JP6291439B2 - A method for producing a radiation shielding composition, a radiation shielding material or a radiation shielding building material. - Google Patents

Description

  The present invention relates to a method for producing a radiation shielding composition, a radiation shielding material, a radiation shielding building material, and the like, and particularly, does not use lead, is safe for the human body, can be reduced in cost, is lightweight, A method of manufacturing a radiation shielding composition, a radiation shielding material, a radiation shielding building material, etc. that has a versatile, yet simple configuration and can effectively shield various types of radiation with only one radiation shielding material. It is to provide.

Due to the scattering of radioactive materials into the atmosphere and diffusion to a vast area caused by the Fukushima Daiichi nuclear power plant damage accident caused by the 2011 off the Pacific coast of Tohoku Earthquake that occurred on March 11, 2011 High radiation doses have been detected in buildings, buildings such as roads, soil, vegetation, forests and rivers.
Currently, in areas where such a high radiation dose is detected, so-called decontamination work is performed to remove soil containing radioactive material accumulated there.
In a state where the soil that is removed in large quantities by the decontamination work is covered with a sheet made of an appropriate material in a storage facility provided in an appropriate area, or stored in a predetermined container such as a container bag made of an appropriate material, Although it is stored, it is assumed that sufficient radiation shielding measures will be taken to shield the radiation emitted from the removed soil and the like and reduce the effects of radiation on workers and neighboring residents.

Therefore, at present, the development and examination of shielding means for effectively shielding the radiation generated from the radioactive pollutant is being carried out.
On the other hand, there is an urgent need to develop technology that completely blocks various types of radiation generated from radiation sources in the future, including radiation harmful to the human body that is still radiated in large quantities from damaged nuclear power plants. Yes.

As a general radiation shielding method known from the past, a technique using lead is used. For example, a method of covering the radiation source using a synthetic resin, rubber product, concrete, or the like containing lead. Has been adopted.

However, lead is harmful to the human body and the environment, tends to elute in nature, has problems of manufacturing and construction costs, is heavy, inconvenient to use, and difficult to process into an appropriate shape. However, it has a disadvantage that it is not versatile and it is difficult to cover and shield radiation sources for a long time due to deterioration. For example, it is used only as a shielding wall material for hospital X-ray rooms. However, this was not suitable as a versatile radiation shielding material.

By the way, it is known that α-rays, β-rays, γ-rays, X-rays, neutron rays and the like are emitted from ordinary radioactive substances.
Α rays have a relatively low transmission capability and can be blocked by paper or the like, and β rays also have a low transmission capability and use a thin metal such as aluminum. Therefore, it is possible to shield the transmission.
On the other hand, γ-rays and X-rays have high transmission capabilities, and it is necessary to shield radiation by using a heavy metal such as lead, a thick iron plate, or a thick concrete shielding material.
Furthermore, since the radiation of neutrons has a very high permeability, it cannot be effectively shielded by the heavy metals and concrete mentioned above, so that they can be easily absorbed and captured by nuclei. It is necessary to slow down the neutron beam sufficiently to make it a low-speed neutron beam. Therefore, it is possible to shield the transmission of the neutron beam by using water or paraffin. Are known.

Considering the conventional technical background as described above, studies have been made to develop various radiation shielding materials on the assumption that lead is not used or the amount of lead used is reduced.
For example, JP 2014-35225 A (Patent Document 1) describes a radiation shielding sheet in which a radiation shielding layer mainly composed of barium sulfate is formed on one surface of an appropriate fibrous fabric, Japanese Unexamined Patent Publication No. 2013-181793 (Patent Document 2) describes a woven fabric made of a linear body made of a radiation shielding material formed by dispersing barium sulfate in an appropriate thermoplastic synthetic resin. .
Furthermore, JP 2014-153068 A (Patent Document 3) describes a radioactive waste storage container in which sulfur, blast furnace slag, incinerated ash, tungsten, barium sulfate, and the like are mixed in a concrete component.

However, such a known technique is effective as a radiation shielding material that does not use lead. However, since the substance used is barium sulfate, it is only a thing that can only shield the transmission of γ rays. However, there is a disadvantage that it is not suitable for shielding various kinds of radiation.
On the other hand, Japanese Patent Laid-Open No. 2014-130050 (Patent Document 4) discloses a radiation shielding material obtained by impregnating a nonwoven fabric with graphite (carbon nanohorn). And X-rays can be shielded, but other radiation cannot be shielded. In addition, Japanese Patent Laid-Open No. 2014-044197 (Patent Document 5) synthesizes boron (boric acid). Although the radiation shielding material incorporated in the resin is disclosed, the boron (boric acid) has an effect of shielding neutron radiation, but includes the problem that other radiation cannot be shielded. Yes.

In addition, JP2013-184853A (Patent Document 6) describes a radiation shielding board in which lead or barium sulfate is mixed in a gypsum component, and JP2014-89127A (Patent). Reference 7) describes a radiation shielding block material formed by mixing boron (boric acid), lead, tungsten, or the like with a gypsum component. Incorporates the problem that it can be shielded, but other radiation cannot be shielded, and the manufacturing cost is high and it is in the form of a block. Yes.

  In addition, JP2013-257164A (Patent Document 8) discloses a radiation shielding material made of a non-woven fabric composed of superabsorbent fibers, which can shield neutron beams, The cost for producing the superabsorbent fiber is high, but it is poor in weather resistance and durability, and therefore includes a problem that it can be used only in a specific field.

On the other hand, Japanese Patent Application Laid-Open No. 2014-145032 (Patent Document 9) discloses a radiation shielding foamed resin molded product obtained by foaming by mixing polyborate with an ethylene vinyl acetate copolymer resin, which uses lead. Although it is not a heavy radiation shielding material like lead products, it is a lightweight radiation shielding material with radiation shielding properties, but it has the disadvantage of high manufacturing cost and poor versatility. It is done.
In other words, the radiation shielding material or the material for the conventional one described above has a high cost constitution including manufacturing cost, and is heavy and flexible even if it does not use lead. Because of its poor nature, its use is not versatile, and each radiation shield can only shield specific radiation individually, so it can completely shield multiple radiation. There is only a method in which individual radioactive shields capable of individually shielding individual radiations are manufactured by individual methods, and a plurality of individual radioactive shields are used in combination. Therefore, it takes a considerable amount of time and cost to construct a complete radiation shielding structure, which is inconvenient.

By the way, as for the shielding of radiation, it is common sense to say that a material having a large mass has a shielding effect at present, but the shielding of mass and radiation is not necessarily proportional.
On the other hand, there are various types of radiation, and there is no universal shielding material.
Depending on the type of radiation, NASA in the United States is conducting research to shield radiation in outer space with polyethylene resin. It has also been found that radiation neutrons have a large water shielding effect.
On the other hand, the shielding material used for shielding X-rays in hospitals is composed of lead and gypsum board. This is because lead has a mass and is effective in shielding radiation, but gypsum board is not as effective in shielding as lead, but gypsum board used in gypsum board has 21% crystal water. It is thought that this moisture greatly affects the shielding of radiation.

The gypsum used in the gypsum board is dihydrate gypsum, and the water intervening in the gypsum as crystal water is in a state where it does not scatter at room temperature, and the water is stably maintained. When water is added to increase the shielding effect, the shielding effect decreases with moisture if water evaporates even if the temporary shielding effect increases.
Then, it is only necessary to confine the water in gypsum in a state where it does not evaporate like crystal water, but it is actually difficult.
Therefore, it is predicted that if gypsum is mixed with a substance that retains moisture, the amount of moisture is improved and the effect of shielding neutrons on radiation, which moisture is best at, is achieved.
In addition, radiation that is of concern in the nuclear accident is not affected by exposure in a short time with radiation at a level such as hospital X-rays, except where access is restricted.
However, there are concerns about health hazards associated with prolonged exposure. Therefore, in order to effectively shield various types of radiation, there is an inconvenience that a complex shielding material must be used.

Here, the shielding effect will be briefly described below with respect to various materials that have been conventionally known to have the shielding effect against individual radiation.
(1) Barium sulfate is safe and relatively inexpensive. The specific gravity is about 4.3 g / cm ³ and is particularly excellent in shielding X-rays and γ-rays.
(2) Calcium sulfate is safe and inexpensive. The specific gravity is about 2.5 g / cm ³ , and the specific gravity is small, but it is effective for shielding neutrons by the crystal water of dihydrate gypsum.
(3) Water-absorbing polymer polymer A polymer of acrylic acid having a large number of carboxyl groups, which can absorb water 200 times its own weight and has a moisturizing power.
When water is added, polymers with moisture and hydrogen atoms are effective in shielding neutrons and γ rays.
(4) A plate-like material in which graphitic carbon atoms are arranged is overlapped in several layers, and the specific gravity is about 0.95 g / cm ³ .
It is safe and inexpensive. Effective for shielding neutrons and gamma rays.
(5) Water containing a large amount of hydrogen atoms is effective for shielding neutrons.
(6) Polyethylene ethylene polymer having a specific gravity of about 2.5 g / cm ³ .
Both are effective shielding materials against γ rays and neutron rays.
(7) Boric acid (boron)
Boron has a property of easily absorbing neutrons, and boron-10 does not have radioactivity even if it absorbs neutrons and becomes boron-11.

Considering the actual radiation shielding material composition, there are various types of radiation depending on the generation mechanism and physical properties. Radiation can be roughly divided into electromagnetic radiation and particle radiation because of its physical properties.
Electromagnetic radiation includes γ rays and X-rays, and the electromagnetic radiation is an electromagnetic wave having a very short wavelength.
On the other hand, what poses a problem in public exposure is that this wavelength is extremely short and has high transparency and is electromagnetic radiation.
Regarding particle radiation, main particle radiation includes α rays, β rays, neutron rays, heavy particle rays, and the like.
α-rays and β-rays can be shielded with several millimeters of paper and aluminum plates, but neutron rays have the highest transmission power and can only be shielded by hydrogen atoms contained in thick walls of water or concrete.

However, the composition of the radiation shielding material varies depending on the radiation dose to be shielded as described above. For example, as a radiation shielding material in an X-ray clinic in a hospital, shielding X-rays of electromagnetic radiation is mainly used. The purpose of shielding.
For a lead equivalent of 1.5 mm, the lead-free shielding material is blended in three types: barium sulfate, a polymer water-absorbing polymer, and polyethylene. The blending ratio is 7: 1: 2.
The lead equivalent in this composition is 1.8 mm, and the actual thickness needs to be 18 mm, which is 10 times the thickness.
However, the lead plate used for radiation shielding in the X-ray clinic has a total thickness of 14 mm because the thickness of the plaster board used for backing the plaster board is 12.5 mm. Is 4 mm and there is no significant change in thickness.
In this case, since the shielding material itself becomes a wall, a predetermined blended product is formed into 910 mm × 1820 mm × 18 mm.

On the other hand, there are areas where radiation doses are still a problem outside the alert area due to the nuclear accident, and people are forced to live in that environment.
According to the guidelines established by the government, if the annual exposure is 1 mSv, the amount is 0.19 μSv per hour.

There are many areas outside the warning area that exceed the standard exposure per hour.
For example, the air dose at a certain place in Fukushima Prefecture is 1.8 μSv as of January 2015.
Examining nearby doses at the same time, there are areas that exceed national standards.
However, many data are less than 50% above the standard.
Considering the current situation, as described above, the radiation shielding material can be shielded most effectively if it is configured so that the composition of the components can be changed depending on the type and level of radiation. become.

JP 2014-035225 A JP 2013-181793 A JP 2014-153068 A JP 2014-130050 A JP 2014-044197 A JP 2013-184853 A JP 2014-089127 A JP2013-257164A JP 2014-145042 A

Accordingly, the object of the present invention is to improve many of the problems of the prior art described above, without using lead, mainly using materials and raw materials that do not adversely affect the human body, and inexpensive including manufacturing costs. It is possible to manufacture a radiation shielding material that can be manufactured at low cost, and has a structure suitable for lightweight, flexible, and versatile applications and can effectively shield desired radiation by a simple method. A method for producing a radiation shielding composition, a method for producing a radiation shielding material, or a radiation shielding method capable of reliably shielding all radiation with only a single radiation shielding material with a simple configuration. The present invention provides a method for manufacturing functional building materials and the like.

Concerns about the effects of radiation continue due to the accident at the Fukushima Daiichi nuclear power plant.
However, the ability to shield radiation with lead as in an X-ray clinic is not generally required.
In addition, the use of lead is restricted, and the development of shielding materials that replace lead is an urgent task.
Various shielding materials that can replace lead have been studied. For expensive materials, tungsten and the like have also been studied.

In recent years, barium sulfate which is excellent in safety and relatively inexpensive has been actively used.
However, since barium sulfate molded into a plate shape lacks workability, a flexible sheet-shaped shielding material has been developed by molding barium sulfate with a resin or rubber binder.
The sheet-shaped shielding material aiming at flexibility has a limited shielding effect due to the limited amount of barium sulfate added.
Therefore, the present inventor has solved the above-mentioned problems in the prior art, developed an ideal radiation shielding material, and intensively studied to realize its manufacturing method. As a result, there is radiation that cannot be shielded only with water. In view of the above, the above-mentioned seven kinds of conventionally known inorganic and organic substances having a function of shielding the organic substance are combined as appropriate, with the water or water-absorbing polymer polymer as a center, and by mixing, the radiation to be shielded The inventors obtained new technical knowledge that an adjustable radiation shielding material is obtained in response to the dose.

In other words, in the present invention, a technical idea for producing a radiation shielding material whose radiation shielding ability can be adjusted by the filling amount of each radiation shielding material was developed, and at the same time, the filling material was foamed. In this case, it is possible to manufacture a radiation shielding material and a radiation shielding building material having a radiation shielding effect capable of heat insulation and sound insulation.
That is, the present inventor has made further studies in order to achieve the above-described object of the present invention. As a result, the above-mentioned radiation can be effectively shielded individually, and particles other than lead can be granular. In the form of a body, at least one kind of each granular body or a plurality of specific selected granular bodies are mixed in the presence of water, and the resulting gel-like radiation shielding composition is identified. It has been found that the object of the present invention described above can be easily achieved by confining in a space region formed of a material having the above flexibility.

Further, the present inventor defines the composition of the one or plural kinds of granular materials confined in the space region and the combination thereof, and mixes the mixture with water so that one radiation shielding composition can be used. , One of the desired specific radiation, a radiation shielding composition capable of shielding the selected specific radiation, or the radiation shielding material using the radiation shielding material or its building material, etc., in an easy manner at low cost. In addition, they have learned that they can be manufactured quickly.

That is, the present invention basically employs the following technical configuration in order to achieve the above object.
That is, the technical configuration according to the first aspect of the present invention basically includes a granule made of a water-absorbing polymer or a granule made of a water-absorbing polymer. A mixture containing water gypsum) is introduced into the mixing tank , and water corresponding to at least several times to several tens of times the weight of the granular material made of the water-absorbing polymer is added to the mixing tank. It is a manufacturing method of the radiation shielding composition characterized by forming a gel-like mixture by carrying out stirring processing for a predetermined time after throwing in.

Further, the technical configuration in the second aspect according to the present invention is characterized in that, in the technical configuration described above, the granular material made of the water-absorbing polymer is further mixed with granular barium sulfate. The method for producing a radiation shielding composition.
Furthermore, in the technical configuration according to the third aspect of the present invention, in the above-described technical configuration, at least granular graphite and boron (boric acid) are further added to the granular material made of the water-absorbing polymer. It is a manufacturing method of the radiation shielding composition characterized by mixing a kind of granular material.

On the other hand, the technical configuration according to the fourth aspect of the present invention is the above-described technical configuration, in which the granular material composed of the water-absorbing polymer and the granular material of calcium sulfate (dihydrate gypsum) are mixed. In some cases, a first step of previously mixing calcium sulfate (dihydrate gypsum) and water in a first mixing tank to form a slurry-like first mixture, and the water-absorbing polymer. Water corresponding to a weight of at least several tens to several hundred times the weight of the granular body and the granular body made of the water-absorbing polymer is mixed in the second mixing tank, A second step of forming a second mixture in which a large amount of water has been added to the water-absorbing polymer, and the first mixture formed in the first step in an appropriate mixing vessel; and Mixing with the second mixture formed in the second step, In the presence of sexual agent, a method for producing a radiation shielding composition characterized in that the third step of performing a mixing process operations are performed.

  The technical configuration in the fifth aspect of the present invention is basically the same as the technical configuration described above in the form of a granular material made of a water-absorbing polymer, and the granular calcium sulfate (dihydrate gypsum). In addition, in the case of mixing at least one kind of granular material selected from barium sulfate, graphite, boron (boric acid), calcium sulfate (dihydrate gypsum) and barium sulfate, graphite, boron (boric acid) A first step of mixing at least one granule selected from the above with water in a first mixing tank to form a slurry-like first mixture, a granule comprising the water-absorbing polymer, and the In the second mixing tank, water corresponding to the weight of at least several tens to several hundreds times the weight of the water-absorbing polymer is mixed in the second mixing tank, and a large amount of the water-absorbing polymer of the particle is obtained. Second water containing water The second step of forming the compound, the first mixture formed in the first step, and the second mixture formed in the second step in an appropriate mixing vessel And a third step of performing a mixing treatment operation in the presence of a surfactant is performed.

Furthermore, the technical configuration in the sixth aspect of the present invention is the above-described technical configuration, wherein the mixing treatment tank includes a special stirring blade as will be described later, and a shearing force. It is a manufacturing method of the radiation shielding composition characterized by providing the stirring blade which has a high structure.
On the other hand, the technical configuration according to the seventh aspect of the present invention is the above-described technical configuration, wherein the mixing tank of the mixing treatment tank has a rotation center axis of 1 to 10 degrees with respect to the vertical axis. It is comprised so that it may rotate in the range of this, It is a manufacturing method of the radiation shielding composition characterized by the above-mentioned.

  As a result of adopting the above-described technical configuration, each of the manufacturing methods related to the radiation shielding composition, the radiation shielding material and the radiation shielding building material according to the present invention completely solves the problems in the prior art, It can be manufactured at low cost including manufacturing cost, using materials and raw materials that do not adversely affect the human body without using lead, and it is also suitable for lightweight, flexible and versatile applications. It is possible to manufacture a radiation shielding material that can effectively shield desired radiation by a simple method with a structure, and at the same time, it can reliably shield desired radiation by a simple method. It has become possible to provide a technical method capable of producing a possible radiation shielding composition, a radiation shielding body, or a building material having a radiation shielding function.

FIG. 1 is a diagram for explaining an outline of a configuration in a specific example of the radiation shielding material in the present invention. FIG. 2 is a diagram for explaining a specific example of a method for applying a foamable radiation shielding material according to the present invention. FIG. 3 is a diagram for explaining another specific example of the construction method of the foamable radiation shielding material according to the present invention. FIG. 4 is a diagram for explaining another specific example of the construction method of the foamable radiation shielding material according to the present invention. FIG. 5 is a view for explaining still another specific example of the construction method of the foamable radiation shielding material according to the present invention. FIG. 6 illustrates the structure of a specific example of the mixing tank used in the present invention. FIG. 7 is a perspective view illustrating another configuration example of the radiation shielding material according to the present invention. FIG. 8 is a perspective view showing the configuration of a specific example of the foamable radiation shielding material according to the present invention. FIG. 9 is an electron microscope for explaining a configuration example of the foamable radiation shielding material in which a water-absorbing polymer according to the present invention and water are mixed with calcium sulfate (dihydrate gypsum) and a foaming agent. It is a photograph. FIG. 10 is an electron micrograph illustrating a configuration example of a radiation shielding material in which calcium sulfate (dihydrate gypsum) is mixed with a mixture of the water-absorbing polymer according to the present invention and water.

The structure of a specific example of the method for producing the radiation shielding composition according to the present invention, the method for producing the radiation shielding material using the radiation shielding material, or the method for producing the radiation shielding building material using the radiation shielding composition according to the present invention is described below. Will be described in detail with reference to FIG.
That is, FIG. 7 is a perspective view showing a specific example of the radiation shielding material 100 according to the present invention configured by sealing the radiation shielding composition 200 according to the present invention in a desired hermetic container 300. In the figure, for example, a water-absorbing polymer polymer or the water-absorbing polymer is contained in a sealed container 300 made of a film-like body composed of a film or sheet having a radiation shielding effect made of polyethylene-based synthetic resin or the like. A mixture in which dihydrate gypsum (calcium sulfate) is mixed with a polymer, and if necessary, a mixture containing at least one radiation shielding material selected from barium sulfate, graphite, boron (boric acid), etc. A radiation shielding material 100 in which the radiation shielding composition 200 in the form of a gel in the presence of moisture is inserted in a sealed state is shown.
In addition, 150 of the same figure (A) shows the upper surface of the said radiation shielding material 100, 160 shows the bottom face part.

In other words, in each of the products obtained by the present invention, as described above, considering that the main purpose is to have versatility that can exert a shielding effect on any of various types of radiation, radiation shielding is considered. In order to realize the essential technical idea of replacing the radiation shielding material mainly composed of lead and concrete, which is the most demanded in the prior art, as a material, it has high water absorption as the main component of the main radiation shielding composition. Some use molecular polymers.
As another specific example of the present invention, as the composition of the radiation shielding composition 200, the water-absorbing polymer polymer may include another radiation shielding material having a function of shielding other types of radiation. A desired radiation shielding material 100 is produced using the radiation shielding composition in which at least one kind, preferably a plurality of kinds, is mixed.

The type of the water-absorbing polymer used in the present invention is not particularly limited, and a water-absorbing polymer generally used conventionally can be used.
The water-absorbing polymer is usually present in a powdery or granular form, but easily absorbs water, and its volume expands to several to several tens of times younger or more, resulting in a gel form. It becomes an object.
The water-absorbing polymer has a water absorption time as follows.
That is, the water absorption time per 1 g of the water-absorbing polymer is generally 50 ml of water in 20 seconds, 100 ml of water in 1 minute, 300 ml of water in 3 minutes, 500 ml of water in 10 minutes. The amount of water absorption is not changed even after 10 minutes or more.
Therefore, in the present invention, sufficient water absorption treatment is performed by setting the water absorption treatment time of each of the water-absorbing polymer polymers described later to a maximum of 10 minutes.

In another specific example of the present invention, dihydrate gypsum (calcium sulfate) is mixed with the water-absorbing polymer, or dihydrate gypsum (with respect to the water-absorbent polymer). Calcium sulfate) and barium sulfate are mixed, and in addition, at least one of graphite and boron (boric acid) is mixed, but the mixing amount or mixing ratio of each is not particularly specified, The mixing amount or mixing ratio can be appropriately changed according to individual applications.
In general, it is desirable to set the mixing ratio of each radiation shielding material to the same value in consideration of the versatility of the radiation shielding material.
The mixing of each radiation shielding material is carried out in the form of a granular or powdery body of each radiation shielding material, put into a predetermined mixing tank, mixed with stirring as appropriate, and then the mixture is mixed with water. In general, a method of further mixing operation by bringing into contact with is used.

However, in the above-described ordinary general mixing method, if the mixing process cannot be performed reliably, some of the radiation shielding materials are separately mixed with water, and then other A method of performing a mixing process by integrating the radiation shielding material may be adopted.

Furthermore, the mixing apparatus used in the present invention is not particularly specified, but it has been found that it is desirable to use a compound mixer because the slurry has a high viscosity, and the mixing apparatus. In the process, it was found that mixing of one batch of 100 kg or more requires a mixer having an internal volume of the mixing tank of 200 L or more and a motor output of 10 KW or more.
Further, as shown in FIG. 6, it is desirable that a stirring blade 31 having a structure having a high shearing force is provided inside the mixing treatment tank 30, and the stirring blade 31 is particularly shown in FIG. ) To (D), it is desirable to have three stirring blades 31 having a shape as shown in FIG. 1, and each stirring blade 31 is arbitrarily connected in a specific direction by an appropriate rotating device 31. It is preferable to be configured to rotate at the number of rotations.
As a specific example of the stirring blade 31 having the structure with high shear force used in the present invention, as shown in FIG. 6, the three stirring blades rotating around the same rotation axis have a predetermined width. The stirring blades are stacked in a vertical direction along the rotation axis, and the two stirring blades provided in the uppermost stage and the middle stage have a portion extending horizontally to the left and right around the rotation axis and the horizontal A portion extending from the both ends of the portion extending to the horizontal plane of the horizontally extending portion at a predetermined angle and obliquely upward at a predetermined angle, and toward the diagonally upward direction The blade further has a blade shape that is formed from an extended portion that is bent at a predetermined angle outwardly with respect to the extended portion by a predetermined length from the free end portion of the extended portion. And The one stirring blade provided in the lowermost stage is composed only of a portion extending horizontally from side to side with respect to the rotation axis, but the portion extending horizontally from side to side is the center axis. A configuration in which stirring blades configured to have a blade shape configured to be twisted in a direction opposite to each other at a predetermined angle with respect to an orthogonal horizontal plane is employed .

Similarly, it is also a desirable example that the mixing treatment tank 30 in the present invention is itself configured to be rotated at an appropriate rotational speed in an appropriate rotational direction by an appropriate rotating device 31. .
Furthermore, in the present invention, as shown in FIG. 6 (E), the mixing treatment tank 30 swivels while its rotation center axis is shifted within a range of 1 to 10 degrees with respect to the vertical axis. Such a configuration is also a preferable specific example for obtaining a highly accurate mixing effect.

In the present invention, as described above, a water-absorbing polymer is used as a main component, or some of the other radiation shielding materials are added to the water-absorbing polymer in an appropriate mixing ratio. The radiation shielding composition 1 is formed by forming the radiation shielding composition 200 in a sealed state in a suitable sealed container 100 in the presence of the water.
Although the shape and capacity of the sealed container 100 in the present invention are not particularly limited, it is desirable that the sealed container 100 is made of a material that is strong and flexible and has a function of shielding radiation.
For example, it is desirable to use a material composed of film bodies 2 and 300 such as a sheet or film mainly composed of a polyethylene-based synthetic resin material.

And the exterior is comprised with the said film body, and the interior space area | region part is formed in the inner surface part, and what comprises the bag-shaped container 100 which has an appropriate sealable opening part is used preferably. Is.
That is, the radiation shielding material 100 according to the present invention includes a polyethylene-based material in which one or more kinds of radiation shielding compositions 200 as described above are mixed with each other in the presence of granules or moisture. It has the structure incorporated in the sealed space part comprised by the film bodies 2 and 300 which mainly consist of a synthetic resin material.
A desired amount of the radiation shielding composition 200 described above is injected into the inside of the container 300 from an appropriate opening (not shown) of the container 300, and the opening is hermetically sealed. The radiation shielding material 100 according to the above is completed.

The shape and various dimensions of the radiation shielding material 100 in the present invention are not particularly limited, and can be appropriately designed according to the purpose and place of use of the radiation shielding material 100.
For example, the radiation shielding material 100 illustrated in FIG. 7A has a cylindrical or columnar outer shape whose cross-sectional shape is circular, elliptical, rectangular, polygonal, or the like. The diameter is preferably about 10 cm to 50 cm, and the length in the longitudinal direction is preferably about 50 cm to 2 m.

On the other hand, the radiation shielding material 100 shown in FIG. 7B has a flat plate shape, and the vertical, horizontal, and height dimensions can be set to appropriate values.
However, for example, when the vertical and horizontal dimensions of the radiation shielding material shown in FIG. 7 (B) exceed 20 cm, particularly when the radiation shielding material 100 is constructed and arranged in a vertical or close state, In order to prevent the gel-like radiation shielding composition 200 from being displaced, it is desirable to arrange and manufacture the shielding wall portion 350 with an appropriate size.
The radiation shielding material 100 according to the present invention described above can be used exclusively in the field where lead has been mainly used and the field where concrete is mainly used, and is less expensive than the conventional one. Since it is lightweight and flexible, it is economical, and it is also efficient because it can reduce the construction cost and simplify the construction.

The radiation shielding material 100 according to the present invention is used by placing, laminating and stacking the radiation shielding material 100 in a state where they are in close contact with each other without being spaced apart like a block material where it is required. It is.
In addition, since most of the radiation shielding composition 200 contained in the radiation shielding material 100 according to the present invention is composed of water, there is no fear of generating harmful substances even when discarded.
Further, when the radiation shielding material 100 according to the present invention is used in a wide range of fields, as shown in FIG. 1 (A), for example, it is composed of a film body mainly composed of a polyethylene-based synthetic resin material. A plurality of sealable bag-like space regions 3 set to an appropriate size, for example, a size of about 100 mm × 100 mm, are desired on the sheet-like material 2 having an appropriate size and an appropriate area. Are arranged in a two-dimensional direction in an aligned state, a zigzag state, or a checkered state along a sheet-like surface 2 at a predetermined interval, and in the respective bag-like space regions 3. It is also possible to use the radiation shielding material 1 (100) configured by sealing the radiation shielding composition 200.

As shown in FIGS. 1B and 1C, the radiation shielding material 1 (100) according to the present invention is used in such a manner that the radiation shielding material is not leaked when used. It is desirable to arrange and construct 1 so as to overlap with each other in a mutually shifted state.
Furthermore, in the present invention, the above-mentioned radiation shielding material 1 or 100 is used as it is, or in the state where a plurality of them are laminated, conventionally used wall materials, ceiling materials, or floor materials, A building material having a novel radiation shielding function is provided by adhering to at least one surface of the other shielding plate portion using an appropriate adhesive or fixing means.
Or you may employ | adopt the structure arrange | positioned in the state pinched | interposed into the inner surface or inner layer part of a general pair of building material base material which the said radiation shielding material is conventionally well-known.

Next, the specific example of the manufacturing method of the said radiation shielding composition 200 in this invention is demonstrated in detail below.
That is, as a basic technical idea of the manufacturing method of the radiation shielding composition 200 in the present invention, a granular material made of a water-absorbing polymer, or a granular sulfuric acid for a granular material made of a water-absorbing polymer. Mixing calcium (dihydrate gypsum) or a mixture of granulated calcium sulfate (dihydrate gypsum) and barium sulfate in a granule made of a water-absorbing polymer is put into a stirring tank, and at least By adding water corresponding to a weight of at least several tens to several hundreds times the weight of the granular material made of the water-absorbing polymer into the stirring tank, the mixture is stirred for a predetermined time. It is a manufacturing method of the radiation shielding composition characterized by forming a mixture.

In this specific example, when the calcium sulfate (dihydrate gypsum) is used, the internal residual water as much as 21% contained in the calcium sulfate (dihydrate gypsum) is sufficiently shielded against radiation. It is desirable to use the calcium sulfate (dihydrate gypsum) that has not been fired because it is desirable to use it in half.
Furthermore, as another specific example of the method for producing the radiation shielding composition 200 in the present invention, the water-absorbing polymer is further provided with at least one granular material of granular graphite and boron (boric acid). It is a manufacturing method of the radiation shielding composition characterized by adding and mixing.

In the manufacturing method of the radiation shielding composition 200 according to the present invention, when only the water-absorbing polymer is used, specifically, for example, 100 particles of the water-absorbing polymer are used. And 50 L of water are introduced into a mixing apparatus having an internal capacity of, for example, 300 L and having a structure as shown in FIG. 6, and output at 37 KW, for example, as shown in FIG. 6. The radiation shielding composition 200 is manufactured by mixing the blade body or the cylindrical body as described above at a rotational speed of 575 revolutions per minute (RPM) for about 10 minutes.

In addition, as other specific examples regarding the mixing of the water-absorbing polymer and water according to the present invention,
In a mixer having an internal capacity of a 300 L drum and a rotary blade, 100 g of the polymer water-absorbing polymer and 50 L of water were placed and mixed for 10 minutes at a rotation speed of 575 RPM and an output of 37 KW.
The polymer water-absorbing polymer that sufficiently absorbed water by this mixing treatment became jelly-like, and the total weight was 50.1 kg.
The polymer water-absorbing polymer obtained in this way has the individual space region portions 3 of the polyethylene-based synthetic resin film-like body 2 in which a plurality of space region portions 3 are formed in a staggered manner as shown in FIG. After that, the opening of each space region portion 3 was hermetically sealed to form a radiation shielding material.
On the other hand, in the present invention, when the radiation-shielding composition 200 is produced by mixing the water-absorbing polymer and the above-described other radiation-shielding material, the respective components are uniformly mixed. Therefore, it became clear that there was a need to introduce a new technical idea.
In order to obtain such a uniform mixing result in the above specific example, the present inventor has found that it is preferable to introduce the following new technical idea as a result of repeated experiments and examinations. It is obtained.

That is, for example, in the case of mixing barium sulfate and calcium sulfate with a water-absorbing polymer, barium sulfate and calcium sulfate are mixed with water in advance to form a slurry in order to maintain a large water content. It has been concluded that it is desirable to adopt a technical idea that a product mixed with a water-absorbing polymer polymer is mixed in a post-process.
The reason for this is that barium sulfate and calcium sulfate can reduce the water absorption capacity of the water-absorbing polymer due to the action of calcium ions.

Therefore, in the specific example of the present invention, it is a preferable specific example to mix barium sulfate and calcium sulfate with water absorbed beforehand.
In other words, barium sulfate and calcium sulfate differ greatly in specific gravity, so that it is difficult to obtain a uniform mixed slurry in a normal mixing operation, but mixing is performed with a polymer water-absorbing polymer and water interposed. By processing, both particles can be uniformly mixed.
In the above specific example of the present invention, when mixing the barium sulfate and calcium sulfate and the polymer water-absorbing polymer prepared for mixing, the surfactant is added in an amount of 0.5% based on the weight of the mixture. When the addition amount is between 5% and 5%, the mixing performance increases, and a good result is obtained that the separation is eliminated.
It goes without saying that such a new technical idea can be applied not only to barium sulfate and calcium sulfate but also to a specific example in which graphite and boron (boric acid) are mixed.

If a detailed example of the above-described specific example in the present invention is described below, the mixing method in the specific example uses a 300 L mixer, and the mixer is rotated at 575 RPM and 37 KW. In order to produce a mixture of about 100 KG, 100 g of a polymer water-absorbing polymer and 50 L of water are added and mixed for 10 minutes. Next, 20 kg of barium sulfate and 20 kg of calcium sulfate were water-containing in 10 KG of water and charged into a polymer water-absorbing polymer mixed with water, and mixed for 4 minutes at a rotation speed of 575 RPM and an output of 37 KW.
When 4 minutes passed, 0.5% of surfactant was added and mixed for 1 minute.
In addition, although the order of the above-mentioned process exhibits a desirable result, if the order is changed, another problem that separation of slurry and foaming of slurry appear, which is not preferable.

Here, when the above technical idea is summarized, as one aspect of the method for producing the radiation shielding composition 200 according to the present invention, a granular body made of a water-absorbing polymer, granular calcium sulfate (dihydrate gypsum), and sulfuric acid In the case of mixing at least one of the barium particles, barium sulfate and calcium sulfate (dihydrate gypsum) are previously mixed with water in the first mixing tank, and the slurry-like first mixture is mixed. The first step to be formed, and the water corresponding to a weight of at least several tens to several hundred times the weight of the granular material made of the water-absorbing polymer and the weight of the granular material made of the water-absorbing polymer. A second step of mixing in a mixing tank to form a second mixture in which a large amount of water is contained in the water-absorbing polymer of the granular material, and the first step in an appropriate mixing tank Formed in the second And the third step of mixing the second mixture formed in the second step and performing a mixing operation in the presence of the surfactant. It is a manufacturing method of a radiation shielding composition.

In the present invention, it is a radiation shielding material that is safe and inexpensive, has a high shielding effect, is a combination of materials mainly composed of barium sulfate and has a high shielding effect on each radiation, and changes the mixing depending on the intended use.
The mixing ratio of each granule is not specified, but it is desirable to manufacture the granules with approximately the same weight ratio.

In addition, as another specific aspect of the present invention, a radiation shielding composition characterized in that the mixing treatment tank is provided with a stirring blade having a structure having a high shearing force in the mixing treatment tank. And the mixing tank of the mixing treatment tank is configured such that the rotation center axis of the mixing tank rotates within a range of 1 to 10 degrees with respect to the vertical axis. A method of manufacturing a radiation shielding composition for manufacturing a product is disclosed.
Furthermore, as another specific aspect, the radiation shielding composition 200 manufactured by the above-described method is put into the space region 3 mainly composed of a synthetic resin material, and then the space region is sealed. A method of manufacturing the radiation shielding material 1 is disclosed, and two-dimensionally parallel or staggered on at least one surface of a sheet-like structure mainly composed of a single synthetic resin material. Alternatively, the radiation shielding composition 200 is individually introduced into each of the plurality of space regions 3 arranged and formed close to each other in a checkered pattern, and then each space region is sealed. A manufacturing method of the radiation shielding material 1 is disclosed.

Furthermore, as another specific aspect in the present invention, the radiation shielding material 1 manufactured by the above-described method is configured to be laminated or stuck on at least one surface of an appropriate building material. A manufacturing method of a radiation shielding building material is disclosed.
Next, the results of studies on the radiation shielding effect of the radiation shielding material 1 (100) obtained by the present invention will be described in detail with reference to Table 1 shown below.
Table 1 below shows the measurement of the radiation shielding effect. First, 10 g of the water-absorbing polymer as the main composition component is mixed with 5 L of water to form a gel, which is molded into a 5 mm thick plate. The shielding rate with respect to various types of radiation of the prepared radiation shielding composition 200 is measured.

Then, 10 wt% of dihydrate gypsum (calcium sulfate), barium sulfate, graphite, and boron (boric acid) were mixed individually with 10 g of the water-absorbing polymer polymer mixed with 5 L of water. The radiation shielding composition 200 having a thickness of 5 mm is formed, and the shielding ratio of the radiation shielding composition 200 against various types of radiation is measured individually.

当該表１から明らかな通り、当該吸水性高分子ポリマーのみからなる当該放射線遮蔽組成物２００に於いては、α線とβ線に対しては１００％の遮蔽効果をはっきするものの、Ｘ線に対する遮蔽効果は、若干不満足であり、γ線、及び中性子線に対しては、理想的な遮蔽効果としては、不十分な特性を示している。 In Table 1, the X-ray shielding rate is calculated using the blank transmission dose rate (100 kv) as a reference value, and the background dose rate is 0.05 +/− 0.01 μS v / h.

As is apparent from Table 1, the radiation shielding composition 200 made of only the water-absorbing polymer exhibits a 100% shielding effect against α rays and β rays, but against X rays. The shielding effect is slightly unsatisfactory, and exhibits insufficient characteristics as an ideal shielding effect for γ rays and neutron rays.

On the other hand, in the radiation shielding composition 200 in which dihydrate gypsum (calcium sulfate) or barium sulfate is mixed in the water-absorbing polymer, the shielding effect against γ rays is greatly improved, It can be seen that the shielding effect against X-rays and neutrons is somewhat improved.
Similarly, in the radiation shielding composition 200 in which graphite or boron (boric acid) is mixed into the water-absorbing polymer, the shielding effect against γ rays, X rays and neutron rays is somewhat improved. I understand that.
As long as judging from such experiments and measurement results, the water-absorbing polymer is mixed with one or more of dihydrate gypsum (calcium sulfate), barium sulfate, graphite or boron (boric acid), Since it is considered that a synergistic effect is exhibited as compared with the case of the water-absorbing polymer alone, it is understood that the mixing treatment operation in the present invention is effective.

Next, the configuration of another aspect related to the invention of the radiation shielding composition, the radiation shielding material, and the radiation shielding building material according to the present invention and the production method thereof will be described below.
That is, the basic technical configuration in the other specific embodiment of the present invention is configured from a foamed product obtained by adding a foaming agent to the radiation shielding composition 200 manufactured in the above specific example. It is the manufacturing method of the radiation shielding material 400 characterized by the above-mentioned, It is the manufacturing method of the radiation shielding building material using the same, As shown in FIG. 8, the said radiation shielding composition 200 mentioned above is shown. Is a foamed radiation shielding material 400 containing a large number of foamed portions 401.
In the figure, reference numeral 402 denotes a part of another radiation shielding material mixed with the water-absorbing polymer.

In this specific example, the conventional radiation shielding material is mainly composed of lead and concrete, so it is heavy, inconvenient to move, and takes time for construction. Not only is the cost high, but there is a problem that the construction cost has also increased significantly due to the time and labor required for the movement and construction of materials.
Therefore, in order to solve such a problem, in the above-described specific embodiment of the present invention, the produced radiation shielding composition 200 is foamed by a specific method and included in the radiation shielding composition 200. By making the radiation shielding material 1 (100) finally obtained by foaming calcium sulfate to be a foamed structure 400, the necessary cost is reduced by reducing the weight, moving the material, and shortening the construction period. Can be greatly reduced.
The foamed radiation shielding material 400 according to another specific example of the present invention includes an air layer, so that the weight-reducing building material for radiation shielding is excellent in heat insulation, soundproofing, and flame retardancy. It becomes.

By the way, the foamed radiation shielding material 400 in this specific example naturally has a reduced mass due to the foaming of calcium sulfate, and the shielding ability against radiation is reduced, but the heat insulating material can ensure a certain thickness. The water-absorbing polymer used in the foamed radiation shielding material 400 is hardly left, but the calcium sulfate mixed with the water-absorbing polymer is sufficiently left. It is considered that the crystal water contained in the calcium sulfate dihydrate gypsum is present even after the foaming treatment and exerts a radiation shielding effect.
Therefore, when the radiation shielding composition 200 is used in a foamed form, it is desirable to mix a large amount of the dihydrate gypsum (calcium sulfate) in advance.

Furthermore, according to the results of another experiment, it was found that the foam shielding material can be sufficiently avoided at the radiation influence level due to the nuclear accident.
Furthermore, it is possible to develop a functional radiation shielding material to which another function is added as a general building material by foaming the mixture by mixing an inorganic material and an organic material.
Next, the basic technical configuration of the method for producing the foamable radiation shielding composition in this specific example will be described.
That is, the basic technical configuration of the production method of the foamable radiation shielding composition in this specific example is the same as that of the water absorbing polymer in the production method of the radiation shielding composition 200 in the above specific example. Thus, the foaming radiation shielding material 400 is manufactured by mixing calcium sulfate and an aluminum foaming agent.

Further, as a further technical configuration in this specific example, in the method for producing the radiation shielding composition in the specific example described above, in the third step, in the presence of an aluminum foaming agent. This is a method for manufacturing the foamable radiation shielding material 400, characterized by performing a mixing treatment operation.
On the other hand, as another technical configuration in this specific example, in the manufacturing method of the foamable radiation shielding material 400 in the specific example described above, with respect to the mixture of the water-absorbing polymer and calcium sulfate, A method for producing a foamable radiation shielding material characterized in that a surfactant and an aluminum foaming agent are mixed, and further, in the method for producing the radiation shielding composition in the above-mentioned specific example. In the third step, the foaming radiation shielding material 10 is manufactured by performing a mixing operation in the presence of a surfactant and an aluminum foaming agent.

Hereinafter, one specific example of the method for producing the foamable radiation shielding material 400 according to the other aspect of the present invention will be described. The water-absorbing polymer polymer, the dihydrate gypsum (calcium sulfate), and the sulfuric acid A case where a foamable radiation shielding material is produced by mixing barium will be described as an example.
Example 1
That is, the foamable radiation shielding material method uses a 300 L mixer, sets the output of 37 KW at a rotation speed of 575 RPM, and produces a mixture of about 100 Kg. For example, as shown in FIG. Using a rotary mixing tank 30, 100 g of the polymer water-absorbing polymer and 50 L of water were added and mixed for 10 minutes.

Next, an aluminum foaming agent is added to the mixed polymer water-absorbing polymer in an amount of 0.05% to 0.5% of the final mixing weight and 0.5% of the surfactant, and the output is 37 kW at a rotation speed of 575 RPM. The mixing process was performed for 3 minutes.
When the mixing treatment for 3 minutes passed, 20 kg of barium sulfate and 20 kg of calcium sulfate were added with 10 kg of water, and the mixture was mixed for 5 minutes at a rotation speed of 575 RPM and an output of 37 KW.
If the mixture is dried, the water content is about 60% with respect to 100 kg, so even if the moisture content after drying is 10%, the mass of 50% of the weight is lost and double foaming is realized.
Specifically, the barium sulfate and calcium sulfate in the blending components are foamed using a conventional cement-based foaming agent.
The foaming phenomenon starts at a temperature around room temperature. On the other hand, the water-absorbing polymer polymer has a function of supporting foaming of the foaming agent.

Although the metal aluminum powder was used as the foaming agent used in the specific example, since it is a mortar foaming agent, it reacts with the alkali component of the mortar to cause foaming. Therefore, the reaction is difficult to occur with neutral calcium sulfate.
Therefore, it is possible to adjust the pH by adding an alkaline soap and to foam a mixed slurry of barium sulfate and calcium sulfate that does not foam by foaming due to the surface active effect.

Example 2
As another specific example of foaming a water absorbent polymer polymer mixed with calcium sulfate (dihydrate gypsum),
The weight ratio of the water-absorbing polymer and water is set to 1: 500, and at the same time, 15 to 50 parts by weight of calcium sulfate (dihydrate gypsum) is mixed.
The mixture was mixed in a mixer having an internal capacity of a 300-liter drum having a rotary blade, and 100 g of a polymer water-absorbing polymer and 50 liters of water were mixed and mixed at an output of 37 kW at a rotational speed of 575 RPM for 10 minutes.
The weight ratio of the water-absorbing polymer and water is set to 1: 500, and at the same time, 15 to 50 parts by weight of calcium sulfate (dihydrate gypsum) is mixed.
The mixture was mixed in a mixer having an internal capacity of a 300-liter drum having a rotary blade, and 100 g of a polymer water-absorbing polymer and 50 liters of water were mixed and mixed at an output of 37 kW at a rotational speed of 575 RPM for 10 minutes.

After that, 0.05 wt% to 0.5 wt% of aluminum foaming agent and 0.5 wt% of surfactant are additionally added to the mixed polymer water-absorbing polymer, and mixed for 13 minutes at an output of 37 KW at a rotation speed of 575 RPM. Processed.
During the mixing process, the jelly-like water-absorbing polymer is rotated in the mixing tank in the mixer to generate frictional heat and rises to a temperature of about 35 ° C., where foaming is performed.
That is, in this specific example, the foaming treatment is not performed in a separate process, that is, in a separate heating step, but the frictional heat generated by the jelly-like water-absorbing polymer is generated in the same mixer. Utilizing it, the temperature of the mixture increases. However, since most of the water is mixed for about 13 minutes due to water, the temperature rises only by about 35 ° C., but this is a desirable temperature for foaming.

Here, for example, the weight ratio of water-absorbing polymer to water is 1: 500, and 50 kg of jelly-like water-absorbing polymer is prepared at a mixing ratio of 500; 50 parts by weight (25 kg) of calcium sulfate (recycled dihydrate gypsum) is added to the jelly-like water-absorbing polymer. ) When mixed.
At this point, a total of 75 kg of mixture is made.
It is assumed that an aluminum foaming agent is mixed into this 75 kg mixture.
If the dihydrate gypsum content is controlled to double foam, the volume is doubled, the water is dried and about 50 kg of water is lost, and a foamed 25 kg gypsum foam is obtained.
In other words, the basic composition of the polymer water-absorbing polymer is that the weight ratio of the water-absorbing polymer to water is 1: 500, and (1) calcium sulfate, (2) barium sulfate, (3) graphite, and (4) boron are appropriately added to this. The products added in proportions are roughly divided into products that protect against radiation in a wave-type polyethylene container that prevents drying, and products that are made by foaming with an aluminum foaming agent in this product and then dried. I can do it.

However, since the foam can be produced only from the calcium sulfate (1) among (1) to (4), it naturally becomes a foam of calcium sulfate. Although this foam has a low density and its shielding ability is drastically reduced, it can shield a low level of radiation, and is excellent in heat insulation and soundproofing for other functions as a building material.
Example 3
Another specific example of foaming treatment by mixing calcium sulfate (dihydrate gypsum) with polymer water-absorbing polymer

Further, as another specific example, the weight ratio of the water-absorbing polymer to water is 1: 500, 50 parts by weight of calcium sulfate (recycled dihydrate gypsum) is mixed, and the aluminum foaming agent is 0.2 wt% and the surfactant. When 0.5 wt% is additionally charged, a foam of at least twice that of dihydrate gypsum can be obtained in forced drying for 15 hours at 80 ° C., and for natural drying in about 75 hours at an ambient temperature of about 20 ° C.
The moisture content after drying is 4-8%.
Here, FIG. 9 shows a configuration example of the foamable radiation shielding material mainly composed of the polymer water-absorbing polymer obtained by the specific example of the present invention.
That is, FIG. 9 shows the foaming after foaming treatment is performed by mixing 10 g of the water-absorbing polymer according to the present invention and 5 L of water and mixing 10% calcium sulfate (dihydrate gypsum) and 2% foaming agent. It is the electron micrograph which image | photographed 3000 times of structural examples of the radiation resistant shielding material.
From the electron micrograph of FIG. 9, it is found that calcium sulfate (dihydrate gypsum) is bonded to the water-absorbing polymer and exhibits a swollen foamed state.
On the other hand, FIG. 10 is a photograph taken at a magnification of 3000 times of a synthetic resin structure composed of a mixture of 10 g of a water-absorbing polymer and 5 L of water and only 10% calcium sulfate (dihydrate gypsum). It is an electron micrograph.
In the electron micrograph of FIG. 10, the white part is calcium sulfate (dihydrate gypsum), the black part shows the water-absorbing polymer, and no foamed structure is present.

Example 4
Still another specific example of foaming treatment by mixing calcium sulfate (dihydrate gypsum) into a polymer water-absorbing polymer The weight ratio of water-absorbing polymer to water is 1; 500 kg of barium sulfate in a jelly form of 20 kg In the case of 20 kg calcium sulfate and 10 kg water, the components remaining after drying are 20 kg of barium sulfate and 20 kg of calcium sulfate. Since the foaming agent becomes difficult to foam when barium sulfate is contained, the foaming agent must be increased. In the description of the above specific example, calcium sulfate can foam more than twice as much as 0.2% of the mixing weight of the aluminum foaming agent, but it must be increased to 0.5% by adding barium sulfate. Can not foam more than double.
In addition, when dihydrate gypsum and a foaming agent are put in a simple polymer water-absorbing polymer jelly and dried, a building material having an effect of heat insulation and sound insulation can be obtained although the purpose is changed.
The function of the water-absorbing polymer at this time is that a jelly-like water-absorbing polymer is interposed between the dihydrate gypsum and helps foam aluminum.

By the way, in relation to the present invention, although there is a difference in the area of heat and cold in the house, there is no house that does not carry out the heat insulating material. The material can be an effective building material 20.
That is, the basic technical constitution of the further invention in the other aspect of the present invention is composed of the foamable radiation shielding material 400, and is a plate-like body or a desired cross-sectional shape, for example, circular or elliptical. A foaming radiation shielding building material characterized by having a main body portion formed of a columnar body or a cylindrical shape having a cross-sectional shape such as a polygon or a rectangle, and the basis of another invention in the other aspect As a technical technical configuration, the radiation shielding composition 200 containing the foaming agent produced by the above-described method is foamed, and simultaneously injected into an appropriate mold part to obtain a plate-like body or a desired cross-sectional shape, for example, a circular shape. A method for producing a foamable radiation shielding building material, which is formed into a columnar body or cylinder having a cross-sectional shape such as an ellipse, a polygon or a rectangle.

As shown in FIG. 2, the foamable radiation shielding building material is used in the space formed by the wooden or metal frame portions 5 to 7 formed on the inner wall surface of the wall portion. It is possible to use the radiation shielding building material 20 so as to cover the other inner wall surface covering board 4 from above, and as shown in FIG. It is also possible to construct so that the foamable radiation shielding building material 20 can be inserted into the space formed by the wooden or metal frame parts 5 to 7 provided between the upper part and the side part. It is.
In the ceiling, as shown in FIG. 4, the foamable radiation shielding is provided in the space formed by the wooden or metal frame parts 8, 9 and 11 formed on the inner wall surface of the ceiling. It is possible to use it by fitting the building material 20 and covering another ceiling surface covering board 12 from above, and as shown in FIG. The foaming radiation shielding building material 20 may be inserted into the space formed by the wooden or metal frame portions 8, 9 and 11 provided therebetween from above or from the side surface thereof. Is possible.

As is clear from the above description, in the present invention, there are substances that have been considered effective with conventional radiation shielding materials, that is, lead and barium sulfate in recent years. The shielding material used is not barium sulfate, but using calcium sulfate (recycled dihydrate gypsum) and waste gypsum board, which has not been used in the past, with moisture, gypsum mass and gypsum crystal water It is a shield.
In other words, in the present invention, when water is trapped, a water-absorbing polymer is used in particular for the purpose of adjusting water retention and fluidity of water and preventing water freezing in cold regions. It is a simple and safe radiation shielding material.
In the present invention, when dihydrate gypsum and a foaming agent are put into such a simple jelly-like polymer water-absorbing polymer and dried, a building material having an effect of heat insulation and sound insulation can be obtained although the purpose is changed.

DESCRIPTION OF SYMBOLS 1,100 ... Radiation shielding material 2 ... Synthetic resin sheet | seat, film body 3 ... Internal space area | region 4 ... Wall material 5 ... Frame part 6 ... Wall part frame 7 ... Frame part 8 ... Wall part frame ... Frame 9 ... Wall frame 10 ... Radiation shielding material 11 ... Wall frame,
DESCRIPTION OF SYMBOLS 20 ... Foaming radiation shielding building material 30 ... Mixing tank 31 ... Rotary blade body part 32 ... Rotating apparatus 150 ... Upper surface part 160 ... Bottom surface part 200 ... Radiation shielding composition 300 ... Synthetic resin container 350 ... Partition wall part 400 ... Foaming property Radiation shielding building material 401 ... Foamed part 402 ... Residual calcium sulfate

Claims (10)

Against granulate consisting of water-absorbing polymers, both when introducing the mixture obtained by mixing calcium sulfate granules to the mixing tank, relative to the weight of the granules consisting of the water-absorbing polymer, several tens of times to several Production of a radiation shielding composition characterized in that a gel-like mixture is formed by carrying out a mixing treatment for a predetermined time after throwing water corresponding to 100 times the weight into the mixing tank. Method.   2. The method for producing a radiation shielding composition according to claim 1, wherein the granular material comprising the water-absorbing polymer is further mixed with granular barium sulfate. The method for producing a radiation shielding composition according to claim 1 or 2, wherein at least one kind of granular graphite or boron is further mixed with the granular material comprising the water-absorbing polymer. In the case of mixing a granular body made of a water-absorbing polymer and a granular body of calcium sulfate, calcium sulfate and water are mixed in advance in a first mixing tank, and a slurry-like first mixture is obtained. The first step of forming the water-absorbing polymer, and water corresponding to a weight of several tens to several hundreds times the weight of the granule made of the water-absorbent polymer and the granule made of the water-absorbent polymer. A second step of mixing in a mixing tank to form a second mixture in which a large amount of water is contained in the water-absorbing polymer of the granular material, and the first step in an appropriate mixing tank And the third step of mixing the first mixture formed in step 2 and the second mixture formed in the second step and performing a mixing operation in the presence of the surfactant. The radiation shielding according to any one of claims 1 to 3, wherein Processes for making compositions. In the case of mixing a granular material composed of a water-absorbing polymer, granular calcium sulfate, and at least one granular material selected from barium sulfate, graphite, boron , calcium sulfate, barium sulfate, graphite and at least one granulate is selected from boron mixed with water in a first mixing tank, a first step of forming a slurry first mixture, and granules consisting of the water-absorbing polymer Water corresponding to several tens to several hundred times the weight of the water-absorbing polymer is mixed in the second mixing tank, and a large amount of the water-absorbing polymer of the granular material is mixed. A second step of forming a second mixture containing water, and the first mixture formed in the first step in an appropriate mixing tank, and formed in the second step Said second mixture Mixing, in the presence of a surfactant, manufacturing method of the radiation shielding composition according to any one of claims 2 or 3, characterized in that the third step of performing a mixing process operations are performed. 6. The method for producing a radiation shielding composition according to claim 1, wherein an aluminum foaming agent is further mixed into the mixed radiation shielding composition. Manufacturing method of shielding material. 6. The method for producing a radiation shielding composition according to claim 4 or 5, wherein in the third step, a mixing operation is performed in the presence of a surfactant and an aluminum foaming agent. A method for producing a foamable radiation shielding material. The radiation shielding composition produced by the method for producing a radiation shielding composition according to any one of claims 1 to 5 is put into a space region mainly composed of a synthetic resin material, and then the space region A method for producing a radiation shielding material, wherein the part is sealed. A method for producing a radiation shielding building material, wherein the radiation shielding material produced in claim 8 is laminated or adhered to at least one surface of an appropriate building material. 8. A method for producing a foamable radiation shielding material according to claim 6 or 7, wherein the foamable radiation shielding material is put into an appropriate mold and subjected to a molding process to form a plate having an appropriate size. Or the manufacturing method of the foamable radiation shielding building material characterized by shape | molding into the columnar body which has suitable cross-sectional shape.

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