KR20220136522A - Air sterilization and indoor air ionizing micro-matter sterilization cleaner - Google Patents

Abstract

The present invention relates to a cleaner for air sterilization and indoor air ionizing micro-matter sterilization, which blocks spread of viruses. In one main body (30), the present invention comprises a mesh net (1), an air cleaning unit (2), a first carbon temperature compensation heater (3), a first honeycomb (4), an air mixer (4a), a UV-C (5), a second honeycomb (6), a first temperature detection sensor (7), a blocking film (8), an atomization spray (9), a second carbon temperature compensation heater (10), a third honeycomb (11), a UV-A (12), an air mixer (4b), a fourth honeycomb (13), a second temperature detection sensor (14), a quartz heater (15), an air suction fan (16), a water tank (17), a drain (18), a water pump (19), a suction temperature sensor (20), and a use water activation device (22).

Description

Air sterilization and indoor air ionizing micro-matter sterilization cleaner

The present invention relates to a vacuum cleaner that sterilizes bacteria floating in the air and sterilizes fine dust and ionized fine substances (charged particles or charged particles) including viruses in indoor air. Sterilize with TiO ₂ coated on a number of honeycombs, humidify with carbon heater and quartz heater to prevent activation of viruses floating in the air, compensate for heat of evaporation It is designed to control temperature and humidity.

In general, water is a polar substance, and in the case of tap water, as it passes through the pipe from the water source to the place of use, the cluster grows due to ionic bonding by water pressure and dissolved ions. Water whose clusters have grown by bonding water molecules breaks down the clusters through cavitation and rotation through the mechanism and finds the original properties of water to make water into a single molecule to make activated water and reduce the molecular population.

By allowing the contaminated air to pass through the atomized space by making the activated water into a single molecule, the substances forming clusters in the air, namely ionized organic compounds, CO ₂ , radon gas, nitrogen oxides, and fine dust (PM2.5~10) ) is combined with monomolecular water and aggregated to collect it, and it also collects microorganisms such as bacteria and viruses contained in the air to create clean air.

Water is atomized inside the sterilizer through a water activation device, contaminants contained in the air fed into the sterilizer are collected in atomized water droplets to remove agglomeration in the sterilizer, and organic suspended matter comes into contact with the titanium dioxide coated on the honeycomb. In order to increase the diffusion rate after contamination is removed by stirring the input air to induce extinction as much as possible, and to increase the diffusion rate, it is compensated to an appropriate temperature through a quartz tube heater, followed by fresh clean air. This helps to reduce the density of indoor air pollution by helping exhaust.

This product controls the humidity in the device to gradually remove pollen, chemicals, and organic compounds mixed in the indoor air by replacing it with water. It is possible to remove the suspended cations in the exhaust air by the carbon fiber mesh.

On the other hand, it should be noted that there may be the following problems in the contents of the technologies of commercially available universal air sterilizer products.

When UV-C and A wavelengths are used, OH- radicals and ozone generation sterilize and oxidize organisms, but the OH- radicals are immediately extinguished, but when used for a long time in a closed room, ozone emitted to the outside of the device is When it accumulates in the respiratory tract and enters the human respiratory tract, it can cause adverse effects, cause problems in the DNA transcription process of living things, cause skin cancer, and cause other problems.

And, in the case of using monazite, air and water are made monomolecular, but monazite has been used in air purifiers and sterilizers by emitting a large amount of negative ions in the past, but since 2005, monazite has been notified as a nuclide and cannot be used artificially. The November 22, 2018 news also previously banned the use of monazite for personal items, but there is a news that the bed industry has been hit by frost because it is used in beds and pillows, which are blind spots. Needs to be.

In addition, although negative ions are emitted from products that emit negative ions cheaply through high-pressure discharge, it will be necessary to prove that excessive electromagnetic waves due to high-pressure discharge are generated in the driving process of negative ion emission and cannot be used in the immediate vicinity of living things.

In the case of using plasma, negative ions and high heat are produced to lower the potential of the organism in the cycle, but there is a problem in that electromagnetic waves are generated there when high-pressure discharge is applied to the waveguide in the process of generating plasma.

In addition, in the case of using PAA (Perasetic Acid), it is an organic acid widely applied to eradication of bacteria, and although it is an approved material for eradicating bacteria, it cannot eliminate the problem of the humidifier wave in the reaction in the respiratory tract.

Patent Application No. 10-2005-0059191 Patent Application No. 10-2009-0045496 Patent Application No. 10-2016-0065535

The present invention is to solve the conventional drawbacks as described above, and an object of the present invention is to effectively eliminate carbon dioxide, carbon monoxide, mold, fine dust, volatile organic compounds and odors, as well as the disappearance of viruses contained in the air. An object of the present invention is to provide a vacuum cleaner that sterilizes air and ionizes fine substances in indoor air that can be removed.

An object of the present invention is to provide an air sterilization and indoor air ionization fine substance sterilization cleaner that detects the temperature in the body and compensates the temperature uniformly through a carbon heater and a quartz heater, thereby blocking the inhabitation of viruses in the room. .

The present invention for achieving the above object, in one body, an air washing unit for washing the air sucked through a mesh, a first carbon temperature compensation heater for compensating for the temperature, and bacteria in the air TiO ₂ A first honeycomb sterilized by a UV-C installed on the top of the first honeycomb to sterilize bacteria by generating ultraviolet rays, and a UV-C installed on the top of the UV-C to sterilize bacteria in the air by TiO ₂ a second honeycomb for sterilization; a first temperature sensor installed on the upper end of the second honeycomb to detect temperature; Atomization spray installed on one side of the temperature sensor to receive water from a water tank and perform a humidification function through a nozzle, and a second carbon temperature compensation to compensate for the temperature with a radiant heat type heating element using carbon with a purity of 99.9% or more A heater, a third honeycomb installed under the atomizing spray to sterilize airborne bacteria by TiO ₂ , and UV-A installed under the third honeycomb to generate ultraviolet rays to sterilize bacteria; A fourth honeycomb installed under the UV-A to sterilize airborne bacteria by TiO ₂ , a second temperature sensor installed under the fourth honeycomb to sense a temperature, and the fourth A quartz heater for passing the air passing through the honeycomb, a suction fan for sucking the air, a water tank for storing water, and a water tank for collecting water in the body and flowing it back into the water tank vertically below the blocking membrane It characterized in that it comprises a drain installed in the water tank, a water activation device installed in the water tank to activate water, a pump for pumping water in the water tank, and a suction temperature sensor for detecting the temperature of the air being sucked in. do it with

The water activation device is characterized in that the flow rate of the fluid is increased by Bernoulli's theorem, and when the pressure is lower than atmospheric pressure, air is drawn in and the water is twisted while rotating to the left, so that the air is sucked in and activated by monomolecularization.

The present invention, as described in detail above, has the effect of efficiently removing carbon dioxide, carbon monoxide, mold, fine dust, volatile organic compounds and odors as well as the disappearance of viruses contained in the air.

1 (A) (B) is a side view and a front view of the air sterilizer of the present invention 2 is a cross-sectional view of the water activation device of the present invention; 3 and 4 are operation control flowcharts of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

Figure 1 (A) is a side view of the present invention air sterilizer, Figure 1 (B) is a front view of the present invention air sterilizer, a mesh (1) for filtering the sucked air, and air washing for washing the sucked air Part (2), a first carbon temperature compensation heater (3), which is a heating element for compensating the temperature above a certain temperature, and a first honeycomb (4) for sterilizing airborne bacteria by TiO ₂ , and 1 UV-C (5) installed on the top of the honeycomb (4) to sterilize bacteria by generating ultraviolet rays, and installed on the top of the UV-C (5) to sterilize bacteria in the air by TiO ₂ A second honeycomb 6, a first temperature sensor 7 installed on the upper end of the second honeycomb 6 to detect a temperature, and a vertical direction installed on the body to separate air and pass it Compensating for the temperature with a shielding film 8 for A _second carbon temperature compensation heater 10 for UV-A (12) installed in the lower part of the comb (11) to generate ultraviolet rays to sterilize bacteria, and a fourth installed in the lower part of the UV-A (12) to sterilize bacteria in the air by TiO ₂ The honeycomb 13, a second temperature sensor 14 installed under the fourth honeycomb 13 to sense a temperature, and the air passing through the fourth honeycomb 13 pass through A quartz heater 15, an air intake fan 16 for sucking air, a water tank 17 for storing water, and the blocking membrane 8 for collecting water in the body and flowing it back into the water tank A drain 18 vertically installed so that the end is opened at the bottom, a water pump 19 for pumping water from the water tank 17, a suction temperature sensor 20 for detecting the temperature of the air being sucked in; A water activating device 22 installed in the water tank 17 to introduce water to activate it, and all of the above It is composed of a body 30 including a portion, and unexplained reference numerals 4a and 4b in the drawing are air agitators for activating the air by spreading it around.

However, a plurality of nozzles are installed in the air washing unit 2 and the atomizing spray 9 to face downward, and water is supplied from the water tank 17 and is configured to be sprayed downward through these nozzles.

However, the UV-C (5) generates ultraviolet rays in a wavelength band of 200-280 nm, and the UC-A (12) generates ultraviolet rays in a wavelength band of 315-400 nm.

2 is a cross-sectional view of the water activation device 22 of the present invention, an inlet 22a through which water is introduced, an active part 22f that activates the introduced water, and a body 22b connected to the inlet 22a. , an O-ring (22c) for preventing the outflow of water, an activator (22d) that is wide and narrow at first, a ramp (22e) installed on the body (22b), is formed on one side of the body (22b) and air is introduced It consists of an air inlet (22g), a spacer (22h), a plastic bolt (22i), an outlet joint (22j), a packing (22k), an O-ring (22m), and a rotary joint (22n). It is lowered and air is drawn in through the air inlet (22g), and water is twisted to the left and sucked in to be activated as a single molecule.

The operation of the present invention constituted in this way will be described,

First, the air in the atmosphere is sucked into the main body 30 through the washable mesh 1 by the silent small air intake fan 16 to create a positive pressure in the device. .

That is, when the air suction fan 16 is operated by driving the motor M and air is drawn into the main body 30 , cleaning is performed through the air washing unit 2 .

The air washing unit 2 is provided with a plurality of nozzles, so that water supplied from the water tank 17 is sprayed through the nozzles to perform primary air washing.

At this time, a 60 cycle ~ 5 mega cycle medium frequency oscillation device is installed in the water tank 17 to make the water monomolecular for air washing through the air washing unit 2 Since the medium frequency energy is inputted by the groundwater or the pipe and the cluster of water collected in the water tank 17 after being supplied or washed is broken, the potential of the water is lowered.

Therefore, a new cluster is formed by meeting carbon dioxide, carbon monoxide, mold, fine dust, volatile organic compounds and odors in the air, and the energy of the dipole polarity of water is lowered to form a film film of water by the flow for washing with water.

Thereafter, the air temperature of the air in the air-washed state rises again through the first carbon temperature compensation heater (3).

This is to increase the temperature in order to block the virus from being activated at a certain temperature (eg, 10° C.) and performing vigorous activity.

In addition, the first temperature sensor 7 is installed at the upper end of the main body 30 to always detect the temperature in the main body 30, and when the temperature falls below a certain temperature, the first carbon temperature compensation heater 3 It compensates for the temperature with heat.

In addition, a second carbon temperature compensation heater 10 is installed on the upper end of the other side of the blocking film 8, and when the temperature falls below a certain temperature, it generates heat and compensates the temperature.

In addition, a first honeycomb 4 is installed on the upper end of the first carbon temperature compensation heater 3 to sterilize bacteria in the air introduced therein with TiO ₂ , the first honeycomb 4 and the second The honeycomb 6 , the third honeycomb 11 , and the fourth honeycomb 13 all serve to sterilize bacteria.

Here, each honeycomb is coated with TiO ₂ to perform a sterilization function.

The current COVID-19 is transmitted by droplets rather than airborne, but the focus is on treating airborne pathogens at the same time.

In the present invention, UV-C (5) is installed on the upper end of the first honeycomb filter (4), so that titanium dioxide reacts to a wavelength of 320 nm to 400 nm) to prevent pathogenic substances, mold, fine dust, volatile organic compounds, and odors. disassemble

At this time, the photocatalytic reaction of titanium dioxide is as follows.

TiO ₂ -> e- + h+(1)

OH- + H+ -> OH-(2)

H ₂ O+ h+ -> OH- + H+O ₂ + e- -> O ₂ -(3)

The titanium dioxide absorbs ultraviolet rays with a wavelength of 380 nm or less to generate electrons (e-) and holes (h+) as shown in Equation (1). It is used to decompose and sterilize organic matter in the air by oxidizing it to generate hydroxyl radicals (OH-).

The electrons generated in Formula (1) reduce the incoming oxygen to generate superoxide (O ₂ −) as in Formula (3), and the generated O ₂ − also exhibits strong sterilization power.

The hole oxidizes moisture adsorbed on the catalyst surface to generate a hydroxyl radical (OH-) with strong oxidizing power or directly oxidizes the adsorbed organic material.

In the above (3) formula, O ₂ -, which is a superoxide, is generated by giving electrons to oxygen, and the generated O ₂ - oxidizes with organic matter, water, air, or the like.

When the titanium dioxide reacts with UV-C (5) (wavelength 320 nm to 400 nm), which is an ultraviolet sterilizer, the anatase type uses a wavelength of 380 nm or less, which corresponds to 3.2 eV, and these holes and electrons are in the second honeycomb (6). Apply the lighting power by

On the other hand, in the state in which the bacteria in the air are sterilized through the first honeycomb 4 , the air is diffused and rotated out by the air agitator 4a.

In addition, the air that is diffused and turned by the air agitator 4a is once again sterilized by UV rays through the UV-C 5 which is an UV sterilizer.

And sterilization is made by TiO ₂ by the second honeycomb 6 installed on the top of the UV-C 5, and water is sprayed by atomizing spray 9 while moving to the right in the drawing through the blocking film 8. It is sprayed downward to clean the air once again.

That is, water is atomized through atomization spray (9) with a low-frequency wave that does little damage to the human body to create a humidification or 3.2ev reaction atmosphere of titanium dioxide film to remove carbon dioxide, carbon monoxide, mold, fine dust, volatile organic compounds, odors and clusters. or induce decomposition to fall into the water tank 17 through the barrier film 8, and the scattering cations in the air react with the anions of moisture to form a cluster, the moisture evaporates, and the remaining particles whose energy is canceled fall.

And since the virus is difficult to disappear below 30℃, it is a quartz heater that is a heating device in the air discharge pipe to compensate for the heat of vaporization (539Cal/g) of water generated at the time of atomization through atomization spray (9) and to activate the molecular motion of flowing air. Install (15).

That is, sterilization by TiO ₂ is performed by the third honeycomb 11, and the quartz heater ( 15), the temperature compensation is made. At this time, the second temperature sensor 14 is installed at the input end of the quartz heater 15 to detect the temperature and compensate.

The air that has passed through the quartz heater 15 passes through the main body 30 and finally passes through the cation removal network 21 to remove positive ions. The positive ion removal network 21 is connected to the air conditioner, and at this time, the The amount of atomization, indoor humidity, and temperature inside the machine are checked and transmitted to the control unit to control the intake air amount and atomization amount.

On the other hand, the water activating device 22 as shown in FIG. 2 is installed in the lower portion of the mesh 1 of the water tank 17, and as the pressure of water increases, air enters the water activating device 22. At this time, the water rotates to the left. As it twists, air is sucked in, and it becomes monomolecular and activated.

In particular, in the present invention, the temperature in the body 30 is sensed by the first temperature sensor 7 and the second temperature sensor 14 in the body 30, and the first carbon temperature with reference to the detected temperature Since the compensation heater (3), the second carbon temperature compensation heater (10), and the quartz heater (15) constantly compensate the temperature, the activation of the virus contained in the inhaled air is blocked.

3 and 4 are operation control flowcharts of the present invention, in the initial power-on state of the UV-C (5) and UV-A (12), it is turned on by identifying whether the air intake fan 16 is on or off. When the air intake fan 16 operates, it does not operate when it is off.

Next, when the power of the water pump 19 is on, the water pump 19 operates, and when it is off, it does not operate.

And it is determined whether the target indoor humidity is within the range or above the range, and if it is below the range, the atomizing spray 9 is turned on. If it is above the range, the atomizing spray 9 is turned off. If it is within the range, the suction temperature sensor 20 ) to determine whether the value is within the set range, turn on the first carbon temperature compensation heater 3 if it is less than the set range, and turn off the first carbon temperature compensation heater 3 if it is above the set range, and if it is within the set range, the second temperature It is determined whether the value of the detection sensor 14 is within a set range.

If the value of the second temperature sensor 14 is less than the set range, the second carbon temperature compensation heater 10 is turned on, and if it is above the snow point range, the second carbon temperature compensation heater 10 is turned off, and if the set range is It is determined whether the value of the first temperature sensor 7 is within a set range.

When the value of the first temperature sensor 7 is less than the set range, the quartz heater 15 is turned on, and when the value is above the set range, the quartz heater 15 is turned off. It returns to the step of determining whether the on-off state of the

In the present invention, carbon dioxide, carbon monoxide, mold, fine dust, volatile organic compounds, odors, etc. in the air having an increased concentration of pathogenic substances in the air are removed, and the wind speed of the discharged air after shower is lowered.

In addition, the present invention has a feature in that the functions of all air purifiers or sterilizers currently coexist with viruses because another problem is mass-produced by human-made technology, but the system is configured in a way to lower the energy level of the virus.

The present invention is a countermeasure against biotechnology, In order to reduce the damage of electromagnetic and magnetic waves, a medium-frequency wave device is used instead of a high-voltage amplifier transformer or a high-frequency device to atomize water. , UV LEDs are used only in a shielded space, monazite is not used to produce negative ions in large quantities, and functions caused by high-voltage discharge are not used because of the side effects of magnetic fields or high-voltage discharge itself.

1: Net 2: Air cleaning unit 3: 1st carbon temperature compensation heater 4: 1st honeycomb 4a, 4b: Air agitator 5: UV-C 6: Second honeycomb 7: First temperature sensor 8: Barrier 9: Atomization spray 10: 2nd carbon temperature compensation heater 11: 3rd honeycomb 12: UV-A 13: 4th honeycomb 14: second temperature sensor 15: quartz heater 16: air intake fan 17: water tank 18: drain 19: water pump 20: suction temperature sensor 21: cation removal network 22: water activation device 22a: inlet 22b: body 22c, 22m: O-ring 22d: activator 22e: lamp 22f: active part 22g: air inlet 22h: spacer 22i: plastic bolt 22j: Outlet joint 22k: Packing 22n; Rotating joint 30: body

Claims (2)

In one main body 30, a mesh (1) for filtering the sucked air, an air washing unit (2) for washing the sucked air, and a first heating element for compensating the temperature above a certain temperature A carbon temperature compensation heater (3), a first honeycomb (4) that sterilizes airborne bacteria by TiO2, and an air agitator (4a) installed on the first honeycomb (4) to diffuse and rotate the air to activate it ), a UV-C (5) installed at the top of the air agitator (4a) to generate ultraviolet light to sterilize bacteria, and a UV-C (5) installed at the top of the UV-C (5) to kill airborne bacteria by TiO ₂ The second honeycomb 6 for sterilization, the first temperature sensor 7 installed on the upper end of the second honeycomb 6 to detect the temperature, and the body installed in the vertical direction to separate the air The temperature is compensated by a blocking film 8 for passing, an atomizing spray 9 installed on one side of the first temperature sensor 7 to perform a humidifying function, and a radiant heat type heating element using carbon with a purity of 99.9% or more. A second carbon temperature compensation heater 10 to do this, and a third honeycomb 11 installed under the second carbon temperature compensation heater 10 to sterilize airborne bacteria by TiO ₂ , and the first 3 UV-A (12) installed at the lower part of the honeycomb 11 to generate ultraviolet rays to sterilize bacteria, and an air agitator installed under the UV-A (12) to diffuse the air and activate it. (4b), a fourth honeycomb 13 installed under the air agitator 4b to sterilize airborne bacteria by TiO ₂ , and a fourth honeycomb installed under the fourth honeycomb 13 to sense the temperature A second temperature sensor 14 for the purpose of this, a quartz heater 15 for passing the air that has passed through the fourth honeycomb 13, an air intake fan 16 for sucking air, and water storage a water tank 17 for evaporating the water; a drain 18 vertically installed under the blocking film 8 to collect water in the body and introduce it back into the water tank; and a drain 18 for pumping water from the water tank 17 A water pump (19) and a suction temperature sensor (2) for detecting the intake air temperature 0), an air sterilizing and indoor air ionized fine substance sterilizing cleaner, characterized in that it includes a water activating device (22) installed in the water tank (17) to activate it by introducing water. According to claim 1, wherein the water activation device (22) is composed of an inlet (22a), a body (22b), an activator (22d), and an air inlet (22g), and the pressure of the water introduced into the inside increases as the fluid velocity increases. Air sterilization and indoor air ionized fine substance sterilizing cleaner, characterized in that it is lowered and air is drawn in through the air inlet (22g), so that water is sucked in while twisting to the left and activated as a single molecule.

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