KR20140107807A - Harmful gases purifying device - Google Patents

Abstract

The present invention relates to a harmful gas purifier, which has each components arranged in a vertical direction so that a high temperature gas mixture can be purified while naturally moving upward without a separate transport device; can stably purify harmful gas by a corona reaction and a catalyst reaction; and can enhance the purification efficiency against harmful gas by minimizing a corona unreacted zone without hindering the movement of the gas mixture. The harmful gas purifier comprises an inlet port allowing a gas mixture with harmful gas to flow in; a corona decomposition unit installed above the inlet port and firstly removing harmful gas by corona discharge with the gas mixture supplied form the inlet port; a catalyst oxidation unit installed above the corona decomposition unit, and secondly removing harmful gas with the gas mixture supplied from the corona decomposition unit, in which harmful gas has firstly removed, and the activation energy due to the corona discharge delivered from the corona decomposition unit; and a discharge unit installed above the catalyst oxidation unit and discharging the gas mixture to outside from the catalyst oxidation unit, in which harmful gas has secondly removed.

Description

{Harmful gas purifying device}

The present invention relates to a harmful gas purifier, and more particularly, to a harmful gas purifier which is arranged in a vertical direction so that a high-temperature mixed gas can be smoothly moved upward without a separate transfer device, The present invention relates to a harmful gas purifying apparatus capable of stably purifying harmful gas by minimizing the corona unreacted zone without inhibiting the movement of the mixed gas and thereby increasing the harmful gas purifying efficiency.

As the use of organic solvents increases, harmful gases such as volatile organic compounds (VOCs) or odorous gases are inevitably generated in various production processes and environmental industries such as waste treatment, painting process and water treatment.

As a method for removing such noxious gases, there are combustion method, adsorption using activated carbon, microbial filtration, etc. Among them, the combustion method causes the initial cost of the facility to be excessively generated and the maintenance cost to be high, And the adsorption method using activated carbon is disadvantageous in that it takes a lot of cost to recover the solvent and the efficiency is low when it is applied for a long time. In the biological treatment method by microbial filtration, when the microorganism grows excessively, And the concentration of the microorganisms can not be kept constant.

In order to solve this problem, a corona discharge method using a high voltage has been used. Corona discharge refers to a phenomenon in which electric discharge occurs at a certain threshold or higher by raising the voltage between two electrodes that are insulated from each other. By discharging the electric current to the noxious gas component and capturing the noxious gas component on the outer wall of the discharge part, .

However, in the conventional noxious gas purifying apparatus using the corona discharge, the flow of the mixed gas containing the noxious gas is transversely formed as in Korean Patent Laid-open No. 10-2001-0068436, And the corona discharge has a circular corona generation region around the corona discharge unit. As shown in FIG. 7, in the plate type reaction as described above, The corona unreacted zone 10 is generated and the mixed gas passing through the corona unreacted zone 10 has a problem that the harmful gas is not properly purified.

In order to solve this problem, a cylindrical cylinder is provided for each corona discharger so as to cover the corona generation region of the corona discharge machine. By injecting a mixed gas into the cylindrical cylinder, all the mixed gas without corona unreacted zone is corona- However, in such a cylindrical reactor, there is a limit in the flow rate passing through the inside of the cylinder. Therefore, there is a problem that it is difficult to apply to a field requiring a large amount of treatment. To solve this problem, in order to increase the number of cylinders There is a problem that a wider installation area is required compared with the plate type reaction furnace.

Therefore, it has become necessary to develop a harmful gas purifying apparatus capable of minimizing the corona unreacted zone, which can be applied to a large-capacity system by easily securing the flow rate with a small installation area.

Korean Patent Laid-Open No. 10-2001-0068436 (Publication No.) 2001.07.23

It is an object of the present invention to provide a harmful gas purifying apparatus which is arranged in a vertical direction so that a high-temperature mixed gas can be smoothly moved upward without a separate transfer device and purified.

It is another object of the present invention to provide a harmful gas purifying apparatus capable of stably purifying harmful gas by corona reaction and catalytic reaction.

It is another object of the present invention to provide a harmful gas purifying apparatus capable of minimizing the corona unreacted zone while preventing the movement of the mixed gas, thereby increasing the harmful gas purifying efficiency.

The present invention relates to a harmful gas purifying apparatus for removing a harmful gas comprising a volatile organic compound or a malodorous gas, comprising: an inlet through which a mixed gas containing the harmful gas flows; A corona decomposing unit provided at an upper portion of the inflow portion to receive the mixed gas from the inflow portion and to discharge a corona discharge to remove the noxious gas first; A catalyst which is provided at an upper part of the corona decomposition part to receive the mixed gas from which the noxious gas is firstly removed from the corona decomposition part and receives the activation energy by the corona discharge from the corona decomposition part to remove the noxious gas secondarily, Oxidized portion; And a discharge unit provided at an upper portion of the catalytic oxidizing unit to receive the mixed gas from which the harmful gas is secondarily removed from the catalytic oxidizing unit and to discharge the mixed gas to the outside; Wherein the corona decomposition unit comprises: an upper housing; A dust collecting part provided at a lower portion of the upper housing; A lower housing provided at a lower portion of the dust collecting portion; And a plurality of discharge devices connected to the high voltage application device and extending downward from the high voltage application device to perform corona discharge using power supplied from the high voltage application device, And an upper insulating portion and a lower insulating portion that are respectively provided in the housing and support upper and lower portions of the discharger so that the discharger is electrically insulated from the upper housing, the lower housing, and the dust collecting portion. Wherein the dust collecting unit includes two bending plates spaced apart from each other; And two side plates connecting the ends of the two bending plates, wherein the bending plate is folded so as to have a folding line in a vertical direction so as to form an indentation at an equal interval inward, And the discharge unit is located at the center of a hollow portion of a regular polygon included as a vertex.

Further, in the dust collecting part of the present invention, the hollow portion is formed in a regular octagonal shape so that adjacent hollow portions communicate with each other, and the catalytic oxidizing portion includes a lattice-shaped receiving portion, a catalyst placed on the receiving portion, And the like.

The inlet portion of the present invention may further comprise an inlet pipe through which the mixed gas flows, a plurality of branch pipes branched from the inlet pipe and communicating with the lower housing of the corona decomposition portion, And a sensor unit for measuring a concentration or a flow rate of the gas, wherein an output value of the high voltage applying unit is varied according to an output value of the sensor unit.

Further, the inflow section of the present invention comprises a flow rate regulating device provided at a branch point of the branch pipe from the inflow pipe, and a flow rate sensor provided inside the branch pipe, The opening amount of the flow rate regulating device is varied.

According to the present invention, since the inlet portion 100, the corona decomposing portion 200, the catalytic oxidizing portion 300, and the discharge portion 400 are arranged in the vertical direction, the high-temperature mixed gas can smoothly move upward without a separate transfer device And can be purified.

Furthermore, the present invention has the effect that the noxious gas is primarily purified from the corona decomposition section 200, and is secondarily purified by the catalytic oxidation section 300 to purify the noxious gas stably.

The dust collecting unit 220 of the corona decomposing unit 200 is folded in multiple folds so as to surround a hollow portion communicating on a regular polygonal shape so that the corona non- (10) can be minimized and the harmful gas purification efficiency can be increased.

1 is a sectional view of a harmful gas purifying apparatus according to an embodiment of the present invention;
2 is a side view of a harmful gas purifying apparatus according to an embodiment of the present invention;
3 is a plan view of a corona disassembly portion of a harmful gas purifier according to an embodiment of the present invention.
4 is a partial cutaway front view of a catalytic oxidizing part of a harmful gas purifying apparatus according to an embodiment of the present invention;
5 is a plan view of a catalytic oxidation part of a harmful gas purifier according to an embodiment of the present invention.
6 is a sectional view of an inlet of a harmful gas purifier according to an embodiment of the present invention;
7 is a plan view of a conventional dust collecting part.

Hereinafter, a harmful gas purifying apparatus according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

FIG. 1 is a sectional view of a harmful gas purifying apparatus according to an embodiment of the present invention, FIG. 2 is a side view of a harmful gas purifying apparatus according to an embodiment of the present invention, and FIG. 3 is a cross sectional view of a harmful gas purifying apparatus according to an embodiment of the present invention. FIG. 5 is a plan view of the catalytic oxidizing part of the apparatus for purifying noxious gas according to the embodiment of the present invention. FIG. 5 is a plan view of the catalytic oxidizing part of the apparatus for purifying noxious gas according to the embodiment of the present invention FIG. 6 is a cross-sectional view of an inlet of the harmful gas purifier according to the embodiment of the present invention, and FIG. 7 is a plan view of a conventional dust collector.

1 to 6, the present invention relates to an inflow section 100 for introducing a mixed gas in which a harmful gas composed of a volatile organic compound and an odorous gas is introduced, and an inflow section 100 provided at an upper part of the inflow section 100, The corona decomposition unit 200 is provided at the upper part of the corona decomposition unit 200 to remove harmful gas from the corona decomposition unit 200 and remove the harmful gas from the corona decomposition unit 200. [ A catalytic oxidizing unit 300 for removing harmful gas from the corona decomposing unit 200 by the activation energy generated by the corona discharge and a catalytic oxidizing unit 300 disposed above the catalytic oxidizing unit 300, And a discharge unit 400 for receiving the mixed gas from which the harmful gas is secondarily removed from the unit 300 and discharging the mixture gas to the outside.

The inlet 100 serves to supply a mixed gas in which a harmful gas such as volatile organic compounds (VOCs) or odorous gas is mixed from the outside to the corona decomposing unit 200, And a branch pipe 120 branched from the inflow pipe 110 and connected to the lower housing 230 of the corona decomposing unit 200. [

The inlet pipe 110 is in the form of a pipe, one end connected to an external mixed gas supply source, and the other end branched to extend to each branch pipe 120. A sensor unit 130 such as a flow rate sensor or a concentration sensor is provided in the inlet pipe 110 to adjust the amount of the mixed gas flowing through the flow rate sensor, The output value of the high voltage applying unit 241 can be adjusted by applying the output value of the flow rate sensor and the output value of the concentration sensor in combination.

The branch pipe 120 is formed of a plurality of pipes branched from the other end of the inlet pipe 110 and connected to the lower housing 230 of the corona decomposition unit 200. In the embodiment of the present invention, However, it is also possible that three or more corona decomposing units 200 are provided in parallel.

When the mixed gas introduced into the inlet pipe 110 is directly supplied to the corona decomposing unit 200, the supply amount of the mixed gas applied to the respective positions of the corona decomposing unit 200 may be increased Therefore, it is possible to provide a uniformly mixed gas to the corona decomposition unit 200. For this purpose, the branch pipe 120 is provided with a flow rate sensor 131 in each branch pipe 120 A flow rate regulating device 140 is provided at the other end of the inflow pipe 110, that is, at a branch point of the branch pipe 120 from the inflow pipe 110, and the flow rate sensor 131 ) Of the flow rate regulating device 140 are matched with each other. In this case, the flow rate regulator 140 has a flow rate regulating device 140 installed at the other end of the inflow pipe 110. However, when the flow rate regulator 140 is installed at the inlet of each branch pipe 120, Respectively.

When the flow sensor 131 is provided in each of the branch pipes 120 as described above, only the concentration sensor is provided in the inlet pipe 110 so that the output value of the flow sensor 131 of the branch pipe 120 and the output value of the inlet pipe 110 can be mutually combined to vary the output value of the high voltage applying device 241. [

The corona decomposition unit 200 receives the mixed gas from the inlet unit 100 and primarily removes harmful gas from the mixed gas and supplies the same to the catalyst oxidizing unit 300. To this end, A lower housing 210 provided at a lower portion of the dust collecting unit 220 and connected to the inlet 100 in communication with the upper housing 210, And a corona discharging unit 240 disposed in an inner hollow portion formed by coupling the upper housing 210, the dust collecting unit 220 and the lower housing 230 to perform corona discharge to remove noxious gas .

The upper housing 210 is connected to the lower end of the catalytic oxidizing unit 300 and is connected to the catalytic oxidizing unit 300 so as to supply a mixed gas of which the noxious gas is first purified, A high voltage applying device 241 and an upper insulating portion 243 of the corona discharging portion 240 are provided. The dust collecting unit 220 is connected to the lower end of the upper housing 210 and the mixed gas raised from the dust collecting unit 220 is supplied to the upper housing 210 through the high voltage applying unit 241, And is uniformly supplied to the upper catalytic oxidizing unit 300.

The dust collecting unit 220 is connected to the lower end of the upper housing 210 and communicates with the upper end of the lower housing 230. The discharging unit 242 of the corona discharging unit 240 is provided in the inner hollow part, The mixed gas supplied from the discharge tube 230 can be primarily purified by the discharge unit 242 of the corona discharge unit 240 and moved to the upper housing 210.

The dust collecting unit 220 includes two bending plates 221 spaced apart from each other and two side plates 222 connecting between both ends of the two bending plates 221 to form a hollow portion therein, (221) is multi-folded so as to have a folding line in the vertical direction to form a depression (224) at an equal interval inward. At this time, the depressed portions 224 of the two bending plates 221 are formed at the same positions to face each other, and a hollow portion 223 having a regular polygonal shape including the depressions 224 as the apexes is continuously formed inside Respectively.

In more detail, the folding plate 221 is formed by bending a plate-shaped panel. The wedge-shaped depressed portion 224 has a shape formed at an equal interval inward when viewed from a plan view. That is, the starting point at which the depression 224 starts, the tip of the depression 224, and the end point at which the depression 224 ends are the fold lines of the fold plate 221, . The bending plate 221 is disposed so that the two bending plates 221 are opposed to each other and are spaced apart from each other. Therefore, the starting point, the leading end, and the ending point of the depressed portion 224 of one bending plate 221, When the starting point, the tip end, and the end point of the depressed portion 224 of one bending plate 221 are beyond the regular polygonal shape.

The reason for forming the depression 224 is due to the corona generation region formed by the discharge unit 242 of the corona discharge unit 240 and the corona formed by the discharge unit 242 is centered on the discharge unit 242 And has a circular generation region. When the folding plate 221 of the dust collecting unit 220 is formed as a flat plate, a plurality of discharge units 242 are arranged in the dust collecting unit 220 at equal intervals. In this case, The reaction zone 10 is generated, and the mixed gas passing through the corona non-reaction zone 10 is prevented from being purified. Therefore, in order to minimize the corona unreacted zone 10, the depression 224 is formed in the bending plate 221 so as to surround the corona generation region.

At this time, in order to completely cover the corona generation region, the bending plate 221 is formed into a cylindrical shape and must be applied individually to each of the discharge units 242. In this case, the flow of the mixed gas is not smooth and it can not be applied to a large capacity system. Accordingly, the corona generation region can be appropriately covered and the depressions 224 are formed so that the hollow portions 223 surrounding the respective discharge units 242 are communicated with each other so as not to interfere with the flow of the mixed gas.

That is, the shape of the hollow portion 223 surrounding the discharger 242 is a regular polygonal shape, and the hollow portion 223 having a regular polygonal shape is formed in order to communicate therewith. The bending plate 221 is formed to surround the outer side of the hollow portions, And a side plate 222 are provided.

It is preferable that the shape of the hollow portion 223 connecting the starting point, the leading end and the ending point of the depressed portion 224 of the two bent plates 221, that is, the hollow portion 223 surrounding the discharger 242, Square, square, etc., and can be suitably applied according to the processing capacity and processing efficiency required by the system.

The lower housing 230 is connected to the upper end of the inlet portion 100 and is connected to the lower end of the dust collecting portion 220 so that the mixed gas supplied through the inlet portion 100 is supplied to the dust collecting portion 220, And a lower insulating portion 244 of the corona discharging portion 240 is provided in the inner hollow portion.

The upper housing 210 and the lower housing 230 have a relatively smaller area in plan view than the upper housing 210 and the lower housing 230. In order to install the dust collecting unit 220 in the vertical direction, A plurality of separate supporting pillars 250 may be provided.

The corona discharge unit 240 includes a high voltage application unit 241 provided inside the upper housing 210 and a power supply unit 240 connected to the corona discharge unit 240 by being extended downward from the high voltage application unit 241, A plurality of discharge units 242 for performing corona discharge and upper and lower housings 210 and 230 respectively supporting the upper and lower parts of the discharger 242 so that the discharger 242 can be connected to the upper housing 210, An upper insulating portion 243 and a lower insulating portion 244 electrically insulated from the lower housing 230 and the dust collecting portion 220.

The high voltage applying device 241 is provided in the inner hollow portion of the upper housing 210 so that a high voltage can be applied to the discharger 242, and includes a high voltage generating device and a high voltage distributing device. The high voltage generating apparatus generates a voltage according to an output value set based on the output value of the flow sensor 131 or the concentration sensor 130 of the inlet 100. The high voltage distributor includes a plurality of dischargers 242 coupled thereto So that the voltage generated from the high voltage generating device can be evenly distributed to each of the dischargers 242.

The discharger 242 is formed in a rod shape and extends in the downward direction from the high voltage distribution device of the high voltage application device 241 so that a plurality of the discharge devices 242 are equidistantly disposed inside the dust collection part 220 and are supplied from the high voltage application device 241 The corona discharge is performed using a high voltage. The discharge unit 242 forms a circular corona generating region around the discharge unit 242, thereby noxious gas of the mixed gas passing through the dust collecting unit 220 is firstly purified. The ozone generated by the corona discharge of the discharger 242 is supplied to the catalytic oxidizing unit 300 together with the mixed gas to become the activation energy source of the catalyst 310 of the catalytic oxidizing unit 300.

The upper end of the discharger 242 is coupled to the upper insulating portion 243 and the lower end of the discharger 244 is coupled to the lower housing 230 by the lower insulating portion 244 to be electrically insulated from the lower housing 230 and the dust collecting portion 220 At this time, the upper end of the discharger 242 may be coupled to the upper insulating portion 243 so as to protrude by a predetermined length. This protruding engagement is to allow the discharge device 242 to be easily taken out after removing the superstructure at the time of replacement and maintenance of the discharger 242.

The upper insulating portion 243 is provided in the inner hollow portion of the upper housing 210 and the lower insulating portion 244 is provided in the lower housing 230. The upper insulating portion 243 is provided with a high- (241) can be further combined. The combination of the upper insulating portion 243 and the high voltage applying device 241 causes a vortex in the gas when the mixed gas rising from the dust collecting portion 220 is supplied to the upper catalytic oxidizing portion 300, 220 can be distributed evenly to the relatively wide catalytic oxidizing unit 300. [0064]

The catalytic oxidizing unit 300 is connected to the upper end of the upper housing 210 of the corona decomposing unit 200 and is communicatively coupled to the lower end of the exhaust unit 400, And secondarily removes the noxious gas supplied to the discharging unit 400 by supplying the removed mixed gas.

The catalytic oxidizing unit 300 includes a lattice-shaped pedestal 320 and a catalyst 310 that is seated on the pedestal 320. At this time, the catalyst 310 reacts with the generated activation energy by the ozone generated in the corona decomposition unit 200, and a suitable catalyst 310 material can be selected according to the composition of the noxious gas, the temperature, the humidity, the concentration,

The discharging unit 400 is connected to the upper end of the catalytic oxidizing unit 300 and receives the second purified mixed gas from the catalytic oxidizing unit 300 and discharges the mixed gas to the outside.

The present invention having the above-described structure is characterized in that the inlet portion 100, the corona decomposition portion 200, the catalytic oxidizing portion 300 and the discharge portion 400 are arranged in the vertical direction, It can be moved to the upper part naturally and purified.

Furthermore, the present invention has the effect that the noxious gas is primarily purified from the corona decomposition section 200, and is secondarily purified by the catalytic oxidation section 300 to purify the noxious gas stably.

The dust collecting unit 220 of the corona decomposing unit 200 is folded in multiple folds so as to surround a hollow portion communicating on a regular polygonal shape so that the corona non- (10) can be minimized and the harmful gas purification efficiency can be increased.

100: inlet portion 200: corona decomposition portion
210: upper housing 220:
221: bending plate 222: side plate
223: hollow portion 224: depression
240: corona discharge part 242: discharge part
300: catalytic oxidizing part 310: catalyst
400:

Claims (5)

1. A harmful gas purification apparatus for removing harmful gas comprising volatile organic compounds or odorous gases,
An inflow portion into which a mixed gas containing the noxious gas is introduced;
A corona decomposing unit provided at an upper portion of the inflow portion to receive the mixed gas from the inflow portion and to discharge a corona discharge to remove the noxious gas first;
A catalyst which is provided at an upper part of the corona decomposition part to receive the mixed gas from which the noxious gas is firstly removed from the corona decomposition part and receives the activation energy by the corona discharge from the corona decomposition part to remove the noxious gas secondarily, Oxidized portion; And
A discharging unit provided on the catalytic oxidizing unit to receive the mixed gas from which the noxious gas is secondarily removed from the catalytic oxidizing unit and discharge the mixed gas to the outside;
, ≪ / RTI >
The corona-
An upper housing;
A dust collecting part provided at a lower portion of the upper housing;
A lower housing provided at a lower portion of the dust collecting portion; And
A plurality of discharge units connected to the high voltage application unit and extending downward from the high voltage application unit to perform a corona discharge using a power source supplied from the high voltage application unit and a plurality of discharge units connected to the upper and lower housings, And an upper insulating portion and a lower insulating portion which are respectively provided on the lower housing and the lower housing to support the upper and lower portions of the discharger so that the discharger is electrically insulated from the upper housing, the lower housing and the dust collecting portion. Respectively,
Wherein the dust-
Two bending plates spaced apart from each other; And
Two side plates connecting between both ends of the two bending plates;
Wherein the bending plate is multi-folded so as to have a folding line in the up and down direction so as to form an indentation at an equal interval inward, and the discharge unit is disposed at a center of a regular polyhedron including apexes of the indentations And is disposed at a downstream side of the gas-liquid separator. The method according to claim 1,
Wherein the dust collecting portion is formed in a hollow shape in the shape of a square, so that adjacent hollow portions communicate with each other. 3. The method of claim 2,
Wherein the catalytic oxidizing section comprises a lattice-shaped pedestal portion and a catalyst that is seated on the pedestal portion. The method of claim 3,
Wherein the inflow section includes an inflow pipe into which the mixed gas flows, a plurality of branch pipes branched from the inflow pipe and communicated with the lower housing of the corona decomposition section, and a plurality of branch pipes provided in the inflow pipe, Wherein the output value of the high-voltage applying unit is varied according to an output value of the sensor unit. 5. The method of claim 4,
Wherein the inflow section includes a flow rate adjusting device provided at a branch point of the branch pipe from the inflow pipe and a flow rate sensor provided inside the branch pipe, And the amount of opening of the regulating device is variable.

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