JP2013170959A - Radioactive waste treatment method and apparatus for the same - Google Patents

Abstract

PROBLEM TO BE SOLVED: To separate and remove radioactive nuclides from radioactive waste, especially from radioactive waste including salts.SOLUTION: When separating and removing radioactive nuclides from radioactive waste including the radioactive nuclides, a radioactive waste treatment method adds an oxidizer or a reducer, or pH control chemical to the radioactive waste, and then allowing the radioactive waste to pass through an adsorbent to adsorb and remove the radioactive nuclides.

Description

  The present invention relates to a radioactive waste liquid treatment method and apparatus, and more particularly to a radioactive waste liquid treatment method and apparatus suitable for separating and removing radionuclides from waste liquid containing radionuclides.

  One treatment method for radioactive liquid waste containing radionuclides generated in nuclear facilities is an adsorption treatment method using an ion exchange resin or the like. On the other hand, when the radioactive liquid waste contains a high concentration of salt, the salt may interfere with the adsorption of the radionuclide.

  On the other hand, in Patent Document 1, a powdery or granular substance that adsorbs a radionuclide by performing a chelate formation reaction with the radionuclide is added to the radioactive liquid waste, and the substance that adsorbs the radionuclide is then separated by filtration. Is stated.

Japanese Patent Laid-Open No. 61-40593

  According to the method described in Patent Document 1, it is possible to separate the radionuclide from the radioactive liquid waste while reducing the influence of salt interference. On the other hand, since it is premised on performing a chelate formation reaction with a radionuclide, the degree of effect is limited for a type of radionuclide that does not perform a chelate formation reaction.

  The radionuclide contained in the radioactive liquid waste may have a single chemical form depending on the type, but may exist in a plurality of chemical forms. In particular, radionuclides contained in radioactive liquid waste containing salts tend to exist in multiple chemical forms. Those having a plurality of chemical forms have different charges depending on the form. That is, it may be positive, negative, or neutral. In such a case, it is necessary to prepare a plurality of adsorbents in order to separate and remove a certain type of radionuclide.

  Some compounds exist as compounds that cannot be separated by adsorption treatment due to chemical bonds between impurities and radionuclides contained in the radioactive liquid waste. For example, if radioactive waste liquid contains iodine as a radionuclide and organic matter is present as an impurity, iodine becomes organic iodine such as methyl iodide, and a radionuclide separation method that differs from normal adsorption treatment is applied. Need to do.

  Generally, since the concentration of the radionuclide contained in the radioactive liquid waste is extremely small, it is difficult to measure the chemical form of the radionuclide by chemical analysis or the like in advance. For this reason, it is not easy to select an adsorbent to be used for separation of radionuclides, and it is not easy to confirm beforehand whether or not the adsorbent is chemically bonded to impurities and difficult to be adsorbed.

  The present invention has been made in view of the above-mentioned points. The object of the present invention is to provide a radionuclide from a radioactive liquid waste containing a radionuclide, particularly a radioactive liquid containing a low concentration of the radionuclide contained in a radioactive liquid waste containing a salt. It is an object of the present invention to provide a method and apparatus for treating radioactive waste liquid that can efficiently separate and remove water.

  In order to achieve the above object, the method for treating a radioactive liquid waste of the present invention adds an oxidizing agent or a reducing agent to the radioactive liquid waste and then adsorbs the radioactive liquid waste when separating and removing the radionuclide from the radioactive liquid waste containing the radionuclide. It is characterized by adsorbing and removing the radionuclide by passing water through the material.

  As the oxidizing agent added to the radioactive liquid waste, hydrogen peroxide, ozone, an aqueous solution of permanganic acid and its salt, an aqueous solution of hypochlorous acid and its salt, etc. are employed. As a reducing agent added to the radioactive liquid waste, ascorbic acid, hydrazine, oxalic acid, or the like is employed. When adding an oxidizing agent or a reducing agent, the pH of the waste liquid may be adjusted as necessary.

  When an operation of adding an oxidizing agent or a reducing agent to the radioactive liquid waste is performed, the chemical form of the radionuclide in the radioactive liquid waste is arbitrarily adjusted. Moreover, you may adjust pH of a solution as needed. The chemical form of the radionuclide in the waste liquid can be known from the oxidation-reduction potential of the oxidizing agent or reducing agent to be added, and based on this, an adsorbent for separating the radionuclide can be selected.

  Further, when there is a possibility that organic substances exist as impurities in the radioactive liquid waste, it is desirable to add an oxidizing agent to the radioactive liquid waste to mineralize the organic substance, and then to generate carbon dioxide gas generated when the organic substance is mineralized. After deaeration, the radioactive liquid is passed through the adsorbent to remove the radionuclides by adsorption.

  In addition, in order to achieve the above object, the radioactive waste liquid treatment apparatus of the present invention includes a mixing tank to which radioactive waste liquid is supplied, and an oxidant supply that is connected to the mixing tank and supplies an oxidant into the mixing tank. An apparatus, a pH adjusting agent supply device connected to the mixing tank and supplying a pH adjusting agent into the mixing tank, and an oxidizer connected to the mixing tank, from the oxidizing agent supply device and the pH adjusting agent supply device. And an adsorption device that removes radionuclides contained in the radioactive liquid waste that has been added with a pH adjuster and discharged from the mixing tank.

  According to the present invention, radionuclide can be efficiently separated and removed from a radioactive liquid waste containing a radionuclide, particularly a radioactive liquid waste containing a low concentration of the radionuclide contained in a radioactive liquid waste containing a salt.

It is a block diagram which shows Example 1 of the radioactive waste liquid processing apparatus used for the processing method of the radioactive waste liquid of this invention. It is a block diagram which shows Example 2 of the radioactive waste liquid processing apparatus used for the processing method of the radioactive waste liquid of this invention. It is a block diagram which shows Example 3 of the radioactive waste liquid processing apparatus used for the processing method of the radioactive waste liquid of this invention. It is a block diagram which shows Example 4 of the radioactive waste liquid processing apparatus used for the processing method of the radioactive waste liquid of this invention.

  Hereinafter, based on the illustrated embodiment, a method and apparatus for treating radioactive liquid waste, which is a preferred embodiment of the present invention, will be described.

  FIG. 1 shows a first embodiment of a radioactive waste liquid treatment apparatus used in the method for treating a radioactive waste liquid of the present invention.

  As shown in the figure, the radioactive liquid waste containing the radionuclide is introduced into the adjustment tank 2 through the pipe 10. In the adjustment tank 2, an oxidant supply device 4 and a pH adjustment agent supply device 7 are installed. The oxidant supply device 4 includes an oxidant tank 5, an oxidant supply pipe 6, and an open / close valve (not shown) installed in the oxidant supply pipe 6. The pH adjusting agent supply device 7 includes a pH adjusting agent tank 8, a pH adjusting agent supply pipe 9, and an open / close valve (not shown) installed in the pH adjusting agent supply pipe 9. An oxidant is supplied from the oxidant supply device 4 to the radioactive waste liquid introduced into the adjustment tank 2 from the oxidant tank 5 through the oxidant supply pipe 6. Further, the pH adjuster is supplied from the pH adjuster supply device 7 through the pH adjuster supply pipe 9 from the pH adjuster tank 8. The adjustment tank 2 is equipped with a stirring device (not shown) for mixing the radioactive liquid waste, the oxidizing agent, and the pH adjusting agent, and the radioactive waste liquid, the oxidizing agent, and the pH adjusting agent supplied to the adjusting tank 2 are provided. Mixed.

  Radionuclides contained in radioactive liquid waste include, for example, transition metals such as ruthenium, technetium and niobium, alkali metals such as cesium, alkaline earth metals such as strontium, metal elements such as rare earths such as cerium, halogens such as antimony, tellurium and iodine. It consists of one or more multi-nuclide of non-metallic elements such as carbon and boron.

  As the oxidizing agent supplied from the oxidizing agent supply device 4, for example, hydrogen peroxide, ozone, an aqueous solution of permanganic acid and a salt thereof, and an aqueous solution of hypochlorous acid and a salt thereof are used. Examples of the pH adjuster supplied from the pH adjuster supply device 7 include acid solutions such as hydrochloric acid, nitric acid, sulfuric acid, and phosphoric acid, and alkali solutions such as sodium hydrogen carbonate, sodium carbonate, sodium hydroxide, and potassium hydroxide. Is done.

  The pH adjuster may be added as necessary, or may not be added.

  Here, a non-radioactive nuclide composed of the same element as the radionuclide contained in the radioactive liquid waste may be added as a carrier. In this case, non-radioactive nuclides are added to the adjustment tank 2 from a carrier supply device (not shown).

  The radioactive liquid waste that has passed through the adjustment tank 2 is supplied to the adsorption device 1 through the pipe 11. An operation for decomposing and removing the remaining oxidizing agent may be added to the radioactive waste liquid supplied to the adsorption device 1 as necessary. The adsorption device 1 is filled with one or more kinds of adsorbents depending on the radionuclide contained in the radioactive liquid waste. In the process of passing through the adsorption device 1, the radionuclide contained in the radioactive liquid waste is adsorbed and separated, and water from which the radionuclide has been removed is obtained as treated water.

  As the adsorbent filled in the adsorption device 1, for example, ion exchange resin, chelate resin, activated carbon, oxine-impregnated activated carbon, zeolite, titanic acid, ferrocyanide and the like are used.

Here, the reaction that occurs when an oxidizing agent is added to the radioactive liquid waste will be described using iodine as an example. It is known that a radioactive isotope of iodine, for example I-131, takes a chemical form of iodide ion (I ⁻ ) or iodate ion (IO ₃ ⁻ ). When ozone is added as an oxidizing agent to a radioactive liquid waste containing I ⁻ and IO ₃ ⁻ , the following reaction proceeds and I ⁻ becomes IO ₃ ⁻ .
I ⁻ + 3O ₃ → IO ₃ ⁻ + 3O ₂
Thus, I ^- and IO ₃ ^- in the case of two chemical forms are present, it was necessary to prepare an adsorbent which corresponds to each of the chemical forms, the chemical form IO ₃ ^- adjusted to Thus, an adsorbent corresponding to IO ₃ ⁻ may be prepared, and effects such as a reduction in the number of adsorption towers and a reduction in adsorbent cost can be obtained.

In the present embodiment, the example in which the oxidizing agent and the pH adjusting agent are added to the radioactive liquid waste has been described, but a reducing agent may be added instead of the oxidizing agent. In that case, the oxidizing agent supply device in this embodiment is read as a reducing agent supply device. When, for example, ascorbic acid (C ₆ H ₈ O ₆ ) is added as a reducing agent and hydrochloric acid is added as a pH adjuster to a waste solution containing, for example, radioactive iodine, the following reaction proceeds.
IO ₃ ⁻ + 5I ⁻ + 6H ⁺ → 3I ₂ + 3H ₂ O
C ₆ H ₈ O ₆ + I ₂ → C ₆ H ₆ O ₆ + 2H ⁺ + 2I ⁻
Thereby, when radioactive iodine exists in two kinds of chemical forms of IO ₃ ⁻ and I ⁻ , it can be made one kind of I ⁻ .

  According to the present embodiment, there is an effect that the radionuclide can be efficiently separated and removed from the radioactive liquid waste containing the radionuclide, particularly the radioactive liquid waste containing a low concentration of the radionuclide contained in the radioactive liquid waste containing the salt.

  FIG. 2 shows a second embodiment of the radioactive waste liquid treatment apparatus used in the method for treating radioactive waste liquid of the present invention.

  As shown in the figure, the radioactive liquid waste containing the radionuclide is introduced into the liquidity adjusting unit 21 through the pipe 10. The liquidity adjusting unit 21 is provided with an oxidizing agent supply device 4A and a pH adjusting agent supply device 7A. The oxidant supply device 4A includes an oxidant tank 5A, an oxidant supply pipe 6A, and an open / close valve (not shown) installed in the oxidant supply pipe 6A. The pH adjusting agent supply device 7A includes a pH adjusting agent tank 8A, a pH adjusting agent supply pipe 9A, and an open / close valve (not shown) installed in the pH adjusting agent supply pipe 9A. The oxidant is supplied from the oxidant supply device 4A to the radioactive waste liquid introduced into the liquidity adjusting unit 21 from the oxidant tank 5A through the oxidant supply pipe 6A. Further, the pH adjusting agent is supplied from the pH adjusting agent supply device 7A through the pH adjusting agent supply pipe 9A from the pH adjusting agent tank 8A. In the liquid property adjustment unit 21, the radioactive waste liquid supplied to the liquid property adjustment unit 21, the oxidizing agent, and the pH adjustment agent are mixed. The liquid property adjusting unit 21 has a structure in which the oxidizing agent and the pH adjusting agent can be mixed with the radioactive liquid waste in the process of passing the liquid property adjusting unit 21 such as a static mixer.

  The radionuclide contained in the radioactive liquid waste is composed of the elements shown in Example 1.

  As the oxidizing agent supplied from the oxidizing agent supply device 4A and the pH adjusting agent supplied from the pH adjusting agent supply device 7A, the chemicals shown in Example 1 can be used.

  The pH adjuster may be added as necessary, or may not be added. Moreover, you may supply the non-radioactive nuclide which consists of the same element as the radionuclide contained in a radioactive waste liquid to the liquid property adjustment part 21 as a carrier as needed.

  The radioactive liquid waste that has passed through the liquid adjustment unit 21 is supplied to the adsorption device 1A through the pipe 11A. You may add operation which decomposes | disassembles the remaining oxidizing agent to the radioactive waste liquid supplied to 1 A of adsorption apparatuses as needed. The adsorption device 1A is filled with one or more kinds of adsorbents according to the radionuclide contained in the radioactive liquid waste. In the process of passing through the adsorption device 1A, the radionuclide contained in the radioactive liquid waste is adsorbed and separated, and water from which the radionuclide has been removed is obtained as treated water.

  According to the present embodiment, it is possible to obtain the same effect as that of the first embodiment, and it is possible to simplify the apparatus by using the liquidity adjusting unit.

  FIG. 3 shows a third embodiment of the radioactive waste liquid treatment apparatus used in the method for treating radioactive waste liquid of the present invention.

  As shown in the figure, the radioactive liquid waste containing the radionuclide is introduced into the liquidity adjusting unit 21B through the pipe 10. A pH adjuster supply device 7B is installed in the liquidity adjusting unit 21B. The pH adjusting agent supply device 7B includes a pH adjusting agent tank 8B, a pH adjusting agent supply pipe 9B, and an open / close valve (not shown) installed in the pH adjusting agent supply pipe 9B. The pH adjusting agent is supplied from the pH adjusting agent supply device 7B to the radioactive waste liquid introduced into the liquid adjusting unit 21B from the pH adjusting agent tank 8B through the pH adjusting agent supply pipe 9B. In the liquid property adjusting unit 21B, the radioactive liquid waste supplied to the liquid property adjusting unit 21B and the pH adjusting agent are mixed. The liquid property adjusting unit 21B has a structure in which the pH adjusting agent can be mixed with the radioactive waste liquid in the process of passing the liquid property adjusting unit 21B such as a static mixer.

  The radionuclide contained in the radioactive liquid waste is composed of the elements shown in Example 1.

  As the pH adjusting agent supplied from the pH adjusting agent supply device 7B, the agent shown in Example 1 can be used. Moreover, you may supply the non-radioactive nuclide which consists of the same element as the radionuclide contained in a radioactive waste liquid to the liquid property adjustment part 21B as a carrier as needed.

  The radioactive waste liquid that has passed through the liquidity adjusting unit 21B is supplied to the adsorption device 1B through the pipe 11B. The adsorption device 1B is filled with one or more kinds of adsorbents according to the radionuclide contained in the radioactive liquid waste. In the process of passing through the adsorption device 1B, the radionuclide contained in the radioactive liquid waste is adsorbed and separated, and water from which the radionuclide has been removed is obtained as treated water.

  Here, the effect produced by adjusting the pH of the radioactive liquid waste will be described using ruthenium as an example. It is known that a radioisotope of ruthenium, for example Ru-106, takes a plurality of oxidation numbers and takes a plurality of chemical forms depending on the properties of the radioactive liquid waste. For example, in an alkaline radioactive liquid waste, hydroxide ions bind to form a colloidal ruthenium compound. Colloidal ruthenium compounds are difficult to remove with adsorbents, especially when the concentration is low. Therefore, an acid such as hydrochloric acid is added to the radioactive liquid waste containing ruthenium to adjust the pH of the radioactive liquid waste to 2. At this time, ruthenium is in the form of a positively charged cation or ruthenium chloride combined with chloride ions. Cationic ruthenium can be easily adsorbed and removed by cation exchange resin or chelate resin, and ruthenium chloride by chelate resin.

  According to the present example, the same effect as in Example 2 can be obtained, and since only the pH adjuster is added, the apparatus can be further simplified.

  FIG. 4 shows a fourth embodiment of the radioactive waste liquid treatment apparatus used in the radioactive waste liquid treatment method of the present invention.

As shown in the figure, the radioactive liquid waste containing the radionuclide is introduced into the adjustment tank 22 through the pipe 10. In the adjustment tank 22, an oxidant supply device 4C and a pH adjustment agent supply device 7C are installed. The oxidant supply device 4C includes an oxidant tank 5C, an oxidant supply pipe 6C, and an open / close valve (not shown) installed in the oxidant supply pipe 6C. The pH adjusting agent supply device 7C includes a pH adjusting agent tank 8C, a pH adjusting agent supply pipe 9C, and an open / close valve (not shown) installed in the pH adjusting agent supply pipe 9C. Oxidant is supplied from the oxidant supply device 4C to the radioactive waste liquid introduced into the adjustment tank 22 from the oxidant tank 5C through the oxidant supply pipe 6C. Further, the pH adjusting agent is supplied from the pH adjusting agent supply device 7C from the pH adjusting agent tank 8C through the pH adjusting agent supply pipe 9C. The adjustment tank 22 is equipped with a stirring device (not shown) for mixing the radioactive liquid waste, the oxidizing agent, and the pH adjusting agent, and the radioactive waste liquid supplied to the adjusting tank 22 is mixed with the oxidizing agent and the pH adjusting agent. Is done. At this time, if the radioactive waste liquid contains an organic substance as an impurity, the organic substance reacts with the oxidizing agent to become carbonate ion (CO ₃ ²⁻ ) or hydrogen carbonate ion (HCO ₃ ⁻ ). When the pH of the radioactive liquid waste is acidic, carbonate ions and hydrogen carbonate ions are further oxidized to carbon dioxide (CO ₂ ) and volatilize from the radioactive liquid waste. The volatilized carbon dioxide is discharged from the adjustment tank 22 through the pipe 12. In order to promote the volatilization of carbon dioxide from the radioactive liquid waste, the adjustment tank 22 may be provided with a device (not shown) for bubbling an inert gas such as nitrogen gas to the radioactive liquid waste in the adjustment tank 22.

  The radionuclide contained in the radioactive liquid waste is composed of the elements shown in Example 1.

  As the oxidizing agent and pH adjusting agent supplied from the oxidizing agent supplying device 4C and the pH adjusting agent supplying device 7C, the agent shown in Example 1 can be used.

  The pH adjuster may be added as necessary, or may not be added. Here, a non-radioactive nuclide composed of the same element as the radionuclide contained in the radioactive liquid waste may be added as a carrier. In this case, non-radioactive nuclides are added to the adjustment tank 22 from a carrier supply device (not shown).

  The radioactive liquid waste that has passed through the adjustment tank 22 is supplied to the adsorption device 1C through the pipe 11C. An operation for decomposing and removing the remaining oxidant may be added to the radioactive waste liquid supplied to the adsorption device 1C as necessary. The adsorbing device 1C is filled with one or more kinds of adsorbents depending on the radionuclide contained in the radioactive liquid waste. In the process of passing through the adsorption device 1C, the radionuclide contained in the radioactive liquid waste is adsorbed and separated, and water from which the radionuclide has been removed is obtained as treated water.

  According to the present embodiment, the same effect as that of the first embodiment can be obtained even when the radioactive liquid waste contains impurities composed of organic substances.

  DESCRIPTION OF SYMBOLS 1, 1A, 1B, 1C ... Adsorption device, 2, 22 ... Adjustment tank, 21, 21B ... Liquidity adjustment part, 4, 4A, 4C ... Oxidant supply device, 5, 5A, 5C ... Oxidant tank, 6, 6A, 6C ... oxidizing agent supply piping, 7, 7A, 7B, 7C ... pH adjusting agent supplying device, 8, 8A, 8B, 8C ... pH adjusting agent tank, 9, 9A, 9B, 9C ... pH adjusting agent supplying piping, 10, 11, 11A, 11B, 11C, 12 ... piping.

Claims (11)

In a method for separating and removing radionuclides from radioactive liquid waste containing radionuclides,
A method for treating a radioactive waste liquid, comprising adding an oxidizing agent or a reducing agent to the radioactive waste liquid and then passing the radioactive waste liquid through an adsorption tower packed with an adsorbent to adsorb and remove the radionuclide. In the processing method of the radioactive liquid waste of Claim 1,
A method for treating a radioactive liquid waste, comprising adding a pH adjuster to the radioactive liquid waste added with the oxidizing agent or the reducing agent. In the processing method of the radioactive liquid waste of Claim 1 or 2,
A method for treating a radioactive liquid waste, comprising adding a carrier comprising a non-radioactive nuclide of the same element as the radionuclide contained in the radioactive liquid waste to the radioactive liquid waste added with the oxidizing agent or the reducing agent. In the processing method of the radioactive liquid waste of any one of Claims 1 thru | or 3,
The method for treating a radioactive liquid waste according to claim 1, wherein the oxidizing agent comprises at least one of ozone, hydrogen peroxide, an aqueous solution of permanganic acid and a salt thereof, and an aqueous solution of hypochlorous acid and a salt thereof. In the processing method of the radioactive liquid waste of Claim 4,
A method for treating radioactive waste liquid, comprising passing an inert gas through the radioactive waste liquid to which the oxidizing agent is added. In the processing method of the radioactive liquid waste of Claim 5,
The method for treating a radioactive liquid waste, wherein the inert gas comprises at least one of nitrogen gas, argon gas, and helium gas. In the processing method of the radioactive liquid waste of any one of Claims 1 thru | or 3,
The said reducing agent consists of any one or more of ascorbic acid, hydrazine, and oxalic acid, The processing method of the radioactive liquid waste characterized by the above-mentioned. In the processing method of the radioactive liquid waste of any one of Claim 2 thru | or 7,
The pH adjuster comprises one or more of hydrochloric acid, nitric acid, sulfuric acid, phosphoric acid, aqueous sodium hydrogen carbonate solution, aqueous sodium carbonate solution, aqueous sodium hydroxide solution, and aqueous potassium hydroxide solution. Processing method. In a method for separating and removing radionuclides from radioactive liquid waste containing radionuclides,
A method for treating a radioactive liquid waste, comprising adding a pH adjusting agent to the radioactive liquid waste and then passing the radioactive liquid waste through an adsorption tower packed with an adsorbent to adsorb and remove the radionuclide. In the processing method of the radioactive liquid waste according to claim 9,
The pH adjuster comprises any one or more of hydrochloric acid, nitric acid, sulfuric acid, phosphoric acid, sodium hydrogen carbonate aqueous solution, sodium carbonate aqueous solution, sodium hydroxide aqueous solution, and potassium hydroxide aqueous solution. Method.   A mixing tank to which radioactive liquid waste is supplied, an oxidant supply device connected to the mixing tank and supplying an oxidant into the mixing tank, and a pH adjusting agent connected to the mixing tank and supplied to the mixing tank PH adjusting agent supply device connected to the mixing tank, and the oxidizing agent and pH adjusting agent are added from the oxidizing agent supplying device and the pH adjusting agent supplying device, and are included in the radioactive liquid waste discharged from the mixing tank. An apparatus for treating a radioactive liquid waste comprising an adsorption device for removing the radionuclide.

Images