KR102282525B1 - Catalyst Module for Pulse Type Volatile Organic Compounds Reduction - Google Patents

Abstract

The present invention relates to a catalyst module for reducing pulsed volatile organic compounds, and more particularly, by introducing a toxic fluid, adsorbing the volatile organic compound in the toxic fluid, and applying pulsed thermal energy to the adsorbed volatile organic compound In the catalyst module for reducing pulsed volatile organic compounds that oxidizes and removes volatile organic compounds through desorption and catalytic reaction, it is possible to quickly provide thermal energy for desorption and oxidation of volatile organic compounds, It relates to a catalyst module for reducing pulsed volatile organic compounds that can provide thermal energy with a uniform temperature distribution.

Description

Catalyst Module for Pulse Type Volatile Organic Compounds Reduction

The present invention relates to a catalyst module for reducing pulsed volatile organic compounds, and more particularly, by introducing a toxic fluid, adsorbing the volatile organic compound in the toxic fluid, and applying pulsed thermal energy to the adsorbed volatile organic compound It relates to a catalyst module for reducing pulsed volatile organic compounds that oxidizes and removes volatile organic compounds through desorption and catalytic reaction.

Volatile Organic Compounds (VOC) have high vapor pressure, low boiling point, and easily evaporate even at room temperature and diffuse into the air. Most of them have a pungent odor and are harmful to the human body.

Methods for removing such volatile organic compounds include a catalytic oxidation method, an adsorption treatment method, and a direct combustion method.

The direct combustion method is a method of decomposing exhaust gas through combustion, has the advantage of high removal rate of volatile organic compounds, and is widely used. However, the direct combustion method consumes the operating cost for providing a heat source, and additional incineration is required when the exhaust gas contains halogen compounds or a large amount of inorganic metal compounds. In addition, there is a disadvantage in that there is a possibility of the formation of nitrogen oxides and the like at high temperatures.

The adsorption treatment method is a method of collecting, collecting, and retaining contaminants on the surface of the adsorbent. The adsorption treatment method has the advantages of easy operation and low facility investment compared to other methods, but it is difficult to use when the concentration of pollutants is high, and may cause secondary contamination due to the regeneration of the adsorbent.

The catalytic oxidation method oxidizes and removes volatile organic compounds through catalysis, and has the advantage of high efficiency while requiring relatively low investment and low operating costs compared to other methods.

1 is a partial perspective view of a catalyst module 10 for reducing volatile organic compounds according to the related art. 1, the conventional catalyst module 10 for reducing volatile organic compounds includes a monolith body 11, and an adsorption module for adsorbing volatile organic compounds in a harmful fluid at one side inside the monolith body 11; The rear end of the adsorption module includes a catalyst module that oxidizes and removes volatile organic compounds through catalysis.

At this time, in the conventional catalyst module 10 for reducing volatile organic compounds, thermal energy must be provided for desorption of volatile organic compounds from the adsorption module or for catalysis in the catalyst module. It includes a heating means (12) for applying heat from the side.

That is, the conventional catalyst module 10 for volatile organic compound reduction applies heat from the outside, so it takes time for heat transfer depending on the characteristics of the carrier provided in the catalyst module, and from the outside of the monolith body 11 . Since heat is applied, there is a problem in that the temperature distribution in the monolith body 10 is not uniform. This makes it difficult to efficiently remove volatile organic compounds due to uneven heat supply.

In addition, since the heating is biased toward one side, there is a risk of damage or breakage of the monolith body 10 due to a local high temperature, and problems such as desorption of the catalyst due to the high temperature may occur.

Republic of Korea Patent Publication No. 10-1996411 (2019.06.10.)

The present invention has been devised to solve the above-described problems, and an object of the present invention is to introduce a harmful fluid, adsorb the volatile organic compound in the harmful fluid, and apply pulsed thermal energy to the adsorbed volatile organic compound In the catalyst module for reducing pulsed volatile organic compounds that oxidizes and removes volatile organic compounds through desorption and catalytic reaction, it is possible to quickly provide thermal energy for desorption and oxidation of volatile organic compounds, An object of the present invention is to provide a catalyst module for reducing pulsed volatile organic compounds capable of providing thermal energy with an even temperature distribution.

The catalyst module for reducing pulsed volatile organic compounds according to the present invention forms at least two spaces in the height direction and at least one space in the width direction, and the harmful fluid flows into the selected one of the lengthwise ends. The other side of the direction is a closed shape monolith body (100); an adsorption unit 200 formed to adsorb volatile organic compounds in the harmful fluid flowing from one side to the other side in the longitudinal direction at the selected end of the monolith body 100; At the end where the adsorption unit 200 is not formed, the adsorption unit 200 and the other side in the longitudinal direction are formed to communicate with each other, and the volatile organic compound that is desorbed from the adsorption unit 200 and flows from the other side in the longitudinal direction to one side is added to the catalyst Catalyst 300 for removing by oxidation; and a heating means 400 that supplies pulsed thermal energy to the adsorption unit 200 and the catalyst unit 300, and is provided in a plate shape above and below the adsorption unit 200 and the catalyst unit 300. characterized in that

The catalyst module for reducing pulsed volatile organic compounds according to the present invention forms at least two spaces in the height direction and at least one space in the width direction, and the harmful fluid flows into the selected one of the lengthwise ends. The other side of the direction is a closed shape monolith body (100); an adsorption unit 200 formed at a selected end of the monolith body 100 so that volatile organic compounds in the harmful fluid flowing from one side to the other are adsorbed; At the stage where the adsorption unit 200 is not formed, the adsorption unit 200 is formed in communication with the adsorption unit 200 and the other side, and the volatile organic compound that is desorbed from the adsorption unit 200 and flows from the other side to one side is oxidized and removed by the catalyst. to the catalyst unit 300; and a heating means 400 that supplies pulsed thermal energy to the adsorption unit 200 and the catalyst unit 300, and is provided at a location and number selected inside the adsorption unit 200 and the catalyst unit 300; characterized by including.

In addition, the catalyst module for reducing pulsed volatile organic compounds according to the present invention forms at least two spaces in a height direction and at least one space in a width direction, but harmful fluid flows into a stage selected from one side in the longitudinal direction And the other longitudinal side is a monolith body 100 of a closed shape; an adsorption unit 200 formed to adsorb the volatile organic compound in the harmful fluid flowing from one side to the other side in the longitudinal direction at the selected end of the monolith body 100; At the end where the adsorption unit 200 is not formed, the adsorption unit 200 is formed in communication with the adsorption unit 200 and the other side, and the volatile organic compound desorbed from the adsorption unit 200 and flowing from the other side in the longitudinal direction to one side is oxidized by a catalyst. to remove the catalyst unit 300; and a heating provided on the other side in the longitudinal direction of the monolith body 100 in which the adsorption unit 200 and the catalyst unit 300 are in communication with the adsorption unit 200 and the catalyst unit 300, but supplying pulsed thermal energy. Means 400; characterized in that it includes.

In addition, the heating means 400 is characterized in that it is formed to have a length selected in the width direction.

In addition, the monolith body 100 communicates with the adsorption unit 200 on one side in the longitudinal direction and an inlet 110 through which harmful fluid is introduced, and a closing part for closing the other side in the longitudinal direction of the monolith body 100 . 130, a communication part 140 formed so that the adsorption part 200 and the catalyst part 300 communicate with each other on the other side in the longitudinal direction of the monolith body 100, and the catalyst part 300 An exhaust closure part 121 for closing one longitudinal side of the monolith body 100 and an exhaust communication formed so that the end of the catalyst part 300 communicates with one side in the longitudinal direction of the monolith body 100 in the width direction. Including the part 122, characterized in that it comprises a discharge part 120 through which the fluid is discharged in a direction selected among the width direction of the monolith body (100).

In addition, the adsorption unit 200 and the catalyst unit 300 are formed to alternate in the height direction.

In addition, the monolith body 100 includes a flow rate sensor for measuring the flow rate of the harmful fluid flowing into the adsorption unit 200 and an adsorption amount sensor for measuring the volatile organic compound adsorbed on the adsorption unit 200 . characterized in that

The catalyst module for reducing pulsed volatile organic compounds according to the present invention is capable of evenly supplying pulsed thermal energy for the operation of the adsorption unit where the volatile organic compound is adsorbed and the catalyst unit that removes the volatile organic compound through oxidation by the catalyst. Therefore, there is an advantage in that volatile organic compounds can be efficiently removed.

In addition, the catalyst module for reducing pulsed volatile organic compounds according to the present invention has the advantage of shortening the time for thermal energy to be transferred to the adsorption unit and the catalyst unit.

In addition, since the catalyst module for reducing pulsed volatile organic compounds according to the present invention can prevent the supply of thermal energy biased to either side, there is an advantage in that it can prevent damage or damage due to heat.

In addition, the catalyst module for reducing pulsed volatile organic compounds according to the present invention can perform the desorption operation in the adsorption part and the oxidation operation in the oxidation part by using the thermal energy generated according to the oxidation in the catalyst part. Since the continuous supply of thermal energy using a means is not required, it has an efficient advantage in the use of energy.

1 is a partial perspective view of a catalyst module for reducing volatile organic compounds in the prior art;
2 is a partial sectional perspective view of a catalyst module for reducing pulsed volatile organic compounds according to an embodiment of the present invention;
3 is a view showing a partial cross-sectional view of a catalyst module for reducing pulsed volatile organic compounds according to an embodiment of the present invention;
4 is another view showing a partial sectional perspective view of a catalyst module for reducing pulsed volatile organic compounds according to an embodiment of the present invention;
5 is another view showing a partial cross-sectional view of a catalyst module for reducing pulsed volatile organic compounds according to an embodiment of the present invention;
6 is another diagram showing a partial sectional perspective view of a catalyst module for reducing pulsed volatile organic compounds according to an embodiment of the present invention;
7 is another view showing a partial cross-sectional view of a catalyst module for reducing pulsed volatile organic compounds according to an embodiment of the present invention;
8 is a view showing an actual body of a monolith of a catalyst module for reducing pulsed volatile organic compounds according to an embodiment of the present invention;
9 is another view showing the real thing of the monolith body of the catalyst module for reducing pulsed volatile organic compounds according to an embodiment of the present invention;

Hereinafter, a catalyst module for reducing pulsed volatile organic compounds according to an embodiment of the present invention as described above will be described in detail with reference to the accompanying drawings.

2 is a partial sectional perspective view of a catalyst module for reducing pulsed volatile organic compounds according to an embodiment of the present invention, and FIG. 3 is a catalyst for reducing pulsed volatile organic compounds according to an embodiment of the present invention. It is a diagram showing the module in partial cross-sectional view.

2 to 3 , the catalyst module 1000 for reducing pulsed volatile organic compounds according to an embodiment of the present invention is largely porous, and harmful fluid including volatile organic compounds is introduced from one side in the longitudinal direction. The monolith body 100, in which the volatile organic compound is oxidized and the removed fluid is discharged to at least one selected in the width direction, is formed inside the monolith body 100 so that the volatile organic compound in the harmful fluid is adsorbed. (200), the volatile organic compound desorbed from the adsorption unit 200 flows, and the catalyst unit 300 is oxidized and removed by the catalyst, and the adsorption unit 200 and the catalyst unit 300 are heated to heat the adsorption unit 200 The volatile organic compound is desorbed, and the catalyst unit 300 includes a heating means 400 for oxidizing the volatile organic compound by the catalyst.

The monolith body 100 has a predetermined length in the direction in which the harmful fluid flows and forms a space. At this time, one side of the body 100 in the longitudinal direction includes an inlet 110 through which harmful fluid containing volatile organic compounds and the like flows.

At this time, the monolith body 100 shown in FIGS. 2 and 3 is a view showing a part to support the detailed description of the invention, and the actual body is shown in FIGS. 8 to 9 . The monolith body 100 shown in FIGS. 8 and 9 has porosity, and preferably has at least two steps in a vertical direction and at least one space in a horizontal direction. In addition, the monolith body 100 having a porous branch has a rectangular space in the drawings and photos, but, of course, various shapes such as a circle are possible.

The adsorption unit 200 forms a space having a predetermined length in the longitudinal direction in the monolith body 100 , and communicates with the inlet unit 110 . In the adsorption unit 200 , the adsorbent is treated and the volatile organic compounds in the harmful fluid introduced through the inlet unit 110 are adsorbed. Through this, the adsorption unit 200 adsorbs the volatile organic compounds in the introduced harmful fluid to a certain concentration.

The catalyst unit 300 is formed at the rear end of the adsorption unit 200 , and is formed to communicate with the adsorption unit 200 . The catalyst unit 300, like the adsorption unit 200, has a predetermined length in the longitudinal direction and forms a space, and is formed by processing to enable oxidation of the volatile organic compound by the catalyst. Through this, the volatile organic compound desorbed from the adsorption unit 200 and flowing into the catalyst unit 300 is oxidized to carbon dioxide and water using a catalyst.

As described above, the heating means 400 supplies and heats pulsed thermal energy to the adsorption unit 200 and the catalyst unit 300, so that the volatile organic compound is desorbed from the adsorption unit 200, and the catalyst unit 300 ), the catalysis by the catalyst is made. That is, the heating means 400 heats when the volatile organic compound adsorbed to the adsorption unit 200 reaches a selected concentration (saturation state, etc.), so that the volatile organic compound is desorbed from the adsorption unit 200 . In addition, the heating means 400 heats the catalyst unit 300 to oxidize and remove the desorbed and moved volatile organic compounds by the heating of the catalyst.

The heating means 400 has the advantage of being able to save energy compared to other heat energy supply means by supplying heat energy in a pulse type. In addition, by supplying the thermal energy in a pulse type, not only can the life of the catalyst be extended, but also thermal energy can be supplied only when necessary, so that energy can be efficiently used.

In addition, the body 100 is formed to communicate with the catalyst unit 300, and further includes a discharge unit 120 for discharging the fluid removed by oxidation of the volatile organic compound in the catalyst unit 300 to the outside. Since the discharge part 120 discharges the fluid from which the volatile organic compound has been removed to the outside, it is preferable to be formed in a different direction from the inlet part 110 so as not to mix with the harmful gas introduced through the inlet part 110 .

A preferred shape embodiment of the catalyst module 1000 for reducing pulsed volatile organic compounds according to an embodiment of the present invention described above will be described.

The monolith body 100 forms a space in at least two steps in the height direction, and at least one space in the width direction. At this time, the monolith body 100 is formed with an inlet 110 through which the harmful fluid is introduced at an end selected from one side in the longitudinal direction.

Since the adsorption unit 200 has to communicate with the inlet unit 110, it is formed at the stage where the inlet unit 110 is formed, and is formed to adsorb volatile organic compounds in the harmful fluid flowing from one side in the longitudinal direction to the other. do.

The catalyst unit 300 is formed at the remaining stage where the inlet unit 110 and the adsorption unit 200 are not formed, and the volatile organic compound is transferred from the adsorption unit 200 to the catalyst unit 300 formed at the other stage. The monolith body 100 is formed with a closing part 130 for closing the flow on the other side in the longitudinal direction. In addition, the monolith body 100 includes a communication unit 140 formed to communicate with the adsorption unit 200 and the catalyst unit 300 on the other side in the longitudinal direction.

The communication part 140 can establish communication between the adsorption part 200 and the catalyst part 300 through control of the length when the monolith body 100 is laminated, or it can be formed through a penetrating operation, etc. Yes it is possible

In the discharge part 120 of the monolith body 100, since the fluid flows in the longitudinal direction of the monolith body 100 by the closing part 130 in one direction, there is a risk that the harmful fluid flowing in through the inlet 110 is mixed. there is. To this end, the discharge unit 120 must be discharged in a direction different from the flow direction of the harmful fluid flowing into the monolith body 100 , and preferably, the discharge unit 120 is harmful flowing into one side of the monolith body 100 in the longitudinal direction. It is preferable to form so as to be discharged in the width direction, which is a direction perpendicular to the flow direction of the fluid.

For the above-described configuration, the discharge unit 120 includes the discharge closing unit 121 formed to close one side in the longitudinal direction of the stage where the catalyst unit 300 is formed, so that the fluid passing through the catalyst unit 300 is Block the flow in the inflow direction of hazardous fluids. In addition, when the discharge unit 120 is formed in at least two spaces in the width direction, the discharging communication unit 122 is formed so that the ends of the catalyst unit 300 communicate with each other.

As described above, in the catalyst module 1000 for reducing pulsed volatile organic compounds according to an embodiment of the present invention, harmful fluid is introduced through the inlet 110 from one side in the longitudinal direction of the monolith body 100 and adsorbed. While flowing in the other longitudinal direction along the part 200 , the volatile organic compound is adsorbed, and the volatile organic compound desorbed from the adsorption part 200 through heating of the heating means 400 is removed by the closing part 130 . It is moved to the catalyst unit 300 and is oxidized and removed while flowing from the other side in the longitudinal direction along the catalyst unit 300 to one side. The fluid from which the volatile organic compound has been removed is blocked from flowing in one longitudinal direction by the discharge closure unit 121 , and flows through the discharge communication unit 122 to be discharged to the outside through the discharge unit 120 . .

The catalyst module 1000 for reducing pulsed volatile organic compounds according to an embodiment of the present invention has at least two steps in the height direction, and at least one cell in the width direction, By forming the adsorption unit 200 and the catalyst unit 300 to alternate with each other, it is possible to prevent the length of the adsorption unit 200 and the catalyst unit 300 from being increased to form a flow path.

In addition, the adsorption unit 200 and the catalyst unit 300 are heated by the heating means 400 for heating for desorption of the volatile organic compound in the adsorption unit 200 or for catalysis in the catalyst unit 300 . Since it can be heated at the same time, heat can be efficiently applied to the adsorption unit 200 and the catalyst unit 300 .

The heating means 400 through the above-described configuration may be provided in a plate shape above and below the adsorption unit 200 and the catalyst unit 300 , which is located above and below the adsorption unit 200 and the catalyst unit 300 . Since both heating can be performed, it is possible to quickly reach the temperature for operation in the adsorption unit 200 and the catalyst unit 300 , and also uniformly in the adsorption unit 200 and the catalyst unit 300 . The temperature distribution can be made, and it is also easy to control it.

At this time, of course, the heating means 400 should be formed so as not to interfere with the flow of the volatile organic compound and the harmful fluid including the volatile organic compound flowing through the communication unit 140 .

In particular, in the catalyst module 1000 for reducing pulsed volatile organic compounds according to an embodiment of the present invention, when the catalyst of the catalyst unit 300 is heated by the heating means 400 and oxidation is started by the catalyst, Additional exotherm due to oxidation occurs. That is, since the adsorption operation in the adsorption unit 200 and the oxidation operation in the catalyst unit 300 are possible through the additionally generated heat energy, it is not necessary to continuously supply heat by the heating means 400 .

In other words, through the configuration and location of the adsorption unit 200 and the catalyst unit 300 described above, heat generated during oxidation can be efficiently used, so that heating by the heating means 400 can be minimized, which It has the advantage of being efficient in terms of energy use.

Another embodiment of the heating means 400 will be described.

4 is another view showing a partial sectional perspective view of a catalyst module for reducing pulsed volatile organic compounds according to an embodiment of the present invention, and FIG. 5 is another view for reducing pulsed volatile organic compounds according to an embodiment of the present invention. Another view showing the catalyst module in partial cross-sectional view.

4 and 5 , the heating means 400 may be formed inside the adsorption unit 200 and the catalyst unit 300 . At this time, the heating means 400 may be formed in a position selected from the height direction of the adsorption unit 200 and the catalyst unit 300 , and two or more are formed depending on the area of the adsorption unit 200 and the catalyst unit 300 . You may.

Since the heating means 400 is formed in the adsorption unit 200 and the catalyst unit 300 , it can be directly heated, and thus heating can be efficiently performed in the adsorption unit 200 and the catalyst unit 300 .

In this case, the heating means 400 is preferably disposed at the center in the height direction of the adsorption unit 200 and the catalyst unit 300 for uniform heating of the adsorption unit 200 and the catalyst unit 300, but is not limited thereto. .

In addition, the heating means 400 may be positioned coupled to both sides of the adsorption unit 200 and the catalyst unit 300 , as well as being coupled to the closing unit 130 for closing the other side of the monolith body 100 . If the heating means 400 can be easily located in the adsorption unit 200 and the catalyst unit 300, various embodiments are possible, of course.

6 is another diagram showing a partial sectional perspective view of a catalyst module for reducing pulsed volatile organic compounds according to an embodiment of the present invention, and FIG. 7 is a pulsed volatile organic compound reduction according to an embodiment of the present invention. It is another view showing a catalyst module for a partial cross-sectional view.

6 and 7, the heating means 400 may be formed at the end at which the communication portion 140 is formed. That is, the heating means 400 may be formed at the end of the adsorption unit 200 and the starting point of the catalyst unit 300 to apply heat to the adsorption unit 200 and the catalyst unit 300 .

The heating means 400 having the above configuration can generate heat and transfer heat to the adsorption unit 200 and the catalyst unit 300 to perform adsorption and oxidation operations, and can easily be heated through a simple shape ( 400) has the advantage that it can be formed inside the monolith body 100.

In addition, the heating means 400 may have a rod shape having a certain length in the width direction and various embodiments are possible, but it is preferable to form it in a circular shape to increase the area for supplying heat.

The catalyst module 1000 for reducing volatile organic compounds according to an embodiment of the present invention may further include a controller for controlling the operation of reducing volatile organic compounds. In this case, before transmitting the operation signal, the control unit may measure the selected information and transmit the operation signal according to the measurement. To this end, the control unit includes a flow measurement sensor (not shown) that is formed in the inlet 110 to measure the flow rate of the incoming harmful fluid, and a concentration sensor (not shown) that is formed in the communication unit 140 and specifically controls the concentration of the harmful fluid. ) may be included.

That is, while it is possible to control the flow rate flowing into the flow rate sensor, the desorption in the adsorption unit 200 and the oxidation in the catalyst unit 300 are performed or stopped through the concentration sensor. can do.

The present invention is not limited to the above-described embodiments, and the scope of application is varied, and anyone with ordinary skill in the art to which the present invention pertains without departing from the gist of the present invention as claimed in the claims It goes without saying that various modifications are possible.

100: body
110: inlet
120: discharge part
121: discharge closing part
122: exhaust communication part
130: closed part
140: communication part
200: adsorption unit
300: catalyst unit
400: heating means

Claims (7)

A monolith body 100 having at least two or more stages in the height direction and at least one space in the width direction, wherein harmful fluid flows into a stage selected from one side in the longitudinal direction and the other side in the longitudinal direction is closed;
an adsorption unit 200 formed to adsorb volatile organic compounds in the harmful fluid flowing from one side to the other side in the longitudinal direction at the selected end of the monolith body 100;
At the end where the adsorption unit 200 is not formed, the adsorption unit 200 and the other side in the longitudinal direction are formed to communicate with each other, and the volatile organic compound that is desorbed from the adsorption unit 200 and flows from the other side in the longitudinal direction to one side is added to the catalyst. Catalyst 300 for removing by oxidation; and
A heating means 400 that supplies pulsed thermal energy to the adsorption unit 200 and the catalyst unit 300 in a plate shape above and below the adsorption unit 200 and the catalyst unit 300; , a catalyst module for reducing pulsed volatile organic compounds.
A monolith body 100 having at least two or more stages in the height direction and at least one space in the width direction, wherein harmful fluid flows into a stage selected from one side in the longitudinal direction and the other side in the longitudinal direction is closed;
an adsorption unit 200 formed to adsorb volatile organic compounds in the harmful fluid flowing from one side to the other side in the longitudinal direction at the selected end of the monolith body 100;
At the end where the adsorption unit 200 is not formed, the adsorption unit 200 and the other side in the longitudinal direction are formed to communicate with each other, and the volatile organic compound that is desorbed from the adsorption unit 200 and flows from the other side in the longitudinal direction to one side is added to the catalyst. Catalyst 300 for removing by oxidation; and
Heating means 400 that supplies pulsed thermal energy to the adsorption unit 200 and the catalyst unit 300, and is provided in a selected position and number within the adsorption unit 200 and the catalyst unit 300; A catalyst module for reducing pulsed volatile organic compounds.
A monolith body 100 having at least two or more stages in the height direction and at least one space in the width direction, wherein harmful fluid flows into a stage selected from one side in the longitudinal direction and the other side in the longitudinal direction is closed;
an adsorption unit 200 formed to adsorb volatile organic compounds in the harmful fluid flowing from one side to the other side in the longitudinal direction at the selected end of the monolith body 100;
At the end where the adsorption unit 200 is not formed, the adsorption unit 200 and the other side in the longitudinal direction are formed to communicate with each other, and the volatile organic compound that is desorbed from the adsorption unit 200 and flows from the other side in the longitudinal direction to one side is added to the catalyst. Catalyst 300 for removing by oxidation; and
A heating means provided on the other side in the longitudinal direction of the monolith body 100 in which the adsorption unit 200 and the catalyst unit 300 are connected to supply pulsed thermal energy to the adsorption unit 200 and the catalyst unit 300 in communication. (400); including, a catalyst module for reducing pulsed volatile organic compounds.
4. The method of claim 3,
The heating means 400 is
A catalyst module for reducing pulsed volatile organic compounds, which is formed to have a length selected in the width direction.
The method according to any one of claims 1 to 3,
The monolith body 100 is
An inlet 110 communicated with the adsorption unit 200 on one side in the longitudinal direction and a harmful fluid is introduced thereinto;
A closing part 130 for closing the other side surface in the longitudinal direction of the monolith body 100,
A communication part 140 formed so that the adsorption part 200 and the catalyst part 300 communicate with each other on the other side in the longitudinal direction of the monolith body 100;
An exhaust closing part 121 for closing one longitudinal side of the monolith body 100 in communication with the catalyst part 300, and an end of the catalyst part 300 on one longitudinal side of the monolith body 100 A pulse type volatile organic compound, including a discharge communication unit 122 formed to communicate in the width direction, and a discharge unit 120 through which the fluid is discharged in a direction selected from the width direction of the monolith body 100 Catalyst module for abatement.
The method according to any one of claims 1 to 3,
The adsorption unit 200 and the catalyst unit 300 are
A catalyst module for reducing pulsed volatile organic compounds, which is formed to alternate in the height direction.
The method according to any one of claims 1 to 3,
The monolith body 100 is
and a communication part 140 formed to communicate with the adsorption part 200 and the catalyst part 300 on the other side in the longitudinal direction of the monolith body 100,
a flow rate measuring sensor for measuring the flow rate of the harmful fluid flowing into the adsorption unit 200;
A catalyst module for reducing pulse-type volatile organic compounds, including a concentration sensor formed in the communication unit 140 to measure the concentration of a harmful fluid.

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