JP2014021030A - Removal method of cesium and mineral water generator with cesium removal function - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a removal method of cesium for safely, simply and efficiently clearing out and removing cesium from various kinds of contaminated water such as waste liquid, domestic water, sea water, river water, pond water, water for raising animals and plants, food processing water or drinking water by a simpler facility, and enabling even a general home to easily remove cesium by a simple and inexpensive facility and a mineral water generator with a cesium removal function.SOLUTION: A removal method of cesium has processes of: adding Prussian blue to contaminated water containing cesium; adding processing coagulant obtained by processing natural ore by inorganic acid to solubilize mineral components to the contaminated water containing cesium; generating aggregate containing cesium colored in the Prussian blue and aggregated by the processing coagulant in the contaminated water; and separating the aggregate containing cesium colored in the Prussian blue and aggregated by the processing coagulant from water.

Description

  The present invention relates to a method for removing radioactive cesium contained in various contaminated water such as waste liquid, domestic water, seawater, river water, pond water, animal and plant breeding water, food processing water or drinking water, and a mineral water generator having a cesium removing function. .

  It has been reported that water-soluble cesium is contained in the effluent from the reactor facility following the accident at the Fukushima nuclear power plant. In addition, there is a concern about radioactive contamination of various contaminated water such as domestic water, seawater, river water, pond water, animal and plant breeding water, food processing water or drinking water.

  Cesium has a long half-life of 30 years and accumulates when exposed to the body, so there is a high risk of exposure, so not only wastewater treatment from nuclear facilities, but also water for daily use, seawater, river water, pond water, animal and plant breeding water, Removal from various contaminated water such as food processing water or drinking water is a concern, and establishment of technology for safe decontamination is required, and various researches are underway.

  As a method for removing cesium from contaminated water such as waste liquid, there are various methods, for example, a method of adsorbing and removing with denitrifying bacteria in JP 2007-271306 A, an evaporation concentration method, an ion exchange method, a coagulation precipitation method, or a combination of these methods. Although proposed, an effective removal method has not been established at present.

  Recently, it has been reported that Prussian blue nanoparticles of blue pigment selectively adsorb cesium and have a characteristic that makes it difficult to stably output cesium when placed in gaps in crystal structures such as jungle gym. A decontamination apparatus utilizing the Prussian blue adsorption action has been proposed.

  This decontamination device is a device configured to mix Prussian blue (ferric ferrocyanide) with contaminated water in which cesium 133 · 137 is dissolved, separate it using centrifugal force, and filter it off with a filter. It is.

  However, since hazardous substances that require treatment are the total amount of contaminated water, the removal equipment including a centrifugal separator and a filter becomes large, complicated, and expensive, and maintenance is not easy. In addition, since the entire amount of contaminated water becomes a hazardous substance, it has been difficult to ensure the safety of workers handling the contaminated water. Furthermore, a device for removing water-soluble cesium effectively and safely has been desired in general households.

JP 2007-271306 A

  Therefore, an object of the present invention is to safely and easily remove cesium efficiently and simply with simple equipment from various types of contaminated water such as waste liquid, domestic water, seawater, river water, pond water, animal and plant breeding water, food processing water or drinking water. An object of the present invention is to provide a cesium removal method and a mineral water generator equipped with a cesium removal function that can be removed by sweeping and can easily and safely remove cesium even in general households.

  What solves the above problems includes a process of adding Prussian blue to contaminated water containing cesium, and a processing flocculant in which natural ore is treated with inorganic acid in the contaminated water containing cesium to solubilize mineral components. A step of adding, a step of generating in the contaminated water agglomerates containing cesium colored by the Prussian blue and agglomerated by the treatment flocculant, and colored by the Prussian blue and for the treatment A method for removing cesium, comprising a step of separating agglomerates containing cesium aggregated with a flocculant and water.

  The step of separating the aggregate and the cesium-containing aggregate that is colored with the Prussian blue and aggregated with the processing flocculant is preferably performed by filtration. The cesium removal method preferably includes a step of adding an organic substance to contaminated water containing cesium.

  Moreover, what solves the said subject is the raw | natural water container for accommodating the drinking water containing cesium, Prussian blue added to the drinking water containing the cesium accommodated in this raw | natural water container, In the said raw | natural water container A processing flocculant that is added to drinking water containing cesium contained in a cadmium to form a cesium-containing agglomerate, wherein the natural ore is treated with an inorganic acid to solubilize mineral components; and A water storage container that communicates with the raw water container through a communication port and stores generated water; and agglomerates containing cesium and colored by Prussian blue that are arranged to cover the communication port It is a mineral water generator provided with the cesium removal function characterized by having a filter for performing. The treatment flocculant is preferably adjusted to have a pH of 5 to 7.

According to the invention described in claim 1, cesium can be efficiently and safely produced with simple equipment from various contaminated water such as waste liquid, domestic water, seawater, river water, pond water, animal and plant breeding water, food processing water or drinking water. Can be removed.
According to the invention described in claim 2, cesium can be more reliably removed with simple equipment.
According to the invention described in claim 3, an agglomerate containing cesium can be more reliably formed.
According to the invention described in claim 4, cesium can be easily and safely removed even in a general household.
According to the fifth aspect of the present invention, it is possible to enhance the coagulation ability, and it is possible to coagulate and remove organic substances in drinking water and harmful heavy metals such as arsenic and lead.

It is explanatory drawing for demonstrating the removal method of the cesium of this invention. It is a perspective view of one Example of the mineral water generator of this invention. FIG. 3 is a partial vertical end view of the mineral water generator shown in FIG. 2. It is a disassembled perspective view of the mineral water generator shown in FIG. FIG. 4 is a partially enlarged view of FIG. 3.

  In the present invention, by adding an extremely small amount of Prussian blue and a treatment flocculant with respect to the amount of contaminated water, it is possible to visualize cesium, which is a dangerous substance, and to agglomerate and reduce the volume of dangerous treatment objects containing cesium. Cesium can be removed safely and easily with simple equipment from various contaminated water such as waste liquid, domestic water, seawater, river water, pond water, animal and plant breeding water, food processing water or drinking water. The method and the mineral water generator with the cesium removal function which can remove cesium easily and safely also in a general household were realized.

The method for removing cesium of the present invention will be described with reference to one embodiment shown in FIG.
The method for removing cesium in this example includes the steps of adding Prussian blue to contaminated water containing cesium, and coagulation for treatment in which mineral ore was treated with mineral acid in the contaminated water containing cesium to solubilize mineral components. A step of adding an agent, a step of generating agglomerates containing cesium colored in Prussian blue and agglomerated with a treatment flocculant in contaminated water, and colored with the Prussian blue and agglomeration for treatment A step of separating the water containing the cesium-containing agglomerates aggregated with the agent. Hereinafter, each step will be described in detail.

  In the step of adding Prussian blue to the contaminated water containing cesium, Prussian blue A is added after the contaminated water in the contaminated water storage tank 30 flows into the contaminated water treatment container 31. As a result, Prussian blue nanoparticles selectively adsorb cesium, and the cesium is contained in the gaps of the crystal structure such as jungle gym, which makes it difficult to stably come out. This action of Prussian blue colors the contaminated water. Specifically, when the contaminated water is transparent, it is colored blue with a blue pigment, and when the contaminated water has a color in advance, it is colored with a blue color added to that color.

  In the present application, “Prussian blue” means a blue pigment, and ferric ferrocyanide is used in this example. However, “Prussian blue” in the present application is not limited to ferric ferrocyanide, and widely includes blue pigments having a property of selectively adsorbing cesium.

  Moreover, it is preferable to have the process of adding organic substance to the contaminated water containing cesium. Specifically, the organic substance B is added to the contaminated water treatment container 31 before the treatment flocculant is added. Thereby, the aggregate containing a cesium can be formed more reliably. For example, milk can be suitably used as the organic substance.

  In the step of adding the processing flocculant in which the natural ore is treated with the inorganic acid to the contaminated water containing cesium to solubilize the mineral component, the processing flocculant C is added to the contaminated water treatment vessel 31. Thereby, the aggregate containing the cesium colored with Prussian blue can be formed.

  This processing flocculant is produced by treating natural ore with an inorganic acid and solubilizing mineral components. The natural ore used as a raw material for the processing flocculant is not particularly limited. For example, a coral rock (vermiculite) generated by weathering granite, or a soil generated by further weathering the corrosive rock, Or the mixture of both can be used conveniently.

  As the inorganic acid for treating the natural ore, for example, sulfuric acid, hydrochloric acid, nitric acid or a mixture thereof can be suitably used. Among them, sulfuric acid having excellent solubility and reaction rate and non-volatile sulfuric acid is more preferable.

  As a manufacturing method of the processing flocculant, for example, when 98% sulfuric acid is used, 20 to 25% by weight of sulfuric acid and 50 to 66% by weight of a pulverized rock (previously ground to 1.0 mm or less) The other (water) is mixed, heat-treated and stirred at 65 to 75 ° C. for 5 to 8 hours, and further cooled and stirred for 12 to 15 hours to dissolve and extract minerals.

  And it is preferable that pH of this processing flocculant (mineral concentrate) is adjusted to 5-7 by adding sodium hydroxide or a citrate buffer etc. in a required amount. Thereby, aggregating ability can be improved.

  The step of generating in the contaminated water the aggregate containing cesium that is colored by Prussian blue and aggregated by the processing flocculant C is performed in the contaminated water treatment vessel 31 with Prussian blue A, organic matter B, and the processing flocculant. After adding C, it is performed by leaving it to stand.

  The step of separating the cesium-containing aggregate and water aggregated by the processing coagulant C includes the aggregate S and purified water P in the aggregate container 32 and the liquid container 33 containing the cesium-containing aggregate, respectively. This is done by inflowing and housing the. Specifically, in this embodiment, the aggregate S settles near the bottom in the contaminated water treatment container 31, and therefore flows into the aggregate container 32 through the first discharge port 34 provided near the bottom and is separated. The purified water P is configured to flow into the liquid container 33 and be separated from the second discharge port 35 provided in the vicinity of the upper part in the contaminated water treatment container 31.

  And since the cesium which is a dangerous substance is contained in the aggregate S, the aggregate S separated from water and volume-reduced should just be processed, and a process of cesium can be performed more easily. Moreover, since the cesium in the aggregate S is colored and visualized with Prussian blue, the operator can safely treat the cesium.

  In this embodiment, the aggregate S and the water P are separated by the separation method as described above, but the separation may be performed by filtration. By separating the two by filtration, cesium can be more reliably removed with simple equipment.

  As described above, in the cesium removal method of the present invention, Prussian blue nanoparticles selectively adsorb cesium, and this action of Prussian blue visualizes the portion containing cesium in the contaminated water. A person involved in the treatment of cesium can be surely avoided from touching cesium, and cesium can be more reliably removed by visually checking the object to be treated. Furthermore, since the processing target containing cesium is aggregated and precipitated by the processing flocculant, cesium can be processed more easily and safely by reducing the volume of the processing target.

  Next, a mineral water generator having a cesium removing function according to the present invention will be described with reference to an embodiment shown in FIGS.

  The mineral water generator 1 of this embodiment includes a raw water container 2 for containing drinking water containing cesium, Prussian blue added to drinking water containing cesium contained in the raw water container 2, and a raw water container. 2 is a processing flocculant that is added to drinking water containing cesium contained in 2 to form a cesium-containing agglomerate, wherein the natural ore is treated with an inorganic acid to solubilize mineral components. In order to filter the agglomerates containing the cesium, which is arranged so as to cover the agent, the raw water container 2 through the communication port 5 and store the generated water and the generated water. The filter 8 is provided. Hereinafter, each configuration will be described in detail.

  The mineral water generator 1 is obtained by applying the cesium removal method of the present invention to a mineral water generator.

  The raw water container 2 is a container for injecting drinking water such as tap water and well water. In this raw water container 2, drinking water containing cesium (raw water), Prussian blue, and a processing flocculant are added. Cesium is visualized and agglomerated to produce mineral water.

  As shown in FIG. 4, the raw water container 2 is formed in a bottomed cylindrical body (cylindrical body) having an open upper end, and includes a filter mounting portion 6 having a communication port 5 at the bottom, The upper lid 9 is configured to be detachably fitted in the opening.

  As shown in FIG. 5, the filter mounting portion 6 includes a filter mounting plate 10 that is formed in a concave shape, and a cylindrical portion 11 that is provided below the filter mounting plate 10 and penetrates the filter mounting plate 10. The filter mounting member 12 having the above is arranged, and this filter mounting member 12 is fixed to the bottom of the raw water container 2 with the tube portion 11 inserted through the communication port 5 of the filter mounting portion 6. Yes.

  More specifically, a screw portion (not shown) is formed on the outer periphery of the tube portion 11, and the filter mounting plate 10 is attached to the raw water container 2 by screwing the screw portion and the wing nut 13. It is fixed on the filter mounting portion 6 provided at the bottom of the filter. In addition, it is preferable that the lower part of the filter 8 is formed in the filter mounting plate 10 formed in a concave shape so that it can be fitted.

  As shown in FIG. 3 or 5, the filter 8 includes activated carbon 7 and a ceramic filter 7 </ b> A encapsulating the activated carbon 7. The activated carbon 7 has a function of deodorizing and decoloring by adsorbing impurities remaining in the raw water that has passed through the ceramic filter 7A, and the ceramic filter 7A is formed of ceramics having a fine pore of 0.5 μm. Then, impurities in the raw water aggregated by the processing flocculant are removed by filtration.

  In the mineral water generator 1, in this raw water container 2, a process of adding Prussian blue to drinking water containing cesium, and natural minerals are treated with mineral acid in the drinking water containing cesium to solubilize mineral components. The step of adding the treating flocculant and the step of filtering the aggregate containing cesium aggregated by the treating flocculant are performed.

  The ceramic filter 7A of this example has 0.5 μm fine pores, but in order to remove the agglomerates containing cesium, the fine pores of about 3 μm can be filtered. Any filter having a filter having fine pores of 3 to 3 μm may be used.

  Prussian blue added to drinking water containing cesium contained in the raw water container 2 is for adsorbing cesium and visualizing cesium in the drinking water, and thus the mineral water generator of the present invention. Can visually confirm whether or not cesium has been removed, and can drink the produced water with peace of mind.

  In the present application, “Prussian blue” means a blue pigment, and ferric ferrocyanide is used in this example. However, “Prussian blue” in the present application is not limited to ferric ferrocyanide, and widely includes blue pigments having a property of selectively adsorbing cesium.

  The processing flocculant is for adding to the drinking water containing cesium contained in the raw water container 2 to form an agglomerate containing cesium, and to contain a large number of minerals in the drinking water, It is manufactured by treating natural ore with an inorganic acid and solubilizing mineral components. In addition, this flocculant for treatment is agglomeration of free chlorine, organochlorine compounds and other organic substances that cause harmful effects on the body that dissolves between water molecules, bactericidal action of bacteria such as coliforms, redox It also has the effect of reducing the potential.

  The natural ore used as a raw material for the processing flocculant is not particularly limited. For example, a coral rock (vermiculite) generated by weathering granite, or a soil generated by further weathering the corrosive rock, Or the mixture of both can be used conveniently.

  As the inorganic acid for treating the natural ore, for example, sulfuric acid, hydrochloric acid, nitric acid or a mixture thereof can be suitably used. Among them, sulfuric acid having excellent solubility and reaction rate and non-volatile sulfuric acid is more preferable.

  As a manufacturing method of the processing flocculant, for example, when 98% sulfuric acid is used, 20 to 25% by weight of sulfuric acid and 50 to 66% by weight of a pulverized rock (previously ground to 1.0 mm or less) , Other (water), and heat treatment and stirring at 65 to 75 ° C. for 5 to 8 hours, and further cooling and stirring for 12 to 15 hours to dissolve and extract minerals, thereby treating flocculant (mineral concentrate) ) Can be manufactured.

  And it is preferable that pH of this processing flocculant (mineral concentrate) is adjusted to 5-7 by adding sodium hydroxide or a citrate buffer etc. in a required amount. As a result, the aggregating ability can be enhanced, and organic substances in drinking water and harmful heavy metals such as arsenic and lead can be agglomerated and removed.

  Further, the treatment flocculant thus obtained depends on the chemical composition of the natural ore as a raw material, but when corrosive rock (vermiculite) is used as a raw material, as shown in Table 1 below, minerals 20 or more.

  By adding a processing flocculant containing abundant minerals (trace elements) to drinking water, harmful substances including cesium can be effectively removed by aggregating action of aluminum, iron, silicon, etc. In addition, a large number of trace elements can be quantitatively replenished.

  The water storage container 4 is a container for storing the generated water from which cesium has been removed in the raw water container 2, and is configured as a bottomed cylindrical container having an open upper end as shown in FIG. 3 or FIG. Yes. A cock 14 for taking out the generated water stored in the water storage container 4 to the outside is provided on the side near the lower part of the water storage container 4, and the water storage container 4 is disposed above the table 15 as necessary. It is mounted so that water can be discharged from the cock 14 more easily.

  The raw water container 2 and the water storage container 4 are formed of a synthetic resin container that has been subjected to antibacterial treatment that is transparent or translucent so that the water level and water quality can be observed from the outside.

  The intermediate member 3 is for connecting the raw water container 2 and the water storage container 4 so as to be integrated in the vertical direction, and as shown in FIG. 4 or FIG. The concave body 3A that supports the outer bottom surface of the raw water container 2 on the upper surface of the raw water container, and the lower body of the concave body 3A are arranged to support the concave body 3A at the peripheral edge of the central opening, and at the outer peripheral edge of the water storage container 4 It is comprised from the cyclic | annular body 3B engaged with an upper-end opening edge part.

Below, the usage method of the mineral water generator 1 is demonstrated.
In the state shown in FIG. 2, the upper lid 9 is removed, and raw water to which a required amount of Prussian blue and a required amount (about 0.01 to 0.03% by weight of raw water) processing flocculant are added is poured into the raw water container 2. If necessary, the upper cover 9 is put on.

  Here, the raw water to which the processing flocculant is added is produced into the above-described mineral-rich water after a certain period of time, and cesium, free chlorine, organic chlorine compounds, and other organic substances are aggregated. In addition, various bacteria are controlled and aggregates containing cesium are colored blue by Prussian blue and precipitated in raw water.

  Although the physical and chemical mechanisms of such aggregating action have not been elucidated specifically, a plurality of metal salts such as magnesium, aluminum, calcium, iron, potassium, sodium and silicon form a double salt. It is considered that the charges are efficiently neutralized and aggregated while being entangled in a complicated manner.

  The raw water thus agglomerated is passed through the filter 7 containing the activated carbon 7, and then falls into the water storage container 4 through the cylinder portion 11 and stored. In this process, the raw water is filtered by the ceramic filter 7A to remove the agglomerates containing cesium, and further, the remaining impurities are adsorbed by contact with the activated carbon 7 disposed inside the ceramic filter 7A, thereby causing deodorization, decolorization, etc. Made and purified as a good quality mineral water.

  Here, if the generated water stored in the water storage container 4 is blue, the user may have cesium in the generated water and can avoid drinking. The generated water can be drunk with confidence that the cesium has been removed.

  When the produced water stored in the water storage container 4 is taken out, it is only necessary to open the cock 14, but the relay member 3 may be lifted and pumped up from the upper end opening of the water storage container 4.

  Further, when the activated carbon 7 and the ceramic filter 7A (filter 8) become dirty or clogged due to long-term use, it is only necessary to remove the filter 8 from the filter mounting plate 10 and replace it with a new one. Further, when the filter function is deteriorated, agglomerates containing cesium colored blue by Prussian blue flow into the water storage container 4, so the filter 8 is removed in such a dangerous case to remove the old and new It can be replaced, and the user can confirm the presence or absence of cesium in the produced water one by one, and safety can be ensured by avoiding drinking.

(Cesium removal ability test)
Using the mineral water generator 1, a cesium removal test was performed as follows.
Raw water containing cesium at a rate of 1.1 mg / L is contained in the raw water container 2, and the raw water contains 0.02% by weight of the flocculant for treatment and 0.001% by weight of the total amount of raw water Prussian blue. Then, 0.0005% by weight of the total amount of the raw water was added as an organic substance, and <more sodium hydroxide was added to make it neutral, and the mixture was sufficiently stirred. Then, when the produced water stored in the water storage container 4 through the filter 8 was analyzed by ICP mass spectrometry, the measurement result that the content of cesium was <0.002 mg / L was obtained.

  The measured value “<0.002 mg / L” means that cesium was not detected with the accuracy of the used measuring instrument, and the cesium removal method and the mineral water provided with the cesium removal function of the present invention. The generator confirmed that cesium was effectively removed.

  In addition, although the mineral water generator 1 of the said Example uses the removal method of the cesium of this invention for the mineral water (drinking water) generator for general households, waste liquid, domestic water, seawater, river water When removing cesium from various contaminated water, such as pond water, water for plant and animal breeding, food processing water, etc., configure a contaminated water container with a larger raw water container 2 and use a very small amount of Prussian for each contaminated water. By adding blue and the treatment flocculant and filtering the aggregate containing cesium formed in the contaminated water container with a filter means, cesium can be removed from the contaminated water.

DESCRIPTION OF SYMBOLS 1 Mineral water generator 2 Raw water container 3 Junction member 3A Concave body 3B Annular body 4 Water storage container 5 Communication port 6 Filter mounting part 7 Activated carbon 7A Ceramics filter 8 Filter 9 Upper lid 10 Filter mounting plate 11 Tube part 12 Filter mounting member 13 Wing nut 14 Cock 15 Stand 30 Contaminated water storage tank 31 Contaminated water treatment container 32 Aggregate container 33 Liquid container 34 First outlet 35 Second outlet

Claims (5)

Adding Prussian blue to contaminated water containing cesium; adding a flocculant for treatment in which natural ore is treated with an inorganic acid to solubilize mineral components in contaminated water containing cesium; and the Prussian blue A cesium-containing agglomerate that is colored by the treatment flocculant and formed in the contaminated water; and cesium that is colored by the Prussian blue and agglomerated by the treatment flocculant A method for removing cesium, comprising a step of separating the agglomerate containing water and water. The method for removing cesium according to claim 1, wherein the step of separating water from the aggregate containing cesium colored with the Prussian blue and aggregated with the processing flocculant is performed by filtration. The method for removing cesium according to claim 1 or 2, wherein the method for removing cesium includes a step of adding an organic substance to contaminated water containing cesium. Raw water container for containing drinking water containing cesium, Prussian blue to be added to drinking water containing cesium contained in the raw water container, and drinking water containing cesium contained in the raw water container A flocculant for processing which forms an agglomerate containing cesium by adding to the processing flocculant which natural mineral ore was treated with an inorganic acid to solubilize mineral components, and via the raw water container and the communication port A water storage container for storing the generated water that is communicated and generated, and a filter for filtering agglomerates containing cesium and colored by Prussian blue arranged to cover the communication port Mineral water generator with cesium removal function. The mineral water generator having a cesium removing function according to claim 4, wherein the flocculant for treatment has a pH adjusted to 5-7.

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