JP2014089127A - Radiation shield wall - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a radiation shield wall capable of being installed with ease and effectively shielding γ ray, neutron ray and other radiation rays according to the purpose.SOLUTION: The radiation shield wall is constructed with a pile of dry gypsum blocks formed with radiation shield material composition including water and gypsum. The gypsum is favorably α gypsum, and when viewing the wall from the front, a mating face of the dry gypsum blocks is favorably not a straight surface from a front side to a reverse side of the wall.

Description

  The present invention relates to a radiation shielding wall.

In recent years, various types of radiation therapy have been carried out in the medical field. In order to prevent radiation irradiated to the affected area of a patient from diffusing or penetrating the human body and leaking from the treatment facility, Treatment facilities are partitioned by thick concrete walls, and in some cases, radiation is shielded by combining concrete walls with metal plates such as iron and lead. For this reason, when exchanging equipment for radiation therapy, when the concrete wall is demolished and the equipment is exchanged, construction work for constructing the concrete wall again is necessary, and the demolished wall material is contaminated with radiation. However, there is a problem that it takes time to dispose of it.
Also, if an accident or the like occurs at a nuclear power plant or radiotherapy device, and radiation leaks out, it is difficult to enter the area partitioned by the concrete wall, so it can be constructed by a simple method, There is a need for means for effectively shielding the intended radiation.

Among radiation, γ-rays can be shielded to some extent by iron and lead plates. However, neutrons are difficult to shield effectively because their behavior changes depending on the amount of energy. Is currently required.
Lead plates that can effectively shield γ-rays are expensive and difficult to handle and dispose of, so in order to effectively shield γ-rays at low cost without using lead plates, There has been proposed a radiation shielding wall sandwiched between gypsum board plates containing barium sulfate (see, for example, Patent Document 1).
Further, as a material for shielding neutron rays, a shielding material comprising borate aggregate containing crystal water in calcium aluminate cement or hemihydrate gypsum has been proposed (for example, see Patent Document 2). .
Furthermore, a shielding wall is proposed in which a block having a frame body is supported by the frame body and a column instead of a fixed wall (see, for example, Patent Document 3).

JP 2010-32270 A Japanese Patent Publication No.58-6704 JP 2011-169883 A

The shielding wall described in Patent Document 1 requires an iron plate having a required thickness, so that there are limitations on the installation location, and there is a problem that it is not effective for shielding neutron beams. Moreover, since the shielding material described in Patent Document 2 is inferior in water resistance as described in the document, and the material is acidic, the supporting material is likely to cause a decrease in strength under acidic conditions such as reinforcing bars. There was a problem that it was difficult to use for the use which has.
Although the thickness and height of the shielding material described in Patent Document 3 are appropriately adjusted and can be easily constructed, there is a region that is difficult to shield radiation, such as a frame and a support, and thus sufficient shielding properties can be obtained. However, there is a problem that there are restrictions on the installation location and the intended radiation shielding direction.

  The present invention has been made in consideration of these problems, and an object of the present invention is radiation that can be easily installed and can effectively shield radiation according to the purpose, such as γ-rays and neutron beams. It is an object to provide a shielding wall.

As a result of intensive studies in view of the above problems, the present inventors have found that the above problems can be solved by using a dry gypsum block having a high water content and a light weight, and completed the present invention.
That is, the present invention has the following configuration.
<1> A radiation shielding wall constructed by stacking dry gypsum blocks formed of a radiation shielding material composition containing water and gypsum.
Since the radiation shielding wall of the present embodiment is constructed by stacking dry gypsum blocks, it is easy to construct, dismantle, relocate and change compared to a concrete radiation shielding wall. In addition, since gypsum contains almost no activation element, it is difficult to activate even when radiation arrives, so the generation of radioactive contaminated waste is reduced compared to the conventional method, and dry gypsum blocks that have not been activated are regenerated. It also has the advantage that it can be used.
Furthermore, when constructing a radiation shielding wall with gypsum board, a frame that supports the gypsum board is required, and this frame may be activated, but radiation shielding walls constructed by stacking dry gypsum blocks are Since the walls can be constructed without the need for, the choice of shielding purpose and construction location becomes wider by stacking according to the purpose.

<2> The radiation shielding wall according to <1>, wherein the gypsum is α gypsum.
By using α gypsum to form dry gypsum block, compared with general-purpose β gypsum, the moisture content and density are higher, so the shielding ability is improved, and the formed dry gypsum block is more activated. It will be difficult.

<3> The radiation shielding wall according to <1> or <2>, wherein when the wall is viewed from the front, the mating surface of the dry-type gypsum block is not a straight surface extending from the wall surface to the back surface.
According to this embodiment, it is possible to effectively prevent radiation (particularly neutrons) having rectilinearity from penetrating the mating surface of the dry gypsum block and leaking to the back side of the radiation shielding wall. Examples of the shape of the block whose mating surface is not a straight surface include a rhombus, a butterfly shape, and an arrow shape as the longitudinal cross-sectional shape of the block.
<4> A plurality of dry gypsum blocks are stacked in the thickness direction of the wall, and the surface of the dry gypsum block is located on the back side of the end face of the dry gypsum block on the surface side of the wall, <1> to <3> The radiation shielding wall according to any one of the above.
According to this embodiment, the radiation that goes straight along the end face of the dry gypsum block and enters the mating surface of the dry gypsum block in the radiation shielding wall is shielded by the end face of the dry gypsum block on the back surface, and the back side of the shielding wall It is possible to suppress the penetration to, and to obtain a higher radiation shielding effect.

<5> The radiation shielding material composition further contains at least one element selected from the group consisting of boron, boron compounds, gadolinium, cadmium, and lithium, or an isotope thereof, <1> to <4>. The radiation shielding wall according to any one of the above.
The dry gypsum block formed using the composition by adding a boron-based compound or the like to the radiation shielding material composition mainly composed of gypsum and water has a more effective neutron shielding effect. improves.
<6> The radiation shielding material composition is further selected from the group consisting of lead, tungsten, bismuth, iron, iron oxide, iron ore, magnetite, hematite, barite, barium, and a barium compound. The radiation shielding wall according to any one of <1> to <4>, which contains seed particles.
The dry gypsum block formed using the composition by adding lead or barium-based compounds to the radiation shielding composition containing gypsum and water as main components is particularly effective in shielding gamma rays. Will be improved.

Below, the preferable aspect of this invention is shown.
<A> A dry gypsum block comprising a radiation shielding agent composition containing gypsum and water is a dry gypsum block (a), and is selected from the group consisting of gypsum, water, boron, boron compounds, gadolinium, cadmium, and lithium. A dry gypsum block comprising a radiation shielding material composition containing at least one element or an isotope thereof is a dry gypsum block (b), and gypsum, water, lead, tungsten, bismuth, iron, iron oxide, iron ore, magnetite A dry gypsum block (c) comprising a radiation shielding material composition comprising at least one kind of particles selected from the group consisting of hematite, barite, barium, and barium compounds; A plurality of at least one selected from (a), dry gypsum block (b) and dry gypsum block (c) are arranged in the wall thickness direction. The radiation shielding wall according to any one of <4> to <6>, which is formed.
According to this embodiment, by changing the method of stacking dry gypsum blocks using various additives, as shown in the following aspects <B> to <E>, the optimum radiation for each radiation to be shielded A shielding wall can be easily constructed.
<B> The radiation shielding wall according to <A>, wherein a plurality of the dry gypsum blocks (a) are stacked in the thickness direction of the wall to shield neutron beams.
By stacking a plurality of dry gypsum blocks having a high water content in the thickness direction of the wall, a higher shielding effect of neutron beams can be obtained.
<C> The dry gypsum block (a) is disposed on the radiation incident side of the radiation shielding wall, and at least one of the dry gypsum block (b) and the dry gypsum block (c) is disposed on the back surface thereof, The radiation shielding wall according to <A>, which shields neutron beams.
Placing a dry gypsum block that is difficult to be activated on the radiation-emitting side and placing a dry gypsum block containing boron compounds and barium compounds on the back side of the block increases the neutron beam shielding effect and increases gamma rays. A shielding wall that can be shielded with higher efficiency is formed.

<D> The radiation according to <A>, wherein the dry gypsum block (b) is disposed on the radiation incident side of the radiation shielding wall, and the dry gypsum block (c) is disposed on the back surface thereof to shield neutron beams. Shielding wall.
By placing a dry gypsum block containing a boron compound and a dry gypsum block containing a metal compound such as a barium compound in combination, a higher radiation shielding effect can be obtained, especially for neutron beams and high-energy elementary particles. A radiation shielding wall more suitable for shielding can be constructed.
<E> The radiation shielding wall according to <A>, wherein a plurality of the dry gypsum blocks (c) are stacked in the thickness direction of the wall to shield γ rays.
By arranging a combination of a plurality of dry gypsum blocks containing a metal compound such as a barium compound, a higher shielding effect against γ rays can be obtained.

  ADVANTAGE OF THE INVENTION According to this invention, the radiation shielding wall which can be installed easily and can shield effectively the radiation according to the objectives, such as a gamma ray and a neutron beam, can be provided.

(A) is a perspective view which shows the one aspect | mode of the dry-type gypsum block based on this invention, FIG. (B) is the side view. (A) is a perspective view which shows the one aspect | mode of the radiation shielding wall of this invention formed by laminating | stacking the dry-type gypsum block shown in FIG. 1, (B) is the side view. (A) is a perspective view which shows the one aspect | mode of the radiation shielding wall of this invention formed by laminating | stacking a plurality of rectangular parallelepiped dry type gypsum blocks, (B) is the side view. (A) is a perspective view showing an embodiment of the radiation shielding wall of the present invention in which a plurality of dry gypsum blocks showing a shape in which the side mating surface is not a straight surface extending from the front surface to the back surface of the wall, (B) is a side view thereof. (A) is a perspective view which shows the one aspect | mode of the radiation shielding wall of this invention in which the dry gypsum block which shows the aspect whose upper and lower mating surfaces are not a linear surface is piled up, (B) is the side view. . (A)-(D) It is a model figure which shows how to dry dry gypsum block (a)-dry gypsum block (c) in the radiation shielding wall which shields the radiation according to the objective. (A)-(C) It is a model figure which shows how to dry dry gypsum block (a)-dry type gypsum block (c) in the radiation shielding wall supposing reuse of the gypsum block after use.

Hereinafter, the present invention will be described in detail.
The radiation shielding wall of the present invention is a shielding wall constructed by stacking dry gypsum blocks formed of a radiation shielding material composition containing water and gypsum.
[Dry gypsum block]
The dry gypsum block used for the radiation shielding wall of the present invention (hereinafter referred to as “shielding wall” as appropriate) is a radiation shielding material composition containing water and gypsum. Preferably, when the wall is viewed from the front, the mating surface of the dry gypsum blocks has a shape that is not a straight surface from the wall surface to the back surface.
In the present specification, the surface of the shielding wall 10 on which radiation is incident may be referred to as the “front surface” of the shielding wall, and the surface opposite to the surface on which radiation is incident may be referred to as “back surface”.
1A is a perspective view and a side view showing an embodiment of a gypsum block 12 used in the radiation shielding wall 10 of the present invention, and FIG. 1B is a plan view of the gypsum block 12 shown in FIG. It is a side view and the side view which shows the deformed gypsum block 14 of 1/2 size used for the end surface of the shielding wall 10 used in combination with the gypsum block 12.
The plaster block 12 shown in FIG. 1 (A) is used for shielding radiation from the direction of the arrow described in the side view, and the upper and lower surfaces of the plaster block 12 do not have straight surfaces. In the shielding wall 10 constructed by stacking 12 and 14, radiation does not penetrate through joint portions (joint portions) on the upper and lower surfaces.

2A is a perspective view of the shielding wall 10 constructed by stacking the gypsum blocks 12 and 14 shown in FIGS. 1A and 1B, and FIG. 2B is a side view of the shielding wall 10. FIG.
As shown in FIG. 2 (B), as is apparent from the side view, the upper and lower joint surfaces of the gypsum blocks 12 and 14 have a mode in which radiation does not penetrate at the joints, which is shown in FIG. 2 (A). As described above, when a plurality of dry gypsum blocks are stacked in the thickness direction of the wall, the surface of the dry gypsum block 12 in the second row is located on the back side of the end face of the dry gypsum block 12 on the surface side of the wall. By arrange | positioning so that the penetration of the radiation from the joint of the side surface of the gypsum block 12 can be prevented.

The shape of the dry gypsum block is not limited to that shown in FIGS. 1 to 2 and can be various shapes. Below, the radiation shielding wall constructed | assembled using the modified example of the dry-type gypsum block based on this invention is given and demonstrated with drawing.
For example, as in the embodiment shown in FIG. 3, the dry gypsum block 22 may have a rectangular parallelepiped shape. FIG. 3A is a perspective view showing an embodiment of the radiation shielding wall 20 of the present invention in which a plurality of rectangular parallelepiped dry gypsum blocks 22 are stacked, and FIG. 3B is a side view thereof. According to this embodiment, the upper and lower surfaces and side surfaces of the gypsum block 22 are straight surfaces from the front surface to the back surface of the dry gypsum block when the wall is viewed from the front. When a plurality of rows are stacked in the thickness direction of the wall, the surface of the dry gypsum block 22 is positioned on the back surface side of the dry gypsum block 22 on the surface side of the wall and the back surface side of the top and bottom surfaces as shown in FIG. By stacking in such a manner, penetration of radiation at the joint (joint) portion in the obtained shielding wall 20 is prevented.

  FIG. 4A is a perspective view showing an embodiment of the radiation shielding wall 30 of the present invention in which a plurality of dry gypsum blocks 32 having a shape whose side end surface is not a straight surface extending from the wall surface to the back surface are stacked. It is a figure and (B) is the perspective view. In the embodiment shown in FIG. 4, when the wall is viewed from the front, the mating surface of the dry gypsum block 32 is not a straight surface from the wall surface to the back surface, and the upper and lower mating surfaces are from the wall surface. It becomes a straight surface over the back surface. In the gypsum block 32 having such a shape, radiation is not penetrated at the joint at the joint surfaces on both sides, and when multiple rows are stacked in the thickness direction of the wall, as shown in FIG. By stacking the dry gypsum block 32 so that the surface of the dry gypsum block 32 is positioned on the back surfaces of the top and bottom surfaces of the dry gypsum block 32 on the surface side of the shielding wall 30, it is possible to prevent penetration of radiation at the upper and lower joints.

FIG. 5 (A) is a perspective view showing an embodiment of the radiation shielding wall 40 of the present invention in which a plurality of dry gypsum blocks 42 showing an embodiment in which the upper and lower mating surfaces are not straight surfaces are stacked. Is a perspective view thereof. In the embodiment shown in FIG. 5, when the wall is viewed from the front, the mating surfaces of the upper and lower surfaces of the dry-type gypsum block 42 are not straight surfaces from the wall surface to the back surface, and the side mating surfaces are the wall surfaces. A straight surface extends from the front surface to the back surface. In the gypsum block 42 having such a shape, radiation is not penetrated at the joint at the upper and lower surfaces. When a plurality of rows are stacked in the thickness direction of the wall, the dry gypsum block 42 on the side end surface of the wall By stacking so that the surface of the dry-type gypsum block 42 is positioned on the back surface, it is possible to prevent radiation penetration at the joints in the shielding wall 40.
The dry gypsum block 42 used in FIG. 5 (A) can also be stacked so that the surface shown in the side view of FIG. 5 (B) is the top and bottom surfaces. The upper and lower mating surfaces are not linear surfaces extending from the surface of the wall to the back surface, but are linear surfaces extending from the surface of the wall to the back surface. When stacking in this direction, when multiple rows are stacked in the thickness direction of the wall, the dry gypsum block 42 is stacked so that the surface of the dry gypsum block 42 is positioned on the back surface of the top and bottom surfaces of the dry gypsum block 42. Can be prevented.

  Thus, the dry gypsum block can take various shapes depending on the purpose without departing from the gist of the present invention. For example, when at least one of the upper and lower surfaces and the side surface of the gypsum block is viewed from the front, the mating surface of the dry-type gypsum block is not a straight surface from the wall surface to the back surface. In a portion having a non-exposed surface, penetration of radiation at the mating surface (joint) can be suppressed even with one row. For this reason, the second and subsequent rows may be stacked in the same manner. In addition, when either the upper or lower surface and the side surface of the gypsum block, or both, when the wall is viewed from the front, the mating surface of the dry-type gypsum block is a straight surface from the wall surface to the back surface, As shown in FIG. 3A, by selecting the second and subsequent rows, radiation penetration at the joint is suppressed.

[Radiation shielding material composition]
The radiation shielding material composition constituting the dry gypsum block 12 includes at least water and gypsum.
That is, it is effective to shield radiation, particularly neutron rays that are difficult to shield, by energy absorption by elastic scattering. Therefore, it is preferable to use a material having a high hydrogen density. It is a selection. Although general-purpose concrete also has a high moisture content, the moldability and curing speed are inferior to those of the composition mainly composed of gypsum according to the present invention, and the weight of the obtained block is larger in the same shape. In the present invention, a composition containing gypsum as a main ingredient is used because it is difficult to construct and move.
The gypsum used for the radiation shielding material composition can be arbitrarily selected and used as long as it is a known gypsum material containing calcium sulfate and can be rapidly cured including water. The type of gypsum is described in detail in “Gypsum Lime Handbook, Technical Report (published in 1972)”, and any curable gypsum described here can be used.
As a kind of gypsum, hemihydrate gypsum (CaSO ₄ · 1 / 2H ₂ O: trigonal crystal) that hardens with water can be preferably used. Hemihydrate gypsum is generally classified into α-type hemihydrate gypsum (α gypsum) and β-type hemihydrate gypsum (β gypsum) depending on the crystal system, and both can be used. Among these, α-gypsum is preferable in that it has a large specific gravity, cures quickly, and has a higher density and compressive strength of the cured product. On the other hand, β-gypsum has a standard mixed water amount of 90%, which is higher than 35% of α-gypsum, so that it is a gypsum block having a high neutron beam shielding effect when used in places where strength is not required. I can expect that. Examples of the location that does not require strength include a wall existing on the upper portion of the radiation shielding wall that is relatively free of load, and is preferably used for such a location.

The radiation shielding material composition contains at least gypsum and water, but the content ratio of gypsum and water in the composition is in the range of 20 to 40 parts by mass of water with respect to 100 parts by mass of gypsum. It is preferable.
Moreover, in the radiation shielding material composition according to the present invention, an additive such as a surfactant for improving fluidity may be used in combination as necessary within the range not impairing the effects of the present invention.

In the radiation shielding material composition according to the present invention, in addition to gypsum, it is also a preferable aspect to use a component having radiation shielding ability as described below for the purpose of further improving the radiation shielding properties against various radiations.
The radiation shielding material composition further comprises an element selected from the group consisting of boron, boron compounds, gadolinium, cadmium, and lithium, or an element having a large thermal neutron absorption cross section of at least one of its isotopes. The shielding efficiency of the neutron beam of the obtained gypsum block, in particular, the neutron beam having energy equal to or lower than the thermal neutron can be further improved. Examples of isotopes include ¹¹ B and ¹⁰ B in the case of boron. Here, the element with a large thermal neutron absorption cross section is the elastic scattering of hydrogen as described in “Engineering of Radiation Physics and Accelerator Safety 2nd Edition” (by Shoji Nakamura) Jijinshokan, page 155, Fig. 3.45. It has a cross-sectional area larger than H (n, n) H. Typically, ¹⁰ B, ⁶ Li, Cd, Gd, and the like can be given.
Of these, boron or its isotopes, or boron compounds selected from colemanite, boric acid, boric anhydride, B ₄ C, and the like are preferable because of their high effects and easy availability.
For neutrons with energy higher than thermal neutrons (for example, fast neutrons), energy absorption by elastic scattering is more effective, so materials with high hydrogen density such as polyethylene, paraffin, concrete, etc. are added. It is preferable. Any of these may be added to the radiation shielding material composition as a fluid state, for example, as a liquid component having a high viscosity, as long as it is cured after addition, and as a solid content such as particles, aggregates, gels, etc. You may add to a radiation shielding material composition.
Since the gypsum used in the present invention has a high water content as described above, it is suitable as a neutron shielding material by elastic scattering. Moreover, it is also preferable from the viewpoint of the neutron beam shielding effect to add “heavy water” having a higher hydrogen density instead of or in addition to water in the radiation shielding material composition.
Each compound used for improving the neutron beam shielding effect may be used alone or in combination of two or more.
The addition amount of the compound is preferably in the range of 150 parts by mass to 10 parts by mass with respect to 100 parts by mass of gypsum, and more preferably in the range of 100 parts by mass to 25 parts by mass.

The radiation shielding material composition further comprises at least one particle selected from the group consisting of lead, tungsten, bismuth, iron, iron oxide, iron ore, magnetite, hematite, barite, barium, and a barium compound. By containing γ, it is possible to improve the shielding hardening of γ rays. That is, since γ rays are effectively shielded by a material having a high density, it is also a preferred embodiment to contain metal particles as described above. Among these, barium compounds such as barium and barium sulfate are preferred from the viewpoint of high shielding effectiveness, easy availability, and excellent handling properties.
Each particle used for improving the gamma ray shielding effect may be used alone or in combination of two or more.
The addition amount of the particles is preferably in the range of 400 parts by mass to 40 parts by mass with respect to 100 parts by mass of gypsum, and more preferably in the range of 250 parts by mass to 100 parts by mass.

In order to form the gypsum block, the radiation shielding material composition may be put into a predetermined mold and dried, and considering the fluidity, the solid content concentration of the radiation shielding material composition is 10% by mass to 60%. A mass% range is preferred from the viewpoint of handling properties.
The resulting gypsum block is coated with a water repellent or water-resistant paint on the surface to improve water resistance, or with a potassium soap or carboxylate aqueous solution that hardens by reacting with calcium, or a water-soluble acrylic paint. May be added in the range of 5% by mass to 10% by mass of gypsum.

(Radiation shielding wall)
The radiation shielding wall 10 is formed by stacking the gypsum blocks 12 obtained above.
As shown in FIG. 2 (A), when building a shielding wall by stacking the gypsum blocks 12 and 14, the gypsum blocks 12 are sequentially stacked in the height direction until the required height is reached, and the width direction is also set. The shielding wall 10 having a predetermined area is formed by stacking in parallel until the required width is reached. Further, in order to achieve a necessary shielding rate, a plurality of rows of gypsum blocks 12 and 14 are stacked in the same manner as the stacked gypsum blocks located on the outermost surface from the radiation incident direction. The thickness can be increased, and the region that can be used for radiation shielding is adjusted. At this time, as shown in the perspective view of FIG. 2A, in the case where the plurality of rows of gypsum blocks 12 and 14 are stacked in the thickness direction of the wall to increase the thickness of the shielding wall 10, the dry type on the surface side of the wall is performed. By arranging the gypsum block 12 so that the surface of the gypsum block 12 in the second row is positioned on the back surface side of the side end surface of the gypsum block 12, penetration of radiation from the joints on the side surfaces of the gypsum block 12 can be prevented.
In the present invention, since the radiation shielding wall 10 is formed by stacking the gypsum blocks, the shielding wall can be easily constructed at an arbitrary area and in an arbitrary area. Moreover, it can also be moved simply as needed.
When the shielding wall 10 is fixed at a predetermined place, as shown in the side view of FIG. 2B, a fixing agent 16 is provided between the lowermost surfaces of the gypsum blocks 12 and 14 and a substrate such as a floor. It may be fixed. Examples of the fixing agent include gypsum and mortar, and gypsum is preferable because it can be used easily, has a high curing rate, and has excellent radiation shielding ability.

By changing the type of gypsum block 12 used for the construction of the radiation shielding wall 10, in other words, the type and stacking method of the radiation shielding material composition constituting the gypsum block 12, 14, the type of radiation to be shielded The shielding wall 10 optimal for the target shielding rate is easily formed. Hereinafter, the detailed aspect is demonstrated.
For the convenience of explaining how to stack the gypsum block 12, a gypsum block formed of a radiation shielding material composition containing gypsum and water is hereinafter referred to as gypsum block (a), water, gypsum and boron, boron compound, gadolinium, cadmium, And a gypsum block formed of a radiation shielding material composition containing at least one element selected from the group consisting of lithium and an isotope thereof (specifically, in the embodiment shown below, colemanite). Block (b), at least one particle selected from the group consisting of water, gypsum, lead, tungsten, bismuth, iron, iron oxide, iron ore, magnetite, hematite, barite, barium, and barium compounds ( In the embodiment described below, specifically, a gypsum block formed of a radiation shielding material composition containing barium sulfate) Click referred to as (c).
As described above, since the gypsum block (a) has a high water content, it is effective in shielding neutrons, particularly neutrons with energy higher than thermal neutrons (for example, fast neutrons). As shown in the model diagram, the shielding wall 16 configured by stacking only a plurality of gypsum blocks (a) [denoted as (a) in FIG. 6] is effective for shielding gamma rays. More suitable for shielding.
Also, the gypsum block (b) [denoted as (b) in FIG. 6] contains an element having a large thermal neutron absorption cross section as described above, and therefore, a neutron beam, particularly a neutron beam having energy equal to or lower than thermal neutrons. As shown in FIG. 6 (B), the gypsum block (a) is stacked on the radiation incident surface, and the gypsum block (b) is stacked on the back surface thereof, thereby improving the neutron beam shielding ability. It can be a raised shielding wall.
Since the gypsum block (c) [denoted as (c) in FIG. 6] contains high-density particles, it is effective in shielding gamma rays. Further, the gypsum block (c) is stacked to shield gamma rays. It is possible to provide a shielding wall with higher performance.
As another mode effective for shielding the neutron beam, as shown in FIG. 6 (C), there is a mode in which a gypsum block (a) is stacked on the radiation incident surface and a gypsum block (b) is stacked on the back surface. Can do.
When gamma rays are mainly shielded, as shown in FIG. 6D, it is possible to take a form in which a plurality of gypsum blocks (c) are stacked.

  Furthermore, as shown in FIG. 7 (A), when a plurality of rows of gypsum blocks (a) are stacked on the surface side, and a gypsum block (b) and a gypsum block (c) are stacked behind it to form a shielding wall, For example, when the gypsum blocks (a) in the row where the surface radiation is most exposed are activated (FIG. 7A), only the gypsum blocks (a) stacked in the outermost row are removed [FIG. (B)] By stacking a new gypsum block (a) [FIG. 7C], a shielding wall having the same function as the original construction can be formed, and it is not necessary to replace all gypsum blocks. The amount of waste contaminated with radiation can be reduced.

Hereinafter, the present invention will be specifically described by way of examples. However, the present invention is not limited to these examples, and design modifications that are usually performed by those skilled in the art within a range not departing from the technical idea thereof. Needless to say, this includes a range of application variations.
(Examples 1-1 to 1-6)
(Preparation of radiation shielding material composition 1)
Each component described in the following prescription 1 was put into a container and sufficiently stirred and mixed at room temperature (25 ° C.) to obtain a radiation shielding material composition 1.
(Prescription 1)
・ Α gypsum 100 parts by mass ・ Water (tap water) 30 parts by mass

(Molding dry gypsum block)
The obtained radiation shielding material composition 1 is put into a form having the shape shown in FIG. 1A and having a thickness of 6 cm in the passage direction of radiation, and dried at room temperature (25 ° C.) for about 1 hour. After curing, the mold was removed to obtain a gypsum block (a) used in Example 1.
The thinner gypsum block (a-2) was obtained by processing the gypsum block (a) to a thickness of 3 cm.

(Radiation shielding wall)
The obtained gypsum block (a) was stacked in a row in the radiation incident direction to form the radiation shielding wall of Example 1-1.
Similarly, the surface of the dry gypsum block on the surface side of the wall is positioned on the back side of the end face of the dry gypsum block, positioned so that the side seams do not match, and stacked in two rows in Example 1-2. A radiation shielding wall was formed.
Similarly, the surface of the dry gypsum block on the front surface side of the wall is positioned on the back surface side of the dry gypsum block, and three rows are stacked so that the side seams do not coincide with each other. Formed.
Moreover, the obtained gypsum block (a-2) was piled up in a line in the radiation incident direction to form a radiation shielding wall of Example 1-4.
Similarly, the surface of the dry gypsum block on the surface side of the wall is positioned on the back side of the end face of the dry gypsum block, and the positions of the side seams do not coincide with each other, and three rows are stacked, and the embodiment 1-5 A radiation shielding wall was formed.
Similarly, the surface of the dry gypsum block on the front side of the wall is positioned on the back side of the dry gypsum block, and six rows are stacked so that the side seams do not coincide with each other. Formed.

(Evaluation of radiation shielding wall)
For the radiation shielding walls of Example 1-1 to Example 1-3, the radiation source is γ-ray, Co-60: “Cobalt-60” (10 MBq) and Cs-137: “Cesium-137” ( A shielding experiment was carried out at 10 MBq). Further, shielding experiments were conducted on the radiation shielding walls of Examples 1-4 to 1-6 using Cf-252: “Californium-252” (3.7 MBq) as a neutron beam as a radiation source. . The results are shown in Tables 1 and 2 below.

  As shown in Table 1, the gypsum block (a) achieved a γ-ray shielding rate of 23% to 28% even in the shielding wall of one row of blocks, and was formed by stacking three rows of gypsum blocks (a). According to the radiation shielding wall, it was confirmed that a shielding rate exceeding 70% was achieved for γ rays at a thickness of 18 cm. This shielding rate is a high shielding rate exceeding 20 mm lead equivalent in gamma rays. In addition, as shown in Table 2, the gypsum block (a-2) achieved a neutron beam shielding rate of 20% even in the shielding wall of one row of blocks, and the gypsum blocks (a-2) were stacked in six rows. According to the radiation shielding wall formed in (1), it was confirmed that a shielding rate exceeding 70% was achieved for neutron beams at a thickness of 18 cm. Therefore, it can be seen that the radiation shielding wall of each of the above embodiments can be constructed by a simple method and has excellent radiation shielding properties.

(Examples 2-1 to 2-6)
(Preparation of radiation shielding material composition 2)
Each component described in the following prescription 2 was put into a container, and a radiation shielding material composition 2 was obtained in the same manner as in Example 1-1.
(Prescription 2)
・ Α gypsum 100 parts by mass ・ Collemanite 100 parts by mass ・ Water (tap water) 35 parts by mass

(Molding dry gypsum block)
The obtained radiation shielding material composition 2 is put into a form having the shape shown in FIG. 1 (A) and having a thickness of 6 cm in the radiation passage direction, and dried at room temperature (25 ° C.) for about 1 hour. After curing, the mold was removed to obtain a gypsum block (b) used in Example 1.
A thinner gypsum block (b-2) was obtained by processing the gypsum block (b) to a thickness of 3 cm.

(Radiation shielding wall)
The obtained gypsum block (b) was stacked in a row in the radiation incident direction to form a radiation shielding wall of Example 2-1.
Similarly, the surface of the dry gypsum block (b) on the front surface side of the wall is positioned on the back surface side of the dry gypsum block, and the positions of the side gypsum blocks are determined so as not to coincide with each other. -2 radiation shielding wall was formed.
Similarly, the surface of the dry gypsum block (b) on the surface side of the wall is positioned on the back surface side of the dry gypsum block, and three rows are stacked so that the side seams do not coincide with each other. A radiation shielding wall was formed.
Moreover, the obtained gypsum block (b-2) was piled up in a line in the radiation incident direction to form a radiation shielding wall of Example 2-4.
Similarly, the surface of the dry gypsum block on the front side of the wall is positioned on the back side of the end face of the dry gypsum block, the positions are determined so that the side seams do not coincide with each other, and three rows are stacked. A radiation shielding wall was formed.
Similarly, the surface of the dry gypsum block on the front surface side of the wall is positioned on the back side of the dry gypsum block, and six rows are stacked so that the side seams do not coincide with each other. Formed.

(Evaluation of radiation shielding wall)
For the radiation shielding walls of Example 2-1 to Example 2-6, shielding experiments were performed in the same manner as in Example 1-1 to Example 1-6. The results are shown in Tables 3 to 4 below.

  As shown in Table 3, the gypsum block (b) achieved a radiation shielding rate of 24% to 28% even in the shielding wall of one row of blocks, and the radiation formed by stacking three rows of gypsum blocks (b). According to the shielding wall, it was confirmed that a shielding rate of about 65% was achieved for γ rays. As shown in Table 4, the gypsum block (b-2) achieves a neutron beam shielding rate of 22% even with one row of shielding walls, and is formed by stacking six rows of gypsum blocks (b-2). According to the radiation shielding wall, it was confirmed that a shielding rate of 77% was achieved for the neutron beam, and the gypsum block (b) has a particularly high neutron beam shielding effect.

(Examples 3-1 to 3-6)
(Preparation of radiation shielding material composition 3)
Each component described in the following prescription 3 was put into a container, and a radiation shielding material composition 3 was obtained in the same manner as in Example 1-1.
(Prescription 3)
・ Α gypsum 100 parts by mass ・ Barium sulfate 100 parts by mass ・ Water (tap water) 35 parts by mass

(Molding dry gypsum block)
The obtained radiation shielding material composition 3 is put into a mold having a shape shown in FIG. 1 (A) and having a thickness of 6 cm in the radiation passing direction, and dried at room temperature (25 ° C.) for about 1 hour. After curing, the mold was removed to obtain a gypsum block (c) used in Example 3.
The thinner gypsum block (c-2) was obtained by processing the gypsum block (c) to a thickness of 3 cm.

(Radiation shielding wall)
The obtained gypsum block (c) was stacked in a row in the radiation incident direction to form a radiation shielding wall of Example 3-1.
Similarly, the surface of the dry gypsum block on the front surface side of the wall is positioned on the back side of the end face of the dry gypsum block, the positions are determined so that the side seams do not coincide, and two rows are stacked, and A radiation shielding wall was formed.
Similarly, the surface of the dry gypsum block on the front side of the wall is positioned on the back side of the dry gypsum block, and three rows are stacked so that the side seams do not coincide with each other. Formed.
Moreover, the obtained gypsum block (c-2) was piled up in a row facing the incident direction of the radiation, and the radiation shielding wall of Example 3-4 was formed.
Similarly, the surface of the dry gypsum block on the surface side of the wall is positioned on the back side of the end face of the dry gypsum block, the positions of the side gypsum blocks are determined so as not to coincide with each other, and the three rows are stacked. A radiation shielding wall was formed.
Similarly, the surface of the dry gypsum block on the front side of the wall is positioned on the back side of the dry gypsum block, and six rows are stacked so that the side seams do not coincide with each other. Formed.

(Evaluation of radiation shielding wall)
Radiation shielding experiments were conducted in the same manner as the radiation shielding walls of Example 3-1 to Example 3-6. The results are shown in Tables 5-6 below.

As shown in Table 5, the gypsum block (c) achieved a γ-ray shielding rate of 34% to 45% even in the shielding wall of one row of blocks, and was formed by stacking three rows of gypsum blocks (c). According to the radiation shielding wall, it was confirmed that a shielding rate of about 78% to 88% was achieved for γ rays. This shielding rate is a high shielding rate of 23 mm to 31 cm of lead equivalent in gamma rays. Moreover, as shown in Table 6, the gypsum block (c-2) achieved a neutral wire shielding rate of 17% even in the shielding wall of one block, and the gypsum block (c-2) had six rows. According to the radiation shielding wall formed by stacking, it was confirmed that a shielding rate of 67% was achieved for neutron beams. From the above results, it can be seen that the gypsum block (c) has a particularly high gamma ray shielding effect.
Thus, it was confirmed that the radiation shielding wall of each of the above examples can be easily constructed and has high radiation shielding properties.

10, 20, 30, 40 Radiation shielding wall 12, 22, 32, 42 Dry gypsum block

Claims (6)

  A radiation shielding wall constructed by stacking dry gypsum blocks formed of a radiation shielding material composition containing water and gypsum.   The radiation shielding wall according to claim 1, wherein the gypsum is α gypsum.   The radiation shielding wall according to claim 1 or 2, wherein when the wall is viewed from the front, the mating surface of the dry-type gypsum block is not a straight surface from the wall surface to the back surface.   A plurality of dry gypsum blocks are stacked in the thickness direction of the wall, and the surface of the dry gypsum block is located on the back side of the end face of the dry gypsum block on the surface side of the wall. The radiation shielding wall according to Item 1.   The radiation shielding material composition further comprises at least one element selected from the group consisting of boron, boron compounds, gadolinium, cadmium, and lithium or an isotope thereof. The radiation shielding wall according to Item 1.   The radiation shielding material composition further comprises at least one particle selected from the group consisting of lead, tungsten, bismuth, iron, iron oxide, iron ore, magnetite, hematite, barite, barium, and a barium compound. The radiation shielding wall according to any one of claims 1 to 4, comprising: