JP5293863B2 - Cesium adsorbent and method for producing the same - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a cesium adsorbent made to efficiently supports a metal ferrocyanide compound having superior cesium adsorbing performance, and a method of manufacturing the same. <P>SOLUTION: There is provided the cesium adsorbent formed of a molding obtained from an insoluble metal ferrocyanide compound and a metal oxide. Further, there is provided the method of manufacturing the cesium adsorbent characterized in molding a mixture of the insoluble metal ferrocyanide compound and metal oxide and then solidifying the molding with heat. <P>COPYRIGHT: (C)2013,JPO&amp;INPIT

Description

  The present invention relates to a cesium adsorbent and a method for producing the same. More specifically, the present invention relates to a cesium adsorbent that has a high cesium adsorption capacity and can efficiently remove cesium from a large amount of waste liquid.

  Various methods are being studied for the recovery and removal of radioactive cesium from waste liquids generated from facilities related to the use of nuclear energy such as spent fuel reprocessing facilities. Radioactive cesium is produced by a fission reaction such as uranium 235, but it is an alkali metal that has a long half-life and is easy to elute, so it is contained in various treatment liquids at nuclear facilities. When waste liquid or treated water containing radioactive cesium flows into seawater or ponds, it contains a large amount of coexisting alkali metals such as sodium and potassium, and alkaline earth metals such as calcium. How to get rid of is eagerly desired.

  As a means for removing radioactive cesium from a liquid in which other metal ions coexist, such as seawater, it is well known that a metal ferrocyanide compound has an excellent cesium adsorption ability. However, since the metal ferrocyanide compound is generally a fine powder, it is difficult to use it as an adsorbent as it is. Therefore, it has been studied to use a metal ferrocyanide compound supported on a porous material or the like.

For example, Patent Document 1 describes the use of a combustible cesium adsorbent in which a metal ferrocyanide compound hardly soluble in water is deposited in the pores of activated carbon.
Patent Document 2 describes a cesium separation material having a high cesium adsorption capacity and carrying a copper salt-based water-soluble hexacyanoiron (II) salt in the pores of a porous carrier.
However, since the ratio of the metal ferrocyanide compound deposited in the pores of the activated carbon in Patent Document 1 is small, the amount of the metal ferrocyanide compound supported per unit volume of the activated carbon is small, so that the metal ferrocyanide compound is supported. The activated carbon has a low ability to adsorb cesium. In particular, when adsorbing cesium contained in a large amount of processing liquid, it is necessary to set the treatment time longer, so the adsorption efficiency is poor, and the practical aspect. Is not enough. Furthermore, when a solution containing cesium is treated, the deposited fine metal ferrocyanide or its ionized product may be eluted.
Similarly, in the hexacyanoferrate (II) copper-supported porous resin of Patent Document 2, the ratio of copper hexacyanoferrate supported on the porous resin is small, especially when cesium is adsorbed in a large amount of treatment liquid. Has poor adsorption efficiency and is insufficient in practical use, and when a solution containing cesium is treated, the deposited fine ferrocyanide or its ionized product may be eluted.

  Patent Document 2 describes the case where the porous body used for the carrier is a porous resin and the case where it is a porous silica gel. On the other hand, since radioactive cesium is an exothermic nuclide, it generates heat when the concentration in the adsorbent increases, so the resin carrier should be kept at a very low concentration, stored at a very low temperature after adsorption, It is not preferable because it requires a treatment such as solidification with an inorganic substance after incineration removal. For this reason, silica gel, which is an inorganic carrier, is superior in that it can be easily treated after adsorption, but when immersed in contaminated water, it absorbs water and the silica gel tends to collapse. In some cases, the column may be damaged.

  As described above, since the method for supporting a metal ferrocyanide compound described in Patent Documents 1 and 2 cannot support a large amount of a metal ferrocyanide compound, the adsorption efficiency of cesium, that is, various treatment liquids in a nuclear facility. In terms of the ability to remove cesium from the surface, it is not satisfactory in practice.

Japanese Patent Laid-Open No. 2-207839 Japanese Patent Laid-Open No. 11-76807

  In view of the above situation, an object of the present invention is to provide a cesium adsorbent containing a metal ferrocyanide compound having high cesium adsorption performance and a method for producing the same.

  As a result of intensive studies to solve the above problems, the present inventors have found that a molded product obtained from an insoluble ferrocyanide compound and a metal oxide becomes a cesium adsorbent that solves the above problems, The present invention has been completed.

The cesium adsorbent according to claim 1 is a cesium adsorbent comprising an insoluble ferrocyanide compound and colloidal silica containing anhydrous silicic acid having a particle diameter of 5 to 30 nm .

Claim 2 is a mixture obtained by mixing an insoluble ferrocyanide metal compound and colloidal silica containing silicic anhydride having a particle size of 5 to 30 nm and / or colloidal silica dispersion containing silicic anhydride having a particle size of 5 to 30 nm. 2. The method for producing a cesium adsorbent according to claim 1 , wherein the cesium adsorbent is heated and solidified after being molded.

Claim 3, the precursor of the metallic oxide, in addition an insoluble ferrocyanide metal compound comprising reacting in a dispersed state, cesium adsorbent consisting of an insoluble ferrocyanide metal compound and metal oxide It is a manufacturing method.
According to a fourth aspect of the present invention, a molded product composed of an insoluble ferrocyanide metal compound and a metal oxide is impregnated in a solution containing a metal oxide precursor or coated with a solution, and then subjected to a hydrolysis reaction, thereby forming a molded product. It is a cesium adsorbent in which a metal oxide is formed.

Claim 5, cesium adsorbent consisting of an insoluble ferrocyanide metal compound and a metal oxide, after applying the immersion or solution in a solution containing a precursor of a metal oxide, characterized in that it further heating claims Item 5. A method for producing a cesium adsorbent according to Item 4 .

6. The cesium adsorbent according to claim 5, wherein the precursor of the metal oxide is any one of silicon tetraethoxide, silicon tetramethoxide, and partial hydrolysis condensates thereof. It is a manufacturing method.

  The cesium adsorbent of the present invention is excellent in cesium adsorption capacity, and can remove cesium from a large amount of cesium-containing waste liquid in a short time.

The insoluble ferrocyanide compound in the present invention is a poorly water-soluble ferrocyanide obtained by reacting a salt containing a metal other than a divalent or higher alkaline earth or a salt containing a ferrocyanide ion or an acid. It is a metal halide compound and can be used without particular limitation.
For example, ferrocyanide, iron ferrocyanide ammonium, potassium ferrocyanide, which is a metal compound of ferrocyanic acid represented by the general formula M [Fe (CN) ₆ ] (M represents a metal component, etc.) , Sodium ferrocyanide, copper ferrocyanide, copper potassium ferrocyanide, cobalt ferrocyanide, potassium potassium ferrocyanide, nickel ferrocyanide, nickel ferrocyanide, and the like, III) Ferrosinated ferric acid represented by ₄ [Fe (II) (CN) ₆ ] ₃ and ferrocyanated acid represented by the composition formula NH ₄ Fe (III) [Fe (II) (CN) ₆ ] From the viewpoint of easy availability, ferric ammonium can be particularly preferably used.

  Examples of the metal oxide in the present invention include silica, alumina, titania, zirconia, and composite oxides such as silica-alumina, silica-titania, silica-zirconia, but can be used without particular limitation. Two or more types may be used in combination.

When used as metal oxide fine particles, metal oxide fine particles having a particle diameter of 1 to 100 nm are preferable because they are excellent in binding property to a ferrocyanide metal compound.
Further, those having a hydroxyl group (hydroxy group) on the surface are preferable because crosslinking and curing due to a dehydration reaction by heating or the like can be expected. Specifically, metal oxide fine particles with titanol, alumina, and silanol groups, or fine particles of titania, alumina, silica, and zirconia, and metal oxide fine particles with a hydroxyl group (hydroxy group) on the surface are used. it can. For example, the titania fine particles include Toagosei Co., Ltd., trade name High Titanium A-1, the alumina fine particles as trade names Alumina Sol 520 manufactured by Nissan Chemical Industries, Ltd., and the zirconia fine particles as Nanouse ZR-30BF.
In particular, a colloidal dispersion liquid dispersed in water using water as a dispersion medium is preferred because it is easy to disperse and handling is easy because there is no scattering of fine powder during the blending operation. If necessary, the organic solvent may be replaced with a dispersion medium or used in combination with water.
Among such metal oxide fine particles, colloidal silica is most typical, and a cesium adsorption / removal agent after adsorption removal of radioactive cesium is preferable because disposal of waste by vitrification is performed.

  In addition, when using metal oxide fine particles provided as a solid powder, it is difficult to mix both solid fine powders uniformly. A mixture can be formed with the metallocyanide compound.

The metal oxide preferably used in the present invention is colloidal silica in which silicic anhydride (silica fine particles) having a particle diameter of 5 to 30 nm is colloidally dispersed in water or an organic solvent. Either the water-dispersed type or the organic solvent-dispersed colloidal silica can be used, but the water-dispersed type is preferred. In the case of water-dispersed colloidal silica, since a large number of hydroxyl groups are present on the surface of the silica fine particles, a stronger molded body can be obtained because it is firmly bonded to the insoluble ferrocyanide compound.
Furthermore, the water-dispersed colloidal silica is divided into an acidic aqueous solution type and a basic aqueous solution-dispersed type, both of which can be used. Insoluble ferrocyanide compounds can be used in a basic atmosphere having a pH of 10 or more or an acidic atmosphere having a pH of 1 or less. Since it is easy to decompose | disassemble, it is preferable to use the thing of the range of pH 2-9.
Further, from the viewpoint of diversity of curing catalyst selection, appropriate hydrolysis of metal alkoxide, and condensation state, an acidic aqueous solution-dispersed colloidal deer is preferably used. Even those outside the preferred pH range can be used by adjusting the pH to the preferred range by adding an acid or base.

As a specific colloidal silica, it is possible to use a commercial product as it is. For example, as a commercial product dispersed in an acidic aqueous solution, Snowtex O (trade name) manufactured by Nissan Chemical Industries, Ltd., Catalyst Chemical Industry Co., Ltd. Cataloid SN (trade name) manufactured by Co., Ltd., and as a commercial product dispersed in a basic aqueous solution, Snowtex C (trade name), Snowtex 30 (trade name) and Snowtex manufactured by Nissan Chemical Industries, Ltd. No. 40 (trade name), Cataloid S30 (trade name) and Cataloid S40 (trade name) manufactured by Catalyst Kasei Kogyo Co., Ltd. may be mentioned.
Further, as commercial products dispersed in an organic solvent, MA-ST (trade name), IPA-ST (trade name), NBA-ST (trade name) manufactured by Nissan Chemical Industries, Ltd., etc., and Catalyst Chemical Industry Co., Ltd. OSCAL1132 (brand name), OSCAL1232 (brand name), etc. which are manufactured are mentioned.

When a metal oxide precursor is used, an alkali silicate salt or a metal alkoxide can be used.
Examples of the alkali silicate alkali salt used in the present invention include lithium, sodium, potassium, magnesium, calcium, aluminum, and zirconium, and may be orthosilicate alkali salt or metasilicate alkali salt. One or more of these can be used. Their hydrates are also included.
In the case of sodium silicate, for example, No. 1 (SiO ₂ / R ₂ O = 1.9 to 2.3), No. 2 (SiO ₂ / R ₂ O = 2.4) defined in JIS K 1408 to 2.7), No. 3 _{(SiO 2 / R 2 O =} 2.9~3.4) of water glass, one sodium metasilicate _{(SiO 2 / R 2 O =} 0.95~1.05) Two types of sodium metasilicate (SiO ₂ / R ₂ O = 0. 9 to 1.1), sodium orthosilicate (SiO ₂ / R ₂ O = 0.48 to 0.52) and the like can be mentioned.
(SiO ₂ / R ₂ O) is a molar ratio in terms of oxide of alkali silicate and may be expressed as MR.

  Hydrolysis of alkali silicate in the presence of acid, gelation of the resulting silica hydrosol, and addition of an insoluble ferrocyanide compound in the course of drying, insoluble ferrocyanation on silica gel of metal oxide Metal compounds can be combined. For example, a silica hydrosol obtained by adding an insoluble ferrocyanide compound dispersed in sulfuric acid to an aqueous solution of sodium silicate called water glass is gelled, dried after washing, and then insoluble ferrocyanated. A mixture composed of a metal compound and a metal oxide can be formed.

The metal alkoxide is not particularly limited, and examples thereof include a lower alkoxide of a metal selected from Si, Al, Zr and Ti. Examples of lower alkoxides include methoxide, ethoxide, propoxide, butoxide, and isomers thereof such as isopropoxide, sec-butoxide, t-butoxide, etc., and one or more of these can be used. .
Specific examples of metal alkoxides include silicon tetraethoxide (ethyl silicate), silicon tetramethoxide (methyl silicate), silicon tetrabutoxide (butyl silicate), propyl silicate, aluminum triisopropoxide, zirconium tetrabutoxide, titanium tetraisooxide. A propoxide etc. are mentioned. Among these, silicon tetramethoxide and silicon tetramethoxide are preferable.

A partially hydrolyzed condensate of a metal alkoxide obtained by adding a small amount of water and / or acid to the metal alkoxide can also be used in place of or mixed with the metal alkoxide. Use of a partial hydrolyzate is preferred because film formation after application is promoted. Specific examples of the metal alkoxide partially hydrolyzed condensate obtained by adding a small amount of water and / or acid to the metal alkoxide include ethyl polysilicate, for example, Colcoat Co., Ltd., trade name: ethyl silicate 40, methyl poly Examples of the silicate include those manufactured by Colcoat Co., Ltd., trade names: methyl silicate 51, butyl polysilicate, and the like.
Moreover, it is preferable to use alcohols, such as methyl alcohol, together with a metal alkoxide.

Furthermore, if necessary, a curing catalyst and water necessary for hydrolysis can be added to the alkoxysilane solution. Examples of such curing catalysts include lithium salts of aliphatic carboxylic acids such as formic acid, propionic acid, butyric acid, lactic acid, tartaric acid and succinic acid, alkali metal salts such as sodium salt and potassium salt, and quaternary ammonium salts such as benzyltrimethylammonium salt. Is mentioned. Specifically, sodium acetate, potassium acetate, choline acetate, benzyltrimethylammonium acetate and the like can be preferably used.
In addition, inorganic salts such as hydrochloric acid, sulfuric acid and phosphoric acid, inorganic bases such as sodium hydroxide, ammonia, tetramethylammonium hydroxide and the like can also be used.

The cesium adsorbent of the present invention is obtained by mixing and molding an insoluble ferrocyanide compound and a metal oxide or a metal oxide precursor. In order to increase the cesium adsorption capacity, the proportion of the insoluble ferrocyanide compound in the cesium adsorbent is preferably 5 to 95% by mass, more preferably 10 to 85% by mass.
On the other hand, since the metal oxide has an effect of improving the shape retention when the cesium adsorbent is immersed in the treated water, the metal oxide in the cesium adsorbent is preferably 5 to 95% by mass, More preferably, it is 15-90 mass%.
If the ratio of the insoluble ferrocyanide metal compound is less than 5% by mass, the cesium adsorption ability may be inferior. On the other hand, if it exceeds 95% by mass, the ratio of metal oxide decreases, so It may become brittle and insufficient in hardness.

  Furthermore, other components can be added to the cesium adsorbent of the present invention for the purpose of flow control and the like. Examples include glass, alumina, bentonite, mica, various clay minerals including zeolite, cellulosic flow modifiers, foaming agents and antifoaming agents.

  The mixing method of the insoluble ferrocyanide metal compound and the metal oxide in the present invention is not particularly limited, and a known mixing method can be used. Since it is desirable to mix as uniformly as possible, it is preferable to mix in advance using a kneader such as a kneader before molding.

The cesium adsorbent of the present invention is preferably used after the mixture of the metal ferrocyanide compound and the metal oxide is formed.
Although there is no limitation in particular as a shaping | molding method, For example, the wet shaping | molding method generally used in the ceramic industry, die press molding, injection molding, extrusion molding, casting molding, etc. are mentioned. Among these, die press molding, injection molding, and extrusion molding are preferably used because of excellent mass productivity.

  As the cesium adsorbent of the present invention, those formed into pellets, pipes, spheres, irregular shapes or honeycomb shapes are preferable from the viewpoint of facilitating handling of the cesium adsorbent and reducing the flow resistance of treated water. .

The cesium adsorbent of the present invention is dried by a production process including molding and solidified by heating. The heating condition is not particularly limited as long as it is equal to or lower than the decomposition temperature of the metal ferrocyanide compound, but it is preferably heated at 70 to 130 ° C. for 1 to 20 hours in order to sufficiently heat.
The decomposition temperature of ferric ammonium ferrocyanide was about 270 ° C. when TG / DTA (weight / differential thermal analyzer) in the presence of air was used.

Furthermore, in order to increase the hardness of the molded product and to prevent the removal of ferrocyanide metal compound fine particles from the molded product and the elution of ferrocyanide ions, the molded product is added to a metal alkoxide solution that is a precursor of a metal oxide. It is preferable to use after being immersed and filtered, followed by a dehydration polycondensation reaction.
When the metal alkoxide is dissolved in water or alcohol and applied, it is converted into an oxide by hydrolysis to form a film made of the metal oxide. In the present invention, the metal alkoxide has a function of binding the metal oxide particles. presume.
In addition, there is no limitation in particular about the immersion method to a metal alkoxide solution, the filtration method, and heating conditions, A well-known method is applicable.

The cesium adsorbent obtained by the heat treatment can be packed as it is into the adsorption tower, and the cesium adsorbent filled with the cesium adsorbent is supplied with a solution containing cesium and brought into contact with the cesium adsorbent. Is removed.
The conditions for bringing the cesium adsorbent into contact with the waste liquid are not particularly limited, but conditions such as the adsorbent filling amount and the waste liquid flow rate can be appropriately selected according to the concentration of cesium in the solution.

Hereinafter, the present invention will be described more specifically with reference to Examples and Comparative Examples.
<Example 1>
Colloidal silica dispersion (manufactured by Nissan Chemical Industries, Ltd., product name: Snow) of 800 g of ferrous ferrocyanide (trade name: MIRORI BLUE 905, manufactured by Dainichi Seika Co., Ltd.), an insoluble ferrocyanide metal compound 1000 g (Tex O) (200 g as a solid content) was mixed with a table kneader and kneaded for 10 minutes.
The mixture obtained by kneading was formed into a cylindrical pellet shape having a diameter of 2 mm by an extrusion molding machine and heated at 150 ° C. for 3 hours by a ventilation dryer. This is Treatment Agent 1.
For evaluation, an artificial seawater (trade name: Daigo Artificial Seawater SP, manufactured by Nippon Pharmaceutical Co., Ltd.) and an ultrapure water device (trade name: RFU554CA, manufactured by Advantech Toyo Co., Ltd.) were used so that the Cs concentration of cesium chloride was 10 ppm. It adjusted using the ultrapure water obtained in this way, and simulated contaminated water was adjusted.
1 g of the treatment agent 1 and 100 ml of the simulated contaminated water are placed in a 100 ml plastic container and shaken for 48 hours on a scale 2 with a shaker (trade name: WATER BATH INCUBATOR MODEL BT-3 manufactured by Yamato Scientific Co., Ltd.). After letting go, it was filtered with a membrane filter.
After adding 1 ml of nitric acid to 1 g of the filtrate obtained by the above filtration, dilute 100 times with ultrapure water, add 0.2 ml of nitric acid to 2 g of the diluted solution, and then dilute 10 times with ultrapure water. Got.
Using an ICP mass spectrometer (trade name Agilent 7500cs, manufactured by Agilent Technologies, Inc.) as the analytical solution, a calibration curve was obtained using the preliminarily prepared simulated contaminated water as the Cs concentration standard solution, and the Cs concentration of the sample containing the treatment agent 1 was added. As a result, the Cs concentration was 0.22 ppm, and 97.8% of cesium was removed. Next, 3 g of ferrous sulfate heptahydrate was added to a 100 ml volumetric flask to 1 g of the filtrate obtained by the above-described filtration, and after adding 80 ml of water, 1 ml of sulfuric acid was added and dissolved uniformly. 0.5 ml of an aqueous ferrous sulfate solution made up to 100 ml by adding pure water was placed in a 20 ml volumetric flask, and the whole was adjusted to 20 ml with pure water. After 30 minutes, the absorbance at a wavelength of 720 nm was measured using a UV-VIS spectrophotometer (V-550 manufactured by JASCO Corporation), and compared with a calibration curve prepared in advance using an aqueous potassium ferrocyanide solution, ferrocyanide ions When the concentration was quantified, ferrocyanide ion was 1.4 mg / L.
Further, 1 g of treatment agent 1 was immersed in 100 g of simulated contaminated water, set on the shaker, shaken for 48 hours on scale 2, and as a result of visual observation of the presence or absence of destruction, no destruction occurred. However, a slight crack was observed.

<Example 2>
A metal alkoxide ethylpolysilicate and a solution consisting of 1000 g of ethyl silicate 40 (trade name, manufactured by Colcoat Co.) consisting of tetraethoxysilane and ethanol and 1000 g of methanol were prepared, and the treatment agent obtained in Example 1 was added to this solution. 1 g of 1 was soaked and left for 2 hours, then the excess solution was removed by filtration, and the treatment agent 1 impregnated with the solution was again heated at 120 ° C. for 3 hours in a ventilating dryer. Obtained.
As a result of quantifying the Cs concentration of the sample containing the treatment agent 2 by the same method as in Example 1, the Cs concentration was 0.43 ppm, and 95.7% of cesium was removed. Ferrocyanide ion was 0.4 mg / L. In addition, no breakage such as cracking of the treatment agent caused by immersion in simulated contaminated water occurred.

<Example 3>
Treatment agent 3 was obtained in the same manner as in Example 1, except that ferric iron ferrocyanide was changed to iron (III) hexacyanoferrate (II) (imported and sold by Wako Pure Chemical Industries, Ltd.).
Next, as for the treatment agent 3, the Cs concentration of the sample containing the treatment agent 3 was quantified by the same method as in Example 1. As a result, the Cs concentration was 0.20 ppm, and 98.0% of cesium was removed. In addition, no breakage such as cracking of the treatment agent caused by immersion in simulated contaminated water occurred.

<Example 4>
Treatment agent 4 was obtained in the same manner as in Example 1, except that ferric ferrocyanide ammonium was changed to cobalt ferrocyanide (trade name: CsTreat, manufactured by SELION OY).
Next, for the treatment agent 4, the Cs concentration of the sample containing the treatment agent 4 was quantified in the same manner as in Example 1. As a result, the Cs concentration was 0.15 ppm, and 99.5% of cesium was removed. In addition, no breakage such as cracking of the treatment agent caused by immersion in simulated contaminated water occurred.

<Example 5>
The treating agent 2 obtained in Example 2 was packed in a cylindrical column having an inner diameter of 3 cm so that the volume became 100 ml. Next, the filled treatment agent is once taken out into a 500 ml beaker, and 100 ml of artificial seawater (trade name: Daigo Artificial Seawater SP, manufactured by Nihon Pharmaceutical Co., Ltd.) containing no cesium is added and the surface of the treatment agent or the treatment agent is stirred gently. Air bubbles adhered between them were removed.
Next, the treatment agent in the beaker and the artificial seawater were filled with care so as not to collect air in the treatment agent layer. At this time, the liquid level of the artificial seawater in the column was about 3 cm above the treatment agent layer.
Next, simulated contaminated water containing 10 ppm of cesium prepared by the same method as in Example 1 was poured into the column using a tube pump (Furue Science Co., Ltd., trade name RP-ASB). The flow rate of simulated contaminated water poured into the column is two ways of space velocity (SV value) 1, 10, and water flowing out from the lower part of the column after 1 hour is collected, and ICP-mass is obtained in the same manner as in Example 1. Cesium was analyzed with an analyzer. The concentration of cesium in the decontamination water obtained from the bottom of the column when SV = 1 is 0.01 ppm or less, the cesium removal rate is 99.99% or more, and the decontamination obtained from the bottom of the column when SV = 10 The cesium concentration in water was 1.0 ppm, the cesium removal rate was 90%, and the ferrocyanide ion was 0.4 mg / L. In addition, no breakage such as cracking of the treatment agent caused by immersion in simulated contaminated water occurred.

<Example 6>
Colloidal silica dispersion (manufactured by Nissan Chemical Industries, Ltd., product name: Snow) of 800 g of ferrous ferrocyanide (trade name: MIRORI BLUE 905, manufactured by Dainichi Seika Co., Ltd.), an insoluble ferrocyanide metal compound 1000 g (Tex O) (200 g as a solid content) was mixed with a table kneader and kneaded for 10 minutes.
The mixture obtained by kneading was poured into an aluminum dish-shaped container so as to have a thickness of about 5 mm, and heated at 70 ° C. for 6 hours and then at 130 ° C. for 3 hours with a draft dryer. . After returning to room temperature, the mixture was crushed with a crusher, and fine particles and coarse particles were removed with a vibration sieve to obtain particles having an irregular shape of 2 to 3 mm.
The irregularly shaped particles were prepared by preparing a solution comprising 1200 g of metal alkoxide methylpolysilicate and ethyl silicate 51 (trade name, manufactured by Colcoat Co., Ltd.) consisting of tetramethoxysilane and methanol, 300 g of methanol, and 230 g of water. After being immersed for 2 hours, the excess solution was removed by filtration, and the solution impregnated with the solution was heated at 110 ° C. for 4 hours with an air dryer. The obtained product was immersed in 1200 g of pure water at 60 ° C. and 1 hour later, water was removed by filtration. Subsequently, 1200 g of pure water at 20 ° C. was added and the extraction was carried out three times. After sufficiently extracting water, the treatment agent 5 was dried at 120 ° C.
Moreover, as a result of quantifying Cs concentration by the same method as Example 3, Cs concentration was 0.08 ppm and 99.2% of cesium was removed. Ferrocyanide ion was 0.2 mg / L. There was no damage such as cracking of the treatment agent due to immersion in simulated contaminated water.

<Example 7>
216 g of ferric ferrocyanide ferric ferrocyanide (ACROS) is dispersed in 20 liters of 4N sulfuric acid, and 20 liters of an aqueous solution of 18% sodium silicate (MR3.3) silica is added and mixed to react. A hydrosol was formed and left for 1 hour. This was washed with water to remove sodium sulfate, and then 28% by weight aqueous ammonia was added to adjust the pH to 8.0. Subsequently, this slurry was kept at 80 ° C. for 12 hours for aging, and the particle size was 0.5 mm to 2 mm. Ferrocyanide composite silica particles were obtained. After separation by filtration, drying was performed at 120 ° C. for 12 hours with a ventilation dryer. The obtained iron ferrocyanide composite silica particles had a surface area of 450 m ² / g and a pore volume of 0.8 ml / g. This was aerated with air at 30 ° C. and 95% humidity for 24 hours. 1000 g of the ferrocyanide-composited silica particles were weighed, and in the same manner as in Example 6, methyl polysilicate, which is a metal alkoxide, and methyl silicate 51 (trade name, manufactured by Colcoat Co.) consisting of tetramethoxysilane and methanol, and 300 g of methanol. Then, a solution consisting of 230 g of water was prepared, immersed in this solution and allowed to stand for 2 hours. Then, the excess solution was removed by filtration, and the solution impregnated was heated at 110 ° C. for 4 hours with an air dryer. . The obtained product was immersed in 1200 g of pure water at 60 ° C. and 1 hour later, water was removed by filtration. Subsequently, 1200 g of pure water at 20 ° C. was added and the extraction was carried out three times. After sufficiently extracting water, the treatment agent 6 was dried at 120 ° C.
As a result of quantifying the Cs concentration by the same method as in Example 3, the Cs concentration was 0.07 ppm, and 99.3% of cesium was removed. Ferrocyanide ion was 0.2 mg / L. There was no damage such as cracking of the treatment agent due to immersion in simulated contaminated water.

<Comparative Example 1>
According to Japanese Patent Application Laid-Open No. 11-76807, which is Patent Document 2, 2 g of amorphous silica gel having an irregular particle diameter of about 2 to 3 mm (silica gel ID type manufactured by Aichi Silica Industry Co., Ltd .: pore volume 0.95 ml) After weighing into a conical flask with a glass stopper, an aqueous solution of potassium hexacyanoferrate (II) (concentration 22.7% by weight, the same shall apply hereinafter) is added dropwise with shaking to make the whole slightly wet and free of fluidity. did.
Next, 20 ml of ethanol was added, shaken, and then the process of separating the emulsion of potassium hexacyanoferrate (II) precipitated in ethanol by decantation was repeated twice. Excess potassium hexacyanoferrate (II) (0.033 g) and ethanol were recovered by distilling the emulsion.
In the remaining part from which the emulsion was removed, ethanol was completely distilled off under reduced pressure to obtain a composite with silica gel carrying potassium hexacyanoferrate (II) precipitate.
Next, 20 ml of an ethanol solution containing 8.0 moles of copper (II) chloride with respect to the supported potassium hexacyanoferrate (II) was added, and the mixture was reacted by shaking for 24 hours at room temperature. The reaction proceeded rapidly and the silica gel immediately became dark reddish purple, but precipitation in the external solution was negligible even after 24 hours. After the reaction, the silica gel portion was separated by filtration and then aged by heating at 60 ° C. for 6 hours. The filtration was easy.
After standing to cool, thoroughly wash with water until copper ion is not detected by decantation, air-dry at room temperature, and 2.4 g (in terms of dry weight) of treating agent 7 that seems to carry insoluble hexacyanoiron (II) acid salt. Obtained.
The silica gel used in Comparative Example 1 is irregular particles having a size of about 2 to 3 mm, but during this washing process, the treatment agent was broken into a size of about 0.1 to 1 mm and collapsed.
Hereinafter, as a result of quantifying the Cs concentration by the same method as in Example 1 except that the treatment agent 1 was changed to the treatment agent 1 instead of the treatment agent 1 obtained in Example 1, the Cs concentration was 0.15 ppm. .5% was removed. Ferrocyanide ion was 2 mg / L, greatly exceeding 1 mg / L or less of the wastewater standard value of the Water Pollution Control Law. Moreover, the disintegration further proceeded by immersion in simulated contaminated water.

  The cesium adsorbent in the present invention is excellent in cesium adsorption capacity, and can remove cesium from a large amount of cesium-containing waste liquid in a short time. Therefore, a waste liquid containing cesium generated from facilities related to nuclear power use. And soil containing cesium scattered by accidents related to the use of nuclear power, washing water used for decontamination, washing water for ash when incineration of waste containing cesium, and leachate from landfills where it was landfilled, In particular, it can be used as a treatment agent for removing cesium from a liquid in which many metal ions other than cesium coexist.

Claims (6)

A cesium adsorbent comprising colloidal silica containing an insoluble ferrocyanide compound and silicic anhydride having a particle diameter of 5 to 30 nm. A mixture obtained by mixing an insoluble ferrocyanide compound with colloidal silica containing anhydrous silicic acid having a particle size of 5 to 30 nm and / or colloidal silica dispersion containing anhydrous silicic acid having a particle size of 5 to 30 nm is molded and then heated. It solidifies, The manufacturing method of the cesium adsorption agent of Claim 1 characterized by the above-mentioned. A method for producing a cesium adsorbent comprising an insoluble ferrocyanide compound and a metal oxide , wherein the insoluble ferrocyanide compound is added to and dispersed in a metal oxide precursor. A metal oxide is formed on a molded product by immersing or applying a molded product composed of an insoluble ferrocyanide metal compound and a metal oxide to a solution containing a metal oxide precursor and then applying a hydrolysis reaction. Cesium adsorbent. The cesium adsorbent comprising an insoluble ferrocyanide compound and a metal oxide is immersed in a solution containing a metal oxide precursor or coated , and then further heated . A method for producing a cesium adsorbent. The method for producing a cesium adsorbent according to claim 5, wherein the precursor of the metal oxide is any one of silicon tetraethoxide, silicon tetramethoxide, and a partial hydrolysis condensate thereof.