KR102427415B1 - sterilization deodorization system using the ozone and low temperature plasma photocatalyst - Google Patents

Abstract

The present invention relates to a sterilization deodorization system using ozone and low temperature plasma photocatalyst, in order to provide convenience of use by installing an ozone generating unit and an air sterilizing unit respectively inside a case, prevent UV rays from harmful UV lamps from being exposed to the outside, maximize sterilizing power by sufficiently increasing the contact time between the UV lamp and air, supply high-concentration oxygen required for ozone to generate more than four times more ozone than existing ozone products such that sterilization and deodorization effects are maximized, and filter fine dust and odors contained in the sterilized air so that a user can inhale clean air. The sterilization deodorization system using ozone and low temperature plasma photocatalyst includes the case, the ozone generating unit installed inside the case, the air sterilizing unit installed inside the case, and a control unit for controlling the operations of the ozone generating unit and air sterilizing unit.

Description

Sterilization deodorization system using the ozone and low temperature plasma photocatalyst

The present invention relates to a sterilization and deodorization system using ozone and a low-temperature plasma photocatalyst, and more particularly, an ozone generator and an air sterilizer for sterilizing and deodorizing air are installed in one case to sterilize and deodorize air, and it can be obtained at the same time In addition, the air sterilized through the air sterilization device is exhausted with fine dust and odors removed through the filter unit, and at the same time, the ozone sprayed through the ozone generator is sprayed into the human body at dawn when no one is indoors. It relates to a sterilization and deodorization system using ozone and low-temperature plasma photocatalyst that does not interfere.

In general, the indoor air used by humans contains various viruses, bacteria and fine dust, and if a person inhales such polluted air, he or she can become infected with diseases such as pneumonia or Corona 19. There is a trend to use an air sterilizer equipped to sterilize the air.

Conventional air sterilizers are mainly used to sterilize air with UV rays generated from UV lamps, or to sterilize and deodorize air with ozone generated from ozone generators.

Here, since the conventionally used ultraviolet lamp mainly uses ultraviolet (UV-C), which has the shortest wavelength of 280 nm to 100 nm, exposure to the human body can cause burns, skin cancer, and cataracts. Although the lamp has a high effect of sterilizing the air, there is a problem in that it is not effective in removing odors, so its use is limited in places for deodorization.

On the other hand, the conventional ozone generator is a strong oxidizing agent that is excellent for removing unpleasant odors and smells, but when the ozone concentration is high, it can harm the human body due to strong oxidation, so special attention is required for use.

That is, the ultraviolet and ozone are excellent for sterilization and odor removal, but there is a problem in use and handling, so that they can only be used individually.

As an example of the prior art that solves these problems and enables the simultaneous use of ultraviolet and ozone, Utility Model Registration No. 0182607 (name: sterilization and deodorizer using ultraviolet and ozone) has been disclosed. A lamp is mounted in a case of a predetermined volume, a blowing fan for forcibly introducing air is installed at one end of the case, and a filtering net for filtering foreign substances in the incoming air is installed at the other end of the case to blow the air. Bacterial components in the air introduced by the fan are sterilized by the ultraviolet and ozone emitted from the ultraviolet lamp and the ozone lamp, respectively, and the odor is removed and then discharged. It was configured to be selectively operated according to the mode set by the control panel by providing a control panel for driving the control panel.

However, the prior art sterilization deodorizer using ultraviolet rays and ozone has a problem in that the air introduced into the case is not sufficiently sterilized by the operation of the blower fan and is forcibly exhausted quickly, thereby weakening the sterilization power.

In addition, in order to generate ozone normally, ozone is generated with oxygen (purity of 21%) in the air, so there is a problem in that it is difficult to expect sterilization and deodorization effects using general air.

In addition, the prior art has a purpose of sterilizing viruses and bacteria contained in the air, but there is a problem that the objective of complete air sterilization cannot be achieved because foreign substances such as fine dust cannot be filtered out.

The present invention has been devised to solve the above problems, and provides convenience of use by installing an ozone generating unit and an air sterilizing unit inside the case, respectively, and also exposing the ultraviolet light of the ultraviolet lamp harmful to the human body to the outside. At the same time, it maximizes the sterilization power by sufficiently increasing the contact time between the UV lamp and the air, and at the same time supplies high-concentration oxygen required for ozone to generate ozone 4 times more than that of existing ozone products, maximizing the sterilization and deodorization effect, and It is to provide a sterilization and deodorization system using ozone and low-temperature plasma photocatalyst that allows users to inhale clean air by filtering fine dust and odors contained in the air.

The present invention is configured as follows in order to achieve the above object. That is, by installing the dividing plate in the transverse direction inside, an ozone installation space is formed on the lower side, a sterilization installation space is formed on the upper side, an intake hole through which air flows into the lower part is formed, and the upper front edge is curved. , an air injection hole is formed in the front and curved corners of the sterilization installation space so that the air sterilized in the sterilization installation space is sprayed in a fan shape in front, and an ozone injection hole is formed in the center of the front to spray ozone generated in the ozone installation space. In the case, the support part is installed to support it, or the caster is installed to move it; an ozone generator installed in the ozone installation space to generate ozone for sterilizing and deodorizing air introduced into the interior through the intake hole and exhausting it through the ozone injection hole; an air sterilizer installed in the sterilization installation space to sterilize the air introduced into the interior through the intake hole and exhaust the air through the air injection hole; and a control unit for controlling the operation of the ozone generator and the air sterilizer.

In addition, the ozone generator includes a compressor for compressing the air introduced into the intake hole, a moisture removal filter for removing moisture from the compressed air supplied from the compressor, and air removed from the moisture removal filter to generate oxygen Oxygen generator, oxygen generated from the oxygen generator flows in to generate ozone, and an ozone generator that sprays the ozone through an ozone injection hole formed in the front of the case, and a moisture absorption pad for absorbing moisture filtered from the moisture removal filter characterized in that it is configured.

In addition, the air sterilization device is installed at the rear of the partition plate, an intake fan for sucking the air flowing into the intake hole into the sterilization installation space, and an ultraviolet lamp installed upright in the sterilization installation space to sterilize the air introduced by ultraviolet rays; , a photocatalyst coating filter fixed to the outer periphery of the UV lamp to improve sterilization in response to the light of the UV lamp, and a filter insertion hole communicating with the sterilization installation space on one side of the case corresponding to the front part of the UV lamp is formed , a HEPA filter that is inserted and separated into the filter insertion hole and removes fine dust from the air sterilized by the UV lamp; It is characterized in that it is arranged in a blower fan that forcibly sucks air passing through the filter unit and exhausts it to the outside through the air injection hole.

On the other hand, a sterilization pipe formed as a hollow to communicate with the intake fan, a UV lamp is inserted into the long upwardly formed inside, the air introduced through the intake fan is first sterilized with the UV lamp, and then exhausted in an open upward direction. and a first air flow disposed in a position spaced apart from the front of the sterilization pipe, and formed with a through-portion through which the air exhausted from the upper direction of the sterilization pipe exits to the front by opening both lower sides to delay the flow of air to increase the sterilization power The delay plate and the first air flow delay plate are disposed at a spaced apart position, and are divided into both sides with the center spaced apart to increase the sterilization power by delaying the flow of air, and a curved vortex portion formed concave on the inside A UV lamp is installed in the air passing through the penetrating part to generate a vortex for secondary sterilization, and the curved vortex part is inclined forward to form an inclined part for guiding the secondary sterilized air forward, and the inclined part A concave central vortex part is formed at one end, and ultraviolet lamps are installed inside the central vortex part divided into both sides, so that the air passing through the central vortex part is tertiarily sterilized with an ultraviolet lamp. characterized in that it is composed.

In addition, the lower part of the sterilization pipe is wide and gradually narrowed by a predetermined height, and an expansion part is formed to accommodate the air flowing in from the intake fan, and is formed on the inner circumferential surface of the sterilization pipe, and the introduced air causes an irregular vortex to generate ultraviolet rays. It is characterized in that it is composed of a plurality of vortex projections formed at a predetermined interval and height to increase the amount of contact with the lamp.

On the other hand, the control unit is characterized in that it consists of a timer installed to operate at a set time of the ozone generator and the air sterilizer, and a detection sensor installed on the outer surface of the case to automatically stop when the ozone generator detects a movement of a person during operation do it with

Furthermore, one side of a fixing bracket having an open bottom is fixed to the rear surface of the case, and is formed in a “∨” shape with an open top on the wall where the case is installed, and one end of the fixing bracket is inserted It is characterized in that it is composed of a wall bracket that can be hung and installed on the wall.

As described above, according to the present invention, by installing the ozone generator and the air sterilizer together inside the case, an excellent effect can be obtained for sterilizing air and removing odors, and fine dust contained in the air sterilized through the filter unit and It has the effect of maximizing sterilization and deodorization power as it can remove odors.

In addition, by installing an oxygen generator in the ozone generator, high-concentration oxygen with a purity of 90% or more can be supplied to the ozone generator to generate more than 4 times more ozone than existing products, and thus the sterilization power displayed at the same time is also 4 times or more. Powerful ozone has the effect of increasing sterilization and deodorization power.

In addition, by installing a photocatalytic coating filter that responds to the ultraviolet rays of the ultraviolet lamp, there is an effect of improving the air sterilization power.

In addition, by installing the sterilization pipe so that the ultraviolet lamp is inserted, the air sucked into the intake fan is in close contact with the ultraviolet rays generated from the ultraviolet lamp to improve the sterilization power.

In addition, by installing the first and second air flow delay plates, not only can the sterilization time be increased by delaying the air flow time, but also the UV lamps are arranged in three rows to reduce the moving air to the primary, secondary and tertiary stages. It has a sterilizing effect.

In addition, by configuring the filter unit with a HEPA filter and an activated carbon filter, there is an effect of supplying clean air by filtering out both fine dust and odors remaining in the sterilized air that has passed through the UV lamp.

In addition, by installing a blowing fan in front of the filter unit, there is an effect that the blowing fan forcibly sucks in the sterilized air and exhausts it to the outside in a situation in which the air is blocked by the filter unit and cannot escape or the moving speed is reduced.

In addition, the ozone generator has an effect of preventing the ozone harmful to the human body from coming into contact with the skin or being inhaled in advance by operating the ozone generator only in the early morning hours when there are no people indoors through the control unit.

In addition, it can be placed on the ground by installing a support part or caster on the bottom of the case, or is configured to be placed on a wall using a fixing bracket on the back of the case, so that the user can select and install it on the desired indoor place and on the ground or wall. can have an effect.

1 is a perspective view showing a sterilization and deodorization system using ozone and low-temperature plasma photocatalyst according to the present invention;
2 is a perspective view showing the inside of the sterilization and deodorization system using ozone and low-temperature plasma photocatalyst according to the present invention.
3 is a side cross-sectional view of a sterilization and deodorization system using ozone and low-temperature plasma photocatalyst according to the present invention;
4 is a plan cross-sectional view of a sterilization and deodorization system using ozone and low-temperature plasma photocatalyst according to the present invention;
5 is a side view of the sterilization and deodorization system using ozone and low-temperature plasma photocatalyst according to the present invention installed on the wall
6 is a schematic diagram showing the state of controlling the sterilization and deodorization system using ozone and low-temperature plasma photocatalyst according to the present invention
7 is a perspective view showing the inside in a state in which the first and second air flow delay plates are installed in the sterilization and deodorization system using ozone and low-temperature plasma photocatalyst according to the present invention;
8 is a perspective view showing a state in which air is sterilized while moving in the first and second air flow delay plates;
9 is a side cross-sectional view of a sterilization and deodorization system using ozone and low-temperature plasma photocatalysts installed with first and second air flow delay plates;
10 is a plan sectional view of a sterilization and deodorization system using ozone and low-temperature plasma photocatalyst installed with first and second air flow delay plates;
11 is a side cross-sectional view showing an enlarged view of a portion of the sterilization pipe in FIG. 9;

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

1 to 4 in the accompanying drawings, the present invention includes a case 100, an ozone generating device 200 installed inside the case 100, and an air sterilizing device installed inside the case 100. and a control unit 400 for controlling the operation of the ozone generator 200 and the air sterilizer 300 .

The case 100 is formed in a rectangular or circular shape formed upright, and a dividing plate 110 is installed in the transverse direction inside, and an ozone installation space 120 is formed in the lower part of the dividing plate 110, and the upper part A sterilization installation space 130 is formed in each.

In addition, a plurality of intake holes 140 are arranged in the lower portion of the case 100 to introduce external air into the ozone installation space 120 , and then an ozone generating device 200 and an air sterilizing device 300 to be described later. ) is configured to move air.

Here, the intake hole 140 is formed in the lower front and side of the case 100 is configured to secure the inflow of air.

In addition, a plurality of air injection holes 150 are arranged on the front surface and the curved edge portion of the front vertical edge portion of the case 100 in a curved state.

Therefore, when the air that has passed through the air sterilizer 300 is sprayed in all directions through the air injection holes 150 formed in the front and curved corners, it spreads widely in a fan shape and quickly spreads the sterilized air to every corner of the room. provided effects can be obtained.

In addition, the ozone injection hole 160 is arranged in the front central portion of the case 100, and is configured to spray ozone generated by the ozone generator 200 in all directions.

In addition, when supporting the case 100, a support unit 170 made of rubber or urethane is installed at four corners, or a caster 180 having wheels to move the case 100 freely is installed. can be

In addition, in order to install the case 100 on the wall (W), as shown in the attached drawing FIG. 5 , a fixing bracket 190 of a "∧" shape with an open lower part is fixed to the rear side of the case 100, and the installation A wall bracket 191 in the shape of "∨" with an open top is fixed to the wall W to be anchored with an anchor bolt.

Therefore, after one end of the fixing bracket 190 is inserted into the open part of the wall bracket 191, it is hung and installed on the indoor wall (W).

The ozone generator 200 is installed in the ozone installation space 120 as shown in the accompanying drawing 3, and generates ozone using the air introduced into the intake hole 140, and the intake hole 140. A compressor 210 for compressing the air introduced into the An oxygen generator 230 for generating oxygen by receiving air from which moisture has been removed is installed, and an ozone generator 240 for generating ozone by receiving high-concentration oxygen is installed, and the ozone generated in this way is formed on the front surface of the case 100 It is sprayed to the outside through the ozone injection hole 160 .

In addition, a trace amount of moisture filtered through the moisture removal filter 220 flows downward and is then installed to be absorbed and removed by the moisture absorption pad 250 .

The ozone generator 200 configured in this way can generate high-concentration oxygen with a purity of 90% or more through the oxygen generator 230 in a state of removing moisture from the air, and then generate ozone with the ozone generator 240 . Ozone, which is generated using oxygen that is four times higher than oxygen with a purity of 21%, can provide efficacy that is four times higher in sterilization and deodorization power.

Here, the ozone (O ₃₎ is generated by a chemical reaction of high-concentration oxygen (O ₂₎ by a silent discharge method, but when about 1 to 2 hours have elapsed, the ozone (O ₃₎ is converted to oxygen (O ₂₎ again.

Using this, as shown in the accompanying drawing 6, using the timer 410 configured in the control unit 400, the air is sterilized and deodorized by operating it until dawn, for example, from 3 am to 5 am when there are no people in the room. , it is configured so that oxygen beneficial to the human body can be inhaled in the morning when a person starts living indoors after time elapses.

In addition, there is a detection sensor 260 that detects the movement of the human body on the front of the case 100 and transmits the signal to the control unit so that the ozone generator 200 can automatically stop when a person is active at a set time for operation. is installed

Therefore, the ozone generator 200 can purify indoor air without people by using high sterilizing power and deodorizing power, and is beneficial to the human body during human life, for example, strengthening the immune system function and preventing arteriosclerosis, etc. It has an action effect that can provide high concentration oxygen with the efficacy of

The timer 410 of the control unit 00 configured as described above may be configured to set the operation of not only the ozone sterilizer 200 but also the air sterilizer 300 to provide convenience in use.

The air sterilization device 300 is installed in the sterilization installation space 130 formed on the upper side of the case 100, and is configured to maximize the sterilization power of the indoor air together with the ozone generator 200, the rear of the partition plate 110 The intake fan 310 is installed in the air intake hole 140 is configured to forcibly transfer the air to the sterilization installation space (130).

In addition, a plurality of ultraviolet lamps 320 are installed upright in the sterilization installation space 130, and a photocatalyst coating filter 330 coated with a photocatalyst that responds to ultraviolet rays is fixed on the outer periphery of the ultraviolet lamp 320. , is configured to strongly sterilize the air introduced into the intake fan 310 together with the ultraviolet lamp 320 .

In the photocatalytic coating filter 330, when light is irradiated to titanium dioxide (TiO ₂ ), holes from which electrons are released from the crystal surface react with water molecules to form hydroxy radicals having a very high oxidizing power, and organic compounds The sterilizing power of the photocatalyst coating filter 330 and the ultraviolet lamp 320 that oxidizes and decomposes the air is added, so that the air purification ability can be doubled.

In addition, the filter unit 340 is installed in front of the UV lamp 320, and the filter unit 340 is detachably provided through a filter insertion hole formed on one side of the case to replace or replace the filter unit 340. It is configured to be washable.

Here, the filter unit 340 includes a HEPA filter 341 that filters out foreign substances such as fine dust contained in the air sterilized by the UV lamp 320, and the HEPA filter 341 is disposed in front of the sterilized air. It consists of an activated carbon filter 342 that removes the contained odor.

Accordingly, the air that has passed through the ultraviolet lamp 320 and the filter unit 340 can provide clean sterilization air in a state in which fine dust and odors are removed as well as sterilization.

In addition, in the process of air passing through the sea wave filter 341 and the activated carbon filter 342, the air is blocked by fine holes and the transport speed is slowed, and this problem also affects the output exhausted to the air injection hole 150. It is difficult to spray sterilized air to a long distance indoors.

To solve this, a blower fan 350 is installed in front of the filter unit 340 to suck in the sterilized air and forcibly spray it into the air injection hole 150 .

Here, the blowing fan 350 is installed on both sides of the inner curved edge of the case 100, respectively. The reason for this is that when the blower fan 350 is disposed in the center, the pressure of the curved edge portion is relatively lower than the center, so it is not possible to provide an output reaching a long distance, but when the blowing fan 350 is installed on both sides, the curved edge part This is because the high pressure of the air can affect the output in the central part to increase the injection output efficiency, and thereby spread the sterilized air to a long distance in the room.

On the other hand, it will be apparent that the air sterilized by the air sterilization device 300 exhibits a higher sterilization power as the contact time and contact area with the ultraviolet lamp 320 are longer and wider.

To this end, as shown in the accompanying drawings 7 to 10, a sterilization pipe 360 formed in a hollow directly above the intake fan 310 is provided so that the contact time and area between the ultraviolet lamp 320 and the air is increased. It is installed upright at a height of , and the ultraviolet lamp 320 is inserted into the open upper part of the sterilization pipe 360 to perform primary sterilization.

With this configuration, the air sucked in through the intake fan 310 flows into the sterilization pipe 360 and comes into close contact with the ultraviolet lamp 320 at the same time to increase the sterilization effect.

That is, if the UV lamps 320 are installed at a predetermined interval, the air located at the interval is relatively far from the UV lamp 320 and therefore does not have the effect of UV light with a short wavelength, but is not affected by the sterilization pipe 360 . As the introduced air is positioned close to the UV lamp 320 without leaving the outside, the effect of UV light is transmitted as it is, thereby exhibiting high sterilization power.

In addition, a first air flow delay plate 370 is installed at a position spaced apart from the front of the sterilization pipe 360, and the first air flow delay plate 370 has through portions 371 formed in lower portions of both sides, respectively. As a result, a small amount of air can be moved forward to the through portion 371, so the UV lamp 320 and the through portion 371 installed in the rear of the sterilization installation space 130 where the sterilization pipe 360 is located. It is configured so that the air that is not escaped and is delayed can be continuously sterilized.

In addition, a second air flow delay plate 380 is installed at a position spaced apart from the first air flow delay plate 370 in the front, and the second air flow delay plate 380 is divided and spaced apart from the center of the partition plate. (110) is installed on both sides of the upper surface, respectively.

In addition, a concave curved vortex portion 381 is formed on the inner surface of the second air flow delay plate 380 , that is, a surface corresponding to the through portion 371 , and a photocatalytic coating is applied to the curved vortex portion 381 . The UV lamp 320 to which the filter 330 is fixed is installed upright.

In addition, an inclined portion 382 inclined forwardly is formed at one end of the curved vortex portion 381 , and a concave central vortex portion 383 is formed at one end of the inclined portion 382 .

Therefore, the center of the second air flow delay plate 380 divided in the center is secured with a circular space by the central vortex portion 383 formed to be concave, and photocatalytic coating is applied to the space of the central vortex portion 383 secured in this way. The UV lamp 320 to which the filter 330 is fixed is installed upright.

When the air that has passed through the through part 371 configured in this way flows into the second air flow delay plate 380, it is guided to the curved vortex part 381 and vortexed the UV lamp 320 like a whirlwind after secondary sterilization, In the state guided forward along the inclined portion 382 inclined forward, a vortex is generated again in the relatively narrow central vortex portion 383 , and it is closely attached to the UV lamp 320 to perform tertiary sterilization.

That is, the time for the air introduced into the intake fan 310 to exit to the air injection hole 150 by the first air flow delay plate 370 and the second air flow delay plate 380 is delayed, so that the ultraviolet lamp ( 320) can be sufficiently increased, and the air can be completely sterilized sequentially by primary, secondary and tertiary by using the ultraviolet lamps 320 arranged in three rows, respectively.

Furthermore, as shown in the accompanying drawings, the lower portion of the sterilization pipe 360 has a large area and a predetermined height, so that the air introduced in the state that accommodates the intake fan 310 having a relatively large area is discharged to the outside. The expansion pipe 361 is formed so as not to go out.

In addition, a plurality of vortex projections 362 convexly protruding at a predetermined interval and height are formed on the inner periphery of the sterilization pipe 360 , and when the air sucked into the intake fan 310 moves upward, the vortex projections It collides with the 362 and causes an irregular vortex to increase the close force with the UV lamp 320 .

The control unit 400 is electrically connected to the ozone generator 200 and the air sterilizer 300 to control the operation, and as described above, by using the timer 410 to operate only for a time set by the user. , it is configured to prevent contact with ozone, which is harmful to the human body.

In the present invention configured as described above, by installing the ozone generating device 200 and the air sterilizing device 300 inside the case 100 , it is possible to simultaneously provide sterilization and deodorization of air, and also in the oxygen generator 230 . Oxygen with high purity generated can increase the sterilization and deodorization power by generating a relatively large amount of ozone. In addition, the ozone generation time can be controlled to prevent harm to the human body, and also the first and second airflows. With the retardation plates 370 and 380, it is possible to sufficiently sterilize the extended contact time between ultraviolet rays and air, and it is possible to provide clean air by removing fine dust and odors contained in the sterilized air through the filter unit 340. there will be

The present invention is not limited to the above-described embodiments and can be implemented with various modifications within the scope permitted by the technical idea of the present invention.

Case: 100 Divider: 110
Ozone installation space: 120 Sterilization installation space: 130
Intake hole: 140 Air injection hole: 150
Ozone injection hole: 160 Support part: 170
Caster: 180 Fixing bracket: 190
Wall bracket: 191 Ozone generator: 200
Compressor: 210 Water removal filter: 220
Oxygen generator: 230 Ozone generator: 240
Moisture absorption pad: 250 Detection sensor: 260
Air sterilizer: 300 Intake fan: 310
UV lamp: 320 Photocatalyst coating filter: 330
Filter unit: 340 HEPA filter: 341
Activated carbon filter: 342 Blowing fan: 350
Sterilization pipe: 360 Expansion part: 361
Vortex projection: 362 First air flow delay plate: 370
Penetration: 371 Second airflow delay plate: 380
Curved vortex part: 381 Inclined part: 382
Central vortex part: 383 Control part: 400
Timer: 410

Claims (7)

An ozone installation space 120 is formed on the lower side by installing the dividing plate 110 in the horizontal direction, a sterilization installation space 130 is formed on the upper side, and an intake hole 140 through which air is introduced into the lower side. This is formed, and the upper front edge is curved, and the air injection hole 150 is formed so that the air sterilized in the sterilization installation space 130 is sprayed in the front in a fan shape on the front and the curved edge part, and in the center of the front An ozone injection hole 160 for spraying ozone generated in the ozone installation space 160 is formed, and a support unit 170 is installed and supported on the lower surface, or a caster 180 is installed to allow movement of the case 100 );
an ozone generator 200 installed in the ozone installation space 120 to generate ozone that sterilizes and deodorizes air introduced into the interior through the intake hole 140 and sprays it into the ozone injection hole 160;
an air sterilizer 300 installed in the sterilization installation space 130 to sterilize the air introduced into the interior through the intake hole 140 and spray it into the air injection hole 150;
A control unit 400 for controlling the operation of the ozone generating device 200 and the air sterilizing device 300;
The air sterilization device 300 is installed behind the partition plate 110, and the intake fan 310 for sucking the air flowing into the intake hole 140 into the sterilization installation space 130,
An ultraviolet lamp 320 that is installed upright in the sterilization installation space 130 and sterilizes the air introduced by ultraviolet rays;
a photocatalyst coating filter 330 fixed to the outer periphery of the ultraviolet lamp 320 and improving sterilization power in response to the light of the ultraviolet lamp 320;
A filter insertion hole communicating with the sterilization installation space 130 is formed on one side of the case 100 corresponding to the front part of the UV lamp 320, and is inserted and separated into the filter insertion hole, and in the UV lamp 320 A filter unit 340 comprising a HEPA filter 341 for removing fine dust in the sterilized air, and an activated carbon filter 342 installed in front of the HEPA filter 341 to deodorize odors;
It is disposed in front of the filter unit 340, and forcibly sucks air passing through the filter unit 340, and consists of a blower fan 350 that ejects the air through the air injection hole 150 to the outside,
Formed hollow to communicate with the intake fan 310, the ultraviolet lamp 320 is inserted into the long upwardly formed inside, and the air introduced through the intake fan 310 is first sterilized with the ultraviolet lamp 320. , and a sterilization pipe 360 that exhausts in an open upward direction,
The sterilization pipe 360 is disposed in a position spaced apart from the front, and the lower part of both sides is opened to delay the flow of air to increase the sterilization power, so that the air exhausted from the upper direction of the sterilization pipe 360 exits to the front ( 371) is formed with a first air flow delay plate 370, and,
The first air flow delay plate 370 is disposed in a spaced position from the front, and is divided into both sides with the center spaced apart to increase the sterilization power by delaying the flow of air, and a curved vortex portion formed concave on the inside ( 381), the ultraviolet lamp 320 is installed, the air passing through the penetrating portion 371 generates a vortex for secondary sterilization, and the curved vortex portion 381 is formed to be inclined forward, and the secondary sterilized air is sterilized. An inclined portion 382 guiding forward is formed, and a concave central vortex portion 383 is formed at one end of the inclined portion 382, and the central vortex portion 383 divided into both sides is inside the UV lamp. Ozone and low-temperature plasma photocatalyst, characterized in that it is installed and consists of a second air flow delay plate 380 that tertiarily sterilizes the air passing through the central vortex part 383 with an ultraviolet lamp 320. Sterilization and deodorization system using.



The method of claim 1,
The ozone generator 200 is
A compressor 210 for compressing the air introduced into the intake hole 140, and
a water removal filter 220 for removing moisture from the compressed air supplied from the compressor 210;
an oxygen generator 230 for generating oxygen by introducing the air removed from the moisture removal filter 220;
Oxygen generated from the oxygen generator 230 flows in to generate ozone, and then the ozone generator 240 injects the ozone into the ozone injection hole 160 formed in the front surface of the case 100;
A sterilization and deodorization system using ozone and low-temperature plasma photocatalyst, characterized in that the moisture absorption pad 250 is configured to absorb the moisture filtered from the moisture removal filter 220.
delete delete The method of claim 1,
The sterilization pipe 360 has a wide lower portion and is gradually narrowed by a predetermined height, and an expansion pipe 361 formed to receive air introduced from the intake fan 310,
It is formed on the inner circumferential surface of the sterilization pipe 360, and the introduced air causes an irregular vortex to increase the amount of contact with the UV lamp 320. A sterilization and deodorization system using ozone and low-temperature plasma photocatalyst.
The method of claim 1,
The control unit 400 is provided with a timer 410 installed to operate at a set time of the ozone generator 200 and the air sterilizer 300,
The ozone generator 200 is composed of a detection sensor 260 installed on the outer surface of the case 100 so as to transmit a signal that detects the movement of a person during operation to the control unit 400,
The set time of the ozone generator 200 is set to operate from 3 am to 5 am when there is no person in the room, and when the detection sensor 260 detects the movement of a person during operation, the signal is sent to the control unit 400 A sterilization and deodorization system using ozone and low-temperature plasma photocatalyst, characterized in that it is transferred to stop the ozone generator 200.
The method of claim 1,
One surface of the fixing bracket 190 of the "∧" shape with an open lower part is fixed to the rear surface of the case 100,
A wall bracket (W) on which the case 100 is installed is formed in a “∨” shape with an open top, and one end of the fixing bracket 190 is inserted and hung to be installed on the wall W (W). 191), a sterilization and deodorization system using ozone and low-temperature plasma photocatalyst.

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