KR102582572B1 - Air cleaning apparatus - Google Patents

Abstract

The present invention relates to an air purifying device, comprising an internal space in which a collection liquid is accommodated at a predetermined water level, a supply pipe that guides external air into the internal space so that a swirling air flow is formed in the internal space, and a A housing provided with an exhaust pipe that guides air to the outside; a first blowing fan installed inside the supply pipe and blowing external air toward the internal space; a second blowing fan installed inside the discharge pipe and blowing air in the internal space toward the outside; a first collection net formed with meshes through which air blown by the first blowing fan can pass, and driven to rotate around the center; a second collection net formed with meshes through which the air blown by the second blowing fan can pass, and driven to rotate around the center; and a collection network supply unit that supplies the collection liquid to a predetermined position of the first collection network and a predetermined position of the second collection network, respectively.

Description

Air cleaning apparatus {Air cleaning apparatus}

The present invention relates to an air purifying device.

An air purifying device is a device that removes dust and other contaminants contained in the air. In general, air purifying devices mainly use a solid filter method that removes dust and other contaminants contained in the air by passing air introduced from the outside through a HEPA (High Efficiency Particulate Absorber) filter made of fiber.

However, the solid filter type air purifying device had the problem of low purification efficiency due to the characteristics of the HEPA filter, which has a low filtration rate for ultrafine dust with a diameter of 2.5 ㎛ or less.

In addition, solid filter-type air purifying devices require frequent replacement of the HEPA filter due to its small purification capacity, and the high cost of the HEPA filter requires additional maintenance costs in addition to the purchase cost of the device. There was a problem with this.

The present invention is intended to solve the problems of the prior art described above, and its purpose is to provide an improved air purifying device that can increase purification efficiency for ultrafine dust and other contaminants.

Furthermore, the purpose of the present invention is to provide an improved air purifying device that can reduce the time and cost required for maintenance.

The present invention to solve the above-described problem is an air purifying device according to a preferred embodiment, which includes an internal space in which a collection liquid is accommodated at a predetermined water level, and external air is supplied to the internal space so that a swirling air current is formed in the internal space. a housing including a supply pipe that guides the air in the interior space and an exhaust pipe that guides the air in the interior space to the outside; a first blowing fan installed inside the supply pipe and blowing external air toward the internal space; a second blowing fan installed inside the discharge pipe and blowing air in the internal space toward the outside; a first collection net formed with meshes through which air blown by the first blowing fan can pass, and driven to rotate around the center; a second collection net formed with meshes through which the air blown by the second blowing fan can pass, and driven to rotate around the center; and a collection network supply unit that supplies the collection liquid to a predetermined position of the first collection network and a predetermined position of the second collection network, respectively.

The present invention relates to an air purifying device, and has the following effects.

First, the present invention is a collection solution based on water that can collect various contaminants, including ultrafine dust with a significantly small particle size, harmful substances such as mold and pollen, and water-soluble harmful gases such as sulfur dioxide and ammonia gas. By purifying the air using , air purification efficiency can be improved.

Second, the present invention can further improve air purification efficiency by actively contacting air and the collection liquid using a collection net that is rotated while wet in the collection liquid.

Third, the present invention can further improve air purification efficiency by rotating the collection liquid using a swirling air current and actively contacting the air and the collection liquid.

Fourth, the present invention configures the collection liquid based on water with a large purification capacity and low price, thereby improving the convenience of maintenance by extending the exchange cycle of the collection liquid, and lowering the unit exchange price of the collection liquid. Management costs can be reduced.

1 is a partial cross-sectional view showing the schematic configuration of an air purifying device according to a first embodiment of the present invention.
Figure 2 is a plan view of the air purifying device shown in Figure 1;
FIG. 3 is a partial cross-sectional view showing the operating state of the air purifying device shown in FIG. 1.
Figure 4 is a top view of a capture net according to the first embodiment.
Figure 5 is a partial enlarged view of the collection net shown in Figure 4.
Figure 6 is a diagram showing the contact between air and the collection liquid in the blowing fan and the collection net.
FIG. 7 is a diagram showing a state in which the air purifying device and the air curtain device shown in FIG. 1 are connected.
Figure 8 is a partial cross-sectional view showing a schematic configuration of an air purifying device according to a second embodiment of the present invention.
FIG. 9 is a partial cross-sectional view showing the operating state of the air cleaning device shown in FIG. 8.
10 to 12 are diagrams showing a state in which a blowing fan and a collection net are installed in a supply pipe and a discharge pipe, respectively.
Figure 13 is a partial cross-sectional view showing the schematic configuration of an air purifying device according to a third embodiment of the present invention.
Figure 14 is a partial cross-sectional view showing the schematic configuration of an air purifying device according to a fourth embodiment of the present invention.

Hereinafter, some embodiments of the present invention will be described in detail through illustrative drawings. When adding reference numerals to components in each drawing, it should be noted that identical components are given the same reference numerals as much as possible even if they are shown in different drawings. Additionally, when describing embodiments of the present invention, if detailed descriptions of related known configurations or functions are judged to impede understanding of the embodiments of the present invention, the detailed descriptions will be omitted.

In describing the components of the embodiment of the present invention, terms such as first, second, A, B, (a), and (b) may be used. These terms are only used to distinguish the component from other components, and the nature, sequence, or order of the component is not limited by the term. Additionally, unless otherwise defined, all terms used herein, including technical or scientific terms, have the same meaning as generally understood by a person of ordinary skill in the technical field to which the present invention pertains. Terms defined in commonly used dictionaries should be interpreted as having a meaning consistent with the meaning in the context of the related technology, and should not be interpreted in an ideal or excessively formal sense unless explicitly defined in the present application. No.

Figure 1 is a partial cross-sectional view showing the schematic configuration of an air cleaning device according to a first embodiment of the present invention, Figure 2 is a plan view of the air cleaning device shown in Figure 1, and Figure 3 is an air cleaning device shown in Figure 1. This is a partial cross-sectional view showing the operating state of the device.

Referring to FIG. 1, the air cleaning device 100 according to a preferred embodiment of the present invention includes a housing 110 and blows the air (A) contained in the internal space 112 of the housing 110 to be discharged to the outside. A blowing fan 120 that rotates along the blowing fan 120, a collection net 130 coupled to the rotation shaft 122 of the blowing fan 120, and a collection liquid (Lc) supplied to the collecting net 130. It may include a collection liquid supply unit 140, etc.

First, the housing 110 is a device that provides a space for purifying the air (A).

As shown in FIG. 1, the housing 110 has an internal space 112 in which the collected liquid Lc is accommodated at a predetermined water level, and air outside the housing 100 (hereinafter referred to as the 'exterior'). It may be provided with a supply pipe 114 that guides (A) into the inner space 112 and a discharge pipe 116 that guides the air (A) in the inner space 112 to the outside. This housing 110 preferably has a cylindrical shape, but is not limited thereto.

The internal space 112 is formed inside the housing 110 to have a volume appropriate for the formation of the swirling airflow S1, which will be described later, and the installation of the blowing fan 120 and the collection net 130. In this internal space 112, the collection liquid Lc is accommodated at a predetermined level.

The collection liquid Lc is a liquid substance for collecting dust and other contaminants contained in the air A supplied to the internal space 112 through the supply pipe 114, which will be described later, and removing them from the air A. The type of liquid substance that can be used as this collection liquid (Lc) is not particularly limited. For example, the collection liquid Lc may be either water, a sterilizing material capable of removing bacteria, or a chemical solution in which a collecting material capable of collecting predetermined contaminants is added to water.

The housing 110 is preferably provided so that the collection liquid Lc can be exchanged or recharged. For example, as shown in FIG. 1, the housing 110 includes a lower housing 110a that has an open upper surface and accommodates the collected liquid Lc at a predetermined level, and a lower housing 110a that has an open lower surface and includes a hook coupling and other couplings. It may be composed of an upper housing (110b) that is detachably coupled to the lower housing (110a) by means of a method. An O-ring or other sealing member (not shown) may be installed at the interface where the lower housing 110a and the upper housing 110b are in contact to prevent the collection liquid (Lc), air (A), etc. from leaking to the outside. .

The supply pipe 114 communicates with the internal space 112 so as to guide external air A into the internal space 112. Therefore, when the air (A) contained in the internal space 112 is discharged to the outside by the blowing fan 120, which will be described later, and a negative pressure is applied to the supply pipe 114, the external air (A) flows through the supply pipe 114. It can be re-supplied to the internal space 112.

The structure of this supply pipe 114 is not particularly limited. For example, as shown in FIG. 1, the supply pipe 114 has an outlet 114b through which air (A) introduced from the outside through an inlet 114a is discharged at a lower height than the water surface of the collected liquid Lc. It may be coupled to the peripheral surface of the housing 110 so as to communicate with the internal space 112. Then, the external air (A) can be supplied into the collection liquid (Lc) through the supply pipe (114). Through this, the air purification efficiency of the air purifying device 100 can be improved by increasing the contact area and contact time between the air (A) supplied through the supply pipe 114 and the collection liquid (Lc).

In addition, the supply pipe 114 is preferably installed so that a swirling airflow (S1) is formed in the internal space 112. For example, as shown in FIG. 2 , the supply pipe 114 may be coupled to the peripheral surface of the housing 110 to extend along the tangential direction of the internal space 112. Then, as shown in FIG. 3, in the inner space 112, the air (A) supplied to the inner space 112 through the supply pipe 114 forms a swirling airflow that rises while rotating along the inner peripheral surface of the inner space 112. (S1) is formed. In this way, the air (A) raised along the swirling airflow (S1) rises to the top of the internal space (112). Meanwhile, the housing 110 preferably has a cone shape whose diameter gradually decreases toward the top so that the swirling airflow S1 can be strengthened, but the housing 110 is not limited to this.

As shown in FIG. 3, the collection liquid (Lc) contained in the internal space 112 is rotated by the swirling air current (S1) to form a vortex (V1). Because of this, the collected liquid Lc forms a 'U' shape in which the water level rises toward the inner peripheral surface of the internal space 112 due to centrifugal force. Then, on the inner peripheral surface of the internal space 112, contact is actively made between the collected liquid Lc and the air A, respectively rotating along the inner peripheral surface of the internal space 112. Therefore, other contaminants contained in the air (A) can be removed from the air (A) by being primarily collected in the collection liquid (Lc) rotating along the inner peripheral surface of the internal space (112).

The discharge pipe 116 communicates with the internal space 112 so as to guide the air A contained in the internal space 112 to the outside. Accordingly, the air A blown toward the discharge pipe 116 by the blowing fan 120, which will be described later, may be discharged to the outside through the discharge pipe 116.

The structure of this discharge pipe 116 is not particularly limited. For example, as shown in FIG. 1, the discharge pipe 116 has an inlet 116a through which the air A contained in the internal space 112 flows in the direction of gravity by a predetermined distance from the water surface of the collected liquid Lc. are spaced in the opposite direction, and the outlet 116b, through which the air A flowing into the inlet 116a is discharged, penetrates the bottom surface of the internal space 112 and extends to the outside, on the lower surface of the housing 110. can be combined By installing the discharge pipe 116 so that the inlet 116a is spaced apart from the surface of the collected liquid Lc, it is possible to prevent the collected liquid Lc contained in the internal space 112 from flowing directly into the discharge pipe 116. there is.

Next, the blowing fan 120 is a device that provides the driving force necessary for the air (A) contained in the internal space 112 to be discharged to the outside through the discharge pipe 116.

The blowing fan 120 is preferably configured as an axial fan capable of blowing air A in the axial direction, but is not limited thereto.

As shown in FIG. 3, the blowing fan 120 is spaced apart from the inlet 116a of the discharge pipe 116 by a predetermined distance in the direction opposite to the direction of gravity, and the internal space 112 is concentric with the discharge pipe 116. can be installed in That is, the blowing fan 120 may be installed in the internal space 112 so that the rotation axis 122 of the blowing fan 120 and the central axis of the discharge pipe 116 are located on a straight line. This blowing fan 120 sucks the air (A) in the internal space 112, more specifically, the air (A) that rises to the top of the internal space 112 by the swirling airflow (S1) and blows the air (A) through the discharge pipe 116. The air (A) blown by the blowing fan 120 can be discharged to the outside through the discharge pipe 116. Then, the negative pressure acts on the internal space 112 and the supply pipe 114, so that the external air (A) can be re-supplied to the internal space 112 through the supply pipe 114.

As described above, the air (A) supplied to the internal space 112 through the supply pipe 114 forms a swirling airflow (S1), but some of the air (A) is separated from the swirling airflow (S1). It can be fluid. As a result, some of the air (Ad) of the air (A) released from the swirling air flow (S1) flows along the outer peripheral surface of the discharge pipe (116) and flows to the outside through the discharge pipe (116) while containing dust and other contaminants. As it is discharged, there is a risk that the air purification efficiency of the air purifying device 100 may decrease.

In order to solve this problem, the blowing fan 120 is provided so that a portion of the air (A) blown by the blowing fan 120 flows into the discharge pipe 116 and the remaining portion flows along the outer peripheral surface of the discharge pipe 116. It can be. As shown in FIG. 3, when the housing 110 is provided so that a swirling airflow (S1) rising along the inner peripheral surface of the internal space 112 is formed, some of the air (A) deviating from the swirling airflow (S1) The air (Ad) may rise along the outer peripheral surface of the discharge pipe 116. In this case, the blowing fan 120 causes a portion (Ae) of the air blown by the blowing fan 120 to be discharged to the outside through the discharge pipe 116, and at the same time, the remaining portion (Ac) is discharged to the outside through the discharge pipe 116. ) can be arranged to descend along the outer circumferential surface of the. Then, the air (Ac) blown by the blower fan 120 to flow along the outer peripheral surface of the discharge pipe 116 (hereinafter referred to as 'first air (Ac)') and the air to flow along the outer peripheral surface of the discharge pipe 116. The air Ad (hereinafter referred to as 'second air Ad') separated from the swirling airflow S1 proceeds in opposite directions. Accordingly, the first air (Ac) can push the second air (Ad) so that it no longer flows toward the inlet (116a) of the discharge pipe (116). This first air (Ac) and the second air (Ad) pushed out by the first air (Ac) pass through the space between the discharge pipe 116 and the inner peripheral surface of the internal space 112 and join the swirling airflow (S1). Accordingly, the first air (Ac) may function as an air curtain that blocks the second air (Ad) from directly flowing into the discharge pipe 116. Through this, the blowing fan 120 can improve the air purification efficiency of the air purifying device 100 by minimizing the air (A) discharged to the outside in an unfiltered state by the collection liquid (Lc).

As described above, the method of installing the blowing fan 120 so that the first air (Ac) functions as an air curtain is not particularly limited. For example, as shown in FIG. 3, the blowing fan 120 may have a diameter larger than the discharge pipe 116 by a predetermined ratio. Then, the air (A) blown from the central area facing the discharge pipe 116 among the entire area of the blowing fan 120 can be mainly discharged to the outside through the discharge pipe 116, and can be discharged to the outside through the discharge pipe 116. The air (A) blown from the outer area mainly flows along the outer peripheral surface of the discharge pipe 116 to form the above-described first air (Ac).

The driving source of the blowing fan 120 is not particularly limited. For example, as shown in FIG. 3 , the blowing fan 120 may be rotationally driven by the driving motor 150 by having a rotation shaft 122 coupled to the driving motor 150 . The drive motor 120 is preferably installed in the internal space 112, but is not limited thereto. That is, the drive motor 120 may be installed outside the housing 110. This drive motor 150 preferably rotates the blowing fan 120 at a speed of 1500 RPM to 2000 RPM, but is not limited thereto.

On the other hand, if a blowing fan, pump, or other blowing member (not shown) is additionally installed inside the discharge pipe 116 or in a duct connected to the discharge pipe 116, the blowing fan 120 will blow the air (A) in the internal space 112. ) can be automatically rotated by the airflow formed as the air is discharged to the outside by this blowing member. Accordingly, in this case, the drive motor 150 may be omitted. Additionally, an auxiliary blowing fan (not shown) may be installed inside the supply pipe 114 to assist the blowing fan 120 to supply external air (A) to the internal space 112.

FIG. 4 is a plan view of a collection net according to the first form, FIG. 5 is a partial enlarged view of the capture net shown in FIG. 4, and FIG. 6 is a view showing the contact between air and the collection liquid in the blowing fan and the collection net. am.

Next, the collection net 130 is a device that induces contact between the air (A) and the collection liquid (Lc).

As shown in FIG. 3, the central axis of the collection net 130 may be axially coupled to the rotation axis 122 of the blowing fan 120. Then, the collection net 130 can be rotated together with the blowing fan 120 in a concentric state with the blowing fan 120 and the discharge pipe 116. This collection network 130 may be directly shaft-coupled with a drive motor (not shown) other than the drive motor 150 described above and driven to rotate independently. For convenience of explanation, the present invention will be described below based on the case where the collection net 130 is axially coupled to the rotation shaft 122 of the blowing fan 120.

The installation location of the collection net 130 is not particularly limited. For example, as shown in FIG. 3, the collection net 130 collects particles (Lcp) of the collection liquid (Lc) formed by scattering the collection liquid (Lc) by the swirling air current (S1) into the collection net ( 130) may be installed in a predetermined position so as to reach at least a portion of the space. In this case, the blowing fan 120 is also positioned at a position where the particles (Lcp) of the collecting liquid (Lc) formed by scattering the collecting liquid (Lc) by the swirling air current (S1) can reach at least a portion of the blowing fan (120). can be installed in Then, the blowing fan 120 and the collection net 130 can receive the collection liquid Lc not only from the collection liquid supply unit 140, which will be described later, but also from the swirling air current S1. Accordingly, the collection liquid supply unit 140 may be omitted depending on the installation location of the blower fan 120 and the collection net 130 and other environmental conditions.

The installed number of collection nets 130 is not particularly limited. For example, as shown in FIG. 3, the collection net 130 is a first axis coupled to the rotation axis 122 of the blowing fan 120 so as to be located further away from the discharge pipe 116 than the blowing fan 120. It may be provided with a collection net 131 and a second capture net 133 that is axially coupled to the rotation axis 122 of the blowing fan 120 so as to be located closer to the discharge pipe 116 than the blowing fan 120. In this case, the first collection net 131 is disposed between the top of the internal space 112 and the blowing fan 120, and the second collecting net 133 is placed between the blowing fan 112 and the outlet 116. is placed in Then, the air (A) sucked in by the blowing fan 120 sequentially passes through the first collecting net 131, the blowing fan 120, and the second collecting net 133.

As shown in FIG. 4, the collection net 130 preferably has a disk structure, but is not limited thereto. In addition, the collection net 130 preferably has the same diameter as the blowing fan 120 or has a diameter smaller than the blowing fan 120 by a predetermined ratio, but is not limited thereto. That is, the collection net 130 may have a larger diameter than the blowing fan 120. In addition, when the collection net 130 is axially coupled to the rotation axis 122 of the blower fan 120, the center of the collection net 130 is an insertion hole ( 130a) may be formed.

As shown in FIG. 5 , the collection net 130 may have a mesh structure in which a plurality of meshes 135 are formed. These meshes 135 have a size and shape that allows air (A) to pass through.

This collection net 130 is preferably made of a material with good wettability. Additionally, the collection net 130 may be formed of a flexible material whose shape can be varied. For example, as shown in FIG. 5, the collection net 130 may be a woven material formed by weaving warp yarns 137 and weft yarns 139 made of fibers. In this case, the collection net 130 may be arranged in a sagging state due to gravity when not rotating, and may be arranged in a state unfolded into a disk shape due to centrifugal force when rotating. However, it is not limited to this, and the collection net 130 may be formed to maintain a constant shape by resisting gravity even when not rotating. For example, the collection net 130 can be formed into a single piece by processing high-rigidity synthetic resin, metal, or other materials using processing methods such as injection and casting.

Next, the collection liquid supply unit 140 is a device that supplies the collection liquid Lc to the collection net 130.

The configuration of the collection liquid supply unit 140 is not particularly limited. For example, as shown in FIG. 3, the collection liquid supply unit 140 includes a collection liquid pump 142 for pumping the collection liquid Lc contained in the internal space 112, and a collection liquid pump 142. It may be provided with a collection liquid supply pipe 144 that supplies the collection liquid (Lc) pumped by to a predetermined position of the collection net 130.

The collection liquid pump 142 is installed so that at least a part of it is immersed in the collection liquid Lc accommodated in the internal space 112 so as to be able to pump the collection liquid Lc. The type of pump that can be used as the collection liquid pump 142 is not particularly limited, and the collection liquid pump 142 may be configured as a typical pump used to pump liquid substances.

This collection liquid pump 142 is preferably driven when the collection net 130 is rotated, but is not limited to this.

The collection liquid supply pipe 144 is connected to the discharge port of the collection liquid pump 142, and extends the collection liquid Lc delivered from the collection liquid pump 142 toward a predetermined position of the collection net 130 to a position where it can be discharged. do. For example, as shown in FIG. 3, when the first and second collection nets 131 and 133 are installed, the collection liquid supply pipe 144 is supplied with air (A) sucked in by the blowing fan 120. It may be installed to discharge the collection liquid (Lc) toward the center of the first collection network 131, which reaches it first. Additionally, a spray nozzle 146 that sprays the collection liquid Lc toward the center of the first collection net 131 may be installed at the end of the collection liquid supply pipe 144.

Hereinafter, with reference to the drawings, the manner in which air A is purified in the collection net 130 will be described.

First, the drive motor 150 and the collection liquid pump 142 are driven. Then, the blowing fan 120 and the collection net 130 are rotated and the collection liquid Lc is sprayed from the spray nozzle 146 toward the center of the first collection net 131. Accordingly, as shown in FIG. 3, a swirling airflow (S1) and a vortex (V1) are formed in the internal space 112, and the air (A) rising along the swirling airflow (S1) is caused by the vortex (V1). The rotating collection liquid (Lc) is in contact with the inner peripheral surface of the internal space (112). In this contact process, dust and other contaminants contained in the air (A) are collected in the collection liquid (Lc) rotated by the vortex (V1), so that the air (A) is primarily purified.

While the collected liquid (Lc) is rotated by the swirling air current (S1), some of the collected liquid (Lc) scatters toward the blowing fan (120) and the collecting net (130). Then, the particles (Lcp) of the collection liquid (Lc) scattered by the swirling air current (S1) are supplied to the blower fan 120 and the collection net 130, and in particular, to the center of the first collection net 131. The collection liquid Lc sprayed from the spray nozzle 146 is additionally supplied.

First, as shown in FIG. 6, the collection liquid Lc supplied to the first collection net 131 from each of the swirling airflow S1 and the spray nozzle 146 is changed when the first collection net 131 rotates. Due to the centrifugal force that acts, it spreads from the center of the first collection network 131 toward the outside and is distributed over the entire area of the first collection network 131. Then, the first collection net 131 is rotated in a wet state as a whole by the collection liquid Lc. However, the first collection net 131 rotates rapidly along the blowing fan 120 at a speed of 1500 RPM to 2000 RPM. As a result, the collection liquid Lc rotating along the first collection net 131 in a wet state reaches the first collection net 131 by the suction force of the blowing fan 120. It is actively in contact with the exposed air (A). In addition, as shown in FIG. 5, the collection liquid Lc is formed by scattering from the first collection net 131 or is formed in the first collection net 131 by the centrifugal force acting on the first collection net 131. The particles (Lcp) of the collection liquid (Lc) formed as the collected liquid (Lc) collides with the mesh structure of the first collection net (131) also actively interact with the air (A) that has reached the first collection net (131). comes into contact In this contact process, dust and other contaminants contained in the air (A) are collected in the collection liquid (Lc), and the air (A) is secondarily purified.

In this way, the air (A) secondarily purified in the first capture net 131 passes through the meshes 135 of the first capture net 131 and moves toward the blowing fan 120. In addition, the collection liquid (Lc) supplied to the first collection net 131 is scattered toward the inner peripheral surface of the internal space 112 by centrifugal force and rejoins the collection liquid (Lc) accommodated in the internal space 112, or is blown. It is guided toward the blowing fan 120 by the suction force of the fan 120.

Next, as shown in FIG. 6, the collected liquid (Lc) supplied to the blowing fan 120 from the swirling airflow (S1) and the first collecting net 131 acts when the blowing fan 120 rotates. By centrifugal force, it spreads from the center of the blower fan 120 toward the outside and is distributed over the entire area of the blower fan 120. Then, the blowing fan 120 is rotated in a wet state as a whole by the collection liquid Lc. Accordingly, the collected liquid Lc, which rotates rapidly along the blower fan 120 while wetting the blower fan 120, actively comes into contact with the air A reaching the blower fan 120. In addition, the collected liquid (Lc) is formed by scattering from the blowing fan (120) due to the centrifugal force acting on the blowing fan (120), or the collected liquid (Lc) that reaches the blowing fan (120) is formed by blowing fan (120) and The particles (Lcp) of the collection liquid (Lc) formed during the collision are also actively contacted with the air (A) reaching the blowing fan (120). In this contact process, dust and other contaminants contained in the air A are collected in the collection liquid Lc, thereby purifying the air A thirdly.

In this way, the air (A) purified thirdly by the blowing fan 120 is blown toward the discharge pipe 116 by the blowing fan 120. In addition, the collection liquid (Lc) supplied to the blowing fan 120 is scattered toward the inner peripheral surface of the internal space 112 by centrifugal force and rejoins the collecting liquid (Lc) accommodated in the internal space 112, or the blowing fan ( It is guided toward the discharge pipe 116 by the air (A) blown by 120).

Next, as shown in FIG. 6, the collection liquid (Lc) supplied to the second collection net 133 from the swirling air flow (S1) and the blowing fan 120 is changed when the second collection net 133 rotates. Due to the centrifugal force acting, it spreads from the center of the second capture net 133 toward the outside and is distributed over the entire area of the second capture net 133. However, the second collection net 133 rotates rapidly along the blowing fan 120 at a speed of 1500 RPM to 2000 RPM. For this reason, the collected liquid Lc rotating along the second collecting net 133 in a wet state is the air blown to the second collecting net 133 by the blowing fan 120. It is in active contact with (A). In addition, as shown in FIG. 5, the collection liquid Lc is formed by scattering from the second collection net 133 or is formed in the second collection net 133 by the centrifugal force acting on the second collection net 133. The particles (Lcp) of the collected liquid (Lc) formed as the collected liquid (Lc) collides with the mesh structure of the second collecting net (133) also contact the air (A) blown into the second collecting net (133). do. In this contact process, dust and other contaminants contained in the air (A) are collected in the collection liquid (Lc), thereby purifying the air (A) four times.

In this way, the air (A) purified four times in the second capture net 133 passes through the meshes 135 of the second capture net 133 and is blown toward the discharge pipe 116. In addition, the collection liquid (Lc) supplied to the second collection net 133 is scattered toward the inner peripheral surface of the internal space 112 by centrifugal force and rejoins the collection liquid (Lc) accommodated in the internal space 112, or is blown. The air (A) blown by the fan 120 is guided toward the discharge pipe 116. However, most of the collection liquid (Lc) supplied by the spray nozzle 146 is scattered toward the inner peripheral surface of the internal space 112 by centrifugal force from the first collection net 131 and the blowing fan 120, and is collected by the second collection net 146. Only a portion of the collection liquid (Lc) supplied by the spray nozzle 146 may be delivered to the net 133. In addition, the second collection net 133 rotates at high speed along the blowing fan 120, and the centrifugal force acting on the collection liquid Lc supplied to the second capture net 133 is caused by the air A. 2 It is relatively superior to the pressing force that guides the collection liquid (Lc) supplied to the collection network 133 toward the discharge pipe 116. Accordingly, only a very small portion of the total quantity of the collected liquid (Lc) is discharged in the form of liquid particles (Lcp) through the discharge pipe 116 along with the air (A). In this air purifying device 100, even when used for a long time, the quantity of the collection liquid (Lc) is kept constant within a predetermined standard range, so that the exchange cycle of the collection liquid (Lc) can be extended, and the collection liquid (Lc) By being discharged to the outside in the form of liquid particles (Lcp), bacterial contamination and other hygiene problems can be prevented.

Due to the nature of the HEPA filter, conventional solid filter-type air purifying devices have difficulty removing pollutants such as ultrafine dust, whose particle size is significantly small, harmful substances such as mold and pollen, and harmful gases. On the other hand, the air purifying device 100 contains ultrafine dust with significantly smaller particle size, harmful substances such as mold and pollen, and various contaminants including water-soluble harmful gases such as sulfur dioxide (S02) and ammonia gas (NH3). The air (A) is purified using a collection liquid (Lc) based on water that can capture, and the air purification efficiency can be improved compared to conventional air purification devices. In addition, the collection liquid (Lc) is water-based and has a large purification capacity and low price compared to a HEPA filter. Accordingly, the air cleaning device 100 can improve the convenience of maintenance by lengthening the replacement cycle of the collection liquid (Lc), and reduce the cost of maintenance by lowering the unit replacement price of the collection liquid (Lc). there is.

Meanwhile, as above, the collection liquid (Lc) supplied to the collection net 130 and the blowing fan 120 by the collection liquid supply unit 140 acts when the collection net 130 and the blowing fan 120 rotate. It is separated from the collection net 130 and the blowing fan 120 by the centrifugal force and the flow of air (A) formed by the blowing fan 120. That is, the collection liquid Lc supplied to the collection net 130 and the blowing fan 120 is released after wetting the collection net 130 and the blowing fan 120 for only a short time. Accordingly, the collection liquid supply unit 140 continuously supplies new collection liquid Lc to the collection net 130 and the blowing fan 120 in accordance with the departure trend of the collection liquid Lc. Then, the collection net 130 and the blowing fan 120 are continuously cleaned by new collection liquid Lc continuously supplied by the collection liquid supply unit 140. Through this, it is possible to prevent bacteria from proliferating due to the collection liquid Lc accumulating in the collection net 130 and the blowing fan 120.

In general, a liquid has the characteristic of promoting natural vaporization as the difference in relative speed between it and the gas in contact with it increases. However, in the case of the air cleaning device 100, the collection liquid Lc not only comes into contact with the swirling airflow S1 rapidly accelerated by the blowing fan 120, but also the blowing fan 120 or the collection net 130. It rotates rapidly along and comes into contact with the air (A) passing through the blowing fan 120 or the collection net 130. Because of this, natural vaporization of water contained in the collection liquid Lc actively occurs in the internal space 112. The water vapor generated by this natural evaporation is mixed with the air (A), and the air (A) can be discharged to the outside through the outlet 116 in a humidified state by the mixed water vapor. Accordingly, the air purifying device 100 can be utilized as an air washer equipped with both an air purifying function and an air humidifying function.

FIG. 7 is a diagram showing a state in which the air purifying device and the air curtain device shown in FIG. 1 are connected.

Referring to FIG. 7, the outlet 116 of the air cleaning device 100 may be connected to the air curtain device 500 installed at the entrance of various facilities through an air supply line 510. Then, the air (Ae) discharged from the air purifying device 100 is supplied to the air curtain device 500, thereby purifying the air curtain that blocks external air from entering the facility. It can be formed using clean air (Ae). Through this, the indoor air quality of a facility where the air curtain device 500 is installed at the entrance can be improved.

In addition to combining the air cleaning device 100 with the air curtain device 500, the air cleaning device 100 can be used for various purposes. In other words, the air purifying device 100 consists of various products such as air purifiers, outdoor air suppliers, humidifiers, and air cleaners that can be used in various fields such as residential facilities, commercial facilities, industrial facilities, road facilities, transportation, and electronic products. It can be used to:

FIG. 8 is a partial cross-sectional view showing a schematic configuration of an air cleaning device according to a second embodiment of the present invention, and FIG. 9 is a partial cross-sectional view showing an operating state of the air cleaning device shown in FIG. 8.

The air cleaning device 200 according to the second embodiment of the present invention is similar to the above-described air cleaning device in that the structure of the housing 210 and the installation positions of the blowing fan 220 and the collection net 230 are changed. It has a difference from (100). Hereinafter, the air cleaning device 200 will be described focusing on these differences, and descriptions of content that overlaps with the air cleaning device 100 described above will be omitted or only briefly mentioned.

As shown in FIG. 8, the supply pipe 214 has an outlet 214b through which air (A) introduced from the outside through an inlet 214a is discharged to the surface of the collection liquid Lc contained in the internal space 212. It may be coupled to the peripheral surface of the housing 210 so as to communicate with the internal space 212 at a higher position. Then, the external air (A) can be supplied to the space above the water surface of the collection liquid (Lc) through the supply pipe 214. In addition, the discharge pipe 216 has an inlet 216a through which the air of the internal space A is introduced, and is lower than the outlet 214b of the supply pipe 214, and the water level of the collected liquid Lc contained in the internal space 212 is lower than that of the discharge pipe 216. In addition to being located higher than the inlet 216a, the outlet 216b through which the air A flowing into the inlet 216a is discharged penetrates the ceiling of the internal space 212 and extends to the outside of the upper surface of the housing 210. can be combined with

In addition, the blowing fan 220 is located between the water surface of the collection liquid Lc contained in the internal space 212 and the inlet 216a of the discharge pipe 216, and is located in the internal space 212 so as to be concentric with the discharge pipe 216. ) can be installed. In addition, the first collection net 231 may be axially coupled to the rotation axis 222 of the blowing fan 220 so as to be positioned between the water surface of the collection liquid (Lc) contained in the internal space 212 and the blowing fan 220. , the second collection net 233 may be axially coupled to the rotation shaft 222 of the blowing fan 220 so as to be located between the blowing fan 220 and the inlet 216a of the discharge pipe 216.

The first trapping net 221 and the second trapping net 223 preferably have a disk shape, but are not limited thereto. However, it is not limited to this, and a collection net (not shown) with a cover structure may be installed instead of the first collection net 231 and the second collection net 232 having a disc shape, or a first collection net having a disc shape may be installed. The net 231 and the second collecting net 232 may be omitted and a mesh pattern may be formed on the outer surface of the blades of the blowing fan 220.

As shown in FIG. 9, when the drive motor 250 and the collection liquid pump 242 of the collection liquid supply unit 240 are driven, the blowing fan 220 is rotated and the air contained in the internal space 212 ( A) is discharged to the outside through the discharge pipe 216, and the external air (A) is returned to the interior space 212 through the supply pipe 214 by the negative pressure applied to the interior space 212 and the supply pipe 214. supplied. The air (A) re-supplied to the internal space 212 in this way forms a swirling airflow (S2) that rotates and descends along the inner circumferential surface of the internal space 212, and this swirling airflow (S2) forms an inner space ( A vortex (V2) is formed in the collection liquid (Lc) contained in 212). Accordingly, the air (A) and the collection liquid (Lc), each rotating along the inner peripheral surface of the internal space 212, come into contact with each other, so that dust and other contaminants contained in the air (A) are collected in the collection liquid (Lc) and are collected. As the water contained in the liquid (Lc) naturally evaporates, the air (A) is primarily purified and humidified.

In addition, the air (A) that descends to the bottom of the internal space 212 along the swirling airflow (S2) flows from the center of the bottom of the internal space 212 toward the blowing fan 220 due to the suction force of the blowing fan 220. It rises. Then, the air A raised toward the blowing fan 220 sequentially passes through the first collecting net 231, the blowing fan 220, and the second collecting net 233. This air (A) is sent to the first collection net 231, the blowing fan 220, and the second collection net 233 by the swirling airflow S2 and the spray nozzle 246 of the collection liquid supply unit 240, respectively. After being further purified and humidified by the supplied collection liquid (Lc), it is discharged to the outside through the discharge pipe 216.

Meanwhile, the unexplained reference numeral '244' indicates a collection liquid supply pipe that delivers the collection liquid (Lc) pumped from the collection liquid pump 240 to the spray nozzle 246.

Figures 10 to 12 are diagrams showing a state in which a blowing fan and a collection net are installed in a supply pipe and a discharge pipe, respectively.

The blowing fan 220 and the collection net 230 have been described as being installed in the internal space 212 so as to be located between the surface of the collected liquid Lc and the inlet 216a of the discharge pipe 216, but are not limited thereto. .

For example, the blowing fan 220 and the collection net 230 may be installed inside the supply pipe 214 instead of the internal space 212, or may be additionally installed inside the supply pipe 214. Correspondingly, a drive motor 250 for rotating the blowing fan 220 and the collection net 230 may also be installed inside the supply pipe 214.

For example, the blowing fan 220 and the collection net 230 may be installed inside the discharge pipe 216 instead of the internal space 212, or may be additionally installed inside the discharge pipe 216. Correspondingly, a drive motor 250 for rotating the blowing fan 220 and the collection net 230 may also be installed inside the discharge pipe 216.

As above, when the blower fan 220, the collection net 230, and the drive motor 250 are installed in the supply pipe 214 and the discharge pipe 216, the collection liquid supply unit 240 is installed inside the supply pipe 214. It may be provided to supply the collection liquid (Lc) to the collection net 230 installed in and the collection net 230 installed inside the discharge pipe 216, respectively. For example, the connection pipe 241 is connected to the discharge port of the collection liquid pump 242, and the first collection liquid supply pipe 245 and the second collection liquid supply pipe 247 branch from the connection pipe 241. In addition, the first collection liquid supply pipe 245 extends to the inside of the supply pipe 214, and the second collection liquid supply pipe 247 extends to the inside of the discharge pipe 216. In this case, the connection pipe 241, the first collected liquid supply pipe 245, and the second collected liquid supply pipe 247 are preferably connected by a three-way valve 243, but are not limited to this. By providing the collection liquid supply unit 240 in this way, the collection liquid (Lc) can be supplied to each of the collection net 230 installed inside the supply pipe 214 and the collection net 230 installed inside the discharge pipe 216. .

As above, when the blowing fan 220 and the collecting net 230 are installed, the external air (A) is primarily purified and purified inside the supply pipe 214 by the blowing fan 220 and the collecting net 230. It is supplied to the internal space 212 in a humidified state. Next, the air (A) supplied to the internal space 212 is secondarily purified and humidified by the swirling air current (S2) and then flows into the discharge pipe 216. Thereafter, the air A flowing into the discharge pipe 216 is purified and humidified three times by the blowing fan 220 and the collection net 230 inside the discharge pipe 216 and then discharged to the outside.

Figure 13 is a partial cross-sectional view showing the schematic configuration of an air purifying device according to a third embodiment of the present invention.

The air cleaning device 300 according to the third embodiment of the present invention is similar to the above-described air cleaning device in that the structure of the housing 310 and the installation positions of the blowing fan 320 and the collection net 330 are changed. It has differences from (100, 200). Hereinafter, the air cleaning device 300 will be described focusing on these differences, and descriptions of content that overlaps with the air cleaning devices 100 and 200 described above will be omitted or only briefly mentioned.

First, the housing 310 includes an internal space 312 in which the collected liquid Lc is accommodated at a predetermined level, a supply port 314 that guides external air A to the internal space 312, and an internal space 312. An outlet 316 that guides the air A in the space 312 to the outside may be provided. This housing 310 preferably has a cylindrical shape, but is not limited thereto.

The supply port 314 may be formed by opening the upper surface of the housing 310 to communicate with the internal space 312. The number of supply ports 314 installed is not particularly limited, and at least one supply port 314 may be formed open in the housing 310.

The outlet 316 is formed by opening the peripheral surface of the housing 310 to communicate with the internal space 312, and is located at a height between the water surface of the collection liquid Lc contained in the internal space 312 and the supply port 314. It can be formed to be positioned. The number of installed discharge ports 316 is not particularly limited, and at least one discharge port 316 may be formed open in the housing 310.

Next, the blowing fan 320 is installed in the internal space 312 at a height between the supply port 314 and the discharge port 316, and is installed to face the water surface of the collected liquid Lc. Preferably, the blowing fan 320 is installed so that the rotation axis 322 of the blowing fan 320 and the supply port 314 are concentric. The rotation shaft 322 is shaft-coupled with a drive motor 350 installed in the internal space 312 or outside, and through this, the blower fan 320 can be rotationally driven by the drive motor 350. This blowing fan 320 can blow the air (A) contained in the internal space 312 toward the surface of the collected liquid (Lc).

Next, the collection net 330 is coupled to the rotation axis 322 of the blowing fan 320 so that it can be rotated along the blowing fan 320. However, the present invention is not limited to this, and the collection net 330 may be shaft-coupled with a drive motor (not shown) other than the drive motor 350 described above and driven to rotate independently. For convenience of explanation, the present invention will be described below based on the case where the collection net 330 is axially coupled to the rotation shaft 322 of the blowing fan 320.

The installation location of the collection net 330 is not particularly limited. For example, the collection net 330 may be installed in the internal space 312 so as to be located between the supply port 314 and the blowing fan 320. However, it is not limited to this, and the collection net 330 is installed between the blower fan 320 and the water surface of the collected liquid (Lc) instead of between the supply port 314 and the blower fan 320, or the blower fan 320 Another collection net may be additionally installed between the surface of the water and the collection liquid (Lc).

The collection net 330 preferably has a disk shape, but is not limited thereto. However, it is not limited to this, and instead of the disc-shaped collection net 330, a collection net (not shown) with a cover structure may be installed, or the disc-shaped collection net 330 may be omitted and the blade of the blowing fan 320 may be installed. A mesh pattern may be formed on the outside of the field.

The collection liquid supply unit 340 includes a collection liquid pump 342 that pumps the collection liquid (Lc) stored in the internal space 312, and a collection liquid (Lc) pumped by the collection liquid pump 342 into a collection network. It may be provided with a collection liquid supply pipe 344 that supplies the collected liquid to a predetermined location (330). The predetermined position of the collection net 330 is not particularly limited. For example, the collection liquid supply pipe 344 may be provided to discharge the collection liquid Lc pumped by the collection liquid pump 342 toward the center of the collection network 330. Additionally, a spray nozzle 346 that sprays the collection liquid Lc toward the center of the first collection net 330 may be installed at the end of the collection liquid supply pipe 344.

Hereinafter, the manner in which the air (A) is purified in the collection net 330 will be described.

First, the drive motor 350 and the collection liquid pump 342 are driven. Then, the blowing fan 320 and the collection net 330 are rotated and the collection liquid Lc is sprayed from the spray nozzle 346 toward the center of the collection net 330.

The collection liquid (Lc) supplied from the injection nozzle 346 to the collection net 330 spreads from the center of the collection net 330 toward the outside by the centrifugal force that acts when the collection net 330 rotates. distributed over the entire area of 330. Then, the collection net 330 is rotated in a wet state as a whole by the collection liquid Lc. As a result, the collected liquid (Lc) rotating along the collection net 330 in a wet state is mixed with the air (A) that reaches the collection net 330 by the suction force of the blowing fan 320. actively contacted. In addition, the collection liquid (Lc) is formed by scattering from the collection net 330 due to the centrifugal force acting on the collection net 330, or the collection liquid (Lc) that reaches the collection net 330 is formed by the collection net 330. Particles (Lcp) of the collection liquid (Lc) formed while colliding with the mesh structure are also actively contacted with the air (A) reaching the collection network (330). In this contact process, dust and other contaminants contained in the air (A) are collected in the collection liquid (Lc), and the water contained in the collection liquid (Lc) naturally evaporates, thereby primarily purifying the air (A). and humidified.

In this way, the air (A) that is primarily purified in the capture net 330 passes through the mesh of the capture net 330 and moves toward the blowing fan 320. In addition, the collection liquid (Lc) supplied to the collection net 330 is scattered toward the inner peripheral surface of the internal space 312 by centrifugal force and rejoins the collection liquid (Lc) accommodated in the internal space 312, or is scattered by a blowing fan ( It is guided toward the blowing fan 320 by the suction force of 320).

Next, the collected liquid Lc supplied from the collection net 330 to the blowing fan 320 spreads from the center of the blowing fan 320 toward the outside by the centrifugal force that acts when the blowing fan 320 rotates. As it goes, it is distributed over the entire area of the blowing fan 320. Then, the blowing fan 320 is rotated in a wet state as a whole by the collection liquid Lc. Accordingly, the collected liquid Lc, which rotates rapidly along the blower fan 320 while wetting the blower fan 320, actively comes into contact with the air A reaching the blower fan 320. In addition, the collected liquid (Lc) is formed by scattering from the blowing fan (320) due to the centrifugal force acting on the blowing fan (320), or the collected liquid (Lc) that reaches the blowing fan (320) is mixed with the blowing fan (320). The particles (Lcp) of the collection liquid (Lc) formed during the collision are also actively contacted with the air (A) reaching the blowing fan (320). In this contact process, dust and other contaminants contained in the air (A) are collected in the collection liquid (Lc), and the water contained in the collection liquid (Lc) naturally evaporates, thereby secondary purification of the air (A). and humidified.

Meanwhile, the air A, which is secondarily purified by the blowing fan 320, is blown by the blowing fan 320 toward the water surface of the collected liquid Lc accommodated in the internal space 312. In addition, the collected liquid (Lc) supplied to the blowing fan 320 is scattered toward the inner peripheral surface of the internal space 312 by centrifugal force, or the collected liquid (Lc) is blown by the air (A) blown by the blowing fan 320. By being guided toward the water surface, it rejoins the collection liquid Lc accommodated in the internal space 312.

In addition, the air (A) blown toward the water surface of the collection liquid (Lc) comes into contact with the water surface of the collection liquid (Lc), and natural vaporization of the water contained in the collection liquid (Lc) actively occurs on the water surface of the collection liquid (Lc). do. Because of this, the collection liquid Lc can be discharged to the outside through the outlet 316 formed on the peripheral surface of the housing 310 in a state that is additionally humidified by the water vapor generated by this natural evaporation.

Figure 14 is a partial cross-sectional view showing the schematic configuration of an air purifying device according to a fourth embodiment of the present invention.

The air cleaning device 400 according to the fourth embodiment of the present invention includes the structure of the housing 410, the installation position of the blowing fan 420 and the collection net 430, and the structure of the collection liquid supply unit 440. It is different from the air cleaning device 300 described above in that has been changed. Hereinafter, the air cleaning device 400 will be described focusing on these differences, and descriptions of content that overlaps with the air cleaning device 300 described above will be omitted or only briefly mentioned.

First, the housing 410 includes a supply port 414 that guides external air (A) to the internal space 412, and an outlet 416 that guides air (A) in the internal space 412 to the outside. can be provided. This housing 410 preferably has a cylindrical shape, but is not limited thereto.

The supply port 414 may be formed by opening one side of the housing 410 to communicate with the internal space 412. The number of supply ports 414 installed is not particularly limited, and at least one supply port 414 may be formed open in the housing 410.

The outlet 416 may be formed by opening the other side of the housing 410 opposite to the one side so as to communicate with the internal space 412. The number of installed discharge ports 416 is not particularly limited, and at least one discharge port 416 may be formed open in the housing 410.

Next, the blowing fan 420 is installed in the internal space 412 to be located between the supply port 414 and the discharge port 416. Preferably, the blowing fan 420 may be installed so that the rotation axis 422 of the blowing fan 420 and the supply port 414 are concentric. The rotation shaft 422 is shaft-coupled with a drive motor 450 installed in the internal space 412 or outside, and through this, the blower fan 420 can be rotationally driven by the drive motor 450. This blowing fan 420 can blow the air (A) contained in the internal space 412 toward the outlet 416.

Next, the collection net 430 is coupled to the rotation axis 422 of the blowing fan 420 so that it can be rotated along the blowing fan 420. However, the present invention is not limited to this, and the collection net 430 may be shaft-coupled with a drive motor (not shown) other than the drive motor 450 described above and driven to rotate independently. For convenience of explanation, the present invention will be described below based on the case where the collection net 430 is axially coupled to the rotation shaft 422 of the blowing fan 420.

The installation location of the collection net 430 is not particularly limited. For example, the collection net 430 may be installed in the internal space 412 so as to be located between the supply port 414 and the blowing fan 420. However, it is not limited to this, and the collection net 430 is installed between the blower fan 420 and the outlet 416 instead of between the supply port 414 and the blower fan 420, or the blower fan 420 and the outlet ( 416) Other capture networks may be additionally installed.

The collection net 430 preferably has a disk shape, but is not limited thereto. That is, instead of the disc-shaped collection net 430, a collection net (not shown) with a cover structure is installed, or the disc-shaped collection net 430 is omitted and a mesh pattern is formed on the outer surface of the blades of the blowing fan 420. It can also be formed.

The collection liquid supply unit 440 stores the collection liquid (Lc), includes a collection liquid storage chamber 442 installed in the internal space 412 or outside, and a collection liquid (Lc) stored in the collection liquid storage chamber 442. ) can be provided with a collection liquid pump 444 that pumps the collection liquid pump 444 and a collection liquid supply pipe 446 that supplies the collection liquid (Lc) pumped by the collection liquid pump 444 to a predetermined position of the collection network 430. there is. The predetermined position of the collection net 430 is not particularly limited. For example, the collection liquid supply pipe 446 may be provided to discharge the collection liquid Lc pumped by the collection liquid pump 444 toward the center of the collection network 430. Additionally, a spray nozzle 448 that sprays the collection liquid Lc toward the center of the first collection net 430 may be installed at the end of the collection liquid supply pipe 446.

This air cleaning device 400 stores the collected liquid (Lc) in a collected liquid storage chamber 442 provided separately from the housing 410, and the air (A) blown by the blowing fan 420 It is the same as the air cleaning device 300 described above, except that the collected liquid Lc is discharged directly to the outside through the outlet 416 without additional contact with the surface of the water. Accordingly, description of the specific aspect in which the air A is purified by the air purifying device 400 will be omitted.

Meanwhile, the unexplained reference symbol 'Lcp' represents particles formed by scattering of the collection liquid (Lc).

The above description is merely an illustrative explanation of the technical idea of the present invention, and various modifications and variations will be possible to those skilled in the art without departing from the essential characteristics of the present invention.

Accordingly, the embodiments disclosed in the present invention are not intended to limit the technical idea of the present invention, but are for illustrative purposes, and the scope of the technical idea of the present invention is not limited by these embodiments. The scope of protection of the present invention should be interpreted in accordance with the claims below, and all technical ideas within the equivalent scope should be construed as being included in the scope of rights of the present invention.

100, 200, 300, 400: Air purifying device
110, 210, 310, 410: Housing
120, 220, 320, 420: Blowing fan
122, 222, 322, 422: Rotation axis
130, 230, 330, 430: Collection net
140, 240, 340, 440: Collected liquid supply unit
150, 250, 350, 450: Drive motor
500: Air curtain device
510: air supply line
S1, S2: Swirling air flow
V1, V2: Vortex
A:air
Ad: first air
Ac: secondary air
Lc: Collected liquid

Claims (6)

An internal space in which a collection liquid that collects contaminants contained in the air is accommodated at a predetermined level, and a swirling air current for forming a vortex in the collection liquid contained in the internal space is formed in the internal space by introducing external air into the internal space. a housing having a supply pipe that guides the air in the inner space to the outside;
a first blowing fan installed inside the discharge pipe and blowing air in the inner space toward the outside;
A first collection net installed inside the discharge pipe, having a mesh structure with a plurality of meshes, and having a rotation axis coupled to the rotation axis of the first blowing fan to rotate along the first blowing fan;
a second blowing fan installed inside the supply pipe and blowing external air toward the internal space;
a second capture net installed inside the supply pipe, having a mesh structure with a plurality of meshes, and having a rotation axis coupled to the rotation axis of the second blowing fan and being driven to rotate along the second blowing fan; and
An air purifying device comprising a collection liquid supply unit that supplies the collection liquid contained in the internal space to predetermined positions of each of the first collection network and the second collection network. delete delete delete According to paragraph 1,
The collection liquid supply device includes a collection liquid pump for pumping the collection liquid contained in the internal space, and a first collection liquid supply pipe for supplying the collection liquid pumped by the collection liquid pump to a predetermined position of the first collection net. and a second collection liquid supply pipe for supplying the collection liquid pumped by the collection liquid pump to a predetermined position of the second collection net. According to clause 5,
The collected liquid supply device is an air purifying device further comprising a connection pipe that connects the first collected liquid supply pipe and the second collected liquid supply pipe to the collected liquid pump, respectively.

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