JP2015184198A - Storage unit of polluted water - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a storage unit of polluted water capable of simplifying the unit and reducing the cost.SOLUTION: The storage unit includes: a tank 11 having a hollow shape, which is capable of reserving polluted water containing radioactive substance therein; a suction/discharge unit 12 that sucks gas to discharge the gas from the tank 11 to the outside; a removal unit 13 that removes the radioactive substance from the gas discharged from the tank 11; and an air supply device 14 capable of supplying the air from the outside to the inside of the tank 11 when the differential pressure between the inner pressure of the tank 11 and the external pressure reaches a preset predetermined differential pressure.

Description

  The present invention relates to a contaminated water storage device for storing contaminated water containing radioactive substances.

  For example, when an accident occurs in a nuclear power plant, contaminated water containing radioactive substances is generated. The generated contaminated water is temporarily stored in a storage tank, and radioactive substances are sequentially removed from the contaminated water using a treatment device. The removed radioactive substances are stored in a storage container, while the radioactive substances are removed. Water is released into rivers.

  The contaminated water contains tritium, cesium, and the like as radioactive substances, and the inside of the storage tank is generally maintained at a negative pressure in order to prevent leakage of radioactive substances from the storage tank. Further, since hydrogen is generated from the contaminated water stored in the storage tank, it is necessary to periodically scavenge this hydrogen. Therefore, conventionally, the inside of the storage tank is maintained in a negative pressure state, and a predetermined amount of air is supplied to the inside, while air containing the same amount of hydrogen is discharged from the inside. In addition, as a storage apparatus of contaminated water, there exists a thing described in the following patent document 1, for example.

JP-A-63-032398

  In the conventional contaminated water storage device, a predetermined amount of air is supplied into the storage tank, while the air containing the same amount of hydrogen is discharged from the inside to maintain the negative pressure inside the storage tank. To ensure safety. However, the conventional contaminated water storage device requires an air supply device for supplying air into the storage tank and an air discharge device for discharging the air in the storage tank. There is a problem that increases.

  The present invention solves the above-described problems, and an object of the present invention is to provide a contaminated water storage device that enables simplification and cost reduction of the device.

  In order to achieve the above object, the contaminated water storage device of the present invention comprises a tank having a hollow shape and capable of storing contaminated water containing radioactive substances therein, and sucking the gas in the tank to the outside. A suction / exhaust device for discharging, a removing device for removing radioactive substances from the gas discharged from the tank, and an air outside the tank when the differential pressure between the internal pressure and the external pressure of the tank reaches a predetermined differential pressure. And an air supply device capable of supplying the air inside.

  Therefore, the tank can store contaminated water containing radioactive substances, the suction exhaust device sucks the gas in the tank and discharges it to the outside, and the removal device removes the radioactive substances from the gas discharged from the tank. The air supply device supplies air outside the tank to the inside when the differential pressure between the internal pressure and the external pressure of the tank reaches a predetermined differential pressure. Therefore, the hydrogen generated inside the tank is discharged by the suction / exhaust device, so that the hydrogen concentration in the tank does not increase, and when the differential pressure between the internal pressure and the external pressure of the tank becomes a predetermined differential pressure. By supplying air into the tank, the negative pressure in the tank is maintained. And since an air supply apparatus does not have a drive device, it can simplify and reduce cost of an apparatus.

  In the contaminated water storage device according to the present invention, the air supply device includes an air supply passage that communicates a gas phase portion outside and inside the tank, and an inleak valve provided in the air supply passage. It is said.

  Therefore, by providing an inleak valve in the air supply passage as an air supply device, the device can be simplified and reduced in cost.

  In the contaminated water storage device of the present invention, the suction exhaust device includes a gas discharge passage that communicates a gas phase portion outside and inside the tank, a pump provided in the gas discharge passage, and hydrogen in the tank. It has a hydrogen concentration sensor for detecting the concentration, and a control device for driving and controlling the pump based on the detection result of the hydrogen concentration sensor.

  Therefore, when the hydrogen concentration sensor detects the hydrogen concentration in the tank, the control device drives and controls the pump based on the detection result of the hydrogen concentration sensor. That is, when the hydrogen concentration in the tank increases, the pump is driven to discharge the gas in the tank to the outside from the gas discharge passage, so that the hydrogen concentration does not increase in the tank and safety can be improved. it can.

  In the contaminated water storage device of the present invention, the contaminated water contains sludge, and a gas injection device capable of ejecting gas toward the bottom in the tank, and the contaminated water stored in the tank. It is characterized in that a cooling device is provided for cooling.

  Therefore, when the contaminated water contains sludge, the gas injection device jets gas toward the bottom inside the tank to stir the sludge, and the cooling device cools the contaminated water. It can prevent and improve safety.

  In the contaminated water storage device of the present invention, the tank is disposed in a space closed by a partition wall, and the suction / exhaust device sucks the gas in the tank and removes radioactive substances by the removal device. The air supply device supplies the air in the space into the tank when the differential pressure between the internal pressure of the tank and the pressure in the space reaches a predetermined differential pressure. Yes.

  Therefore, the tank is disposed in the space, and the suction exhaust device sucks the gas in the tank and removes the radioactive material, and then discharges it outside the space. On the other hand, the air supply device When the differential pressure reaches a predetermined differential pressure, the air in the space is supplied into the tank, so that leakage of radioactive material to the outside can be prevented and safety can be improved.

  In the contaminated water storage device according to the present invention, the air supply device includes an air supply passage that communicates a gas phase portion outside and inside the tank, and a resistance portion provided in the air supply passage. It is said.

  Accordingly, since the resistance portion is provided in the air supply passage, when the differential pressure between the internal pressure and the external pressure of the tank reaches a predetermined differential pressure, air outside the tank is supplied to the inside of the tank against the resistance portion. As a result, the configuration can be simplified.

  In the contaminated water storage device of the present invention, the air supply device has an air supply passage that communicates the liquid phase portion inside and outside the tank.

  Accordingly, since the air supply passage constituting the air supply device communicates between the outside and inside of the tank and the liquid phase portion inside the tank, the contaminated water in the tank becomes a resistance portion, and the differential pressure between the internal pressure and the external pressure of the tank is a predetermined differential pressure. Then, the air outside the tank is supplied to the inside of the tank through the liquid phase portion, and the configuration can be simplified.

  According to the contaminated water storage device of the present invention, the suction / exhaust device that sucks the gas in the tank and discharges it to the outside, and when the differential pressure between the internal pressure and the external pressure of the tank reaches a predetermined differential pressure, Since an air supply device that can supply external air to the inside is provided, hydrogen generated inside the tank is not discharged, so that the hydrogen concentration does not increase, and air is supplied into the tank. Thus, the negative pressure in the tank is maintained, and the air supply device does not have a driving device, so that the device can be simplified and reduced in cost.

FIG. 1 is a schematic diagram illustrating a contaminated water storage device according to the first embodiment. FIG. 2 is a schematic diagram illustrating a contaminated water storage device according to the second embodiment. FIG. 3 is a schematic diagram illustrating a contaminated water storage device according to the third embodiment. FIG. 4 is a schematic diagram illustrating the operation of the contaminated water storage device. FIG. 5 is a schematic diagram illustrating a contaminated water storage device according to the fourth embodiment. FIG. 6 is a schematic view showing the operation of the contaminated water storage device. FIG. 7 is a schematic diagram illustrating a contaminated water storage device according to the fifth embodiment.

  Exemplary embodiments of a contaminated water storage device according to the present invention will be described below in detail with reference to the accompanying drawings. In addition, this invention is not limited by this embodiment, and when there are two or more embodiments, what comprises combining each embodiment is also included.

[First Embodiment]
FIG. 1 is a schematic diagram illustrating a contaminated water storage device according to the first embodiment.

  As shown in FIG. 1, the contaminated water storage device according to the first embodiment includes a tank 11, a suction exhaust device 12, a removal device 13, and an air supply device 14.

  The tank 11 has a hollow shape, has a predetermined size, and can store contaminated water containing a radioactive substance therein. When the contaminated water is stored in the tank 11, the contaminated water is stored. The liquid phase portion 11a and the upper gas phase portion 11b are formed. The suction exhaust device 12 sucks air (gas) in the tank 11 and discharges it to the outside. The suction / exhaust device 12 includes a gas discharge passage 21 that communicates the gas phase portion 11 b inside and outside the tank 11, and a pump 22 provided in the gas discharge passage 21. The removal device 13 is provided on the tank 11 side of the pump 22 in the gas discharge passage 21, and is a filter 23 that removes radioactive substances from the air discharged from the tank 11.

  The air supply device 14 can supply air outside the tank 11 to the inside when the differential pressure between the internal pressure and the external pressure of the tank 11 reaches a predetermined differential pressure. The air supply device 14 includes an air supply passage 24 that communicates the gas phase portion 11 b inside and outside the tank 11, and an inleak valve 25 provided in the air supply passage 24. Here, since the tank 11 stores the contaminated water containing the radioactive substance inside, the inside of the tank 11 needs to be maintained in a negative pressure state in order to prevent leakage of the radioactive substance to the outside. The specified pressure (negative pressure) is set. The predetermined differential pressure is set according to a specified pressure (negative pressure) in the tank 11. Therefore, the inleak valve 25 is normally closed, and opens when the differential pressure between the internal pressure (negative pressure) and the external pressure (atmospheric pressure) of the tank 11 exceeds a predetermined differential pressure, and external air is supplied to the air supply passage 24. And, it is supplied to the inside of the tank 11 through the inleak valve 25.

  The suction / exhaust device 12 includes a hydrogen concentration sensor 26 that detects the hydrogen concentration in the tank 11, and a control device 27 that drives and controls the pump 22 based on the detection result of the hydrogen concentration sensor 26. The hydrogen concentration sensor 26 is provided in the gas discharge passage 21 and detects the concentration of hydrogen in the air in the tank 11. The control device 27 drives and controls the pump 22 according to the hydrogen concentration in the air in the tank 11 detected by the hydrogen concentration sensor 26. Specifically, the control device 27 drives the pump 22 when the hydrogen concentration in the tank 11 is higher than a predetermined determination value. Here, the judgment value is a hydrogen concentration that does not explode when ignited by hydrogen in the tank 11. Further, the control device 27 increases the rotation speed of the pump 22, that is, increases the suction force as the hydrogen concentration in the tank 11 increases.

  Therefore, the tank 11 stores contaminated water containing a radioactive substance, and the suction / exhaust device 12 sucks air in the tank 11 through the gas discharge passage 21 and discharges it to the outside when the pump 22 is driven. At this time, the filter 23 of the removing device 13 removes the radioactive substance from the air flowing through the gas discharge passage 21. And since the suction exhaust apparatus 12 attracts | sucks the air in the tank 11, and discharges outside, the pressure in the tank 11 turns into a negative pressure. In the air supply device 14, when the differential pressure between the internal pressure and the external pressure in the tank 11 reaches a predetermined differential pressure, the inleak valve 25 is opened, and external air is supplied into the tank 11 through the air supply passage 24.

  As a result, since the gas inside the tank 11 is discharged to the outside by the suction / exhaust device 12, the hydrogen concentration in the tank 11 does not increase, and the safety of the tank 11 is ensured. Moreover, since the inside of the tank 11 is maintained in a negative pressure state by the air supply device 14, leakage of radioactive material to the outside is prevented, and the safety of the tank 11 is also secured in this respect.

  As described above, in the contaminated water storage device according to the first embodiment, the tank 11 that has a hollow shape and can store the contaminated water containing the radioactive substance therein, and the gas in the tank 11 is sucked to the outside. When the pressure difference between the internal pressure and the external pressure of the tank 11 reaches a predetermined differential pressure set in advance, the suction exhaust apparatus 12 that discharges to the tank, the removal apparatus 13 that removes radioactive substances from the gas discharged from the tank 11, and the tank 11 An air supply device 14 capable of supplying external air to the inside is provided.

  Therefore, the tank 11 can store contaminated water containing radioactive substances, the suction exhaust device 12 sucks the gas in the tank 11 and discharges it outside, and the removal device 13 from the gas discharged from the tank 11. The radioactive substance is removed, and the air supply device 14 supplies air outside the tank 11 to the inside when the differential pressure between the internal pressure and the external pressure of the tank 11 reaches a predetermined differential pressure. Therefore, the hydrogen generated in the tank 11 is discharged by the suction / exhaust device 12, so that the hydrogen concentration in the tank 11 does not increase, and the pressure difference between the internal pressure and the external pressure in the tank 11 is predetermined. When the differential pressure is reached, air is supplied into the tank 11 so that the negative pressure in the tank 11 is maintained. Since the air supply device 14 does not have a drive device, the device can be simplified and reduced in cost.

  In the contaminated water storage device of the first embodiment, as the air supply device 14, an air supply passage 24 that communicates the gas phase portion 11 b inside and outside the tank 11, and an inleak valve 25 provided in the air supply passage 24. Provided. Therefore, by providing the inleak valve 25 in the air supply passage 24 as the air supply device 14, the device can be simplified and the cost can be reduced.

  In the contaminated water storage device of the first embodiment, the suction exhaust device 12 includes a gas discharge passage 21 that communicates the gas phase portion 11b inside and outside the tank 11, a pump 22 provided in the gas discharge passage 21, A hydrogen concentration sensor 26 that detects the hydrogen concentration in the tank 11 and a control device 27 that drives and controls the pump 22 based on the detection result of the hydrogen concentration sensor 26 are provided. Therefore, when the hydrogen concentration sensor 26 detects the hydrogen concentration in the tank 11, the control device 27 drives and controls the pump 22 based on the detection result of the hydrogen concentration sensor 26. That is, when the hydrogen concentration in the tank 11 increases, the pump 22 is driven to discharge the gas in the tank 11 to the outside from the gas discharge passage 21, so that the hydrogen concentration does not increase in the tank 11 and safety is ensured. Can be improved.

[Second Embodiment]
FIG. 2 is a schematic diagram illustrating a contaminated water storage device according to the second embodiment.

  As shown in FIG. 2, the contaminated water storage device according to the second embodiment includes a tank 31, a suction exhaust device 32, a removal device 33, and an air supply device 34.

  The tank 31 has a hollow shape, has a predetermined size, and can store contaminated water containing radioactive substances therein. When the contaminated water is stored in the tank 31, the contaminated water is stored. The liquid phase portion 31a and the upper gas phase portion 31b are formed. Moreover, this contaminated water contains the sludge S and tends to settle at the bottom. The tank 31 is disposed in a space R of the storage chamber 51 whose outer periphery is closed by a partition wall.

  The suction / exhaust device 32 sucks air (gas) in the tank 31 and discharges it to the outside of the storage chamber 51. The suction / exhaust device 32 includes a gas discharge passage 41 that communicates the outside of the storage chamber 51 and the gas phase portion 31 b inside the tank 31, and a pump 42 provided in the gas discharge passage 41. The removal device 33 is a filter 43 that is provided closer to the tank 31 than the pump 42 in the gas discharge passage 41 and removes radioactive substances from the air discharged from the tank 31.

  The air supply device 34 can supply air outside the tank 31 to the inside when the differential pressure between the internal pressure and external pressure of the tank 31 (pressure in the space R of the storage chamber 51) reaches a predetermined differential pressure. is there. The air supply device 34 includes an air supply passage 44 that communicates the gas phase portion 31 b inside and outside the tank 31, and an inleak valve 45 provided in the air supply passage 44. The in-leak valve 45 is normally closed and opens when the differential pressure between the internal pressure (negative pressure) of the tank 31 and the pressure in the space R of the storage chamber 51 (atmospheric pressure) exceeds a predetermined differential pressure. The air in the space R is supplied to the inside of the tank 31 through the air supply passage 44 and the inleak valve 45.

  Further, the tank 31 of the present embodiment temporarily stores sludge S such as generated powder together with water and discharges and processes it as necessary. In the tank 31 for storing such sludge S, if the contaminated water is stored for a long period of time, the sludge S settles and adheres to the water, so it is necessary to stir the inside of the tank to ensure fluidity. There is.

  The tank 31 is provided with a gas injection device 52 capable of injecting gas toward the bottom in the interior, and a cooling device 53 for cooling contaminated water stored therein. The gas injection device 52 includes an air compressor 61, a compressed air supply passage 62, and a number of injection nozzles 63. The air compressor 61 is disposed outside the storage chamber 51. The compressed air supply passage 62 has a base end connected to the air compressor 61, a tip extending through the storage chamber 51 and extending into the tank 31, and a number of injection nozzles 63 at the horizontal portion along the bottom. It is provided downward.

  The cooling device 53 includes a pump 64, a cooling water circulation passage 65, a refrigerator 66, and a cooling tower 67. The pump 64 is disposed outside the storage chamber 51. The cooling water circulation passage 65 is connected to the water supply port of the pump 64 at the base end, extends into the tank 31 through the storage chamber 51, and is disposed along the bottom, and then the tip is outside the tank 31. It is pulled out and passes through the storage chamber 51 and is connected to the water intake port of the pump 64. The refrigerator 66 is arranged outside the storage chamber 51 and performs heat exchange between the water supply side and the water intake side in the cooling water circulation passage 65. The cooling tower 67 is disposed outside the storage chamber 51 and cools the cooling water flowing through the cooling water circulation passage 65.

  The storage chamber 51 is provided with a drip tray 54 below the tank 31, and can receive leaked water from the tank 31. The storage chamber 51 is provided with an intake passage 55 and an exhaust passage 56, and the exhaust passage 56 is provided with a pump 57 and a filter 58. Furthermore, although not shown, the tank 31 is provided with a contaminated water supply passage for supplying contaminated water containing sludge to the inside and a contaminated water discharge passage for discharging contaminated water containing sludge to the outside.

  Therefore, the tank 31 stores the contaminated water containing the radioactive substance and the sludge S, and the suction / exhaust device 32 sucks the air in the tank 31 through the gas discharge passage 41 when the pump 42 is driven. At this time, the filter 43 of the removing device 33 removes radioactive substances from the air flowing through the gas discharge passage 41. Then, since the suction / exhaust device 32 sucks the air in the tank 31 and discharges it to the outside of the storage chamber 51, the pressure in the tank 31 becomes a negative pressure. When the differential pressure between the internal pressure of the tank 31 and the pressure in the space R of the storage chamber 51 reaches a predetermined differential pressure, the air supply device 34 opens the inleak valve 45 and the air in the space R passes through the air supply passage 44 and the tank 31. Supplied inside.

  As a result, since the gas inside the tank 31 is discharged to the outside by the suction / exhaust device 32, the hydrogen concentration in the tank 31 does not increase, and the safety of the tank 31 is ensured. Moreover, since the tank 31 is maintained in a negative pressure state by the air supply device 34, leakage of radioactive material to the outside is prevented, and the safety of the tank 31 is also secured in this respect.

  As described above, in the contaminated water storage device according to the second embodiment, the contaminated water includes the sludge S, and the gas injection device 52 capable of ejecting gas toward the bottom in the tank 31 and the tank A cooling device 53 for cooling the contaminated water stored in the interior of 31 is provided.

  Therefore, when the contaminated water contains the sludge S, the gas injection device 52 agitates the sludge S by jetting gas toward the bottom in the tank 31, and cools the contaminated water by the cooling device 53. The sludge S can be prevented from sticking and the safety can be improved.

  In the contaminated water storage device of the second embodiment, the tank 31 is disposed in the space R of the storage chamber 51 closed by the partition wall, and the suction exhaust device 32 sucks the gas in the tank 31 and removes it. The air supply device 34 discharges the air in the space R to the inside of the tank 31 when the differential pressure between the internal pressure of the tank 31 and the pressure in the space R becomes a predetermined differential pressure. To supply. Accordingly, the tank 31 is disposed in the space R, and the suction / exhaust device 32 sucks the gas in the tank 31 to remove the radioactive substance and then discharges it outside the space R. On the other hand, the air supply device 34 When the differential pressure between the internal pressure and the pressure in the space R becomes a predetermined differential pressure, the air in the space R is supplied into the tank 31 to prevent leakage of radioactive material to the outside and improve safety.

[Third Embodiment]
FIG. 3 is a schematic diagram illustrating a contaminated water storage device according to the third embodiment, and FIG. 4 is a schematic diagram illustrating an operation of the contaminated water storage device. In addition, the same code | symbol is attached | subjected to the member which has the same function as embodiment mentioned above, and detailed description is abbreviate | omitted.

  As shown in FIG. 3, the contaminated water storage device of the third embodiment includes a tank 11, a suction exhaust device 12, a removal device 13, and an air supply device 71. Here, since the tank 11, the suction / exhaust device 12, and the removal device 13 are the same as those described in the first embodiment, the description thereof is omitted.

  The air supply device 71 can supply air outside the tank 11 to the inside when the differential pressure between the internal pressure and the external pressure of the tank 11 reaches a predetermined differential pressure. The air supply device 71 is provided in an air pot 72, an air supply passage 73 having a base end connected to the air pot 72 and a tip communicating with the gas phase portion 11 b inside the tank 11, and the air supply passage 73. And a U-shaped portion 74. The air pot 72 has a predetermined amount of space and opens to the outside. The U-shaped portion 74 is provided in the middle of the air supply passage 73, and is filled with an appropriate amount of liquid (such as oil or water) in order to function as a resistance portion. The U-shaped portion 74 is normally closed, and opens when the differential pressure between the internal pressure (negative pressure) and the external pressure (atmospheric pressure) of the tank 11 exceeds a predetermined differential pressure, and the air in the air pot 72 is supplied to the air supply passage. The liquid in 73 and the U-shaped portion 74 passes as bubbles and is supplied to the inside of the tank 11.

  Therefore, as shown in FIG. 4, the tank 11 stores contaminated water containing a radioactive substance, and the suction exhaust device 12 is driven by the pump 22 so that the air in the tank 11 is discharged by the gas discharge passage 21. The filter 23 of the removing device 13 removes radioactive substances from the air flowing through the gas discharge passage 21 at this time. And since the suction exhaust apparatus 12 attracts | sucks the air in the tank 11, and discharges outside, the pressure in the tank 11 turns into a negative pressure. When the differential pressure between the internal pressure and the external pressure in the tank 11 reaches a predetermined differential pressure, the air supply device 71 causes the air in the air pot 72 to pass through the liquid in the air supply passage 73 and the U-shaped portion 74 as bubbles and the inside of the tank 11. To be supplied.

  As a result, since the gas inside the tank 11 is discharged to the outside by the suction / exhaust device 12, the hydrogen concentration in the tank 11 does not increase, and the safety of the tank 11 is ensured. In addition, since the tank 11 is maintained in a negative pressure state by the air supply device 71, leakage of radioactive material to the outside is prevented, and the safety of the tank 11 is also secured in this respect.

  As described above, in the contaminated water storage device of the third embodiment, the air supply device 71 includes an air supply passage 73 that communicates the gas phase portion 11b between the outside and the inside of the tank 11, and the air supply passage 73. A U-shaped portion 74 is provided as a provided resistance portion, and this U-shaped portion 74 is filled with an appropriate amount of liquid.

  Therefore, since the U-shaped portion 74 filled with the liquid is provided in the air supply passage 73, when the differential pressure between the internal pressure and the external pressure of the tank 11 reaches a predetermined differential pressure, the air outside the tank 11 flows into the air supply passage. The liquid in 73 and the U-shaped portion 74 passes as bubbles and is supplied to the inside of the tank 11, so that the configuration can be simplified.

[Fourth Embodiment]
FIG. 5 is a schematic diagram showing the contaminated water storage device of the fourth embodiment, and FIG. 6 is a schematic diagram showing the operation of the contaminated water storage device. In addition, the same code | symbol is attached | subjected to the member which has the same function as embodiment mentioned above, and detailed description is abbreviate | omitted.

  As shown in FIG. 5, the contaminated water storage device according to the fourth embodiment includes a tank 11, a suction exhaust device 12, a removal device 13, and an air supply device 81. Here, since the tank 11, the suction / exhaust device 12, and the removal device 13 are the same as those described in the first embodiment, the description thereof is omitted.

  The air supply device 81 is capable of supplying air outside the tank 11 to the inside when the differential pressure between the internal pressure and the external pressure of the tank 11 reaches a predetermined differential pressure. This air supply device 81 is provided at an air supply passage 82 where the base end portion opens to the outside and the tip end portion communicates with the liquid phase portion 11 a at the bottom of the tank 11, and at the connection portion between the tank 11 in the air supply passage 82. A restricting portion (for example, an orifice) 83 is provided as a resistance portion. The throttle 83 is immersed in the contaminated water.

  Therefore, as shown in FIG. 6, the tank 11 stores contaminated water containing a radioactive substance, and the suction exhaust device 12 is driven by the pump 22 so that the air in the tank 11 is discharged by the gas discharge passage 21. The filter 23 of the removing device 13 removes radioactive substances from the air flowing through the gas discharge passage 21 at this time. And since the suction exhaust apparatus 12 attracts | sucks the air in the tank 11, and discharges outside, the pressure in the tank 11 turns into a negative pressure. When the differential pressure between the internal pressure and the external pressure of the tank 11 reaches a predetermined differential pressure, the air supply device 81 stably passes the external air through the air supply passage 82 and flows out of the throttle portion 83 at a high flow rate. 11 is supplied with air.

  As a result, since the gas inside the tank 11 is discharged to the outside by the suction / exhaust device 12, the hydrogen concentration in the tank 11 does not increase, and the safety of the tank 11 is ensured. Moreover, since the inside of the tank 11 is maintained in a negative pressure state by the air supply device 81, leakage of radioactive material to the outside is prevented, and the safety of the tank 11 is also secured in this respect.

  Thus, in the contaminated water storage device of the fourth embodiment, as the air supply device 81, the air supply passage 82 that communicates the liquid phase portion 11 a between the outside and the inside of the tank 11, and the air supply passage 82. An aperture portion 83 is provided as a provided resistance portion.

  Accordingly, since the air supply passage 82 is provided with the throttle portion 83 filled with water, when the differential pressure between the internal pressure and the external pressure of the tank 11 reaches a predetermined differential pressure, the air outside the tank 11 is supplied to the air supply passage 82. , And flows out of the throttle 83 at a high flow rate, so that it is stably supplied to the inside of the tank 11, and the configuration can be simplified.

[Fifth Embodiment]
FIG. 7 is a schematic diagram illustrating a contaminated water storage device according to the fifth embodiment. In addition, the same code | symbol is attached | subjected to the member which has the same function as embodiment mentioned above, and detailed description is abbreviate | omitted.

  As shown in FIG. 7, the contaminated water storage device of the fifth embodiment includes a tank 11, a suction exhaust device 12, a removal device 13, and an air supply device 91. Here, since the tank 11, the suction / exhaust device 12, and the removal device 13 are the same as those described in the first embodiment, the description thereof is omitted.

  The air supply device 91 is capable of supplying air outside the tank 11 to the inside when the differential pressure between the internal pressure and the external pressure of the tank 11 reaches a predetermined differential pressure. This air supply device 91 includes an air pot 92 and an air supply passage having a base end connected to the air pot 92 and a tip communicating from the upper part of the tank 11 to the liquid phase part 11a through the gas phase part 11b inside. 93. The air pot 92 has a predetermined amount of space and opens to the outside.

  Therefore, the tank 11 stores contaminated water containing a radioactive substance, and the suction / exhaust device 12 sucks air in the tank 11 through the gas discharge passage 21 and discharges it to the outside when the pump 22 is driven. At this time, the filter 23 of the removing device 13 removes the radioactive substance from the air flowing through the gas discharge passage 21. And since the suction exhaust apparatus 12 attracts | sucks the air in the tank 11, and discharges outside, the pressure in the tank 11 turns into a negative pressure. When the differential pressure between the internal pressure and the external pressure of the tank 11 reaches a predetermined differential pressure, the air supply device 91 supplies air in the air pot 92 as bubbles to the liquid phase portion 11 a of the tank 11 through the air supply passage 93.

  As a result, since the gas inside the tank 11 is discharged to the outside by the suction / exhaust device 12, the hydrogen concentration in the tank 11 does not increase, and the safety of the tank 11 is ensured. Further, since the tank 11 is maintained in a negative pressure state by the air supply device 91, leakage of radioactive material to the outside is prevented, and the safety of the tank 11 is also secured in this respect.

  Thus, in the contaminated water storage device of the fifth embodiment, as the air supply device 91, an air supply passage 93 that communicates the air pot 92 and the liquid phase portion 11a inside the tank 11 is provided.

  Therefore, since the tip of the air supply passage 93 communicates with the liquid phase portion 11a of the tank 11, when the differential pressure between the internal pressure and the external pressure of the tank 11 reaches a predetermined differential pressure, the air outside the tank 11 is transferred to the air supply passage 93. Is supplied to the inside of the tank 11 as bubbles, and the configuration can be simplified.

  In the above-described embodiments, the shapes of the tank, the suction / exhaust device, the removal device, and the air supply device are not limited to each embodiment, and may be set as appropriate.

DESCRIPTION OF SYMBOLS 11,31 Tank 11a Liquid phase part 11b Gas phase part 12,32 Suction exhaust apparatus 13,33 Removal apparatus 14,34,71,81,91 Air supply apparatus 21,41 Gas discharge passage 22,42 Pump 23,43 Filter 24 , 73, 82, 93 Air supply passage 25 Inleak valve 26 Hydrogen concentration sensor 27 Control device 51 Storage chamber 52 Gas injection device 53 Cooling device 74 U-shaped portion (resistance portion)
83 Diaphragm (resistor)

Claims (7)

A tank that can store contaminated water that has a hollow shape and contains radioactive substances inside,
A suction exhaust device for sucking and discharging the gas in the tank to the outside;
A removal device for removing radioactive substances from the gas discharged from the tank;
An air supply device capable of supplying air outside the tank to the inside when the differential pressure between the internal pressure and the external pressure of the tank reaches a predetermined differential pressure set in advance;
A contaminated water storage device characterized by comprising:   2. The contaminated water according to claim 1, wherein the air supply device includes an air supply passage that communicates a gas phase portion inside and outside the tank, and an inleak valve provided in the air supply passage. Storage device.   The suction / exhaust device includes a gas discharge passage that communicates a gas phase portion outside and inside the tank, a pump provided in the gas discharge passage, a hydrogen concentration sensor that detects a hydrogen concentration in the tank, The contaminated water storage device according to claim 1, further comprising a control device that drives and controls the pump based on a detection result of a hydrogen concentration sensor.   The contaminated water contains sludge, and a gas injection device capable of ejecting gas toward the bottom in the tank and a cooling device for cooling the contaminated water stored in the tank are provided. The storage device for contaminated water according to any one of claims 1 to 3, wherein the storage device is contaminated.   The tank is disposed in a space closed by a partition wall, and the suction exhaust device sucks the gas in the tank and removes radioactive substances by the removal device, and then discharges it outside the space. 5. The air supply device according to claim 1, wherein the air supply device supplies air in the space into the tank when a differential pressure between the internal pressure of the tank and the pressure in the space reaches a predetermined differential pressure. The contaminated water storage device according to claim 1.   2. The contaminated water according to claim 1, wherein the air supply device includes an air supply passage that communicates a gas phase portion inside and outside the tank, and a resistance portion provided in the air supply passage. Storage device.   2. The contaminated water storage device according to claim 1, wherein the air supply device has an air supply passage that communicates a liquid phase portion inside and outside the tank.

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