JP2022071972A - Air cleaner - Google Patents

Abstract

To provide an air cleaner capable of preventing the risk of secondary infection caused by viruses and bacteria captured in the cleaner.SOLUTION: An air cleaner 10 includes a housing 14 in which air flows, a bacterium-virus capturing filter 40 installed in the housing for capturing bacteria or viruses, a bacterium-virus deactivation gas generating unit 38 installed in the housing 14 for generating a gas to deactivate the bacteria or viruses. The bacterium-virus deactivation gas generating unit 38 works in the closed state of the housing 14 including the bacterium-virus deactivation gas generating unit 38 and the bacterium-virus capturing filter 40.SELECTED DRAWING: Figure 3

Description

The present invention relates to an air purification device.

The new coronavirus has become a social problem, and it is an important issue to ensure the safety of medical staff and prevent infection in hospitals, especially in hospital-acquired infections in the medical field. WHO has also confirmed that the new coronavirus can be transmitted by inhaling fine particles containing viruses floating in the air. Fine particles containing these viruses contain a large number of viruses in the particles of the brim and runny nose. It has been found that not only sneezing and sneezing but also normal conversation is released from the mouth and nose. It is conceivable to capture these floating fine particles in the air using a filter of an air purification device to prevent infection by a virus.

In addition, new types of coronaviruses such as MARS, SARS, and this time coronavirus have been repeatedly outbreaks and epidemics for several years. Furthermore, infection, such as the new influenza that originated in pigs, where inhalation of fine particles floating in the air is one of the infection routes, has become a global issue, and countermeasures are required.

Therefore, it is conceivable to mount a high-performance filter on an air purification device, and an air purification device equipped with a high-performance HEPA filter is known, for example, as shown in Patent Document 1.

Japanese Unexamined Patent Publication No. 2017-537294

However, although these air purification devices can capture viruses and bacteria, they cannot sterilize them, and the captured viruses and bacteria and the viruses and bacteria attached to the inner wall of the air purification device cause secondary infection. There is a risk of. The principle will be described below.

Fine particles containing viruses suspended in the air are sucked into the air purification device by the power of a fan and captured by the fibers of the filter as they pass through the HEPA filter. In addition, a part of it adheres to the inner wall of the air purification device and the surface of other parts. The density of viruses and bacteria floating in the external space may be higher inside the air purifier as it results in the collection of viruses and bacteria.

These attached viruses and bacteria are alive (active) as they are. Coronavirus has been reported to maintain infectious activity for 1 to 14 days, depending on conditions. Some bacteria live longer, and some fungal spores live for more than a few months.

The filter of the air purification device captures not only fine particles but also dust in the air, so if it is used for a certain period of time, it will become clogged with accumulated dust and the air flow will be insufficient, so maintenance work such as replacement work. Is required. In addition, when other electrical parts or the like break down and are repaired, the inside of the housing is opened for repair. When the filter is removed, fine particles with viruses and bacteria may be scattered from the surface. In addition, even when the cover of the housing is opened for repairing parts, there is a high possibility that particles containing viruses and bacteria attached to the inner wall will fly out. When replacing these filters or repairing parts, the risk of workers being infected by particles resuspending in the air can be quite high.

An object of the present invention is to provide an air purification device capable of preventing a risk of secondary infection by a virus or a bacterium captured inside.

The features of the present invention are a housing through which air flows, a fungus / virus collection filter provided in the housing for collecting bacteria or a virus, and a fungus or virus provided in the housing. It has a bacterium / virus inactivating gas generating part that generates gas for inactivating the bacterium, and the bacterium / virus inactivating gas generating part is the bacterium / virus inactivating gas generating part and the bacterium / virus catching part. It is in an air purification device that operates with the inside of the housing closed, including a collecting filter.

Preferably, the fungus / virus collection filter is a ULPA, HEPA or quasi-HEPA filter specified in JIS Z 8122. Further, preferably, the Bacterial / Virus Inactive Gas Generating Unit generates at least one selected from ozone gas, chlorine oxide, hydrogen peroxide, hypochlorous acid, ethylene oxide, and formaldehyde.

Since these gases are often harmful to the human body, during sterilization work, the air purifier is stopped to blow air, and the air outlet is closed to seal the inside to generate sterilizing gas. It is preferable to sterilize. The generation of gas may be stopped when the internal gas concentration reaches the concentration required for sterilization. Also, after sterilization, when using it as a normal air purification device, open the air outlet and operate the fan.
The residual gas inside may be removed by a treatment filter located on the outlet side of the air purification device. However, if it is diluted with a large indoor volume and the concentration below the allowable concentration is secured, the treatment filter may not be used.

According to the present invention, it is possible to provide an air purification device capable of preventing the risk of secondary infection due to a virus or bacterium captured inside.

It is a perspective view which shows the appearance of the air purification apparatus which concerns on 1st Embodiment of this invention. It is a perspective view which shows the state which the lid is opened in the air purification apparatus which concerns on 1st Embodiment of this invention. It is a perspective view which shows the internal part of the air purification apparatus which concerns on 1st Embodiment of this invention. FIG. 4 (a) is an exploded perspective view showing an entrance portion used in the first embodiment of the present invention, and FIG. 4 (b) shows an entrance side opening / closing member of the entrance portion in the first embodiment of the present invention. It is a perspective view which shows the closed state. It is a perspective view which shows the periphery of the outlet side opening / closing member used in 1st Embodiment of this invention. It is a perspective view which shows the drive mechanism which drives the opening / closing member used in the 2nd Embodiment of this invention. It is a block diagram which shows the control apparatus used in the 2nd Embodiment of this invention. It is a timing chart which shows the control operation in 2nd Embodiment of this invention.

An embodiment of the present invention will be described with reference to the drawings.

1 to 3 show an air purifier 10 according to a first embodiment of the present invention. The air purification device 10 has, for example, a vertically long rectangular parallelepiped housing 12. An operation panel 14 is provided on the front surface of the housing 12. Various switches such as a drive switch for driving the air purification device 10 and a fumigation switch for setting the fumigation mode described later are arranged on the operation panel 14, and various operations for operating the air purification device 10 are arranged. I do.

Further, the housing 12 is provided with an inlet portion 16 on the upper surface of the housing 12, and an outlet portion 18 is provided on the lower surface of the housing 12. A large number of inlet side holes 20 are formed in the inlet portion 16. As shown by the arrow A, air enters the housing 12 through the inlet side hole 20 of the inlet portion 16, and as shown by the arrow B, air is discharged from the outlet portion 18.

The air purifying device 10 is installed in a medical field, for example, and when the patient's examination is completed, the virus or bacteria adheres not only to the inside of the air purifying device 10 but also to the outer wall of the housing 12 of the air purifying device 10 that collects air. there is a possibility. Normally, it is sterilized by wiping it with alcohol or the like, but in order to ensure safety, it is desirable that the outer wall of the air purifier 10 is made of a sterilizing material.
For example, the following can be used as a sterilizing material for the outer wall of the housing 10.
(1) A paint or a photocatalyst film containing a photocatalyst on the surface.
The photocatalyst works with indoor light and light from windows to sterilize. Light here is an electromagnetic wave including ultraviolet rays, visible light, and infrared rays.
(2) Those containing metallic copper or silver on the surface.

Further, a lid 22 is provided on the side surface of the housing 12. The lid 22 is attached to the housing 12 so as to be removable by, for example, a screw. When the lid 22 is removed, as shown in FIG. 2, the opening 24 is opened, and internal members such as the light irradiation device 36 and the fungus / virus collection filter 40 housed in the housing 12 are maintained. It is possible to work when it is replaced at times or when electrical parts etc. break down. Further, a power cord 26 and a plug 28 for supplying electric power are connected to the housing 12. Further, for example, four casters 30 are provided on the lower surface of the housing 12 to assist the movement of the air purifying device 10.

As shown in FIG. 3, in the housing 12, in order from the top, a pre-filter 32, a photocatalyst filter 34, a light irradiation device 36, a fungus / virus inert gas generating unit 38, a fungus / virus collection filter 40, A fan 42, a sterilizing gas treatment filter 44, and a post filter 46 are arranged.

The pre-filter 32 is a coarse filter in which large debris and dust are captured.

The photocatalyst filter 34 is a filter coated with titanium oxide, tungsten oxide, or the like as a photocatalyst. A photocatalyst strongly exhibits a catalytic function with ultraviolet rays having a short wavelength, but it is known that a photocatalyst also exhibits a catalytic function with visible light by supporting a metal atom or the like.

In this embodiment, the light irradiation device 36 uses ultraviolet rays having a strong effect and is composed of a plurality of ultraviolet lamps. The photocatalyst of the photocatalyst filter 34 is generated on the surface by the ultraviolet rays generated from the ultraviolet lamps. Most of the adsorbed organic substances can be decomposed by the active oxygen species.
In addition to the ultraviolet lamp, an ultraviolet LED may be used to generate ultraviolet rays. When visible light is used, a visible light lamp or LED may be used.

The photocatalytic filter 34 has a role of adsorbing relatively large saliva particles containing a large amount of bacteria and viruses among the suspended particles and adsorbing and decomposing malodorous gas and organic solvent gas. In addition, malodors caused by emissions and chemicals, and organic solvent gases such as formaldehyde are common in the medical field, and photocatalysts are also effective against this. By capturing large saliva particles containing viruses and bacteria here, it is possible to reduce the burden on the next-stage bacteria / virus collection filter 38 and extend the maintenance cycle. In addition, bacteria and viruses that are protected by saliva and are difficult to respond to the activation gas described later can also be decomposed and sterilized.

The Bacterial / Virus Inert Gas Generating Unit 38 is composed of, for example, an ozone generator. There are several types of ozone gas generators, but two examples are given below.
(1) Ozone generator using electric discharge Usually, it is commercially available as an ozonizer. It is a device that produces ozone from oxygen in the air as a raw material by discharging at high voltage. The amount of ozone generated can be controlled by voltage, current, and time.
(2) Ultraviolet ozone tube An ultraviolet lamp with an ultraviolet wavelength of 200 nm or less can generate ozone using oxygen in the air as a raw material, and is commonly called an ozone tube. It is commercially available.
Although the inactivating gas has been described with ozone in the first embodiment, an inactivating gas such as chlorine oxide, hydrogen peroxide, hypochlorous acid, ethylene oxide, and formaldehyde may be used.

As the fungus / virus collection filter 40, for example, a HEPA filter defined by JIS Z 8122 is used. In this fungus / virus collection filter 40, among the floating fine particles, particles having a small diameter often pass through the photocatalyst filter 34, but these fine particles are captured by the fungus / virus collection filter 38. .. The HEPA filter guarantees the ability to capture 99.97% of 0.3um particles, and can guarantee a capture rate of 95% or more, which is safe for infection protection specified by the medical mask N95.

The purified air that has passed through the HEPA filter is blown out to the outside through the sterilizing gas treatment filter 44 and the post filter 46. The air that blows out is safe and contains almost no viruses or bacteria.

As the HEPA filter, it is preferable to use a paper-like filter obtained by entwining a fibrous material. It is more preferable to use a fluororesin, for example, polytetrafluoroethylene (PTFE) as the material of the fiber. Chemical fibers such as nylon and vinyl, glass fibers, etc. are oxidized and deteriorated by ozone. Fluororesin has the characteristics that it is not easily deteriorated by ozone, and that it has water repellency and does not allow viruses, bacteria, and fungi to grow. Further, if it is a fluororesin, it is possible to manufacture a fiber having a small diameter and having a small pressure loss.

In the first embodiment, a HEPA filter was used as the fungus / virus collection filter 40, but in order to achieve a virus or bacterium capture rate of 95% or more required for infection control, JIS is also used. Either ULPA or quasi-HEPA specified in Z 8122 may be used. ULPA is defined as a single-pass capture rate of 0.15um particles of 99.9995% or higher, HEPA is defined as a single-pass capture rate of 0.3um particles of 99.97% or higher, and quasi-HEPA is defined as a single-pass capture rate of 0.3um particles of 95. It is specified as% or more. If the collection efficiency may be moderate depending on the type of virus or bacterium to be targeted, a medium-performance filter defined as a medium particle collection efficiency may be used for particles of 5 um or less.

In this first embodiment, a photocatalyst is used in combination with the HEPA filter, and the effects of the combined use are as follows.

If viruses or bacteria floating in the air are contained in the fine particles and are captured by the filter as a brim or runny nose-protected mass, the following adverse effects may occur.

The brim and other lumps are large, and the HEPA filter is quickly clogged.
Protected by a brim and runny nose, ozone gas does not come into contact with viruses and bacteria, resulting in insufficient bactericidal effect. As a countermeasure, a photocatalyst filter 34 and a light irradiation device 36 for exciting the photocatalyst are arranged in front of the HEPA filter. The photocatalyst can be excited by light to generate active species and decompose organic substances adhering to the surface. Large particles wrapped in a brim or runny nose have a large inertial force, so that most of them collide with the surface of the photocatalyst filter 34 and are captured. Bacteria and viruses, including brim and runny nose, are decomposed on the surface of the photocatalyst, so sterilization is completed at the same time. Therefore, by letting the photocatalytic filter 34 handle the large particles, the burden on the HEPA filter can be reduced, the replacement time can be extended, and the sterilization of viruses and bacteria protected by the brim and runny nose can be ensured. As mentioned above, another merit of the photocatalyst is the effect of decomposing odorous gas, and it is possible to take measures against odors in hospital rooms and nursing rooms, and measures against sick houses such as formaldehyde and organic solvents at the same time.

The light irradiation device 36 can replace one of the ultraviolet lamps shown in this example by using an ozone lamp having a short wavelength and generating ozone. The wavelength of this ozone tube also has a bactericidal effect, and also has an effect of sterilizing bacteria and viruses captured on the surface of the HEPA filter.

In this first embodiment, the fan 42 is arranged on the downstream side (lower side) of the fungus / virus collection filter 40. The fan 42 is for sucking air into the inside of the housing 12 and blowing out the air.

As shown in FIG. 4A, the above-mentioned entrance portion 16 is provided with an entrance side opening / closing member 48. In the entrance side opening / closing member 48, for example, two elongated holes 50, 50 are formed in parallel near the left and right ends of the entrance side opening / closing member 48. Insertion screws 52, 52 fixed to the inlet portion 16 are inserted into the long holes 50, 50, and the insertion screws 52, 52 are loosened, and the long holes 50, 50 are formed along the insertion screws 52, 52. By moving, the entrance side opening / closing member 48 slides to the entrance portion 16.

The above-mentioned entrance side hole 20 is composed of a housing side hole 20a formed on the housing 12 side and an opening / closing member side hole 20b formed in the entrance side opening / closing member 48. As shown in FIG. 1, when the housing side hole 20a and the opening / closing member side hole 20b are in the same position, the inlet side hole 20 is opened to allow ventilation, and as shown in FIG. 4 (b). When the inlet side opening / closing member 48 is moved in the C direction to a position where they do not match, the inlet side hole 20 is closed and ventilation is prohibited. The white part in FIG. 4B shows an open state, and the black part shows a closed state.

Further, as shown in FIG. 5, an outlet side opening / closing member 54 is provided on the downstream side (lower side) of the above-mentioned fungus / virus collection filter 40 on the upstream side (upper side) of the fan 42. The outlet-side opening / closing member 54 is slidably arranged on a fixing plate 56 provided in the housing 12. A handle 58 is provided on one end side of the outlet side opening / closing member 54 so that the outlet side opening / closing member 54 can be manually moved. An outlet side hole 60 is formed in the outlet side opening / closing member 54 and the fixed plate 56, and the outlet side hole 60 is opened / closed by sliding the outlet side opening / closing member 54 in the same manner as the above-mentioned inlet side hole 20. It has become. The outlet side opening / closing member 54 has a guide portion, and packing is attached around the outlet side hole 60 so that gas does not leak.

Next, the operation of the air purification device 10 according to the first embodiment will be described.
First, the operation of purifying air by the air purifying device 10 in the normal mode will be described. In the normal mode, the inlet side hole 20 and the outlet side hole 60 are open, and the operation panel 14 is driven. When the switch is pressed, the light irradiation device 36 is activated, and then the fan 42 starts to rotate.

When the fan 42 starts rotating, as shown in FIG. 1, air enters the housing 12 through the inlet side hole 20, and first, the pre-filter 32 captures large dust and dirt contained in the air. Next, the photocatalytic filter 34 adsorbs relatively large saliva particles containing a large amount of bacteria and viruses among the suspended particles in the air, and also adsorbs and decomposes malodorous gas and organic solvent gas.

Next, the fungus / virus collection filter 40 captures small-diameter particles that have passed through the photocatalyst filter 34.

Further, it passes through the sterilizing gas treatment filter 44 and the post filter 46, and safe air containing almost no virus or bacteria is ejected from the outlet portion 18 to the outside.

Next, a mode for inactivating viruses and bacteria adhering to the inner wall of the fungus / virus collection filter 40 and the housing 12 (hereinafter referred to as fumigation mode) will be described. In the captured state, the virus and bacteria in the room are concentrated inside the air purification device 10 and the concentration is high. For maintenance, open the lid 22 and replace the bacteria / virus collection filter 40. Then, there is a high risk of secondary infection due to viruses and bacteria flying away. Therefore, it is necessary to inactivate viruses and bacteria attached to the HEPA filter and the inner wall.

While the air purification device 10 is operating in the normal mode, it only captures floating viruses and bacteria inside, and does not perform inactivation treatment. This is because the gas used for the inactivating treatment is harmful to the human body at a concentration that can be inactivated.

If the air purifier 10 is used in the daytime and not at night, the fumigation mode is performed according to the following procedure after the air purifier 10 is stopped.

First, as shown in FIG. 4B, the inlet side opening / closing member 48 is slid to close the inlet side hole 20. Similarly, the outlet side opening / closing member 54 is slid to close the outlet side hole 60. The outlet side hole 60 may be closed by the outlet portion 18 of the housing 12, but the downstream side of the fungus / virus collection filter 40 and the upstream side of the fan 42 are optimal. This is because the virus and the virus are not stopped by the fungus / virus collection filter 40 and do not reach the fan 42. Further, the wiring of the fan 42 is easily deteriorated by ozone gas or the like, and it is better not to expose the fan 42 to ozone gas or the like.

When both the inlet side hole 20 and the outlet side hole 60 are closed and the inside is sealed, the fumigation switch is pressed. When the fumigation switch is pressed, the Bacterial / Virus Inactive Gas Generating Unit 38 is turned on. Bacterial / virus Inert gas is generated. The gas concentration may be controlled by a timer from the internal volume of the device and the generation time to control the on / off time, or a gas concentration sensor may be installed inside to turn off the generation when the specified concentration is reached. ..

When the Bacterial / Virus Inactive Gas is ozone, it is desirable to determine the internal concentration in the range of 0.5 to 10 ppm. This is because it is known that the inactivating effect of a virus or a bacterium by gas is a function of concentration × time. Further, in deteriorating the internal device and the housing 12, and in treating the gas inside after the fumigation treatment, it is too difficult to use the inactivating gas treatment filter 44 or to dilute it to an allowable concentration due to the size of the room. This is because it is easier to do without increasing the concentration.

When the inactivating gas treatment filter 44 is used, when the inactivating gas is ozone, the gas is treated by decomposition by manganese dioxide or adsorption by activated carbon to reduce the concentration of the gas that goes out. The location of the gas treatment filter may be on the downstream side of the portion sealed in the fumigation mode. Furthermore, it is still effective if it is on the upstream side of the fan. This is because the fan wiring can be prevented from deteriorating by treating the inactivating gas.

After sterilizing the inside of the housing 12 or inactivating the virus in the smoking mode as described above, the lid 22 is removed, and the internal members such as the light irradiation device 36 and the fungus / virus collection filter 40 are maintained at the time of maintenance. The work can be performed safely in the event of replacement or failure of electrical parts or the like.

Next, a second embodiment according to the present invention will be described. In the first embodiment described above, the fumigation mode is manually performed, but in the second embodiment, the fumigation mode is automatically performed. By performing it manually as in the first embodiment, it is effective for raising awareness (managing by oneself) that it is a sterilization work, unlike normal operation. There is also the merit that the structure and electric circuit can be simplified. On the other hand, in the second embodiment, the fumigation mode can be easily performed.

In this second embodiment, as shown in FIG. 6, a drive unit 62 is provided on at least one of the inlet side opening / closing member 48 and the outlet side opening / closing member 54. The drive unit 62 rotates a rack 64 attached to the side surface of the inlet side opening / closing member 48 and the exit side opening / closing member 54, a gear 66 that meshes with the rack 64, a worm 68 that meshes with the gear 66, and the worm 68. It is composed of a motor 70 for making the motor 70. By rotating the motor 70 in the forward and reverse directions, the inlet side opening / closing member 48 and the outlet side opening / closing member 54 can be slid. Further, the slide positions of the inlet side opening / closing member 48 and the exit side opening / closing member 54 can be detected by the position sensor 72 to control the stop position of the slide operation.

Further, the air purifier 10 has a control unit 74 as shown in FIG. The control unit 74 is composed of, for example, a computer and operates according to a program. Signals from the concentration sensor 76, the timer 78, and the drive switch 80 are input to the control unit 74. Further, the control unit 74 outputs a control signal to the light irradiation device 36, the fungus / virus inert gas generation unit 38, the fan 42, and the drive unit 62.

FIG. 7 shows a timing chart of control by the control unit 74.
First, when the drive switch 80 is turned on, the inlet side opening / closing member 48 and the outlet side opening / closing member 54 are first opened via the drive unit 62, and then the light irradiation device 36 and the fan 42 are operated.

For example, when the work of one day is completed, the drive switch 80 is turned off, the light irradiation device 36 and the fan 42 are stopped, and then the inlet side opening / closing member 48 and the outlet side opening / closing member 54 are closed via the drive unit 62. Enter fumigation mode.

When the fumigation mode is entered, the timer 78 starts the coefficient and activates the Bacterial / Virus Inactive Gas Generating Unit 38 to generate gas. While this gas is generated, the concentration in the housing 12 may be kept constant based on the concentration information acquired from the concentration sensor 76.

After that, when the timer 78 is turned off, the operation of the Bacterial / Virus Inactive Gas Generating Unit 38 is stopped, and the fumigation mode is terminated.

In the above embodiment, it has been described as an independent air purification device, but it may be installed as a unit in a ventilation facility installed in a building or the like. In this case, the housing 12 corresponds to the duct of the ventilation equipment. Further, in this case, the moving caster 30 is unnecessary, and the operation panel 14 is installed at a distant place, but the operation and function of the apparatus described in the above embodiment are the same.

10 Air purification device 12 Housing 14 Operation panel 16 Inlet 18 Exit 20 Inlet side hole 22 Lid 24 Opening 26 Power cord 28 Plug 30 Caster 32 Pre-filter 34 Photocatalytic filter 36 Light irradiation device 38 Bacterial / virus inert gas Generating part 40 Bacteria / virus collection filter 42 Fan 44 Inert gas treatment filter 46 Post filter 46
48 Inlet side opening / closing member 50 Long hole 52 Insert screw 54 Exit side opening / closing member 56 Fixing plate 58 Handle part 60 Exit side hole 62 Drive part 64 Rack 66 Gear 68 Warm 70 Motor 72 Position sensor 74 Control part 76 Concentration sensor 78 Timer 80 Drive switch

Claims (18)

A housing that allows air to flow inside,
A fungus / virus collection filter provided in the housing to collect bacteria or viruses,
It is provided in the housing and has a fungus / virus inactivating gas generating portion that generates gas for inactivating the fungus or virus.
The Bacterial / Virus Inactive Gas Generating Unit is an air purification device that operates with the inside of the housing closed including the Bacterial / Virus Inactivating Gas Generating Unit and the Bacterial / Virus Collecting Filter. The air purification device according to claim 1, wherein the housing is provided with a fan that forms the air flow. The air purification device according to claim 2, wherein the fan is provided on the downstream side of the fungus / virus inert gas generating portion, and the upstream side of the fan is closed. The air purification device according to any one of claims 1 to 3, wherein the fungus / virus collection filter is a ULPA, HEPA, quasi-HEPA filter or a medium-performance filter specified in JIS Z 8122. The air purification device according to any one of claims 1 to 4, wherein the fungus / virus collection filter is detachably attached to the housing. The air purification according to any one of claims 1 to 5, wherein the Bacterial / Virus Inactive Gas Generating Unit generates at least one selected from ozone gas, chlorine oxide, hydrogen peroxide, hypochlorous acid, ethylene oxide, and formaldehyde. Device. 4. Air purification device. The air purification device according to any one of claims 1 to 7, wherein the inert gas treatment filter for treating the Bacterial / Virus Inactive Gas before it goes out is installed on the downstream side of the closed portion in the housing. 6. Air purifier. The air purifying device according to claim 9, wherein the light irradiation device has an ozone lamp that generates ozone. The air purifier according to any one of claims 1 to 10, wherein the fungus / virus collection filter is made of polytetrafluoroethylene fiber. The air purifying device according to any one of claims 1 to 11, further comprising a concentration sensor for detecting the gas concentration in the housing, a control unit for controlling the Bacterial / Virus Inert Gas Generation Unit according to the output of the concentration sensor, and a control unit having the control unit. .. The air purifying device according to any one of claims 1 to 12, further comprising a control unit having a timer and controlling the Bacterial / Virus Inert Gas Generating Unit according to the setting of the timer. The air purifying device according to any one of claims 1 to 13, further comprising an opening / closing member for opening / closing the housing, a driving unit for driving the opening / closing member, and a control unit for controlling the driving unit. The air purifying device according to claim 14, wherein the control unit controls to operate the Bacterial / Virus Inactive Gas Generating Unit after closing with the opening / closing member. The air purifying device according to claim 2, further comprising an opening / closing member for opening / closing the housing and a driving unit for driving the opening / closing member, and controlling the opening / closing member to be closed after the fan is stopped. The air purifying device according to claim 2 or 16, further comprising an opening / closing member for opening / closing the housing and a driving unit for driving the opening / closing member, and controlling the fan to be driven after the opening / closing member is opened. The air purifying device according to claim 2, 16 or 17, wherein the fan is stopped and then the fungus / virus inert gas generating unit is controlled to operate.

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