JPS6249957B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to a radiation shielding device used, for example, during periodic inspections of nuclear power plants.

During periodic inspections of nuclear power plants, for example, when performing maintenance and inspection work on the nozzle section of the reactor pressure vessel, the blocker that closes the space between the inner surface of the opening of the shielding wall and the nozzle section is removed. Since radiation from the pressure vessel leaks through this space, exposure of workers to this radiation poses a problem. Therefore, when carrying out the above maintenance and inspection work, first, in order to prevent radiation from leaking through the space, this space is temporarily closed off by stacking lead bricks as a shielding material. The lead bricks will be removed once the above maintenance and inspection work is completed.

However, in the work of shielding the above space with lead bricks and the work of removing them, each lead brick is heavy, and if the space is large, a large number of lead bricks are required. It takes not only a lot of effort but also a lot of time.
Therefore, each of the above-mentioned workers is exposed to a large amount of radiation. In addition, after removing the lead brick, since this lead brick is radioactive,
There is also the problem of generating large amounts of radioactive solid waste that is difficult to dispose of.

This invention was made based on the above circumstances, and its purpose is to facilitate the shielding work and removal work in a space where radiation should be shielded, and to reduce the radiation exposure of workers during these works. An object of the present invention is to provide a radiation shielding device that can reduce radiation dose and reduce the amount of radioactive solid waste generated.

An embodiment of the present invention will be described below based on the drawings.

FIG. 1 shows a radiation shielding device used, for example, during periodic inspections of nuclear power plants, and this device is composed of a shielding material storage body 1 and a shielding material supply and recovery mechanism 2.

The storage body 1 closes a space to be shielded from radiation, for example, a space D between the main steam nozzle part B of the reactor pressure vessel A and the inner surface of the opening of the shielding wall C. It is composed of two types: a storage enclosing bag 3 and a storage closing bag 4. The enclosing bag 3 has a box-like shape, and a covering hole 3a is provided in the center thereof so as to enclose the main steam nozzle part B of the pressure vessel A, for example. It is being Note that 5 and 5 are fasteners for fixing the left and right sides of the enclosing bag 3 after the nozzle B is wrapped therein. The closed bag body 4 is formed into a bag shape with a bellows-shaped side portion, and is expandable and retractable. and,
The enclosing bag body 3 and the closing bag body 4 are each provided with two plugged nozzles 6, 6. These plugged nozzles 6, 6 are for supplying the above-mentioned shielding material 7 into the interior of the enclosing bag 3 and the closing bag 4, and for discharging the shielding material 7 from the inside. These plugged nozzles 6, 6 are for connecting a plurality of enveloping bags 3 and closing bags 4 when they are used in combination. Note 2
1 is a plug of a nozzle 6 with a plug.

Next, the supply and recovery mechanism 2 for supplying the shielding material 7 to the storage body 1 and recovering the shielding material 7 from the storage body 1 will be described below.

The supply and recovery mechanism 2 includes a shielding material tank 8,
A shielding material 7 for shielding radiation is stored in this tank 8.

In addition, a shielding liquid having a specific gravity of about 1 to 5 is used for the shielding material 7, for example, water has a specific gravity of 1, and BaHgBr ₄ has a specific gravity of 3.
An aqueous solution with a specific gravity of 5 is HCO ₂ Tl.
A mixed aqueous solution with C ₃ H ₂ O ₄ Tl ₂ is used. A shielding material supply pipe 9 and a shielding material return pipe 10 are connected to the tank 8, the other ends of which are respectively connected to the storage body 1 side. A transfer pump 11 is inserted into this supply pipe 9, and this pump 1
1 allows the shielding material 7 in the tank 8 to be supplied to the storage body 1. Note that 12 is the tank outlet valve,
13 is a pump outlet valve, and 14 is a tank return valve. A shielding material recovery pipe 15 is branched from the supply pipe 9 between the tank outlet valve 12 and the pump 11, and this recovery pipe 15 is connected to the supply pipe 9 on the storage body 1 side than the pump outlet valve 13. There is.
Note that 16 is a recovery valve. In addition, the pump 11
A shielding material recirculation line 17 branches off from the supply line 9 between the tank return valve 14 and the pump outlet valve 13, and this recirculation line 17 is connected to a return line 10 between the tank return valve 14 and the tank 8. Note that 18 is a recirculation valve. Further, an in-system vacuum break pipe 19 is branched from the return pipe 10 between the return port valve 14 and the storage body 1 side, and 20 is the vacuum break valve.

Next, the operation of the embodiment with the above configuration will be described in the case where the space D between the main steam nozzle B and the shielding wall C of the reactor pressure vessel A is shielded during a periodic inspection.

First, the enclosing bag 3 is wrapped around the main steam nozzle B and fixed with fasteners 5, 5. If the space D cannot be closed even with the surrounding bag 3, a closing bag 4 is arranged around the surrounding bag 3 to close the space D, as shown in FIG. Obstruction. When the enclosing bag body 3 and the plurality of closing bags 4 are disposed at the same place in this way, for example, the plugged nozzle 6a and the plugged nozzle 6
The supply piping 9 and the return piping 10 are connected to b, respectively, and the surrounding bag 3 and the closing bag 4 are connected between the supply piping 9 and the return piping 10.
The other plugged nozzles 6 are connected by continuous piping 22 so that the nozzles 6 are connected in series.

In order to supply the shielding material 7 to the storage body 1 consisting of the enclosing bag body 3 and the closing bag body 4 connected to the supply and recovery mechanism 2 in this way, first, the plug 6a of each plug-equipped nozzle 6, the pump outlet valve 13, transfer pump 11 with only recovery valve 16 and vacuum breaker valve 20 closed
Activate. At this time, the shielding material 7 in the tank 8 flows through the supply pipe 9 and the recirculation pipe 17, and is returned to the tank 8 via the return pipe 10 for circulation.

Next, the pump outlet valve 13, the plug 2 of each plug-equipped nozzle 6
1 and the return valve 14 are opened and the recirculation valve 18 is closed, the shielding material 7 returns to the tank 8 and circulates through the supply pipe 9, the storage body 1 and the return pipe 10. After confirming the circulation in this manner, the return valve 14 is closed and the shielding material 7 is filled into the storage body 1. After filling the inside of the storage body 1 with the shielding material 7, the transfer pump 11 is stopped and the plugs 21 of each plug-equipped nozzle 6 are closed.

When the above-mentioned storage unit 1 is removed after the periodic inspection work around the installation location of storage unit 1 is completed,
First, the tank outlet valve 12, pump outlet valve 13, and return port valve 14 are closed. Then, by opening the plugs 21 of each plugged nozzle 6, the recovery valve 16, and the recirculation valve 18 to start the transfer pump 11, and opening the vacuum break valve 20 immediately after startup, the shielding material in the storage body 1 is 7 is collected in tank 8. After that, the storage body 1 is closed to the closing bag body 4... and the enclosing bag body 3.
Remove in this order.

According to the above-mentioned embodiment, the shielding work of the space D to be shielded is performed by closing this space D with the storage body 1, and then installing the supply and recovery mechanism 2 inside the storage body 1. The above-mentioned shielding material 7
This can be done more easily than the conventional method of stacking lead bricks for shielding. Further, even if the space D is wide, the space D can be closed by the storage body 1 formed by combining a plurality of enclosing bags 3 and closing bags 4, so that the space D can be easily closed. Can be shielded. Further, the work of removing the storage body 1 can be easily carried out since the shielding material 7 inside the storage body 1 can be removed after being collected by the supply and recovery mechanism 2. Therefore, the working time for the above-mentioned shielding work and removal work can be shortened, and the radiation exposure dose of the workers can be reduced.

Furthermore, during shielding, the bag-shaped container 1 is mainly contaminated by the radiation from the pressure vessel A.
Therefore, compared to conventional lead bricks, the amount of radioactive solid waste generated after the removal work can be reduced.

Furthermore, since the closed bag body 4 (storage body 1) is configured to be expandable and contractible, when the shielding material 7 is filled, the shielding bag body 4 is shaped to extend outward due to the internal pressure of the shielding material 7. becomes. Therefore, the space D
can be occluded well, and its shielding ability can be further enhanced.

It should be noted that the shielding ability required here is not perfect, such as the sealing structure of pipes through which fluid normally flows, and therefore there is no problem even if there are some gaps. .

Moreover, since a shielding liquid having a specific gravity of about 1 to 5 can be used as the shielding material 7, shielding can be performed according to the required shielding ability. That is, as shown in Figure 5,
The radiation (gamma ray) shielding ability of the shielding material 7 increases as its specific gravity increases. In FIG. 5, I indicates a shielding material 7 having a specific gravity of 1, for example, a water shielding ability line, and I indicates a shielding material 7 having a specific gravity of 3, for example.
The shielding ability line of the BaHgBr ₄ aqueous solution shows the shielding ability line of the shielding material 7 having a specific gravity of 5, for example, a mixed aqueous solution of HCO ₂ Tl and C ₃ H ₂ O ₄ Tl ₂ .

Note that this invention is not limited to the above embodiment. For example, the space to be shielded is not limited to the space between the main steam nozzle of the reactor pressure vessel and the opening of the shielding wall, and an enclosing bag body having the above-mentioned covering holes configured to have various hole diameters may be used. By simply doing this, the space between the other nozzle portion of the pressure vessel and the opening of the shielding wall can be similarly shielded. Furthermore, it goes without saying that the radiation shielding device of the above embodiment is used not only in nuclear power plants, but also in other spaces to be shielded. Further, the fluid shielding material is not limited to an aqueous solution, but may be a slurry-like material in which shielding particles are interposed in a liquid.

As explained above, the present invention has a radiation shielding wall having a space through which a pipe passes, a covering hole that covers the pipe, and a notch connected to the covering hole, and is opened and closed through the notch. Attached to the piping through the covered hole,
An enclosing bag including a shielding material inflow nozzle and a shielding material outflow nozzle, and a plurality of enclosing bags arranged around the enclosing bag, each having a bellows structure so as to expand and contract in any direction along the extension direction of the radiation shielding wall. a closure bag that expands and contracts in the same direction and is provided with a shielding material inflow nozzle and a shielding material outflow nozzle, respectively; a tank that accommodates the shielding material; and this tank, the enclosing bag, and any one of the plurality of closure bags. A shielding material supply pipe disposed between the shielding material inflow nozzle and a shielding material outflow nozzle of any bag body other than the bag connected to the tank and the shielding material supply pipe. The shielding material return pipe arranged between the above-mentioned enclosing bag body and the closing bag body should be connected in series between the shielding material inflow nozzle of any bag body and the shielding material outflow nozzle of any bag body. A plurality of continuous pipes arranged, a transfer pump inserted in the shielding material supply pipe, a tank outlet valve inserted in the shielding material supply pipe between the transfer pump and the tank, and the pump A pump outlet valve inserted in the shielding material supply pipe on the discharge side of Recirculation disposed between the interposed tank return valve and the shielding material supply piping between the transfer pump and the pump outlet valve, and the shielding material return piping between the tank return valve and the tank. It is characterized by comprising a pipe, a recirculation valve inserted in the recirculation pipe, and a vacuum breaking part inserted in the shielding material return pipe on the side opposite to the tank of the tank return valve. Therefore, the shielding work and the removal work in the space can be easily performed. As a result, the working time required for each of the above-mentioned tasks can be shortened, and the radiation exposure dose of the worker can be reduced. Also, during the shielding of the above-mentioned space, the main sources of radiation contamination are:
Since only the enclosing bag and the closing bag are used, the amount of radioactive solid waste generated can be reduced. Furthermore, since the inner closing bag of the storage body is configured to be expandable and retractable, the space can be closed well when filled with the shielding material. Therefore, the shielding ability can be further improved, and the effect is great. Further, according to the present invention, by appropriately changing the size of the covering hole of the enclosing bag, it can be applied to pipe penetration parts of various diameters, and the sizes of the enclosing bag and the closing bag and the closing bag can be applied to pipe penetration parts of various diameters. By appropriately adjusting the number of bodies, etc., it can be easily applied to penetrating parts of various widths or complex shapes. In addition, since the closure bag is expandable and has a bellows structure so that it can all expand and contract in any direction along the extension direction of the radiation shielding wall, the concave and convex portions of each bellows mesh to provide good shielding. In addition to being able to provide a structure, it also has good directionality when expanding and contracting. Furthermore, the shielding material supply/recovery mechanism is simple in structure and operation, and is extremely effective in improving workability.

[Brief explanation of the drawing]

The drawings show one embodiment of the present invention, with Fig. 1 being a configuration diagram of the equipment used in a nuclear power plant, Fig. 2
The figure is a front view of the shielding material storage body from the direction of Figure 1.
FIG. 3 is a perspective view of the enclosing bag, FIG. 4 is a perspective view of the closing bag, and FIG. 5 is a shielding ability diagram of the shielding material. 1... Shielding material storage body, 2... Shielding material supply and collection mechanism, D... Space section.

Claims (1)

[Scope of Claims] 1. A radiation shielding wall having a space through which the piping passes, and a radiation shielding wall having a covering hole that covers the piping and a notch that connects to the covering hole, and opening and closing the said covering through the notch. an enclosing bag attached to the piping through a hole and provided with a shielding material inflow nozzle and a shielding material outflow nozzle; and a plurality of enclosing bags arranged around the enclosing bag in any direction along the extension direction of the radiation shielding wall. a closed bag which has a bellows structure so as to expand and contract in the same direction and is equipped with a shielding material inflow nozzle and a shielding material outflow nozzle, respectively; a tank containing the shielding material; this tank and the enclosing bag; A shielding material supply pipe arranged between any one shielding material inflow nozzle of a plurality of closed bags, and the inside of other bags other than the bag connected to the tank and the shielding material supply pipe. A shielding material return pipe disposed between the shielding material outflow nozzle of the arbitrary bag body, and the shielding material inflow nozzle of the arbitrary bag body and the arbitrary bag to connect the enclosing bag body and the closing bag body in series. a plurality of continuous pipes arranged between the body and the shielding material outflow nozzle; a transfer pump inserted in the shielding material supply pipe; and a shielding material supply pipe interposed between the transfer pump and the tank. a tank outlet valve inserted into the shielding material supply pipe on the discharge side of the pump; a recovery pipe that bypasses the transfer pump and the pump outlet valve; A recovery valve, a tank return valve inserted in the shielding material return piping, a shielding material supply piping between the transfer pump and the pump outlet valve, and a shielding material return piping between the tank return valve and the tank. a recirculation pipe installed between the recirculation pipe, a recirculation valve inserted in the recirculation pipe, and a vacuum break section inserted in the shielding material return pipe on the opposite side of the tank of the tank return valve. A radiation shielding device characterized by comprising the following.