KR20060015680A - Emission shield door assembly and opening - closing apparatus thereof - Google Patents

Abstract

The present invention comprises a door housing provided with a predetermined space therein, a soft plate provided on each of the inner opposing surfaces of the door housing and a neutron shielding layer provided between the soft plate, the neutron shielding layer Is a polyethylene or paraffin containing at least 5% boron to provide a radiation shielding door that can prevent the outflow of neutron radiation to the outside as well as primary radiation. The present invention also provides a guide for guiding the opening and closing of the radiation shielding door, the radiation shielding door, a main opening and closing means for driving the radiation shielding door to be opened and closed along the guide, and the radiation shielding door to be opened and closed in an emergency. It is configured to include an auxiliary opening and closing means for driving provides a radiation shielding door opening and closing device that can easily open and close the high load of the radiation shielding door, convenient maintenance and repair, and can open and close the radiation shielding door in an emergency.

Radiation, neutron, shielding, galvanized steel sheet, polyethylene, switchgear

Description

Emission shield door assembly and opening-closing apparatus

1A is a perspective view showing a radiation shielding door according to the present invention;

FIG. 1B is a cross-sectional view illustrating the interior of the radiation shielding door of FIG. 1A. FIG.

Figure 2a is a cross-sectional view showing the front of the doorway is installed the radiation shielding door opening and closing device according to the present invention.

Figure 2b is a cross-sectional view showing the side of the entrance to the radiation shielding door opening and closing device according to the present invention.

Figure 2c is a longitudinal cross-sectional view of the doorway installed with the radiation shielding door opening and closing apparatus according to the present invention.

* Description of the symbols for the main parts of the drawings *

100: radiation shielding door 110: door housing

120: soft plate 130: neutron shielding layer

140: galvanized steel sheet layer 200: radiation shielding door opening and closing device

210: guide 220: main switchgear

230: auxiliary opening and closing device 240: buffer means

The present invention relates to a radiation shielding door, and more particularly, to a radiation shielding door capable of preventing the radiation emitted from a radiation treatment room or the like, in particular, neutron beams, from leaking out through an entrance.

In addition, the present invention relates to a radiation shielding door opening and closing device, and more particularly, an auxiliary opening and closing means for opening and closing of a high load of the radiation shielding door is easy, easy to maintain and repair, and to open and close the radiation shielding door in an emergency. It relates to a radiation shielding door opening and closing device.

Radioactive ray refers to particle rays and radiations emitted when the radioactive element decays. More specifically, it refers to α rays, β rays, and γ rays emitted as the radionuclides decay, but the broad meaning is Includes particle beams and electromagnetic waves generated by various reactions involving an atomic nucleus.

Such radiation has been used for the diagnosis and treatment of diseases, especially in the case of gamma rays has shown a significant effect in the treatment of cancer. It is also used to effectively sterilize various medical products (syringes, surgical sutures, compression bandages, etc.). However, when radiation is irradiated above a certain amount, acute or chronic radiation disorders may occur, and genetic mutations may occur.

Therefore, in buildings where radiation leakage is concerned, such as nuclear power plants and hospitals, the corresponding walls and doors should be constructed with radiation shielding walls and shielding doors to prevent radiation leakage.

In general, the radiation shielding door is to prevent the radiation from leaking out through the entrance and is manufactured by stacking the iron plate and the soft plate. In the radiation shielding door as described above, primary radiations α, β, and γ radiated from the general radiation generator may be shielded to some extent. However, the shielding efficiency is very low among the neutron beams emitted from the high energy (more than 10Mev) radiation generator. However, in order to shield the neutron beam, there is a problem that the thickness of the radiation shielding door cannot be made infinitely thick.

On the other hand, the radiation shielding door as described above is produced by stacking the iron plate and the soft plate has a high load.

Conventionally, a wheel drive method or a roller drive method was used to open and close the high load radiation shielding door as described above.

Among these, the wheel driving method is a method of opening and closing the radiation shielding door by installing a rail at the lower portion of the radiation shielding door and installing a wheel at the bottom of an entrance corresponding to the installed rail to move the rail along the wheel.

In the roller driving method, a rail is installed under the radiation shielding door, and a plurality of rollers supported by rolling bearings are installed on the bottom of the doorway corresponding to the installed rail to move the rail along the rollers to open and close the radiation shielding door. That's the way.

However, each driving method has the following problems.

First of all, in the case of the wheel drive method, the radiation shielding door is manufactured with high load, and a very large shear stress is applied to the shaft of the wheel supporting the radiation shielding door. Therefore, the wheel shaft should be made large to support the shear stress, and the wheel size also has to be large. In addition, as the size of the wheels increases, the size of the rails must also increase proportionally, and there is a design difficulty. As the size of the wheels and the rails increases, there is a problem that a deficiency of shielding occurs through this portion.

In the case of the roller driving method, if the load of the radiation shielding door is not evenly distributed on the roller, the concentrated load is generated on a part of the roller and the radiation shielding door is inclined. In addition, the rolling bearing and bearing housing supporting the rollers should be large in order to prevent the load from being concentrated on a part of the rollers.

In addition, the rail used in the wheel drive method and the roller drive method is typically used for rail vehicles rail, so it is difficult to withstand high loads and the surface hardness is smaller than the conventional wheel or roller. As a result, pitting occurs when the surface of the rail is peeled off repeatedly during the opening and closing of the radiation shielding door. The fitting phenomenon increases the frictional resistance between the rail and the wheel and between the rail and the roller, thereby weakening the driving performance. .

In addition, another problem of the conventional radiation shielding door opening and closing device is to lift a radiation load door with a high load in order to replace a wheel or a roller installed at a lower portion of the radiation shielding door, which requires expensive equipment such as a crane. The work is not easy.

In addition, the conventional switchgear as described above has a disadvantage in that the radiation shielding door is driven by the electric motor, and the radiation shielding door cannot be opened and closed when the electric motor cannot be operated due to a power failure.

Accordingly, an object of the present invention is to provide a radiation shielding door capable of preventing the neutron beams from leaking out through the entrance as well as the primary radiation.

Still another object of the present invention is to provide a radiation shielding door opening and closing device that can easily open and close a high load radiation shielding door, and is convenient to manufacture, maintain and repair, and can open and close the radiation shielding door in an emergency.

The radiation shielding door of the present invention for achieving the above object is a door housing provided with a predetermined space therein, a soft plate provided on each of the inner opposing surfaces of the door housing, and a neutron shield provided between the soft plate Layer, wherein the neutron shielding layer comprises polyethylene or paraffin containing at least 5% or more boron.

In addition, the radiation shielding door opening and closing apparatus of the present invention includes a guide for guiding the opening and closing of the radiation shielding door, the radiation shielding door, a main opening and closing means for driving the radiation shielding door to open and close along the guide, and the radiation in an emergency It is configured to include an auxiliary opening and closing means for driving the shield door to open and close.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

Fig. 1A is a perspective view showing a radiation shielding door according to the present invention, and Fig. 1B is a cross sectional view showing the inside of the radiation shielding door of Fig. 1A.

As shown in the figure, the radiation shielding door of the present invention (hereinafter, the shielding door 100) is composed of a door housing 110, a soft plate 120 and a neutron shielding layer 130 provided inside the door housing 110. do.

The door housing 110 is formed in a hollow shape so that a predetermined space is provided in a rectangular parallelepiped shape having a predetermined thickness. In addition, a predetermined space provided inside the door housing 110 includes a soft plate 120 and a neutron shielding layer 130. In this case, the soft plate 120 is provided in pairs and positioned on both inner surfaces of the door housing 110, respectively, and spaced apart from each other by a predetermined interval. In addition, a neutron shielding layer 130 is positioned between the soft plates 120.

Here, the door housing 110 is made of an iron plate excellent in radiation shielding rate, the outer surface is provided with an electrogalvanized steel sheet layer 140 of a predetermined thickness. The galvanized steel sheet layer 140 provided on the outer surface of the door housing 110 is formed by attaching a separately produced electric zinc plated steel sheet to the door housing after manufacturing the door housing, or before manufacturing the door housing. It is formed by electroplating zinc on one side.

In the present invention, the radiation shielding door 100 preferably has a thickness of the door housing 110 of at least 6 mm so as to ensure radiation shielding. In addition, the thickness of the galvanized steel sheet layer 140 formed on the outer surface of the door housing 110 is preferably formed to at least 2mm.

In addition, the soft plate 120 is made of lead excellent in radiation shielding rate, the thickness is preferably at least 50mm or more. In the present invention, in order to increase the radiation shielding rate, the thickness of the soft plate 120a positioned on the side where the radiation is generated is 100 mm and the soft plate 120b located on the opposite side is 50 mm.

On the other hand, the neutron shielding layer 130 is made of polyethylene having excellent performance in blocking the neutron beam, the thickness thereof is preferably at least 270mm or more. In addition, the neutron shielding layer 130 may use paraffin in addition to polyethylene.

In this case, as polyethylene and paraffin used in the neutron shielding layer 130, it is most preferable to use polyethylene and paraffin containing at least 5% or more of boron (B) in order to maximize the radiation shielding rate.

Figure 2a is a cross-sectional view showing the front surface of the entrance and exit door is equipped with a radiation shielding door opening and closing device according to the present invention, Figure 2b is a cross-sectional view showing the side of the entrance and exit door is provided with a radiation shielding door opening and closing device according to the present invention, Figure 2c It is a longitudinal cross-sectional view of the entrance and exit provided with the radiation shielding door opening and closing apparatus which concerns on this invention.

As shown in the drawings, the shielding door opening and closing device 200 of the present invention is a shielding door 100 as a means for opening and closing the shielding door 100 installed at the entrance of a radioisotope use facility such as a nuclear power plant, a hospital, and the like. A guide 210 for guiding the opening and closing of the shielding door 100, a main opening and closing unit 220 for driving the shielding door 100 to open and close along the guide 210, and a shielding door 100 in an emergency It is configured to include an auxiliary opening and closing means 230 for driving to open and close.

In this case, a space 400 for accommodating the shielding door is provided at one side of the entrance 300 in which the shielding door opening and closing device 200 is installed, and is accommodated in the accommodation space 400 when the shielding door 100 is opened. do.

In addition, the wall of the use facility provided with the entrance 300 is a radiation shielding wall made of lead and reinforced concrete to prevent radiation leakage.

The shielding door 100 is provided with a predetermined space therein, the outer side of the door housing 110 is provided with a galvanized steel sheet layer of a predetermined thickness and on both opposite inner surfaces of the door housing 110 Each comprising a soft plate 120 and a shielding layer 130 made of neutron polyethylene or paraffin provided between the soft plate 120.

Here, the shielding door 100 is the same as that shown in FIGS. 1A and 1B, and a detailed description thereof will be omitted.

The guide 210 is positioned above the shielding door 100 to guide the opening and closing direction of the shielding door 100, and both ends of the frame 212 are fixed to both side wall surfaces of the doorway 300, and the frame A guide rail 214 provided on the upper surface, a guide block 216 moving along the guide rail 214, and a bracket coupled to the guide block 216 and moving together with the guide block 216 218.

The structure of the guide 210 will be described in more detail. The frame 212 is an I-shaped steel having a predetermined length and is spaced apart from the upper portion of the shielding door 100 by a predetermined distance, and both ends are formed at one side of the entrance 300. It is fixed to the wall surface and the side wall surface of the storage space 400, respectively. In addition, a plurality of sensors (s) are attached to the vertical surface of the frame (212), the sensor (s) for detecting the opening and closing position of the shielding door 100 by detecting the position of the bracket 218. In the present invention, a limit switch is used.

The upper surface of the frame 212 is provided with a guide rail 214 formed long in the longitudinal direction of the frame 212, that is, the opening and closing direction of the shielding door 100, the guide rail on the upper surface of the guide rail 214 Four guide blocks 216 moving along 214 are coupled, and a pair of brackets 218 are coupled to the guide block 216. That is, a pair of guide blocks 216 are coupled to one bracket 218. In this embodiment, the number of the guide rails 214 is illustrated as one, but this is just an example and may be provided as two or more as necessary, but it is most preferably provided as a pair.

 The pair of brackets 218 are coupled to each other so that the frame 212 is positioned inside the bracket 218 in a rectangular cross-sectional shape, and the upper plate 218a and the lower plate 218b are each the guide block ( 216 and the shield door (100). In addition, the pair of brackets 218 are spaced apart by a predetermined interval in the longitudinal direction of the frame 212.

At this time, the guide block 216 is coupled to the lower surface of the upper plate 218a, and a bolt b for coupling with the shielding door 100 is fixed to the lower plate 218b.

Here, both ends of the frame 212 are fixed to one side wall surface of the entrance 300 and the side wall surface of the storage space 400 as described above. At this time, there is a method of fixing the frame 212 is a method of fixing directly to the wall using an anchor bolt, and a method of fixing the H beam vertically to the wall and then fixed with a bolt.

Among these, the anchor bolt is used to directly fix the wall to the wall, which is used when the entrance and the storage space are pre-installed. Fix the frame after installing the anchor.

The method of fixing bolts after installing the H beam is used when the entrance and storage space is not installed. The H beam that can support the frame is installed at the same time as the shielding wall is installed and the frame is installed on the installed H beam. Fixed to use.

Therefore, the user can select and use one of the two methods according to the situation.

The main opening and closing means 220 is a pair fixed to each of the upper side wall surface of the frame 212, that is, one side wall surface of the entrance 300 is fixed to both ends of the frame 212 and the side wall surface of the storage space 400 The sprocket 222, the electric motor 224 for driving one of the sprockets of the pair of sprockets 222, and a chain 226 for connecting the pair of sprockets 222 to each other.

Here, the pair of brackets 218 are coupled to the chain 226, and when the electric motor 224 is driven to rotate the sprocket 222, the pair of brackets 218 are guide rails 214. It moves along and opens and closes the shielding door 100. At this time, the electric motor 224 is rotated forward or reverse to open or close the shield door (100).

The auxiliary opening and closing means 230 is an actuator 230 which is operated by pneumatic or hydraulic pressure as an opening and closing means for opening or closing the shield door 100 in an emergency where the operation of the electric motor 224 is impossible due to a power failure. to be. In this embodiment, a cylinder 230 is used, and the cylinder 230 is fixed to an upper wall surface of the accommodation space 400, and an end of the rod 232 is one bracket of the pair of brackets 218. Is connected to.

As described above, if the operation of the electric motor 224 is impossible due to a power failure or the like, when the cylinder 230 is operated by pneumatic or hydraulic pressure, the rod 232 is drawn in or drawn out, and the bracket 218 is moved and the bracket is moved. 218 moves along the guide rail 214 and opens and closes the shield door 100.

At this time, the one side wall surface of the doorway 300 and the side wall surface of the storage space 400 is provided with a buffer means 240 for mitigating the impact generated when the opening and closing of the radiation shielding door 100 is completed. At this time, the buffer means 240 is preferably used in large capacity in consideration of the weight of the shielding door (100).

On the other hand, in the present embodiment, the auxiliary opening and closing means is configured to open and close the shield door 100 using pneumatic or hydraulic pressure, but is not necessarily limited thereto.

Although not shown in the drawing, a separate sprocket and a handle corresponding to the sprocket are provided on the shield door, and the sprocket and the handle are connected by a chain, and then the handle may be rotated to manually open the shield door. At this time, the sprocket may be used without coupling the handle to the sprocket of the main opening and closing means.

In addition, after the gear is provided in the shielding door and the corresponding gear is coupled to the handle to rotate the handle can manually open the shielding door.

Of course, the present invention is not limited to the above two examples, and various transmission means can be used to open and close the shield door 100 in various ways.

As described above, the configuration and operation of the radiation shielding door and its opening and closing device according to a preferred embodiment of the present invention are illustrated according to the above description and drawings, but these are merely described for example and do not depart from the spirit of the present invention. It will be apparent to those skilled in the art that various changes and modifications can be made without departing from the scope of the present invention.

As described above, the radiation shielding door of the present invention is provided with an electrogalvanized steel layer on the outer surface of the door housing, and is provided with a neutron shielding layer made of polyethylene or paraffin containing 5% or more of boron therein, so that not only the primary radiation but also the neutron beam It can be prevented from leaking out through the radiation shielding door.

In addition, the radiation shielding door opening and closing device is easy to maintain and repair as the radiation shielding door and the bracket is fixed with bolts, and the auxiliary shielding means is provided to open and close the radiation shielding door in case of emergency such as power failure. There is this.

Claims (10)

A door housing having a predetermined space therein; Soft plates respectively provided on opposite inner surfaces of the door housing; A neutron shielding layer provided between the soft plates; The neutron shielding layer is configured to include a radiation shielding door comprising a polyethylene or paraffin containing at least 5% boron. The method of claim 1, Radiation shielding door is provided on the outer surface of the door housing is further provided with a galvanized steel sheet layer of a predetermined thickness. Radiation shielding doors; A guide for guiding opening and closing of the radiation shielding door; Main opening and closing means for driving the radiation shielding door to be opened and closed along the guide; Auxiliary opening and closing means for driving the radiation shielding door to be opened and closed in an emergency; Opening and closing device of the radiation shielding door comprising a. The method of claim 3, wherein The main opening and closing means, A pair of sprockets provided on both sides of the upper portion of the radiation shielding door, an electric motor for driving one of the sprockets of the pair of sprockets, a chain connecting the pair of sprockets to each other and both ends of the chain and the radiation shielding door, respectively Opening and closing device of the radiation shielding door comprising a bracket coupled to move along the guide. The method according to claim 3 or 4, The auxiliary opening and closing means, the opening and closing device of the radiation shielding door including an actuator which is located on the upper portion of the radiation shielding door, the end of the rod coupled to the radiation shielding door. The method of claim 5, The actuator is a pneumatic or hydraulically operated opening and closing device of the radiation shielding door. The method according to claim 3 or 4, The auxiliary opening and closing means, the opening and closing device of the radiation shielding door comprising a chain or gear for moving the radiation shielding door, and a handle for driving the chain or gear. The method of claim 6, Opening and closing device of the radiation shielding door further comprises a buffer means for mitigating the shock generated when opening and closing the radiation shielding door. The method of claim 6, Opening and closing device of the radiation shielding door further comprises a sensor for detecting the opening and closing position of the radiation shielding door. A radiation shielding door according to claim 1 or 2; A guide for guiding opening and closing of the radiation shielding door; Main opening and closing means for driving the radiation shielding door to be opened and closed along the guide; Auxiliary opening and closing means for driving the radiation shielding door to be opened and closed in an emergency; Opening and closing device of the radiation shielding door comprising a.

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