KR102502413B1 - air sterilizer - Google Patents

Abstract

The present invention relates to an air sterilizing device that sterilizes air using plasma discharge. More specifically, by configuring an actuator that performs plasma discharge with flexible electrodes, the size and shape of the device can be freely implemented. The present invention is configured to maximize the area where the flexible electrodes are in contact with the air. Thus, air sterilization efficiency by plasma is improved. In addition, the air sterilized by plasma is double sterilized by passing air through a UV LED again, thereby providing maximum sterilizing power compared to the same area.

Description

Air sterilizer {air sterilizer}

The present invention relates to a device for sterilizing air using plasma, and more particularly, to an air sterilizing device that maximizes the sterilizing power of air through structural features capable of improving a discharge effect in a plasma discharge module.

Plasma is called the fourth state of matter after solid, liquid, and gas. When high energy is applied to the gas state, an aggregate of particles composed of ion nuclei and free electrons is created, which is called the plasma state.

Since plasma contains numerous various functional ions, it is effective in improving adhesion during printing, coating, and bonding by modifying the surface by removing fine foreign substances, changing surface roughness, and forming polar functional groups as well as cleaning the surface of materials. . In more detail, plasma can be used in various ways depending on the type, high-temperature and high-density plasma can be used for nuclear fusion device technology, and vibration plasma can be used for semiconductor wafer surface treatment technology or lead frame surface treatment technology. In addition, atmospheric plasma can be used in chemical process technologies such as etching and deposition surface treatment for semiconductor display manufacturing, medical devices and medical sterilizers, and water treatment technologies. Plasma is being applied and used in various fields such as bio/medicine, material industry, and energy/environmental industry.

Atmospheric pressure plasma, unlike vacuum plasma, does not require separate vacuum equipment because it operates in an open space, and the equipment cost is relatively low, and the equipment maintenance and operating costs are low, so there are many methods for generating plasma at atmospheric pressure. Research is being done. Plasma can generate plasma with different physical and chemical characteristics through adjustment of input frequency, input voltage/current, input waveform, supply gas, etc., and depending on the discharge structure and discharge mode, Dielectric Barrier Discharge (DBD) , Corona Discharge, Glow Discharge, Arc Discharge, Micro Hollow Cathode Discharge (MHCD), and Inductively Coupled Plasma (ICP). are distinctly

Describing the structure of a general plasma actuator, when a pair of electrodes are spaced apart at a certain interval and a voltage is applied, a discharge is formed in the space between the electrodes and the reaction gas is ionized to become plasma. Among them, the basic driving principle of the plasma actuator of the DBD structure, which is dielectric barrier discharge, is to use the volume force generated by the combination of the electric field generated by the local ionization of air through the actuator and the electrode arrangement. However, the plasma actuator for the conventional DBD structure has a disadvantage in that the plasma production capacity is lower than that of other device structures because the electrode spacing is small or the plasma processing cross-sectional area is small, and an electrode design to increase power efficiency is required.

In addition, since there are limitations in the volume and design of the entire system when designing a system with a conventional non-flexible electrode, a technology using a flexible substrate beyond the conventional flat electrode is required as a plasma application technology in recent years. .

The present invention has been made to solve the above problems, and an object of the present invention is to provide a sterilization device for sterilizing air using atmospheric pressure plasma discharge, by configuring an actuator that performs plasma discharge with a flexible electrode. The size and shape of the device can be freely implemented, and the efficiency is improved by configuring the flexible electrode to maximize the contact area with air, and it provides maximum sterilization power by re-sterilizing the sterilized air using UV LED. It is to provide an air sterilization device capable of.

The air sterilization device of the present invention includes an inlet through which external air flows into the device; an outlet through which the air inside the device is discharged to the outside; a fan provided inside the device to allow air to pass through the inlet and the outlet by operation to form a flow of air inside the device; at least one filter disposed between the inlet and the outlet; and a hexagonal flat surface disposed between the inlet and the outlet and disposed in a direction perpendicular to the flow direction of the air formed by the fan, wherein the edge of the flat surface extends in the vertical direction. A sterilization module unit provided and accommodated in a housing including a first housing and a second housing that are formed in a ∪ or ∩ shape in cross section with respect to the flow direction of the air as an axis, facing each other and coupled to each other, The first housing is disposed on the inlet side, the second housing is disposed on the outlet side, and at least one through hole having a predetermined area through which air passes is formed on each surface, and the sterilization unit module comprises the first housing. In the housing, a flexible material including a first electrode formed in an axial shape, a dielectric concentric with the first electrode and formed to surround the first electrode, and a second electrode formed in contact with the outer circumferential surface of the dielectric A flexible electrode composed of includes a plasma module spirally arranged on one plane of the first housing, and an ultraviolet module including a plurality of UV LEDs in the second housing, wherein the UV LEDs are arranged in the second housing. It is characterized in that at least one is disposed on each side of one plane of the housing.

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In addition, the flexible electrode is characterized in that the flexible electrodes neighboring in the radial direction have a predetermined distance from each other.

In this case, the first housing is characterized in that it includes a plurality of protrusions arranged radially at regular intervals on the one plane, and the flexible electrode is disposed while being caught by the protrusions.

At this time, the plurality of projections are characterized in that they are arranged at each vertex position of the plane.

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In this case, the plasma module is characterized in that a plurality of second electrodes are formed, and predetermined second electrodes are coupled to each other in the form of a bundle, and the bundle is arranged in a grid pattern on an outer circumferential surface of the dielectric.

At this time, the dielectric is characterized in that composed of any one or more of Teflon, silicon, glass fiber.

In addition, the second electrode is characterized in that SUS or tin material.

In addition, the filter is composed of a first filter composed of a pre-filter and a second filter composed of a deodorization filter, and one plane of the first filter and the second filter is horizontal to the air flow direction inside the device. It is characterized by being arranged in one direction.

At this time, the first filter and the second filter are respectively disposed on both sides of the sterilization module unit along the flow direction of the air, the first filter is disposed on the inlet side, and the second filter is disposed on the outlet side. characterized by being

At this time, the second filter is characterized in that the graphite filter of the coal gate method.

The air sterilization device of the present invention according to the above configuration can realize the maximum plasma discharge effect by having a plasma actuator with a flexible electrode structure, so it can be configured by minimizing other structural components, so the structure is simple to manufacture and install. It is useful for miniaturization of the device, and it is possible to freely implement the size and shape of the sterilizer to be configured by the flexible electrode, so there is an advantage that it can be manufactured into a sterilizer of an appropriate form according to the needs of the user. In addition, a sufficient sterilization effect can be achieved with only atmospheric pressure air without a separate reaction gas, and a structure that maximizes the contact between the air flow and the plasma actuator as well as double sterilization of air using UV LED , There is an effect of providing an air sterilization device with high efficiency of sterilization power compared to the size of the device while being driven with low power.

1 is a device configuration diagram according to an embodiment of an air sterilization device of the present invention
2 is a perspective view according to an embodiment of a second filter of the present invention
Figure 3 is a perspective view according to one embodiment of a housing accommodating the sterilization module of the present invention
Figure 4 is a perspective view according to an embodiment of the plasma module and the first housing of the present invention
5 is a plan view of a plasma module and a first housing according to an embodiment of the present invention;
6 is a perspective view according to an embodiment of a flexible electrode of the present invention
7 is a side view according to an embodiment of a flexible electrode of the present invention
Figure 8 is a perspective view according to an embodiment of the ultraviolet module and the second housing of the present invention
Figure 9 is a plan view according to an embodiment of the ultraviolet module and the second housing of the present invention

Hereinafter, the technical idea of the present invention will be described in more detail using the accompanying drawings. Prior to this, the terms or words used in this specification and claims should not be construed as being limited to the usual or dictionary meaning, and the inventor appropriately uses the concept of the term in order to explain his/her invention in the best way. It should be interpreted as a meaning and concept consistent with the technical idea of the present invention based on the principle that it can be defined.

Therefore, since the embodiments described in this specification and the configurations shown in the drawings are only one of the most preferred embodiments of the present invention and do not represent all of the technical ideas of the present invention, various alternatives may be used at the time of this application. It should be understood that variations may exist.

Hereinafter, the technical idea of the present invention will be described in more detail using the accompanying drawings. Since the accompanying drawings are only examples shown to explain the technical idea of the present invention in more detail, the technical idea of the present invention is not limited to the form of the accompanying drawings.

Referring to FIG. 1, the air sterilization device of the present invention includes an inlet 110 through which external air flows into the device, an outlet 120 through which air inside the device is discharged to the outside, and is provided inside the device, Air passes through the inlet 110 and the outlet 120 by operation and at least one fan 130 disposed between the inlet 110 and the outlet 120 to form a flow of air inside the device. It is disposed between the above filter 200 and the inlet 110 and the outlet 120, and includes a first housing 311 having a flat surface, and is made of a flexible material on a flat surface of the first housing 311. It is characterized in that it includes a sterilization module unit 300 including a plasma module 320 in which the configured flexible electrode 321 is disposed. At this time, the present invention is characterized in that the first housing 311 is disposed so that the one plane is perpendicular to at least one of the flow directions of air formed inside the device. In addition, the air sterilization apparatus of the present invention includes a frame 10 forming a certain space therein, and the inlet 110, the outlet 120, the fan 130, the filter ( 200) and the sterilization module unit 300 are preferably configured to be accommodated.

Referring to FIG. 1, the inlet 110 is formed in any one part of the frame 10 constituting the device, and is formed so that the inside and outside of the device are through, so that external air is introduced into the device. characterized by The inlet 110 may be formed on at least one of an upper surface, a lower surface, a side surface, a front surface, and a rear surface of the device, and the inlet 110 may be configured in plurality according to the user's needs, and at least one or more of the inlets 110 may be provided. It is preferable to be formed in the device as. The inlet 110 may be formed as a hole in the frame 10 of the device, or may be formed in the form of a pipe to create a flow path inside the device through the pipe and connect the outside and the inside of the device. can In one embodiment of the present invention, the inlets 110 are formed on the bottom of the device, and may be configured as a pair and disposed on both sides of the device.

Referring to FIG. 1, the outlet 120 is formed in any part of the frame 10 constituting the device, like the inlet 110, and is characterized in that the inside and outside of the device are formed to pass through, At this time, the outlet 120 is characterized in that the air inside the device is configured to be discharged to the outside of the device. The outlet 120 may be formed on at least one of a top surface, a bottom surface, a side surface, a bottom surface, and a rear surface of the device, and the outlet 120 may be configured in plurality according to the user's needs, and at least one or more of the outlets 120 may be provided. It is preferably formed in the device composed of. The outlet 120 may be formed as a hole in the frame 10 of the device, or may be formed in the form of a pipe to create a flow path inside the device through the pipe and connect the outside and the inside of the device. can In one embodiment of the present invention, the outlet 120 may be formed on an upper surface of the device.

Referring to FIG. 1 , a fan 130 is provided inside the device, and the rotation of the fan 130 forms a flow of air inside the device. The air flow direction of the fan 130 is determined according to the arrangement and rotation direction, and the fan 130 of the present invention moves the air flow from the inlet 110 to the outlet 120. Characterized in that it is disposed inside the device. The fan 130 may be disposed without limitation as long as it can form a flow of air inside the device, and for example, when it is desired to advantageously discharge air to the outside of the device, the fan 130 is installed at the outlet ( 120), or the fan 130 may be disposed close to the inlet 110 when it is desired to favorably introduce air into the device. In addition, the fan 130 selects a flow direction (angle) of air to be formed according to the user's needs, arranges the blades of the fan 130 so that they are perpendicular to the flow direction, and rotates the blades clockwise. The direction can be determined by rotating in a clockwise or counterclockwise direction. That is, the fan 130 moves the air inside the device toward the outlet 120 while the outside air is introduced into the device through the inlet 110 by the rotation of the fan 130, and the outlet ( 120), the air inside the device is discharged to the outside, and the flow of air is formed in the direction from the inlet 110 to the outlet 120 inside the device by the fan 130. In addition, the apparatus may further include a flow path connected from the inlet 110 to the outlet 120, and in this case, the fan 130 is located inside the flow path so that the fan 130 rotates. Air introduced into the inlet 110 may be configured to move to the outlet 120 by. At this time, since the flow path can be formed without limitation as long as it connects the user's inlet 110 and outlet 120, it includes a plurality of bends while having various angles and directions inside the device according to the user's needs. It can be. The fan 130 may be provided by determining an output according to a user's needs, and may be provided in plural numbers. In the case where a plurality of fans 130 are provided, it is preferable that the plurality of fans are aligned and arranged so as to form a flow in the same direction. desirable. In one embodiment of the present invention, when the inlet 110 is formed on the bottom side of the device and the outlet 120 is formed on the upper side of the device, the fan 130 is on the side of the inlet 110. , and the wings are disposed in a direction horizontal to the ground so that the external air flowing into the inlet 110 moves upward and the air flow direction is perpendicular to the ground so that it is discharged through the outlet 120 It can be positioned to form one upward.

Referring to FIG. 1 , the filter 200 is configured to filter air flowing into the device and is disposed between the inlet 110 and the outlet 120 inside the device. The filter 200 is formed in a shape having a flat surface, and filters impurities by allowing air to pass through the flat surface. In order to increase filtering efficiency, the filter 200 is preferably arranged so that one plane is perpendicular to the air flow direction inside the device. For example, if the air flow direction is an upward flow direction perpendicular to the ground, one plane of the filter 200 is disposed in a direction parallel to the ground, so that when the air flows, the filter 200 It is preferable to be formed so as to increase filtering efficiency by passing through a large area. Preferably, the filter 200 is made of a material capable of filtering a component to be filtered according to a user's selection. It is preferable that at least one filter 200 is formed, and when a plurality is provided, it may be composed of different materials to filter different components.

In one embodiment of the present invention, the filter 200 may be composed of a first filter 210 composed of a pre-filter and a second filter 220 composed of a deodorizing filter. That is, the first filter 210 and the second filter 220 are disposed horizontally with the ground so that one plane is perpendicular to the flow direction of the air, and both sides of the sterilization module unit 300 along the flow direction It may be in the form of being placed in each. In more detail, the first filter 210 may primarily filter air introduced into the device as a pre-filter, and thus the first filter 210 may be disposed on the side of the inlet 110 . At this time, the first filter 210 may be configured in a form in which a dust net and a HEPA filter are combined to filter impurity particles such as dust, viruses, bacteria, and fine particles of fine dust contained in the air. there is. Accordingly, by using the first filter 210 to primarily filter impurities in the air and passing the filtered air through the sterilization module unit 300, the sterilizing power of the air can be improved. In addition, the first filter 210 may further include a UV-LED that generates ultraviolet light capable of removing harmful factors filtered by the filter 200 in order to improve the replacement cycle of the filter 200. - It is preferable that the LED is disposed to irradiate ultraviolet rays to the first filter 210 . In this case, the UV-LED may be an LED that generates UV-C in ultraviolet light. In addition, the second filter 220 passes through the sterilization module unit 300 as a deodorizing filter and may be configured to finally filter ozone or other harmful substances before the sterilized air is discharged to the outside. 2 The filter 220 may be disposed on the outlet 120 side. At this time, FIG. 2 is an example of the second filter 220, and the second filter 220 removes harmful components including ozone that may be generated by the plasma generated by the sterilization module unit 300. It may be a deodorizing filter capable of filtering. In addition, in order to more effectively deodorize ozone, the second filter 220 may be formed of an activated carbon filter 200 made of graphite, and the activated carbon filter 200 has a passage 221 of a predetermined area arranged therein. It may be composed of a filter 200 of a coal gate method. Therefore, the air filtered with impurities in the air passes through the sterilization module unit 300, sterilization is performed by plasma and ultraviolet rays, and the air sterilized by the flow of air passes through the second filter 220, Since the deodorizing effect can be realized while finally absorbing ozone or other harmful components generated by the plasma of the sterilization module unit 300, the air discharged through the outlet 120 has a stronger sterilization effect. has the effect of being discharged as

Referring to FIG. 3 , the sterilization module unit 300 includes a plasma module 320 that performs at least a plasma discharge, so that the air flowing inside the device by the plasma module 320 is directly decomposed using plasma. It is characterized by purifying the air by doing. The sterilization module unit 300 is preferably disposed between the inlet 110 and the outlet 120, and includes a housing 310 having at least one plane, so that the housing 310 is accommodated and the air It may be provided inside the sterilization device. If the housing 310 includes a flat surface of a predetermined area, it may be selected and formed in various shapes such as a circle, a triangle, and a rectangle according to the user's needs. The housing 310 is preferably arranged so that one plane of the housing 310 is perpendicular to at least one of the flow directions of the air formed inside the device, and in one embodiment of the present invention, the air When the flow direction is upward, one flat surface of the housing 310 may be disposed in a direction parallel to the ground. The sterilization module unit 300 includes at least a plasma module 320, and additionally, an ultraviolet module 330 including a UV-LED generating ultraviolet light may be further configured, as well as air Any module constituting a device capable of sterilization may be configured without limitation and accommodated in the housing 310 . At this time, being accommodated in the housing 310 means including being attached to the outer surface of the housing 310 .

4 and 5, the plasma module 320 is a device for realizing a plasma discharge. As a feature of the present invention, the plasma module 320 has a plasma actuator formed of a flexible electrode 321 made of a flexible material. characterized by The plasma module 320 is composed of a flexible electrode 321 in the form of a wire, and can be arranged in various forms according to the user's needs. In one embodiment of the present invention, the plasma module 320 is accommodated in a first housing 311 including a flat surface in the form of the flexible electrode 321, and is placed on a flat surface of the first housing 311. It is characterized in that the flexible electrodes 321 are arranged and arranged. In addition, it is preferable to have a structure that optimizes contact with air by disposing one plane of the first housing 311 so that it can pass vertically in the flow direction of air formed inside the device. . The plasma module 320 is characterized by forming a plasma discharge using atmospheric pressure, and by maximizing the amount of active species including OH radicals generated by the formed plasma discharge necessary for air sterilization, the generated active species It is characterized in that it is a device for performing air sterilization by using. Accordingly, the plasma module 320 of the present invention uses the flexible electrode 321 to construct a structure capable of maximally generating active species, and by helically arranged, the flexible electrode 321 and the air contact It is characterized by optimizing the area to provide the maximum sterilization effect.

Referring to FIGS. 4 and 5, according to an embodiment of the present invention, the plasma module 320 has the flexible electrode 321 spirally arranged on the plane of the first housing 311, and the work The plane is characterized in that it is disposed perpendicular to the air flow direction. At this time, the flexible electrodes 321 are arranged in a spiral form with respect to the dielectric electrodes adjacent to each other in the radial direction at regular intervals. In addition, a plurality of protrusions 311b may be included on one plane of the first housing 311, and a plurality of protrusions 311b of a predetermined bundle are arranged in a row on each stem for a plurality of stems arranged in a radial form. In other words, it may include a plurality of protrusions 311b arranged radially at regular intervals. In one embodiment of the present invention, the first housing 311 may have a shape including a hexagonal flat surface, and a plurality of protrusions 311b may be radially arranged at each vertex of the hexagon. Accordingly, the flexible electrode 321 may be formed in the sterilization module unit 300 in a spiral arrangement while being sequentially caught on each of the protrusions 311b. Therefore, the flexible electrodes 321 are arranged spirally at intervals on one plane of the first housing 311 by the protrusions 311b, so that the flexible electrodes 321 and the air pass through the area. can be formed to a maximum, so that the efficiency of sterilization can be maximized when the plasma module 320 performs plasma discharge and sterilizes air. In addition, by configuring the plasma module 320 with the flexible electrode 321, the shape of the plasma device can be easily changed or miniaturized, thereby providing a highly efficient sterilization effect compared to the same area of the device. 320 has an advantage in that it is easy to configure the device because plasma discharge is possible using atmospheric pressure without a separate discharge gas supply.

6 and 7, the plasma module 320 of the present invention, in the flexible electrode 321, may be in the form of a wire composed of a dielectric 321b barrier discharge (DBD) method. . In more detail, the flexible electrode 321 includes a first electrode 321a formed in an axial shape and a dielectric material 321b having a concentric circle with the first electrode 321a and surrounding the first electrode 321a. and a second electrode 321c formed in contact with an outer circumferential surface of the dielectric 321b. At this time, it is preferable that at least one of the first electrode 321a, the second electrode 321c, and the dielectric 321b is formed of a flexible material and configured as a flexible electrode 321 capable of changing its shape. do. In addition, in the flexible electrode 321, the dielectric material 321b is positioned between the first electrode 321a and the second electrode 321c so that the first electrode 321a and the second electrode 321c are connected to each other. Preferably, it is configured to be insulated, and a high voltage is applied to the first electrode 321a, and the second electrode 321c may be a ground electrode. The first electrode 321a serves as a central axis of the flexible electrode 321 and may be formed in the form of an inner line having a predetermined diameter. At this time, the first electrode 321a may be tin or stainless (SUS), and may be formed of tin in an embodiment of the present invention. The dielectric 321b is formed to entirely cover the outer surface of the first electrode 321a, and is provided to insulate the first electrode 321a from the second electrode 321c. In this case, the dielectric 321b may be made of at least one material selected from among Teflon, silicon, and glass fiber. In the case of silicon, it is made of heat-resistant silicon to withstand high temperatures. The second electrode 321c is formed in contact with the outer circumferential surface of the dielectric 321b, and is preferably formed to emit plasma as it serves as a ground electrode. Accordingly, the second electrode 321c may be formed in the form of a bundle in which a plurality of predetermined wires are adjacently coupled, and the bundle may be formed in a plurality and arranged in a grid pattern on the outer surface of the dielectric 321b. there is. That is, a bundle of the plurality of second electrodes 321c is arranged in a grid on the outer circumferential surface of the dielectric 321b, so that the plasma emitted to the outside of the second electrode 321c is sterilized by contact with air. to be In this case, the second electrode 321c may be tin or stainless (SUS), and may be stainless in an embodiment of the present invention.

As shown in FIGS. 3, 8 and 9, the sterilization module unit 300 of the present invention further includes an ultraviolet module 330 including at least one UV LED 331 in the housing 310 to accommodate characterized by The ultraviolet module 330 is for sterilizing the air inside the device using ultraviolet rays generated by the UV LED 331, and may be accommodated and disposed together in the housing 310 in which the plasma module 320 is accommodated. In one embodiment of the present invention, the housing 310 may further include a second housing 312 formed in a form corresponding to the first housing 311 and including one plane, The first housing 311 and the second housing 312 may face each other and be combined, and the ultraviolet module 330 is disposed in the second housing 312, and the ultraviolet module 330 is the sterilizing agent. It can be accommodated in the module unit 300 . In this case, the UV LED 331 may be an LED that forms a wavelength of UV-C. In one embodiment of the present invention, the second housing 312 may be formed in a hexagonal shape on one flat surface, and the UV module 330 may include a plurality of UV-LEDs 331, so that the flat surface At least one UV-LED 331 may be disposed on each side. The second housing 312 is preferably disposed adjacent to the first housing 311, and may be disposed at the rear end of the first housing 311 according to the air flow direction. That is, the ultraviolet module 330 is discharged so that the air introduced into the device through the inlet 110 passes through the plasma module 320 to perform plasma sterilization and then passes through the ultraviolet module 330. (120) side. Therefore, in the air decomposed and sterilized through the plasma module 320, the air is sterilized once more using ultraviolet rays generated by the UV-LED 331 for the remaining impurities, thereby sterilizing the same area. It is possible to provide a device with a maximized effect.

When the housing 310 is composed of the first housing 311 and the second housing 312 and is engaged and coupled to each other, the first housing 311 is disposed on the side of the inlet 110 of the device, and the 2 The housing 312 is disposed on the side of the outlet 120 of the device, so that the air flowing into the device first passes through the plasma module 320 and then passes through the ultraviolet module 330 to sterilize the air. characterized by being At this time, the first housing 311 and the second housing 312, as shown in Figs. 4 and 8, include a flat surface in a form corresponding to each other, and each of them has a vertical direction along the edge of the flat surface. It is formed to extend, and the cross section in a direction perpendicular to the one plane may be formed in a ∪ or ∩ shape. Accordingly, the first housing 311 and the second housing 312 are coupled so that their extended corners come into contact with each other, thereby forming a space inside, and each flexible electrode 321 and UV-LED are accommodated in each formed space. In addition, a power supply unit 311a for supplying power to each of the flexible electrode 321 and the UV-LED may be arranged to increase the configuration efficiency of the device. In addition, as shown in FIGS. 4, 5, 8 and 9, the first housing 311 and the second housing 312 may include at least one through hole 311c or 312a having a predetermined area on each surface. And, air may be introduced into the sterilization module unit 300 through the through holes 311c and 312a, or sterilized air may be discharged. At this time, the through-holes 311c and 312a may be formed in the first housing 311 more than the second housing 312, and the through-holes 311c, 312a) may be formed, which is to increase the efficiency of the ultraviolet module 330 that performs sterilization by irradiating ultraviolet light. That is, the first housing 311 and the second housing 312 are arranged to face each other and arranged on one plane, so that the air to be sterilized can pass through the plasma over a wider area, There is an advantage in providing the maximum sterilization effect compared to the area by configuring to generate as many active species as possible and then sterilizing the air once more by passing the ultraviolet module 330 therethrough.

Referring to FIG. 1 , the present invention may further include an belongings sterilization unit 400 formed in a predetermined area on the frame 10 of the device and capable of sterilizing belongings. The belongings sterilization unit 400 may be provided with a predetermined area on the frame 10, form a space inside the frame 10, and open and close the space by opening and closing the door. can be formed as Therefore, after opening the door, inserting belongings into the inner space, and closing the door, the sterilization device formed inside may be processed to sterilize the belongings accommodated in the space. At this time, the belongings sterilization unit 400 may be configured to perform ultraviolet sterilization using UV-LEDs, and at least one UV-LED is provided in the space so that the UV-LEDs generate ultraviolet rays for a predetermined time. You can sterilize your belongings. At this time, the UV-LED may generate UV-C. The belongings sterilization unit 400, as an embodiment of the present invention, may be formed in a drawer shape, may be located on the lower side of the frame 10 of the device, and a UV-LED provided inside the drawer. may be a configuration that interlocks with the ultraviolet module 330 or may be provided as a separate configuration. Also, in another embodiment, the belongings sterilization unit 400 may be formed in a drawer shape communicating with the inside of the device. It may be configured to communicate to the inside of the ultraviolet module 330. Therefore, by putting belongings in the belongings sterilization unit 400 in advance, and when the ultraviolet module 330 is operated, the belongings put in the belongings sterilization unit 400 are irradiated with ultraviolet rays, so that the belongings are also sterilized together. .

As described above, the present invention has been described with specific details such as specific components and limited embodiment drawings, but this is only provided to help a more general understanding of the present invention, and the present invention is not limited to the above embodiment. No, and those skilled in the art to which the present invention pertains can make various modifications and variations from these descriptions.

Therefore, the spirit of the present invention should not be limited to the described embodiments, and not only the scope of the claims described later, but also all modifications equivalent or equivalent to the scope of the claims belong to the scope of the scope of the present invention. .

10 : frame
110: inlet 120: outlet
130: fan
200: filter 210: first filter
220: second filter
300: sterilization module unit 310: housing
320: plasma module

Claims (15)

an inlet through which external air is introduced into the device;
an outlet through which the air inside the device is discharged to the outside;
a fan provided inside the device to allow air to pass through the inlet and the outlet by operation to form a flow of air inside the device;
at least one filter disposed between the inlet and the outlet; and
It is disposed between the inlet and the outlet, and is formed to include a hexagonal flat surface disposed in a direction perpendicular to the flow direction of the air formed by the fan, and the corner of the flat surface is formed extending in the vertical direction, A sterilization module unit provided in a housing including a first housing and a second housing having a ∪ or ∩ shape in cross section with respect to the flow direction of the air, facing each other and coupled to each other,
The first housing is disposed on the inlet side, the second housing is disposed on the outlet side, and at least one through hole having a predetermined area through which air passes is formed on each surface,
The sterilization unit module,
The first housing includes a first electrode formed in an axial shape, a dielectric concentric with the first electrode and formed to surround the first electrode, and a second electrode formed in contact with an outer circumferential surface of the dielectric. and a plasma module in which a flexible electrode made of a flexible material is spirally arranged on one plane of the first housing,
The second housing includes an ultraviolet module including a plurality of UV LEDs, and at least one UV LED is disposed on each side of one plane of the second housing.
delete According to claim 1,
The flexible electrode,
Air sterilization device, characterized in that the flexible electrodes adjacent in the radial direction have a predetermined distance from each other.
According to claim 3,
The first housing,
Including a plurality of projections arranged radially at regular intervals on the one plane,
Air sterilization device, characterized in that the flexible electrode is disposed while being hooked on the protrusion.
According to claim 4,
Air sterilization apparatus, characterized in that the plurality of projections are arranged at each vertex position of the plane.
delete delete delete delete According to claim 1,
The plasma module,
The second electrode is formed in plurality,
The air sterilization device, characterized in that in the form of a bundle in which predetermined second electrodes are coupled to each other, the bundle is arranged in a grid pattern on the outer circumferential surface of the dielectric.
According to claim 1,
The dielectric is an air sterilization device, characterized in that composed of at least one material of Teflon, silicon, glass fiber.
According to claim 1,
The second electrode is an air sterilization device, characterized in that SUS or tin material.
According to claim 1,
The filter,
A first filter composed of a pre-filter;
It consists of a second filter composed of a deodorizing filter,
An air sterilization device, characterized in that one plane of the first filter and the second filter is disposed in a direction parallel to the air flow direction inside the device.
According to claim 13,
The first filter and the second filter
Disposed on both sides of the sterilization module unit along the flow direction of the air,
The first filter is disposed on the inlet side,
The air sterilization apparatus, characterized in that the second filter is disposed on the outlet side.
According to claim 14,
The second filter,
An air sterilization device characterized in that it is a graphite filter of a coal gate method.

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