JP2001183494A - Radiation shielding wall - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a radiation shielding wall allowing cables to be passed in a through-hole later and having a higher percentage for allowable current. SOLUTION: The radiation shielding wall, provided with an encircled radiation generating body, has a cable tray 13 arranged in a linear through-hole 11, in which a plurality of cables 3 are placed.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a radiation shielding wall surrounding a radiation generating body such as an accelerator.

[0002]

2. Description of the Related Art FIG. 4 is a sectional view of a conventional radiation shielding wall. An L-shaped through hole 2 is formed in a radiation shielding wall 1 which is a concrete wall having a thickness of several meters. A plurality of CV cables 3 are guided in the through holes 2. An accelerator body (not shown) to which one end of the CV cable 3 is connected is installed inside the radiation shielding wall 1. On both sides of the radiation shielding wall 1, a cable tray 4 having a U-shaped cross section on which CV cables 3 are laid is provided. On the accelerator main body side of the through hole 2, a refractory plate 5, which is a calcium silicate plate through which the CV cable 3 penetrates, is fastened to the radiation shielding wall 1. The space between the refractory plate 5 and the CV cable 3 is sealed with a refractory putty 6 which is a sealing material. CV
The fire spread paint 7 is applied to the surface of the cable 3 by about 1 meter from the fireproof plate 5 toward the accelerator main body.

In the radiation shielding wall 1 having the above structure, when the radiation advances from the accelerator body toward the radiation shielding wall 1, the radiation is shielded by the radiation shielding wall 1. The radiation that has penetrated into the through-hole 2 collides with the inner wall of the through-hole 2 since the inside of the through-hole 2 is bent halfway, so that the radiation is prevented from being emitted to the outside.

[0004]

In the radiation shielding wall having the above-described structure, the through-hole 2 is bent in the middle to prevent the radiation from being emitted to the outside. There is a problem that it is difficult to pass the cable 3 and it is also difficult to install a metal fluid pipe or the like through which the cooling water, N _{2 and the} like circulate later in the through hole 2. Further, when the number of CV cables 3 becomes large, the plurality of CV cables 3 are brought into close contact in the through-hole 2, heat is generated by the CV cables 3 themselves, dielectric breakdown easily occurs, and the allowable current rate ( There is also a problem that the current value that can be actually passed through the cable / the current value that can be passed through the cable by design) becomes low.

SUMMARY OF THE INVENTION An object of the present invention is to solve the above-mentioned problems, and it is possible to pass a cable through a through hole later, and to improve the allowable current rate of the cable. It is an object of the present invention to obtain a radiation shielding wall that can be used.

[0006]

In the radiation shielding wall according to the first aspect of the present invention, a cable tray on which a plurality of cables are laid is disposed inside a through hole that penetrates linearly.

In the radiation shielding wall according to a second aspect of the present invention, the through hole is inclined upward toward the outside of the radiation shielding wall.

In the radiation shielding wall according to a third aspect of the present invention, a supporting member is provided so as to cover the radiation generating main body, and a supporting member for separating and supporting each cable is provided at an upper end opening of the through hole penetrating vertically. Can be

In the radiation shielding wall according to a fourth aspect of the present invention, a pipe through which a cable can pass is provided in the through hole.

In the radiation shielding wall according to a fifth aspect of the present invention, a pipe through which a cooling medium for cooling the radiation generating main body flows is provided in the upper space in the through hole.

In the radiation shielding wall according to a sixth aspect of the present invention, a waste material of a CV cable that absorbs radiation is provided at one end in the through hole.

In the radiation shielding wall according to a seventh aspect of the present invention, a fireproof plate through which a cable passes is fastened to the shielding wall on the radiation generating main body side of the through hole, and a fireproof plate is provided between the fireproof plate and the cable. Sealed with putty, and fire spread paint is applied to the surface of the cable.

[0013]

DESCRIPTION OF THE PREFERRED EMBODIMENTS Embodiment 1 FIG. 1 is a sectional view of a radiation shielding wall according to Embodiment 1 of the present invention, and FIG. 2 is a sectional view of the radiation shielding wall taken along line II-II of FIG. In a shielding wall 10 which is a concrete wall having a thickness of several meters, a through hole 11 extending linearly is formed. A sleeve 12 which is a steel pipe having an inner diameter of 300 mm is embedded in the through hole 11. A cable tray 13 having a U-shaped cross section obtained by dividing the inside of the sleeve 12 into two parts is mounted in the sleeve 12. In the cable tray 13, a plurality of CV cables 3 each having one end connected to an accelerator body (not shown) are laid in parallel. A plurality of CV cables 3 are also laid in parallel below the inner wall surface of the sleeve 12. The upper portion of the sleeve 12 conduit 14 made of steel of the following sizes 54 ^phi mm penetrates the sleeve 12.

On the accelerator main body side of the through hole 11, a refractory plate 5, which is a calcium silicate plate through which the CV cable 3 penetrates, is fastened to the radiation shielding wall 10. The space between the refractory plate 5 and the CV cable 3 is sealed with a refractory putty 6 which is a sealing material. On the surface of the CV cable 3, a fire spread paint 7 having a length of about 1 meter is applied from the refractory plate 5 toward the accelerator main body. In the sleeve 12, a fireproof plate 5 is provided.
A plurality of iron rods 15 for reducing radiation are provided adjacent to. In the sleeve 12, a CV cable waste material 16 filled in a polyethylene bag is placed adjacent to the iron round bar 15. The CV cable waste material 16 is obtained by finely cutting the CV cable 3 and is composed of copper as a conductor and polyethylene or the like as an insulating coating material. Copper having a large atomic number mainly absorbs gamma rays. The neutron beam is mainly absorbed by hydrogen atoms contained in a large amount in polyethylene or the like. A cable tray 4 having a width of 600 mm and a U-shaped cross section is provided on both sides of the radiation shielding wall 10, on which a plurality of CV cables 3 are laid.

The radiation shielding wall 10 is formed by pouring concrete around the sleeve 12. Next, the cable tray 13 is mounted in the sleeve 12, and the CV cables 3 are laid in parallel on the cable tray 13, and a plurality of CV cables 3 are also laid in parallel below the inner wall surface of the sleeve 12. After that, the CV cable waste material 16 and the iron round bar 15 are arranged in the sleeve 12 on the accelerator body side, the fireproof plate 5 having the CV cable 3 penetrated is fastened to the radiation shielding wall 10, and the fireproof plate 5 and the CV cable 3 is sealed with a refractory putty 6, and a fire spread paint 7 is applied to the surface of the CV cable 3.

In the radiation shielding wall 10 having the above configuration, when the radiation advances from the accelerator main body toward the radiation shielding wall 10, the radiation is shielded by the radiation shielding wall 10. The speed of the radiation that has entered the through hole 11 is reduced by the iron round bar 15 and absorbed by the CV cable waste material 16. Also, a plurality of CV cables 3 are laid in parallel on a cable tray 13 in the sleeve 12, and heat of the CV cable 3 itself is transferred from the upper space in the sleeve 12 by natural convection to the sleeve 12 on the anti-radiation main body side. Is released to the outside through the opening. A plurality of CV cables 3 are also laid in parallel below the inner wall surface of the sleeve 12.
The heat of the V cable 3 itself is also released to the outside from the opening of the sleeve 12 on the anti-radiation main body side by natural convection from the space below the cable tray 13. As a result, it was confirmed that the allowable current ratio of the conventional device was 0.3, whereas the allowable current ratio of the present embodiment was significantly improved to 0.65. When the sleeve 12 is inclined at an inclination angle (1/100) so that the anti-accelerator body side of the sleeve 12 is higher than the accelerator body side, the space in the CV cable 3 becomes more active due to the chimney effect. A convection is generated, and the exhaust heat effect becomes larger. According to actual measurements by the inventor of the present application,
The allowable current ratio was further improved to a value of 0.70.

[0017] In addition, the upper portion of the sleeve ¹² 54 φ mm
The conduit 14 made of a steel pipe having the following size is
Penetrates inside. When it is necessary to electrically connect the outside of the shielding wall 10 and the accelerator body using the CV cable 3 after the construction, the connection can be made by a simple operation of penetrating the CV cable 3 into the conduit tube 14. Can be.
The inner diameter of the conduit 14 is set to a small diameter such that when radiation enters the conduit, the inner wall surface is reflected, refracted, and attenuated. In this embodiment, the conduit 14 is arranged in the upper space of the sleeve 12, but a fluid pipe through which cooling water, N _2, etc. flows may be provided in this space. In the upper space of the sleeve 12, high-temperature air stays under the influence of natural convection as compared with the lower space. However, by providing a fluid pipe through which a refrigerant for cooling the accelerator body flows, the upper space is positively affected. And the temperature rise in the sleeve 12 can be suppressed, and the allowable current rate can be further increased.

Embodiment 2 FIG. FIG. 3 is a sectional view of a radiation shielding wall according to Embodiment 2 of the present invention. Embodiment 2
Then, a vertically extending through hole 2 is formed in a shielding wall 10 which is a concrete wall having a thickness of several meters which covers the accelerator body.
0 is formed. Inside diameter of this through hole 20 is 300
The sleeve 21 which is a steel pipe of mm is embedded. A lattice-like support member 22 is attached to the opening of the through hole 20. CV penetrating through each space of the support member 22
The cable 3 is tied to the support member 22 so as to be separated from each other by a wire, a securing string or the like (not shown). On one side of the sleeve 21 Conduit 23 consisting of steel pipes of the following sizes 54 ^phi mm penetrates.

On the accelerator body side of the through hole 20, a refractory plate 5, which is an iron plate through which the CV cable 3 penetrates, is attached to the radiation shielding wall 1.
It is fastened to 0. The space between the refractory plate 5 and the CV cable 3 is sealed with a refractory putty 6 which is a sealing material. CV
The surface of the cable 3 is coated with a fire spread paint 7 having a length of about 1 meter from the refractory plate 5 toward the accelerator main body. A plurality of iron rods 15 for reducing radiation are provided adjacent to the refractory plate 5 in the sleeve 21.
In the sleeve 21, a CV cable waste material 16 filled in a polyethylene bag is placed on an iron round bar 15. On each of the accelerator main body side and the anti-accelerator main body side with respect to the shielding wall 10, a cable tray 4 having a width of 600 mm and a U-shaped cross section on which a plurality of CV cables 3 are laid is provided.

In the radiation shielding wall having the above configuration, the support member 2
Since the CV cables 3 penetrating through the respective space portions 2 are bound to the support member 22 by wires so as to be separated from each other,
The CV cable 3 itself is hardly affected by the heat from the adjacent CV cable 3, and the heat of the CV cable 3 itself is efficiently discharged to the outside through the opening of the sleeve 21 by natural convection. As a result, in this embodiment,
It was confirmed by actual measurement that the allowable current rate was significantly improved to 0.70 or more.

It should be noted that instead of the iron round bar 15, an iron ball such as a pachinko ball may be used as the radiation moderator. In this case, the iron balls need only be dropped between the CV cables 3 after the CV cables 3 are mounted in the through holes 20, and the workability is improved.

Further, in each of the embodiments, the waste material of the CV cable is used as the radiation absorbing material, but polyethylene beads, sand or the like may be used. Further, it is desirable that the through hole is formed at a position as far as possible from the beam line of the accelerator main body. In some cases, only the iron round bar as the moderator is used, and the absorber can be eliminated. In addition, as the radiation generating body, the explanation has been given of the accelerator body that mainly emits neutrons as radiation, but for this reason, iron that slows down neutrons was used as a moderator, but mainly for nuclear power plants that emit gamma rays The facility uses lead as a moderator. The radiation shielding wall of the present invention can be applied to a medical linac.

[0023]

As described above, according to the radiation shielding wall according to the first aspect of the present invention, a cable tray on which a plurality of cables are laid is disposed inside a through hole that penetrates straight. Therefore, the heat of the cable is efficiently released to the outside, and the allowable current rate of the cable is improved.

Further, according to the radiation shielding wall according to the second aspect of the present invention, since the through-hole is inclined upward and outward, heat generated from the cable is inclined at the opening of the through-hole. It is discharged to the outside by convection from the upper end,
The allowable current rate of the cable is further improved.

According to a third aspect of the present invention, there is provided a radiation shielding wall which covers the radiation generating main body and supports each cable at an upper end opening of a vertically penetrating through hole. Since the support member is provided, the heat generated from the cable is less likely to be affected by each other, and the heat generated from the cable is discharged to the outside by convection from the upper end, which is the opening of the through hole, and the allowable current rate of the cable is improved I do.

According to the radiation shielding wall according to the fourth aspect of the present invention, a pipe through which a cable can pass is provided in the through hole, so that after the construction, the outside of the shielding wall and the radiation generating body are connected to each other by the cable. When it becomes necessary to make an electrical connection using the conduit, work connection can be easily performed using this conduit tube.

According to the radiation shielding wall according to the fifth aspect of the present invention, since a pipe through which a cooling medium for cooling the radiation generating body flows is provided in the upper space in the through hole, the radiation generated from the cable is provided. The heat staying in the upper space is exchanged with the cooling medium in the pipe, and the temperature rise in the through hole is suppressed, and the allowable current rate of the cable is improved.

Further, according to the radiation shielding wall according to the sixth aspect of the present invention, the waste material generated in connection with the cable is used, and there is no need to prepare a radiation absorbing material, and the cost is reduced. You.

Further, according to the radiation shielding wall of the present invention, a fireproof plate through which a cable passes is fastened to the shielding wall on the radiation generating main body side of the through hole. The space between them is sealed with a fire-resistant putty, and a fire spread paint is applied to the surface of the cable, so that fire prevention measures are taken on the radiation generating body side of the radiation shielding wall.

[Brief description of the drawings]

FIG. 1 is a sectional view of a radiation shielding wall according to Embodiment 1 of the present invention.

FIG. 2 is a cross-sectional view of the radiation shielding wall of FIG. 1 taken along the line II-II.

FIG. 3 is a sectional view of a radiation shielding wall according to Embodiment 2 of the present invention.

FIG. 4 is a sectional view of a conventional radiation shielding wall.

[Explanation of symbols]

3 CV cable, 5 fire-resistant plate, 6 fire-resistant putty, 7 fire-retardant paint, 10 radiation shielding wall, 11, 20 through hole, 12, 21 sleeve, 13 cable tray, 1
4,23 Conduit, 16 CV cable waste, 22 support members.

Claims (7)

[Claims] 1. A radiation shielding wall provided around a radiation generating main body, and in which a tray on which a plurality of cables are laid is disposed inside a through hole penetrating linearly. 2. The radiation shielding wall according to claim 1, wherein the through hole is inclined upward and outward. 3. A radiation shielding wall provided so as to cover a radiation generating main body, and a support member provided at an upper end opening of a vertically penetrating through-hole to support each cable at a distance. 4. The radiation shielding wall according to claim 1, wherein a pipe through which a cable can pass is provided in the through hole. 5. The radiation shielding wall according to claim 1, wherein a pipe through which a cooling medium for cooling the radiation generating body flows is provided in an upper space portion in the through hole. 6. The radiation shielding wall according to claim 1, wherein a waste material of a CV cable for absorbing radiation is provided at one end in the through hole. 7. A fireproof plate through which a cable penetrates is fastened to the radiation generating main body side of the through hole, a space between the fireproof plate and the cable is sealed with a fireproof putty, and a fire spread paint is applied to the surface of the cable. The radiation shielding wall according to claim 1, wherein the radiation shielding wall is formed.