KR20240024866A - Anti-virus system, anti-virus equipment using the same, and collecting device of living and dead virus - Google Patents

Abstract

The anti-virus system of the present invention has an air inlet for introducing air from the quarantine target and an air outlet for discharging air, and kills viruses by irradiating ultraviolet rays or electromagnetic waves disposed between the air inlet and the air outlet. It is equipped with a unit, and is designed to suck air from the outside air or the quarantine target, kill viruses or bacteria in the virus killing unit, and send clean air to the outside air or the quarantine target.
Quarantine equipment targeted by the anti-virus system, such as personal respirators, indoor breathing quarantine equipment for multiple people, quarantine equipment for passageways through which people and goods enter and exit, and virus-killing home appliances, such as air conditioners, heaters, air purifiers, etc. Once various quarantine equipment is distributed, daily life and domestic and international economic activities will be revitalized. In particular, vaccine research and development experts will develop the corresponding vaccine as soon as a new virus appears using the live virus collector and thermal virus collector developed with the system of the present invention. This made it possible for it to be disseminated.

Description

Anti-virus system, quarantine equipment equipped with the same, and live virus and fever virus collector {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 that kills viruses in the breathing air to enable safe breathing, quarantine equipment equipped with the same, and a live virus and scald virus collector.

COVID-19, a recently discovered respiratory virus, is a new virus different from SARS or MERS. Many people are infected, and normal daily life and economic activities are not carried out due to fear of infection. In addition, existing vaccines and treatments do not work against new viruses, so an overall decline in social functions is inevitable until vaccines and treatments are developed. Moreover, it is not a local problem, but has developed into a pandemic that is sweeping the world, causing astronomical damage in many ways.

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

When a new respiratory virus occurs, it is common to spray disinfectant on the suspected area and wear a mask. Although masks are relatively convenient to use, they have the problem of being insufficient for complete quarantine, so they are not a fundamental solution. In addition, social distancing is implemented by refraining from various gatherings and avoiding visiting crowded places. Although it is effective in preventing infection, it cannot avoid the problem of a significant decline in citizens' daily lives and economic activities.

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

The fundamental difficulty in quarantining respiratory viruses is that, just as the flu virus continues to mutate, mutated viruses frequently emerge, making it difficult to cover them with existing vaccines and making it difficult to be sure of infection prevention.

Accordingly, there is a need to develop respiratory virus quarantine equipment that can prevent various respiratory viruses and all mutated viruses in the future. In addition, with the outbreak of a new virus, it is urgent to immediately develop a vaccine optimized for inhalation by the patient. Furthermore, the possibility of this coronavirus being an artificial biological weapon has been raised, 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 since the device is complex and uses ozone, it is difficult to adopt because it is difficult to consider it harmless to the human body or the environment. there is.

In addition, Patent Publication No. 10-2012-0082982 provides an air sterilization system and method for indoor spaces with indoor air flow, but sterilizing water containing hypochlorous acid is electrolyzed from the upper part of the room by electrolyzing water containing chlorine. As a spraying method, hypochlorous acid is inhaled through breathing, so it is difficult to adopt it because it is difficult to avoid controversy over its harmfulness to the human body.

Utility Model Registration No. 20-0251333 Public Patent Publication No. 10-2012-0082982

The present invention is provided with an air inlet that introduces air from the quarantine target and an air outlet that discharges air, and a virus killing unit that kills viruses by irradiating ultraviolet rays or electromagnetic waves disposed between the air inlet and the air outlet, The object of the present invention is to provide an anti-virus system that sucks air from the outside air or the quarantine target, kills viruses or bacteria in the virus killing unit, and sends safe air to the outside air or the quarantine target.

In addition, the present invention is a quarantine object of the anti-virus system, including an anti-virus respirator for personal mobility, an indoor quarantine facility for indoor installation to prevent virus transmission by respiratory droplets of several people, and a quarantine facility for installation in the passage of travelers and delivered goods. We provide equipment, virus-killing air conditioners (heaters), virus-killing air purifiers, and various quarantine equipment and facilities for indoor installation that create upward airflow to kill viruses.

In addition, the present invention provides a thermal virus collector and a live virus collector between the quarantine target and the virus killing unit of the anti-virus system. From this, we provide research and development equipment for a new fever virus vaccine that controls the degree of destruction of the DNA and RNA of the fever virus captured in the fever virus collector, and live viruses of respiratory diseases are extracted from the live virus collector. It is collected and distributed to vaccine development companies to contribute to vaccine development. Here, the thermal virus refers to a virus that has suffered thermal injury due to ultraviolet rays, infrared electromagnetic waves, etc.

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

As an embodiment of applying the anti-virus system of the present invention, a virus killing unit is provided with a personal respirator to which an intake air hose and an discharge air hose are connected, a virus killing chamber for killing viruses, and the air passing through it is supplied to the respirator. A personal anti-virus respirator including an inhalation air hose for connection, an exhaust air hose for connecting exhaled air from the respirator to the virus killing chamber, and indoor breathing equipment that allows multiple people to breathe safe air can be configured.

The exhaust air hose and the suction air hose are each provided with a blower.

Each of the blowers starts operation by a sensor that detects the discharge of exhaled breath and the intake of inhaled breath, and the power source for operating the sensor and blower is a battery when portable, or an alternating current power when used inside a facility. It is desirable to use

In the exhaust air hose, a means for collecting live viruses required by vaccine development companies is provided between the respirator and the killing chamber of the virus killing unit.

The live virus collecting means is connected to the middle of the discharge air hose and has a structure capable of inserting and withdrawing a collection medium capable of collecting live viruses.

In addition, the thermal virus collecting means is also connected to the middle of the suction air hose or the part discharged from the death chamber to the outside air.

The suction air hose 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 anti-virus.

The virus killing unit is based on having a first killing chamber and a second killing chamber in one unit to allow inhalation of inhaled breath and discharge of exhaled breath to pass independently, and the first and second killing chambers are one. It is also possible to use it as a death chamber.

In addition, the quarantine equipment equipped with the anti-virus system can be composed of portable personal respiratory quarantine equipment and installed type quarantine equipment for multiple people's breathing. In addition, passage quarantine equipment equipped with a virus killing unit as exemplified in the anti-virus system can be configured to quarantine people entering and leaving and delivered goods.

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

It also provides a basic system for constructing a virus-killing respiratory system as military equipment to prepare for biological warfare against bacteria.

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

It allows the live virus to be safely and quickly collected from the patient's breath so that it can be quickly used for research on treatments for the virus and development of vaccines.

Provides a collector that safely and easily captures fever viruses. Using this, we examine the destruction state of the DNA and RNA of the captured fever virus, control the destruction state, that is, the degree of laceration, and provide research and development equipment for a vaccine for fever virus that can be inoculated by breathing for the first time in the medical world.

In addition, by being able to wear personal respiratory quarantine equipment and move around, those infected with the virus or in quarantine can move freely. In addition, by installing multi-use respiratory quarantine equipment in restaurants, classrooms, and various assembly places, the restaurant industry, school education, and academies will be able to return to normal, and political, economic, social, and cultural activities can be carried out normally.

Additionally, a virus killing respirator to prepare for biological warfare against viruses can be applied to a gas mask.

In addition, if the anti-virus system of the present invention is applied to the ventilation system of livestock sheds, etc., animal infectious diseases such as avian influenza and swine fever can be blocked.

It also provides a basic system for constructing a virus-killing respiratory system as military equipment to prepare for biological warfare against bacteria.

1 is a basic conceptual diagram of an anti-virus system according to the present invention.
Figures 2a and 2b show cross-sectional and longitudinal cross-sectional views, respectively, of the electromagnetic wave irradiation type virus killing unit used in the anti-virus breathing system according to the present invention.
Figures 3a and 3b show cross-sectional and longitudinal cross-sectional views, respectively, of the ultraviolet irradiation type virus killing unit used in the anti-virus respiratory system according to the present invention.
Figure 4 shows the air flow of the anti-virus system through which the breathing air passes through the virus killing chamber, the live virus collection means, the thermal virus collection means, and the quarantine object (respirator, etc.) by applying the virus killing unit according to the present invention. It is shown.
Figure 5 shows an example of an anti-virus breathing system according to the present invention made portable and worn in a bag.
Figure 6 shows an example of an indoor application of the anti-virus system according to the present invention to circulate an upward air current that prevents virus transmission by respiratory air and droplets of several people.
Figure 7 shows an embodiment of the anti-virus system according to the present invention installed in an airport, a port, a passage for the public to enter or exit, or a passage for transporting goods for quarantine of delivered goods.
Figure 8a shows the anti-virus system according to the present invention applied to an air purifier, and Figure 8b shows an example of the anti-virus system applied to an air conditioner, etc.

Hereinafter, the anti-virus 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 a virus killing unit 100 that irradiates ultraviolet rays or electromagnetic waves to the air passing through an air inlet 12 and an air outlet 14. The air that passes through the virus killing unit (100) is sent to the quarantine target (101), such as the human body or indoors, and the air coming out of the quarantine target (101) is sent to the virus killing unit (100) to kill 100% of the viruses suspended in the air. let me do it

A blower (16) is connected to the air inlet (12) or air outlet (14) of the killing chamber of the virus killing unit to help circulate the air in the system and, if necessary, to introduce external air containing oxygen or to prevent viruses from entering. Allows dead air to be exported to the outside.

Figures 2a and 2b show cross-sectional and longitudinal cross-sectional views, respectively, of the electromagnetic wave irradiation type virus killing unit used in the anti-virus breathing system according to the present invention.

As an example of the virus killing unit 100 that irradiates electromagnetic waves in the radiant wave area, Figure 2a shows a cross-sectional view of the virus killing unit 100, and Figure 2b shows a longitudinal cross-sectional view of the virus killing unit 100. .

The virus killing unit 100 is provided with at least one virus killing chamber, and when provided with one killing chamber, air flows in one direction. In the illustrated embodiment, the first killing chamber 110 and the second killing chamber 120 ) When used in a personal breathing system, inhalation and exhalation are allowed to pass independently, and the virus killing unit (100) includes a virus killing chamber, a heating unit, and an electromagnetic wave converter (140), and protection surrounding them. It consists of a layer or an insulating layer 130. That is, the virus killing unit 100 consists of a high-density heating unit and an electromagnetic wave converter 140 in a cylinder, and is provided with an electromagnetic wave conversion chamber 143 that also serves as an electromagnetic wave guide so that high-density electromagnetic waves are irradiated. and converting heat energy into electromagnetic waves of infrared wavelength by an electromagnetic wave converter 140, and providing at least one virus killing chamber 110, 120 in the electromagnetic wave conversion chamber 143 of the virus killing unit 100. do. High-density electromagnetic waves of a wavelength beneficial to the human body are irradiated to the air passing through the virus killing chamber, and viruses and bacteria contained in the air passing through the killing chamber are 100% killed by electromagnetic waves.

As an example of a virus killing chamber, a heating unit and an electromagnetic wave converter 140 are exemplified. The electromagnetic waves generated from the exemplified electromagnetic wave converter irradiate electromagnetic waves of a wavelength with a high absorption rate to organisms and proteins at high density, and the air Only viruses suspended in the air are quickly heated and killed at the speed of light at a temperature higher than the air heating temperature.

In addition to this, ultraviolet irradiation devices and microwave irradiation devices are also included in the scope of the present invention, and the heating unit and electromagnetic wave converter are representative examples. In each of the following examples, for convenience of explanation and understanding, it will be noted that an ultraviolet irradiation device or a microwave irradiation device can be optionally used. The same applies to the description of the claims.

In addition, the virus killing chambers 110 and 120 are composed of a straight cylindrical shape and serve as a guide for focusing electromagnetic waves. By this, the density of electromagnetic waves can be increased along with the compact shape, and the degree of thermal injury of the virus can be uniformly controlled by uniform electromagnetic waves being irradiated.

In this shape, a heating unit and an electromagnetic wave converter 140 are provided around the first death chamber 110 and the second death chamber 120, so that the first death chamber 110 and the second death chamber 120 By applying heat energy to the electromagnetic wave converter, high-density electromagnetic waves can be generated and irradiated to viruses in the air, killing them. Additionally, an insulating layer 130 is formed around the first death chamber 110 and the second death chamber 120 to ensure thermal efficiency and safety.

The heating unit and electromagnetic wave converter 140 includes a heater such as a heating wire, and an electromagnetic wave generator, such as titanium monoxide (TiO), is applied to the side facing the virus killing chamber to convert heat energy into electromagnetic wave energy. The electromagnetic wave energy is absorbed by the black body coated on the outside of the death chamber (110, 120) and converted into heat 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. Electromagnetic waves of infrared wavelength heat only viruses in the air passing through the death chamber from 100℃ to 270℃, and are used by controlling the killing temperature. In addition, the base material of the death chamber is preferably titanium (Ti), and stainless steel (SUS) material is also possible.

The killing temperature is adjusted to 270°C in general personal respirators, and is adjusted to the lowest possible temperature in thermal virus collector applications.

At this time, when high-density electromagnetic waves of the wavelength absorbed by organisms are irradiated into the air passing through the killing chamber, only suspended bacteria or viruses are heated to 270°C, and the air heating temperature is much lower, so a virus killing unit containing a killing chamber is installed indoors. It is easy to install and easy to put in a bag.

And the housing 131 surrounding the entire exterior of the death unit 100 is configured to accommodate all of the above components. Optionally, it is more desirable for thermal efficiency and safety to create a vacuum portion 145 around the first death chamber 110 and the second death chamber 120.

Figures 3a and 3b show cross-sectional and longitudinal cross-sectional views, respectively, of the ultraviolet irradiation type virus killing unit used in the anti-virus respiratory system according to the present invention.

The virus killing unit 100 has at least one virus killing chamber, and in the illustrated embodiment, it illustrates quarantine equipment that kills viruses by having a first killing chamber 110 and a second killing chamber 120. The ultraviolet irradiation room of the exemplary quarantine equipment includes one or more ultraviolet ray generators 141 and an ultraviolet ray reflector 142 surrounding them.

The ultraviolet reflector is made of a known titanium dioxide (TiO ₂ ) material, and ultraviolet rays are irradiated at high density to viruses in the air passing through the killing chamber, reducing the existing killing efficiency of about 95% to 99% to 100%. It becomes effective.

In addition, when high-density electromagnetic waves or high-density ultraviolet rays are irradiated in the killing chamber of FIGS. 2 and 3 above to kill 100% of viruses, an ultrafine filter (17) is provided to avoid respiration of modified DNA and RNA of viruses. It is desirable to solve the problem raised by the medical community that breathing dead viruses is harmful to the human body by allowing people to breathe clean air that has filtered out dead viruses.

Figure 4 shows the air flow of the anti-virus system through which the breathing air passes through the virus killing chamber, the live virus collection means, the thermal virus collection means, and the quarantine target (respirator, etc.) by applying the virus killing unit according to the present invention. It is shown.

In other words, by applying the virus killing unit according to the present invention, the air sucked from the atmosphere or indoors passes through the virus killing chamber and enters the quarantine target, supplies safe air, and removes the virus-contaminated (including) air of the quarantine target again. This is a conceptual diagram showing the air flow of an anti-virus system that is discharged into indoor air or the atmosphere. In addition, a means for collecting live viruses and a means for collecting dead or lacerated viruses are provided so that lacerated or live viruses can be captured.

There is a risk of infection if you breathe the atmosphere or indoor air, which may contain various viruses, so it is necessary to sterilize it before breathing. For this purpose, the virus is passed through the virus killing unit (100) before breathing, and then passed through the respiratory tract (150) and lungs through inhalation and then out through exhalation. In addition, since exhaled breath may contain viruses, it must pass through the virus killing unit 100 and be released into the atmosphere.

The virus killing unit 100 is preferably divided into inhalation and discharge purposes and is provided with a first killing chamber 110 and a second killing chamber 120.

The suction air hose 112 and the discharge air hose 122 are connected to the respirator 150, and the air entering and leaving the respirator 150 is discharged into the death chamber 110 of the virus killing unit 100, which kills viruses. 120). The respirator 150 is designed to be worn covering the nose and mouth like a mask. The suction air hose 112 is designed to connect the air that has passed 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 connects the exhaled air from the respirator 150 to the second killing chamber 120 of the virus killing unit 100 through the exhalation port 150b.

This respiratory anti-virus system can be composed of personal respiratory quarantine equipment, or, if necessary, can be configured with multiple respiratory quarantine equipment in an indoor space where two or more people are gathered.

The virus killing unit 100 is exemplified by using a killing chamber for electromagnetic wave irradiation, which is beneficial to the human body, but an ultraviolet irradiation type virus killing unit can also be used.

In addition, in the discharge air hose 122, 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, so that the virus It can be collected and used as a sample to develop a virus vaccine or treatment.

The live virus collecting means 124 is connected to the middle of the discharge air hose 122 and has a structure capable of inserting and withdrawing a collection medium 126 capable of collecting live viruses. The collection medium may be a solid medium made by drying Korean paper or the like soaked in broth.

In addition, a thermal virus collector 114 is provided between the suction air hose 112 passing through the first death chamber 110 and the inhalation port of the respirator to capture dead or thermal viruses and use them in research and development of a new thermal vaccine. It can be used as a sample, and it can be configured as equipment to directly research, develop, and produce the virus strains distributed by companies developing vaccines.

In addition, thermal virus collection can be done with an ultra-fine filter, and the material of the filter can be made of a material that can filter viruses, for example, microfiber or non-woven material.

By installing valves or connection connectors (127) on the air hoses at the front and rear of the live virus collection means and the thermal virus collection means, the front and rear valves are locked, and the collector (means) is detached and attached to thoroughly prevent the virus from leaking to the outside.

A blower 116 is connected to the suction air hose 112 and the discharge air hose 122, and each blower is preferably started to operate 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 drawing are merely exemplary.

In addition, in order to adjust the thermal killing state of the dead virus captured in the dead or thermal virus collection means, a non-contact temperature gauge (128) is provided to measure the electromagnetic wave irradiation density, and a virus killing unit (100) is installed according to the measured electromagnetic wave irradiation density. ) adjusts the intensity of electromagnetic waves. For this purpose, a voltage regulating device 129 (FIG. 3b) is provided. Accordingly, by checking the thermal state of the virus, a vaccine development expert can adjust the thermal state of the virus so that the thermal state is optimized as a respiratory vaccine for each individual breather.

Figure 5 shows an embodiment of the anti-virus system 10 according to the present invention made portable and worn in a bag.

*The virus killing unit 100 is placed in the bag 161, and the suction air hose 112 and the discharge air hose 122 are connected between the virus killing unit 100 and the respiratory tract 150. The wearer's inhaled air allows external air to pass through the virus killing unit 100 and then passes through the inhalation air hose 112 into the lungs through the inhalation port, mouth, and nose of the respirator, and the exhaled air from the wearer's lungs passes through the respirator ( It passes from the exhalation port of 150) through the discharge air hose 122 and through the virus killing unit 100. Accordingly, it is possible to breathe and exhale safe, killed air in any environment.

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

It is also possible to remove dead viruses by installing the ultrafine filter 17 near the respiratory tract 150 or near the virus killing unit 100.

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

You can attach a virus killing unit and air hose to an existing gas mask, or design the personal mobile virus killing respirator of Figure 5 to be more compact and construct a virus killing gas mask that can be carried on your back or worn on your waist and worn at the same time as a chemical, biological and radiological warning is issued. It is an anti-virus system

Figure 6 shows an example of an indoor application of the anti-virus system according to the present invention to circulate an upward air current that prevents 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 indoor spaces, for example, in restaurants, cafes, classrooms, transportation, offices, auditoriums, conference rooms, etc. It indicates the state of being applied to quarantine equipment that creates an upward current that prevents infection.

The air in the indoor or outdoor atmosphere is passed through the air inlet (12) of the virus killing room and the killing chamber of the virus killing unit (100) to kill viruses, and then re-introduced indoors through the air outlet (14) of the virus killing chamber. If possible, the air that has passed through the virus killing unit (100) is discharged indoors or, if there is no indoor ventilation facility, discharged into the outside atmosphere.

A blower (16) is installed at the air inlet (12) and air outlet (14) of the virus killing chamber to promote air circulation and at the same time create an upward air current. A hood is placed at the upper end of the air inlet (12) of the virus killing chamber. (19) Alternatively, it is guided to flow toward the virus killing unit (100) through the corrugated duct and ceiling duct. Accordingly, the exhaled air and droplets of several people indoors rise upward according to the rising air current and pass through the first virus killing chamber 100 through the hood, corrugated duct, and ceiling duct, thereby eliminating the virus in the air. It is 100% killed. Even if an infected person is indoors, the air containing the virus does not spread to the person next to it, but rises along the rising air current. It is desirable to install a cough droplet screen to maintain the upward airflow when coughing.

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

By irradiating high-density electromagnetic waves or high-density ultraviolet rays toward the air passing through the death chamber, all viruses floating in the air are 100% killed. Virus-killed air is blown upward from the lower duct or hose, and the exhaled air and droplets of several people are sucked up to the hood. Therefore, an upward air current is formed in the vertical direction toward the hood, preventing the virus contained in respiratory droplets from being transmitted horizontally to the person next to it.

In addition, for the virus killing unit 100 in large indoor rooms, it is preferable to select an ultraviolet irradiation type virus killing room with good cost-effectiveness, and in small and medium-sized rooms, it is desirable to use a virus killing room that irradiates electromagnetic waves of a wavelength beneficial to the human body.

Additionally, it is possible to remove dead viruses by installing a filter 17 at the air outlet 14.

Figure 7 shows an embodiment of the anti-virus system 10 according to the present invention installed in a passageway through which the public enters and exits, such as an entrance passageway at an airport or a port or a public building, or a passageway for transporting goods for quarantine of delivered goods.

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

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

The virus killing unit 100 uses an ultraviolet irradiation type virus killing chamber with good cost-effectiveness in the case of passages where many people pass, and electromagnetic wave irradiation of a wavelength beneficial to the human body is used for quarantine equipment in passages through which patients or a special number of people pass. It is also advisable to apply an eclipse chamber.

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

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

Additionally, it is desirable to install a filter 17 at the air outlet 14 to remove dead viruses.

Figure 8 shows another example of an anti-virus system including the virus killing unit 100 according to the present invention, Figure 8a shows an example applied to the air purifier 210, and Figure 8b shows a virus killing unit 100 according to the present invention. An example of an air conditioner 220 equipped with a death unit 100 and a hot air blower is shown.

As for the air purifier 210 and the air conditioner 220 (including the hot air blower), it is preferable to select an ultraviolet irradiation type killing room shown in FIGS. 3A and 3B, which has good cost-effectiveness and does not generate heat in the summer. Viruses killed by ultraviolet rays must be removed and breathed through a filter. A filter that filters out dead viruses can be installed at the entrance or exit of the virus killing room. The filter of a conventional air purifier or air conditioner can be used, or the filter function can be strengthened. You may.

In this way, by placing an anti-virus system equipped with a virus killing unit 100 on the air inlet side of an existing air purifier or air conditioner, the air coming out of the air purifier 210 or the air conditioner 220 (including the hot air blower) is free from viruses. is removed and dead viruses are filtered out, providing safe air.

As a result, the problem of air purifiers or air conditioners spreading the virus when there is a person infected with the virus indoors has been solved.

In addition to the examples described above (FIGS. 5, 6, 7, and 8), the anti-virus system of the present invention can of course be included in other quarantine equipment configured in other forms, and is especially effective against existing chemical, biological and biological attacks. It can be applied to military equipment that prevents unexpected bacterial and virus attacks by applying a virus killing unit to gas masks, which are military equipment. That is, an anti-virus system that constitutes a gas mask that kills viruses and bacteria 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: Suction air hose
120: Second death chamber
122: Air hose for discharge
140: Heating unit and electromagnetic wave converter
141: Ultraviolet ray generator

Claims (12)

It is equipped with an air inlet that guides air from the quarantine target and an air outlet that discharges air, and a virus killing unit that kills viruses by irradiating ultraviolet rays or electromagnetic waves disposed between the air inlet and the air outlet. An anti-virus system that sucks air from a target, kills viruses or bacteria in the virus killing unit, and sends clean air to the outside air or to the quarantine target.
The method of claim 1, wherein the conversion chamber of the virus killing unit consists of a high-density electromagnetic wave converter in a cylinder, which also serves as an electromagnetic wave guide so that high-density electromagnetic waves are irradiated, or a cylindrical reflector surrounding the high-density ultraviolet ray generator. An anti-virus system comprising an ultraviolet ray death chamber in which the reflector is made of a highly reflective material of titanium dioxide (TiO _² ).
The method of claim 1, comprising: a respirator worn over the user's nose and mouth to kill viruses contained in personal breathing air subject to quarantine; an inhalation hose connecting air passing through the virus killing unit to the respirator; and exhaled air. An anti-virus system comprising a personal respirator that kills viruses in personal respiratory droplets, including an exhaust hose connecting the virus killing unit to the virus killing unit.
An anti-virus system using the anti-virus system according to claim 3 and having a live virus collector for collecting live viruses for vaccine research between the respirator and the virus killing unit in the discharge hose.
The anti-virus system according to claim 3, wherein an anti-(fever) virus collecting means for researching and developing a new fever virus vaccine is provided at the suction hose between the respiratory tract and the virus killing unit or at the outlet from the virus killing unit.
The anti-virus system according to claim 5, comprising a non-contact temperature measuring device and a voltage control device for adjusting the death or thermal state of the anti-virus collected by the anti-(thermal) virus collection means.
The anti-virus system according to claim 3, wherein the discharge hose and the suction hose are each provided with a blower, and each blower is activated by a sensor that detects discharge and suction.
The anti-virus system according to claim 3, wherein the virus killing unit has a first killing chamber and a second killing chamber within one unit to allow inhalation and discharge to pass independently.
It includes an anti-virus system according to claim 1 or 2, is provided with a blower and an air inlet for sucking indoor air, kills viruses by passing the sucked air through a virus killing unit, and then kills viruses through the air outlet. An anti-virus system that constitutes indoor respiratory droplet quarantine equipment that causes human respiratory droplets to pass through the killing unit again according to the rising air current and is discharged to the outside air or returned indoors, creating a circulation of the rising air flow of virus-killing air.
It includes an anti-virus system according to paragraph 1 or 2, wherein the anti-virus system is installed in the entrance passage of an airport or port, a passage through which the public enters or exits, or a goods transfer passage for quarantine of delivered goods, and the inside An anti-virus for passage quarantine that is equipped with a blower and an air inlet to suck in air, kills the virus by passing the sucked air through a virus killing unit, and then discharges it to the outside air or returns it to the quarantine space through the air outlet. system.
The anti-virus system according to claim 1, applied to a ventilation system in a negative pressure hospital room or a ventilation system in a livestock house equipped with the virus killing unit.
A gas mask, which is military equipment against chemical, biological, and radiological attacks that is subject to quarantine by the anti-virus system according to paragraph 1, includes a virus killing unit to prevent unexpected bacterial and viral attacks, and constitutes a gas mask that kills viruses and bacteria. anti-virus system.