KR102594271B1 - Air pollutant decomposition and sterilization device - Google Patents

Abstract

The present invention relates to a device for decomposing and sterilizing air pollutants, comprising: a casing unit 100 equipped with a controller 110; A filter unit 200 that receives indoor air or outdoor air, separates contaminants contained in the introduced indoor air or outdoor air, and discharges them to the top; and a plurality of first and second photocatalyst filters 302, 304 and a plurality of light dissipating members 306, which are mounted on the upper part of the filter unit 200 and sterilize the filtered air, and the plurality of first and It is characterized in that it includes a sterilization unit 300 including a photocatalyst sheet 305 attached to the second photocatalyst filters 302 and 304.

Description

Air pollutant decomposition and sterilization device}

The present invention relates to a device for decomposing and sterilizing air pollutants, and more specifically, to separate, decompose, and sterilize pollutants contained in indoor air so that the air quality of indoor air can always be maintained in a comfortable state. By exhausting outdoor air indoors to create a positive pressure in the indoor space, the differential pressure between indoors and outdoors decomposes air pollutants, blocking the inflow of harmful substances such as outdoor bacteria, viruses, fine dust, and radon. and sterilization devices.

In general, modern people live indoors most of the day, so they are inevitably vulnerable to indoor air pollution. According to the World Health Organization's experimental results, the risk of infection increases by up to 40% when the building is not ventilated, so various ventilation devices are being released to manage indoor air, especially bacteria, viruses, mold, harmful gases, Ventilation devices using photocatalytic filters are being released to remove various air pollutants such as bad odors.

For example, in Korean Patent Publication No. 10-2019-0082343, in the indoor ventilation system, the indoor ventilation system is installed in a room with a hallway, and the indoor ventilation system sucks in external air in the hallway to remove pollutants. An outside air inlet that supplies the removed outside air into the room; an internal air discharge unit that discharges the indoor polluted internal air to the outside; sensor unit; and a central control device connected to the sensor unit, wherein the measured value detected by the sensor unit is transmitted to the central control device, and the external air inlet and internal air outlet are automatically controlled by commands from the central control device. An indoor ventilation system using hallway air, characterized by including a demand control system, has been published.

However, according to the above-mentioned prior art literature, it simply discharges indoor air to the outside, and is installed in a place where air circulation is easy, such as a hallway. Even if internal air is discharged, it is limited to the area around the internal air discharge part. Since only air in a narrow spatial range can be discharged, there is a problem in that the efficiency of indoor air management is significantly reduced.

In addition, in the case of photocatalytic filters applied to ventilation devices, not only are their structures complex, but their efficiency in decomposing and removing harmful substances contained in indoor air is significantly reduced.

The background or prior art described herein is only intended to help understand the technical significance of the present invention, and does not mean technology that is widely known in the technical field to which this invention belongs before the application of the present invention.

Republic of Korea Patent Publication No. 10-2019-0082343

In order to solve this problem, the present invention was created based on the above-mentioned background technology, and the pollutants contained in indoor air are separated, decomposed, and sterilized to be exhausted, thereby maintaining the indoor air quality in a comfortable state at all times. The purpose is to provide a device for decomposing and sterilizing air pollutants.

In addition, the present invention exhausts outdoor air indoors to create a positive pressure in the indoor space, thereby blocking the inflow of harmful substances such as outdoor bacteria, viruses, fine dust, and radon due to the differential pressure between the indoor and outdoor spaces. The purpose is to provide a device for decomposing and sterilizing pollutants.

In addition, the present invention improves the contact area and contact time between indoor air from which pollutants are separated or introduced outdoor air and a photocatalyst filter, thereby decomposing air pollutants and maximizing the sterilization efficiency of the indoor air or outdoor air. The purpose is to provide a sterilization device.

In addition, the present invention allows the oxygen saturation in the indoor space to be maintained at a constant level by adjusting the amount of purified air exhausted, as well as increasing the partial pressure of oxygen in the indoor space, thereby ensuring smooth oxygenation. The purpose is to provide a device for decomposing and sterilizing air pollutants that can be supplied.

However, the purpose of the present invention is not limited to this, and of course, even if not explicitly mentioned, purposes or effects that can be understood from the means of solving the problem or the embodiment are also included.

According to an embodiment of the present invention for achieving this problem, a casing unit 100 provided with a controller 110; A filter unit 200 that receives indoor air or outdoor air, separates contaminants contained in the introduced indoor air or outdoor air, and discharges them to the top; and a plurality of first and second units mounted on the upper part of the filter unit 200, formed with a plurality of passage holes to allow filtered air to pass through, and coated with a photocatalyst component to ensure sterilization and movement of the filtered air passing through. A sterilizing unit 300 including second photocatalyst filters 302 and 304 and a plurality of light emitting members 306 that emit UVA or visible light to the first and second photocatalyst filters 302 and 304; It is characterized by including.

According to one embodiment of the present invention, the filter unit 200 includes a HEPA filter 202; A filter fixture 210 on which the lower surface of the HEPA filter 202 is seated; The upper surface of the HEPA filter 202 is closely attached and fixed, and an air outlet 222 is in communication with the intake fan 308 to allow filtered indoor air or outdoor air to flow into the sterilizing unit 300. Formed connection frame portion 220; Outdoor air supply means 270 for supplying the outdoor air; An outdoor air supply frame 260 is coupled to the connection frame portion 220 and configured on the outer peripheral surface of the HEPA filter 202, and is connected to the outdoor air supply means 270 to supply the outdoor air to the HEPA filter 202. ); It is characterized in that it includes a filter cover 240 configured to surround the HEPA filter 202.

According to one embodiment of the present invention, the outside air supply frame 260 is detachably coupled to the connection frame portion 220 and has an outside air supply port 264 connected to the outside air supply means 270. A support panel 262 and a mesh panel 266 coupled to the inner surface of the supply support panel 262 at a predetermined interval and guiding the outdoor air to be distributed and pass through the outer peripheral surface of the HEPA filter 202. and a filtration filter 268 configured between the mesh panel 266 and the HEPA filter 202 to filter the outdoor air.

According to one embodiment of the present invention, the sterilizing unit 300 further includes a photocatalyst sheet 305 attached to the plurality of first and second photocatalyst filters 302 and 304.

According to one embodiment of the present invention, the photocatalyst sheet 305 has an upper surface of the photocatalyst filter forming a predetermined slope outward from the center of the sterilizing unit 300 among the plurality of first photocatalyst filters 302. It is configured to be attached to the photocatalyst filter, which forms a predetermined inclined surface from the outside to the center of the sterilizing unit 300, and is configured to be attached to the lower surface.

According to one embodiment of the present invention, the sterilizing unit 300 includes a fan mounting unit 310 provided with an intake fan 308 for sucking in filtered air; A first filter support pipe 322 forming an outer surface to guide the movement of filtered air sucked in by the intake fan 308, and a second filter support pipe formed inside the first filter support pipe 322 ( 324) and a third filter support pipe 326, which is formed inside the second filter support pipe 324 and has an exhaust hole 328, and the first and second filter support pipes 322 , 324), a first air movement path 323 on which the first photocatalyst filter 302 is mounted, and a second air passage 323 on which the second photocatalyst filter 304 is mounted on an oblique side of the second and third filter support pipes. Filter support means 320 forming an air movement path 325; a filter fixing means (330) to which the upper end of the filter support means (320) is coupled and an exhaust fan (350) for exhausting sterilized air is mounted; It is configured inside the exhaust hole 328 and includes an exhaust control means 370 on which the light dissipating member 306 is mounted on the outer peripheral surface.

According to one embodiment of the present invention, the fan mounting part 310 includes an air discharge hole 312 that discharges the air sucked in from the intake fan 308 toward the first photocatalyst filter 302, and the air discharge hole ( A guide panel 314 that guides the air flowing in through 312) to move toward the first air movement path 323, and whether the air discharge hole 312 is opened or closed and is configured on the guide panel 314, and It is characterized by including an opening and closing damper 316 to control the opening and closing amount.

According to one embodiment of the present invention, the sterilizing unit 300 is equipped with the first and second photocatalyst filters 302 and 304, a filter support means 320, and an exhaust control means 370, and the fan It is characterized in that it further includes a blocking frame 360 configured to allow filtered air flowing into the mounting unit 310 to flow only into the first air movement path 323.

According to one embodiment of the present invention, the exhaust control means 370 is configured inside the exhaust hole 328 to control whether the exhaust hole 328 is opened and closed and the amount of opening and closing, and the lower end is the blocking frame. It is coupled to (360) and electrically connected to the controller 110, and the central control shaft 372 is coupled to the central control shaft 372, and rotates by a certain angle under the control of the controller 110. It is characterized in that an exhaust volume control member 374 is further configured to open and close the exhaust hole 328 while moving.

According to one embodiment of the present invention, the displacement control member 374 includes an adjustment body whose outer peripheral surface is coupled to the inner peripheral surface of the third filter support pipe 326, and is rotatably connected to the adjustment body, and the central control shaft. A plurality of control panels 378 are connected to the rotating means configured inside the 372 to open and close the exhaust hole 328, and are provided on the upper part of the plurality of control panels 378, through which the exhausted air passes. It is characterized by being composed of a perforated plate 376 on which an air passage hole is formed and a photocatalyst component is coated.

According to one embodiment of the present invention, the light dissipating member 306 is mounted on the first and second photocatalytic filters 302 and 304.

According to this embodiment of the present invention, the contaminants contained in indoor air are separated, decomposed, and sterilized to be exhausted, thereby achieving the effect of maintaining pleasant indoor air quality at all times.

In addition, according to an embodiment of the present invention, outdoor air is exhausted indoors to create a positive pressure in the indoor space, so that harmful substances such as outdoor bacteria, viruses, fine dust, and radon are introduced due to the differential pressure between the indoor and outdoor spaces. It has the effect of blocking something from happening.

In addition, according to an embodiment of the present invention, the sterilization efficiency of indoor air or outdoor air can be maximized by improving the contact area and contact time between indoor air from which contaminants are separated or introduced outdoor air and the photocatalyst filter. It works.

In addition, according to an embodiment of the present invention, by adjusting the amount of purified air exhausted, the oxygen saturation in the indoor space can be maintained at a constant level and the partial pressure of oxygen in the indoor space can be maintained at a constant level. This has the effect of enabling a smooth supply of oxygen.

In addition, the various and beneficial advantages and effects of the present invention are not limited to the above-described content, and may be more easily understood in the process of explaining specific embodiments of the present invention.

1 and 2 are perspective views showing an air pollutant decomposition and sterilization device according to an embodiment of the present invention;
Figure 3 is a side view showing an air pollutant decomposition and sterilization device according to an embodiment of the present invention;
Figure 4 is a diagram schematically showing the internal structure of an air pollutant decomposition and sterilization device according to an embodiment of the present invention;
Figure 5 is an enlarged view showing the filter unit of the air pollutant decomposition and sterilization device according to an embodiment of the present invention;
6 and 7 are enlarged views showing the sterilization unit of the air pollutant decomposition and sterilization device according to an embodiment of the present invention;
Figures 8 and 9 are enlarged views showing the exhaust control means of the air pollutant decomposition and sterilization device according to an embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the attached drawings. First, when adding reference signs to components in each drawing, it should be noted that the same components are given the same reference numerals as much as possible even if they are shown in different drawings. Additionally, in describing the present invention, if it is determined that a detailed description of a related known configuration or function may obscure the gist of the present invention, the detailed description will be omitted.

In addition, terms such as “include,” “comprise,” or “have” described below mean that the corresponding component may be included, unless specifically stated to the contrary, and thus do not exclude other components. Rather, it should be construed as being able to further include other components, and all terms, including technical or scientific terms, are generally used by those skilled in the art to which the present invention pertains, unless otherwise defined. It has the same meaning as understood. Additionally, when describing the components of the present invention, terms such as first, second, A, B, (a), and (b) may be used. These terms are only used to distinguish the component from other components, and the nature, sequence, or order of the component is not limited by the term. When a component is described as being “connected,” “coupled,” or “connected” to another component, that component may be directly connected or connected to that other component, but there is another component between each component. It will be understood that elements may be “connected,” “combined,” or “connected.”

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

As shown, the air pollutant decomposition and sterilization device of the present invention includes a casing portion 100 forming the exterior, a filter portion through which indoor air or outdoor air flows in, and filters contaminants contained in the introduced indoor and outdoor air. (200) and a sterilizing unit ( 300).

The casing part 100 is configured to have the sterilization part 200 built in, and the lower end is detachably coupled to the filter part 200 to form the appearance of the air pollutant decomposition and sterilization device of the present invention, and one surface of the outer circumference thereof It consists of a controller 110 that controls the operation of the intake fan 308 and the exhaust fan 350, and an exhaust unit 120 that prevents external foreign substances from entering the exhaust fan 350.

This casing part 100 is detachably coupled to the fan mounting part 310 of the sterilizing unit 300, which will be described later.

Meanwhile, the controller 110 configured in the casing unit 100 is configured to control whether or not the external air supply means 270, such as the intake fan 308 and the air pump, is driven to control the intake amount of external air, and the exhaust It is configured to control the operation of the fan 350 to control the exhaust amount of air to create positive pressure in the indoor space.

In other words, it improves air quality by continuously supplying sterilized air to the indoor space, and at the same time, when the front door is opened while positive pressure is created in the indoor space, dust, bacteria, viruses, radon, etc. are released to the outdoors due to the pressure difference between the inside and outside. The idea is to force it to be ejected.

The filter unit 200 is configured to intake and filter indoor air or supply outdoor air, and is a component that filters the supplied outdoor air and discharges it to the sterilizing unit 300 to sterilize it, It is composed of a HEPA filter 202, a filter fixture 210, a connection frame 220, a filter cover 240, a support plate 250, and an external air supply frame 260.

The filter fixture 210 is seated on the lower surface of the HEPA filter 202 so that the HEPA filter 202 can be detachably fixed, and is coupled to the support plate 250 so that the HEPA filter 202 is positioned vertically from the ground. It is configured to maintain a stable position.

At this time, the filter fixture 210 has a filter fixing flange 212 coupled to the central lower surface of the support plate 250 in a fitting manner to enable separation and fixation with the support plate 250 along the lower circumferential surface. It is desirable to configure it, but it is not limited to this.

Here, the support plate 250 is composed of a plurality of pieces spaced apart at predetermined intervals along the upper circumferential surface, and a detachable groove 252 is formed so that the lower end of the filter cover 240 is detachably coupled, and the central portion penetrates. It is configured so that the filter fixture 210 can be mounted.

In addition, the filter unit 200 of the present invention is configured to adhere and fix the upper surface of the HEPA filter 202 mounted on the filter fixture 210, and indoor or outdoor air passing through the HEPA filter 202 is A connection frame part 220 is formed to guide the direction of movement of air so that it can flow into the sterilizing unit 300.

The connection frame part 220 is coupled to the upper part of the fan mounting part 310 in which the intake fan 308 is built, and is configured to communicate with the fan mounting part 310 at the center thereof, so that indoor or outdoor air passing through the HEPA filter 202 As air is sucked in by the intake fan 308, an air discharge portion 222 is formed to allow the air to flow into the fan mounting portion 310.

In addition, the connection frame portion 220 includes a protrusion fixing portion 224 into which the mounting protrusion 315 of the fan mounting portion 310 is inserted and fixed so that the lower end of the fan mounting portion 310 is tightly coupled. may be further configured.

In addition, the filter unit 200 is coupled to the lower end of the connection frame unit 220, is configured to contact the outer peripheral surface of the HEPA filter 202, and is connected to the outdoor air supply means 270 and the air supply line, etc. to provide outdoor air. An outdoor air supply frame 260 is further configured to receive the supplied outdoor air and exhaust the supplied outdoor air to the HEPA filter 202 to perform filtration.

The external air supply frame 260 may be composed of a plurality of units spaced apart at a predetermined distance at the lower end of the connection frame unit 220, and in the present invention, a total of three units are formed at equal intervals along the lower circumferential surface of the connection frame unit 220. However, it is not limited to this.

This outside air supply frame 260 has an upper end detachably coupled to the lower circumferential surface of the connection frame portion 220, a lower end coupled to the detachable groove 252 of the support plate 250, and an outside air supply means 270 and A supply support panel 262 on which an outdoor air supply port 264 is formed is coupled to the inner surface of the supply support panel 262 at a predetermined interval to allow connection, and the supplied outdoor air is connected to the outer peripheral surface of the HEPA filter 202. It includes a mesh panel 266 that guides the air to be dispersed and passed through, and a filtration filter 268 located between the mesh panel 266 and the HEPA filter 202 to filter outdoor air.

Here, the mesh panel 266 is coupled at its upper and lower ends to the inner end of the supply support panel 262, and is connected to the outdoor air supply port 264 to disperse the outdoor air supplied from the outdoor air supply port 264. A predetermined space is provided between the filtration filter 268 and the mesh panel 266, and the outside air supplied through the outside air supply port 264 passes through a plurality of spaces formed in this space and the mesh panel 266. It is configured to circulate through the hole, pass through the filtration filter 266, and evenly flow into the entire outer surface of the HEPA filter 202.

Here, the outside air supply port 264 is configured to pass through the filter cover 240, which will be described later, and is connected to an air supply line made of a structure such as a normal pipe and the end of this air supply line to supply outside air to the outside air supply port 264. It is configured to be connected to the external air supply means (270).

The filter cover 240 is configured to surround the HEPA filter 202, and serves to prevent dust over a certain size from being adsorbed to the HEPA filter 202 when surrounding outdoor air is sucked in by the driving force of the intake fan 308. do.

Meanwhile, the intake fan 308 is mounted and driven inside the fan mounting unit 310, and can only intake external air supplied from the external air supply means 210 and supply it to the sterilizing unit 300, but is not limited to this, and is not limited to this, and the filter The indoor air around the cover 240 may also be sucked in and supplied to the sterilizing unit 300. At this time, it is desirable that the intensity of the drive is controlled according to the control of the controller 310.

In the sterilizing unit 300, air filtered while passing through the HEPA filter 202 is introduced through the intake fan 308, and harmful substances such as bacteria and viruses contained in the introduced air are removed, and the harmful substances are removed. It is a component that generates positive pressure in the indoor space while exhausting air into the indoor space, and includes a filter member consisting of first and second photocatalyst filters 302 and 304 and a light dissipation member 306, and a fan mounting unit ( 310), a filter support means 320, a filter fixing means 330, an exhaust guide 340, and an exhaust fan 350.

The first photocatalyst filter 302 primarily sterilizes the air introduced by the intake fan 308, and is installed between the first filter support pipe 322 and the second filter support pipe 324 of the filter support means 320. It is mounted on the first air movement path 323 formed.

The second photocatalyst filter 304 secondly sterilizes the air that was first sterilized through the first photocatalyst filter 302, and is formed between the second filter support pipe 324 and the third filter support pipe 326. It is mounted on the second air movement path 325.

The first and second photocatalyst filters 302 and 304 are coated with a photocatalyst on the surface, and are configured to have a trapezoidal cross-sectional shape, and form a plurality of air passage holes to control the flow rate of the moving filtered air. It is configured to improve, and is configured to be combined in opposite shapes. However, it is not limited to this, and of course, it can be arranged in various forms for photocatalytic efficiency.

In addition, the first photocatalyst filter 302 of the present invention maximizes light transparency on one side, further increases the efficiency of sterilizing air passing through the air passage hole, and further increases the flow rate of moving air. A photocatalyst sheet 305 may be attached.

The photocatalyst sheet 305 is configured to allow filtered air to pass through first contact with the photocatalyst sheet 305 before passing through the first photocatalyst filter 302.

Preferably, among the plurality of first photocatalyst filters 302, the photocatalyst filter forming a predetermined slope outward from the center of the sterilization unit 300 is configured to be attached to the upper surface, and on the contrary, the sterilization unit 300 ) may be configured to be attached to the lower surface of the photocatalyst filter forming a predetermined slope from the outside to the center.

Accordingly, the effect of improving the flow rate of air through the air passage holes of the first and second photocatalyst filters 302 and 304, which are configured to have a predetermined slope due to the trapezoidal shape, is further increased, while the moving air and By increasing the contact area and contact time, it will be possible to maximize the effect of sterilization treatment by photocatalyst.

The light dissipation member 306 is formed of the first and second photocatalyst filters 302 and 304, respectively, and is preferably configured such that photocatalyst filters having opposite inclined surfaces are connected to the upper and lower surfaces, respectively, and are connected to the central part thereof. It is designed to sterilize by irradiating UVA to generate oxidation and reduction reactions of harmful substances.

The light dissipating member 306 may be composed of a lamp assembly including a UVA lamp that irradiates UVA or visible light toward the first and second photocatalyst filters 302 and 304 and the photocatalyst sheet 305, or a visible light lamp. , causing an oxidation-reduction reaction to occur on the surfaces of the first and second photocatalyst filters 302, 304 and the photocatalyst sheet 305, and when the incoming air comes into contact with the surface where this oxidation-reduction reaction occurred, harmful substances are removed with strong oxidation power. This is to ensure removal and sterilization.

A plurality of such light dissipating members 306 are formed on the outer peripheral surface of the exhaust control means 370, and may be configured to be spaced apart along the axial direction of the central control axis 372 of the exhaust control means 370, and the controller 110 ) is preferably configured to control the intensity of the light emission by controlling.

Meanwhile, the fan mounting unit 310 comprised in the sterilizing unit 300 of the present invention intakes indoor or outdoor air that has passed through the HEPA filter 102 according to the Venturi principle, and supports the filter for the sucked indoor or outdoor air. It is configured to flow into the internal space of the means 320.

This fan mounting portion 310 is configured with a fixing flange 318 to be connected to the filter support means 320 and the blocking frame 360 at the top, and directs the air sucked in from the intake fan 308 toward the first photocatalyst filter 302. An air discharge hole 312 is formed to discharge air.

Here, the inner surface of the fixing flange 318 is configured to be in close contact with the first filter support pipe 322 of the filter support means 320, and is used for fixing the first filter support pipe 322 together with the blocking frame portion 360. and is configured to maintain airtightness.

In addition, the fan mounting part 310 is configured to have an intake fan 308 mounted at the bottom and a filter support means 320 to be seated at the top thereof, and the air flowing in through the air discharge hole 312 is A guide panel 314 is further provided to guide movement toward the first air movement path 323.

Here, an opening/closing damper 316 may be further configured on the guide panel 314 to control whether the air discharge hole 312 is opened or closed and the opening/closing amount.

The opening/closing damper 316 is configured to rotate under the control of the controller 110 and adjust the open area of the air discharge hole 312. At this time, the opening and closing damper 316 may be composed of an opening and closing panel and a motor.

In addition, the opening/closing damper 316 has been described as being located at the lower part of the intake fan 308, but it is not limited to this, and is also provided on the exhaust fan 350 side to enable adjustment of the amount of sterilized air being exhausted. It could be.

The blocking frame 360 supports the first and second photocatalyst filters 302 and 304, the filter support means 320, and the exhaust control means 370, and allows the air flowing in through the air discharge hole 312 to be installed. It is configured so that air can only flow into the first air movement path 323 formed between the first filter support pipe 322 and the second filter support pipe 324.

This blocking frame 360 is configured so that its outer circumferential surface is in close contact with the inner circumferential surface of the first filter support tube 322, and the lower ends of the second filter support tube 324 and the first photocatalyst filter 302 are inserted into the upper surface thereof. It is configured to be fixed.

At this time, the blocking frame 360 may be configured so that the second filter support pipe 324 and the fixing ribs into which the lower ends of the first photocatalyst filter 302 are inserted and fixed are spaced at a predetermined distance along the circumferential surface.

In addition, the blocking frame 360 is configured to communicate with the air discharge hole 312 to form an air communication part 362 that supplies air flowing in from the air discharge hole 312 to the first air movement path 323. do.

In addition, the blocking frame 360 guides the air discharged from the second filter support pipe 324 to the upper center so that it can flow into the internal space of the third filter support pipe 326, that is, toward the exhaust hole 328. , A guide flange 364 configured to couple the lower end of the second photocatalyst filter 304 to the inside may be further configured.

Here, it is preferable that the central control shaft 372 of the exhaust control means 370, which will be described later, is fixedly coupled to the central portion of the guide flange 364.

The filter support means 320 is equipped with first and second photocatalyst filters 302 and 304, and the air sucked through the intake fan 308 passes through the first and second photocatalyst filters 302 and 304. As a component that performs sterilization treatment and simultaneously exhausts the sterilized air, it includes first to third filter support pipes (322, 324, 326) and first and second air movement paths (323, 325). ) is composed of.

The first to third filter support pipes 322, 324, and 326 are configured so that their lower ends are coupled to the above-described fan mounting portion 310 and the blocking frame 360, respectively, and their upper ends are coupled to the filter fixing means 330 to be described later. do.

Additionally, the first filter support pipe 322 may be made of a metal material such as iron, stainless steel, or aluminum, but is not limited thereto.

In addition, the second and third filter support tubes 324 and 326 are preferably made of quartz tubes with high transmittance of UVA or visible light emitted from the light dissipating member 306, but are not limited thereto.

The first to third filter support pipes 322, 324, and 326 form the first and second air movement paths 323 and 325 therein.

Preferably, a first air movement path 323 is formed between the inner peripheral surface of the first filter support pipe 322 and the outer peripheral surface of the second filter support pipe 324, and the first air movement path 323 is provided with 1 It is configured to be equipped with a photocatalyst filter 302.

In addition, a second air movement path 325 is formed between the inner peripheral surface of the second filter support pipe 324 and the outer peripheral surface of the third filter support pipe 326, and a second photocatalyst is formed in this second air movement path 325. The filter 304 is configured to be mounted.

The filter support means 320 configured in this way allows the air discharged through the air discharge hole 312 to flow into the first air movement path 323 and move upward, thereby performing primary sterilization by the first photocatalyst filter 302. To achieve this, the upwardly moved air flows into the second air movement path 325 by the filter fixing means 330 and is configured to undergo secondary sterilization by the second photocatalyst filter 304.

In addition, the air that has undergone secondary sterilization is configured to flow into the exhaust hole 328 of the third filter support pipe 326 and be exhausted while moving upward.

The filter fixing means 330 is coupled to the upper end of the filter support means 320 and prevents leakage of moving air, while the exhaust fan 350 is coupled to exhaust the sterilized air into the indoor space. As an element, the upper surface is open so that the sterilized air can be exhausted to the outside.

This filter fixing means 330 is coupled to the upper end of the first filter support pipe 322 of the filter support means 320 on the outer peripheral surface as the lower surface, and the air passing through the first filter support pipe 322 on the inner peripheral surface, i.e. A movement guide unit 332 is configured to move the air that has undergone primary sterilization toward the second filter support pipe 324.

In addition, the filter fixing means 330 is provided with a detachable flange 334 formed at the center so that the third filter support pipe 326 is mounted.

At this time, the detachable flange 334 is formed to extend from one end of the movement guide portion 332.

In addition, the filter fixing means 330 is further provided with an exhaust guide hole 336 that discharges air exhausted through the exhaust hole 328 toward the outdoor space.

At this time, the above-described opening/closing damper 316 may be further configured in the discharge guide hole 336, but is not limited to this.

The exhaust guide 340 is fixed to the upper surface of the filter fixing means 330, and has a plurality of passing holes to allow the exhausted air to pass through, and is fixed so that the exhaust portion 120 of the casing portion 100 is spaced at a predetermined distance. do.

The exhaust fan 350 is coupled to the upper end of the third filter support pipe 326 of the filter support means 320 and the first and second air movement paths 323 and 325 formed inside the filter support means 320. ) It is a component that improves the moving speed of air moving to the outside and exhausts the air flowing into the exhaust hole 328 of the third filter support pipe 326 to the outside.

The driving force of the exhaust fan 350 is controlled according to the control of the controller 310, and the exhaust fan 350 is configured to regulate the amount of exhaust air to create positive pressure in the indoor space. In other words, a pressure differential is created between the sealed interior and exterior.

Meanwhile, the present invention is configured inside the third filter support pipe 326, that is, inside the exhaust hole 328, and includes an exhaust control means 370 for controlling whether the exhaust hole 328 is opened and closed and the amount of opening and closing. It can be configured further.

The exhaust control means 370 is mounted on the exhaust hole 328 and controls the exhaust area of the exhaust hole 328. It is coupled to the guide flange 364 of the blocking frame 360 and is electrically connected to the controller 110. A central control shaft 372 that is connected to the central control shaft 372 and an exhaust volume control member ( 374).

Here, the displacement control member 374 has an adjustment body whose outer peripheral surface is coupled to the inner peripheral surface of the third filter support pipe 326, is rotatably connected to this adjustment body, and is rotatable inside the central control shaft 372. A plurality of control panels 378 are connected to a rotating means such as a motor to open and close the exhaust hole 328, and an air passage hole through which the exhausted air passes is formed on the upper part of the plurality of control panels 378. It consists of a perforated plate 376 coated with a photocatalyst component.

At this time, a rotation guide groove 374a is formed along the inner peripheral surface of the control body to support the rotation of the plurality of control panels 378.

The control panel 378 is composed of the first to fourth control panels 378a, 378b, 378c, and 378d, and is arranged under the perforated plate 276, and is stacked on top of each other.

When the rotation means is rotated under the control of the controller 110, the first control panel 378a is drawn into the lower surface of the second control panel 378b, thereby reducing the exhaust area of the exhaust hole 328. It is configured to improve the exhaust area of the exhaust hole 9328 as the first and second control panels 378a and 378b are drawn into the third control panel 378c.

The above description is merely an illustrative explanation of the technical idea of the present invention, and various modifications and variations will be possible to those skilled in the art without departing from the essential characteristics of the present invention. Accordingly, the embodiments disclosed in the present invention are not intended to limit the technical idea of the present invention, but are for illustrative purposes, and the scope of the technical idea of the present invention is not limited by these embodiments. The scope of protection of the present invention should be interpreted in accordance with the claims below, and all technical ideas within the equivalent scope should be construed as being included in the scope of rights of the present invention.

100: Casing part 110: Controller
120: exhaust part
200: filter unit 210: filter fixture
212: Filter fixing flange 220: Connection frame part
222: Air discharge unit 224: Protrusion fixing unit
230: Outdoor air inlet 240: Filter cover
250: Support plate 252: Removal groove
260: External air supply frame 262: Supply support panel
264: External air supply port 266: Mesh panel
268: Filtration filter 270: External air supply means
300: Sterilization unit 302: First photocatalyst filter
304: Second photocatalyst filter 306: Light dissipation member
308: intake fan 310: fan mounting portion
312: air discharge hole 314: information panel
315: Mounting protrusion 316: Opening/closing damper
318: fixed flange 320: filter support means
322: first filter support pipe 323: first air movement path
324: Second filter support pipe 325: Second air movement path
326: Third filter support pipe 328: Exhaust hole
330: Filter fixing means 332: Movement guide unit
334: Detachment flange 336: Discharge guide hole
340: exhaust guide 342: coupling pin
350: exhaust fan 360: blocking frame
362: air communication part 364: guide flange
370: Exhaust control means 372: Central control shaft
374: Displacement volume control member 374a: Rotation guide groove
376: Perforated plate 378: Control panel

Claims (10)

Casing portion 100 equipped with a controller 110;
A filter unit 200 that receives indoor air or outdoor air, separates contaminants contained in the introduced indoor air or outdoor air, and discharges them to the top; and
It is mounted on the upper part of the filter unit 200, has a plurality of passage holes formed to allow filtered air to pass through, and a plurality of first and second filters coated with a photocatalyst component to ensure sterilization and movement of the filtered air passing through. A sterilizing unit 300 including two photocatalyst filters 302 and 304 and a plurality of light emitting members 306 that emit UVA or visible light to the first and second photocatalyst filters 302 and 304. Contains,
The sterilization unit 300,
A fan mounting portion 310 provided with an intake fan 308 that intakes filtered air;
A first filter support pipe 322 forming an outer surface to guide the movement of filtered air sucked in by the intake fan 308, and a second filter support pipe formed inside the first filter support pipe 322 ( 324) and a third filter support pipe 326, which is formed inside the second filter support pipe 324 and has an exhaust hole 328, and the first and second filter support pipes 322 , 324), a first air movement path 323 on which the first photocatalyst filter 302 is mounted, and a second air passage 323 on which the second photocatalyst filter 304 is mounted on an oblique side of the second and third filter support pipes. Filter support means 320 forming an air movement path 325;
a filter fixing means (330) to which the upper end of the filter support means (320) is coupled and an exhaust fan (350) for exhausting sterilized air is mounted;
Exhaust control means 370 configured inside the exhaust hole 328 and on which the light dissipating member 306 is mounted on the outer peripheral surface;
An air pollutant decomposition and sterilization device comprising a.
According to paragraph 1,
The filter unit 200,
HEPA filter (202);
A filter fixture 210 on which the lower surface of the HEPA filter 202 is seated;
The upper surface of the HEPA filter 202 is closely attached and fixed, and an air outlet 222 is formed in communication with the intake fan 308 to allow filtered indoor air or outdoor air to flow into the sterilization unit 300. Connection frame portion 220;
Outdoor air supply means 270 for supplying the outdoor air;
An outdoor air supply frame 260 is coupled to the connection frame portion 220 and configured on the outer peripheral surface of the HEPA filter 202, and is connected to the outdoor air supply means 270 to supply the outdoor air to the HEPA filter 202. );
A filter cover 240 configured to surround the HEPA filter 202;
An air pollutant decomposition and sterilization device comprising a.
According to paragraph 2,
The external air supply frame 260 is,
A supply support panel 262 that is detachably coupled to the connection frame 220 and has an outdoor air supply port 264 connected to the outdoor air supply means 270,
A mesh panel 266 coupled to the inner surface of the supply support panel 262 at a predetermined interval and guiding the outdoor air to be distributed and pass through the outer peripheral surface of the HEPA filter 202;
A filtration filter 268 configured between the mesh panel 266 and the HEPA filter 202 to filter the outdoor air.
An air pollutant decomposition and sterilization device comprising a.
According to paragraph 1,
In the sterilization unit 300,
Attached to the plurality of first and second photocatalyst filters 302 and 304,
Among the plurality of first photocatalyst filters 302, the photocatalyst filter forming a predetermined slope outward from the center of the sterilization unit 300 is configured to be attached to the upper surface, and is attached to the upper surface of the photocatalyst filter 302 from the outside of the sterilization unit 300. An air pollutant decomposition and sterilization device, characterized in that the photocatalyst filter forming a predetermined inclined surface in the center further includes a photocatalyst sheet 305 configured to be attached to the lower surface.
delete According to paragraph 1,
In the fan mounting portion 310,
an air discharge hole 312 that discharges the air sucked in from the intake fan 308 toward the first photocatalyst filter 302;
a guide panel 314 that guides the air flowing in through the air discharge hole 312 to move toward the first air movement path 323;
An opening/closing damper (316) is provided on the guide panel (314) to control whether the air discharge hole (312) is opened or closed and the amount of opening/closing.
An air pollutant decomposition and sterilization device comprising a.
According to paragraph 1,
In the sterilization unit 300,
The first and second photocatalyst filters 302 and 304, a filter support means 320, and an exhaust control means 370 are installed, and the filtered air flowing into the fan mounting unit 310 flows through the first air movement path. An air pollutant decomposition and sterilization device further comprising a blocking frame (360) configured to allow inflow only from the (323) side.
According to paragraph 1,
The exhaust control means 370,
A central control shaft configured inside the exhaust hole 328 to control whether the exhaust hole 328 is opened or closed and the amount of opening and closing, the lower end of which is coupled to the blocking frame 360, and electrically connected to the controller 110. (372) and an exhaust volume control member 374 that is coupled to the central control shaft 372 and rotates by a certain angle under the control of the controller 110 to open and close the exhaust hole 328.
An air pollutant decomposition and sterilization device further comprising:
According to clause 8,
The displacement control member 374 is
An adjustment body whose outer peripheral surface is coupled to the inner peripheral surface of the third filter support pipe 326,
A plurality of control panels 378 rotatably connected to the control body and connected to a rotation means formed inside the central control shaft 372 to open and close the exhaust hole 328,
A perforated plate 376 is formed on the upper part of the plurality of control panels 378, has an air passage hole through which exhausted air passes, and is coated with a photocatalyst component.
An air pollutant decomposition and sterilization device comprising:
According to paragraph 1,
The light dissipating member 306 is
An air pollutant decomposition and sterilization device, characterized in that it is mounted on the first and second photocatalyst filters (302, 304).

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