JP2013221898A - Waste liquid treatment system and waste liquid treatment method - Google Patents

Abstract

Disclosed is a waste liquid treatment system and a waste liquid treatment method capable of disposing of zeolite and anion resin generated as secondary waste by treating metal ions in decontamination waste liquid.
A waste liquid treatment system 40 according to the present invention decontaminates a decontamination target system 41 of a nuclear reactor facility, and includes a decontamination waste liquid circulation line L11, a chemical liquid supply unit 42, a zeolite filling tank 43, The anion resin tower 44, the first decontamination waste liquid branch line L12, and the second decontamination waste liquid branch line L13, and by treating the metal ions in the decontamination waste liquid 58, the secondary waste It becomes possible to dispose of the generated zeolite and anion resin respectively.
[Selection] Figure 2

Description

  The present invention relates to a waste liquid treatment system and a waste liquid treatment method.

  In radiation handling facilities such as nuclear power plants and spent fuel reprocessing plants, structural parts such as pipes that come into contact with radioactive liquid waste containing radioactive materials are associated with the operation of nuclear power plants and reprocessing plants in radiation handling facilities. A film such as an oxide or salt containing a radioactive substance adheres to or forms on the inner surface. If the operation period of the facility becomes longer, the radiation dose around pipes and equipment increases, and there is a risk that the dose of workers will be increased during periodic inspections, maintenance work, or waste demolition work. In order to reduce the exposure of workers, it is necessary to remove (decontaminate) radioactive substances adhering to piping and equipment.

  A typical reactor to be decontaminated is a reactor primary cooling system (primary cooling system). A scale called a clad containing a radioactive substance is attached to the primary cooling system. This cladding serves as a radiation source for workers to receive radiation exposure around the primary cooling system piping and equipment. In order to reduce radiation exposure and improve the working environment, it is necessary to remove the cladding and decontaminate piping and equipment. For decontamination of piping and equipment, for example, a chemical contamination removal method in which chemical treatment is performed using a chemical is used (for example, see Patent Document 1).

  In addition, decontamination waste liquid generated by decontamination of equipment in such a radiation handling facility is used to chemically remove radioactive substances such as metal ions contained in the decontamination solution using an ion exchange resin such as a cation resin or anion resin. Has been proposed (for example, see Patent Document 2).

Japanese Patent Publication No. 3-10919 Japanese Patent No. 2941429

  In the waste liquid treatment method for decontamination waste liquid, cation resin and mixed bed resin (mixed of cation resin and anion resin) used for the treatment of metal ions in decontamination waste liquid are generated as secondary waste. Spent cation resin and mixed bed resin have high doses, so incineration is difficult. In addition, since the cationic resin is an organic substance, the mixed-bed resin contains a chelate compound in addition to being an organic substance. Therefore, it is difficult to solidify it into a solid substance and embed it in a disposal site.

  That is, high-dose organic substances cause hydrogen gas to be generated by radioactive decomposition. In addition, the chelate compound promotes nuclide migration and causes the barrier performance of the disposal site to deteriorate. For these reasons, the organic substances and chelate compounds used in the treatment of the decontamination waste liquid are not allowed to be buried. Therefore, the cation resin and mixed bed resin generated as secondary waste cannot be disposed of and must be stored in the nuclear power plant.

  The present invention has been made in view of the above, and is a waste liquid treatment system capable of disposing of zeolite, anion resin generated as secondary waste by treating metal ions in the decontamination waste liquid, and decontamination It aims at providing the processing method of a waste liquid.

  The first invention of the present invention for solving the above-described problem is that a chemical solution supplied to a decontamination target system of a nuclear reactor facility is discharged from the decontamination target system as a decontamination waste liquid and circulated to the decontamination target system. A decontamination waste liquid circulation line, a chemical liquid supply unit that is provided in the decontamination waste liquid circulation line, and supplies a chemical liquid containing one or both of an oxidizing agent and a reducing agent to the decontamination waste liquid, and the decontamination waste liquid One or more inorganic ion exchanger filling tanks equipped with an inorganic ion exchanger that adsorbs metal ions contained therein, and an anion resin tower comprising an anion exchange resin that adsorbs anions contained in the decontamination waste liquid; The decontamination waste liquid extraction line and the inorganic ion exchanger filling tank are connected, the decontamination waste liquid is supplied to the inorganic ion exchanger filling tank, and the first decontamination waste liquid is returned to the decontamination waste liquid extraction line. Branch line and before A decontamination waste liquid extraction line and the anion resin tower are connected, the decontamination waste liquid is supplied to the anion resin tower, and a second decontamination waste liquid branch line is returned to the decontamination waste liquid extraction line. This is a featured waste liquid treatment system.

  A second invention is the waste liquid treatment system according to the first invention, wherein the inorganic ion exchanger filling tank is selected according to the type of metal ions to be removed. .

  A third invention is the waste liquid treatment system according to the first or second invention, wherein the inorganic ion exchanger is zeolite.

  According to a fourth aspect of the present invention for solving the above-mentioned problems, a decontamination waste liquid generated when decontamination of a decontamination target system of a reactor facility is supplied to an inorganic ion exchanger filling tank, An inorganic ion exchanger permeation step for adsorbing metal ions dissolved in the waste liquid to the inorganic ion exchanger, and the decontamination waste liquid from which the reducing agent is removed are passed through the anion resin tower, and the metal ions remaining in the decontamination waste liquid And an anion resin permeation step for removing the reducing agent.

  A fifth aspect of the invention is a waste liquid treatment method according to the fourth aspect of the invention, wherein the inorganic ion exchanger filling tank selects an inorganic ion exchanger according to the type of metal ions to be removed.

  According to a sixth invention, in the fourth or fifth invention, in at least one of the above steps, the chemical solution supplied to the decontamination target system is discharged from the decontamination target system as a decontamination waste liquid, and the decontamination The waste liquid treatment method is characterized in that the waste liquid is circulated at least once by a decontamination waste liquid circulation line to be circulated to a target system.

  According to the present invention, it is possible to dispose of zeolite and anion resin generated as secondary waste by treating metal ions in the decontamination waste liquid.

FIG. 1 is a schematic configuration diagram schematically showing a nuclear power plant to which a waste liquid treatment system according to an embodiment of the present invention is applied. FIG. 2 is a schematic view showing a waste liquid treatment system according to an embodiment of the present invention. FIG. 3 is a flowchart showing the procedure of the decontamination waste liquid processing method according to the embodiment of the present invention. FIG. 4 is an explanatory view showing a state in one step of the processing method of the decontamination waste liquid according to the embodiment of the present invention. FIG. 5 is an explanatory diagram showing a state in one step of the processing method of the decontamination waste liquid according to the embodiment of the present invention. FIG. 6 is an explanatory diagram showing a state in one step of the processing method of the decontamination waste liquid according to the embodiment of the present invention. FIG. 7 is an explanatory view showing a state in one step of the processing method of the decontamination waste liquid according to the embodiment of the present invention. FIG. 8 is an explanatory view showing a state in one step of the processing method of the decontamination waste liquid according to the embodiment of the present invention. FIG. 9 is an explanatory diagram illustrating a state in one step of the processing method of the decontamination waste liquid according to the embodiment of the present invention. FIG. 10 is a diagram showing another configuration of the waste liquid treatment system according to the embodiment of the present invention.

  Hereinafter, embodiments of a waste liquid treatment system and a waste liquid treatment method according to the present invention will be described in detail with reference to the drawings. In addition, this invention is not limited by the following Example. In addition, constituent elements in the following embodiments include those that can be easily assumed by those skilled in the art, those that are substantially the same, and those in a so-called equivalent range. Furthermore, the constituent elements disclosed in the following embodiments can be appropriately combined.

<Nuclear power plant>
A case where the waste liquid treatment system according to the embodiment of the present invention is applied to a nuclear power plant will be described with reference to the drawings. The nuclear power plant nuclear reactor uses light water as the reactor coolant and neutron moderator, and converts it into high-temperature and high-pressure water that does not boil throughout the primary system. This is a pressurized water reactor (PWR) that generates steam by exchanging it and sends the steam to a turbine generator to generate electricity. The present embodiment is not limited to PWR but can be applied to an improved pressurized water reactor (APWR) or a boiling water reactor (BWR) which is an improvement of the PWR. It can also be applied to radiation handling facilities.

  FIG. 1 is a schematic configuration diagram schematically showing a nuclear power plant to which a waste liquid treatment system according to an embodiment of the present invention is applied. As shown in FIG. 1, a nuclear power plant 10 includes a reactor cooling system (hereinafter also referred to as a primary system) 12 including a nuclear reactor 11 and a turbine system (hereinafter referred to as a secondary system) that exchanges heat with the reactor cooling system 12. 13). Reactor coolant (primary cooling water) flows through the reactor cooling system 12, and secondary coolant (secondary cooling water) flows through the turbine system 13.

  The reactor cooling system (primary system) 12 includes a nuclear reactor 11 and a steam generator 16 connected to the nuclear reactor 11 through a cold leg 15a and a hot leg 15b. In addition, a pressurizer 17 is interposed in the hot leg 15b, and a reactor coolant pump 18 is interposed in the cold leg 15a. The reactor 11, the cold leg 15 a, the hot leg 15 b, the steam generator 16, the pressurizer 17, and the reactor coolant pump 18 are accommodated in the reactor containment vessel 19.

  As described above, the nuclear reactor 11 is a pressurized water nuclear reactor, and its interior is filled with a nuclear reactor coolant (primary cooling water). In the nuclear reactor 11, a large number of fuel assemblies 21 are accommodated, and a large number of control rods 22 for controlling nuclear fuel fission in the fuel rods of the fuel assemblies 21 can be inserted into the fuel assemblies 21. Is provided.

  When the nuclear fuel in the fuel rod of the fuel assembly 21 is fissioned while controlling the fission reaction by the control rod 22, thermal energy is generated by this fission. The generated thermal energy heats the reactor coolant, and the heated reactor coolant is sent to the steam generator 16 via the hot leg 15b. On the other hand, the reactor coolant sent from each steam generator 16 via the cold leg 15 a flows into the reactor 11 and cools the reactor 11.

  The pressurizer 17 interposed in the hot leg 15b suppresses boiling of the reactor coolant by pressurizing the reactor coolant that has become high temperature. Further, the steam generator 16 evaporates the secondary coolant by causing the reactor coolant (primary cooling water), which has become high temperature and high pressure, to exchange heat with the secondary coolant (secondary cooling water), thereby generating steam. The reactor coolant generated and cooled to high temperature and pressure is cooled. The reactor coolant pump 18 circulates the reactor coolant in the reactor cooling system 12, and sends the reactor coolant from the steam generator 16 to the reactor 11 via the cold leg 15a and also the reactor coolant. From the nuclear reactor 11 to the steam generator 16 through the hot leg 15b.

  The reactor coolant circulates between the reactor 11 and the steam generator 16. The reactor coolant is light water used as a coolant and a neutron moderator.

  The turbine system (secondary system) 13 includes a turbine 25 connected to each steam generator 16 via a steam pipe 24, a condenser 26 connected to the turbine 25, a condenser 26, and each steam generator. And a water supply pump 28 interposed in a water supply pipe 27 that connects to the water supply pipe 27. A generator 29 is connected to the turbine 25.

  A series of operations in the turbine system 13 of this nuclear power plant will be described. When steam flows from the steam generator 16 into the turbine 25 through the steam pipe 24, the turbine 25 rotates. When the turbine 25 rotates, the generator 29 connected to the turbine 25 generates power. Thereafter, the steam discharged from the turbine 25 flows into the condenser 26. The condenser 26 has a cooling pipe 30 disposed therein, and one of the cooling pipes 30 is connected to a water intake pipe 31 for supplying cooling water (for example, seawater). Is connected to a drain pipe 32 for draining the cooling water. The condenser 26 cools the steam flowing in from the turbine 25 by the cooling pipe 30 to return the steam to the liquid. The secondary coolant that has become liquid is sent to the steam generator 16 via the feed water pipe 27 by the feed water pump 28. The secondary coolant sent to the steam generator 16 becomes steam again by exchanging heat with the reactor coolant in the steam generator 16.

  In such a nuclear power plant 10, members constituting the reactor equipment such as nuclear reactor equipment and various pipes are generally made of a steel material such as stainless steel or carbon steel. When these components that make up the nuclear reactor equipment are used, the surfaces of the components making up the nuclear reactor equipment such as nuclear reactor equipment and various pipes are corroded by contact with high-temperature water (primary cooling water). A film is formed. The film is made of at least one metal or oxide of RI, Cr, Fe, and Ni.

  Radioactivity in the reactor water is taken into the coating formed on the wetted parts of the reactor equipment and the inner surface of the piping exposed to high-temperature water (primary cooling water), and it becomes an exposure radiation source. Such a system for decontamination of reactor equipment such as reactor equipment and various pipes is decontaminated using the waste liquid treatment system according to the embodiment of the present invention. In addition, decontamination means removing the radioactive substance adhering to piping, equipment, etc. of the system for decontamination of nuclear reactor equipment.

(Waste liquid treatment system)
FIG. 2 is a schematic diagram illustrating a waste liquid treatment system according to the present embodiment. As shown in FIG. 2, the waste liquid treatment system 40 according to the present embodiment is for decontamination of a decontamination target system 41 of a nuclear reactor facility, and includes a decontamination waste liquid circulation line L11, a chemical liquid supply unit 42, , Zeolite filling tank (inorganic ion exchanger filling tank) 43, anion resin tower 44, ultraviolet (UV) tower (ultraviolet irradiation means) 45, first decontamination waste liquid branch lines L12-1, L12-2, And a second decontamination waste liquid branch line L13.

  The decontamination target system 41 of the nuclear reactor equipment is a member constituting the nuclear reactor equipment such as nuclear reactor equipment and various pipes.

  The decontamination waste liquid circulation line L11 is a decontamination target for the reactor equipment using the chemical liquid (first chemical liquid 52, second chemical liquid 53, and third chemical liquid 54) supplied to the decontamination target system 41 of the nuclear reactor equipment as the decontamination waste liquid 58. It is a line that is discharged from the system 41 and circulated to the decontamination target system 41 of the reactor facility. The decontamination waste liquid 58 is a waste liquid generated when the chemical liquid (the first chemical liquid 52, the second chemical liquid 53, and the third chemical liquid 54) passes through the decontamination target system 41 of the reactor facility.

  The decontamination waste liquid discharge line L14 is a line for discharging the decontamination waste liquid 58 from the decontamination target system 41 of the reactor facility. The decontamination waste liquid 58 in the decontamination target system 41 of the nuclear reactor facility passes through the decontamination waste liquid discharge line L12, is treated with the waste liquid, and is then discarded in a drum can.

  The decontamination waste liquid circulation line L11 and the decontamination waste liquid discharge line L12 are provided with control valves V11 and V12, respectively. The amount of the decontamination waste liquid 58 drawn out to the decontamination waste liquid circulation line L11, the decontamination waste liquid discharge line L12 The discharge amount of the decontamination waste liquid 58 to be discharged is adjusted by the control valves V11 and V12, respectively.

  The filter 59 is provided in the decontamination waste liquid circulation line L11 and removes deposits in the decontamination waste liquid 58. An example of the filter 59 is poremet. The control valve V13 is provided in the decontamination waste liquid circulation line L11 on the downstream side of the filter 59, and the discharge amount of the decontamination waste liquid 58 discharged from the filter 59 is adjusted by the control valve V13.

  The heating device 60 is provided in the decontamination waste liquid circulation line L <b> 11, and includes a heating tank 61 that stores the decontamination waste liquid 58, and a heating unit 62 that is provided around the heating tank 61. As the heating means 62, for example, a heater or the like is used. The warming device 60 warms the decontamination waste liquid 58 to, for example, 80 ° C to 100 ° C.

  Control valves V14 and V15 are provided downstream of the heating device 60 in the decontamination waste liquid circulation line L11 in the liquid flow direction, and the flow path of the decontamination waste liquid 58 discharged from the heating device 60 is adjusted. It is adjusted by valves V14 and V15. The decontamination waste liquid circulation line L11 is provided with a pump P1, and the flow rate of the decontamination waste liquid 58 circulating through the decontamination waste liquid circulation line L11 is adjusted by the pump P1.

  The zeolite filling tanks 43 </ b> A and 43 </ b> B are tanks provided with zeolite (inorganic ion exchanger) that adsorbs metal ions contained in the decontamination waste liquid 58. In this example, zeolite is used as the inorganic ion exchanger, but the present invention is not limited to this, and inorganic ion exchangers such as zirconium phosphate, clay minerals, and non-zeolite inorganic ion exchangers are used. Is appropriately selected according to the type of metal ion to be removed.

  The first decontamination waste liquid branch lines L12-1 and L12-2 connect the decontamination waste liquid circulation line L11 and the zeolite filling tanks 43A and 43B, respectively, and supply the decontamination waste liquid 58 to the zeolite filling tanks 43A and 43B. , A line that returns to the decontamination waste liquid circulation line L11. The first decontamination waste liquid branch line L12-1 is provided with control valves V21 and V22, and the supply amount of the decontamination waste liquid 58 is adjusted by the control valves V21 and V22. The second decontamination waste liquid branch line L12-2 is provided with control valves V23 and V24, and the supply amount of the decontamination waste liquid 58 is adjusted by the control valves V23 and V24.

  The anion resin tower 44 is a tower provided with an anion exchange resin that adsorbs anions contained in the decontamination waste liquid 58. In this embodiment, one is provided, but the present invention is not limited to this, and a plurality of them may be provided.

  The second decontamination waste liquid branch lines L13-1 and L13-2 connect the decontamination waste liquid circulation line L11 and the anion resin tower 44, supply the decontamination waste liquid 58 to the anion resin tower 44, and decontamination waste liquid circulation. This is a line that returns to the line L11. Control valves V25 and V26 are provided in the second decontamination waste liquid branch lines L13-1 and L13-2, and the supply amount of the decontamination waste liquid 58 is adjusted by the control valves V25 and V26.

  The chemical liquid supply unit 42 is provided in the decontamination waste liquid circulation line L <b> 11, and supplies a chemical liquid containing one or both of an oxidizing agent and a reducing agent to the decontamination waste liquid 58. In the present embodiment, the chemical liquid supply unit 42 includes a first chemical liquid supply unit 55 that supplies the first chemical liquid 52, a second chemical liquid supply unit 56 that supplies the second chemical liquid 53, and a third chemical liquid 54 that supplies the third chemical liquid 54. And a chemical solution supply unit 57. The chemical solution supply unit 42 is connected to the chemical solution supply line L14-1 connected to the first chemical solution supply unit 55, the chemical solution supply line L14-2 connected to the second chemical solution supply unit 56, and the third chemical solution supply unit 57. The chemical solution supply line L14-3, the chemical solution supply lines L14-1 to L14-3, and the chemical solution supply line L14-4 connecting the decontamination waste liquid circulation line L11 are included. Each chemical solution that passes through the chemical solution supply lines L14-1, L14-2, and L14-3 passes through the chemical solution supply line L14-4 and is supplied to the decontamination waste liquid circulation line L11.

  The chemical liquid supply line L14-1 is provided with a pump P2, and the first chemical liquid 52 is supplied from the first chemical liquid supply unit 55 by the pump P2. The chemical liquid supply line L14-2 is provided with a pump P3, and the second chemical liquid 53 is supplied from the second chemical liquid supply unit 56 by the pump P3. The chemical solution supply line L14-3 is provided with a pump P4, and the third chemical solution 54 is supplied from the third chemical solution supply unit 57 by the pump P4.

  Moreover, the adjustment valve V31 is provided in the chemical solution supply line L14-1, and the supply amount of the first chemical solution 52 is adjusted by the adjustment valve V31. Moreover, the adjustment valve V32 is provided in the chemical solution supply line L14-1, and the supply amount of the second chemical solution 53 is adjusted by the adjustment valve V32. Further, the chemical supply line L14-3 is provided with a control valve V33, and the supply amount of the third chemical liquid 54 is adjusted by the control valve V33.

As the first chemical liquid 52, one containing at least one of permanganic acid (HMnO ₄ ), potassium permanganate (KMnO ₄ ), a nitric hydrofluoric acid mixed liquid of nitric acid and hydrofluoric acid, or the like is used. Permanganic acid and potassium permanganate are illustrated as examples of the oxidizing agent, and any chemical (oxidizing agent) having an equivalent oxidizing power can be used. The first chemical liquid 52 is supplied from the first chemical liquid supply unit 55 to the decontamination waste liquid circulation line L11 through the chemical liquid supply lines L14-1 and L14-4 by the pump P2. The first chemical liquid 52 is formed in the first chemical liquid 52 using chromium (Cr) -based oxide or the like adhering to members such as nuclear reactor equipment and various pipes constituting the decontamination target system 41 of the nuclear reactor equipment as chromic acid. It melts and removes from the member which comprises the decontamination object system | strain 41 of a nuclear reactor installation. As a density | concentration of the 1st chemical | medical solution 52, 0.005 mass% or more and 0.5 mass% or less are preferable, More preferably, 0.01 mass% or more and 0.3 mass% or less, More preferably, 0.01 mass% or more 0 .1% by mass or less.

As the second chemical solution 53, one containing at least one of oxalic acid (H ₂ C ₂ O ₄ ), citric acid (C ₆ H ₈ O ₇₄ ), and a mixed solution of nitric hydrofluoric acid is used. The mixed liquid of oxalic acid, citric acid, and nitric hydrofluoric acid is exemplified as an example of the reducing agent, and any chemical (reducing agent) having an equivalent reducing power can be used. The second chemical liquid 53 is supplied from the second chemical liquid supply unit 56 to the decontamination waste liquid circulation line L11 through the chemical liquid supply lines L14-2 and L14-4 by the pump P3. The second chemical solution 53 contains iron (Fe) oxide, nickel (Ni) oxide, etc. adhering to members such as reactor equipment and various pipes constituting the decontamination target system 41 of the reactor facility. Dissolve in 2 chemicals 53. Moreover, Cr oxide and unreacted permanganic acid are reduced. As a density | concentration of the 2nd chemical | medical solution 53, 0.005 mass% or more and 0.5 mass% or less are preferable, More preferably, 0.01 mass% or more and 0.3 mass% or less, More preferably, 0.01 mass% or more 0 .1% by mass or less.

As the third chemical liquid 54, hydrogen peroxide (H ₂ O ₂ ) or the like is used. H ₂ O ₂ is exemplified as an example of the oxidizing agent, and any chemical (oxidizing agent) having an equivalent oxidizing power can be used. The third chemical liquid 54 is supplied from the third chemical liquid supply unit 57 to the decontamination waste liquid circulation line L11 through the chemical liquid supply lines L14-3 and L14-4 by the pump P4. The third chemical liquid 54 decomposes oxalic acid by irradiating the oxalic acid chelate contained in the decontamination waste liquid 58 with ultraviolet rays.

  The first chemical liquid 52, the second chemical liquid 53, and the third chemical liquid 54 are attached according to the type of film that is attached to members such as reactor equipment and various pipes that constitute the decontamination target system 41 of the reactor facility. It is preferable to use an appropriate combination of chemicals that dissolve the.

  The UV tower 45 is provided in a decontamination waste liquid extraction line L15 branched from the decontamination waste liquid circulation line L11, and a storage tank 65 for storing the decontamination waste liquid 58, and an ultraviolet ray (UV) for irradiating the storage tank 65 with ultraviolet rays (UV). And an irradiation device 66 for irradiating the decontamination waste liquid 58 with UV light.

  The decontamination waste liquid extraction line L15 is provided with control valves V41 and V42, and the supply amount of the decontamination waste liquid 58 is adjusted by the control valves V41 and V42.

  The waste liquid treatment system 40 according to the present embodiment treats metal ions in the decontamination waste liquid 58 generated by decontaminating members such as nuclear reactor equipment and various pipes constituting the decontamination target system 41 of the reactor facility. Thus, the zeolite and the anion resin generated as secondary waste can be disposed respectively. That is, since the decontamination waste liquid 58 generated by decontaminating members such as the reactor equipment and various pipes constituting the decontamination target system 41 of the reactor facility contains radioactive substances, the zeolite filling tank 43A, The radioactive substance is adsorbed on the zeolite in 43B and the anion resin in the anion resin tower 44, and the zeolite and the anion resin become radioactive waste contaminated with the radioactive substance. In particular, the zeolite in the zeolite filling tanks 43A and 43B absorbs radioactive materials and has a high dose, and therefore cannot be incinerated. However, since zeolite is an inorganic substance, hydrogen gas is not generated by radioactive decomposition like organic substances. Therefore, even if the radioactive substance is adsorbed and becomes a high dose, it is solidified into a solid substance. Can be buried in In addition, as described later, the anion resin tower 44 is assumed to contain a chelate compound. Chelate compounds promote nuclide migration and reduce barrier performance at disposal sites, so anion resins cannot be buried. However, since the anion resin tower 44 is used for the treatment of radioactive substances contained in the decontamination waste liquid 58 after treating the decontamination waste liquid 58 in the zeolite filling tanks 43A and 43B, the used anion resin has a low dose. Can be incinerated.

  Therefore, if the waste liquid treatment system 40 according to the present embodiment is used, the zeolite in the zeolite filling tanks 43A and 43B can be buried as waste, and the anion resin used in the anion resin tower 44 can be incinerated. By treating the metal ions in 58, the zeolite and anion resin generated as secondary waste can be disposed respectively. As a result, the waste liquid treatment system 40 according to the present embodiment can dispose of waste that could not be disposed by using a conventionally used decontamination solution treatment method.

Next, the processing method of the decontamination waste liquid concerning a present Example is demonstrated. FIG. 3 is a flowchart showing a procedure of the processing method of the decontamination waste liquid according to the present embodiment, and FIGS. 4 to 9 are explanatory views showing states in each process. As shown in FIG. 3, the processing method of the decontamination waste liquid concerning a present Example has the following processes.
(A) The first chemical liquid 52 containing permanganic acid is supplied to the decontamination target system 41 of the nuclear reactor equipment, and at least Cr contained in the deposits attached to the equipment in the decontamination target system 41 of the nuclear reactor equipment 1st chemical | medical solution supply process (step S11) which melt | dissolves in 1 chemical | medical solution 52, and decontaminates the installation in the decontamination object system | strain 41 of a nuclear reactor installation.
(B) The second chemical solution 53 containing oxalic acid is supplied to the decontamination target system 41 of the nuclear reactor equipment and the equipment in the decontamination target system 41 of the nuclear reactor equipment is supplied to the decontamination waste liquid 58 supplied with the first chemical liquid 52. The second chemical solution supply step (step S12) in which Fe and Ni contained in the deposits adhering to the reactor are dissolved in at least the second chemical solution 53 to decontaminate the equipment in the decontamination target system 41 of the reactor equipment.
(C) The decontamination waste liquid 58 generated when the decontamination target system 41 of the reactor facility is decontaminated is supplied to the zeolite filling tanks 43A and 43B, and the metal ions dissolved in the decontamination waste liquid 58 are converted into zeolite. Adsorbing zeolite permeation process (step S13)
(D) The decontamination waste liquid 58 from which the metal dissolved in the zeolite filling tanks 43A and 43B has been removed is supplied to the UV tower 45, the third chemical liquid 54 containing H ₂ O ₂ is supplied to the UV tower 45, Irradiation and third chemical supply / UV irradiation process for decomposing oxalic acid contained in decontamination waste liquid 58 (step S14)
(E) Anion resin permeation process for removing metal ions and oxalic acid remaining in the decontamination waste liquid 58 by passing the decontamination waste liquid 58 from which oxalic acid has been removed through the anion resin tower 44 (step S15).

  As shown in FIG. 4, the first chemical liquid 52 containing permanganic acid is passed through the decontamination waste liquid circulation line L11 from the first chemical liquid supply section 55 via the chemical liquid supply lines L14-1 and L14-4. Supply to the decontamination target system 41 (first chemical supply step: step S11).

  As a result, Cr oxides and the like contained in the deposits attached to the equipment in the decontamination target system 41 of the nuclear reactor equipment are dissolved in the first chemical liquid 52 as at least chromic acid, and the decontamination target of the nuclear reactor equipment It removes from the equipment in the system 41, and decontaminates the equipment in the decontamination target system 41 of the reactor equipment.

  The first chemical liquid 52 in the decontamination target system 41 of the nuclear reactor equipment is extracted from the decontamination waste liquid circulation line L11 and circulated through the decontamination waste liquid circulation line L11 to return to the decontamination target system 41 of the nuclear reactor equipment. . Specifically, the first chemical liquid 52 in the decontamination target system 41 of the nuclear reactor facility is extracted from the decontamination waste liquid circulation line L11 as the decontamination waste liquid 58, and impurities in the decontamination waste liquid 58 are removed by the filter 59. Then, it is heated to a predetermined temperature (for example, about 80 ° C. to 100 ° C.) in the heating tank 61. The temperature at which the decontamination waste liquid 58 is heated in the heating tank 61 is appropriately adjusted by a heater (heating means) 62.

  Then, the decontamination waste liquid 58 is supplied again to the decontamination target system 41 of the reactor facility while maintaining the heated temperature. The supply amount of the decontamination waste liquid 58 supplied from the heating tank 61 to the decontamination target system 41 of the reactor facility is adjusted by the pump P1.

  Further, the decontamination waste liquid 58 is reduced in the amount of the first chemical liquid 52 by removing impurities in the decontamination waste liquid 58 by the filter 59 or by being heated in the heating tank 61. The first chemical liquid 52 may be appropriately supplied from the chemical supply unit 55 to the decontamination waste liquid 58 so that the first chemical liquid 52 can be sufficiently supplied into the decontamination target system 41.

  The number of times that the decontamination waste liquid 58 is circulated to the decontamination target system 41 of the nuclear reactor facility through the decontamination waste liquid circulation line L11 may be one time or a plurality of times.

  The first chemical liquid 52 is heated and circulated through the decontamination waste liquid circulation line L11 while maintaining the temperature, so that the Cr oxide contained in the deposits attached to the equipment in the decontamination target system 41 of the reactor equipment is It is removed from the equipment in the decontamination target system 41 of the reactor equipment, and the equipment in the decontamination target system 41 of the reactor equipment is decontaminated.

  After the decontamination waste liquid 58 is circulated at least once between the decontamination target system 41 of the nuclear reactor facility and the decontamination waste liquid circulation line L11, as shown in FIG. 5, the decontamination supplied with the first chemical liquid 52 is performed. The second chemical liquid 53 containing oxalic acid in the waste liquid 58 passes through the chemical liquid supply lines L14-2 and L14-4 from the second chemical liquid supply unit 56, passes through the decontamination waste liquid circulation line L11, and the decontamination target system 41 of the nuclear reactor equipment. (2nd chemical | medical solution supply process: step S12).

  As a result, Fe oxide, Ni oxide, and the like contained in the deposits attached to the equipment in the decontamination target system 41 of the reactor equipment are dissolved in the second chemical solution 53, and the decontamination target system 41 of the reactor equipment is obtained. The equipment inside is decontaminated. Moreover, Cr oxide and unreacted permanganic acid are reduced.

  Similar to the first chemical liquid 52, the second chemical liquid 53 in the decontamination target system 41 of the nuclear reactor equipment is extracted from the decontamination waste liquid circulation line L11 and circulated through the decontamination waste liquid circulation line L11 to be decontaminated from the nuclear reactor equipment. It passes through the system 41. Specifically, the second chemical liquid 53 supplied into the decontamination target system 41 of the nuclear reactor facility is extracted from the decontamination waste liquid circulation line L11 as the decontamination waste liquid 58, and is contained in the decontamination waste liquid 58 by the filter 59. After removing the impurities, it is heated to about 80 ° C. to 100 ° C. in the heating tank 61. Then, the decontamination waste liquid 58 is supplied again to the decontamination target system 41 of the reactor facility while maintaining the heated temperature.

  In addition, the decontamination waste liquid 58 is reduced in the amount of the second chemical liquid 53 by removing impurities in the decontamination waste liquid 58 with the filter 59 or when heated in the heating tank 61. The second chemical liquid 53 may be appropriately supplied from the chemical supply section 55 to the decontamination waste liquid 58 so that the second chemical liquid 53 can be sufficiently supplied into the decontamination target system 41.

  The number of times that the decontamination waste liquid 58 is circulated to the decontamination target system 41 of the nuclear reactor facility through the decontamination waste liquid circulation line L11 may be one time or a plurality of times.

  The second chemical liquid 53 is heated and circulated through the decontamination waste liquid circulation line L11 while maintaining the temperature, so that the Fe oxide, Ni contained in the deposits attached to the equipment in the decontamination target system 41 of the nuclear reactor equipment Oxides and the like are removed from the equipment in the decontamination target system 41 of the reactor facility, and the equipment in the decontamination target system 41 of the reactor equipment is decontaminated.

  After the decontamination waste liquid 58 is circulated at least once between the decontamination target system 41 of the nuclear reactor equipment and the decontamination waste liquid circulation line L11, as shown in FIG. The decontamination waste liquid 58 generated at the time of decontamination is supplied to the zeolite filling tanks 43A and 43B, and the metal ions dissolved in the decontamination waste liquid 58 are adsorbed on the zeolite (zeolite passage step: step S13).

  The decontamination waste liquid 58 is circulated at least once between the decontamination target system 41 of the nuclear reactor equipment and the decontamination waste liquid circulation line L11, and the dissolved metal is removed in the zeolite filling tanks 43A and 43B.

Thereafter, as shown in FIG. 7, the third chemical liquid 54 containing H ₂ O ₂ is supplied from the third chemical liquid supply unit 57 to the decontamination waste liquid circulation line L11 via the chemical liquid supply lines L14-3 and L14-4. Mix in decontamination waste liquid 58. Thereafter, the decontamination waste liquid 58 is supplied to the storage tank 65 of the UV tower 45 through the decontamination waste liquid extraction line L15. In the storage tank 65, UV is irradiated from the UV irradiation device 66 to the decontamination waste liquid 58, and oxalic acid contained in the decontamination waste liquid 58 is reduced and decomposed (third chemical supply / UV irradiation step: step S14).

  Thereafter, after the oxalic acid is decomposed, the decontamination waste liquid 58 is discharged from the storage tank 65 and supplied from the decontamination waste liquid extraction line L15 to the decontamination target system 41 of the reactor facility through the decontamination waste liquid circulation line L11. The

  The number of times that the decontamination waste liquid 58 is circulated to the storage tank 65 through the decontamination waste liquid circulation line L11 and the decontamination waste liquid extraction line L15 may be one time or a plurality of times.

  Thereafter, as shown in FIG. 8, the decontamination waste liquid 58 is supplied to the anion resin tower 44, the decontamination waste liquid 58 from which oxalic acid has been removed is passed through the anion resin tower 44, and the metal ions remaining in the decontamination waste liquid 58; Oxalic acid or the like that could not be decomposed by the UV tower 45 is adsorbed on the ion exchange resin for treatment (anion resin permeation step: step S15).

  The number of times that the decontamination waste liquid 58 is circulated to the anion resin tower 44 through the decontamination waste liquid circulation line L11 may be one time or multiple times.

  Thereafter, after the decontamination of the decontamination target system 41 of the nuclear reactor facility is completed, as shown in FIG. 9, the decontamination waste liquid 58 is discharged from the decontamination waste liquid discharge line L12 and is subjected to waste liquid treatment. The decontamination waste liquid 58 subjected to the waste liquid treatment is disposed in a drum can or the like.

  Thus, if the processing method of the decontamination waste liquid which concerns on a present Example is used, the decontamination waste liquid which arises by decontaminating members, such as the reactor equipment and various piping which comprise the decontamination object system | strain 41 of a nuclear reactor installation. By treating the metal ions in 58, the zeolite and the anion resin generated as secondary waste can be disposed respectively. That is, radioactive substances dissolved in the decontamination waste liquid 58 produced by decontaminating members such as reactor equipment and various pipes constituting the decontamination target system 41 of the reactor facility are filled in the zeolite filling tanks 43A and 43B. The zeolite and the anion resin become radioactive waste by being adsorbed using the zeolite in the resin and the anion resin in the anion resin tower 44. Zeolite in the zeolite filling tanks 43A and 43B absorbs radioactive materials and has a high dose, and therefore cannot be incinerated. However, since zeolite is an inorganic substance, hydrogen gas is not generated by radioactive decomposition like organic substances. Therefore, even if the radioactive substance is adsorbed and becomes a high dose, it is solidified into a solid substance. Can be buried in Further, as described above, the anion resin tower 44 is assumed to contain a chelate compound, and cannot be buried. However, since the anion resin tower 44 is used for processing radioactive substances contained in the decontamination waste liquid 58 after the decontamination waste liquid 58 is processed in the zeolite filling tanks 43A and 43B, the anion resin after use may have a low dose. Because of its high nature, it can be incinerated.

  Therefore, if the processing method of the decontamination waste liquid according to this embodiment is used, the zeolite in the zeolite filling tanks 43A and 43B can be disposed of as waste and the anion resin used in the anion resin tower 44 can be incinerated. By processing the metal ions in the dyeing waste liquid 58, the zeolite and the anion resin generated as secondary waste can be disposed respectively. Therefore, the processing method of the decontamination waste liquid according to the present embodiment can dispose of the waste that could not be disposed when the conventionally used processing method of the decontamination solution was used.

  In this embodiment, the zeolite filling tank has two stages. However, as shown in FIG. 10, only the zeolite filling tank 43 may be constituted by one stage. Further, a plurality of them may be provided.

In the present embodiment, when decomposing oxalic acid contained in the decontamination waste liquid 58, the third chemical liquid containing H ₂ O ₂ in the decontamination waste liquid 58 in the third chemical liquid supply / UV irradiation step (step S14). After supplying 54, UV is irradiated to decompose oxalic acid contained in the decontamination waste liquid 58. However, the present invention is not limited to this, and the decontamination waste liquid is used in inorganic ion exchangers such as zeolite. If the oxalic acid contained in 58 can be removed, the third chemical supply / UV irradiation step (step S14) may not be provided.

  In this embodiment, the decontamination waste liquid 58 is circulated through the decontamination waste liquid circulation line L11 in each of the above steps, while supplying the first chemical liquid 52, the second chemical liquid 53, and the third chemical liquid 54 in each process, and filling the zeolite. Although the permeation to the tanks 43A and 43B and the anion resin tower 44 is performed, the present invention is not limited to this, and the decontamination condition of the equipment in the decontamination target system 41 of the nuclear reactor equipment and the decontamination waste liquid 58 Depending on the condition, it may be discharged through the decontamination waste liquid discharge line L12 for each process.

  In the present embodiment, the case of decontamination of piping and equipment installed in a nuclear power plant has been described. However, the present invention is not limited to this, and piping and equipment used for facilities that handle hazardous substances. The same can be used in the case of washing.

DESCRIPTION OF SYMBOLS 10 Nuclear power plant 11 Reactor 12 Reactor cooling system 13 Turbine system 15a Cold leg 15b Hot leg 16 Steam generator 17 Pressurizer 18 Reactor coolant pump 19 Reactor containment vessel 21 Fuel assembly 22 Control rod 24 Steam pipe 25 Turbine 26 Condenser 27 Water supply pipe 28 Water supply pump 29 Generator 30 Cooling pipe 31 Water intake pipe 32 Drainage pipe 40 Waste liquid treatment system 41 Reactor system decontamination system 42 Chemical liquid supply section 43 Zeolite filling tank (inorganic ion exchanger filling tank)
44 Anion resin tower 45 Ultraviolet irradiation tower (ultraviolet irradiation means)
52 1st chemical | medical solution 53 2nd chemical | medical solution 54 3rd chemical | medical solution 55, 56, 57 Chemical supply part 58 Decontamination waste liquid 59 Filter 60 Heating device 61 Heating tank 62 Heating means 65 Storage tank 66 Ultraviolet irradiation device (UV irradiation device)
L11 Decontamination waste liquid circulation line L12 First decontamination waste liquid branch line L13 Second decontamination waste liquid branch line L14-1 to L14-4 Chemical supply line L15 Decontamination waste liquid extraction lines V11 to V15, V21 to V26, V31 V33, V41, V42 Control valve

Claims (6)

A decontamination waste liquid circulation line for discharging the chemical solution supplied to the decontamination target system of the nuclear reactor equipment as the decontamination waste liquid from the decontamination target system, and circulating it to the decontamination target system,
A chemical supply unit that is provided in the decontamination waste liquid circulation line, and supplies a chemical liquid containing one or both of an oxidizing agent and a reducing agent to the decontamination waste liquid;
One or more inorganic ion exchanger filling tanks equipped with an inorganic ion exchanger that adsorbs metal ions contained in the decontamination waste liquid;
An anion resin tower provided with an anion exchange resin that adsorbs anions contained in the decontamination waste liquid;
First decontamination waste liquid branch connecting the decontamination waste liquid extraction line and the inorganic ion exchanger filling tank, supplying the decontamination waste liquid to the inorganic ion exchanger filling tank, and returning to the decontamination waste liquid extraction line Line,
A second decontamination waste liquid branch line that connects the decontamination waste liquid extraction line and the anion resin tower, supplies the decontamination waste liquid to the anion resin tower, and returns the decontamination waste liquid extraction line;
A waste liquid treatment system comprising: In claim 1,
In the waste ion treatment system, the inorganic ion exchanger filling tank is selected according to the type of metal ions to be removed. In claim 1 or 2,
A waste liquid treatment system, wherein the inorganic ion exchanger is zeolite. The decontamination waste liquid generated when decontaminating the system to be decontaminated in the reactor facility is supplied to the inorganic ion exchanger filling tank, and the metal ions dissolved in the decontamination waste liquid are adsorbed to the inorganic ion exchanger. An inorganic ion exchanger permeation step;
Passing the decontamination waste liquid from which the reducing agent has been removed through the anion resin tower, the metal ions remaining in the decontamination waste liquid, and the anion resin permeation step for removing the reducing agent;
A waste liquid treatment method comprising: In claim 4,
The inorganic ion exchanger filling tank selects an inorganic ion exchanger according to the type of metal ions to be removed. In claim 4 or 5,
At least one of the above steps is performed at least once by a decontamination waste liquid circulation line that discharges the chemical solution supplied to the decontamination target system from the decontamination target system as a decontamination waste liquid and circulates it to the decontamination target system. A waste liquid treatment method, characterized by comprising:

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