JP2021193361A - Processor for radioactive stock solution - Google Patents

Abstract

To remove a radioactive material in vapor more efficiently while suppressing leakage of the material to the outside.SOLUTION: A processor 1 for a radioactive stock solution includes: separation means 21 having heating means 27, the separation means heating a radioactive stock solution containing salt by the heating means 27 to separate the stock solution into the solid material, the vapor, and the liquid of the salt; a scrubber 40 for receiving the vapor separated by the separation means 21, and removing a radioactive component in the vapor by bringing the circulating liquid with the vapor; and first returning means L7, L14, L15, and 68 for returning the liquid separated by the separation means 21 and liquid which overflows from the scrubber 40 to the front stage of the separation means 21.SELECTED DRAWING: Figure 1

Description

The present invention relates to a device for treating a radioactive stock solution containing salt.

An event has occurred in which a large amount of radioactively contaminated water is generated due to the accident at a nuclear power plant. As a means for treating such radioactively contaminated water, Patent Document 1 discloses an apparatus for reducing the volume of radioactive slurry. This device includes a drying unit that dries the slurry, a mist separator that collects the mist in the steam exhausted from the drying unit, and an exhaust treatment unit that condenses the steam that collects the mist to generate condensed water. It has a line that returns the condensed water to the front stage of the drying unit.

Japanese Patent No. 6110921

The radioactively contaminated water may contain salt derived from groundwater, seawater, etc. that invade the building. The salt content can be separated and removed by evaporating the radioactively contaminated water, but the steam generated at this time contains radioactive substances. In order to prevent leakage of radioactive material in the vapor, it is desirable to remove the radioactive material from the vapor and move it to a more controllable liquid. The apparatus disclosed in Patent Document 1 includes a mist separator and an exhaust gas treatment unit, but the mist separator is intended for removing mist and has a limited ability to remove radioactive substances from steam.

An object of the present invention is to provide a radioactive stock solution processing apparatus capable of more efficiently removing radioactive substances contained in steam while suppressing leakage to the outside.

The undiluted solution processing apparatus of the present invention is provided with a heating means, and by heating a radioactive undiluted solution containing salt by the heating means, the undiluted solution is separated into a solid salt solution, a vapor and a liquid, and the separation means. The separated steam is introduced and the circulating liquid is brought into contact with the steam to remove the radioactive components contained in the steam, and the liquid separated by the separation means and the liquid overflowing from the scrubber are placed in front of the separation means. It has a first return means for returning.

According to the present invention, it is possible to provide a treatment device for a radioactive stock solution capable of more efficiently removing radioactive substances contained in steam while suppressing leakage to the outside.

It is a conceptual diagram which shows the structure of the undiluted solution processing apparatus which concerns on one Embodiment of this invention. It is a conceptual diagram which shows the structure of the container which stores the solid salt content. It is a conceptual diagram which shows the other structure of a container.

Hereinafter, the radioactive stock solution processing apparatus according to the embodiment of the present invention will be described with reference to the drawings. The treatment apparatus of this embodiment treats a radioactive stock solution containing salt. The salt content in the radioactive stock solution is derived from groundwater, but is not limited to this.

The treatment device 1 is connected to the existing contaminated water storage treatment system 100. The contaminated water storage treatment system 100 includes a contaminated water tank 101, a reverse osmosis membrane device (hereinafter referred to as RO device 102), and a concentrated water tank 103. The contaminated water tank 101 stores radioactively contaminated water leaking from a building or trench of a nuclear power plant. The radioactively contaminated water is cooling water injected for cooling nuclear fuel, groundwater contaminated by invading the inside of a building or trench and coming into contact with radioactive substances, seawater, and the like. These radioactively contaminated waters are those from which radioactive cesium and the like have been removed after being removed from buildings and trenches. Since the radioactively contaminated water contains salt, it is filtered by the RO device 102 connected to the contaminated water tank 101, and separated into permeated water from which the salt has been removed and concentrated water from which the removed salt has been concentrated. .. Although only one RO device 102 is shown in FIG. 1, a plurality of RO devices may be arranged in series or in parallel, or a plurality of RO devices connected in series may be arranged in parallel. good. Some of the radioactive substances in the radioactively contaminated water pass through the RO membrane and are contained in the permeated water, but some of them are concentrated in RO concentrated water together with salt. Part of the permeated water of the RO device 102 is reused as cooling water, and the rest is transferred to a multi-nuclide removal facility (not shown) for removing radionuclides. The concentrated water of the RO device 102 is stored in the concentrated water tank 103. A part of the concentrated water is returned to the contaminated water tank 101 in order to suppress the increase of the concentrated water. For this purpose, the concentrated water tank 103 is connected to the contaminated water tank 101 by a connection line L101. The connection line L101 is provided with a valve 104 that is opened when the concentrated water is returned to the contaminated water tank 101.

The treatment device 1 has a stock solution tank 2 connected to the concentrated water tank 103 by the concentrated water supply line L1. A concentrated water receiving tank 3 and a first concentrated water transfer pump 4 are provided on the concentrated water supply line L1 for the purpose of isolating the treatment device 1 from the contaminated water storage treatment system 100. The concentrated water stored in the concentrated water tank 103 by the second concentrated water transfer pump 5 installed between the concentrated water receiving tank 3 and the undiluted solution tank 2 on the concentrated water supply line L1 is the concentrated water receiving tank. It is transferred to the stock solution tank 2 via 3. Hydrochloric acid and caustic soda are injected into the stock solution tank 2 in order to adjust the pH of the concentrated water. The hydrochloric acid stored in the hydrochloric acid tank 6 is supplied to the stock solution tank 2 by the hydrochloric acid pump 7 installed on the hydrochloric acid supply line L2. The caustic soda stored in the caustic soda tank 8 is supplied to the undiluted solution tank 2 by the caustic soda pump 9 installed on the caustic soda supply line L3. The pH of the concentrated water is adjusted to be weakly alkaline to about 7 to 9 for the protection of the rotating drum 24 described later. A stirring device (not shown) for stirring the concentrated water can also be provided in the stock solution tank 2. Further, a sodium carbonate supply device 10 is connected to the stock solution tank 2 in order to remove calcium from the concentrated water. The sodium carbonate aqueous solution stored in the sodium carbonate tank 11 is supplied to the stock solution tank 2 by the sodium carbonate pump 12 installed on the sodium carbonate supply line L4. The sodium carbonate supply device 10 may not be connected to the stock solution tank 2, but it is preferably provided in front of the rotary drum 24. Further, the sodium carbonate may be put into the stock solution tank 2 or the like in the state of powder. The concentrated water whose pH has been adjusted and calcium has been removed is the water to be treated of the treatment device 1, and is referred to as a stock solution in the following description.

The processing apparatus 1 has a separating means 21 for separating the undiluted solution into a solid salt solution, a vapor, and a liquid. The undiluted solution is supplied to the separating means 21 by the undiluted solution supply line L5. A stock solution supply pump 22 for transferring the stock solution and a stock solution preheater 23 for preheating the stock solution are provided on the stock solution supply line L5. The undiluted solution preheater 23 may be omitted. The separating means 21 has a pair of rotating drums 24 and a pair of scrapers 25 combined with each drum. The pair of rotating drums 24 are cylindrical drums having the same configuration and shape. The pair of rotating drums 24 come into contact with each other in the radial direction along the contact line 26 extending in the axial direction of the rotating drums 24, and rotate around each rotation center C in opposite directions. The pair of rotating drums 24 rotate in opposite directions with each other in a direction having an upward velocity component at each contact line 26. By rotating in this direction, solid matter can be separated more efficiently. However, the pair of rotating drums 24 may rotate in the opposite direction. The undiluted solution is supplied to the recess 28 formed between the pair of rotating drums 24. As the pair of rotating drums 24, for example, a twin drum dryer T series manufactured by Katsuragi Kogyo Co., Ltd. can be used.

Each rotating drum 24 has a heated steam flow path 27 through which heated steam flows in the vicinity of the rotation center C. The heating steam flow path 27 constitutes a heating means for the rotating drum 24. The surface (outer peripheral surface) of the rotary drum 24 is heated by the heated steam, the undiluted solution adhering to the surface can be evaporated, and the salt contained in the undiluted solution can be deposited on the surface as a solid substance. The pair of rotating drums 24 are covered with a casing 30. The undiluted vapor formed by evaporation fills the upper space of the casing 30 and is supplied to the scrubber 40 described later through a duct 32 connected to the upper surface of the casing 30. The unevaporated undiluted solution moves downward along the surface of the rotary drum 24, is located below the rotary drum 24, and is collected by the liquid recovery unit 31 integrally formed with the casing 30. By heating the undiluted solution with a heating means in this way, the undiluted solution is separated into a solid salt solution, a vapor, and a liquid. The solids are removed and stored as radioactive solid waste by the methods shown below.

The scraper 25 is a blade-shaped stationary body that extends in the axial direction of the rotary drum 24 and comes into contact with the surface of the rotary drum 24, and scrapes off the solid matter S deposited on the surface of the rotary drum 24. The solid S scraped off by the scraper 25 falls due to gravity and is housed in the receiving portion 29 below the scraper 25. The scraper 25 is located on the opposite side of the contact line 26 with respect to the rotation center C of each drum. Therefore, the undiluted solution supplied to the recess 28 is heated while moving along the upper outer peripheral surface of the rotary drum 24, and the solid salt S is scraped off by the scraper 25 at a position beyond the center line in the height direction. ..

As described above, the scrubber 40 is connected to the casing 30 by the duct 32. The steam separated by the separating means 21 is introduced into the scrubber 40 through the duct 32. The scrubber 40 has an outer casing 41 connected to the duct 32 and an inner casing 42 housed in the outer casing 41. The steam descends from the outer casing 41, flows into the inner casing 42 from the lower end opening of the inner casing 42, and rises in the internal space of the inner casing 42. The scrubber 40 has a circulating water line L6 and a circulating water pump 43 provided in the circulating water line L6. An overflow line L7 is connected to the lower part of the outer casing 41. Liquid (circulating water) is retained in the space of the outer casing 41 below the connection portion of the overflow line L7. The circulating water line L6 is connected to the bottom surface of the outer casing 41. The liquid collected at the bottom of the outer casing 41 flows upward through the circulating water line L6 by the circulating water pump 43, and is sprayed downward from the upper part of the inner casing 42. The sprayed liquid makes gas-liquid contact with the rising vapor in the inner casing 42, removes radioactive substances contained in the vapor, and returns to the bottom of the outer casing 41. The steam from which the radioactive substances have been removed is mist-removed by the mist separator 44 and discharged from the scrubber 40 as exhaust gas. A part of the steam introduced into the scrubber 40 condenses and collects at the bottom of the outer casing 41. Therefore, a part of the liquid collected at the bottom of the outer casing 41 is discharged from the outer casing 41 through the overflow line L7. The overflow line L7 is connected to the liquid recovery unit 31, and the discharged liquid is collected by the liquid recovery unit 31.

The exhaust gas discharged from the scrubber 40 is introduced into the steam separator 50. The steam separator 50 is penetrated by a cold water line L8 through which cold water supplied from the air-cooled chiller unit 51 flows. The steam contained in the exhaust gas is condensed with cold water to become condensed water. The cold water obtained by cooling the steam is returned to the air-cooled chiller unit 51 through the cold water line L8. The non-condensable component contained in the exhaust gas is separated from the condensed water as a gas. The condensed water is stored in a condensed water tank 52 connected to the bottom of the steam separator 50. Although only one steam separator 50 is shown in FIG. 1, a plurality of steam separators may be arranged in parallel.

A gas discharge line L9 is connected to the upper part of the steam separator 50. The discharge line L9 is connected to an activated carbon filter 53 that filters the gas discharged from the steam separator 50. The activated carbon filter 53 has a filter containing fiber activated carbon, and for example, an activated carbon fiber filter (WAC filter) manufactured by Wakaida Engineering Co., Ltd. can be used. The activated carbon filter 53 is connected to the exhaust blower 55 via a damper 54. The gas from which the radioactive substance has been removed by the activated carbon filter 53 is released to the outside of the system after confirming the concentration of the radioactive substance.

The processing device 1 has an electric boiler 61 for supplying the heated steam flowing through the heated steam flow path 27 of the rotary drum 24. The water heated by the electric boiler 61 becomes heated steam and is supplied to the rotary drum 24 through the hot steam supply line L10. In order to prevent the generation of scale in the electric boiler 61, the hardness component contained in water is removed in advance by the water softening device 62. The heated steam is supplied to the heated steam flow path 27, condensed in the heated steam flow path 27, becomes drain water, and flows out of the rotary drum 24. The drain water is heat exchanged by the undiluted solution preheater 23, collected in the drain tank 64, returned to the inlet side of the water softening device 62 by the drain pump 65, and reused. A heat exchanger 66 is provided downstream of the drain pump 65, and the drain water is cooled by the cold water supplied from the air-cooled chiller unit 67. By lowering the temperature of the drain water supplied to the water softening device 62, the water softening device 62 can be protected. The water softening device 62 is connected to the water tank 60 in order to replenish the circulating water. General water such as city water is stored in the irrigation tank 60.

The irrigation water is also used for cleaning the rotary drum 24, the scrubber 40, and the liquid recovery unit 31. For this purpose, a first washing water supply line L11 for supplying water to the rotary drum 24, a second washing water supply line L12 for supplying water to the scrubber 40, and a third washing water supply line L12 for supplying water to the liquid recovery unit 31. The washing water supply line L13 and the like are provided. Since the rotary drum 24 and the liquid recovery unit 31 are in contact with water containing salt, they are periodically washed with water in order to prevent blockage due to precipitation of salt. Since the bottom of the scrubber 40 also accumulates radioactive substances contained in the steam, it is regularly washed with water. Further, a circulation cleaning line L14 connecting the bottom and the top of the liquid recovery unit 31 is provided. A circulation cleaning pump 68 is provided on the circulation cleaning line L14. By circulating the undiluted solution staying in the liquid recovery unit 31, it is possible to prevent the precipitation and accumulation of salt at the bottom of the liquid recovery unit 31.

The processing device 1 has a first return means for returning the liquid separated by the separation means 21 and the liquid overflowing from the scrubber 40 to the previous stage of the separation means 21. A first return line L15 branched from the circulation cleaning line L14 and connected to the stock solution tank 2 is provided. The undiluted solution staying at the bottom of the liquid recovery unit 31 can be returned to the undiluted solution tank 2 through a part of the circulation cleaning line L14 and the first return line L15. That is, a part of the circulation cleaning line L14, the first return line L15, and the circulation cleaning pump 68 constitute a return means for returning the liquid separated by the separation means 21 to the previous stage of the separation means 21. Further, as described above, the overflow line L7 connects the scrubber 40 to the liquid recovery unit 31. Therefore, the overflow line L7, a part of the circulation cleaning line L14, the first return line L15, and the circulation cleaning pump 68 constitute a return means for returning the liquid overflowing from the scrubber 40 to the front stage of the separation means 21. The first return means circulates a liquid containing a radioactive substance in the system of the processing device 1 to prevent the radioactive substance from leaking to the outside of the system.

The processing device 1 has a second return means for returning the condensed water generated by the steam separator 50 to the front stage of the separation means 21, particularly to the inlet side of the RO device 102. A second return line L16 for connecting the condensed water tank 52 to the contaminated water tank 101 located in front of the RO device 102 is provided. The second return line L16 is provided with a condensed water transfer pump 69. The second return line L16 and the condensed water transfer pump 69 constitute a second return means. Since the condensed water contains almost no salt, the salt concentration of the radioactively contaminated water supplied to the RO device 102 can be reduced by returning the condensed water to the contaminated water tank 101. The second return line L16 may be connected to the pipe between the contaminated water tank 101 and the RO device 102 instead of the contaminated water tank 101, which exceeds the salt osmotic pressure for the RO device 102 to operate. It is necessary to apply pressure to the reverse osmosis membrane 105 of the RO device 102. However, as described above, in the contaminated water storage treatment system 100 targeted by the present embodiment, the concentrated water tank 103 is connected to the contaminated water tank 101 by the connection line L101. Therefore, the salt contained in the radioactively contaminated water is confined in the system of the contaminated water storage treatment system 100, and the salt concentration of the radioactively contaminated water increases with time. Therefore, unless some measures are taken, a pressure exceeding the osmotic pressure of the salt cannot be applied to the reverse osmosis membrane 105, and the operation of the RO device 102 becomes difficult. The second return means not only prevents the radioactive material from leaking out of the system, but also lowers or suppresses the increase in the salt concentration of the radioactively contaminated water supplied to the RO device 102, so that the operating reliability of the RO device 102 is reduced. It can enhance the sex.

The salt solid matter separated by the separation means 21 is collected in a hard container 80 installed in the collection area R below the separation means 21. The configuration of the hard container 80 is not limited, but a steel container such as a drum can, a container made of a metal other than iron, a container made of resin, and the like can be used. The hard container 80 of this embodiment is a drum can. When a certain amount of solid matter is accumulated in the receiving portion 29 of the separating means 21, the solid matter stored in the receiving portion 29 is transferred to the hard container 80. In the collection area R, a transfer device (not shown) for transferring the solid material from the receiving portion 29 to the hard container 80, a lid tightening machine for tightening the lid of the hard container 80 (not shown), and the like are arranged. Although the rigid container 80 is installed on the trolley 82 with casters, it may be moved by a conveyor. The solid material is first housed in a flexible container 81 made of a plastic film, the flexible container 81 is sealed, evacuated, and then housed in a hard container 80. The solid matter is mainly composed of NaCl, but since it contains impurities, it is likely to come into contact with moisture in the atmosphere and cause deliquescent. If the solid material is directly put into the hard container 80, the hard material may be corroded due to the deliquescent of the solid material, and the solid material may leak. Since solids contain radioactive substances, there is a high need to prevent leakage. Therefore, the flexible container 81 is sealed in advance and evacuated to minimize the amount of water that comes into contact with the solid matter, and the possibility of deliquescent is reduced. If NaCl contains calcium, deliquescent is likely to occur. Therefore, for the purpose of removing calcium, sodium carbonate is added to the concentrated water stored in the stock solution tank 2 as described above.

FIG. 2 shows the configuration of a container for storing the solid matter S. In order to accommodate the solid matter S, first, as shown in FIG. 2A, a bag-shaped flexible container 81 having an open upper input port is accommodated inside the hard container 80. FIG. 2B shows a cross-sectional view of the flexible container 81 and the suction device 90 at this time. A resin nozzle 84 is fixed to the side surface of the flexible container 81, and an inlet valve 85 that rotates about a rotation shaft 86 is provided inside the nozzle 84. The inlet valve 85 is urged in the closing direction (counterclockwise in the figure) by a spring (not shown) provided on the rotary shaft 86, but can be opened toward the internal space by pushing it toward the internal space. Is. The nozzle 84 is provided with a stopper 84a overhanging the inside of the flow path, and in the state shown in FIGS. 2 (a) and 2 (b), the inlet valve 85 abuts on the stopper 84a by the urging force of the spring and is closed. ing. The stopper 84a is provided on the outside of the inlet valve 85. That is, the inlet valve 85 is a check valve. The suction device 90 is connected to an insertion port 92 that can be attached to and detached from the nozzle 84, a mixing chamber 93 that communicates with the insertion port 92, a drive gas introduction unit 94 that opens inside the mixing chamber 93, and a mixing chamber 93. It has a discharge gas discharge unit 95. A first throttle portion 96 and a second throttle portion 97 are provided inside the drive gas introduction portion 94 and the discharge gas discharge portion 95, respectively. That is, the suction device 90 is an ejector. A valve 98 is provided in the insertion port 92 and is closed when the suction device 90 is not used. The suction device 90 is connected to an air supply source 91 (see FIG. 1). The suction device 90 may be an electric type equipped with a motor, but since it handles air containing salt, it is preferable to use an ejector having high resistance to corrosion.

When the flexible container 81 is filled with the solid substance S in a predetermined amount, as shown in FIG. 2 (c), the input port on the upper portion of the flexible container 81 is closed by an appropriate method such as a fastener or a heat seal. The closing portion P is shown by a broken line), and the flexible container 81 is sealed. Next, as shown in FIG. 2D, the insertion port 92 of the suction device 90 is inserted into the nozzle 84, and the valve 98 is opened. The inlet valve 85 is opened by being pushed by the insertion port 92, and the internal space of the flexible container 81 communicates with the suction device 90. Next, air, which is a driving gas, is supplied to the driving gas introduction unit 94 from the air supply source 91. The drive gas supplied to the drive gas introduction unit 94 passes through the first throttle unit 96 to become a low-pressure supersonic flow and flows into the mixing chamber 93. The driving gas sucks the air inside the flexible container 81 through the nozzle 84 and evacuates the inside of the flexible container 81. Here, the vacuum means a state in which the pressure inside the flexible container 81 is lower than the pressure outside the flexible container 81. The flexible container 81 is preferably in a so-called vacuum-packed state in which most of the air inside is removed, although the degree of vacuum inside is not limited. The air sucked from the flexible container 81 is mixed with the drive gas in the mixing chamber 93, further mixed with the drive gas on the upstream side of the second throttle portion 97 of the discharge gas discharge portion 95, and boosted on the downstream side. Is discharged. When the air inside the flexible container 81 is almost removed, the suction device 90 is stopped, the valve 98 is closed, and the insertion port 92 is pulled out from the nozzle 84. At this time, the inlet valve 85 automatically rotates in the closing direction by the urging force of the spring and abuts on the stopper 84a to close, so that the amount of air flowing back into the flexible container 81 is minimized.

After that, the lid of the hard container 80 is closed, the flexible container 81 is airtightly housed in the hard container 80, and the hard container 80 is carried out from the collection area R by the trolley 82. In the present embodiment, the flexible container 81 having an open top is set in the hard container 80 before the solid material S is housed in the flexible container 81. However, after performing the step of evacuating the inside of the flexible container 81 outside the hard container 80, the flexible container 81 may be housed in the hard container 80 and the hard container 80 may be sealed.

FIG. 3 shows another embodiment of the flexible container 81. The nozzle 184 includes a stopper 184a overhanging the inside of the flow path, and the inlet valve 185 abuts on the outer side surface of the stopper 184a. The stopper 184a is provided inside the inlet valve 185. Unlike the inlet valve 85, the inlet valve 185 rotates outside the flexible container 81. That is, the inlet valve 185 can be opened in a direction away from the internal space of the flexible container 81. The inlet valve 185 is urged in the closing direction (clockwise in the figure) by a spring (not shown) provided on the rotary shaft 86. In the state shown in FIG. 3A, the inlet valve 185 abuts on the stopper 184a by the urging force of the spring and is closed. As shown in FIG. 3B, when the insertion port 92 of the suction device 90 is inserted into the nozzle 184 and the valve 98 is opened, the inlet valve 185 is opened by rotating counterclockwise due to the suction force of the suction device 90. , The internal space of the flexible container 81 communicates with the suction device 90. In the present embodiment, when the internal space of the flexible container 81 becomes empty and the suction by the suction device 90 is stopped, the inlet valve 185 is automatically operated by the differential pressure between the internal pressure of the flexible container 81 and the atmospheric pressure. Therefore, the spring of the rotating shaft 86 can be omitted. Although not shown, a valve such as a futon compression bag that can be sucked by simply hitting the insertion port 92 of the suction device 90 may be used. That is, the openable inlet portion (for example, the insertion port 92) of the flexible container 81 is opened by the suction device 90, the air inside the flexible container 81 is sucked, and the inside of the flexible container 81 is evacuated. Any configuration can be adopted as long as possible.

Since the air sucked from the flexible container 81 contains radioactive substances, it is filtered by the HEPA filter 99 filter built in the suction device 90. The HEPA filter 99 is provided on the downstream side of the second throttle portion 97 of the discharge gas discharge portion 95, and captures most of the radioactive substances contained in the air sucked from the flexible container 81. The outlet of the discharged gas discharge unit 95 is connected to the gas discharge line L9 by the air discharge line L17 (see FIG. 1). Therefore, the air discharged from the suction device 90 is filtered by the activated carbon filter 53 containing the fiber activated carbon. Since the air discharge line L9 joins the gas discharge line L9 on the inlet side of the activated carbon filter 53, the number of activated carbon filters 53 can be suppressed. The air discharged from the suction device 90 may be filtered by an activated carbon filter different from the activated carbon filter 53.

In this embodiment, as described above, the scrubber 40 is used to remove the radioactive substance from the stock solution. The scrubber 40 can be suitably used for purifying gas, and can remove most of the radioactive substances contained in the vapor of the undiluted solution. Unlike filters, there is no need to replace parts, so maintenance is easy. Further, a part of the radioactive substance remaining in the steam of the undiluted solution is transferred to the condensed water by the steam separator 50. As described above, since the radioactive substance is removed from the steam in two steps, not only the efficiency of removing the radioactive substance is improved, but also the load of the steam separator 50 is reduced. Since the concentration of the radioactive substance contained in the gas separated by the steam separator 50 is considerably reduced, the load on the activated carbon filter 53 can be suppressed.

Further, in the present embodiment, the entire amount of the liquid generated by the separation means 21 and the scrubber 40 is returned to the stock solution tank 2 upstream of the separation means 21. Since it is not necessary to change the return destination according to the concentration of radioactive substances, there is no need for equipment for measuring the concentration of radioactive substances and switching pipes, and the configuration of the equipment is simplified. As for the condensed water generated by the steam separator 50, the same effect can be obtained because the entire amount is returned to the contaminated water tank 101.

Further, according to the present embodiment, since the salt content is extracted from the concentrated water in the form of a solid substance, not only the salt concentration of the concentrated water can be reduced, but also the volume of the concentrated water itself can be reduced. The salinity of the concentrated water is about 8000 to 80,000 ppm, which is lower than that of the slurry, but the salinity is very high. Therefore, by sequentially taking out the concentrated water stored in the concentrated water tank 103 and treating it with the processing apparatus 1 of the present embodiment, it is possible to reduce the number of the concentrated water tank 103.

On the other hand, the salt taken out as a solid substance is sealed in a vacuum-packed state and further stored in a hard container 80, so that the possibility of leakage due to deliquescent is reduced.

1 Processing device 10 Sodium carbonate supply device 21 Separation means 24 Rotating drum 25 Scraper 26 Contact line 27 Heating steam flow path (heating means)
28 Recess 40 Scrubber 50 Steam separator 53 Activated carbon filter 81 Flexible container 84,184 Nozzle 90 Suction device 101 Contaminated water tank 102 RO device 103 Concentrated water tank C Drum rotation center L1 Concentrated water supply line L101 Connection line S Solid material

Claims (9)

A separation means provided with a heating means, which separates the undiluted solution into a solid salt solution, a vapor, and a liquid by heating the radioactive undiluted solution containing salt by the heating means.
A scrubber that removes radioactive components contained in the vapor by introducing the vapor separated by the separation means and bringing the circulating liquid into contact with the vapor.
A radioactive stock solution processing apparatus having a first return means for returning the liquid separated by the separation means and the liquid overflowing from the scrubber to the previous stage of the separation means. A steam separator that separates the steam contained in the exhaust gas discharged from the scrubber,
The processing apparatus according to claim 1, further comprising a second return means for returning the condensed water generated by the steam separator to the previous stage of the separation means. The processing apparatus according to claim 2, further comprising a filter containing fibrous activated carbon for filtering the gas discharged from the steam separator. A contaminated water tank for storing radioactively contaminated water containing salt, a back-penetrating membrane device connected to the contaminated water tank and filtering the radioactively contaminated water stored in the contaminated water tank, and a back-penetrating membrane device connected to the contaminated water tank. The contaminated water storage treatment system is connected to a contaminated water storage treatment system having a concentrated water tank for storing the concentrated water generated by the back-penetrating membrane device and a connection line for connecting the concentrated water tank to the contaminated water tank. The processing apparatus according to 2 or 3.
The second return means has a concentrated water supply line that supplies the concentrated water stored in the concentrated water tank as the undiluted solution to the separating means, and the second returning means transfers the liquid condensed by the steam separator to the reverse osmosis membrane device. A processing device that returns to the entrance side. The separating means is a rotary drum provided with the heating means, and the rotary drum for precipitating the salt content on the surface by heating the undiluted solution adhering to the surface by the heating means, and the surface of the rotary drum. The processing apparatus according to any one of claims 1 to 4, further comprising a scraper for scraping the precipitated solid matter. The rotary drums are a pair of rotary drums that come into contact with each other in the radial direction along a contact line extending in the axial direction, and the pair of rotary drums rotate in opposite directions in a direction having an upward velocity component in the contact line. The processing apparatus according to claim 5, wherein the stock solution is supplied to a recess formed by the pair of rotating drums, and the scraper is located on the opposite side of the contact line with respect to the rotation center of each rotating drum. .. The processing device according to any one of claims 1 to 6, which is provided in front of the separation means and has a sodium carbonate supply device for adding sodium carbonate to the undiluted solution. The processing apparatus according to any one of claims 1 to 7, which is detachably provided on the nozzle of the flexible container for storing the solid material and has a suction device for evacuating the inside of the flexible container. .. The processing apparatus according to claim 8, further comprising a filter containing fibrous activated carbon for filtering the gas discharged from the suction device.

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