KR20190059736A - Vocs concentration module of volatile organic compound treatment system having an filter arrangement device - Google Patents

Abstract

The present invention relates to a volatile organic compound (VOC) treatment system, which is installed in a facility for discharging a large amount of VOCs, such as a painting facility of a shipyard, and forms a mounting stand capable of mounting an individual VOC concentration module for treating the VOCs, in each layer to store and release a plurality of VOC concentration modules, such that a large amount of the VOCs can be treated and the treatment continuity is secured, and more particularly, to a VOCs concentration module of a VOC treatment system having a filter arrangement device, which can uniformly absorb the VOC in all cartridge units in a module in the individual VOC concentration module, and can uniformly absorb the VOC in omnidirectional surfaces of a filter fiber surrounding an individual cartridge unit, such that the entire absorption performance of the VOC concentration module is increased, and a regeneration lifespan of the cartridge units in the module is set to the same so as to increase the operation efficiency.

Description

TECHNICAL FIELD [0001] The present invention relates to a VOCs concentrating module for a volatile organic compound processing system having a filter array device,

The present invention relates to a VOCs concentration module of a volatile organic compound processing system having a filter array device, and more particularly, to a VOCs concentration module for a volatile organic compound processing system having a filter array device, Which is capable of handling a large amount of volatile organic compounds and capable of handling a large number of VOCs enrichment modules by stacking a plurality of VOCs enrichment modules capable of mounting individual VOCs enrichment modules capable of handling the volatile organic compounds In particular, individual VOCs concentration modules can uniformly adsorb volatile organic compounds on all cartridge units in the module, and filter fibers that enclose individual cartridge units adsorbs volatile organic compounds homogeneously in all directions, resulting in total adsorption of the VOCs concentration module Increased performance and in-module Katrina It relates to a volatile organic compound processing system provided with a filter device arranged in line with the same playback life of the unit to increase the operating efficiency of the system VOCs concentration module.

The odor components generated in sewage treatment plants, pig farms, livestock wastewater treatment plants, slaughterhouses, food factories, and various chemical plants vary widely in composition of pollutants depending on the source and source of the pollutants. Major odor inducing substances include hydrogen sulfide and mercaptan Sulfur compounds, nitrogen compounds such as ammonia and amines, and volatile organic compounds (VOCs) or volatile sulfur compounds including benzene, toluene, ethylbenzene, and xylene.

Such odorous components are generally converted to water and carbon dioxide, and are generally removed. Currently, the odor gas treatment techniques currently used include physical and chemical deodorization methods such as activated carbon absorption method, chemical solution cleaning method, ozone oxidation method, , An activated sludge method, and a bio-filter.

These methods may be used alone or in combination of two or more depending on the treatment environment in which odor gas is to be removed. However, the physico-chemical deodorization method has problems of operating costs such as chemicals and material costs, Requires a lot of area and has a drawback in that a high power loss is required due to a high pressure loss.

In recent years, there has been a growing interest in a method for deodorizing charged microorganisms using a microorganism carrier capable of operating at a small cost in a small space among the biological deodorization methods at a low cost and having high deodorization efficiency.

The method for deodorizing a carrier-loaded microorganism is a method for removing odorous gas by introducing a malodorous gas into a packed column filled with a carrier immobilizing microorganisms. The microorganisms in the packed column are maintained by the energy generated by the decomposition of the malodorous gas and a small amount of nutrients. do. That is, the malodorous components are decomposed and removed by the cultured microorganism.

The biological method using microorganisms as described above has been mainly used for general wastewater treatment, but recently it has been applied to the field of odor removal and its utilization has been increasing.

However, in such a biological method, the biofilter is difficult to operate stably due to the characteristics of the biofilter utilizing limited microorganisms when the concentration of volatile organic compounds in the polluted gas is rapidly changed or the flow rate is fluctuated. Since the concentration and flow rate of such volatile organic compounds are frequently changed, there is a great difficulty in applying and operating the biofilter in the actual field.

In particular, the shipyard will carry out painting and drying work on numerous pieces of equipment alternately. In this process, not only the paint mist that is scattered during painting, but also the paint The solvent is evaporated into the atmosphere and various volatile organic compounds such as toluene are contained in a large amount in the air inside the painting room.

When such volatile organic compounds are released into the atmosphere as they are, the volatile organic compounds react with the light to generate photochemical oxides such as ozone, aldehydes or nitrogen compounds in the smog, thereby causing environmental pollution such as photochemical smog and global warming in large cities. In addition, most of the substances forming volatile organic compounds generate irritating and unpleasant odors even at low concentrations. They are carcinogens that cause skin disorders such as nervous system when they come into contact with human skin or respiratory system. Recently, Regulatory emission controls are being put in place for emissions facilities.

It is relatively easy to have a dedicated volatile organic compound treatment facility in automobile maintenance related fields where a small amount of intermittent painting work is performed. However, in the case of shipbuilding equipment requiring large capacity of continuous processing ability, In most cases, it is discharged as it is to the atmosphere. Even if a volatile organic compound treatment facility is equipped, the cost of the pollution abatement facility increases, and since an exclusive site for a large-area treatment facility is secured, There is a problem that the volatile organic compound treatment is not actively performed.

The present applicant has proposed a mobile processing apparatus capable of absorbing and desorbing volatile organic compounds through 2013 Patent Application No. 0154153.

However, since the polluted gas containing volatile organic compounds is supplied laterally through one connecting portion provided on the side surface in such a mobile processing apparatus, a plurality of cartridge units arranged long in the lateral direction inside the unit are uniformly volatile organic There is a structural disadvantage that volatile organic compounds are concentrated in the cartridge units in the vicinity of the connection without collecting the compounds. This nonuniform collection state of the cartridge units results in unnecessary power dissipation since heating is performed based on the multi-collecting cartridge unit for complete desorption in the desorption process. Furthermore, such unnecessary heating may also cause the durability of the cartridge unit to deteriorate. The different non-uniform collection conditions of the cartridge units ultimately lead to differences in the regeneration life of individual cartridge units, resulting in some unnecessary unit replacement processes during module operation.

In addition, since the pollution gas containing volatile organic compounds is supplied in the lateral direction as described above, there is a structural disadvantage in that the volatile organic compounds are concentrated on only a part of the filter fibers surrounding the individual cartridge units in the individual cartridge units . This inhomogeneous collecting state of the filter fibers ultimately affects the adsorption capacity and furthermore, the life of the cartridge unit which repeats adsorption and desorption is reduced.

Disclosure of the Invention The present invention has been made to solve the above problems, and its object is to provide a VOC concentrating module installed in a facility for discharging a large amount of volatile organic compounds, such as paint facilities of a shipyard, The present invention provides a volatile organic compound processing system capable of processing a large amount of volatile organic compounds and ensuring process continuity, by allowing a plurality of VOCs concentration modules to be manufactured and dispatched by layering them.

In addition, individual VOCs concentration modules can uniformly adsorb volatile organic compounds on all cartridge units in the module, and adsorb the volatile organic compounds uniformly on all directions of the filter fibers surrounding the individual cartridge units, thereby improving the overall adsorption performance of the VOCs concentration module It is another object of the present invention to provide a filter arrangement device applied to a VOCs concentration module of a volatile organic compound processing system capable of increasing the operating efficiency of the system by matching the regeneration life of the cartridge unit in the module.

According to the present invention, there are provided a plurality of VOCs concentration modules for collecting and processing volatile organic compounds; A storage tower for storing the VOCs concentration modules arranged vertically and horizontally to accommodate the VOCs concentration modules; An ascending / descending tower which can move the ascending / descending body in the left / right direction and stores the individual concentrated modules dispatched from the receiving tower as an ascending / descending body and vertically transporting; And a stacking table for receiving individual VOCs concentration modules from the elevating tower and placing them on the ground; Wherein the VOCs concentration module comprises: a first connection part for supplying a pollutant gas containing a volatile organic compound; And the volatile organic compound is adsorbed through the filter fiber of the internal cartridge unit by desorbing the volatile organic compound by the temperature change of the cartridge unit to concentrate the volatile organic compound concentration of the internal pollutant gas, Lt; / RTI > A second connection part for receiving and discharging the polluted gas whose concentration of the volatile organic compound is controlled from the reaction part; And a filter array device for rotating the cartridge unit in the reaction unit during the adsorption of volatile organic compounds in the cartridge unit; The VOCs concentration module includes a VOCs concentration module.

Preferably, the reaction part has an upper first space connected to the first connection part, a second space divided by the partition space by the partition wall and in which the cartridge units are installed, And a third space communicating with the second space and communicating with the second connection unit, the cartridge unit having an upper portion fitted into the partition wall and communicating with the first space, and a lower portion closed and wound on the side The second space and the third space are passed through the filter fiber, and the filter arranging device includes: a revolving plate formed on the partition wall; A plurality of revolving plates rotatably coupled to the circumferential edge region of the revolving plate and inserted into the standing up state of the cartridge unit to seat the top of the cartridge unit; A satellite gear portion coupled to a lower portion of the rotation plate and having a gear formed along an outer periphery thereof; A center gear portion coupled to the lower surface of the revolving plate so as to be horizontally rotatable and having a gear engaged with the gear of the satellite gear portion along the outer periphery; A driving rotation shaft to which an upper portion is coupled to a lower surface of a center axis position of the revolving plate; A driven gear portion coupled to a lower portion of the driving rotation shaft and coupled to the upper surface of the communication wall so as to be rotatable in a horizontal direction, A driving gear portion having a gear engaged with the gear of the driven gear portion along an outer periphery thereof; And a driving unit for providing rotational force to the driving gear unit. And a control unit.

Preferably, the revolving plate is divided into a first space and a second space, and is coupled to the partition wall so as to be horizontally rotated. The revolving plate is disposed in a circumferential direction on a top edge region of the revolving plate, The driven gear portion engaged with the gear is rotated according to the rotation of the drive gear portion and the rotational force is transmitted to the idler through the drive rotation shaft A plurality of cartridge units disposed on the idler plate are revolved around a driving rotary shaft and a central gear portion coupled to a lower surface of the idler plate is rotated together with the revolving plate, The rotation of the rotating plate is rotated by the rotation of the satellite gear portion which is meshed with the gear according to the rotation of the rotor, And the individual cartridge unit being rotated rotates around the magnetic center axis.

Preferably, a groove-shaped rail is formed on an upper surface of the communication wall so as to correspond to a revolution track of the cartridge unit, and a guide rod having a distal end inserted into the rail is coupled to a lower portion of the cartridge unit.

Preferably, the rails are filled with a plurality of balls between adjacent guide rods.

According to the present invention, a plurality of VOCs concentrating modules installed in a facility for discharging large-scale volatile organic compounds such as coating facilities of a shipyard and capable of mounting individual VOCs concentration modules capable of treating volatile organic compounds, It is possible to treat volatile organic compounds with a large capacity and the treatment continuity can be ensured.

It is possible to drastically reduce the site area for disposing the VOCs concentration module by accommodating the individual VOCs concentration modules in the storage towers in which the storages are arranged in the vertical direction and the back and forth direction.

In addition, the VOCs concentration module, which has been adsorbed, is delivered from the storage tower to the ground via the elevator, transferred to the treatment facility by the transfer means, discharged into the storage tower in the reverse order, and a small number of VOCs Can also cover large-scale pollutant gas exhaust facilities and ensure continuity in the treatment of volatile organic compounds.

In particular, individual VOC concentration modules can adsorb volatile organic compounds uniformly on all cartridge units in the module, and adsorb the volatile organic compounds homogeneously on all directions of the filter fibers surrounding the individual cartridge units, thereby improving the overall adsorption performance of the VOCs concentration module It is possible to increase the operating efficiency of the system by matching the reproduction life of the cartridge unit in the module to the same.

1 is a schematic diagram for explaining a volatile organic compound processing system according to an embodiment of the present invention.
2 is a view for explaining a volatile organic compound processing system according to an embodiment of the present invention.
3 is a view for explaining a VOCs concentration module according to a first embodiment of a volatile organic compound processing system.
4 is a view for explaining a process of adsorbing and desorbing volatile organic compounds in a VOCs concentration module.
5 is a view for explaining an example of a cartridge unit applied to the present invention.
6 is a view for explaining a VOCs concentration module and a filter arrangement device applied to the VOCs concentration module according to a second embodiment of the present invention.
7 is a perspective view for explaining the filter arraying apparatus of FIG.
8 is a perspective view for explaining the gear arrangement in the idle plate of Fig. 7;
9 is a partial cross-sectional view for explaining the filter arraying apparatus of Fig.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. First, it should be noted that the same components or parts among the drawings denote the same reference numerals whenever possible. In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted so as not to obscure the subject matter of the present invention.

The volatile organic compound processing system according to the present invention can be installed and operated in a facility for discharging pollutant gas containing volatile organic compounds (VOCs), particularly in a facility for discharging a large amount of volatile organic compounds such as painting equipment of a shipyard.

This volatile organic compound treatment system disposes of separate VOCs concentration modules for adsorbing and desorbing volatile organic compounds in multi-layer towers to treat the pollutant gases discharged from the pollutant discharge ducts of the facility individually, thereby treating large amounts of volatile organic compounds .

In addition, a plurality of VOCs concentration modules arranged in the multi-layer towers can be quickly loaded and unloaded according to operating conditions to ensure continuity of volatile organic compound treatment.

FIG. 1 is a schematic diagram for explaining a volatile organic compound processing system according to an embodiment of the present invention, and FIG. 2 is a view for explaining a volatile organic compound processing system according to an embodiment of the present invention.

The volatile organic compound treatment system shown in FIGS. 1 and 2 can be installed in a large area of a large-scale VOCs discharge facility, but can be installed with a small area, and at the same time, has a large capacity of continuously treating VOCs It is designed to be equipped.

1 and 2, the system for treating volatile organic compounds according to the present invention is a system for treating volatile organic compounds in volatile organic compounds (VOCs) discharged from a pollutant gas exhaust facility 100, A plurality of VOCs concentration modules 200 for collecting and treating organic compounds and storage compartments for accommodating the VOCs concentration modules 200 are arranged in the vertical direction and the back and forth direction to accommodate the VOCs concentration modules 200 A tower 300 and a lifting and lowering tower 430 which can move in the left and right direction and accommodate the individual concentration modules 200 discharged from the receiving tower 300 in the ascending and descending members 430, A stacking unit 500 for receiving the individual VOCs concentration module 200 from the lift tower 400 and placing the VOCs concentration module 200 on the ground and collecting the individual VOCs concentration module 200 from the stacking unit 500 Transfer Is associated with an individual VOCs concentration module 200 transported by the transmission means 600 and the conveying means 600 can comprise a treatment facility 700 for removing a volatile organic compound. In the above description, the VOCs concentration module 200 adsorbing the volatile organic compounds is discharged from the storage tower 300 and transferred to the treatment facility 700. However, when the process is completed, The concentration module 200 is moved to the stacking table 500 again by the conveying means 600 and is raised and lowered through the elevating tower 400 so as to be housed in a proper storage tray of the storage tower 300.

In the present invention, the VOCs concentration module 200 for volatile organic compounds (VOCs) concentrates the volatile organic compounds in the internal cartridge unit by introducing the polluted gas discharged from the pollutant gas exhaust facility, concentrates the volatile organic compounds in the polluted gas, And then discharged and discharged to a filter side (for example, a regenerative combustion device represented by the treatment facility 700 or a biofilter) for removing actual volatile organic compounds.

Actually, the VOCs concentration module 200 means the number of the cartridge units is the treating ability of the volatile organic compounds. It is true that there is not a big problem because there is not a large amount of volatile organic compounds to be processed even if the VOCs concentration module 200 is miniaturized or installed and operated only in the automobile maintenance field where the small capacity intermittent painting work is performed.

However, in the case of a shipbuilding painting facility that performs coating and drying operations for numerous pieces of equipment, it is difficult to cover the volatile organic compound processing capacity with only one VOCs concentration module 200. In the shipyard painting facility, not only the paint mist that is scattered during painting but also the solvent of the paint is evaporated into the air during drying of the painted equipment, so that various volatile organic compounds such as toluene are contained in the air inside the painting room. It is relatively easy to have a dedicated volatile organic compound treatment facility. However, in case of shipbuilding equipment requiring large capacity of continuous treatment, most volatile organic compound treatment facilities are not equipped with a proper site, , The cost of pollution abatement facilities increases and the site for large-scale treatment facilities must be secured. Therefore, most of the volatile organic compounds are not disposed of, for example, by installing an abatement treatment facility .

The present invention proposes a volatile organic compound processing system capable of treating a polluted gas with only a limited number of VOCs concentration modules in accordance with the reality of such a shipyard coating facility. That is, the individual VOCs concentration modules 200 are accommodated in the storage tower 300 in which the storages are arranged in the vertical direction and the left-and-right direction, so that the site area for the arrangement of the VOCs concentration module 200 can be drastically reduced. The VOCs concentration module 200 having been already adsorbed is discharged from the storage tower 300 to the ground via the lift tower 400 and transferred to the treatment facility 700 using the transfer means 600 to discharge the volatile organic compounds A small number of VOCs concentration modules 200 can cover a large-scale pollutant gas exhaust facility 100 and can ensure continuity in the treatment of volatile organic compounds by putting them in the storage tower 300 in reverse order Will be.

First, the polluted gas exhaust system 100 discharges polluted gas including volatile organic compounds (VOCs) through the duct 110. The duct 110 is connected to the distributor 120 and the distributor 120 supplies the pollution gas including the volatile organic compound to the individual concentration module 200 through the plurality of supply pipes 130.

The pollutant gas exhaust facility 100 may be any facility that exhausts pollutant gas including volatile organic compounds, and may be a facility requiring a large capacity of continuous processing capability for a volatile organic compound, such as a painting facility of a shipyard .

The storage tower 300 connects the vertical frame 310 and the horizontal frame 320 vertically and horizontally to form storage compartments in which the VOCs concentration modules 200 can be housed, A plurality of storages are arranged in a row in the left-right direction (Y-axis direction), and a plurality of storages are arranged in a row in the left-right direction and the storages are connected in a vertical direction The body is configured so that the heights are arranged vertically and horizontally. As an example, FIG. 1 shows a configuration in which three storage compartments are connected to the right and the left, and three storage compartments are connected to the upper and lower storage compartments.

The VOCs concentration module 200 is placed on the horizontal frame 320 connected in the forward and backward direction (X-axis direction) of the horizontal frames constituting the storage compartment. The horizontal frame 320 is provided with a plurality of rollers 331 capable of transporting the VOCs concentration module 200 mounted on the upper portion in the forward and backward direction (X axis direction) by rotation and a plurality of rollers 331 A plurality of horizontal chains 332 are provided. For example, the horizontal chain 332 links the two adjacent rollers 331 and orbitally moves by the rotational force of a motor (not shown), thereby rotating the rollers 331 connected to the horizontal chain 332 The VOCs concentration module 200 can be configured to be transported in the forward and backward directions (X-axis direction).

On the other hand, an elevating tower 400 is connected to the rear end of the receiving tower 300 in the X-axis direction.

The lifting and lowering tower 400 connects the vertical frame 410 and the horizontal frame 420 longitudinally and laterally to connect the vertical frame 410 and the horizontal frame 420 vertically and horizontally to correspond to the length of the storage tower 300 in the left- And a lifting body 430 which can be moved in the left-right direction (Y-axis direction) is built in the body.

The lifting and lowering member 430 connects the vertical frame 431 and the horizontal frame 432 vertically and horizontally to form a body corresponding to the storage boxes arranged in an upper row and a lower row of the storage tower 300, A lift tray 433 which can be moved in the vertical direction (Z-axis direction) is incorporated.

In order to move the elevating body 430 in the left-right direction (Y-axis direction) as a whole, a roller 440 is continuously provided in the lower portion of the elevating body 430 in the left-right direction (Y-axis direction). The roller 440 is rotated by the rotational force of a motor (not shown) to transfer the elevator 430 in the left-right direction (Y-axis direction). Therefore, the lifting bodies 430 can be disposed adjacent to the storage tanks arranged in a row in the storage tower 300 individually.

An elevator driver 434 is provided on the elevator 430 and the elevator tray 433 is connected to the vertical chain 435 linked to the elevator driver 434. The vertical chain 435 is orbited by the rotational force of the elevating driver 434 so that the elevating tray 433 connected to the vertical chain 435 ascends and descends in the vertical direction (Y axis direction).

Further, the VOCs concentration module 200 is transferred from the storage tower 300 onto the lifting tray 433. The lifting tray 433 is provided with a plurality of rollers 433a capable of transporting the VOCs concentration module 200 placed on the top in the forward and backward direction (X-axis direction) by rotation and a plurality of rollers 433a A plurality of horizontal chains 433b are provided. For example, the horizontal chain 433b links the two adjacent rollers 433a and orbitally moves by the rotational force of a motor (not shown), and the rollers 433a connected to the horizontal chain 433b rotate The VOCs concentration module 200 can be configured to move in the front-back direction (X-axis direction).

That is, the elevator 430 can move in the left-right direction (Y-axis direction) in the elevator tower 400 and the elevator tray 433 inside the elevator 430 can move up and down in the elevator 430 (In the Y-axis direction), the lifting tray 433 can be disposed adjacent to all the housings of the housing tower 300 and can receive the VOCs concentration module 200 from the housings .

On the other hand, a loading table 500 is connected to the rear end of the lifting tower 400 in the X-axis direction.

The stacking table 500 may include a stacking plate 530 formed at a predetermined height on the ground and a rotating tray 510 coupled to an upper portion of the stacking plate 530.

The VOCs concentration module 200 housed in the loading table 500 can be transported in the same manner as a forklift truck, Can be transferred to the processing facility 700 for removing the volatile organic compounds by the means.

The VOCs concentration module 200 is transferred from the lift tray 433 of the lift tower 400 to the rotary tray 510. The rotary tray 510 is provided with a plurality of rollers 511 capable of transporting the VOCs concentration module 200 mounted thereon in the forward and backward directions (X-axis direction) by rotation and a plurality of rollers 511 A plurality of horizontal chains 512 are provided. For example, the horizontal chain 512 connects the two adjacent rollers 511 and orbitally moves by the rotational force of a motor (not shown), and the rollers 511 connected to the horizontal chain 512 rotate The VOCs concentration module 200 can be configured to move in the front-back direction (X-axis direction).

Here, the loading plate 530 may be provided with a rotation hole 520 for rotating the rotation tray 510 by itself. Even in the case of the minimized modular processing system, the existing idle site is provided as an installation site rather than a separate large dedicated space. Therefore, in many cases, the transfer means (forklift, for example) for approaching to the stacking table 500 to which the VOCs concentration module 200 is finally delivered and placed is difficult to approach in a desired direction (for example, the X axis direction).

When the external force is applied to the rotation tray 510, the rotation tray 520 functions to smoothly rotate the rotation tray 510 according to the external force. Here, the external force may be a rotational force, and may be directly applied to the rotary tray 510 or indirectly applied to the rotary shaft 520 to rotate the rotary tray 510 itself.

Thus, the transport means will be able to access the VOCs enrichment module 200 sufficiently even if only one direction is allowed by the facility arrangement among the many approach directions accessible for transport to the stand 500.

3 is a view for explaining a VOCs concentration module according to a first embodiment of a volatile organic compound processing system.

Referring to FIG. 3, the VOCs concentration module 200 according to the embodiment of the present invention includes a first connection part 210 and a second connection part 270 which are connected to an external pipe and can receive or exhaust gas, And a reaction unit 220 for absorbing the volatile organic compound through the filter fiber 232 surrounding the inner cartridge unit 230 and desorbing and discharging the volatile organic compound due to the temperature change of the cartridge unit 230 Lt; / RTI >

In the present invention, the VOCs concentration module 200 may operate in various modes, such as an adsorption mode, a desorption mode, and a pretreatment mode according to operating conditions.

In the adsorption mode, the volatile organic compound is adsorbed from the polluted gas by the operation of adsorbing the volatile organic compound into the internal cartridge unit 230 by flowing the polluted gas discharged from the polluted gas discharge facility. Through this adsorption mode, the VOCs concentration module 200 will be able to operate as a filter for volatile organic compounds.

In the desorption mode, the volatile organic compounds adsorbed in the internal cartridge unit 230 are desorbed by the adsorption mode and are discharged to the outside. The discharged volatile organic compounds are discharged to the filter side (for example, A regenerative combustion device or a biofilter). Through this desorption mode, the VOCs enrichment module 200 will be able to operate as a reservoir for volatile organic compounds.

The pretreatment mode is installed and operated on the front side of a filter device for removing volatile organic compounds in a facility for discharging pollution gas containing volatile organic compounds, and the volatile organic compounds in the polluted gas The compound is concentrated and allowed to exit at a constant concentration.

The first connection part 210 may be connected to the pollutant gas exhaust port of the pollutant gas exhaust facility 100 to supply the pollutant gas to the reaction part 220 or may be supplied with the volatile organic compound The purified air may be discharged by the adsorption or the reaction unit 220 may discharge the polluted gas whose concentration of the volatile organic compound is adjusted to the target concentration concentration.

The second connection unit 270 is connected to the pollutant gas outlet of the pollutant gas exhaust unit 100 to supply the pollutant gas to the reaction unit 220 or to adsorb the volatile organic compound by the reaction unit 220 Or the pollutant gas whose concentration of the volatile organic compound is adjusted to the target concentration concentration by the reaction unit 220 may be discharged.

Therefore, the first connection part 210 may operate as an air intake part for absorbing the polluted gas or as an exhaust part for exhausting the purified air. Likewise, the second connection part 270 may operate as an air intake part for drawing in the polluted gas or as an exhaust part for exhausting the purified air.

The first valve 211 and the second valve 271 for introducing the polluted gas into the reaction part 220 and discharging the polluted gas to the outside of the reaction part 220 are connected to the first connection part 210 and the second connection part 270, Will be installed.

The first valve 211 is installed in the first connection part 210 and operates according to the control of the control part to open and close the first connection part 210. The second valve 271 is installed in the second connection part 270 and operates according to the control of the control part to open and close the second connection part 270.

Although the first valve 211 is shown in the first connection part 210 and the second valve 271 is shown in the second connection part 270 in the drawings and the above description, It is also possible that the first valve 211 and the second valve 271 are installed at the connection portion with the first connection part 210 and the second connection part 270 in the reaction part 220, Any position can be used as long as it can be sucked in or exhausted from the internal gas.

The reaction unit 220 has an internal space through which the contaminant gas can be sucked and / or desorbed from the first connection unit 210 or the second connection unit 270, The organic compound is adsorbed or desorbed and exhausted through the first connection part 210 or the second connection part 270.

The reaction unit 220 may include a first space A communicating with the first connection unit 210 by the partition wall 221 and a second space B including the lower cartridge unit 230 And the second space (B) and the third space (C) communicate with each other. That is, the wall dividing the second space B and the third space C has a plurality of communication holes, and the second space B and the third space C communicate with each other. Here, the third space C will be in communication with the second connection portion 270.

The reaction unit 220 includes a cartridge unit 230 for adsorbing volatile organic compounds from the polluted gas through the filter fiber 232 wound on the partition wall 221 and wound around the compartment 230, A thermocouple 233 for measuring the temperature of each of the cartridge units 230, and a control unit 240 for controlling the temperature of the reaction unit 220, And a concentration measuring unit 260 for measuring the concentration of the volatile organic compound in the pollutant gas in the reaction unit 220.

Here, the cartridge unit 230 is coupled to the upper portion of the communication hole 222 of the partition wall 221. The upper portion of the cartridge unit 230 is opened while the lower portion thereof is closed so that the upper opening portion of the cartridge unit 230 is in communication with the upper space of the reaction portion 220. Since the lower portion of the cartridge unit 230 is clogged, the cartridge unit 230 can be vented to the outside through the filter fiber 232 wrapped around the side of the cartridge unit 230. As a result, And communicates with the lower space.

4 (a), the polluted gas in the adsorption mode of the VOCs concentration module 200 is supplied to the third space C of the reaction part 220 through the second connection part 270 And then moved to the second space B. The pollutant gas moves into the interior of the cartridge unit 230 through the filter fiber 232 of the cartridge unit 230 and is discharged through the upper first communication hole 222 partitioned along the open upper communication hole 222 of the cartridge unit 230 It will be moved to the space (A). At this time, the filter fibers 232 of the cartridge unit 230 will adsorb the volatile organic compounds from the polluted gas.

Then, the cartridge unit 230 adsorbing the volatile organic compound is heated according to the supply of the electric current, and the cartridge unit 230 having the increased temperature will desorb the adsorbed volatile organic compound.

4 (b), in the detachment mode of the apparatus for moving and desorbing volatile organic compounds, the outside air flows through the first connection part 210 into the partitioned first space 210 of the reaction part 220, And the supplied external air is moved to the lower second space B along the opened upper communication hole 222 of the cartridge unit 230. [ At this time, the heated cartridge unit 230 desorbs the volatile organic compound that has been adsorbed, and the polluted gas containing the desorbed volatile organic compound will be exhausted along the second connection part 270.

Meanwhile, in the inner space of the reaction unit 220, a plurality of cartridge units 230 are inserted into the partition wall 221 and are mounted thereon. The densities of the cartridge units 230 can be adjusted through the arrangement of the cartridge units 230, and the respective cartridge units 230 are preferably spaced apart from each other.

The cartridge unit 230 may include a heat transfer resistive frame 231 having a certain space therein and a filter fiber 232 wound around the heat transfer resistive frame 231.

Accordingly, the filter fiber 232 is a filter capable of adsorbing and desorbing volatile organic compounds according to air movement.

5 is a view for explaining an example of a cartridge unit according to an embodiment of the present invention.

A power supply connection part (not shown) of a conductive material may be provided at the upper and lower ends of the heat transfer resistance frame 231 to connect the power supply line 240. In this heat transfer structure, when a current is supplied through the power line 240, the heat resistance frame 231 may be heated according to the amount of current to control the temperature of the filter fiber 232. Here, the heat conductive resistance frame 231 is preferably a mica board as a resistance material for electric current, but any material can be used as long as it is a heat resistant material. As shown in FIG. 5, the heat transfer resistive frame 231 includes two or more vertical ribs formed in a plate shape and arranged parallel to each other between the power connection portions in a state where the surfaces of the plates are opposed to each other. The power supply line 240 is connected to the heat transfer resistance frame 231 so that the heat transfer resistance frame 231 is connected to the heat transfer resistance frame 231 according to the current supply, The temperature of the filter fiber 232 is controlled.

The filter fiber is preferably an activated carbon fiber (ACF). This activated carbon fiber is a fibrous adsorbent, fibrous activated carbon made by burning and reviving natural fiber, artificial organic material, and chemical fiber as a carrier. It has a higher adsorption capacity than powder or granular activated carbon and can be easily regenerated at a high temperature, thus having a long lifetime and lower maintenance cost than general activated carbon. Particularly, it is suitable as an adsorbent material for volatile organic compounds (VOCs) such as the present invention because of its large surface area, large adsorption capacity, fast adsorption and desorption rates, and excellent releasability. The filter fiber 232 is wound and fixed several times on the heat transfer resistance frame 231 and can receive the temperature as it is heated by the heat transfer resistance frame 231.

As shown in FIG. 5, the heat-resistant frame 231 may have a plurality of ribs formed in a lattice structure to ensure firmness and sufficiently transmit heat to the internal flow space and the filter fibers 232 .

The temperature measuring unit 250 is a unit for measuring the temperature of the cartridge unit 230 and is preferably provided in the reaction unit 220 to detect the temperature of the cartridge unit 230 in the reaction unit 220, Type Infrared Thermometer.

The thermocouple 233 is installed in each of the cartridge units 230 to separately measure the current temperature of the cartridge unit 230.

The concentration measuring device 260 is configured to measure the concentration of the volatile organic compound in the pollutant gas in the reaction part 220.

The volatile organic compound of the polluted gas that is sucked in the reaction part 220 will be adsorbed to the filter fiber 232 of the cartridge unit 230. When a current is applied by the power line 240 to increase the temperature of the cartridge unit 230, the volatile organic compounds adsorbed on the filter fibers 232 are desorbed. As the temperature is higher, Lt; / RTI > Therefore, it is possible to control the desorption amount of the volatile organic compound through the temperature control of the cartridge unit 230, and as a result, the concentration of the volatile organic compound in the pollutant gas in the reaction part 200 can be controlled in the above- will be. Particularly, the concentration of the volatile organic compound in the pollutant gas in the reaction part 200 can be controlled to a predetermined target concentration, and the control to the target concentration concentration will be performed by controlling the operation of the reaction part 200.

Meanwhile, in the individual VOCs concentration module 200, the inner cartridge unit 230 winds and fixes the filter fiber 232 several times along the outer surface of the heat transfer resistive frame 231. Since the lower portion of the cartridge unit 230 is clogged, So that the volatile organic compound can be adsorbed on the filter fiber 232. As a result,

However, in the structure of the VOCs concentration module 200 as shown in FIG. 3, the polluted gas containing volatile organic compounds is supplied in a lateral direction through one first connection part 210 provided on the side, The volatile organic compounds are concentrated on the cartridge units in the vicinity of the first connection part 210 without collecting the volatile organic compounds evenly on the plurality of long cartridge units 230. [

This uneven collecting state of the cartridge units 230 eventually results in unnecessary power wastage because heating is performed on the heat-resistant resistive frame 231 based on the multi-collecting cartridge unit for complete desorption in the desorption process. Moreover, such unnecessary heating may cause the durability of the cartridge unit 230 to be weakened. The different non-uniform collection states of the cartridge units 230 ultimately lead to differences in the reproduction life of the individual cartridge units, resulting in some unnecessary unit replacement processes during module operation.

Since the contaminant gas containing the volatile organic compound is supplied in the lateral direction as described above, only the volatile organic compound in the individual cartridge unit 230, on some of the filter fibers 232 surrounding the individual cartridge unit 230, But also has structural drawbacks that are concentratedly adsorbed. This inhomogeneous collecting state of the filter fibers 232 eventually affects the adsorption capacity and furthermore, the life of the cartridge unit 230 which repeats adsorption and desorption is reduced.

Therefore, in order to compensate for the disadvantages of the uneven adsorption state between the cartridge units and the heterogeneous adsorption state of the filter fibers in the individual cartridge unit, the present invention is characterized in that the cartridge units 230 in the VOCs concentration module 200 are revolved The frequency of exposing the volatile organic compounds to each cartridge unit 230 is equalized to induce a uniform adsorption state between all the cartridge units 230 and the cartridge unit 230 is rotated to rotate the cartridge unit 230 A filter capable of uniformly adsorbing the entire filter fiber 232 to enhance the overall adsorption performance of the VOCs concentration module 200 and to improve the operating efficiency of the system by matching the regeneration life of the cartridge unit 230 in the module Array device.

6 is a view for explaining a VOCs concentration module and a filter arrangement device applied to the VOCs concentration module according to a second embodiment of the present invention, FIG. 7 is a perspective view for explaining the filter array device of FIG. 6, 8 is a perspective view for explaining the gear arrangement in the idle plate of Fig. 7, and Fig. 9 is a partial cross-sectional view for explaining the filter arraying apparatus of Fig.

Referring to FIGS. 6 to 9, the VOCs concentration module 200 according to the second embodiment of the present invention includes a first connection part 210 connected to an external pipe to receive polluted gas, A reaction part 220 for adsorbing the volatile organic compound through the filter fiber 232 surrounding the unit 230 and desorbing the volatile organic compound by the temperature change of the cartridge unit 230, The reaction unit 220 includes an upper first space A communicating with the first connection unit 210 by the partition wall 221 and a cartridge unit 230 located below the first space A. [ And the second space B and the third space C are communicated with each other. The reaction unit 220 incorporates a cartridge unit 230 for adsorbing volatile organic compounds from the polluted gas through the filter fiber 232 wound around the partition wall 221 and wound around the cartridge unit 230, The upper part of the partition wall 221 is engaged. In FIG. 6, the illustration of the power supply line, the temperature measuring instrument, the thermocouple, the concentration measuring instrument and the like is omitted for convenience of explanation.

In the VOCs concentration module 200 according to the second embodiment of the present invention, the filter array device arranges the cartridge units 230 in a circular shape in the reaction part 220 and the circularly arranged cartridge units 230 in the reaction part 220 and at the same time rotate each individual cartridge unit 230 about its own central axis. That is, the filter array device can rotate the cartridge unit 230 while rotating it.

The filter array device includes an orbiting plate 221a formed in the partition wall 221 and a cartridge unit 230 rotatably coupled to a circumferential edge region of the orbiting plate 221a, A plurality of revolving plates 235 for receiving the upper portion of the cartridge unit 230, a satellite gear portion 930 coupled to the lower portion of the revolving plate 235 and having gears formed along the outer periphery thereof, A center gear portion 920 coupled to the lower surface of the revolving plate 221a so as to be horizontally rotatable and having a gear engaged with the gear of the satellite gear portion 930 along the outer periphery thereof, A driving rotation shaft 913 to which the upper portion is coupled and a lower portion of the driving rotation shaft 913 so as to be horizontally rotatable on the upper surface of the communication wall 950 for separating the second space B from the third space C. A driven gear portion 912 having a gear formed along the outer periphery thereof, A driving gear portion 911 formed along the outer periphery of a gear engaged with the gear of the gear portion 912 and a driving portion 910 providing rotation force to the driving gear portion 911.

The revolving plate 221a is coupled to the partition wall 221 so as to divide the first space A and the second space B as a part of the partition wall 221 and to horizontally rotate . A plurality of revolving plates 235 are arranged in the circumferential direction on the upper surface edge region of the revolving plate 221a.

The revolving plate 235 is coupled to the revolving plate 221a so as to allow the individual cartridge unit 230 to stand in a standing state while being horizontally rotated.

The cartridge units 230 arranged in the circumferential direction in the edge region of the revolving plate 221a revolve around the center axis (driving rotation axis) of the revolving plate 221a in accordance with the rotation of the revolving plate 221a. Also, the individual cartridge unit 230 rotates about the self-centering axis in accordance with the rotation of the rotation plate 235.

A drive unit 910 such as a motor rotates the drive gear unit 911 to provide a rotational force for rotating the revolving plate 221a and the rotation plate 235. [

The driven gear portion 912 engaged with the gear is rotated according to the rotation of the driving gear portion 911 and is transmitted to the revolving plate 221a through the driving rotation shaft 913 as it is, . Therefore, the plurality of cartridge units 230 arranged in the idler plate 221a will revolve around the driving rotary shaft 913. [

The center gear portion 920 coupled to the lower surface of the revolving plate 221a is rotated together with the rotation of the idler plate 221a and the planet gear portion 920, 930 are rotated, and the rotation force is transmitted to the rotation plate 235 as it is to rotate the rotation plate 235. Therefore, the individual cartridge unit 230 mounted on the rotation plate 235 will rotate around the magnetic center axis.

Therefore, although the contaminated gas supplied to the inside of the module through the first connection unit 210 is supplied only in one lateral direction, since all the cartridge units 230 revolve, all the cartridge units in the module are uniformly So that the volatile organic compound can be adsorbed.

Since the individual cartridge unit 230 rotates, the filter fibers 232 surrounding the individual cartridge unit 230 are uniformly dispersed in all directions in the direction of the volatile organic compound The compound can be adsorbed.

As a result, the cartridge units 230 in the VOCs concentration module 200 are revolved so that the frequency of exposing the volatile organic compounds to each cartridge unit 230 is equalized by the movement of the cartridge units 230, thereby inducing a uniform adsorption state between all the cartridge units 230 The cartridge unit 230 is rotated to homogeneously attract all the surfaces of the filter fibers 232 wrapping the cartridge unit 230 by self rotation so as to increase the total adsorption performance of the VOCs concentration module 200, The operating life of the system 230 can be made equal to the operating life of the system.

On the other hand, the revolving and revolving movement of the physical cartridge unit 230 adds a large rotational force to the cartridge unit 230, which must maintain the standing posture in the reaction part 220. In other words, since the upper portion of the cartridge unit 230 is fixed to the rotation plate 235, it is possible to reduce the revolution and the rotational movement by itself. However, since the lower portion of the cartridge unit 230 is free, And the standing posture is shifted due to accumulation. The cartridge unit 230 detaches the volatile organic compound adsorbed through the electric heating after the adsorption. In this process, if the lower portions of the cartridge units 230 are in contact with each other, electrical contact can be invited, which is extremely dangerous.

For this reason, a groove-shaped rail 951 is formed on the upper surface of the communication wall 950 so as to correspond to the orbit of the cartridge unit 230, and a distal end of the rail 951 The guide bar 236 is inserted into the guide bar 236. [

The upper portion of the cartridge unit 230 is fixed to the rotation plate 235 and the lower portion thereof is restrained to the rail 951 through the guide rod 236 so that the lower portions of the cartridge units 230 contact each other The situation will be blocked.

At this time, the rails 951 may be filled with a plurality of balls 952 in order to better block the adjacent cartridge units 230, that is, the cartridge units 230, which are in a relation to each other in the orbiting motion.

The upper part of the cartridge unit 230 is already fixed to the rotation plate 235 so that the upper part of the cartridge unit 230 can not be contacted. The balls 952 are filled between the guide rods 236 adjacent to each other so that the gap between the adjacent guide rods 236 is kept constant so that the adjacent cartridge units 230 are not in contact with each other while the guide rods 236 revolve. The number of the balls 952 filled between the guide rods 236 adjacent to each other may be adjusted so that the contact between the cartridge units 230 that can be performed in the course of the rotation of the cartridge unit 230 is also blocked.

As described above, an optimal embodiment has been disclosed in the drawings and specification. Although specific terms have been employed herein, they are used for purposes of illustration only and are not intended to limit the scope of the invention as defined in the claims or the claims. Therefore, those skilled in the art will appreciate that various modifications and equivalent embodiments are possible without departing from the scope of the present invention. Accordingly, the true scope of the present invention should be determined by the technical idea of the appended claims.

100: Pollution gas exhaust facility 200: VOCs concentration module
300: storage tower 400: lifting tower
500: stacking table 600: conveying means
700: Treatment facility

Claims (5)

A plurality of VOCs concentration modules for collecting and processing volatile organic compounds;
A storage tower for storing the VOCs concentration modules arranged vertically and horizontally to accommodate the VOCs concentration modules;
An ascending / descending tower which can move the ascending / descending body in the left / right direction and stores the individual concentrated modules dispatched from the receiving tower as an ascending / descending body and vertically transporting; And
A stacking table for receiving individual VOCs concentration modules from the lift tower and arranging them on the ground; In the volatile organic compound processing system,
The VOCs concentration module,
A first connection part for supplying a pollution gas containing a volatile organic compound;
And the volatile organic compound is adsorbed through the filter fiber of the internal cartridge unit by desorbing the volatile organic compound by the temperature change of the cartridge unit to concentrate the volatile organic compound concentration of the internal pollutant gas, Lt; / RTI >
A second connection part for receiving and discharging the polluted gas whose concentration of the volatile organic compound is controlled from the reaction part; And
A filter array device for rotating the cartridge unit in the reaction part in the process of adsorbing volatile organic compounds in the cartridge unit; Wherein the VOCs concentrate module comprises:
The method according to claim 1,
The reaction unit may include a first upper space connected to the first connection unit, a second space divided from the first space by the partition wall, in which the cartridge units are installed, and a second space communicated with the second space, And a third space connected to the second connection portion,
The cartridge unit is communicated with the first space through an upper portion of the partition wall, the lower portion is closed, and the second space and the third space are ventilated through the filter fiber wound on the side,
The filter array device includes:
A revolving plate formed on the partition wall;
A plurality of revolving plates rotatably coupled to the circumferential edge region of the revolving plate and inserted into the standing up state of the cartridge unit to seat the top of the cartridge unit;
A satellite gear portion coupled to a lower portion of the rotation plate and having a gear formed along an outer periphery thereof;
A center gear portion coupled to the lower surface of the revolving plate so as to be horizontally rotatable and having a gear engaged with the gear of the satellite gear portion along the outer periphery;
A driving rotation shaft to which an upper portion is coupled to a lower surface of a center axis position of the revolving plate;
A driven gear portion coupled to a lower portion of the driving rotation shaft and coupled to the upper surface of the communication wall so as to be rotatable in a horizontal direction,
A driving gear portion having a gear engaged with the gear of the driven gear portion along an outer periphery thereof; And
A driving unit for providing rotational force to the driving gear unit; Wherein the VOCs concentrate module comprises:
3. The method of claim 2,
The plate is divided into a first space and a second space, and is coupled to the partition wall for horizontal rotation,
The revolving plate is disposed in a circumferential direction on an upper surface edge region of the revolving plate and is coupled to the revolving plate so as to allow the individual cartridge unit to stand in a standing state and to be horizontally rotated,
The driven gear portion engaged with the gear is rotated according to the rotation of the driving gear portion and the rotational force is transmitted to the idler plate through the driving rotary shaft to rotate the idler plate so that the plurality of cartridge units arranged on the idler plate rotate In addition,
The center gear portion coupled to the lower surface of the revolving plate is rotated together with the revolving plate and the satellite gear portion engaged with the gear is rotated according to the rotation of the center gear portion to rotate the rotation plate with the rotation force, Wherein the individual cartridge unit is rotated about a self-centering axis.
The method of claim 3,
Wherein a groove-shaped rail is formed on an upper surface of the communication wall so as to correspond to an orbit of the cartridge unit,
And a guide rod having a distal end coupled to the rail is coupled to the lower portion of the cartridge unit.
5. The method of claim 4,
Wherein a plurality of balls are filled in the rails between adjacent guide rods.

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