KR20220026762A - Anti-virus system, anti-virus equipment using the same, and collecting device of living and dead virus - Google Patents

Abstract

An anti-virus system of the present invention comprises: an air inlet for inducing air from an object being disinfected and an air outlet for discharging air; and a virus killing unit which is provided between the air inlet and the air outlet and kills virus by irradiating ultraviolet rays or electromagnetic waves, in which air is sucked from external air or the object being disinfected, and viruses or bacteria are killed so that safe and clean air can be sent to external air or the object being disinfected. This anti-virus system can be applied to various anti-virus apparatuses such as personal respirators, disinfection equipment for indoor breathing of several people, disinfection equipment for passages through which people and articles enter and exit, and virus killing home appliances such as air conditioners, hot-air blowers, air cleaners, etc. The spread of various anti-virus apparatuses can contribute to activation of economic activities at home and abroad. In particular, with the help of the live virus collector and the device for collecting heat-damaged viruses developed by the system of the present invention, vaccine research and development experts can develop and distribute the vaccine as soon as a new virus appears.

Description

{Anti-virus system, anti-virus equipment using the same, and collecting device of living and dead virus}

The present invention relates to an anti-virus system, which enables safe breathing by killing viruses in breathing air, a quarantine device having the same, and a live virus and laceration virus collector.

Corona 19, a recent respiratory virus, is a new virus different from SARS and MERS, and many people are infected, and normal daily life and economic activities are not achieved due to fear of infection. In addition, existing vaccines and therapeutics do not work for new viruses, so a general decline in social functioning is inevitable until vaccines and therapeutics are developed. Moreover, it is not a local problem, but a global pandemic, causing astronomical damage in various ways.

In addition, the development of a vaccine for a new virus usually takes 2-3 years or more, and even if a treatment or vaccine is developed, if a mutant or new virus occurs, this problem is repeated because there is no reliable prevention equipment and treatment.

When a new respiratory virus occurs, it is common to spray disinfectant on the suspected area and wear a mask. Masks are relatively convenient to use, but there is a problem that complete quarantine is insufficient, so it is not a fundamental solution. In addition, social distancing is enforced by refraining from various gatherings and avoiding visits to crowded places, which has an effect of preventing infection, but it is inevitable that the daily life and economic activities of citizens will be greatly reduced.

In addition, negative pressure is applied to the ward where the patient is hospitalized to prevent the breathing air from leaking out of the ward, but the air in the ward itself may contain viruses, so people entering the ward are inevitably exposed to a dangerous environment. Therefore, it is necessary to sterilize the patient's breathing air itself and discharge it to the air or to the outside atmosphere.

The fundamental difficulty in preventing respiratory viruses is that, like the flu virus, which mutates repeatedly, mutated viruses frequently appear, making it difficult to cover them with existing vaccines and to ensure prevention of infection.

Therefore, it is necessary to develop respiratory virus prevention equipment that can prevent various respiratory viruses and all viruses that have been mutated in the future. In addition, at the same time as the outbreak of the new virus, it is urgent to develop a vaccine optimized for the patient's own inhalation. Moreover, this corona virus even raises the possibility of artificial biological weapons, causing fear in people around the world.

In this regard, as a prior art, Utility Model Registration No. 20-0251333 provides an air purifier equipped with an ozone disinfection device, but it is difficult to adopt because the device is complicated and it is not considered harmless to the human body or the environment in that it uses ozone. there is.

In addition, Korean Patent Application Laid-Open No. 10-2012-0082982 provides an air sterilization system and method for an indoor space with indoor air flow, but electrolyzes water containing chlorine to sterilize water containing hypochlorous acid from the upper part of the room. As a spraying method, hypochlorous acid is inhaled through breathing, so it is difficult to adopt it in that it is difficult to avoid controversy about harm to the human body.

Utility model registration No. 20-0251333 Laid-Open Patent Publication No. 10-2012-0082982

The present invention includes an air inlet for guiding air from a quarantine target and an air outlet for discharging air, and a virus killing unit for killing viruses by irradiating ultraviolet or electromagnetic waves disposed between the air inlet and the air outlet, An object of the present invention is to provide an anti-virus system capable of sending safe air to the outside air or quarantine target by inhaling the air from the outside air or the quarantine target to kill the virus or bacteria in the virus killing unit.

In addition, the present invention provides an anti-virus respirator for personal movement, an indoor quarantine facility for preventing virus transmission by respiratory droplets of multiple people for indoor installation, and a quarantine installed in the passage of travelers and deliveries, in the quarantine target of the anti-virus system We provide equipment, virus-killing air conditioners (warm air conditioners), virus-killing air purifiers, and various quarantine equipment and facilities for indoor installation that create an updraft to kill viruses.

In addition, the present invention provides a laceration virus collector and a live virus collector between the quarantine target of the anti-virus system and the virus killing unit. From this, there is provided a vaccine R&D equipment for a novel laceration virus that controls the degree of laceration in the destruction state of DNA and RNA of the laceration virus captured by the laceration virus collector, and the live virus of respiratory disease is transferred from the live virus collector. Collect and distribute to vaccine development companies so that they can contribute to vaccine development.

In order to achieve the object of the present invention, the present invention includes a virus killing chamber having an air inlet and an air outlet, an electromagnetic wave or ultraviolet irradiation chamber for virus killing, and a protective layer (or heat insulating layer) and a housing surrounding it. It consists of an anti-virus system including a virus killing unit.

As an embodiment to which the anti-virus system of the present invention is applied, a virus killing unit having a personal respirator connected to an inhalation air hose and an exhaust air hose, and a virus killing chamber for killing viruses, and air passing therethrough to the respirator It is possible to configure a personal anti-virus respirator including an inhalation air hose that connects, an exhaust air hose that connects exhaled air from the respirator to the virus killing chamber, and an indoor respirator that allows several people to breathe safe air.

A blower is provided in each of the exhaust air hose and the intake air hose.

Each of the blowers is started by a sensor that detects the discharge of the exhalation and the suction of the inhalation, and the power source for operating the sensor and the blower is a battery when it is portable, and AC power is used when it is used in a facility. It is preferable to use

A live virus collecting means required by a vaccine developer is provided between the respiratory tract and the death chamber of the virus killing unit in the exhaust air hose.

The live virus collecting means is connected to the middle of the air hose for discharging, and has a structure capable of inserting and withdrawing a collecting medium capable of collecting live virus.

In addition, the laceration (dead, anti) virus collecting means is also connected to the portion discharged to the outside air in the middle of the inhalation air hose or the death chamber.

The air hose for inhalation is equipped with an electromagnetic wave irradiation density meter and an electromagnetic wave irradiation time (voltage or wind speed) controller to control the thermal (destruction) state of the DNA and RNA of the antivirus.

The virus killing unit is based on having a first death chamber and a second death chamber in one unit to allow inhalation of inhalation and discharge of exhalation to pass independently, and the first and second death chambers are one It is also possible to make it into the death chamber of

In addition, the quarantine equipment provided with the anti-virus system can consist of a portable personal respiratory quarantine equipment and an installation-type quarantine equipment for breathing of several people. In addition, it is possible to prevent entry and exit and deliver goods by configuring the passage quarantine equipment equipped with the virus killing unit exemplified in the anti-virus system.

The passage quarantine equipment is also installed at the entrances and delivery terminals of airports and ports, customs and important institutions.

In addition, it provides a basic system for composing a virus-killing respirator as a military equipment in preparation for the biological warfare of biological weapons.

Regardless of the emergence of a new virus or a strain of the virus, it is possible to kill all viruses and breathe in safe air.

It enables the safe and rapid capture of live virus from the patient's breath so that it can be used quickly for virus treatment research and vaccine development.

Provided is a trap that safely and easily traps laceration (dead) viruses. Using this, we examine the state of destruction of the collected laceration virus DNA and RNA, and control the destruction state, that is, the degree of laceration, to provide a vaccine R&D equipment for laceration virus that is inoculated by breathing for the first time in the medical field.

In addition, by being able to wear personal mobile respiratory quarantine equipment, the activities of those infected with the virus or quarantined can be freed. In addition, by installing multi-use respiratory quarantine equipment in restaurants, classrooms and various gathering places, restaurants, school education, and private institutes will be able to restore normalcy and conduct political, economic, social and cultural activities normally.

In addition, a virus-killing respirator in preparation for the virus-bacterial warfare of biological weapons can be applied to a gas mask.

In addition, if the antivirus system of the present invention is applied to the ventilation device of a livestock barn, such as livestock, it is possible to block animal infectious diseases such as avian flu and swine fever.

In addition, it provides a basic system for composing a virus-killing respirator as a military equipment in preparation for the biological warfare of biological weapons.

1 is a basic conceptual diagram of an anti-virus system according to the present invention.
2A and 2B show a cross-sectional view and a longitudinal cross-sectional view, respectively, of an electromagnetic wave irradiation type virus killing unit used in the antiviral respiratory system according to the present invention.
3a and 3b show a cross-sectional view and a longitudinal cross-sectional view, respectively, of a UV-irradiated virus killing unit used in the antiviral respiratory system according to the present invention.
4 shows the air flow of the antivirus system through which the virus killing unit according to the present invention is applied, the breathing air passes through the virus killing chamber, the live virus collecting means, the antivirus collecting means, and the quarantine target (respiratory, etc.) it has been shown
5 shows an embodiment of a state in which the anti-virus respiratory system according to the present invention is manufactured as a portable and worn in a bag.
6 shows an embodiment of a state in which the anti-virus system according to the present invention is applied indoors to circulate an updraft to prevent virus transmission by respiratory air and droplets of several people.
7 shows an embodiment of a state in which the anti-virus system according to the present invention is installed in an airport, a port, a passage through which the public enters, or an article transfer passage for quarantine of delivered goods.
Fig. 8a shows the anti-virus system according to the present invention applied to an air purifier, and Fig. 8b shows an embodiment of the applied state to the air conditioner 8b.

Hereinafter, an antivirus system according to the present invention will be described in more detail with reference to the accompanying drawings.

1 is a basic conceptual diagram of an anti-virus system according to the present invention.

The anti-virus system 10 of the present invention includes an air inlet 12 and an air outlet 14 and a virus killing unit 100 for irradiating ultraviolet or electromagnetic waves to the air passing therethrough. The air that has passed through the virus killing unit 100 is sent to the quarantine target 101 such as the human body or indoors, and the air from the quarantine target 101 is sent to the virus killing unit 100 to kill 100% of the virus suspended in the air. let

A blower 16 is connected to the air inlet 12 or the air outlet 14 of the killing chamber of the virus killing unit to help circulate air in the system, and if necessary, external air containing oxygen is introduced, or the virus It allows the dead air to be expelled to the outside.

2A and 2B show a cross-sectional view and a longitudinal cross-sectional view, respectively, of the electromagnetic wave irradiation type virus killing unit used in the antiviral respiratory system according to the present invention.

As one embodiment of the virus killing unit 100 irradiating electromagnetic waves in the radiation region, FIG. 2A shows a cross-sectional view of the virus killing unit 100, and FIG. 2B shows a longitudinal cross-sectional view of the virus killing unit 100 .

The virus killing unit 100 has at least one virus killing chamber, and in the illustrated embodiment, it is provided with a first killing chamber 110 and a second killing chamber 120 to be used in a personal respiratory system. The exhalation is allowed to pass independently, and the virus killing chamber includes a heating unit and an electromagnetic wave converter 140 , and a protective layer or heat insulating layer 130 surrounding it. High-density electromagnetic waves of wavelengths beneficial to the human body are irradiated to the air passing through the virus killing chamber, and 100% of viruses or bacteria contained in the air passing through the death chamber are killed.

As an example of the virus killing chamber, the heating unit and the electromagnetic wave converter 140 were exemplified. The electromagnetic wave generated by the illustrated electromagnetic wave converter is irradiated with high density electromagnetic waves of a wavelength having a high absorption rate in organisms and proteins, and air Only the virus suspended in the air is rapidly heated and killed at a temperature higher than the air heating temperature at the speed of light.

In addition to this, an ultraviolet irradiation device or a microwave irradiation device is also included in the scope of the present invention, and the heating unit and the electromagnetic wave converter are representatively exemplified. Hereinafter, in each embodiment, for convenience of explanation and understanding, it is stated that an ultraviolet irradiation device and a microwave irradiation device can be selectively used. The same applies to the description of the claims.

And, the virus killing chambers 110 and 120 are configured in a straight cylindrical shape to serve as a focusing guide for electromagnetic waves. Thereby, it is possible to increase the density of electromagnetic waves with a compact shape, and uniformly irradiated with electromagnetic waves to uniformly control the degree of laceration of the virus.

In such a shape, a heating unit and an electromagnetic wave converter 140 are provided around the first dying chamber 110 and the second dying chamber 120 , By applying thermal energy to the electromagnetic wave converter to generate high-density electromagnetic waves, it can be irradiated to the virus in the air to kill the virus. And by forming the heat insulating layer 130 around the first dying chamber 110 and the second dying chamber 120, to ensure thermal efficiency and safety.

The heating unit and the electromagnetic wave converter 140 include a heater such as a heating wire, and an electromagnetic wave generator, for example, titanium monoxide (TiO), is coated on a surface facing the virus killing chamber to convert thermal energy into electromagnetic energy. The electromagnetic wave energy is absorbed by the black body coated on the outside of the death chambers 110 and 120 and is converted into thermal energy, and is converted back into electromagnetic waves of a wavelength beneficial to the human body in the titanium monoxide coated inside the death chamber. Only the virus in the air passing through the death chamber by electromagnetic wave of infrared wavelength is heated from 100°C to 270°C, and the death temperature is adjusted to be used. And the base material of the death chamber is preferably titanium (Ti), stainless (SUS) material is also possible.

The death temperature control is adjusted to 270° C. in a general personal respiratory system, and used by adjusting the temperature as low as possible for a laceration virus collector.

At this time, if high-density electromagnetic waves of the absorption wavelength of the organism are irradiated into the air passing through the death chamber, only the suspended bacteria or viruses are heated to 270°C, and the air heating temperature is much lower. Easy to install and easy to put in a bag.

And the housing 131 surrounding the entire exterior of the death unit 100 is adapted to accommodate all of the above components. Optionally, it is more preferable for thermal efficiency and safety to form a vacuum unit 145 around the first and second dying chambers 110 and 120 .

3a and 3b show a cross-sectional view and a longitudinal cross-sectional view, respectively, of a UV-irradiated virus killing unit used in the antiviral respiratory system according to the present invention.

The virus killing unit 100 includes at least one virus killing chamber, and in the illustrated embodiment, the first and second killing chamber 110 and the second killing chamber 120 are provided to exemplify a quarantine device for killing viruses. The ultraviolet irradiation chamber of the illustrated prevention equipment includes one or more ultraviolet generators 141 and an ultraviolet reflector 142 surrounding it.

The ultraviolet reflector is made of known titanium dioxide (TiO² material), and ultraviolet rays are irradiated with high density to viruses in the air passing through the apoptosis chamber. it comes to me

And in the killing chamber of FIGS. 2 and 3, when high-density electromagnetic waves or high-density ultraviolet rays are irradiated to kill 100% of virus bacteria, an ultra-fine filter 17 is provided to avoid breathing the modified DNA and RNA of the virus bacteria It is desirable to breathe clean air filtered out of dead viruses to solve the medical problem that breathing of dead viruses is harmful to the human body.

4 shows the air flow of the antivirus system through which the virus killing unit according to the present invention is applied, in which breathing air passes through the virus killing chamber, the live virus collecting means, the antivirus collecting means, and the quarantine target (respiratory, etc.) it has been shown

That is, by applying the virus killing unit according to the present invention, the air inhaled from the atmosphere or indoors passes through the virus killing room, enters the quarantine target, supplies safe air, and returns the virus-contaminated (included) air of the quarantine target again. It is a conceptual diagram showing the air flow of the anti-virus system, which is discharged to indoor air or the atmosphere. In addition, a live virus collecting means and an anti (threshold killing) virus collecting means are provided so that the dead or live virus can be captured.

There is a risk of infection if you breathe air or indoor air that may contain various viruses as it is, so you need to sterilize it and breathe it. For this purpose, before breathing, the virus killing unit 100 is passed, and then, through the respiratory tract 150 and the lungs with an inhalation, it is allowed to go out with an exhalation. In addition, in the case of exhalation, since there is a possibility that the virus is included, it must be passed through the virus killing unit 100 and released to the atmosphere.

It is preferable that the virus killing unit 100 be separately provided with a first killing chamber 110 and a second killing chamber 120 for inhalation and discharging.

The inhalation air hose 112 and the exhaust air hose 122 are connected to the respirator 150, and the air entering and exiting the respirator 150 is a death chamber 110 of the virus killing unit 100 that kills the virus. 120) to pass. The respirator 150 is designed to be worn while covering the nose and mouth like a mask. The inhalation air hose 112 is configured to connect the air passing through the first killing chamber 110 of the virus killing unit 100 to the respirator 150 through the inhalation port 150a. The exhaust air hose 122 is configured to connect the exhaled air from the respirator 150 to the second killing chamber 120 of the virus killing unit 100 through the exhalation port 150b.

Such an anti-virus system for respiration may be composed of individual respiration prevention equipment, or, if necessary, may consist of a plurality of respiration prevention equipment in an indoor space where two or more people gather.

The virus killing unit 100 exemplifies the use of a death chamber for electromagnetic wave irradiation beneficial to the human body, and a UV irradiation type virus killing unit can also be used.

In addition, in the air hose 122 for the discharge, a live virus collecting means 124 is provided between the exhalation port 150b of the respirator 150 and the second killing chamber 120 of the virus killing unit 100, It can be collected and used as a sample to be used in the development of virus vaccines or therapeutics.

The live virus collecting means 124 is connected to the middle of the exhaust air hose 122 and has a structure in which a collecting medium 126 capable of collecting live virus can be inserted and taken out. As the collection medium, a solid medium (badge) in which Korean paper moistened with broth or the like is dried may be used.

And between the air hose 112 for inhalation passing through the first death chamber 110 and the inhalation port of the respirator, a laceration virus collector 114 is provided to collect laceration (dead) viruses to research and develop a new laceration vaccine. It can be used as a sample to be used, and it can be composed of equipment that directly researches and develops virus strains sold by companies that develop vaccines.

And the laceration virus can be collected with an ultra-fine filter, and the material of the filter can be made of, for example, microfiber or non-woven material that can filter the virus.

By installing valves or connecting connectors 127 on the front and rear air hoses of the live virus collecting means and the lacerated virus collecting means, the front and rear valves are locked, and the collector (means) is detached and attached, so that the virus is thoroughly prevented from leaking to the outside.

A blower 116 is connected to the air hose 112 for intake and the air hose 122 for discharge, respectively, and each blower is preferably operated by a sensor 151 that detects exhalation and inhalation. Do. The sensor may be provided in the respirator 150 or the virus killing unit 100, and the positions shown in the drawings are merely exemplary.

In addition, a non-contact temperature measuring device 128 for measuring the electromagnetic wave irradiation density is provided in order to adjust the laceration death state of the dead virus captured by the dead virus collecting means, and according to the measured electromagnetic wave irradiation density, the virus killing unit 100 Controls the strength of electromagnetic waves. To this end, a voltage regulating device 129 (FIG. 3B) is provided. Accordingly, by checking the laceration state of the virus, a vaccine development expert can adjust the laceration status of the virus so that the laceration condition is optimized as a respiratory vaccine for each respiratory tract.

5 shows an embodiment of a state in which the anti-virus system 10 according to the present invention is manufactured to be portable and worn in a bag.

The virus killing unit 100 is placed in the bag 161 , and an inhalation air hose 112 and an exhaust air hose 122 are connected between the virus killing unit 100 and the respirator 150 . The wearer's inhaled air passes through the virus killing unit 100, then passes through the inhalation air hose 112 and enters the lungs through the inhalation port, mouth, and nose of the respirator, and the exhaled air coming out of the wearer's lungs is 150) to pass through the virus killing unit 100 through the exhaust air hose 122 from the exhalation port. Accordingly, in any environment, it is possible to breathe in and spit out safe air that has been annihilated.

The sensor attached to the respirator is, for example, a pressure sensor, and operates the inhalation blower and the exhalation blower according to positive and negative pressures of exhalation and inspiration. Inspiratory and exhalation blowers are installed near the inlet and outlet of the virus killing unit and are battery powered.

And it is also possible to remove the dead virus by installing the ultra-fine filter 17 near the respirator 150 or near the virus killing unit 100 .

In addition, in preparation for bacterial and viral biochemical warfare, it is also possible to apply a personal respirator that prevents personal respiratory droplets as military equipment to a gas mask.

By attaching a virus killing unit and air hose to an existing gas mask, or by designing a more compact design for personal movement virus killing respirator in FIG. It is an anti-virus system

6 shows an embodiment of a state in which the anti-virus system according to the present invention is applied indoors to circulate an upward air flow to prevent virus transmission by respiratory air and droplets of several people.

That is, the anti-virus system 10 according to the present invention is manufactured for an indoor space, and, for example, a virus is transmitted to the person next to it by breathing droplets of several people in a restaurant, cafe, classroom, transportation, office, auditorium, conference room, etc. It shows the state applied to the quarantine equipment that creates an updraft that prevents the spread of .

Air from indoor or outdoor air passes through the death chamber of the virus killing unit 100 through the air inlet 12 of the virus killing room to kill the virus, and then flows back into the room through the air outlet 14 of the virus killing room As much as possible, the air that has passed through the virus killing unit 100 is discharged into the room or, if there is no indoor ventilation, it is discharged to the outside atmosphere.

A hood disposed at the upper end of the air inlet 12 of the virus killing chamber by installing a blower 16 at the air inlet 12 and the air outlet 14 of the virus killing chamber to promote air circulation and at the same time create an upward airflow. (19) or induces to flow toward the virus killing unit 100 through the corrugated duct and the ceiling duct. Accordingly, the exhaled air and droplets of several people in the room rise upward according to the updraft, and as it passes through the first virus killing chamber 100 through the hood, corrugated duct and ceiling duct on the top, the virus in the air 100% killed. Even if an infected person is indoors, the air containing the virus does not spread to the people next to it, but rises up along the updraft. It is preferable to install a cough droplet screen so that the updraft is maintained even when coughing.

The virus killing unit 100 is composed of an ultraviolet or electromagnetic wave irradiation type killing chamber.

By irradiating high-density electromagnetic waves or high-density ultraviolet rays toward the air passing through the death chamber, 100% of all viruses floating in the air are killed. Virus-killed air is blown up from a lower duct or hose, causing several people's exhaled air and droplets to be sucked up into the hood. Therefore, an upward airflow is formed in the vertical direction toward the hood, and the virus contained in respiratory droplets is not transmitted to the next person in the horizontal direction.

And the virus killing unit 100 in a large room selects a UV irradiation type virus killing room with good cost-effectiveness, and it is preferable to use a virus killing room that irradiates electromagnetic waves of a wavelength beneficial to the human body in a small and medium-sized room.

It is also possible to remove dead viruses by installing a filter 17 at the air outlet 14 .

7 shows an embodiment of a state in which the anti-virus system 10 according to the present invention is installed in an access passage of an airport or port, a passage through which the public such as a public building enters, or an article transfer passage for quarantine of delivered goods.

A plurality of damper holes 205 for blowing air are formed in the side surface of the passage 200 , and a blower 16 is provided on the upper ceiling of the passage 200 to suck air and blow it into the virus killing chamber. The blower is preferably a blower made of a fan for an air curtain. To do the above, in order to construct the passage prevention equipment that kills 100%, the virus killing room is made long, that is, the air inlet is made in a long rectangle, and the passage speed is slowed until 100% of the viruses in the air are killed for a sufficient time. for high-density investigations.

Therefore, the blower 16 is also installed on the side of the air inlet 12 or the air outlet 14, a fan blower for a long air curtain. The blower 16 sucks the air in the long passage 200 and sends the air containing the virus to the long killing unit 100 . It is configured to kill 100% of the virus in the air in the long death chamber of the virus killing unit 100 .

The virus killing unit 100, in the case of a passage through which many people pass, uses a UV irradiation-type virus killing room with good cost-effectiveness. It is also desirable to apply a feeding room.

Viruses attached to people or articles passing through the passage 200 to which the anti-virus system 10 of the present invention is applied are suspended in the air due to a strong air shower effect and are killed while passing through the virus killing unit 100 .

Accordingly, it is possible to block the spread of the virus through goods or travelers.

In addition, it is preferable to install a filter 17 at the air outlet 14 to remove dead viruses.

8 is another embodiment of an anti-virus system having a virus killing unit 100 according to the present invention. FIG. 8A shows an embodiment of a state applied to the air purifier 210, and FIG. 8B shows a virus according to the present invention. An embodiment of the state applied to the air conditioner 220 having the killing unit 100 and the hot air heater is shown.

The air purifier 210 and the air conditioner 220 and the air conditioner 220, it is preferable to select the UV-irradiated dying room shown in FIGS. 3A and 3B, which has a good cost-effectiveness and does not generate heat in summer. Viruses that have been killed by UV rays must be removed with a filter to breathe. A filter that filters out dead viruses can be installed at the entrance or exit of the virus killing room. Use a conventional air purifier or air conditioner filter or reinforce the filter function You may.

In this way, by arranging an anti-virus system having a virus killing unit 100 on the air inlet side of an existing air purifier or air conditioner, the air coming out through the air purifier 210 or air conditioner 220 (including a hot air conditioner) is not a virus. is removed, and a safe air filtered from dead viruses is supplied.

Accordingly, when there is a virus infected person in the room, there was a problem that the air purifier or air conditioner rather spread the virus, which can be solved.

And, in addition to the example diagrams described above (Fig. 5, Fig. 6, Fig. 7, Fig. 8), the anti-virus system of the present invention can be included in other anti-virus equipment configured in other forms, of course, and, in particular, By applying a virus killing unit to a gas mask, which is a military equipment, it can be applied to military equipment that prevents even unexpected bacterial and virus attacks. That is, the anti-virus system constituting the virus-bacterial killing gas mask is also included in the present invention.

10: Anti-Virus System
12: air inlet
14: air outlet
16: blower
100: virus killing unit
110: first death chamber
112: air hose for suction
120: second death chamber
122: exhaust air hose
140: heating unit and electromagnetic wave converter
141: ultraviolet generator

Claims (12)

A virus killing unit having an air inlet for inducing air from a quarantine target and an air outlet for discharging air, and a virus killing unit that kills viruses by irradiating ultraviolet or electromagnetic waves disposed between the air inlet and the air outlet; An anti-virus system that inhales air from a target and kills viruses or bacteria in the virus killing unit to send clean air to outside air or quarantine targets.
According to claim 1, wherein the conversion chamber of the virus killing unit consists of a high-density electromagnetic wave converter in a cylindrical shape to serve as an electromagnetic wave guide so that high-density electromagnetic waves are irradiated, or a cylindrical reflector surrounding the high-density ultraviolet generator Equipped with, the anti-virus system having an ultraviolet radiation chamber comprising a material having a high reflectance of titanium dioxide (TiO _² ) for the reflector.
The respirator according to claim 1, wherein the respirator is worn on the user's nose and mouth in order to kill the virus contained in the personal breathing air to be quarantined, the inhalation hose connecting the air passing through the virus killing unit to the respirator, and exhaled air An anti-virus system having a personal respirator that kills the virus of personal respiratory droplets including a discharge hose connecting to the virus killing unit.
An anti-virus system having a live virus trap for vaccine research using the anti-virus system according to claim 3, and in the discharge hose, between the respiratory tract and the virus killing unit.
The anti-virus system according to claim 3, wherein an anti-virus collecting means for research and development of a novel laceration virus vaccine is provided at the outlet between the respiratory system and the virus killing unit or discharged from the virus killing unit in the suction hose.
[Claim 6] The anti-virus system according to claim 5, wherein the anti-virus system includes a non-contact temperature measuring device and a voltage adjusting device for controlling the death or thermal state of the anti-virus collected by the anti-virus collecting means.
The antivirus system according to claim 3, wherein each blower is provided in the discharge hose and the suction hose, and each blower is activated by a sensor that detects discharge and suction.
The antivirus system according to claim 3, wherein the virus killing unit has a first and a second death chamber in one unit so that inhalation and discharge pass independently.
The anti-virus system according to claim 1 or 2, comprising a blower for inhaling indoor air and an air inlet, passing the inhaled air through a virus killing unit to kill viruses, and then passing through the air outlet to kill the virus. An anti-virus system composing indoor respiratory droplet prevention equipment that allows human respiratory droplets to pass through the death unit again according to the rising airflow, exhausts them to the outside air or returns them to the room, and creates a circulation of the rising airflow of the virus killing air.
An anti-virus system according to claim 1 or 2, wherein the anti-virus system is installed in an access passage of an airport or port, a passage through which the public enters, or an article transfer passage for quarantine of delivered goods, Anti-virus for disinfection of passages that have a blower and an air inlet that inhale the air, pass the inhaled air through the virus killing unit to kill the virus, and then discharge it to the outside air through the air outlet or return it to the quarantine space system.
The anti-virus system according to claim 1, wherein the anti-virus system is applied to a ventilation device of a negative pressure ward having the virus killing unit or a ventilation device in a livestock house.
A gas mask, which is a military equipment against an existing chemotherapy attack, which is the target of the anti-virus system according to paragraph 1, includes a virus killing unit to prevent even unexpected bacterial and virus attacks, and constitutes a virus and bacteria killing gas mask. anti-virus system.

Images