JP2006038468A - Shielding concrete considering radiation and construction method thereof - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide shielding concrete considering radiation for reliably and inexpensively reducing the radiation of concrete for shielding radiation, and to provide a method for constructing the shielding concrete. <P>SOLUTION: The shielding concrete of walls 12, 13 and a ceiling 14 around a radiation treatment room 10 in which a radiation source 11 is installed is placed by using a placing form made of low-radiation concrete. For a floor 15, the shielding concrete is placed, low-radiation concrete is placed for constructing a low-radiation layer 16, and the whole inside of the radiation treatment room 10 is activated to a low level. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to shielding concrete used in buildings that handle radiation such as PET facilities, medical radiation irradiation facilities, accelerator facilities, isotope storage facilities, uranium treatment facilities, nuclear reactor facilities, and in particular, considers the activation of concrete. Shielded concrete and its construction method.

In recent years, even in medical facilities, there are an increasing number of facilities that handle radiation, such as PET facilities that perform cancer diagnosis and medical radiation irradiation facilities that perform cancer treatment. In such facilities that handle radiation, radiation shielding concrete made of reinforced concrete (hereinafter referred to as shielding concrete) is provided around the place where the radiation source is installed so that radiation does not leak outside the management area. I have to.
As a concrete composition used for the above-mentioned shielding concrete, water, river sand, sea sand, mountain sand, crushed stone, etc. as well as ordinary reinforced concrete, ordinary Portland cement made from limestone, clay, iron oxide, etc. A concrete composition kneaded with an aggregate obtained from the above is used, but the above cement and aggregate include Na, Mg, Al, Si, Co, Eu, ²⁴ Na, ¹⁵² Eu, ⁶⁰ Co, etc. Since the element that becomes the parent nuclides of the radioisotopes is contained, when the radiation, especially thermal neutron rays, are incident on the shielding concrete, the elements are changed to radioactive isotopes, and the shielding is caused by the decay of the radioactive isotopes. Radiation is released from the body. In particular, Na, Mg, Al, Si, and the like, which are ²⁴ Na-producing parent nuclides contained in cement, are all changed to ²⁴ Na having a half-life of about 15 hours by irradiation with neutrons. Release. The production ratio of ²⁴ Na per unit mass of the produced parent nuclide is 0.02 for Mg, 0.01 for Al, and 0.002 for Si when Na is 1. The total mass of the produced parent nuclides per unit volume calculated by multiplying each mass of the produced ²⁴ Na parent nuclides by the above production ratio is called Na total amount, and this Na total amount becomes a problem when designing low activation concrete. .
These radiations are not emitted to the outside of the room where the radiation source is installed because the shielding concrete has a certain thickness. This may cause radiation exposure to users, medical personnel, and workers during facility maintenance. In recent years, the disposal method of radioactive waste at the time of facility dismantling has also become a problem.
Therefore, in order to keep the above-mentioned activation low, a part of the cement is replaced with limestone powder, or as the cement, the Na content is 0.25 wt% or less, and the Mg content is 1.0 wt% or less. A method of constructing the shielding concrete using a concrete composition containing cement in which the total amount of Na is reduced by setting the Al content to 2.3% by weight or less has been performed (for example, Patent Document 1, 2).
In addition, passive measures such as providing sufficient cooling time are often taken for exposure during maintenance.
JP 2003-238226 A Japanese Patent Laid-Open No. 62-133394

By the way, since the cement with a small total amount of Na as described above is more expensive than the commonly used Portland cement, the construction cost is increased when the entire shielding concrete is constructed using such cement. was there. In addition, even when a part of the cement is replaced with limestone powder, the cost of manufacturing the concrete is increased and the cost is increased.
In addition, the activation of shielding concrete by neutron beams etc. occurs only near the indoor surface, although it depends on the intensity of the radiation source and the distance between the radiation source and the shielding body. It was uneconomical to use cemented concrete.

  The present invention has been made in view of the conventional problems, and provides a radiation-considering shielding concrete capable of reliably and inexpensively reducing the activation of concrete that shields radiation, and a construction method thereof. With the goal.

Invention of Claim 1 of this application is shielding concrete which considered radiation of concrete while shielding radiation, Comprising: The indoor side surface of the said shielding concrete was coat | covered with low activation concrete. Is.
The invention according to claim 2 is the shielding concrete considering the activation according to claim 1, wherein all the surfaces of the shielding concrete on the indoor side are covered with the low activation concrete.
The invention according to claim 3 is the shielding concrete in consideration of activation according to claim 1 or 2, wherein the thickness of the low activation concrete is 25 to 50% of the total thickness of the concrete. Is.

The invention according to claim 4 is a method for constructing a shielding concrete that shields radiation and considers the activation of concrete, and uses a mold made of low activation concrete to form a ceiling part and a wall part. Either one or both of the shielding concrete is placed, and the indoor side surface of the shielding concrete is covered with the low activation concrete.
According to a fifth aspect of the present invention, there is provided the shielding concrete construction method considering the activation according to the fourth aspect, wherein the low-activation concrete is placed on the floor surface made of the shielding concrete, and the shielding concrete chamber is provided. It is characterized by covering the inner surface.
The invention according to claim 6 is a method for constructing shielding concrete that shields radiation and takes into account the activation of concrete, and includes a precast member made of low activation concrete, a ceiling, a wall, and a floor portion made of shielding concrete. And the entire interior side of the shielding concrete is covered with low activation concrete.

According to the present invention, when constructing a structure using concrete that shields radiation, the shielding concrete of the ceiling portion and the wall portion is cast using the low-activation concrete formwork or the precast member as the formwork. By covering the indoor surface of the concrete that shields radiation with low-activation concrete, radiation of the concrete can be suppressed, so that radiation can be shielded and the radiation released into the room Can be greatly reduced.
Further, since the floor surface made of shielding concrete is covered with the precast member of the low activation concrete and the low activation concrete, all surfaces on the indoor side of the shielding concrete can be easily covered with the low activation concrete. .

Hereinafter, the best mode of the present invention will be described.
FIG. 1 is a schematic view showing a part of a medical facility provided with shielding concrete considering activation according to the best mode of the present invention. In FIG. 1, 10 is a radiation treatment in which a radiation source 11 is installed. Rooms 21 and 22 are adjacent rooms, and 31 to 33 are rooms on the upper floor. The walls 12 and 13 and the ceiling 14 and the floor 15 around the radiation treatment room 10 are constructed of shielding concrete that is thicker than other rooms. In this example, the above shielding concrete is made of ordinary Portland cement made of limestone, clay, iron oxide, etc., as well as ordinary reinforced concrete, from water, river sand, sea sand, mountain sand, crushed stone, crushed sand, etc. While constructing using the concrete composition which knead | mixed the obtained aggregate, the indoor side surface of the said radiation treatment room 10 is coat | covered with the low activation layer 16 which consists of low activation concrete.
This low-activation concrete usually replaces concrete cement mainly composed of cement, water, and aggregate with limestone powder with a low content of elements activated by neutrons, etc. In this way, it is possible to reduce the radiation of the walls 12, 13 and the ceiling 14, and the floor 15 around the radiotherapy room 10. That is, the total amount of Na in the cement is about 650 g / m ³ , depending on the type of cement, whereas the total amount of Na in the limestone powder is about 70 g / m ³ . Therefore, for example, if about 35% of the cement is replaced with limestone powder by weight, the total amount of Na can be reduced by about 30%, so that the radiation of concrete can be reduced. In addition, since aggregates of granite and andesite have a large total amount of Na, these aggregates can be replaced with low activation materials such as boron (B), Fe, Ti, Pb, or CaCO _3. By doing so, it is possible to further reduce the radiation of the concrete.

By the way, when the radiation source 11 is operated, since the shielding member 11k such as lead is usually installed around the radiation source 11, particularly in the radiation direction, the walls 12, 13 and the ceiling made of shielding concrete are installed. 14, the primary radiation with high energy is hardly directly incident on the floor 15, and the radiation that is scattered and enters the walls 12, 13 and the ceiling 14, the floor 15 has a small energy. Even if the element that becomes the parent nuclides of radioisotopes such as Na, Mg, Al, Si, Co, and Eu is contained in the shielding concrete, it is attenuated by the low activation concrete when it penetrates to a certain depth, The element that is the generated parent nuclides cannot be changed to a radioisotope.
Particularly in medical facilities, since the energy of radiation itself is often small, generally, the sum of the thickness of the shielding concrete and the thickness of the low activation concrete constituting the walls 12, 13 and the ceiling 14, and the floor 15 is L = 150-180 cm. In this example, in order to reduce the radiation inside the radiation treatment room 10 with the minimum activation layer 16 having the minimum thickness, as shown in FIG. 2, the low activation layer made of low activation concrete is used. The thickness χ of 16 was set to be (χ / L) = 0.25 to 0.5 (37.5 to 90 cm). As a result, the space in the radiation therapy room 10 can be used effectively, and the entire shielding concrete does not need to be made into expensive low-activation concrete. Can be implemented efficiently.

Next, the construction method of the radiation treatment room 10 in which the low activation layer 16 made of the above low activation concrete is disposed on the surface will be described. For the walls 12 and 13 and the ceiling 14, as shown in FIG. 3, a low activation concrete composition is used, for example, by using a casting mold 17 having a thickness of about 5 cm formed by an extrusion molding method. By placing concrete of 12, 13 and the ceiling 14, the indoor side of the shielding concrete is reduced in radiation. At this time, the placing molds 18 and 18 used on the adjacent chambers 21 and 22 side may be ordinary concrete.
Further, as shown in FIG. 4, the floor 15 is casted with shielding concrete, and after the shielding steel plate 19 is placed thereon, the reduced activation concrete is placed to construct the reduced activation layer 16. The shielding steel plate 19 may be omitted. Thereby, all the surfaces of the inside of the radiation treatment room 10 can be covered with the low activation layer 16 made of low activation concrete.
Alternatively, a precast member may be manufactured using the low activation concrete composition, and the precast member may be attached to the walls 12 and 13, the ceiling 14, and the floor 15. At this time, it is preferable that the joint portion between the shielding concrete and the precast member is filled with a sealing material made of a low activation material.

Thus, according to the present embodiment, the thickness of the entire shielding concrete is reduced to 0 on the walls 12 and 13 and the ceiling 14 and the floor 15 around the radiation treatment room 10 where the radiation source 11 is installed. Since the low activation layer 16 made of low activation concrete having a thickness of about 25 to 0.5 times is provided so as to reduce the overall radiation inside the radiation treatment room 10, it is inexpensive. Efficient measures to reduce radiation can be implemented.
At this time, for the walls 12 and 13 and the ceiling 14, the concrete of the walls 12 and 13 and the ceiling 14 is placed using a casting mold 17 made of low-radiation concrete, and the indoor side of the shielding concrete is reduced to a low radiation. If the floor 15 is casted with shielding concrete and then placed with low activation concrete, the entire surface inside the radiation therapy room 10 can be easily reduced with low radiation concrete. The coating layer 16 can be covered.

In the above embodiment, the radiation reduction of the shielding concrete in the medical facility has been described. However, the thickness of the radiation reducing layer is also reduced in the radiation reduction of the shielding concrete of the facility having a large radiation energy such as an accelerator facility. If designed so that (χ / L) = 0.25 to 0.5, the shielding concrete can be sufficiently reduced in radiation. For example, the shielding concrete around the beam target of the accelerator facility is 200 to 300 cm. In this case, the thickness of the low activation layer may be set to 100 to 150 cm.
Moreover, in the said example, although what substituted a part of cement for the limestone powder was used as low activation concrete, you may use the low activation concrete containing a cement with little Na total amount.

  As described above, according to the present invention, it is possible to reduce the activation of the shielding concrete structure with a simple configuration and at a low cost. It is possible to easily reduce the radiation of the shielding concrete structure of the building that handles radiation, and to construct the shielding concrete considering the activation at low cost.

It is a schematic diagram which shows a part of medical facility provided with the shielding concrete in consideration of the activation which concerns on the best form of this invention. It is a figure which shows the range which should consider the activation of shielding concrete. It is a figure which shows the low radiationization method of shielding concrete. It is a figure which shows the low radiationization method of shielding concrete.

Explanation of symbols

10 radiation therapy room, 11 radiation source, 11k shielding member, 12, 13 wall,
14 Ceiling, 15 floors, 16 Low activation layer made of low activation concrete,
17 Punching formwork made of low activation concrete, 18 Punching formwork,
19 Shielded steel plate, 21, 22 Adjacent room, 31-33 Room on the upper floor.

Claims (6)

  Radiation-resistant shielding concrete, characterized by covering the indoor surface of shielding concrete that shields radiation with low-activation concrete.   2. The shielding concrete considering radiation according to claim 1, wherein all surfaces on the indoor side of the shielding concrete are covered with low activation concrete.   3. The shielding concrete considering radiation according to claim 1, wherein the thickness of the low activation concrete is set to 25 to 50% of the total thickness of the concrete.   When constructing shielding concrete that shields radiation, the shielding concrete of either one or both of the ceiling part and the wall part is placed using a mold made of low activation concrete, and the interior side of the shielding concrete A method for constructing shielding concrete considering radiation, characterized in that the surface is covered with low activation concrete.   5. Construction of shielding concrete considering radiation according to claim 4, characterized in that low activation concrete is placed on the floor surface made of shielding concrete to cover the indoor surface of said shielding concrete. Method.   A method for constructing shielding concrete for shielding radiation, wherein a precast member made of low activation concrete is attached to a ceiling, a wall and a floor portion made of shielding concrete, and the entire interior side of the shielding concrete is reduced to low activation concrete. A method for constructing shielding concrete considering radiation, characterized in that it is covered with a metal.

Images