JP2012230078A - Decontamination device, decontamination method, nuclear power plant, and reconstruction method therefor - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a decontamination device capable of suppressing release of exhaust flowing out from a nuclear reactor pressure vessel to atmosphere without substantially recovering radioactive materials, and to provide a decontamination method, a nuclear power plant and a reconstruction method therefor.SOLUTION: The decontamination device includes: a scrubbing container 32 that is an exhaust stack for discharging exhaust from a reactor container 10 and stores scrubbing liquid 31; and an exhaust tube 33 that is a bent tube for releasing gas inside the reactor container 10 and supplies the scrubbing liquid 31 inside the scrubbing container 32 with the exhaust from the reactor container 10.

Description

  The present invention relates to an apparatus for decontaminating exhaust from a reactor building, a decontamination method, a nuclear power plant using the decontamination method, and a method for remodeling the nuclear power plant.

  In nuclear power plants, if the heat removal function of the reactor containment vessel is lost due to some reason, the temperature inside the reactor containment vessel rises because the heat cannot be removed from the reactor containment vessel, and the pressure inside the reactor containment vessel increases. It is possible that the reactor containment vessel will be damaged at a high level. In the unlikely event that the reactor core is damaged and the reactor pressure vessel is damaged, the reactor will be stored in order to cool the melt of the reactor core discharged outside the reactor pressure vessel. Water injection into the container is required, and steam is generated during this water injection operation. In addition, non-condensable gas such as hydrogen is generated by water-metal reaction. Such steam and non-condensable gas may increase the pressure inside the reactor containment vessel and cause damage to the reactor containment vessel.

  In nuclear power plants, measures are taken to prevent such damage to the containment vessel. Specifically, the steam and non-condensable gas in the reactor containment vessel are released to the outside by a vent facility. At the time of venting, vapor and non-condensable gas in the containment vessel containing radioactive substances are passed through the suppression pool to reduce the radiation dose, and then discharged from the containment vessel and then released from the exhaust stack. (Refer to patent document 1 etc.).

Japanese Patent Laid-Open No. 9-329691

  The release of steam and non-condensable gas from the reactor containment vent was first performed with the expectation of scrubbing and removal of radioactive materials by suppression pool water, and water injection into the wet well vent line reactor containment vessel. After being submerged, perform dry well venting. At the time of dry well venting, it is not expected to remove scrubbing of radioactive material by suppression pool water.

  The present invention has been made in view of the above circumstances, and a decontamination apparatus, a decontamination method, a nuclear power plant, and a modification thereof, which can suppress exhausted exhaust gas from being released into the atmosphere without sufficiently collecting radioactive substances. It aims to provide a method.

  In order to achieve the above object, according to the present invention, the exhaust gas from the reactor containment vessel is passed through the scrubbing liquid in the scrubbing vessel. Furthermore, by making the emergency gas processing system that has been installed conventionally with pressure resistance specifications, the emergency gas processing system can be used even during venting.

  ADVANTAGE OF THE INVENTION According to this invention, it can suppress that the exhaust_gas | exhaustion which flowed out from the reactor pressure vessel was discharge | released to air | atmosphere, without fully recovering a radioactive substance.

It is the schematic showing the principal part of the nuclear power plant to which the decontamination apparatus concerning the 1st Embodiment of this invention is applied. It is the schematic showing the principal part of the nuclear power plant to which the decontamination apparatus concerning the 2nd Embodiment of this invention is applied. It is the schematic showing the principal part of the nuclear power plant to which the decontamination apparatus concerning the 3rd Embodiment of this invention is applied.

  Embodiments of the present invention will be described below with reference to the drawings.

(First embodiment)
FIG. 1 is a schematic diagram showing a main part of a nuclear power plant to which a decontamination apparatus according to a first embodiment of the present invention is applied.

  The nuclear power plant shown in FIG. 1 includes a reactor containment vessel 10 that houses a reactor pressure vessel 11 and a decontamination device 30 that purifies a gas containing radioactive material that has flowed out of the reactor pressure vessel 11. .

  The reactor pressure vessel 11 contains a reactor (not shown), supplies a cooling water supply system (not shown) for supplying cooling water for cooling the reactor, and supplies generated steam to a turbine (not shown). A main steam pipe (not shown) or the like is connected, but normally a closed system is formed with airtightness.

  The reactor containment vessel 10 surrounds the reactor pressure vessel 11 with airtightness, and includes a dry well 12 that houses the reactor pressure vessel 11 and a wet well 13 that stores a pressure suppression pool 14. Yes. The dry well 12 and the wet well 13 are connected by a plurality of connection pipes 15. The wet well 13 forms the pressure suppression pool 14 on the lower side of the internal space, while the upper side, that is, the space above the liquid surface of the pressure suppression pool 14 is a gas phase portion. The connection pipe line 15 extending from the dry well 12 extends to the inside of the wet well 13, and its tip is immersed in the pressure suppression pool 14. The periphery of the reactor containment vessel 10 is surrounded by the reactor building 16 with airtightness.

  The decontamination apparatus 30 includes a scrubbing container 32 for storing the scrubbing liquid 31, a pressure-resistant exhaust pipe 33 for supplying exhaust gas from the reactor containment vessel 10 to the scrubbing liquid 31 in the scrubbing container 32, and an exhaust pipe 33. Pressure-resistant gas processing device 34 for removing radioactive substances in the exhaust gas flowing through the water, a water supply system 35 for supplying the scrubbing liquid 31 to the scrubbing vessel 32, and a pH adjuster supply system 36 for supplying the pH adjusting agent to the scrubbing liquid 31 , An inert gas supply system 37 for supplying an inert gas to the scrubbing liquid 31, and a drain tank 38 for storing the used scrubbing liquid 31 discharged from the scrubbing container 32.

  In the present embodiment, the scrubbing vessel 32 is an exhaust cylinder that discharges the exhaust from the reactor containment vessel 10. That is, the exhaust tube constitutes the scrubbing container 32. When the existing exhaust pipe is used as the scrubbing container 32, the water tightness and pressure resistance of the exhaust pipe are supplemented as necessary so that the scrubbing liquid 31 can be retained for a long period of time. The outer periphery of the scrubbing container 32 is surrounded by a shielding wall 39 made of a material that absorbs radiation. The shielding wall 39 needs to cover at least a portion of the scrubbing container 32 below the liquid surface 40 of the scrubbing liquid 31. In the present embodiment, the shielding wall 39 extends upward from the lower end portion of the scrubbing container 32 (the ground surface 41 in the present embodiment) to a position exceeding the liquid level 40 of the scrubbing liquid 31.

  At this time, in the present embodiment, a water level gauge 42 for detecting the water level of the scrubbing liquid 31 in the scrubbing container 32 is provided. While confirming the position of the liquid level 40 with the water level gauge 42, the water supply / drainage of the scrubbing water 31 is executed as necessary so that the liquid level 40 falls within a predetermined height range. The water level meter 42 may be any means that can detect the water level of the scrubbing liquid 31. However, in the present embodiment, for example, a manometer is used as an example, so that the water level of the scrubbing liquid 31 can be visually recognized from the outside. A water level gauge 42 is installed outside the shielding wall 39. For example, the water level of the scrubbing liquid 31 can be monitored at a remote location based on a detection signal from the water level gauge 42, but even if the power source is lost because the configuration illustrated in FIG. 1 does not require power. There is an advantage that the water level of the scrubbing liquid 31 can be known.

  In the present embodiment, the exhaust pipe 33 is a vent pipe that allows the gas in the reactor containment vessel 10 to escape. That is, the vent pipe that connects the reactor containment vessel 10 and the exhaust cylinder 32 constitutes the exhaust pipe 33. The exhaust pipe line 33 is connected to the dry well 12 to allow the exhaust from the dry well 12 to escape, the dry well vent line 43 to be connected to the wet well 13, and the wet well vent line 44 to release the exhaust gas from the gas phase, and the dry well The vent line 43 and the wet well vent line 44 merge to have a gas processing line (SGTS line) 45 connected to the scrubbing vessel 32. The exhaust pipe 33 including these parts is pressure resistant. The dry well vent line 43 and the wet well vent line 44 are provided with shut-off valves 46 and 47, respectively, and the shut-off valves 46 and 47 are normally closed to maintain the airtightness of the reactor containment vessel 10. ing. The gas treatment line 45 passes through the shielding wall 39 and the side wall of the scrubbing container 32, and a sparger (porous dispersion tube) 48 provided at the tip is exposed in the scrubbing liquid 31 in the scrubbing container 32. The portion of the shielding wall 39 and the scrubbing container 32 through which the merge pipe 45 passes is sealed to ensure water tightness. Further, in order to secure a distance that the air bubbles discharged from the sparger 48 float in the scrubbing liquid 31, the position of the sparger 48 is preferably as low as possible.

  The gas processing device 34 is provided upstream of the scrubbing container 32, that is, in the middle of the exhaust pipe 33 (in this embodiment, the gas processing line 45). The configuration of the gas processing device 34 is not necessarily limited. For example, a HEPA filter (not shown) that collects particulates in the exhaust including radioactive particulates, heating means (not shown) for heating the exhaust, and in the heated exhaust A charcoal filter (not shown) for collecting iodine.

  The water supply system 35 includes a scrubbing water source 49, a water supply pipe 50 connecting the water source 49 and the scrubbing container 32, a shutoff valve 51 and a pump 52 provided in the water supply pipe 50. As the water source 49, a sea, a river, a lake, a pool constructed in advance, or the like can be used, but when a purification treatment facility for purifying used scrubbing water in the drainage tank 38 is provided, It is also conceivable to use the drain tank 38 as the water source 49. The pump 52 may be a fixed type, but may be a movable type or a portable type mounted on a pump car. Moreover, although the case where the shut-off valve 51 is located on the downstream side of the pump 52 is illustrated, the positional relationship may be reversed.

  The pH adjuster supply system 36 includes a pH adjuster tank 53 storing the pH adjuster, a pH adjuster supply pipe 54 through which the pH adjustor passes, a shutoff valve 55 and a pump 56 provided in the pH adjuster supply pipe 54. Have. The pH adjuster is a chemical that makes scrubbing water alkaline (for example, pH 10 or more) in order to increase the recovery efficiency of iodine in the scrubbing container 32. For example, caustic soda (NaOH) can be used. In the present embodiment, the pH adjuster supply pipe 54 is joined to the water supply pipe 50, but may be connected to the scrubbing container 32 without being joined to the water feed pipe 50. Moreover, although the case where the shut-off valve 55 is located on the downstream side of the pump 56 is illustrated, the positional relationship may be reversed.

  The inert gas supply system 37 includes a gas supply device 57 serving as an inert gas supply source, an inert gas supply pipe 58 connecting the gas supply apparatus 57 and the scrubbing container 32, and an inert gas supply pipe 58. The provided shut-off valve 59 is provided. The inert gas is a gas for suppressing the combustion of hydrogen gas, and nitrogen gas (N2), argon gas (Ar), or the like can be used. As the inert gas supply device 57, for example, a device that generates nitrogen gas using air as a raw material, or a gas cylinder filled with an inert gas can be used. The inert gas supply pipe 58 is directly connected to the scrubbing container 32 in the present embodiment, but may be configured to merge with the water supply pipe 50 and the pH adjuster supply pipe 54. The inert gas supply line 58 is not particularly provided with a pump, but may be provided if necessary.

  The drain tank 38 only needs to have a configuration and capacity capable of receiving the used scrubbing liquid 31 and storing it for a long period of time. However, the drain tank 38 stores the used scrubbing liquid 31 that may contain a radioactive substance. Must be a structure. In the present embodiment, for example, a buried tank made of concrete is used. The drain tank 38 is connected to the bottom of the scrubbing container 32 through a drain pipe 60. The drain pipe 60 is provided with a shutoff valve 61, and the scrubbing liquid 31 flows from the scrubbing container 32 into the drainage tank 38 by opening the shutoff valve 61. Further, an exhaust pipe 62 having a HEPA filter 63 is connected to the drain tank 38, and when it is necessary to lower the pressure in the drain tank 38, the drain tank 38 passes through the HEPA filter 63 from the exhaust pipe 62. The gas inside can be discharged. Although not particularly illustrated, a purification device for purifying the gas may be provided separately. It is also conceivable that the exhaust pipe 62 is connected to the scrubbing container 32 or another scrubbing container (not shown) to scrub the exhaust from the drain tank 38.

  In the nuclear power plant configured as described above, when radioactive material flows out of the reactor pressure vessel 11 into the reactor containment vessel 10 due to unexpected factors, the radioactive material is set by purifying the gas in the reactor containment vessel 10 according to the following procedure. It releases after reducing below the value.

  When the series of steps is roughly divided, the first step of storing the scrubbing liquid 31 using the exhaust tube as the scrubbing container 32 and the gas in the reactor containment vessel 10 are supplied to the scrubbing liquid 31 and passed through the scrubbing liquid 31. This is divided into a second step of discharging.

  In the first step, the scrubbing liquid 31 is supplied and stored in the scrubbing vessel 32 when it becomes necessary to discharge the gas in the reactor containment vessel 10 that may contain a radioactive substance.

  When storing the scrubbing liquid 31 in the scrubbing container 32, first, with the shutoff valves 46, 47, 61 closed, the shutoff valve 51 of the water supply system 35 is opened and the pump 52 is driven to drive the scrubbing water of the water source 49. 31 is poured into the scrubbing vessel 32. At the same time or before and after this, the shutoff valve 55 of the pH adjusting agent supply system 36 is opened and the pump 56 is driven to mix a predetermined amount of the pH adjusting agent in the pH adjusting agent tank 53 into the scrubbing water 31.

  The second step is performed in a state where the scrubbing liquid 31 is injected into the scrubbing vessel 32 when it is necessary to discharge the gas in the reactor containment vessel 10 that may contain a radioactive substance.

  When releasing the gas in the reactor containment vessel 10, at least one of the shut-off valves 46 and 47 is opened, and the gas in the reactor containment vessel 10 is injected into the scrubbing vessel 32 through the exhaust pipe 33. At this time, the gas discharged through the wet well vent line 44 through the pressure suppression pool 14 by opening the shut-off valve 47 was discharged via the dry well vent line 43 by the amount of radioactive material recovered in the pressure suppression pool 14. Compared with gas, the content of radioactive material is reduced at the time of discharge from the reactor containment vessel 10. The exhaust gas flowing through the exhaust pipe 33 having the pressure resistance specification passes through the gas processing device 34 in the middle of the gas processing line 45 and is heated by a heating means (not shown) while being heated by a HEPA filter (not shown). Then, fine particles containing radioactive fine particles are collected, and iodine is collected by a charcoal filter (not shown). Basically, at this point, the content of radioactive material is below the set value.

  The exhaust gas that has passed through the gas processing device 34 is discharged from the sparger 48 at the outlet of the exhaust pipe 33 into the scrubbing liquid 31 in the scrubbing vessel 32. If unexpected hydrogen combustion is a concern during the injection of the exhaust gas into the scrubbing liquid 31, the shutoff valve 59 of the inert gas supply system 37 is opened, and the inert gas of the gas supply device 57 is removed from the scrubbing vessel. It is poured into scrubbing water 31 in 32. When radioactive material remains in the exhaust gas that has passed through the gas treatment device 34, when the material floats in the scrubbing liquid 31, fine particles including residual radioactive fine particles are collected in the scrubbing liquid 31, and residual iodine Is recovered in the scrubbing liquid 31. In this way, the exhaust gas whose content of radioactive material has further decreased in the process of ascending to the liquid surface 40 of the scrubbing liquid 31 rises in the exhaust pipe constituting the scrubbing container 32 and is finally released to the atmosphere at a high position. .

  During the scrubbing of the exhaust, the shut-off valves 46, 47, 51, 55, 59, 61 and the pumps 52, 56 are operated as necessary to interrupt the supply of exhaust and inert gas, supply / drainage of the scrubbing liquid 31, etc. Is executed as appropriate. When the scrubbing is completed, the scrubbing water 31 in the scrubbing container 32 is discharged to the drain tank 38 as necessary, and the scrubbing water 31 is stored in the scrubbing container 32 if necessary.

  According to the present embodiment, even when a radioactive substance flows into the reactor containment vessel 10, the gas in the reactor containment vessel 10 is guided to the scrubbing vessel 32, and scrubbed through the exhaust gas to the scrubbing liquid 31. The radioactive material in it can be recovered. Even if the heating means does not operate normally due to loss of the power source in the exhaust pipe 33 or the like, and there is a concern that the recovery efficiency of the radioactive material by the gas processing device 34 may be reduced, regardless of the presence or absence of the power source. Since the recovery effect of the radioactive material by scrubbing can be expected, it is possible to suppress the exhaust gas flowing out from the reactor pressure vessel 11 from being released into the atmosphere without sufficiently recovering the radioactive material.

  In addition, if the scrubbing liquid 31 is stored in the scrubbing container 32 from the normal time, the shutoff valves 46, 47, 59 can be used even if the pumps 52, 56 of the water supply system 35 and the pH adjuster supply system 36 do not operate normally. The scrubbing process can be executed by appropriately opening and closing.

  In addition, since the scrubbing container 32 is used to store the scrubbing water 31, the existing nuclear power plant can be easily remodeled into the nuclear power plant of the present invention. When the present invention is applied to an existing nuclear power plant, the process is mainly performed by installing a water supply system 35 for supplying a scrubbing liquid 31 from a position where exhaust gas is discharged in a scrubbing vessel 32 (exhaust tube). The scrubbing liquid 31 is supplied to the scrubbing container 32 so that the water level becomes high. At this time, when the exhaust pipe 33 (vent pipe) protrudes into the scrubbing container 32 and the sparger 48 is installed at the exhaust outlet, the scrubbing liquid 31 is stored so as to have a higher water level than the sparger 48. Needless to say. In the case where a sea, a river, or the like exists in the vicinity as the water source 49, for example, a pump car or the like can be used for the water supply system 35. In addition, when the watertightness of the existing exhaust pipe is insufficient to make the scrubbing container 32, water shielding treatment is applied to the inner wall surface or the outer wall surface of the exhaust pipe, and when there are cracks or pores, they are removed. Watertightness is appropriately ensured by, for example, a sealing process for closing. Further, when it is necessary to increase the pressure resistance, it is appropriately reinforced.

  At this time, when an existing nuclear power plant is used as a base, an AM line (accident management line) 76 that bypasses the gas processing device 34 from the dry well vent line 43 and connects to the gas processing line 45 is installed. At the time of wet well venting and dry well venting, it has been assumed that gas is discharged from the exhaust pipe (in this example, the scrubbing container 32) via the AM line 76 without passing through the gas processing line 45. Therefore, when the gas processing apparatus 34 is originally in an existing nuclear power plant, the gas processing apparatus 34 is not always designed to withstand the pressure at the time of venting. In that case, by exchanging the gas processing device 34 with a pressure resistant specification, exhaust gas during wet well venting and dry well venting can be supplied to the scrubbing vessel 32 after passing through the gas processing device 34. become. Further, when the existing gas processing apparatus 34 is used, for example, it is conceivable to install a bypass line 77 with a small valve that bypasses the shutoff valve 46 in the dry well vent line 43. The small valve has a smaller opening diameter than the shut-off valve 46, and at the time of dry well venting, the shut-off valve 46 of the dry well vent line 43 is closed and the small valve of the bypass line 77 is opened to increase the pressure loss. By reducing the internal pressure, the vent gas can be passed through the existing gas processing apparatus 34 having insufficient pressure resistance. When the same measures are required at the time of wet well venting, a bypass line (not shown) with a small valve that bypasses the shutoff valve 47 in the wet well vent line 44 is installed.

  Further, the scrubbing water 31 in the scrubbing container 32 may increase the content of radioactive material as the scrubbing progresses. Therefore, when the exhaust pipe is used as the scrubbing container 32, the scrubbing container 32 is formed by the shielding wall 39 formed of a material that absorbs radiation (for example, concrete or lead) in order to suppress scattering of radiation from the scrubbing container 32. It is desirable to cover at least the portion below the liquid surface 40 of the scrubbing liquid 31.

  Further, in order to improve the recovery efficiency of iodine by the scrubbing water 31, it is desirable to install a pH adjuster supply system 36. Similarly, when it is necessary to prepare for hydrogen combustion of exhaust gas, an inert gas supply system 37 is also installed.

  When scrubbing is performed for a long period of time, a drain tank 38 is installed as a discharge destination of the used scrubbing liquid 31. However, if there is a pool that can be used as the drainage tank 38 in the existing nuclear power plant, the pool may be used as the drainage tank 38 without being newly established.

(Second Embodiment)
FIG. 2 is a schematic diagram showing a main part of a nuclear power plant to which a decontamination apparatus according to a second embodiment of the present invention is applied. In the present embodiment, the same parts as those of the above-described embodiment are denoted by the same reference numerals as those of the above-described drawings, and description thereof will be omitted as appropriate.

  The present embodiment is different from the first embodiment in that a scrubbing container 32 a is provided separately from the exhaust pipe 17. That is, the scrubbing liquid 31 is not injected into the exhaust cylinder 17, and the scrubbing container 32 a is installed between the gas treatment device 34 and the exhaust cylinder 17 in the exhaust system.

  The decontamination apparatus 30a of the present embodiment includes a scrubbing vessel 32a and an exhaust pipe 33 that supplies exhaust gas from the reactor containment vessel 10 to the scrubbing liquid 31 in the scrubbing vessel 32a, as well as a water supply system 35, pH A regulator supply system 36, an inert gas supply system 37, a drain tank 38, and the like are provided.

  The scrubbing container 32a may be a tank having a desired capacity, pressure resistance, and water tightness. In the present embodiment, the exhaust pipe 33, the water supply pipe 50, the pH adjuster supply pipe 54, the inert gas supply pipe 58, and the drain pipe 60 are connected to the scrubbing container 32a instead of the exhaust pipe 17. Yes. If the scrubbing container 32a has insufficient radiation shielding capability, the shielding wall 39a is installed. In the present embodiment, since a dedicated tank can be prepared as the scrubbing container 32a separately from the exhaust pipe 17, a sealed tank can be used except for the connection portion of the pipe, and the upper and lower sides can be used not only around the side wall. The entire structure including the wall surface may be covered with the shielding wall 39a. In the scrubbing container 32 a, a portion (for example, a ceiling portion) connected to the internal gas phase portion is connected to the exhaust cylinder 17 via the exhaust pipe line 64.

  Other configurations are the same as those of the first embodiment.

  In the nuclear power plant according to the present embodiment, when the gas in the reactor containment vessel 10 is purified to reduce the radioactive material below the set value and released to the atmosphere, the scrubbing liquid 31 is largely stored in the scrubbing vessel 32a. And the second step of supplying the gas in the reactor containment vessel 10 to the scrubbing liquid 31 and discharging it through the scrubbing liquid 31. The contents of the first procedure and the second procedure are substantially the same as those of the first embodiment. In the case of the present embodiment, the exhaust gas that has passed through the gas treatment device 34 is scrubbed in the scrubbing container 32 a, and the exhaust gas that has been scrubbed to reduce the content of radioactive material is discharged to the atmosphere via the exhaust pipe 64 and the exhaust cylinder 17. To be released.

  Also in this embodiment, the same effects as those of the first embodiment can be obtained.

  Further, since the scrubbing vessel 32a is additionally installed between the exhaust pipe 17 and the gas processing device 34, it is easy to remodel an existing nuclear power plant into the nuclear power plant of the present invention. When the present invention is applied to an existing nuclear power plant, the process is mainly performed so that the scrubbing container 32a and the water supply system 35 are installed, and the water level is higher than the position where the exhaust gas is discharged in the scrubbing container 32a. The scrubbing liquid 31 is supplied to the scrubbing container 32a. The procedure for injecting the scrubbing water 31 into the scrubbing container 32a is the same as in the first embodiment.

  Further, when the radiation shielding property of the scrubbing container 32a is insufficient, it is desirable to install a shielding wall 39a. In order to improve the recovery efficiency of iodine by the scrubbing water 31, it is desirable to install a pH adjuster supply system 36. Similarly, when it is necessary to prepare for hydrogen combustion of exhaust gas, it is desirable to install an inert gas supply system 37. In addition, when scrubbing over a long period is assumed, it is desirable to install a drain tank 38 as a discharge destination of the used scrubbing liquid 31. These points are the same as those in the first embodiment.

  In the present embodiment, the exhaust gas after scrubbing is discharged to the atmosphere through the exhaust tube 17, but such a configuration is not necessarily required, and the scrubbing from the scrubbing container 32 a is not necessarily performed. It is also conceivable that the later exhaust is released into the atmosphere.

(Third embodiment)
FIG. 3 is a schematic diagram showing a main part of a nuclear power plant to which a decontamination apparatus according to a third embodiment of the present invention is applied. In the present embodiment, the same parts as those of the above-described embodiment are denoted by the same reference numerals as those of the above-described drawings, and description thereof will be omitted as appropriate.

  Although the present embodiment is the same as the two embodiments described above in that the gas flowing out from the reactor pressure vessel 11 is purified, the periphery of the reactor building 16 is covered with the sealed building 65 and the exhaust from the sealed building 65 is exhausted. It differs in that it is discharged and scrubbed. In the present embodiment, for example, even if an unexpected disaster is encountered and the radioactive material flowing out of the reactor pressure vessel 11 faces a situation where it can leak to the outside of the reactor building 16, the radioactive material It is for suppressing scattering to the surrounding environment.

  The decontamination apparatus 30b according to the present embodiment mainly includes a sealed building 65 that surrounds the reactor building 16, a scrubbing vessel 32b that stores the scrubbing solution 31, and a scrubbing solution 31 in the scrubbing vessel 32b. An exhaust pipe 33b for supplying exhaust gas from 65, a circulation pipe 66 for returning the exhaust gas passed through the scrubbing container 32b to the sealed building 65, a dosimeter 67 provided in the circulation pipe 66, a circulation pipe A discharge system 68 that branches off from the passage 66 and discharges the exhaust gas that has passed through the scrubbing container 32b to the atmosphere, shutoff valves 69 and 70 provided in the circulation pipe 66 and the discharge system 68, respectively, and between the scrubbing container 32b and the sealed building 65 Are provided with gas processing devices 71-73 for removing radioactive substances in the exhaust gas circulating in

  The sealed building 65 can be made of, for example, the same material and structure as the outer wall of the reactor building 16, surrounds the reactor building 16 with airtightness, and the gas in the sealed building 65 is sealed in the sealed building 65. Prevents leaking outside. The sealed building 65 is assumed to have a predetermined volume, pressure resistance, and shielding properties.

  For example, the scrubbing container 32b may be the same as the scrubbing container 32a of the second embodiment, and the exhaust line 33b, the water supply line 50, the pH adjuster supply line 54, the inert gas supply line 58, the drainage A pipe line 60 and a circulation pipe line 66 are connected to the scrubbing container 32b. If the scrubbing vessel 32b has insufficient radiation shielding capability, a shielding wall 39b is installed.

  The circulation conduit 66 connects a portion (for example, a ceiling portion) connected to the gas phase portion in the scrubbing container 32 b and the sealed building 65. The circulation line 66 is provided with a pump 74 as necessary. The pump 74 may be provided in the exhaust pipe 33b. However, in the circulation system including the discharge pipe 33b and the circulation pipe 66, it is necessary to provide the pump 74 upstream of the connection portion of the discharge system 68 with the discharge pipe 75. .

  The gas processing devices 71-73 shown in the path of the circulation line 66 remove radioactive materials in the exhaust gas circulating between the sealed building 65 and the scrubbing container 32b, as in the scrubbing container 32b. For example, the gas processing device 71 filters the exhaust gas such as a HEPA filter and collects fine particles, the gas processing devices 72 and 73 each filter absorbs fine particles such as activated carbon and zeolite, and the like. . The type of filter can be appropriately changed depending on the nuclide to be removed. Further, the order of the gas processing devices 71-73 in the exhaust flow direction is not limited to the mode of FIG. 3, and the positional relationship with the scrubbing container 32b is not limited. Accordingly, there may be a configuration in which at least one of the gas processing devices 71-73 is provided in the exhaust pipe line 33b. Further, the gas processing devices 71-73 are not necessarily required, and may be appropriately omitted depending on the situation and the case. In some cases, four or more types of gas processing devices may be provided.

  The discharge system 68 includes an exhaust pipe 17 and an exhaust pipe line 75 that connects the exhaust pipe 17 and the circulation pipe 66. However, the exhaust pipe line 75 may not be connected to the exhaust pipe 17 and the exhaust gas after scrubbing may be discharged from the exhaust pipe line 75 to the atmosphere without going through the exhaust pipe 17. The shut-off valve 70 is provided in the exhaust pipe 75.

  Other configurations are the same as those of the first embodiment.

  In the present embodiment, the periphery of the reactor building 16 is covered with a sealed building 65, the scrubbing liquid 31 is stored in the scrubbing vessel 32b, and the exhaust gas from the sealed building 65 is supplied to the scrubbing solution 31 in the scrubbing vessel 32b. By doing so, the radioactive material in the exhaust is recovered. As a result, radioactive substances in the exhaust can be reduced. In the present embodiment, since the radioactive substance can be further recovered from the exhaust gas after scrubbing by the gas processing device 71-73, the exhaust gas purification effect is higher.

  In order to further reduce the radioactive substances, for example, the shutoff valve 69 of the circulation line 66 and the shutoff valve 59 of the inert gas supply system 37 are opened, and the other shutoff valves 51, 55, 61 are opened. In the closed state, the gas in the sealed building 65 is sequentially circulated to the scrubbing vessel 32b, the gas processing devices 71-73, etc. via the circulation line 66. At this time, since the dose of the circulating exhaust gas can be detected by the dosimeter 67, the dose of the gas in the sealed building 65 has fallen below the set value while circulating between the sealed building 65 and the scrubbing vessel 32b. If the detected value of 67 is confirmed, the shutoff valve 69 of the circulation pipe 66 is closed and the shutoff valve 70 of the exhaust pipe 75 is opened to confirm that the radioactive material has been sufficiently reduced and then released. Exhaust gas can be released to the atmosphere via system 68.

  Also in the present embodiment, the exhaust gas flowing out from the reactor pressure vessel 11 can be purified before being released to the atmosphere on the same principle as the above-described embodiment.

  Moreover, with respect to the existing nuclear power plant, the sealed building 65, the scrubbing container 32b, the water supply system 35, and the exhaust pipe 33b are installed at a minimum so that the water level becomes higher than the position where the exhaust gas is discharged in the scrubbing container 32b. In addition, by supplying the scrubbing liquid 31 to the scrubbing vessel 32b, the radioactive material that can leak from the reactor building 16 can be recovered. Moreover, it can be set as the structure with a higher purification effect by further adding the circulation line 66, the word processing apparatus 71-73, etc. FIG.

(Other)
The above-described embodiments can be combined as appropriate, and can be appropriately changed in design without departing from the technical idea of the present invention. Further, in the first and second embodiments, the configuration in which the exhaust gas can be guided from both the dry well 12 and the wet well 13 to the scrubbing containers 32 and 32a has been described as an example. One of the wet well vent line 44 and the wet well vent line 44 may be omitted, and exhaust gas may be supplied from either the dry well vent line 43 or the wet well vent line 44 to the scrubbing containers 32 and 32a.

DESCRIPTION OF SYMBOLS 10 Reactor containment vessel 11 Reactor pressure vessel 12 Dry well 13 Wet well 17 Exhaust tube 30, 30a, 30b Decontamination device 31 Liquid for scrubbing 32 Scrubbing vessel (exhaust tube)
32a, 32b Scrubbing containers 33, 33a Exhaust pipe (vent pipe)
33b Exhaust pipe 34 Gas treatment device 35 Water supply system 36 pH adjuster supply system 37 Inert gas supply system 38 Drain tanks 39, 39a, 39b Shielding walls (shielding means)
43 Dry Well Vent Line 44 Wet Well Vent Line 65 Sealed Building 66 Circulation Line 67 Dosimeter 68 Release System 69, 70 Shut-off Valve 71-73 Gas Processing Device

Claims (24)

A scrubbing vessel for exhausting exhaust from the reactor containment vessel and storing scrubbing liquid;
A decontamination apparatus comprising: a vent pipe for releasing gas in the reactor containment vessel, and an exhaust pipe for supplying exhaust gas from the reactor containment vessel to a scrubbing liquid in the scrubbing vessel . A scrubbing container for storing a scrubbing liquid;
A decontamination apparatus comprising: an exhaust pipe for supplying exhaust gas from the reactor containment vessel to the scrubbing liquid in the scrubbing vessel. A sealed building surrounding the reactor building containing the reactor containment vessel;
A scrubbing container for storing a scrubbing liquid;
A decontamination apparatus comprising: an exhaust pipe for supplying exhaust gas from the sealed building to the scrubbing liquid in the scrubbing container. In the decontamination apparatus of Claim 3,
A circulation line for returning the exhaust gas through the scrubbing container to the sealed building;
A dosimeter installed in this circulation line;
A discharge system that branches off from the circulation line and discharges the exhaust gas that has passed through the scrubbing vessel to the atmosphere;
A decontamination apparatus comprising a shutoff valve provided in each of the circulation line and the discharge system.   4. The decontamination apparatus according to claim 1, wherein the exhaust pipe has a dry well vent line for releasing exhaust from the dry well and a wet well vent line for releasing exhaust from the wet well. Decontamination equipment characterized by   The decontamination apparatus according to any one of claims 1 to 3, further comprising a pressure-resistant gas treatment apparatus that removes radioactive substances in the exhaust gas flowing through the exhaust pipe upstream of the scrubbing container. apparatus.   The decontamination apparatus according to any one of claims 1 to 3, further comprising shielding means that is formed of a material that absorbs radiation and covers at least a portion of the scrubbing container below the liquid level of the scrubbing liquid. Decontamination equipment.   The decontamination apparatus according to any one of claims 1 to 3, further comprising a water supply system for supplying a scrubbing liquid to the scrubbing container.   The decontamination apparatus according to any one of claims 1 to 3, further comprising a pH adjusting agent supply system for supplying a pH adjusting agent to the scrubbing liquid.   4. The decontamination apparatus according to claim 1, further comprising an inert gas supply system that supplies an inert gas to the scrubbing liquid.   The decontamination apparatus according to any one of claims 1 to 3, further comprising a drainage tank for storing used scrubbing liquid discharged from the scrubbing container.   5. The decontamination apparatus according to claim 4, further comprising a gas treatment device that removes radioactive substances in the exhaust gas circulating between the scrubbing container and the sealed building. The scrubbing liquid is stored in an exhaust pipe that discharges exhaust from the reactor containment vessel.
A decontamination method characterized in that the gas in the reactor containment vessel is supplied to the scrubbing liquid in the scrubbing vessel. The scrubbing liquid is stored in a scrubbing container,
A decontamination method characterized by supplying exhaust gas from a reactor containment vessel to the scrubbing liquid in the scrubbing vessel. Cover the periphery of the reactor building with a sealed building,
The scrubbing liquid is stored in a scrubbing container,
A decontamination method, wherein exhaust gas from the sealed building is supplied to the scrubbing liquid in the scrubbing container. In the decontamination method of Claim 15,
Circulate the exhaust through the scrubbing container back to the sealed building,
A decontamination method, wherein the exhaust gas is discharged to the atmosphere when the circulating exhaust gas dose falls below a set value. A containment vessel,
A scrubbing vessel for exhausting the exhaust from the reactor containment vessel and storing scrubbing liquid;
A nuclear power plant comprising: a vent pipe for releasing gas in the reactor containment vessel, and an exhaust pipe for supplying exhaust gas from the reactor containment vessel to the scrubbing liquid in the scrubbing vessel. A containment vessel,
A scrubbing container for storing a scrubbing liquid;
An nuclear power plant comprising an exhaust pipe for supplying exhaust gas from the reactor containment vessel to the scrubbing liquid in the scrubbing vessel. The reactor building,
A sealed building that surrounds the reactor building,
A scrubbing container for storing a scrubbing liquid;
An nuclear power plant comprising: an exhaust pipe for supplying exhaust from the sealed building to the scrubbing liquid in the scrubbing vessel. Installed a water supply system that supplies scrubbing liquid to an exhaust pipe that discharges the exhaust from the reactor containment vessel.
A method for remodeling a nuclear power plant, characterized in that a scrubbing liquid is supplied to the exhaust pipe so that the water level is higher than a position where the exhaust gas is discharged in the exhaust pipe. A scrubbing vessel, a water supply system for supplying the scrubbing solution to the scrubbing vessel, and an exhaust line for supplying exhaust gas from the reactor containment vessel to the scrubbing solution in the scrubbing vessel,
A method for remodeling a nuclear power plant, comprising supplying a scrubbing liquid to the scrubbing container so that the water level is higher than a position where exhaust gas is discharged in the scrubbing container. A closed building that covers the periphery of the reactor building, a scrubbing container that stores scrubbing liquid, a water supply system that supplies the scrubbing liquid to the scrubbing container, and an exhaust from the sealed building to the scrubbing liquid in the scrubbing container Install an exhaust line
A method for remodeling a nuclear power plant, comprising supplying a scrubbing liquid to the scrubbing container so that the water level is higher than a position where exhaust gas is discharged in the scrubbing container.   23. The method for remodeling a nuclear power plant according to any one of claims 20 to 22, wherein a shielding means that is formed of a material that absorbs radiation and covers at least a portion below the liquid surface of the scrubbing liquid of the exhaust pipe is installed. A method for remodeling a nuclear power plant.   The method for remodeling a nuclear power plant according to any one of claims 20 to 22, wherein an inert gas supply system for supplying an inert gas to the scrubbing liquid in the exhaust stack is installed.

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