KR102058044B1 - Rotation cartridge and system for removing volatility organic compound having the same - Google Patents

Abstract

The present invention is characterized in that it comprises a hub coupled to the rotating shaft, the frame connected to the hub and at least two cell cartridges detachably coupled to the frame, the adsorbent therein.

Description

ROTATION CARTRIDGE AND SYSTEM FOR REMOVING VOLATILITY ORGANIC COMPOUND HAVING THE SAME}

The present invention relates to a volatile organic compound removal system that recovers energy and simultaneously removes harmful components in a method for treating a gas containing harmful components generated in a multi-use facility, an event hall, various manufacturing processes, and an automobile coating process. More particularly, the present invention relates to a volatile organic compound removal system capable of continuous operation, easy regeneration of the adsorbent, and efficient energy recovery.

In general, waste gases generated during semiconductor or LCD production processes are added in photoresists such as volatile organic compounds (VOCs), perfluorinated compounds (PFCs), butyl acetate and 2-ectoethylethyl acetate. Consisting of a mixture of substances, moisture and other foreign substances, ie particles.

Volatile organic compounds are harmful air and odor-causing substances that cause environmental pollution such as smog formation through photochemical reactions, odor generation, and urban ozone concentration increase, along with harmful effects on human body such as respiratory disorder and carcinogenicity. Known as a substance.

Methods for treating volatile organic compounds include adsorption treatment, catalytic thermal oxidation, and thermal storage oxidation.

However, the conventional organic compound treatment technology has a disadvantage in that it is difficult to continuously drive and replacement of the adsorbent is not easy.

In addition, the cartridge containing the conventional adsorbent varies where the cartridge needs to be replaced according to the degree of adsorption of the VOC, and in order to replace the entire adsorbent, the entire container containing the adsorbent must be replaced. There is a problem that becomes difficult.

In addition, when replacing the adsorbent inside the cartridge without replacing the cartridge to replace the conventional adsorbent, there is a disadvantage that dust is generated to contaminate the system, and cleaning is not easy.

The problem to be solved by the present invention is to adsorb and remove volatile organic compounds (hereinafter referred to as VOC) generated in the industrial field, to desorb the concentrated VOC to the adsorbent to regenerate the adsorbent, the desorbed VOC can be decomposed using a catalyst To provide a rotary cartridge and a volatile organic compound removal system.

Another problem to be solved by the present invention is to provide a rotary cartridge and a volatile organic compound removal system that can partially replace the adsorbent deteriorated adsorption force by replacing the cell cartridge requiring the adsorbent according to the degree of VOC adsorption.

Another problem to be solved by the present invention is to provide a rotary cartridge and a volatile organic compound removal system that allows the user to partially replace the cartridge, reducing the weight of each cell cartridge to ensure user convenience.

Another problem to be solved by the present invention is to provide a volatile organic compound removal system that can reduce the energy in the process of adsorption and desorption of the VOC, continuous operation.

The objects of the present invention are not limited to the above-mentioned objects, and other objects that are not mentioned will be clearly understood by those skilled in the art from the following description.

In order to achieve the above object, the present invention is characterized in that the rotary cartridge is removable, and includes a cell cartridge having a space for accommodating the adsorbent therein.

The present invention includes a hub coupled to a rotating shaft, a frame connected to the hub, and at least two cell cartridges detachably coupled to the frame and accommodating an adsorbent therein.

The frame may include a rim disposed to surround the hub, and a plurality of arms connecting the hub and the rim to be spaced apart from each other in the circumferential direction with respect to the rotation axis and supporting at least one end of the cell cartridge. Can be.

The frame further includes a plurality of compartment ribs protruding upward from each of the arms, and a sector area in which the cell cartridges are located between the adjacent compartment ribs may be defined.

The separation distance between the adjacent ribs can be greater as the distance from the hub.

The adjacent partition ribs, the hub and the rim may define the sector area corresponding to the planar shape of one cell cartridge.

Each sector area may have the same shape.

The plurality of compartment ribs may comprise insulation.

Each cell cartridge includes a cell body defining a storage space opened up and down, an upper cover covering an upper portion of the storage space, an upper cover formed with an air flow port, and a lower cover formed with an air flow port, and a lower cover formed with an air flow port. can do.

The upper cover may have a larger width than the cell body.

A portion of the top cover may cover at least a portion of the compartment rib when the cell cartridge is coupled to the frame.

Filling holes may be provided in the cell body.

The present invention also provides a rotary cartridge comprising a plurality of cell cartridges including a hub coupled to a rotating shaft, a frame connected to the hub, and at least two cell cartridges detachably coupled to the frame and accommodating an adsorbent therein. And a driving unit for isolating the cell cartridge to rotate the rotary cartridge such that the plurality of cell cartridges are moved in the order of the adsorption module to which the harmful components are supplied and the desorption module to which the harmful components adsorbed on the adsorbent are desorbed.

The driving unit may rotate the rotary cartridge by a predetermined rotation angle and then rotate to stop for a predetermined time.

The plurality of cell cartridges may have the same shape.

Specific details of other embodiments are included in the detailed description and the drawings.

According to the volatile organic compound removal system of the present invention has one or more of the following effects.

First, the present invention has the advantage that can be continuously driven without discharging to the outside, while effectively removing the VOC generated in the industrial field.

Secondly, the present invention has a structure in which the rotating cartridge circulates the adsorption module and the detachable module, and has a structure that is sealed at a stop, so that it is not necessary to connect a plurality of equipment in parallel for continuous operation, and replace the rotating cartridge. There is also an advantage that does not need to be done.

Third, the present invention also has the advantage of partially replacing the adsorbent is reduced adsorption power by replacing the cell cartridge requiring the adsorbent according to the degree of VOC adsorption.

Fourth, the present invention allows the user to partially replace the cartridge, and also has the advantage of ensuring the convenience of the user by reducing the weight of each cell cartridge.

Fifth, the present invention, even if the adsorption capacity is increased, by adding the number of cell cartridges, it is easy to change the design according to the adsorption capacity, and the number of cell cartridges can be adjusted in consideration of the adsorption and desorption efficiency of the VOC, the optimum efficiency There is an advantage that can be easily implemented.

Sixth, the present invention has the advantage that the energy is reduced because the microwave is used to desorb the adsorbent, re-use the heat generated during the decomposition in the catalyst module, and desorb the harmful components from the adsorbent.

The effects of the present invention are not limited to the above-mentioned effects, and other effects not mentioned will be clearly understood by those skilled in the art from the description of the claims.

1 is a conceptual diagram of a volatile organic compound removal system according to a first embodiment of the present invention.
2 is a cross-sectional view from the top of the volatile organic compound removal system according to the first embodiment of the present invention.
3 is a cross-sectional side view of the volatile organic compound removal system shown in FIG. 2.
4 is another cross-sectional view of the volatile organic compound removal system shown in FIG. 2.
5 is a view showing a rotating cartridge according to the first embodiment of the present invention.
6 is a cross-sectional view of the rotary cartridge shown in FIG. 5.
7 is a view illustrating a cell cartridge separated from the rotating cartridge of FIG. 5.
8 is a view illustrating a frame in which a cell cartridge is removed from the rotating cartridge of FIG. 6.
9 is a perspective view of a cell cartridge according to a first embodiment of the present invention.
FIG. 10 is a cross-sectional view taken along line AA of FIG. 9.
11 is a cross-sectional view illustrating a state in which a detachable duct and a rotating cartridge are in contact with each other according to another embodiment of the present invention.
12 is a view illustrating an upper detachment duct according to an embodiment of the present invention.
13 is a view showing a tackifier according to an embodiment of the present invention.
14 is a cross-sectional view showing a sealing member according to another embodiment of the present invention.
15 is a cross-sectional view showing a sealing member according to another embodiment of the present invention.

Advantages and features of the present invention, and methods for achieving them will become apparent with reference to the embodiments described below in detail in conjunction with the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below, but can be implemented in various different forms, and only the embodiments make the disclosure of the present invention complete, and the general knowledge in the art to which the present invention belongs. It is provided to fully inform the person having the scope of the invention, which is defined only by the scope of the claims. Like reference numerals refer to like elements throughout.

In the drawings, the thickness or size of each component is exaggerated, omitted, or schematically illustrated for convenience and clarity of description. In addition, the size and area of each component does not necessarily reflect the actual size or area.

In addition, the angle and direction mentioned in the process of demonstrating the structure of this invention are based on what was described in drawing. In the description of the structure in the specification, if the reference point and the positional relationship with respect to the angle is not clearly mentioned, reference is made to related drawings.

1 is a conceptual diagram of a volatile organic compound removing system according to a first embodiment of the present invention, FIG. 2 is a cross-sectional view of the volatile organic compound removing system according to a first embodiment of the present invention, and FIG. 3 is shown in FIG. One side cross-sectional view of one volatile organic compound removal system, and FIG. 4 is another cross sectional view of the volatile organic compound removal system shown in FIG.

1 to 4, the volatile organic compound removal system 1 according to an embodiment of the present invention receives an exhaust gas containing harmful components such as VOC and absorbs harmful components contained in the exhaust gas. After adsorption, the purge gas is discharged.

For example, the volatile organic compound removal system 1 according to an embodiment includes an adsorption module 10 and 12 receiving exhaust gas containing harmful components such as VOCs, an adsorption function capable of adsorbing harmful components, and heat storage. A desorption module for desorbing and adsorbing harmful components adsorbed by the adsorbent 71 having a function at the same time, a rotary cartridge 20 having a plurality of cell cartridges partitioned into a plurality of areas and accommodating the adsorbent 71, and adsorbing harmful components. And a driving unit for rotating the rotating cartridge 20.

The volatile organic compound removal system 1 according to an embodiment may further include a microwave generator, a catalyst module 60, and cooling means.

Adsorption modules 10 and 12 are connected to a pollution source to supply exhaust gas, and a space is disposed therein to remove harmful components from the exhaust gas.

For example, the exhaust gas inflow passage 12 and the exhaust gas inflow passage 12 connected to the polluting source for exhausting the exhaust gas are supplied through the exhaust gas inflow passage 12, and a rotating cartridge 20 is provided therein. It may include the adsorption duct 10 is located. The adsorption duct 10 is connected to a purge gas discharge passage 13 through which the purge gas from which noxious components are removed from the adsorption duct 10 is discharged. Adsorption modules 10 and 12 are provided with a main fan 14 to provide flow force to the exhaust gas.

The adsorption duct 10 accommodates the rotary cartridge 20 therein, and is a space where harmful components are adsorbed by the adsorbent 71 of the rotary cartridge 20.

The adsorbent 71 may be selected and used as a material having an adsorption function and a heat storage function capable of adsorbing harmful components. For example, the adsorbent 71 may be formed of a cordierite material, a bent ceramic sheet, alumina, silica, a polymer resin, aluminum, stainless steel, asfest, or a material selected from the group consisting of natural fibers. The composite material is used as a heat storage material and a coating material of one or more selected from the group consisting of zeolite, activated carbon, activated carbon fiber, alumina, silica, photocatalyst and low temperature oxidation catalyst with adsorption function It may consist of one prepared by adding both. Of course, the adsorbent 71 may be made of one material selected from the group consisting of zeolite, activated carbon, activated carbon fiber, alumina, silica, photocatalyst and low temperature oxidation catalyst having adsorption function. Preferably, the adsorbent 71 may be configured to include a core having a heat storage function and a coating layer coating the core and having an adsorption function as described below.

Zeolites are known as three-dimensional inorganic algae molecules in which silicon (Si) and aluminum (Al) are each connected through four bridged oxygens. Here, since aluminum has a negative charge as it combines with four oxygens, various cations exist in the zeolite to offset this charge. Specifically, the cations are present in the pores and the remaining spaces are usually filled with water molecules, so that they have relatively free mobility within the pores and are easy to ion exchange with other cations. In addition, the heated and dehydrated zeolites have a characteristic of filling the empty space by sucking the small molecules of the size that can pass through the pore inlet and the water space again, so that the dehydrated zeolite is adsorbent ( 71) or as an absorbent. Zeolites are generally divided into β-zeolites, A-zeolites, ZSM-5 zeolites, X-zeolites, Y-zeolites, or L-zeolites, depending on the structure or the ratio of silicon to aluminum. In the present invention, a zeolite of a kind capable of easily adsorbing the adsorption target can be selected and used depending on the intended use of the adsorbent 71. Specifically, in an embodiment of the present invention, β-zeolite may be used as the volatile organic compound adsorption material, and Y-zeolite may be used as the moisture adsorption material.

The adsorbent 71 may be formed in a network structure or a predetermined shape (corresponding to the storage section) and then positioned in the cell cartridge 210 in the form of an adsorption cartridge.

The desorption module is a flow path through which the harmful components are desorbed from the adsorbent 71 to which the harmful components are adsorbed, and the concentrated gas in which the harmful components are concentrated is flowed. The detachable module may be connected to at least one cell cartridge 210 of the rotary cartridge 20. For example, the detachable module is formed to correspond to the at least one cell cartridge 210, and is in contact with the boundary of the cell cartridge 210 to isolate the cell cartridge 210, and the detachable space together with the cell cartridge 210 ( It further includes a detachable duct 30 defining 301. The detachable duct 30 will be described later with reference to FIG. 11.

 The desorption module may be connected to the catalyst module 60 for removing harmful components of the desorption gas. Specifically, the desorption module has one side connected to the desorption duct 30, the other side is connected to the catalyst module 60, the first circulation passage 32 for providing the desorbed gas to the catalyst module 60, and one side The second circulation passage 31 is connected to the catalyst module 60 and the other side is connected to the desorption duct 30 so that a part of the air from which the harmful components have been removed from the catalyst module 60 is supplied back to the desorption duct 30. And, it may further include a discharge passage 33 which is connected to the catalyst module 60, the air from which harmful components have been removed is discharged to the outside.

The air supplied through the second circulation passage 31 may receive heat from the catalyst module 60 or heat from cooling means described later to save desorption energy.

The amount of air supplied through the desorption module is preferably smaller than the amount of air supplied through the adsorption modules 10 and 12. In general, 1/5 to 1/20 is preferred. At this time, the desorption time and method should be properly determined so that there is no loss of energy accumulated in the adsorbent 71 during desorption. Specifically, the size of the desorption duct 30 is smaller than that of the adsorption duct 10, and the desorption duct 30 has a size corresponding to 1 to 2 cell cartridges 210, and the adsorption duct 10 has 10 sizes. To 40 cell cartridges 210.

The adsorbent 71 in the desorption duct 30 is desorbed using temperature, pressure, light energy or sound wave energy. Preferably, the desorption in the desorption module may be performed by heating the adsorbent 71 with microwaves. The embodiment further includes a microwave generator 50 for supplying microwaves to the adsorbent 71 in the desorption duct 30.

The microwave generator 50 may be disposed inside or outside the adsorption duct 10.

The catalyst module 60 decomposes harmful components concentrated in the air supplied from the desorption module. Decomposed harmful components are discharged to the outside by a separate device. The air from which harmful components have been removed from the catalyst module 60 may be circulated again and supplied to the inside of the desorption duct 30.

In order to reduce energy by utilizing waste heat, and to effectively desorb and decompose harmful components, the catalyst module 60 heats the air supplied from the desorption module, decomposes harmful components, and desorbs heat of decomposed air. It can be delivered to the adsorbent 71 in the module. In addition, the catalyst module 60 may reduce the heat provided to the catalytic reaction by transferring the heat of the air from which the harmful components are decomposed to the concentrated gas discharged from the desorption module.

Specifically, the catalyst module 60 may include a catalyst cartridge 62, heat exchangers 63 and 65, a circulation fan 64, and a heater 61.

The catalyst cartridge 62 may oxidize and decompose harmful components, and may be selected from zeolite, alumina (Al ₂ O ₃ ), activated carbon, and mixed oxide metal. The catalyst cartridge 62 may be an oxidized molded body capable of oxidizing harmful components.

The heater 61 heats the concentrated gas supplied from the desorption module to the catalyst module. The heater 61 may use various heating means.

The heat exchangers 63 and 65 exchange heat between the concentrated gas supplied from the desorption duct 30 and the air passing through the catalyst cartridge 62. The first heat exchanger (63, 65) heats the concentrated gas using the waste heat of the air before discharge to the outside. Therefore, the first heat exchangers 63 and 65 can reduce energy for heating the concentrated gas.

In addition, the heat exchangers 63 and 65 may exchange heat between the air passing through the catalyst cartridge 62 and the air supplied into the desorption duct 30. The heat exchangers 63 and 65 may be provided in plural numbers.

Part of the air passing through the heat exchangers 63 and 65 is discharged to the outside through the discharge passage 33, or the other part is flowed back to the adsorption duct 10 through the second circulation passage (31).

The circulation fan 64 provides flow force to air flowing through the desorption module and the catalyst module 60.

The cooling means cools the adsorbent 71 heated in the desorption module. In the case of the heated adsorbent 71, since harmful components are hardly adsorbed in the exhaust gas, it is possible to cool by supplying external air from the cooling means.

The cooling means may have various configurations for supplying external air to the adsorbent 71 from which harmful components are desorbed. In addition, the cooling means may be configured to directly discharge the cooling air cooling the adsorbent 71 from which the harmful components are desorbed to the outside, or to the outside through the catalyst module 60.

The outflow air discharged from the cooling means may exchange heat with the air supplied into the desorption duct 30 to supply heat to the adsorbent 71.

The cooling means may have a separate cooling space for accommodating the cell cartridge 210, or may be connected to the detachable duct 30 and may not have a separate cooling space as in the embodiment.

Specifically, the cooling means is one side is connected to the outside air and the other side is connected to the desorption duct 30, the outside air passage 41, one side is connected to the desorption duct 30, the other side is connected to the catalyst module 60 And a cooling passage 42 to be used.

The cooling passage 42 and the outside air passage 41 are disposed in front of the first and second circulation passages 31 in the rotation direction of the rotary cartridge 20. Therefore, the adsorbent 71 which has completed the desorption can be effectively cooled.

In addition, intermittent valves 71, 72, and 73 may be disposed in each flow path to control the flow of air. Specifically, intermittent valves 71, 72, and 73 are disposed in the adsorption modules 10 and 12, the desorption module, and the cooling passage 42, respectively. These intermittent valves 71, 72, 73 may be closed when the rotary cartridge 20 is rotated and open when stopped.

Hereinafter, the structure and operation of the rotary cartridge 20 will be described in detail.

FIG. 5 shows a rotary cartridge 20 according to a first embodiment of the invention, FIG. 6 is a sectional view of the rotary cartridge 20 shown in FIG. 5, and FIG. 7 is a rotary cartridge 20 of FIG. The cell cartridge 210 is separated, and FIG. 8 is a view illustrating a frame 220 in which the cell cartridge 210 is removed from the rotating cartridge 20 of FIG. 6.

1 to 8, the rotation cartridge 20 is configured to be rotatable, so that the adsorbents 71 respectively stored in the plurality of cell cartridges 210 to circulate the adsorption modules 10 and 12 and the desorption module. .

The rotary cartridge 20 has a plurality of cell cartridges 210 that receive and detach the adsorbent 71. For example, the rotation cartridge 20 may include a hub 221, a frame 220, and a plurality of cell cartridges 210.

The rotating shaft 229 is coupled to the hub 221. The rotating shaft 229 transmits the driving force of the driving unit. The hub 221 is connected by the drive unit and the rotation shaft 229. Specifically, the hub 221 has a structure in which a hole into which the rotation shaft 229 is inserted is formed.

The frame 220 is connected to the hub 221 and supports at least some regions of the plurality of cell cartridges 210. The frame 220 supports the cell cartridges 210 and has a structure through which air flowing into the cell cartridge can pass.

For example, the frame 220 connects the rim 222 which surrounds the hub 221, connects the hub 221 and the rim 222, and is spaced apart in the circumferential direction about the rotation shaft 229. And at least one arm 223 supporting at least one end of the cell cartridge 210.

Rim 222 has a structure that is open up and down. The shape of the rim 222 is preferably a ring shape centered on the hub 221 of the rotary cartridge 20. This is because the shape of the cell cartridge 210 does not change even when the rotary cartridge 20 is rotated, so that it is easy to seal with the detachable duct 30.

Rim 222 is a plate-shaped, it is preferable that the width is larger than the thickness in the vertical direction. The rim 222 may define a cross section and a side surface perpendicular to the rotation axis 229. The rim 222 may be mounted with an edge of the cell cartridge 210.

The plurality of arms 223 divide the inner space of the rim 222 into a plurality of regions. The plurality of arms 223 extend radially from the rotation axis 229 and connect the hub 221 and the rim 222. The plurality of arms 223 may be spaced apart along the circumferential direction about the rotation axis 229.

The plurality of arms 223 may be disposed with a constant pitch along the circumferential direction. The number of the plurality of arms 223 is not limited, and if the plurality of arms 223 is too large, the weight of the rotating cartridge 20 itself increases, obstructs the air flow, if too small, the cell cartridge 210 ) May not be supported.

Thus, the plurality of arms 223 support at least one end of the cell cartridge 210. One arm 223 may be supported by one end of one of the two cell cartridges 210 disposed adjacent to each other and the other end of the other. The plurality of arms 223 do not vertically overlap with the central portions of the plurality of cell cartridges 210, but are disposed vertically with both ends.

In order to secure the support space of the cell cartridge 210, the widths of the plurality of arms 223 may be larger than the height. In addition, in order to maintain the sealing force during rotation of the cell cartridge, the distance between the plurality of arm arms adjacent to each other may be larger as the distance from the hub 221.

Meanwhile, the frame 220 may further include a plurality of compartment ribs 228 protruding upward from each arm 223. Compartment ribs 228 may protrude upward from each arm 223 and be disposed in at least some region of arm 223. The partition rib 228 defines the sector area S1 in which the cell cartridges 210 are located, and restricts the cell cartridge 210 from flowing in the planar direction (in the circumferential direction).

A sector area S1 in which the cell cartridges 210 are located between the partition ribs 228 adjacent to each other may be defined. The separation distance between the partition ribs 228 adjacent to each other may increase as the distance from the hub 221 increases.

The partition ribs 228 adjacent to each other and the hub 221 and the rim 222 connected to the partition ribs 228 may define a sector area S1 corresponding to the planar shape of one cell cartridge 210. . Each sector area S1 may have the same shape.

As another example, each sector region S1 has a fan shape defined by two strings (arms 223) formed around the hub 221 and an arc (part region of the rim 222) connecting the two strings. Has At this time, the sector angles θ of the plurality of sector regions S1 are formed to be the same.

When the shape and size of each sector area S1 are different from each other, when the rotary cartridge 20 is rotated, each cell cartridge 210 is not sealed with the detachment duct 30, so that the removal of harmful components becomes difficult. It is preferable that the regions S1 have the same shapes.

Compartment ribs 228 may each restrict heat transfer between cell cartridges 210. For example, the plurality of compartment ribs 228 may comprise a thermal insulator. The heat insulating agent may include a material having a lower thermal conductivity than the frame 220.

The partition rib 228 has a length corresponding to the arm 223, or has a length greater than the arm 223, and may be disposed to vertically overlap the arm 223 and a portion of the rim 222.

The partition rib 228 may be provided with an insertion groove into which a part of the cell cartridge 210 is inserted. A part of the cell cartridge 210 is inserted into the insertion groove to fix the cell cartridge 210.

The frame 220 may further include a plurality of fixing members 228 protruding upward from the rim 222. The fixing member 228 may protrude upward from the rim 222 of each sector region S1 and be disposed at least in a portion of the rim 222 which defines each sector region S1.

The cell cartridge 210 is positioned by its own weight in a section region defined by two compartment ribs 228 adjacent to each other and a hub 221 and a fixing member 228 in plan view, and the compartment rib 228 and the fixing member. 228 may limit movement in plane.

Of course, as another example, the plurality of fixing members 228 may be detachable or movable to fix the cell cartridge 210 to the sector area. At this time, the fixing member 228 may cover a portion of the cell cartridge 210 from the top. Specifically, the plurality of fixing members 228 may be coupled to the rim 222 by a fastening member such as a screw.

FIG. 9 is a perspective view of a cell cartridge 210 according to a first embodiment of the present invention, and FIG. 10 is a cross-sectional view taken along line A-A of FIG.

9 and 10, the cell cartridge 210 is detachably coupled to the frame 220 and defines a storage space S accommodating an adsorbent therein. The plurality of cell cartridges 210 may have the same shape. For example, the cell cartridge 210 may include a cell body 212, an upper cover 211, and a lower cover 213.

The cell body 212 has a structure in which air is introduced to be adsorbed and discharged by the adsorbent 71. The cell body 212 has a storage space S for accommodating the adsorbent 71 cartridge therein. The cell body 212 has a structure that is open up and down.

The cell body 212 extends from top to bottom. The shape of the cell body 212 is not limited, but is formed to correspond to the sector area S1. The cell body 212 may have the same size as the sector area S1 or smaller than the sector area S1, and the cell body 212 may have the same shape as the sector area S1. In detail, the cell body 212 may extend in width from one side to the other direction. The cell body 212 may have a fan shape. The narrower side of the cell body 212 is disposed adjacent the hub 221 and the wider side is positioned on the rim 222.

The cell body 212 may be provided with a filling hole. The filling port is a hole through which the adsorbent passes. The adsorbent may be filled through the filling port. Specifically, the filling hole may be disposed on a surface of the cell body 212 adjacent to the hub 221 or the partition rib 228. The filling opening is closed by hub 221 or compartment rib 228 upon coupling to frame 220.

In addition, a window through which microwaves pass may be formed in the cell body 212. The window may include a mesh structure or a plurality of holes.

The upper cover 211 covers an upper portion of the storage space S of the cell body 212, and an air flow port 211a is formed. The air flow port may have a completely open shape, but in order to prevent separation of the adsorbent stored in the storage space S, it is preferable to have a mesh structure. More preferably, the air flow port of the upper cover 211 may be a porous plate.

The air flow port of the upper cover 211 may be formed only in an area vertically overlapping the storage space S of the cell body 212. The width W1 of the upper cover 211 may be larger than the width W2 of the cell body 212. Both ends of the upper cover 211 may protrude to both sides of the cell body 212. Both ends of the upper cover 211 provides a space in which the detachable duct 30 or the sealing member 350 is in contact. Therefore, the upper cover 211 structure improves the sealing force of the inner space and the outside of the detachable duct 30.

A portion of the upper cover 211 may cover at least a portion of the compartment rib when the cell cartridge 210 is coupled to the frame 220. Preferably, the top covers 211 of the cell cartridges 210 adjacent to each other may cover the entire upper portion of one compartment rib together.

The lower cover 213 covers a lower portion of the storage space S of the cell body 212, and an air flow port is formed. The air flow port may have a completely open shape, but in order to prevent separation of the adsorbent stored in the storage space S, it is preferable to have a mesh structure. More preferably, the air flow port of the lower cover 213 may be a porous plate.

The air flow port of the lower cover 213 may be formed only in an area vertically overlapping the storage space S of the cell body 212. The lower cover 213 may have a larger width than the cell body 212 or have the same width as the cell body 212. Both ends of the lower cover 213 may protrude to both sides of the cell body 212. Both ends of the lower cover 213 may be inserted into the insertion groove of the partition rib 228. Both ends of the lower cover 213 are inserted into the indentation grooves 228a of the partition ribs 228 to fix the cell cartridge 210.

A sealing member 218 is disposed between the lower cover 213 and the arm 223 or / and the rim 222. The sealing member 218 prevents leakage of air between them. Therefore, the lower cover 213 structure improves the sealing force of the internal space and the exterior of the detachable duct 30.

Rotating cartridge 20 may be arranged in a plurality of stacked along the flow direction of the exhaust gas. Of course, the type of adsorbent 71 filled in the plurality of rotating cartridges 20 may be different from each other.

The driving unit (not shown) rotates the cartridge 20 so that the plurality of cell cartridges 210 are moved in the order of the adsorption modules 10 and 12 to which noxious components are supplied, and the desorption modules to which noxious components adsorbed to the adsorbent 71 are desorbed and flowed. Rotate). Referring to FIG. 2, the drive unit rotates the rotation cartridge 20 counterclockwise and stops it.

The drive unit rotates the rotation cartridge 20 by a predetermined rotation angle and then rotates to stop for a predetermined time. At this time, the preset rotation angle is preferably the same as the fan-shaped angle of each cell cartridge 210. While the rotary cartridge 20 is stopped, harmful components are adsorbed by the adsorbent 71 in the adsorption duct 10, and harmful components are desorbed by the adsorbent 71 in the desorption duct 30.

The driving unit rotates the rotary cartridge 20 so that each cell cartridge 210 circulates the adsorption duct 10 and the detachment duct 30, and the boundary of each cell cartridge 210 and the detachment duct 30 correspond to each other. By stopping the rotary cartridge 20 in position, some of the cell cartridges 210 are isolated from the adsorption duct 10 inside the removable duct 30.

Although not shown in the figure, it may further include a control unit for controlling the overall operation of the volatile organic compound removal system. The control unit may control the driving unit and each of the control valves 71, 72, and 73.

The control unit may close each of the control valves 71, 72, and 73 while the driving unit is in operation, and open each of the control valves 71, 72, and 73 while the driving unit is stopped.

11 is a cross-sectional view illustrating a state in which a detachable duct and a rotating cartridge are in contact with each other according to another embodiment of the present invention, and FIG. 12 is a diagram illustrating an upper detachable duct 310 according to an embodiment of the present invention.

In particular, referring to FIGS. 11 to 12, the detachable duct 30 has a fan shape corresponding to the cell cartridge when viewed from the top, and is formed to isolate at least one to two cell cartridges from the outside. .

Specifically, the detachable duct 30 includes an upper detachable duct 310 covering an upper portion of the cell cartridge and a lower detachable duct 320 covering the lower portion.

The upper detachable duct 310 is in close contact with the upper cover of the cell cartridge to seal the air duct, and the lower detachable duct 320 is in close contact with the lower surface of the cell cartridge or the lower surface of the frame to seal the air flow port.

The upper detachable duct 310 may be located on an upper surface of the rotary cartridge 20, and the lower detachable duct 320 may be located on a lower surface of the rotary cartridge 20. In detail, when the upper detachable duct 310 and the lower detachable duct 320 contact the air flow port of the cell cartridge of the rotary cartridge 20, the detachable space 301 is not sealed with the external space.

The detachable space 301 forms a space in the upper or lower portion of the cell cartridge, so that the microwaves provided into the detachable duct 30 can be easily transmitted.

The upper detachable duct 310 and the lower detachable duct 320 have an open shape to one side. The upper detachable duct 310 and the lower detachable duct 320 may include a duct cover 311 and a detachable body 313 extending from an edge of the duct cover 311 to define an opening.

The duct cover 311 covers the top or bottom of the at least one cell cartridge. Specifically, the duct cover 311 has a fan shape covering one cell cartridge or a plurality of cell cartridges.

The detachable body 313 extends in the direction crossing the duct cover 311 at the edge of the duct cover 311. The detachable body 313 separates the space between the duct cover 311 and the rotation cartridge 20. The detachable body 313 contacts one surface of the rotating cartridge 20.

The detachable duct 30 is located inside the adsorption duct 10 and contacts the boundary of at least one cell cartridge to seal between the adsorption duct 10 and the interior of the detachment duct 30. The desorption space 301 is a space formed inside the adsorption duct 10. If the detachable duct 30 is disposed inside the adsorption duct 10, there is an advantage of saving space in the system.

The detachable duct 30 has a structure that is moved up and down, and may be opened or closed. Specifically, the upper detachable duct 310 and the lower detachable duct 320 may further include a moving means (not shown) for moving in the vertical direction. The moving means may include a rack and a gear for moving the upper and lower detachment ducts 310 and the lower detachment ducts 320 up and down, or racks and screws, cylinders and pistons, and the like.

The rotary cartridge 20 and the detachable duct 30 are made of metal material to prevent leakage of rigidity and microwaves. When the rotary cartridge 20 and the detachable duct 30 are made of a metal material, even when the rotary cartridge 20 and the contact duct come into contact with each other, microwaves may leak or desorbed desorbed gas may flow between them.

If the microwave leaks, noise is generated in the equipment, various sensors, and the communication equipment, thereby disturbing the control and disturbing the operation of the equipment.

In addition, when using a silicone-based sealing material to prevent the outflow of the desorption gas between the rotary cartridge 20 and the desorption duct 30, there is a problem that is cured by the microwave.

Therefore, in the present invention, in order to prevent leakage of the microwaves and the desorption gas in the desorption space 301 and to prevent hardening of the sealing material, a sealing member 350 for sealing the desorption space 301 is installed.

The sealing member 350 is disposed between the rotary cartridge 20 and the detachable duct 30 to seal the detachable space 301.

If the sealing member 350 is a single silicon-based structure, the leakage of microwaves cannot be prevented and hardened to leak desorbed gas therein, and if the single metal-based structure is used to prevent the leakage of microwaves, It is weak and can not prevent leakage of desorption gas.

Therefore, the sealing member 350 of the embodiment applies a dual structure of different materials.

For example, the sealing member 350 may include a first packing 351 and a second packing 352 of a different material from the first packing 351.

The first packing 351 and the second packing 352 form a closed loop. That is, the first packing 351 and the second packing 352 have a ring shape.

Specifically, the first packing 351 and the second packing 352 are disposed between the lower end of the detachable body 313 of the upper detachable duct 310 and the upper end of the rotary cartridge 20, and the first packing 351. And the second packing 352 is disposed between the upper end of the detachable body 313 of the lower detachable duct 320 and the lower end of the rotary cartridge 20.

The first packing 351 and the second packing 352 are coupled to each removable duct 30. The first packing 351 and the second packing 352 are coupled to the lower end of the detachable body 313 of each detachable duct 30.

The first packing 351 is disposed closer to the center of the detachable space 301 than the second packing 352. The second packing 352 surrounds the first packing 351 from the outside.

The first packing 351 may include a conductive material, and the second packing 352 may include a rubber or resin material. The first packing 351 is a metal material, but the sealing force is inferior, but can effectively block the microwave, the second packing 352 can be cured by the microwave, but the flexible material is excellent in the sealing force.

If the first packing 351 is a conductive material, it is possible to block microwaves emitted from the inside of the detachable duct 30, to prevent the microwaves from going to the second packing 352, and the second packing 352. Blocks the desorption gas leaking into the first packing 351 from leaking outside.

Therefore, the sealing member 350 of the embodiment has a dual structure to prevent the outflow of the desorption gas, to prevent the outflow of microwaves, and to prevent the hardening of the second packing 352.

The first packing 351 may include a conductive material to block microwaves. For example, the first packing 351 may include a conductive metal and a conductive polymer. Preferably, the material of the first packing 351 is metal.

In order to improve the packing force of the first packing 351, the first packing 351 may have a mesh structure, a spiral structure, and a finger structure. Since the mesh structure, the spiral structure, and the finger structure are formed of a conductive material and an empty space, when the first packing 351 is in close contact with the rotating cartridge 20, the adhesion force is improved while being deformed. The finger structure will be described later.

The second packing 352 is made of an elastic or flexible rubber or resin material. Preferably, the second packing 352 may include a silicon-based material. Silicone-based materials have excellent versatility and excellent sealing power.

13 is a view showing a tackifier according to an embodiment of the present invention.

The present invention provides an improved microwave absorption having a core-shell structure comprising a silicon carbide bead disposed in the inner core and an adsorbent material 71b disposed on the outer shell of the inner core. An adsorbent 71 having properties can be provided.

The adsorption material may be formed of a material having a high adsorption performance for gaseous or particulate matter, and the adsorption material may be porous having a plurality of micropores. Specifically, the adsorbent material may be zeolite, activated alumina, or a mixture thereof.

In detail, the silicon carbide beads 71a may be silicon carbide having a spherical shape, a bead, or a non-uniform shape. Silicon carbide has a feature of absorbing microwaves, and the present invention adopts the characteristics of absorbing microwaves of silicon carbide, and the silicon carbide beads 71a are disposed in the inner core of the adsorbent 71, whereby the microwaves of the adsorbent 71 are absorbed. It may be to improve reactivity.

Figure 14a is a cross-sectional view showing a state before the sealing member is in close contact according to another embodiment of the present invention, Figure 14b is a cross-sectional view showing a state after the sealing member in close contact in accordance with another embodiment of the present invention.

Referring to FIG. 14, the sealing member 350 of another embodiment has a difference in the structure of the first packing 351-1 compared with the embodiment of FIG. 12.

The first packing 351-1 may include a resin material and a conductive material. The first packing 351-1 may have a form in which a resin material and a conductive material are mixed in order to increase the sealing force while blocking the microwave by the conductive material. Here, the conductive material is preferably metal.

For example, the first packing 351-1 may include an inner core 351 a of a resin material having elasticity and a coating part 351 b of a metal material disposed to surround the inner core 351 a.

The material of the coating part 351b has a thin thickness that is elastically deformed, and is a structure in which the sealing power is strengthened by the elastic force of the inner core 351a.

Of course, although not shown in the drawings, the first packing 351-1 may have a structure in which metal particles are dispersed in a resin material.

15 is a cross-sectional view showing a sealing member according to another embodiment of the present invention.

Referring to FIG. 15, the sealing member 350 of another embodiment has a difference in the structure of the first packing 351-2 compared with the embodiment of FIG. 12.

The first packing 351-2 is a conductive metal material and has a structure having elastic force.

Specifically, the plurality of protrusions 354 and the base 353 to which the plurality of protrusions 354 are connected may be included. The plurality of protrusions 354 may protrude from the base 353 and have a structure that is elastically deformable.

In detail, the protrusion 354 may have a thin thickness, an empty space therein, or may have a bending structure. Therefore, while the plurality of protrusions 354 are elastically deformed, the adhesion of the first packing 351-2 is improved.

The plurality of protrusions 354 may be repeated with a constant pitch P in the outward direction of the detachable duct 30. The pitch P between the plurality of protrusions 354 preferably has a value between 0.0001% and 0.05% of the wavelength of the microwave. If the pitch P between the plurality of protrusions 354 has a value between 0.05% of the wavelength of the microwave, leakage of the microwaves between the plurality of protrusions 354 can be prevented.

Although the above has been illustrated and described with respect to preferred embodiments of the present invention, the present invention is not limited to the specific embodiments described above, but in the art to which the invention pertains without departing from the spirit of the invention as claimed in the claims. Various modifications can be made by those skilled in the art, and these modifications should not be individually understood from the technical spirit or the prospect of the present invention.

10: adsorption duct 20: rotary cartridge
30: desorption duct 60: catalyst module

Claims (14)

A hub coupled to the rotating shaft;
A frame connected to the hub; And
At least two cell cartridges detachably coupled to the frame and containing an adsorbent therein;
The frame,
A rim disposed to surround the hub;
A plurality of arms connecting the hub and the rim and spaced apart from each other in the circumferential direction with respect to the rotational shaft, and supporting at least one end of the cell cartridge;
A plurality of compartment ribs protruding upwardly from each arm,
A sector area in which the cell cartridges are located between the adjacent ribs of the compartment is defined,
Each cell cartridge,
A cell body defining an upper and lower storage space;
An upper cover covering an upper portion of the storage space and in which an air flow port is formed; And
A lower cover covering a lower portion of the storage space and having an air flow port formed therein;
Both ends of the upper cover is mounted on the upper portion of the partition ribs,
Both ends of the lower cover are inserted into the insertion groove of the partition rib,
And a top cover and a bottom cover having a width greater than that of the cell body.
delete delete The method of claim 1,
And the separation distance between the adjacent ribs from each other increases as the distance from the hub increases. The method of claim 1,
Said adjacent ribs and said hub and said rim define said sector area corresponding to a planar shape of one said cell cartridge. The method of claim 1,
And each sector area has the same shape as each other. The method of claim 1,
And the plurality of compartment ribs comprise a thermal insulator. delete delete The method of claim 1,
And a portion of the top cover covers at least a portion of the compartment rib when the cell cartridge is coupled to the frame. The method of claim 1,
The cell body is provided with a filling hole. A rotation cartridge comprising a plurality of cell cartridges including a hub coupled to a rotating shaft, a frame connected to the hub, and a detachable coupling to the frame and accommodating an adsorbent therein; And
A driving unit for rotating the rotary cartridge to isolate the cell cartridge so that the plurality of cell cartridges are moved in an order of an adsorption module to which noxious components are supplied, and a desorption module to desorb harmful substances adsorbed to the adsorbent;
The frame,
A rim disposed to surround the hub;
A plurality of arms connecting the hub and the rim and spaced apart from each other in the circumferential direction with respect to the rotational shaft, and supporting at least one end of the cell cartridge;
A plurality of compartment ribs protruding upwardly from each arm,
A sector area in which the cell cartridges are located between the adjacent ribs of the compartment is defined,
Each cell cartridge,
A cell body defining an upper and lower storage space;
An upper cover covering an upper portion of the storage space and in which an air flow port is formed; And
A lower cover covering a lower portion of the storage space and having an air flow port formed therein;
Both ends of the upper cover is mounted on the upper portion of the partition ribs,
Both ends of the lower cover are inserted into the insertion groove of the partition rib,
The upper cover and the lower cover is a volatile organic compound removal system having a larger width than the cell body. The method of claim 12,
The drive unit is a volatile organic compound removal system for rotating the rotary cartridge by a predetermined rotation angle and then rotated for a predetermined time. The method of claim 12,
The plurality of cell cartridges have the same shape as each other volatile organic compound removal system.

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