KR101794749B1 - Apparatus for concentrating volatile organic compound gas having stack type filter - Google Patents

Abstract

An apparatus for concentrating a volatile organic compound gas having a stack type filter according to the present invention comprises: a housing forming a flow path of a gas containing a volatile organic compound; And a plurality of adsorption cells having adsorbability of the volatile organic compound, wherein the plurality of adsorption cells are arranged in a stacked manner so as to have a first surface facing downstream of the flow path and a second surface facing upstream of the flow path, unit; A first head configured to be able to be transported in parallel with the first surface and configured to supply heated air; A second head portion configured to be able to be transported in the same direction at the same time as the first head portion in parallel with the second surface, the concentrated organic gas passing through the filter unit being gathered; And a first leak blocking portion formed to surround the end portion of the first head portion and preventing the gas around the first head portion from being introduced into the first head portion.

Description

TECHNICAL FIELD [0001] The present invention relates to an apparatus for concentrating volatile organic compounds (GAS)

The present invention relates to an apparatus for concentrating a volatile organic compound gas having a stacked filter.

Volatile Organic Compound (VOC) refers to a liquid or gaseous organic compound that is easily vaporized into the atmosphere because of its high vapor pressure. Organic solvents are used in various industrial fields such as LCD and semiconductor manufacturing, painting, and production of petrochemical products, from which various VOCs are produced. VOCs often have odor and toxicity, and they are also precursors to photochemical oxides that cause global warming and destruction of the ozone layer. As a result, policy and technological efforts are being made to minimize the emission of volatile organic compounds and to preserve the environment in each country and most industrial sectors.

Treatment of malodorous or volatile organic compounds depends on the kind, concentration or amount of gas, and techniques such as incineration by heat, adsorption, absorption, condensation, biofiltration, catalytic oxidation, and photocatalytic oxidation are used. The double adsorption method has a high facility cost, has process flexibility, can be mass-processed, and can be applied to low-concentration pollutants. In the case of the adsorption type, the organic compounds adsorbed on the filter are accumulated over time and the purification efficiency of the filter is lowered. Therefore, an apparatus for separating and concentrating the organic compounds from the filter and regenerating the filter is indispensable. A rotor type in which a heated gas is supplied to a section of a disk-shaped filter to be rotated to separate an adsorbed organic compound is most commonly used in accordance with a regeneration method. Recently, a filter is configured in the form of a rotating cylinder, And a method in which the filter is regenerated by supplying a high temperature gas from the inside to the outside of the filter in some rotation sections has been proposed.

However, when the filter is rotated, the filter has to have a circular or cylindrical shape, which inevitably creates an insoluble space in which the filter is not mounted, which lowers the efficiency of the filtration process as a whole and has a complicated structure of the apparatus.

SUMMARY OF THE INVENTION An object of the present invention is to provide a volatile organic compound gas concentration apparatus having a stacked filter which is excellent in purifying efficiency of a gas containing VOC and can reduce the energy cost for operation.

It is another object of the present invention to minimize the decrease in the concentration of VOC due to the inflow of gas around the head during the regeneration.

According to an aspect of the present invention, there is provided an apparatus for concentrating a volatile organic compound gas having a stacked filter according to the present invention, comprising: a housing forming a flow path of a gas containing a volatile organic compound; And a plurality of adsorption cells having adsorbability of the volatile organic compound, wherein the plurality of adsorption cells are arranged in a stacked manner so as to have a first surface facing downstream of the flow path and a second surface facing upstream of the flow path, unit; A first head configured to be able to be transported in parallel with the first surface and configured to supply heated air; A second head portion configured to be able to be transported in the same direction at the same time as the first head portion in parallel with the second surface, the concentrated organic gas passing through the filter unit being gathered; And a first leak blocking portion formed to surround the end portion of the first head portion and preventing the gas around the first head portion from being introduced into the first head portion.

As an example relating to the present invention, the filter unit may be arranged in the form of a vertical wall in the housing.

In one embodiment of the present invention, the apparatus for concentrating volatile organic compound gas having the stack type filter is formed so as to surround an end portion of the second head portion, and a gas around the second head portion, And a second leak interrupting portion for preventing the second leak interrupting portion from being introduced.

As an example related to the present invention, the apparatus for concentrating volatile organic compound gases having the stack type filter may further include a heater attached to the first head part and capable of being carried along with the first head part.

In one embodiment of the present invention, the apparatus for concentrating volatile organic compound gases having the stacked filter may include a first contact panel disposed to be spaced apart from the first surface, ; And a first buffer unit disposed between the first contact panel and the first surface and configured to be partitioned by individual adsorption cells constituting the plurality of adsorption cells.

As an example related to the present invention, the apparatus for concentrating volatile organic compound gas having the stacked type filter may further include a second contact panel disposed to be spaced apart from the second surface, ; And a second buffer unit disposed between the second contact panel and the second surface and configured to be partitioned by individual adsorption cells constituting the plurality of adsorption cells.

As an example related to the present invention, the first leak blocking portion may include: a first shielding wall formed around the first head portion along the circumferential direction of the second head portion; And a second shielding wall spaced from the first shielding wall and formed along a circumferential direction of the first shielding wall.

As an example related to the present invention, the apparatus for concentrating volatile organic compound gas having the stacked filter may further include a sealing part formed of a flexible material, attached to the end of the first shielding wall and the end of the second shielding wall, .

As an example related to the present invention, the first contact panel may include openings for individual adsorption cells constituting the plurality of adsorption cells.

As an example related to the present invention, the opening is formed in a rectangular shape having a first width (w ₁ ) and a second width (w ₂ ), and the distance between the opening in the first width direction and the adjacent opening d _1, wherein when the distance d ₂ d between the openings adjacent to the opening in the second lateral direction, the first width of the first leakage barrier unit (162) (S ₁₎ and a second width (S ₂₎ is 2w ₁ + d ₁ ? S ₁ ? W ₁ + 2d ₁ and 2w ₂ + d ₂ ? S ₂ ? W ₂ + 2d ₂ Respectively.

As an example related to the present invention, the first head portion may be formed so that the first leak blocking portion can be continuously transferred in contact with the first contact pad.

According to the apparatus for concentrating volatile organic compound gas having a stack type filter according to the present invention, there is provided a stationary filter unit in which adsorption cells are stacked, and a movable first head and a second head for regenerating the filter, Compared to the rotor type and the cylinder type which rotate the filter in order to minimize the area in which the filter can not be arranged, the air purification efficiency is excellent and the energy cost for blowing is reduced. In addition, since the leak blocking portion is formed in the head portion for regeneration, the gas is prevented from flowing into the inside of the head portion by the wind pressure when moving the head portion, and the concentration of organic gas is increased.

FIG. 1 is a front perspective view of a volatile organic compound gas concentration apparatus 100 having a stacked filter according to the present invention.
FIG. 2 is a rear perspective view of the apparatus 100 for concentrating volatile organic compound gas having the stacked type filter of FIG.
Figure 3 is a front perspective view of a filter unit 150 associated with the present invention.
Fig. 4 is a rear perspective view of the filter unit 150 of Fig.
Figure 5 is a side view of the filter unit 150 of Figure 3
6 is a view conceptually showing the feeding of the first head portion 161 during reproduction of the filter unit 150 of Fig. 3
7 is a perspective view showing the configuration of the first head portion 161 related to the present invention.
8 is a view for explaining the relative sizes of the first contact panel 155 and the first head portion 161 related to the present invention
9 is a view sequentially showing the operation states of the first head portion 161 and the first leak blocking portion 162 during reproduction according to the present invention

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, a volatile organic compound gas concentration apparatus having a stack type filter according to the present invention will be described in detail with reference to the accompanying drawings.

Fig. 1 is a front perspective view of a volatile organic compound gas concentration apparatus 100 having a stacked filter according to the present invention, and Fig. 2 is a front perspective view of a volatile organic compound gas concentration apparatus 100 having a stacked type filter of Fig. It is a perspective view.

1 and 2, a volatile organic compound gas concentration apparatus 100 having a stacked filter includes a housing 110 for forming a flow path for gas to be treated containing a volatile organic compound, 165, 167, 171, 175 for regenerating the filter unit 150. The filter unit 150 includes a plurality of filter units 150,

At one side of the housing 110, an inlet 120 for introducing a gas to be treated is provided. The inlet 120 may have a louver damper structure capable of regulating or shutting off the air flow rate. The inlet 120 is provided with a blowing fan 140 for forming wind pressure required for operation. An outlet 130 for discharging the purified gas may be disposed downstream of the filter unit 150. High Efficiency Particulate (HEPA) for removing particulates contained in the gas filtered by the volatile organic compound through the filter unit 150 is provided in the interior of the outlet 130 or between the filter unit 150 and the outlet 130, air filter may be provided.

Fig. 3 is a front perspective view of the filter unit 150 related to the present invention, Fig. 4 is a rear perspective view of the filter unit 150 of Fig. 3, and Fig. 5 is a side view of the filter unit 150 of Fig.

As shown in Figs. 3 to 5, the filter unit 150 includes a plurality of adsorption cells having adsorbability of volatile organic compounds. The filter unit 150 is formed in a vertical wall shape in the housing 110 so as to have a first surface facing downstream of the flow path and a second surface facing upstream of the flow path. do. Each adsorption cell may be in the form of a zeolite supported on a standardized honeycomb structure. The plurality of adsorption cells can be fixed by a frame partitioned in a partitioning manner so as to be accommodated one by one, and the adsorption cell assembly 151 can be constructed. While the gas passes through the adsorption cell assembly 151, various volatile organic compounds contained in the gas are adsorbed to the adsorption cell and only the purified gas is discharged through the second side of the adsorption cell.

And a regeneration device for separating and concentrating the volatile organic compounds adsorbed in the adsorption cells according to the passage of the operation time. The reproducing apparatus includes a first head portion 161 formed to be able to be transported in parallel with the second surface of the filter unit 150 and capable of supplying heated air, A second head portion 171, a first head portion 161, and a second head portion 161. The first head portion 161 and the second head portion 161 are formed so that they can be simultaneously transported in the same direction as the first head portion 161 and the condensed organic gas passing through the filter unit 150 can be collected. A second conveying module 175 for conveying the second head portion 171, and the like. The first head part 161 may be provided with a heater 167 to transfer the first head part 161 and the heater 167 together. The second head portion 171 is connected to the concentrated gas discharge portion 180 provided at one side of the housing 110 by a corrugated pipe or a bellows type pipe.

The first conveying module 165 includes a vertical guide 165a, a vertical conveying motor portion 165b configured to move the first head portion 161 in a controlled manner along the vertical guide 165a, A horizontal guide 165c for guiding the assembly of the vertical conveying motor unit 165a and the vertical conveying motor unit 165b in the horizontal direction and an assembly of the vertical guide 165a and the vertical conveying motor unit 165b And a horizontal feed motor unit 165d. The second conveying module 175 also includes a vertical guide 175a for conveying the second head portion 171 like the first conveying module 165, a vertical conveying motor portion 175b, a horizontal guide 175c, And a horizontal feed motor unit 175d. A guide member such as a ball screw may be used for the vertical guides 165a and 175a, and a member similar to the linear guide may be used for the horizontal guides 165c and 175c. The first head portion 161 and the second head portion 171 are arranged in the same amount in the vertical conveying motor portion 165b and the vertical conveying motor portion 175b and in the horizontal conveying motor portion 165d and the horizontal conveying motor portion 175d, As shown in Fig.

A first leak blocking portion 162 may be formed at an end of the first head portion 161. The first leak blocking portion 162 may be in the form of a flange surrounding the end portion of the first head portion 161 and may prevent the gas around the first head portion 161 from flowing into the first head portion 161 .

The second leak blocking portion 172 may be formed at the end of the second head portion 171. The second leak blocking portion 172 is also in the form of a flange that surrounds the end portion of the second head portion 171 like the first leak blocking portion 162. The gas around the second head portion 171, (171).

The first leak blocking portion 162 and the second leak blocking portion 172 are formed so as to be in contact with the first contact panel 155 and the second contact panel 157, respectively. The first contact panel 155 is spaced apart from the first surface of the filter unit 150 and the second contact panel 157 is disposed spaced apart from the second surface of the filter unit 150. A first buffer portion 156 is formed between the first contact panel 155 and the first surface so as to reduce the temperature deviation during the regeneration and to improve the distributability of the gas flow and the second contact panel 157 and the second And a second buffer unit 158 may be formed between the surfaces. The first buffer unit 156 is formed so as to be divided into individual adsorption cells constituting a plurality of adsorption cells and the second buffer unit 158 is also partitioned by the individual adsorption cells like the first buffer unit 156 . ≪ / RTI > Accordingly, the first leak blocking portion 162 and the second leak blocking portion 172 are in contact with the first contact panel 155 and the second contact panel 157, respectively, The gas for regeneration of the adsorption cell is supplied to the openings 155a and 157a provided for each adsorption cell on the opening 155a and the second contact panel 157 provided for each adsorption cell and the concentrated organic gas is supplied to the concentrated gas discharge unit 180 ).

6 is a view conceptually showing that the first head portion 161 is transported during reproduction of the filter unit 150 of FIG.

The first head portion 161 and the second head portion 171 are arranged such that the first leak blocking portion 162 and the second leak blocking portion 172 are disposed on the first contact panel 155 and the second contact panel 157, So that it can be continuously conveyed in a state of being in contact with the sheet material. The first and second head portions 161 and 171 may be positioned in the openings 155a and 157a corresponding to the plurality of adsorption cells. And a limit sensor for guiding it.

' 형태의 이동경로를 거치도록 설정될 수 있다.The first head portion 161 and the second head portion 171 may have a transfer pattern for making the shortest transfer distance capable of continuous reproduction for each of a plurality of suction cells. That is, when reaching the position where the opening 155a exists with respect to the plurality of apertures 155a arranged in a matrix form, the stop is stopped until the end of the regeneration mode, and then, when the regeneration mode is finished, it is transported toward the next opening. 6, the first head portion 161 and the second head portion 171 pass through all the other openings at the opening of the starting position, In order to naturally reach the opening,

&Quot;,< / RTI >

FIG. 7 is a perspective view showing the structure of the first head part 161 related to the present invention, and FIG. 8 is a view for explaining the relative sizes of the first contact panel 155 and the first head part 161 related to the present invention. And FIG. 9 is a diagram sequentially showing the operation states of the first head portion 161 and the first leak blocking portion 162 during reproduction according to the present invention.

When the head portion 161 and the leak blocking portion 162 are continuously transported, the head portion 161 is partially opened when the head portion 161 is positioned between the opening 155a of the contact panel 155 and the adjacent opening The gas can be introduced into the inside of the head portion 161 through the opening. The leak blocking portion 162 includes a first shielding wall 163 formed around the head portion 161 in the circumferential direction of the head portion 161 and a second shielding wall 163 spaced apart from the first shielding wall 163 And a second shielding wall 164 formed along the circumferential direction of the first shielding wall 163. Sealing portions 163a and 164a formed of a flexible material may be attached to the end portions of the first shielding wall 163 and the second shielding wall 164, respectively.

8 and 9, the opening 155a of the contact panel 155 is formed in a rectangular shape having a first width w ₁ and a second width w ₂ , and the first width w ₁ direction of the opening when the distance between (155a) of the opening (155a) of the opening (155a) adjacent to the distance and the opening (155a) of d _1, the second width (w ₂₎ direction between the adjacent and d ₂ d, the The first width (S ₁ ) and the second width (S ₂ ) of the two wall portions are 2w ₁ + d ₁ ≤ S ₁ ≤ w ₁ + 2d ₁ and 2w ₂ + d ₂ ≤S ₂ ≤w ₂ + 2d ₂ Respectively.

That is, FIG. 9 (a) and the like, a head portion 161 with an opening is located at (155a-1) when in the playback _{mode, S 1 ≤ w 1 + 2d} 1 il not be restricted suction action through the other opening And the opening 155a-1 and the opening 155a-2 are partially blocked by the leak blocking portion 162 during movement of the head portion 161 as shown in Figs. 9 (b) and 9 (c) May be 2w ₁ + d ₁ ≤ S ₁ , as a requirement to be able to block the gas in the opening which is open and thereby opened, into the interior of the first shielding wall 163.

Likewise, the present invention is also applied to the case of being transported in the vertical direction. That is, FIG. 9, as (d), the head portion 161, an opening is located at (155a-2) when in the playback _{mode, S 2 ≤ w 2 + 2d} 2 il not be restricted suction action through the other opening The opening 155a-2 and the opening 155a-2 are partially opened by the leak blocking portion 162 during movement of the head portion 161, as shown in Fig. 9 (e) As a requirement that the gas of the open opening can be blocked from entering the inside of the first shielding wall 163, it may be 2w ₂ + d ₂ S ₂ .

The apparatus and method for concentrating volatile organic compound gases having the above-described stacked type filter are not limited in the configuration and the method of the illustrated embodiments. The embodiments may be configured so that all or some of the embodiments may be selectively combined so that various modifications may be made.

100: Volatile organic compound gas concentration apparatus with stacked filter
110: housing 120: inlet
130: outlet 140: blowing fan
150: filter unit 151: adsorption cell assembly
155: first contact panel 155a: opening
156: first buffer 157: second contact panel
157a: aperture 158: second buffer
161: first head portion 162: first leak blocking portion
163: first shielding wall 163a, 164a:
164: second shielding wall 165: first conveying module
165a: Vertical guide 165b: Vertical feed motor part
165c: horizontal guide 165d: horizontal feed motor part
167: Heater 171: Second head part
172: second leak breaking portion 175: second conveying module
175a: Vertical guide 175b: Vertical feed motor part
175c: horizontal guide 175d: horizontal feed motor section
180: concentrated gas discharge portion

Claims (11)

A housing for forming a flow path for a gas containing a volatile organic compound;
And a plurality of adsorption cells having adsorbability of the volatile organic compound, wherein the plurality of adsorption cells are arranged in a stacked manner so as to have a first surface facing downstream of the flow path and a second surface facing upstream of the flow path, unit;
A first head configured to be able to be transported in parallel with the first surface and configured to supply heated air;
A second head portion configured to be able to be transported in the same direction at the same time as the first head portion in parallel with the second surface, the concentrated organic gas passing through the filter unit being gathered;
A first leak blocking portion formed to surround an end portion of the first head portion and preventing a gas around the first head portion from being introduced into the first head portion;
A first contact panel spaced apart from the first surface and configured to be in contact with the first head portion; And
And a first buffer portion disposed between the first contact panel and the first surface and formed so as to be able to be partitioned by individual adsorption cells constituting the plurality of adsorption cells, Device.
The method according to claim 1,
Wherein the filter unit is disposed in a vertical wall shape in the housing.
The method according to claim 1,
Further comprising a second leak blocking portion formed to surround the end portion of the second head portion and preventing a gas around the second head portion from flowing into the second head portion. Gas concentrator.
The method according to claim 1,
Further comprising a heater attached to the first head portion and capable of being transported together with the first head portion.
delete The method according to claim 1,
A second contact panel disposed to be spaced apart from the second surface and configured to be in contact with the second head portion; And
Further comprising a second buffer portion disposed between the second contact panel and the second surface, the second buffer portion being formed so as to be partitioned by individual adsorption cells constituting the plurality of adsorption cells, wherein the volatile organic compound gas concentration Processing device.
The method according to claim 1,
Wherein the first leak-
A first shielding wall formed around the first head portion along a circumferential direction of the first head portion; And
And a second shielding wall spaced from the first shielding wall and formed along the circumferential direction of the first shielding wall.
8. The method of claim 7,
Further comprising a sealing portion which is attached to an end of the first shielding wall and an end of the second shielding wall, respectively, and which is formed of a flexible material.
9. The method of claim 8,
Wherein the first contact panel includes openings for individual adsorption cells constituting the plurality of adsorption cells.
10. The method of claim 9,
The opening is formed in a rectangular shape having a first width (w ₁ ) and a second width (w ₂ )
A distance between the opening in the first width direction and the adjacent opening is d ₁ and a distance between the opening in the second width direction and the adjacent opening is d ₂ ,
The first width (S ₁ ) and the second width (S ₂ ) of the first leak-
2w ₁ + d ₁ ? S ₁ ? W ₁ + 2d ₁
2w ₂ + d ₂ ? S ₂ ? W ₂ + 2d ₂
Respectively, of the stacked type filter.
11. The method of claim 10,
Wherein the first head portion is formed so that the first leak blocking portion can be continuously transported in contact with the first contact panel.

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