KR102268724B1 - high density fusion plasma sterilization and deodorizer - Google Patents

Abstract

It is an object of the present invention to provide a sterilization and deodorization device capable of generating high-concentration active species by using droplet clusters and thus producing deodorizing and sterilizing effects for a large space in a short time.
The present invention is a liquid plasma generating device that is primarily treated with high concentration active species by droplet clusters, and then sends them to a cylindrical plasma source disposed adjacent thereto to secondarily plasma-treat the air to almost completely remove the air in a short time. purify

Description

High density fusion plasma sterilization and deodorizer

The present invention relates to a sterilizer and deodorizer using plasma.

Discharge between water and plasma is divided into a method directly generated in water and a method generated at the water surface. When generating plasma in water, there is a problem in that it is difficult to supply a sufficiently high voltage to initiate discharge due to the high conductivity of water. In addition, it is difficult to secure a stable discharge characteristic, and the metal material of the electrode may be eluted in water.

On the other hand, in the plasma generated between the water surface layer and the high-frequency electrode, a high concentration of OH radicals, NO radicals, O radicals, H ₂ It has high sterilization and deodorization power because it contains active species such as _{O 2} and O _{3 .} It is reported that the droplet cluster has a structure in which 1000 to several hundred thousand water molecules are bonded. Droplet clusters contain more than 100 times more active species than discharges in air.

Therefore, if this phenomenon is properly applied, a high-efficiency sterilization and deodorization device can be made.

Patent Publication No. 10-2019-0067633 proposes a deodorizer that supplies moisture and generates plasma, but the present invention intends to propose a sterilization deodorizer that can generate a higher concentration of active species.

It is an object of the present invention to provide a sterilization and deodorization device capable of generating high-concentration active species by using droplet clusters and thus producing deodorizing and sterilizing effects in a wide space and in a short time.

The present invention is

As a sterilizer and deodorizer,

housing;

a liquid plasma generator disposed inside the housing;

a cylindrical plasma source disposed adjacent to the liquid plasma generator;

an ozone conversion catalyst filter disposed on the top or bottom of the housing; and

a fan for sucking gas into the housing; and

The liquid plasma generator,

container for liquid; and

a dielectric barrier discharge (DBD) electrode module or plasma jet electrode module arranged on the top of the vessel; and

The cylindrical plasma source,

an internal electrode disposed at the center of the cylinder;

a mesh-type external electrode spaced apart from the internal electrode and forming a cylindrical outer periphery; and

Including; dielectric barrier plasma electrode arranged in a cylindrical shape in the space between the inner electrode and the outer electrode;

The gas sucked into the sterilization and deodorizer by the fan is first generated by the liquid plasma generator to generate a droplet cluster containing high-concentration active species to sterilize, decompose, and deodorize.

Substances including suction gas, liquid plasma, droplet clusters, active species, and decomposition products are sent to a cylindrical plasma source, and a high voltage and high frequency is applied to the dielectric barrier plasma electrode of the cylindrical plasma source and the inner and outer electrodes are grounded to form a dielectric Secondary sterilization and deodorization treatment by generating plasma between the barrier plasma electrode and the internal electrode and between the dielectric barrier plasma electrode and the external electrode, and discharging the purified gas through the ozone conversion catalyst filter to the outside of the housing It provides a sterilization and deodorizer characterized in that.

In the above, it further includes a HEPA filter on the ceiling and the wall of the housing, the ceiling HEPA filter is exposed to the air to provide a sterilizing and deodorizing device characterized in that the exhausted through the ceiling HEPA filter.

In the above, the liquid plasma generator provides a sterilization and deodorizer characterized in that the liquid is supplied so as to leave a gap between the surface of the liquid and the plasma jet electrode module or the dielectric barrier plasma electrode module at the top of the container.

In the above, the liquid plasma generator provides a sterilization deodorizer, characterized in that the ground module including an insulator and a metal electrode arranged on the surface of the insulator is disposed on the upper end of the container, and the dielectric barrier plasma electrode is arranged between the ground module.

In the above, the sterilization and deodorization device further includes an ultraviolet lamp, and the ozone removal filter and the ultraviolet lamp provide a sterilization and deodorizer, characterized in that a plurality of alternately arranged.

The present invention is

A liquid plasma generator for sterilization and deodorization, comprising:

container for liquid;

a dielectric barrier plasma electrode module arranged on the top of the vessel; and

a ground module arranged between the dielectric barrier plasma electrode modules;

The dielectric barrier plasma electrode module includes a sharply tapered metal electrode and a dielectric surrounding the metal electrode,

The ground module is made by arranging a metal electrode on an insulator,

The pointed part of the dielectric barrier plasma electrode module is disposed between the grounding module and the grounding module,

It provides a liquid plasma generator for sterilization and deodorization, characterized in that the lower end of the dielectric barrier plasma electrode module generates a plasma discharge at a distance from the liquid surface to form liquid plasma and droplet clusters.

In the above, sterilization, characterized in that the dielectric barrier plasma electrode module and the ground module are alternately arranged to form a column or the ground module is arranged in a mesh shape, and the tapered portion of the dielectric barrier plasma electrode module is disposed in the mesh opening A liquid plasma generator for a deodorizer is provided.

The present invention is

A cylindrical plasma source for sterilization and deodorization, comprising:

an internal electrode disposed at the center of the cylinder;

a mesh-type external electrode spaced apart from the internal electrode and forming a cylindrical outer periphery; and

Including; dielectric barrier plasma electrode arranged in a cylindrical shape in the space between the inner electrode and the outer electrode;

For sterilization and deodorization, characterized in that by applying a high voltage to the dielectric barrier plasma electrode of the cylindrical plasma source and grounding the inner electrode and the outer electrode to generate plasma between the dielectric barrier plasma electrode and the inner electrode and between the dielectric barrier plasma electrode and the outer electrode A cylindrical plasma source is provided.

The present invention is

A plasma processing module for sterilization and deodorization, comprising:

comprising the liquid plasma generator and the cylindrical plasma source disposed adjacent the liquid plasma device;

It provides a plasma treatment module for sterilization and deodorization, characterized in that the gas is primarily treated with a liquid plasma generator, and the generated material is sent to a cylindrical plasma source for secondary plasma treatment.

In the above, as the plasma discharge gas, there is provided a sterilization and deodorizer characterized in that air, inert gas, oxygen, or carbon dioxide is supplied.

The present invention is

A liquid plasma generator for sterilization and deodorization, comprising:

container for liquid;

a plasma jet electrode module arranged on the top of the vessel; and

Including; a ground module arranged around the plasma jet electrode module;

The plasma jet electrode module includes a needle-shaped electrode and a counter electrode spaced apart from the needle-shaped electrode,

The ground module is made by arranging a metal electrode on an insulator,

An end of the plasma jet electrode module is disposed between the grounding module and the grounding module,

It provides a liquid plasma generator for sterilization and deodorization, characterized in that the lower end of the plasma jet electrode module is spaced apart from the liquid surface to generate plasma discharge to form liquid plasma and droplet clusters.

According to the present invention, the liquid plasma and air are first purged with active species contained in a high concentration in the droplet cluster by the liquid plasma generator, and the resulting material is sent back to the adjacent cylindrical plasma source for secondary plasma treatment. Thus, it can be cleaned quickly and completely.

The liquid plasma generator disposes a dielectric barrier plasma electrode module on the top of a container containing a liquid, and discharges a stable liquid plasma at a distance of at least 3 mm from the liquid surface, and the cylindrical plasma source applies a high voltage to the dielectric barrier plasma electrode and Because both the electrode and the external cylindrical electrode are grounded to discharge the plasma between the two ground electrodes, a very rich plasma can be obtained, resulting in an efficient sterilization and deodorization action.

Water or hydrogen peroxide solution contained in the liquid has an effect of removing ozone among various active species, so there is little concern about ozone post-treatment according to plasma treatment, and ozone removal can be accomplished almost completely in a short time by an additional filter and ultraviolet rays.

A HEPA filter is further included in the housing to remove foreign substances, and the purified gas can be discharged through the HEPA filter on the ceiling.

1 is a schematic diagram showing the configuration of a sterilization deodorizer of the present invention.
Figure 2 is a configuration diagram showing the configuration of the liquid plasma generator to enter the sterilization deodorizer of the present invention.
Figure 3 is a block diagram showing the configuration of a cylindrical plasma source entering the sterilization deodorizer of the present invention.

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

The present invention arranges the liquid plasma generating device 100 and the cylindrical plasma source 200 adjacent thereto in the sterilization and deodorizer housing 90 as shown in FIG. 1, and the filter and the ultraviolet lamp are arranged on these upper portions, and the housing ceiling and wall We propose a sterilization and deodorizer equipped with a HEPA filter. The HEPA filter can remove more than 99.97% of dust with a size of 0.3 μm or more.

A droplet cluster containing an active species in a high concentration is generated by the liquid plasma generating device 100, and this is again injected into the cylindrical plasma source 200 installed next to the droplet cluster by the cylindrical plasma source 200. It is decomposed into active species (OH, NO, O, H ₂ O ₂ , O _{3 ,} etc.) and generates plasma again to emit a high concentration of active species and plasma to the outside of the cylindrical plasma source 200 . A high frequency of 1 to 50 kV of 1 kHz to 50 kHz is applied to the electrode of the cylindrical plasma source, so that the droplet cluster is _{decomposed into atoms and/or molecules such as OH, NO, O, H 2} O ₂ , O ₃ as described above, and high-concentration activity create a species

That is, the air that requires sterilization and deodorization is sucked into the sterilization and deodorizer by the fan, and the cause of odor is caused by the liquid plasma primarily generated by the liquid plasma generating device 100 and the high concentration active species contained in the droplet cluster. The organic matter is decomposed and removed, and the gas, organic matter decomposition product, liquid plasma, and droplet cluster including organic matter are sent back to the cylindrical plasma source 200 again to generate plasma again, making the active species more concentrated, sterilizing and deodorizing effect to maximize

The cylindrical plasma source 200 is used to have a structure in which active species generated inside are emitted to the outside. By the dielectric barrier plasma electrode (described later in FIG. 2) in the middle of the cylindrical plasma source 100, and by the inner and outer metal electrodes, plasma is generated and active species are emitted to the outside of the cylindrical plasma source 100. Make the distribution uniform in the sterilization and deodorization space.

In addition, in the upper part of the sterilization and deodorization space by plasma, a filter 400 containing manganese dioxide, an ultraviolet lamp 500, and a HEPA filter 300 surrounding the inner wall and ceiling of the sterilization and deodorizer are arranged to perform additional sterilization and deodorization treatment. , to remove the generated ozone. The filter 400 containing manganese dioxide functions to convert ozone (O ₃ + (MnO ₂ ) → O2 + O), the HEPA filter 300 functions to filter foreign matter such as dust, and the ultraviolet lamp 500 has sterilizing power and ozone removal have a function

In the case of ultraviolet lamps, UV C below 240 nm generates ozone and above 240 nm decomposes ozone. In this example, a 254nm wavelength was applied, and the sterilization power was increased in the sterilization resonance frequency range of known bacteria and ozone was decomposed (O ₃ + UV 254nm → O2 + O).

However, the UV lamp UV C -1 at the bottom of the sterilizer generates ozone by applying a wavelength of 185 nm, and the UV lamp disposed above it applies 254 nm UV C-2 and 254 nm UV C-3 to oxidize ozone. It can be configured to convert to highly active O radicals.

Although three pairs of manganese dioxide filters and an ultraviolet lamp are shown in FIG. 1 as a preferred embodiment, they may be arranged in a plurality (one or more pairs) alternately with each other.

FIG. 2 shows in detail the liquid plasma generating apparatus 100 for generating droplet clusters including high concentration active species by generating liquid plasma.

A plurality of grounding modules in which the electrodes 30 are formed on the insulator 20 on the upper end of the container 10 containing the liquid are arranged at a distance from each other. The electrode 30 may be grounded by being connected to a ground electrode disposed at the bottom of the container 10 through a wire.

These may represent a form in which a dielectric barrier plasma electrode and a grounding module are alternately arranged to form a column on a liquid container, and may form a shape like a liquid container lid made of a net. Dielectric barrier plasma electrode modules made of an electrode 40 and a dielectric 50 surrounding the electrode 40 are arranged in the opening (interval portion between the insulators 20) of the ground module in a downwardly tapering shape. The tapered pointed part is disposed in the opening of the net-shaped ground module, but is disposed so as not to contact the electrode module. A high voltage is applied to the dielectric barrier plasma electrode module by a power source, and a ground electrode for this is disposed in a large area at the bottom of the container to connect a power ground terminal.

Also, in the above, the plasma electrode may be configured as a plasma jet electrode instead of a dielectric barrier plasma electrode module. A widely known plasma jet electrode can be used, and generally consists of a needle-shaped electrode in the center and a counter electrode (ground electrode) spaced apart from the needle-shaped electrode and arranged around the needle-shaped electrode. When using the plasma jet electrode, a grounding module may be disposed around the jet electrode module, and the grounding module may be omitted.

In the solution contained in the container 10 and the discharge unit, a high voltage is applied to the sharp-shaped dielectric barrier plasma electrode module to cause plasma discharge.

The distance between the liquid and the electrode should be 3 mm or more so that the discharge is stable. _{Active species (OH, O, NO, H 2} O ₂ , etc.) generated by liquid plasma discharge between the electrode and the solution are discharged together with the droplet cluster, and the density of the active species dissolved in the droplet cluster is higher than that of the gas. more than 100 times higher. _{In addition, there is an advantage that O 3} is hardly generated as an active species by discharge on the liquid surface. The electrode 30 of the ground module may be made of a metal such as Ti or W, and the metal is disposed on the surface of the insulator 20 so that charged particles are attached to the metal electrode, thereby increasing the electric potential of the insulator. It prevents the insulation from being damaged by rising. The electrode 30 of the ground module may be configured to be exposed on both sides of the insulator 20 or exposed on either side.

A liquid (water or an aqueous solution of 5% to 10% H ₂ O ₂ ) is automatically supplied to the container 10, and the gap between the upper electrode module and the liquid surface is set at 3 mm or more (3 to 30 mm) to ensure stable plasma to cause a discharge. That is, the distance between the electrode and the liquid surface is set to 3 mm or more to prevent instability of discharge caused by abnormal discharge or the like. The liquid is automatically supplied to the container 10 by the position sensor 70 at the appropriate level.

The air sucked into the sterilization and deodorizer by the fan 60 contains viruses, bacteria, and organic matter generating odors. Contaminated air first reacts with the liquid plasma generated by the liquid plasma generator 100 and the active species included in the generated droplet cluster to sterilize and disinfect, and organic matter is decomposed.

The droplet cluster including active species generated in the liquid plasma discharge is discharged to the outside through the space between the electrode modules at the top of the container 10 and is incident to the inlet of the cylindrical plasma source 200 together with the air sucked in by the fan 60 . do.

The liquid plasma generated by the dielectric barrier plasma electrode module in the liquid plasma generator 100 is emitted into the air in the form of droplet clusters, and active species particles (OH, NO, O, H ₂ O ₂ , ON , O _3, etc.) in a high concentration, so the sterilization and deodorization effect is very high. This is because the effect of confining the active species in the space limited by the droplet and the droplet itself can cause a reaction to generate the active species.

In particular, when an aqueous solution of hydrogen peroxide (H ₂ O ₂ ) is used, OH with high activity is decomposed therefrom, and thus sterilization and deodorization power are greatly improved.

The air primarily treated in the liquid plasma generator 100 enters the cylindrical plasma source 200 together with decomposition products, droplet clusters, liquid plasma, and active species, and is again discharged by high voltage and high frequency electromagnetic waves and ultraviolet rays. Due to the plasma, it is decomposed into water molecules and high-concentration atomic and molecular states (OH, NO, O, H ₂ O ₂ , O _3, etc.) and released from the cylindrical plasma source 200, and high sterilization and deodorization performance have This will have a sterilization, disinfection and deodorization performance more than 10 times higher than that of using only a conventional cylindrical plasma source.

3 shows the configuration of the cylindrical plasma source 200 and the plasma generation phenomenon in detail.

An internal electrode 210 made of a metal that is difficult to oxidize, such as W or Ti, is disposed in the central cylindrical inner center, and a mesh-shaped metal external electrode 220 (metal that is difficult to oxidize, such as W, Ti) is also disposed on the outer periphery forming the cylindrical outer periphery do. Also, a dielectric barrier plasma electrode 230 having a cylindrical shape is disposed between the internal electrode 210 and the external electrode 220 . The dielectric barrier plasma electrode 230 arranges a metal electrode 231 (a metal that is difficult to oxidize, such as W and Ti) in the center and surrounds the periphery with a dielectric 232 having a dielectric constant of 5 to 15 to make a rod-shaped electrode, A plurality of rod-shaped electrodes are arranged to form a cylindrical shape.

This electrode configuration causes plasma discharge between the intermediate dielectric barrier plasma electrode 230 and the inner electrode 210 and the outer electrode 220 so that active species are formed in the entire cylinder. In this embodiment, a high voltage is applied to the dielectric barrier plasma electrode 230 , and a ground terminal is connected to the remaining internal and external electrodes to connect the dielectric barrier plasma electrode 230 and the internal electrode 210 and the dielectric barrier plasma electrode. Plasma discharge was generated between both 230 and the external electrode 220 . In this way, a very abundant plasma can be obtained, and high-concentration active species are sterilized and deodorized, and are diffused out of the cylinder through the openings of the outer mesh-shaped external electrode of the cylindrical plasma source. As a result, the purified air can be discharged from the sterilization and deodorizer, and these are finally discharged to the outside through the removal of ozone and foreign matter such as dust by the UV lamp and filters as described above.

_{On the other hand, O 3} generated in the liquid plasma generator 100 and the cylindrical plasma source 200 is decomposed by water molecules and electrons of the plasma (O ₃ +H ₂ O → 2OH + O ₂ , O ₃ + e → O ₂ + O + e) OH and O radicals with high activity are formed, and the _{amount of O 3} generated decreases. That is, since the liquid is used, an effect of removing ozone by water can be obtained, and a separate system for removing ozone is not required.

However, in order to more reliably activate ozone, an ultraviolet lamp 500 and a manganese dioxide filter 400 were installed at the top of the sterilization and deodorizer.

As the UV lamp 500, the UV C lamp (254 nm) corresponds to a resonance frequency range for viruses and bacteria and has a particularly high sterilization power. Instead of UV-C lamp 1 (254 nm), UV-C 1 at the bottom is 240 nm or less, for example, using a 185 nm wavelength lamp to generate ozone and UV-C 2 (254 nm), UV-C 3 (254 nm) at the top Ozone may be decomposed with a lamp and a MnO ₂ catalyst to generate highly active O atomic radicals.

MnO ₂ decomposes ozone as a catalyst to generate highly active O radicals.

O ₃ + (MnO ₂ ) → O2 + O (radical)

_{Through this process, O 3} is almost decomposed without using activated carbon by passing through UV-C lamps, and the concentration of emitted ozone is controlled to 0.05 ppm or less.

In the above, the filter and the ultraviolet lamp may be arranged at the upper or lower end of the housing, and installation of the ultraviolet lamp may be omitted.

In addition, in this embodiment, the air outlet of the sterilization and deodorizer is not separately configured, but a HEPA filter is installed on the ceiling and wall of the housing to allow the purified air to escape through the ceiling. may be

In addition, although air is used as the plasma discharge gas in the above embodiment, an inert gas such as Ar or He, oxygen (O ₂ ), or a gas such as carbon dioxide (CO ₂ ) may be supplied as the discharge gas.

As described above, the sterilization and deodorizer according to the present invention can purify contaminated air by quickly and completely sterilizing and deodorizing liquid plasma, cylindrical plasma source, and UV lamp and filters.

On the other hand, the specific numerical values presented in the above embodiments and experimental examples are exemplary and can be modified as needed, and those skilled in the art to which the present invention pertains will appreciate that the present invention does not change the technical spirit or essential features of the present invention. It will be understood that it may be implemented in the form Therefore, it should be understood that the embodiments described above are illustrative in all respects and not restrictive. The scope of the present invention is indicated by the following claims rather than the above detailed description, and all changes or modifications derived from the meaning and scope of the claims and their equivalent concepts should be interpreted as being included in the scope of the present invention. do.

Container (10), insulator (20), electrode (30), electrode (40), dielectric (50), fan (60), position sensor (70)
Liquid plasma generator 100, cylindrical plasma source 200,
Internal electrode 210 , external electrode 220 , dielectric barrier plasma electrode 230 , electrode 231 , dielectric 232 ,
HEPA filter 300, filter 400, UV lamp 500,

Claims (1)

As a sterilizer and deodorizer,
housing;
a liquid plasma generator disposed inside the housing;
a cylindrical plasma source disposed adjacent to the liquid plasma generator;
an ozone conversion catalyst filter disposed on the top or bottom of the housing; and
a fan for sucking gas into the housing; and
The liquid plasma generator,
container for liquid; and
a plasma jet electrode module or a dielectric barrier plasma electrode module arranged on the top of the vessel;
The cylindrical plasma source,
an internal electrode disposed at the center of the cylinder;
a mesh-type external electrode spaced apart from the internal electrode and forming a cylindrical outer periphery; and
Including, a dielectric barrier plasma electrode arranged in a cylindrical shape in the space between the inner electrode and the outer electrode;
The gas sucked into the sterilization and deodorizer by the fan is first generated by the liquid plasma generator to generate a droplet cluster containing high-concentration active species to sterilize, decompose, and deodorize.
Substances including suction gas, liquid plasma, droplet clusters, and decomposition products are sent to a cylindrical plasma source, applying a high voltage to the dielectric barrier plasma electrode of the cylindrical plasma source, and grounding the inner and outer electrodes to connect the dielectric barrier plasma electrode and the inner electrode. Plasma is generated between the electrodes and plasma is also generated between the dielectric barrier plasma electrode and the external electrode, and active species are emitted outside the cylindrical plasma source to perform secondary sterilization and deodorization treatment. A sterilization and deodorizer characterized in that the gas is discharged to the outside of the housing.

Images