JP2018069134A - Toxic gas removal unit, toxic gas removal facility, and vehicle - Google Patents

Abstract

PROBLEM TO BE SOLVED: To nullify toxic gas generated from various pharmaceuticals to a human body.SOLUTION: A toxic gas removal unit has a flow passage 2 having secured airtightness, by linking singly a fluid inlet 2a to a fluid outlet 2b, an acid gas removal part 3 for adhering and removing acid gas, a basic gas removal part 4 for adhering and removing basic gas, and an organic gas removal part 5 for adhering and removing organic gas. The organic gas removal part 5 is positioned on the fluid outlet 2b side in the flow passage 2, and respective removal parts 3, 4, 5 are arranged in series from the fluid inlet 2a side toward the fluid outlet 2b side.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a toxic gas removal unit, a toxic gas removal facility, and a vehicle.

  Conventionally, for example, Patent Document 1 discloses that acid gas and / or basic gas is collected and removed in a clean room. For example, Patent Document 2 discloses an air treatment system that provides filtration of harmful gas (for example, ammonia).

  Further, for example, Patent Documents 3 to 5 disclose prevention of introduction of toxic gas into the vehicle interior.

Japanese Patent No. 3830533 Special table 2009-514658 gazette JP 2008-167900 A Japanese Patent No. 4682949 Japanese Patent No. 4682950

  By the way, many chemical tanks are installed in the nuclear power plant, and various chemicals necessary for the operation of the nuclear power plant are held in these chemical tanks. In addition, in nuclear power plants, mobile equipment such as tank trucks that carry chemicals to chemical tanks pass. Therefore, in nuclear power plants, it is necessary to ensure the safety of human bodies even if these chemical tanks and mobile equipment are destroyed by earthquakes, tornadoes, accidents, etc., and chemicals are released into the atmosphere. .

  This invention solves the subject mentioned above, and aims at providing the poisonous gas removal unit, the poisonous gas removal equipment, and vehicle which can invalidate the poisonous gas which generate | occur | produces with various chemical | medical agents with respect to a human body. To do.

  In order to achieve the above-described object, a toxic gas removal unit according to one aspect of the present invention includes a flow path in which a fluid inlet and a fluid outlet are connected to each other to ensure airtightness, and an acidic gas that adsorbs and removes acidic gas. A gas removal unit, a basic gas removal unit that adsorbs and removes a basic gas, and an organic gas removal unit that adsorbs and removes an organic gas, and the organic gas removal unit is disposed in the flow passage. The removal portions are arranged in series from the fluid inlet side toward the fluid outlet side on the fluid outlet side.

  According to this toxic gas removal unit, the organic gas removal part is set as the fluid outlet side in the flow passage, and the removal parts are arranged in series from the fluid inlet side to the fluid outlet side, so that they are contained in the toxic gas. The acidic component, basic component, and organic component are sequentially removed. The acid gas removal unit and the basic gas removal unit are more likely to adsorb components than the organic gas removal unit, and the acid gas removal unit and the basic gas removal unit are more effective in gas flow than the organic gas removal unit. By disposing on the upstream side, the adsorption performance of each component of the toxic gas can be enhanced. As a result, toxic gas generated by various chemicals can be invalidated for the human body.

  In the toxic gas removal unit according to one aspect of the present invention, the acidic gas removal unit, the basic gas removal unit, and the organic gas removal from the fluid inlet side toward the fluid outlet side in the flow passage. It is preferable to arrange them in series in the order of the parts.

  According to this toxic gas removal unit, the acidic gas removal unit is easier to adsorb components than the basic gas removal unit, and the acidic gas removal unit is more gas-reactive than the basic gas removal unit or the organic gas removal unit. By arrange | positioning in the upstream of a flow, the adsorption | suction performance of each component of toxic gas can be improved more. As a result, the effect of invalidating the toxic gas generated by various chemicals to the human body can be remarkably obtained.

  In the toxic gas removal unit according to one aspect of the present invention, it is preferable that a toxic gas detection unit that detects acid gas, basic gas, and organic gas is provided at the fluid inlet of the flow passage.

  According to this toxic gas removal unit, it is possible to recognize the presence or absence of toxic gas by having the toxic gas detection unit at the fluid inlet of the flow passage, thereby determining whether or not to use the toxic gas removal unit. be able to.

  In the toxic gas removal unit according to one aspect of the present invention, it is preferable that a toxic gas detection unit that detects acid gas, basic gas, and organic gas is provided at the fluid outlet of the flow passage.

  According to this toxic gas removal unit, since the toxic gas detection unit is also provided at the fluid outlet of the flow passage, the toxic gas removal unit functions appropriately in addition to the detection of the toxic gas by the toxic gas detection unit on the fluid inlet side. It can be determined whether or not.

  Further, in the toxic gas removal unit according to one aspect of the present invention, the radioactive gas removal unit that adsorbs and removes the radioactive gas is provided within the flow passage through the high-performance filter that collects particles contained in the gas. It is preferable to arrange | position to the said fluid exit side rather than a property gas removal part.

  According to this toxic gas removal unit, the radioactive substance can be removed after the adsorption of each component of the toxic gas.

  In order to achieve the above-described object, a toxic gas removal facility according to one aspect of the present invention includes a fluid outlet of the toxic gas removal unit according to any one of the above-described devices connected to a room, and the toxic gas removal device. It is preferable that a blower for introducing gas from the fluid inlet of the unit to the fluid outlet is connected.

  According to this toxic gas removal facility, the toxic gas removal unit can invalidate the toxic gas to the human body and supply this gas to the room.

  In order to achieve the above object, a toxic gas removal facility according to one aspect of the present invention includes the toxic gas removal unit according to any one of the above, and a radioactive gas removal unit that adsorbs and removes the radioactive gas. A fluid outlet of the toxic gas removal unit is connected to a fluid inlet of the radioactive gas removal unit through a high performance filter that collects particles contained in the gas, and the fluid outlet of the radioactive gas removal unit A blower is connected to the room and introduces gas from the fluid inlet of the toxic gas removal unit to the fluid outlet and from the fluid inlet of the radioactive gas removal unit to the fluid outlet.

  According to this toxic gas removal facility, radioactive substances can be removed while invalidating the toxic gas to the human body, and this gas can be supplied to the room.

  In order to achieve the above-mentioned object, a vehicle according to one aspect of the present invention has a fluid outlet of the toxic gas removal unit according to any one of the above-described aspects connected to a vehicle compartment, and the toxic gas removal unit includes: A blower is provided that sends gas from the fluid inlet to the fluid outlet to maintain the interior of the vehicle interior at a positive pressure relative to the exterior of the vehicle interior.

  According to this vehicle, even if toxic gas (and radioactive gas) is contained in the gas outside the passenger compartment, the toxic gas (and radioactive gas) can be prevented from entering the passenger compartment. As a result, toxic gas (and radioactive gas) generated by various chemicals can be invalidated to the human body, and people and cargo can be safely carried.

  The vehicle according to one aspect of the present invention preferably includes an air lock chamber having an interior door that is opened and closed with respect to the interior of the vehicle and an exterior door that is opened and closed with respect to the exterior of the interior of the vehicle.

  According to this vehicle, the air lock chamber alternately opens and closes the vehicle interior door and the vehicle exterior door, thereby preventing external gas from entering the interior when a person enters or exits. As a result, people can safely enter and leave the passenger compartment.

  Further, in the vehicle according to the aspect of the present invention, when the air conditioner that harmonizes the air in the vehicle interior and the toxic gas removal unit are used, the operation of the air conditioner is stopped or circulated in the vehicle interior. It is preferable to provide a control unit for performing the operation.

  According to this vehicle, the control unit performs control to stop the operation of the air conditioner or circulate the vehicle interior when using the toxic gas removal unit. As a result, it is possible to automatically prevent the toxic gas from entering the interior of the passenger compartment.

  According to the present invention, toxic gas generated by various chemicals can be invalidated for the human body.

FIG. 1 is a cross-sectional view of a toxic gas removal unit according to an embodiment of the present invention. FIG. 2 is a perspective view showing a part of the toxic gas removal unit according to the embodiment of the present invention. FIG. 3 is a cross-sectional view showing a part of the toxic gas removal unit according to the embodiment of the present invention. FIG. 4 is a schematic view of another example of the toxic gas removal unit according to the embodiment of the present invention. FIG. 5 is a schematic view of another example of the toxic gas removal unit according to the embodiment of the present invention. FIG. 6 is a schematic view of another example of the toxic gas removal unit according to the embodiment of the present invention. FIG. 7 is a configuration diagram of the toxic gas removal facility according to the embodiment of the present invention. FIG. 8 is a configuration diagram of another example of the toxic gas removal facility according to the embodiment of the present invention. FIG. 9 is a configuration diagram of another example of the toxic gas removal facility according to the embodiment of the present invention. FIG. 10 is a schematic view showing a part of the toxic gas removal facility shown in FIG. FIG. 11 is a schematic view showing a part of the toxic gas removal facility shown in FIG. FIG. 12 is a configuration diagram of a vehicle 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 sectional view of a toxic gas removal unit according to this embodiment. FIG. 2 is a perspective view showing a part of the toxic gas removal unit according to the present embodiment. FIG. 3 is a cross-sectional view showing a part of the toxic gas removal unit according to the present embodiment. 4 to 6 are schematic views of other examples of the toxic gas removal unit according to the present embodiment.

  As shown in FIG. 1, the toxic gas removal unit 1 of this embodiment includes a flow path 2, an acid gas removal unit 3, a basic gas removal unit 4, an organic gas removal unit 5, and a high-performance filter 6. And including.

  The flow passage 2 allows gas to pass therethrough, and is formed in a cylindrical shape in which one end and the other end are opened and connected to one. One end of the flow passage 2 is configured as a fluid inlet 2a that introduces gas into the cylinder, and the other end is configured as a fluid outlet 2b that discharges gas out of the cylinder. The fluid inlet 2a and the fluid outlet 2b are determined by connecting a blower 15E (see FIG. 7 and the like) to the flow passage 2 to generate a gas flow. In addition, although the flow path 2 is formed in the square cylinder shape in this embodiment, there is no limitation in a cylindrical cross-sectional shape. Moreover, although the flow path 2 is formed in a straight line in the present embodiment, there is no limitation and the flow path 2 may be bent or curved.

  The acid gas removal unit 3 includes a filter 11 and a rack 12. The filter 11 includes a casing 11A and an adsorbent 3A. The casing 11A allows gas to pass inside and outside. Specifically, the casing 11A is formed as a rectangular box as shown in FIGS. The casing 11A is made of a highly rigid metal material, the rectangular side surfaces of the four sides are hermetically closed by the side plate 11Aa, and a part of the upper and lower surfaces are made of an upper and lower surface plate 11Ab made of a porous plate such as punching metal. It has air permeability. That is, the casing 11A allows gas to pass through the upper and lower surface plates 11Ab.

  In this embodiment, the filter 11 is provided with a plurality of casings 11 </ b> A (two in this embodiment) with a vertical spacing. In the filter 11, the space between the rectangular side plates 11Aa is hermetically closed by the closing plate 11Ac between the upper and lower sides of each casing 11A, and only the interval between the remaining side plates 11Aa is left. An opening 11Ad is formed so as to open. The closing plate 11Ac is constituted by a continuous side plate 11Aa of the casing 11A arranged vertically. Accordingly, a plurality of casings 11 </ b> A that are provided at intervals in the vertical direction are integrally configured while maintaining the mutual interval by the mutual side plates 11 </ b> Aa being continuous. Moreover, opening part 11Ad is comprised as a hole opened in the part which mutual side plate 11Aa of casing 11A arrange | positioned up and down was continued.

  Further, in the present embodiment, the filter 11 is formed such that the side plate 11Aa in which the opening 11Ad is formed as a hole projects so as to protrude from both sides and the vertical direction. The projecting side plate 11Aa has an edge piece 11Ae extending on the outer periphery in the opening direction of the opening 11Ad. Further, the protruding side surface plate 11Aa is formed with two gripping portions 11Af that protrude outward in the opening direction of the opening portion 11Ad. That is, it is possible to hold the filter 11 by holding the grip portion 11Af with both hands. In the filter 11 described above, for convenience of explanation, the side plate 11Aa side where the opening 11Ad, the edge piece 11Ae, and the gripping portion 11Af are formed is the front side, and the opposite side plate 11Aa side is the back side, and the front side The side plate 11Aa side between the back side and the back side is defined as the side surface side.

  The adsorbent 3A is accommodated in the casing 11A described above. The adsorbent 3 </ b> A adsorbs acidic components contained in the gas flowing through the flow passage 2. Specifically, the adsorbent 3 </ b> A includes a base material that constitutes the base material and an attachment material that is attached to the base material. Although it does not specifically limit as a material used for a base material, What is necessary is just to have a several pore on the surface, For example, activated carbon, an alumina, a zeolite, a silica gel, activated clay, etc. are mentioned. 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. The base material is formed in a granular shape, a linear shape, or a felt shape. Moreover, an alkaline chemical is applied to the adsorbent 3A as an adhering substance. With this configuration, this adsorbent 3A removes hydrochloric acid, chlorine, and the like as acidic components by reaction adsorption. The adsorbent 3A is formed to have a particle size that allows the base material to be held in the casing 11A without dropping from the holes of the upper and lower surface plates 11Ab having air permeability.

  The rack 12 arrange | positions the filter 11 mentioned above in the flow path 2, as shown in FIG. 1 and FIG. The rack 12 includes a front plate 12A that divides the inside of the flow passage 2 into a fluid inlet 2a side and a fluid outlet 2b side, and a peripheral plate 12B that is provided at the periphery of the front plate 12A and extends along the inner peripheral surface of the flow passage 2. It is comprised as a box which the back of the side opposite to front board 12A opens. In the present embodiment, since the flow passage 2 is formed in a rectangular tube shape, the rack 12 has a front plate 12A formed in a quadrangular shape and a peripheral plate 12B formed in a square shape accordingly. In the rack 12, an insertion hole 12C through which the above-described filter 11 is inserted is formed in the front plate 12A. In the present embodiment, the rack 12 has three insertion holes 12 </ b> C so that a plurality (three in the present embodiment) of the filters 11 can be inserted. The rack 12 is provided with a support member 12D that guides and supports the insertion of the filter 11 inserted through the insertion hole 12C along the front-rear direction, which is the insertion direction of the filter 11, inside the box. Yes. Such a rack 12 is disposed inside the flow passage 2 via a gasket (not shown) so that the space between the peripheral plate 12B and the inner peripheral surface of the flow passage 2 is airtight. Therefore, the rack 12 allows the flow passage 2 to communicate with the fluid inlet 2a side and the fluid outlet 2b side only through the insertion hole 12C formed in the front plate 12A.

  The filter 11 is inserted into the insertion hole 12C of the rack 12 from the back side. And the filter 11 is accommodated in the inside of the rack 12 when the part which protruded in the both sides and the up-down direction in the side plate 11Aa of the front side contacts the front plate 12A of the rack 12. The filter 11 is supported by the rack 12 by fastening the front side plate 11Aa to the front plate 12A of the rack 12 with a bolt. Further, a gasket (not shown) is interposed at a contact portion between the side plate 11 </ b> Aa on the front side of the filter 11 and the front plate 12 </ b> A of the rack 12. Therefore, as shown in FIG. 1, the filter 11 is accommodated in the opening 11Ad, the upper and lower plates 11Ab of the casing 11A, and the casing 11A between the fluid inlet 2a and the fluid outlet 2b with respect to the flow passage 2. Gas is circulated through the adsorbent 3A. In addition, as shown in FIG. 1, the flow direction of the gas in the filter 11 is supplied from the opening 11Ad on the front side when the gas is supplied from the fluid inlet 2a of the flow passage 2 and discharged from the fluid outlet 2b. It passes through the adsorbent 3A, passes up and down, and is discharged to the back. Although not clearly shown in the drawing, the filter 11 is reversed from the rear side with respect to the gas flow direction shown in FIG. Gas passes through the adsorbent 3A in the vertical direction and is discharged from the opening 11Ad on the front side.

  The basic gas removal unit 4 includes a filter 11 and a rack 12, similarly to the acid gas removal unit 3. The description of the filter 11 and the rack 12 is as described above. In the basic gas removal unit 4, the adsorbent 4 </ b> A (see FIG. 3) is accommodated in the casing 11 </ b> A of the filter 11. The adsorbent 4 </ b> A adsorbs a basic component contained in the gas flowing through the flow passage 2. Specifically, the adsorbent 4 </ b> A includes a base material that constitutes the base material and an attachment material that is attached to the base material. Although it does not specifically limit as a material used for a base material, What is necessary is just to have a several pore on the surface, For example, activated carbon, an alumina, a zeolite, a silica gel, activated clay, etc. are mentioned. 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. The base material is formed in a granular shape, a linear shape, or a felt shape. Further, an acidic chemical is applied to the adsorbent 4A as an attachment material. With this configuration, the adsorbent 4A removes ammonia, hydrazine, and the like as basic components by reaction adsorption. The adsorbent 4A is formed to have a particle size that allows the base material to be held in the casing 11A without dropping from the holes of the upper and lower surface plates 11Ab having air permeability.

  The organic gas removal unit 5 includes a filter 11 and a rack 12, similarly to the acid gas removal unit 3. The description of the filter 11 and the rack 12 is as described above. In the organic gas removal unit 5, the adsorbent 5 </ b> A (see FIG. 3) is accommodated in the casing 11 </ b> A of the filter 11. The adsorbent 5 </ b> A adsorbs a basic component contained in the gas flowing through the flow passage 2. Specifically, the adsorbent 5A includes a base material that constitutes the base. Although it does not specifically limit as a material used for a base material, What is necessary is just to have a several pore on the surface, For example, activated carbon, an alumina, a zeolite, a silica gel, activated clay, etc. are mentioned. 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. The base material is formed in a granular shape, a linear shape, or a felt shape. Further, the adsorbent 5A is an additive-free substance, and removes it by physically adsorbing methanol, ethanolamine or the like as an organic component. The adsorbent 5A is formed to have a particle size that allows the base material to be held in the casing 11A without dropping from the holes of the upper and lower surface plates 11Ab having air permeability.

  As the high-performance filter 6, for example, a high efficiency particulate air filter (HEPA filter) with a target particle diameter of 0.15 μm and a removal efficiency of 99.97% is applied.

  The toxic gas removal unit 1 includes an acid gas removal unit 3, a basic gas removal unit 4, an organic gas removal unit 5, and a high performance filter 6 in the flow passage 2, on the fluid inlet 2 a side. To the fluid outlet 2b side in series. In the toxic gas removal unit 1 of the present embodiment, as shown in FIG. 1, the high performance filters 6 are arranged on the fluid inlet 2 a side and the fluid outlet 2 b side of the flow passage 2. The toxic gas removal unit 1 includes the organic gas removal unit 5 on the fluid outlet 2b side between the high performance filters 6, and the removal units 3, 4, from the fluid inlet 2a side to the fluid outlet 2b side. 5 are arranged in series. In FIG. 1, the toxic gas removal unit 1 includes an acid gas removal unit 3, a basic gas removal unit 4, and an organic gas removal unit between the high performance filters 6 from the fluid inlet 2 a side toward the fluid outlet 2 b side. They are arranged in series in the order of 5. In FIG. 4, the toxic gas removal unit 1 includes a basic gas removal unit 4, an acid gas removal unit 3, and an organic gas between the high performance filters 6 from the fluid inlet 2 a side to the fluid outlet 2 b side. The removal units 5 are arranged in series in the order. In FIG. 5, the toxic gas removal unit 1 includes two acidic gas removal units 3 and two basic gas removal units 4 from the fluid inlet 2a side to the fluid outlet 2b side between the high-performance filters 6. The organic gas removal units 5 are arranged in series in this order. Here, the configurations of the acidic gas removing unit 3 and the basic gas removing unit 4 include the adsorbent 3A that adsorbs the acidic component to the casing 11A in some of the plurality of filters 11 described above, and the rest. In some cases, the adsorbent 4A for adsorbing the basic component is accommodated in the casing 11A. The acidic gas removing unit 3 and the basic gas removing unit 4 are configured such that an adsorbent 3A that adsorbs an acidic component is accommodated in one of the upper and lower casings 11A of the filter 11 described above, and the other of the upper and lower casings 11A. There is also a form in which the adsorbent 4A that adsorbs the basic component is accommodated.

  Therefore, in the toxic gas removal unit 1 of the present embodiment, dust having a particle diameter of 0.15 μm or more is removed from the gas introduced into the flow path 2 from the fluid inlet 2a by the high performance filter 6 on the fluid inlet 2a side. The Thereafter, the acidic component is removed from the gas by the acidic gas removing unit 3, or the basic component is removed by the basic gas removing unit 4, and then the organic component is removed by the organic gas removing unit 5. Further, after that, the dust having a particle diameter of 0.15 μm or more in the adsorbents 3A, 4A, and 5A that has flowed out from the removal portions 3, 4, and 5 is removed by the high-performance filter 6 on the fluid outlet 2b side.

  According to the toxic gas removal unit 1, the organic gas removal unit 5 is set to the fluid outlet 2b side in the flow passage 2, and the removal units 3, 4, and 5 are connected in series from the fluid inlet 2a side to the fluid outlet 2b side. By disposing, the acidic component, basic component, and organic component contained in the toxic gas are sequentially removed. The acidic gas removing unit 3 and the basic gas removing unit 4 are easier to adsorb components than the organic gas removing unit 5, and the acidic gas removing unit 3 and the basic gas removing unit 4 are replaced with the organic gas removing unit 5. In addition, the adsorption performance of each component of the toxic gas can be enhanced by disposing the gas upstream of the gas flow. As a result, toxic gas generated by various chemicals can be invalidated for the human body. In particular, the toxic gas removal unit 1 of the present embodiment is applied as a countermeasure against toxic gas generated at the time of an accident at a nuclear power plant, inside or outside the facility of the nuclear power plant.

  Further, in the toxic gas removal unit 1 of the present embodiment, the acidic gas removal unit 3, the basic gas removal unit 4, and the organic gas removal unit 5 from the fluid inlet 2 a side toward the fluid outlet 2 b side inside the flow passage 2. It is preferable to arrange in series in this order.

  According to the toxic gas removal unit 1, the acid gas removal unit 3 is easier to adsorb components than the basic gas removal unit 4, and the acid gas removal unit 3 is replaced with the basic gas removal unit 4 or the organic gas removal unit. By disposing on the upstream side of the gas flow with respect to the part 5, the adsorption performance of each component of the toxic gas can be further enhanced. As a result, the effect of invalidating the toxic gas generated by various chemicals to the human body can be remarkably obtained.

  Further, in the toxic gas removal unit 1 of the present embodiment, as shown in FIGS. 1, 4, and 5, toxic gas detection that detects acidic gas, basic gas, and organic gas at the fluid inlet 2 a of the flow passage 2. It is preferable to have the part 7A. The toxic gas detection unit 7A detects these components by analyzing the acidic component, basic component, and organic component of the toxic gas contained in the surrounding gas.

  According to this toxic gas removal unit 1, it is possible to recognize the presence or absence of toxic gas by having the toxic gas detection unit 7 </ b> A at the fluid inlet 2 a of the flow passage 2, so that the toxic gas removal unit 1 is used. It can be determined whether or not.

  Further, in the toxic gas removal unit 1 of the present embodiment, as shown in FIGS. 1, 4, and 5, the toxic gas that detects acidic gas, basic gas, and organic gas also at the fluid outlet 2 b of the flow passage 2. It is preferable to have the detection unit 7B. Similarly to the toxic gas detection unit 7A, the toxic gas detection unit 7B detects these components by analyzing the acidic component, basic component, and organic component of the toxic gas contained in the surrounding gas.

  According to the toxic gas removal unit 1, the toxic gas detection unit 7B is also provided at the fluid outlet 2b of the flow passage 2, so that the toxic gas detection can be performed in addition to the detection of the toxic gas by the toxic gas detection unit 7A on the fluid inlet 2a side. It can be determined whether the unit 1 functions properly.

  Further, the toxic gas removal unit 1 of the present embodiment further includes a radioactive gas removal unit 8 as shown in FIG. The radioactive gas removal unit 8 is provided inside the flow passage 2 and further provided on the fluid outlet 2b side through the high performance filter 6 on the fluid outlet 2b side. The radioactive gas removal unit 8 includes a radioactive gas filter 8A and a downstream high-performance filter 8B in order from the fluid inlet 2a side toward the fluid outlet 2b side.

The radioactive gas filter 8 </ b> A includes a filter 11 and a rack 12, similarly to the acidic gas removal unit 3. The description of the filter 11 and the rack 12 is as described above. In this radioactive gas filter 8A, an adsorbent 8Aa (see FIG. 3) is accommodated in the casing 11A of the filter 11. The radioactive gas filter 8A adsorbs radioactive substances contained in the gas. Specifically, the adsorbent 8Aa includes a base material that constitutes the base material and an attachment material 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. The base material is formed in a granular shape, a linear shape, or a felt shape. Moreover, the radioactive gas filter 8A contains triethylenediamine (TEDA: Tri-Ethylene-Di-Amine) or potassium iodide (KI) as an attachment material. This radioactive gas filter 8A has a radioactive substance containing mist-like cesium (Cs), strontium (Sr), etc. in addition to gaseous radioactive iodine (iodine I ₂ , organic iodine CH ₃ I), as described above. By adsorbing, the passage of radioactive gas containing the radioactive substance is blocked.

  As with the high performance filter 6, for example, a HEPA filter (High Efficiency Particulate Air Filter) having a removal efficiency of 99.97% with a target particle diameter of 0.15 μm is applied to the downstream high performance filter 8B.

  Therefore, in the radioactive gas removal unit 8, dust having a particle diameter of 0.15 μm or more in the adsorbents 3A, 4A, and 5A flowing through the high performance filter 6 on the fluid outlet 2b side and flowing out from the removal units 3, 4, and 5 Radioactive material is removed from the removed gas by the radioactive gas filter 8A. Thereafter, dust having a particle diameter of 0.15 μm or more in the adsorbent 8Aa flowing out from the radioactive gas filter 8A is removed by the high performance filter 6 on the fluid outlet 2b side.

  Thus, in the toxic gas removal unit 1 of the present embodiment, the radioactive gas removal unit 8 that adsorbs and removes the radioactive gas is disposed in the flow path 2 via the high-performance filter 6 that collects particles contained in the gas. It is preferable that the organic gas removing unit 5 be disposed on the fluid outlet 2b side.

  According to the toxic gas removal unit 1, radioactive materials can be removed after adsorption of each component of the toxic gas.

  Moreover, in the toxic gas removal unit 1 of this embodiment, as shown in FIG. 6, when the radioactive gas removal unit 8 is provided, the radioactive gas detection unit 8 </ b> C may be provided at the fluid inlet 2 a of the flow passage 2. The radioactive gas detector 8C detects a radioactive gas and includes a gas chromatograph and a gamma ray detector. The radioactive gas detection unit 8C detects the radioactive gas when, for example, the radioactive gas is generated at the time of an accident at the nuclear power plant.

  According to this toxic gas removal unit 1, the presence or absence of radioactive gas can be recognized by having the radioactive gas detection unit 8 </ b> C at the fluid inlet 2 a of the flow passage 2, and thereby the toxic gas including the radioactive gas removal unit 8. It can be determined whether or not the removal unit 1 is used.

  Further, in the toxic gas removal unit 1 of the present embodiment, it is preferable that the fluid outlet 2b of the flow passage 2 also has a radioactive gas detection unit 8D as shown in FIG. The radioactive gas detection unit 8D detects the radioactive gas in the same manner as the radioactive gas detection unit 8C.

  According to this toxic gas removal unit 1, since the fluid outlet 2 b of the flow passage 2 also has the radioactive gas detector 8 </ b> D, in addition to the detection of radioactive gas by the radioactive gas detector 8 </ b> C on the fluid inlet 2 a side, toxic gas removal It can be determined whether or not the radioactive gas removal unit 8 of the unit 1 functions appropriately.

  FIG. 7 is a configuration diagram of the toxic gas removal facility according to the present embodiment. In the toxic gas removal unit 1 described above, when no toxic gas is generated and not used, the fluid inlet 2a and the fluid outlet 2b of the flow passage 2 are closed by a lid (not shown). As shown in FIG. 7, the fluid inlet 2a and the fluid outlet 2b of the flow passage 2 are formed by connecting pipes to which a pipe 14 is connected. Although the connection pipe is not clearly shown in the figure, a flange is provided at the tip, and the lid is attached through the flange, and is joined to the flange on the pipe 14 side by a bolt or the like through the flange. .

  In this toxic gas removal unit 1, the fluid inlet 2 a side of the flow passage 2 is connected to the fan unit 15 by the pipe 14, and the fluid outlet 2 b side of the flow passage 2 is connected to the room 16 by the pipe 14.

  The fan unit 15 has a flow passage 15A similar to the flow passage 2 of the toxic gas removal unit 1, and the vertical filter 15B and the coarse filter are sequentially arranged inside the flow passage 15A from the fluid inlet 15Aa side to the fluid outlet 15Ab side. 15C, the heating part 15D, and the air blower 15E are arrange | positioned. The vertical filter 15B corresponds to the high performance filter 6 of the toxic gas removal unit 1. As the coarse filter 15C, 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 heating unit 15D is, for example, an electric heater, and heats the gas that is circulated inside the flow passage 15A. That is, the heating unit 15D reduces the relative humidity inside the flow passage 15A, suppresses the influence of moisture on the subsequent toxic gas removal unit 1, and improves the performance of the toxic gas removal unit 1. The blower 15E generates a gas flow from the fluid inlet 15Aa side to the fluid outlet 15Ab side of the flow passage 15A. The blower 15 </ b> E also causes a gas flow in the flow passage 2 of the toxic gas removal unit 1. That is, the blower 15E causes a gas flow from the fluid inlet 2a side to the fluid outlet 2b side in the flow passage 2 of the toxic gas removal unit 1, and the gas that has passed through the toxic gas removal unit 1 is introduced into the room 16.

  The room 16 is surrounded by walls, a ceiling, and a floor. This room 16 is, for example, a control room installed in the reactor building for controlling and monitoring the nuclear power plant, a room installed in the reactor building for meeting and living, and an accident at a nuclear power plant. An alternative control room installed outside the reactor building to control and monitor nuclear facilities, etc., an alternative room installed outside the reactor building to hold meetings and live in the event of a nuclear power plant accident, etc. There are emergency rooms for evacuating people who are engaged in nuclear facilities and residents near the nuclear power plant in the event of an accident at a nuclear power plant, and hospitals and nursing care facilities near the nuclear power plant. Although not explicitly shown in the figure, the room 16 is provided with air conditioning equipment for appropriately maintaining the internal temperature and humidity. The room 16 is adjusted so that the internal pressure becomes higher than the external pressure (atmospheric pressure) of the room 16 by the air blown by the blower 15E of the fan unit 15.

  In the toxic gas removal facility shown in FIG. 7, the toxic gas detector 7A may be provided on the fluid inlet 15Aa side of the flow passage 15A in the fan unit 15.

  As described above, in the toxic gas removal facility shown in FIG. 7, the fluid outlet 2b of the toxic gas removal unit 1 is connected to the chamber 16 and gas is introduced from the fluid inlet 2a of the toxic gas removal unit 1 to the fluid outlet 2b. A fan unit 15 (blower 15E) is connected.

  According to such a toxic gas removal facility, the toxic gas removal unit 1 can invalidate the toxic gas to the human body and supply the gas to the room 16.

  Furthermore, according to the toxic gas removal facility of the present embodiment, the toxic gas removal unit 1 includes the radioactive gas removal unit 8, thereby removing the radioactive substance while invalidating the toxic gas to the human body, 16 can be supplied.

  When the toxic gas removal unit 1 includes the radioactive gas removal unit 8, the radioactive gas detection unit 8 </ b> C may be provided on the fluid inlet 15 </ b> Aa side of the flow passage 15 </ b> A in the fan unit 15.

  Moreover, according to the toxic gas removal equipment of this embodiment, when a plurality of toxic gas removal units 1 are prepared, when the function of the used toxic gas removal unit 1 is deteriorated, the unused toxic gas removal unit 1 is put on standby. The poison gas removal unit 1 can be exchanged.

  FIG. 8 is a configuration diagram of another example of the toxic gas removal facility according to the present embodiment. In the toxic gas removal facility shown in FIG. 8, the toxic gas removal unit 1 does not include the radioactive gas removal unit 8, and the radioactive gas removal unit 8 is configured as a radioactive gas removal unit 80 independent of the toxic gas removal unit 1. ing.

  The radioactive gas removal unit 80 is connected between the toxic gas removal unit 1 and the room 16. Therefore, the toxic gas removal facility shown in FIG. 8 includes the toxic gas removal unit 1 and the radioactive gas removal unit 80 that adsorbs and removes the radioactive gas, and collects particles contained in the gas. The fluid outlet 2b of the toxic gas removal unit 1 is connected to the fluid inlet 80a of the radioactive gas removal unit 80 and the fluid outlet 80b of the radioactive gas removal unit 80 is connected to the chamber 16 via the toxic gas removal unit 1 The fan unit 15 (blower 15E) for introducing gas from the fluid inlet 2a to the fluid outlet 2b and the fluid inlet 80a of the radioactive gas removal unit 80 to the fluid outlet 80b is connected.

  According to this toxic gas removal facility, radioactive substances can be removed while invalidating the toxic gas to the human body, and this gas can be supplied to the room 16. In addition, according to this toxic gas removal facility, the toxic gas removal unit 1 and the radioactive gas removal unit 80 are configured as independent units, so either one or both of them are placed in the room 16 depending on the situation. It can be connected and used. Moreover, since the toxic gas removal unit 1 and the radioactive gas removal unit 80 are configured as independent units, they can be replaced for each unit having a reduced function.

  FIG. 9 is a configuration diagram of another example of the toxic gas removal facility according to the present embodiment. 10 and 11 are schematic views showing a part of the toxic gas removal facility shown in FIG.

  In the toxic gas removal facility shown in FIG. 9, a radioactive gas removal unit 80 connected to the fan unit 15 is connected to the room 16 in parallel with the toxic gas removal unit 1 connected to the fan unit 15.

  Furthermore, the toxic gas removal facility shown in FIG. 9 includes an oxygen gas supply means 17, a carbon dioxide removal means 18, and a harmful substance removal means 19 in addition to the above configuration.

  The oxygen gas supply means 17 supplies oxygen gas to the inside of the room 16, and includes, as an oxygen gas storage section, a cylinder that stores compressed oxygen gas and an oxygen generator that generates oxygen. The oxygen gas supply means 17 is connected to the room 16 by a pipe 14 and supplies oxygen gas into the room 16 by opening a flow rate adjusting valve (not shown). The flow rate of the oxygen gas supplied to the room 16 is adjusted by adjusting the flow rate using the flow rate adjustment valve, and the pressure inside the room 16 is adjusted to be higher than the pressure outside the room 16 (atmospheric pressure). Therefore, a pressure detection unit 20 that detects the pressure inside the room 16 is provided in the room 16.

  The carbon dioxide removing means 18 takes in part of the air inside the room 16, removes carbon dioxide in the taken-in air, and sends the air from which the carbon dioxide has been removed to the inside of the room 16.

  For example, as shown in FIG. 10, the carbon dioxide removing means 18 has a casing 18 a that is formed in a cylindrical shape surrounded by an outer wall and has openings on one end side and the other end side. . The carbon dioxide removing means 18 is provided with a carbon dioxide removing filter 18b in the casing 18a. The carbon dioxide removal filter 18b is, for example, an alkali agent such as sodium hydroxide (NaOH) or lithium hydroxide (LiOH), or a carbon dioxide adsorption formed by solidifying a component that easily adsorbs carbon dioxide such as amines. It consists of an agent. Therefore, when air passes through the casing 18a, carbon dioxide in the air is adsorbed and the concentration can be reduced. Although not clearly shown in the figure, the carbon dioxide removing means 18 may be one that allows air to pass through an aqueous solution of sodium hydroxide. The carbon dioxide removing means 18 is connected to the room 16 by a pipe 14 and removes carbon dioxide inside the room 16 by opening an on-off valve (not shown).

  In the room 16, a carbon dioxide concentration detection unit 21 that detects the carbon dioxide concentration in the air inside the room 16 is provided.

The harmful substance removing means 19 takes in part of the air inside the room 16, removes harmful substances harmful to the human body in the taken-in air, and sends the air from which the harmful substances have been removed to the inside of the room 16. . Here, the harmful substances include carbon monoxide (CO) and ammonia (NH ₃ ) generated by humans.

As shown in FIG. 11, the harmful substance removing unit 19 includes a basic component removing unit 19a, a heat exchanging unit 19b, a heating unit 19c, a combustion unit 19d, and an acidic component removing unit 19e. . The basic component removal unit 19a is a cylindrical casing filled with acid-added activated carbon impregnated with an acidic component such as phosphoric acid, and removes basic (alkaline) ammonia gas from the air passing through the inside of the casing. To do. The heat exchange unit 19b includes a heat transfer tube into which low-temperature air that has passed through the basic component removal unit 19a is introduced, and a heat transfer tube into which high-temperature air that has passed through the combustion unit 19d is introduced. By exchanging heat between the heat tubes, heat recovery is performed between the air that has passed through the basic component removal unit 19a and the air that has passed through the combustion unit 19d. The heating unit 19c heats the air that has passed through the heat exchanging unit 19b to a temperature (for example, 300 ° C. or higher) necessary for combustion in the subsequent combustion unit 19d. The combustion unit 19d burns the air heated by the heating unit 19c, thereby burning a harmful gas component contained in a minute amount in the air to produce an acidic gas such as SO ₂ , NOx, and CO ₂ . As the combustion unit 19d, a catalyst combustor filled with a catalyst, a direct combustor using an electric heater, or the like can be selected. The air that has passed through the combustion unit 19d is cooled by the heat exchange unit 19b. The acidic component removing unit 19e is a cylinder-shaped casing filled with basic-added activated carbon with a basic component added, and removes acidic components of air passing through the inside of the casing. That is, the acidic component of the air that has passed through the heat exchange unit 19b is removed. The harmful substance removing means 19 is connected to the room 16 by a pipe 14 and removes toxic substances inside the room 16 by opening an on-off valve (not shown).

  In the room 16, a harmful substance concentration detection unit 22 that detects the harmful substance concentration in the air inside the room 16 is provided.

  Further, in the toxic gas removal facility shown in FIG. 9, the radioactive gas detection unit 8C of the radioactive gas removal unit 8 also functions as a radioactive noble gas detection unit. The radioactive noble gas contains xenon (Xe), krypton (Kr), and the like. The radioactive gas detection unit 8C detects, for example, when radioactive gas is generated at the time of an accident in a nuclear facility, and when the radioactive gas is generated after the fuel in the nuclear reactor is melted, When the detected value of radiation exceeds the detected value of radioactive gas, radioactive noble gas can be detected, and when the detected value of radiation falls below, the radioactive rare gas radiation attenuates and the radioactive noble gas decreases. Can be detected.

  The toxic gas removal facility shown in FIG. 9 is operated as follows. First, when an accident occurs in a nuclear power plant and radioactive noble gas is detected by the radioactive gas detection unit 8D, the blower 15E of each fan unit 15 is not operated, and the toxic gas removal unit 1 and the radioactive gas removal unit 80 are not operated. Gas is not introduced into the room 16, and the oxygen gas supply means 17 is connected to the room 16 so that the inside of the room 16 has a positive pressure. Thereby, oxygen is supplied to the inside of the room 16 in a state where the radioactive gas and the radioactive noble gas are shut off. As a result, it is possible to prevent a person inside the room 16 from being exposed to the radioactive gas or the radioactive noble gas and prevent a person inside the room 16 from breathing.

  In addition, when radioactive gas is detected without detecting the radioactive rare gas by the radioactive gas detection unit 8D, the supply of oxygen by the oxygen gas supply means 17 is stopped, and the blower 15E of the fan unit 15 is operated to release the radioactive gas. Gas through the removal unit 80 is introduced into the room 16. Furthermore, when no radioactive noble gas is detected by the radioactive gas detection unit 8D and no toxic gas is detected by the toxic gas detection unit 7A, the supply of oxygen by the oxygen gas supply means 17 is stopped and the fan of the fan unit 15 is blown. The gas through the toxic gas removal unit 1 is introduced into the room 16 by operating 15E.

  And in the said state when radioactive noble gas is detected by the radioactive gas detection part 8D, when a carbon dioxide concentration exceeds a threshold value (for example, about 3500 ppm or more which normally inhibits human health at about 300 ppm to 390 ppm) The carbon dioxide removal means 18 is connected to the room 16 so that the carbon dioxide concentration inside the room 16 becomes a threshold value (for example, 3500 ppm) or less. As a result, the health of the person inside the room 16 can be maintained.

  Further, in the above-described state where the radioactive gas detection unit 8D detects the radioactive noble gas, the concentration of the harmful substance exceeds a threshold (for example, the concentration of carbon monoxide or ammonia is a concentration that inhibits human health). ), The harmful substance removing means 19 is connected to the room 16 so that the harmful substance concentration inside the room 16 is less than or equal to the threshold value. As a result, the health of the person inside the room 16 can be maintained.

  By the way, when an accident occurs at a nuclear power plant, first, even if no radioactive noble gas is detected by the radioactive gas detection unit 8D, the blower 15E of each fan unit 15 is not operated, and the toxic gas removal unit 1 and the radioactive gas are not operated. Gas may not be introduced from the gas removal unit 80 into the room 16, and the oxygen gas supply means 17 may be connected to the room 16 so that the inside of the room 16 has a positive pressure. This is effective for reliably preventing a person inside the room 16 from being exposed to radioactive gas or radioactive noble gas when an accident occurs at a nuclear power plant.

  FIG. 12 is a configuration diagram of a vehicle according to the present embodiment.

  A vehicle 25 shown in FIG. 12 is a general heavy load vehicle, for example, configured to be able to travel by wheels 25A. The vehicle 25 is provided with a seat 25D other than the driver's seat 25C and a cargo section 25E inside a passenger compartment 25B surrounded by a floor, a wall, and a ceiling. Although not shown in the drawing, the cargo section 25E is loaded with an air cylinder, protective clothing, food, or the like as a safety measure.

  The vehicle 25 is provided with the toxic gas removal unit 1 and the fan unit 15 described above. That is, the fluid outlet 2b of the flow passage 2 in the toxic gas removal unit 1 is connected to the vehicle compartment 25B, and the fan unit 15 is connected to the fluid inlet 2a of the flow passage 2 in the toxic gas removal unit 1 with gas outside the vehicle compartment 25B. Is provided to introduce.

  The toxic gas removal unit 1 has the same configuration as that shown in FIGS. 1 to 6, but is reduced in size when loaded on the vehicle 25. For example, the filter 11 of each removal unit 3, 4, 5 is 1 It is configured as one.

  The fan unit 15 has the same configuration as that shown in FIGS. 7 to 9, but is reduced in size when loaded on the vehicle 25. For example, the fan unit 15 has only the blower 15E. The fan unit 15 is connected to the fluid inlet 2a side of the flow passage 2 in the toxic gas removal unit 1 in FIG. 12, but may be connected to the fluid outlet 2b side. The fan unit 15 sends a gas from the fluid inlet 2a of the flow passage 2 of the toxic gas removal unit 1 to the fluid outlet 2b so that the air volume that can maintain the inside of the passenger compartment 25B at a positive pressure relative to the outside of the passenger compartment 25B The thing of the performance to obtain is applied. The fan unit 15 may obtain power from an engine (not shown) of the vehicle 25. In this embodiment, power is supplied from the battery of the vehicle 25 or a dedicated battery.

  According to this vehicle 25, even if toxic gas (and radioactive gas) is contained in the gas outside the passenger compartment 25B, it is possible to prevent the toxic gas (and radioactive gas) from entering the passenger compartment 25B. . As a result, toxic gas (and radioactive gas) generated by various chemicals can be invalidated to the human body, and people and cargo can be safely carried. Therefore, when toxic gas is generated due to an accident at a nuclear power plant, the vehicle 25 is used as a toxic gas countermeasure mobile vehicle, and is used for transportation of countermeasure personnel, evacuation transportation for nearby residents, transportation of equipment, and the like.

  Further, the vehicle 25 includes an air lock chamber 25F in the passenger compartment 25B. The air lock chamber 25F is provided such that an opening leading to the interior of the vehicle interior 25B can be opened and closed by a vehicle interior door 25Fa. Further, the air lock chamber 25F is provided with an opening that opens to the outside of the vehicle compartment 25B so that it can be opened and closed by the vehicle outer door 25Fb. Since the air lock chamber 25F communicates with the interior of the vehicle compartment 25B through the vehicle interior door 25Fa, the fan unit 15 maintains a positive pressure with respect to the outside of the vehicle compartment 25B in the same manner as the vehicle compartment 25B. Therefore, the air lock chamber 25F prevents the external gas from entering the interior when a person enters or exits by alternately opening and closing the vehicle interior door 25Fa and the vehicle exterior door 25Fb. As a result, people can safely enter and leave the passenger compartment 25B. Note that the vehicle 25 of the present embodiment may be provided with a passenger door 25I through which a person can enter and exit without going through the air lock chamber 25F when no toxic gas exists outside the vehicle compartment 25B.

  The vehicle 25 includes a control unit 25G. The control unit 25G receives a detection signal from the toxic gas detection unit 7A installed outside the passenger compartment 25B. In addition, the control unit 25G starts or stops the operation of the fan unit 15. The control unit 25G operates the fan unit 15 when an acidic component, a basic component, or an organic component is detected by the toxic gas detection unit 7A. As a result, it is possible to automatically prevent the toxic gas from entering the passenger compartment 25B.

  Further, the control unit 25G starts or stops the operation of the air conditioner 25H. The air conditioner 25H harmonizes the air inside the passenger compartment 25B, takes air from the outside of the passenger compartment 25B, circulates the air inside the passenger compartment 25B, and the temperature and humidity of the air. To adjust. Then, when the fan unit 15 is operated to use the toxic gas removal unit 1, the control unit 25G performs control to stop the operation of the air conditioner 25H or to circulate the vehicle interior 25B. As a result, it is possible to automatically prevent the toxic gas from entering the passenger compartment 25B.

  By the way, it is preferable that the vehicle 25 of this embodiment comprises the vehicle interior 25B as a container, and is detachable with respect to the trailer vehicle. By comprising in this way, when toxic gas generate | occur | produces, the compartment 25B of a container can be attached and operated as needed.

DESCRIPTION OF SYMBOLS 1 Toxic gas removal unit 2 Flow path 2a Fluid inlet 2b Fluid outlet 3 Acid gas removal part 4 Basic gas removal part 5 Organic gas removal part 6 High performance filter 7A, 7B Toxic gas detection part 8 Radioactive gas removal part 80 Radioactive gas Removal unit 15 Fan unit 15E Blower 25 Vehicle 25B Car room 25F Air lock room 25Fa Car door 25Fb Car door 25G Control unit 25H Air conditioner

Claims (10)

A fluid passage in which the fluid inlet and the fluid outlet are connected together to ensure airtightness;
An acid gas removal unit that adsorbs and removes the acid gas;
A basic gas removal unit for adsorbing and removing basic gas;
An organic gas removal unit that adsorbs and removes organic gas;
Have
A toxic gas removal unit in which the organic gas removal unit is the fluid outlet side in the flow path, and the removal units are arranged in series from the fluid inlet side to the fluid outlet side.   The acid gas removal unit, the basic gas removal unit, and the organic gas removal unit are arranged in series in the flow path from the fluid inlet side toward the fluid outlet side in this order. Toxic gas removal unit.   The toxic gas removal unit according to claim 1 or 2, further comprising a toxic gas detection unit that detects acid gas, basic gas, and organic gas at the fluid inlet of the flow passage.   The toxic gas removal unit according to claim 3, further comprising a toxic gas detection unit that detects acid gas, basic gas, and organic gas at the fluid outlet of the flow passage.   A radioactive gas removal unit that adsorbs and removes a radioactive gas is disposed in the flow path on the fluid outlet side of the organic gas removal unit through a high-performance filter that collects particles contained in the gas. Item 5. The toxic gas removal unit according to any one of Items 1 to 4.   A fluid outlet of the toxic gas removal unit according to any one of claims 1 to 5 is connected to a room, and a blower for introducing gas from the fluid inlet of the toxic gas removal unit to the fluid outlet is connected to the room. , Toxic gas removal equipment. Toxic gas removal unit according to any one of claims 1 to 4,
A radioactive gas removal unit that adsorbs and removes the radioactive gas;
And a fluid outlet of the toxic gas removal unit is connected to a fluid inlet of the radioactive gas removal unit via a high performance filter that collects particles contained in the gas, and a fluid outlet of the radioactive gas removal unit Is connected to the room, and is connected to a fan for introducing gas from the fluid inlet of the toxic gas removal unit to the fluid outlet and from the fluid inlet of the radioactive gas removal unit to the fluid outlet.   A fluid outlet of the toxic gas removal unit according to any one of claims 1 to 5 is connected to the vehicle interior, and gas is sent from the fluid inlet of the toxic gas removal unit to the fluid outlet to pass through the vehicle interior. A vehicle provided with a blower that maintains a positive pressure with respect to the outside of the passenger compartment.   The vehicle according to claim 8, further comprising an airlock chamber having an interior door that is opened and closed with respect to the interior of the vehicle interior and an exterior door that is opened and closed with respect to the exterior of the interior of the vehicle interior. An air conditioner that harmonizes the air in the passenger compartment;
A control unit for controlling the operation of the air conditioner to stop or circulate in the vehicle interior when using the toxic gas removal unit;
The vehicle according to claim 8, comprising:

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