KR20200107116A - Interior ventilation system with improved removal performance of harmful substances - Google Patents

Abstract

The present invention relates to an indoor ventilation system with improved harmful substance removal performance. According to the present invention, the indoor ventilation system with improved harmful substance removal performance comprises: an electric dust collector; and an air duct connected to the electric dust collector, wherein the electric dust collector comprises a device body, a primary filter, a discharge unit, a dust collection unit, a secondary filter, a light source body, an air flow means, and a rotation means. According to the present invention, the efficiency in removing harmful substances can be further increased.

Description

Indoor ventilation system with improved toxic component removal performance {INTERIOR VENTILATION SYSTEM WITH IMPROVED REMOVAL PERFORMANCE OF HARMFUL SUBSTANCES}

The present invention relates to an indoor ventilation system with improved toxic component removal performance, and more particularly, in discharging indoor polluted gas to the outdoors, from the polluted gas to impurities (dust) as well as harmful components (odor, bacteria). It relates to an indoor ventilation system with improved toxic component removal performance by completely removing (separating, decomposing) and allowing only clean gas to be discharged to the outdoors.

Environmental pollution with a large odor due to the desire to pursue a more pleasant environment along with the increase in national income along with industrial development and economic development. It is emerging as a problem.

Accordingly, the Ministry of Environment has enacted and regulated the ``Odor Prevention Act (Act No. 14532)'' so that people can live in a healthy and comfortable environment by continuously managing odors generated at business sites. Most of the facilities that generate odors are non-regulated facilities, and it is difficult to regulate or guide by law, and thus, there is a limit to the solution of odors.

The main facilities that generate such a life odor are restaurants, laundry, gas stations, septic tanks and sewers, among which the odors generated in restaurants are cooked in kitchens and halls of various restaurants such as meat and fish restaurants, Chinese restaurants, and deep-fried restaurants. And occurs in the cooking process.

As such, the treatment method mainly used in Korea for the treatment of odors exhausted from restaurants is a very simple method such as simple ventilation or local ventilation, followed by diffusion and dilution, and the outlet side of the blower is limited. In the case of low pressure, odorous substances are intensively discharged toward the direction, and civil complaints are increasing as odorous substances settle around them.

In particular, in direct grilled restaurants that use charcoal to cook meat and fish, ammonia, sulfur compounds (hydrogen sulfide, methyl mercaptan, etc.), aldehydes (acetaldehyde, propionaldehyde, n), including various types of volatile organic compounds (VOCs) -Various pollutants such as valeraldehyde, etc.) are being discharged.

Here, it is common to apply a single technology such as absorption, adsorption, electrostatic precipitating, and filtration as a treatment technology for removing odors and remains generated in direct grilled restaurants.

Among them, the electric dust precipitator is an air purification device that uses corona discharge to charge particles in a gas containing gas and separates the charged particles from the gas by electrostatic force. Related prior art through No. 10-0652804 (name of the invention: electric dust collector and ventilation device having the same), Korean Patent Registration No. 10-0343036 (name of invention: total heat exchange type ventilation device including electric dust collector), etc. Many of these are disclosed.

However, the electrostatic precipitators employed in the above-described prior art separate particulate pollutants contained in the gas using a prefilter and an ionizer (ionizer / ionizer) as well-known. ), but it is virtually impossible to completely remove harmful ingredients (odor and bacteria).

In this way, when polluted gases in the workplace where harmful substances have not been completely removed are discharged to the outside, there is a problem of environmental degradation that pollutes the atmosphere of the surrounding area, and it also causes discomfort to passers-by, and complaints are not endless. The existing problems such as, etc. have still existed.

In the end, research and development of an indoor ventilation system is urgently needed to completely remove harmful components (odors, bacteria) from indoor polluted gases discharged to the outside, and to solve problems of environmental degradation and discomfort.

(Document 1) Korean Patent Registration No. 10-0652804 (Registration Date: 2006.11.24.) (Document 2) Korean Patent Registration No. 10-0343036 (Registration Date: 2002.06.21.) (Document 3) Republic of Korea Utility Model Registration No. 20-0339073 (Registration Date: 2004.01.07.)

An object of the present invention is to solve all the problems described above, and to cleanly purify indoor polluted gas, but to filter out fine dust mixed in the polluted gas and a second filter of photocatalyst and Provides an indoor ventilation system with improved toxic component removal performance that makes the gas discharged to the outdoors more clean by completely purifying and sterilizing contaminated gases through the photochemical reaction of ultraviolet rays and photocatalyst using a light source (UV lamp). Is in.

Another object of the present invention is to allow the secondary filter employing the photocatalyst to rotate inside the device (electric precipitator), thereby promoting the photocatalytic reaction through even UV irradiation to the entire photocatalyst, thereby further enhancing the efficiency of removing harmful components. It is to provide an indoor ventilation system with improved removal performance of harmful components that can be increased.

In order to achieve the above object, the present invention provides an electric precipitator for removing impurities and harmful components from the exhausted pollutant gas as well as the air flow of the exhaust flow generation, and is connected to the electric precipitator to prevent inhalation of indoor polluted gas and outdoor discharge In the indoor ventilation system including an air duct for inducing fluid transport, the electric precipitator comprises: a box-shaped device body in which path flows of inflow and outflow of polluted gas are formed; A primary filter provided inside the device body and first filtering out substances having large particles among impurities mixed in the polluted gas entering the device body; A discharge unit for charging impurities mixed in the polluted gas passing through the primary filter; A dust collecting unit that collects the material charged by the discharge unit by using an electrostatic phenomenon; in addition, it is provided inside the device body and is mixed with contaminated gas discharged to the outside of the device body through a photochemical reaction by light irradiation. A secondary filter that decomposes harmful components; A light source body that generates ultraviolet rays for accelerating reaction of the photocatalyst and sterilizing contaminated gas while provided inside the device body; An air flow means for inducing gas flow of external air inflow and internal air discharge while provided inside the apparatus body; And, in the state of being installed inside the device body, in addition to increasing the photochemical reaction efficiency by rotating the secondary filter, rotating means for increasing the gas sterilization efficiency by changing the flow of gas passing through the interior of the device body. It is characterized.

In addition, the device main body is an external housing provided with an internal space for internal accommodation of components, an internal housing disposed in the internal space to connect the secondary filter, the light source body, and the air flow means and the rotating means. It is made of a case, and inside the inner case, a first jig is provided and coupled to one side, and a second jig is provided and coupled to the other side, and the air duct is connected and gas is introduced into the inner space through the suction. An engine is formed at one end, and an exhaust pipe is formed through each of the other ends to allow external discharge of the gas introduced into the internal space.

In addition, the secondary filter includes a filter pallet forming the outer shape of the filter, and a photocatalyst layer coated on the surface of the filter pallet and performing a photochemical reaction by light irradiation.

In addition, the light source body is a plurality of UV lamps that are assembled to the second jig and disposed close to the secondary filter to eradicate 99.9% of bacteria irradiated with ultraviolet rays.

In addition, the rotating means includes a rotating jig for installing the secondary filter and rotating the mounted secondary filter so that ultraviolet rays are evenly irradiated to the entire photocatalyst layer, and the gas movement speed is retarded by the induction of a vortex. , A driving motor generating power required for rotation of the rotating jig, and at least one rotating roll transmitting power generated by the driving motor to the rotating jig, and the rotating jig is fitted with a plurality of the secondary filters. And a mounting portion capable of arranging in all directions, and a disk-shaped disk portion supported by the first jig and the second jig, respectively, and inside the mounting portion, a moving flow of gas continues, while ultraviolet light emission from the light source body and the photocatalyst layer A reaction chamber in which an optical reaction takes place is provided.

In addition, the filter pallet has a structure in which a plurality of contact pieces protruding from one surface of the base plate and a plurality of contact pieces that promote the decomposition efficiency of harmful components by increasing the contact area of the polluted gas, are arranged at predetermined intervals.

In addition, the photocatalyst layer is applied to a part or all of the filter pallet, and is made of titanium oxide.

As can be seen from the above description, the indoor ventilation system with improved toxic component removal performance of the present invention allows polluted gases discharged to the outside to pass through the inside of the electric precipitator (internal inflow, path movement, external discharge), and in the process In addition to the preferential removal of impurities using the primary filter, the photochemical reaction of the secondary filter (photocatalyst) and the ultraviolet rays of the light source are used to completely decompose and sterilize the harmful components mixed in the polluted gas. Shows the effect.

In addition, according to the rotational motion of the rotating jig equipped with the secondary filter, ultraviolet rays emitted from the light source body are evenly irradiated to the photocatalyst layer of the secondary filter, thereby increasing the efficiency of the photochemical reaction. It has the effect of greatly improving the decomposition ability of various harmful ingredients such as.

Along with this, it is possible to more completely decompose and sterilize harmful components mixed in polluted gases discharged from indoor to outdoor through the process so far. In particular, odors generated in direct grilled restaurants and smoke (hazardous gases) from remains It is a very useful invention that can greatly contribute to the establishment of an eco-friendly urban infrastructure through the improvement of air pollution problems in the city center through efficient treatment.

1 is a system configuration diagram showing an embodiment of an indoor ventilation system with improved toxic component removal performance according to the present invention.
2 is a perspective view showing the external structure of an indoor ventilation system with improved toxic component removal performance according to the present invention.
3 is a cross-sectional view showing the internal structure of the indoor ventilation system with improved toxic component removal performance according to the present invention.
4A and 4B are perspective and cross-sectional views showing a configuration relationship between a secondary filter and a rotating means in an indoor ventilation system with improved toxic component removal performance according to the present invention.
5 is a cross-sectional view showing a flow relationship of gas passing through the interior of the indoor ventilation system with improved toxic component removal performance according to the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art can easily implement the present invention.

First of all, in adding reference numerals to elements of the drawings, it should be noted that the same elements are assigned the same numerals as possible even if they are indicated on different drawings. In addition, in describing the present invention, when it is determined that a detailed description of a related known configuration or function may obscure the subject matter of the present invention, a detailed description thereof will be omitted.

In the accompanying drawings, FIG. 1 is a system configuration diagram showing an embodiment of an indoor ventilation system with improved toxic component removal performance according to the present invention, and FIG. 2 is a diagram showing the external structure of an indoor ventilation system with improved toxic component removal performance according to the present invention. 3 is a cross-sectional view showing the internal structure of an indoor ventilation system with improved toxic component removal performance according to the present invention, and FIGS. 4A and 4B are secondary views in the indoor ventilation system with improved toxic component removal performance according to the present invention. A perspective view and a cross-sectional view showing a configuration relationship between a filter and a rotating means, and FIG. 5 is a cross-sectional view showing a flow relationship of gas passing through the interior of the indoor ventilation system with improved toxic component removal performance according to the present invention.

As shown in FIG. 1, the indoor ventilation system (A) with improved toxic component removal performance according to the present invention is provided with impurities (dust, etc.) from the polluted gas exhausted as well as the air flow of the generation of exhaust flow. Electric precipitator (1) that removes harmful components (odor, etc.), and a single line connected from each indoor branch location for fluid transport that induces inhalation and outdoor discharge of indoor polluted gases that occur individually or/and simultaneously. In an integrated state, it includes an air duct 2 extended and installed to the outdoors through the electric precipitator 1.

The electrostatic precipitator 1 is an air purification device for simultaneously removing impurities as well as harmful substances (odors, bacteria) from exhaust polluted gases, and as shown in Figs. 2 and 3, a case forming the appearance of the device As a case, a box-shaped device body 11 is formed in which path flows for inflow and outflow of contaminated gas are formed, and contamination entering the device body 11 while being provided inside the device body 11 A primary filter 12 for first filtering out substances having large particles among impurities mixed in the gas, and a discharge unit 13 for charging impurities mixed in the polluted gas that has passed through the primary filter 12; A dust collecting unit 14 that collects the material charged by the discharge unit 13 by using an electrostatic phenomenon, and a photochemical reaction by light irradiation in a state further provided inside the device body 11 A secondary filter (15) that decomposes harmful components mixed in the polluted gas discharged to the outside of the device body (11) through chemical reaction, photochemical reaction, and a photocatalyst in a state provided inside the device body (11) A light source body 16 that generates ultraviolet rays (UV) for promotion and sterilization of polluted gas, and air that induces gas flow of external air inflow and internal air discharge while provided inside the device body 11 In addition to increasing the photochemical reaction efficiency by rotating the secondary filter 15 while being installed in the flow means 17 and the device body 11, the gas movement flow through the device body 11 is changed. It includes a rotating means 18 (delayed) to increase the gas sterilization efficiency.

In addition, the electric power of the discharge unit 13, the dust collecting unit 14, the light source body 16, the air flow unit 17, and the rotating unit 18 is received and the overall operation of the device is performed using the received electric power. It further includes a control unit 19 to control.

The device body 11 includes an outer housing 11-1 provided with an inner space 11a for internally receiving the components, and the secondary filter 15 by being accommodated and disposed in the inner space 11a. And a light source body 16, and an inner case 11-2 to which the air flow means 17 and the rotation means 18 are mounted in connection.

In addition, inside the inner case 11-2, a first jig 11-3 for supporting one end of the rotating jig of the rotating means 18 to be described later is provided and coupled, and supports the other end of the rotating jig. A second jig (11-4) is provided and coupled.

It is preferable that the outer housing 11-1 is formed by assembling a frame by linking and assembling profiles disposed vertically and transversely, and is configured by attaching and assembling a plurality of finishing panels surrounding the frame. .

In addition, an intake pipe 11-11 is formed at one end of the air duct 2 to allow gas inflow into the internal space 11a through the connection of the air duct 2, and flows into the internal space 11a. Exhaust pipes 11-12 for allowing gas to be discharged to the outside are respectively formed through the other ends.

The primary filter 12 contains relatively particles among impurities mixed in the polluted gas flowing into the inner space 11a while being disposed at a predetermined position in the inner space 11a close to the intake pipe 11-11. It is a fiber mat type prefilter that filters out large substances preferentially.

The discharge unit 13 is an ionizer (ionizer) required for electric charge of impurities mixed in the polluted gas passing through the primary filter 12.

The dust collecting unit 14 is a collector required to collect impurities (charged particles) charged by the corona discharge by the discharge unit 13 using an electrostatic phenomenon.

The secondary filter 15, as shown in FIGS. 4A and 4B, is a filter pallet 151 forming the outer shape of the filter, and a photochemical reaction by light irradiation while being coated on the surface of the filter pallet 151 It consists of a photocatalyst layer 152 to do.

Here, in the filter pallet 151, a number of contact pieces protruding from one surface of the base plate by increasing the contact area of the polluted gas to promote the decomposition efficiency of harmful components, and a number of them at predetermined intervals. It is desirable to have an arranged structure.

In addition, the photocatalyst formation (152) is applied (coated) to a part or all of the filter pallet 151, and it is preferable to use titanium oxide (TiO2) as a material, but is not limited thereto and has the same function. As long as it is an effective ingredient, it is possible to employ any number of different materials.

A light source body (16) is assembled on the second jig (11-3) provided and coupled to the inner case (11-2) of the device body (11) and is close to the secondary filter (15) It is preferable to use a plurality of UV lamps that eradicate (sterilize) 99.9% of the bacteria irradiated with ultraviolet rays in the arranged state, but it is not necessarily limited to this, and any luminous lamp that exhibits the same effect can be used as much as possible. .

The air flow means 17 is provided at the entrance of the inner case 11-2 of the device body 11, and forced inflow of polluted gas into the outer housing 11-1 and the inner case 11-2 ) An intake fan 171 that induces gas flow through and an exhaust fan that induces a gas flow that discharges gas passing through the inner case 11-2 while being provided at the outlet of the inner case 11-2. It consists of 172.

The rotating means 18, as shown in Figs. 4A and 4B, attaches the secondary filter 15 and rotates the mounted secondary filter 15 so that ultraviolet rays are applied to the entire photocatalyst layer 152. Generated from the rotation jig 181, which generates power required for rotation of the rotation jig 181, and the driving motor 182 to ensure evenly irradiation and delay the gas movement speed due to the induction of eddy currents. It consists of at least one or more rotary rolls 183 for transmitting the resulting power to the rotation jig 181.

The rotating jig 181 includes a mounting portion 181-1 capable of fitting, assembling and arranging the plurality of secondary filters 15, and the first jig 11-3 and the second jig 11-4. ) Consists of a disk-shaped disk portion (181-2) each supported.

In addition, a reaction chamber 181a is provided inside the mounting part 181-1 in which a gas flow is continued while ultraviolet light is emitted from the light source 16 and an optical reaction of the photocatalyst layer 152 is performed.

The drive motor 182 is a servo motor suitable for precisely controlling the rotational speed of the rotating jig 181 because it can control the speed of the motor shaft 182-1 on its own in response to an input signal. Although preferred, it is not necessarily limited thereto, and it is possible to employ any number of different mechanical elements or/and electronic elements exhibiting the same effect.

The rotating roll 183 is in close contact with the edge of the disk portion 181-2 of the rotating jig 181, and the rotating jig 181 is rotated correspondingly by making a linkage rotation by the operation of the driving motor 182 It is a roller to make it possible.

Here, a drive gear 182-2 is provided on the motor shaft 182-1 of the drive motor 182, and the drive gear 182 meshes with the roll shaft 183-1 of the rotary roll 183. The gear 183-2 is shaft-coupled, and the driving gear 182-2 and the interlocking gear 182-2 are preferably bevel gears that are widely used to meet each other at a right angle to transmit motion between the two axes. However, it is not necessarily limited thereto, and any mechanical element that exhibits the same working relationship and effect may be employed differently.

The air duct 2 is a line structure for transporting fluid, and individually or/and simultaneously inhales contaminated gas generated indoors, and the contaminated gas so sucked finally passes through the electric precipitator 1. Since impurities and harmful components are removed in the process of being discharged to the outside (outside) afterwards, it is preferable to have a circular or rectangular shape when viewed in cross section.

Reference numeral (b) denotes a bearing that is provided at a portion where the disk portions of the first jig and the second jig and the rotating jig contact each other to facilitate the rotational motion of the rotating jig.

The operation of the indoor ventilation system (A) having improved toxic component removal performance according to the present invention having the above configuration will be described in detail.

First, as shown in Fig. 1, the present invention is installed and used for the purpose of completely separating and removing harmful components (odor, bacteria, etc.) as well as impurities (dust, etc.) mixed in indoor polluted gas. 19) Impurities and harmfulness mixed in the polluted gas by the electric precipitator (1) in the process of operating the electric precipitator (1) through operation and discharging the polluted gas generated indoors to the outdoors through the air duct (2). As the dust is removed (decomposed, sterilized), the gas exhausted outdoors becomes clean.

Specifically, impurities having large particles are preferentially separated by the pre-filter 12 in the process of passing the contaminated gas through the main body 11 of the electric precipitator 1, and then the discharge unit 13 By corona discharge, particles (impurities) in polluted gas are separated from the gas by electrostatic force and collected by the dust collecting part 14.

Subsequently, the secondary filter 15 decomposes and sterilizes harmful components such as odors and bacteria mixed in the contaminated gas, and is finally discharged to the outdoors in a state that is purified with a clean gas, and the program of the control unit 19 When the intake fan 171 and the exhaust fan 172 of the air flow means 17 are operated by driving, indoor polluted gas continuing the exhaust flow along the air duct 2 is the intake pipe of the device body 11 The contaminated gas is forcibly introduced into the internal space 11a of the device body 11 through (11-11), and the contaminated gas introduced into the reaction chamber of the rotating jig 181 disposed inside the internal case 11-2 It is discharged to the outside through the exhaust pipe 11-12 of the device body 11 through (181a).

Subsequently, the contaminated gas flowing into the internal space 11a and continuing the flow of the path movement to the reaction chamber 181a inside the inner case 11-2 of the device body 11 is the reaction chamber 181a. ), harmful components are decomposed and sterilized by the secondary filter 15 in the process of passing through, which is the photocatalytic photochemical reaction of the photocatalytic layer 152 of the secondary filter 15 and the light source body 16 It is made up by the generated ultraviolet rays and is completely purified into a clean gas.

Here, as described above, the rotation jig 181 in which the secondary filter 15 is mounted can be rotated by driving the rotating means 18 in the process of passing the polluted gas through the reaction chamber 181a. As the secondary filter 15 rotates when the rotation jig 181 rotates, the ultraviolet rays emitted from the light source body 16 are evenly irradiated to the entire photocatalyst layer 152, thereby increasing the efficiency of the optical reaction. It can be greatly increased, and the movement flow of the polluted gas passing through the reaction chamber 181a is retarded (refer to FIG. 5) due to the change in gas flow according to the rotational motion of the rotating jig 181 (vortex generation), so the efficiency of sterilization This can be remarkably improved, allowing complete gas purification.

In summary, according to the indoor ventilation system (A) with improved toxic component removal performance of the present invention, the polluted gas generated indoors passes through the device body 11 (internal inflow, path movement, external discharge), and in the process In addition to preferential removal of impurities using the primary filter 12, the photochemical reaction of the secondary filter (15 / photocatalyst) and the ultraviolet rays of the light source body 16 are used to completely decompose and sterilize harmful components mixed in the polluted gas. Through the box, it is possible to achieve the effect of purifying with clean gas.

In addition, according to the rotational motion of the rotation jig 181 of the rotation means 18 on which the secondary filter 15 is mounted, the filter pallets 151 of the secondary filter 15 are rotated at the same time, whereby the filter Various harmful components (odor, bacteria, etc.) mixed in the polluted gas in accordance with the increase in the efficiency of the photochemical reaction by evenly irradiating the ultraviolet rays emitted from the light source body 16 with the photocatalytic layer 152 coated on the surfaces of the pallets 151 ) Can have the effect of greatly improving the resolution.

The above description is only illustrative of the technical idea of the present invention, and those of ordinary skill in the art to which the present invention belongs can make various modifications, changes, and substitutions within the scope not departing from the essential characteristics of the present invention. will be. Accordingly, the embodiments disclosed in the present invention and the accompanying drawings are not intended to limit the technical idea of the present invention, but are for description, and the scope of the technical idea of the present invention is not limited by these embodiments and the accompanying drawings. . In addition, the scope of protection of the present invention should be interpreted by the following claims, and all technical thoughts within the scope equivalent thereto should be interpreted as being included in the scope of the present invention.

1: electric dust collector, 2: air duct
11: device body, 11a: internal space
11-1: outer housing, 11-2: inner case
11-3: 1st jig, 11-4: 2nd jig
11-11: intake pipe, 11-12: exhaust pipe
12: primary filter, 13: discharge unit
14: dust collecting unit, 15: secondary filter
16: light source, 17: air flow means
18: rotating means, 19: control unit
151: filter pallet, 152: photocatalyst layer
171: intake fan, 172: exhaust fan
181: rotating jig, 181a: reaction chamber
181-1: mounting part, 181-2: dike part
182: drive motor, 182-1: motor shaft
182-2: drive gear, 183: rotary roll
183-1: roll shaft, 183-2: interlocking gear

Claims (7)

An electric precipitator that removes impurities and harmful components from the polluted gas exhausted as well as the air flow generated by the exhaust flow, and an air duct for fluid transport connected to the electric precipitator to induce the intake of indoor polluted gases and discharge outdoors. In the indoor ventilation system,
The electric precipitator may include: a box-shaped device body in which path flows for inflow and outflow of polluted gas are formed;
A primary filter provided inside the device body and first filtering out substances having large particles among impurities mixed in the polluted gas entering the device body; A discharge unit for charging impurities mixed in the polluted gas passing through the primary filter; In addition, a dust collecting unit that collects the material charged by the discharge unit using an electrostatic phenomenon;
A secondary filter that is provided inside the device body and decomposes harmful components mixed in the polluted gas discharged to the outside of the device body by photochemical reaction by light irradiation;
A light source body that generates ultraviolet rays for accelerating reaction of the photocatalyst and sterilizing contaminated gas while provided inside the device body;
An air flow means for inducing gas flow of external air inflow and internal air discharge while provided inside the apparatus body; And,
In a state installed inside the device body, rotating means for increasing the gas sterilization efficiency by changing the flow of gas passing through the device body in addition to increasing the photochemical reaction efficiency by rotating the secondary filter; characterized in that it comprises Indoor ventilation system with improved performance of removing harmful substances.
The method of claim 1,
The device body is an external housing provided with an internal space for internal accommodation of components, and an internal case which is accommodated and arranged in the internal space to connect the secondary filter, the light source body, and the air flow means and the rotating means. Done,
Inside the inner case, a first jig is provided and coupled to one side, and a second jig is provided and coupled to the other side,
An intake pipe for connecting the air duct and allowing gas to flow into the internal space is formed at one end,
An indoor ventilation system with improved toxic component removal performance, characterized in that an exhaust pipe for allowing external discharge of the gas introduced into the internal space is formed through each of the other ends.
The method of claim 2,
The secondary filter includes a filter pallet forming an external shape of the filter,
An indoor ventilation system with improved toxic component removal performance, comprising a photocatalyst layer coated on the surface of the filter pallet and performing a photochemical reaction by light irradiation.
The method of claim 2,
The light source body is a plurality of UV lamps that are assembled to the second jig and disposed in close proximity to the secondary filter to eradicate 99.9% of bacteria irradiated with ultraviolet rays.
The method of claim 3,
The rotating means includes a rotating jig for installing the secondary filter and rotating the mounted secondary filter so that ultraviolet rays are evenly irradiated to the entire photocatalyst layer, and the gas movement speed is retarded due to the induction of vortex,
A driving motor for generating power required for rotation of the rotating jig,
It is composed of at least one or more rotary rolls that transmit the power generated by the drive motor to the rotating jig,
The rotating jig is composed of a mounting portion capable of fitting and assembling and arranging a plurality of secondary filters, and a disk-shaped disk portion supported by the first jig and the second jig, respectively,
An indoor ventilation system having improved toxic component removal performance, characterized in that a reaction chamber is provided inside the mounting unit in which a moving flow of gas is continued while ultraviolet light emission from the light source body and an optical reaction of the photocatalyst layer are provided.
The method of claim 3,
In the filter pallet, a number of contact pieces that increase the contact area of polluted gases to promote the decomposition efficiency of harmful ingredients protrude from one surface of the base plate, and a number of them form a structure arranged at predetermined intervals. Indoor ventilation system with improved performance.
The method of claim 3,
The photocatalyst layer is applied to a part or the whole of the filter pallet, and the indoor ventilation system having improved toxic component removal performance, characterized in that it is made of titanium oxide.

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