JP7128139B2 - Radioactive waste liquid treatment method and radioactive waste liquid treatment system - Google Patents

Description

An embodiment of the present invention relates to a radioactive waste liquid treatment method and a radioactive waste liquid treatment system.

Substances present dissolved or in particulate form in radioactive effluents, especially radionuclides such as cesium (Cs), strontium (Sr), iodine (I) and other alpha nuclides (U, Pu, Np, Am, Cm) There are known techniques for separating and recovering substances such as by adsorption treatment.

Due to the accident at the Fukushima Daiichi Nuclear Power Station, a large amount of contaminated water (radioactive liquid waste) containing seawater components was generated. This radioactive waste liquid contains substances such as Co, Ru, i, Sb and Tc in addition to highly concentrated radioactive Cs and Sr. In addition to Cs and Sr, α-nuclides such as U, Pu, Am, Cm and Np are also contained in the circulating cooling water and debris in the fuel section. Therefore, there is a risk of environmental pollution due to radioactive waste liquid flowing into the ocean or groundwater.

In addition, at multiple nuclear power sites overseas, the contaminated water generated at the accident reactor is being treated. Cs and Sr are the main substances to be treated, but their concentration composition in water quality is greatly different. From the viewpoint of securing disposal sites for radioactive waste, it is strongly desired to suppress the amount of waste adsorbents generated.

Conventionally, an adsorption method is used as one of the treatment methods for removing radionuclides from liquids. For example, for Sr, an adsorption method using an adsorbent such as zeolite having a small Si/Al ratio such as A-type zeolite, titanate, or titanium silicate is known. However, the adsorption amount of the adsorbent has an upper limit depending on the quality of treated water. For example, there is known a technique for reusing an adsorbent that has reached its adsorption upper limit. For example, there is a technique of recovering the adsorption capacity of the adsorbent by desorbing the components to be adsorbed from the adsorbent that has reached the adsorption upper limit. However, the adsorbents used in the treatment of radioactive waste liquid are radioactive, and desorption and reuse of such adsorbents have not been carried out.

JP 2015-107457 A

Abe, H., Shunsuke, S., Toshiaki, S., Naoki, T., Seiji, Y., Hisao, O., Akira, I., Michitaka, S. (2016). Daiichi Nuclear Power Plant - 16081,”Proc., WM2016 Conference, Phoenix, Arizona, USA.

A large amount of contaminated water (water to be treated) generated by the accident at the Fukushima Daiichi Nuclear Power Station is still undergoing adsorption treatment. Although stable treatment has been achieved, there is a problem that a large amount of waste adsorbent is generated. Therefore, there is a demand to suppress the amount of radioactive waste generated. In particular, following the accident at the Fukushima Daiichi Nuclear Power Plant, an efficient usage form of adsorbent suitable for adsorption in the field of nuclear power is desired.

The embodiment of the present invention has been made in consideration of such circumstances, and provides a radioactive waste liquid treatment technology capable of reducing waste generated when treating water to be treated generated from a nuclear power plant. intended to

A radioactive waste liquid treatment method according to an embodiment of the present invention includes at least one of cesium, strontium, iodine, antimony, ruthenium, technetium, cobalt, uranium, plutonium, americium, curium, neptunium, barium, calcium, and magnesium. a step of adsorbing the specific substance in the first water to be treated, wherein the substance is contained in the first water to be treated, and adsorbing the specific substance in the first water to be treated; a step of adsorbing the specific substance contained in the second water to be treated, which is different from the second water to be treated, on the adsorbent used to adsorb the specific substance in the first water to be treated; and extracting at least part of the adsorbent stored in the adsorption tower from the first adsorption tower and transferring it to a second adsorption tower for treating the second water to be treated .

An embodiment of the present invention provides a radioactive waste liquid treatment technology capable of reducing waste generated when treating water to be treated generated from a nuclear power plant.

The figure which shows the radioactive liquid waste processing system of 1st Embodiment. 4 is a flow chart showing the radioactive waste liquid treatment method of the first embodiment. The figure which shows the radioactive liquid waste processing system of 2nd Embodiment. 6 is a flow chart showing a radioactive waste liquid treatment method of the second embodiment. The figure which shows the radioactive liquid waste processing system of 3rd Embodiment. 8 is a flow chart showing a radioactive waste liquid treatment method according to the third embodiment.

(First embodiment)
The present embodiment will be described below with reference to the accompanying drawings. First, a radioactive waste liquid treatment system and a radioactive waste liquid treatment method according to a first embodiment will be described with reference to FIGS. 1 and 2. FIG.

Reference numeral 1 in FIG. 1 denotes the radioactive waste liquid treatment system of the first embodiment. This radioactive liquid waste treatment system 1 purifies water W1 and W2 to be treated as radioactive liquid waste generated from a nuclear power plant. For example, specific substances contained in the water W1 and W2 to be treated are adsorbed by the adsorbent 2 to perform purification treatment.

Specific substances of the present embodiment include cesium (Cs), strontium (Sr), iodine (I), antimony (Sb), ruthenium (Ru), technetium (Tc), cobalt (Co), uranium (U), plutonium ( Pu), americium (Am), curium (Cm), neptunium (Np), barium (Ba), calcium (Ca), and magnesium (Mg).

The specified substances are radionuclides such as cesium (Cs), strontium (Sr), iodine (I), antimony (Sb), ruthenium (Ru), technetium (Tc), cobalt (Co), uranium (U), At least one of plutonium (Pu), americium (Am), curium (Cm), neptunium (Np), and barium (Ba), and calcium (Ca), magnesium (Mg), sodium ( Na), potassium (K), ammonia (NH ₃ ), carbonate ion (CO ₂ ^- HCO ₃ ^- ), sulfate ion (SO ₄ ^2- ), chloride ion (Cl ^- ), hydroxide ion (OH ^- ) At least one type of and may be included.

In other words, the specific substance may include both the radionuclide that is the source of contamination of the radioactive liquid waste and the substance derived from seawater. Substances derived from seawater are harmless to the human body. However, when the radionuclides contained in the waters W1 and W2 to be treated are adsorbed onto the adsorbent 2, substances derived from seawater may inhibit the adsorbing action. In particular, some adsorbents 2 adsorb more seawater-derived substances than radionuclides. Therefore, in the radioactive waste liquid treatment system 1 of the present embodiment, both radionuclides and seawater-derived substances can be treated.

In this embodiment, the adsorbent 2 can remove the water to be treated W1, W2 containing at least two types of specific substances, ie, radionuclides and seawater-derived substances. In particular, seawater-derived substances that inhibit adsorption of radioactive substances can be efficiently removed.

As shown in FIG. 1 , the radioactive waste liquid treatment system 1 includes a first adsorption tower 3 containing an adsorbent 2 and a second adsorption tower 4 containing the adsorbent 2 . The adsorbent 2 is made of zeolite or titanium-based material, and is accommodated in adsorption towers 3 and 4 in the form of powder or slurry. The type of adsorbent 2 is adjusted according to the specific substance to be adsorbed. This adsorbent 2 has a specific gravity slightly greater than 1 and sinks in water, but has almost the same specific gravity as water. Therefore, when the flow velocity or pressure of water reaches or exceeds a predetermined value, the adsorbent 2 can flow together with the water.

The first adsorption tower 3 is connected via a first supply pipe 6 to a first pre-treatment tank 5 in which the first water W1 to be treated is stored. Further, a first post-treatment tank 7 in which treated first water W1 to be treated is stored is connected via a first discharge pipe 8 .

The second adsorption tower 4 is connected via a second supply pipe 10 to a second pre-treatment tank 9 in which the second water W<b>2 to be treated is stored. Furthermore, a second post-treatment tank 11 in which the post-treatment second treatment target water W2 is stored is connected via a second discharge pipe 12 .

The first water W1 to be treated before treatment contains a specific substance at a predetermined concentration. Furthermore, the second water to be treated W2 before treatment contains the specific substance at a concentration that is at least twice that of the first water to be treated W1 before treatment. That is, the first water W1 to be treated before treatment and the second water W2 to be treated before treatment have different concentrations of the contained specific substances. The concentration in the present embodiment may be ion concentration, weight concentration, volume concentration, or molar concentration.

In this embodiment, the concentration of the specific substance in the water to be treated W2 stored in the second pre-treatment tank 9 is the highest. The water to be treated W1 and W2 stored in the second post-treatment tank 11 and the first pre-treatment tank 5 have a higher concentration of specific substances than at least the water to be treated W1 stored in the first post-treatment tank 7 .

Note that the second water to be treated W2 before treatment may have the same specific substance concentration as the specific substance contained in the first water to be treated W1 before treatment, provided that the concentration of the specific substance is different from that of the first water to be treated W1 before treatment. Good luck. Furthermore, when there are two types of specific substances contained in the first water to be treated W1 before treatment, the concentration of at least one specific substance in the second water to be treated W2 before treatment is equal to that of the first treatment before treatment. It suffices if there is more than the target water W1. For example, when the first water to be treated W1 before treatment contains two types of specific substances, cesium and calcium, the concentration of cesium contained in the second water to be treated W2 before treatment is doubled or more. For example, the concentration of calcium may be lower than that of the first water W1 to be treated before treatment.

Further, in the present embodiment, in the aspect in which the concentration of the specific substance is different between the first water to be treated W1 before treatment and the second water to be treated W2 before treatment, either one of the water to be treated W1 before treatment, It includes that W2 does not contain the specific substance at all, that is, the concentration is zero.

A first treatment system 13 (first treatment device) having a first adsorption tower 3 to treat the first water W1 to be treated, and a second treatment system 14 having a second adsorption tower 4 to treat the second water W2 to be treated. (Second processing device) is provided. Note that the adsorbent 2 used in the first adsorption tower 3 can be reused in the second adsorption tower 4 . Since the used adsorbent 2 becomes radioactive waste, the amount of radioactive waste generated can be reduced by reusing this adsorbent 2 and using it in a plurality of treatment systems 13 and 14 .

A first treatment form is a form in which the first water W1 to be treated is treated using the adsorbent 2 housed in the first adsorption tower 3 . A mode in which the adsorbent 2 used in the first adsorption tower 3 is transferred to the second adsorption tower 4 and the second water W2 to be treated is treated in the second adsorption tower 4 is the second treatment mode. The radioactive waste liquid treatment system 1 of this embodiment can be switched from the first treatment mode to the second treatment mode.

It should be noted that the concentration of the specific substance in the second water to be treated W2 before being treated by the adsorbent 2 in the second treatment mode is the concentration of the specific substance in the last treated water W2 in the first treatment mode (immediately before switching the mode). 1 The concentration is more than twice the concentration of the water W1 to be treated. That is, before and after (immediately before and immediately after) switching from the first treatment mode to the second treatment mode, the concentrations of the specific substances contained in the water W1 and W2 to be treated that come into contact with the adsorbent 2 are different.

When transferring the adsorbent 2 stored in the first adsorption tower 3 to the second adsorption tower 4, if another adsorbent 2 is already stored in the second adsorption tower 4, the second The adsorbent 2 of the adsorption tower 4 is pulled out.

The first treatment system 13 and the second treatment system 14 may constitute one water treatment system. In that case, the first treatment system 13 may be provided downstream of the second treatment system 14 in the system for treating one type of water to be treated generated from the same pollution source. That is, the second water W2 to be treated after being treated in the second adsorption tower 4 may be the first water W1 to be treated before being treated in the first adsorption tower 3 .

Next, a mechanism for transferring the adsorbent 2 stored in the first adsorption tower 3 to the second adsorption tower 4, that is, a switching mechanism for switching from the first treatment mode to the second treatment mode will be described.

The first adsorption tower 3 is a cylindrical container, and is installed so that the axis of the cylinder is oriented in the vertical direction. A first water pipe 15 is connected to the lower portion (bottom plate portion) of the first adsorption tower 3 . A first circulation pipe 16 is connected to the upper portion (ceiling portion) of the first adsorption tower 3 . Furthermore, the first water flow pipe 15 and the first circulation pipe 16 are connected to the first liquid feed pump 17 . A loop-shaped flow path is formed by the first water flow pipe 15 and the first circulation pipe 16 . A replenishment water tank 18 is connected to the first liquid feed pump 17 via a replenishment connection pipe 19 .

The first liquid feed pump 17 is connected to the transfer pump 21 via the first transfer pipe 20 . Furthermore, the transfer pump 21 is connected to the second adsorption tower 4 via the second transfer pipe 22 . Also, the second transfer pipe 22 is provided with a monitor 23 (detector) for monitoring the transfer amount of the adsorbent 2 transferred.

The second adsorption tower 4 is a cylindrical vessel, and is installed so that the axis of the cylinder is oriented in the vertical direction. A second water pipe 24 is connected to the lower portion (bottom plate portion) of the second adsorption tower 4 . A second circulation pipe 25 is connected to the upper portion (ceiling portion) of the second adsorption tower 4 . Furthermore, the second water flow pipe 24 and the second circulation pipe 25 are connected to a second liquid feed pump 26 . A loop-shaped flow path is formed by the second water flow pipe 24 and the second circulation pipe 25 . The second pre-treatment tank 9 is connected to the second liquid feed pump 26 via a tank connection pipe 27 .

The radioactive waste liquid treatment system 1 includes a controller 28 that controls the first liquid feed pump 17 , the transfer pump 21 and the second liquid feed pump 26 . Note that the control of the first liquid feed pump 17, the transfer pump 21, and the second liquid feed pump 26 may be performed manually.

The transfer amount of the adsorbent 2 detected by the monitor 23 is input to the controller 28 . The control unit 28 also includes a timer that counts the elapsed time.

The monitor 23 is a monitoring device using light such as laser. The monitor 23 acquires the slurry concentration (turbidity) of the water flowing through the second transfer pipe 22 . The control unit 28 can calculate the transfer amount of the adsorbent 2 by summing up the slurry concentration, the flow rate by the transfer pump 21 and the time. From this calculated amount of transfer, it can be grasped whether the transfer of the adsorbent 2 from the first adsorption tower 3 to the second adsorption tower 4 has been completed.

In the first treatment system 13, when the adsorbent 2 is extracted from the first adsorption tower 3, makeup water W3, which is a fluid for transfer, is supplied from the makeup water tank 18 to the first liquid feed pump 17, and the first liquid feed pump 17 is driven. Then, the make-up water W3 is supplied to the lower part of the first adsorption tower 3 from the first water flow pipe 15, and the make-up water W3 flows out from the upper part of the first adsorption tower 3 to the first circulation pipe 16. That is, the make-up water W3 can be passed through the first adsorption tower 3 from the bottom to the top. This flow of water forms a loop-shaped flow path that circulates through the first liquid feed pump 17 , the first water flow pipe 15 , the first adsorption tower 3 , and the first circulation pipe 16 . This flow of water causes the adsorbent 2 to fluidize and flow together with the make-up water W3.

By driving the transfer pump 21 , the adsorbent 2 is transferred to the second adsorption tower 4 together with the make-up water W3 through the first transfer pipe 20 and the second transfer pipe 22 .

In the second treatment system 14, the untreated second water W2 to be treated is supplied from the second untreated tank 9 to the second liquid feed pump 26, and the second liquid feed pump 26 is driven. Then, the second water W2 to be treated is supplied from the second water flow pipe 24 to the lower part of the second adsorption tower 4, and the second water W2 to be treated flows out from the upper part of the second adsorption tower 4 to the second circulation pipe 25. be. That is, water can be passed from the bottom to the top of the second adsorption tower 4 . This flow of water forms a loop-shaped flow path that circulates through the second water flow pipe 24 , the second circulation pipe 25 , and the second liquid feed pump 26 . By this water flow, the adsorbent 2 transferred from the first adsorption tower 3 is arranged. Then, the adsorbent 2 is evenly accommodated inside the second adsorption tower 4 .

Then, when all or a predetermined amount of the adsorbent 2 stored in the first adsorption tower 3 is transferred to the second adsorption tower 4, the pumps 17, 21, 26 are stopped.

In this embodiment, first, the adsorbent 2 is made to adsorb|suck the specific substance of the 1st process target water W1 in the 1st adsorption tower 3. As shown in FIG. The adsorbent 2 stored in the first adsorption tower 3 is used until it reaches a breakthrough state. Here, the breakthrough state indicates a state in which the adsorption capacity of the specific substance has reached its upper limit. For example, when the concentration of the specific substance contained in the first water W1 to be treated is substantially the same before and after passing through the first adsorption tower 3, the adsorbent 2 of the first adsorption tower 3 is broken. It can be considered as overdone.

Note that the upper limit value of the adsorption capacity indicating the breakthrough state is set to a different value depending on each of the processing systems 13 and 14 . For example, even if the adsorbent 2 is in a breakthrough state in the first treatment system 13, it may not be in a breakthrough state in the second treatment system 14 yet. Further, even if the adsorption capacity of the predetermined adsorbent 2 for one type of specific substance contained in the first treatment target water W1 to be treated in the first treatment system 13 reaches the upper limit, the second treatment to be treated in the second treatment system 14 is performed. 2. There are cases where the adsorption capacity for other types of specific substances contained in the water W2 to be treated does not reach the upper limit.

In this embodiment, by transferring the adsorbent 2 stored in the first adsorption tower 3 to the second adsorption tower 4, the first treatment system 13 for treating the first water W1 to be treated is in a breakthrough state. The adsorbent 2 can be reused in the second treatment system 14 that treats the second water W2 to be treated. That is, in the second adsorption tower 4, the specific substance of the second water W2 to be treated is adsorbed on the adsorbent 2 used for the adsorption of the specific substance of the first water W1 to be treated. In this way, in the first treatment system 13, the adsorbent 2 that has passed through can be reused, so the amount of the adsorbent 2 that becomes waste can be reduced.

When the water W1, W2 to be treated contains a plurality of types of specific substances, even if one type of specific substance is in a breakthrough state, the other types of specific substances are not yet processed. It may not be in the breakthrough state. Therefore, when a plurality of types of water to be treated W1 and W2 having different specific substances to be adsorbed are treated, the adsorbent 2 used for treating one type of water to be treated W1 is replaced with another type of water W1 to be treated. It is used for treatment of the water W2 to be treated.

Further, at least part of the adsorbent 2 stored in the first adsorption tower 3 that treats the first water W1 to be treated is extracted from the first adsorption tower 3, and the second adsorption tower that treats the second water W2 to be treated I am planning to move it to 4. In this way, the first treatment mode in which the first water W1 to be treated is treated using the first adsorption tower 3 is changed to the second treatment mode in which the second water W2 to be treated is treated using the second adsorption tower 4. can be switched.

Further, the specific substance contained in the second water W2 to be treated, whose concentration of the specific substance is at least twice that of the first water W1 to be treated, is added to the adsorption of the specific substance in the first water W1 to be treated. It is made to adsorb to the adsorbent 2 used. In this way, when the adsorbent 2 used for treatment of the first water W1 to be treated is reused for treatment of the second water W2 to be treated, the treatment efficiency of the second water W2 to be treated can be improved. can. In addition, it is possible to prevent the specific substance adsorbed by the adsorbent 2 during the treatment of the first water W1 to be treated from eluting out during the treatment of the second water W2 to be treated.

Moreover, when extracting the adsorbent 2 from the first adsorption tower 3, water is passed through the first adsorption tower 3 from the bottom to the top. In this way, the worker can extract the adsorbent 2 from the first adsorption tower 3 without touching the adsorbent 2, so that the radiation exposure of the worker can be suppressed. Furthermore, the adsorbent 2 can be efficiently transferred to the first adsorption tower 3 without performing the desorption operation.

Also, the adsorbent 2 extracted from the first adsorption tower 3 is transferred through pipes 16 , 20 , 22 connected from the first adsorption tower 3 to the second adsorption tower 4 . In this way, when the adsorbent 2 is extracted from the first adsorption tower 3, the operator can do so without touching the adsorbent 2, so that the radiation exposure of the operator can be suppressed.

Further, when extracting the adsorbent 2 from the first adsorption tower 3, the make-up water W3, which is a fluid for transfer from the make-up water tank 18, is supplied to the first liquid feed pump 17 so that the operator can touch the adsorbent 2. The adsorbent 2 can be extracted without

Further, the concentration of the specific substance contained in the make-up water W3, which is the fluid for transfer, is equal to or lower than the concentration of the specific substance contained in the first water W1 to be treated after being treated with the adsorbent 2 of the first adsorption tower 3. preferably. In this way, the adsorbent 2 can be transferred while maintaining its adsorption capacity.

In this embodiment, the make-up water W3 stored in the make-up water tank 18 is passed through the first adsorption tower 3 to extract the adsorbent 2, but other modes may be used. For example, the adsorbent 2 may be extracted by passing the treated first water W<b>1 to be treated stored in the first treated tank 7 through the first adsorption tower 3 .

Although not shown, each pipe is provided with a valve. Control is performed such that the corresponding valve is opened when water is allowed to flow through each pipe, and the corresponding valve is closed when water is not allowed to flow. Alternatively, the opening/closing of the valve may be controlled manually.

Next, the radioactive liquid waste treatment method executed by the radioactive liquid waste treatment system 1 of the first embodiment will be described with reference to the flowchart of FIG. The operation of the radioactive waste liquid treatment system 1 will be described including the effects that are passively generated. Note that FIG. 1 will be referred to as appropriate.

As shown in FIG. 2 , first, in step S 11 , the operator controls various valves to supply the first water to be treated W 1 before treatment from the first pretreatment tank 5 to the first adsorption tower 3 . Then, the adsorbent 2 of the first adsorption tower 3 adsorbs the specific substance contained in the first water W1 to be treated. The treated first water W1 to be treated is stored in the first post-treatment tank 7 . Note that the control unit 28 may control the valve.

In the next step S12, the operator determines whether or not the adsorbent 2 of the first adsorption tower 3 has passed through. This determination is made with reference to the treatment amount of the first water W1 to be treated or the usage period of the adsorbent 2 in the first treatment system 13 . Note that the control unit 28 may make this determination. Here, when the adsorbent 2 of the first adsorption tower 3 is not in the breakthrough state (NO in step S12), the process returns to step S11. On the other hand, when the adsorbent 2 of the first adsorption tower 3 is in the breakthrough state (YES in step S12), the process proceeds to step S13.

In step S<b>13 , the control unit 28 drives the first liquid feed pump 17 to supply the makeup water W<b>3 in the makeup water tank 18 to the first adsorption tower 3 . Then, the make-up water W3 is passed through the first adsorption tower 3 from the bottom to the top.

In the next step S14, the adsorbent 2 is extracted from the first adsorption tower 3 through the first circulation pipe 16 along with the flow of the make-up water W3. Here, a loop-shaped flow path is formed that circulates through the first liquid feed pump 17, the first water communication pipe 15, the first adsorption tower 3, and the first circulation pipe 16. As shown in FIG. This flow of water causes the adsorbent 2 to fluidize and flow together with the make-up water W3.

In the next step S15, the control unit 28 drives the transfer pump 21 to transfer the adsorbent 2 to the second adsorption tower 4 together with the makeup water W3 through the first transfer pipe 20 and the second transfer pipe 22. transfer. In addition, the loop-shaped flow circulating through the first liquid feed pump 17, the first water pipe 15, the first adsorption tower 3, and the first circulation pipe 16, and the transfer of the adsorbent 2 to the second adsorption tower 4 You can go at the same time.

In the next step S<b>16 , the controller 28 uses the monitor 23 to monitor the transfer amount of the adsorbent 2 transferred through the second transfer pipe 22 . Note that an operator may perform this monitoring.

In the next step S17, the control unit 28 determines whether the transfer of the adsorbent 2 from the first adsorption tower 3 to the second adsorption tower 4 has been completed based on the monitored transfer amount. In addition, an operator may perform this determination. If the transfer of the adsorbent 2 has not been completed (NO in step S17), the process returns to step S13. On the other hand, when transfer of the adsorbent 2 is completed (YES in step S17), the process proceeds to step S18.

In the next step S<b>18 , the operator controls various valves to supply the untreated second water W<b>2 to be treated from the second untreated tank 9 to the second adsorption tower 4 . Then, the adsorbent 2 of the second adsorption tower 4 adsorbs the specific substance contained in the second water W2 to be treated. The second treated water W<b>2 after treatment is stored in the tank 11 after the second treatment. Note that the control unit 28 may control the valve.

The above completes the radioactive waste liquid treatment method. A new adsorbent 2 may be added to the first adsorption tower 3 from which the adsorbent 2 has been extracted.

In this embodiment, the adsorbent 2 is transferred from the first adsorption tower 3 to the second adsorption tower 4 via the first transfer pipe 20 and the second transfer pipe 22 . In other words, the adsorbent 2 is transferred using the hydraulic transfer mechanism, but other modes may be used. For example, at least a portion of the transfer of the adsorbent 2 from the first adsorption tower 3 to the second adsorption tower 4 uses a transfer mechanism using a belt conveyor, a transfer mechanism using a screw, a gravity drop mechanism, an extrusion mechanism, or an air transfer mechanism. You can use it. By doing so, an appropriate mechanism can be used according to the transfer mode of the adsorbent 2 .

An example of each mechanism will be described. A transport mechanism by a belt conveyor is a mechanism for transporting the adsorbent 2 by a belt conveyor. A transfer mechanism using a screw is a mechanism that transfers the adsorbent 2 using a screw-like mechanical element such as an Archimedian screw. The gravity drop mechanism is that the first adsorption tower 3 is provided at the top of the second adsorption tower 4, and the adsorbent 2 is placed inside the second adsorption tower 4 by opening the bottom plate of the first adsorption tower 3. It is a mechanism to drop and transfer. The push-out mechanism is a mechanism that pushes out and transports the adsorbent 2 from the first adsorption tower 3 using a mechanical element such as a piston. The air transfer mechanism is a transfer mechanism that uses air as a transfer fluid instead of the makeup water W3.

In this embodiment, only the first treatment system 13 provided with the first adsorption tower 3 and the second treatment system 14 provided with the second adsorption tower 4 are illustrated, but there are three or more treatment systems. can be Then, the adsorbent 2 that has passed through the first treatment system 13 is transferred to the second treatment system 14, and the adsorbent 2 that has passed through the second treatment system 14 is subjected to the third treatment. You can transfer it to the system.

(Second embodiment)
Next, a radioactive liquid waste treatment method and a radioactive liquid waste treatment system 1A according to a second embodiment will be described with reference to FIGS. 3 and 4. FIG. The same reference numerals are assigned to the same components as those shown in the above-described embodiment, and overlapping descriptions are omitted.

As shown in FIG. 3, the radioactive waste liquid treatment system 1A of the second embodiment includes a transfer tank 29 used during the transfer of the adsorbent 2 from the first adsorption tower 3 to the second adsorption tower 4. As shown in FIG.

A first circulation pipe 16 extending from the first adsorption tower 3 is connected to the transfer tank 29 . An auxiliary circulation pipe 30 extending from the transfer tank 29 is connected to the first liquid feed pump 17 . A first transfer pipe 20 extending from the first liquid feed pump 17 is connected to a transfer tank 29 . Further, an auxiliary transfer pipe 31 extending from the transfer tank 29 is connected to the transfer pump 21 . A loop-shaped flow path is formed by the first water flow pipe 15 , the first circulation pipe 16 , the transfer tank 29 , and the auxiliary circulation pipe 30 .

The first circulation pipe 16 is provided with a monitor 32 for monitoring the transfer amount of the adsorbent 2 transferred. The transfer amount of the adsorbent 2 detected by the monitor 32 is input to the control section 28 .

In the first treatment system 13, when the adsorbent 2 is extracted from the first adsorption tower 3, makeup water W3, which is a fluid for transfer, is supplied from the makeup water tank 18 to the first liquid feed pump 17, and the first liquid feed pump 17 is driven. First, make-up water W3 is supplied to the lower part of the first adsorption tower 3 from the first liquid feed pump 17 through the first water pipe 15 . Then, the make-up water W3 is discharged from the upper portion of the first adsorption tower 3 into the first circulation pipe 16, and then flows into the transfer tank 29. A loop-shaped flow path is formed to circulate through the first liquid feed pump 17, the first water pipe 15, the first adsorption tower 3, the first circulation pipe 16, the transfer tank 29, and the auxiliary circulation pipe 30. This flow of water causes the adsorbent 2 to fluidize and flow together with the make-up water W3.

The adsorbent 2 extracted from the first adsorption tower 3 is stored in the transfer tank 29 . In addition, in the transfer tank 29 , a filter that retains only the adsorbent 2 and allows water to pass through may be provided on the outlet side connected to the auxiliary circulation pipe 30 .

A monitor 32 monitors the transfer amount of the adsorbent 2 extracted from the first adsorption tower 3 . After a sufficient amount of adsorbent 2 has been transferred from the first adsorption tower 3 to the second adsorption tower 4, the first liquid feed pump 17 is temporarily stopped.

Next, the first liquid feed pump 17 switches the supply destination of the makeup water W3, and supplies the makeup water W3 from the first liquid feed pump 17 to the transfer tank 29 via the first transfer pipe 20. FIG. By driving the transfer pump 21 , the adsorbent 2 is transferred from the transfer tank 29 to the second adsorption tower 4 together with the make-up water W3 through the auxiliary transfer pipe 31 and the second transfer pipe 22 .

Then, when all or a predetermined amount of the adsorbent 2 stored in the transfer tank 29 is transferred to the second adsorption tower 4, the transfer pump 21 is stopped.

In addition, when the second treatment system 14 is provided at a place away from the first treatment system 13, after the adsorbent 2 extracted from the first adsorption tower 3 is stored in the transfer tank 29, this transfer Tank 29 may be removed from first processing system 13 . Then, the transfer tank 29 may be moved to the second processing system 14 . In other words, the transfer tank 29 may be transferred using a vehicle, ship, or the like. After connecting the transfer tank 29 to the second treatment system 14 , the adsorbent 2 stored in the transfer tank 29 may be introduced into the second adsorption tower 4 . In the second embodiment, by using the transfer tank 29, the adsorbent 2 can be transferred even if the piping is not connected from the first adsorption tower 3 to the second adsorption tower 4.

Next, the radioactive liquid waste treatment method executed by the radioactive liquid waste treatment system 1A of the second embodiment will be described with reference to the flowchart of FIG. A description will be given including the effects passively caused by the operation of the radioactive waste liquid treatment system 1A. Note that FIG. 3 will be referred to as needed.

As shown in FIG. 4 , first, in step S<b>21 , the operator controls various valves to supply the first untreated water W<b>1 to be treated from the first untreated tank 5 to the first adsorption tower 3 . Then, the adsorbent 2 of the first adsorption tower 3 adsorbs the specific substance contained in the first water W1 to be treated. The treated first water W1 to be treated is stored in the first post-treatment tank 7 . Note that the control unit 28 may control the valve.

In the next step S22, the operator determines whether or not the adsorbent 2 of the first adsorption tower 3 has passed through. Note that the control unit 28 may make this determination. Here, when the adsorbent 2 of the first adsorption tower 3 is not in the breakthrough state (NO in step S22), the process returns to step S21. On the other hand, when the adsorbent 2 of the first adsorption tower 3 is in the breakthrough state (YES in step S22), the process proceeds to step S23.

In step S<b>23 , the control unit 28 drives the first liquid feed pump 17 to supply the makeup water W<b>3 in the makeup water tank 18 to the first adsorption tower 3 . Then, the make-up water W3 is passed through the first adsorption tower 3 from the bottom to the top.

In the next step S24, the adsorbent 2 is extracted from the first adsorption tower 3 through the first circulation pipe 16 along with the flow of the make-up water W3. Here, a loop-shaped flow path is formed that circulates through the first liquid feed pump 17, the first water communication pipe 15, the first adsorption tower 3, the first circulation pipe 16, the transfer tank 29, and the auxiliary circulation pipe 30. . This flow of water causes the adsorbent 2 to fluidize and flow together with the make-up water W3.

In the next step S25, the adsorbent 2 extracted from the first adsorption tower 3 is transferred to the transfer tank 29 through the first circulation pipe 16. The adsorbent 2 extracted from the first adsorption tower 3 is stored in the transfer tank 29 .

In the next step S26, the control unit 28 monitors the transfer amount of the adsorbent 2 transferred through the first circulation pipe 16 by the monitor 32. As shown in FIG. Note that an operator may perform this monitoring.

In the next step S27, the control unit 28 determines whether or not the transfer of the adsorbent 2 from the first adsorption tower 3 to the transfer tank 29 is completed based on the monitored transfer amount. In addition, an operator may perform this determination. If the transfer of the adsorbent 2 has not been completed (NO in step S27), the process returns to step S23. On the other hand, when transfer of the adsorbent 2 is completed (YES in step S27), the process proceeds to step S28.

In step S<b>28 , the first liquid feed pump 17 switches the supply destination of the makeup water W<b>3 and supplies the makeup water W<b>3 from the first liquid feed pump 17 to the transfer tank 29 via the first transfer pipe 20 . The adsorbent 2 is extracted from the transfer tank 29 through the auxiliary transfer pipe 31 along with the flow of the make-up water W3.

In the next step S29, the controller 28 drives the transfer pump 21 to transfer the adsorbent 2 together with the makeup water W3 to the second adsorption tower 4 through the auxiliary transfer pipe 31 and the second transfer pipe 22. be done.

In the next step S<b>30 , the controller 28 uses the monitor 23 to monitor the transfer amount of the adsorbent 2 transferred through the second transfer pipe 22 . Note that an operator may perform this monitoring.

In the next step S31, the controller 28 determines whether the transfer of the adsorbent 2 from the transfer tank 29 to the second adsorption tower 4 has been completed based on the monitored transfer amount. In addition, an operator may perform this determination. If the transfer of the adsorbent 2 has not been completed (NO in step S31), the process returns to step S28. On the other hand, when transfer of the adsorbent 2 is completed (YES in step S31), the process proceeds to step S32.

In step S<b>32 , the operator controls various valves to supply the untreated second water W<b>2 to be treated from the second untreated tank 9 to the second adsorption tower 4 . Then, the adsorbent 2 of the second adsorption tower 4 adsorbs the specific substance contained in the second water W2 to be treated. The second treated water W<b>2 after treatment is stored in the tank 11 after the second treatment. Note that the control unit 28 may control the valve.

The above completes the radioactive waste liquid treatment method. A new adsorbent 2 may be added to the first adsorption tower 3 from which the adsorbent 2 has been extracted.

In the second embodiment, the adsorbent 2 is transferred from the first adsorption tower 3 to the transfer tank 29 , and the adsorbent 2 is transferred to the second adsorption tower 4 using this transfer tank 29 . Therefore, even if the second adsorption tower 4 is located far from the first adsorption tower 3, the adsorbent 2 can be transferred.

(Third embodiment)
Next, a radioactive liquid waste treatment method and a radioactive liquid waste treatment system 1B according to a third embodiment will be described with reference to FIGS. 5 and 6. FIG. The same reference numerals are assigned to the same components as those shown in the above-described embodiment, and overlapping descriptions are omitted.

As shown in FIG. 5, one adsorption tower 34 is provided in one treatment system 33 in the radioactive waste liquid treatment system 1B of the third embodiment.

A first pre-treatment tank 5 in which untreated first water W1 to be treated is stored is connected to this one adsorption tower 34 via a first supply pipe 6 . Further, a first post-treatment tank 7 in which treated first water W1 to be treated is stored is connected via a first discharge pipe 8 .

Furthermore, a second pre-treatment tank 9 in which untreated second water W2 to be treated is stored is connected to this one adsorption tower 34 via a second supply pipe 10 . Furthermore, a second post-treatment tank 11 in which the post-treatment second treatment target water W2 is stored is connected via a second discharge pipe 12 .

The radioactive waste liquid treatment system 1B includes a valve 35 provided in the first supply pipe 6, a valve 36 provided in the first discharge pipe 8, a valve 37 provided in the second supply pipe 10, and a valve 37 provided in the second discharge pipe 12. A control unit 28 is provided for controlling the valve 38 to be connected.

In the first processing mode, the valve 35 provided in the first supply pipe 6 and the valve 36 provided in the first discharge pipe 8 are opened, and the other valves 37 and 38 are closed. Here, the adsorption tower 34 causes the adsorbent 2 to adsorb the specific substance of the first water W1 to be treated. And it is used until the adsorbent 2 accommodated in the adsorption tower 34 reaches a breakthrough state. When the adsorbent 2 reaches the breakthrough state, the first processing mode is switched to the second processing mode.

In the second processing mode, the valve 37 provided in the second supply pipe 10 and the valve 38 provided in the second discharge pipe 12 are opened, and the other valves 35 and 36 are closed. Then, the adsorption tower 34 causes the adsorbent 2 to adsorb the specific substance of the second water W2 to be treated.

Next, the radioactive waste liquid treatment method executed by the radioactive waste liquid treatment system 1B of the third embodiment will be described with reference to the flowchart of FIG. A description will be given including the effects passively caused by the operation of the radioactive waste liquid treatment system 1B. Note that FIG. 5 will be referred to as needed.

As shown in FIG. 6, first, in step S41, the control unit 28 opens the valve 35 provided in the first supply pipe 6 and the valve 36 provided in the first discharge pipe 8, and the other valves 37, 38 is closed. Here, the first water to be treated W<b>1 before treatment is supplied from the first pretreatment tank 5 to the adsorption tower 34 . Then, the adsorption tower 34 causes the adsorbent 2 to adsorb the specific substance of the first water W1 to be treated. The treated first water W1 to be treated is stored in the first post-treatment tank 7 . The operator may control the valves 35-38.

Next, in step S42, the operator determines whether or not the adsorbent 2 in the adsorption tower 34 has passed through. Note that the control unit 28 may make this determination. If the adsorbent 2 in the adsorption tower 34 is not in the breakthrough state (NO in step S42), the process returns to step S41. On the other hand, when the adsorbent 2 of the adsorption tower 34 is in the breakthrough state (YES in step S42), the process proceeds to step S43.

Next, in step S43, the control unit 28 opens the valve 37 provided in the second supply pipe 10 and the valve 38 provided in the second discharge pipe 12, and closes the other valves 35 and 36. By switching the opening and closing of the valves 35 to 38 in this way, it is possible to switch from the first processing mode to the second processing mode.

Next, in step S44, the untreated second water W2 to be treated is supplied from the second untreated tank 9 to the adsorption tower . Then, the adsorption tower 34 causes the adsorbent 2 to adsorb the specific substance of the second water W2 to be treated. The second treated water W<b>2 after treatment is stored in the tank 11 after the second treatment. The operator may control the valves 35-38.

In the radioactive waste liquid treatment system 1B of the third embodiment, from the first treatment mode in which the first treatment target water W1 is treated in one adsorption tower 34 containing the adsorbent 2, the second treatment target water W2 is treated. It is possible to switch to a second processing mode for processing. In this way, when changing from the first treatment mode for treating the first water W1 to be treated to the second treatment mode for treating the second water W2 to be treated, the adsorbent 2 is replaced with respect to the adsorption tower 34. without. Therefore, the worker does not have to touch the adsorbent 2, and the radiation exposure of the worker can be suppressed.

The radioactive waste liquid treatment method according to the present embodiment has been described based on the first to third embodiments, but the configuration applied in any one embodiment may be applied to another embodiment, You may combine the structure applied in each embodiment.

In addition, in the flowchart of the present embodiment, each step is exemplified in a form in which each step is executed in series. good. Also, some steps may be executed in parallel with other steps.

In addition, in this embodiment, although the aspect which the 1st treatment system 13 is provided with the one 1st adsorption tower 3 is illustrated, another aspect may be sufficient. For example, two or more first adsorption towers 3 may be provided in the first treatment system 13 . Moreover, in the present embodiment, an aspect in which one second adsorption tower 4 is provided in the second treatment system 14 is exemplified, but other aspects may be employed. For example, two or more second adsorption towers 4 may be provided in the second treatment system 14 .

According to at least one embodiment described above, the specific substance contained in the second water to be treated, which has a different concentration of the specific substance from the first water to be treated, is used to adsorb the specific substance in the first water to be treated. By including the step of adsorbing to the adsorbent, it is possible to reduce the waste generated when treating the water to be treated generated from the nuclear power plant.

While several embodiments of the invention have been described, these embodiments have been presented by way of example and are not intended to limit the scope of the invention. These embodiments can be implemented in various other forms, and various omissions, replacements, changes, and combinations can be made without departing from the scope of the invention. These embodiments and their modifications are included in the scope and spirit of the invention, as well as the scope of the invention described in the claims and equivalents thereof.

1 (1A, 1B)... Radioactive waste liquid treatment system, 2... Adsorbent, 3... First adsorption tower, 4... Second adsorption tower, 5... First pre-treatment tank, 6... First supply pipe, 7... First Post-treatment tank 8 First discharge pipe 9 Second pre-treatment tank 10 Second supply pipe 11 Second post-treatment tank 12 Second discharge pipe 13 First treatment system 14 2nd treatment system 15... 1st water communication pipe 16... 1st circulation pipe 17... 1st liquid feed pump 18... replenishment water tank 19... replenishment connection pipe 20... first transfer pipe 21... transfer Pump 22 Second transfer pipe 23 Monitor 24 Second water pipe 25 Second circulation pipe 26 Second liquid transfer pump 27 Tank connection pipe 28 Control unit 29 Transfer tank, 30... Auxiliary circulation pipe, 31... Auxiliary transfer pipe, 32... Monitor, 33... Treatment system, 34... Adsorption tower, 35 to 38... Valve, W1... First water to be treated, W2... Second water to be treated , W3 . . . make-up water.

Claims (14)

At least one of cesium, strontium, iodine, antimony, ruthenium, technetium, cobalt, uranium, plutonium, americium, curium, neptunium, barium, calcium, and magnesium in the first water to be treated a step of adsorbing the specific substance of the first water to be treated to an adsorbent;
The step of causing the adsorbent used for adsorbing the specific substance in the first water to be treated to adsorb the specific substance contained in the second water to be treated, the concentration of the specific substance being different from that of the first water to be treated. When,
At least part of the adsorbent contained in the first adsorption tower for treating the first water to be treated is extracted from the first adsorption tower and transferred to a second adsorption tower for treating the second water to be treated a step;
including,
Radioactive waste liquid treatment method. The adsorbent using the specific substance contained in the second water to be treated in which the concentration of the specific substance is twice or more of the first water to be treated to adsorb the specific substance in the first water to be treated. be adsorbed to
The radioactive waste liquid treatment method according to claim 1. The specific substance is
at least one of cesium, strontium, iodine, antimony, ruthenium, technetium, cobalt, uranium, plutonium, americium, curium, neptunium, barium;
at least one of calcium, magnesium, sodium, potassium, ammonia, carbonate ion, sulfate ion, chloride ion, and hydroxide ion;
including,
3. The radioactive waste liquid treatment method according to claim 1 or 2. Reusing the adsorbent that has passed through in a first treatment system that treats the first water to be treated in a second treatment system that treats the second water to be treated,
The radioactive waste liquid treatment method according to any one of claims 1 to 3. A step of switching from a form of treating the first water to be treated to a form of treating the second water to be treated in one adsorption tower containing the adsorbent,
The radioactive waste liquid treatment method according to any one of claims 1 to 4. When extracting the adsorbent from the first adsorption tower, passing water from the bottom to the top of the first adsorption tower,
The radioactive waste liquid treatment method according to any one of claims 1 to 5 . Transferring the adsorbent extracted from the first adsorption tower through a pipe connected to the first adsorption tower,
The radioactive waste liquid treatment method according to any one of claims 1 to 6 . transferring the adsorbent through the pipe connected from the first adsorption tower to the second adsorption tower;
The radioactive waste liquid treatment method according to claim 7 . transferring the adsorbent from the first adsorption tower to a transfer tank, and transferring the adsorbent to the second adsorption tower using the transfer tank;
The radioactive waste liquid treatment method according to any one of claims 1 to 7 . Supplying fluid for transfer to the first adsorption tower when extracting the adsorbent from the first adsorption tower,
The radioactive waste liquid treatment method according to any one of claims 1 to 9 . The concentration of the specific substance contained in the transfer fluid is equal to or lower than the concentration of the specific substance contained in the first water to be treated after treatment,
The radioactive waste liquid treatment method according to claim 10. including the step of monitoring the transfer amount of the adsorbent withdrawn from the first adsorption tower;
The radioactive waste liquid treatment method according to any one of claims 1 to 11. In at least part of the transfer of the adsorbent from the first adsorption tower to the second adsorption tower, a hydraulic transfer mechanism, a belt conveyor transfer mechanism, a screw transfer mechanism, a gravity drop mechanism, an extrusion mechanism, and a pneumatic transfer mechanism using at least one mechanism of
The radioactive waste liquid treatment method according to any one of claims 1 to 12. At least one of cesium, strontium, iodine, antimony, ruthenium, technetium, cobalt, uranium, plutonium, americium, curium, neptunium, barium, calcium, and magnesium in the first water to be treated from the first treatment form that includes and adsorbs the specific substance of the first water to be treated to an adsorbent,
The specific substance contained in the second water to be treated, the concentration of the specific substance being different from that of the first water to be treated, is adsorbed on the adsorbent used to adsorb the specific substance in the first water to be treated. It can be switched to two processing modes,
At least part of the adsorbent contained in the first adsorption tower for treating the first water to be treated is extracted from the first adsorption tower and transferred to a second adsorption tower for treating the second water to be treated configured as
Radioactive waste liquid treatment system.

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