KR101957799B1 - Apparatus for eliminating fine dust by wet scrubbing - Google Patents

Abstract

A wet type fine dust removing apparatus for collecting and removing fine dust contained in the inflow air by fine water particles is disclosed.
The wet type fine dust removing apparatus includes: a housing having a fluid inflow portion into which a fluid mixture of fine dust and air flows; A mist particle spraying unit installed in the housing and spraying mist particles to the fluid to cause fine dust to be adsorbed on the mist particles; The filter is installed in the housing to supply a cyclone filter and a turbulent flow to the flow of the fluid to supply the cyclone filter and the fog particle spraying section for collecting the fog particles adsorbed by the fine dust, collect the fog particles collected in the cyclone filter And a water tank for storing water.

Description

[0001] APPARATUS FOR ELIMINATING FINE DUST BY WET SCRUBBING [0002]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a wet type fine dust removing apparatus, and more particularly, to a wet type fine dust removing apparatus for collecting and removing fine dust contained in inflow air by mist particles.

Environmental pollution including air pollution is accelerating due to the development of industry, and side effects caused by environmental pollution are also emerging as social problems. Accordingly, various solutions are being discussed in order to reduce environmental pollution at national and international level and to reduce the emission of harmful substances. Particularly in the case of air pollution, fine dusts, including ultrafine dust generated by the use of carbon fuels such as coal and oil, are included. Various fine dust collecting devices for removing such fine dust have been disclosed.

However, the conventional fine dust collecting apparatuses can not sufficiently remove the fine dust, the apparatus is complicated, and maintenance is difficult, for example, the filter must be replaced.

Korean Patent Publication No. 10-2016-0024507 (Feb. Korean Patent No. 10-1503022 (2015.03.18.) U.S. Pat. No. 5,500,111 B (Apr. 29, 2996).

SUMMARY OF THE INVENTION The present invention has been made in view of the above problems, and it is an object of the present invention to improve the fine dust removing performance by collecting fine dust particles contained in the introduced air as fine water particles and adsorbing the fine dust particles on a cyclone carrier having a large specific surface area The present invention has been made in view of the above problems, and it is an object of the present invention to provide a wet type fine dust removing apparatus.

According to an aspect of the present invention, there is provided an apparatus for removing wet type fine dust, comprising: an air inlet through which inflow air containing fine dust flows; A water particle jetting part for supplying water particles to the inflow air so as to adsorb fine dust contained in the inflow air; A water particle collecting unit for collecting water particles to which fine dust is adsorbed; A water tank for supplying water to the water particle spraying unit, for collecting and storing water particles adsorbing fine dust from the water particle collecting unit; And a blowing fan for sucking the inflow air and forming an air flow for discharging the purified air from which the fine dust has been removed, wherein the water particle collecting unit includes a plurality of carriers collecting the water particles adsorbed by the fine dust .

The carrier of the water particle collecting portion may be a ball-shaped pleated ball having a pleated structure formed by bending a thin sheet.

The carrier of the water particle collecting part may be a porous ceramic ball coated with silver iodide.

The water particle collecting part is detachably coupled to the housing, and the carrier can be accommodated so as to be detachable from the number of water particle turns.

And a discharge port connected to the water tank so that the water collected in the water particle collecting part is collected in the water tank may be provided at one end of the water particle collecting part.

A porous ceramic ball coated with silver iodide may be stored in the water tank.

The water particle jetting part may jet ultrasonic waves from the water tank. And a nozzle unit connected to an end of the conduit and injecting water supplied from the water tank into the injection space, wherein the water injection unit includes a conduit connected from the water tank to an upper portion of an injection space through which water particles are injected, can do.

According to an aspect of the present invention, there is provided a wet type fine dust removing apparatus comprising: a housing having a fluid inlet through which a fluid mixed with fine dust and air flows; A mist particle spraying unit installed in the housing and spraying mist particles to the fluid to cause the fine dust particles to be adsorbed on the mist particles; A cyclone filter installed in the housing for collecting the mist particles on which the fine dust is adsorbed by forming a cyclone and a turbulent flow with respect to the flow of the fluid and water supplied to the mist particle spraying part, And a water tank for collecting and storing the mist particles.

The wet type fine dust removing apparatus according to the present invention may further include a drain path provided between the cyclone filter and the water tank to recover mist particles collected in the cyclone filter to the water tank.

Here, the mist particle injecting unit may include a guide pipe connected from the water tank to an upper portion of the injection space through which the mist particles are injected; And a nozzle unit installed at one end of the guide pipe and spraying water supplied from the water tank into the spray space in the form of mist particles.

The wet type fine dust removing apparatus according to the present invention may further include a blower installed in the housing and blowing the fluid passing through the cyclone filter to be forcibly discharged to the outside of the housing.

The wet type fine dust removing apparatus according to the present invention may further include a humidity adjusting unit installed in the housing and removing at least a part of moisture remaining in the fluid passing through the cyclone filter.

The humidity controller may include a ceramic filter for absorbing moisture remaining in the fluid and / or a heater for evaporating the moisture by heating.

The wet type fine dust removing apparatus according to the present invention may further include a plurality of ceramic balls accommodated in the water tank and coated with silver iodide.

The cyclone filter separates the fluid flowing into the cyclone and the turbulent flow into the mist particles and the filtered fluid having the fine dust adsorbed thereon. The cyclone filter has a plurality of cyclone carriers capable of maximizing the specific surface area with respect to the unit volume space .

Here, each of the plurality of cyclone carriers may be a combination of a plurality of cone-shaped micro-hopper structures.

In addition, the cyclone filter can be installed to be rotatable with respect to the housing, so that the probability that the mist particles adsorbed by the fine dust are trapped in the micro-hopper structure can be increased.

The wet type fine dust removing apparatus according to the present invention has a simple structure and can collect fine dust contained in the air introduced into the fine water particles and adsorb the fine dust on the cyclone carrier having a large specific surface area, have.

BRIEF DESCRIPTION OF THE DRAWINGS The accompanying drawings, which are incorporated in and constitute a part of the specification, illustrate preferred embodiments of the invention and together with the description serve to explain the principles of the invention, And shall not be interpreted.
BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a view of a welding system including a wet type fine dust removing apparatus according to a first embodiment of the present invention. FIG.
2 is a view showing a welding system including a wet type fine dust removing apparatus according to a second embodiment of the present invention.
3 is a view of a welding system including a wet type fine dust removing apparatus according to a third embodiment of the present invention.
Fig. 4 is a view showing an embodiment of a carrier accommodated in the water particle collecting part of Figs. 1 to 3. Fig.
Fig. 5 is a view showing an embodiment of a ceramic ball housed in the water tank of Figs. 1 to 3. Fig.
FIG. 6 is a schematic view showing a wet type fine dust removing apparatus according to a fourth embodiment of the present invention; FIG.
7 is a conceptual view of a cyclone dust collector for explaining a dust collecting principle of a cyclone filter.
FIG. 8 is a perspective view showing a cyclone carrier constituting a cyclone filter of the wet type fine dust removing apparatus of FIG. 6; FIG.
Fig. 9 is a view for explaining a relationship between a direction of inflow of a fluid and a microwave hopper constituting the cyclone carrier of Fig. 4; Fig.
10 is a schematic view showing a wet type fine dust removing apparatus according to a fifth embodiment of the present invention.
11 is a flowchart schematically illustrating a method of removing a wet type fine dust according to an embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. In order to clearly illustrate the present invention, parts not related to the description are omitted, and the same reference numerals are used for the same or similar components throughout the specification.

FIG. 1 shows a wet type fine dust removing apparatus 100 according to a first embodiment of the present invention.

Referring to the drawings, a wet type fine dust removing apparatus 100 includes an air inlet 110; A water particle jetting section 120; A water particle recovery unit 130; A water tank 140; And a blowing fan 160. The wet type fine dust removing apparatus 100 can adsorb fine dust having a particle size of 10 μm or less by adsorbing it on a carrier having a very large specific surface area by coagulating it with high humidity. For this, the water particle collecting part 130 may include a plurality of carriers 131 collecting the water particles adsorbed by fine dust.

The inflow air containing the fine dust may be introduced into the air inlet 110. The water particle spraying section 120 can supply water particles to the inflow air so as to adsorb fine dust contained in the inflow air.

The water particle collecting unit 130 can collect the water particles adsorbed by the fine dust. The water tank 140 can supply water to the water particle spraying unit 120 and recover and store the water particles adsorbed by the fine dust from the water particle collecting unit 130. The air blowing fan 160 may draw air from the inlet air to form an air flow so that purified air from which fine dust is removed is discharged. At this time, the water particle collecting unit 130 may include a plurality of carriers 131 collecting the water particles adsorbing fine dust.

Therefore, by collecting the fine dust contained in the introduced air as fine water particles and adsorbing the fine particles on the carrier 131 having a large specific surface area, the fine dust removing performance can be improved by a simple structure.

The inflow air containing the fine dust may be introduced into the air inlet 110. Fine dust may be contained in the inflow air flowing through the air inlet 110. The fine dust is adsorbed by the water particles injected from the water particle injecting section 120, (130). At this time, the fine dust is removed from the inflow air, and the air from which the fine dust is removed can be discharged through the air discharge port 160 through the water particle recovery unit 130.

At this time, the air inlet 110 and the air outlet 160 are disposed in the same indoor space, and the air including the dust in the indoor space flows through the air inlet 110, and the air from which the fine dust is removed passes through the air outlet 160 And the operation is repeated, so that the fine dust can be removed from the room air.

At this time, the blowing fan 160 sucks the inflow air through the air inlet 110 to form an air flow so that the purified air from which the fine dust is removed is discharged through the air outlet 160. Further, the blowing fan 160 can control the operation speed according to the concentration of the fine dust in the air, thereby adjusting the amount of the introduced air. For this purpose, a dust sensor for measuring the concentration of the fine first in the air may be additionally provided. In this case, a separate control unit is provided, and the control unit can control the operation of the blowing fan 160 according to the concentration of the dust measured by the dust sensor.

On the other hand, the air flow from the air inlet 110 to the air outlet 160 can be horizontally aligned. In this case, the internal structure of the wet type fine dust removing apparatus 100 can be simplified.

In addition, the water particle collecting unit 130 may be disposed so as to be in contact with the end of the water particle spraying unit 120 according to the air flow. In this case, the water particles adsorbing the fine dust can be effectively recovered.

In another embodiment, the cross-sectional area of the jetting space through which the water particles are injected may be smaller than the cross-sectional area of the water particle collecting portion 130. In addition, the cross-sectional area of the space in which the air blowing fan 150 on the side of the air outlet 160 is provided may be substantially equal to the cross-sectional area of the water particle collecting part 130. In this case, the air flow passing through the water particle spraying unit 120 can evenly contact the entire surface of the water particle collecting unit 130, thereby improving water particle collecting performance.

1 shows an embodiment in which the air flow from the air inlet 110 to the air outlet 160 is horizontally aligned. However, the present invention is not limited to this, and a bent structure or a vertical structure is also possible.

The water particle spraying section 120 can supply water particles to the inflow air so as to adsorb fine dust contained in the inflow air. The water particle spraying unit 120 can spray the water supplied from the water tank 140 by ultrasonic waves.

In this case, the water tank in which the water in the water tank 140 is stored is arranged at a higher level than the ultrasonic wave generating unit, water is supplied to the ultrasonic wave generating unit from the water tank by the water supply controlling unit as much as necessary for the ultrasonic wave generating unit, Water can be generated from the unit by ultrasonic jetting by ultrasonic waves. At this time, the water particles injected by the ultrasonic wave generating unit may be discharged to the injection space of the water particle spraying unit 120 through a separate conduit and / or an outlet.

In another embodiment, the water particle spraying unit 120 can spray water stored in the water tank 140 through a nozzle to atomize the water particles into the spraying space and discharge the water. At this time, the nozzles may be disposed at the upper portion of the jetting space and form water screens from the upper portion into the jetting space, and the water particles may be jetted.

To this end, the water particle sprayer 120 may include a conduit, a nozzle unit, and / or a pump. The conduit may be connected to the upper portion of the jet space through which the water particles are jetted from the water tank 140. In addition, the nozzle unit is connected to the end of the conduit and can inject water supplied from the water tank 140 into the injection space. In addition, the pump can draw water from the water tank 140 to the nozzle unit when the nozzle unit is installed on the top of the water tank 140.

On the other hand, the nozzle unit can be arranged to cover the upper area of the cross section perpendicular to the air flow direction of the jetting space so as to sufficiently cover the upper space of the jetting space. In this case, the nozzle unit may be disposed at an upper portion of the jetting space to form a water screen from the upper portion of the jetting space to the jetting space and jet water particles. Accordingly, fine particles passing through the spray space can be effectively adsorbed by the water particles sprayed into the spray space.

The water particle spraying part 120 is connected to the water tank 140 at one end of the water particle spraying part 120. The water particle spraying part 120 is connected to the water tank 140, May be provided.

At this time, the water tank 140 can be separated from the housing 101. The inlet of the water particle spraying unit 120 and the water outlet 141 of the water tank 140 are connected to each other, 140 to supply water particles or water to the water particle spraying unit 120. In this case, the inlet of the water particle spraying unit 120 is provided with a cap which is opened when the water tank 140 is pushed from the outside, and is opened only when the water tank 140 is coupled. When the water tank 140 is separated, 120 may be closed.

At this time, a water particle generator including a separate ultrasonic generator may be included between the water outlet 141 of the water tank 140 and the inlet of the water particle sprayer 120.

The water particle collecting unit 130 can collect the water particles adsorbed by the fine dust. For this, the water particle collecting unit 130 may include a carrier 131 that is accommodated in a space defined by a partition wall or the like. At this time, fine particles passing through the water particle collecting part 130 by the carriers 131 can collect the water particles adsorbed.

The carrier 131 of the water particle collecting part 130 may be a ball-shaped pleated ball having a pleated structure formed by bending a thin sheet. The pleated ball may have a shape as shown in Fig. The pleated ball is formed of a PVC material so that the pleated ball can be easily formed at a low cost.

The pleated ball having a pleated structure as shown in the figure has a structure capable of maximizing the specific surface area per unit volume, and the flow of the fine dust can be made turbulent by the shape of the pleated ball. In addition, it is possible to maximize the time for allowing fine dust having moisture to accumulate on the carrier by maximizing the area of contact with the air flow.

On the other hand, since it has a wrinkle structure, the humidity in the carrier is always high, so that the propagation of microorganisms such as bacteria can be facilitated. Therefore, by allowing the ceramic ball coated with silver iodide to be immersed in the water contained in the water tank 140 as shown in FIG. 5, the water sprayed from the water particle spraying unit 120 is sprayed on the fine dust and bacteria It is possible to sterilize contaminated objects.

The carrier 131 can be formed with a structure in which the specific surface area per unit volume is maximized and turbulence is generated while rotating the air flow. As a result, the air adsorbing fine dust having a high humidity is allowed to adhere to a large area or surface area while causing rotation and turbulence while passing through the carrier 131, thereby collecting the air adsorbed by the fine particles by the carrier 131 Can be made effective.

In another embodiment, the carrier 131 of the water particle recovery unit 130 may be a porous ceramic ball coated with silver iodide. At this time, silver iodide coated on the porous ceramic balls can be dissolved in the water particles that are sprayed from the water particle spraying unit 120 and collect fine particles and / or contaminants such as bacteria. At this time, the silver iodide coated on the porous ceramic balls can be present as iodine component and silver component ion in the water.

In this case, the iodine component of the silver iodide coated on the porous ceramic balls can agglomerate the fine dust and increase the size thereof. Accordingly, the water particles adsorbed by the fine dust effectively aggregate the fine dust by the iodine component of the support 131, so that the support 131 can collect the fine dust effectively.

In addition, the silver component of silver iodide coated on the porous ceramic balls can sterilize various microorganisms generated in the carrier, thereby enhancing the quality of the fine dust-removed air. Accordingly, the water particles adsorbed by the fine dust effectively sterilize various microorganisms by the silver component of the carrier 131, and the carrier 131 sterilizes various microorganisms, thereby enhancing the quality of air from which the fine dust is removed. In addition, the silver iodide is coated on the porous ceramic balls, so that it is possible to use the one material to enable the coagulation of fine dust and sterilization of various microorganisms.

The silver iodide coated on the porous ceramic ball is intended to perform the function of a coagulant and the function of a fungicide. The present invention is not limited to this and does not limit the use of various other materials.

On the other hand, the support 131 may have a structure in which the specific surface area per unit volume is maximized and turbulence is generated while rotating the air flow. As a result, the air adsorbing fine dust having a high humidity is removed while being deposited on a large surface area while being rotated and turbulent while passing through the carrier 131, thereby collecting the air adsorbed by the fine particles by the carrier 131 Can be made effective.

To this end, a rotating spiral structure is formed in the space in which the carriers 131 of the water particle collecting part 130 are received, and the carriers 131 can be received along the rotating spiral structure. As another embodiment, a structure such as a partition wall formed on the air inlet surface along a section perpendicular to the air flow may be formed with a rotating spiral structure so that the introduced air flows while drawing a rotating spiral. Also, a structure such as a partition wall formed on the air discharge surface along a cross section perpendicular to the air flow forms a rotating spiral structure so that the discharged air flows while drawing a rotating spiral.

In another embodiment, an additional air flow guide portion is disposed on the air inlet surface along a cross section perpendicular to the air flow on the water particle spraying portion 120 side in the water particle collecting portion 130 so that air adsorbed on the fine dust 131) while being rotated and turbulent, and can be removed while being deposited on a large surface area. As a result, the air adsorbing fine dust having a high humidity is removed while being deposited on a large surface area while being rotated and turbulent while passing through the carrier 131, thereby collecting the air adsorbed by the fine particles by the carrier 131 Can be made effective.

The water particle collecting part 130 is detachably coupled to the housing 101 and can be received so that the carrier 131 can be detached from the water particle turning part 130. [ That is, the water particle collecting unit 130 may be detachably coupled to the housing 101. In this case, the water particle collecting part 130 can be installed in the housing 101 in a structure in which the water particle collecting part 130 can be inserted into and / or detached from the housing 101. Therefore, fine dust accumulated in the carrier 131 can be rinsed off with water for a predetermined period of time, and the carrier 131 can be used again. That is, the water particle collecting unit 130 becomes reusable.

As another example, the carrier 131 can be accommodated so as to be detachable at the number of water particle turns 130. In this case, only the carrier 131 is discharged to the outside from the storage space of the number of water particle turns 130. Only the carrier 131 is rinsed off with water to remove fine dust from the carrier 131, It can be stored in the storage space of the number of particle turns 130. That is, the carrier 131 becomes reusable.

For this purpose, a storage section is provided in the rear end area of the water particle spraying section 120 of the housing 101. The door is openable and closable in a part of the storage section. Filling or discharging.

In another embodiment, a water particle collecting part 130 is detachably coupled to the housing 101. One end of the water particle collecting part 130 is coupled to the water particle injecting part 120, 130 may be connected to an air outlet 160 through which the air blowing fan 150 is installed.

On the other hand, in the carrier 131 of the water particle collecting part 130, water particles adsorbing fine dust are collected. When a predetermined amount or more of fine dust is adhered to the carrier 131, fine particles of the carrier 131 are adsorbed on the water particles The collection performance may be deteriorated. In this case, the fine dust is separated from the carrier 131 in which the fine dust is collected, and the carrier 131 can collect the fine water-absorbed water particles again.

For this purpose, fine dust can be separated from the carrier 131 by various methods. The water particle collecting part 130 may be separated from the housing 101 or the carrier 131 may be separated from the water particle collecting part 130 and washed in water or rinsed in flowing water.

As another embodiment, fine particles can be separated from the carrier 131 by blowing compressed air from one direction or flowing clean water in a state where the water particle recovery unit 130 is not separated to the housing 101. The water particle collecting part 130 is provided with water or compressed air inlet and outlet and water or compressed air is introduced into the water particle collecting part 130 in which the carrier 131 is stored through the inlet, Can be discharged. At this time, a separate blocking portion may be provided at the outlet side of the water particle collecting portion 130 to prevent fine dust or other contaminants from flowing out from the water particle collecting portion 130 through the air outlet 160.

2, the wet type fine dust removing apparatus 200 includes an agitator 132, and the agitator 132 is rotated to agitate the inside of the carrier 131 to stir the carrier (not shown) 131 may be detached from the carrier 131. [0064] In this case, an embodiment in which water or compressed air is injected into the carrier 131 may be applied together.

In this case, the stirrer 132 can turn the lever, which is exposed to the outside from the outside, to operate. As another embodiment, the stirrer 132 may be operated using a motor by connecting the motor. In this case, a separate sensor is attached to detect the degree of adhesion of water particles and / or fine dusts to the carrier 131 by the sensor, and when it is determined that the particles are attached to the carrier 131 by a predetermined amount or more, The stirrer may be actuated. At this time, the stirrer may be operated by detecting the weight increase by the sensor for measuring the weight.

On the other hand, a window may be provided so that the degree of adhesion of water particles and / or fine dust or the like to the carrier 131 can be discriminated from the outside.

On the other hand, fine dust and / or other contaminants may be adhered to the carrier 131, so that air having fine dust and / or other contaminants removed from the inflow air may be discharged through the air outlet 160, A part of the moisture supplied through the scarf 120 may be discharged together with the purified air so as to have a humidifying function of supplying moisture to the indoor space.

One end of the water particle collecting part 130, for example, a part connected to the water tank, has an outlet connected to the water tank 140 so that the water collected in the water particle collecting part 130 is collected into the water tank 140 . For this purpose, the inner structure of the water particle collecting part 130 may have a funnel-like structure so that water can be collected at the discharge port side.

At this time, the water tank 140 can be separated from the housing 101, and water can be supplied through the water inlet 142 by separating the water tank 140. The outlet of the water particle collecting part 130 and the water inlet 142 of the water tank 140 are connected to each other so that the water collected in the water particle collecting part 130 can be recovered to the water tank 140 . In this case, the discharge port of the water particle collecting part 130 is provided with a cap which is opened when it is pressed from the outside, and is opened only when the water tank 140 is engaged. When the water tank 140 is separated, 130 may be closed.

The water tank 140 can supply water to the water particle spraying unit 120 and recover and store the water particles adsorbed by the fine dust from the water particle collecting unit 130. In the water tank 140, a porous ceramic ball 143 coated with silver iodide may be stored so as to be immersed in water. In this case, the silver iodide coated on the porous ceramic balls 143 can be present as ions of iodine component and silver component in water. Therefore, the iodine component and the silver component are dissolved in the water sprayed by the water particle sprayer 120, respectively.

At this time, the iodine component dissolved in the water can coagulate the fine dust to increase the size thereof. In addition, the silver component dissolved in water can sterilize various microorganisms generated in the carrier, thereby enhancing the quality of fine dust-removed air.

3, the wet type fine dust removing apparatus 300 according to another embodiment of the present invention may include a first filter 170 and a second filter 180. At this time, the primary filter 170 is installed at the front end of the water particle spraying unit 120, so that dust particles having a large particle size can be primarily removed at the front of the water particle spraying unit 120. For this purpose, it may be installed between the air inlet 110 or between the air inlet 110 and the water particle sprayer 120.

The secondary filter 170 may be additionally disposed to remove various odors, VOCs, and / or bacteria that have not been removed through the water particle spraying unit 120 and the water particle collecting unit 130. Further, the secondary filter 170 may include a moisture removing filter for removing moisture.

According to the present invention, the fine dust particles contained in the inflow air are collected as fine water particles and adsorbed on a carrier having a large specific surface area, whereby the fine dust removing performance can be improved by a simple structure.

FIG. 6 is a schematic view showing a wet type fine dust removing apparatus according to a fourth embodiment of the present invention. FIG.

6, the wet type fine dust removing apparatus 200 according to the fourth embodiment of the present invention includes a housing 210, a mist particle spraying unit 220 installed in the housing 210, a housing (not shown) A cyclone filter 230 and a water tank 240 that are installed in the water tank 210.

The housing 210 has a fluid inlet 211 into which a fluid mixed with fine dust and air flows. The fluid inlet 211 can be installed below the housing 210, and the inflow fluid is separated from the clean air and fine dust in the cyclone filter 230. The clean air is discharged to the upper portion of the housing 210, and the fine dust is recovered to the water tank 240.

The mist particle injecting section 220 converts the water provided in the water tank 240 into fog particles in the form of fine moisture particles and injects the fog particles into the fluid flowing through the fluid inlet section 211. Whereby fine dust contained in the fluid is adsorbed on the mist particles. Here, considering the dust collecting performance by the cyclone filter described later, the fine dust particles adsorbed on the mist particles may have a diameter of about 10 mu m.

To this end, the fog particle spraying unit 220 may include a guide pipe 221 for carrying water and a nozzle unit 225. The guide pipe 221 connects the water tank passage 240 and the nozzle unit 225 and transfers the purified water in the water tank 240. One end of the guide pipe 221 is connected to the upper part of the injection space inside the housing 210. Here, the fog particle spraying unit 220 may further include a pump 223 installed in the guide pipe 221. The pump 223 provides a transfer force to transfer the water contained in the water tank 240 through the guide pipe 221.

The nozzle unit 225 is installed at one end of the guide tube. The nozzle unit 225 converts the water supplied through the guide tube 221 into a foggy particle form and injects the water into the above-mentioned injection space. The fog particles may be generated by an ultrasonic generator (not shown) provided separately or by evaporation of water by a heating device. As shown in FIG. 6, a plurality of nozzle units 225 are provided, and fine water particles can be sprayed in the form of mist particles throughout the jetting space.

In this embodiment, the pump 223 is included as one component of the mist particle spraying unit 220. However, the present invention is not limited thereto, and the water tank 240 may be disposed on the nozzle unit 225 It is also possible to constitute a structure capable of freely falling by gravity.

The cyclone filter 230 is installed in the housing 210, and forms a cyclone and a turbulent flow with respect to a flow of the fluid to collect fog particles adsorbed by the fine dust. Details of the cyclone filter 230 will be described later.

The water tank 240 supplies water to the mist particle spraying unit 220, and collects and stores the mist particles collected by the cyclone filter 230. The wet type fine dust removing apparatus according to the fourth embodiment of the present invention may further include a drain path 231 provided between the cyclone filter 230 and the water tank 240. The drainage path 231 is a path for collecting the mist particles collected by the cyclone filter 230 into the water tank 240.

The water tank 240 may have a structure detachable from the housing 210. The water tank 240 can be separated and water can be supplied through the water inlet 241. The drainage path 231 of the cyclone filter 230 and the water inlet 241 of the water tank 240 are connected to each other so that the mist particles collected in the cyclone filter 230 can be recovered into the water tank 240 .

In the water tank 240, a porous ceramic ball 245 coated with silver iodide (AgI) may be stored so as to be precipitated in water. In this case, the silver iodide (AgI) coated on the porous ceramic balls 245 can be present as ions of iodine component and silver component in water. Accordingly, the mist particles in the form of fine water particles sprayed from the mist particle spraying unit 220 melt the iodine component and the silver component, respectively. At this time, the iodide component dissolved in the water can agglomerate the fine dust to increase its size. Therefore, fine dust can be agglomerated to a particle size of 5 to 10 mu m which is high in dust collection efficiency in the cyclone filter.

In addition, the silver (Ag) component dissolved in water can sterilize various microorganisms, thereby enhancing the quality of the fine dust-removed air. In other words, the bactericidal action of the silver iodide (AgI) component inhibits the growth of microorganisms such as fungi in the cyclone carrier.

The wet type fine dust removing apparatus according to the fourth embodiment of the present invention may further include a blower 250. The blower is installed in the housing 210 and blows the fluid that has passed through the cyclone filter 230 to be forcibly discharged to the outside of the housing 210. That is, the blower 250 sucks the inflow air and forms an air flow so that the purified air from which the fine dust is removed is discharged. The blower 250 can control the operation speed according to the concentration of the fine dust in the air, thereby adjusting the amount of the introduced air. For this purpose, a dust sensor for measuring the concentration of fine dust in the air may be additionally provided. In this case, a separate control unit is provided, and the control unit can control the operation of the blower 250 according to the concentration of the dust measured by the dust sensor.

The wet type fine dust removing apparatus according to the fourth embodiment of the present invention may further include a humidity controller 260. The humidity adjusting unit 260 is installed in the housing 210 and removes at least a portion of the moisture remaining in the fluid that has passed through the cyclone filter 230, that is, the purified air. For this purpose, the humidity controller 260 may include a ceramic filter for absorbing moisture remaining in the fluid and / or a heater for evaporating moisture by heating. Here, ceramic filters such as diatomaceous earth, zeolite, kaolin, titanium, and elvan can be applied to the ceramic filter. The heater may include a heating element, that is, a heating wire arranged on the cyclone filter 230.

Referring to Figs. 7 to 9, the cyclone filter will be described in detail.

7 is a conceptual diagram of a cyclone dust collector for explaining the dust collecting principle of the cyclone filter. Referring to the drawings, the cyclone dust collector includes a conical body 270. At one side of the main body 270 is formed an inlet 271 through which fine dust flows, and at both ends thereof, first and second outlets 273 and 275 are formed. That is, the inlet port 271 is formed in the side surface of the upper end portion of the main body 270, that is, in the radial direction, as shown in FIG. The fluid including the fine dust introduced through the inlet 271 is separated into the fine dust D and the air A by the cyclone principle. That is, the fine dust D having a relatively high density passes through the inlet 271 and has a radial tangential force, and receives a force toward the wall inside the main body 270. In addition, it is moved downward by the gravity by a spiral, and is discharged to the outside of the dust collector through the first outlet 273. On the other hand, air (A) having a relatively low density moves to the center portion while being separated from fine dust inside the body 270. Since the dust collector is formed in a conical shape as shown in FIG. 7, the air A pushed to the center is converted into a reverse vortex reversal, and is spirally moved to the upper part of the dust collector. The separated air A is discharged to the outside of the dust collector through the second outlet 275 formed in the direction opposite to the first outlet 273. The main technical feature of the present invention is that the principle of the cyclone dust collector described above is applied to a cyclone filter (230 of FIG. 1).

Referring to FIG. 8, the cyclone filter 230 (FIG. 6) may include a plurality of cyclone carriers 235. Each cyclone carrier 235 forms a cyclone and a turbulent flow to separate the incoming fluid into the mist particles and the filtered fluid in which the fine dust is adsorbed. The cyclone carrier 235 may have a structure capable of maximizing the specific surface area with respect to the unit volume space. The cyclone carrier 235 can be made of a PVC material, so that the cyclone carrier 235 can easily form its shape at low cost.

Each cyclone carrier 235 may be composed of a combination of a plurality of cone-shaped micro-hopper 237 structures. This microwave hopper 237 separates the fine dust-containing fluid flowing on substantially the same principle as that of the cyclone dust collector described with reference to Fig. That is, when the fluid flows into the microwave hopper 237, the fog particles that have collected the fine dust due to the structure of the microwave hopper 237 are moved in the direction of one direction And the fluid from which the fine dust has been removed is spirally moved in a direction different from the traveling direction of the mist particles in a state separated from the center of the microwave hopper 237.

Here, the microwave hopper 237 constituting the cyclone carrier 235 may be arranged so as to be perpendicular to the fluid flow direction F, as shown in FIG. 9, to produce a cyclone filter. By thus fabricating the micro-hopper 237, the trajectory of the particles in the micro-hopper 237 is prolonged and the residence time is prolonged, so that the fine dust particles and air can be separated more efficiently.

10 is a schematic view showing a wet type fine dust removing apparatus according to a fifth embodiment of the present invention.

10, the wet type fine dust removing apparatus 300 according to the fifth embodiment of the present invention includes a housing 310, a mist particle spraying unit 320 installed in the housing 310, a housing A cyclone filter 330 and a water tank 340 that are installed in the water tank 310. The wet type fine dust removing apparatus 300 according to the present embodiment is different from the wet type fine dust removing apparatus 200 according to the fourth embodiment in that the cyclone filter 330 is rotatable with respect to the housing 310 In order to make the difference.

That is, the cyclone filter 330 can be installed to be rotatable with respect to the housing 310. In this case, when the cyclone filter 330 in which the cyclone carrier 335 made of a combination of the micro-hopper structures is rotated at a predetermined speed, the entry direction of the mist particles adsorbed by the fine dust is made perpendicular to the plurality of micro- The probability of incidence is greatly increased. As a result, the probability that fine particles adsorbed by mist particles are confined in the micro-hopper structure can be increased, and thus the performance can be further improved.

Here, a bearing structure may be provided between the housing 310 and the cyclone filter 330 so as to be rotatable, and a separate driving motor (not shown) for rotating the cyclone filter 330 may be further included . Further, a blade (not shown) for converting a linear motion into a rotational motion may be installed on the upper or lower part of the cyclone filter 230 and may be rotationally driven by a linear motion of the fluid passing through the inside of the housing.

11 is a schematic flowchart of a method of removing wet type fine dust according to an embodiment of the present invention.

Referring to FIGS. 6 and 11, the fluid containing fine dust flows into the housing 210 through the fluid inlet 211 of the housing 210 (S10). At this time, water is sprayed onto the inflow fluid by replacing water with fog particles in the form of fine moisture through the fog particle spraying unit 220 (S20). The sprayed mist particles are combined with the fine dust, and the fine dust is collected (S30). Here, the fog particles contain a silver iodide component, so that the size of the fine dust to be collected can be made larger.

The mist particles collecting the fine dust and the fluid introduced through the fluid inlet 211 are filtered while passing through the cyclone filter 230 (S40). That is, the fine dust is separated from the clean air by the cyclone principle, and is recovered to the water tank 240 through the recovery path 231. On the other hand, the clean air passes through the cyclone filter 230 and is discharged to the outside of the housing 210. The discharged air is dehumidified while passing through the humidity controller 260 (S50).

As described above, by applying the cyclone separation method, fine dust removal performance can be improved while simplifying the structure. In addition, the water containing silver iodide is sprayed in the form of mist particles, and the particle size of the coagulated fine dust can be relatively increased by aggregating the fine dust, so that the separation performance in the cyclone filter can be further improved.

Furthermore, by providing the cyclone filter rotatably with respect to the housing, it is possible to increase the probability that the inflow fluid enters the radial direction of the microwave hopper formed on the cyclone carrier. As a result, the fine dust removing performance can be further improved.

The above-described embodiments are merely illustrative, and various modifications and equivalent embodiments can be made by those skilled in the art. Therefore, the true scope of protection of the present invention should be determined by the technical idea of the invention described in the claims.

200, 300: wet type fine dust removing apparatus 210, 310: housing
211: fluid inflow section 220, 320: mist particle spraying section
221: Guide tube 223: Pump
225: nozzle unit 230, 330: cyclone filter
231: Drain path 235, 335: Cyclone carrier
237: Micro hopper 240, 340: Water tank
241: Water inlet 245: Porous ceramic ball
250: blower 260: humidity controller

Claims (10)

A housing having a fluid inflow portion into which a fluid mixed with fine dust and air flows;
A mist particle spraying unit installed in the housing and spraying mist particles to the fluid to cause the fine dust particles to be adsorbed on the mist particles;
A cyclone filter rotatably installed in the housing for separating the fog particles adsorbed by the fine dust and the filtered fluid by forming a cyclone and a turbulent flow with respect to the flow of the fluid,
And a water tank for supplying water to the fog particle spraying part and for recovering and storing the fog particles collected by the cyclone filter,
Wherein the cyclone filter includes a plurality of cyclone carriers capable of maximizing a specific surface area with respect to a unit volume space,
Wherein each of the plurality of cyclone carriers comprises a combination of a plurality of cone-shaped micro-hopper structures formed by bending a sheet. The method according to claim 1,
And a drain path provided between the cyclone filter and the water tank for collecting mist particles collected in the cyclone filter into the water tank. The method according to claim 1,
Wherein the mist particle injecting unit includes:
A guide tube connected from the water tank to an upper portion of the spray space in which the mist particles are sprayed;
And a nozzle unit installed at one end of the guide tube for spraying water supplied from the water tank into the spray space in the form of mist particles. The method according to claim 1,
And a blower installed in the housing for blowing the fluid that has passed through the cyclone filter to the outside of the housing for forced discharge. The method according to claim 1,
And a humidity adjusting unit installed in the housing to remove at least a portion of moisture remaining in the fluid passing through the cyclone filter. 6. The method of claim 5,
The humidity controller may include:
A ceramic filter for absorbing moisture remaining in the fluid, and a heater for evaporating the moisture by heating. The method according to claim 1,
And a plurality of ceramic balls accommodated in the water tank and coated with silver iodide. delete delete delete

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