KR200376289Y1 - catalyzer reaction apparatus - Google Patents

Abstract

Provided is a catalytic reaction apparatus for volatile organic compounds generated in a painting facility. The provided catalytic reaction apparatus includes a main body, a suction port located below the main body and connected to communicate with an interior of a painting facility, a filter chamber provided inside the main body to communicate with the suction port, and positioned above the filter chamber. A fan chamber provided inside the main body and having a blower for forcibly sucking contaminant gas generated in the coating equipment through the suction port, and an exhaust duct installed at an upper portion of the main body so as to communicate with the fan chamber; The pre-filter as the primary filter, the PP filter as the secondary filter, the catalytic oxidation adsorbent filter as the third filter, and the fiber filter as the fourth filter are sequentially stacked.

Description

Catalytic reaction apparatus for volatile organic compounds generated in coating facilities

The present invention relates to a catalytic reaction apparatus for volatile organic compounds generated in a coating facility.

Among the various air pollutants known to date, the pollutants that are particularly harmful to the human body include volatile nitrogen compounds (VOCs), for example nitrogen compounds, which are produced in a large amount during heat treatment after coating a vehicle. have. Accordingly, it is prescribed in the related law that an air purifying device is essentially provided in various coating equipments for painting the vehicle.

On the other hand, the air purifier for purifying pollutants such as nitrogen compounds has an adsorption filter that adsorbs the pollutants, and passes the polluted air through the adsorption filter to adsorb / smell odorous gas or smoke through the adsorption filter. The deodorizing apparatus is the mainstream, and the adsorption filter installed in the air purifier is a filter filled with a substance capable of adsorbing contaminants, and an example thereof is an activated carbon filter.

1 is a configuration diagram for explaining a typical example of a conventional air purifier.

Referring to FIG. 1, in the air purifier 100, a main body 110 is divided into a filter chamber 120, a fan chamber 130, and an exhaust duct 140, in front of the filter chamber 120. The suction port 150 is positioned to communicate with the interior of the painting facility (300). The filter chamber 120 is provided with a pre-filter and a plurality of activated carbon filters 121. The activated carbon filters 121 are vertically arranged at predetermined intervals in the filter chamber 120, and each of the activated carbons arranged vertically. Behind the filter 121, a damper 160 for forming an air passage is installed. Accordingly, the existing air purifier 100 generates suction force in the fan chamber 130, forcibly sucks in the polluted air inside the coating facility 300 through the suction port 150, and the sucked polluted air is activated carbon. After passing through the filter 121 to filter the contaminants (nitrogen compounds) and discharged to the exhaust duct 140 to remove the contaminants.

In this case, in the conventional air purifier 100, when the activated carbon filter 121 is used for a predetermined period, contaminants (nitrogen compounds, etc.) are adsorbed to the surface and inside of the activated carbon, so that the filtering efficiency is reduced. For this reason, the conventional air purifier 100 is a filter regeneration means for removing the contaminants adsorbed on the activated carbon filter 121, such as combustion, microbial or catalytic oxidation filter regeneration means (not shown in the figure). More).

However, since the conventional air purifying apparatus 100 must have a separate filter regenerating means to regenerate the activated carbon filter 121 as described above, the apparatus itself is excessively large and occupies a lot of installation space, as well as its manufacturing cost. There is a problem that rises.

In addition, through the filter regeneration means included in the existing air purification apparatus 100 can not expect the filter regeneration efficiency of 30 ~ 40% or more, if the reused activated carbon filter with a low regeneration efficiency as described above, Filtering efficiency of pollutants (nitrogen compounds, etc.) is reduced, and pollutants (nitrogen compounds, etc.) are released into the air without being completely filtered by the activated carbon filter, causing air pollution.

Therefore, the present invention was devised to solve the general problems of the air purifier installed in the existing painting facility,

The technical problem to be achieved by the present invention is to provide a catalytic reaction apparatus for volatile organic compounds that can perform efficient filtering without replacing the existing activated carbon with a catalytic oxidation adsorbent without a separate filter regeneration means.

Another technical problem to be achieved by the present invention is to provide a catalytic reaction apparatus for volatile organic compounds that can reduce the size of the apparatus as well as reduce the manufacturing cost by excluding the filter regeneration means.

Another object of the present invention is to provide a catalytic reaction apparatus for volatile organic compounds capable of fundamentally oxidizing and decomposing volatile organic compounds by applying a multi-filter structure.

As a specific means of the present invention for solving the above technical problem;

main body;

A suction port located below the main body and connected to communicate with an interior of a painting facility;

A filter chamber provided inside the main body to communicate with the suction port;

A fan chamber provided inside the main body so as to be positioned above the filter chamber, and having a blower for forcibly sucking the polluted gas generated in the painting facility through the suction port; And

An exhaust duct installed in an upper portion of the main body so as to communicate with the fan chamber; Including,

The filter chamber has a pre-filter as a primary filter, a PP filter as a secondary filter, a catalytic oxidation adsorbent filter as a third filter, and a fiber filter as a fourth filter. And a catalytic reaction device for volatile organic compounds.

In a preferred embodiment, the tertiary filter installed in the filter chamber is arranged vertically at a predetermined interval between the secondary filter and the fourth filter, and formed in an annular shape inside each tertiary filter. The surface of the zeolite is filled with a plurality of carriers coated with an oxidation catalyst.

More preferably, the tertiary filter is provided with guide rails on the upper and lower surfaces thereof so as to slide to the filter chamber, and a handle is provided at the front thereof, and an opening and closing door is provided at the filter chamber.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

2 is a cross-sectional view for explaining a catalytic reaction apparatus of volatile organic compounds generated in the coating facility according to the present invention.

Referring to FIG. 2, the catalytic reaction apparatus 1 has a main body 11 installed outside the coating equipment. The main body 11 is connected to communicate with the painting equipment through the suction port 4 installed in the lower portion, the filter chamber 2 and the fan chamber 3 is configured in the upper, lower divided form, An exhaust duct 5 communicating with the fan chamber 3 is installed at an upper portion thereof.

At this time, the first to fourth filters 21 to 24 are sequentially stacked on the filter chamber 2, and each of the filters 21 to 24 is formed by filling a filter material in the filter body having a mesh shape. Has

The primary filter 21 is made of Poly Wowen as its constituent material and performs a pre-filter role.

The secondary filter 22 is located directly above the primary filter 21, and the material of the secondary filter 22 is formed of P. P and serves as a medium-filter.

The tertiary filter 23 is a catalytic oxidation adsorbent filter for oxidizing and decomposing volatile organic compounds. A plurality of carriers 232 having an oxidation catalyst applied to a surface of a zeolite shaped in a ring form are filled in the filter body 231. Has been configured. Such tertiary filters 23 are arranged vertically at a predetermined interval between the secondary filter 22 and the fourth filter 24, and contaminant gas containing volatile organic compounds is formed in each tertiary filter. An open section 25 and a closed section 26 are formed in a zigzag form between the respective tertiary filters 23 so as to pass through the 23.

Here, the carrier 232 filled in the tertiary filter 23 is completely oxidatively decomposed volatile organic compounds into CO ₂ + H ₂ O using the adsorption characteristics of the zeolite 232a and the oxidation reaction of the oxidation catalyst 232b. Thus, unlike conventional adsorbents (such as activated carbon), volatile organic compounds can be oxidized and decomposed fundamentally. In particular, benzene (carcinogen) contained in volatile organic compounds and toluene and xylene, which are toxic and can form surface ozone, are completely oxidized and decomposed into CO ₂ and H ₂ O by adsorption and oxidation. This has the advantage of excellent, high safety and long lasting. In this case, the life of the carrier 232 has a longer life (at least about 1 year) than the conventional activated carbon filter, when the oxidation catalyst 232b coated on the surface of the zeolite 232a is consumed by reaction with the volatile organic compound Can be re-coated and regenerated by the oxidation catalyst 232b. In other words, the carrier 232 applied to the tertiary filter 23 of the present invention, unlike the existing activated carbon filter, which should have a separate filter regeneration means, regenerates and uses the carrier 232 without installing a filter regeneration means. It can be.

Meanwhile, in order to regenerate the carrier 232 as described above, the tertiary filter 23 should be easily detachable from the filter chamber 2, and for this purpose, the slide mount detachment method is applied to the present invention.

FIG. 3 is an enlarged view of a main body to explain a third order filter to which a slide mount detachment method is applied.

Referring to FIG. 3, the filter chamber 2 is provided with an opening / closing door 27, and the tertiary filter 23 is guide rails 231a disposed on upper and lower surfaces thereof so that the third filter 23 slides to the filter chamber 2. Is provided. Such opening and closing door 27 is preferably provided with a separate sealing means (not shown in the figure) for preventing the outflow of polluted gas, the predetermined portion of the filter body 231 of the tertiary filter 23 It is preferable to provide a handle (231b). Alternatively, the opening and closing door 27 and the tertiary filter 23 may be integrally formed. In this case, the tertiary filter 23 and the filter chamber are also separated through the operation of separating the opening and closing door 27 from the filter chamber 2. It can be separated in (2). In addition, the filter body 231 of the tertiary filter 23 is provided with a prefabricated structure or a separate opening means (for example, carrier injection hole (h) to facilitate the filling and discharging operation of the carrier 232) ) May be provided. Accordingly, in the regeneration operation of the carrier 232 which has reached the end of its service life, the opening and closing door 27 of the filter chamber 2 is opened, and the tertiary filter 23 is detached from the inside of the filter chamber 2 in a slide manner. After reapplying the oxidation catalyst 232b while the carrier 232 filled in the primary filter 23 is discharged to the outside, and after the application of the oxidation catalyst 232b is finished, the above operation is performed in the reverse order. The task is complete.

Referring back to FIG. 2, the quaternary filter 24 is installed directly above the tertiary filter 23. Such a fourth-order filter 24 serves as a final filter as a fiber filter.

Meanwhile, the fan chamber 3 is located above the filter chamber 2 in the main body as shown in FIG. 2, and the fan chamber 3 includes a blower 31: a driving motor 32. Is installed, and an exhaust duct 5 communicating with the blower 31 is installed at an upper portion of the fan chamber 3.

Thus, the operation of the catalytic reaction device of the volatile organic compounds generated in the coating facility according to the present invention having the configuration as described above will be described.

4 is a functional state diagram of a catalytic reaction device of volatile organic compounds generated in the coating facility according to the present invention.

Referring to FIG. 4, when the blower 31 installed in the fan chamber 3 is driven to suction the polluted gas generated in the coating facility 10 through the suction port 4 into the main body 11, the suction The pollutant gas is filtered through the primary filter 21 and the secondary filter 22 installed in the filter chamber 2. Thereafter, the polluted gas is induced to flow into the open section 25 provided on the upper and lower portions of the tertiary filter 23 (arrows in the drawing), in which case the contamination is caused by the carrier 232 of the tertiary filter 23. Volatile organic compounds present in the gas are oxidized and decomposed at the source. Thereafter, the polluted gas is exhausted to the outside through the exhaust duct 5 through the fourth filter 24 and the blower 31.

Therefore, the catalytic reaction device 1 according to the present invention is arranged in the filter chamber 2 provided in the main body 11, the first to fourth filters 21 to 24 arranged in a number of times, especially pollutants, in particular volatile organic compounds It can be filtered to prevent air pollution, and the carrier 232 filled in the tertiary filter 23 is composed of zeolite and an oxidation catalyst applied to the zeolite, thereby completely oxidizing and decomposing volatile organic compounds. There is an advantage. In addition, the carrier 232 can be regenerated without using a separate filter regeneration means through the operation of reapplying the oxidation catalyst.

As described above, the catalytic reaction apparatus according to the present invention is provided with a plurality of filters arranged in the filter chamber, but the third filter has the effect of being able to oxidize and decompose volatile organic compounds by filling a carrier which is a catalytic oxidation adsorbent.

In addition, the carrier filled in the tertiary filter has the advantage that the device can be miniaturized without having a separate filter regeneration means, as well as the manufacturing cost can be reduced.

1 is a configuration diagram for explaining a typical example of a conventional air purifier.

2 is a cross-sectional view for explaining a catalytic reaction apparatus of volatile organic compounds generated in the coating facility according to the present invention.

FIG. 3 is an enlarged view of a main body to explain a third order filter to which a slide mount detachment method is applied.

4 is a functional state diagram of a catalytic reaction device of volatile organic compounds generated in the coating facility according to the present invention.

<Explanation of symbols for major parts of drawing>

1: catalytic reaction device 2: filter chamber

3: fan chamber 4: inlet

5: exhaust duct 10: coating equipment

11: main body 21-24: 1st-4th order filter

25: open section 26: closed section

27: opening and closing door 31: Brow

32: drive motor 231: filter body

231a: carrier 231b: guide rail

232: handle 232a: zeolite

232b: oxidation catalyst h: carrier insertion hole

Claims (3)

main body; A suction port located below the main body and connected to communicate with an interior of a painting facility; A filter chamber provided inside the main body to communicate with the suction port; A fan chamber provided inside the main body so as to be positioned above the filter chamber, and having a blower for forcibly sucking the polluted gas generated in the painting facility through the suction port; And An exhaust duct installed in an upper portion of the main body so as to communicate with the fan chamber; Including, The filter chamber has a pre-filter as a primary filter, a PP filter as a secondary filter, a catalytic oxidation adsorbent filter as a third filter, and a fiber filter as a fourth filter. Catalytic reaction device of the volatile organic compound. The method of claim 1, The tertiary filter installed in the filter chamber is vertically arranged with a plurality of predetermined intervals between the secondary filter and the fourth filter, and oxidized on the surface of the zeolite formed in a ring shape inside each tertiary filter. Catalytic reaction apparatus for volatile organic compounds generated in a coating facility, characterized in that the carrier is filled with a plurality of carriers coated with a catalyst. According to claim 2, wherein the tertiary filter is provided with guide rails on the upper and lower surfaces of the tertiary filter to be slide-coupled to the filter chamber, a handle is provided on the front thereof, and the opening and closing door is provided on the filter chamber. Catalytic reaction device for volatile organic compounds generated in the facility.