KR102578725B1 - Fine dust coarsening complex treatment equipment - Google Patents

Abstract

The present invention relates to a fine dust coarsening complex treatment device, in which particles of harmful gases, including dust and fine dust collected through a duct or hood, pass through a water film layer caused by the injection of pressure water sprayed in the form of steam or fog. A fine dust coarsening device that promotes the separation of coarse particles with moisture adsorbed through cohesion between fine particles using the difference in specific gravity due to centrifugal force and centripetal force; Most of the fine dust is removed by more than 80% by the fine dust coarsening device, and the remaining fine dust is separated and discharged by particle size by centrifugal force and centripetal force, and the fine dust with smaller particles is finally placed in a fine dust separation pack. It is characterized by including a fine dust separation device that is removed from the combustion and carbonization process, and the fine phenol component generated in the process of cutting and processing polyurethane foam and using it for duct insulation purposes. It simultaneously removes harmful gas substances in the workplace caused by volatile organic compound (VOC) solvents, which are the main material of adhesives used in the dust removal and insulation adhesion process, and has high adsorption efficiency for gases, odors, and vapors. The pressure loss is small and the collection efficiency of fine dust is high, so secondary dust treatment is not necessary and simultaneous treatment of dust and gas (especially wet gas) is possible.

Description

Fine dust coarsening complex treatment equipment}

The present invention relates to a complex treatment device for fine dust coarsening, and more specifically, to ultrafine dust generated during combustion and carbonization and fine phenol generated during the process of cutting and processing polyurethane foam and using it for duct insulation purposes. It is a fine dust coarsening complex treatment device that can simultaneously remove harmful gas substances in the workplace caused by volatile organic compound (VOC) solvents, which are the main material of adhesives used in the dust removal process and adhesive adhesion process. It's about.

In general, according to WHO standards, fine dust and ultrafine dust refer to particulate matter with particle diameters of 10㎛ and 2.5㎛, respectively, and in Korea, they are regulated separately at 10㎛ and 2.5㎛, respectively.

Currently, one of the main causes of fine dust in Korea is combustion, especially combustion in thermal power plants. It is understood that fine dust originating from combustion of thermal power plants accounts for 20-30% of domestic fine dust emissions. A significant amount of fine dust is also generated during the production of semiconductors, Korea's main product.

In most cases, fine dust comes directly from the source as solid fine dust such as carbon, soot, minerals, and silicon oxide. In addition, there is a photochemical reaction in which gaseous substances react chemically with other substances in the air to become fine dust.

The main methods for treating dust include electrostatic dust collection, cleaning dust collection, filtered dust collection, and centrifugal dust collection.

Electric dust collection uses high voltage, so there is a problem with ozone being emitted. Even though the equipment is expensive, it is difficult to remove dust when the dust particle size range is large. If there is a large difference in resistivity, it is disadvantageous for vibration suppression, and problems such as vibration suppression performance depending on temperature must also be resolved. Above all, when the electrostatic precipitator is attached or detached, fine dust that exceeds the permissible emission standard by several times is instantaneously emitted due to hunting due to dust re-scattering, but no clear solution has been proposed for this.

The general cleaning dust collection method cannot be applied to PM2.5 because the dust removal efficiency of particles with a particle size of l㎛ or less is close to 0%. The venturi type can theoretically handle even l㎛ particles through design optimization, but there are limits to its practical application because the pressure loss is too high, exceeding 300 mmHg2O.

Filtered dust collection can be applied individually differently depending on the size of the dust, but application may be difficult depending on the shape and specific gravity of the dust. Application is impossible when moisture is high, and application is even more difficult when acid and alkali are introduced simultaneously. There is a problem that the scale of the vibration isolation facility is large and the installation cost increases rapidly depending on the application temperature.

Centrifugal force dust collection not only has a large pressure loss, but also has a dust removal efficiency of close to 0% for particles with a particle diameter of 10㎛ or less, so it cannot be practically applied to fine dust removal.

Removing fine dust using a conventional dust collection device has many problems. To solve this problem, a technology for coarsening fine dust was proposed.

Registered Patent Publication No. 0464969, a conventional technology for removing fine dust, etc., is F2 and NOX, which are gases generated during the production of semiconductors in a semiconductor factory or generated and discharged through acid treatment and other chemical treatment processes. , R-SH type DMS, SiO2, etc. are introduced into the multi-tower device and treated in multiple stages to create a gas harmless to the environment from which the dust has been removed and discharged into the atmosphere.

The configuration of the prior art described above is to inject the generated gas by forming a gas inlet at the upper part of the outer cylinder, and spraying steam into the injected gas from a plurality of steam nozzles installed inside the upper part of the outer cylinder, and then injecting steam at regular intervals. The cleaning liquid is sprayed from a plurality of cleaning liquid nozzles installed below the steam nozzle, and is allowed to pass through a multi-venturi installed between the outer tube and the inner tube, and then the cleaning liquid is sprayed from a plurality of cleaning liquid nozzles installed at the lower part of the multi-venturi. While spraying, the gas passes through a packing part installed to a certain standard at the bottom of the multi-venturi, passes through the bubbling part of the inner cylinder, sprays the cleaning liquid from a cleaning liquid nozzle installed thereon, and then passes through the bubbling part again. After contacting the cleaning liquid sprayed from the cleaning liquid nozzle above, it passes through the multi-tawi device through an outlet formed at the top of the inner cylinder to discharge a harmless gas into the environment from which dust has been removed.

The above prior art relates to chemical conversion to change F2 to HF and NO to NO2 by activating molecular motion without coarsening fine dust, and there is no separate device for mixing steam and gas in a limited space. , there is a problem in that fine dust cannot be removed by using high-velocity gas to turn the cleaning liquid into fine droplets.

As a prior document to solve the above problems, Patent Publication No. 10-1906495 (announced on October 10, 2018) “Fine dust coarsening device and method for removing fine dust using the same” refers to a fine dust coarsening device and a method for removing fine dust using the same. In the fine dust treatment device including a post-processing device for processing the processing fluid discharged from the fine dust coarsening device, the fine dust coarsening device mixes gas containing fine dust and steam to form a fluid. Fluid mixing section; One or more fluid inlets that discharge the fluid in a vortex form into an inner tube of one or more first double pipes in the fine dust treatment tank; a cleaning liquid spraying unit corresponding to each of the fluid inlets and spraying cleaning liquid on the fluid discharged from the fluid inlet; and a cleaning liquid spraying unit corresponding to the fluid inlet and each of the fluid inlets. It is disposed on the inner tube of the double pipe, and a vortex generator is disposed at the fluid inlet portion to allow the fluid to be discharged in the form of a vortex into the inner tube of the first double pipe, and the inner pipe of the first double pipe is the fine dust. It is positioned so as not to be submerged in the cleaning liquid at the bottom of the treatment tank, and the outer pipe of the first double pipe is positioned so that its lower end is submerged in the cleaning liquid at the bottom of the fine dust treatment tank.

Since fine dust is collected while cleaning is performed only by the cleaning liquid sprayed from the cleaning liquid spray part of the prior literature configured as above, there is a problem in that fine dust is discharged without condensing in the cleaning liquid.

In addition, when treating fine dust that could not be removed in the post-processing device, the area through which air containing fine dust flows into the grid bead is gradually formed to have a narrower cross-sectional area toward the bottom, and water droplets and liquid droplets are finely crushed and supplied to this. This removes fine dust, but this also has the problem that fine dust is not completely removed and is discharged as is.

Registered Patent Publication No. 10-1906495 (announced on October 10, 2018)

In order to solve the above-mentioned problems, the present invention removes dust from fine phenol components generated during the process of cutting and processing ultrafine dust and polyurethane foam generated during combustion and carbonization and uses it for duct insulation purposes, and adhesion to insulation. The purpose is to provide a fine dust coarsening complex treatment device that can simultaneously remove harmful gas substances in the workplace caused by volatile organic compound (VOC) solvents, which are the main material of adhesives used in the process.

The present invention has high adsorption efficiency for gas, odor, vapor, etc., low pressure loss, and high collection efficiency of fine dust, so secondary dust treatment is not necessary, and simultaneous treatment of dust and gas (especially wet gas) is possible. The purpose is to provide a dust coarsening complex treatment device.

The present invention maximizes efficiency by ensuring that the coarsening element, fine dust separation pack, and spray layer are formed in a multi-stage form when removing dust and gas. The processing speed is faster than that of a general dust collector, and the scale is larger than that of existing dust collectors. The purpose is to provide a fine dust coarsening complex treatment device that can be used efficiently by forming a small size.

The present invention has many holes in the impulse plate, so gas is collected evenly, and it can be used even when there are rapid temperature changes, so there is no need for additional installation of cooling coils or heaters to maintain a constant temperature, so maintenance costs are low. The purpose is to provide a coarsening complex processing device.

The present invention is a means to achieve the above object,

Particles of harmful gases, including dust and fine dust collected through ducts and hoods, pass through a water film layer caused by spraying pressured water in the form of steam or fog, and moisture is adsorbed through cohesion between fine particles. A fine dust coarsening device that promotes separation using the difference in specific gravity due to centrifugal force and centripetal force; More than 80% of most fine dust is removed by the fine dust coarsening device, and the remaining fine dust is separated and discharged by particle size by centrifugal force and centripetal force. Fine dust with smaller particles is ultimately removed from the fine dust separation pack. It provides a fine dust coarsening complex processing device comprising a fine dust separation device to remove fine dust.

The fine dust coarsening device of the present invention includes a coarsening device box; A radial chamber installed on the upper inner side of the coarsening device enclosure; a mixing chamber coupled to the radial chamber and the coarsening means to uniformly mix the dust and fine dust properties that have passed through the water film layer in the form of fog and supply them to the separation tube of the coarsening means installed in equal divisions; It is installed connected to the mixing chamber, and a vortex is formed through a cyclone element to change the airflow of dust and coarsened fine dust contained in the incoming harmful gas, and the centrifugal force caused by the vortex is used to smoothly maintain particle contact. means of communication; A dust hopper installed integrally at the lower part of the coarsening device box to collect and discharge fine dust solidified in the coarsening means; a first discharge conveyor installed at the bottom of the dust hopper to discharge solidified fine dust collected by the dust hopper; It is characterized by including a top cone installed on the upper part of the coarsening device enclosure so that fine dust that has not been solidified by the coarsening means can be supplied to the fine dust separation device.

The radial chamber of the present invention is characterized in that a plurality of spray nozzles are installed radially to spray steam and pressure water in the form of mist.

The coarsening means of the present invention includes a separation tube radially installed at the bottom of the mixing chamber; A cyclone element is installed at the top of the inside of the separation tube to generate a change in airflow in the dust or coarsened fine dust contained in the harmful gas flowing through the mixing chamber and generates centrifugal force due to a vortex to generate contact between particles; A round manifold installed between radially installed separation tubes consisting of a moisture inflow pipe and a moisture supply pipe to supply moisture to the spray device; A spray device connected to the round manifold and installed inside each of the plurality of separation tubes; an airflow rising induction tube in which a plurality of separation tubes are respectively fixed to the inside so as to induce an upward movement of the airflow generated in the separation tubes; It is characterized by including a coarsening element installed between the separation tube and the airflow rising induction pipe so that the positive and negative pressures are instantaneously formed in the fine dust that has completed primary dropletization to promote the agglomeration phenomenon.

The coarsening element of the present invention is characterized in that the airflow flowing between the separation tube and the airflow rising induction pipe is formed in the form of a grid so that positive and negative pressures are instantaneously formed.

The fine dust separation device of the present invention includes a separation device box connected to the fine dust coarsening device and a connection duct into which dropletized and primary coarsened fine dust flows; A fine dust separation pack installed on the upper inner side of the separation device box 210 so that fine dust that is not treated in the fine dust treatment device and flows into the inside can be reprocessed by pressure water and cleaning air; a washing device that sprays washing water and washing air to wash untreated fine dust flowing into the fine dust separation pack; An impulse plate installed in the separation device box to support the fine dust separation pack; A storage hopper installed at the lower part of the separation device box to collect fine dust that has been reprocessed and coarsened by a fine dust separation pack and a washing device; a second discharge conveyor installed below the storage hopper to discharge coarsened fine dust; It is characterized in that it includes; an exhaust duct installed on the upper part of the enclosure lid installed on the upper part of the separation device enclosure so that air from which fine dust has been removed is discharged.

The connection duct of the present invention is characterized in that it is installed biased to one side from the center of the separator enclosure so that residual fine dust flowing in from the fine dust coarsening device generates a vortex phenomenon.

The fine dust separation pack of the present invention includes a plurality of separation pieces arranged at predetermined intervals in a zigzag shape; A separator bracket coupled to a zigzag-shaped separator and installed on the impulse plate; It is characterized in that it includes a blocking plate that has a through hole through which fine dust moved by an upward air current flows into only one place, is located in close contact with the upper part of the impulse plate, and is fixed to the outer periphery of the separation bracket.

The cleaning device of the present invention includes an air supply pipe through which cleaning air is supplied; A plurality of air nozzles installed at predetermined intervals in the air supply pipe; A washing water supply pipe through which washing water is supplied; It is characterized in that it includes a plurality of washing water nozzles installed at predetermined intervals in the washing water supply pipe.

The present invention is a main method of adhesive used in the process of removing ultrafine dust and fine phenol components generated in the process of cutting and processing polyurethane foam generated during combustion and carbonization and using it for insulation of ducts, and in the adhesion process of insulators. It has the effect of simultaneously removing harmful gas substances in the workplace caused by solvents such as Volatile Organic Compound (VOC).

The present invention has a high adsorption efficiency for gas, odor, steam, etc., a small pressure loss, and a high collection efficiency of fine dust, so secondary dust treatment is unnecessary and simultaneous treatment of dust and gas (especially wet gas) is possible. .

The present invention maximizes efficiency by ensuring that the coarsening element, fine dust separation pack, and spray layer are formed in a multi-stage form when removing dust and gas, and the processing speed is faster than that of a general dust collector, making the scale larger than that of existing dust collectors. By forming a small scale, there is an effect of efficient use of installation space.

The present invention has many holes in the impulse plate, so gas is collected evenly, and it can be used even when there are rapid temperature changes, so there is no need for additional installation such as cooling coils or heaters to keep the temperature constant, so maintenance costs are low. there is.

The present invention accounts for 20 to 30% of fine dust generated by combustion, such as in domestic thermal power plants, and mostly exists in the form of solid carbon, soot, minerals, silicon oxide, etc., by steaming fine dust. It has the effect of removing fine dust below PM 2.5, which is difficult to remove with general cleaning methods, by coagulating and deliquescenting it.

In addition, the present invention is a coarsening device and fine dust to remove exhaust gases F ₂ , NOx, R-SH, silver, SiO 2 , etc., and dust generated during the production of semiconductors in a semiconductor factory or during cleaning using acid treatment and chemicals. The dust separation device removes fine dust in multiple stages and releases harmless gas into the atmosphere.

Figure 1 is a diagram showing a fine dust coarsening complex processing device according to the present invention.
Figure 2 is a cross-sectional view showing a configuration in which a coarsening means is coupled to the mixing chamber shown in Figure 2.
Figure 3 is a plan view showing a spray device installed in the coarsening means of the fine dust coarsening complex treatment device shown in Figure 1.
Figure 4 is a cross-sectional view showing the configuration of the coarsening means shown in Figure 3.
Figure 5 is a view showing the coarsening element of the coarsening means shown in Figure 3 expanded.
Figure 6 is a diagram showing the configuration of the fine dust separation device shown in Figure 1.
Figure 7 is a plan view showing an installed state showing the organic structural relationship between the residual fine dust separation pack, the pressure water supply device, and the air cleaning supply device installed in the residual fine dust tank of Figure 6.
Figure 8 is an enlarged view of the fine dust separation pack shown in Figure 6.
Figure 9 is a diagram showing the process of removing fine dust by the fine dust coarsening complex processing device according to the present invention.

Hereinafter, a fine dust coarsening complex processing device according to the present invention will be described.

The fine dust coarsening complex treatment device according to the present invention allows particles of harmful gases, including dust and fine dust collected through ducts and hoods, to pass through a water film layer caused by the injection of pressure water sprayed in the form of steam or fog. A fine dust coarsening device (100) that promotes the separation of coarse particles with moisture adsorbed through inter-particle cohesion using the difference in specific gravity due to centrifugal force and centripetal force; Most of the fine dust is removed by more than 80% by the fine dust coarsening device 100, the remaining fine dust is separated and discharged by particle size by centrifugal force and centripetal force, and fine dust with small particles is finally fine dust. It is characterized in that it includes a fine dust separation device (200) that is finally removed from the separation pack (220).

The fine dust coarsening complex processing device according to the present invention, which has the above features, will be described in detail with the accompanying drawings.

1 to 8, the fine dust coarsening complex processing device according to the present invention includes a fine dust coarsening device 100 and a fine dust separation device 200.

The fine dust reducing device 100 allows particles of harmful gases, including dust and fine dust collected through ducts and hoods, to pass through a water film layer caused by the injection of pressure water sprayed in the form of steam or fog, thereby forming a barrier between fine particles. A coarsening device box (110), a radial chamber (120), a mixing chamber (130), and a coarsening means ( 140), a dust hopper 150, a first discharge conveyor 160, and a top cone 170.

The coarsening device box 110 has a cylindrical shape with a space formed on the inside.

The mixing chamber 130 is installed on the inner upper part of the coarsening device box 110 to divide and supply harmful gas to the coarsening means 140.

The radial chamber 120 is composed of a radial chamber body 121 formed in a cylindrical shape, and a chamber inlet pipe 122 connected to a duct and a hood is formed on one side of the radial chamber body 121, and the chamber inflow pipe 122 is formed. A chamber discharge pipe 123 is formed on the other side of the radial chamber body 121 on which the pipe 122 is formed and connected to the mixing chamber 130.

A spray nozzle 124 is installed in the radial chamber body 121, and the spray nozzle 124 is installed radially in the radial chamber body 121 to remove harmful substances, including dust and fine dust collected through the duct and hood. In order to coarsen the gas and promote an instantaneous adsorption reaction, steam or pressure water is sprayed in the form of mist.

The mixing chamber 130 is a coarsening means 140 that uniformly mixes the dust and fine dust properties that have passed through the water film layer in the form of fog and supplies them to the separation tube 141 of the coarsening means 140 installed in equal parts. It is installed inside the coarsening device box 110 to be coupled.

In addition, the mixing chamber 130 allows dust and fine dust that has passed through the fog-shaped water film layer in the radial chamber body 121 of the radial chamber 120 to flow into the separation tube 141 of the coarsening means 140. A number of holes (unmarked) are formed to allow this.

The coarsening means 140 is installed connected to the lower part of the mixing chamber 130 and passes through the cyclone element 142 to form a vortex to change the airflow of dust and coarsened fine dust contained in the incoming harmful gas. It creates a whirlpool and uses centrifugal force to maintain smooth contact between particles.

The coarsening means 140 consists of a separation tube 141, a cyclone element 142, a round manifold 143, a spray device 144, an airflow upward induction pipe 145, and a coarsening element 146.

The separation tube 141 is installed radially in the lower part around the center of the mixing chamber 130 to induce the inflow of dust contained in harmful gases or coarsened fine dust.

The cyclone element 142 is installed at the top inside the separation tube 141 to generate an airflow change in the dust or coarsened fine dust contained in the harmful gas flowing in through the mixing chamber 130, and generates a vortex to generate centrifugal force. This causes the particles to come into contact.

The cyclone element 142 is shaped like a screw to change the airflow of dust or coarsened fine dust contained in the incoming harmful gas, and this screw shape generates a vortex.

The round manifold 143 consists of a moisture inlet pipe 143-1 and a moisture supply pipe 143-2 and is installed between the radially installed separation tubes 141 to supply moisture to the spray device 144.

The moisture inlet pipe 143-1 is connected to a water supply pipe 320 connected to the high-pressure spray pump 310 installed in the water supply tank 300 and supplies water to the moisture supply pipe 143-2.

The moisture supply pipe (143-2) is connected to the moisture inlet pipe (143-1) and is installed between radially installed separation tubes (141) to supply moisture to the spray device (144).

The spray device 144 is connected to the round manifold 143 and is installed inside each of the plurality of separation tubes 141. The spray device 144 sprays pressure water supplied through the water supply pipe 320, the moisture inlet pipe 143-1, and the moisture supply pipe 143-2 in the form of mist by driving the high-pressure spray pump 310. It consists of a spray nozzle that

The airflow rising induction pipe 145 is fixed to each of the plurality of separation tubes 141 so as to induce an upward movement of the airflow generated in the separation tubes 141.

In addition, the airflow rising induction pipe 145 is spaced apart from the separation tube 141, and induces the airflow generated in the separation tube 141 to rise through the spaced gap. And the lower end of the airflow upward induction pipe 145 is formed to gather toward the center.

The coarsening element 146 is installed between the separation tube 141 and the airflow rising induction pipe 145 so that the fine dust that has completed primary dropletization can instantaneously form positive and negative pressures to promote the agglomeration phenomenon. . In addition, the coarsening element 146 is shown in an unfolded state in FIG. 5, but since it is installed in the space between the separation tube 141 and the airflow rising induction pipe 145, its installation shape is cylindrical. It is installed.

The coarsening element 146 is configured in a lattice shape so that positive and negative pressures are instantaneously formed in the airflow flowing between the separation tube 141 and the airflow rising induction pipe 145, and in order to form the lattice shape, horizontal bars 146 are used. -1) and a vertical bar (146-2), and the horizontal bar (146-1) and the vertical bar (146-2) are bent to generate positive pressure to form a zigzag shape.

By the coarsening means 140, as the harmful gas particles pass through the water film layer caused by the injection of pressure water sprayed in the form of steam or fog, all moisture is adsorbed through the cohesive force between fine particles, forming coarse particles, and the raw material is They are separated by the specific gravity difference caused by the tensile force and the centripetal force. The coarsening particles fall into the dust hopper 150 installed at the lower part of the coarsening device box 110.

The dust hopper 150 collects falling coarse particles so that they can be discharged to the outside by the first discharge conveyor 160. The dust hopper 150 is installed integrally at the lower part of the coarsening device box 110 to collect and discharge fine dust solidified in the coarsening means.

The first discharge conveyor 160 is installed at the lower part of the dust hopper 150 to discharge solidified fine dust collected by the dust hopper 150. Additionally, the first discharge conveyor 160 may be configured in a screw shape.

The fine dust separation device 200 removes more than 80% of the fine dust by the fine dust coarsening device 100, and separates and discharges the remaining fine dust by particle size by centrifugal force and centripetal force. Small fine dust is finally removed from the fine dust separation pack (220).

The fine dust separation device 200 includes a separator box 210, a fine dust separation pack 220, a cleaning device 230, an impulse plate 240, a storage hopper 250, and a second discharge conveyor 260. Includes.

The separation device box 210 is connected to the fine dust coarsening device 100 and the connection duct 180 so that dropletized and primarily coarsened fine dust flows in. And the connection duct 180 is installed biased on one side of the separator enclosure 210 so that the remaining fine dust flowing in from the fine dust reducing device 100 generates a vortex phenomenon.

The fine dust separation pack 220 is located on the upper inner side of the separation device box 210 so that fine dust that is not treated in the fine dust treatment device 100 and flows into the inside can be reprocessed by pressure water and cleaning air. It is installed.

The fine dust separation pack 220 is composed of a plurality of separation pieces formed in a zigzag shape at predetermined intervals, and a separation bracket 222 is coupled to the separation piece 221 formed in a zigzag shape and installed on the impulse plate 240. ) is configured, has a through hole through which fine dust moved by the rising airflow flows into only one place, and is located in close contact with the upper part of the impulse plate 240, and a blocking plate 223 is provided on the outer periphery of the separation bracket 222. It is installed.

The washing device 230 sprays washing water and washing air to wash untreated fine dust flowing into the fine dust separation pack 220.

The cleaning device 230 is installed in a 'ㄷ' shape so that the air supply pipe 231 through which cleaning air is supplied is located on both sides of the upper center of the residual fine dust separation pack 220, and the air supply pipe is A plurality of air nozzles 232 are installed at predetermined intervals at the bottom of the air supply pipe 231, and a washing water supply pipe 233 is installed at the center of the 'C' shape of the air supply pipe 231 to supply washing water. A plurality of washing water nozzles 234 are installed at predetermined intervals at the bottom of the washing water supply pipe 233 to spray washing water supplied through the washing water supply pipe 233.

The impulse plate 240 is installed in the separation device box 210 and supports the fine dust separation pack 220. In addition, the impulse plate 240 is fixed to the inner periphery of the separator housing 210 by welding or the like, and a separator bracket 222 is fixed to the top. In addition, a plurality of impulse plate holes are formed in the impulse plate 240 so that untreated fine dust flows into the separator enclosure 210 and rises in the direction where the fine dust separation pack 220 is located, causing coarsening.

The storage hopper 250 is installed at the lower part of the separation device box 210 and collects coarsened fine dust that is reprocessed by the fine dust separation pack 220 and the washing device 230. The storage hopper 250 is configured to have a diameter that gradually decreases from the top to the bottom, and has a drop hole (not marked) at the center of the bottom so that the roughened fine dust can be discharged to the second discharge conveyor 260. is formed

The second discharge conveyor 260 is installed below the storage hopper 250 to discharge coarsened fine dust. Additionally, the second discharge conveyor 260 may be configured in a screw shape.

The discharge duct 270 is installed on the upper part of the enclosure lid 212 installed on the upper part of the separator enclosure 210 so that air from which fine dust has been removed is discharged.

The process of removing harmful gases including dust and fine dust collected through the fine dust coarsening complex processing device according to the present invention configured as described above will be described with reference to FIG. 9.

Referring to FIG. 9, the fine dust coarsening complex processing device of the present invention allows particles of harmful gases, including dust and fine dust collected through a duct and a hood, to enter the chamber inlet pipe 122 of the radial chamber 120. When flowing in through, a water film layer is formed by pressure water sprayed in the form of steam and fog sprayed from the spray nozzle 124 radially installed in the radial chamber body 121, and the dust and fine dust collected in the water film layer are formed. As harmful gases containing pass through, all moisture is absorbed through cohesion between fine particles, resulting in coarsening.

Coarse particles that are coarsened while passing through the water film layer and fine dust that is not coarsened are supplied to the mixing chamber (130) through the chamber discharge pipe (123) of the radial chamber (120). The coarsened particles supplied to the mixing chamber 130 and the fine dust that has not been coarsened are uniformly mixed with the dust and fine dust properties that have passed through the water film layer in the form of a fog, and are divided into a plurality of equally divided separation tubes 141. Each is supplied.

The coarsened particles and non-coarsened fine dust supplied inside the plurality of separation tubes 141 generate centrifugal force and centripetal force by the cyclone element 142 installed inside the plurality of separation tubes 141, and these It promotes the separation of coarsened particles and non-coarsened fine dust by using the difference in specific gravity caused by centrifugal force and centripetal force.

In addition, when centrifugal force and centripetal force are generated by the cyclone element 142, moisture is supplied through the moisture inlet pipe 143-1 and moisture supply pipe 143-2 of the round manifold 143, and the supplied moisture is The spray device 144 is used to form droplets of fine dust that has not been coarsened.

Fine dust that has been coarsened through the spray device 144 installed inside the plurality of separation tubes 141 falls to the bottom of the separation tube 141, and the fallen coarse particles are collected in the dust hopper 150 and It is supplied to the first discharge conveyor 160 installed at the bottom and discharged to the outside of the coarsening device box 110.

And the fine dust in the droplet state, which has not been completely coarsened by the interaction between the cyclone element 142 and the spray device 144, passes between the separation tube 141 and the airflow upward induction pipe 145. do.

At this time, while passing through the coarsening element 146 in which a lattice space is formed between the separation tube 141 and the airflow induction pipe 145, positive and negative pressure are instantaneously formed, resulting in mutual condensation due to the difference in attraction between particles. Complete coarsening is achieved by promoting hyperagglomeration.

And the fine dust that moves toward the top cone 170 while passing through the coarsening element 146 is supplied to the fine dust separation device 200 through the connection duct 180.

The fine dust that has not been coarsened flows into the separation device enclosure 210 through the connection pipe 211 to which the connection duct 180 is coupled. At this time, the connection pipe ( 211) is installed, centrifugal force and centripetal force are generated as fine dust flows in.

The fine dust generated by the centrifugal force and centripetal force is guided as an upward airflow from the central part of the separation device box 210 and enters the residual fine dust separation pack 220. The fine dust entering the residual fine dust classification pack 220 flows through the impulse plate 240, and the fine dust flows into the impulse plate 240 by the blocking plate 223 into the residual fine dust separation pack ( 220).

A plurality of the residual fine dust separation packs 220 are installed in succession in a 'W' shape, so the fine dust moving between them is installed in the air nozzle 232 installed in the air supply pipe 231 and the washing water supply pipe 233. Cleaning is performed for a predetermined period of time using air and washing water sprayed from the washing water nozzle 234. The cleaning operation as described above prevents the purification of fine dust and the washing water from sticking to the residual fine dust separation pack 220 and hardening it.

The air with the fine dust finally removed from the residual fine dust separation pack 220 is vented through the discharge duct 270, and the fine dust coarsened by the washing water is stored in the lower part of the separation device box 210. It falls into the hopper 250 and is stored.

The coarsened fine dust stored in the storage hopper 250 is discharged to the outside by the second discharge conveyor 260 at regular intervals.

As explained above, the adhesive used in the process of removing ultrafine dust generated during combustion and carbonization and fine phenol dust generated in the process of cutting and processing polyurethane foam and using it for duct insulation purposes and in the adhesion process of insulation It can simultaneously remove harmful gas substances in the workplace caused by solvents such as Volatile Organic Compound (VOC), which is the main substance of .

In addition, the present invention has high adsorption efficiency for gas, odor, steam, etc., low pressure loss, and high collection efficiency of fine dust, so secondary dust treatment is unnecessary and simultaneous treatment of dust and gas (especially wet gas) is possible. .

In addition, the present invention maximizes efficiency by ensuring that the coarsening element, fine dust separation pack, and spray layer are formed in a multi-stage form when removing dust and gas, and the processing speed is faster than that of a general dust collector, so the scale of the existing dust collector is reduced. Installation space can be used efficiently by making it small in size compared to the original. In addition, the impulse plate 240 has many holes, so harmful gases including fine dust are collected evenly, and it can be used even when there are rapid temperature changes, so there is no need to install additional cooling coils or heaters to maintain a constant temperature. This has the advantage of being easy to maintain and having low maintenance costs.

In addition, the amount of fine dust generated by combustion, such as in domestic thermal power plants, accounts for 20 to 30%, and most of the fine dust that exists in the form of solid carbon, soot, minerals, and silicon oxide is removed using steam. It is effective in removing fine dust below PM 2.5, which is difficult to remove with general cleaning methods, by coagulating and deliquescenting it.

In _addition , the present invention is a coarsening device ( 100) and the fine dust separation device 200 remove fine dust in multiple stages and discharge harmless gas into the atmosphere.

The above description is merely an illustrative explanation of the technical idea of the present invention, and various modifications, changes, and substitutions can be made by those skilled in the art without departing from the essential characteristics of the present invention. will be. Accordingly, the embodiments disclosed in the present invention and the attached drawings are not intended to limit the technical idea of the present invention, but are for illustrative purposes, and the scope of the technical idea of the present invention is not limited by these embodiments and the attached drawings. The scope of protection of the present invention should be interpreted in accordance with the claims below, and all technical ideas within the equivalent scope should be construed as being included in the scope of rights of the present invention.

100: Fine dust coarsening device 110: Fine dust coarsening device enclosure
120: Radial chamber 121: Radial chamber body
122: Chamber inlet pipe 123: Chamber discharge pipe
124: spray nozzle 130: mixing chamber
140: Coarse means 141: Separation tube
142: Cyclone element 143: Round manifold
143-1: Moisture inflow pipe 143-2: Moisture supply pipe
144: Spray device 145: Airflow upward induction pipe
146: Coarse element 146-1: Transverse bar
146-2: Jongba 150: Dusthopper
160: First conveyor 170: Topcon
180: Connection duct 200: Fine dust separation device
210: Separator enclosure 211: Connector
212: Enclosure lid 220: Fine dust separation pack
221: Separation piece 222: Separation bracket
223: blocking plate 230: washing device
231: Air supply pipe 232: Air nozzle
233: Washing water supply pipe 234: Washing water nozzle
240: Impulse plate 250: Storage hopper
260: Second discharge conveyor 270: Discharge duct
300: Water supply tank 310: High pressure spray pump
320: Water supply pipe

Claims (9)

Particles of harmful gases, including dust and fine dust collected through ducts and hoods, pass through a water film layer caused by spraying pressured water in the form of steam or fog, and moisture is adsorbed through cohesion between fine particles. A fine dust coarsening device (100) that promotes separation using the difference in specific gravity due to centrifugal force and centripetal force;
More than 80% of fine dust is removed by the fine dust coarsening device (100), the remaining fine dust is separated and discharged by particle size by centrifugal force and centripetal force, and fine dust with small particles is finally discharged into a fine dust separation pack. Includes a fine dust separation device 200 that is removed from,
The fine dust reduction device 100,
A coarsening device box (110);
A radial chamber 120 installed on the upper inner side of the coarsening device box 110;
A mixing device that is combined with the radial chamber (120) and the coarsening means (140) to uniformly mix the dust and fine dust properties that have passed through the water film layer in the form of fog and supply them to the separation tube (141) of the coarsening means installed in equal divisions. a chamber 130;
It is installed to be connected to the mixing chamber 130, and a vortex is formed through the cyclone element 142 to change the airflow of dust and coarsened fine dust contained in the incoming harmful gas, and the centrifugal force caused by the vortex is used to contact the particles. A coarsening means (140) for smoothly maintaining the;
A dust hopper (150) installed integrally at the lower part of the coarsening device box (110) to collect and discharge fine dust solidified in the coarsening means (140);
A first discharge conveyor 160 installed at the lower part of the dust hopper 150 to discharge solidified fine dust collected by the dust hopper 150;
It includes a top cone (170) installed on the upper part of the coarsening device box (110) to supply fine dust that has not been solidified by the coarsening means (140) to the fine dust separation device (200),
The coarsening means 140 is,
A separation tube 141 installed radially at the bottom of the mixing chamber 130;
It is installed at the top of the inside of the separation tube (141) to generate a change in airflow in the dust or coarsened fine dust contained in the harmful gas flowing through the mixing chamber (130), and generates centrifugal force by vortex to generate contact between particles. A cyclone element 142 that does;
A round manifold (143) installed between radially installed separation tubes (141) consisting of a moisture inlet pipe (143-1) and a moisture supply pipe (143-2) to supply moisture to the spray device (144);
A spray device (144) connected to the round manifold (143) and installed inside each of the plurality of separation tubes (141);
an airflow rising induction pipe 145 in which a plurality of separation tubes 141 are each fixed to the inside so as to induce an upward movement of the airflow generated in the separation tubes 141;
A coarsening element (146) installed between the separation tube (141) and the airflow rising induction pipe (145) so that positive and negative pressures can be instantaneously formed in fine dust that has completed primary dropletization to promote agglomeration. Contains,
The coarsening element 146 is,
The airflow flowing between the separation tube 141 and the airflow induction pipe 145 is formed in a grid shape so that positive and negative pressure are instantaneously formed, and the grid shape is composed of a horizontal bar 146-1 and a vertical bar 146-2. A complex treatment device for fine dust coarsening, wherein the horizontal bar (146-1) and the vertical bar (146-2) are bent to form a zigzag shape. delete According to paragraph 1,
The radial chamber 120,
A fine dust coarsening complex treatment device characterized in that a plurality of spray nozzles (124) are installed radially to spray steam and pressure water in the form of fog. delete delete According to paragraph 1,
The fine dust separation device 200,
A separation device box (210) connected to the fine dust coarsening device (100) and a connection duct (180) into which dropletized and first coarsened fine dust flows;
A fine dust separation pack (220) installed on the upper inner side of the separation device enclosure (210) so that fine dust that has not been processed in the fine dust treatment device (100) and flows into the interior can be reprocessed by pressure water and cleaning air. class;
a washing device 230 that sprays washing water and washing air to wash untreated fine dust flowing into the fine dust separation pack 220;
An impulse plate 240 installed in the separation device box 210 to support the fine dust separation pack 220;
A storage hopper 250 installed at the lower part of the separation device box 210 to collect fine dust that has been reprocessed and coarsened by the fine dust separation pack 220 and the cleaning device 230;
a second discharge conveyor 260 installed below the storage hopper 250 to discharge coarsened fine dust;
An exhaust duct 270 installed on the upper part of the enclosure lid 212 installed on the upper part of the separation device enclosure 210 so that air from which fine dust has been removed is discharged;
A fine dust coarsening complex treatment device comprising: According to clause 6,
The connection duct 180 is,
A fine dust coarsening complex treatment device, characterized in that the remaining fine dust flowing in from the fine dust coarsening device 100 is installed biased to one side from the center of the separator enclosure 210 so that a vortex phenomenon occurs. According to clause 6,
The fine dust separation pack 220 is,
A plurality of separation pieces 221 are formed in a zigzag shape at predetermined intervals;
A separation bracket (222) coupled to the separation piece (221) configured in a zigzag shape and installed on the impulse plate;
A blocking plate (223) having a hole through which fine dust moved by an upward air current flows into only one place, is located in close contact with the upper part of the impulse plate (240), and is fixed to the outer periphery of the separation bracket (222);
A fine dust coarsening complex treatment device comprising: According to clause 6,
The washing device 230,
An air supply pipe 231 through which cleaning air is supplied;
A plurality of air nozzles 232 installed at predetermined intervals in the air supply pipe 231;
a washing water supply pipe 233 through which washing water is supplied;
A plurality of washing water nozzles (234) installed at predetermined intervals in the washing water supply pipe (233);
A fine dust coarsening complex treatment device comprising:

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