KR101949253B1 - Harmful air purification method using a wet scrubber and the scrubber multilayer structure - Google Patents

Abstract

The present invention relates to a wet scrubber characterized by comprising: a first chamber in which a cleaning liquid is sprayed from an upper portion and a noxious air is supplied from a pollution facility, and a rinsing liquid is filled in an inner lower portion, A chamber comprising a second chamber; An exhaust unit provided at the end of the second chamber for exhausting the cleaned air to be cleaned, wherein at least one filter is provided to block the leakage of the cleaning liquid; And a control unit for controlling the movement of the harmful air and the spraying of the cleaning liquid, wherein the first chamber and the second chamber are a laminated structure in which the inside is communicated.
According to the present invention, harmful air generated from pollution facilities such as barns is purified through a scrubber of a multi-layer structure and supplied to polluted facilities, thereby stabilizing the domestic animals and minimizing the stress applied to domestic animals You can expect.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a wet scrubber having a multi-layer structure and a method for cleaning harmful air using the scrubber,

The present invention relates to a wet scrubber, and more particularly, to a wet scrubber which is capable of purifying harmful air generated in a pollution facility such as a poultry house through a scrubber of a multi-layer structure and supplying purified air to a pollution facility, A wet scrubber having a multi-layer structure capable of minimizing the stress applied to the livestock, and a method for cleaning harmful air using the scrubber.

In general, wet scrubbers typically use a cleaning fluid to make cleaning of contaminated air more efficient. The cleaning solution is to remove the contaminants that remain in the contaminated air through chemical reaction such as neutralization in the contact surface between the contaminant and water. In order to achieve high efficiency, the cleaning solution should be selected as the cleaning solution which is most likely to be chemically reacted.

The performance of the wet scrubber is determined by how efficiently it can contact the harmful air with the water containing this cleaning liquid. Therefore, in the past, a method of using a filling material or providing a spray nozzle for supplying water with a small particle size was provided so that the water containing the cleaning liquid and the harmful air can sufficiently contact with each other.

As an example of such a wet scrubber, a wet gas scrubber having a cleaning liquid rotating supply unit of Korean Patent No. 10-0866163 has been registered.

The conventional scrubber is further provided with a rotation supply part rotatably connected to the rinse solution inflow pipe in the wet gas scrubber, wherein the rotation supply part is a hollow supply rod whose one end is communicated with the rinse solution inflow pipe, Wherein the rotating supply portion is rotated by an opposite direction thrust produced by the recoil when the washer fluid is discharged through the discharge port of each supply rod, and the height of the gas inlet port of the housing Wherein at least one filler layer is formed between the height of the gas outlet and the rinse solution inlet pipe and the rotation feeder are provided on the top of each of the filler layers and the feed rod has an adjusting opening formed at a free end in a direction different from the outlet, And a control valve for controlling the flow rate through the opening, And the rotation speed of the rotation supply unit is controlled by changing the flow rate of the control opening by the valve. The gas cleaning liquid is supplied to the cleaning liquid at a low pressure by the rotation supply unit rotating at low speed, Thereby significantly reducing the droplets of the cleaning liquid, thus preventing the outflow of the cleaning liquid and the air pollution. In addition, since a high-pressure pump is not required, it is an object of the present invention to reduce costs and noise by energy saving.

However, the conventional scrubber has to be enlarged so that frequent contact between the harmful air and the cleaning liquid can be achieved, and since the structure of the tower is made to increase the area efficiency, the scrubber is bulky and has a very high height. . In addition, the higher the height, the more difficult it is to install, the longer the installation period, the higher the difficulty in proportion to the height in terms of maintenance, and the higher the maintenance cost. Particularly, the conventional scrubber has a structure of a tower type, which makes it difficult to maintain and repair. In particular, maintenance can be performed only through a separate ladder or the like, .

In addition, there is a problem that corrosion of the cleaning liquid is strong due to the acidity of the cleaning liquid. Therefore, a material having a high resistance to corrosion is required because the material is limited in manufacturing the scrubber. In particular, A good stainless steel or the like) must be used.

In addition, since the chemical cleaning liquid is a waste, it needs to be managed separately. In case of leaking without disposal, serious environmental pollution may occur. Therefore, the cleaning liquid needs to be managed separately by a professional manpower and a company, which may increase the economic burden due to the operation.

Therefore, it is required to develop a technology for improving the cleaning efficiency of the wet scrubber. Further, it is possible to reduce the size of the device in terms of the scale of the apparatus, Research and development of wet scrubber that can be pursued is urgent.

Korean Patent No. 10-0866163 B

SUMMARY OF THE INVENTION The present invention has been proposed in order to solve the above-mentioned problems, and an object of the present invention is to provide a method and apparatus for purifying harmful air generated in a pollution facility such as a house, And a method for cleaning harmful air using the scrubber.

Another object of the present invention is to provide a wet scrubber having a multi-layer structure capable of eliminating odors and complaints caused by bad odors, and a method for purifying harmful air using the scrubber.

It is still another object of the present invention to provide a wet scrubber of a multi-layer structure capable of increasing the cleaning efficiency as well as the cleaning efficiency by doubling the flushing time of the harmful air, and a harmful air cleaning method using the scrubber, .

Still another object of the present invention is to provide a wet scrubber of a multi-layer structure which can easily perform drainage treatment and prevent environmental pollution by using a mixture of a fluid and a microorganism as a cleaning liquid, and a method for cleaning harmful air using the scrubber.

It is a further object of the present invention to provide a wet scrubber of a multi-layer structure capable of increasing the activity of microorganisms and preventing mortality, thereby doubling the detergency against harmful air by providing a plurality of windows, an oxygen generator and a temperature controller in the chamber, And a method for purifying harmful air using the scrubber.

It is still another object of the present invention to provide a wet scrubber of a multi-layer structure capable of raising the cleaning effect by increasing the frequency of contact between cleaning time and cleaning time of the noxious air, And to provide an air purification method.

It is still another object of the present invention to provide a wet scrubber of a multi-layer structure capable of inducing eddy currents of harmful air passing through a swirling flow path and a second flow path of a cleaning fluid accommodated in a second chamber, And a method for purifying harmful air using the scrubber.

Another object of the present invention is to provide a wet scrubber of a multi-layer structure capable of doubling the cleaning effect by increasing the frequency of contact between the harmful air and the cleaning liquid by further providing wings for amplifying the vortex phenomenon in the second flow path, And to provide a purification method.

Yet another object of the present invention is to provide a wet scrubber of a multi-layer structure capable of early detection of an operation error and quick response, And a method for purifying harmful air using the scrubber.

In order to achieve the above-mentioned object, the present invention provides a wet scrubber, comprising: a first chamber in which a flow path of an upper longitudinally zigzag shape in an inner longitudinal direction is formed and a cleaning liquid is sprayed from an upper portion thereof and noxious air is supplied from a pollution facility; A chamber filled with a second chamber through which the washer fluid is sprayed; An exhaust unit provided at the end of the second chamber for exhausting the cleaned air to be cleaned, wherein at least one filter is provided to block the leakage of the cleaning liquid; And a control unit for controlling the movement of the harmful air and the spraying of the cleaning liquid, wherein the first chamber and the second chamber are a laminated structure in which the inside is communicated.

Preferably, the chamber further comprises a window formed on at least one side so that the daylight can illuminate the interior.

Wherein the chamber comprises: an oxygen generator for supplying oxygen to each of the first chamber and the second chamber; A temperature controller for controlling the temperature of the cleaning liquid; And a cleaning liquid supply unit for spraying the cleaning liquid into each of the first chamber and the second chamber.

The first chamber is provided with an inlet through which a first duct communicated with the pollution facility is connected to one side and a first communication hole communicated with the second chamber on the other side. It is preferable that a zigzag-shaped flow passage is formed alternately in the lower portion.

The first duct may include a duct filter for filtering foreign matter contained in harmful air.

Wherein the second chamber is formed with a second communication hole communicating with the first chamber on one side and the exhaust part on the other side, and at least one second partition is disposed in parallel to the upper portion of the inner wall at a predetermined interval, It is preferable that a flow path is formed adjacent to the water surface by being spaced apart from the cleaning liquid surface.

The second partition may further include a blade for inducing a vortex phenomenon of harmful air on a bottom surface facing the water surface.

Wherein the vane is a plate flexibly bent according to the wind direction; And a rotary shaft connected at one side to the plate and at the other side to be rotatably coupled with the second partition.

It is preferable that the cleaning liquid is a mixture in which the fluid and the microorganism are mixed in a predetermined ratio.

It is preferable that the mixture is a mixture of at least any one or all of Bacillus subtilis, nitrifying bacteria, lactic acid bacteria and yeast in a predetermined ratio.

The exhaust unit may include: a collecting unit for collecting the washing liquid filtered through the filter; And an exhaust hole through which the cleaned air is exhausted and connected through the pollution facility and the second duct.

The second duct comprising: a fan device for forcing the scrubber to flow a fluid; A temperature regulator for regulating the exhaust temperature of the purifying air; And an ion generator.

Preferably, the collecting part is formed with a slope on one side where the washing liquid is collected, and the slope is connected to the second chamber so that the washing liquid is collected in the second chamber.

A wet scrubber of a multi-layer structure is used to introduce harmful air into the first chamber; A second step of spraying a cleaning liquid to the noxious air introduced into the first chamber to perform first cleaning; A third step of introducing the noxious air into the second chamber communicating with the first chamber and containing the cleaning liquid therein; A fourth step of secondly cleaning the cleaning solution contained in the second chamber by contacting the harmful air with the cleaning solution; And a fifth step of filtering and purifying the cleaning liquid from the purified air that has been cleaned through the second chamber.

Exposing the cleaning liquid to daylight in the second and third steps; And supplying oxygen to the cleaning liquid.

In the fourth step, it is preferable that the method further comprises generating a vortex on the water surface of the cleaning liquid.

According to the embodiment of the present invention, the harmful air generated in the contaminated facilities such as the housing can be purified and re-supplied, so that the stable feeding of the domestic animal and the stress applied to the domestic animal can be minimized.

In addition, since the present invention is capable of eliminating odor caused by harmful air, it is possible to expect the effect of eliminating the complaints caused by the malodor and the resulting conflicts.

In addition, the present invention has a stacked structure in which the chamber is vertically communicated, thereby doubling the flushing time of the noxious air, thereby enhancing the purification efficiency as well as the purification capacity.

Further, since the present invention uses a mixture of a fluid and a microorganism as a cleaning liquid, it is easy to carry out a drainage treatment and can prevent an environmental pollution.

In addition, the present invention can provide a plurality of windows, an oxygen generator, and a temperature controller in the chamber to improve the activity of the microorganisms, prevent mortality, and thereby increase the detergency against harmful air.

It is a further object of the present invention to provide an apparatus and a method for cleaning a first chamber in which a flow path of a first chamber is formed in a zigzag shape in the longitudinal direction to improve the cleaning effect by increasing the frequency of contact with the cleaning liquid.

In addition, the present invention can swing the cleaning liquid contained in the second chamber and induce vortexing of the harmful air passing through the second flow path, thereby increasing the frequency of contact between the harmful air and the cleaning liquid, thereby doubling the cleaning effect.

Further, according to the present invention, a wing for amplifying the vortex phenomenon is further provided in the second flow path, thereby increasing the frequency of contact between the harmful air and the cleaning liquid, thereby doubling the cleaning effect.

In addition, since the cleaning liquid injection state is visually confirmed through the window, it is possible to quickly determine an operation error, and quick action is possible. Therefore, an effect of minimizing a work loss due to an error can be expected.

1 is a perspective view illustrating a scrubber according to a preferred embodiment of the present invention,
2 is a cross-sectional view illustrating a first chamber according to a preferred embodiment of the present invention,
3 is a cross-sectional view illustrating a second chamber according to a preferred embodiment of the present invention,
4 is a detailed view illustrating a wing according to a preferred embodiment of the present invention,
5 is a cross-sectional view illustrating vortex phenomenon in a second chamber according to a preferred embodiment of the present invention,
6 is a front view illustrating a control unit according to an exemplary embodiment of the present invention.
7 is a detailed view for explaining a mixture feeder according to a preferred embodiment of the present invention,
8 is a detailed view for explaining an oxygen generator according to a preferred embodiment of the present invention,
9 is a detailed view for explaining a temperature controller according to a preferred embodiment of the present invention,
FIG. 10 is a detailed view illustrating an exhaust unit according to a preferred embodiment of the present invention,
FIG. 11 is a flowchart illustrating a harmful air cleaning method using a scrubber according to a preferred embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear.

In describing the present invention, the defined terms are defined in consideration of the function of the present invention, and it can be changed according to the intention or custom of the technician working in the field, and the definition is based on the contents throughout this specification It should be reduced.

The present invention will be described with reference to pollution facilities, but it is not limited to the one rail of the pollution facility, it can be applied to a place where a stench occurs, such as a public toilet, a plating factory, Especially, it can be applied to most facilities such as companies that require atmospheric environment facilities according to business category and business.

1 is a perspective view illustrating a scrubber according to a preferred embodiment of the present invention.

As shown in the figure, the scrubber 100 purifies noxious air generated from pollution facilities such as houses to reliably maintain the livestock and relieve complaints caused by odors as well as stress applied to the livestock.

The scrubber 100 includes a chamber 110 for purifying noxious air generated from a housing having a vertically communicated laminated structure, an exhaust unit 180 for supplying the purified air to the housing, and an exhaust unit for exhausting the noxious air and exhausting the purified air And a control unit 200 for managing the cleaning liquid.

The chamber 110 has a stable multi-layered structure with a narrower bottom and a plurality of windows 190 formed on at least one side thereof.

The window 190 is a transparent material made of acrylic or glass, and the window 190 is for allowing the daylight to illuminate the inside of the window 190 so that the cleaning liquid is exposed to daylight.

Here, the cleaning liquid is a liquid phase obtained by mixing a fluid (e.g., water) and microorganisms at predetermined ratios, and the microorganism is a mixture of photosynthetic bacteria, nitrifying bacteria, lactic acid bacteria, and yeast At least one or all of nitrifying bacteria, lactic acid bacteria and yeast bacteria is preferably combined with the photosynthetic bacteria in a predetermined ratio.

These microorganisms feed on ammonia, carbon dioxide, methane gas, and hydrogen sulfide, which are generated from the house, and call off the odor and produce sugar, oxygen, vitamins and physiologically active substances. Therefore, it makes the breeding environment pleasant and it helps the growth to lower the production cost.

Describing the role of each microorganism in detail,

Photosynthetic bacteria are essential microorganisms, and they can improve the livestock environment by rapid elimination of odor-inducing substances, antiviral substance secretion, antiviral control, photosynthesis and nutrient production.

Bacillus (Bacillus) is an excellent environment for the improvement of the housing environment and the decomposition of polymer organic matters such as proteins by suppressing harmful bacteria and eliminating bad odors, and it relieves larvae such as flies by kinase (enzyme) separation.

Lactic acid bacteria produce antiviral substances while lowering the acidity and eliminate the stench odor through the inhibition of the bacteria.

Yeast increases immunity to various diseases of livestock.

The nitrifying bacteria have an excellent effect for eliminating odors generated in the housing.

Such a microorganism uses a mixture of a fluid and a microorganism as a cleaning liquid, thereby facilitating corrosion, exposure or drainage treatment, and preventing environmental pollution.

Therefore, if the inside of the chamber is uniformly illuminated through the window 190, it is possible not only to quickly remove malodor due to photosynthetic bacteria, but also to control infections caused by viruses in the domestic animal, It is possible to expect an effect of improving the value of the product.

In addition, the window 190 allows the inside of the chamber 110 to be visually confirmed, so that, when an error or a malfunction occurs, the window 190 can cope promptly and provide a pleasant housing environment.

The chamber 110 includes a first chamber 120 through which the harmful air flowing through the housing is introduced and a first chamber 120 for cleaning the first chamber 120, and a harmful air purified in the first chamber 120 as a stacked communication structure. And a second chamber 130 for cleaning the second chamber 130. The first chamber 120 and the second chamber 130 are preferably arranged in the upper layer and the lower layer as shown in the figure, The first chamber 120 and the second chamber 130 will be described with reference to FIGS. 2 and 3. FIG.

FIG. 2 is a cross-sectional view illustrating a first chamber according to a preferred embodiment of the present invention, and FIG. 3 is a cross-sectional view illustrating a second chamber.

As shown in the figure, the first chamber 120 has an inlet port for supplying polluted air to one side and a first communication port 127 for communicating with the second chamber 130 on the other side. The inside of the first chamber 120 is divided into a plurality of compartments, A plurality of first partition walls 123 for forming a first flow path 125 of a predetermined shape, and a cleaning liquid for purifying harmful air is sprayed from above.

The inlet 121 is connected to the housing through the first duct 101. The first duct 101 is preferably a spiral duct connecting between the first chamber 120 and the housing, It is highly desirable that at least one duct filter (not shown) is present in the interior of the housing to filter out by-products of the housing (e.g., dust, etc.). The duct filter may be provided with a duct filter F in the first chamber inlet as well as the first duct.

The first partition wall 123 is formed to increase the contact time with respect to the first flow path 125 between the inlet 121 and the first communication hole 127 to increase the contact frequency with the cleaning liquid. As shown in the figure, the first partition wall 123 is formed by vertically alternating a plurality of plate materials with a predetermined interval therebetween so as to form a first flow path 125 of a zigzag shape.

7, the cleaning liquid is sprayed through the cleaning liquid supply unit 160. The cleaning liquid supply unit 160 includes a first supply pipe 163 for supplying the cleaning liquid to the first chamber 120, And a second supply pipe 167 for supplying a cleaning liquid to the chamber 130. The first supply pipe 163 is provided with a plurality of first nozzles 165 at regular intervals in the longitudinal direction and a second supply pipe 167 Are provided with a plurality of second nozzles 169 at regular intervals in the longitudinal direction.

Accordingly, the cleaning liquid sprayed into the first chamber 120 is sprayed through the plurality of first nozzles 165 spaced along the first supply pipe 163 to clean the noxious air passing through the first flow path 125 .

As shown in FIG. 3, the second chamber 130 is a housing having a predetermined cleaning liquid accommodated in the bottom thereof. The second chamber 130 has a second communication hole 137 formed at an upper portion thereof and an exhaust portion 180 at the other side thereof. And the inside is divided into a plurality of compartments through at least one second partition 131 between the second communication port 137 and the exhaust part 180.

2, the second communication opening 137 is a hole connected to the first communication opening 127 to introduce the noxious air cleaned in the first chamber 120, and the second communication opening 137 is communicated with the first communication hole 137, It is preferable to be hermetically connected to the sphere 127 by packing or the like.

The second partition wall 131 separates the interior of the second chamber 130 into a plurality of compartments and is spaced apart from the cleaning fluid filled in the first partition wall 131. The second partition wall 131 is disposed between the cleaning fluid and the second partition wall 131, (135).

This second partition 131 is formed by forming the second flow path 135 of the bottleneck structure so as to increase the cleaning efficiency by doubling the cleaning time of the noxious air with the cleaning time of the noxious air, So that the contact time with the cleaning liquid sprayed from the second nozzle 169 is doubled, and the harmful air is generated while passing through the second flow path 135 The cleaning liquid in the gaseous state delivered from the generation and disappearance of the bubbles is brought into active contact with the harmful air, thereby maximizing the cleaning efficiency of the harmful air.

Although the gap between the surface of the second flow path 135 and the end of the second partition 131 is not particularly limited, it is preferable to maximize the space of the air using the bottleneck phenomenon, And is preferably 5 to 30 mm.

When the distance between the second flow paths 135 is less than 5 mm, the second flow path 135 may be clogged by the cleaning liquid which generates the surface flow, thereby obstructing the smooth flow of the air. Since the surface flow effect is small, the second flow path 135 has a critical effect in the upper range since it does not greatly contribute to the improvement of the harmful air cleaning efficiency.

However, the height of the second flow path 135 is not limited and may be variable by a predetermined factor, which may be variable by the flow of the rinse fluid as shown in the second flow path 135, The flow is forced by the blower (not shown) and thus induces a variable situation of the second flow path 135.

This variable state may be larger or smaller than the second flow path 135, but the flow path does not close the flow path, but induces a vortex phenomenon of the harmful air.

Here, since the blower is generally used in a fluid circulating apparatus, a detailed description and a drawing are omitted, but brief description will be made. In general, the blower is disposed in a region where air is introduced or exhausted. Accordingly, in the present invention, the first duct 101 and the second duct 103 may be disposed in any one of the selected ducts.

The eddy current of the harmful air induces a sludge on the surface of the cleaning liquid, thereby doubling the friction between the harmful air and the cleaning liquid, thereby improving the cleaning power. At this time, the vortex phenomenon can be doubled depending on the air flow capacity of the blower, thereby improving the purification ability of the air.

The action of the vortex is as follows.

A flow is generated on the surface of the cleaning liquid due to the wind pressure generated when it is sucked from the blower, thereby generating air bubbles in the cleaning liquid, and generating and bubbling the generated air bubbles repeatedly generates fine gas in the form of water vapor. And the contact area between the harmful air and the cleaning liquid component is widened. Therefore, the harmful air is more purified and moved to the next compartment. The action of this vortex is repeated every time it passes through several compartments.

It is one of the characteristics of the present invention that the compartments of the present invention are configured to take advantage of such a vortex action.

The second partition wall 131 is provided with a vane 140 for maximizing the vortex phenomenon and maximizing the frequency of contact between the cleaning liquid and the harmful air. The description will be made with reference to FIGS. 4 and 5 .

FIG. 4 is a detailed view for explaining a wing according to a preferred embodiment of the present invention, and FIG. 5 is a sectional view for explaining vortex phenomenon in the second chamber.

As shown in the figure, the wing 140 is installed through a coupling hole 133 provided on the bottom of the second partition 131. The wing 140 includes a plate 141 and a plate 141 which are flexibly bent according to the wind direction, And a rotation shaft 143 provided between the first and second barrier ribs 131 and 131.

The plate 141 is preferably a flat plate made of resin or silicon, and is bent in the front, back, or right and left directions depending on the wind direction, as shown in the figure. At this time, it is preferable that the wind direction is generated by a blower installed in at least one of the first duct 101 and the second duct 103 shown in Fig. TiO ₂ in the form of powder is present in a dispersed state in the silicon material, and TiO ₂ has a large antimicrobial action with a large oxidizing power, and has a malodor removing and sterilizing action. In other words, the flexibility of silicon and the antibacterial property of TiO ₂ can be seen to have a synergistic effect. Silicon in which TiO ₂ is dispersed can be produced by a conventional method, so a detailed description of the production method is omitted.

The rotary shaft 143 is integrally formed with the plate 141 in one side and the other side is rotatably coupled through the coupling hole 133 and the bearing B or the like.

Since the rotary shaft 143 is rotatably coupled to the coupling hole 133, the rotary shaft 143 rotates in one direction or the opposite direction together with the plate 141 according to the amount of air to generate a vortex phenomenon of air, So as to improve the purification ability against harmful air.

Meanwhile, as shown in FIG. 1, the control unit 200 for managing the cleaning liquid, in addition to the suction of the harmful air and the exhaust of the purified air, includes switches and indicators that perform various functions as shown in FIG. 6, The description will be made with reference to Figs. 6 to 9.

FIG. 6 is a front view for explaining a control unit according to a preferred embodiment of the present invention, FIG. 7 is a detailed view for explaining an oxygen generator, FIG. 8 is a detailed view for explaining a temperature regulator, Fig. 5 is a detailed view for explaining the mixture supplier. Fig.

As shown in the figure, the control unit is provided with various operation switches and gauges for indicating operation states. For example, the control unit displays operation switches and operation states of a power indicator, an inverter digital controller and an oxygen supplier, an air conditioner, an internal circulation heater, There is a gauge.

When the oxygen generator is operated through the control unit 200, the oxygen generator 150 installed at one side of the chamber 110 operates as shown in FIG. 7 so that the oxygen is supplied to the first chamber 120 through the first supply unit 151, 2 supply unit 153 to supply oxygen to the second chamber 130.

Oxygen is supplied as a means to prevent microorganisms from being killed by microorganisms as well as to increase their activity.

As shown in FIG. 8, in addition to oxygen, a cleaning liquid temperature controller 170 for appropriately maintaining a cleaning liquid for preventing microorganisms from passing on the body is provided. The cleaning liquid temperature controller 170 is provided with a water temperature regulating refrigerator And a water temperature control heater, which are controlled by the control unit 200.

9, a predetermined fluid and microorganisms are mixed in the cleaning liquid supply unit 160 through the fluid supply unit 161 and the microorganism supply unit 162. As shown in FIG. 9, the cleaning liquid is a mixture of a fluid and microorganisms in a predetermined ratio, And the microorganisms are supplied through the microbial dispenser of the control unit 200. At this time, it is preferable that the microbial dispenser is provided with an air conditioner for preventing the microbes from being killed.

In addition, the controller 200 may further include an internal circulation heater. In addition, a switch for operating the ion generator and a gauge for checking the operation state for improving microbial mortality and optimal activity as well as improving the purification performance of the harmful air . At this time, although not shown, it is preferable that the ion generator is provided in a duct that supplies purified air as a house.

Here, since the internal circulation heater, the ion generator, and the like are generated by the conventional hot air fan, the description of the installation state and structure thereof and the drawing are omitted.

The cleaning solution mixed in the microbial supply part 162 is filled in the second chamber 130 and flows through the first supply pipe 163 to the lower part of the first chamber 120 and through the second supply pipe 167 The microorganism supply unit 162 and the first supply pipe 163 and the second supply pipe 167 are connected to each other through a conventional pump (not shown) .

Meanwhile, the noxious air supplied to the chamber 110 is rectified through the first chamber 120 and the second chamber 130, and then supplied as a house through the exhaust unit 180 as shown in FIG. 10, The description will be made with reference to Fig.

10 is a detailed view illustrating an exhaust unit according to a preferred embodiment of the present invention.

1, the exhaust unit 180 is provided at the end of the second chamber 130 to prevent the leakage of the cleaning liquid contained in the air when purified air from the chamber 110 is exhausted by the housing .

The exhaust unit 180 includes a first exhaust filter 181 through which purified air flows through the second chamber 130 and a second exhaust filter 183 provided between the first exhaust filter 181 and the exhaust port And a collecting unit 185 collecting the cleaning liquid filtered through the first exhaust filter 181 and the second exhaust filter 183.

As shown in the drawing, the first exhaust filter 181 is a plate having a plurality of perforations. The first exhaust filter 181 allows the purified air to be exhausted through the perforations, and the fluid contained in the air is filtered in a region other than the perforations.

The first exhaust filter 181 is formed with a plurality of perforations so as to smoothly exhaust the purified air.

The perforation is preferably a hole having a size suitable for exhausting, and it is very preferable that the hole is at least a millimeter (mm) or a centimeter (cm) size hole. This is to enable smooth exhaust of purified air through minimization of bottleneck phenomenon. If the perforation has a size smaller than that (for example, micrometer (占 퐉)), the air may not be smoothly exhausted, It will only be a hall.

A plurality of second exhaust filters 183 are provided at regular intervals to filter the remaining air pollutants such as dust and the like into the second duct 103 connected to the exhaust port 189, To the housing.

The cleaning liquid filtered through the second exhaust filter 183 is collected in the collecting part 185 through the plurality of collecting holes 187 provided between the second exhaust filter 183 and the exhaust port 189.

The collecting unit 185 is made of a slope so that the washing liquid collected through the collecting hole 187 is collected in the second chamber 130 as shown in FIG. (160).

Therefore, the cleaning liquid filtered by the second exhaust filter 183 is guided by the collecting part 185 made of a slope through the collecting hole 187 to be recycled into the second chamber, whereby the consumption of the cleaning liquid is reduced So that the continuity of the air purification operation can be maintained.

Hereinabove, the scrubber of the present invention has been described, and the method for purifying harmful gas using the scrubber of the present invention will be described below.

FIG. 11 is a flowchart illustrating a harmful air cleaning method using a scrubber according to a preferred embodiment of the present invention.

A method for cleaning harmful gas using a scrubber includes a first step of introducing harmful air into the first chamber, a second step of spraying a cleaning liquid to the harmful air introduced into the first chamber to perform first cleaning, A third step of introducing the cleaning liquid into the second chamber in which the cleaning liquid is received and the cleaning liquid contained in the second chamber, the fourth step of secondarily cleaning the noxious air by bringing the cleaning liquid accommodated in the second chamber into contact with the noxious air, And a fifth step of filtering and supplying the cleaning liquid to the housing.

The first step is to introduce the noxious air into the first chamber, the noxious air is generated from the housing, and the housing and the first chamber are connected through the duct.

The duct may be provided with a filter for blocking the inflow of dust or the like that enters together with the harmful air, and may further include a blower for forcing the inflow of the harmful air together with the filter.

In the second step, the harmful air is primarily purified through one side of the first chamber through the flow path through which the cleaning liquid is injected, while moving to the other side.

At this time, the first chamber is formed in a zigzag manner so that the flow time of the noxious air is doubled through the plurality of partition walls. Thus, the detoxifying ability is improved by increasing the contact frequency with the noxious air.

And, the harmful air in the first chamber flows into the second chamber through the third step, and the harmful air is forcedly induced by the blower.

Preferably, the blower is provided in at least one of a first duct connecting the first chamber and the housing, and a second duct connecting the second chamber and the housing.

The noxious air introduced into the second chamber is purified by a fourth step of secondarily cleaning the noxious air using the bottleneck phenomenon of the rinse liquid and the air.

The bottleneck phenomenon is generated by dividing the internal space of the second chamber into a plurality of compartments at regular intervals, which are generated by partition walls spaced apart from the cleaning liquid filled in the space, and more particularly, the harmful air narrows the flow path between the compartment and the compartment , The flow velocity is doubled, and harmful air passing through the flow path induces a variation of the flow path along with a sag on the surface of the cleaning liquid, thereby eventually causing eddy air passing through the flow path to generate a vortex phenomenon.

The vortex generates bubbles in the cleaning liquid, and the generated bubbles are repeatedly generated and extinguished to generate minute vapor in the form of water vapor, thereby collecting harmful substances contained in the harmful air to purify the harmful air.

This vortex was repeated each time it passed through a number of compartments to double the detergency of the noxious air. In addition, a plurality of nozzles for spraying a cleaning liquid are formed in each compartment so that harmful air can be purified through the spraying of the cleaning liquid as well as vortex action.

In addition, the first to fourth steps may further include a step of sunlighting the inside of the chamber, in order to increase the activity of the cleaning liquid containing the microorganisms, thereby further improving the cleaning ability.

In addition to sunlight, oxygen may be further injected into the chamber, and oxygen is present as a step for preventing the dead of live cells and for improving activity.

The fifth stage is a step of discharging the purified air from the chamber. The purified air supplied through the second duct connecting the exhaust section and the housing is re-supplied to the housing, and the purified air supplied to the housing is suppressed A heat exchanger or an ion generator, and the like.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. Therefore, the embodiments disclosed in the present invention are intended to illustrate rather than limit the scope of the present invention, 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 construed according to the following claims, and all technical ideas within the scope of equivalents should be construed as falling within the scope of the present invention.

100: scrubber 101: first duct
103: second duct 110: chamber
120: first chamber 121: inlet
123: first partition 125: first flow path
127: first communication port 130: second chamber
131: second partition 133: fastening hole
135: second flow path 137: second communication port
140: wing 141: plate
143: rotating shaft 150: oxygen generator
151: first supply part 153: second supply part
160: Cleaning liquid supply unit 161: Fluid supply unit
162: Microorganism supply unit 163: First supply pipe
165: first nozzle 167: second supply pipe
169: second nozzle 170: cleaning liquid temperature controller
180: exhaust part 181: first exhaust filter
183: second exhaust filter 185: collecting part
187: collecting hole 189: exhaust port
190: window 200: control unit

Claims (16)

In a wet scrubber,
A first chamber in which a cleaning liquid is sprayed from an upper portion and a noxious air is supplied from a contamination facility, a chamber including a cleaning fluid filled in an inner lower portion and a second chamber in which a cleaning fluid is sprayed from an upper portion;
An exhaust unit provided at the end of the second chamber for exhausting the cleaned air to be cleaned, wherein at least one filter is provided to block the leakage of the cleaning liquid; And
And a control unit for controlling the movement of the harmful air and the spraying of the cleaning liquid,
Wherein the first chamber and the second chamber have a laminated structure in which the inside is communicated,
Wherein the second chamber comprises:
A second communication port connected to the first chamber is formed on one side and the exhaust section is provided on the other side. At least one second partition is disposed in parallel to the upper portion of the inner wall at a predetermined interval, A channel is formed adjacent to the water surface,
The second barrier ribs
The wet scrubber of claim 1, further comprising a blade for inducing eddy currents of harmful air on a bottom surface facing the water surface. The method according to claim 1,
The chamber may comprise:
And a window formed on at least one side so that the daylight can illuminate the inside of the wet scrubber. The method according to claim 1,
The chamber may comprise:
An oxygen generator for supplying oxygen to each of the first chamber and the second chamber;
A temperature controller for controlling the temperature of the cleaning liquid; And
And a cleaning liquid supply unit for spraying the cleaning liquid into the first chamber and the second chamber, respectively. The method according to claim 1,
Wherein the first chamber comprises:
And a first communication port connected to the second chamber is formed on the other side. At least one first partition is alternately installed in the upper and lower portions of the inner wall, Wherein a flow path of a zigzag shape is formed. 5. The method of claim 4,
The first duct,
And a duct filter for filtering the foreign substances contained in the harmful air. delete delete The method according to claim 1,
The wing
A plate which flexibly flexes according to the wind direction; And
And a rotary shaft rotatably coupled to the second partition, the other side being connected to the plate, and the other side being rotatably coupled to the second partition. The method according to claim 1,
The cleaning liquid,
The wet scrubber of the multi-layer structure is characterized in that the fluid and the microorganism are mixed in a predetermined ratio. 10. The method of claim 9,
The micro-
A wet scrubber of a multi-layer structure, wherein the photosynthetic microorganism is a mixture of at least any one or all of Bacillus subtilis, nitrifying bacteria, lactic acid bacteria and yeast in a predetermined ratio. The method according to claim 1,
The exhaust unit includes:
A collecting part for collecting the washing liquid filtered through the filter; And
And exhaust air exhausted from the cleaned air and connected through the pollution facility and the second duct. 12. The method of claim 11,
The second duct
A fan device for forcing the scrubber to flow the fluid;
A temperature regulator for regulating the exhaust temperature of the purifying air; And
And an ion generator disposed in the wet scrubber. 12. The method of claim 11,
Wherein,
The one surface on which the cleaning liquid is collected is formed into a slope,
Wherein the slope is connected to the second chamber so that the cleaning liquid is collected in the second chamber. A wet scrubber of the multilayer structure according to any one of claims 1 to 5 and 8 to 13 is used,
A first step of causing harmful air to flow into the first chamber;
A second step of spraying a cleaning liquid to the noxious air introduced into the first chamber to perform first cleaning;
A third step of introducing the noxious air into the second chamber communicating with the first chamber and containing the cleaning liquid therein;
A fourth step of secondly cleaning the cleaning solution contained in the second chamber by contacting the harmful air with the cleaning solution; And
And a fifth step of filtering and discharging the cleaning liquid from the purified air that has been cleaned through the second chamber,
In the fourth step,
And generating a vortex on the water surface of the cleaning liquid. 15. The method of claim 14,
In the second and third steps,
Exposing the cleaning liquid to sunlight; And
And supplying oxygen to the cleaning liquid.
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