KR100807152B1 - Device for purifying polluted air - Google Patents

Abstract

The present invention relates to an apparatus for purifying air contaminated with odor or volatile organic substances, etc., wherein the purifying apparatus of the present invention is an air purifying apparatus for purifying contaminated air, and the polluted air purifier is a cylindrical housing. At least one bag filter connected to the inlet and received inside the housing, an upper part connected only to the bag filter through a conduit, and a lower part of the conduit connected to the inlet; A cylindrical photochemical catalyst oxidation unit formed so that air supplied from the bag filter can be discharged to the bottom through the space, and defined as a space between the oxidizing unit outer cylinder located inside the bag filter and an open top thereof and the photochemical catalyst oxidation unit After the air is discharged to the lower portion of the photochemical catalyst oxidizing unit is discharged to the upper through the space Rib, the housing within the post is connected to the air discharge fan (fan) and the air discharge fan rear end located in the processor upper consisting of a air vent for discharging air in the housing outside the photochemical catalytic oxidation unit one of the TiO ₂ coating or At least one plate and at least one UV lamp.

 Photochemical catalyst, UV lamp, ozone, odor, volatile organic substance, vacuum, vacuum blower, watermill

Description

Cleaner of polluted air {DEVICE FOR PURIFYING POLLUTED AIR}

1 is a front sectional view schematically showing an apparatus for treating odors and volatile organic substances in polluted air of a conventional bioclimax;

Figure 2 is a front sectional view schematically showing a device described in Korean Patent Laid-Open No. 2002-0035432 filed by the applicant of the present invention;

3 is a view showing a first embodiment of the polluted air purifying apparatus of the present invention, (a) is a plan view, (b) is a front sectional view,

4 is a front sectional view schematically showing one form of the photochemical catalyst oxidation unit included in the contaminated air purification apparatus of the present invention;

5 is a front sectional view schematically showing another form of the photochemical catalyst oxidation unit included in the contaminated air purification apparatus of the present invention;

6 is a front sectional view schematically showing another form of the photochemical catalyst oxidation unit included in the contaminated air purification apparatus of the present invention;

7 is a perspective view showing one form in which a photochemical catalyst is installed in the photochemical catalyst oxidation unit of the present invention;

8 is a front sectional view of the air purifier showing a case in which water is further removed from the air by storing water in an outer cylinder of the oxidation unit of the polluted air purifier of the present invention;

9 is a view showing a second embodiment of the polluted air purifying apparatus of the present invention, (a) is a plan view, (b) is a front sectional view,

10 is a view showing a third embodiment of the polluted air purifying apparatus of the present invention, where (a) is a plan view, (b) is a front sectional view, and

11 is a view showing a fourth embodiment of the polluted air purifying apparatus of the present invention, where (a) is a plan view and (b) is a front sectional view.

The present invention relates to an apparatus for purifying air contaminated with odor or volatile organic substances, and more particularly, after inhaling air containing many odor-causing substances and volatile organic substances and the like through filtration and appropriate processes. The present invention relates to a contaminated air purifying apparatus which re-extracts only clean air by oxidative removal.

In general, the air exhausted from various industrial facilities, restaurants or toilets are odorous and contain a large amount of volatile organic substances (VOCs) that are harmful to the human body and the natural environment. Therefore, when odorous air or the like is discharged to the surrounding environment, not only it causes discomfort, but also harmful to the environment and the human body, it is necessary to remove the causative agent that provides the odor from the air.

Various techniques have been developed to remove odor-causing substances or volatile organic substances from the air containing odors. In Germany, Bio Climatic, as shown in FIG. Using ozone oxidation and UV photooxidation, a device was developed to remove odors from polluted air and to treat volatile organic substances. Looking at the configuration of the device is provided with a pre-treatment chamber (5) for filtering dust particles having an inlet (1) and filter (3) of the contaminated air; Ozone generating UV lamp (7) is installed across the air flow direction of the photooxidation reaction chamber (9) for photooxidation and ozone oxidation treatment of odor and volatile organic substances (VOC) in the contaminated air passed through the pretreatment chamber (5) Wow; It includes an adsorption means (11) filled with carbon and includes an adsorption chamber (13) and an exhaust port (15) for adsorption treatment of untreated materials in the air passing through the photooxidation reaction chamber (9).

In the contaminated air treatment apparatus, dust particles in contaminated air are filtered through the pretreatment chamber 5, and then some of the odors and volatile organic compounds in the air are decomposed and oxidized while passing through the photooxidation reaction chamber 9, and the rest The remaining harmful substances are adsorbed through the adsorption chamber 13 to discharge the finally purified air.

However, although the purified air can be obtained by the above method, the oxidation treatment efficiency of the photooxidation reaction chamber 9 is lowered to 8-9%, so that the adsorption chamber is provided with the adsorption means 11 filled with additional carbon. In (13) it was necessary to adsorb most of the remaining contaminants. However, when the pollutants are removed by adsorption, there is a problem that the adsorption means should be replaced periodically because contaminants adhere to the adsorption means 11 and blockage occurs or adsorption efficiency decreases over time. .

This problem is due to the extremely low oxidation efficiency of the photooxidation reaction chamber 9, which does not substantially contribute to the removal of harmful substances.

Applicant of the present invention, in order to solve the problems of the prior art, as shown in Figure 2 in the Republic of Korea Patent Publication No. 2002-0035432 and the inlet for the inlet air; A pretreatment chamber connected to one end of the inlet and having a filter therein for filtering dust and fine dust particles from contaminated air introduced through the inlet; It is connected to the outlet end of the pretreatment chamber, the inside is provided with an ozone generating UV lamp, a TiO ₂ -based photocatalyst is applied to the photooxidation of odor and volatile organic substances (VOC) in the contaminated air passed through the pretreatment chamber and A photooxidation reaction chamber for treating the ozone oxidation reaction; A post-treatment chamber connected to an outlet end of the photo-oxidation reaction chamber and having post-treatment means containing an ozone reaction catalyst to remove residual ozone contained in air passing through the photo-oxidation reaction chamber; There has been proposed a contaminated air treatment apparatus including an air outlet connected to an outlet end of the aftertreatment chamber.

Applicant's invention proposed in the Republic of Korea Patent Publication of the present invention compared with the conventional technology of the Bioclimatic company, only need a post-treatment chamber to remove residual ozone, but does not need the adsorption chamber, such as the periodic replacement of the adsorption means Maintenance work and additional material input are not required.

This difference is due to the application of TiO ₂ -based photocatalysts to promote the photooxidation reaction and to replace the UV lamps with ozone generating UV lamps to convert some of the oxygen in the air into ozone to increase the reactivity.

However, the technique proposed in Korean Patent Laid-Open Publication No. 2002-0035432 is a large-capacity odor removing device for treating a large amount of contaminated air, such as a large building, and is not suitable for use as a small odor removing device for home use.

This is because the inlet, the pretreatment chamber, the photooxidation chamber, the aftertreatment chamber and the outlet are connected in series in order to obtain sufficient odor and volatile organic substance removal effect. In this case, since the size is enlarged to have sufficient air treatment capacity It is not suitable for home use.

In addition, in the case of a small air treatment device that often discharges purified air in a place where a lot of people are crowded compared with the conventional polluted air treatment device, the concentration of ozone in the air discharged as compared to the large air purification device is also possible. This needs to be kept in a lower range.

It is an object of the present invention to provide a contaminated air purifying apparatus having a structure suitable for home use and having no problem in the treatment performance, human hazard and capacity of contaminated air.

It is another object of the present invention to provide a contaminated air purifying apparatus which can further reduce the amount of ozone that may be released in a small amount in the air.

Another object of the present invention is to provide a contaminated air purifying apparatus having a contaminated air treatment function and a vacuum cleaner function.

The present invention aims to provide a contaminated air purifying apparatus capable of supplying fresh air through ventilation with outside air.

The treatment apparatus of the present invention for achieving the above object is an air purifying apparatus for purifying polluted air, the polluted air purifier is a cylindrical housing, the polluted air inlet provided on the outside of the housing, the inlet One or more bag filters connected and housed in the housing, the upper part of which is connected only to the bag filter through a conduit and the lower part of which is open so that air supplied from the bag filter through the conduit can be discharged to the lower part. The cylindrical photochemical catalyst oxidation unit is defined as a space between the oxidizing unit outer cylinder located inside the bag filter and the upper portion is opened, and the air discharged to the lower portion of the photochemical catalyst oxidation unit is formed through the space. After-treatment unit formed to be discharged into the air exhaust fan (fan) located above the post-treatment unit in the housing and It is connected to the rear end of the air discharge fan is composed of an air outlet for discharging the air to the outside of the housing, the photochemical catalyst oxidation unit is characterized in that it comprises one or more plates and one or more UV lamps coated with TiO ₂ .

In this case, a high pressure blower is connected to one rear end of the bag filter through a pipe line, and a valve for selecting a pipe line connected to the photochemical catalyst oxidation unit and a pipe connected to the high pressure blower is further provided to the bag filter. It is preferable to be able to select and treat the air sucked in through the high pressure blower and the case of purifying via the photochemical catalyst oxidation unit.

Another example of the air purifying apparatus of the present invention is an air purifying apparatus for purifying contaminated air, wherein the contaminated air purifying apparatus is installed in a cylindrical housing, the outside of the housing for indoor use An intake port, an outdoor intake port installed outside the housing and inhaling outdoor air, a heat exchanger housed in the housing and heat exchanged between the air sucked through the indoor intake port and the air sucked through the outdoor intake port, and outdoor air pass through One or more bag filters (outside bag filter) connected to the heat exchanger to allow, one or more bag filters (betting bag filter) connected to the heat exchanger to allow indoor air to pass therethrough, and the upper part through the conduit It is connected only to the outside air filter and the inside air bag filter, and the lower part is open to the outside air through a pipeline. And a cylindrical photochemical catalyst oxidizing unit formed to discharge air supplied from the bet bag filter to the lower portion, a space between the oxidizing unit outer cylinder located inside the bag filter and an open top thereof, and the photochemical catalyst oxidizing unit. The post-treatment unit is formed so that the air discharged to the lower portion of the photochemical catalyst oxidizing unit is discharged to the upper through the space, the air discharge fan (top) located in the upper portion of the post-treatment unit in the housing and connected to the rear end of the air discharge fan Consists of an air outlet for discharging to the outside of the housing, the photochemical catalyst oxidation portion is characterized in that it comprises one or more plates and one or more UV lamps coated with TiO ₂ .

At this time, a high pressure blower is connected to a rear end of one of the bet bag filters through a conduit, and a valve for selecting a conduit connected to the photochemical catalyst oxidation unit and a conduit connected to the high pressure blower. It is preferred that the additionally installed and treated by dividing the sucked air directly through the high pressure blower and the case of purifying via the photochemical catalyst oxidation unit.

It is more preferable that each of the purification apparatuses having the above characteristics further includes a separate suction port so that the bag filter connected to the high pressure blower is connected to the separate suction port to suck air through the separate suction port. .

The one or more plates included in the photochemical catalyst oxidizing unit may be installed to protrude toward the center of the ozone generating UV lamp from the inner wall of the photochemical catalyst oxidizing unit over the entire length of the photochemical catalyst oxidizing unit.

Alternatively, the one or more plates included in the photochemical catalyst oxidizing unit have a spiral shape extending from the top to the bottom along the inner wall of the photochemical catalyst oxidizing unit to minimize air pressure decrease and increase air residence time to purify small air. Suitable for the device.

In order to further enhance the effect of the photochemical catalyst, the plate is effective because it consists of a plurality of segments partitioned at regular intervals to generate turbulence.

In order to increase the oxidation power of the photochemical catalyst oxidation portion, the one or more UV lamps are preferably ozone generating UV lamps.

For uniform air treatment, when there are a plurality of UV lamps, it is preferable to be disposed at the same interval on the circumference of a circle included in the photochemical catalyst oxidation unit and the same as the center of the photochemical catalyst oxidation unit.

At this time, when the corona anion generator is further disposed in the center of the photochemical catalyst oxidation unit, the air cleaning function can be ensured, which is more effective for air purification.

In order to remove the strong oxidized component remaining after the reaction participation and minimize the effect on the human body, the ozone catalyst component including MnO ₂ and CuO is transported in the carrier or honeycomb-shaped air in the post-treatment unit. It is preferred to include post-treatment means in the form of impregnation or coating on the path surface.

In order to further purify the air components discharged from the photochemical catalyst oxidizing unit, water is stored in the lower portion of the outer cylinder of the oxidizing unit and a tube is connected to the lower end of the photochemical catalyst oxidizing unit so that the tube is deposited in the water, thereby lowering the photochemical catalyst oxidizing unit. It is preferable that the air discharged from the air passes through the water.

In order to increase the frequency of contact between water and air while reducing the pressure loss caused by the passage of water film, it is preferable that a stirrer is provided inside the tube.

When the stirrer is installed, an appropriate deposition depth is 10 cm or less.

In addition, in the air flow direction, the post-treatment means further includes an adsorption means, and when the air treated by the post-treatment means is made to pass through the adsorption means, it is possible to remove even the pollutant that may remain. effective.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings. In the following description, it should be noted that the contaminated air purifier is also used as an air purifier or purifier for the convenience of the substrate.

3 shows a first embodiment of the contaminated air purification apparatus 100 of the present invention.

As can be seen in the drawings, the contaminated air purification apparatus 100 of the present invention is connected to the cylindrical housing 122, the contaminated air inlet 107 installed on the outside of the housing 122, the inlet 107 And one or more bag filters 101 housed in the housing 122, the upper part of which is connected only to the bag filter 101 through a conduit 105 and the lower part of the bag filter 101 that is open to the bag filter. A cylindrical oxidation section 106 formed to discharge air supplied from the lower portion, a space between the oxidation section outer cylinder 116 located inside the bag filter and the top opened and the photochemical catalyst oxidation section An aftertreatment unit 109 formed to allow air discharged to the lower portion of the photochemical catalyst oxidation unit to be discharged upwardly through the space, an air discharge fan 114 positioned above the aftertreatment unit in the housing 122, and the Rear of air exhaust fan (114) It is connected to the air outlet 108 for discharging the air to the outside of the housing, the housing 122, the housing is made in a portion other than the air inlet and the air outlet so that the air is made only through the air inlet and the air outlet It has a sealed shape.

The air is first sucked in through the inlet of the air purifier.

Fine particles such as dust contained in the contaminated air sucked through the inlet 107 of the contaminated air purification apparatus are filtered by the bag filter 101 connected to the inlet. Therefore, the content of fine particles is rapidly reduced in the air passing through the bag filter 101. However, through the bag filter, air does not necessarily move upward as shown in the drawing, but may move downward. In the present invention, the arrangement direction of the bag filter is not particularly limited. In particular, when the bag filter is disposed downward so that the air can move downward, even when the power of the air purifier is cut off, dust may be stably stored without being separated from the bag filter.

However, volatile organic substances in the air or substances which are not particulate matter as odor causing substances are not removed by physical filtration by the bag filter and still remain. Therefore, special treatment is required to remove the remaining odor causing substances or volatile organic substances. In the present invention, a method of removing the odor causing substance or the volatile organic substance by an oxidation reaction is adopted.

Therefore, the air passing through the bag filter passes through the photochemical catalyst oxidation unit 106 connected to communicate with only the bag filter through a conduit. An example of the specific shape of the said photochemical catalyst oxidation part is shown in FIG. The shape of FIG. 4 shows the case where the photochemical catalyst oxidation part has a cylindrical shape, but the photochemical catalyst oxidation part only needs to have a cylindrical shape, and is not largely attached to the shape of a cross section, such as a quadrilateral or a pentagon. The rod-shaped UV lamp 102 is installed at the center of the photochemical catalyst oxidation unit. In addition, a TiO ₂ -based photochemical catalyst is coated on one or more surfaces of the plate 110 included in the photochemical catalyst oxidation unit. When the TiO ₂ -based photochemical catalyst is irradiated with short wavelength rays such as ultraviolet rays, electrons or holes excited as conduction bands in the valence band react with water in the air to react with superoxide (O ₂ ⁻ ) radicals or hydroxy (OH) radicals. And odor causing substances or volatile organic substances contained in the air by the radical and the like are removed through a strong oxidation reaction.

Therefore, a short wavelength light source for exciting the TiO ₂ -based photochemical catalyst is required, and the UV lamp 102 serves as the short wavelength light source. In addition, when the UV lamp is used as an ozone generating UV lamp, it acts as a short wavelength light source and simultaneously excites oxygen in the air to form ozone. The ozone also participates in the oxidation reaction as a highly reactive substance, Participation in the superoxide formation reaction by TiO ₂ photochemical catalyst.

The TiO ₂ -based photochemical catalyst coated plates 110 and 110 'may be made of a transparent material such as a glass or a quartz plate to facilitate the passage of ultraviolet rays, but a large problem may be caused by using an opaque plate such as a metal plate. none.

In addition, the plate is preferably installed in such a way that as the air passes through the photochemical catalyst oxidation portion, the contact time with the surface is increased as much as possible, while the pressure loss in the air flow direction is reduced as much as possible.

Therefore, the plate 110 employed in the present invention may be installed to protrude toward the center of the ozone generating UV lamp from the inner wall of the photochemical catalyst oxidation unit over the entire length of the photochemical catalyst oxidation unit as shown in FIG. 4. Can be.

The air passing through the photochemical catalyst oxidizing unit 106 is clean air in which most odor-causing substances are removed, but a substance that may affect the human body when directly discharged, such as ozone, superoxide, or hydroxy radicals. Some of these may be included, so removing them is necessary.

Therefore, the post-treatment means 103 is provided in the post-treatment unit 109 to remove oxidizing substances such as ozone. As described above, the post-processing unit 109 is defined as a space between the oxidation unit outer cylinder 116 formed inside the bag filter 101 and the photochemical catalyst oxidation unit 106 located inside the outer cylinder. Provide a flow path for air. The post-processing means 103 is installed in the middle of the air flow path. The post-treatment means 103 may be used in a form in which an ozone catalyst component including MnO ₂ and CuO is coated or impregnated on the surface of an air passage in the form of a carrier or honeycomb as a commonly used ozone reaction catalyst. In particular, in the case of a carrier, it can be filled into the frame in the form of granules to promote the reaction while forming a movement path of air.

The first aspect of the present invention described above can be used in various forms, these can each appear in the following form.

5 and 6 are examples of modifications of the photochemical catalyst oxidation unit 106 of the form described in FIG. FIG. 5 shows a case in which a plurality of ozone generating UV lamps 102 are installed in the photochemical catalyst oxidation unit, as shown in FIG. In order to uniformly supply ultraviolet rays through the plurality of ozone generating UV lamps 102, the above-described UV is spaced on the circumference included in the photochemical catalyst oxidation unit as a circle having a center coinciding with the center of the photochemical catalyst oxidation unit. A plurality of lamps can be installed. The distance between the center of the circle and the UV lamp (ie, the radius of the circle) is preferably 1/4 to 3/4 of the radius of the circle inscribed to the photochemical catalyst oxidation portion. If the distance is too far, interference with the plate 110 may occur. If the distance is too close, it is difficult to obtain a plurality of installed effects.

In this case, as illustrated in FIG. 6, a corona negative ion generator 111 may be additionally installed at the center portion. Since the corona negative ion generator generates negative ions, in addition to the odor removing effect, an air purifying effect of purifying fresh air may be further obtained.

Further, as a modification of the plate coated with the TiO ₂ -based photochemical catalyst, the spiral plate 110 ′ shown in FIG. 7 may be mentioned. In the case of using the spiral plate 110 ', the residence time of the air is increased, but the resistance to the air flow is not greatly increased, so that even when the length of the photochemical catalyst oxidation portion is not sufficient, sufficient reaction efficiency is maintained while maintaining a smooth air flow. Since it can obtain, it is advantageous for the compact apparatus made into object in this invention.

In this case, in order to impart some turbulent properties to the flow of air to facilitate mixing of the air, the spiral plate preferably has a shape divided into a plurality of segments as indicated by a dotted line in FIG. 7.

In order to more strictly regulate strong oxidizing components such as ozone and various radicals in the discharged air, it is preferable to pass the discharged air through water. To this end, as shown in FIG. 8, it is preferable to store water in the outer cylinder of the oxidizing unit and extend the lower portion of the photochemical catalyst oxidizing unit to the guide tube 118 to induce air to pass through the water. In this case, in order to sufficiently remove the strong oxidizing component in the air by using water, the air needs to be in contact with water for a long time. Therefore, it is necessary to have a deep depth in which the tube extending the lower portion of the photochemical catalyst oxidation part is immersed in water. However, in this case, since the load is added to the fan that finally discharges air, it is not preferable.

Therefore, in the present invention, the stirrer 117 is installed near the lower water surface of the tube in order to obtain a sufficient removal effect without increasing the load of the fan. When the stirrer is installed, the area where water and air contact by the stirrer increases, so that the strong oxidative hydrophilic component can be easily removed even if the depth of deposition of the tube is not large. The stirrer can be in any form as long as it can stir the water, and in particular, a watermill form is effective. As a result, the depth of deposition of the tube can be maintained at 10 cm or less, and since the amount of pressure loss at that time is about 30 mmAq, the contact frequency between water and air can be increased without large pressure loss.

In addition, since the UV lamp or the negative ion discharger is connected to the bottom of the photochemical catalyst oxidation unit 106, it should not be deposited in water.

In the water, KI can be used by dissolving KI below a saturation concentration. When ozone contacts KI, ozone is converted to oxygen and iodine ions are precipitated, and when hydroxyl radicals contact, KOH is formed, so that KI can enhance the ozone removal effect of water. The amount of KI dissolved is not particularly limited, but if it is above the saturation concentration, it is difficult to participate in the reaction.

In addition, after the post-treatment means (ie, the present invention) when the adsorption means 112 made of charcoal, activated carbon, or zeolite, etc., is viewed in the air flow direction in order to remove moisture or finally sterilize the air discharged. In the device configuration of the present invention, the post-processing means 103 may be installed directly above). Adsorption means 112 of the present invention is similar to that employed by the Bioclimax company, but the effect is completely different. That is, in the conventional apparatus employed by the Bioclimax company, since most of the purification is performed in the adsorption chamber 13, there is a problem in that the replacement cycle of the adsorption chamber is shortened because the rate of adsorption of the pollutant to the adsorption chamber is very fast. In the present invention, since most of the contaminants are already removed from the photochemical catalyst oxidation unit and the post-treatment means, the amount of the substance adsorbed on the adsorption means is only small enough to be negligible, and the use of the contaminants may be eliminated. The adsorption means can be used in very long replacement cycles or semi-permanently.

9 shows another embodiment (second embodiment) of the contaminated air purifying apparatus of the present invention.

The purification apparatus of FIG. 9 is one of the plurality of bag filters 101 connected to the high pressure blower 118, except that the purification apparatus of FIG. 3 and a modification thereof (ie, the first embodiment of the present invention) are used. Form).

In addition, the bag filter connected to the high pressure blower is connected to the high pressure blower 118 when the high pressure blower 118 is operated by a valve, and in the first embodiment of the present invention when the discharge fan 114 is operated. Like the purification apparatus described above, it may be connected to the photochemical catalyst oxidation unit 106 through a conduit. In addition, a separate suction port (not shown) is connected to the bag filter connected to the high pressure blower 118 to avoid pressure dispersion to other bag filters.

In general, the blower refers to a blowing means having a pressure ratio between the suction port and the discharge port of 1.1 to 2.0, and is widely used in vacuum cleaners and the like. Since the dust or garbage existing in the room can be sucked at a high pressure due to the pressure of the high pressure blower, the purifying device of the present embodiment can also have a function of a vacuum cleaner.

10 shows another embodiment (third embodiment) of the purification apparatus of the present invention. As can be seen in FIG. 10, the purification apparatus of this embodiment has two suction ports 107 and 123. One of the intake ports can inhale outside air (outside air), and the other is designed to inhale inside air (indoor air). However, when the temperature difference between the outside and the inside air is significant, heat loss or cooling loss may occur. As shown in FIG. 11, the inside and outside air sucked in are exchanged through the heat exchanger 124 connected to the intake port. The heat exchanged outside air is purified through one or more bag filters 101 through the same path as described in the first embodiment of the present invention and discharged through the indoor outlet. On the other hand, the heat exchanged bet may be purified through the same path as the outside air through one or more bag filters connected to the bet and discharged back to the room, or through a valve operation mounted on the bag filter 101 connected to the bet. It is discharged through an outdoor outlet. Like the indoor outlet 108, the discharge fan 120 is attached to the outdoor discharge port 121, and the bag filter-discharge fan-outdoor discharge port is connected to a pipe and the bet discharged to the outdoor discharge port 121 is discharged for indoor use. It is made so as not to mix with the outside air discharged to the. In addition, the bag filter connected to the indoor air inlet 107 and the outdoor outlet 121 and the bag filter connected to the outdoor air inlet and the indoor outlet may be selected and used in an appropriate number.

The polluted air purifying device in the present embodiment has an outside air inlet 123 and an internal air inlet 107, an indoor outlet 108, an outdoor outlet 121, and a heat exchanger 124. The other configuration than that is the same as the purification device in the first embodiment.

Another embodiment of the invention is shown in FIG. The contaminated air purification apparatus illustrated in this embodiment has three intake ports. One is an intake port communicating with the bag filter 101 connected to the high pressure blower described in the second embodiment of the present invention, and the other is an air intake 107 port and an outside air intake port 123 shown in the third embodiment of the present invention. That is, the present embodiment combines the second and third embodiments of the present invention. Therefore, the suction port communicating with the bag filter connected to the high pressure blower 118 may be used in combination with the bet suction port without separately installed. The high pressure blower 118 of the present invention is connected to one of the bag filter and the air inlet 107 and the outdoor air inlet 123 are connected to the appropriate number of bag filters, respectively, after purification and the outdoor outlet 121 and the indoor outlet. Discharge through 108. The method connected to the said bag filter, the method of purifying air, etc. are the same as that in the above-mentioned embodiment.

As described above, the contaminated air purifying apparatus of the present invention is not only designed to efficiently handle a large amount of air efficiently even with a small volume, but also by installing an additional blower or fan to perform vacuum cleaning and air exchange and cleaning. It is an efficient compact air purifier with a function.

As described above has been described through some preferred embodiments of the present invention, it should be noted that the above embodiments are only for explaining the present invention and are not intended to limit the present invention. This is because the scope of the present invention is determined by the matters described in the claims and the matters reasonably inferred therefrom.

As described above, according to the present invention, it is not only possible to provide a contaminated air purifying device suitable for small use, such as a local exhaust micro deodorization device, a workplace air purification or a household, but also a vacuum cleaning function and air cleaning / heat exchange. High efficiency air purifiers with functions can also be provided.

Claims (18)

An air purifier for purifying polluted air, The contaminated air purifier may include a cylindrical housing, a contaminated air intake installed outside the housing, one or more bag filters connected to the intake and received inside the housing, and an upper portion thereof through a conduit. A cylindrical photochemical catalyst oxidation unit which is connected to only the bag filter and is opened to lower the air supplied from the bag filter through the conduit; A post-treatment part defined as a space between the photochemical catalyst oxidation parts and formed so that the air discharged to the lower part of the photochemical catalyst oxidation part is discharged upward through the space, an air discharge fan located above the post-treatment part in the housing; Is connected to the rear end of the air discharge fan consists of an air outlet for discharging air to the outside of the housing , And the photochemical catalyst oxidation unit comprises one or more plates coated with TiO ₂ and one or more UV lamps. The method of claim 1, wherein a high pressure blower is connected to a rear end of one of the bag filters through a conduit, and the bag filter may select a conduit connected to the photochemical catalyst oxidation unit and a conduit connected to the high pressure blower. And a valve is additionally installed so that the sucked air is discharged directly through the high pressure blower and the case of purifying via the photochemical catalyst oxidation unit. The polluted air purifier of claim 2, further comprising a separate intake port, wherein the bag filter connected to the high pressure blower is connected to the separate intake port to suck air through the separate intake port. An air purifier for purifying polluted air, The contaminated air purifier may be provided in a cylindrical housing, an indoor inlet installed outside the housing and sucking indoor air, an outdoor inlet installed outside the housing and sucking outdoor air, and accommodated in the housing. A heat exchanger for heat-exchanging the air sucked through the intake port and the air sucked through the outdoor intake port, one or more bag filters connected to the heat exchanger to allow outdoor air to pass therethrough, and indoor air One or more bag filters connected to the heat exchanger (bag filter), The upper part is connected to only the outside bag filter and the inside bag filter for the outside air through the conduit, and the lower part is a tubular photochemical catalyst formed so that the air supplied from the outside air and the inside bag filter through the pipe can be discharged to the lower side. An oxidizing unit is defined as a space between an oxidizing unit outer cylinder located inside the bag filter and an open top and the photochemical catalyst oxidizing unit, and is configured to allow air discharged to the lower portion of the photochemical catalyst oxidizing unit to be discharged upward through the space. A post-processing unit, an air exhaust fan located at an upper portion of the post-processing unit in the housing, and an air outlet connected to a rear end of the air exhaust fan to discharge air to the outside of the housing, And the photochemical catalyst oxidation unit comprises one or more plates coated with TiO ₂ and one or more UV lamps. 5. The method of claim 4, wherein a high pressure blower is connected to a rear end of one of the bet bag filters through a conduit, and the bag filter selects a conduit connected to the photochemical catalyst oxidation unit and a conduit connected to the high pressure blower. And a valve capable of additionally discharging the sucked air through a high pressure blower and purifying it via a photochemical catalyst oxidation unit. 6. The polluted air purification apparatus as claimed in claim 5, further comprising a separate intake port, wherein the bag filter connected to the high pressure blower is connected to the separate intake port to suck air through the separate intake port. The ozone generating UV lamp according to any one of claims 1 to 6, wherein the one or more plates included in the photochemical catalyst oxidation unit have a central ozone generating UV lamp from the inner wall of the photochemical catalyst oxidation unit over the entire length of the photochemical catalyst oxidation unit. Polluted air purification device, characterized in that installed in the form protruding toward the center of the. The contamination according to any one of claims 1 to 6, wherein the one or more plates included in the photochemical catalyst oxidation portion have a spiral shape extending from the top to the bottom along the inner wall of the photochemical catalyst oxidation portion. Air filter. 9. The polluted air purification system as recited in claim 8 wherein said plate comprises a plurality of segments partitioned at regular intervals. The polluted air purification device according to any one of claims 1 to 6, wherein the one or more UV lamps are ozone generating UV lamps. The method according to any one of claims 1 to 6, wherein the plurality of UV lamps are the same as the center of the photochemical catalyst oxidation unit and are arranged at equal intervals on the circumference of a circle included in the photochemical catalyst oxidation unit. Polluted air filter. 12. The polluted air purification device as recited in claim 11, wherein a corona anion generator is further disposed in the center of the photochemical catalyst oxidation unit. The post-treatment unit according to any one of claims 1 to 6, wherein the post-treatment unit includes a post-treatment unit in which an ozone catalyst component including MnO ₂ and CuO is impregnated or coated on a surface of a carrier or honeycomb-shaped air movement path. Contaminated air purification apparatus, characterized in that included. According to any one of claims 1 to 6, wherein the water is stored in the outer cylinder of the oxidation unit and a tube is connected to the lower end of the photochemical catalyst oxidation unit by depositing the tube in the water discharged from the lower photochemical catalyst oxidation unit A contaminated air purifier, characterized in that the air is formed to pass through the water. 15. The polluted air purification device as recited in claim 14, wherein a stirrer is provided inside the tube. 16. The contaminated air purifier of claim 15, wherein the depth of deposition of the tube is 10 cm or less. 15. The polluted air purification system as recited in claim 14 wherein the KI at a saturation concentration or less is dissolved in the water. The air treated by the post-treatment means of claim 1, further comprising adsorption means including charcoal, activated carbon, or zeolite behind the post-treatment means in the air flow direction. A contaminated air purifying apparatus, characterized in that it is configured to pass through adsorption means.

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