JP5475319B2 - Isolation chamber forming apparatus and isolation chamber cleaning and fumigation method - Google Patents

Description

  The present invention relates to an isolation room forming apparatus including a non-airtight tent that isolates an infected patient infected with a pathogen causing an infectious disease such as influenza from others, and an isolation room cleaning fumigation method.

  Conventionally, an infected patient infected with a pathogen causing an infectious disease such as influenza is isolated from others, and ventilation is performed so that a pathogen emitted from the infected patient does not infect others (for example, A hermetic movable bed described in Patent Document 1).

  The hermetic moving bed described in Patent Document 1 is for transporting a patient. This hermetic moving bed includes a blower fan 7 and an ozone generator 1. The blower fan 7 sends the air in the patient accommodation space 18 to the ozone generator 1. As a result, the patient accommodating space 18 has a negative pressure. For this reason, even if external air enters the patient accommodating space 18 through the valve 16, the air in the patient accommodating space 18 is not directly discharged to the outside. The air sent out by the blower fan 7 is sterilized by ozone generated from the ozone generator 1 and then released to the outside.

  Further, conventionally, an ozone fumigation sterilization apparatus is carried into a room of a medical facility and operated, and ozone is generated from the apparatus to sterilize the entire interior of the room in an ozone atmosphere. However, since ozone is a harmful substance, it is not preferable for the operator to enter the room and operate the ozone fumigation sterilizer. In this respect, Patent Document 2 discloses that an apparatus body of an ozone fumigation sterilization apparatus that generates ozone is disposed inside a room, and a remote control apparatus for operating the apparatus body is disposed outside the room. An ozone fumigation sterilization device is described in which a person enters the room, checks the room, turns on the operation switch of the device main body, exits the room, operates the remote control device, and starts the sterilization treatment on the device main body. ing.

JP 2005-034582 A Japanese Patent Laid-Open No. 11-146905

  Pathogens such as bacteria held by the patient remain on the closed-type movable bed after the patient is accommodated and the top and mat placed on the bed. If this is the case, other patients cannot be accommodated in the closed room type moving bed, and the closed room type moving bed must be disposed of by incineration or the like. However, this is very uneconomical. In Patent Document 1, there is no description about the handling of the closed room type moving bed after accommodating such a patient.

  Here, while the infected patient is housed in the isolated space, the operator operates the air cleaning device to clean the air in the isolated space and release it to the outside. It is conceivable that the inside of the isolation space is fumigated with ozone using an ozone fumigation device such as the ozone fumigation sterilization device described in Patent Document 2 only while the gas is not accommodated. However, the ozone generator and the fan described in Patent Document 1 and the ozone fumigation sterilizer described in Patent Document 2 are all disposed in an isolated space. For this reason, the operator must enter the isolation space and switch these devices on and off. In this case, the operator may come into contact with ozone harmful to the human body generated by the remaining pathogen or the ozone fumigation device.

  An object of the present invention is to safely clean and fumigate air in an isolation space for isolating infected patients.

The isolation chamber forming apparatus of the present invention includes (i) a non-tight tent that isolates and accommodates an infected patient, (ii) an intake port, an exhaust port, a first ozone generator, and an operation input A first operation input unit; a first ozone decomposition catalyst that changes ozone into oxygen; and a HEPA filter that collects particulates, and the intake air in response to an operation input from the first operation input unit. Air sucked from the mouth, and the sucked air passes through the ozone generation site by the first ozone generator and the ozone decomposition catalyst in this order, and passes through the HEPA filter to be discharged from the exhaust port. A cleaning unit, (iii) a second ozone generator, an ozone discharge port, an ozone intake port, a second operation input unit for performing an operation input, and a second ozone for changing ozone to oxygen A cracking catalyst, In response to an operation input from the operation input unit 2, ozone is generated in the second ozone generator and is sent to the ozone discharge port, and air containing the discharged ozone is discharged from the ozone intake port. A fumigation unit that performs ozone recovery that is sucked and passed through the second ozone decomposition catalyst; and (iv) an air inlet of the air purification unit installed outside the tent and an internal space of the tent. A first communication structure for communicating the air in the tent to the air cleaning unit; and (v) the ozone exhaust port of the fumigation unit installed outside the tent and the internal space of the tent. And (vi) the ozone intake port of the fumigation unit installed outside the tent and the internal space of the tent communicate with each other. And the ten And the inside air and a third communicating structure leading to the fumigation portion, the said air cleaning unit fumigation portion, a single air inlet shared between the intake port and the ozone inlet, The single air inlet and the internal space of the tent are housed in a single housing having the exhaust port, the ozone exhaust port, the first operation input unit, and the second operation input unit. The first communication structure and the third communication structure are shared by a single structure communicating with each other.

Isolated chamber cleaning fumigation method of the present invention is installed outside the non-airtight tent isolating housing the infected patient, an intake port and an exhaust port, a first operation input unit for performing operation input A first ozone generator, a first ozonolysis catalyst that changes ozone into oxygen, and an HEPA filter that collects particulates are incorporated in the housing. In response to an operation input from the tent, air inside the tent is sucked from the intake port via a connecting pipe provided in the tent, and the sucked air is used to generate ozone by the first ozone generator and the ozone. passed in the order of the cracking catalyst, and said the step of discharging from the exhaust port is passed through a HEPA filter, it is disposed outside of the tent, and ozone discharge port, an ozone inlet der shared between the intake port A single air inlet, and a second operation input unit for performing an operation input provided to the housing, in the housing, a second ozone generator, a second ozone decomposition catalyst for changing the ozone into oxygen And a fumigation unit containing the ozone generation step of generating ozone in the second ozone generator in response to an operation input from the second operation input unit and sending the ozone toward the ozone discharge port; An ozone recovery step of sucking air containing ozone discharged from the ozone discharge port from the ozone intake port through the connection pipe and passing it through the second ozone decomposition catalyst.

  According to the present invention, since both the air purifier and the ozone fumigator are arranged outside the tent, the operator can operate these devices without entering the tent. The air in the isolation space for isolating the infected patient can be safely cleaned and fumigated.

It is a schematic diagram which shows the whole isolation chamber formation apparatus in 1st embodiment. (A) And (b) is a perspective view which expands and shows a part of tent. It is a schematic diagram which shows the structure of an air purifying fumigator. It is a schematic diagram which shows the modification of the structure of the air purification fumigator in 1st embodiment. It is a flowchart shown about the flow of control of the air purification fumigator at the time of performing air cleaning. It is a flowchart shown about the flow of control of the air purification fumigation machine at the time of performing ozone fumigation. It is a schematic diagram shown about the modification of an isolation chamber formation apparatus. It is a schematic diagram which shows the whole isolation chamber formation apparatus in 2nd embodiment. It is a schematic diagram which shows the structure of an air cleaner. It is a schematic diagram which shows the structure of an ozone fumigation machine. It is a schematic diagram which shows the whole isolation chamber formation apparatus in 3rd embodiment. It is a schematic diagram which shows the structure of an ozone fumigation machine. It is a flowchart shown about the flow of control of the air cleaner at the time of performing ozonolysis. It is a perspective view which shows the modification of an air cleaner and an ozone fumigation machine.

  One embodiment (first embodiment) will be described with reference to FIGS.

  FIG. 1 is a schematic diagram showing the entire isolation chamber forming apparatus 101. The isolation chamber forming apparatus 101 includes a tent 102 and an air cleaning fumigator 103. The tent 102 accommodates an infected patient 151 infected with a pathogen causing infectious diseases such as influenza in its internal space. When the infected patient 151 comes into contact with a third party, the third party may infect the third party with the pathogen. It is for isolating this infected patient 151 so that there is no.

  The tent 102 has a structure that is assembled into a rectangular parallelepiped shape. The tent 102 includes a frame 105 that forms a skeleton and a sheet 106 that serves as a wall. The frame 105 is configured by connecting a plurality of stainless steel pipes. The frame 105 is foldable and can be downsized so that the installation operator can easily carry it. The material of the sheet 106 is, for example, soft vinyl chloride, and another example is Teflon (registered trademark). The sheet 106 is made of a polyester material. The installation operator spreads the folded frame 105 into a rectangular parallelepiped shape and places it on the bottom surface 107. The bottom surface 107 may be a hospital floor or the ground depending on the installation location of the tent 102. Subsequently, the installation worker covers the rectangular parallelepiped four side surfaces, the upper surface, and the lower surface formed by the frame 105 with the sheet 106.

  The sheet 106 has an entrance / exit 108 at a position located on one side surface 106a of the tent 102 (a side surface located on the back side of the bed 152 in FIG. 1). The doorway 108 is formed by a cut made in the tent 102. The entrance / exit 108 is provided in a size that allows passage through the bed 152. In addition, an infected patient 151 and doctors, nurses, assistants, and the like who examine the infected patient 151 enter and exit the tent 102 through the entrance 108. Infected patient 151 lies on bed 152 carried into tent 102 for rest. In addition to the bed 152, a stretcher and a chair (both not shown) can be arranged in the tent 102.

  When the infected patient 151 is in the tent 102, the doorway 108 is covered with a hook-and-loop fastener (not shown) or the like. This weathering prevents air from leaking from the inside of the tent 102 to the outside. Moreover, the entrance / exit 108 may be freely opened and closed by a fastener.

  2A and 2B are perspective views showing a part of the tent 102 in an enlarged manner. A gap SP is formed between the tent 102 and the bottom surface 107. As shown in FIG. 2A, the gap SP may be formed by having a size that does not reach the bottom surface 107 slightly when the sheet 106 is attached to the frame 105. Further, as shown in FIG. 2B, the gap SP is bent even when the sheet 106 is large enough to reach the bottom surface 107 when the sheet 106 is attached to the frame 105. And the unevenness of the bottom surface 107 occurs between the sheet 106 and the bottom surface 107. Further, as shown in FIG. 2B, the gap SP also occurs in the overlapping portion of the sheets 106. That is, the tent 102 is not airtight.

  Returning to FIG. The air cleaning fumigator 103 is located outside the tent 102 and adjacent to the tent 102. The air purification fumigator 103 includes an air purification unit 103A and a fumigation unit 103B. The air cleaning unit 103A sucks air, cleans the sucked air with ozone, changes ozone remaining in the cleaned air into oxygen, and discharges it to the outside. The fumigation unit 103B generates and discharges ozone, creates an ozone atmosphere, and fumigates the space where ozone is discharged. The fumigation unit 103B also sucks air containing ozone and decomposes ozone contained in the sucked air. Details of the air cleaning fumigator 103 will be described later with reference to FIG.

  The isolation chamber forming apparatus 101 includes a connection pipe 109 as first and third communication structures. The connection pipe 109 is a cylindrical short tube that guides the air in the tent 102 to the air inlet 202 of the air cleaning fumigator 103. Here, the sheet | seat 106 has the exhaust hole 110 in the location located in the side surface 106b (left side surface in FIG. 1) of the tent 102 adjacent to the air cleaning fumigator 103. The exhaust hole 110 is positioned in the vicinity of the bottom surface 107 by attaching the seat 106 to the assembled frame 105. The connecting pipe 109 connects the exhaust hole 110 and the air inlet 202 of the air cleaning fumigator 103. Accordingly, the connecting pipe 109 plays a role of communicating the air inlet 202 of the air cleaning fumigator 103 with the internal space of the tent 102.

  The isolation chamber forming apparatus 101 includes a connection pipe 111 as a second communication structure. The connecting pipe 111 is a pipe having a bent shape that guides ozone generated in the air cleaning fumigator 103 to the internal space of the tent 102. Here, the seat 106 is attached to the assembled frame 105 and has an ozone introduction hole 112 at a location above the exhaust hole 110. Then, by attaching the seat 106 to the assembled frame 105, the ozone introduction hole 112 is positioned away from the bottom surface 107 and above the exhaust hole 110. The connection pipe 111 connects the ozone introduction hole 112 and the ozone discharge port 303 of the air purification fumigator 103. Therefore, the connecting pipe 111 plays a role of communicating the ozone discharge port 303 of the air cleaning fumigator 103 with the internal space of the tent 102.

  FIG. 3 is a schematic diagram showing the structure of the air cleaning fumigator 103. The air purification fumigator 103 includes a box-shaped housing 201. The housing 201 includes casters 221 that make the air purifier fumigator 103 movable at four corners of the lower surface. The housing 201 includes an air inlet 202 on the front surface thereof. The housing 201 has a device exhaust port 202a formed on the upper surface thereof. A plurality of blades (not shown) are attached to the housing 201 in parallel so as to traverse each of the intake port 202 and the apparatus exhaust port 202a. That is, the intake port 202 and the device exhaust port 202a are glazed.

  The housing 201 includes a display device 222 and an operation device 223 at a position that is an upper surface of the air purification fumigator 103. In addition, the housing 201 includes a communication unit 217 that receives various instruction signals transmitted from the remote controller RM at a position that is the front surface of the air cleaning fumigator 103. The display device 222 displays information such as the state of the air cleaning fumigator 103. The operation device 223 is used for operation input for causing a control circuit 226 (described later) to control each unit. The control circuit 226 controls each unit provided in the air cleaning fumigator 103 in accordance with an operation input from the operation device 223. Moreover, when it determines with the control circuit 226 having received the instruction | indication signal from the remote controller RM which the communication part 217 receives, according to the content of this instruction | indication signal, it controls each part with which the air purification fumigator 103 is equipped. That is, the operation input to the air cleaning fumigator 103 is realized by either the operation device 223 or the remote controller RM.

  The air cleaning fumigator 103 includes a wind tunnel 204 inside the housing 201. One end of the wind tunnel 204 is located in the vicinity of the air inlet 202. The other end of the wind tunnel 204 is located in the vicinity of the device exhaust port 202a. In this way, the wind tunnel 204 communicates the intake port 202 and the device exhaust port 202a.

  The air purification fumigator 103 is arranged in the wind tunnel 204 in order from the inlet 202 side to the apparatus outlet 202a side, in order, the prefilter 205, the fluorescent lamp 225, the photocatalyst 207, the first and second ozonolysis. An ozone decomposition catalyst 208 as a catalyst, a high-performance deodorizing filter 209, a carbon silk 210, a HEPA filter 211, a fan 212, and a negative ion generator 213 are provided. The pre-filter 205 collects large dust and dust. The fluorescent lamp 225 emits light. The photocatalyst 207 receives irradiating light from the fluorescent lamp 225 and performs sterilization and deodorization. The ozone decomposition catalyst 208 changes ozone into oxygen. The high-performance deodorizing filter 209 collects malodorous substances such as ammonia, acetic acid, and methyl mercaptan. The carbon silk 210 performs deodorization. The HEPA filter 211 collects fine particles. The fan 212 rotates to send the air in the wind tunnel 204 from the intake port 202 toward the device exhaust port 202a. The negative ion generator 213 generates negative ions. Note that the photocatalyst 207 and the ozone decomposition catalyst 208 are both carried on various carriers (not shown).

  Here, the installation position of the HEPA filter 211 is not limited to the position shown in FIG. In other words, the HEPA filter 211 is disposed upstream of the ozone generation point 206d by the cleaning ozone generator 206a on the upstream side (the intake port 202 side) of the gas path by the wind tunnel 204 and between the generation point 206d and the ozone decomposition catalyst 208. Further, it may be located downstream of the ozone decomposition catalyst 208 in the gas path by the wind tunnel 204 (on the apparatus exhaust port 202a side). However, by providing the HEPA filter 211 on the downstream side of the ozone decomposition catalyst 208, the fine particles contained in the air cleaned with ozone are captured by the HEPA filter 211. As a result, the air discharged from the apparatus exhaust port 202a is further cleaned.

  In addition, the air cleaning fumigation machine 103 includes a cleaning ozone generator 206a as a first ozone generator, a cleaning air pump 206aa, and a fumigation ozone generator as a second ozone generator inside the housing 201. 206b and a fumigation air pump 206bb. Both the cleaning ozone generator 206a and the fumigation ozone generator 206b generate ozone by creeping discharge, for example, and are well-known techniques.

  The cleaning air pump 206aa is disposed at the intake port 202. The cleaning air pump 206aa is connected to the cleaning ozone generator 206a through a hollow tube 305a. The cleaning ozone generator 206a is connected to a cleaning ejection nozzle 306a for ejecting gas through another tube 305a. The cleaning jet nozzle 306 a is disposed toward the inner space of the wind tunnel 204. When the cleaning air pump 206aa sends out air toward the cleaning ozone generator 206a, the ozone generated from the cleaning ozone generator 206a is jetted from the cleaning jet nozzle 306a.

  The fumigation air pump 206bb is arranged at the intake port 202. The fumigation air pump 206bb is connected to the fumigation ozone generator 206b via a hollow tube 305b. The fumigation ozone generator 206b is connected to a fumigation ejection nozzle 306b for ejecting gas via another tube 305b. The fumigation jet nozzle 306b is disposed in the apparatus exhaust port 202a. The fumigation air pump 206bb sends air toward the fumigation ozone generator 206b, so that the ozone generated from the fumigation ozone generator 206b is ejected from the fumigation ejection nozzle 306b.

  The air cleaning fumigator 103 includes a control unit 231 that drives and controls each unit. The control circuit 226 forms the core of the control unit 231. The control circuit 226 is connected to the display device 222, the operation device 223, the communication unit 217, the negative ion generator 213, and the dust sensor 218 that senses the degree of air contamination. The control circuit 226 is also connected to the fluorescent lamp 225 via a lighting circuit (not shown). The control circuit 226 is also connected to a motor 224 that is a drive source of the fan 212 via a power transmission mechanism (not shown). Further, the control circuit 226 is also connected to the cleaning ozone generator 206a, the cleaning air pump 206aa, the fumigation ozone generator 206b, and the fumigation air pump 206bb. The operation device 223 is for causing the air purifier / fumigator 103 to perform both operations of air cleaning and ozone fumigation, and functions as a first operation input unit and a function as a second operation input unit. Have both. The remote controller RM and the communication unit 217 are also for causing the air purifier / fumigator 103 to perform both operations of air cleaning and ozone fumigation, and function as the first operation input unit and the second operation. It also has a function as an input unit. The control circuit 226 outputs a control signal to each connected unit to control these units.

  Here, the control unit 231, the wind tunnel 204, the prefilter 205, the cleaning ozone generator 206a, the cleaning air pump 206aa, the tube 305a, the cleaning jet nozzle 306a, the fluorescent lamp 225, and the photocatalyst 207. The ozone decomposing catalyst 208, the high-performance deodorizing filter 209, the carbon silk 210, the HEPA filter 211, the fan 212, and the negative ion generator 213 constitute the air cleaning unit 103A. The control unit 231, the fumigation ozone generator 206b, the fumigation air pump 206bb, the tube 305b, and the fumigation nozzle 306b constitute a fumigation unit 103B.

  FIG. 4 is a schematic diagram showing a modification of the structure of the air cleaning fumigator 103. In the air cleaning fumigation machine 103 of FIG. That is, the air purifier fumigator 103 in FIG. 4 includes an ozone generator 206c as a first ozone generator and a second ozone generator, and an air pump 206cc that feeds air into the ozone generator 206c. I have. The air pump 206cc and the ozone generator 206c are connected by a hollow tube 305, and an electromagnetic valve V is connected to the ozone generator 206c through the hollow tube 305. A hollow tube 305a connected to the cleaning jet nozzle 306a and a hollow tube 305b connected to the fumigation jet nozzle 306b are connected to the electromagnetic valve V. The electromagnetic valve V selectively switches between these two tubes 305a and 305b. Such an electromagnetic valve V is connected to the control circuit 226, and the switching operation is controlled by the control circuit 226.

  Returning to the description based on FIG. The air purification fumigator 103 includes an exhaust path switching mechanism 114. The exhaust path switching mechanism 114 includes a thick cylinder 115 extending upward from the edge of the apparatus exhaust port 202a, and a first thin cylinder 116 and a second thin cylinder 117 extending laterally from the tip of the thick cylinder 115. The first narrow tube 116 is located above the tip of the wind tunnel 204 and reaches the outside of the tent 102. The tip of the first thin tube 116 serves as an exhaust port 203. The second narrow cylinder 117 is located above the ejection nozzle 306. The tip of the second thin cylinder 117 is an ozone discharge port 303, which is connected to the connection pipe 111 and reaches the inside of the tent 102.

  The air cleaning fumigator 103 includes an actuator 118 and a switching valve 119. The switching valve 119 moves between a position PA (shown by a dotted line in FIG. 3) that closes the first thin cylinder 116 and a position PB (shown by a solid line in FIG. 3) that closes the second thin cylinder 117. It is free. The actuator 118 is a drive source that moves the switching valve 119 and is driven in response to a control signal from the control circuit 226. By driving the actuator 118, the switching valve 119 moves between a position where the first thin cylinder 116 is closed and a position where the second thin cylinder 117 is closed.

  FIG. 5 is a flowchart showing the control flow of the air cleaning fumigator 103 when air cleaning is performed. When the control circuit 226 determines the input of the control signal of the air cleaning command input from the communication device 217 that has received the instruction signal issued from the operation device 223 or the remote controller RM (Y in step S101), the control circuit 226 controls the actuator 118. Driven, the switching valve 119 is positioned at the position PB, and the second thin cylinder 117 is closed (step S102).

  Subsequently, the control circuit 226 controls the cleaning ozone generator 206a (or the ozone generator 206), the lighting circuit (not shown) of the fluorescent lamp 225, and the negative ion generator 213 to drive them (step S103). ).

  Subsequently, the control circuit 226 releases the purified air from the device exhaust port 202a (step S104). More specifically, the control circuit 226 controls the cleaning air pump 206aa to send out ozone from the cleaning ozone generator 206a into the wind tunnel 204 in the air cleaning fumigator 103 shown in FIG. The fan 212 is moved by controlling the motor 224, and the air in the wind tunnel 204 is sent from the intake port 202 side to the exhaust port 203 side. Further, in the air purification fumigator 103 of the modified example shown in FIG. 4, the control circuit 226 controls the motor 224 to move the fan 212 and inhale the air in the wind tunnel 204 containing ozone emitted from the ozone generator 206. It sends out from the port 202 side to the exhaust port 203 side. In any case, since the second narrow cylinder 117 is closed by the process of step S102, the gas discharged from the apparatus exhaust port 202a passes through the inside of the first narrow cylinder 116, and the exhaust port 203. To the outside space.

  FIG. 6 is a flowchart showing the control flow of the air cleaning fumigator 103 when performing ozone fumigation. When the control circuit 226 determines the input of the control signal of the ozone fumigation command input from the operation device 223 or the communication unit 217 that has received the instruction signal issued from the remote controller RM (Y in step S201), the control circuit 226 controls the actuator 118. Driven, the switching valve 119 is positioned at the position PA, and the first thin cylinder 116 is closed (step S202).

  Subsequently, the control circuit 226 controls the fumigation ozone generator 206b (or the ozone generator 206) and the fumigation air pump 206bb to drive them (step S203). At this time, since the first thin cylinder 116 is closed, the gas discharged from the fumigation jet nozzle 306b and discharged from the apparatus exhaust port 202a (air containing ozone emitted from the fumigation ozone generator 206b) is Then, it passes through the inside of the second thin cylinder 117 and is discharged into the tent 102 through the exhaust port 203.

  Subsequently, the control circuit 226 waits for processing until the fumigation in the tent 102 is completed (step S204). As an example, this standby is performed until sufficient time has passed for the air in the tent 102 to be fumigated with ozone and the articles in the tent 102 to be disinfected. Here, the control circuit 226 determines in step S204 that the control circuit 226 is connected to a timer circuit (not shown) and that a predetermined time has elapsed due to the time measured by the timer circuit, and the process proceeds to step S205. May be. In step S204, the control circuit 226 determines input of a control signal issued from the operation device 223 when the operator determines that the article in the tent 102 has been sufficiently sterilized and inputs the operation from the operation device 223. Thus, the process may proceed to step S205. As another example, the standby in step S204 is performed until the control circuit 226 determines that the degree of contamination of the air sensed by the dust sensor 218 has reached a predetermined value. As another example of this, a measurement sensor (not shown) for measuring the ozone concentration is installed in the tent 102, and the control circuit 226 waits in response to a signal input from the ozone concentration measurement sensor in step S204. You may make it cancel a state.

  When the control circuit 226 determines that the fumigation in the tent 102 has been completed as described above (Y in step S204), the control circuit 226 stops the fumigation ozone generator 206b (or the ozone generator 206) and the fumigation air pump 206bb. Then, the actuator 118 is driven to position the switching valve 119 at the position PB, and the second narrow cylinder 117 is closed (step S205).

  Subsequently, the control circuit 226 executes a process for collecting ozone in the tent 102 (step S206). More specifically, in step S206, the control circuit 226 first controls the lighting circuit (not shown) of the fluorescent lamp 225 and the negative ion generator 213 to drive them. What is important here is that the control circuit 226 does not control either the cleaning ozone generator 206a or the fumigation ozone generator 206b. Subsequently, the control circuit 226 controls the motor 224 to move the fan 212 and sends the air in the wind tunnel 204 from the intake port 202 side to the exhaust port 203 side. Thereby, the air in the tent 102 is sucked into the air purifying fumigator 103 from the air inlet 202, and the air purifying fumigator 103 decomposes ozone contained in the sucked air. That is, the intake port 202 also serves as an ozone intake port, and the connection pipe 109 also functions as a third communication structure.

  Please refer to FIG. 1 and FIG. In such an isolation room forming apparatus 101, when the infected patient 151 is accommodated in the tent 102, the operator operates the remote controller RM or the operation device 223 of the air cleaning fumigator 103 to operate the air cleaning fumigator 103. An air clean command is input to the operation. In response, in the air cleaning fumigator 103, the air cleaning unit 103A cleans the air in the tent 102. More specifically, when an air cleaning command is input to the air cleaning fumigator 103, the second thin cylinder 117 is closed, and the cleaning ozone generator 206a (or the ozone generator 206) and a lighting circuit (not shown) are displayed. And the negative ion generator 213 are driven. Accordingly, the cleaning ozone generator 206a (or the ozone generator 206) generates ozone. In addition, the fluorescent lamp 225 is turned on and the photocatalyst 207 performs sterilization and deodorization. Further, the negative ion generator 213 generates negative ions.

  In the air cleaning fumigator 103, the fan 212 rotates. Thereby, the air in the tent 102 is sucked from the exhaust hole 110, passes through the connecting pipe 109, and enters the air cleaning fumigator 103 from the intake port 202. Then, the air that has entered the air cleaning fumigator 103 passes through the wind tunnel 204 and reaches the exhaust port 203 through the device exhaust port 202a. At this time, the air cleaning fumigator 103 cleans the air in the wind tunnel 204. More specifically, the air that has entered the air purifier fumigator 103 from the intake port 202 passes through the prefilter 205. The pre-filter 205 removes large dust. The ozone generated from the cleaning ozone generator 206a (or the ozone generator 206) sterilizes and deodorizes the air that has passed through the prefilter 205. The photocatalyst 207 sterilizes and deodorizes this air. The ozone decomposition catalyst 208 changes the ozone remaining in the air into oxygen. The high-performance deodorizing filter 209 removes malodorous substances from the air that has passed through the photocatalyst 207 and the ozone decomposition catalyst 208. The carbon silk 210 deodorizes the air that has passed through the high-performance deodorizing filter 209. The HEPA filter 211 removes remaining floating bacteria and dust remaining in the air that has passed through the carbon silk 210. As a result, the air that has passed through the HEPA filter 211 is cleaned. The negative ion generator 213 mixes negative ions with the purified air. The air containing the negative ions reaches the exhaust port 203 through the device exhaust port 202 a and is discharged to the outside of the tent 102.

  In this manner, the air cleaning fumigator 103 sucks air in the tent 102 that may contain a pathogen held by the infected patient 151, cleans it using ozone, and discharges it to the outside. At this time, the inside of the tent 102 becomes a negative pressure due to the air suction of the air cleaning fumigator 103. For this reason, even if the air outside the tent 102 enters the inside of the tent 102 through the gap SP, the air inside the tent 102 does not leak outside from the air cleaning fumigator 103. That is, while the air purification fumigator 103 is driven, the air in the tent 102 does not leak directly to the outside, and pathogens from the infected patient 151 do not leak to the outside of the tent 102.

  When the infected patient 151 stays in the tent 102 and leaves the tent 102, the operator operates the remote controller RM or the operation device 313 of the air cleaning fumigator 103 to operate the air cleaning fumigator 103. Operation input of ozone fumigation command. In response, in the air cleaning fumigator 103, the fumigation unit 103B performs ozone fumigation of the tent 102. More specifically, when an ozone fumigation command is input to the air cleaning fumigator 103, the first thin tube 116 is closed, and the fumigation ozone generator 206b (or the ozone generator 206) and the fumigation air pump 206bb Drive. When the fumigation air pump 206bb is driven, the ozone generated by the fumigation ozone generator 206b (or the ozone generator 206) is ejected from the fumigation ejection nozzle 306b and fumigates the inside of the tent 102. As a result, the articles in the tent 102 such as the frame 105, the inner surface of the sheet 106, and the bed 152 are sterilized, and the tent 102 can be used repeatedly.

  When the ozone fumigation in the tent 102 ends, the fumigation unit 103B starts decomposing ozone remaining in the tent 102. More specifically, the switching valve 119 closes the second thin tube 117, the lighting circuit (not shown) and the negative ion generator 213 are driven, and the fan 212 is rotated. Thereby, the air in the tent 102 enters the air cleaning fumigator 103, passes through the wind tunnel 204, reaches the exhaust port 203 through the device exhaust port 202a. At this time, ozone remaining in the air passing through the wind tunnel 204 is converted into oxygen by the ozone decomposition catalyst 208. Then, this air reaches the exhaust port 203 through the device exhaust port 202 a and is discharged to the outside of the tent 102.

  Here, when the fumigation unit 103B performs ozone fumigation in the tent 102, the air cleaning fumigator 103 takes in the air in the tent 102. Then, the air purification fumigator 103 changes the oxygen in the taken-in air into ozone and returns the air into the tent 102 again. At this time, since the pressure is balanced between the inside and outside of the tent 102, the ozone in the tent 102 is unlikely to leak out.

  When the fumigation unit 103B decomposes ozone in the tent 102, the air cleaning fumigator 103 sucks the air in the tent 102 containing ozone, and passes the sucked air to the ozone decomposition catalyst 208. Later, it is discharged to the outside. At this time, since the inside of the tent 102 has a negative pressure, even if air outside the tent 102 enters the inside of the tent 102 through the gap SP, ozone inside the tent 102 does not leak outside.

  When the operator determines that sufficient time has passed for the ozone remaining in the tent 102 to disappear, the operator inputs an operation from the operation device 223 and stops the air cleaning fumigator 103.

  What is important here is that the operator performs both the operation of causing the air purification fumigator 103 to clean the air in the tent 102 and the operation of causing the air purification fumigation machine 103 to perform ozone fumigation outside the tent 102. Is that you can. That is, when the infected patient 151 is in the tent 102, there is a possibility that pathogen is contained in the air in the tent 102. In this case, if a person other than the infected patient 151 enters the tent 102, there is a risk of being infected with the pathogen. Further, when the inside of the tent 102 is filled with ozone due to ozone fumigation, it is still dangerous for a human to enter the tent 102 because ozone is toxic to the human body. In this regard, in the isolation chamber forming apparatus 101, the air cleaning fumigation machine 103 is installed outside the tent 102, so that the operator can operate it without entering the tent 102. Therefore, the operator can safely clean and fumigate the air in the tent 102 for isolating the infected patient 151 without being exposed to the risk of contact with pathogens or ozone.

  Further, in the isolation chamber forming apparatus 101 of the present embodiment, since the air purifier fumigator 103 is installed outside the tent 102, it can be easily installed not only indoors but also outdoors, The removal cost can be reduced.

  Furthermore, in the isolation chamber forming apparatus 101 of the present embodiment, the air cleaning fumigation machine 103 sucks air in the tent 102 after performing ozone fumigation, and actively decomposes ozone remaining in the sucked air. The concentration of ozone in the tent 102 can be quickly reduced, and the usage efficiency of the tent 102 can be increased.

  Here, the control content of the control circuit when using the air cleaning fumigator shown in FIG. 4 will be described.

  When the control circuit 226 determines the input of the air cleaning command (Y in step S101 in FIG. 5), the air pump 206cc and the ozone generator 206c are driven, and the tube 305 connected to the ozone generator 206c is ejected for cleaning. The electromagnetic valve V is switched and controlled so as to communicate with the tube 305a that communicates with the nozzle 306a. As a result, the air cleaning unit 103A performs the same operation as described above.

  When the control circuit 226 determines the input of the ozone fumigation command (Y in step S201 in FIG. 6), the air pump 206cc and the ozone generator 206c are driven, and the tube 305 connected to the ozone generator 206c is ejected for fumigation. The electromagnetic valve V is switched and controlled so as to communicate with the tube 305b that communicates with the nozzle 306b. Thereby, the fumigation part 103B performs the same fumigation operation as the fumigation operation described above.

  When the fumigation unit 103B of the air cleaning fumigator 103 performs the ozone recovery operation (Y in step S204 in FIG. 6), the control circuit 226 does not operate the air pump 206cc and the ozone generator 206c, and switches the electromagnetic valve V. Do not control. Thereby, the fumigation part 103B performs the same ozone recovery operation as the ozone recovery operation described above.

  FIG. 7 is a schematic diagram showing a modification of the isolation chamber forming apparatus 101 according to the present embodiment. The tent 102 constituting the isolation chamber forming apparatus 101 may form a horizontally long internal space that can accommodate the bed 152 described with reference to FIG. 1, or as shown in FIG. A vertically long simple tent 102 ′ that forms an internal space in which only a chair 153 for one person can be installed may be used. Furthermore, the shape of the tent 102 is not limited to the example shown in FIG. 1 and FIG. 7, and the sheet 106 covers the frame 105 so that the space for accommodating the infected patient 151 is isolated from the outside. Any shape can be used.

  Next, another embodiment (second embodiment) will be described with reference to FIGS. In this case, the same reference numerals are used for the same parts as those in the first embodiment, and description thereof is also omitted. In the isolation chamber forming apparatus 101 of the present embodiment, the function of the air cleaning unit 103A provided in the air cleaning fumigator 103 is realized by the air cleaning device 181. The function of the fumigation unit 103B provided in the air cleaning fumigator 103 is realized by the ozone fumigator 182.

  FIG. 8 is a schematic diagram showing the entire isolation chamber forming apparatus 101. Both the air cleaner 181 and the ozone fumigator 182 are provided outside the tent 102 and adjacent to the tent 102. The air cleaner 181 and the ozone fumigator 182 may be arranged at positions separated from each other as shown in FIG. Moreover, the air cleaner 181 and the ozone fumigator 182 may be adjacent to each other.

  The air cleaner 181 is a device that sucks air, cleans the sucked air with ozone, and discharges the air to the outside. That is, the air cleaner 181 plays a role as the air purifier 103A. Details of the air cleaner 181 will be described later with reference to FIG.

  The ozone fumigator 182 generates and discharges ozone, creates an ozone atmosphere, and fumigates the space where ozone is discharged. The ozone fumigator 182 also sucks air containing ozone and decomposes ozone contained in the sucked air. That is, the ozone fumigator 182 serves as the fumigation unit 103B. Details of the ozone fumigator 182 will be described later with reference to FIG.

  The isolation chamber forming apparatus 101 includes a connection pipe 109 as a first communication structure. The connection pipe 109 is a cylindrical short cylinder that guides the air in the tent 102 to the air inlet 202 of the air cleaner 181. Here, the sheet 106 has an exhaust hole 110 at a position positioned on one side surface 106 b (the left side surface in FIG. 1) of the tent 102 adjacent to the air cleaner 181. Then, the exhaust hole 110 is positioned in the vicinity of the bottom surface 107 by attaching the seat 106 to the frame 105 of the assembled tent 102. The connecting pipe 109 connects the exhaust hole 110 and the air inlet 202 of the air cleaner 181.

  The isolation chamber forming apparatus 101 includes a connection pipe 111 as a second communication structure. The connecting pipe 111 is a pipe that guides ozone generated by the ozone fumigator 182 to the inside of the tent 102. Here, the sheet 106 has an ozone introduction hole 112 at a position positioned on one side surface 106 c (the right side surface in FIG. 1) of the tent 102 adjacent to the ozone fumigator 182. Then, by attaching the sheet 106 to the frame 105 of the assembled tent 102, the ozone introduction hole 112 is positioned on the side surface 106c. The connection pipe 111 connects the ozone introduction hole 112 and the ozone discharge port 303 of the ozone fumigator 182.

  Further, the isolation chamber forming apparatus 101 also includes a connection pipe 121 as a third communication structure that guides the air in the tent 102 to the ozone fumigator 182. Here, the sheet 106 has an ozone decomposition hole 122 at a position attached to the assembled frame 105 and below the ozone introduction hole 112. Then, by attaching the seat 106 to the assembled frame 105, the ozone decomposition hole 122 is positioned away from the bottom surface 107 and below the ozone introduction hole 112. The connection pipe 121 connects the ozone decomposition hole 122 and the ozone intake port 351 of the ozone fumigator 182.

  FIG. 9 is a schematic diagram showing the structure of the air cleaner 181. The air cleaner 181 according to the present embodiment is configured to include each part related to the air purifier 103A among the parts included in the air cleaner fumigator 103 according to the first embodiment.

  That is, the air cleaner 181 does not include the fumigation ozone generator 206b, the fumigation air pump 206bb, the tube 305b, and the fumigation jet nozzle 306b. Further, the air cleaner 181 does not include the exhaust path switching mechanism 114, the switching valve 119, and the actuator 118. In the air cleaner 181, the device exhaust port 202 a serves as the exhaust port 203.

  The control circuit 226 provided in the air cleaner 181 executes the process shown in FIG. However, the air cleaner 181 does not include the actuator 118. Therefore, the control circuit 226 executes processing other than step S102 shown in FIG. That is, when the control circuit 226 determines the input of the control signal of the air cleaning command input using the operation device 223 or the remote controller RM (Y in step S101), the cleaning ozone generator 206a and the fluorescent lamp 225 are controlled. A lighting circuit (not shown) and the negative ion generator 213 are controlled to drive them (step S103). Subsequently, the control circuit 226 controls the motor 224 to move the fan 212, and sends the air in the wind tunnel 204 from the intake port 202 side to the exhaust port 203 side and releases it to the external space (step S104).

  FIG. 10 is a schematic diagram showing the structure of the ozone fumigator 182. The ozone fumigator 182 of the present embodiment is configured to include each part related to the fumigation part 103B among the parts provided to the air cleaning fumigator 103 of the first embodiment.

  That is, the ozone fumigator 182 includes a box-shaped housing 301. The housing 301 includes casters 311 that can move the ozone fumigator 182 at four corners of the lower surface. The housing 301 has an air inlet 302 formed on the upper surface thereof. Further, the housing 301 forms an ozone discharge port 303 on a side surface thereof. The housing 301 arranges the display device 312 and the operation device 313 at a position that is the upper surface of the ozone fumigator 182. In addition, the housing 301 includes a communication unit 317 that receives various instruction signals transmitted from the remote controller RM at a position that is the front surface of the ozone fumigator 182. The display device 312 displays information such as the state of the ozone fumigator 182. The operation device 313 is used for operation input for causing a control circuit 315 (described later) to control each unit. The control circuit 315 controls each unit provided in the ozone fumigator 182 in accordance with an operation input from the operation device 313. Further, when it is determined that the instruction signal from the remote controller RM received by the communication unit 317 is received, the control circuit 315 controls each unit included in the ozone fumigator 182 according to the content of the instruction signal. That is, the operation input to the ozone fumigator 182 is realized by either the operation device 313 or the remote controller RM.

  In the ozone fumigator 182, a fumigation ozone generator 304 and a tube 305 are disposed inside the housing 301. The tube 305 extends from the air inlet 302 to the ozone outlet 303 through the fumigating ozone generator 304. That is, the tube 305 communicates the air inlet 302 and the ozone outlet 303. The tube 305 includes a fumigation air pump 314 at an end located at the air inlet 302. The fumigation air pump 314 is located in the vicinity of the air inlet 302 and sends out air toward the fumigation ozone generator 304. And the tube 305 is provided with the ejection nozzle 306b for fumigation for ejecting gas in the edge part located in the ozone discharge port 303. FIG. The ozone generated by the fumigation ozone generator 304 is ejected from the fumigation ejection nozzle 306b through the inside of the tube 305.

  In the ozone fumigator 182, the housing 301 includes an ozone inlet 351 below the ozone outlet 303. The housing 301 includes an ozone-decomposed exhaust port 352 on a surface opposite to the surface including the ozone intake port 351. The ozone fumigator 182 includes a wind tunnel 353 that communicates the ozone inlet 351 and the ozone decomposed outlet 352. The ozone fumigator 182 has a fluorescent lamp 354, a photocatalyst 355, and an ozone decomposition catalyst as a second ozone decomposition catalyst in the wind tunnel 353 in order from the ozone intake port 351 side to the ozone decomposition exhaust port 352 side. 356, a high-performance deodorizing filter 357, carbon silk 358, a fan 359, and a negative ion generator 360. The ozone fumigator 182 includes a lighting circuit (not shown) for lighting the fluorescent lamp 354 and a motor 361 for moving the fan 359 inside the housing 301.

  The ozone fumigator 182 includes a control unit 321 that drives and controls each unit. The control circuit 315 is the core of the control unit 321. The control circuit 315 includes a display device 312, an operation device 313, a fumigation ozone generator 304, a fumigation air pump 314, a lighting circuit (not shown), a negative ion generator 360, a motor 361, dust To the sensor 218. The control circuit 315 outputs a control signal to each connected unit and controls these units.

  The control circuit 315 provided in the ozone fumigator 182 executes the processing shown in FIG. However, the ozone fumigator 182 does not include the actuator 118. For this reason, the control circuit 315 executes processes other than steps S202 and S205 shown in FIG. That is, when the control circuit 315 determines the input of the control signal of the ozone fumigation command input using the operation device 313 or the remote controller RM (Y in step S201), the fumigation ozone generator 304 and the fumigation air pump 314 are determined. These are driven to release ozone into the tent 102 (step S203). Subsequently, the control circuit 315 waits for processing until it is determined that ozone fumigation in the tent 102 has been completed (step S204). Subsequently, after waiting, the control circuit 315 stops the fumigation ozone generator 304 and the fumigation air pump 314 (step S204a), controls the lighting circuit (not shown) of the fluorescent lamp 354, and controls the negative ion generator 360. Subsequently, the control circuit 315 controls the motor 361 to move the fan 359 and send the air in the wind tunnel 353 from the ozone intake port 351 side to the ozone-decomposed exhaust port 352 side. It collects (step S206).

  Please refer to FIG. 8 and FIG. In such an isolation room forming apparatus 101, when the infected patient 151 is accommodated in the tent 102, the operator operates the operation device 223 of the air cleaner 181 or the remote controller RM to activate the air cleaner 181. To do. By this operation input, the air cleaner 181 sucks the air in the tent 102, passes the sucked air through various filters, cleans the air with ozone, and remains without being used for cleaning. The ozone is changed to oxygen and released to the outside of the tent 102.

  Please refer to FIG. 8 and FIG. When the infected patient 151 stays in the tent 102 and then leaves the tent 102, the operator operates the operation device 313 of the ozone fumigator 182 and the remote controller RM to activate the ozone fumigator 182. By this operation input, the ozone fumigator 182 generates ozone and ejects it into the tent 102 to fumigate the tent 102. Thereafter, when the ozone fumigation in the tent 102 is finished, the ozone fumigator 182 sucks the air in the tent 102 and changes the ozone contained in the air sucked by the ozone decomposition catalyst 356 into oxygen, and converts the air into the tent 102. To the outside.

  Here, when the air cleaner 181 cleans the air in the tent 102, the air cleaner 181 sucks the air in the tent 102. When the ozone fumigator 182 performs ozonolysis of the air in the tent 102, the ozone fumigator 182 sucks the air in the tent 102. In any of these cases, negative pressure is generated in the tent 102. For this reason, even if the air outside the tent 102 enters the inside of the tent 102 through the gap SP, the air inside the tent 102 does not leak to the outside. In addition, when the ozone fumigator 182 performs ozone fumigation in the tent 102, the ozone fumigator 182 generates ozone from oxygen in the air taken from the outside of the tent 102 and releases it into the tent 102. Therefore, in order to make the inside of the tent 102 have a negative pressure, the operator operates the air cleaner 181 so as to keep the air in the tent 102 at a negative pressure. As a modification, a pipe that connects the air inlet 302 of the ozone fumigator 182 and the tent 102 is provided, and the ozone fumigator 182 sucks air in the tent 102 to generate ozone, and the ozone fumigator 182 generates. The ozone thus discharged may be discharged from the ozone discharge port 303 into the tent 102. In this case, the operator may or may not activate the air cleaner 181.

  Even in the isolation chamber forming apparatus 101 of the present embodiment, the operator can perform ozone fumigation in the air cleaning fumigator 103 even when the air cleaning fumigation machine 103 performs air cleaning in the tent 102 outside the tent 102. You can also perform operations. That is, the operator does not come into contact with pathogens or ozone. Therefore, the operator can safely clean and fumigate the air in the tent 102 for isolating the infected patient 151 without being exposed to the risk of contact with pathogens or ozone.

  Next, still another embodiment (third embodiment) will be described with reference to FIGS. This embodiment is based on the second embodiment. In this case, the same parts as those in the second embodiment are denoted by the same reference numerals, and the description thereof is also omitted.

  FIG. 11 is a schematic diagram showing the entire isolation chamber forming apparatus 101. In the isolation chamber forming apparatus 101 of the present embodiment, the fumigation unit 103B is realized by both the air purifier 181 and the ozone fumigator 182. The tent 102 does not have the ozone decomposition hole 122. Further, the isolation chamber forming apparatus 101 does not include the connecting pipe 121.

  FIG. 12 is a schematic diagram showing the structure of the ozone fumigator 182. The ozone fumigator 182 is a further simplified structure of the ozone fumigator 182 (see FIG. 10) of the second embodiment.

  That is, the air inlet 302 and the ozone outlet 303 are formed in the housing 301 of the ozone fumigator 182, but the ozone inlet 351 and the ozone decomposed outlet 352 are not formed. In addition, the ozone fumigator 182 does not have a function of decomposing ozone in the tent 102. For this reason, a wind tunnel 353, a fluorescent lamp 354, a lighting circuit (not shown), a photocatalyst 355, an ozone decomposing catalyst 356, The high-performance deodorizing filter 357, the carbon silk 358, the fan 359, the negative ion generator 360, and the motor 361 are not provided.

  And the control circuit 315 with which the ozone fumigator 182 is provided performs only the process of step S201 and step S203 among the processes shown in FIG. That is, the control circuit 315 controls the fumigation ozone generator 304 and the fumigation air pump 314 when determining the input of the control signal of the ozone fumigation command inputted from the operation device 313 (Y in step S201). Driven to release ozone into the tent 102 (step S203).

  FIG. 13 is a flowchart showing the control flow of the air cleaner 181 when performing ozonolysis. In the present embodiment, the air cleaner 181 takes charge of decomposing ozone in the tent 102 remaining after fumigation.

  When the control circuit 226 provided in the air purifier 181 determines the input of the control signal of the ozone decomposition command input using the operation device 223 or the remote controller RM (Y in step S301), the control circuit 226 executes ozone recovery (step S301). Step S302). More specifically, in step S302, the control circuit 226 controls the lighting circuit (not shown) of the fluorescent lamp 225 and the negative ion generator 213 to drive them. What is important here is that the control circuit 226 does not control the cleaning ozone generator 206a and the cleaning air pump 206aa at this time, and does not generate ozone in the cleaning ozone generator 206a. Subsequently, the control circuit 226 controls the motor 224 to move the fan 212 and sends the air in the wind tunnel 204 from the intake port 202 side to the exhaust port 203 side. That is, in the present embodiment, the intake port 202 also serves as an ozone intake port, and the intake port 202 also functions as a third communication structure.

  Please refer to FIG. 11 and FIG. In such an isolation room forming apparatus 101, when the infected patient 151 is accommodated in the tent 102, the operator operates the operation device 223 of the air cleaner 181 or the remote controller RM to clean the air in the air cleaner 181. The command is input and the air in the tent 102 is cleaned by the air cleaner 181.

  When the infected patient 151 stays in the tent 102 and leaves the tent 102, the operator operates the operation device 313 of the ozone fumigator 182 or the remote controller RM to input an ozone fumigation command to the ozone fumigator 182. Then, the inside of the tent 102 is fumigated by the ozone fumigator 182. Then, the operator operates the operation device 223 of the air cleaner 181 and the remote controller RM to input an ozone decomposition command to the air cleaner 181 so that the air cleaner 181 recovers ozone in the tent 102.

  Here, in the present embodiment, the ozone fumigator 182 sucks air from the outside of the tent 102, generates ozone from oxygen contained in the sucked air, and sends it into the tent 102. For this reason, ozone fumigation may cause the inside of the tent 102 to have a positive pressure, and ozone may leak from the gaps of the tent 102. For this reason, in this embodiment, when the operator activates the ozone fumigator 182 to perform ozone fumigation in the tent 102, the air purifier 181 is also activated at the same time so that the inside of the tent 102 does not become a positive pressure. With the output, the air in the tent 102 needs to be discharged to the air cleaner 181. After operating the ozone fumigator 182 for a predetermined time, the operator inputs an operation from the operation device 313 to stop the ozone fumigator 182. As a result, the ozone remaining in the tent 102 is released to the outside of the tent 102 after being changed to oxygen by the air cleaner 181. When the ozone in the tent 102 has disappeared, the operator inputs an operation from the operation device 223 and stops the air cleaner 181. As a modification, a pipe that connects the air inlet 302 of the ozone fumigator 182 and the tent 102 is provided, and the ozone fumigator 182 sucks air in the tent 102 to generate ozone, and the ozone fumigator 182 generates. The ozone thus discharged may be discharged from the ozone discharge port 303 into the tent 102. In this case, the operator may or may not operate the air purifier 181 while the ozone fumigator 182 performs ozone fumigation in the tent 102. Of course, the operator needs to operate the air cleaner 181 in order for the air cleaner 181 to decompose the ozone in the tent 102.

  Also in the isolation chamber forming apparatus 101 of the present embodiment, the operator operates the air cleaner 181 to clean the air in the tent 102 outside the tent 102 and the ozone fumigator 182 in the ozone fumigation in the tent 102. Any of the operations for performing the operation can be performed. That is, the operator does not come into contact with pathogens or ozone. Therefore, the operator can safely clean and fumigate the air in the tent 102 for isolating the infected patient 151 without being exposed to the risk of contact with pathogens or ozone.

  Furthermore, in the isolation chamber forming apparatus 101 of the present embodiment, an ozone fumigator 182 with a simplified structure can be employed. For this reason, the manufacturing cost of the isolation chamber forming apparatus 101 can be reduced, and the isolation chamber forming apparatus 101 can be easily installed and removed.

  FIG. 14 is a perspective view showing a modification of the air cleaner 181 and the ozone fumigator 182 of the present embodiment. In the isolation chamber forming apparatus 101, the air cleaner 181 and the ozone fumigator 182 can be accommodated and integrated using a rectangular parallelepiped housing 401. The housing 401 has a rectangular parallelepiped shape. The housing 401 includes casters 402 at the four corners of the lower surface. The housing 401 does not have an upper surface and one side surface, and an opening 403 is formed there. The air cleaner 181 and the ozone fumigator 182 are introduced from the opening 403 and placed on the bottom surface of the housing 401. In the housing 401, a recess 404 for positioning the caster 221 provided in the air cleaner 181 is formed on the bottom surface. When the caster 221 provided in the air cleaner 181 enters the recess 404, the air cleaner 181 does not fall out of the housing 401. Further, when the caster 311 provided in the ozone fumigator 182 enters the recess 404, the ozone fumigator 182 does not fall out of the housing 401. At this time, the inlet 202 formed in the air cleaner 181 and the ozone outlet 303 formed in the ozone fumigator 182 are arranged side by side as shown in FIG. The end of the connection pipe 109 connected to the exhaust hole 110 of the tent 102 is connected to the intake port 202. A connecting pipe 111 connected to the ozone introduction hole 112 of the tent 102 is connected to the ozone discharge port 303. And the exhaust port 203 formed in the air cleaner 181 and the air introduction port 302 formed in the ozone fumigator 182 both face upward.

  Both the air cleaner 181 and the ozone fumigator 182 are also installed outside the tent 102 by the isolation chamber forming apparatus 101 of the present embodiment. For this reason, the operator can perform both negative pressure and cleaning of the air in the tent 102 and ozone fumigation of the air in the tent 102 while being outside the tent 102. Therefore, the operator can safely clean and fumigate the air in the tent 102 for isolating the infected patient 151 without being exposed to the risk of contact with pathogens or ozone.

  Furthermore, in the isolation chamber forming apparatus 101 of the present embodiment, the air cleaner 181 and the ozone fumigator 182 are integrated by the housing 401. For this reason, the installer who installs the isolation chamber forming apparatus 101 can simplify the trouble of installing the air purifier 181 and the ozone fumigator 182 when installing the isolation chamber forming apparatus 101 on the bottom surface 107.

101 Isolation chamber forming device 102 Tent 103 Air cleaning fumigation machine (air cleaning section, fumigation section)
103A Air cleaning part 103B Fumigation part 109 Connection pipe (first communication structure, third communication structure)
111 Connection pipe (second communication structure)
121 Connection pipe (third communication structure)
151 Infected patients 181 Air Cleaner (Air Cleaner)
182 Ozone fumigation machine (Fumigation Department)
201 Housing 202 Inlet (ozone inlet)
203 Exhaust port 206 Ozone generator (first ozone generator, second ozone generator)
206a Ozone generator for cleaning (first ozone generator)
206b Ozone generator for fumigation (second ozone generator)
206d Ozone generation point 208 Ozone decomposition catalyst (first ozone decomposition catalyst)
211 HEPA filter 217 Communication unit (first operation input unit)
223 operation device (first operation input unit, second operation input unit)
303 Ozone outlet 304 Ozone generator (second ozone generator)
313 Operation device (second operation input unit)
317 Communication unit (second operation input unit)
351 Ozone inlet 356 Ozone decomposition catalyst (second ozone decomposition catalyst)
RM remote controller (first operation input unit, second operation input unit)

Claims (5)

A non-airtight tent to isolate and house infected patients;
An intake port, an exhaust port, a first ozone generator, a first operation input unit for performing an operation input, a first ozone decomposition catalyst for changing ozone into oxygen, and HEPA for collecting particulates A filter, and sucks air from the intake port in response to an operation input from the first operation input unit, and the sucked air generates ozone generated by the first ozone generator and the ozone decomposition An air purifier that passes in the order of the catalyst and passes through the HEPA filter and is discharged from the exhaust port;
A second ozone generator, an ozone discharge port, an ozone intake port, a second operation input unit for performing an operation input, and a second ozone decomposition catalyst for changing ozone into oxygen, In response to an operation input from the second operation input unit, ozone emission is generated in the second ozone generator and sent to the ozone discharge port, and air containing the discharged ozone is supplied to the ozone intake port. A fumigation section that performs ozone recovery that is sucked from and passed through the second ozone decomposition catalyst;
A first communication structure that communicates the air inlet of the air purifier installed outside the tent and the internal space of the tent, and guides the air in the tent to the air purifier,
A second communication structure that communicates the ozone discharge port of the fumigation unit installed outside the tent and the internal space of the tent, and guides the ozone generated in the fumigation unit to the inside of the tent;
A third communication structure that communicates the ozone inlet of the fumigation part installed outside the tent and the internal space of the tent, and guides the air inside the tent to the fumigation part;
Equipped with a,
The air purifying unit and the fumigation unit have a single intake port sharing the intake port and the ozone intake port, the exhaust port, the ozone discharge port, the first operation input unit, Stored in a single housing having the second operation input unit,
The first communication structure and the third communication structure are shared by a single structure that allows communication between the single air inlet and the internal space of the tent.
Isolation chamber forming device. The HEPA filter is provided on the downstream side of the ozone decomposition catalyst in a gas path passing through the air cleaning unit.
The isolation chamber forming apparatus according to claim 1. The air cleaning unit and the fumigation unit share the first ozone generator and the second ozone generator by a single ozone generator.
The isolation chamber forming apparatus according to claim 1 or 2 . The air purification unit and the fumigation unit share the first ozone decomposition catalyst and the second ozone decomposition catalyst by a single ozone decomposition catalyst.
The isolation chamber forming apparatus according to claim 1 or 2 . Installed outside the non-airtight tent isolating housing the infected patient, air inlet and an exhaust outlet, a housing and a first operation input unit for performing operation input, the first ozone generator When a first ozone decomposition catalyst for changing the ozone into oxygen, air cleaning unit which incorporates a HEPA filter for collecting particulates from the air inlet in accordance with an input from said first operation input unit The inside of the tent is sucked through a connecting pipe provided in the tent, and the sucked air is passed through the ozone generation site by the first ozone generator and the ozone decomposition catalyst in this order, and the HEPA Passing through a filter and discharging from the exhaust port;
Located outside of the tent, with a ozone outlet, and a single inlet the an ozone inlet of the intake port and shared, and a second operation input unit for performing an operation input to said housing The fumigation unit, which contains the second ozone generator and the second ozone decomposition catalyst for changing ozone into oxygen , is provided in the housing in response to an operation input from the second operation input unit. An ozone release step of generating ozone in the ozone generator and sending it toward the ozone outlet;
An ozone recovery step in which the fumigation unit sucks air containing ozone discharged from the ozone discharge port from the ozone intake port through the connection pipe and passes it through the second ozone decomposition catalyst;
Isolation room cleaning fumigation method comprising.

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