JP5816526B2 - Radioactive substance immobilization method and immobilization equipment - Google Patents

Description

  The present invention relates to a radioactive substance immobilization method and immobilization equipment, and more particularly to a radioactive substance immobilization method and immobilization equipment using an adsorbent capable of adsorbing a radioactive substance.

In recent years, peaceful use of radioactivity has been actively performed, and radioactive waste generated by peaceful use has been subjected to immobilization treatment such as vitrification to prevent the diffusion of radioactive materials and buried.
However, in a landfill site (final disposal site) for waste contaminated with radioactive materials, the waste etc. may be buried without sufficient immobilization. May cause radioactive contamination.
In addition, in the landfill site for waste contaminated with radioactive material, when rain occurs, leachate containing radioactive material is generated, and if the leachate is not properly treated, the contaminated area is further expanded. There is a risk of letting you.

  On the other hand, a method for sufficiently fixing a radioactive substance in such a landfill site has not been studied so far, and it is difficult to sufficiently prevent the expansion of a contaminated area.

  By the way, as a water treatment method for treating water containing a radioactive substance such as leachate from a landfill disposal site, a method using an adsorbent is known, and water containing a radioactive substance is treated with water to be treated. In addition, a water treatment method for performing an adsorption process in which the water to be treated is brought into contact with an adsorbent capable of adsorbing a radioactive substance to adsorb the radioactive substance on the adsorbent is conventionally known.

  With regard to such a water treatment method, for example, Patent Document 1 below describes that an adsorption treatment process for water to be treated containing a radioactive substance is performed using an adsorbent packed tower, and the adsorbent is accommodated. The treated water is introduced into the adsorbent packed tower, the radioactive material is adsorbed on the adsorbent in the adsorbent packed tower, and the adsorbed treated water having a reduced concentration of the radioactive substance compared to the treated water is adsorbed to the adsorbent treated tower. It describes that an adsorption treatment step of discharging from the material packed tower is performed.

  The adsorbent used for such an adsorption process also eventually needs some kind of disposal, but it is clear from Patent Document 1 that the adsorbent can be regenerated. In general, it cannot be said that the radioactive substance is sufficiently fixed just by adsorbing it to the adsorbent. For example, the adsorbent adsorbed with the radioactive substance is sealed in a container and stored in the warehouse. If the container is stored or disposed of in landfills, the radioactive material may be diffused if the container is damaged for any reason.

JP 2000-206291 A

In order to solve such a problem, for example, it is conceivable to fix the radioactive substance by a solidification process using a cement that kneads mortar or concrete and an adsorbent to form a hardened cement body.
In this case, although the possibility that the radioactive substance is diffused can be reduced, there is a possibility that the adsorbent adsorbing the radioactive substance may diffuse to the surroundings during the solidification operation with the cement.
The operation of replacing the adsorbent in the adsorbent packed tower is common to the cement solidifying operation in that the adsorbent adsorbing the radioactive substance may be diffused around.

  An object of the present invention is to solve the above-described problems, and to provide a radioactive substance immobilization method and a radioactive substance immobilization facility capable of suppressing the diffusion of the radioactive substance. It is said.

  The present invention relating to a method for immobilizing a radioactive substance for solving the above-described problem is an adsorbent capable of adsorbing the radioactive substance in a site of a landfill disposal site where a radioactive substance or waste contaminated with the radioactive substance is buried. An adsorbent tank installation process for providing an adsorbent tank containing the adsorbent tank, an adsorption treatment process for adsorbing the radioactive material contained in the leachate leached from the landfill site to the adsorbent in the adsorbent tank, and A solidifying step of solidifying the adsorbent in the adsorbent tank after the adsorbing treatment step with cement is performed to immobilize the radioactive substance in the adsorbent tank.

  Further, the present invention relating to a radioactive substance immobilization facility for solving the above-mentioned problems is directed to a radioactive substance for immobilizing the radioactive substance in a landfill disposal site where a radioactive substance or waste contaminated with a radioactive substance is buried. It is a substance immobilization facility, and is provided in the site of the landfill disposal site, and is contained in an adsorbent tank containing an adsorbent capable of adsorbing the radioactive material, and leachate leached from the landfill disposal site. To-be-treated water conveying means for introducing the treated water containing the leaching water into the adsorbent tank in order to adsorb the radioactive substance on the adsorbent in the adsorbent tank, the leachable water includes A solidifying means for solidifying the adsorbent adsorbing the radioactive substance with cement in the adsorbent tank is provided.

  According to the present invention, an adsorbent tank containing an adsorbent capable of adsorbing a radioactive substance is provided in a landfill disposal site, and the radioactive substance contained in leachate leached from the landfill disposal site is adsorbed to the adsorbent tank. In the adsorption process step, the adsorption process step for adsorbing the adsorbent in the material tank and the solidification process for solidifying the adsorbent material in the adsorbent tank after the adsorption process step with cement are performed. The used adsorbent can be prevented from diffusing outside the landfill site.

It is a block diagram showing a schematic structure of water treatment equipment concerning one embodiment of the present invention. It is a block diagram which shows schematic structure of the water treatment equipment which concerns on other embodiment of this invention. It is a fragmentary sectional view showing a schematic structure of a membrane separation module of a reverse osmosis membrane separation device used in water treatment equipment concerning other embodiments of the present invention. It is a block diagram which shows schematic structure of the water treatment equipment which concerns on other embodiment of this invention. It is a block diagram which shows schematic structure of the water treatment equipment which concerns on other embodiment of this invention.

Hereinafter, with respect to the embodiment of the method for immobilizing a radioactive substance of the present invention, an adsorption treatment is performed on water to be treated including leachate from a landfill disposal site (final disposal site) where a radioactive pollutant is buried. The case where it performs is demonstrated to an example.
(First embodiment)
First, equipment and the like used in connection with the first embodiment relating to the radioactive substance immobilization method will be described with reference to the drawings.
In the first embodiment, the water treatment facility for removing the radioactive substance from the treated water is used as an immobilization facility for immobilizing the radioactive substance contained in the treated water. 1 is a block diagram showing a schematic configuration of a water treatment facility (immobilization facility).
In addition, the code | symbol 1 in FIG. 1 represents the landfill disposal site which may leach a to-be-processed water, and the code | symbol 2 represents the receiving tank for storing the leachate discharged | emitted from the said landfill disposal site 1. .
Reference numerals 10 and 20 are adsorption treatment units each containing an adsorbent capable of adsorbing a radioactive substance, and 10 is a first adsorption treatment unit (10) for adsorbing treated water on the upstream side of the water treatment. (Hereinafter also referred to as “first adsorption treatment unit”), and 20 is a second adsorption process performed on the water to be treated that has been subjected to the first adsorption treatment by the first adsorption treatment unit on the downstream side of the water treatment. A second adsorption processing unit (hereinafter also referred to as “second adsorption processing unit”).

The first adsorption processing unit 10 is provided in the site of the landfill disposal site 1, and the first adsorption processing unit 10 stores an adsorbent tank capable of adsorbing the radioactive substance. 10a is provided.
Reference numeral 300 denotes a treated material containing the leachate to adsorb the radioactive material contained in the leachate leached from the landfill site to the adsorbent in the adsorbent tank 10a of the first adsorption processing unit 10. The water-to-be-processed conveyance means for introducing water into the said adsorbent tank from the said receiving tank 2 is represented.
Further, in the immobilization facility according to the present embodiment, after the radioactive material is adsorbed to some extent by the adsorbent accommodated in the adsorbent tank 10a, the adsorbent is solidified with cement in the adsorbent tank. Means (not shown) are provided.

  In addition, the broken line A of FIG. 1 represents the management area which performs management based on the radioactive concentration of the adsorbent and the retention amount of the adsorbent in the water treatment facility (immobilization facility) of the present embodiment. As shown, in the present embodiment, the first adsorption processing unit 10 is installed in the management area, and other components such as the second adsorption processing unit 20 are provided outside the management area.

In the water treatment facility of the present embodiment, as shown in FIG. 1, in order from the first adsorption treatment unit 10, the primary treated water storage unit 30, the pH adjustment unit 40, the nitrification unit 50, the denitrification unit 60, the coagulation sedimentation. Part 70, neutralizing part 80, sand filtering part 90, and chelate treatment part 100, and the second adsorption treatment part 20 is provided downstream of the chelate treatment part 100.
In addition, the water treatment facility of this embodiment includes an ultrafiltration unit 110 and a disinfection unit 120 in this order on the downstream side of the second adsorption treatment unit 20, and the water treatment facility of this embodiment Is configured so that water that has been treated in the disinfection unit 120 can be discharged out of the system as treated water.
That is, in this embodiment, each part is arrange | positioned in series along the process of water treatment so that the treated water processed in each part may be sent forward and processed as to-be-processed water in the next stage.

The second adsorption processing unit 20 includes an adsorption tower 20a having a container for containing an adsorbent and an adsorbent accommodated in the container, and the adsorption tower 20a is formed from one of the containers. The introduced water to be treated is configured to be moved and discharged to the other side of the container while being in contact with the adsorbent inside the container.
That is, the adsorption tower 20a adsorbs the radioactive substance contained in the water to be treated by contact between the water to be treated and the adsorbent on the adsorbent and passes through the adsorption tower 20a. It is comprised so that the density | concentration of can be reduced rather than the said to-be-processed water.

In the second adsorption processing unit 20, when the radioactive substance to be adsorbed is radioactive cesium, radioactive iodine, radioactive strontium, or the like, the adsorbent to be contained in the container is an aluminosilicate such as zeolite. Minerals; phyllosilicate minerals such as mica and sericite; ferrocyan compounds such as potassium ferrocyanide, cobalt ferrocyanide, and ferrocyanide can be suitably used.
In addition, when using these substances as an adsorbent, they may be used alone or in combination.
In that case, these can be used in the form of a powder or a porous material obtained by sintering the powder.
On the other hand, the material of the container is not particularly limited as long as it does not cause a significant decrease in physical properties due to radiation.

In contrast to the second adsorption processing unit 20 configured by the adsorption tower 20a, the first adsorption processing unit 10 includes the number of containers containing adsorbents in the adsorption tower 20a of the second adsorption processing unit 20. It is comprised by the adsorbent tank 10a made from concrete which has a volume of double to several dozen times or more.
In addition, the adsorbent tank 10a of the first adsorption processing unit 10 is provided with a tank body in a form in which a peripheral wall and a bottom wall are formed of concrete having a certain thickness in a part of the landfill disposal site, It is provided to be completely isolated.
Further, the first adsorption processing unit 10 accommodates the adsorbent in the tank body of the adsorbent tank 10a so as to have a constant deposition thickness, and forms an adsorbent layer of the adsorbent inside. A suction pipe extending from the opening on the upper end side to the tank bottom of the tank body in a form passing through the adsorbent layer is provided.
In addition, as an adsorbent for forming the adsorbent layer, a material similar to that described with respect to the second adsorption processing unit 20 can be employed.
However, the adsorbent used in the first adsorption processing unit 10 is not necessarily the same as the adsorbent used in the second adsorption processing unit 20, and the shape, material, etc. are different from those used in the second adsorption processing unit 20. It may be.
Conversely, the adsorbent used with the second adsorption processing unit 20 may be used in common, and the adsorbent layer may be formed of the same adsorbent as the second adsorption processing unit 20.

And in this embodiment, the 1st adsorption processing part 10 makes the water containing the leachate leached from the said landfill disposal site by rain etc. to be treated water, and conveys the said treated water via the said receiving tank 2 The water to be treated introduced from the upper part of the adsorbent tank 10a by means 300 is passed through the adsorbent layer to carry out the adsorbing treatment of the radioactive substance, and the adsorbed treated water after the adsorbing treatment is used in the adsorbent tank 10a. It is configured to be pumped from the bottom to the tank upper end side through the suction pipe and flow down to the primary treated water reservoir 30 as primary treated water.
That is, the first adsorption treatment unit 10 is configured to be able to reduce the concentration of radioactive material in the treated water by adsorbing the radioactive material in the treated water that passes through the adsorbent layer to the adsorbent. .

  Further, the adsorbent tank 10a constituting the first adsorption processing unit 10 has a sufficient storage space above the adsorbent layer, and the adsorbent of the adsorption tower 20a is new as will be described later. The adsorbent used in the adsorption tower 20a when it is replaced with a new one can be newly deposited on the adsorbent layer and used for the adsorption treatment in the adsorbent tank 10a. .

In addition, the to-be-processed water conveyance means 300 for conveying to-be-processed water from the said receiving tank 2 to the said adsorbent tank 10a is provided between the said receiving tank 2 and the said adsorbent tank 10a in this embodiment. And a pump serving as a power source for moving the water to be treated through the pipe.
Further, in the present embodiment, the solidifying means for solidifying the adsorbent used for adsorbing the radioactive substance in the adsorbent tank 10a using cement is used to mix the adsorbent with cement and water. A mixer is provided.

The primary treated water storage unit 30 includes an adjustment tank for stabilizing the flow rate and water quality when the adsorption treated water adsorbed by the first adsorption treatment unit 10 is subjected to the subsequent processing. ing.
In addition, the pH adjusting unit 40 includes a pH adjusting tank for temporarily storing water introduced from the primary treated water storage unit 30, and a biological nitrification denitrification process for water to be treated in the pH adjusting tank. A pH adjusting mechanism for adjusting the pH to be suitable for carrying out.
The nitrification unit 50 biologically oxidizes organic nitrogen, ammonia nitrogen, or the like contained in the water to be treated introduced from the pH adjustment unit 40 to nitrate nitrogen or nitrite nitrogen. The denitrification section 60 includes a denitrification section 60 for reducing nitrate nitrogen or nitrite nitrogen in the water to be treated introduced from the nitrification section 50 and converting it into nitrogen gas. It has a nitrogen tank.

The coagulation sedimentation unit 70 includes a sedimentation tank for coagulating and sedimenting suspended matter such as activated sludge used for biological treatment in the denitrification unit 60.
The neutralization unit 80 includes a treated water tank for neutralizing the water to be treated introduced from the coagulation sedimentation unit 70, and the sand filtration unit 90 is neutralized by the neutralization unit 80. It is provided to further remove suspended substances contained in the treated water.
The chelate treatment unit 100 is a front side of the second adsorption treatment unit 20 in order to capture a heavy metal ion or the like in the water to be treated introduced into the second adsorption treatment unit 20 with a chelating agent. Is provided.

The ultrafiltration unit 110 provided on the downstream side of the second adsorption processing unit 20 captures the adsorbent particles from the second adsorption processing unit 20 by an ultrafiltration membrane even if the adsorbent particles leak, In order to more reliably suppress the concentration of radioactive material in the treated water discharged below the reference value.
The water treatment facility according to the present embodiment disinfects the permeated water that has passed through the ultrafiltration membrane of the ultrafiltration unit 110 with the disinfection unit 120 and discharges the disinfected water out of the system as treated water. Configured to get.

Immobilization of the radioactive material contained in the leachate from the landfill site can be carried out by performing the following steps (a) to (e) using such a water treatment facility. .

(A) an adsorbent tank installation step of providing an adsorbent tank containing an adsorbent capable of adsorbing the radioactive substance in the site of a landfill disposal site in which radioactive substances or waste contaminated with the radioactive substance is buried;
(B) an adsorption treatment step of adsorbing the radioactive substance contained in the leachate leached from the landfill site to the adsorbent in the adsorbent tank;
(C) A part or all of the site of the landfill disposal site including the installation location of the adsorbent tank is a management area for performing management based on the radioactive concentration of the adsorbent and the amount of the adsorbent retained, A water treatment process for further removing the radioactive substance remaining in the adsorption treated water by transporting the adsorption treated water after adsorbing the radioactive substance to the adsorbent to the outside of the management area;
(D) a returning step of returning the radioactive material removed in the water treatment step to the adsorbent tank provided in the management area;
(E) A solidification step of solidifying the adsorbent in the adsorbent tank with cement.

In the adsorbent tank installation step, it is preferable that the adsorbent tank 10a to be installed is a closed space that is completely shut off from the outside during the final solidification step. It is preferable not to provide a drain outlet or the like at the bottom of the main body, and it is preferable to form an opening only on the upper side of the tank main body.
Further, the tank bottom is inclined so that the installation part of the suction pipe is deeper than the other part, and the adsorption treated water is automatically gathered toward the suction pipe located at the deepest part of the tank body. Is preferred.

In order to reduce the pumping power by the suction pipe by allowing the adsorption treated water to flow naturally, a drain outlet is provided at the bottom of the tank body of the adsorbent tank 10a so that the adsorption treated water is discharged from the drain outlet. Also good.
However, in this case, there is a possibility of generating labor for closing the drain outlet in the solidification step.

  Further, as described above, the adsorbent tank 10a preferably has a scale having an adsorbent accommodating space several to several tens of times larger than the adsorbent accommodating space in the adsorption tower 20a. .

  In the present embodiment, the radioactive material is adsorbed to the adsorbent tank 10a of the first adsorption processing unit 10 while the water to be treated is allowed to flow down from the first adsorption processing unit 10 to the disinfection unit 120 in order. A first adsorption process (adsorption process step) and a second adsorption that further removes radioactive substances remaining in the adsorption-treated water subjected to the first adsorption process in the adsorption tower 20a of the second adsorption treatment unit 20 In addition, as described above, the storage space for the adsorbent in the first adsorption processing unit 10 is significantly higher than the storage space for the adsorbent in the second adsorption processing unit 20. When the process of replacing the adsorbent used in the second adsorption processing unit 20 with a new one (adsorbent replacement process) is carried out, the second adsorption processing unit 20 has been used so far. The And the old adsorbent is housed in the adsorbent vessel 10a of the first suction unit 10 can be used for adsorption treatment step is.

  That is, it is possible to carry out a return process for returning the radioactive material to the management area by transporting the adsorbent of the adsorption tower 20a used in the water treatment process to the management area and storing it in the adsorbent tank, By carrying out the return process in such a form, the adsorbent of the adsorption tower 20a accommodated in the adsorbent tank at this time can be used for the adsorption process (adsorption process process) in the first adsorption processing unit 10. .

However, if the adsorbent replacement process is performed after the radioactive material is excessively adsorbed to the adsorbent of the second adsorption processing unit 20, and the obtained adsorbent is returned to the adsorbent tank 10a, the radiation is emitted. Adsorbents with high active density will be handled.
In addition, in the “Ionizing Radiation Hazard Prevention Regulation” (hereinafter also referred to as “ionization law”) established by the Ministry of Health, Labor and Welfare, for example, cesium with a radioactive concentration exceeding 10,000 Bq / kg is particularly strict as a radioactive substance. Is required, and provisions are made regarding aspects of radiation work. In addition, in the radiation damage prevention guidelines established in Tokyo, special management is required for fly ash exceeding 8,000 Bq / kg.
Therefore, this adsorbent replacement step is preferably performed before the radioactivity concentration of the adsorbent used in the second adsorption processing unit 20 exceeds 10,000 Bq / kg (between 10,000 Bq / kg or less). It is preferable to carry out before exceeding 000 Bq / kg (between 8,000 Bq / kg or less).
By exchanging the adsorbent of the second adsorption processing unit 20 at such timing, it is possible to reduce the need for strict management of the old adsorbent after the exchange.
However, if the adsorbent replacement process is performed in a state where the adsorbent of the second adsorption processing unit 20 has an excessively low radioactivity concentration, the adsorbent replacement process must be frequently performed, and water treatment is performed. This is not preferable from the viewpoint of efficiency.
Therefore, the adsorbent replacement step is preferably performed in a state where the radioactive concentration of the adsorbent in the second adsorption processing unit 20 is 6,400 Bq / kg or more.

Moreover, in this embodiment, since the adsorbent of the 2nd adsorption processing part 20 replaced in this adsorbent replacement process can be utilized for the adsorption process in said 1st adsorption processing part 10, consumption of adsorbent The amount can be suppressed.
That is, the adsorbent used in the second adsorption treatment is replaced with a new one with a radioactivity concentration of, for example, 10,000 Bq / kg or less, and in some cases 8,000 Bq / kg or less. Since this level of radioactivity concentration still has sufficient adsorption performance, it is preferable to utilize this effectively in the first adsorption treatment.

And the 1st adsorption processing part 10, although the adsorption performance of a radioactive substance falls with progress of the time utilized for an adsorption treatment process, since an adsorbent is added by an adsorbent exchange process after that, the 1st adsorption treatment The adsorption performance of the entire unit is improved at the time of the adsorbent replacement process.
Accordingly, it is possible to reduce the content of radioactive substances in the water to be treated which is discharged from the first adsorption processing unit 10 to the outside of the management area and is subjected to the water treatment process in the second adsorption processing unit 20. The time until the radioactivity concentration of the adsorbent of the adsorption processing unit 20 exceeds the above value can be prolonged. That is, the frequency of the adsorbent replacement process can be reduced.

In addition, about what radioactivity density | concentration the adsorbent of the 2nd adsorption process part 20 becomes, for example, the quality of the adsorption process water currently stored in the adjustment tank in the primary treated water storage part 30 is regularly It is possible to predict the amount of water flowing down from the adjustment tank while monitoring the content of the radioactive substance by analyzing it.
That is, since the water passing through the second adsorption treatment unit 20 contains almost no radioactive substance, almost the entire amount of radioactive substance contained in the water to be treated flowing down from the adjustment tank is the second adsorption treatment. It will be adsorbed by the adsorbent of the part.
Therefore, by dividing the total amount of this radioactive substance by the total mass of the adsorbent accommodated in the adsorption tower, the radioactivity concentration of the adsorbent can be obtained, and the timing for carrying out the adsorbent replacement process can be grasped. Can do.

However, since it usually takes time to measure water quality, another method is to measure the air dose in the vicinity of the second adsorption treatment unit and compare it with the data on the relationship between the adsorption amount and the air dose prepared in advance. Thus, a method of estimating the radioactive concentration inside the adsorption tower can also be adopted.
According to this method, since the air dose can be measured immediately, the amount of adsorption at the time of the measurement can be reflected, and the replacement timing can be managed accurately.
In addition, since the relationship between the amount of adsorption and the air dose may be different for each adsorbent, it is preferable to measure data for each adsorbent.

In addition, when it becomes impossible to bring the adsorbent into the adsorbent tank 10a of the first adsorption processing section 10 from the second adsorption processing section 20, a solidification process is performed in which the adsorbent is solidified with cement in the adsorbent tank 10a. The water treatment may be continued by newly providing a first adsorption treatment unit (for example, in a section adjacent to the closed first adsorption treatment unit) in the same landfill disposal site.
In carrying out the solidification step, a method may be employed in which cement milk, mortar, concrete, or the like is accommodated in the adsorbent tank 10a and the admixture is mixed in the adsorbent tank. The adsorbent may be once taken out from the tank body of the material tank 10a, and the taken-out adsorbent may be mixed with cement and water outside the tank and then returned to the tank body again.

After that, the upper part of the adsorbent tank 10a may be closed with concrete or the like so as to be a closed space completely cut off from the outside.
In this way, the radioactive substance diffused in the landfill site can be fixed in the adsorbent tank in the form of a hardened cement body.
In the case where a drain outlet is provided in the tank main body of the adsorbent tank 10a, after the adsorbent is taken out of the tank, the drain outlet is closed, and then the radioactive material is the same as described above. A hardened cement body containing the adsorbent adsorbing adsorbent and cement may be formed in the adsorbent tank.

Thus, in this embodiment, since the main adsorption process (adsorption process process) and the solidification process are performed in the landfill disposal site, it is possible to prevent the diffusion of radioactive substances outside the site of the landfill disposal site. .
Further, in the present embodiment, an auxiliary adsorption process (water treatment process) is performed in the second adsorption processing unit 20 provided outside the management area, and the obtained radioactive substance is adsorbed on the adsorbent. The adsorbent is returned to the adsorbent tank, and the adsorbent to be returned is returned with a radioactivity concentration that is easy to handle, so that the radioactive substance can be easily returned to the adsorbent tank.
That is, in this embodiment, the radioactive substance immobilization method which can suppress the spreading | diffusion of a radioactive substance can be implemented simply.

(Second embodiment)
Next, a second embodiment according to the water treatment method of the present invention will be described with reference to FIG.
Also in this second embodiment, the adsorbent tank 10a is provided in the landfill disposal site 1, and a part or all of the landfill disposal site 1 including the installation location of the adsorbent tank 10a is set as a management area, and the management is performed. In the point which implements an adsorption treatment process within an area and implements a water treatment process etc. outside this management area, it is common with 1st embodiment.

In the second embodiment, a membrane separation unit 200 including a reverse osmosis membrane separation device between the first adsorption processing unit 10 and the second adsorption processing unit 20, and the upstream side of the membrane separation unit 200 The water treatment equipment used is different from that of the first embodiment in that the safety filter section 130 provided in the first embodiment is provided.
Further, in the second embodiment, the concentrated salt 160 or the radioactive substance contained in the water is concentrated by evaporating the water, and the condensed water obtained by condensing the water evaporated in the evaporated and concentrated unit 160 is used. The water treatment facility used is different from that of the first embodiment in that a condensate storage unit 170 is further provided.
In the present embodiment, the adsorption-treated water that has been subjected to the adsorption treatment in the first adsorption treatment unit 10 is reversed to the concentrated water in which the concentration of the radioactive substance is improved and the permeated water in which the concentration is reduced. The membrane separation unit 200 is configured so that a membrane separation process for membrane separation using an osmosis membrane can be performed by a reverse osmosis membrane separation apparatus provided in two stages.
That is, in the present embodiment, the first membrane separation device 140 for separating the adsorption treated water subjected to the adsorption treatment in the first adsorption treatment unit 10 into concentrated water and permeated water, and the first membrane separation device. A membrane separation unit 200 including two reverse osmosis membrane separation devices of a second membrane separation device 150 for further membrane separation of 140 permeated water into concentrated water and permeated water using a reverse osmosis membrane is provided. .

In this second embodiment, the water treatment facility is configured so that the permeated water of the second membrane separation device 150 can be discharged out of the system as treated water. The water treatment facility is configured such that the water is subjected to an adsorption treatment in the second adsorption treatment unit 20 together with the concentrated water of the first membrane separation device 140.
In the water treatment facility of the present embodiment, the adsorption-treated water that has been subjected to the adsorption treatment in the second adsorption treatment 20 is used as the condensed water after the evaporating and concentrating unit 160 removes salts and radioactive substances. It is configured to be discharged out of the system or returned to the first adsorption processing unit 10 or the upstream side again.

  The first membrane separation device 140 is a reverse osmosis membrane separation device having a planar membrane type module, and turbulent flow is formed on the surface of the planar reverse osmosis membrane by the water to be subjected to membrane separation. The second membrane separation device 150 is preferably a reverse osmosis membrane separation device having a spiral type reverse osmosis membrane module, a hollow fiber type reverse osmosis membrane module or a pleated type reverse osmosis membrane module.

  As the reverse osmosis membrane separation device having this planar membrane type module, a plurality of spacers 7 are arranged as illustrated in FIG. 3, and a reverse osmosis membrane (plane membrane 6) is interposed between the spacers 7. What is provided with the planar membrane type module 4 made.

The planar membrane type module 4 shown in FIG. 3 has a structure in which disk type planar membranes and spacers with dimples are alternately laminated.
Specifically, in the planar membrane type module 4, a disk-like planar membrane (reverse osmosis membrane) 6 is provided between the disc-like spacers 7 in a cylindrical reverse osmosis membrane module body 5. A plurality of reverse osmosis membrane portions 8 are laminated.
The reverse osmosis membrane separation device is provided with a treated water channel 9 for introducing treated water on the inner peripheral surface of the reverse osmosis membrane module main body 5, and is treated from the treated water channel 9 around the reverse osmosis membrane. Water is introduced, and the turbulent flow due to the water to be treated is formed on the surface of the planar film 6 by the introduction of the water to be treated.
In addition, an end plate 3 is provided on the reverse osmosis membrane portion 8 so as to withstand a pressure higher than the osmotic pressure.
In the planar membrane type module 4 shown in FIG. 3, the permeated water pipe 11 is passed through the central portion of the reverse osmosis membrane portion 8.
In the flat membrane type module 4, the permeated water separated by the reverse osmosis membrane is discharged by the permeate pipe 11, and the concentrated water concentrated by each reverse osmosis membrane is discharged to the outside of the module body 5 by the concentrated water pipe 12. It is configured to be discharged.

It is preferable to provide the reverse osmosis membrane separation device having such a planar membrane type module on the front stage side of the two-stage membrane separation apparatus, the latter side spiral type reverse osmosis membrane module, hollow fiber type reverse osmosis This is because the formation of deposits on the membrane surface is suppressed as compared with a reverse osmosis membrane separation device having a membrane module or a pleated reverse osmosis membrane module.
On the other hand, since the permeated water of the reverse osmosis membrane separation device having a flat membrane type module is introduced on the rear stage side, there is a low risk of deposits forming on the membrane surface, and the membrane area relative to the size of the device It is preferable to use a reverse osmosis membrane separation apparatus having a spiral type reverse osmosis membrane module, a hollow fiber type reverse osmosis membrane module, or a pleated type reverse osmosis membrane module that can easily secure a large amount of water.

In this embodiment, salts and radioactive substances are concentrated on the concentrated water side by membrane separation.
Therefore, in the present embodiment, in order to prevent salt circulation in the system, the evaporation concentration unit 160 performs evaporation concentration processing on water after passing through the second adsorption processing unit 20, and solidifies the salt content. In order to prevent salt circulation in the system.
However, if the component to be solidified contains a radioactive substance at a concentration exceeding 10,000 Bq / kg, special management may be required, so that the solid obtained by the evaporation concentration process is 10,000 Bq. / Kg or less, more preferably 8,000 Bq / kg or less.
When performing such a process, the evaporated water may be discharged through the condensed water storage unit 170, the first adsorption processing unit 10, the primary treated water storage unit 30, or the like, or these It may be returned to a plurality of places including and circulated.
Moreover, a part of the water after passing through the second adsorption processing unit 20 may be circulated as it is, and the remaining part may be subjected to an evaporation concentration process.

  In the first embodiment, since organic nitrogen or the like contained in the leachate has been biologically treated, it needs to be treated when excess sludge or the like is generated. By providing the osmotic membrane separation devices 140 and 150 to discharge only the permeated water and condensed water in which the concentration of radioactive material has been sufficiently reduced, extra processing objects such as excess sludge are generated. Can be suppressed.

In the present embodiment, the concentrated water contains the radioactive substance remaining in the adsorption-treated water after the first adsorption treatment (adsorption treatment step) in the form of being contained in the concentrated water by the membrane separation. A water treatment process is performed in which the radioactive material contained in the concentrated water is removed by reverse osmosis membrane separation and is adsorbed and removed by the second adsorption treatment unit 20.
Therefore, similarly to the first embodiment, the returning step can be performed by returning the adsorbent used in the second adsorption processing unit 20 to the adsorbent tank 10a.
Moreover, in this 2nd embodiment, it is also possible to return the said concentrated water to the adsorbent tank 10a without carrying out the adsorption process in the said 2nd adsorption process part 20, and to implement the said return process.
Further, a part of the concentrated water is returned to the adsorbent tank 10a as it is, and the remaining part is adsorbed by the second adsorption processing unit 20, and the adsorbent used for the adsorption processing is returned to the adsorbent tank 10a and the returning step. May be implemented.

  In addition, the point that a cement hardened body in which the adsorbent is finally solidified with cement is formed in the adsorbent tank and the radioactive substance is fixed in the adsorbent tank is common to the first embodiment. I won't go into detail.

(Other embodiments)
The present invention is not limited to the first embodiment and the second embodiment described above.
Conventionally known technical matters can be appropriately added to these embodiments, or, among the configurations exemplified in these embodiments, those not essential parts of the present invention can be appropriately deleted. .
Furthermore, it is possible to change the configurations of the first embodiment and the second embodiment to those having the same type of function, or to change the order of the components in the processing flow.
For example, in the first embodiment, the chelate processing unit is arranged in the front stage of the second adsorption processing unit, but the chelating agent is likely to adsorb and contaminate the radioactive material, and the chelating agent is contaminated. May not be preferable, the chelate treatment unit may be installed at a stage subsequent to the second adsorption treatment unit.

  Further, for example, in the second embodiment, the concentrated water of the second membrane separation device 150 is introduced into the second adsorption processing unit 20 together with the concentrated water of the first membrane separation device 140. Since 150 concentrated water usually contains very little radioactive substance, the concentrated water is returned to the adjustment tank of the primary treated water storage unit 30 without being introduced into the second adsorption processing unit 20. May be.

Furthermore, in the second embodiment, when there is a possibility that the reverse osmosis membrane is deteriorated by the radioactive substance and the service life is excessively shortened than usual, the second adsorption processing unit 20 is exemplified as shown in FIG. May be provided on the upstream side of the membrane separation unit 200.
In the second embodiment, when the radioactive material can be sufficiently removed by the first membrane separation device 140, the second membrane separation device 150 may not be provided.
On the other hand, in actual use, the permeated water discharged may be treated by providing a third adsorption treatment unit as a safety net in the subsequent stage of the membrane separation unit for safety.
That is, a safety net may be configured by the third adsorption processing unit on the assumption that the reverse osmosis membrane is unexpectedly damaged and the radioactive material leaks to the permeate side.
Furthermore, when using a reverse osmosis membrane like embodiment of FIG.2 and FIG.4, although it is set as the structure which performs an evaporative concentration process with respect to concentrated water, this structure is not essential. In other words, when the salt concentration in the concentrated water is not a problem, it may be returned without performing the evaporation concentration process.

Moreover, in this invention, as shown in FIG. 5, the adsorbent tank 10a provided in the site of a landfill disposal site, and the radioactive substance contained in the leachate leached from the said landfill disposal site are the said adsorbent. To-be-treated water conveying means 300 for introducing the to-be-treated water containing the leachate water into the adsorbent tank for adsorbing to the adsorbent in the tank, and the radioactive material contained in the leachate water was adsorbed As long as the adsorbent is solidified with cement in the adsorbent tank, the second adsorbing treatment unit 20 and the membrane separation unit 200 may not be provided.
That is, the radioactive substance immobilization facility of the present invention is simplified as shown in FIG. 5 in which the treated water stored in the receiving tank 2 is introduced into the adsorbent tank 10a through the treated water transfer means 300. A configuration is also possible.

  Further, although no further detailed description will be given here, it goes without saying that it is possible to make changes beyond the above examples.

4 Flat Membrane Type Module 6 Flat Membrane 7 Spacer 9 Processed Water Channel 10 First Adsorption Treatment Unit 10a Adsorbent Tank 20 Second Adsorption Treatment Unit 20a Adsorption Tower 30 Primary Treatment Water Reservoir 40 pH Adjustment Unit 50 Nitrification Unit 60 Denitrification Unit 70 coagulation sedimentation unit 80 neutralization unit 90 sand filtration unit 100 chelate treatment unit 110 ultrafiltration unit 120 disinfection unit 140 first membrane separation device 150 second membrane separation device 200 membrane separation unit 300 treated water transport means

Claims (10)

  From the landfill disposal site, an adsorbent tank installation process in which an adsorbent tank containing an adsorbent capable of adsorbing the radioactive substance is provided in the site of the landfill disposal site where the radioactive substance or the waste contaminated with the radioactive substance is buried. Adsorption treatment step for adsorbing the radioactive substance contained in the leachate to be leached to the adsorbent in the adsorbent vessel, and the adsorbent in the adsorbent vessel after performing the adsorption treatment step with cement A method for immobilizing a radioactive substance, wherein a solidifying step for solidifying is performed to immobilize the radioactive substance in the adsorbent tank.   A part or all of the site of the landfill site including the place where the adsorbent tank is installed is a management area for performing management based on the radioactive concentration of the adsorbent and the amount of the adsorbent retained, and the adsorption treatment A water treatment step is carried out outside the control area for transporting the adsorbed treated water after the adsorbent is adsorbed to the adsorbent in the process to further remove the radioactive substance remaining in the adsorbed treated water. And further performing a return step of returning the radioactive material removed in the water treatment step to the adsorbent tank provided in a management area, and performing the solidification step after the return step. The immobilization method of the radioactive substance as described.   The water treatment step is performed by adsorbing the radioactive substance remaining in the adsorption treated water to the adsorbent outside the management area, and the adsorbent used in the water treatment step is transported to the management area. The method for immobilizing a radioactive substance according to claim 2, wherein the returning step is performed by accommodating the adsorbent tank.   The method for immobilizing a radioactive substance according to claim 3, wherein the returning step is performed before the radioactive concentration of the adsorbent used in the water treatment step exceeds 10,000 Bq / kg.   The method for immobilizing a radioactive substance according to claim 4, wherein the returning step is performed before the radioactive concentration of the adsorbent exceeds 8,000 Bq / kg.   The adsorption-treated water is membrane-separated into a concentrated water with an increased concentration of the radioactive substance and a permeated water with a reduced concentration by a reverse osmosis membrane, and the radioactive material remaining in the adsorption-treated water is removed from the concentrated water. The radioactive substance fixation according to claim 2, wherein the water treatment step to be contained and removed is performed outside the management area, and the return step is performed to return the radioactive material contained in the concentrated water to the adsorbent tank. Method.   In the water treatment step, an adsorbing process for adsorbing a radioactive substance contained in the concentrated water to an adsorbent is carried out, and the adsorbent used for the adsorbing process is transported to the management area and the adsorbent tank The method for immobilizing a radioactive substance according to claim 6, wherein the returning step for accommodating the radioactive substance is carried out.   The method for immobilizing a radioactive substance according to claim 7, wherein the returning step is performed before the radioactive concentration of the adsorbent used for the adsorption treatment of the concentrated water exceeds 10,000 Bq / kg.   The method for immobilizing a radioactive substance according to claim 8, wherein the returning step is performed before the radioactive concentration of the adsorbent exceeds 8,000 Bq / kg. A radioactive substance immobilization facility for immobilizing the radioactive substance in a landfill site where a radioactive substance or waste contaminated with a radioactive substance is buried,
An adsorbent tank provided in the site of the landfill disposal site and containing an adsorbent capable of adsorbing the radioactive substance, and a radioactive substance contained in leachate leached from the landfill disposal site To-be-treated water conveying means for introducing the treated water containing the leachate into the adsorbent tank to adsorb the adsorbent in the adsorbent, and the adsorbent adsorbing the radioactive substance contained in the leachate water A radioactive substance immobilization facility comprising a solidifying means for solidifying with cement in an adsorbent tank.

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