JP3864173B2 - Hazardous substance treatment system - Google Patents

Description

【Technical field】
[0001]
  The present invention relates to a hazardous substance processing system. More specifically, the present invention relates to a hazardous substance processing system for detoxifying harmful gases, harmful gases, bacteria, and the like that adversely affect the human body.
[0002]
[Prior art]
  In recent years, new materials for buildings have been developed, but various materials are used for such new materials. When this new material burns, not only flame and smoke, but also carbon monoxide, ammonia, Generates toxic gases such as aldehydes. Such toxic gases are a cause of increasing the number of fire victims.
  In addition, toxic gases are not limited to fires, and can be generated by accidents such as gas leaks in plants and terrorism (hereinafter abbreviated as terrorism). To protect human lives from such toxic gases, It is necessary to quickly remove harmful gases from places where people are present, such as by detoxifying them.
  As a method for treating such a harmful gas, there is a technique described below (see Conventional Example 1 and Patent Document 1).
  The toxic gas removal method of Conventional Example 1 is a method in which a toxic gas removal liquid having a pH of 7 to 9 is sprayed and diffused and reacted with an acidic toxic gas harmful to the human body generated due to a fire or the like. Thus, the toxic gas can be neutralized and detoxified.
[Patent Document 1]
  JP-A-11-300152
[0003]
[Problems to be solved by the invention]
  However, since the harmful gas removal method of Conventional Example 1 sprays the liquid harmful gas removal liquid, the sprayed place may be immersed in the removal liquid. And since the harmful gas removal liquid is alkaline, there is a possibility that an object sprinkled with the removal liquid may be damaged by the removal liquid. There is a problem.
  Further, since the toxic gas removing liquid is only sprayed in the air, no effect is obtained for the toxic gas present in a place not in contact with the toxic gas removing liquid. For example, when sprayed from the ceiling or the like, there is a problem that it is not possible to treat the gas that has entered the cabinet shadows or cabinets.
  On the other hand, no device or method has been developed to efficiently detoxify bacteria that have been dispersed in the air or remove them from the air, and such bacteria can be used as a countermeasure against terrorism, accidents, natural disasters, etc. There is a need for a way to handle this.
[0004]
  In view of such circumstances, the present invention can remove toxic gases, harmful gases, bacteria, and the like that adversely affect the human body present in the atmosphere from the atmosphere and render them harmless, and causes little damage to the treated place. The purpose is to provide a hazardous substance treatment system.
[0005]
[Means for Solving the Problems]
  The hazardous substance treatment system according to claim 1 is a treatment system used for detoxifying and treating a harmful substance contained in a fluid, wherein the treatment system sucks a fluid containing the harmful substance; Disposing means for discharging the fluid sucked by the sucking means, and a hazardous substance processing means for processing a harmful substance contained in the fluid sucked by the sucking means between the sucking means and the discharging means. And withThe harmful substance processing means is provided between the floating substance removing apparatus and the suction means for removing the floating substance contained in the fluid sucked by the suction means from the fluid. A neutralizing device for neutralizing harmful substances, and a catalyst device provided with a catalyst that reacts with harmful substances, provided between the floating substance removing device and the discharging means, and the suction means; A first flow path switching means is provided between the neutralization device, and a second flow path switching means is provided between the floating substance removing device and the catalyst device. Provided, the first flow path switching means comprises a processing path for communicating the suction means and the neutralization device, and a bypass path for communicating the suction means and the suspended solids removal device, The second flow path switching unit includes a processing path for communicating the floating substance removing device and the catalyst device, and a bypass path for communicating the floating substance removing device and the discharging unit.It is characterized by that.
  The hazardous substance processing system according to claim 2 is characterized in that, in the invention according to claim 1, the processing system is mounted on a transportation means.
  Claim3The hazardous substance treatment system of claim1In the described invention, the catalyst device includes a heater that heats the fluid to 100 ° C. or more.
  Claim4The hazardous substance treatment system of claim1In the invention described above, switching control means for controlling the first flow path switching means and the second flow path switching means is provided, and the switching control means receives the type of the harmful substance contained in the fluid. An input unit, a path selection unit that selects a path of the first flow path switching unit and a path of the second flow path switching unit based on the type of harmful substance input to the input unit, and the path selection unit The switching means actuating section switches the path of the first flow path switching means and the path of the second flow path switching means based on the selected path.
  Claim5The hazardous substance treatment system of claim1In the described invention, the suction unit includes a detection unit that detects the type of the harmful substance contained in the fluid, and a detection unit that detects the type of the harmful substance contained in the fluid, and the detection unit A signal transmission unit that transmits a signal corresponding to the type of the detected harmful substance, and the switching control unit receives the signal transmitted from the signal transmission unit of the detection unit and inputs the signal to the input unit. A receiving unit is provided.
  Claim6In the hazardous substance processing system according to claim 1, in the invention according to claim 1, the suction means sucks a pump for sucking fluid, a suction part connected to a suction port of the pump, and a suction part provided in the suction part. And a cooler for cooling the fluid.
  Claim7The hazardous substance treatment system of claim6In the described invention, a flame blocking member for preventing a flame from entering is attached to the suction port of the suction portion, and the flame blocking member is a porous flame-retardant substance.
  Claim8In the hazardous substance processing system according to claim 1, in the invention according to claim 1, the suction means sucks a pump for sucking fluid, a suction part connected to a suction port of the pump, and a suction part provided in the suction part. And a heater for heating the fluid.
  Claim9In the hazardous substance processing system according to claim 1, in the invention according to claim 1, the suction means sucks a pump for sucking fluid, a suction part connected to a suction port of the pump, and a suction part provided in the suction part. It is characterized by comprising a filter part for adsorbing harmful substances contained in fluid.
[0006]
  According to the first aspect of the present invention, the fluid containing the hazardous substance can be processed by the hazardous substance processing means after being sucked by the suction means, and the clean fluid is discharged after the harmful substance is processed. Can do. For this reason, it is possible to treat harmful substances without adversely affecting the place where the fluid is treated and the people in the place, and it is possible to prevent the surrounding environment from being contaminated by the discharged fluid. Secondary disasters can be prevented. Moreover, since it penetrates into the shadows and gaps of furniture and buildings, even harmful substances can be reliably treated. Furthermore, since harmful substances can be sucked together with the fluid, even if the harmful substances are easily diffused in the fluid, the diffusion can be prevented and the spread of damage can be effectively prevented.In addition, the suspended solids removal device can remove the powder and particles contained in the fluid, such as smoke and dust, and then release them to the atmosphere. It is possible to prevent secondary disasters from occurring. Furthermore, if both the first flow path switching means and the second flow path switching means are switched to the processing path, the fluid can be passed through both the neutralization device and the catalyst device. Then, if the harmful substance is acidic or alkaline, it can be reliably neutralized with a neutralizer, Even if it is a substance that is decomposed by heat, it can be decomposed and rendered harmless by the catalyst device. Therefore, since a fluid containing a plurality of harmful substances can be processed with one processing system, it is possible to easily and efficiently process a fluid containing the harmful substances. Further, if the first flow path switching means is switched to provide a bypass path, the suction means and the suspended solid removal device can be directly communicated with each other. Then, if it is not possible to determine whether the harmful substance is acidic or alkaline, the fluid can be supplied directly to the suspended solids removal device without passing through the neutralization device. Can be prevented from occurring. Furthermore, if the second flow path switching means is switched to a bypass path, the floating substance removing device and the discharging means can be directly communicated with each other. Then, if the harmful substance can be processed only by the neutralization device and the suspended substance removing device, it is not necessary to operate the catalyst device, so that the harmful substance can be processed efficiently.
  According to the invention of claim 2, since it is mounted on the transportation means, it can be quickly moved to the site where hazardous substances are processed. Therefore, since harmful substances can be processed quickly, it is possible to prevent damage from spreading.
  Claim3According to the invention, since the fluid can be heated to 100 ° C. or higher by the heater, any harmful substance that is weak against heat, such as bacteria and substances that are easily decomposed by heat, is decomposed and harmless by the catalytic device. Can be
  Claim4According to the invention, when the type of the hazardous substance is input from the input unit, the optimum path is selected according to the type of the hazardous substance by the path selection unit, and the first channel switching unit and the second flow are selected by the switching unit operating unit. The path switching means is switched. For this reason, it is possible to reliably handle harmful substances, and it is possible to prevent mistakes in route selection in each flow path switching means.
  Claim5According to this invention, when the suction means sucks the fluid, the detection means detects the type of the harmful substance, and therefore, the route selection through which the fluid is passed can be performed more quickly and reliably.
  Claim6According to the invention, even if a very high temperature fluid containing harmful substances such as air at a fire site is sucked, the fluid is cooled by the cooler and then supplied to the pump and the hazardous substance processing means. Therefore, the pump or the like can be prevented from being damaged by the high temperature fluid.
  Claim7According to the invention, even when air or the like in a place where a flame exists such as a fire site is sucked, only a fluid containing harmful substances can be sucked without absorbing the flame. It is possible to prevent the pump from being damaged by the flame.
  Claim8According to the invention, if the fluid sucked by the heater is heated, harmful substances that are weak against heat in the fluid, such as bacteria, can be treated. In other words, since harmful substances can be processed by both the suction part and the hazardous substance processing means, it is possible to reliably process harmful substances that are vulnerable to heat and reduce the burden on the hazardous substance processing means. it can.
  Claim9According to this invention, the harmful substance contained in the sucked fluid can be adsorbed also in the filter portion. That is, since the hazardous substance can be processed by both the suction unit and the hazardous substance processing means, the hazardous substance can be reliably processed and the burden on the hazardous substance processing means can be reduced.
[0007]
DETAILED DESCRIPTION OF THE INVENTION
  Next, an embodiment of the present invention will be described with reference to the drawings.
  FIG. 1 is a schematic side view of a hazardous substance processing system 1 of the present embodiment. FIG. 2 is a schematic plan view of the hazardous substance processing system 1 of the present embodiment. FIG. 3 is a block diagram of the hazardous substance processing system 1 of the present embodiment.
[0008]
  As shown in FIGS. 1 to 3, the hazardous substance processing system 1 according to the present embodiment is composed of a suction means 10, a discharge means 20, and a harmful substance treatment means 30. It is characterized in that after a fluid such as gas or liquid existing inside a pit or the like is sucked, harmful substances contained in the sucked fluid are made harmless by the harmful substance processing means 30 or removed from the fluid. .
[0009]
  1 and 2, reference numeral 2 indicates a power source for supplying power to each means. However, power may be supplied to each means from a commercial power source without providing a power source.
  Reference numeral 20 indicates a discharging means. The discharging means 20 may be a simple pipe, but if a means for forcibly discharging the fluid such as a blower is provided, the fluid can be discharged efficiently.
[0010]
  As shown in FIGS. 1 to 3, the suction unit 10 includes a pump 12 that can suck fluid, such as a vacuum pump or a vacuum blower.
  Between the pump 12 of the suction means 10 and the discharge means 20, there is provided a harmful substance processing means 30 for processing a harmful substance contained in the fluid sucked by the suction means 10. The harmful substance processing means 30 includes a suspended substance removing device 31, a neutralizing device 35, and a catalyst device 40. These devices can treat harmful substances in the fluid in a state where the fluid supplied to the inside is isolated from the surrounding environment, that is, in a state where the fluid is sealed in the device. It will be described later.
[0011]
  Therefore, according to the harmful substance processing system 1 of the present embodiment, if the pump 12 is operated, a fluid containing the harmful substance can be sucked, and therefore the harmful substance can be removed from a place where a person or the like is present. Then, the sucked fluid can be sent to the hazardous substance processing means 30 and processed in the hazardous substance processing means 30 while being isolated from the surrounding environment. For this reason, it is possible to treat the harmful substance without adversely affecting the place where the harmful substance is generated or the person in the place.
  Further, since the sucked fluid is discharged to the outside after processing the harmful substance, it is possible to prevent the surrounding environment from being contaminated by the fluid discharged from the discharging means 20. Therefore, since it is possible to prevent the surrounding environment from being contaminated by the fluid discharged from the hazardous substance processing system 1, it is possible to prevent a secondary disaster or the like from occurring due to the discharged fluid.
  Furthermore, since harmful substances are sucked together with the fluid, even harmful substances that have entered the shadows and gaps of furniture and buildings can be reliably removed from the place and processed. Moreover, even if the harmful substance is a substance that easily diffuses in the fluid, the diffusion can be prevented and the spread of damage can be effectively prevented.
[0012]
  Next, the suction unit 10 and the hazardous substance processing unit 30 will be described in detail.
  First, the suction means 10 will be described in detail.
  1-3, the code | symbol 11 has shown the hose of the suction means. The hose 11 has a proximal end communicating with the pump 12, and a suction portion 50 for introducing a fluid into the hose 1 is provided at the distal end.
  For this reason, if the hose 11 is drawn out and the suction part 50 is moved to the place where the harmful substance is generated and the pump 12 is operated, the harmful substance can be absorbed together with the fluid in that place.
[0013]
  As shown in FIGS. 1 to 3, a tank 13 containing a porous material such as activated carbon, coal, carbon black or the like is interposed between the base end of the hose 11 and the pump 12.
  Then, between the base end of the hose 11 and the tank 13 and between the tank 13 and the pump 12, flow path switching valves 61 and 62, which are flow path switching means, are interposed, respectively. The flow path switching valve 61 includes a processing path for communicating the hose 11 and the tank 13 and a bypass path for communicating the hose 11 and the flow path switching valve 62. The flow path switching valve 62 includes a first path that allows the flow path switching valve 61 and the pump 12 to communicate with each other, and a second path that allows the tank 13 and the pump 12 to communicate with each other.
  For this reason, if the flow path switching valve 61 is switched to the processing path and the flow path switching valve 62 is the second path, the aspirated fluid can be passed through the tank 13, so that harmful substances in the fluid are porous. It can be removed by adsorbing to a substance.
  Conversely, if the flow path switching valve 61 is switched to the bypass path and the flow path switching valve 62 is the first path, the sucked fluid can be directly sent to the pump 12. Then, harmful substances that cannot be completely treated by adsorption with a porous material such as bacteria, viruses, and rickets can be reliably sent to the harmful substance processing means 30 described later.
  The tank 13 may not be provided. In this case, the base end of the hose 11 and the pump 12 may be directly communicated with each other.
[0014]
  Next, the hazardous substance processing means 30 will be described in detail.
  As shown in FIGS. 1 to 3, a suspended substance removing device 31 for a hazardous substance processing means 30 is provided between the pump 12 of the suction means 10 and the discharge means 20. This floating substance removing device 31 is for removing floating substances contained in a fluid, for example, powder such as dust and smoke, and mist such as water droplets and oil droplets from the fluid. Or a mist collector.
  Since the floating substance removing device 31 can release the fluid after removing the floating substance contained in the fluid, the surrounding environment can be prevented from being contaminated by the discharged fluid. A disaster can be prevented.
[0015]
  A neutralizing device 35 is provided between the floating substance removing device 31 and the pump 12 of the suction means 10. The neutralization device 35 includes a neutralization tank that stores an acidic or alkaline neutralization liquid, and a neutralization liquid circulator 35b that circulates the neutralization liquid in the neutralization tank.
[0016]
  Between the pump 12 of the suction means 10 and the neutralization device 35 and between the neutralization device 35 and the suspended solids removal device 31, flow path switching valves 63 and 64, which are flow path switching means, are respectively provided. Each is intervened. The flow path switching valve 63 includes a processing path that allows the pump 12 and the neutralization device 35 to communicate with each other, and a bypass path that allows the pump 12 and the flow path switching valve 64 to communicate with each other. The flow path switching valve 64 includes a first path that allows the flow path switching valve 63 and the suspended solids removal device 31 to communicate with each other, and a second path that allows the neutralizer 35 and the suspended solids removal apparatus 31 to communicate with each other. Yes.
  For this reason, if the flow path switching valve 63 is switched to the processing path and the flow path switching valve 62 is the second path, the fluid can be passed through the neutralizing device 35. Then, when the fluid contains an acidic harmful substance, an alkaline neutralizing solution is contained in the neutralizing tank, and when the fluid contains an alkaline harmful substance, an acidic neutralizing solution is accommodated in the neutralizing tank. If a fluid is passed through the tank, it is possible to neutralize and detoxify harmful substances so that the human body is not adversely affected.
  On the contrary, if the flow path switching valve 63 is switched to the bypass path and the flow path switching valve 64 is the first path, the fluid can be directly sent from the pump 12 to the suspended substance removing device 31. Then, when it is not possible to specify whether the harmful substance contained in the fluid is acidic or alkaline, it is possible to prevent an abnormal reaction from occurring in the neutralizing device 35.
  The type of the flow path switching valve and the valve connection method are not limited to the above-described configuration, and when the fluid flows from the pump 12 to the suspended solid removal device 31, a path for passing the fluid to the neutralization device 35 and the fluid Any configuration may be employed as long as the route directly sent from the pump 12 to the suspended substance removing device 31 can be switched.
[0017]
  On the other hand, a catalyst device 40 is provided between the floating substance removing device 31 and the discharge means 20. The catalyst device 40 includes a heater for heating a fluid and a catalyst through which the fluid heated by the heater is passed. For example, a catalyst deodorization treatment device (KATATOR: manufactured by OES Co., Ltd.). ) Etc.
[0018]
  A flow path switching valve 67, which is a flow path switching means, is interposed between the floating substance removing device 31 and the catalyst device 40. The flow path switching valve 67 includes a processing path that allows the suspended substance removing device 31 and the catalyst device 40 to communicate with each other, and a bypass path that allows the suspended substance removing device 31 and the discharge means 20 to communicate with each other.
  For this reason, if the flow path switching valve 67 is switched to the processing path, the fluid can be passed through the catalyst device 40. If the fluid is passed through the catalyst, the harmful substance in the fluid can be decomposed by a catalytic reaction, so that the harmful substance can be efficiently and reliably rendered harmless. In addition, since the suspended matter is removed by the suspended matter removing device 31 before the fluid is passed through the catalyst, the catalyst of the catalyst device 40 becomes dirty, soot and the like are accumulated, and the catalyst is clogged to lower the catalyst function. Can be prevented.
  In addition, before the fluid is passed through the catalyst, the fluid is heated to 100 ° C. or higher by a heater and then supplied to the catalyst. Therefore, the catalytic reaction of the catalyst can be activated, and harmful substances can be decomposed more efficiently. be able to.
  If the harmful substance is a heat-sensitive substance such as bacteria, viruses, rickets, or a substance that is easily decomposed by heat, the harmful substance can be rendered harmless simply by heating the fluid with a heater.
  The type of the flow path switching valve and the valve connection method are not limited to the above configuration, and when the fluid flows from the suspended substance removing device 31 to the discharge means 20, a path for passing the fluid to the catalyst device 40 and the fluid floating Any configuration may be employed as long as the route directly sent from the substance removing device 31 to the discharging means 20 can be switched.
[0019]
  Because of the configuration as described above, according to the harmful substance processing means 30, the flow path switching valve 63 and the flow path switching valve 67 are both switched to the processing path, and the flow path switching valve 64 is switched to the second path. In this case, the fluid can be passed through both the neutralization device 35 and the catalyst device 40. Then, if the harmful substance is acidic or alkaline, it can be reliably neutralized by the neutralizing device 35, and even if it is a neutral substance, it is decomposed by the catalyst device 40 to be harmless if it is a substance that is decomposed by heat. Can do. Therefore, since a fluid containing a plurality of harmful substances can be processed with one processing system, it is possible to easily and efficiently process a fluid containing the harmful substances.
  Further, if the harmful substance can be treated only by the catalyst device 40 and the suspended substance removing device 31, the flow path switching valve 63 is switched to the bypass path and the flow path switching valve 64 is switched to the first path, and the flow path switching valve 67 is switched. Is switched to the processing path, the fluid can be passed only through the suspended substance removing device 31 and the catalyst device 40. Then, since it is not necessary to operate the neutralization apparatus 35, a harmful substance can be processed efficiently, without worrying about causing an abnormal reaction.
  Further, if the toxic substance can be processed only by the neutralization device 35 and the suspended solid removal device 31, the flow path switching valve 63 is switched to the processing path, and the flow path switching valve 64 is switched to the second path. If 67 is switched to the detour path, the fluid can be passed through only the suspended substance removing device 31 and the neutralizing device 35. Then, since it is not necessary to operate the catalyst device 40, it is possible to efficiently treat harmful substances.
  That is, since a device that allows fluid to pass can be freely selected according to the type of the hazardous substance, the processing operation can be performed efficiently, and the occurrence of danger during the processing operation can be prevented. As a result, the types of hazardous substances that can be treated become abundant.
  The flow path switching valve 63 and the flow path switching valve 64 are the first flow path switching means referred to in the claims, and the flow path switching valve 67 is the second flow path switching means referred to in the claims.
[0020]
  Further, the heating device 36 and the tank 45 may be provided in the harmful substance processing means 30.
  As shown in FIGS. 1 to 3, a heating device 36 is provided between the flow path switching valve 63 and the neutralizing device 35 so that the fluid can be heated to about 100 ° C. or more by, for example, an electric heater or a gas burner. If the harmful substance contained in the fluid is a substance that is vulnerable to heat, such as bacteria or a substance that is easily decomposed by heat, the harmful substance is rendered harmless simply by heating the fluid with the heating device 36. can do.
  A flow path switching valve 66 such as a three-way valve is provided between the heating device 36 and the neutralization apparatus 35, and a flow path switching such as a three-way valve is performed between the flow path switching valve 63 and the flow path switching valve 64. If the valve 65 is provided and connected to the flow path switching valve 65 and the flow path switching valve 66, the fluid is supplied to both the heating device 36 and the neutralizing device 35 when the fluid flows from the pump 12 to the suspended substance removing device 31. You can pass either one or the other.
  The type of the flow path switching valve and the connection method of the valves are not limited to the above configuration, and when the fluid flows from the pump 12 to the suspended substance removing device 31, the fluid is passed through both the heating device 36 and the neutralizing device 35. Any configuration may be used as long as one of them can be passed.
[0021]
  As shown in FIGS. 1 to 3, if a tank 45 similar to the tank 13 described above is provided between the flow path switching valve 67 and the catalyst device 40, it cannot be completely removed by the suspended matter removing device 31. It can be removed from the fluid by adsorbing dust and mist.
  A flow path switching valve 70 such as a three-way valve is provided between the tank 45 and the catalyst device 40, and a flow path switching valve 69 such as a three-way valve is provided between the flow path switching valve 63 and the flow path switching valve 64. The flow path switching valve 69 and the flow path switching valve 70 are connected. If a flow path switching valve 68 such as a three-way valve is provided between the tank 45 and the flow path switching valve 70, the tank 45 and the catalyst device are flowed when the fluid flows from the suspended substance removing device 31 to the discharge means 20. The fluid can be passed through both of the fluids 40, or only one of them can be passed.
  The type of the flow path switching valve and the valve connection method are not limited to the above-described configuration, and when the fluid flows from the suspended substance removing device 31 to the discharge means 20, the fluid is passed through both the tank 45 and the catalyst device 40. Any configuration may be used as long as one of them can be passed.
[0022]
  Next, an operation of processing hazardous substances by the hazardous substance processing system 1 of the present embodiment will be described.
  In the following, an explanation will be given of an operation for processing a hazardous substance generated in the event of a fire, an operation for processing a hazardous substance that is sensitive to heat, and an operation for processing a toxic gas. Substances are not limited to the hazardous substances generated in the above case, but can be applied to the treatment of harmful substances generated by terrorism, natural disasters, accidents, and the like.
  Moreover, the path | route which flows a fluid is not restricted to the following paths, If the combination of the path | routes of the flow-path switching valves 61-70 is changed, it can select suitably according to the kind of harmful substance.
[0023]
  First, the work for treating harmful substances generated in the event of a fire will be described.
  FIG. 7A is an explanatory diagram of a procedure for treating hazardous substances generated at the time of a fire by the hazardous substance treatment system 1 of the present embodiment, and FIG. 7B is harmful to heat by the hazardous substance treatment system 1 of the present embodiment. It is explanatory drawing of the procedure which processes a substance. In a fire, it is known that building materials and the like burn and generate harmful substances such as carbon monoxide, aldehyde, hydrogen cyanide, ammonia, phosgene and hydrogen chloride. However, since all the harmful substances generated cannot be grasped, when a fluid is passed through the neutralization device 35 or the catalyst device 40, an abnormal reaction in the neutralization device 35 or an explosion in the catalyst device 40 may occur. Therefore, the work to deal with harmful substances generated in the event of a fire can be removed safely and effectively from the location of the fire if only adsorption treatment and removal of suspended substances are performed, and the discharged air is given to the surrounding environment. The impact can be minimized.
[0024]
  In the processing operation, first, as shown in FIG. 7A, the sucked fluid is pumped from the tank 13 to the pump 12. The flow path switching valves 61 to 70 are switched so that the floating substance removing device 31, the tank 45, and the discharging means 20 flow in this order.
  Next, the hose 11 is drawn out and the suction part 50 is moved to a place where harmful substances are generated. Then, if the pump 12 is operated, smoke and generated harmful substances can be absorbed together with the air in the place.
  Then, about 10 to 20% of smoke and generated harmful substances are adsorbed by the porous substance housed in the tank 13. Then, after dust and the like are removed by the floating substance removing device 31, approximately 10 to 20% of smoke and harmful substances can be adsorbed by the porous substance in the tank 45.
  Therefore, since about 20 to 40% of the smoke contained in the sucked fluid and the generated harmful substances can be adsorbed from the fluid, the contamination of the surrounding environment by the air discharged from the discharge means 20 is suppressed. Can do.
  Hazardous substances generated during a fire include carbon monoxide, hydrogen chloride, hydrogen cyanide, ammonia, phosgene, aldehydes, sulfur, halogen compounds, ethane, hydrogen, ketones, and organic acids.
  Further, although not a harmful substance generated in the event of a fire, the fluid is pumped from the tank 13 to the pump 12. If the floating substance removing device 31, the tank 45, and the discharging means 20 are flowed in this order, tearing agents such as chlorobenzylidenemalononitrile, emetics such as Adamsite, and the like can be processed.
[0025]
  If a fire breaks out in a closed space such as a building, if the air at the fire site continues to be sucked, the inside of the building becomes negative pressure and there is a risk of backdraft. Etc. You may supply inert gas, such as. In this case, there is a possibility that two effects of removal of harmful substances by suction and prevention of fire spread by supplying inert gas may be obtained.
[0026]
  Next, an operation for treating harmful substances that are sensitive to heat will be described.
  If terrorism or chemical weapons are used, such as bacteria such as carbon or cholera, yellow fever virus or smallpox virus, etc. You can do it. Therefore, if the heat-sensitive hazardous substance is heat-treated, the harmful substance can be detoxified safely and effectively, and the influence of the discharged air on the surrounding environment can be suppressed.
  Therefore, as shown in FIG. 7B, if the flow path switching valves 61 to 70 are switched so that the sucked fluid flows from the pump 12 in the order of the floating substance removing device 31, the catalyst device 40, and the discharging means 20. Since harmful substances that are weak against heat can be reliably treated, contamination of the surrounding environment by air discharged from the discharge means 20 can be suppressed.
  The following are harmful bacteria and heat-sensitive substances treated in the above operations.
  Bacteria include carbon, shigella, plague, cholera, and typhoid.
  Non-bacterial heat-sensitive harmful substances include yellow fever virus, viruses such as smallpox virus and parrot virus, fungi such as Fusarium, rash typhoid and Q fever, rickettsia such as Rocky mountain spotted fever.
[0027]
  Next, an operation for treating toxic gas will be described.
  If toxic gas is sprayed due to terrorism or use of chemical weapons, etc., if the gas is acidic or alkaline, neutralization is an effective means for detoxification, and redox If it can be decomposed by reaction, it is effective to treat with a catalyst.
[0028]
  Therefore, as long as it is a harmful substance that can be rendered harmless by neutralization, as shown in FIG. 8A, the sucked fluid is transferred from the pump 12 to the neutralizing device 35, the floating substance removing device 31, and the discharging means 20. If the flow path switching valves 61 to 70 are switched so as to flow in order, harmful substances can be reliably processed.
  In this case, the neutralizing solution to be used differs depending on the harmful substance, but harmful substances that can be treated with an aqueous sodium hydroxide solution as the neutralizing liquid include nerve agents such as sarin, tabun, soman, VX gas, sulfur mustard, Examples include mustard gas such as nitrogen mustard, erosion agents such as leucite and phosgene oxime, suffocating agents such as phosgene, diphosgene and chlorine, and cyanides such as hydrogen cyanide and cyanogen chloride.
  In addition, examples of harmful substances that can be treated using a slaked lime aqueous solution as a neutralizing solution include sulfur dioxide gas, hydrogen fluoride gas, and inorganic gases such as nitric acid.
  Further, as a neutralizing solution, harmful substances that can be treated using a mixed solution of sodium sulfite and sodium carbonate to which a small amount of a surfactant is added include a suffocating agent such as chloropicrin.
  Nervous agents such as sarin, tabun, soman, VX gas, mustard gases such as sulfur mustard and nitrogen mustard, erosive agents such as leucite and phosgene oxime, asphyxants such as phosgene, diphosgene and chlorine, hydrogen cyanide and cyanogen chloride Since cyanide such as is neutralized and then passed through the tank 45, it is adsorbed by a porous material such as activated carbon, so that it can be treated more effectively.
  Furthermore, sarin, tabun, soman, VX gas, hydrogen cyanide, phosgene, and the like are neutralized and then passed through the catalyst device 40, and if they remain unneutralized, they are decomposed by a redox reaction. Therefore, it can process more effectively.
  Furthermore, sarin, tabun, soman, VX gas, hydrogen cyanide, phosgene, etc. are neutralized and then passed through both the tank 45 and the catalyst device 40, so that they are decomposed by oxidation-reduction reactions and adsorbed on porous materials such as activated carbon. Can be processed more effectively.
[0029]
  Further, if it is a harmful substance that can be decomposed by the oxidation-reduction reaction, as shown in FIG. 8B, the sucked fluid flows from the pump 12 in the order of the floating substance removing device 31, the catalyst device 40, and the discharge means 20. Thus, if the flow path switching valves 61 to 68 are switched, harmful substances can be reliably processed.
  Hazardous substances that can be treated in the above work include inorganic compounds such as ammonia, hydrogen sulfide, hydrogen cyanide, hydrogenated hydrogen, hydrogen selenide, and nitrogen compounds, and organic compounds such as toluene, acetylene, methanol, ethylene oxide, methylamine, and chloroform. There are compounds.
[0030]
  Moreover, if an electromagnetic valve is used as the flow path switching valves 61 to 70, the paths of all the flow path switching valves 61 to 70 can be switched easily and in a short time. In particular, if the switching control means 80 for controlling the opening and closing of the flow path switching valves 61 to 70 is provided as follows, the paths of all the flow path switching valves 61 to 70 can be switched simultaneously and accurately in a short time. Can do.
  As shown in FIG. 3, the switching control unit 80 includes an input unit 81, a route selection unit 82, and a switching unit operating unit 83.
  The input unit 81 is for inputting the type of harmful substance contained in the fluid.
  The path selection unit 82 selects the path of the flow path switching valves 61 to 70 based on the type of harmful substance input to the input unit 81.
  The switching means actuating unit 83 switches the path of the flow path switching valves 61 to 70, that is, the path through which the fluid passes, based on the path selected by the path selecting unit 82.
  Then, if the type of the hazardous substance is input from the input unit 81, the path selection unit 82 selects the optimum path according to the type of the hazardous substance, and the switching unit operating unit 83 determines the path of the flow path switching valves 61 to 70. It is switched automatically. For this reason, a hazardous | toxic substance can be processed reliably and the mistake of the path | route selection in the flow-path switching valves 61-70 can be prevented.
[0031]
  And the detection part 91 (for example, chemical agent detection alarm device (made by Hiroyuki Yamada)) which detects the kind of harmful substance contained in the fluid in the suction part 50 of the suction means 10, and this detection part 91 detect. Detection means 90 including a signal transmission unit 92 that transmits a signal corresponding to the type of the harmful substance is provided, and the switching control unit 80 receives a signal transmitted from the signal transmission unit 92 and receives an input unit. A receiving unit 84 for inputting to 81 may be provided.
  In this case, if the suction unit 50 of the suction unit 10 sucks the fluid, the detection unit 90 automatically detects the type of harmful substance in the fluid. Then, since it is possible to prevent an erroneous determination of the type of harmful substance and an input error to the input unit 81, it is possible to more quickly and reliably select a route through which the fluid passes.
[0032]
  In the case where the detection means 90 is not provided as described above, the type of the harmful substance investigated using the gas detection tube or the like is provided with an input unit 81 such as a keyboard or a touch screen, and is input by manual input. Also good. In addition, the type of harmful substance may be determined from the symptoms of a person who has suffered damage.
[0033]
  Next, the suction unit 50 will be described.
  FIG. 4 is a schematic explanatory diagram of the suction unit 50 used for processing harmful substances generated in the event of a fire. FIG. 5 is a schematic explanatory diagram of a suction unit 50 used for processing a harmful substance that is weak against heat. FIG. 6 is a schematic explanatory diagram of a suction unit 50 used for processing harmful substances such as chemical weapons.
[0034]
  First, the suction part 50 used for the process of the harmful substance contained in a high temperature fluid at the time of a fire etc. is demonstrated.
  As shown in FIG. 4, the suction part 50 is attached to the tip of the hose 11 of the suction means 10 and introduces fluid to be sucked into the hose 11. Inside the suction portion 50, there are an inner passage 51a whose base end communicates with the hose 11, an outer passage 51b whose distal end communicates with the outside, the outer passage 51b, the base end, and the inner passage 51a. A connection passage 51c that communicates with the tip is formed. That is, the passage through which the fluid flows is bent inside the suction unit 50 so that the flow path of the fluid inside the suction unit 50 becomes long. A heat radiating member 52 is attached to the outer peripheral surface of the suction part 50.
  For this reason, even if the fluid containing harmful substances such as air at the fire site is very hot, the sucked fluid is cooled while flowing from the outer passage 51b to the connection passage 51c and the inner passage 51a. Therefore, the fluid can be cooled to some extent before flowing into the hose 11. Moreover, since the heat radiating member 52 is provided on the outer peripheral surface of the suction portion 50, the cooling effect can be enhanced. Therefore, even if a high temperature fluid is sucked, the fluid can be supplied to the pump 12 and the hazardous substance processing means 31 after the fluid is cooled by the heat radiating member 52 and each flow path. Can be prevented.
[0035]
  In addition, if the front end of the outer passage 51b, that is, the suction port 51h for sucking the fluid, a flame blocking member 53, which is a porous flame retardant material such as activated carbon or ceramic, is attached. Even if air in a place where a flame exists, such as a fire site, is sucked, only a fluid containing harmful substances can be sucked without absorbing the flame. Since it can prevent damaging by a flame, it is suitable.
  The outer passage 51b, the connection passage 51c, the inner passage 51a, and the heat dissipating member 52 are coolers referred to in the claims.
  The cooler is not limited to the above-described configuration, and is not particularly limited as long as the fluid sucked by the suction unit 50 can be cooled and then supplied to the pump 12 and the like. There is no particular limitation.
[0036]
  Next, the suction unit 50 used for processing harmful substances that are weak against heat will be described.
  As shown in FIG. 5, a fluid passage 51 having a distal end communicating with the outside and a proximal end communicating with the hose 11 is formed at the center of the suction portion 50. A heater 54 that can heat the fluid flowing in the fluid passage 51 such as a heater and a gas burner is provided around the fluid passage 51.
  For this reason, if the harmful substance contained in the sucked fluid is bacteria that is weak against heat, it can be processed in the fluid passage 51 of the suction unit 50. In other words, since harmful substances can be processed by both the suction unit 50 and the hazardous substance processing means 30, it is possible to reliably process harmful substances that are sensitive to heat and reduce the burden on the hazardous substance processing means 30. can do.
  In addition, if the cooler 55 is provided between the fluid passage 51 and the hose 11, it is possible to prevent the heated fluid from flowing to the pump 12 and the like.
[0037]
  Next, the suction unit 50 used for processing of harmful substances such as chemical weapons will be described.
  As shown in FIG. 6, a fluid passage 51 having a distal end communicating with the outside and a proximal end communicating with the hose 11 is formed at the center of the suction portion 50. A filter unit 56 that adsorbs harmful substances contained in the sucked fluid is provided at the base end of the fluid passage 51. This filter part 56 is comprised from the pre-processing part 57 which consists of activated carbon and soda lime, and the post-processing part 58 which consists of felt.
  For this reason, if the sucked fluid passes through the filter unit 56, among the harmful substances contained in the fluid, a substance having a large particle size (for example, a particle size of 100 mm or more) can be adsorbed in the pretreatment unit 57. A substance having a small particle size (for example, a particle size of less than 100 mm) can be adsorbed in the post-processing unit 57. That is, since the hazardous substance can be processed by both the filter unit 56 of the suction unit 50 and the hazardous substance processing means 30, the hazardous substance can be reliably processed and the burden applied to the hazardous substance processing means 30. Can be reduced.
[0038]
  In addition, if the hazardous substance processing system 1 of this embodiment is installed in a station premises, a factory, a building, or the like, a rapid process can be performed when a hazardous substance is generated. As shown in FIG. If it is installed in a transportation means such as a trailer, a tow truck, etc., it can be quickly moved to the site where harmful substances are generated. Therefore, even if a harmful substance is generated in a place where the hazardous substance processing system 1 is not present, the harmful substance can be quickly processed, so that the damage can be prevented from spreading.
[0039]
【The invention's effect】
  According to the first aspect of the present invention, the fluid containing the hazardous substance can be processed by the hazardous substance processing means after being sucked by the suction means, and the clean fluid is discharged after the harmful substance is processed. Can do. For this reason, it is possible to treat harmful substances without adversely affecting the place where the fluid is treated and the people in the place, and it is possible to prevent the surrounding environment from being contaminated by the discharged fluid. Secondary disasters can be prevented. Moreover, since it penetrates into the shadows and gaps of furniture and buildings, even harmful substances can be reliably treated. Furthermore, since harmful substances can be sucked together with the fluid, even if the harmful substances are easily diffused in the fluid, the diffusion can be prevented and the spread of damage can be effectively prevented.In addition, the suspended solids removal device can remove the powder and particles contained in the fluid, such as smoke and dust, and then release them to the atmosphere. It is possible to prevent secondary disasters from occurring. Furthermore, if both the first flow path switching means and the second flow path switching means are switched to the processing path, the fluid can be passed through both the neutralization device and the catalyst device. Then, if the harmful substance is acidic or alkaline, it can be reliably neutralized by a neutralizer, and even if it is a neutral substance, if it is a substance that is decomposed by heat, it can be decomposed and rendered harmless by a catalytic device. . Therefore, since a fluid containing a plurality of harmful substances can be processed with one processing system, it is possible to easily and efficiently process a fluid containing the harmful substances. Further, if the first flow path switching means is switched to provide a bypass path, the suction means and the suspended solid removal device can be directly communicated with each other. Then, if it is not possible to determine whether the harmful substance is acidic or alkaline, the fluid can be supplied directly to the suspended solids removal device without passing through the neutralization device. Can be prevented from occurring. Furthermore, if the second flow path switching means is switched to a bypass path, the floating substance removing device and the discharging means can be directly communicated with each other. Then, if the harmful substance can be processed only by the neutralization device and the suspended substance removing device, it is not necessary to operate the catalyst device, so that the harmful substance can be processed efficiently.
  According to the invention of claim 2, since it is mounted on the transportation means, it can be quickly moved to the site where hazardous substances are processed. Therefore, since harmful substances can be processed quickly, it is possible to prevent damage from spreading.
  Claim3According to the invention, since the fluid can be heated to 100 ° C. or higher by the heater, any harmful substance that is weak against heat, such as bacteria and substances that are easily decomposed by heat, is decomposed and harmless by the catalytic device. Can be
  Claim4According to the invention, when the type of the hazardous substance is input from the input unit, the optimum path is selected according to the type of the hazardous substance by the path selection unit, and the first channel switching unit and the second flow are selected by the switching unit operating unit. The path switching means is switched. For this reason, it is possible to reliably handle harmful substances, and it is possible to prevent mistakes in route selection in each flow path switching means.
  Claim5According to this invention, when the suction means sucks the fluid, the detection means detects the type of the harmful substance, and therefore, the route selection through which the fluid is passed can be performed more quickly and reliably.
  Claim6According to the invention, even if a very high temperature fluid containing harmful substances such as air at a fire site is sucked, the fluid is cooled by the cooler and then supplied to the pump and the hazardous substance processing means. Therefore, the pump or the like can be prevented from being damaged by the high temperature fluid.
  Claim7According to the invention, even when air or the like in a place where a flame exists such as a fire site is sucked, only a fluid containing harmful substances can be sucked without absorbing the flame. It is possible to prevent the pump from being damaged by the flame.
  Claim8According to the invention, if the fluid sucked by the heater is heated, harmful substances that are weak against heat in the fluid, such as bacteria, can be treated. In other words, since harmful substances can be processed by both the suction part and the hazardous substance processing means, it is possible to reliably process harmful substances that are vulnerable to heat and reduce the burden on the hazardous substance processing means. it can.
  Claim9According to this invention, the harmful substance contained in the sucked fluid can be adsorbed also in the filter portion. That is, since the hazardous substance can be processed by both the suction unit and the hazardous substance processing means, the hazardous substance can be reliably processed and the burden on the hazardous substance processing means can be reduced.
[Brief description of the drawings]
FIG. 1 is a schematic side view of a hazardous substance processing system 1 of the present embodiment.
FIG. 2 is a schematic plan view of the hazardous substance processing system 1 of the present embodiment.
FIG. 3 is a block diagram of the hazardous substance processing system 1 of the present embodiment.
FIG. 4 is a schematic explanatory diagram of a suction unit 50 used for processing harmful substances generated in a fire.
FIG. 5 is a schematic explanatory diagram of a suction unit 50 used for processing a heat-sensitive harmful substance.
FIG. 6 is a schematic explanatory diagram of a suction unit 50 used for processing a toxic gas.
7A is an explanatory diagram of a procedure for treating hazardous substances generated in a fire by the hazardous substance treatment system 1 of the present embodiment, and FIG. 7B is vulnerable to heat by the hazardous substance treatment system 1 of the present embodiment. It is explanatory drawing of the procedure which processes a harmful substance.
FIG. 8 is an explanatory diagram of a procedure for processing a toxic gas by the hazardous substance processing system 1 of the present embodiment.
FIG. 9 is an explanatory view of a transportation means equipped with the hazardous substance processing system 1 of the present embodiment.
[Explanation of symbols]
    1 Hazardous material treatment system
    10 Absorption means
    11 Hose
    12 Pump
    20 Discharge means
    30 Hazardous substance treatment means
    31 Suspended material processing equipment
    35 Neutralizer
    40 Catalytic device
    50 Absorber
    80 switching control means
    81 Input section
    82 Route Selector
    83 Switching means operating part
    84 Receiver
    90 detection means
    91 Detector
    92 Signal transmitter

Claims (9)

A processing system used for detoxifying and processing harmful substances contained in a fluid,
A suction means for sucking a fluid containing harmful substances;
A discharge means for discharging the fluid sucked by the suction means;
A toxic substance treatment means for treating a toxic substance contained in the fluid sucked by the suction means between the suction means and the discharge means ;
The hazardous substance processing means is
A suspended matter removing device for removing suspended matter contained in the fluid sucked by the suction means;
A neutralizing device for neutralizing harmful substances, provided between the floating substance removing device and the suction means;
Comprising a catalyst device provided between the floating substance removing device and the discharging means, and provided with a catalyst that reacts with harmful substances,
A first flow path switching means is provided between the suction means and the neutralization device,
Between the floating substance removing device and the catalyst device, a second flow path switching means is provided,
The first flow path switching means includes a processing path for communicating the suction means and the neutralization device, and a detour path for communicating the suction means and the suspended solids removal device,
The second flow path switching unit includes a processing path for communicating the floating substance removing device and the catalyst device, and a bypass path for communicating the floating substance removing device and the discharging unit. A hazardous substance processing system characterized by that. The hazardous substance treatment system according to claim 1, wherein the treatment system is mounted on a transportation means. Hazardous material treatment system according to claim 1, wherein the catalytic converter, characterized in that it comprises a heater for heating the fluid above 100 ° C.. Switching control means for controlling the first flow path switching means and the second flow path switching means is provided, and the switching control means includes an input unit for inputting a type of harmful substance contained in the fluid, Based on the type of harmful substance input to the input unit, the route selection unit that selects the route of the first flow path switching unit and the route of the second flow path switching unit, and the path selected by the route selection unit Te, harmful material treatment system according to claim 1, wherein the comprising a switching means operating unit for switching the route of the path and the second flow path switching unit of the first flow path switching unit. The suction means comprises a detection means for detecting the type of harmful substance contained in the fluid, a detection part for detecting the type of harmful substance contained in the fluid, and a harmful substance detected by the detection part A signal transmission unit that transmits a signal corresponding to the type of the signal, and the switching control unit includes a reception unit that receives the signal transmitted from the signal transmission unit of the detection unit and inputs the signal to the input unit. The hazardous substance processing system according to claim 1, wherein: The suction means comprises a pump for sucking fluid, a suction part connected to a suction port of the pump, and a cooler provided in the suction part for cooling the sucked fluid. Item 1. A hazardous substance processing system according to item 1. The harmful substance according to claim 6, wherein a flame blocking member for preventing a flame from entering is attached to the suction port of the suction portion, and the flame blocking member is a porous flame retardant substance. Processing system. The suction means comprises a pump for sucking fluid, a suction part connected to a suction port of the pump, and a heater for heating the sucked fluid provided in the suction part. Item 1. A hazardous substance processing system according to item 1. The suction means includes a pump for sucking fluid, a suction portion connected to the suction port of the pump, and a filter portion provided in the suction portion for adsorbing harmful substances contained in the sucked fluid. The hazardous substance processing system according to claim 1.

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