KR102283732B1 - Plasma generation unit for odor removal, odor removal device including plasma generation module, and odor removal device in poultry farms using the same - Google Patents

Abstract

The present invention relates to a plasma generation unit for removing odors, comprising: a frame installed in an exhaust passage through which a gas containing an odor component passes, and including a hollow in communication with the exhaust passage; a plurality of first electrodes installed across the hollow of the frame and spaced apart from each other by a set interval to be arranged in plurality; and a plurality of second electrodes installed across the hollow of the frame, arranged to cross an extension direction of the first electrodes respectively, and generating plasma for removing the odor component by power applied together in a state of being close to the first electrodes. According to the present invention, by arranging electrodes for corona discharge to cross each other, ozone and radicals generated through discharge are evenly generated in the exhaust passage, thereby dramatically increasing the ratio of ozone and radicals mixed with the odor.

Description

Plasma generation unit for odor removal, odor removal device including plasma generation module and poultry odor removal device using the same

The present invention relates to a plasma generating unit for removing odors, a malodor removing device including a plasma generating module, and a poultry farm odor removing device using the same, and more particularly, by stacking two electrodes for plasma generation in a crossed structure, When mixed with ozone or radicals generated by plasma, by increasing the mixing ratio, a plasma generating unit for odor removal that can improve odor removal efficiency, a odor removal device including a plasma generating module, and a poultry farm odor removal device using the same it's about

In livestock farms, a stench is generated along with a large amount of livestock waste. Unlike common air pollutants, these odors tend to directly affect the lives of nearby residents, and livestock waste treatment facilities are recognized as representative disgusting facilities.

For this reason, conventional water washing method, biological deodorization method, oxidation method, enzymatic decomposition method, adsorption method, masking method, combustion method, air dilution method and chemical treatment method have been used to remove the odor of livestock waste. A method to remove the is commercially available.

This plasma-based method is a method of decomposing odor components by generating ozone and reactive active species (radicals) with strong oxidizing power through corona discharge. It has the advantage that it can be applied to (Volatile Organic Compounds).

However, conventional apparatuses for removing odors using plasma have relatively low mixing efficiency of ozone and radicals with odor components, resulting in loss of odor reduction effect and cost loss.

Korean Patent Registration Publication No. 10-1178999

The present invention provides a odor removal plasma generating unit and plasma generating module for odor removal that can increase the mixing ratio of ozone and radicals generated through corona discharge with odor-causing components to increase the efficiency of a odor removal method using plasma An object of the present invention is to provide a device and a device for removing odors from poultry farms using the same.

In order to achieve this object, the present invention provides a frame installed in an exhaust passage through which a gas containing a malodorous component passes, and including a hollow in communication with the exhaust passage; Doedoe installed across the hollow of the frame, a plurality of first electrodes spaced apart from each other; And installed across the hollow of the frame, the first electrode and the extending direction are arranged to cross each other, the odor component by the power applied together with the first electrode in close or close contact with the first electrode Provided is a plasma generating unit for removing odors including second electrodes for generating plasma for removing odors.

According to another aspect of the present invention, there is provided a dust collector for collecting the gas containing the odor component to filter out foreign substances contained in the gas; a plasma generator comprising the plasma generating unit according to any one of claims 1 to 3, generating ozone and radicals through a plasma reaction to remove odor components of the gas from which foreign substances have been filtered by the dust collector; a blower that sucks in the gas containing the odor component and introduces it into the plasma generator through the dust collector; and a plasma generating module including a deodorizer that refracts the passage of the gas to increase the probability and time that the ozone and radicals react with the malodorous component.

According to another aspect of the present invention, the present invention, a dust collector for collecting the gas containing the odor component from the poultry manure treatment facility to filter out foreign substances contained in the gas; a plasma generator comprising the plasma generating unit according to any one of claims 1 to 3, generating ozone and radicals through a plasma reaction to remove odor components of the gas from which foreign substances have been filtered by the dust collector; a blower for sucking the gas containing the odor component from the chicken manure treatment facility and introducing it into the plasma generator through the dust collector; and a deodorizer that refracts the passage of the gas to increase the probability and time for the ozone and radicals to react with the malodor component.

According to the present invention, the following effects are obtained.

First, by arranging electrodes for corona discharge to cross each other so that ozone and radicals generated through discharge are evenly generated in the exhaust passage, the mixing ratio of ozone and radicals with components that cause odor can be dramatically increased. .

Second, by collecting the gas containing the odor component flowing into the plasma generator and collecting the dust in a filtered state, it is expected to improve the odor removal efficiency and extend the durability of the device.

Third, by sucking the gas containing the odor component through the blower and providing it to the plasma generator, it is possible to suppress the occurrence of dew condensation in the device due to humidity, thereby improving the odor removal efficiency.

Fourth, by refracting the flow path of the gas containing the odor component in the deodorizer to increase the probability and time that ozone and radicals react with the odor component, the flow rate is increased due to the installation of the blower, so ozone and radicals are mixed with the odor component. This decrease can be suppressed.

1 is a view showing the structure of a module in which a plasma generating unit and a plurality of units are stacked according to an embodiment of the present invention.
2 is a view showing the overall configuration of an odor removal apparatus in which a plasma generating module is installed according to another embodiment of the present invention.
3 is a view showing a detailed configuration of the dust collector of FIG. 2 .
4 is a view showing the detailed configuration of the plasma generator and the blower of FIG. 2 .
FIG. 5 is a view showing the flow of gas containing malodorous components formed by the deodorizer in the dust collector of FIG. 2 .
6 is a view showing the detailed configuration of the deodorizer of FIG.

1 shows a structure of a plasma generating unit 10 and a plasma generating module 20 formed by stacking a plurality of units according to an embodiment of the present invention.

Referring to FIG. 1A , the plasma generating unit 10 according to an embodiment of the present invention intersects plasma electrodes in order to increase the mixing ratio of ozone and radicals generated through corona discharge with the odor-causing component. It relates to a structure, comprising a frame (11), a first electrode (12) and a second electrode (13).

The frame 11 is a structure in which the two electrodes 12 and 13 are installed. The frame 11 is installed on an exhaust passage through which a gas containing an odor component passes, and includes a hollow communicating with the exhaust passage therein. Here, although not shown in the drawings, the frame 11 may be formed in a polygonal shape including a quadrangle, a circle shape, an arc shape, or an oval shape. In addition, as shown in FIG. 4 , it may have a structure installed in the exhaust flow path to support the electrodes 12 and 13 , but may be a structure formed as a part of the exhaust flow path.

The first electrode 12 is formed in a columnar or polygonal column shape and installed across the hollow of the frame 11 described above, and is disposed in a plurality of spaced apart from each other by a set interval along the width direction of the hollow.

The second electrode 13 is formed in a cylindrical or polygonal column shape and is installed across the hollow of the frame 11 in the same way as the first electrode 12 , and is disposed so that the first electrode 12 and the extending direction intersect each other. do. At this time, the second electrode 13 and the first electrode 12 may be in a state in which the intersecting portions are adjacent to or in close contact with each other, and power is applied to the first electrode 12 and the second electrode 13 to prevent odor components. Plasma is created to remove

Here, as shown in the drawings, the first electrode 12 and the second electrode 13 may be disposed in a structure in which the two electrodes 12 and 13 are formed in the same shape and are orthogonal to each other, but the technical aspect of the present invention The idea is not limited thereto, and it goes without saying that the two electrodes 12 and 13 may be formed in different shapes and disposed in different structures. For example, the first electrode 12 may have a cylindrical shape and the second electrode 13 may have a polygonal prism shape and may be disposed in a structure that intersects each other in an oblique direction (acute angle and an obtuse angle appear), and the first electrode (12) and a portion of the second electrode 13 are bent, respectively, to be formed in a structure in which the bent portions enter each between the first electrodes 12 and the second electrodes 13 arranged at a set interval in opposite directions. can In other words, the cross structure of the first electrode 12 and the second electrode 13 according to an embodiment of the present invention only exemplifies the simplest structure for the convenience of manufacturing and installation, and It goes without saying that any structure in which ozone and radicals due to corona discharge are evenly generated in the exhaust flow path across the direction transverse to the traveling direction may be included in the technical idea of the present invention.

Referring to FIG. 1B , the above-described plasma generating units may be stacked in a thickness direction to form a module 20 . To this end, a plurality of through-holes for coupling the plurality of plasma generating units 10 are formed on the upper and lower surfaces of the frame 11 in the thickness direction, and on the side surface for coupling of the plurality of plasma generating units 10 . Through-holes for installation of the plasma generating unit 10 are formed as well as for use. A plurality of plasma generating units 10 of the present invention may be stacked in series so that the removal efficiency of the odor component is improved by mixing ozone and radicals contained in the gas a plurality of times according to the plasma reaction (FIG. 1). (refer to (b)), in order to process a large amount of odor components, a plurality of them may be arranged in parallel. As described above, the plurality of adjacent plasma units and frames 11 may be coupled to each other, but may be in close contact with each other.

In addition, the plasma generating unit 10 and the plasma generating module 20 of the present invention may be used for odor removal as well as for wastewater treatment.

Hereinafter, the malodor removal apparatus 100 in which the plasma generating module 20 is installed according to another embodiment of the present invention will be described in detail with reference to FIGS. 2 to 6 . However, content overlapping with the above will be omitted or abbreviated.

Referring to FIG. 2 , the malodor removal apparatus 100 according to another embodiment of the present invention includes the above-described plasma generating module 20 to remove odors generated from poultry manure. To this end, the odor removal device 100 of the present invention includes a dust collector 110 , a first pipe 120 , a plasma generator 130 , a blower 140 , a second pipe 150 , a third pipe 160 , It includes a deodorizer 170 and a controller 180 . With the driving force of the blower 140 controlled by the controller 180, the gas containing the odor component of the poultry chicken poultry is collected and filtered through the dust collector 110, and the odor component is removed through the plasma generator 130. Ozone and radicals are generated and mixed, and the mixing probability and time are increased through the deodorizer 170 to enable more efficient odor removal.

However, the malodor removal device 100 of the present invention is only described on the assumption that it removes the odor of poultry chicken for convenience of explanation, and is not limited thereto. Of course, it can be used.

2 and 3, the dust collector 110 is to filter foreign substances by collecting the gas containing the odor component generated from the poultry manure processing facility, the dust collection chamber 111, the suction port 112, the bag filter ( 113 ), a diaphragm pump 114 , a pressure tank 115 , a differential pressure gauge 116 and a rotary valve 117 .

The dust collection chamber 111 is connected to the poultry manure treatment facility in the poultry farm on the side, and an inlet 112 through which the gas containing the odor component is introduced is formed, and a bag filter 113 for filtering the gas containing the odor component inside is formed. ) is installed, and a rotary valve 117 for discharging foreign substances including sludge is installed at the lower part. At this time, the dust collecting chamber 111 is formed in a structure in which the path becomes narrower toward the lower portion toward the rotary valve 117 . A bag filter (113, bag filter) is a mechanical facility that desorbs and collects foreign substances such as dust contained in exhaust gas using a filter bag. 111) is installed extending from the upper part to the lower part. The diaphragm pump 114 is installed above the dust collection chamber 111 and sprays the compressed air supplied from the pressure tank 115 to the filter bag described above to drop foreign substances including sludge attached to the filter bags. At this time, a differential pressure gauge 116 is formed in the dust collecting chamber 111 to determine the replacement cycle of the filter bag, and the durability of the filter bag is determined through a pressure change in the chamber 111 . Thereafter, the condensed liquid in the chamber formed by the fallen foreign matter and the condensation moves to the lower part of the chamber 111 and is discharged out of the chamber through opening and closing of the rotary valve 117 . Here, the configurations and functions of the bag filter 113 , the diaphragm pump 114 , and the rotary valve 117 are the same as those already known, and thus detailed descriptions thereof will be omitted.

Referring to FIGS. 2 and 4 , the gas containing the odor component from which foreign substances have been filtered through the dust collector 110 is supplied to the plasma generator 130 through the first pipe 120 , and the plasma generator 130 is Ozone and radicals are generated in the gas containing the odor component by using the plasma generating modules 131 composed of one plasma generating unit 10 . Here, the detailed configuration of the plasma generating module 131 is replaced with the contents of FIG. 1 described above, and the plasma generating module 131 is disposed at a position close to the rear end of the first pipe 120 , and the first pipe 120 . Plasma is preemptively supplied to the gas containing the odor component supplied from Thereafter, the gas containing the odor component in which ozone and radicals are mixed is supplied to the deodorizer 170 through the second pipe 150 . However, in order to increase the mixing ratio of ozone and radicals and odor components, it has a cylindrical shape with an empty inside at a position close to the second pipe 150 , that is, at the rear end of the flow path formed in the plasma generator 130 , and has a plurality of minutes along the circumferential surface. The air injection unit 132 in which the perforations 132a are formed is formed in a direction that crosses the flow path of the gas. Accordingly, air is injected into the gas containing the odor component mixed with ozone and radicals to form a vortex in the space, thereby dramatically increasing the mixing ratio. However, the above-described air injection unit 132 may be selectively manually operated by a user according to the flow rate of the gas containing the odor component or the concentration of the odor component, and various types of measuring the flow rate of the gas and the concentration of the odor component Of course, it can be automatically operated in conjunction with the sensor.

The driving operation of the plasma generating module 131 and the driving operation of the air spraying unit 132 are controlled by the controller 180, and each plasma generating unit 10 of the plasma generating module 131 includes a part and the remaining part, Alternatively, it is possible to prevent overheating of the plasma generating module 131 by being divided into a plurality of groups, such as a part and a part, and alternately operated.

The blower 140 provides suction and blowing power by the rotation of the blower fan so that the gas containing the odor component is delivered from the poultry poultry processing facility through the dust collector 110 through the plasma generator 130 to the deodorizer 170 . To provide, it is installed on the second pipe (150). Since the gas containing the odor component delivered from the poultry manure treatment facility contains a large amount of moisture in nature, when the flow rate of the delivered gas is slow, there is a problem in that the plasma generation efficiency is reduced due to the generation of dew condensation. Accordingly, the odor removal apparatus 100 of the present invention maintains the flow rate of the gas at an appropriate level using the driving force of the blower 140 , thereby suppressing the generation of dew and maintaining the plasma generation efficiency intact.

Referring to FIGS. 2 and 5 , as described above, the gas containing the odor component supplied and delivered into the odor removal device 100 is supplied from the dust collector 110 to the first pipe ( It is supplied to the plasma generator 130 through 120 , and is transferred back to the deodorizer 170 through the second pipe 150 . At this time, the first pipe 120 and the second pipe 150 are connected to the third pipe 160 and the second pipe 150 connected to the rear end of the plasma generator 130 contains ozone and odor components mixed with radicals. The gas flow rate can be adjusted through the third pipe 160 . Specifically, when the ozone and radical mixing ratio of the gas delivered through the second pipe 150 is lower than the appropriate value, or the mixing ratio is close to the appropriate value, but the mixing time is short, that is, when the odor removal efficiency does not reach it, Part of the mixed gas of the second pipe 150 may be supplied to the first pipe 120 to re-enter the process of mixing ozone and radicals of the plasma generator 130 . To this end, a first valve 151 and a second valve 161 provided as a butterfly valve are further installed in the second pipe 150 and the third pipe 160 , respectively, so that the second pipe 150 is mixed. A part of the gas may be re-entered into the first pipe 120 , or all of the gas may be delivered to the deodorizer 170 .

Referring to FIGS. 2 and 6 , the deodorizer 170 connected to the rear end of the second pipe 150 refracts the exhaust path of the gas containing the odor component mixed with ozone and radicals multiple times, so that ozone and radicals are odor components Increases the chance and time to react. To this end, the deodorizer 170 includes a pawling 171 , an exhaust port 172 , and a drain port 173 .

The palling (171, palling) is made of synthetic resin or SUS material, and has several hollows inside to refract the moving direction of the gas several times without greatly hindering the progress of the gas. As the polling 171 is filled in a constant or random arrangement, the gas containing the odor component mixed with ozone and radicals transmitted from the second pipe 150 connected to the lower part of the deodorizer 170 is converted into a plurality of pollings 171 . ), the reaction probability and reaction time are greatly increased, thereby greatly improving the odor removal efficiency.

As described above, in the malodor removal process of the present invention, the gas containing the odor component is transferred by using the suction power and the blowing power of the blower 140 to prevent dew condensation in the device. The probability and time to react with the component can be lowered. Accordingly, it is possible to compensate for halving the malodor removal efficiency by using the blower 140 by refracting the path of the mixed gas in the deodorizer 170 using the pawlings 171 several times.

In addition, when ozone and radicals in the deodorizer 170 _{react with odor components including H 2} S and NH ₃ and are changed to water vapor, they are discharged to the outside through the exhaust port 172, and the water vapor is condensed to form water. If necessary, it is discharged to the outside through the drain hole 173 installed in the lower part.

Although the present invention has been described with reference to the embodiments shown in the drawings, which are merely exemplary, those skilled in the art will understand that various modifications and equivalent other embodiments are possible therefrom. Accordingly, the true technical protection scope of the present invention should be determined by the technical spirit of the appended claims.

10: plasma generating unit
11: frame 12: first electrode
13: second electrode 20: plasma generating module
100: odor removal device
110: dust collector 111: dust collection chamber
112: inlet 113: bag filter
114 diaphragm pump 115 pressure tank
116: differential pressure gauge 117: rotary valve
120: first pipe 130: plasma generator
131: plasma generating module 132: air injection unit
132a: injection hole 140: blower
150: second pipe 151: first valve
160: third pipe 161: second valve
170: deodorizer 171: polling (palling)
172: exhaust port 173: drain port
180: controller

Claims (14)

a dust collector for collecting a gas containing an odor component generated in a waste treatment facility and filtering out foreign substances contained in the gas;
A frame is installed in the exhaust passage through which the gas containing the odor component passes, and a frame including a hollow communicating with the exhaust passage, and a plurality of first installed across the hollow of the frame and spaced apart from each other by a set interval Electrodes, installed across the hollow of the frame, disposed so that the first electrode and the extending direction cross each other, and in close or close contact with the first electrode by power applied together with the first electrode Plasma generator for generating a plurality of plasma generating units including second electrodes for generating plasma are disposed along the exhaust flow path, thereby generating ozone and radicals through a plasma reaction to remove odor components of the gas from which foreign substances are filtered by the dust collector ;
It is disposed in the rear of the plasma generator in the exhaust passage, is disposed in a position close to the plasma generator, sucks the gas containing the odor component and introduces it into the plasma generator through the dust collector, the odor component is included a blower for introducing the gas containing the odor component at a flow rate or higher so that moisture contained in the gas does not condense; and
By refracting the flow path of the gas and lowering the flow rate of the gas containing the odor component moving at the flow rate set by the blower below the set flow rate, the probability and time that the ozone and radicals react with the odor component increases It includes a deodorizer that allows
The deodorizer,
It is formed in a structure including a plurality of hollows penetrating through the body, and is filled in a predetermined or random arrangement to refract the movement path of the gas containing the odor component a plurality of times.
A first pipe connecting the dust collector and the plasma generator to form an inflow path of the gas containing the odor component from which the foreign matter is filtered between the dust collector and the plasma generator, the plasma generator, the blower and the deodorizer A second pipe for forming a mixing path of the ozone and radicals and the gas containing the odor component between the plasma generator and the deodorizer by sequentially connecting the second pipe, and the second pipe and the first pipe, By re-entering a portion of the gas in the mixing path into the inflow path, a third pipe that increases the mixing ratio of the ozone and radical with the gas containing the odor component of the second pipe is further included,
The third pipe,
and a second valve of a butterfly valve installed at a connection portion with the second pipe to re-enter a part of the gas of the mixing path formed by the second pipe into the inflow path formed by the first pipe,
The plasma generator,
A plurality of extensions are formed in a direction transverse to the traveling direction of the gas containing the odor component, and by spraying air in the opposite direction to the traveling direction, the ozone and radicals that have passed through the plasma generating unit and the mixing ratio of the odor component are increased. A malodor removal device comprising an air jet to be enhanced by a vortex. The method according to claim 1,
The plasma generating unit,
A malodor removal apparatus in which adjacent plasma generating units and the frames are in close contact with each other or in a modular structure in which the frames are coupled to each other. The method according to claim 1,
The frame is
Polygonal, circular, arc-shaped, or oval-shaped odor removal devices. delete The method according to claim 1,
The dust collector,
A malodor removal device including a plasma generating module including a bag filter coated with a catalyst in order to filter the gas containing the odor component collected therein. 6. The method of claim 5,
The dust collector,
A malodor removal apparatus including a plasma generating module including a diaphragm pump for ejecting the foreign substances from the bag filter by spraying compressed air to the foreign substances attached to the bag filter. 6. The method of claim 5,
The dust collector,
In order to determine a replacement cycle of the bag filter due to the attachment of foreign substances, the apparatus for removing odors including a plasma generating module including a differential pressure gauge for measuring pressure loss inside and outside the bag filter. 6. The method of claim 5,
The dust collector,
A malodor removal device including a plasma generating module including a rotary valve at a lower portion for discharging a condensed liquid generated by the condensed liquid and foreign substances dropped from the bag filter. delete delete delete delete The method according to claim 1,
Further comprising a controller for controlling the driving operation of the plasma generator,
The plasma generator,
A plurality of the plasma generating units are disposed along the exhaust passage, and the adjacent plasma generating units and the frames are arranged in close contact with each other or the frames are coupled to each other to form a modular structure,
The controller is
A malodor removal apparatus including a plasma generating module for sequentially or selectively driving some of the plasma generating units and other parts. a dust collector for collecting the gas containing the odor component from the poultry manure treatment facility to filter out foreign substances contained in the gas;
A frame is installed in the exhaust passage through which the gas containing the odor component passes, and a frame including a hollow communicating with the exhaust passage, and a plurality of first installed across the hollow of the frame and spaced apart from each other by a set interval Electrodes, installed across the hollow of the frame, disposed so that the first electrode and the extending direction cross each other, and in close or close contact with the first electrode by power applied together with the first electrode Plasma generator for generating a plurality of plasma generating units including second electrodes for generating plasma are disposed along the exhaust flow path, thereby generating ozone and radicals through a plasma reaction to remove odor components of the gas from which foreign substances are filtered by the dust collector ;
In the exhaust passage, the gas containing the odor component is sucked from the rear of the plasma generator and introduced into the plasma generator through the dust collector, so that the moisture contained in the gas containing the odor component does not condense. a blower for introducing the contained gas at a flow rate or higher; and
By refracting the flow path of the gas and lowering the flow rate of the gas containing the odor component moving at the flow rate set by the blower below the set flow rate, the probability and time that the ozone and radicals react with the odor component increases It includes a deodorizer that allows
The deodorizer,
It is formed in a structure including a plurality of hollows penetrating through the body, and is filled in a predetermined or random arrangement to refract the movement path of the gas containing the odor component a plurality of times.
A first pipe connecting the dust collector and the plasma generator to form an inflow path of the gas containing the odor component from which the foreign matter is filtered between the dust collector and the plasma generator, the plasma generator, the blower and the deodorizer A second pipe for forming a mixing path of the ozone and radicals and the gas containing the odor component between the plasma generator and the deodorizer by sequentially connecting the second pipe, and the second pipe and the first pipe, By re-entering a portion of the gas in the mixing path into the inflow path, a third pipe that increases the mixing ratio of the ozone and radical with the gas containing the odor component of the second pipe is further included,
The third pipe,
and a second valve of a butterfly valve installed at a connection portion with the second pipe to re-enter a part of the gas of the mixing path formed by the second pipe into the inflow path formed by the first pipe,
The plasma generator,
A plurality of extensions are formed in a direction transverse to the traveling direction of the gas containing the odor component, and by spraying air in the opposite direction to the traveling direction, the ozone and radicals that have passed through the plasma generating unit and the mixing ratio of the odor component are increased. A malodor removal device comprising an air jet to be enhanced by a vortex.

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