KR102573699B1 - air transmission blocking device for infectious diseases - Google Patents

Abstract

The present invention relates to a device for blocking airborne transmission of infectious diseases, comprising: an intake unit for suctioning droplets and aerosol discharged from the respiratory system of a user along with ambient air through a plurality of inlets formed through at least one surface of a box-shaped case; a purification unit installed to be connected to the intake unit to filter and sterilize the air containing the droplets and aerosol introduced into the box-shaped case through a first connection pipe connected to the intake unit; and an exhaust unit installed to be connected to the purification unit to discharge the filtered and sterilized air containing the droplets and aerosol introduced through a second connection pipe connected to the purification unit, to the outside through a plurality of outlets formed through at least one surface of the box-shaped case, wherein the exhaust unit is arranged above the intake unit and discharges the filtered and sterilized air containing the droplets and aerosol through the outlets while forming a vertical laminar flow in the direction of gravity. Therefore, provided is a device for blocking airborne transmission of infectious diseases, wherein the blocking of airborne transmission of viruses indoors can be facilitated.

Description

Air transmission blocking device for infectious diseases}

The present invention relates to a device for blocking air propagation of infectious diseases, and more particularly, inhalation of viruses discharged from a user's respiratory tract is performed, and after inhalation, filtered and sterilized air forms a vertical laminar flow in the direction of gravity and flows indoors. The present invention relates to an air propagation blocking device for infectious diseases that can smoothly block air propagation of viruses indoors as the probability of inhaling viruses indoors decreases by being supplied.

BACKGROUND OF THE INVENTION [0002] Recently, the occurrence of diseases caused by microorganisms, which are pathogens, proliferating in living organisms, such as corona, is greatly increasing.

At this time, one of the infection routes of infectious agents such as viruses or bacteria may be airborne transmission.

Airborne transmission is the transmission of droplets and aerosols discharged from the nose and mouth of an individual as a medium of infection to the respiratory tract of others through the air. Filtering and disinfection of droplets and aerosols expelled from the respiratory tract are required.

Accordingly, as recently disclosed in Korean Patent Publication No. 10-2021-0102033, etc., the use of 'air conditioning devices' or 'air conditioning systems' for filtering and sterilizing indoor air or forcing ventilation is increasing.

However, since general air conditioning devices or air conditioning systems are placed at a considerable distance from the user's breathing zoon, it takes a considerable amount of time to filter and sterilize by inhaling droplets and aerosols after discharging them from the personal respiratory system, so it takes a certain amount of time indoors. Since convection is bound to occur, there is a risk of inhaling droplets and aerosols containing infectious agents by people indoors during the time convection occurs.

For the above reasons, an attempt has been made to develop a device capable of inhaling air near the respiratory tract of a person and supplying filtered and sterilized air near the respiratory tract of a person, but satisfactory results have not been obtained so far.

Republic of Korea Patent Publication No. 10-2021-0102033

The present invention has been proposed to solve the problems of the prior art as described above, and inhalation of the virus discharged from the user's respiratory tract is performed close to the user's respiratory tract, and the filtered and sterilized air is gravitational force near the user's respiratory tract. Provides an air propagation blocking device for infectious diseases that allows the air propagation of viruses to be blocked indoors smoothly as the probability of inhalation of the virus by the user and others other than the user indoors is lowered by forming a vertical laminar flow in the direction of action and being supplied indoors But it has a purpose.

In order to achieve the above object, the present invention,

an intake unit for inhaling droplets and aerosol discharged from a user's respiratory system along with ambient air through a plurality of inlets formed on at least one surface of the box-shaped case; a purification unit installed connected to the intake unit to filter and sterilize the air containing the droplets and aerosols flowing into the box-shaped case through a first connection pipe connected to the intake unit; And a plurality of air containing the filtered and sterilized droplets and aerosols introduced through a second connection pipe connected to the purification unit and connected to the purification unit, formed on at least one surface of the case in the form of a container. An exhaust unit discharging the air to the outside through an outlet, wherein the exhaust unit discharges the filtered and sterilized air containing the droplets and aerosol in a vertical laminar flow in a direction of gravity through the outlet. We propose an air propagation blocking device for infectious diseases.

At least one of the intake unit, purification unit, and exhaust unit may be embedded in, attached to, or separated from at least one of a ceiling, a wall surface, and a floor inside a building.

Each of the intake unit, purification unit, and exhaust unit may be disposed on a movable body that moves inside a building by rotation of a wheel.

The intake unit and the exhaust unit may be disposed on the movable body and spaced apart from the surface of the movable body on the top or side.

The inlet of the intake unit is formed to have a diameter gradually smaller or fewer in number as the distance to the first connection pipe decreases, and may be formed intensively at a point where a relatively large number of people are located. .

The inlet of the intake unit may be formed with a downward slope from the front end to the end.

The purification unit may include a fan rotating in one direction by a motor drive; and a filtering member filtering the droplet and aerosol from the air sucked in by the suction force generated by the rotation of the fan. and a sterilization module for sterilizing the droplet and aerosol sucked by the suction force generated by the rotation of the fan.

The air flowing by the rotation of the fan may flow at a speed of 1-1.5 m/s in summer and 0.20-0.25 m/s in winter.

The purification unit may further include a sensor for detecting at least one of the droplets and aerosols, infectious substances, fine dust, substances harmful to the human body, odor particles, and carbon dioxide contained in the air.

The purification unit may further include an input module for injecting additives into the air.

The input module may input the additives, and at least one of oxygen, perfume, phytoncide, and fragrance.

The sterilization module may include an ultraviolet lamp and a plasma generator.

The case of the purification unit may include a soundproofing pad disposed along an inner surface.

The purification unit determines the amount of air inflow into the case from the outdoor space, the amount of air discharged from the inside of the case into the outdoor space, the air inflow period, the air discharge period, the air inflow time, the air discharge time, the air inflow rate, and the air discharge rate. It may further include an air inlet and outlet module to control.

The air inlet and outlet module may include an air inlet pipe leading from an outdoor space to the case; An air discharge pipe leading from the case to an outdoor space; and a rotating fan disposed in each of the air inlet pipe and the air discharge pipe.

The purification unit may further include a temperature and humidity control module for adjusting the temperature and humidity of air inside the case.

As the distance to the second connection pipe decreases, the outlet of the exhaust unit is formed to have a gradually smaller diameter or fewer in number, and may be formed intensively at a point where a relatively large number of people are located. .

The outlet of the exhaust unit may be formed in a pipe shape.

The exhaust unit may include a lamp that is turned on when power is applied.

The exhaust unit may include a sensor for detecting the presence of users and the number of users.

The first connection pipe and the second connection pipe may be formed in the form of a pipe having a constant cross-section or a form of a corrugated pipe having a variable length and a change in direction.

The movable body includes at least one through hole communicating with the inlet of the intake unit on at least one surface.

The through hole of the movable body may be formed with a downward slope from the front end to the end.

In the device for blocking air propagation of infectious diseases according to the present invention, an intake unit, a purification unit, and an exhaust unit are disposed adjacent to the user's breathing area indoors, and the ambient air in the room sucked in by the intake unit and the droplets discharged from the user's respiratory tract And as the aerosol passes through the purification unit, filtering and sterilization of droplets and aerosols contained in the air is performed, and the air filtered and sterilized in the purification unit passes through the exhaust unit in the direction of gravity near the user's breathing area. Since it can be discharged while forming a laminar flow, it is possible to lower the probability of inhalation of the virus by the user and others other than the user indoors, so that the air propagation of the virus in the room can be smoothly blocked.

In the device for blocking air propagation of infectious diseases according to the present invention, the intake unit, the purification unit, and the exhaust unit are disposed adjacent to the user's breathing area indoors, but in particular, can be arranged on a mobile body moving indoors, which is more closely related to the user's breathing area. Air intake is made at various points in the room adjacent to the user's breathing area, and filtered and sterilized air is supplied to various points in the room that are closer to the user's breathing area, forming a vertical laminar flow in the direction of gravity. could be smoother.

1 is an exemplary view showing a form in which a device for blocking air propagation of an infectious disease according to the present invention is fixedly installed inside a building.
2 is an exemplary view showing another form in which an air propagation blocking device for infectious diseases according to the present invention is fixedly installed indoors of a building.
3 is an exemplary view showing another form in which the air propagation blocking device for infectious diseases according to the present invention is fixedly installed inside a building.
4 is a perspective view showing an external appearance of an intake unit in an apparatus for blocking air propagation of infectious diseases according to the present invention.
5 is an exemplary view showing the arrangement of the purification unit in the air propagation blocking device for infectious diseases according to the present invention.
6 is an exemplary diagram showing a form in which an air propagation blocking device for infectious diseases according to the present invention is applied to a mobile body.
7 is a cross-sectional view showing the internal structure of the device for blocking air propagation of infectious diseases according to the present invention shown in FIG. 6 .
8 is an exemplary view showing another form in which the air propagation blocking device for infectious diseases according to the present invention is applied to a mobile body.
FIG. 9 is an exemplary view showing another form of a first connection pipe and a second connection pipe in the device for blocking air propagation of infectious diseases according to the present invention shown in FIG. 8 .
FIG. 10 is an exemplary diagram showing a form in which an exhaust unit in the form of a parasol is applied to a mobile body in the apparatus for blocking air propagation of infectious diseases according to the present invention shown in FIG. 8 .
FIG. 11 is an exemplary view showing the bottom of a parasol-shaped exhaust unit in the device for blocking air propagation of infectious diseases according to the present invention shown in FIG. 10 .

Hereinafter, the present invention will be described in detail based on the accompanying drawings.

As shown in FIGS. 1 to 3, the device (A) for blocking air propagation of infectious diseases according to the present invention includes an intake unit (100); purification unit 200; and an exhaust unit 300.

The intake unit 100 of the present invention inhales droplets and aerosols discharged from a user's respiratory system along with ambient air through a plurality of inlets 111 formed on at least one side of a box-shaped case 110.

At this time, in the intake unit 100, as the fan 230 of the purification unit 200 described below rotates and a suction force acts on the inside of the case 110, the intake unit 100 sucks droplets and aerosols discharged from the user's respiratory system together with the surrounding air. this can be done

In addition, the inlet 111 of the intake unit 100 is formed so that its diameter gradually decreases or the number of inlets decreases as the distance to the first connection pipe 220 described below decreases, so that the first connection pipe 220 ), the air intake rate and flow rate through each inlet 111 can be relatively uniform, regardless of the distance to reach ), and the air intake rate and flow rate can be concentrated at the point where there are relatively many people, so that the air at the point where there are relatively many people of inhalation can be concentrated.

Here, since the inlet 111 of the intake unit 100 is inclined downward from the front end to the end, the inflow of air can be smoothed and the inflow of foreign substances can be suppressed.

Meanwhile, the intake unit 100 may be embedded in, attached to, or separated from, any one of the ceiling 1, the wall surface 2, and the floor 3 inside the building.

Therefore, droplets and aerosol discharged from the user's respiratory system located inside the building can be inhaled by the intake unit 100 .

At this time, the air intake unit 100 spaced apart from one of the ceiling 1, the wall surface 2, and the floor 3 inside the building is supported by the support member 4 so that the spaced state can be maintained.

In addition, since the shape of the intake unit 100 is not limited, it may be formed in various shapes as shown in FIG. 4 according to the conditions of the installation site.

In addition, the intake unit 100 may be disposed on the movable body 10 that moves inside the building by rotating the wheels 11 .

Therefore, the intake unit 100 can inhale droplets and aeroline discharged from the user's respirator together with ambient air at various points inside the building.

At this time, the movable body 10 includes at least one through hole 12 communicating with the inlet 111 of the intake unit 100 on at least one surface, so that air including droplets and aerosol passes through the through hole 12 to the intake unit. It may flow into the inlet 111 of (100).

Here, the through hole 12 of the movable body 10 is directed from the front end to the end and is inclined downward, so that the inflow of air can be smoothly and the inflow of foreign substances can be suppressed.

In addition, the intake unit 100 disposed on the movable body 10 may be spaced apart from the top or side of the movable body 10 by the support of the first connection pipe 220 described below.

Therefore, since the intake unit 100 is located closer to the user's breathing area, inhalation of droplets and aerosol discharged from the user's respiratory system can be facilitated.

The purification unit 200 of the present invention is connected to the intake unit 100 and is connected to the intake unit 100 through a first connection pipe 220 that flows into the box-shaped case 210 and Filters and sterilizes air containing aerosols.

At this time, the purification unit 200 includes a fan 230 rotating in one direction by driving a motor (reference numerals not shown); a filtering member 240 for filtering droplets and aerosols from the air sucked in by the suction force generated by rotation of the fan 230; And a sterilization module 250 for sterilizing droplets and aerosols included in the air sucked by the suction force caused by the rotation of the fan 230; included in the air sucked into the case 210 by the rotation of the fan 230. The droplets and aerosols may be filtered and sterilized in the process of passing through the filtering member 240 and the sterilization module 250.

Here, the filtering member 240 of the purification unit 200 may be of any type as long as it can filter droplets and aerosols contained in the air, and thus a detailed description of the filtering member 240 will be omitted.

In addition, the sterilization module 250 of the purification unit 200 includes an ultraviolet lamp (not shown in the drawing) and a plasma generator (not shown in the drawing), so that the air is irradiated with ultraviolet rays from the ultraviolet lamp and plasma is generated from the plasma generator. Sterilization of contained droplets and aerosols can be achieved.

At this time, the ultraviolet lamp and the plasma generator may be installed regardless of the order.

In addition, the purification unit 200 further includes an input module 260 for injecting additives into the air, so that the exhaust unit ( 300), more pleasant air can be discharged.

In addition, the purification unit 200 further includes an air inlet and outlet module 280, so that the air inflow from the outdoor space to the inside of the case 210 by the air inlet and outlet module 280, the air inflow from the inside of the case 210 to the outside Air discharge into the space, air intake cycle, air discharge cycle, air introduction time, air discharge time, air introduction rate, and air discharge rate may be adjusted.

At this time, the air inlet and discharge module 280, the air inlet pipe 281 leading from the outdoor space to the case 210; An air discharge pipe 282 leading from the case 210 to the outdoor space: and a rotating fan 283 disposed on each of the air inlet pipe 281 and the air discharge pipe 282; As the rotation is performed, outdoor air may be introduced into the case 210 through the air inlet pipe 281 and air may be discharged from the inside of the case 210 to the outdoor space through the air discharge pipe 282. there is.

In addition, the purification unit 200 further includes a sensor 270 that detects at least one of droplets and aerosols, infectious substances, fine dust, harmful substances to the human body, odor particles, and carbon dioxide contained in the air, thereby responding to the signal of the sensor 270. As the fan 230, the sterilization module 250, and the air inflow and outflow module 280 operate, the degree of filtering and sterilization of the air passing through the purification unit 200, the inflow of external air and the outflow of internal air Since the degree can be adjusted, at least one of droplets and aerosols, infectious substances, fine dust, harmful substances to the human body, odor particles, and carbon dioxide can be smoothly removed.

For example, when a relatively large amount of at least one of droplets and aerosols, infectious substances, fine dust, harmful substances to the human body, odor particles, and carbon dioxide is detected by the sensor 270, the fan 230, the sterilization module 250, and air inlet and As the operation time and intensity of the discharge module 280 increase, at least one of droplets and aerosols in the air, infectious substances, fine dust, substances harmful to the human body, odor particles, and carbon dioxide may be smoothly removed.

Here, the wind speed of the fan 230 is adjusted so that the flow speed of air that closes on the human body can be maintained within a comfortable range for the human body (eg, 0.1-1.5 m/s).

In addition, since the case 210 of the purification unit 200 includes the soundproof pad 211 disposed along the inner surface, transmission of rotational noise of the fan 230 to the outside of the case 110 can be minimized.

In addition, since the purification unit 200 further includes a temperature and humidity control module 290, the temperature and humidity of the air inside the case 210 can be controlled by the temperature and humidity control module 290.

At this time, the temperature and humidity control module 290 may have any conventional structure and method as long as the temperature and humidity of the air inside the case 210 can be controlled, and thus a detailed description of the temperature and humidity control module 290 will be omitted.

Further, the case 210 of the purification unit 200 includes at least one opening (reference numeral not indicated), and the first connection pipe 220 and the second connection pipe 320 described below are connected by the opening. this can be done

In this case, a plurality of first connection pipes 220 of the purification unit 200 may be provided.

Therefore, as the air is introduced through each of the plurality of first connection pipes 220, the air can be smoothly introduced into the purification unit 200.

Also, the first connection pipe 220 of the purification unit 200 may be a pipe having a certain cross-sectional shape.

Here, a tube having a certain cross-sectional shape may include at least one joint part 221 as shown in FIG. 9 .

Therefore, bending of the first connection pipe 220 may be formed by the rotation of the joint part 221 .

Also, the first connection pipe 220 of the purification unit 200 may be a corrugated pipe.

Since the first connection pipe 220 of the purification unit 200 is a corrugated pipe, a variable length and a curved shape can be achieved.

On the other hand, the purification unit 200 may be embedded in, attached to, or separated from any one of the ceiling 1, the wall surface 2, and the floor 3 inside the building.

Therefore, the connection between the intake unit 100 and the purification unit 200 embedded in, attached to, or spaced apart from any one of the ceiling 1, the wall surface 2, and the floor 3 inside the building can be easily connected.

At this time, the purification unit 200 spaced apart from any one of the ceiling 1, the wall surface 2, and the floor 3 inside the building is supported by the support member 4 so that the spaced state can be maintained.

In addition, there is no limitation on the arrangement of the purification unit 200.

That is, the purification unit 200 may be disposed adjacent to the intake unit 100, disposed adjacent to the exhaust unit 300, or disposed between the intake unit 100 and the exhaust unit 300, as shown in FIG. .

In addition, the purifying unit 200 may be disposed on the movable body 10 that moves inside the building by rotating the wheels 11 .

Therefore, the air containing droplets and aerosols introduced from the intake unit 100 disposed in the movable body 10 can be quickly filtered and sterilized by the purification unit 200 .

The exhaust unit 300 of the present invention is connected to the purification unit 200 and is installed through a second connection pipe 320 connected to the purification unit 200 to filter and sterilize air containing droplets and aerosols. It is discharged to the outside through an outlet 311 formed of a plurality of pieces on at least one surface of the case 310 in the form of an addition.

At this time, the outlet 311 of the exhaust unit 300 is formed so that its diameter gradually decreases as the distance to the second connection pipe 320 decreases, or the number of outlets 311 reaches the second connection pipe 320. Regardless of the distance, not only can the air discharge speed and flow rate through each outlet 311 be relatively uniform, but also concentrated at a point where a relatively large number of people are located, so that air is discharged at a point where a relatively large number of people are located. can be done intensively.

Here, since the outlet 311 of the exhaust unit 300 is formed in a tubular shape, straightness can be imparted during air flow through the outlet 311 .

Also, the second connection pipe 320 of the exhaust unit 300 may be a pipe having a predetermined cross-sectional shape.

At this time, the tube having a certain cross-sectional shape may include at least one joint part 321 as shown in FIG. 9 .

Accordingly, the second connection pipe 320 may be bent by the rotation of the joint part 321 .

Also, the second connection pipe 320 of the exhaust unit 300 may be a corrugated pipe.

Since the second connection pipe 320 of the exhaust unit 300 is a corrugated pipe, a variable length and a curved shape can be achieved.

In addition, the exhaust unit 300 includes a lamp 330 that is turned on when power is applied, so that an operating state can be displayed by turning on the lamp 330 and visibility can be easily secured at night.

In addition, the exhaust unit 300 includes a sensor 340 for detecting the presence of a user and the number of users, so that the operation of the purification unit 200 can be performed only when a user exists according to the signal of the sensor 340. As the number of users increases, the strength and time of the fan 230, the sterilization module 250, and the air inlet and outlet module 280 of the purification unit 200 may be increased.

On the other hand, the exhaust unit 300 may be embedded in, attached to, or separated from any one of the ceiling 1, the wall surface 2, and the floor 3 inside the building.

Therefore, the connection between the purification unit 200 and the exhaust unit 300 embedded in, attached to, or spaced apart from any one of the ceiling 1, the wall 2, and the floor 3 inside the building can be easily connected.

At this time, the exhaust unit 300 spaced apart from one of the ceiling 1, the wall surface 2, and the floor 3 inside the building is supported by the support member 4 so that the spaced state can be maintained.

In addition, the exhaust unit 300 discharges air containing filtered and sterilized droplets and aerosols through the outlet 311 in a vertical laminar flow in the direction of gravity, thereby suppressing horizontal movement, convection, and vortex of indoor air. there is.

In addition, the exhaust unit 300 may be disposed on the movable body 10 that moves inside the building by rotating the wheels 11 .

Accordingly, the air containing the filtered and sterilized droplets and aerosol introduced from the purifying unit 200 disposed in the mobile body 10 may be discharged to the outside of the mobile body 10 by the exhaust unit 300 .

At this time, the exhaust unit 300 disposed on the movable body 10 may be spaced apart from the top or side of the movable body 10 by the support of the second connection pipe 320 .

Therefore, the formation height of vertical laminar flow, that is, the section of vertical laminar flow, can be maximized by the discharge of air in the direction of gravity through the outlet 311 of the exhaust unit 300, so that the horizontal movement of indoor air, convection and vortex flow are more can be suppressed.

In addition, the exhaust unit 300 disposed above the surface of the movable body 10 can be formed in various shapes, for example, in any one of a plate shape and a cylindrical shape, as well as in a parasol shape as shown in FIG. It can be.

Here, in the exhaust unit 300 formed in the form of a parasol, as shown in FIG. 11, the outlet 311 is formed at intervals over the entire bottom surface of the case 310, so air flows in the direction of gravity through the outlet 311. Formation of vertical laminar flow by discharge can be smooth.

On the other hand, since the intake unit 100 and the exhaust unit 300 are formed to be positionally adjustable so that they can be placed close to the user's breathing area, the risk of propagation of infectious agents can be further minimized.

The air propagation blocking of infectious diseases through the air propagation blocking device (A) according to the present invention will be described in detail as follows.

The intake unit 100 of the present invention may be embedded in, attached to, or separated from, any one of the ceiling 1, the wall 2, and the floor 3 inside the building.

At this time, since a plurality of inlets 111 are formed on at least one surface of the case 110 of the intake unit 100, the fan 230 of the purification unit 200 rotates and the suction force acts on the inside of the case 110. Accordingly, through the inlet 111, inhalation of droplets and aerosols discharged from the user's respiratory system along with ambient air can be performed.

Accordingly, the probability that droplets and aerosols discharged from the user are propagated to others located indoors may be reduced.

In the present invention, the purification unit 200 is buried, attached, or spaced apart from one of the ceiling 1, the wall 2, and the floor 3 inside the building, and is sucked in by the first connection pipe 220. Since it is connected to the unit 100, air including droplets and aerosol sucked by the intake unit 100 is introduced into the purification unit 200 through the first connection pipe 220.

At this time, the purification unit 200 includes a fan 230 rotating in one direction by a motor drive; a filtering member 240 for filtering droplets and aerosols from the air sucked in by the suction force generated by rotation of the fan 230; And a sterilization module 250 for sterilizing droplets and aerosols contained in the air sucked by the suction force generated by the rotation of the fan 230; In the process of passing through the filtering member 240 and the sterilization module 250, droplets and aerosols included in the air inhaled may be filtered and sterilized.

Here, the sterilization module 250 includes a UV lamp and a plasma generator, and sterilization of droplets and aerosols included in the air can be achieved by UV irradiation from the UV lamp and plasma generation from the plasma generator.

In addition, the purification unit 200 may further include an air inlet and outlet module 280, and the air inflow from the outdoor space into the case 210 by the air inlet and outlet module 280, the case 210 ) Air discharge from inside to outdoor space, air intake cycle, air discharge cycle, air intake time, air discharge time, air intake rate, and air discharge rate can be adjusted.

At this time, the air inlet and discharge module 280, the air inlet pipe 281 leading from the outdoor space to the case 210; An air discharge pipe 282 leading from the case 210 to the outdoor space: and a rotating fan 283 disposed at each of the air inlet pipe 281 and the air discharge pipe 282; As the rotation is rotated, outdoor air may be introduced into the case 210 through the air inlet pipe 281, and air may be discharged from the inside of the case 210 to the outdoor space through the air discharge pipe 282. It can be done.

However, when a relatively large amount of air, droplets and aerosols flow into the purification unit 200, filtering and sterilization may be insufficient.

However, in the present invention, the purification unit 200 includes a sensor 270 that detects at least one of droplets and aerosols, infectious substances, fine dust, harmful substances to the human body, odor particles, and carbon dioxide contained in the air. ) When at least one of droplets and aerosols, infectious substances, fine dust, harmful substances to the human body, odor particles, and carbon dioxide is detected in a relatively large amount, the fan 230, the sterilization module 250, and air are introduced according to the sensor 270 signal. and the discharge module 280 is operated, and the operating time of the fan 230, the sterilization module 250, and the air inlet and discharge module 280 increases, so that droplets and aerosols in the air, infectious substances, fine dust, At least one of substances harmful to the human body, odor particles, and carbon dioxide may be smoothly removed.

In addition, in the present invention, the purification unit 200 further includes an input module 260 for introducing additives into the air, and at least one of additives such as oxygen, perfume, phytoncide, and aromatic is injected by the input module 260. Accordingly, more pleasant air can be discharged through the exhaust unit 300 .

In addition, in the present invention, the purification unit 200 may further include a temperature and humidity control module 290. As the temperature and humidity of the air inside the case 210 is controlled by the temperature and humidity control module 290, the indoor air becomes more can be comfortable

In the present invention, the exhaust unit 300 is buried, attached, or spaced apart from one of the ceiling 1, the wall 2, and the floor 3 inside the building, and is purified by the second connection pipe 320. Connected to the unit 200, air containing droplets and aerosol filtered and sterilized by the purification unit 200 is introduced into the exhaust unit 300 through the second connection pipe 320.

At this time, the exhaust unit 300 has a plurality of outlets 311 formed on at least one surface of the case 310 in the form of a box, and air including filtered and sterilized droplets and aerosols is discharged to the outside through the outlets 311. , in other words, can be supplied to the room where the exhaust unit 300 is disposed.

Therefore, as the user inhales the air discharged from the exhaust unit 300, the probability of inhaling a virus indoors may be reduced.

Here, the exhaust unit 300 of the present invention, in particular, discharges air containing filtered and sterilized droplets and aerosols in the direction of gravity through the outlet 311, thereby forming a vertical laminar flow of indoor air. Since horizontal movement, convection, and vortex can be suppressed, the air propagation of infectious agents indoors can be minimized, which can further enhance the quarantine effect.

As described above, the device (A) for blocking air propagation of infectious diseases according to the present invention not only inhales the virus discharged from the user's respiratory tract near the user's respiratory tract, but also inhales the filtered and sterilized air near the user's respiratory tract in the direction of gravity action Since it forms a vertical laminar flow and supplies it indoors, the probability of inhaling the virus by the user and others other than the user indoors can be lowered, so the air propagation of the virus can be blocked indoors smoothly, which can enhance the quarantine effect.

Meanwhile, through the above description, the intake unit 100, the purification unit 200, and the exhaust unit 300 of the present invention are embedded in any one of the ceiling 1, the wall 2, and the floor 3 inside the building. , It may be seen as being attached or spaced apart, but this is just an example. The intake unit 100, the purification unit 200, and the exhaust unit 300 of the present invention are wheels 11 as shown in FIGS. 6 and 7 ) It can be placed on the mobile body 10 that moves inside the building by rotation.

Therefore, the intake unit 100 can suck droplets and aerosols discharged from the user's respiratory system at various points inside the building, including droplets and aerosols introduced from the intake unit 100 disposed on the moving body 10. The air to be filtered and sterilized can be quickly filtered and sterilized by the purifying unit 200, and the air containing the filtered and sterilized droplets and aerosols flowing from the purifying unit 200 disposed on the movable body 10 is filtered and sterilized by the exhaust unit 300. ), it is possible to form a vertical laminar flow in the direction of gravity near the user's breathing area and discharge it, so as to inhale and discharge air as close to the user's breathing area as possible, it is possible to reduce the probability of inhalation of the virus by others in the room. In addition, it is possible to lower the probability of inhaling the virus by the user himself, so that the transmission of the virus indoors can be more smoothly blocked.

At this time, the intake unit 100 and the exhaust unit 300 disposed on the movable body 10 may be spaced apart from the top or side of the surface of the movable body 10 as shown in FIG. 8, and the exhaust unit 300 When vertical laminar flow is formed by the discharge of air in the direction of gravity through the outlet 311 of the vertical laminar flow formation section can be relatively longer, so that the horizontal movement of indoor air, convection and vortex can be further suppressed indoors Airborne transmission of infectious agents can be minimized, which can further enhance the quarantine effect.

Here, the intake unit 100 and the exhaust unit 300 are formed to be positionally adjustable so that they can be placed close to the user's breathing area, thereby minimizing the risk of transmission of infectious agents.

Since the present invention as described above is not limited to the above-described embodiments, it can be modified within the scope not departing from the gist of the present invention claimed in the claims, and such changes are defined by the description of the claims below. fall within the protection scope of the invention.

1: Ceiling 2: Wall
3: bottom 4: support member
10: moving body 11: wheel
12: through hole 100: intake unit
110: case 111: inlet
200: purification unit 210: case
211: soundproofing pad 220: first connector
221: joint 230: fan
240: filtering member 250: sterilization module
260: input module 270: sensor
280: air inlet and outlet module 281: air inlet pipe
282: air discharge pipe 283: rotating fan
290: temperature and humidity control module 300: exhaust unit
310 Case 311 Outlet
320: second connector 321: joint
330: lamp 340: sensor
A: Device for blocking air propagation of infectious diseases

Claims (19)

an intake unit for inhaling droplets and aerosol discharged from a user's respiratory system along with ambient air through a plurality of inlets formed on at least one surface of the box-shaped case;
a purification unit installed connected to the intake unit to filter and sterilize the air containing the droplets and aerosols flowing into the box-shaped case through a first connection pipe connected to the intake unit; and
A plurality of outlets are formed on at least one surface of the case in the form of a container for the air containing the filtered and sterilized droplets and aerosols introduced through a second connection pipe connected to the purification unit and connected to the purification unit. Including; an exhaust unit that discharges to the outside through
The exhaust unit discharges the air containing the filtered and sterilized droplets and aerosols through the outlet in a vertical laminar flow in the direction of gravity,
The purification unit determines the amount of air inflow into the case from the outdoor space, the amount of air discharged from the inside of the case into the outdoor space, the air inflow period, the air discharge period, the air inflow time, the air discharge time, the air inflow rate, and the air discharge rate. An air propagation blocking device for infectious diseases, characterized in that it further comprises an air inlet and outlet module for controlling. According to claim 1,
At least one of the intake unit, purification unit, and exhaust unit is an air propagation blocking device for infectious diseases, characterized in that embedded in, attached to, or spaced apart from at least one of a ceiling, a wall and a floor inside a building. According to claim 1,
The air propagation blocking device for infectious diseases, characterized in that the intake unit, the purification unit and the exhaust unit are disposed on a movable body that moves in the interior of a building by rotating wheels. According to claim 1,
The inlet of the intake unit is formed to gradually decrease in diameter or number as the distance to the first connection pipe decreases, and is formed intensively at a point where a user is located. of air propagation blocker. According to claim 1,
The air propagation blocking device for infectious diseases, characterized in that the inlet of the intake unit is directed from the front end to the end and is formed with a downward slope. According to claim 1,
The purification unit may include a fan rotating in one direction by a motor drive; and a filtering member filtering the droplet and aerosol from the air sucked in by the suction force generated by the rotation of the fan. and a sterilization module for sterilizing the droplets and aerosols sucked by the suction force generated by the rotation of the fan. According to claim 6,
Air propagation blocking device for infectious diseases, characterized in that the air flowing by the rotation of the fan flows at a speed of 0.1-1.5 m / s. delete According to claim 1,
The air inlet and outlet module may include an air inlet pipe leading from an outdoor space to the case; An air dissipation pipe leading from the case to an outdoor space; and a rotating fan disposed in each of the air inlet pipe and the air discharge pipe. According to claim 1,
The air propagation blocking device of infectious diseases, characterized in that the purification unit further comprises a temperature and humidity control module for adjusting the temperature and humidity of the air inside the case. According to claim 1,
The purification unit further includes a sensor for detecting at least one of the droplets and aerosols, infectious substances, fine dust, harmful substances to the human body, odor particles, and carbon dioxide contained in the air, An air propagation blocking device for infectious diseases, characterized in that the operation is controlled. According to claim 6,
The air propagation blocking device for infectious diseases, characterized in that the purification unit further comprises an input module for injecting additives into the air. According to claim 1,
The outlet of the exhaust unit is formed to gradually decrease in diameter or number as the distance to the second connection pipe decreases, and is concentrated at a point where the user is located. Air propagation blocking device. According to claim 1,
The air propagation blocking device for infectious diseases, characterized in that the outlet of the exhaust unit is formed in a tube shape. According to claim 1,
The air propagation blocker of infectious diseases, characterized in that the exhaust unit includes a lamp that is turned on according to power application. According to claim 1,
The air propagation blocking device for infectious diseases, characterized in that the exhaust unit includes a sensor for detecting the presence of users and the number of users, and the operation of the purification unit is controlled according to signals from the sensors. According to claim 1,
The air propagation blocking device for infectious diseases, characterized in that the first connecting pipe and the second connecting pipe are formed in the form of a pipe having a constant cross-section or a corrugated pipe having a variable length and a change in direction. According to claim 3,
The apparatus for blocking air propagation of infectious diseases, characterized in that the moving body includes at least one through hole communicating with the inlet of the intake unit on at least one surface. According to claim 3,
The air propagation blocking device for infectious diseases, characterized in that the intake unit and the exhaust unit are disposed on the movable body, spaced apart from the surface of the movable body on the top or side, and are positionally adjustable.

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