixed is left at the drain port, the boring water may rise up and come off due to water pressure when boric acid water is supplied from the drain port into the reactor cavity CV before the nuclear fuel is carried in. is there. Since the strainer removed from the drain port moves in the reactor cavity CV by the water flow, it may collide with the fuel transfer device and damage the fuel transfer device. In order to prevent such a problem from occurring, it is necessary to remove the strainer before boric acid water is filled in the reactor cavity CV.

However, there are currently the following requirements for the cavity decontamination work performed in the above procedure.
1) Since the worker performs the cavity decontamination work while entering the reactor cavity CV, the worker is exposed during the work. For this reason, it is desirable to shorten the work time in the reactor cavity CV and reduce the exposure dose of the worker as much as possible. At present, in addition to the decontamination work, workers are also carrying out the extra work of installing and removing the strainer, so we want to reduce the number of work steps and shorten the work time.
2) In the periodic inspection process, since the next stage nuclear fuel cannot be carried in unless the cavity decontamination work is completed, the cavity decontamination work is an element for determining the entire period of the periodic inspection process. If the cavity decontamination work can be completed quickly, the work time of the entire periodic inspection process will be shortened. Therefore, the cavity decontamination work should be completed early.

The above two requirements can be met if the strainer can be fixed to the drain.
This is because if the strainer can be fixed to the drain, the work of attaching the strainer before the cavity decontamination and the work of removing the strainer before applying boric acid water are not required, so the number of man-hours for workers is reduced. This is because the working time can be shortened.

Further, if the strainer can be fixed to the drain outlet, the drainage work and the decontamination work can be performed at the same time, so that the cavity decontamination work time can be further shortened.
The reason is as follows.
As described above, the boric acid water in the reactor cavity CV must be completely drained in order for the worker to perform the work of attaching the strainer. For this reason, at present, the system waits in a state where the work in the reactor cavity cannot be performed until the boric acid water in the reactor cavity CV is completely drained. However, if the strainer can be fixed to the drain, the strainer is already attached to the drain when draining before the cavity decontamination work. Then, since the decontamination work can be performed before drainage in the reactor cavity CV is completed, the waiting time is reduced, and the decontamination work can be started earlier by that much.

The following methods can be considered as a method of fixing the strainer to the drain outlet.
1) Fixing to surrounding structures Since there is a fuel transfer device as a structure around the drain d in the reactor cavity CV, the strainer can be fixed to the fuel transfer device by a method such as bundling or bolt-on. Conceivable. However, the fuel transfer device is a very important device, and it is not preferable because fixing the strainer may affect the operation of the fuel transfer device.
2) Welding It may be possible to fix the strainer to existing equipment such as the floor, eye plate cradle, and fuel transfer device by welding. However, it is difficult to evaluate the impact on the soundness and strength of existing equipment because welding to existing equipment is very risky. In addition, since the strainer cannot be removed, it becomes impossible to clean the strainer after the cavity decontamination.
3) Method by processing existing equipment It is also possible to fix the strainer by processing the drain port and forming a screw hole or fixing groove. However, this method also involves processing a screw hole and a fixing groove in an existing facility, and therefore, it is difficult to evaluate the influence of this processing on the soundness and strength of the facility, and the risk is high.

On the other hand, although the technical field is different from the strainer attached to the drain outlet of the drain d in the reactor cavity CV, Patent Document 1 discloses a technique capable of attaching a manhole cover without processing an existing manhole. ing.
The technology of Patent Document 1 is a technology in which a swinging lever is provided on the back surface of the manhole cover (the surface disposed in the manhole), and the manhole is fixed by this lever. Specifically, the tip of the lever is provided with a saw blade-like tip engaging portion, and by swinging the lever, the tip engaging portion is bitten into the inner surface of the manhole, and the manhole cover is closed. Fixed to an existing manhole.

However, although the technique of Patent Document 1 can be used to fix the manhole, it cannot be used as a strainer fixing mechanism attached to the drain outlet of the drain d in the reactor cavity CV. This is because, in the case of the technique of Patent Document 1, scratches are formed on the inner surface of the manhole by the saw blade-shaped tip engaging portion at the tip of the lever. However, in the reactor cavity CV, the existing equipment is scratched as described above. This is because the act of forming should be avoided.
Moreover, the technique of Patent Document 1 cannot be fixed unless the work is performed from within the manhole, and cannot be employed for fixing the strainer, which cannot be performed from the drain d.

As described above, no technology has been developed that can fix the strainer to the drain outlet of the drain d under the special condition of the drain outlet of the reactor cavity CV. It is currently difficult to fix the strainer to the drain of d. Therefore, in the present situation, the strainer is removed every time before filling the reactor cavity CV with water, and the strainer is attached every time during the cavity decontamination work.
Therefore, in order to reduce the exposure of workers and shorten the cavity decontamination work time, it does not affect the operation of existing facilities and reactors, and is fixed to the drain outlet of the drain d so as not to rise. There is a need for a strainer with a mechanism that can be used.

JP 2000-178996 A

  In view of the above circumstances, an object of the present invention is to provide a drain drainage strainer fixing mechanism that can fix a strainer to a drainage without processing existing equipment.

The drain drainage strainer fixing mechanism of the first invention is a fixing mechanism for fixing a strainer attached to a water supply / drainage port for supplying and discharging boric acid water to / from a reactor cavity of a nuclear reactor, The fixing mechanism includes a plurality of swing arms swingably provided on the strainer body of the strainer, and a swing operation mechanism that swings the swinger by operating the swing arm from the side of the water supply / drainage port of the strainer body. Each of the swing arms is disposed in the water supply / drain port, and one end of the swing arm is disposed in the water supply / drain port. When the arm is swung, one end of the arm is disposed so as to approach and separate from the inner surface of the water supply / drainage port from the radial direction of the water supply / drainage port. Characterized in that it comprises a mechanism for pressing against the inner surface of the water supply and drainage port.
The drain drainage strainer fixing mechanism according to a second aspect of the present invention is the first invention, wherein the surface of the swing arm that is opposite to the central axis of the strainer body is formed in an arcuate surface. The pressing member is characterized in that the radius of curvature of the arcuate surface is the same as the radius of curvature of the inner surface of the water supply / drain port.
The drain drainage strainer fixing mechanism according to a third aspect of the present invention is the first or second aspect of the invention, wherein the swing arm has a portion between one end and the other end pivotally supported by the strainer body, The fixing means is movable along the radial direction with respect to the strainer main body, and when the fixing means moves toward the center of the strainer main body, the tip of the strainer main body makes the other end of the oscillating arm. An urging pin provided at a position where the urging pin can be urged toward the center thereof, an elastic member disposed at a position where the urging pin can be urged toward the central axis of the strainer body, and the elastic member And a fixing force adjusting section for adjusting a fixing force applied to the urging pin.
The drain drainage strainer fixing mechanism according to a fourth aspect of the present invention is the first, second or third aspect of the invention, wherein the strainer body is a cylindrical member having one end opened and the other end closed. .

According to the first invention, the strainer body is fixed to the drain port by fixing the swing of the swing arm by the fixing means in a state where one end of the plurality of swing arms is pressed against the inner surface of the drain port by the swing operation mechanism. can do. Therefore, when supplying water into the reactor cavity from the drain port, the strainer can be prevented from floating due to water pressure. Then, since the strainer can be kept fixed to the drain outlet, it is possible to reduce the number of work steps performed by the worker in the reactor cavity. That is, when the decontamination work is performed, the strainer mounting / removal work becomes unnecessary, so that the decontamination work time can be shortened and the exposure dose of the operator can be reduced. In addition, since the decontamination work can be started quickly, the entire regular inspection process can be shortened.
According to the second aspect of the invention, the surface pressed against the inner surface of the drainage port in the pressing member is an arcuate surface, and the radius of curvature is the same length as the radius of curvature of the inner surface of the water supply / drainage port. The contact area with can be increased. Then, since the frictional force which generate | occur | produces between both can be enlarged, a strainer main body can be firmly fixed to a drain outlet. Moreover, since the arcuate surfaces are only in surface contact with each other, the inner surface of the water supply / drainage port is not damaged.
According to the third invention, since the member that generates the fixing force is an elastic member such as a leaf spring or a coil spring, vibration caused by the flow of boric acid supplied from the drain into the reactor cavity, or boric acid Even if thermal expansion or contraction caused by changes in water temperature or air temperature occurs, it is possible to suppress fluctuations in the fixing force for fixing the strainer body to the drain outlet. And if the force which presses the end of a rocking | fluctuation arm to a drain outlet inner surface is adjusted with a fixing force adjustment part, a strainer can be fixed with the fixing force which can prevent a strainer's lift.
According to the fourth invention, the members constituting the swing arm and the fixing means can be disposed in the strainer. Then, since the members existing outside the strainer can be reduced, the handleability of the strainer can be improved and the filtration area can be increased.

It is a schematic explanatory drawing of the strainer 1 which employ | adopted the fixing mechanism of this embodiment, Comprising: With respect to the line CL, the schematic side view is shown on the right side, and the schematic sectional drawing is shown on the left side. It is the II-II sectional view taken on the line of FIG. 2A is a schematic cross-sectional view of the strainer 1 cut along a cross-section taken along line III-O-III in FIG. 2, and FIG. 3B is a schematic enlarged cross-sectional view of the fixing means 30. 4A is a cross-sectional view taken along line IV-O ₁ -O ₂ -IV in FIG. 3, and FIG. 4B is a schematic enlarged plan view of fixing means 30. It is a schematic explanatory drawing of the nuclear reactor in the state where the strainer 1 was attached. It is a schematic explanatory drawing of the nuclear reactor in the state where the strainer 1 is not attached.

Next, an embodiment of the present invention will be described with reference to the drawings.
The drain drainage strainer fixing mechanism of the present invention is a mechanism provided in a strainer attached to the drainage drainage port of the reactor cavity, and the strainer can be attached to the drainage port without affecting the reactor cavity or the like. It has the feature in the point made like this.

  As shown in FIG. 5, in a nuclear power plant nuclear reactor, a reactor vessel PV and a reactor cavity CV are provided in a reactor containment vessel W. A drain d for supplying and discharging boric acid water into and from the reactor cavity CV is communicated with the reactor cavity CV when the nuclear fuel is carried into and out of the reactor vessel PV.

  In FIG. 5, reference numeral 1 denotes a drain drainage strainer (hereinafter simply referred to as a strainer 1) attached to the opening of the drain d (hereinafter referred to as a water supply / drainage da). The strainer 1 includes a strainer body 10 and a fixing mechanism for fixing the strainer body 10 to the water supply / drain port da (FIG. 1).

First, in FIG. 1, the strainer body 10 includes a mesh portion 11 and a base portion 12 disposed at the water supply / drain port da.
The base portion 12 is a ring-shaped member and has a flange on the outer peripheral edge thereof. This flange is formed so that its outer diameter is larger than the inner diameter of the water supply / drain port da.
The mesh part 11 is a member formed in a cylindrical shape with one end opened and the other end closed, and is provided so as to cover the opening of the base part 12. Specifically, one end (lower end in FIG. 1) of the mesh portion 11 is fixed to one surface (upper surface in FIG. 1) so as to cover the opening of the base portion 12. .

  For this reason, if the strainer body 10 is arranged at the water supply / drain port da, the outer diameter of the flange of the base portion 12 is larger than the inner diameter of the water supply / drain port da, and the mesh portion 11 is provided so as to cover the opening of the base portion 12. Therefore, the water supply / drain port da can be covered with the mesh portion 11 of the strainer body 10. Then, the boric acid water supplied to and discharged from the reactor cavity CV through the drain d can be configured to pass through the mesh portion 11 of the strainer body 10 without fail.

1 to 3, the fixing mechanism swings the plurality of swing arms 21 attached to the strainer body 10 and the plurality of swing arms 21 or fixes the swing. And fixing means 30.
One end (the lower end in FIGS. 1 to 3) of the plurality of swing arms 21 is disposed so as to swing along the radial direction of the strainer body 10. One end of each of the plurality of swing arms 21 is located below the opening of the strainer body 10 and below the base 12.

  Since the structure is as described above, if the strainer body 10 is disposed at the water supply / drain port da and one end of the plurality of swing arms 21 is urged away from the central axis of the strainer body 10 by the fixing means 30, the plurality of swingers 10 are moved. One end of the moving arm 21 is pressed against the inner surface of the water supply / drain port da. Then, a frictional force can be generated between one end of the arm 21 and the inner surface of the water supply / drain port da. If the swing of the plurality of swing arms 21 is fixed by the fixing means 30 in this state, the strainer 1 can be fixed to the water supply / drain port da by the frictional force generated between them.

That is, if the strainer 1 provided with the fixing mechanism of the present embodiment is used, the strainer 1 is fixed to the water supply / drain port da without performing special processing or the like on existing facilities such as the water supply / drain port da and the reactor cavity CV. I can leave. Then, when the boric acid water is supplied into the reactor cavity CV from the water supply / drain port da, the strainer 1 can be prevented from being lifted by water pressure.
In addition, the processing of the reactor cavity CV is unnecessary, and the strainer 1 is not fixed to the equipment in the reactor cavity CV, so that there is no influence on the soundness and strength of the equipment.

  If the strainer 1 can be fixed to the water supply / drain port da, the number of work steps performed by the worker in the reactor cavity CV can be reduced. That is, when the decontamination work is performed, the strainer 1 is not required to be attached and detached, so that the decontamination work time can be shortened and the exposure dose of the operator can be reduced. In addition, since the decontamination work can be started quickly, the entire regular inspection process can be shortened.

(Description of fixing mechanism)
Next, the fixing mechanism that is a feature of the present invention will be described in detail.
First, the fixing mechanism includes a plurality of swing arms 21 and fixing means 30 as described above.

(Swinging arm 21)
As shown in FIG. 2, the plurality of oscillating arms 21 are arranged around the central axis of the strainer body 10 so as to be mutually rotated and arranged at equal angular intervals. For example, in FIG. 2, four swing arms 21 are provided at 90 ° intervals.

  As shown in FIGS. 1 to 3, each swing arm 21 swings between the one end (the lower end in FIG. 1) and the other end (the upper end in FIG. 1) on the base portion 12 of the strainer body 10. It is mounted movably. Specifically, the swing arm 21 is pivotally supported by a bracket provided on the base portion 12. Moreover, the swing arm 21 is formed to have such a length that one end protrudes from one end of the strainer body 10. For this reason, when the swing arm 21 is swung while the strainer body 10 is disposed at the water supply / drain port da, one end of the swing arm 21 approaches and separates from the inner surface of the water supply / drain port da.

(Fixing means 30)
On the other hand, in the strainer body 10, a fixing means 30 is provided at a position corresponding to the other end (the upper end in FIG. 1) of each swing arm 21.
3 and 4, reference numeral 35 indicates a fixed base of the fixing means 30 fixed to the strainer body 10. The fixing base 35 includes a ring-shaped member 35a and a fixing force adjusting unit holding member 35b.
The ring-shaped member 35 a is provided inside the strainer body 10 and is fixed to the inner surface of the mesh member 11.
Further, the fixing force adjusting portion holding member 35b is provided so as to sandwich the mesh member 11 of the strainer body 10 between the ring-shaped member 35a and is fixed to the outer surface of the mesh member 11. The fixing force adjusting portion holding member 35b is a hollow member having one end opened, and is arranged so that the one end opened is located on the mesh member 11 side.

  As shown in FIGS. 1, 3, and 4, the ring-shaped member 35 a and the mesh member 11 are formed with a plurality of through holes that penetrate both along the radial direction of the strainer body 10. The plurality of through holes are provided at positions corresponding to the plurality of swinging arms 21 in the circumferential direction of the strainer body 10, and are formed between the inside of the strainer body 10 and the hollow portion of the fixing force adjusting portion holding member 35b. They communicate with each other.

  Each through hole is provided with an urging pin 31 provided so as to be movable along the through hole. The urging pin 31 is disposed such that the tip (end on the central axis side of the strainer body 10) is in contact with the other end of the corresponding swing arm 21, and the base end holds the fixing force adjusting portion. It is disposed in the hollow portion of the member 35b.

On the other hand, a screw hole is formed on the outer surface of the fixing force adjusting portion holding member 35b so as to be substantially coaxial with the through hole. The screw member 33 is screwed into the screw hole, and the tip of the screw member 33 is disposed in the hollow portion of the fixing force adjusting portion holding member 35b.
A nut member 34 is screwed into a portion of the screw member 33 located outside the fixing force adjusting portion holding member 35b, and the nut member 34 can fix the movement of the screw member 33 relative to the screw hole. It is configured.

  And in the hollow part of the fixing force adjustment part holding member 35b, between the front-end | tip of the screw member 33 and the base end of the urging | biasing pin 31, the leaf | plate spring 32 which is an elastic member is arrange | positioned in the compressed state. . That is, the urging pin 31 is always urged toward the center of the strainer body 10 by the leaf spring 32.

Since the configuration is as described above, if the base member 12 of the strainer body 10 is disposed at the water supply / drain port da and the screw member 33 is advanced toward the center of the strainer body 10, the urging pin 31 is moved to the center of the strainer body 10. Can be moved toward. Then, the other end of the swing arm 21 is pushed by the urging pin 31, so that the swing arm 21 swings. That is, the swing arm 21 can be swung from the outer surface of the strainer body 10, in other words, by an operation from the side of the strainer body 10 on the side of the water supply / drainage port.
Since the swing arm 21 pushed by the urging pin 31 swings so that one end thereof moves toward the inner surface of the water supply / drain port da, one end thereof is pressed against the inner surface of the water supply / drain port da.
In this state, if the movement of the screw member 33 is fixed by the nut member 34, one end of the swing arm 21 can be fixed while being pressed against the inner surface of the water supply / drain port da.

  The urging pin 31, the leaf spring 32, and the screw member 33 of the fixing means 30 correspond to a swing operation mechanism referred to in the claims. In the above-described embodiment, the fixing means 30 also serves as a swing operation mechanism. However, it goes without saying that a swing operation mechanism may be provided separately from the fixing means 30.

  Since the force (fixing force) pressing one end of the swing arm 21 against the inner surface of the water supply / drain port da is proportional to the advance amount of the screw member 33, the fixing force can be easily adjusted by moving the screw member 33 back and forth. be able to. Then, the strainer 1 can be fixed to the water supply / drain port da with an appropriate fixing force that can prevent the strainer 1 from being lifted.

Further, since the leaf spring 32 is provided between the screw member 33 and the urging pin 31, fluctuations in the fixing force can be suppressed. For example, even if vibration due to the flow of boric water supplied from the water supply / drain port da to the reactor cavity CV or thermal expansion or contraction due to changes in the water temperature or temperature of the boric acid occurs, the fixing force is a predetermined force. This can be maintained. Therefore, the strainer 1 can be attached to the water supply / drain port da in a more stable state.
The elastic member is not limited to the leaf spring 32, and any member having a function equivalent to that of the leaf spring 32 described above, such as a coil spring, can be used.

Further, if a means for confirming the degree of the fixing force is provided, the current fixing force can be accurately grasped, so that the strainer 1 can be fixed to the water supply / drain port da with a more appropriate fixing force. This is preferable because it is possible.
For example, as shown in FIGS. 3 and 4, an opening 35h is provided on the upper surface of the fixing force adjusting portion holding member 35b, and a plate 31a that moves together with the urging pin 31 is provided below the opening 35h. And the scale L etc. which can be confirmed from the opening 35h are provided in the upper surface of the plate 31a. Then, based on the scale L of the plate 31a that can be confirmed from the opening 35h, the amount that the urging pin 31 is pushed, that is, the fixing force can be grasped.

  The screw member 33 and the nut member 34 are the fixing force adjusting unit referred to in the claims, but the fixing force adjusting unit is not limited to the above-described configuration, and one end of the swing arm 21 is connected to the inner surface of the water supply / drain port da. Any force can be adopted as long as the force can be adjusted, in other words, the force pushing the urging pin 31 and the fixing force generated by the leaf spring 32 can be adjusted.

In the above embodiment, the case where the number of the swinging arms 21 is four has been described. However, the number of the swinging arms 21 may be at least two, and may be three or five or more.
Further, the swing arm 21 may be mounted so that its central axis is disposed in a plane including the central axis of the strainer body 10 and swings while the central axis is disposed on this plane. preferable. In this case, since the force applied to the swing arm 21 is balanced within a plane including the central axis of the strainer body 10, the strainer 1 can be fixed in a stable state.

(Pressing member 22)
If one end of each swing arm 21 is configured to be able to exert a frictional force to the extent that the strainer 1 does not move between the inner surface of the water supply / drain port da when pressed against the inner surface of the water supply / drain port da, There is no particular limitation.
However, if one end of the swing arm 21 is configured as follows, the inner surface of the water supply / drain port da is not damaged, and more effectively between the swing arm 21 and the inner surface of the water supply / discharge port da. A frictional force can be generated, which is preferable.

1 and 2, reference numeral 22 indicates a pressing member provided at one end of the swing arm 21.
The main body portion 22a of the pressing member 22 is attached to one end of the swing arm 21 via the bracket 21a so as to be slightly swingable in the left-right direction and the up-down direction. Specifically, the bracket 21a is connected to the one end of the swing arm 21 by a pin so as to be slightly swingable in the vertical direction, and the main body portion 22a is swinged slightly to the left and right with respect to the bracket 21a by the pin. They are connected so that they can.

As shown in FIG. 2, the outer surface of the main body portion 22a is formed in an arcuate surface. Specifically, in the main body portion 22a, the surface facing the inner surface of the water supply / drain port da when the strainer main body 10 is disposed at the water supply / drain port da is formed in an arcuate surface. The outer surface (arc-shaped surface) of the main body 22a is formed so that the radius of curvature thereof is the same as the radius of curvature of the inner surface of the water supply / drain port da.
An elastic member 22b having elasticity such as rubber is provided on the outer surface of the main body 22a.

Because of the above configuration, if the swing arm 21 is swung and one end thereof is pressed against the inner surface of the water supply / drainage port da, the pressing member 22 can be brought into close contact with the inner surface of the water supply / drainage port da. Specifically, when the elastic member 22b provided on the outer surface of the main body portion 22a is deformed, the main body portion 22a and the inner surface of the water supply / drainage port da can be brought into contact with no gap therebetween. Since the contact area between the pressing member 22 and the inner surface of the water supply / drainage port da is increased and the frictional force generated between them can be increased, the strainer body 10 can be firmly fixed to the water supply / drainage port da.

  The pressing member 22 is provided with the elastic member 22b on the outer surface of the main body 22a. However, the elastic member 22b may not be provided on the outer surface of the main body 22a. Even in this case, the main body portion 22a can be slightly swung in the left-right direction and the up-down direction with respect to the one end 21 of the swing arm 21, and the outer surface of the main body portion 22a is a smooth curved surface with a radius of curvature of water supply / drainage. If it is formed so as to have the same radius of curvature of the inner surface of the mouth da, the adhesion to the inner surface of the water supply / drainage port da can be improved, and the inner surface of the water supply / drainage port da is not damaged by the main body portion 22a. However, if the elastic member 22b is provided, the adhesion between the main body portion 22a and the inner surface of the water supply / drainage port da can be further increased, and the possibility that the inner surface of the water supply / drainage port da is damaged by the main body portion 22a can be further reduced. Therefore, it is preferable.

(Other embodiments of strainer 1)
In the above embodiment, the case where the mesh portion 11 of the strainer body 10 is cylindrical has been described, but the mesh portion 11 may not necessarily be cylindrical, and may be planar or prismatic.
However, if the mesh part 11 is cylindrical, it is possible to increase the filtration area, and it is easy to arrange the swing arm 21 and the members constituting the fixing mechanism in the mesh part 11. Then, since the member which exists outside the strainer 1 can be decreased, the handleability of the strainer 1 can be improved.

  The mesh portion 11 of the strainer body 10 is not particularly limited in the shape of the through hole, the size of the through hole, the distribution density of the through holes, and the like, as long as it is formed so as not to allow the activated impurities to pass through. Good. In particular, in the case of the cylindrical mesh portion 11 as described above, it is preferable to provide a through hole on the entire mesh portion 11 so as to ensure a sufficient passage area even if the water level is lowered. Specifically, it is preferable to provide a through-hole up to the vicinity of the connection portion with the base portion 12 in the mesh portion 11 (that is, to the tip of the opening). Since the through-hole exists up to the floor surface of the reactor cavity CV, the water drainage from the reactor cavity CV can proceed smoothly.

  And in the strainer 1 provided with the fixing mechanism of this embodiment, since there are few detachable parts and there is little possibility that parts will dissipate, there is very little possibility that parts will fall out of the strainer 1. Then, even if the strainer 1 provided with the fixing mechanism of the present embodiment is fixed to the water supply / drain port da of the drain d, the possibility that components dropped from the strainer 1 are mixed into the reactor vessel PV can be extremely reduced. Safety at the time can also be secured.

  The drain drainage strainer fixing mechanism of the present invention is connected to a drainage supply / drainage port for supplying boric acid water to the reactor cavity, a tank / pit / pool supply / drainage port, a floor drain, a roof drainage drainage port, etc. Is suitable.

1 Strainer 10 Strainer Main Body 21 Swing Arm 22 Pressing Member 22
30 Fixing means 31 Energizing pin 32 Leaf spring d Drain da Water supply / drain CV Reactor cavity

Claims (4)

A fixing mechanism for fixing a strainer attached to a water supply / drain port for supplying / exhausting water to / from a reactor cavity of the nuclear reactor,
The fixing mechanism is
A plurality of swing arms provided swingably on the strainer body of the strainer;
A swing operation mechanism that swings the swing arm by operating the swing arm from the side opposite to the drainage / drainage port of the strainer body;
A fixing means for fixing the swing of the plurality of swing arms;
Each swing arm
When the strainer body is disposed in the water supply / drain port, one end thereof is disposed in the water supply / drain port,
When the swing arm is swung, one end thereof is disposed so as to approach and separate from the inner surface of the water supply / drainage port from the radial direction of the water supply / drainage port,
The fixing means includes
A drain drainage strainer fixing mechanism comprising a mechanism for pressing one end of the swing arm against the inner surface of the water supply / drainage port. One end of the swing arm is provided with a pressing member having an arc-shaped surface located on the opposite side to the central axis of the strainer body,
The pressing member is
2. The drain drainage strainer fixing mechanism according to claim 1, wherein the radius of curvature of the arcuate surface is the same as the radius of curvature of the inner surface of the water supply / drainage port. The swing arm is
A portion between one end and the other end is pivotally supported by the strainer body,
The fixing means includes
It is movable along the radial direction with respect to the strainer main body, and when moving toward the center of the strainer main body, the tip of the other end of the swinging arm faces the center of the strainer main body. An urging pin provided at a position where urging is possible;
An elastic member disposed at a position where the biasing pin can be biased toward the central axis of the strainer body;
3. The drain drainage strainer fixing mechanism according to claim 1, further comprising a fixing force adjusting unit that adjusts a fixing force applied to the biasing pin from the elastic member. The strainer body is
4. The drain drainage strainer fixing mechanism according to claim 1, wherein the drainage strainer is a cylindrical member having one end opened and the other end closed.

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