JP5337967B1 - Methods for decontamination and separation / recovery of radioactive materials - Google Patents

Abstract

The present invention provides a novel means capable of removing radioactive substances from a decontaminated material with high efficiency by a simple process while suppressing generation of new contaminated waste.
A method for decontaminating a radioactive substance according to the present invention includes contacting a decontaminated object contaminated with a radioactive substance such as radioactive cesium with sodium metasilicate in an aqueous medium. By the action of sodium metasilicate, radioactive material can be efficiently adsorbed and removed from the decontaminated material. If the radioactive substance in the washing waste liquid is precipitated and separated by filtration, the radioactive substance in the washing waste liquid can be reduced below the detection limit. Therefore, according to the present invention, it is possible to construct a circulation type decontamination system in which sodium metasilicate is added to the washing waste liquid from which the precipitate has been separated and recycled as the washing liquid.
[Selection] Figure 1

Description

  The present invention relates to a method for separating and removing a radioactive substance such as radioactive cesium from an object to be decontaminated.

  Conventionally, decontamination waste liquid is collected by decontaminating radioactive compounds containing radioactive cesium by jetting water to the decontamination object using a high-pressure pump, but radioactive substances containing radioactive cesium adhering to the decontamination object are collected. The efficiency of decontamination of compounds is not always satisfactory. The recovered decontamination waste liquid is filtered through an RO membrane (reverse osmosis membrane) to separate radioactive compounds containing radioactive cesium (especially cesium particles are 1 micron or less). Contains a lot of sand and dirt, and the RO membrane is clogged up quickly, so it is necessary to replace the RO membrane frequently, so there is a lot of radioactive waste contaminated with radioactive compounds including radioactive cesium. is there.

  Patent Document 1 describes the use of zeolite as an absorbent for heavy metals. Non-Patent Document 1 describes that an RO membrane (reverse osmosis membrane) is used as a filter medium. Neither affects the patentability of the present invention.

JP 2011-136411 A

Takuma Environmental Technology Study Group Editor Ohm Co., Ltd. Publishing August 20, 2000, p.108-172

  Radioactive compounds containing radioactive cesium are easy to dissolve in water, and it is difficult to separate and recover chlorides and other water-insoluble salts. Therefore, filtration using RO membranes and porous inorganic compounds such as It is a conventional method to adsorb and recover by a compound such as zeolite. These conventional methods have the above-mentioned problems, and furthermore, decontamination and collection work must be performed through separate steps, and decontamination work cannot be performed unless much time and money are spent.

  Accordingly, an object of the present invention is to provide a novel means capable of removing radioactive substances from a decontaminated material with high efficiency by a simple process while suppressing generation of new contaminated waste.

  As a result of diligent research, the inventors of the present application remove radioactive cesium from a decontaminated material with high efficiency by using a cleaning agent prepared by adding sodium metasilicate in an aqueous medium as a cleaning liquid for decontamination. As a result, the present invention was completed.

That is, this invention provides the decontamination method of radioactive cesium including contacting the to-be-contaminated material contaminated with radioactive cesium with sodium metasilicate in an aqueous medium.

  ADVANTAGE OF THE INVENTION According to this invention, the radioactive substance containing radioactive cesium can be separated and removed from a to-be-decontaminated material with high efficiency by a simple process process. According to the method of the present invention, the radioactive material in the cleaning waste liquid can be greatly reduced, so that the cleaning waste liquid can be flown into the sea as a harmless waste liquid instead of contaminated waste, and sodium metasilicate is added again. Thus, it can be recycled as the cleaning liquid in the present invention. If a circulation system that recycles the cleaning liquid is constructed, the work efficiency can be improved and the generation of contaminated waste can be greatly suppressed.

It is a schematic diagram showing an example of a circulation type decontamination system that performs high-pressure cleaning → recovery of cleaning waste liquid → separation of radioactive substances → recycling of cleaning liquid.

The object to be decontaminated in the present invention is not particularly limited as long as it is an object contaminated with a radioactive substance. Radioactive material is radioactive cesium.

  In the present invention, the object to be decontaminated is brought into contact with sodium metasilicate in an aqueous medium. If the object to be decontaminated is a solid object having a certain shape, a cleaning liquid prepared by adding sodium metasilicate into an aqueous medium is sprayed on the object to be decontaminated, or the object to be decontaminated is immersed in the cleaning liquid. do it. If the object to be decontaminated is an aqueous liquid (a liquid mainly composed of water), sodium metasilicate may be added to the object to be decontaminated. For example, solid sodium metasilicate may be added, A solution prepared by adding sodium acid in a high concentration to an aqueous medium may be used as a washing solution stock solution, and this may be mixed with an object to be decontaminated at an appropriate ratio. Any of these embodiments is encompassed by the term “contacting the decontamination product with sodium metasilicate in an aqueous medium”.

  The following is considered as a principle by which sodium metasilicate adsorbs radioactive cesium and the like. That is, since sodium metasilicate has a molecular structure similar to that of zeolite, it is considered that cesium is adsorbed by exchanging with cesium + → sodium +. However, the scope of the present invention is not limited by such a theory.

  The concentration of sodium metasilicate used (that is, the concentration in the system where the decontaminated product and sodium metasilicate are brought into contact with each other) may be about 10 mM to 1000 mM, for example, 10 mM or more, 20 mM or more, 30 mM or more, 40 mM or more. , Or 50 mM or more and 700 mM or less, 500 mM or less, 400 mM or less, or 300 mM or less. The washing solution stock solution can be prepared at an appropriate sodium metasilicate concentration depending on the concentration used.

  The cleaning liquid containing sodium metasilicate in an aqueous medium is not particularly limited as long as sodium metasilicate is added and dissolved and dispersed in the aqueous medium. Specifically, it may be one obtained by adding sodium metasilicate to pure water or tap water, or, for example, described in Patent No. 4590481, sodium metasilicate is added to water ionized using water as a raw material. Alkaline ion aqueous cleaning agents can also be used as the cleaning solution stock solution. The particle diameter of sodium metasilicate in the cleaning liquid is not particularly limited, but is usually 50 microns or less, specifically about 5 to 50 microns, for example, 10 microns or more, 20 microns or more, or 30 microns or more. 5 to 10 microns. Such an aqueous cleaning liquid can be produced by a known method. For example, according to the method for producing an aqueous cleaning agent using a homogenizer described in Japanese Patent No. 4699506, the particle diameter of sodium metasilicate in the cleaning liquid can be reduced.

  The radioactive substance adsorbed and removed from the object to be decontaminated with sodium metasilicate can be easily separated from the washing waste liquid by filtration. The pore diameter of the filter medium can be appropriately selected, and is usually about 1 to 50 microns, for example, about 2 to 20 microns, but is not limited thereto.

  When alkaline earth metal ions coexist in the washing waste liquid, a hydrate of silicic acid-alkaline earth metal is generated by reaction with alkaline earth metal ions, and the formation of precipitates containing radioactive substances is promoted. This reaction is usually completed within a few seconds to 10 minutes. Thereby, the efficiency which removes a radioactive substance by filtration from washing | cleaning waste liquid can be improved more. Therefore, in the present invention, it is preferable that alkaline earth metal ions coexist in the cleaning waste liquid. Alkaline earth metal ions may be included in the cleaning liquid from the beginning, or alkaline earth metal chloride may be added to the cleaning waste liquid after contacting the object to be decontaminated with sodium metasilicate. Earth metal ions may coexist. The specific method for allowing the alkaline earth metal ion to coexist can be appropriately selected according to the embodiment of the method of the present invention. Preferable examples of alkaline earth metal ions include calcium ions (calcium chloride), magnesium ions (magnesium chloride), and strontium ions (strontium chloride). The concentration at which alkaline earth metal ions coexist (for example, the amount of alkaline earth metal chloride used) may be selected as appropriate, as long as a sufficient amount that causes aggregation and precipitation in the washing waste liquid can be added, and is not particularly limited. . For example, when calcium chloride is used, a sufficient effect can be obtained by using about several tens of grams for 1 L of washing waste liquid.

  Also, aeration of air, oxygen, carbon dioxide, etc. in the cleaning waste liquid or in the cleaning liquid in which the decontaminated material is immersed promotes the formation of precipitates containing radioactive substances. The removal efficiency can be further increased.

  Use of alkaline earth metal ions and ventilation of air or the like may be performed either in combination or in combination.

  The cleaning waste liquid after separating the radioactive substance can be re-used as a cleaning liquid by adding sodium metasilicate (solid or high concentration cleaning liquid stock solution) again. According to the method of the present invention, radioactive substances in the cleaning waste liquid can be removed with very high efficiency, so that only the used filter material is required to generate contaminated waste, and the amount of contaminated waste can be greatly reduced. it can.

  Hereinafter, specific examples of embodiments of the method of the present invention will be described.

  For example, when the object to be decontaminated is a large object such as a building such as a reactor building, a road, or a vehicle, a cleaning liquid containing sodium metasilicate may be sprayed onto the object to be decontaminated using a high-pressure pump. The discharge pressure of the high-pressure pump is usually about 10 MPa to several hundred MPa, and may be, for example, 10 to 100 MPa, 20 to 50 MPa, or 20 to 40 MPa, but is not limited thereto, and can be appropriately selected. . Since radioactive substances are efficiently adsorbed and removed from the decontamination object by the action of sodium metasilicate, high-pressure cleaning at a relatively low discharge pressure is possible. Collect the washing waste liquid, add alkaline earth metal chloride, or ventilate the cleaning waste liquid with air or the like (this may be done in combination) to precipitate the radioactive material in the washing waste liquid. Separate by filtration. The washing waste liquid after separating the precipitate can be recycled as a washing liquid by adding sodium metasilicate (solid or high concentration washing liquid stock solution). The specific example shown in FIG. 1 is an example of a circulating decontamination system that performs high-pressure cleaning → recovery of cleaning waste liquid → separation of radioactive substances → recycling of cleaning liquid. Although the coagulation sedimentation process step by ventilation of alkaline earth metal ions or air is not shown in the figure, the coagulation sedimentation process step can be performed in the process before the filter 4 (for example, between 3 and 4).

  When the decontaminated material is soil collected from the contaminated area, incinerated ash containing radioactive materials, or a relatively small object, the decontaminated material may be immersed in the cleaning liquid. In the case of soil or incineration ash, immerse and wash the soil or incineration ash in the cleaning liquid, then separate the soil / incineration ash from the cleaning waste liquid, and then add alkaline earth metal chloride to the cleaning waste liquid. To form a precipitate. In the case of cleaning small objects such as instruments, alkaline earth metal ions may be allowed to coexist in the cleaning liquid from the beginning. Also in this aspect, it is possible to construct a circulation type decontamination system of cleaning the decontamination object in the cleaning tank → separating the radioactive substance from the cleaning waste liquid → reusing the cleaning liquid.

  If the decontamination product is a decontamination waste liquid (aqueous liquid containing radioactive material) generated by other known decontamination methods, or highly concentrated contaminated water generated in nuclear power plants, etc., What is necessary is just to add the washing | cleaning liquid undiluted | stock solution prepared by the solid or high concentration of sodium metasilicate to a decontamination thing so that a sodium metasilicate density | concentration may become said density | concentration range. By treating with the method of the present invention, radioactive substances contained in the waste liquid / contaminated water can be removed with high efficiency, so that the treated water can be flown into the sea and used for the regeneration of the washing liquid as described above. You can also.

Adsorption test data of cesium on sodium metasilicate Concentration of sodium metasilicate aqueous solution used for the sample An aqueous solution (cleaner, sodium metasilicate concentration: about 390 mM) in which 100 kg of sodium metasilicate nonahydrate was added to 900 L of pure water was used as a stock solution.

2. Examination of concentration used
All the analytical samples of (1) to (3) were filtered through a glass filter G5 (3 to 5 μm), and the cesium concentration was measured by atomic absorption.

(1) Sample A The cleaner was diluted 20 times and tested.
Cleaner stock solution 5mL + Cesium hydroxide (20ppm) 95mL
Test result: Cesium hydroxide (20ppm) became 19ppm.

(2) Sample B The cleaner was diluted 20 times and tested.
Cleaner stock solution 5mL + cesium hydroxide (20ppm) 95mL + calcium chloride (1g)
Test result: Cesium hydroxide (20ppm) became 9ppm.

(3) Sample C The cleaner was diluted 2 times and tested.
Aqueous solution (stock solution) 50mL + Cesium hydroxide (20ppm) 50mL + Calcium chloride (4g)
Test result: Cesium hydroxide (20 ppm) became 1 ppm or less below the lower limit of quantification.

  The present invention solved the problem of contamination of radioactive materials including radioactive cesium that spread throughout Fukushima Prefecture and neighboring prefectures caused by a major accident caused by the earthquake and tsunami of the Fukushima Nuclear Power Plant in a short period of time, and withdrew from the decontaminated materials This is a method capable of separating and recovering radioactive materials containing radioactive cesium with high efficiency. In addition, the radioactive waste containing radioactive cesium that has been collected and filtered can be disposed of only with the filter medium used, and thus the contaminated waste can be greatly reduced, which is extremely beneficial.

DESCRIPTION OF SYMBOLS 1 Washing waste liquid collection tank 2 Precipitate 3 Circulating pump 4 Filter 5 Pressure gauge 6 Pressure gauge 7 Filtration tank 8 Pressure gauge 9 Reclaimed water tank 10 Sodium metasilicate water tank 11 Circulation pump 12 High pressure pump 13 Injection recovery nozzle 14 Washing waste liquid collection vacuum pump

Claims (8)

A method for decontaminating radioactive cesium , comprising contacting a decontaminated object contaminated with radioactive cesium with sodium metasilicate in an aqueous medium. The method according to claim 1 , wherein the particle diameter of sodium metasilicate in the aqueous medium is 50 microns or less. The method of Claim 1 or 2 including spraying the washing | cleaning liquid which contains sodium metasilicate in an aqueous medium with respect to a to-be-decontaminated thing. The method of Claim 1 or 2 including immersing a to-be-decontaminated thing in the washing | cleaning liquid which contains sodium metasilicate in an aqueous medium. A the dividend dyed is an aqueous liquid, comprising adding sodium metasilicate into the dividend dyed, Method according to claim 1 or 2. The method according to any one of claims 1 to 5 , further comprising coexisting an alkaline earth metal ion in the washing waste liquid after the object to be decontaminated and sodium metasilicate are brought into contact with each other. The method according to any one of claims 1 to 6 , further comprising filtering the washing waste liquid after contacting the material to be decontaminated with sodium metasilicate to separate the precipitate. The method according to claim 7 , further comprising adding sodium metasilicate to the washing waste liquid after separating the precipitate and reusing it as a washing liquid.

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