JP7060293B2 - How to store inside the radioactive waste storage container and the radioactive waste storage container - Google Patents

Description

Patent Law Article 30 Paragraph 2 Applicable Presented at "RADIEX 2015 Environmental Radioactivity Countermeasures / Waste Disposal International Exhibition" held on July 15, 2015 by the Environmental Newspaper. (1) Publication date July 15, 2015 to July 17, 2015 (2) Publication place Japan Science Foundation Science Museum 2-1 Kitanomaru Park, Chiyoda-ku, Tokyo 102-0091 International Exhibition of Environmental Radioactivity Countermeasures and Waste Disposal RADIEX Radix 2015 (3) Published by U Ishii "Utaki Ryokuchi Kagaku Kenkyusho" "INTERPLAN" (4) Contents of published invention [A] Reduction of radiation shielding and attenuation of radioactive substances Container body. [B] Vehicle carrier installation type assembly unpacking type dose transmission reduction box body. [C] Shielding reduction pack (no water content) Mineral fiber (rock wool molded body), mineral powder (dromite), activated carbon powder mixed filling sealed bag body.

Regarding reduction of radiation transmission of radioactive substances, protection of public exposure, protection of occupational exposure, protection of medical exposure, and treatment of radioactive waste related to measures to reduce radiation transmission emitted from environmental radioactive contaminants.

It is well known that objects with higher atomic numbers are more effective in shielding radiation, mainly gamma rays. Also, the larger the atomic number, the heavier the weight. If the weight of the radiation shield is heavy, the burden and cost of transportation and work will increase and the cost will be high. Also, an object with a larger atomic number is more expensive. In addition, the costs of manufacturing a structure having mechanical strength to shield environmental radioactive contaminants, radioactive waste, and radioactive substances using an object having a large atomic number are high. For this reason, it is desired to develop a radiation shielding material that is inexpensive and lightweight even if it contains a substance having a large atomic number.

Japanese Patent Application Laid-Open No. 2015-125143 In the document, it is specified that rock wool and mineral fibers are provided as a water-retaining base material inside the structure, and it is presumed that the effect of reducing radiation transmission is obtained by containing water. Further, the radiation transmission reducing effect of the document is shown to have a radiation shielding effect due to the weight of the water-retaining substrate. That is, the invention of the present document is an invention useful for radiation shielding by a water-retaining base material integrated with a structural material and water content, but it is predicted to what extent rock wool and mineral fibers themselves can obtain a radiation transmission reducing effect. Not.

In that respect, in the present invention, rock wool or a molded product obtained by compressing rock wool is invented to exert an effect on reducing radiation shielding, and therefore the present invention is not included in the invention of the present document and is exceptional. Is the invention of.
Further, although the invention of a container for storing radioactive substances, environmental radioactive contaminants, and radioactive waste is specified in the document, the cross-sectional shape of the outer wall plate constituting the container of the present invention is mountain-folded or valley-folded. It is a new invention characterized by a bellows structure plate, a folded plate shape, and an uneven fold, and although this outer wall plate is a thin plate, it has sufficient mechanical strength against a load from above. Stacking of multiple containers is possible.

That is, in the art, heavy-duty containers using metals with large atomic numbers and concrete containers with large wall thickness were common, but the container of the present invention is a structural plate as shown above. It is the invention of a new lightweight container that makes it possible to reduce the weight and manufacturing cost, and therefore to effectively utilize the space above the rare land that is indispensable for waste treatment.

The purpose is to provide radiation transmission reducing materials useful for public exposure protection of nuclide radiation, occupational exposure protection, medical exposure protection, and structures related to radioactive waste treatment using lightweight mineral fibers and artificial mineral fibers. do.

The radiation shielding reduction base material and the radioactive material attenuation body of the invention of claim 1 are a radiation shielding reduction base material and a radioactive material attenuation body, characterized in that the material having reduced radiation transmission is rock wool.

The radiation shielding reduction base material and radioactive material according to claim 1, wherein the radiation shielding reduction base material and the radioactive substance attenuated according to claim 2 have a density of the rock wool material of 10 kg / m3 or more. It is a decaying body.

The radiation shielding reduced body and the radioactive substance attenuated body of the invention of claim 3 have a chemical composition (% by weight) of SiO2 having a content of 35 to 45%, Al2O3 having a content of 10 to 20%, and Fe2O3 having a content of 0 to 3. The radiation shielding according to claim 1 or 2, wherein the rock wool contains%, MgO content of 4 to 8%, CaO content of 30 to 40, and MnO content of 0 to 1%. It is a reduced base material and a radioactive material attenuater.

The radiation shielding reducing body and the radioactive substance dampening body of the invention of claim 4 are made by compressing mineral fibers containing rock wool or granular cotton of rock wool so as to have a high density, out of 10 kg / m3 to 4000 kg / m3. The radiation shielding reduction base material and the radioactive substance attenuator according to claim 1 to 3, which are molded to the weight value of any one of the above.

The radiation shielding reducing body and the radioactive substance dampening body of the invention of claim 5 are formed by compressing or squeezing so that the water-containing mineral fiber or the water-impregnated rock wool remains. The radiation shielding reduction base material and the radioactive substance attenuator according to claim 1 to 4.

The radiation shielding reduction body and the radioactive substance attenuator of the invention of claim 6 are a mixture of a granular molded body of rock wool and a radioactive substance or a contaminant contaminated with a radioactive substance, or a granular substance or a radioactive substance in the mixture. A mixed constituent base material made by mixing any of powdered microcrystalline carbon, dromite, raw lime, talc, and boron is pressed and compressed, or the constituent base material is compressed in the vertical direction, the horizontal direction, or all. It is a radiation shielding reduction base material and a radioactive material attenuator, which are formed by forming multiple layers in the direction and laminating and compressing them.

In the radiation shielding reduction base material and the radioactive substance attenuated body of the invention of claim 7, water is formed on the surface of the fine crystalline carbon having a granular size of 2 mm to 0.1 mm or 50 μm to 1 μm in powder form. It is a radiation shielding reduction base material and a radioactive material attenuator, which are characterized by having the above.

From claim 1, the radiation shielding reduction base material and the radioactive substance attenuator of the invention of claim 8 are formed by impregnating water or water containing a radioactive substance so as to remain. 9. The radiation shielding reduction base material and the radioactive substance attenuator according to 9.

The invention according to claim 9, wherein the radiation shielding reduction base material and the radioactive substance attenuator container have a sealing lid for preventing the filling inside the container from leaking to the outside of the container. A mixed constituent base material made by mixing any one of them or a plurality of the types according to claims 1 to 8 is filled, and radioactive waste is inserted into the mixed constituent filled base material, or radioactive substances are mixed. It is a radiation shielding reduction base material and a radioactive material attenuator container characterized by injecting the contained water.

The radiation shielding reduction base material and the radioactive substance-attenuating body bag of the invention of claim 10 have a sealing lid so that the filling inside the bag does not leak to the outside of the bag, or the end of the filling opening of the bag is heated. The inside of the crimped bag is filled with a mixed constituent base material obtained by mixing any one of claims 1 to 9 or any of the above claims 1 to 8, and the mixing thereof is performed. Composition A radiation shielding reduction base material and a radioactive material dampening body bag characterized by inserting and mixing radioactive substances into a filling base material or injecting water containing radioactive substances.

The radiation shielding reduction and radioactive substance attenuating body container or bag body of the invention of claim 11 has a function of communicating the internal space of the container or bag body with the outside, or a part of the lid attached to the container or bag body is used. Since it has a function of communicating the internal space with the outside, at least one of a water inlet, an air vent, and a gas vent is provided in the material portion of any of the container, the bag, and the lid. The radiation shielding reduction base material and the radioactive substance attenuating body container or bag according to any one of claims 9, 10 or 12 to 17, characterized in that.

The container for storing the environmental radioactive contaminants and radioactive substances of the invention of claim 12 is erected on the upper end portion of the bottom wall plate having at least one outer wall plate body consisting of at least one body. A fitting portion is formed between the upper and lower axial ends of the outer side wall plate body to enable connection with the other outer wall plate body by fitting with the same or the same other outer wall plate body. Container The shape of the container or the shape of the box is formed.
In the gap between the outer wall plate and the outer wall plate arranged on the center side of the bottom wall plate so as to recede from the outer wall plate to the center side of the bottom wall plate, and inside the inner wall plate. A gap area between the upper surface of the radioactive substance or the radioactive substance contaminated in the container to be stored or the lower surface of the lid and the lower surface of the container and the upper surface of the bottom wall plate. It is characterized in that a plurality of radioactive shielding reduction base materials and radioactive material attenuating body containers according to claim 9, 10 or 11 are provided, or a plurality of radioactive shielding reducing and radioactive material damping body bags are provided. It is a container for storing environmental radioactive contaminants and radioactive substances.

The radiation shielding reduction base material and the radioactive substance attenuation container body of the invention of claim 13 have the plurality of outer wall plates and the said one by fitting the lower end portions of the plurality of outer wall plate bodies with the upper end portions of the bottom wall. The plurality of outer wall plates and the bottom wall and the inside of the container shape or the box shape are formed in a container shape or a box shape in which a fitting portion that enables connection of the bottom wall plates is formed. The radiation shielding reduction base material and a radioactive substance attenuation container body according to claim 12, which are characterized in that the wall plate body is configured as an assembly / unpacking method that enables separation.

In the radiation shielding reduction base material and the radioactive substance attenuation container body of the invention of claim 14, the outer wall plate body is a metal plate, a resin plate, a plate body formed by combining carbon fiber and resin, and a hollow structure-shaped plate. The body or a metal plate, a resin plate, or a plate made by combining carbon fiber and resin is divided into equal parts multiple times, and the bellows structure plate is mountain-folded or valley-folded, or a folded plate shape or unevenness. The radiation shielding reduction base material and the radioactive substance attenuation container body according to claim 12 or 13, which are folded structural plates.

The radiation shielding reduction base material and the radioactive substance attenuation container body of the invention of claim 15 are the outer wall plate body, and the inner side wall plate body is a bellows structure in which the resin plate is divided into equal parts a plurality of times, and is mountain-folded and valley-folded. Plate body or folded plate shape body, hollow structure shape plate body, unevenly folded metal plate, resin plate, plate body made by combining metal and resin, glass plate, carbon fiber and resin combined processing A heat insulating material, a hollow structure plate, or a plate-like body is provided on the inner side surface region of the plate body or the inner side surface of the outer wall plate body according to claim 13. The radiation shielding reduction base material and the radioactive substance attenuation container body according to claims 11 to 13.

The radiation shielding reduction base material and the radioactive substance attenuation container body of the invention of claim 16 are among a bellows structure plate body having a mountain fold and a valley fold cross section, a fold plate shape body, and an outer wall plate body having an uneven fold. Of the flat plate-shaped body (band), chevron plate (angle), unequal-sided chevron, groove-shaped body (channel), and hat that are fitting members at one end of the cross-sectional shape or one end of the cross-sectional shape. Any one of them is provided by welding, bonding, heat welding, screw, bolt, or nut fixing method.
On the upper surface of the end of the bottom wall plate, a chevron plate with a bending plate angle of right angle or less for fitting the fitting member, an unequal side chevron with a bending plate angle of right angle or less, a groove shape (channel), and a hat. The radiation shielding reducing base material according to claims 12 to 15, wherein any of the above is provided by a method of welding, bonding, heat welding, rivets, screws, bolts, or nuts. It is a radioactive material attenuation container body.

In the radiation shielding reduction base material and the radioactive substance attenuation container body of the invention of claim 17, a lid is installed on the upper end surface of the outer wall plate in which the outer wall plate is provided on the upper surface of the end portion of the bottom wall plate. , Bolts for fixing, flat plate-shaped body (band) with through holes for providing fixtures for nuts, chevron plate (angle), unequal side chevron, groove-shaped body (channel), hat Any of them are provided by welding, bonding, heat welding, rivets, screws, bolts, or nuts.
The radiation shielding according to claims 12 to 16, wherein a through hole for providing a plurality of bolts and nut fixtures is provided at an end portion of a lid body installed on the upper surface of the outer wall plate. Reduced substrate and radioactive material attenuation container body.

In the radiation shielding reducing base material and the radioactive substance attenuating body of the invention of claim 18, the radiation transmission reducing fiber is either an inorganic fiber or an organic fiber, and the radiation transmission reducing fiber is described in claims 1 to 8. It is a radiation shielding reduction base material and a radioactive material attenuator, which are characterized by covering the surface of any one of them.

In the radiation shielding reduction base material and the radioactive substance attenuator of the invention of claim 19, the mineral having a high electric resistance value and excellent electric insulation property, or a material having a reduction in radiation transmission belonging to the mineral is dolomite or talc (talc). ), Which is a radiation shielding reduction base material and a radioactive substance dampening body, which are powders and granules made of any of the above-mentioned minerals, dolomites and talc.

The radiation shielding reduction base material and the radioactive substance attenuator of the invention of claim 19 are powdered or semi-fibred dolomites and talc (sinters) having a granular size of 5 mm to 0.1 mm or 50 μm to 1 μm. A radiation shielding reduction base material and a radioactive material attenuation body, characterized in that water is adhered to any surface of talc).

As described above, according to the radiation shielding reduction base material, the radioactive material dampening body, the radioactive material dampening body container or bag body, and the radioactive material dampening body container body of the present invention, the molded body made of rock wool material and rock wool material is formed. In terms of chemical composition (% by weight), SiO2 has a content of 35 to 45%, Al2O3 has a content of 10 to 20%, Fe2O3 has a content of 0 to 3%, MgO has a content of 4 to 8%, and CaO has a content of CaO. Since 30 to 40 and Mn0 are contained in an amount of 0 to 1%, a radiation shielding effect is exhibited.
Further, as an example of reducing radiation shielding, a rock wool granule having a thickness of 15 cm (density 0.
As a result of covering the land surface where radiation is radiating from the ground with a mixed molded body having a density of 0.30 to 0.36 g / cm3, which is obtained by compressing 2 g / cm3), the air dose is 35 to 40 immediately after the covering is applied. It was confirmed by the monitoring post (installation location, latitude 37.758934 longitude 140, 44704 height 50 cm) managed and measured by the Nuclear Regulation Authority that the reduction was about%. In addition, the effect of reducing radiation transmission of the rock wool fiber molded body has been confirmed by performing a measurement similar to the above on the land where radiation is emitted near the installation location of the monitoring post.
In addition, as the density of rock wool increases, the number of rock wool fibers in a unit volume increases and the resistance of air flow increases, so the electrical resistance value becomes extremely high and the electrical insulation increases. Since it can be presumed to be absorbed, it has a radiation shielding effect.
Further, the present invention can be utilized for various radiation shielding applications. In addition, because it is lightweight, the transportation and work load are reduced.
In addition, the rock wool fiber material of the present invention and its molded body store and store radioactive waste on roofs, walls, doors, floors or radiation protective clothing, protective aprons, shelters and medical treatment where radiation is emitted. It also has a synergistic effect that can be used as a radiation protection material for the walls, roofs and floors of facilities.

FIG. 1 is a cross-sectional view according to Embodiments 1 to 4 of the present invention. FIG. 2 is a cross-sectional view according to the fifth embodiment of the present invention. FIG. 3 is a cross-sectional view according to a sixth embodiment of the present invention. FIG. 4 is a cross-sectional view according to the seventh embodiment of the present invention. FIG. 5 is a cross-sectional view according to embodiments 6 and 8 of the present invention. FIG. 6 is a cross-sectional view according to embodiments 10 and 11 of the present invention. FIG. 7 is a cross-sectional view according to the tenth embodiment of the present invention. FIG. 8 is a perspective view according to embodiments 9.10, 11 of the present invention. FIG. 9 is a perspective view according to embodiment 9.10 of the present invention. FIG. 10 is a perspective view according to embodiments 9, 10 and 11 of the present invention. FIG. 11 is a perspective view according to embodiments 9, 10 and 11 of the present invention. FIG. 12 is a perspective view according to embodiments 9, 10 and 11 of the present invention. FIG. 13 is a perspective view according to embodiments 9, 10 and 11 of the present invention. FIG. 14 is a perspective view according to embodiments 11 to 17 of the present invention. FIG. 15 is a cross-sectional view according to embodiments 13 and 14 of the present invention. FIG. 16 is a perspective view according to embodiments 11 to 17 of the present invention. FIG. 17 is a perspective view according to embodiments 11 to 17 of the present invention. FIG. 18 is a partial cross-sectional view according to embodiments 11 to 17 of the present invention. FIG. 19 is a cross-sectional view according to embodiments 11 to 17 of the present invention. FIG. 20 is a cross-sectional view according to embodiments 11 to 17 of the present invention. FIG. 21 is a cross-sectional view and a perspective view according to embodiments 11 to 17 of the present invention. FIG. 22 is a cross-sectional view according to embodiments 9, 10 and 11 of the present invention. FIG. 23 is a cross-sectional view according to another embodiment.

<First Embodiment>

A radiation shielding reduction base material and a radioactive material attenuator, characterized in that the material having reduced radiation transmission is rock wool.

Since rock wool fibers have fine pores and voids, it can be inferred that they have a function of absorbing electron waves, which is preferable for shielding radiation.
In addition, artificial mineral fibers that do not form a bonding agent for fiber molding are preferable for permanent radiation shielding because they are not affected by the environment and hardly deteriorate.

<Second embodiment>
The radiation shielding reduction base material and the radioactive material attenuating body according to claim 1, wherein the density of the rock wool material is 10 kg / m3 or more, are preferable because they can be lightweight shielding bodies.
It is also useful because it has excellent fire resistance and can withstand use in high temperature regions.
It should be noted that FIG. 1 is a diagram showing the difference in the density of the rock wool granular material and the difference in the grain shape due to the compression processing.

<Third embodiment>
The chemical composition (% by weight) is such that SiO2 has a content of 35 to 45%, Al2O3 has a content of 10 to 20%, Fe2O3 has a content of 0 to 3%, MgO has a content of 4 to 8%, and CaO has a content of 30. 40. The radiation shielding reduction base material and radioactive substance attenuator according to claim 1 or 2, which are rock wool containing 0 to 1% of MnO, are useful for radiation shielding as described above. Since it contains a material, it is preferable for reducing shielding.

<Fourth Embodiment>
A claim characterized in that mineral fibers containing rock wool or granular cotton of rock wool are compressed to a high density and molded to a weight value of any one of 10 kg / m3 to 4000 kg / m3. Items 1 to 3 are preferable because the radiation shielding reduction base material and the radioactive substance attenuating body are more subjected to the radiation shielding effect by being compression-molded as described above.

In addition, rock wool is easy to compress because it is mainly made of basalt and other natural minerals, iron furnace slag, and blast furnace slag. The higher the density of rock wool, the larger the number of rock wool fibers in a unit volume, and the higher the resistance of air flow, the higher the electrical resistance value and the higher the electrical insulation, which is preferable for shielding radiation.

Further, as a molding method, it is preferable to compression-mold the rock wool fiber itself using a known compression machine or a heavy machine, but the method is not limited to this method, and the bonding material or the resin is locked during compression. It may be molded by spraying and adding to wool fibers.
Further, for example, a form in which inorganic fibers and organic fibers are mixed and compression-molded may be used.

<Fifth Embodiment>
The radiation shielding reducing base material according to claims 1 to 4, wherein the mineral fiber moistened with water or the rock wool moistened with water is compressed or squeezed so as to retain the water content, and is molded. And the radioactive substance attenuator is preferable because it contains water, which is a compound of hydrogen and oxygen, which is preferable for shielding neutron rays.
In addition, water-containing rock wool is desirable for waste reduction because it can be reused for soil improvement and greening soil at disposal.

<Sixth Embodiment>
A mixture of a granular molded body of rock wool and a radioactive substance or a contaminant contaminated with a radioactive substance, or a mixture of fine crystalline carbon, dolomite, fresh lime, talc, and boron consisting of a granular substance or a powder in the mixture. It is molded by applying pressure to a mixed constituent base material made by mixing any of them and compressing it, or by forming multiple layers of the constituent base material in the vertical direction, the lateral direction, or the omnidirectional direction and laminating and compressing them. It is preferable to mix any of dromite, fresh lime, talc, and boron for the radiation shielding reduction base material and the radioactive substance attenuator, which are characterized by radiation shielding.

In addition, dolomite and talc each have an effect of contributing to radiation shielding. The reason for this is that, as specified in the rock wool molded body as described above, the electric resistance value is high and the electric insulation property is excellent, so that it is preferable to form the rock wool granular molded body in multiple layers.

<7th embodiment>
Radiation shielding reduction base material and radioactive material characterized by the adhesion of water to the surface of powdered fine crystalline carbon having a granular size of 2 mm to 0.1 mm or 50 μm to 1 μm. The attenuated body is preferable because it can be presumed that it is useful for shielding radiation due to the inclusion of water in the surface or pores of the activated carbon and the ionic effect of the activated carbon.

<8th embodiment>
The radiation shielding reduction base material and the radioactive substance attenuator according to claims 1 to 9, which are formed by impregnating water or water containing a radioactive substance so as to remain, have a water content. It is preferable for stable storage and long-term storage because water containing radioactive substances can be retained in a static state in rock wool, which is excellent in quality.

<9th embodiment>
One of the items according to claims 1 to 8 or a plurality of types according to claims 1 to 8 are placed inside the container having a closed lid so that the filling inside the container does not leak to the outside of the container. A radiation shielding reduction base material and a radioactive substance, which are characterized by filling a mixed composition base material made of a mixture and inserting radioactive waste into the mixed composition base material to be mixed or injecting water containing a radioactive substance. The dampening container is made by injecting radioactive waste or water containing radioactive substances into a container selected from plastic, metal, glass, carbon fiber and resin, stone composite base material, stone, concrete, and wood materials. , Preferred for stable storage and storage.

In addition, when designing a concrete container, a silica material finer than general cement particles, which is a well-known highly watertight concrete and can be molded with extremely few air bubbles and voids inside the concrete, is distributed among the cement particles. If concrete is selected, the diffusion coefficient of water will be 1/9 of that of conventional concrete, and evapotranspiration from stored items and deterioration of water vapor in the installation location environment can be reduced, and a container with a useful life of 300 years can be manufactured. Preferred for long-term storage of waste.
It is more preferable to select a container having multiple layers by combining a container of concrete, carbon fiber, resin, and stone having few voids, because the service life is further increased.
In addition, the box body made by hollowing out stones and minerals made by our predecessors from ancient times, and the box body made of stone and mineral plate-like bodies on the bottom wall and side walls and joining the ends of each are also radioactive. Preferred for long-term storage of waste.
Further, a container in which a stainless steel container and a resin container are stacked in multiple layers is also preferable.

<10th embodiment>
Any one of claims 1 to 9 is provided inside the bag, which is formed by constructing a sealing lid so that the filling inside the bag does not leak to the outside of the bag, or by heat-pressing the end of the filling opening of the bag. Alternatively, a mixed constituent base material obtained by mixing any of the items according to claims 1 to 8 is filled, and a radioactive substance is inserted into the mixed constituent base material to be mixed, or water containing the radioactive substance is injected. For the radiation shielding reduction base material and the radioactive substance attenuating body bag, which are characterized by the above, the invention is made by selecting a synthetic resin of polyolefin or fluororesin, or a bag in which a synthetic resin or a synthetic resin is coated with a metal foil. Once done, it is preferred for storage and storage of radioactive waste or water containing radioactive substances. As the material of the bag body, it is preferable to select a material having waterproofness, durability, and tensile strength.

<11th embodiment>
The container, bag, and lid have a function of communicating the inside space of the container and the bag with the outside, or because a part of the lid attached to the container and the bag has a function of communicating the inside space and the outside. The invention according to any one of claims 9, 10 or 12 to 17, wherein the material portion of any one of the above is provided with at least one of a water inlet, an air vent, and a gas vent. The radiation shielding reduction base material and the radioactive substance attenuating body container or bag body are preferable because the gas and water generated inside the container or bag body can be discharged to the outside. Further, the method of fixing the members of the water inlet, the air vent, and the gas vent to the container or the bag is attached by a known method suitable for each member of the water inlet, the air vent, and the gas vent, the material of the container or the bag. It is good. As an example, if the material is resin, thermocompression bonding or selection of an adhesive is preferable, and if the material is metal, rivets and welding are preferable.

<12th embodiment>
An outer wall plate body consisting of at least one body is erected on the upper end portion of the bottom wall plate consisting of at least one body, and the same or the same other outer wall plate body is located between the upper and lower axial end portions of the outer wall plate body. A container container shape or a box body shape formed by forming a fitting portion that enables connection with the other outer wall plate body by fitting with the outer side wall plate is formed.
Inside the gap between the outer wall plate and the outer wall plate arranged on the center side of the bottom wall plate so as to recede from the outer wall plate to the center side of the bottom wall plate, and inside the inner wall plate. A gap area between the upper surface of the radioactive material or the radioactive material contaminated in the container to be stored or the lower surface of the lid and the lower surface of the container and the upper surface of the bottom wall plate. It is characterized in that a plurality of radiation shielding reduction base materials and radioactive material damping material containers according to claim 9, 10 or 11 are provided, or a plurality of radiation shielding reduction base materials and radioactive material damping material bags are provided. Environmentally radioactive contaminants and containers for storing radioactive substances are preferable because they require less work personnel for assembly and unpacking.

The material of the outer wall plate body, the bottom wall plate, the inner side wall plate, and the container body to be stored inside the inner side wall plate body configured in this embodiment will be described in the ninth embodiment described above ([0042]]. It is preferable to select one of the materials obtained from [0043].
In addition, use screws, bolts, nuts, and all screw rods to fix the fitting points or other fixing points at the places where the outer wall plate body, bottom wall board, and inner wall plate are fitted or fixed. It is preferable to fix it.

<13th embodiment>
A container shape in which a fitting portion that enables connection between the plurality of outer wall plates and the bottom wall plate is formed by fitting the lower end portions of the plurality of outer wall plates and the upper end portion of the bottom wall. Alternatively, it is formed in a box shape, and is configured as an assembly / unpacking method capable of separating the plurality of outer wall plates, the bottom wall, and the inner side wall plate of the container shape or the box shape. The radiation shielding reduction base material and the radioactive material attenuation container body according to claim 12, which are characterized by the above, are preferable because the number of working personnel may be small for assembly and unpacking.

The material of the outer wall plate body, the bottom wall plate, the inner side wall plate, and the container body to be stored inside the inner side wall plate body composed of this embodiment is among the materials described in the above-mentioned ninth embodiment. It is preferable to select one of the above.
Further, as described in the twelfth embodiment, screws, bolts, nuts, and all screw rods are used to fit the outer wall plate body, the bottom wall plate, and the inner side wall plate at the fitting place or the fixing place. It is preferable to fix the fixed part or other fixed parts.

<14th embodiment>
The outer wall plate is a metal plate, a resin plate, a plate formed by combining carbon fiber and resin, a hollow structure-shaped plate, or a metal plate, a resin plate, and carbon fiber and resin are combined and processed. The present invention according to claim 12 or 13, wherein any of the above-mentioned plates is a bellows-structured plate having mountain folds and valley folds a plurality of times in equal divisions, or a fold-shaped or unevenly folded structural plate. The radiation shielding reduction base material and the radioactive substance attenuation container body are preferable because they require less work personnel for assembly and unpacking.
Further, it is preferable because the same container body can be stacked in a plurality of layers depending on the mechanical strength.

For this bellows structure plate, a metal plate with a thickness of about 0.3 mm to 2 mm can be selected. Even with such a thickness, for example, the container body is designed so that the weight of the stored items can be up to 3000 kg and the total load of the stack can be up to 8000 kg. Is preferable for weight reduction because it can be manufactured.

<Fifteenth Embodiment>
The outer wall plate and the inner side wall plate are made of a bellows-structured plate that is mountain-folded or valley-folded multiple times by dividing the resin plate into equal parts, or a folded plate-shaped body, a hollow-structured plate, or a metal that is unevenly folded. It is any of a plate, a resin plate, a plate made by combining a metal and a resin, a glass plate, and a plate made by combining a carbon fiber and a resin, and is an inner side surface region of the plate or a claim. The radiation shielding reduction base material and radioactivity according to claims 11 to 13, wherein any of a heat insulating material, a hollow structure plate, and a plate-like body is provided on the inner surface of the outer wall plate body according to item 13. The material attenuation container body is preferable because the same container body can be stacked in a plurality of layers depending on the mechanical strength.

When a hollow structure-shaped plate is selected for the outer side wall plate and the inner side wall plate, the hollow structure-shaped plate is preferable because it has mechanical strength. If multiple metal rods, metal plates, or metal foils are inserted into the multiple spaces in the area between the ribs of the hollow structure plate and the front and back plates, the weight of the plate will increase, but the radiation shielding effect will also increase. preferable.

<16th embodiment>
Fitted into one end of the cross-sectional shape or one end of the cross-sectional shape of any of a bellows structure plate having a mountain fold and a valley fold, a fold plate shape, and an outer wall plate having an uneven fold. Weld, bond, heat weld, screw, bolt, or nut to any of the flat plate (band), angle plate (angle), unequal side angle, groove (channel), and hat that are the members. It is provided by the fixing method of
On the upper surface of the end of the bottom wall plate, a chevron plate with a bending plate angle of right angle or less for fitting the fitting member, an unequal side chevron with a bending plate angle of right angle or less, a groove shape (channel), and a hat. The radiation shielding reducing base material according to claims 12 to 15, wherein any of the above is provided by a method of welding, bonding, heat welding, rivets, screws, bolts, or nuts. The radioactive material attenuation container body is preferable because it is a lightweight body and the same container body can be stacked in a plurality of layers depending on the mechanical strength.

In order to stack the container bodies in a plurality of layers, the bottom wall end portion of the container body is stacked on the container body in which the protrusion member is fitted or fitted into the right angle portion of the upper surface of the lid formed of the container body and fixed. A through hole is opened near the end of the square tube (aggregate) fixed to the through hole (at the same position as the above-mentioned protrusion member position), and the protrusion member of the container body lid having the through hole below has a through hole. The upper and lower containers can be stably placed at that position by inserting the container body, so that the container body having this configuration is preferable for long-term storage.

<17th embodiment>
A through hole for providing a fixing tool for bolts and nuts for installing and fixing a lid is opened on the upper end surface of the outer wall plate in which the outer wall plate is provided on the upper surface of the end portion of the bottom wall plate. Weld, bond, heat weld, rivet, screw, bolt, or nut any of the flat plate (band), angle plate (angle), unequal side angle, groove (channel), and hat. It is provided by the fixing method,
The rock wool molded body according to claims 12 to 16, wherein a through hole for providing a plurality of bolts and nut fixtures is provided at an end portion of a lid body installed on the upper surface of the outer wall plate. Moreover, it is preferable because the same container body can be stacked in a plurality of layers depending on the mechanical strength.
When steel sheet is selected as the material of the present invention, it is recommended that the surface of the metal be hot-dip galvanized in order to prevent corrosion of the metal.

<18th embodiment>
The radiation-transmitting reducing fiber is either an inorganic fiber or an organic fiber, and the radiation-transmitting reducing fiber covers the surface of any one of claims 1 to 8. The shield-reducing base material and the radioactive substance dampening body include ceramic fibers, glass fibers, carbon fibers (carbon fibers), and metal fibers (materials are iron alloys, nickel, chromium alloys, tungsten) made of inorganic substances as materials belonging to the fibers. (Alloys, copper alloys) and the like belong to inorganic fibers, and among them, fibers made of tungsten alloys are preferable for reducing radiation shielding.

In addition, cotton, linen, silk and the like for organic natural fibers made of organic substances, and aramid, polyamide, polyester, polyethylene, acrylic, rayon and the like for synthetic fibers belong to the organic fibers. In addition, rock wool can be obtained by coating, packaging, and packing the surface of the rock wool molded body with a fiber laminated composite in which one of the above-mentioned fiber materials is selected or a plurality of the above-mentioned fiber materials are selected. It is preferable because the strength of the molded body is increased, which is preferable for transportation and movement, and it can be presumed that the radiation shielding effect is increased.
The rock wool molded body coated with this fiber material is preferable because it can be used for radiation protection clothing and radiation protection aprons, and is useful for occupational exposure protection and medical exposure protection.

In addition, radioactively contaminated water is permeated into rock wool and fiber-coated rock wool moldings, and the rock wool and rock wool moldings (fiber coverings) are submerged in a pond where radioactive substances are settled, or radioactive substances are soiled. It is preferable to install a rock wool molded body (fiber coating) near the bottom of drainage channels, side ditches, manholes, and irrigation canals where soils that are attached to, deposited, and assimilated on trees, leaves, and branches are present. ..

<19th embodiment>
A mineral having a high electrical resistance value and excellent electrical insulation, or a material belonging to the mineral having reduced radiation transmission is dolomite or talc, and the mineral or dolomite or talc is among the minerals or talc. The radiation shielding reduction base material and the radioactive substance attenuating body, which are characterized by being powder or granules composed of either of them, have the effect that each of fresh lime and talc contributes to radiation shielding. The reason for this is that as described above in the rock wool molded body, dolomite and talc have high electrical resistance and excellent electrical insulation, which is preferable for reducing the shielding of nuclide radiation.

<20th embodiment>
Water is attached to the surface of any of the calcined or semi-baked, light-baked dolomite, and talc, which are in the form of powder with a granular size of 5 mm to 0.1 mm or 50 μm to 1 μm. The radiation shielding reduction base material and the radioactive material attenuater are characterized in that magnesium oxide, which is a component of dolomite fired at high temperature, has excellent moisture resistance and electrical insulation, and neutrons are produced by adhering water to the material. Since it is speculated that the effect of reducing the shielding of the line is exhibited, it is preferable for reducing the shielding of the nuclear species radiation.

<Other Embodiment 1>
Select one of radioactive contaminated water containing tritium, which is trihydrogen, radioactive material, radioactive waste, water containing radioactive material, and sludge containing radioactive material in order to reduce the exposure of workers from nuclear species radiation. The specified sealable container or sealable bag by operating the above-mentioned mechanical equipment of any of the above-mentioned automatic filling and packaging electric equipment, remote manual filling and packaging machine equipment, and manual filling and packaging machine equipment for packaging purposes and packing purposes. The body packaging material is filled, and after the filling, a lid is attached to the filling injection port, or the filling injection port is hermetically closed by heat crimping. A method for transporting, storing, and storing radioactive waste that emits nuclear species radiation by selecting and using one of a shield-reducing base material and a radioactive substance-damping body, a container, a bag body, and a container.

<Other Embodiment 2>
Of the above claims 1 to 11, a folded plate structure plate is provided between the back plate body and the front plate body, and the inner region space of the back plate body, the front plate body, and the folded plate structure plate body is provided. It is a radiation shielding reduction plate structure base material characterized by being provided with any of the above.
The radiation shielding reduction plate structural base material is used for roofs, walls, doors, floors of building structures that store and store radioactive substances, environmental radioactive contaminants, and radioactive waste, or containers, containers, and lids for storing radioactive waste. It is intended to be used for the side wall, bottom wall, and lid of the container containing it, and also for the purpose of standing as a wall in and near the land where radioactive waste is stored. The plate-shaped structure of the other embodiment 2 is shown in the cross-sectional view of FIG. 23.
<The above-mentioned drawings according to the embodiment of the present invention include a transparent perspective view>

Rock wool granular cotton 10
Rock wool compressed granular cotton 11
Rock wool water-containing compression molded product 12
Dolomite 13
Microcrystalline carbon with water on the surface 14
Adhering water 15
Talc 16
Synthetic resin tube body (filled with rock wool) 17
Sealed thermocompression bonding site line 18
Waterproof hose shape 19
Insulok 20
Opening 21
Thin stainless steel drum 22
Lid 23
Belt 24
Bolts and nuts 25
Box (folding) 26
Surface layer carbon fiber resin multi-layer material 27
Inner side resin 28
Radioactive waste 29
Assembly and unpacking method container 30
Bottom wall 31
Hollow structure plate 32
Bellows structure metal side wall plate 33
Radioactive waste storage container 34
Degassing bubble 35
Bottom wall below the waist 36
Closure fixing bolt insertion through hole 37
Strut fitting angle 38
Side wall fitting part 39
Back thin plate 40
Table thin plate 41
Vent 42
All screw rods 43
Nut 44
Yamagata stick 45
Yamatani mountain shape steel plate 46
Screw 47
Metal container 48
Closure fixing bolt (with lifting tool mounting hole) 49
Radioactive material storage area 50
Fitting part 51
Rib 52
Cylindrical pipe 53
Pedestal 54
Pedestal reinforcement plate 56
All screw bar locking nut 57
Square tube 58
Warning triangle 59
Dotted line enclosure 60 to show internal structure
Flat plate (top surface) 61
Waterproof bag body 62
Resin box 63
Stone container 64

Claims (8)

A plurality of outer wall plates are erected on a bottom wall plate consisting of at least one body, or on the upper surface or side surface end under the waist of the bottom wall.
The same other outer wall plates are fixed to each other at the horizontal ends of the plurality of outer wall plates, or to each other's fitting portions formed at the horizontal ends of the plurality of outer wall plates. It is a box type in which the same other outer wall plate is fitted and fixed.
A plurality of square tubes are provided on the bottom wall plate or the bottom surface under the waist of the bottom wall.
A flat plate having a plurality of through holes for inserting a plurality of bolts is provided on the top surface in a state where the plurality of outer wall plates are erected.
A support angle for fitting the same outer wall plate or the same other outer wall plate between the upper and lower ends of the outer wall plate in the horizontal direction (reference numeral 38 in FIG. 16). Is provided,
The outer wall plate is provided with a side wall fitting portion (reference numeral 39 in FIG. 19) at the lower end of the outer wall plate.
An unequal-sided chevron with a bending plate angle of a right angle or less or a chevron plate with a bending plate angle of a right angle or less (angle) on the upper surface of the end of the bottom wall plate or the upper surface of the end below the waist of the bottom wall consisting of at least one body. , The side wall fitting portion (reference numeral 39 described in FIG. 19) of any of the grooved bodies (channels) is provided, and the bottom surface of the bottom wall plate (“reference numeral 31” described in FIG. 19 ) or the bottom wall waist. A plurality of square tubes (“reference numeral 58” described in FIG. 19 ) are fixed to the bottom surface of the lower portion (“reference numeral 36” described in FIG. 19 ) .
Fitting between column angles (reference numeral 38 described in FIG. 16) which are facing fitting members fixed to both ends in the horizontal direction of the plurality of outer wall plates, and fixed to the plurality of outer wall plates. The side wall fitting portion (reference numeral 39 described in FIG. 19) is fitted to the bottom wall plate or the side wall fitting portion fixed to the bottom of the bottom wall (“reference numeral 39” in FIG. 19). A radioactive waste storage container characterized by a box shape that is shaped to be combined. The outer shape of the outer wall plate is characterized by being a thin plate shape having a thickness of 0.3 mm to 2 mm, which is any one of a bellows structure plate shape, a flat plate shape, a folded plate structure plate shape, and an uneven folded structure plate shape. Item 1. The radioactive waste storage container according to Item 1. The radioactive waste storage container according to claim 1 or 2, wherein any of a heat insulating material, a hollow structure plate, and a flat plate-shaped body is provided on the inner side surface of the outer wall plate body. The outer wall plate body of the container is configured to stand on the bottom wall plate or the end portion below the waist of the bottom wall, and the lid is installed on the top surface of the outer wall plate body.
A plurality of through holes for inserting bolts are formed at the end of the lid body installed on the top surface of the outer wall plate body, and a flat plate or a chevron fixed to the top surface of the outer wall plate body. A bolt or a lifting tool mounting through hole is formed in a plurality of through holes formed in either a plate body ( angle ) or a groove shape ( channel ) and through holes formed at the end of the lid body. The radioactive waste storage container according to any one of claims 1 to 3, wherein the lid fixing bolts are inserted into the through holes of each other to fix the lid body to the outer wall plate body. A through hole is formed in the bottom surface of the square tube provided on the bottom surface of the bottom wall plate configured in the radioactive waste storage container.
A protrusion member is formed and fixed on the upper surface of the lid provided in another radioactive waste storage container that is the same as the radioactive waste storage container.
4. The fourth aspect of the invention is characterized in that the protrusion member is inserted into the through hole formed in the square tube and the radioactive waste storage container (the total load of the stacked stack can be up to 8000 kg, including the stored load) is stacked. Radioactive waste storage container described in . Outer wall plate, bottom wall, bottom wall under waist, square tube, lid, strut fitting angle, fitting material, side wall fitting member, hollow structure plate, bolt, nut constituting the radioactive waste storage container. , Screws, flat plates, angle plates (angles), irregular chevrons, grooves, and hats are made of metal, steel steel plates, or steel steel plates whose surface is hot-dip zinc-plated. The radioactive waste storage container according to any one of claims 1 to 5, wherein the material is selected from any of concrete, highly watertight concrete, plastic, glass, and carbon fiber. A method for fixing a plurality of the outer wall plates to an upper surface or a side surface end of a bottom wall plate composed of at least one body, or a horizontal end portion of the plurality of outer wall plates. A method of fixing the fitting member formed on the outer wall plate, a flat plate, a support fitting angle, a chevron plate (angle), an unequal side chevron, a groove (channel), and a hat on the outer wall plate. As the fixing method of any of the above and the fixing method of the square tube, any fixing material of welding, adhesion, heat welding or rivet is selected.
It is formed in any one of the plurality of outer wall plates, the bottom wall plate, and the bottom wall in order to be separated from the plurality of outer wall plates, the bottom wall plate, and the bottom wall under the waist. The fitting portions for fixing the fitting portions to form a box shape are fixed to each other with screws, bolts, or nuts.
The invention according to claim 1 to 6, wherein the box-shaped screw, bolt, or nut is removed so as to be separated from the plurality of outer wall plates, the bottom wall plate, and the bottom wall under the waist. One of the radioactive waste storage containers. Automatic filling and packaging electric machine for packaging and packaging purposes by selecting one of radioactively contaminated water containing tritium, which is triple hydrogen, radioactive substances, radioactive waste, water containing radioactive substances, and sludge containing radioactive substances. Operate the above-mentioned mechanical equipment of any of equipment, remote manual filling and packaging machine equipment, and manual filling and packaging machine equipment, and inside the sealable bag body, inside the specified sealable container, or sealable bag body packaging. One of the inside of the material is filled with any of the radioactively contaminated water containing the selected tritium, the radioactive substance, the radioactive waste, the water containing the radioactive substance, and the sludge containing the radioactive substance. A method for storing a form in which the lid is attached or the filling / injection port is hermetically closed by heat crimping into the radioactive waste storage container according to any one of claims 1 to 7.

Images