KR20130119336A - Gas purification apparatus - Google Patents

Abstract

PURPOSE: An air cleaner applies an air inlet having a vane in a novel structure, a droplet spray apparatus and a and gas-liquid separator and can effectively remove contaminants such as dust from air through a cyclone wet air cleaning device as a the multi level structure and a dry or wet air cleaning device located on the upper part of the cyclone wet air cleaning device. CONSTITUTION: An air cleaning device (1000) comprises a cyclone wet air cleaning device (100) and a wet scrubber (200-1-200-2) with at least one step installed on the upper part of the cyclone wet air cleaning device or a dry air cleaning device. The cyclone wet air cleaning device comprises: a cylindrical main body; an air inlet (30) of which at least one is installed in a diagonal or a normal direction, not the center point of the cylindrical main body, and comprises an opening and a vane which acts as a rotary plate of the air for rotating the flow of air; and a droplet spray apparatus (20-1-20-3) installed inside of the air inlet inside of the main body of the cyclone wet air cleaning device to sprays the washing solution with the droplet.

Description

Air purification apparatus

The present invention relates to an air purifying apparatus capable of removing dust, soot, pollen and other harmful substances from air.

The present invention relates to an air purifier, and a method of purifying air can be largely divided into a dry method and a wet method, or a method of mixing dry and wet methods.

A representative example of the dry method is a method using a filter. In the case of the filter method, the fine particulate dust cannot be completely collected and purified, and when a gas containing dust is attracted, it accumulates on the surface of the filter, and due to the clogging of the filter, the dust collection efficiency is drastically reduced and it becomes a hotbed of pathogens or bacteria. Therefore, there is a problem of maintenance due to regular replacement, and the secondary filter causes the environmental pollution due to the generation of secondary environmental pollutants due to the discarded filter nonwoven fabric. In addition, there are other gas purification apparatuses including photocatalyst, electrostatic precipitating, and plasma in other dry methods, but gas purification efficiency is low, and negative ion generating gas purification apparatus is known to have side effects of ozone generation, which is harmful to human health. . The dry-type centrifugal type gas purifier is theoretically capable of gas purification efficiency of 90 ~ 95%, but it is impossible to collect and purify the fine particulate dust, pollen, tobacco smoke, and harmful gas with less than 5μm harmful to human health and hygiene. It is an industrial gas purifier that simply centrifugally removes dust in the gas.

On the other hand, the wet method is a method of purifying the gas by the viscous adhesion of water by attracting the gas flow in the gas purifier and the two-dimensional water film surface contact. Only contaminants in the gas in contact with the water film surface area are purified by the viscous adhesion of water, and most of the contaminants that do not contact the water film surface area are not purified, and gases containing excessive moisture are discharged to provide precision equipment. There was a problem of corrosion. In terms of gas dynamics, conventional wet gas purifiers are capable of purifying fine dust smaller than 0.1 μm and their gas purification efficiencies are relatively higher than those of other types of gas purifiers, but they are limited to less than 85% in theory. There was a problem of being unsanitary and pathologically sterilizing the washing water as a hotbed of pathogens. In particular, the conventional wet method has a problem in that the purified gas and moisture recombine again.

Meanwhile, referring to the related patent technology, Korean Patent Publication No. 10-1994-0023518 discloses a technique for spraying water with a nozzle using a pump, which does not require a pump, and discloses a technology for separating air and moisture. Patent Publication No. 10-2006-0055008 is a technology that after the water is supplied from the bottom to the top of the water, the water is scattered from the air rising from the bottom through three scattering means, the pump is essential for the supply of the wash water In addition, there is no disclosure about the technology in which the air only rises and rotates.

Republic of Korea Patent Publication No. 10-1994-0023518 Republic of Korea Patent Publication No. 10-2006-0055008

An object of the present invention is a technology related to an air purifying device that can be used for home or industrial use, as well as applying a gas-liquid separation device capable of separating droplets and air with a simple structure, the injection of the droplets is a simple structure rather than an expensive nozzle It is sprayed through the pipe shape of the, and also easy to clean the droplet spraying device is applied to provide a highly efficient air purifier as a simple structure.

In particular, the present invention is a multi-stage air purifier composed of two or more stages, the first stage of the bottom of the contaminated air is a cyclone wet air purifier, the upper or two stages of the air purifier that can be used wet or dry It aims to provide.

The present invention provides a cyclone wet air purifier, and at least one stage of a wet scrubber or a dry air purifier installed above the cyclone wet air purifier, wherein the cyclone wet air purifier is cylindrical. Main body; An air inlet installed in at least one air inlet in a diagonal or normal direction instead of the center point of the cylindrical body, the air inlet including a vane and an opening that serve as a rotating plate of air for rotating the flow of air; And a droplet spraying device installed in the air inlet or in the main body of the cyclone wet air purifying device to spray and spray the cleaning liquid by dropping the liquid from the wet state air rotating in the cyclone wet air purifying device. The gas-liquid separator which separates and removes and sends dry air to the upper wet scrubber or dry air purifier is penetrated between the cyclone wet air purifier and the upper wet scrubber or dry air purifier. It provides an air purifying device.

In particular, the gas-liquid separator comprises: a cylindrical separator; At least one wet air inlet installed at a lower side of the cylindrical separator and installed in an oblique direction rather than a center direction of the cylindrical separator to allow the injected wet air to rise while rotating; And a drain pipe installed at a lower bottom of the cylindrical separation part and removing droplets collected on the bottom surface to the outside.

In particular, it is preferable that a fan for forcibly delivering air to the front end of the wet air inlet or the rear end of the separation unit is further installed.

In particular, it is preferable to further have a cylindrical enlarged separation portion larger in diameter than the separation portion above the separation portion.

In particular, it is preferable to further have an orifice in the separating part or enlarged separating part.

In particular, the droplet ejection apparatus includes a cleaning liquid pipe having one or more cleaning holes through which cleaning liquids can be injected, and a collision plate that is spaced apart from the cleaning liquid pipe so that the cleaning liquids sprayed from the cleaning holes collide to form droplets. It is preferable to make it.

In particular, it is preferable that the cleaning hole of the cleaning liquid pipe further increases the cutting width from the inner diameter to the outer diameter so that the cleaning liquid is sprayed in a fan shape.

In particular, when a wet scrubber is used on the upper portion of the cyclone wet air purifier, the tank containing the cleaning liquid is divided into a first tank and a second tank, and the cleaning liquid of the first tank is supplied to the cyclone wet air purifier. The cleaning liquid of the second tank is supplied to the upper wet scrubber, and the make up water supplied from the outside is supplied only to the second tank, and when the cleaning liquid for refilling the first tank is required, It is preferable that a pipe is provided so that the cleaning liquid of the tank is supplied to the first tank.

In particular, it is preferable that the level of the cleaning liquid of the second tank is higher than that of the first tank, and the cleaning liquid is moved from the second tank to the first tank by the level difference.

The present invention applies an air inlet, a droplet ejection device, and a gas-liquid separation device having a vane of a novel structure, and has a cyclone wet air purification device as a multi-stage structure, and a dry or wet air purification device located above the cyclone wet air purification device. The device can effectively remove dust and other contaminants from the air.

Figure 1a is a conceptual diagram of the air purifier of the present invention having a wet scrubber on the top, Figure 1b is a conceptual diagram of the air purifier of the present invention having a dry air purifier on the top.
Figure 2a is a view for explaining the installation direction of the air inlet is installed on the lower side of the cyclone wet air purifier of the present invention, Figure 2b is a view for explaining the structure of the vane (vane) of the air inlet of the present invention 2C is a view for explaining the principle that the air introduced due to the vanes in the air inlet of the present invention has a rotational direction rather than a linear direction, and FIG. 2D is an embodiment in which a droplet ejection apparatus is installed inside the air inlet. 2E is a view for explaining an embodiment in which a droplet ejection apparatus is installed in a cyclone wet air purifier.
3A is a perspective view of the droplet ejection apparatus of the present invention, FIG. 3B is a cross sectional view thereof, and FIG. 3C is a longitudinal sectional view thereof.
Figure 4a is a perspective view of a gas-liquid separation device according to a preferred embodiment of the present invention, Figures 4b and 4c is a horizontal cross-sectional view and a vertical cross-sectional view, Figure 4d is a cross-sectional view of a gas-liquid separation device having four wet air inlet, Figure 4e 4 is a cross-sectional view of the gas-liquid separator further having an enlarged separator, FIG. 4F is a cross-sectional view of the gas-liquid separator further including an orifice, and FIG. 4G is a cross-sectional view of the gas-liquid separator further having a lid thereon.
FIG. 5 is a more detailed embodiment of FIG. 1A, which is an embodiment of the air purifier of the present invention having a three-stage wet scrubber on top of a cyclone wet air purifier.
FIG. 6 is a view for explaining the sludge deposit accumulated in the cleaning liquid pipe automatically descends to the pump through the pipe together with the cleaning liquid in the air purifier of the present invention.

1A and 1B are conceptual views of an air purifying apparatus 1000 according to a preferred embodiment of the present invention. 1A and 1B, the air purifier 1000 of the present invention is a structure in which two or more stages of wet and dry air purifiers are combined, and a cyclone wet type as a wet air purifier at the lower end where the air inlet is located. The air purifier 100 is an essential component, but may have a wet or dry air purifier on the cyclone wet air purifier 100.

Figure 1a is a three-stage air purifying apparatus 1000 according to an embodiment of the present invention, the lowermost one stage is a cyclone wet air purification apparatus 100, the cyclone wet air purification apparatus 100 ) Is an embodiment in which the wet scrubber (200-1, 200-2) is composed of two stages. Of course, the wet scrubber 200 may be composed of three or more stages. Gas-liquid separators 10-1, 10-2, and 10 between the cyclone wet air purifier 100 and each of the wet scrubbers 200-1 and 200-2 and on top of the wet scrubbers 200-2. -3) is installed between the two air purifiers through each stage to separate the cleaning droplets from the air rising from the lower air purifier to the upper air purifier. The wet scrubber may also be filled with a packing material to increase the gas-liquid contact area.

FIG. 1B is a conceptual diagram of an air purifier 1000 according to an exemplary embodiment of the present invention, which has a cyclone wet air purifier 100 positioned at the bottom thereof, which is the same as that of FIG. 1A, but has a dry air purification thereon. As an apparatus, it has various dry air purification apparatuses 300, such as a filter and the electrostatic precipitating filter 310. As shown in FIG. A gas-liquid separator 10 is located between the air purifiers between the cyclone wet air purifier 100 and the dry air purifier 300. Purified air is discharged to the outside through the air outlet 320 at the top of the dry air purifier 300, but it is preferable that a forced blower such as a fan is installed at the air outlet 320, but not shown in the drawings. It was.

In FIG. 1A and FIG. 1B, the droplet ejection apparatus 20-1 of the cyclone wet air purifier 100 is expressed as being installed in the main body of the cyclone wet air purifier 100, but this is in the air inlet 30. It may be installed, or may be installed at the same time in the cylinder body of the air inlet 30 and the cyclone wet air purifier (100). In addition, in FIG. 1A, the droplet ejection apparatuses 20-1 to 20-3 are each provided in one stage, but they may be installed in multiple stages vertically and horizontally, but only one of them is represented for convenience of description. .

Hereinafter, each component in the air purifier 1000 of the present invention will be described.

Structure of the air inlet 30

Figure 2a is a view for explaining the installation position of the air inlet 30 is installed on the lower side of the cyclone wet air purification apparatus 100 of the present invention, the air inlet 30 is a cyclone wet air purification apparatus as shown in FIG. The contaminated air introduced into the cyclone wet air purifier 100 from the outside is positioned at a predetermined angle, or in an oblique direction (or normal direction) without facing the center point of the cross section of the cyclone wet air purifier 100. The droplets and air are easily separated by the cyclone effect while rotating upward along the inner wall.

Figure 2b is a view showing the structure of the vane (vane) of the air inlet (30) of the present invention, part of the air inlet 30 of the present invention is connected to the cyclone wet air purifier 100 is blocked partly air Is a vane 32 serving as a rotation guide of air for rotating circularly rather than linearly, and has an opening 31 partially open. As such, a part of the rear end of the air inlet 30 is formed by the vane 32, and the reason will be described in more detail with reference to FIG. 2C.

FIG. 2C is a view for explaining the role of the vane 32 in the air inlet 30 of the present invention. In the vane 32, a part a1 of the total amount of air introduced a3 is vaned by the vane 32. It is combined with the air (a2) flowing into the opening 31 while rotating along the curve of, the air (a3) in the cyclone wet air purifier (100) due to the air (a2) having a rotational force by this vane (32) ) Is increased compared to the case where the vane (32) is absent. That is, the air inlet 30 itself of the present invention is located in an oblique direction (see FIG. 2A) instead of the center point of the cyclone wet air purifying apparatus 100 to allow the introduced air to rise while rotating, and the air inlet 30. Due to the vanes 32 in the inner side, a dual structure rotational motion enhancement method is used to further increase the rotational force of the air.

On the other hand, the outer wall itself of the cyclone wet air purifier 100 may serve as a vane 31, the vane 31 may be formed in a separate configuration at the rear end of the air inlet (30). The vane 31 is a component for rotating the flow of air. The vane 31 is not limited in shape as long as it serves as a guide for allowing the air to be curved instead of going straight in various forms such as a screw type and a plate having an arc. .

2A to 2C are omitted descriptions of the apparatus for injecting droplets into the air flowing into the air inlet 30. Hereinafter, dusts are removed from the air having a lot of dust coming from the air inlet 30 through FIGS. 2D and 2E. The position of the droplet ejection apparatus 20 for providing a surface area for the purpose of description will be described.

FIG. 2D illustrates a case where the droplet ejection apparatus 20 is located inside the air inlet 30, and FIG. 2E illustrates that the droplet ejection apparatus 20 is not included in the cyclone wet air purifying apparatus 100 instead of the air inlet 20. This is an example of where a dog exists. Of course, the droplet injection device 20 may be installed in both the air inlet 30 and the cyclone wet air purifying apparatus 1001 in the mixed form of FIGS. 2D and 2E.

Hereinafter, the structure of the droplet ejection apparatus 20 will be described in detail.

Of the droplet ejection apparatus 20  rescue

3A is a perspective view of the droplet ejection apparatus 20 of the present invention, and FIGS. 3B and 3C are cross-sectional views.

The droplet ejection apparatus 20 of the present invention includes a cleaning liquid pipe 21 and a collision plate 25. First, the cleaning liquid pipe 21 has a basic shape of a conventional pipe having a space in which the cleaning liquid can flow. In addition to this basic form, the cleaning liquid spraying hole 22 is formed in the lower portion of the cleaning liquid pipe 21 at regular or irregular intervals in order to spray the cleaning liquid. The cleaning liquid sprayed into the cleaning liquid spraying hole 22 hits the colliding plate 25 installed at a predetermined interval below, and is dispersed in droplets having a small size, for example, particles of several tens of micrometers to several mm in size, and contaminated air. Pollutants are delivered through mass exchange. Of course, if necessary, the impingement plate 25 is composed of a porous plate, so that some of the cleaning liquid that has passed through the porous plate may also receive contaminants through material exchange with contaminated air rising from the lower portion. When the spraying apparatus 20 using the cleaning liquid pipe 21 and the impingement plate 25 of the present invention is sprayed at an appropriate pressure or higher, the gas-liquid surface area is increased and the blockage is higher than that of the conventional gas-liquid surface area increasing method using a packing material. There is no merit that can maintain constant performance at all times.

3B and 3C, the cleaning liquid spraying hole 22 is preferably formed by cutting at the same angle α at the inner diameter 23 and the outer diameter 24 with respect to the central axis of the cleaning liquid pipe 21. Do. In addition, even if the angle is not the same angle with respect to the central axis, the cutting liquid is cut in an oblique direction (or "8" shaped incision) so as to increase the cutting width from the inner diameter 23 to the outer diameter 24, thereby cleaning liquid out of the washing liquid spraying hole 22. When it is sprayed, it is preferable to spray while spreading in a fan shape so as to hit the impingement plate 25. This is because droplets are easy in the case of being widely sprayed and colliding with the collision plate 25.

As described above, the impingement plate 25 of the present invention may use a porous plate such as metal or plastic having a plurality of holes. The cleaning liquid injected from the injection hole 22 of the cleaning liquid pipe 21 collides with droplets, and the cleaning liquid that has permeated through the holes of the porous plate 25 falls down and contaminates through air and mass exchange. Will be removed. The cleaning liquid, which is hit by the impingement plate 25 and droplets, is lowered after receiving contaminants from the rising air.

Of gas-liquid separator 10  rescue

4A is a perspective view of a gas-liquid separator according to a preferred embodiment of the present invention, and FIGS. 4B and 4C are horizontal and vertical cross-sectional views thereof.

In order to separate and remove the droplets downward from the mixed air of the wet state, and to separate the dry air upwards, the gas-liquid separator 10 of the present invention is a cylindrical separator 11, wet air inlet 12 And a drain tube 13. Further, preferably, a fan 17 for blowing air is provided at the front end of the wet air inlet 12 or the rear end of the separation unit 11 (the rear end of the expansion separation unit 14 when the expansion separation unit 14 is provided). Installed to help the flow of air in the gas-liquid separator 10 of the present invention.

Cylindrical separator 11 means a conventional cylindrical chamber shape. The cylindrical separating part 11 of the present invention includes not only a cylindrical shape having the same diameter in all cross sections of the separating part, but also a modified cylindrical shape in which the upper and / or lower diameters are narrowed or widened based on the cylindrical type. Used to mean. In addition, in the cylindrical separation unit 11 of the present invention, one or more wet air inlets 12 to be described later are installed on the lower side, and in particular, it is preferable to be installed at positions symmetrically with each other evenly two or four. .

In addition, the upper part of the cylindrical separation part 11 has a cylindrical dry air outlet 15 which is narrower than the diameter of the cylindrical separation part 11, and the fan 17 in the said dry air outlet 15 is carried out. It is preferable to be installed. Of course, the fan 17 may be installed at the top of the separation unit 11 without the dry air outlet 15, or at the top of the expansion separation unit 14 to be described later.

The reason why the separating part 11 should be cylindrical in the present invention is that the separating part 11 must have a cylindrical shape in order to rise while the wet air entering through the wet air inlet 12 rotates. In addition, for the same reason, the enlarged separator 14 to be described later should also have a cylindrical shape.

As described above, the wet air inlet 12 is located below the cylindrical separator 11. The wet air flowing into the lower part of the cylindrical separation part 11 naturally rises and rotates. In this process, heavy moisture naturally dense by the centrifugal force aggregates and rides on the inner wall of the separation part 11. Falling to the bottom, the cleaning liquid is discharged through the drain pipe 13 is installed in the lower portion of the separation unit 11, in particular, the center of the bottom surface of the separation unit (11).

Therefore, in order to ascend the wet air entering the wet air inlet 12 while performing a preliminary rotation, as shown in FIG. 4B, the wet air inlet 12 is not in the center direction of the cylindrical separator 11 but in a diagonal direction (or, normal). Direction). The advantage is the same principle as the above-described air inlet 30 is located in an oblique direction with respect to the cyclone wet air purification apparatus 100 to rotate the air. That is, when the wet air inlet 12 is installed in the oblique direction as described above, the wet air injected into the wet air inlet 12 rises while rotating in a linear manner as shown in FIG. 4C, and the droplets of the cleaning liquid are in this pre-rotating process. Because of the high density, by naturally falling to the inner wall of the separation unit 11 and descending by gravity, droplet separation is possible using a cyclone principle in which air and liquid droplets are separated. Therefore, the liquid droplets are removed from the air at the upper portion of the separation unit 11 to become a dry air state with little moisture.

The drain pipe 13 of the present invention is a drain pipe for discharging the liquid droplets separated from the above-described cylindrical separation part 11 to the outside, and the bottom surface (= bottom) of the separation part 11 in a straight line as shown in FIG. It is located near the floor. In addition, as shown in Figure 4e may be a form bent in a "U" shape. When the U-shaped portion is bent as shown in FIG. 4E, the droplets are filled in the “U” -shaped portion, so that the dry air does not escape into the drain tube 13 and then rises to the upper portion of the separating portion 11 and is discharged to the outside. There is an advantage.

4D is a cross-sectional view of the gas-liquid separator 10 having four wet air inlets 12. As described above, in the cyclone-type gas-liquid separator 10 of the present invention, one or more wet air inlets 12 may be installed on the lower wall of the separator 11. For example, in FIGS. 4A and 4B, an embodiment having two wet air inlets 12 has been described, but three or more are possible. In particular, it is also possible to have four wet air inlets 12, as shown in Figure 4d, wherein the installation direction of each wet air inlet 12 is the same direction after the injection of wet air into the separating portion 11 (half in Figure 4d) It should be installed in consideration of the installation position so that it can rotate to the wet air inlet 12 so that the air rotates clockwise.

4E is a cross-sectional view of the gas-liquid separator 10 further having an enlarged separator. The cyclone-type gas-liquid separator 10 of the present invention may further have an enlarged separator 14 having a diameter D1 larger than the diameter D2 of the separator 11 in order to increase the gas-liquid separation efficiency. The expansion separator 14 should also be cylindrical (= cylindrical) like the separator 11. As described above, the separator 11 and the enlarged separator 14 must be cylindrical so that the air can rise while rotating. The enlarged separator 14 is located at the upper portion of the cylindrical separator 11, and if there is an enlarged separator 14, the dry air outlet 15 should be located at the upper portion of the enlarged separator 14. Of course, as described above, the fan 17 may be directly coupled to the upper portion of the expansion separator 14 without a separate dry air outlet 15.

In the present invention, in addition to the separation unit 11, the expansion separation unit 14 is further provided because the centrifugal force is increased by increasing the diameter. In other words, the centrifugal force = mrω ² , and r is the radius, and the larger the radius, the greater the centrifugal force, and therefore, the greater the moisture, the greater the centrifugal force.

4F is a gas-liquid separator 10 according to another embodiment of the present invention, which further includes an orifice 16. In the present invention, as shown in FIG. 4F, an orifice 16 having a diameter D3 of a through hole 16a smaller than the diameter D2 of the separation part 11 may be further provided on the separation part 11. This is because the orifice 16 is further provided inside the upper part of the separator 11 to induce a substance such as dust in the air to hit the orifice 16 and fall downward. Of course, unlike FIG. 4F, the orifice 16 may be installed inside the upper end of the separator 11 of the first embodiment without the enlarged separator 14. That is, the installation of the orifice 16 may be installed inside the upper end of the separator 11 with or without the enlarged separator 14.

Figure 4g is another embodiment of the gas-liquid separator of the present invention is an embodiment further having a cap 18 of the shape of the top. When the upper air purification apparatus is configured in the form of a multi-stage wet scrubber (see FIG. 1A), it may further have a cover 18 that serves as an umbrella so that droplets falling from the upper portion do not flow into the gas-liquid separator placed underneath. . In this case, the air that has risen through the gas-liquid separator 10 is discharged through the vent 19 under the cover 18.

The invention Example  Wet on top Scrubber  Of air purifier

Figure 5 is a more specific embodiment of the above-described Figure 1a, an embodiment of the air purifying apparatus of the present invention having a two-stage wet scrubber (200-1, 200-3) on top of the cyclone wet air purification apparatus 100 to be.

Air containing dust introduced into the cyclone wet air purifier 100 is rotated and the droplets are heavy, so the specific gravity falls to the bottom, and the air rising while rotating is the wet scrubber 200-1 of the first stage. Only the droplets are separated through the gas-liquid separator 10-1 located in the cyclone wet air purifier 100, and only air is transferred to the first stage wet scrubber 200-1. The air transferred to the first stage wet scrubber 200-1 delivers dust to the water sprayed by the droplet ejection apparatuses 20-2 and 20-3 of the first wet scrubber 200-1, and then becomes more clean. After separating the remaining droplets while passing through the gas-liquid separator 10-2 in the air state and passing only the air, again scrubbing the dust in the second wet scrubber 200-2, the gas-liquid separator 10 -3) discharges clean air from which dust is removed to external or other process.

In addition, the circulation of the washing | cleaning liquid in FIG. 5 is demonstrated. In the lower part of the air purifying apparatus of the present invention, it is preferable that the reservoir of the washing liquid is divided into two. That is, the first storage tank 410 in which the cleaning solution of the cyclone wet air purifier 100, through which the most polluting cleaning solution circulates, and the cleaning solution collected in the bottom surface of the second wet scrubber, in which the relatively clean cleaning solution circulates are stored. It can be divided into two tanks (420). The cleaning liquid collected on the bottom surface of the first wet scrubber may be selectively connected to the first tank 410 or the second tank 420 to circulate the cleaning liquid, which is an embodiment connected to the first tank in FIG. 5A. The cleaning solution of the tank is dropleted through each droplet spraying device 20 through a pipe connected as shown in FIG. 5, and then collected again into a corresponding first tank 410 or second tank 420, and the circulation process is performed again. Repeat The cleaning solution is used several times instead of one time, and some of the cleaning solution is drained. If necessary, the cleaning solution is made up with clean cleaning solution, so that the cleaning solution maintains a constant contamination level.

In particular, make-up water is preferably supplied to the second tank 420 in which a relatively clean cleaning liquid is used. On the other hand, since the first tank 410 becomes more dirty as the dust melts from the air as the operating time passes, the cleaning solution of the first tank 410 must also be partially replenished with a clean cleaning solution. It is also possible to supply make up water directly to the first tank 410, but it is preferable to allow the cleaning liquid to move from the relatively clean second tank 420 to the first tank 410 as shown in FIG. 5. . In FIG. 5, the cleaning liquid is moved from the second tank 420 having a high water level to the first tank 410 through the connecting pipe 430 between the first tank 410 and the second tank 420. At this time, the water level h2 of the second tank 420 is higher than the water level h1 of the first tank 410 and thus the first tank (420) from the second tank 420 by this water level difference (h ₂ > h ₁ ). Preferably, the cleaning liquid is supplied to the 410, but the present invention is not limited thereto, and the cleaning solution may be forcibly transferred from the second tank 420 to the first tank 410 by a pump or the like.

In addition, unlike FIG. 5, in the second tank 420, a droplet spraying device 20 in which a cleaning liquid is supplied from any one pipe connected to the first tank, for example, the first tank, instead of the first tank 410. One or more pipes connected to -1 to 20-3 and the second tank 420 may be directly connected to each other.

Of the air purifier of the present invention Droplet ejection apparatus  Self-cleaning

Referring to FIG. 6, when the power of the pump is turned off, sludge-like deposits s accumulated in the cleaning liquid pipe 21 are lowered to the pump through the pipe together with the cleaning liquid. This means that when the pump is turned off, the cleaning liquid pipe 21 and the pipe connecting the same naturally take a weak level of vacuum, and the deposit s accumulated in the cleaning liquid pipe 21 is transferred to the pump direction by the vacuum to naturally clean the cleaning pipe. It is possible to wash (21). This automatic cleaning is installed in the air inlet 30, or the liquid spraying device 20 installed in the cyclone wet air purifying apparatus 100 in the same principle, when the pump off, automatic cleaning of the cleaning liquid pipe 21 by vacuum is It is possible.

10: gas-liquid separator 11: separator
12: wet air inlet 13: drain pipe
15: dry air outlet 17: fan
18: cover 19: ventilation holes
20: droplet ejection apparatus 21: cleaning liquid pipe
22: washing liquid spray hole 23, 24: inner diameter, outer diameter
25 crash plate 30 air inlet
31: opening 32: vane
100: cyclone wet air purifier
200: wet scrubber 300: dry air purifier
410: the first tank 420: the second tank
430: connector 1000: air purifier

Claims (9)

An air purifier comprising a cyclone wet air purifier and at least one wet scrubber or dry air purifier installed above the cyclone wet air purifier.
The cyclone wet air purification apparatus, the cylindrical body; An air inlet installed in at least one air inlet in a diagonal or normal direction instead of the center point of the cylindrical body, the air inlet including a vane and an opening that serve as a rotating plate of air for rotating the flow of air; And a droplet spraying device installed in the air inlet or in the main body of the cyclone wet air purifying apparatus to droplet and spray the cleaning liquid.
The cyclone wet air purifier and the gas-liquid separator which separates and removes droplets from the wet state of the rotating air in the cyclone wet air purifier and sends the dry air to the upper wet scrubber or dry air purifier, the cyclone wet air purifier and the Air cleaning device, characterized in that the installation is penetrated between the upper of the wet scrubber or dry air purifier.
The gas-liquid separator is:
Cylindrical separator;
At least one wet air inlet installed at a lower side of the cylindrical separator and installed in an oblique direction rather than a center direction of the cylindrical separator to allow the injected wet air to rise while rotating; And
And a drain pipe installed at a lower bottom of the cylindrical separation part to remove droplets collected on the bottom surface to the outside.
The air purifier of claim 1, further comprising a fan for forcibly delivering air to the front end of the wet air inlet or the rear end of the separation unit.
The air purifier of claim 1, further comprising an enlarged separator having a larger diameter than the separator in an upper portion of the separator.
The air purifying apparatus according to claim 2 or 4, further comprising an orifice in the separating part or the enlarged separating part.
According to claim 1 or 2, wherein the droplet injection device is installed in the cleaning liquid pipe formed with one or more cleaning holes for spraying the cleaning liquid and the lower portion of the cleaning liquid pipe and the cleaning liquid sprayed from the cleaning hole collides with the droplets Air purifier comprising a collision plate capable of.
The air purifying apparatus of claim 6, wherein the cleaning hole of the cleaning liquid pipe further increases the cutting width from the inner diameter to the outer diameter so that the cleaning liquid is sprayed in a fan shape.
According to claim 1, When using a wet scrubber on the upper portion of the cyclone wet air purifier, the tank containing the cleaning liquid is divided into a first tank and a second tank,
The cleaning liquid of the first tank is supplied to the cyclone wet air purifier, the cleaning liquid of the second tank is supplied to the upper wet scrubber,
Make-up water supplied from the outside is supplied only to the second tank,
When the cleaning liquid for refilling the first tank is necessary, the pipe is installed so that the cleaning liquid of the second tank is supplied to the first tank.
The air purifier of claim 8, wherein the level of the cleaning liquid of the second tank is higher than that of the first tank, and the cleaning liquid is moved from the second tank to the first tank by the level difference.

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