JP2016090514A - Radioactive substance removal device and radioactive substance removal system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a radioactive substance removal device capable of preventing an influence to the outside of a casing due to a radioactive ray emitted from a filter.SOLUTION: The radioactive substance removal device includes: a radioactive filter unit 21 that has a radioactive filter formed into a cylindrical form and capable of adsorbing radioactive iodine and radioactive methyl iodine contained in gas and a radioactive substance; and a casing 11 that accommodates the radioactive filter unit 21 and forms a flow passage that allows the gas to flow from the inside of the cylindrical form of the radioactive filter to the outside thereof.SELECTED DRAWING: Figure 3

Description

  The present invention relates to a radioactive substance removing device and a radioactive substance removing system that remove radioactive substances in, for example, a nuclear power plant.

In a nuclear facility such as a nuclear power plant, radioactive substances such as radioactive mist and radioactive fine particles mainly composed of cesium, strontium and the like, and a radioactive gas, particularly elemental iodine ( ¹²⁹ I ₂ , ¹³¹ I, from the viewpoint of protecting the surrounding environment. ₂ , ¹³³ I ₂ ) and methyl iodide (CH ₃ ¹²⁹ I, CH ₃ ¹³¹ I, CH ₃ ¹³³ I) as important components, it is important to reduce the amount of radioactive iodine released. It is a difficult issue.

  Conventionally, the radioactive gas removal device described in Patent Document 1 is provided on a cylindrical casing and on the other end side of the cylindrical casing, and extends from the opening on one end side of the casing to the opening on the other end side. A blower for circulating gas in the casing, a radioactive filter provided in the casing for adsorbing radioactive iodine, radioactive methyl iodide and radioactive substances contained in the gas, and a radioactive filter in the casing A downstream high-performance filter that collects particles dispersed from the radioactive filter and is provided in the casing and upstream of the gaseous filter than the radioactive filter. And a gas treatment filter that adsorbs an organic solvent gas component and an acid gas component contained in the gas.

JP 2014-35286 A

  According to the radioactive gas removal device described in Patent Document 1, the gas flowing through the casing from one end side to the other end side of the casing by the blower sequentially passes through the gas treatment filter, the radioactive filter, and the downstream high-performance filter. Is discharged outside the casing. At this time, first, the organic solvent gas component and the acid gas component contained in the gas are adsorbed by the gas processing filter. Next, the radioactive iodine and radioactive methyl iodide contained in the gas are adsorbed and removed by the radioactive filter. Next, particles scattered from the radioactive filter are collected by the downstream high-performance filter. As a result, since the organic solvent gas component and the acid gas component are removed by the gas treatment filter before the gas passes through the radioactive filter, the situation that the radioactive filter is clogged by the organic solvent gas component and the acid gas component is prevented, The deterioration of the performance of the radioactive filter can be suppressed. Moreover, after the gas passes through the radioactive filter, the downstream high-performance filter collects the particles separated from the radioactive filter, so that the radioactive filter particles accompanying the radioactive iodine and radioactive methyl iodide and the radioactive substance are encased in the casing. Can be prevented from being released to the outside.

  In the above-described radioactive gas removing device, gas is circulated in the casing from one end side to the other end side of the cylindrical casing, and the radioactive substance is adsorbed on the radioactive filter. For this reason, radiation is emitted from the radioactive filter from which the radioactive substance is adsorbed and removed on one end side of the cylindrical casing, and the outside on the one end side of the casing may be exposed to the radiation.

  The present invention solves the above-described problems, and an object thereof is to provide a radioactive substance removing device and a radioactive substance removing system capable of preventing the radiation emitted from a filter from affecting the outside of the casing.

  In order to achieve the above-mentioned object, the radioactive substance removing device of the present invention includes a radioactive filter unit having a radioactive filter formed in a cylindrical shape capable of adsorbing and removing radioactive iodine and radioactive methyl iodide contained in gas. And a casing that accommodates the radioactive filter unit and forms a flow path through which gas can flow from the inside to the outside of the cylindrical shape of the radioactive filter.

  According to this radioactive substance removing device, since the gas is circulated from the inside to the outside of the cylindrical shape of the radioactive filter, most of the radioactive iodine and radioactive methyl iodide are removed by adsorption inside the cylindrical shape of the radioactive filter. For this reason, the amount of radiation emitted outside the cylindrical shape of the radioactive filter is reduced. As a result, it is possible to prevent the outside of the casing from being exposed to radiation, and to prevent the radiation emitted from the radioactive filter from affecting the outside of the casing.

  Further, in the radioactive substance removing device of the present invention, the radioactive filter unit is formed in a cylindrical shape capable of collecting particles contained in the gas and is disposed inside the cylindrical shape of the radioactive filter. A filter, and a second high-performance filter capable of collecting particles contained in the gas and formed in a cylindrical shape and disposed outside the cylindrical shape of the radioactive filter, and the casing includes the radioactive filter And each said high performance filter is accommodated in the inside, and the flow path which can distribute | circulate gas from the cylindrical inner side of said 1st high performance filter through the said radioactive filter to the cylindrical outer side of said 2nd high performance filter is formed It is characterized by that.

  According to this radioactive substance removing device, since a part of the radioactive substance is collected together with the particles contained in the gas from the first high performance filter inside the cylindrical shape of the radioactive filter, the cylindrical outer side of the radioactive filter is collected. The amount of radiation released at is further reduced. As a result, it is possible to further prevent the outside of the casing from being exposed to radiation, and to assist the effect of preventing the radiation emitted from the radioactive filter from affecting the outside of the casing. And since a part of radioactive substance is collected with the particle | grains contained in gas from a 1st high performance filter, the filter function of a radioactive filter can be maintained. Furthermore, since the particles separated from the radioactive filter are collected by the second high-performance filter, the amount of radiation emitted outside the cylindrical shape of the radioactive filter is further reduced. As a result, it is possible to further prevent the outside of the casing from being exposed to radiation, and to assist the effect of preventing the radiation emitted from the radioactive filter from affecting the outside of the casing.

  In addition, the radioactive substance removing device of the present invention includes a shield that is configured to shield radiation and is disposed so as to surround the casing.

  According to this radioactive substance removing device, the shielding body can further prevent the situation of being exposed to radiation outside the casing, and can assist the effect of preventing the radiation emitted from the radioactive filter from affecting the outside of the casing. .

  In the radioactive substance removing device of the present invention, the radioactive filter unit is characterized in that the radioactive filter formed in a cylindrical shape has a multiple structure or a thickness equivalent to the multiple structure.

  The adsorption removal performance of radioactive iodine and radioactive methyl iodide by the radioactive filter is proportional to the thickness of the gas flow direction to the radioactive filter, and the permeability coefficient of radioactive iodine and radioactive methyl iodide ((1- Since the removal efficiency [%] / 100) is reduced, it is possible to improve the removal efficiency of the radioactive gas by using a multiple structure of the radioactive filter.In addition, the thickness of the single structure is made as thick as the multiple structure. For example, it is possible to reduce the size of the apparatus while improving the performance of the radioactive filter unit by the interval of multiple structures.

  In the radioactive substance removing device of the present invention, the casing has an opening that can open an upper position of the radioactive filter unit to be accommodated and a lid that can open and close the opening, and the radioactive filter unit includes: It is provided to be movable in the vertical direction with respect to the casing and to be able to pass through the opening.

  According to this radioactive substance removing device, when replacing the radioactive filter unit, the radioactive filter unit is moved upward and taken out from the opening of the casing, so that an operator approaches the cylindrical outside of the radioactive filter unit. In order to prevent, the influence on the exterior of the casing by the radiation emitted from the radioactive filter can be prevented.

  In order to achieve the above object, a radioactive substance removal system of the present invention includes the radioactive substance removal apparatus according to any one of the above, and a casing having the same structure as the casing of the radioactive substance removal apparatus, In a state in which a heating device capable of heating a gas flowing in the casing and accommodating a heating unit formed in a cylindrical shape, the casing of the radioactive substance removing device, and the casing of the heating device are connected to each other. And a blower that circulates gas through each casing with the heating device upstream.

  According to this radioactive substance removal system, the heating device is arranged upstream of the radioactive substance removal apparatus, so that the influence of moisture on the radioactive filter of the radioactive substance removal apparatus is suppressed, and radioactive iodine and radioactive substances in the radioactive filter are suppressed. The adsorption performance of methyl iodide can be improved. In addition, since the casing of the heating device has the same structure as that of the radioactive substance removing device, the heating device can be configured simply by changing the heating unit, and the system can be easily constructed.

  Further, in the radioactive substance removal system of the present invention, the radioactive gas removal system has a casing having the same structure as the casing of the radioactive substance removal apparatus, and can remove volcanic ash contained in the gas flowing in the casing. Each of the casings further includes a volcanic ash removing device that accommodates a volcanic ash filter unit formed in a cylindrical shape, and the casing of the volcanic ash removing device is connected to the casing of the heating device, and the volcanic ash removing device is upstream. It is characterized in that gas is circulated.

  According to this radioactive material removal system, the volcanic ash removal device is arranged upstream of the radioactive material removal device, so that the filter of the radioactive material removal device can be prevented from being clogged by volcanic ash, and the radioactive material removal performance can be improved. Can be improved. Moreover, by making the casing of the volcanic ash removal device the same structure as the casing of the radioactive substance removal device, the volcanic ash removal device can be configured simply by changing the volcanic ash filter unit, and the system can be easily constructed.

  In the radioactive substance removal system of the present invention, the radioactive gas removal system is characterized in that a plurality of the radioactive substance removal apparatuses are connected.

  According to this radioactive substance removal system, even if the function of one radioactive substance removal apparatus is reduced by connecting a plurality of radioactive substance removal apparatuses, the radioactive gas removal action is maintained by another radioactive substance removal apparatus. Can do.

  In the radioactive substance removal system of the present invention, a plurality of the radioactive gas removal systems are arranged in parallel.

  According to this radioactive substance removal system, when a plurality of radioactive gas removal systems are arranged in parallel, for example, when replacing the radioactive filter unit of the radioactive substance removal device in one radioactive gas removal system, the other radioactive gas removal system The radioactive gas removal action can be continued.

  ADVANTAGE OF THE INVENTION According to this invention, the influence on the exterior of a casing by the radiation discharge | released from a filter can be prevented.

FIG. 1 is a side view of a radioactive substance removal system according to an embodiment of the present invention. FIG. 2 is a plan view of the radioactive substance removal system according to the embodiment of the present invention. FIG. 3 is a side sectional view of the radioactive substance removing device according to the embodiment of the present invention. FIG. 4 is a plan view of the radioactive substance removing device according to the embodiment of the present invention. FIG. 5 is a plan view of the radioactive substance removing device according to the embodiment of the present invention with the lid removed. FIG. 6 is a side sectional view of the filter unit of the radioactive substance removing device according to the embodiment of the present invention. FIG. 7 is a side sectional view of the filter unit of the radioactive substance removing device according to the embodiment of the present invention. FIG. 8 is a partially enlarged side sectional view of the filter unit of the radioactive substance removing device according to the embodiment of the present invention. FIG. 9 is a partially enlarged side sectional view of the filter unit of the radioactive substance removing device according to the embodiment of the present invention. FIG. 10 is a side sectional view of the heating unit of the radioactive substance removing device according to the embodiment of the present invention. FIG. 11 is a side sectional view of the volcanic ash filter unit of the radioactive substance removing device according to the embodiment of the present invention. FIG. 12 is a partially enlarged side sectional view of the volcanic ash filter unit of the radioactive substance removing device according to the embodiment of the present invention. FIG. 13 is a partially enlarged side sectional view of the volcanic ash filter unit of the radioactive substance removing device according to the embodiment of the present invention.

  Embodiments according to the present invention will be described below in detail with reference to the drawings. In addition, this invention is not limited by this embodiment. In addition, constituent elements in the following embodiments include those that can be easily replaced by those skilled in the art or those that are substantially the same.

  FIG. 1 is a side view of the radioactive substance removal system according to the present embodiment. FIG. 2 is a plan view of the radioactive substance removal system according to the present embodiment.

  As shown in FIGS. 1 and 2, the radioactive substance removal system 100 of the present embodiment has a radioactive gas removal chamber 101 that is tightly surrounded and closed by a reinforced concrete wall 101A, a ceiling 101B, a floor 101C, and the like. It is installed in the radioactive gas removal chamber 101. The radioactive substance removal system 100 includes a radioactive substance removal apparatus 1, a heating apparatus 2, a volcanic ash removal apparatus 3, and a blower 4. These are connected in order of the volcanic ash removal device 3, the heating device 2, the radioactive substance removal device 1, and the blower 4. In addition, the volcanic ash removal device 3 is connected to an air supply pipe 5 that leads to the outside of the radioactive gas removal chamber 101. The blower 4 is connected to an exhaust pipe 6 that leads to the outside of the radioactive gas removal chamber 101. The radioactive substance removal system 100 includes a radioactive gas removal system S in which gas is circulated by the blower 4 in the order of the volcanic ash removal apparatus 3, the heating apparatus 2, and the radioactive substance removal apparatus 1. FIG. 2 is a diagram of a room outside the radioactive gas removal chamber 101, a working room, or the like that supplies gas outside the radioactive gas removal chamber 101 via the air supply pipe 5 and passes through the radioactive gas removal system S via the exhaust pipe 6. Discharge into any room that is not clearly indicated.

  As shown in FIGS. 1 and 2, the radioactive substance removal system 100 according to the present embodiment includes a plurality (two in the present embodiment) of radioactive substance removal apparatuses 1 connected to each other. Further, in the radioactive substance removal system 100 of the present embodiment, as shown in FIG. 2, a plurality of the radioactive gas removal systems S described above (three systems in this embodiment) are arranged in parallel. Moreover, the radioactive substance removal system 100 of this embodiment is provided with the crane apparatus 102 in the ceiling 101B in the radioactive gas removal chamber 101, as shown in FIG. The crane apparatus 102 is configured such that the suspended portion 102 </ b> A can access the radioactive substance removing apparatus 1, the heating apparatus 2, the volcanic ash removing apparatus 3, and the blower 4. This crane apparatus 102 is operated in an operation chamber 103 isolated from the radioactive gas removal chamber 101 as shown in FIG. As shown in FIG. 1, the open portion 5 </ b> A of the air supply pipe 5 that leads to the outside of the radioactive gas removal chamber 101 is covered with a hood 7 so as to prevent intrusion of rainwater and the like. Further, the hood 7 is provided with a cover 8 such as a net at an opening thereof so as to prevent entry of dust and the like.

  Note that the radioactive gas removal chamber 101 does not necessarily have to be provided. In this case, the crane apparatus 102 may be a fixed type such as a jib crane or a bridge crane, or a movement such as a truck crane, a wheel crane, or a crawler crane. The formula applies. Further, the radioactive gas removal system S may be configured such that the supply side is open to the outside air and the exhaust side is open to some room.

  FIG. 3 is a side sectional view of the radioactive substance removing device according to the present embodiment. FIG. 4 is a plan view of the radioactive substance removing device according to the present embodiment. FIG. 5 is a plan view of the radioactive substance removing device according to the present embodiment with the lid removed. 6 and 7 are side sectional views of the radioactive filter unit of the radioactive substance removing device according to the present embodiment.

  As shown in FIGS. 3 to 4, the radioactive substance removing device 1 has a radioactive filter unit 21 housed inside a casing 11.

  The casing 11 includes a case main body 12, a storage portion 13, and a lid body 14. The case main body 12 of the casing 11 is formed in a cylindrical shape, and in this embodiment, as shown in FIGS. 4 and 5, it is formed in an elliptical cylindrical shape in plan view. Further, the case body 12 is connected to an inlet pipe 12A and an outlet pipe 12B extending in opposite directions along the longitudinal direction. The inlet pipe 12 </ b> A and the outlet pipe 12 </ b> B are provided at positions above the side portion of the case body 12, and both are provided with the center C coincident at the same height position. The inlet pipe 12A and the outlet pipe 12B are provided with connecting flanges 12Aa and 12Ba at their openings. The case main body 12 has a cylindrical upper portion partially closed by a top plate 12C and a cylindrical lower portion closed by a bottom plate 12D.

  The accommodating part 13 of the casing 11 is formed in a cylindrical shape, and in this embodiment, as shown in FIGS. 4 and 5, it is formed in a circular cylindrical shape in plan view. The accommodating portion 13 is arranged in a cylindrical shape of the case main body 12 so as to be biased toward one of the oval circular sides of the case main body 12 and is formed with a part of the one circular shape. In addition, the upper end of the accommodating portion 13 is connected to the top plate 12 </ b> C of the case main body 12, and the connecting portion is formed as an opening 12 </ b> E that can open the upper portion of the case main body 12. In addition, the lower end of the housing portion 13 is provided away from the bottom plate 12D of the case body 12. Further, in the accommodating portion 13, the inlet pipe 12 </ b> A is connected to a portion of the case body 12 formed with a part of one of the oval circles. Accordingly, the inlet pipe 12A is connected to the inside of the case body 12 via the accommodating portion 13 and communicates with the outlet pipe 12B. In addition, the accommodating portion 13 is provided with an annular plate-shaped latching portion 13 </ b> A in the cylindrical shape at a position below the inlet pipe 12 </ b> A. In addition, the bottom plate 12D of the case body 12 with the center of the housing portion 13 provided with a housing support base 13B having an insertion hole 13Ba facing upward.

  The lid 14 of the casing 11 is detachably attached to the top plate 12C of the case body 12 with a plurality of bolts 14A and the like, and can open and close an opening 12E that can open the upper part of the case body 12. . That is, by attaching the lid 14, the upper position of the housing part 13 is closed, and a flow path is formed as the casing 11 from the inlet pipe 12 </ b> A to the outlet pipe 12 </ b> B through the case body 12 through the housing part 13. . On the other hand, the upper position of the accommodating portion 13 is opened by removing the lid 14.

  In the casing 11 described above, a shield 15 may be provided. The shield 15 is configured to shield radiation by a metal plate, a water storage container, a mercury storage container, or the like formed of, for example, lead or tungsten. As shown in FIG. 3, the shield 15 is provided so as to mainly cover the cylindrical periphery of the case body 12. Although not shown in the drawing, the shield 15 may be provided so as to cover the top surface of the top plate 12C (including the lid 14), and when the bottom plate 12D is raised by a leg or the like without being grounded. You may provide so that the lower surface of this baseplate 12D may be covered.

  As shown in FIGS. 3 and 5 to 7, in the radioactive filter unit 21, a filter case 23 is held in a filter case 22. The filter case 22 of the radioactive filter unit 21 includes a top plate 22A, a bottom plate 22B, and a support 22C. The top plate 22A and the bottom plate 22B are formed in a disc shape, and their centers are connected by a support column 22C. The top plate 22 </ b> A is formed to have an outer diameter larger than the inner diameter of the annular plate-shaped hooking portion 13 </ b> A in the housing portion 13, and is provided to be hooked on the inner edge of the hooking portion 13 </ b> A. The top plate 22A has a through hole 22Aa at the center. The bottom plate 22B closes the bottom of the filter case 22. The bottom plate 22B is formed to have an outer diameter smaller than the inner diameter of the annular plate-shaped latching portion 13A in the accommodating portion 13, and is provided so as to pass through the latching portion 13A. Yes. When the lower end of the column 22C extends through the bottom plate 22B and the top plate 22A is hooked on the latching portion 13A, the column 22C is inserted into the insertion hole 13Ba of the housing support 13B. That is, the filter case 22 is supported by the top plate 22A with a height position determined in the storage portion 13, and the horizontal position is determined and supported by the support column 22C. As shown in FIG. 3, the filter case 22 includes a through hole 22 </ b> Aa of the top plate 22 </ b> A and a space between the top plate 22 </ b> A and the bottom plate 22 </ b> B in the casing 11 from the inlet pipe 12 </ b> A through the housing portion 13. 12 is interposed in the flow passage leading to the outlet pipe 12B. On the other hand, the filter case 22 is lifted upward, so that the column 22C is removed from the insertion hole 13Ba of the housing support 13B, and the top plate 22A is separated from the latching portion 13A and from the opening 12E of the case body 12 in the casing 11. It can be taken out of the casing 11. Attachment and removal of the filter case 22 from the casing 11 can be performed by the crane device 102 described above.

  The filter part 23 of the radioactive filter unit 21 is formed in a cylindrical shape as shown in FIG. 3, and is held between the top plate 22A and the bottom plate 22B of the filter case 22. The filter portion 23 is provided so that gas can flow between the inside and the outside thereof, the inside of the cylindrical shape passes through the through hole 22Aa of the top plate 22A, and the outside of the cylindrical shape between the top plate 22A and the bottom plate 22B. In the casing 11, it is interposed in the flow path from the inlet pipe 12 </ b> A to the outlet pipe 12 </ b> B through the case body 12 through the housing portion 13.

  The filter unit 23 of the radioactive filter unit 21 includes a radioactive filter 23A. The radioactive filter 23 </ b> A is formed to have a cylindrical shape of the filter portion 23. The radioactive filter 23A adsorbs radioactive iodine and radioactive methyl iodide contained in the gas flowing through the casing 11. Specifically, the radioactive filter 23 </ b> A includes a base material that constitutes a matrix and an attachment substance that is attached to the base material. The material used for the substrate is not particularly limited as long as it has a plurality of pores on the surface, and examples thereof include activated carbon, alumina, zeolite, silica gel, and activated clay. The zeolite may be either natural zeolite or synthetic zeolite. Examples of zeolite include mordenite zeolite. A base material can be used individually or in combination of 2 types or more, respectively. Moreover, the radioactive filter 23A contains triethylenediamine (TEDA: Tri-Ethylene-Di-Amine) or potassium iodide (KI) as an attachment substance. With this configuration, the radioactive filter 23A adsorbs radioactive substances including Cs (cesium) in addition to radioactive iodine and radioactive methyl iodide. The radioactive filter 23A has a multiple structure (double structure in the present embodiment) as shown in FIG. 6, or a single structure having a thickness equivalent to the multiple structure as shown in FIG. It may be done. For example, if the thickness of one of the multiple structures shown in FIG. 6 is 5 cm, the thickness of the single structure shown in FIG. 7 is 10 cm.

  Moreover, the filter part 23 of the radioactive filter unit 21 has the high performance filter 23B. The high performance filter 23B is formed so as to form a cylindrical shape of the filter portion 23. The high performance filter 23B collects particles contained in the gas flowing through the casing 11. As the high-performance filter 23B, for example, a HEPA filter (High Efficiency Particulate Air Filter; removal efficiency of 99.97 [%] when the target particle diameter is 0.15 [μm]) is applied. The high-performance filter 23B includes a first high-performance filter 23B that is disposed inside the cylindrical shape of the radioactive filter 23A, and a second high-performance filter 23B that is disposed outside the cylindrical shape of the radioactive filter 23A. The first high-performance filter 23B collects particles contained in the gas before the gas flowing through the casing 11 reaches the radioactive filter 23A, thereby preventing the radioactive filter 23A from being clogged with the particles and radioactive. The filter function of the filter 23A can be maintained. Further, since the second high-performance filter 23B is made of, for example, activated carbon, alumina, zeolite, silica gel, activated clay, etc., as described above for the radioactive filter 23A, the substrate of the radioactive filter 23A is crushed by some event. In the case of being separated, the crushed pieces can be collected so that the crushed pieces are not released.

  8 and 9 are partially enlarged side sectional views of the filter unit of the radioactive substance removing device according to the present embodiment. The above-described radioactive filter unit 21 can be taken out of the casing 11 together with the filter unit 23 by lifting the filter case 22 upward. 8 and 9 show a configuration in which the radioactive filter 23A and the high-performance filter 23B of the filter unit 23 can be taken out and attached separately.

  As shown in FIG. 8, the high-performance filter 23B of the filter unit 23 is held in the filter case 22 in the same manner as described above. Further, the upper end of the radioactive filter 23 </ b> A of the filter unit 23 is fixed to a partial top plate 22 </ b> Ab that constitutes a part of the top plate 22 </ b> A of the filter case 22. A portion overlapping the top plate 22A is provided on the partial top plate 22Ab, and a seal member (for example, a Y-shaped seal) 24 is disposed corresponding to the overlapping portion. Further, the radioactive filter 23A of the filter unit 23 has a seal member (for example, Y-shaped seal) 24 disposed at the lower end thereof corresponding to the upper surface of the bottom plate 22B. Thereby, only the radioactive filter 23 </ b> A of the filter unit 23 can be lifted and removed from or attached to the casing 11.

  Further, as shown in FIG. 9, the second high performance filter 23B of the filter unit 23 is held in the filter case 22 in the same manner as described above. Further, the upper end of the radioactive filter 23 </ b> A of the filter unit 23 is fixed to a partial top plate 22 </ b> Ab that constitutes a part of the top plate 22 </ b> A of the filter case 22. A portion overlapping the top plate 22A is provided on the partial top plate 22Ab, and a seal member (for example, a Y-shaped seal) 24 is disposed corresponding to the overlapping portion. Further, a seal member (for example, a Y-shaped seal) 24 is disposed on the lower end portion of the radioactive filter 23A of the filter portion 23 corresponding to the upper surface of the bottom plate 22B. The upper end of the first high-performance filter 23B of the filter unit 23 is fixed to a partial top plate 22Ab that constitutes a part of the top plate 22A of the filter case 22. A portion overlapping the partial top plate 22Ab of the radioactive filter 23A is provided on the partial top plate 22Ab, and a seal member (for example, a Y-shaped seal) 24 is disposed corresponding to the overlapping portion. Further, a seal member (for example, a Y-shaped seal) 24 is disposed at the lower end portion of the first high-performance filter 23B of the filter portion 23 so as to correspond to the upper surface of the bottom plate 22B. Thereby, the 1st high performance filter 23B of the filter part 23 and the radioactive filter 23A can be taken out with respect to the casing 11, or can be attached to it by lifting up.

  FIG. 10 is a side sectional view of the heating unit of the radioactive substance removing device according to this embodiment. In the heating device 2, a heating unit 26 shown in FIG. 10 is accommodated in a casing 11 (see FIGS. 1 and 2) having the same structure as the casing 11 of the radioactive substance removing device 1. In the heating unit 26 of the heating device 2, a heating unit 27 is held in the heating case 22 having the same structure as the filter case 22 of the radioactive filter unit 21. The heating case 22 is denoted by the same reference numeral as the filter case 22 and the description thereof is omitted. The heating unit 27 is formed in a cylindrical shape, and is held between the top plate 22 </ b> A and the bottom plate 22 </ b> B of the heating case 22. The heating unit 27 is provided so that gas can flow between the inner side and the outer side thereof, the cylindrical inner side passes through the through hole 22Aa of the top plate 22A, and the cylindrical outer side between the top plate 22A and the bottom plate 22B. In the casing 11, it is interposed in the flow path from the inlet pipe 12 </ b> A to the outlet pipe 12 </ b> B through the case body 12 through the housing portion 13. The heating unit 27 is not limited as long as it heats the circulating gas. For example, a configuration in which a plurality of thin plates are arranged with a gap therebetween and the circulating gas is heated by heating the thin plates. and so on. The heating unit 26 can be taken out of the casing 11 together with the heating unit 27 by lifting the filter case 22 upward.

  FIG. 11 is a side sectional view of the volcanic ash filter unit of the radioactive substance removing device according to this embodiment. In the volcanic ash removal device 3, a volcanic ash filter unit 28 shown in FIG. 11 is accommodated in a casing 11 (see FIGS. 1 and 2) having the same structure as the casing 11 of the radioactive substance removal device 1. The volcanic ash filter unit 28 of the volcanic ash removal device 3 has a filter portion 29 held in a filter case 22 having the same structure as the filter case 22 of the radioactive filter unit 21. The filter portion 29 is formed in a cylindrical shape and is held between the top plate 22A and the bottom plate 22B of the filter case 22 and held. The filter portion 29 is provided so that gas can flow between the inside and the outside thereof, the inside of the cylindrical shape passes through the through hole 22Aa of the top plate 22A, and the outside of the cylindrical shape is between the top plate 22A and the bottom plate 22B. In the casing 11, it is interposed in the flow path from the inlet pipe 12 </ b> A to the outlet pipe 12 </ b> B through the case body 12 through the housing portion 13.

  The filter unit 29 of the volcanic ash filter unit 28 includes a volcanic ash filter 29A. The volcanic ash filter 29 </ b> A is formed to have a cylindrical shape of the filter portion 29. This volcanic ash filter 29 </ b> A collects particles similar to volcanic ash contained in the gas flowing through the inside of the casing 11. As the volcanic ash filter 29A, for example, a coarse filter, that is, a medium-performance particulate filter or a high-performance filter having a slightly larger collected particle diameter than a high-performance filter is applied.

  The filter unit 29 of the volcanic ash filter unit 28 includes a coarse filter 29B. The coarse filter 29 </ b> B is formed so as to form a cylindrical shape of the filter portion 29. The coarse filter 29B collects coarse particles (such as dust) contained in the gas flowing through the casing 11. As the coarse filter 29B, for example, an air filtration filter having a target particle diameter of 50 [μm] or more, or a medium-high performance filter having a target particle diameter of 25 [μm] or more is applied. The coarse filter 29B is arranged inside the volcanic ash filter 29A. The coarse filter 29B collects coarse particles contained in the gas before the gas flowing through the casing 11 reaches the volcanic ash filter 29A, thereby preventing the volcanic ash filter 29A from being clogged with the particles, thereby preventing the volcanic ash filter 29A. The filter function can be maintained.

  The filter unit 29 of the volcanic ash filter unit 28 includes a high-performance filter 29C. The high-performance filter 29C is formed so as to form a cylindrical shape of the filter portion 29. The high performance filter 29C collects particles contained in the gas flowing through the inside of the casing 11. As the high-performance filter 23B, for example, a HEPA filter (High Efficiency Particulate Air Filter; removal efficiency of 99.97 [%] when the target particle diameter is 0.15 [μm]) is applied. And the high performance filter 29C is arrange | positioned at the cylindrical outer side of the volcanic ash filter 29A. The high performance filter 29C collects particles that have passed through the volcanic ash filter 29A.

  12 and 13 are partially enlarged side sectional views of the volcanic ash filter unit of the radioactive substance removing device according to the present embodiment. The volcanic ash filter unit 28 described above can be taken out of the casing 11 together with the filter portion 29 by lifting the filter case 22 upward. 12 and 13 show a configuration in which the volcanic ash filter 29A of the filter unit 29 and the other filters 29B and 29C can be taken out and attached separately.

  As shown in FIG. 12, the coarse filter 29B and the high-performance filter 29C of the filter unit 29 are held in the filter case 22 in the same manner as described above. The volcanic ash filter 29 </ b> A of the filter unit 29 has an upper end fixed to a partial top plate 22 </ b> Ab that constitutes a part of the top plate 22 </ b> A of the filter case 22. A portion overlapping the top plate 22A is provided on the partial top plate 22Ab, and a seal member (for example, a Y-shaped seal) 24 is disposed corresponding to the overlapping portion. Further, the volcanic ash filter 29A of the filter unit 29 has a seal member (for example, Y-shaped seal) 24 disposed at the lower end thereof corresponding to the upper surface of the bottom plate 22B. Thus, only the volcanic ash filter 29 </ b> A of the filter unit 29 can be lifted upward and removed from or attached to the casing 11.

  As shown in FIG. 13, the high-performance filter 29C of the filter unit 29 is held in the filter case 22 in the same manner as described above. The volcanic ash filter 29 </ b> A of the filter unit 29 has an upper end fixed to a partial top plate 22 </ b> Ab that constitutes a part of the top plate 22 </ b> A of the filter case 22. A portion overlapping the top plate 22A is provided on the partial top plate 22Ab, and a seal member (for example, a Y-shaped seal) 24 is disposed corresponding to the overlapping portion. Further, a seal member (for example, a Y-shaped seal) 24 is disposed at the lower end of the volcanic ash filter 29A of the filter unit 29 corresponding to the upper surface of the bottom plate 22B. The coarse filter 29B of the filter unit 29 has an upper end fixed to a partial top plate 22Ab constituting a part of the top plate 22A of the filter case 22. A portion overlapping the partial top plate 22Ab of the radioactive filter 23A is provided on the partial top plate 22Ab, and a seal member (for example, a Y-shaped seal) 24 is disposed corresponding to the overlapping portion. Further, a seal member (for example, Y-shaped seal) 24 is disposed at the lower end portion of the coarse filter 29B of the filter portion 29 corresponding to the upper surface of the bottom plate 22B. Thereby, the coarse filter 29B of the filter part 29 and the volcanic ash filter 29A can be lifted upward and removed from or attached to the casing 11.

  As described above, the radioactive substance removing device 1 of the present embodiment has a radioactive filter unit 21 having a cylindrically formed radioactive filter 23A that can adsorb and remove radioactive iodine and radioactive methyl iodide contained in gas. And a casing 11 that accommodates the radioactive filter unit 21 and forms a flow path through which gas can flow from the cylindrical inner side to the outer side of the radioactive filter 23A.

  According to this radioactive substance removing device 1, since the gas is circulated from the inner side to the outer side of the cylindrical shape of the radioactive filter 23A, most of the radioactive iodine and radioactive methyl iodide are adsorbed on the inner side of the cylindrical shape of the radioactive filter 23A. Since it is removed, the amount of radiation emitted outside the cylindrical shape of the radioactive filter 23A is reduced. As a result, it is possible to prevent exposure to radiation outside the casing 11 and to prevent the radiation emitted from the radioactive filter 23 </ b> A from affecting the outside of the casing 11.

  Moreover, in the radioactive substance removal apparatus 1 of this embodiment, the radioactive filter unit 21 is the 1st arrange | positioned inside the cylindrical shape of the radioactive filter 23A which can collect the particle | grains contained in gas and is formed in a cylindrical shape. The casing 11 has a high-performance filter 23B and a second high-performance filter 23B that is capable of collecting particles contained in the gas and is formed in a cylindrical shape and disposed outside the cylindrical shape of the radioactive filter 23A. The radioactive filter 23A and each high-performance filter 23B are accommodated inside, and the gas can flow from the cylindrical inside of the first high-performance filter 23B through the radioactive filter 23A to the cylindrical outside of the second high-performance filter 23B. Form a road.

  According to this radioactive substance removing device 1, a part of the radioactive substance is collected together with particles contained in the gas from the first high-performance filter 23B inside the cylindrical shape of the radioactive filter 23A. The amount of radiation emitted outside the tube is further reduced. As a result, it is possible to further prevent a situation where the outside of the casing 11 is exposed to radiation, and to assist the effect of preventing the radiation emitted from the radioactive filter 23 </ b> A from affecting the outside of the casing 11. And since a part of radioactive substance is collected with the particle | grains contained in gas from the 1st high performance filter 23B, the filter function of 23 A of radioactive filters can be maintained. Furthermore, since the particles separated from the radioactive filter 23A are collected by the second high-performance filter 23B, the radiation emission amount on the outside of the cylindrical shape of the radioactive filter 23A is further reduced. As a result, it is possible to further prevent a situation where the outside of the casing 11 is exposed to radiation, and to assist the effect of preventing the radiation emitted from the radioactive filter 23 </ b> A from affecting the outside of the casing 11.

  In addition, the radioactive substance removing device 1 of the present embodiment includes a shield 15 that is configured to shield radiation and is disposed around the casing 11.

  According to the radioactive substance removing device 1, the shield 15 further prevents the situation of being exposed to radiation outside the casing 11, and prevents the radiation emitted from the radioactive filter 23A from affecting the outside of the casing 11. Can help.

  Moreover, in the radioactive substance removal apparatus 1 of this embodiment, the radioactive filter unit 21 sets the radioactive filter 23A formed in the cylindrical shape to a multiple structure or a thickness equivalent to the multiple structure.

  The adsorption removal performance of radioactive iodine and radioactive methyl iodide by the radioactive filter 23A is proportional to the thickness of the flow direction of the gas to the radioactive filter 23A in a logarithmic manner. 1-removal efficiency [%] / 100) is reduced, it is possible to improve the removal efficiency of radioactive gas by providing the radioactive filter 23A with a multiple structure, and the thickness of a single structure is equivalent to the multiple structure. If the thickness is increased, the size of the apparatus can be reduced while improving the performance of the radioactive filter unit 21 by the interval of the multiple structure.

  Moreover, in the radioactive substance removal apparatus 1 of this embodiment, the casing 11 has the opening part 12E which can open | release the upper position of the radioactive filter unit 21 to accommodate, and the cover body 14 which can open and close the said opening part 12E, and is radioactive. The filter unit 21 is provided so as to be movable in the vertical direction with respect to the casing 11, and is provided so as to be able to pass through the opening 12E.

  According to this radioactive substance removing device 1, when exchanging the radioactive filter unit 21, the radioactive filter unit 21 is moved upward and taken out from the opening 12 </ b> E of the casing 11, so that the radioactive filter unit 21 is placed outside the cylindrical shape of the radioactive filter unit 21. In order to prevent the worker from approaching, the influence of the radiation emitted from the radioactive filter 23A on the outside of the casing 11 can be prevented.

  Moreover, the radioactive substance removal system 100 of this embodiment has the casing 11 of the same structure as the radioactive substance removal apparatus 1 mentioned above and the casing 11 of the radioactive substance removal apparatus 1, and heats the gas distribute | circulated in the said casing 11 Each casing with the heating device 2 as an upstream in a state in which the heating device 2 that accommodates the heating unit 26 that is formed in a cylindrical shape and the casing 11 of the radioactive substance removing device 1 and the casing 11 of the heating device 2 are connected to each other. 11 is provided with a radioactive gas removal system S including a blower 4 for circulating gas.

  According to this radioactive substance removal system 100, by arranging the heating device 2 upstream of the radioactive substance removal apparatus 1, the influence of moisture on the radioactive filter 23A of the radioactive substance removal apparatus 1 is suppressed, and the radioactive filter 23A The adsorption performance of radioactive iodine and radioactive methyl iodide can be improved. Moreover, by making the casing 11 of the heating device 2 the same structure as the casing 11 of the radioactive substance removing device 1, the heating device 2 can be configured simply by changing the heating unit 26, and the system can be easily constructed. it can.

  Moreover, in the radioactive substance removal system 100 of this embodiment, the radioactive gas removal system | strain S has the casing 11 of the same structure as the casing 11 of the radioactive substance removal apparatus 1, and volcanic ash contained in the gas distribute | circulated in the said casing 11 The volcanic ash removing device 3 that accommodates the volcanic ash filter unit 28 that is formed in a cylindrical shape and can be removed, and the casing 11 of the volcanic ash removing device 3 is connected to the casing 11 of the heating device 2. Gas is circulated through each casing 11 with 3 as an upstream.

  According to the radioactive substance removing system 100, the volcanic ash removing device 3 is arranged upstream of the radioactive substance removing device 1, so that the radioactive substance removing device 1 mainly uses the volcanic ash applied to the first high-performance filter 23B as a filter. Suppression of clogging and the like can be suppressed, and the radioactive substance removal performance can be improved. Moreover, by making the casing 11 of the volcanic ash removal device 3 the same structure as the casing 11 of the radioactive substance removal device 1, the volcanic ash removal device 3 can be configured simply by replacing the volcanic ash filter unit 28, and system construction is facilitated. It can be carried out.

  In the radioactive substance removal system 100 of this embodiment, the radioactive gas removal system S is connected to a plurality of radioactive substance removal apparatuses 1.

  According to this radioactive substance removing system 100, even if the function of one radioactive substance removing apparatus 1 is lowered by connecting a plurality of radioactive substance removing apparatuses 1, the other radioactive substance removing apparatus 1 can remove radioactive gas. Can be maintained.

  In the radioactive substance removal system 100 of the present embodiment, a plurality of radioactive gas removal systems S are arranged in parallel.

  According to this radioactive substance removal system 100, when a plurality of radioactive gas removal systems S are arranged in parallel, for example, when the radioactive filter unit 21 of the radioactive substance removal apparatus 1 in one radioactive gas removal system S is replaced, The radioactive gas removal system S can continue the radioactive gas removal action.

DESCRIPTION OF SYMBOLS 1 Radioactive substance removal apparatus 2 Heating apparatus 3 Volcanic ash removal apparatus 4 Blower 11 Casing 12 Case main body 12E Opening part 14 Cover body 15 Shielding body 21 Radioactive filter unit 23A Radioactive filter 23B High performance filter (1st high performance filter, 2nd high performance) filter)
26 Heating unit 28 Volcanic ash filter unit 100 Radioactive substance removal system S Radioactive gas removal system

Claims (9)

A radioactive filter unit having a radioactive filter formed in a cylindrical shape capable of adsorbing and removing radioactive iodine and radioactive methyl iodide contained in a gas;
A casing that houses the radioactive filter unit and forms a flow path through which gas can flow from the inside to the outside of the cylindrical shape of the radioactive filter;
The radioactive substance removal apparatus characterized by including. The radioactive filter unit is
A first high performance filter that is capable of collecting particles contained in the gas and is formed in a cylindrical shape and disposed inside the cylindrical shape of the radioactive filter;
A second high-performance filter that can collect particles contained in the gas and is formed in a cylindrical shape and disposed outside the cylindrical shape of the radioactive filter;
Have
The casing accommodates the radioactive filter and each of the high-performance filters inside, and gas flows from the cylindrical inside of the first high-performance filter to the cylindrical outside of the second high-performance filter through the radioactive filter. The radioactive substance removing device according to claim 1, wherein a possible flow path is formed.   3. The radioactive substance removing device according to claim 1, further comprising a shield configured to shield radiation and disposed around the casing. 4. The radioactive filter unit is
The radioactive substance removing device according to any one of claims 1 to 3, wherein the radioactive filter formed in a cylindrical shape has a multiple structure or a thickness equivalent to the multiple structure. The casing has an opening capable of opening an upper position of the radioactive filter unit to be accommodated, and a lid capable of opening and closing the opening.
The radioactive substance according to any one of claims 1 to 4, wherein the radioactive filter unit is provided so as to be movable in a vertical direction with respect to the casing and is capable of passing through the opening. Removal device. The radioactive substance removing device according to any one of claims 1 to 5,
A heating device having a casing having the same structure as the casing of the radioactive substance removing device, and containing a heating unit formed in a cylindrical shape capable of heating the gas flowing in the casing;
A blower that circulates gas to each casing with the heating device as an upstream in a state where the casing of the radioactive substance removing device and the casing of the heating device are connected;
A radioactive substance removal system comprising: a radioactive gas removal system comprising: The radioactive gas removal system is:
A volcanic ash removal device that has a casing having the same structure as the casing of the radioactive substance removal device, and that accommodates a volcanic ash filter unit that is formed in a cylindrical shape and capable of removing volcanic ash contained in the gas flowing in the casing. Including
The radioactive substance removal system according to claim 6, wherein gas is circulated through each casing with the volcanic ash removal device as an upstream in a state where the casing of the volcanic ash removal device is connected to the casing of the heating device. .   The radioactive substance removal system according to claim 6 or 7, wherein a plurality of the radioactive substance removal devices are connected to the radioactive gas removal system.   The radioactive substance removal system according to claim 6, wherein a plurality of the radioactive gas removal systems are arranged in parallel.

Images