KR20240015049A - A disinfection system for decomposing and annihilating virus by cavitation, and a method for preparing mucosal vaccine by the system - Google Patents

Abstract

The present invention is provided with an air inlet through which air flows in from the quarantine target and an air outlet through which air is discharged, and a cavitation unit disposed between the air inlet and the air outlet, including a region for decomposing and destroying viruses. , This is a cavity area where viruses are decomposed and destroyed by ultra-high temperature and ultra-high pressure within the area. Air is sucked in from the outside air or the quarantine target, and viruses or bacteria are decomposed and destroyed in the cavity generation and extinction area, and then returned to the outside air or the quarantine target. Provides a cavitation quarantine system that includes a cavitation unit capable of sending clean air, and a method of preparing a customized mucosal vaccine using this system.

Description

A cavitation quarantine system that decomposes and destroys viruses and a method of preparing mucosal vaccines using this system {A disinfection system for decomposing and annihilating virus by cavitation, and a method for preparing mucosal vaccine by the system}

The present invention relates to a cavitation quarantine system that decomposes and destroys viruses. Virus decomposition and annihilation is achieved by ultra-high temperature and ultra-high pressure in the occurrence and extinction area of the cavity. Provides a cavitation quarantine system equipped with a cavitation unit that circulates safe clean air into the atmosphere or the quarantine target, and relates to a method of processing viral antigen samples collected from the air intake into the area of creation and disappearance of the cavity into a mucosal vaccine. will be.

The recently emerged respiratory virus COVID-19 is a new virus different from SARS or MERS, and many people are infected and are unable to carry out normal daily life or economic activities due to fear of infection. In addition, existing vaccines and treatments do not work against new and mutated viruses, so an overall decline in social functions is inevitable until a complete vaccine and treatment is 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, it takes a lot of time and money to develop a virus vaccine, and even if a treatment or vaccine is developed, a new vaccine may need to be developed again if a mutant or mutated virus occurs.

When a respiratory virus occurs, it is common to wear a mask. Although masks are relatively convenient to use, they have the problem of incomplete 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, negative pressure is applied to the room where the patient is hospitalized to prevent exhaled air from the patient from leaking out of the room. However, viruses can float in the air within a hospital room, so people entering the hospital room are inevitably exposed to a dangerous environment. Therefore, it is necessary to discharge safe, clean air that removes all bacteria and viruses floating in the patient's breathing air into indoor air or the external atmosphere.

The fundamental difficulty in preventing respiratory viruses is that mutations and viruses continue to emerge, making it difficult to cover them with existing vaccines, and there are concerns about vaccine side effects. In addition, as the monkeypox virus begins to spread, it is estimated that there will be a large demand for vaccines against the monkeypox virus.

Accordingly, there is a need to develop respiratory virus quarantine equipment that can quarantine various respiratory viruses and all mutant viruses and has no side effects. In addition, as soon as a new virus occurs, it is necessary to immediately develop a mucosal vaccine optimized for each individual by catching the virus floating in the patient's exhaled air. The development of a mucosal vaccine without side effects optimized for the respiratory passage mucosa of respiratory quarantine equipment wearers is especially necessary for patients with underlying diseases, special constitutions, and the elderly.

In this regard, as a prior art, Korean Utility Model Registration No. 20-0251333 provides an air purifier equipped with ozone disinfection equipment, 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 environment. .

In addition, Korean 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 by electrolyzing water containing chlorine is distributed to the upper part of the room. It is a method of sowing from . Since hypochlorous acid is inhaled through breathing, 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 intended to provide a cavitation quarantine system that decomposes and destroys bacteria or viruses through ultra-high temperature and ultra-high pressure phenomena in the cavity generation and extinction area of the cavitation unit. In addition, the system is intended to provide a method of preparing and inoculating a customized mucosal vaccine optimized for the user.

The cavitation quarantine system of the present invention is a cavitation unit that decomposes or annihilates viruses (virus decomposition and annihilation, VDA) by inhaling virus floating air in the atmosphere and quarantine targets (including respiratory organs) through the generation and disappearance area of the cavity of the cavitation unit. It is circulated through.

Heating and shock are phenomena that occur in ultra-fine cavities underwater at ultra-high temperature and ultra-high pressure conditions in the cavity creation and extinction areas of the cavitation unit. Therefore, the impact of ultra-high temperature and ultra-high pressure cannot be detected in the vicinity of the cavitation unit, so it is suitable for application to mobile personal respirators.

The cavitation quarantine system of the present invention includes a cavitation unit having an air inlet and an air outlet, and a cavity generation and disappearance area included in the unit, and viruses are removed from the cavity generation and disappearance area.

The present invention uses a cavitation quarantine system to remove viruses floating in the discharged air and air or indoor air from the quarantine target, return the extinguished, safe clean air to the quarantine target, and provide an air flow that discharges the clean air into the room or the atmosphere. do.

That is, it is provided with an air inlet through which air flows in from the quarantine target and an air outlet through which air is discharged, and a cavitation unit disposed between the air inlet and the air outlet, and by ultra-high temperature and ultra-high pressure phenomenon in the cavity of the cavitation unit. , Viruses are reliably decomposed and destroyed. In other words, it is designed to suck in air from the outside air and the quarantine target, decompose and destroy viruses or bacteria in the cavitation unit, and send clean air to the outside air or the quarantine target.

Additionally, using a cavitation quarantine system, it is also possible to prepare a mucosal vaccine by capturing viruses contained in the air exhaled by an individual while moving. It is also possible to prepare a mucosal vaccine by capturing viruses contained in the air exhaled by the public indoors.

The method of preparing the mucosal vaccine includes collecting weakened and inactivated viruses or live viruses at the air inlet of the cavitation unit; Weakening the captured virus over time; and inoculating the user with the weakened virus. In other words, it is possible to provide a method of preparing a mucosal vaccine using a cavitation quarantine system. A respirator equipped with a cavitation quarantine system that collects antigen samples from the air intake passage of the cavitation unit that decomposes and destroys viruses, and controls various states of the virus in detailed steps in consultation with professional medical professionals to create an optimized mucosal vaccine. It is possible to provide optimized mucosal vaccines to the wearer.

In addition, the method of preparing a mucosal vaccine using the cavitation quarantine system according to the present invention is based on voltage or hertz (Hz) so that the operation of the cavitation unit can be adjusted in response to the user's age, health status, underlying disease, and special constitution. Allows you to adjust.

In addition, the method of preparing a mucosal vaccine using the cavitation quarantine system according to the present invention includes collecting viruses by equipping the cavitation unit with at least one virus collector, or collecting a sample soaked in an adhesive solution in the user's nasal/posterior cavity. It further includes the step of collecting a disease virus sample collected by scraping with a cotton swab, and using the collected virus as a sample to prepare a customized (optimized) mucosal vaccine.

In addition, the method of preparing a mucosal vaccine using the cavitation quarantine system according to the present invention involves collecting disease virus samples every day for 15 days in the step of collecting disease virus samples, and storing them in an antigen sample storage box for 15 days in order of the time elapsed after collection. It is provided so that the antigen sample can be placed in the storage box and then inoculated into the user's mucous membrane in the order of time elapsed after collection.

The cavitation quarantine system of the present invention includes a personal respirator, indoor public quarantine equipment, access passage quarantine equipment installed in the passage of travelers' delivered goods, a virus removal air purifier, quarantine air conditioners (including hot air blowers), and various transportation air conditioning facilities. It can be applied to quarantine facilities in boarding rooms connected to and to quarantine facilities in spaces connected to air conditioning facilities in underground and above-ground facilities. Therefore, it is possible to freely carry out all daily activities by circulating safe, clean air that removes viruses through cavitation units installed indoors in churches, classrooms, restaurants, residences, offices, conference rooms, karaoke rooms, and arcades.

In addition, the present invention provides at least one collector that collects viruses between the quarantine object of the cavitation quarantine system and the air intake port of the cavitation unit. A more optimized mucosal vaccine can be created by controlling the state of the weakened and inactivated virus according to the prescription discussed with a mucosal vaccine expert.

In addition, medical devices for dispensing the above-mentioned mucosal vaccines, where safety is a top priority, must be dispensed under the guidance of a specialist in the skin, respiratory, and digestive systems and a pharmacist. By collecting academic papers and medical record data recognized in the medical field, we provide a manual for operating the medical device so that the medical device can be operated more safely and without side effects.

And, as an embodiment of applying the cavitation quarantine system of the present invention, a personal respirator including an intake air hose, an exhaust air hose, and a cavitation unit is provided. In addition, an airborne cavitation quarantine system can be constructed that includes an air hose or duct for suction and an air hose or duct for discharge, and includes a cavitation unit that destroys viruses. The exhaust air hose and the suction air hose may each be equipped with a blower.

Each of the blowers can start operation by a sensor that detects the discharge of exhaled breath and the intake of inhaled breath, and the operation of the sensor and blower uses batteries when portable, and alternating current when used fixedly in the facility. Power can be used.

In addition, passageway quarantine equipment equipped with a cavitation unit can be configured to quarantine people entering and leaving and delivered goods. The cavitation unit and virus collector can be applied to existing air conditioning equipment installed in passenger boarding spaces, various underground facility spaces, and ground facility spaces of various transportation facilities equipped with the cavitation unit.

In addition, by applying the cavitation quarantine system according to the present invention, various bacteria and viruses are heated, decomposed, and destroyed, and at the same time, by allowing the air to pass through the water, all yellow dust and fine dust are removed and destroyed, creating pollution-free oxygen like the air in the forest. Provide sufficient clean air.

In addition, as a military equipment (gas mask) to prepare for the bacterial warfare of biological weapons, it provides the basic system that constitutes a respiratory system that removes and destroys viruses.

The present invention more reliably removes viruses floating in a small amount of breathing air with good cost-effectiveness. According to the present invention, safe clean air is discharged in which all bacterial viruses floating in the small amount of inhaled air that people breathe are removed, regardless of the appearance of a new virus or the mutation of the virus. In addition, viruses are decomposed and destroyed in the ultra-high temperature and ultra-high pressure phenomenon that occurs in the cavity generation and extinction area of the cavitation unit.

The cavitation unit of the cavitation quarantine system can quickly eliminate viruses floating in a small amount of air discharged from the exhalation port of a personal respirator. When necessary, the captured virus can be used as a mucosal vaccine, allowing immediate development of a respiratory mucosal vaccine optimized for the patient.

Therefore, it can contribute to the research and development of optimized mucosal vaccines for each individual, prevent serious side effects that occur with mass-produced vaccinations, and make it easier to deal with viruses that mutate and mutate.

The new mucosal vaccine preparation medical device is equipped with a collector or bottle that can safely and easily handle live viruses and weakened inactive viruses. Using this, it can be used as a medical device to prepare a mucosal vaccine by performing a mucosal vaccine preparation process that optimizes the elapsed time and degree of attenuation and inactivation of the captured live virus for each individual.

The medical device is equipped with a sample storage box that clearly displays the time elapsed after collection of the collected antigen sample by date. Using this, respiratory mucosal vaccines can be prepared safely and simply. For example, 15 vaccinations (oral administration) enable immune memory and immediately generate antitoxin when a respiratory disease virus invades.

Therefore, the virus from the patient's own body is prepared into a mucosal vaccine optimized for the patient's body and can be inoculated into the respiratory passage mucosa without side effects. As a vaccine against mutant viruses, it is preferable to replace the mRNA vaccine with the mucosal vaccine instead of inoculating the mRNA vaccine as a booster vaccine to prevent side effects of mass-produced vaccines.

Additionally, it is possible to wear a personal respirator and move around, allowing those infected with the virus or in quarantine to move freely. In addition, public respiratory quarantine equipment will be installed in churches, classrooms, restaurants, and various indoor gathering places to restore normality to daily activities. By equipping transportation facilities with quarantine ventilation devices for boarding spaces and underground air conditioning facilities, business facilities such as public transportation and underground shopping malls become more active, and installing quarantine ventilation devices for air conditioning facilities in buildings makes daily life and work life possible. Also, when applied to a humidifier, viruses can be removed at the same time as humidification, and dust such as yellow dust can also be removed.

Additionally, in preparation for the viral germ warfare of biological weapons, a virus-removing respirator or a virus-removing respirator can be applied to a gas mask.

In addition, by installing livestock quarantine equipment applying the cavitation quarantine system of the present invention to the ventilation system of livestock barns, etc., it is possible to immediately block outbreaks of avian influenza, swine fever, etc.

In addition, a cavitation quarantine system is provided that can be applied to a ventilation system in a negative pressure room equipped with the above virus removal and extinction unit.

Figure 1 is a basic conceptual diagram of a cavitation quarantine system that decomposes and destroys viruses (Virus Decomposition Annihilation) according to the present invention.
Figure 2 is a conceptual diagram of a cavitation unit according to the present invention.
Figures 3a and 3b show a configuration diagram of the cavity generation and disappearance areas of the cavitation unit and the antigen sample collector of the cavitation quarantine system of the present invention (Figure 3a), and an example of a portable manufacturing system using the same (Figure 3b).
Figure 4 shows an example of applying the cavitation quarantine system of the present invention to indoor public breathing, removing viruses by creating an upward airflow that prevents virus transmission by public breathing air and droplets, and circulating safe clean air. indicates.
Figure 5 shows an embodiment of the cavitation quarantine system of the present invention installed in an airport, a port, a passage for the public to enter or exit, or a goods transfer passage for quarantine of delivered goods.
Figures 6a and 6b and Figures 6c and 6d are various embodiments of the cavitation quarantine system of the present invention, where Figure 6a is applied to a humidifier or air purifier, Figure 6b is applied to an air conditioner (heater), and Figure 6c is a traffic It is applied to quarantine ventilation equipment installed in the passenger boarding space of an institution, and Figure 6d shows an example of application to the air conditioning equipment of a building.
Figure 7 is a flowchart showing a method of preparing a mucosal vaccine by installing a live virus collector at the air inlet of the cavitation unit of the present invention. The active antigen (live virus cells) collected in the collector is collected and segmented, and divided according to the elapsed time. This is a flow chart for using it as a mucosal vaccine by weakening it and making it inactive.
Figure 8 is an example of a storage box for storing antigen samples (virus adhesion aqueous solution) for each time period after virus collection.

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

Figure 1 is a basic conceptual diagram of a cavitation quarantine system that decomposes and destroys viruses (Virus Decomposition Annihilation) according to the present invention.

The system according to the present invention decomposes and destroys viruses floating in the air discharged from the quarantine object 101 and sends them back to the quarantine object or discharges them to the outside. In other words, it creates an air flow that circulates safe, clean air.

The cavitation quarantine system 10 of the present invention is provided with an air inlet 12, an air outlet 14, and a cavitation unit 100, and directs virus floating air entering through the air inlet 12 into a cavity generation and extinction area. is sent to the cavitation unit 100, which destroys viruses floating in the air and sends safe clean air to the quarantine target 101 or to the outside.

And the air entering the cavitation unit 100 having the cavity area 109, that is, the cavity generation and disappearance areas 109a and 109b, passes through at least one antigen sample collector 107 provided at the entrance as needed, and generates The virus and a portion of the inactivated virus are collected in the antigen sample collector 107. Then, the air enters the cavity generation and extinction areas 109a and 109b of the cavitation unit 100, and the viruses in the air are surely destroyed, and clean air is sent to the quarantine target 101 or to the outside.

In addition, in the mucosal cylindrical collector similar to the nostril, some live viruses and some inactivated viruses are collected, used as antigen samples for preparing mucosal vaccines, and an optimized customized vaccine can be prepared and self-inoculated (orally administered).

A blower (16) is provided at the air inlet (12) or air outlet (14) of the cavitation unit (100), which is a virus removal unit, to help circulate air between the cavitation unit (100) and the quarantine target (101) and, if necessary, External air or air to be treated (20) can be introduced, or clean air in which viruses have been destroyed can be sent to the outside.

Figure 2 is a conceptual diagram of a cavitation unit according to the present invention.

This is a conceptual diagram of the cavitation unit according to the present invention. First, the air to be treated (20) or external air coming from a quarantine object (101) such as a respirator passes through at least one virus collector (107) selectively provided in the cavitation unit (100). I order it. Air is introduced into the tank, passes through cavity generation and disappearance areas (109a, 109b), and safe, clean air from which viruses have been removed is discharged into the atmosphere (outside air) or respiratory tract. In other words, it shows a circulation line that inhales air containing viruses (20) and expels safe clean air in which the viruses are decomposed or destroyed.

The virus collector 107 provided in the cavitation unit 100 can collect inactive viruses contained in the user's exhaled air and use them as data to diagnose the user's disease state. In addition, the virus contained in exhaled air or the atmosphere can be collected by the virus collector 107, stored to be weakened and inactivated over time, and then used as an antigen sample for use as a mucosal vaccine.

The cavitation unit 100 consists of a water tank filled with water, and the cavity area 109 formed in the water tank to decompose and destroy viruses is composed of a cavity generation area 109a and a cavity extinction area 109b.

When external air (exhaled air, air) containing a virus is introduced into the water tank of the cavitation unit 100, cavities ( Cavity) creates an instantaneous ultra-high temperature and pressure, causing viruses and bacteria to decompose and disappear.

The basic concept of reliably destroying viruses in an eco-friendly manner that is harmless to the human body and the surrounding environment is realized by the cavitation unit 100. In the water tank of the cavitation unit 100, a cavity generation area (109a) and an extinction area (109b) are formed by ultrasonic vibration, and as a result, an instantaneous ultra-high temperature phenomenon occurs, and a large pressure occurs in the cavity extinction area (109b), which destroys the cavity. Change causes shock. The instantaneous temperature in the cavity generation area 109a reaches a maximum of 5000 degrees Celsius, and the instantaneous impact in the cavitation hole extinction area 109b reaches a maximum of 2000 atmospheres. The air containing the virus is allowed to enter the cavity generation area (109a) and the extinction area (109b), is exposed to ultra-high temperatures, and is subjected to a large impact in the cavitation extinction area (109b) to kill the virus.

Viruses floating in the air are heated, decomposed, destroyed, and destroyed by the above-mentioned ultra-high temperatures and pressures beyond imagination. However, as it is a phenomenon that occurs instantaneously in water, the temperature, impact, or noise that can be felt from the outside due to the effect on the water tank forming the cavity area 109 are minimal. Therefore, it is suitable for application to personal portable respirators, and is also good for application to various quarantine equipment facilities for fixed indoor installation.

All various viruses are heated, decomposed, destroyed and destroyed, and the purified air is continuously sent to the respiratory tract of the quarantine target (101) through the air outlet (14), and the remainder is discharged into the atmosphere.

Figures 3a and 3b show a configuration diagram of the cavity generation and disappearance areas of the cavitation unit and the antigen sample collector of the cavitation quarantine system of the present invention (Figure 3a), and an example of a portable manufacturing system using the same (Figure 3b).

As shown in Figure 3a, the cavity area 109 of the cavitation unit 100 of the cavitation quarantine system that decomposes and destroys viruses is made in the shape of a water tank, and the cavity is generated by at least one oscillator module 110. It has a generation area (109a) and a cavity disappearance area (109b) where the cavity disappears. An ultrafine cavity is generated by the vibrator module 110. Ultra-fine cavities, which occur countless times, float to the top of the water tank due to the buoyancy of water. Between the cavity generation area 109a and the cavity disappearance area 109b, bubbles of virus-containing external air coming from the air inlet 108 mix, contact, and collide with the ultrafine cavity. In the cavity generation/disappearance areas (109a, 109b), the virus contained in the external air bubbles is subjected to ultra-high temperature and ultra-high pressure, and is thermally decomposed, destroyed, and destroyed, and safe clean air is discharged to the quarantine target or the atmosphere. As the air passes through a water tank and is discharged, foreign substances such as dust or yellow dust in the air are captured in the water due to the viscosity of the water, and clean air is discharged to the outside. In FIG. 3A , for convenience, it is shown that external air and exhaled air are processed together in one cavitation unit 100, but it is also possible to process them separately in a separate cavitation unit 100. In this case, exhaled air or indoor air is disinfected and then discharged to the outside air. Of course, processing in one cavitation unit 100 separated by a partition is also included in the scope of the present invention.

An air pump 120 is connected to the air inlet 108, and at least one collector 107 to collect viruses may be provided as needed. The virus collector 107 installed at the air inlet collects some viruses in the air, such as the nostril mucosa, in front or behind the air pump 120, and most of the virus-containing air flows into the cavity generation and extinction area. The virus is decomposed and destroyed by the action of the cavity.

This virus catcher can be applied to personal quarantine systems as well as public quarantine systems. In other words, quarantine facilities for the public are also equipped with collectors to collect antigen samples, helping to accurately identify local transmission of various bacterial viruses of respiratory diseases. In this way, it is possible to easily prevent and respond to the spread of viruses, and to establish countermeasures by checking information on the occurrence and contagion of various mutations and mutant viruses in a timely manner.

It is preferable that a gas-liquid separation membrane 109c, such as a filter, be provided at the top of the cavity area 109 to prevent liquid from being discharged.

Through the cavity area 109, the air from which the virus has been removed can be discharged into the atmosphere or sent to a respirator or quarantine target, and can also be configured to pass through the outlet pocket 113.

By applying the cavity generation and extinction areas 109a and 109b of the cavitation unit 100 to a mobile respirator, it is recommended to provide a valve to prevent liquid from coming out of the air outlet or air inlet to prevent leakage of water in the tank when moving. desirable. It is advisable to provide a check valve to prevent backflow at the inlet connection of the pump 120. It is desirable to collect the leaked solution at the bottom of the outlet pocket (113), connect it to the pump (120), and suck it up to the cavity generation and disappearance areas (109a, 109b) in the water tank.

Figure 3b shows an example in which the cavity generation and disappearance areas of the cavitation unit and the antigen sample collector configuration diagram (Figure 3a) are manufactured in a portable manner.

The cavity generation and extinction areas (109a, 109b) of the cavitation unit and the antigen sample collector (107) are portable and can be worn on the waist or back as a backpack and used while moving.

The virus floating air (20) that is continuously inhaled during movement passes through the cavity area (109), and the clean air that thoroughly heats, decomposes, destroys, and destroys the virus by receiving the ultra-high temperature and ultra-high pressure of the cavity area (109) is stored in the outlet pocket. It is collected in (113) and sent to the mobile respirator (125) worn by the user through the inhalation air hose (112). Exhaled air is collected in the inlet pocket 113a through the exhaled air hose 122, and as the check valve opens and closes (on/off), the virus is removed by receiving ultra-high temperature and ultra-high pressure in the cavity area 109. Afterwards, it changes into clean air and is discharged into the atmosphere or collected in the outlet pocket (113).

A blower is connected to each of the air hoses 112 and 122, and the operation of each blower can be controlled by a sensor that detects exhalation and inhalation.

By applying the cavity generation and extinction areas (109a, 109b) of the cavitation unit (100) to the mobile respirator (125), they are applied to the air outlet or air inlet to prevent water leakage from the water tank of the cavitation unit (100) when moving. It is desirable to provide a valve to prevent liquid from coming out. In addition, it is advisable to provide a check valve to prevent backflow at the inlet connection of the pump 120. It is best to collect the leaked solution at the bottom of the outlet pocket (113), connect it to the pump inlet, and suck it up to the cavity creation/dissipation area. A collector 107 that collects viruses may be provided before and after the pump 120. The installation positions of the pump 120 and the collector 107 are not limited to those shown in the drawing, and may be installed at the top if necessary.

A handling handle 121 or other connector can be installed on the top of the cavitation unit 100. For example, other connections or auxiliary equipment, such as a connector for replenishing water in the water tank of the cavitation unit 100 and an external air inlet, may be installed on the handling handle 121.

Also, preferably, an inlet pocket (113a) is provided on the air inlet side of the cavity generation/disappearance area and is used as a buffer for the sucked air.

Preferably, it is desirable to install blowers at the air outlet 14 and the air inlet 12. In particular, the blower at the air outlet 14 allows air greater than the user's breathing volume to be sent to the respirator worn by the user. Therefore, it is also desirable to sufficiently inhale fresh air containing oxygen through the atmospheric inlet and discharge it from the respiratory tract into the atmosphere. You won't feel stuffy even if you cover your nose and mouth with a respirator, and you can breathe warm air when you wear it in cold weather.

The electricity of the cavitation generation and extinction area 100 and the collection device that collects live viruses and weakened inactivated viruses can be used as alternating current power for fixed types or direct current power for mobile types.

In the virus collector 107, inactive viruses in exhaled air are collected and used as antigens to treat the user's underlying respiratory disease, or the live viruses collected in the virus collector 107 are stored to be weakened and inactivated over time. Afterwards, it can be used as an antigen sample for use as a mucosal vaccine.

In other words, the present invention can be used as a medical device that automatically prepares respiratory passage mucosal vaccines, and can be used as a medical device that collects viruses at the entrances of the virus removal and extinction areas (109a, 109b) and recycles them into mucosal vaccines.

Figure 4 shows that in the cavitation quarantine system 10 of the present invention, the cavity generation and extinction area of the cavitation unit 100 is applied indoors to create an upward airflow that prevents virus transmission by respiratory air and droplets of the public, thereby spreading the virus. This is an example of a state in which safe, clean air is circulated after decomposition and destruction.

In other words, the cavitation quarantine system 10 according to the present invention is manufactured for indoor spaces and installed in restaurants, hospitals, cafes, classrooms, offices, lecture halls, conference rooms, etc., to create a safe upward airflow of clean air. Examples are shown. This prevents the virus from being transmitted to the next person through respiratory droplets from multiple people.

In the cavitation quarantine system 10, the air 20 to be treated indoors, outdoors or in the atmosphere is passed through the cavitation unit 100 having cavity generation and extinction areas 109a and 109b, and safe clean air from which viruses are removed is delivered to the air outlet ( 14), it is sent to the indoor space of the quarantine target or discharged into the outdoor air. Indoors, it is desirable to create an upward airflow through the lower air outlet.

A blower (16) is installed at the air inlet (12) and air outlet (14) of the virus removal unit (100) to promote air circulation and at the same time create an upward air current, thereby creating a hood (19) connected to the air inlet (12). ) is guided to flow toward the cavitation unit 100. Accordingly, the exhaled air and droplets of several people indoors rise upward according to the rising airflow, and as they pass through the cavity generation and extinction areas 109a and 109b described above of the cavitation unit 100, viruses in the air are decomposed and destroyed. Safe, clean air is provided. The role of the rising airflow is to ensure that the air containing the virus does not spread to the next person, but moves upward along the rising airflow and is sucked into the cavity generation and disappearance areas (109a, 109b) to remove the virus. The cavitation unit 100 includes the cavity area 109 described above.

Figure 5 shows an embodiment of the cavitation quarantine system of the present invention installed in an airport, a port, a passage for the public to enter or exit, or a goods transfer passage for quarantine of delivered goods.

The passage quarantine entrance room (200) has closed front and rear doors, and is equipped with a blower (16) that sucks indoor air and blows it to the virus removal unit (100). The blower is a blower similar to an air curtain fan and is installed in one or more sets lengthwise on the ceiling. The air flow passes through the virus removal unit 100 and is blown out through both walls of the passage. The air sour causes viruses attached to passengers and cargo to float in the air, creating a cavity in the cavitation unit (100). Air to be treated (20) is blown into the extinction area to decompose and destroy the virus.

As a result, it is possible to block the spread of viruses through goods or travelers, making free travel possible.

Figures 6a and 6b and Figures 6c and 6d are examples of the cavitation quarantine system of the present invention applied to various quarantine targets. Figure 6a is applied to a humidifier or air purifier, and Figure 6b is applied to an air conditioner (heater). Figure 6c is applied to quarantine ventilation equipment installed in the passenger boarding space of transportation, and Figure 6d is applied to quarantine ventilation equipment of air conditioning equipment installed in above-ground or underground spaces, showing examples of the above-described application states.

Figure 6a shows a humidifier or air purifier 210 to which the virus removal unit 100 is applied, Figure 6b shows an air conditioner 220 to which the virus removal unit 100 is applied, and Figure 6c shows the quarantine target 101. This indicates the state in which the cavity generation and disappearance area of the cavitation unit 100 is applied to quarantine the traffic cabin of a transportation facility, and is applied to the damper or diffuser installed in the ceiling air passage of the cabin subject to quarantine connected to the blower of the air conditioner. By blowing into the cabin, a downward airflow of clean air that destroys viruses is created from the ceiling to the floor of the cabin, allowing passengers to block breathing droplets and breathe clean air. Figure 6d shows that it is used in air conditioning equipment in above-ground or underground spaces. This system provides clean air to the quarantine target (101) through the cavity generation/disappearance area of the installed cavitation unit (100), and is applied to air conditioning equipment or system cooling/heating systems in underground or above-ground facilities.

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

Figure 7 is a flowchart showing a method of preparing a mucosal vaccine by installing a live virus collector at the air inlet entering the cavity generation and disappearance area of the cavitation unit of the present invention, and active antigen (live virus cells) collected in the antigen sample collection device. This is a flowchart of collecting, subdividing, weakening and inactivating over time and using it as a mucosal vaccine.

The method of preparing a mucosal vaccine according to the present invention includes an air inlet through which air flows in from a quarantine target and an air outlet through which air is discharged, and the cavity of the cavitation unit disposed between the air inlet and the air outlet is generated and destroyed. It is provided with an area, and the cavity is generated. The cavity is generated by sucking external air and air from the quarantine target into the extinction area. By the ultra-high temperature/ultra-high pressure of the extinction area, viruses or bacteria in the intake air are decomposed and destroyed to prevent external air or quarantine. Using a cavitation quarantine system according to the present invention, which includes a cavity generation and extinction area that is capable of sending clean air to the target, the exhaled air contained in the collector is provided between the air outlet of the removal unit and the respirator. Collecting a weakened and inactivated virus or a user's virus; and placing the captured virus in a collection bottle to weaken or inactivate it over time; and inoculating the user with the weakened virus. Additionally, the virus capturing step can also be applied to quarantine equipment for the public. Quarantine facilities for the public are equipped with collectors that collect antigen samples, helping to accurately identify local transmission of various bacterial viruses of respiratory diseases. In this way, it is possible to easily prevent and respond to the spread of viruses, and to establish countermeasures by checking information on the occurrence and contagion of various mutations and mutant viruses in a timely manner.

Figure 8 is an example of a storage box 350 for storing antigen samples (virus adhesion aqueous solution) for each time period after collection.

In addition, the method of preparing a mucosal vaccine in the cavitation quarantine system according to the present invention involves collecting disease virus samples every day for 15 days in the step of collecting disease virus samples, and using an antigen sample storage box (350) that can be stored for 15 days in order of the time elapsed after collection. ), the antigen sample collection bottle 354 is placed in the storage groove 352 of the storage box 350, and the antigen sample can be inoculated into the user's mucous membrane in the order of the elapsed time after collection. For convenience of order management, it is convenient to attach an identification number 356 to the storage groove 352 of the storage box 350.

In the cavitation quarantine system, the antigens (bacteria, virus cells) attached to the collector are gradually weakened and inactivated over time after collection, and die after living for about 15 days.

Taking advantage of this fact, the degree of the weakened inactivation state is preferably divided into 15 stages, and the virus antigen (bacterial virus cell) at the higher stage of the weakened inactivation state is inoculated first, and the antigen (bacterial virus cell) at the lower level is gradually inoculated. You can select up to 15 vaccinations, and antibodies (immune cells) receive invasion signals from antigens (bacteria and virus cells) to produce antibodies and antitoxins.

Towards the final goal of allowing the live virus, which is the antigen, to be remembered for a lifetime in immune memory cells (memory: Tcell, Bcell), the user's age, constitution, underlying condition, and degree of weakened inactivity are controlled, vaccination time, and vaccination stage. It is advisable to select carefully with control. For this purpose, it is recommended to have voltage regulation and hertz regulation devices in the system.

For confirmed patients, the virus is collected every day during the treatment period of approximately 15 days and placed in a collection bottle used to prepare mucosal vaccines.

For 15 days, the aqueous solution containing the virus collected in 15 pipettes is sprayed into the nasal/rear cavity, one per day from the pipette of the first day to the pipette of the 15th day, and inoculated by oral administration. After a few days, check to see if antibodies have developed. If not, wear a portable personal bag respirator, collect viruses every day from a collector attached to the personal respirator, and inoculate until antibodies develop. As time passes after collection, the virus becomes increasingly weakened or inactivated and becomes insufficient to invade the antibody cells of the respiratory mucosa.

Therefore, in order to reliably eliminate the side effects of mucosal vaccination, the level is gradually lowered from the impossibility of invasion to the level of possible invasion, and the vaccination (oral administration) multiple times safely up to 15 times allows for immune memory, so that when the respiratory disease virus invades, antibodies are immediately released, Produce antitoxin.

As described above, the virus captured from the user's breath can be administered orally by applying it directly to the user's throat and larynx by preparing it as a mucosal vaccine optimized for the user's body under the guidance of the doctor in charge. In order to standardize the method of preparing the self-prepared mucosal vaccine, it is necessary to form a “health care consultative body” of medical personnel working in the field of respiratory virus mucosal vaccines and doctors who directly treat critically ill patients infected with respiratory diseases and prepare a work manual. This is desirable to prevent the side effects of existing mass-produced vaccinations.

Claims (16)

It is provided with an air inlet 12 through which air flows in from the quarantine target and an air outlet 14 through which air is discharged, and a cavitation unit 100 disposed between the air inlet and the air outlet to decompose and destroy the virus. And, the ultrasonic vibrator module 110 is provided in the cavity generation and extinction areas (109a and 109b) of the cavitation unit, and the cavity is instantaneously generated by the ultrasonic vibrator module (110) within the cavity generation and extinction areas (109a and 109b). By forming a cavity that decomposes and destroys the virus using ultra-high temperature and pressure, the cavity of the cavitation unit is created by sucking in air from the outside or the quarantine target. It decomposes and destroys the virus or bacteria in the destruction areas (109a, 109b). A cavitation quarantine system including a cavitation unit 100 that is capable of sending clean air to the outside air or to a quarantine target.
The method of claim 1, wherein a cavity is generated by an ultrasonic transducer module 110 in the cavity generation/disappearance area (109a, 109b) of the cavitation unit, and the cavity generation area and extinction area are formed on an upper part of the ultrasonic transducer module (110). A cavitation quarantine system that forms regions (109a, 109b) and has air inlets in the cavity generation region and extinction region (109a, 109b) to decompose and destroy bacteria or viruses in the air.
According to claim 1, at least one collector for collecting viruses is installed at the air inlet of the cavity area included in the cavitation unit (100) that sucks air containing viruses, so that live viruses in exhaled air or the atmosphere can be collected. Cavitation quarantine system.
The method of any one of claims 1 to 3, wherein in the virus collector installed at the air inlet entering the cavity generation and extinction area of the cavitation unit, some viruses in the air are collected, and the remaining virus-containing air is stored in the cavity. A cavitation quarantine system is designed to heat, decompose, and destroy viruses and bacteria contained in the air that flow into the area of occurrence and extinction, and clean air coming out of the area of cavity generation and extinction is used as breathing air or discharged to the outside.
The method of claim 1, wherein the cavitation unit is equipped with a portable respirator that can be worn by an individual, and the clean air that is heated, decomposed, and destroyed in the cavity generation and extinction area of the cavitation unit is stored in an outlet pocket. is introduced into the respiratory tract through the air hose, and the exhaled air of the respirator is stored in the inlet pocket through the exhaled air hose and flows into the air inlet into the cavity generation and extinction area of the cavitation unit, where it heats and decomposes and destroys the virus. A cavitation prevention system that allows treatment.
The method of claim 1 or 5, wherein a blower is selectively installed at the air inlet and air outlet or the inhalation hose and the exhalation hose of the cavity generation and extinction area of the cavitation unit, and the blower is a sensor that detects inhalation and exhalation. A cavitation prevention system comprising a cavitation unit whose operation is initiated by.
The method of claim 1, further comprising a blower and an air inlet for sucking indoor air, and allowing the sucked air to pass through the cavity creation and extinction areas of the cavitation unit to heat, decompose, and destroy the virus, and then through the air outlet at the bottom of the room. By creating an upward air current, several people's respiratory droplets rise upward according to the rising air flow, allowing them to pass through the cavity generation and disappearance area, being discharged to the outside air or returned indoors, and the virus is decomposed. A cavitation quarantine system including a cavitation unit, including cavity generation and extinction areas, which constitutes indoor quarantine equipment by creating circulation of upward airflow of extinguished air.
The cavitation quarantine system, which includes the cavity generation and disappearance areas of the cavitation unit according to paragraph 1, is installed in the entrance passage of airports and ports, the passage through which the public enters and exits, or the goods transfer passage for quarantine of delivered goods, and removes the inside air. It is equipped with a suction blower and an air inlet, and allows the sucked air to pass through the cavity generation and extinction area to heat, decompose, and destroy the virus, and then discharge it to the outside air through the air outlet or return it to the quarantine space. Cavitation prevention system for passageways, including cavity generation and destruction areas.
A cavitation quarantine system for air purification that includes a cavity generation and extinction area that heats, decomposes, and destroys bacteria and viruses of various respiratory diseases by applying the cavitation quarantine system according to paragraph 1 to an air purifier or air conditioner.
The cavitation quarantine system according to paragraph 1 is installed at the air inlet of the air conditioner of a transportation facility, and blows clean air into the room from a damper or diffuser installed in the ceiling air passage of the room subject to quarantine connected to the blower of the air conditioner, thereby eliminating viruses. A cavitation quarantine system for transportation facilities that creates a downward airflow from the ceiling to the cabin floor, blocking respiratory droplets among passengers and allowing them to breathe clean air.
The cavitation quarantine system according to paragraph 1 is applied to air conditioning equipment or system cooling/heating equipment in underground or above-ground facilities, including the cavity generation and extinction area to supply clean air that heats, decomposes, and destroys various bacterial viruses. Cavitation quarantine system for air conditioning.
By applying the cavitation quarantine system according to paragraph 1, various bacterial viruses are heated, decomposed, and destroyed, and at the same time, by allowing air to pass through water, yellow dust and fine dust are captured and removed by the viscosity of water, thereby heating the virus. A cavitation prevention system for humidified or clean air that includes a cavity generation and extinction area that decomposes and disappears.
A cavitation quarantine system for a ventilation device that includes a cavity generation and extinction area that heats, decomposes, and destroys viruses by applying the cavitation quarantine equipment according to paragraph 1 to a ventilator in a negative pressure hospital room or a ventilation device in a livestock house.
Equipped with a cavitation quarantine system according to paragraph 6, the respirator worn by the user is composed of a gas mask, and the cavitation quarantine system for a gas mask includes cavity generation and disappearance areas (109a, 109b) of the cavitation unit in the gas mask and a virus collector. .
Preparing a cavitation quarantine system including the cavitation unit 100 according to claim 1, and collecting live viruses or weakened and inactivated viruses at the air outlet or air inlet of the cavitation unit; A step of weakening the collected virus over time by placing it in a collection bottle so that it is inactivated; allowing the virus collected using a virus collector attached to a cavitation unit to obtain an antigen sample of a mucosal vaccine, How to utilize the cavitation quarantine system.
The method of claim 15, wherein the step of weakening the disease virus sample includes collecting the disease virus sample every day for 15 days, providing an antigen sample storage box that can be stored for 15 days in the order of time elapsed after collection, and storing the sample in the storage box in order of time elapsed after collection. A method of utilizing a cavitation quarantine system for preparing a mucosal vaccine using a collector of a cavitation unit, including the step of storing an antigen sample.