KR101480215B1 - Air cleaner apparatus for construction like tunnel - Google Patents

Abstract

According to the present invention, there is provided an air conditioner comprising: a dehumidifier installed inside a tunnel for removing moisture from the air in the tunnel; A dust collector connected to the dehumidifier to remove fine dust in the air introduced from the dehumidifier; A catalytic reactor connected to the dust collector to remove carbon monoxide in the air introduced from the dust collector through a catalytic reaction; A plasma reactor connected to the catalytic reactor to remove volatile organic compounds in the air flowing from the catalytic reactor through a corona discharge; And a blower for generating a suction force to be sequentially transferred to the dust collector, the catalytic reactor, and the plasma reactor after the air in the tunnel is introduced through the dehumidifier, wherein the plasma reactor has an inlet And a discharge port through which the air is discharged, a pair of discharge electrodes being spaced apart from each other inside the discharge port, a body having a dielectric body disposed between the discharge electrodes, and a discharge electrode connected to the discharge electrode, And a power supply unit for generating a corona discharge on the high-voltage main body while supplying the high-voltage power to the high-voltage power source, wherein the high-voltage main body is barium titanate.
As described above, in the tunnel air purification apparatus, moisture and fine dust removed through the dehumidifier and the dust collector are passed through the catalytic reactor and the plasma reactor again. Accordingly, the air discharged to the outside of the tunnel is in a state in which the removal of carbon monoxide by the catalytic reaction of the catalytic reactor and the decomposition and removal of the volatile organic compounds by the corona discharge of the plasma reactor are completed.

Description

[0001] The present invention relates to an air cleaner apparatus,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a tunnel air purification apparatus, and more particularly, to a tunnel air purification apparatus for removing moisture, oil, and air pollutants from the atmosphere in a tunnel.

In general, a tunnel is a tunnel having a hollow section of considerable size formed by piercing through a mountain, underground, or a spruce for the purpose of traffic, watering, and the like.

However, the air in the tunnel is contaminated by various harmful substances emitted by vehicles, and in particular, in the case of tunnels in which construction is essential for the construction of high mountainous areas or highlands, The pollution degree of the inside air becomes considerably high. At this time, as a hazardous material and the like fine dust, carbon monoxide (CO), nitrogen oxides (NOx) volatile organic compound (VOC _S).

Accordingly, in the tunnel, a jet fan is installed in the tunnel to remove the harmful substance from the inside of the tunnel to create a comfortable driving environment, thereby ventilating the air inside the tunnel. That is, a plurality of jet fans having a blowing direction identical to the traveling direction of the vehicle are provided on the ceiling portion of the tunnel, and the contaminated air inside the tunnel is discharged to the outside of the tunnel by the blowing action of the jet fan, Is ventilated.

However, such a conventional ventilation system using a jet fan has a problem in that polluted air in the tunnel is discharged untreated to the surrounding environment of the tunnel, which inevitably involves contamination of the surrounding environment.

An object of the present invention is to provide a tunnel air purification apparatus for purifying gas-phase and particulate air pollutants in a tunnel and discharging the same.

According to the present invention, there is provided an air conditioner comprising: a dehumidifier installed inside a tunnel for removing moisture from the air in the tunnel; A dust collector connected to the dehumidifier to remove fine dust in the air introduced from the dehumidifier; A catalytic reactor connected to the dust collector to remove carbon monoxide in the air introduced from the dust collector through a catalytic reaction; A plasma reactor connected to the catalytic reactor to remove volatile organic compounds in the air flowing from the catalytic reactor through a corona discharge; And a blower for generating a suction force to be sequentially transferred to the dust collector, the catalytic reactor, and the plasma reactor after the air in the tunnel is introduced through the dehumidifier, wherein the plasma reactor has an inlet A main body having a discharge port through which the air is discharged, a pair of discharge electrodes spaced apart from each other, and a dielectric body disposed between the discharge electrodes, and a discharge electrode connected to the discharge electrode, And a power supply unit for generating a corona discharge on the high-dielectric material, wherein the high-dielectric material is barium titanate.

Also, a room temperature catalyst may be provided inside the catalytic reactor.

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A slid duck may be connected between the power supply unit and the discharge electrode, and a voltage supplied to the discharge electrode through the slid duck may be 3.3 to 3.5 kV.

In the tunnel air purification apparatus according to the present invention, moisture and fine dust removed through a dehumidifier and a dust collector are passed through a catalytic reactor and a plasma reactor again. Accordingly, the air discharged to the outside of the tunnel is in a state in which the removal of carbon monoxide by the catalytic reaction of the catalytic reactor and the decomposition and removal of the volatile organic compounds by the corona discharge of the plasma reactor are completed.

1 is a schematic block diagram of a tunnel air purification apparatus according to an embodiment of the present invention.
2 is a schematic structural view of the catalytic reactor shown in Fig.
3 is a schematic structural view of the plasma reactor shown in Fig.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Reference will now be made in detail to the preferred embodiments of the present invention, examples of which are illustrated in the accompanying drawings.

1 is a schematic block diagram of a tunnel air purification apparatus according to an embodiment of the present invention. Referring to FIG. 1, the tunnel air purification apparatus includes a dehumidifier 100, a dust collector 200, a catalytic reactor 300, a plasma reactor 400, and a blower 500.

The dehumidifier 100 removes moisture in the air inside the tunnel (not shown). That is, the dehumidifier 100 receives the air in the tunnel in the state of being installed in the tunnel, removes moisture, and discharges it to the dust collector 200 to be described later. The dehumidifier 100 may remove moisture from the air inside the tunnel through a dehumidifying agent, a dehumidifying filter, or a heating system. However, the present invention is not limited thereto.

Thus, the dehumidifier 100 removes moisture from the air inside the tunnel, thereby increasing the efficiency of the purification while improving the contact ratio between the carbon monoxide and the catalyst supplied to the catalytic reactor 300. In addition, the dehumidifier 100 may be provided with a humidity sensor (not shown) and a humidity controller (not shown). After the humidity sensor senses the humidity in the air, the humidity sensor senses the humidity in the air and transmits the sensed humidity to the dust collector 200 while controlling the humidity controller (not shown) The humidity in the air can be controlled.

The dust collector 200 removes fine dust in the air inside the tunnel. That is, the dust collector 200 is connected to the dehumidifier 100 and removes moisture through the dehumidifier 100 to remove fine dust. Then, the dust collector 200 discharges the air to the catalyst reactor 300 to be described later. do. The dust collector 200 may remove fine dust in the air supplied from the dehumidifier 100 through a filter, a cyclone, or an electric dust collection system. However, the present invention is not limited thereto and a known dust collector can be selectively applied to the dust collector 200. Of course.

The catalytic reactor 300 removes carbon monoxide from the air inside the tunnel. That is, the catalytic reactor 300 is connected to the dust collector 200 to remove carbon monoxide from the dust-removed air through the dust collector 200, and then discharges the carbon monoxide to the plasma reactor 400, . The catalytic reactor 300 removes carbon monoxide in the air supplied from the dust collector 200 through a catalytic reaction. 2, the room temperature catalyst 310 is inserted into the tubular body 301 of the catalytic reactor 300. At this time, the room temperature catalyst 310 is connected to the inlet 301 of the body 301 301 and then discharged through the discharge port 302 to the plasma reactor 400 to be described later to maintain the removal efficiency through the catalytic reaction even at a low temperature of 25 ° C or lower.

The plasma reactor 400 removes volatile organic compounds in the air inside the tunnel. That is, the plasma reactor 400 is connected to the catalytic reactor 300 to remove the carbon monoxide-removed air through the catalytic reactor 300, to remove volatile organic compounds, and then to be discharged to the outside of the tunnel. The plasma reactor 400 removes the volatile organic compounds in the air supplied from the catalytic reactor 300 by a plasma reaction.

3, the plasma reactor 400 includes a main body 410 having a dielectric 414 therein, a power supply 420 for supplying a voltage to generate a corona discharge by the dielectric 414, ). The main body 410 is a tubular structure having a space portion therein. The main body 410 has an inlet 411 connected to the catalytic reactor 300 to allow the air to flow therethrough, And an outlet 412 for discharging it to the outside is formed. The high dielectric 414 is filled between the discharge electrodes 413 in a state where a pair of discharge electrodes 413 are provided in the body 410 so as to be spaced apart from each other. Here, barium titanate (BaTiO 3) may be selected as the high-dielectric 414. The power supply unit 420 is connected to the discharge electrode 413 to supply a voltage to the discharge electrode 413 so that a corona discharge is generated in the high dielectric 414. A slider (not shown) may be connected between the power supply unit 420 and the discharge electrode 413. The slider duck causes the voltage supplied to the discharge electrode 413 to be maintained at 3.3 to 3.5 kV.

The plasma reactor 400 generates a corona discharge on the dielectric 414 charged between the discharge electrodes 413 so that the air introduced into the body 410 flows into the dielectric 414, The volatile organic compounds in the air are decomposed and removed.

Here, the tunnel air purification apparatus according to one embodiment is described as cleaning the air passing through the dust collector 200 through the catalytic reactor 300 and flowing into the plasma reactor 400 The present invention is not limited thereto and the air that has passed through the dust collector 200 may be first introduced into the plasma reactor 400 to flow into the catalytic reactor 300 with the volatile organic compounds removed, Of course.

The blower 500 allows the air inside the tunnel to be discharged to the outside of the tunnel. That is, the air blower 500 sequentially moves the dust collector 200, the catalytic reactor 300, and the plasma reactor 400 after the air in the tunnel is introduced into the dehumidifier 100, And a suction force is generated so as to be discharged to the outside of the tunnel. The blower 500 is connected to the outlet 412 of the plasma reactor 400 and sequentially conveys the air to the dehumidifier 100, the dust collector 200, and the catalytic reactor 300 connected to each other. (Not shown) connected to the dehumidifier 100, the dust collector 200, and the catalytic reactor 300, and is connected to the dehumidifier 100. The dehumidifier 100 is connected to the catalytic reactor 300 through a plurality of branch lines A suction force may be generated in the catalytic reactor 100, the dust collector 200, and the catalytic reactor 300, respectively.

Operation of the tunnel air purifier according to one embodiment of the present invention will now be described. When the blower 500 is operated, the air inside the tunnel flows into the dehumidifier 100. When the air in the tunnel flows into the dehumidifier 100, moisture in the air is removed from the dehumidifier 100, and then the dust is moved to the dust collector 200.

When the air is introduced into the dust collector 200, the dust collector 200 removes fine dust from the air and discharges the air to the catalyst reactor 300. The air introduced into the catalytic reactor 300 is discharged through the plasma reactor 400 after the carbon monoxide in the air is removed by the catalytic reaction of the room temperature catalyst 310 in the catalytic reactor 300.

The air introduced into the plasma reactor 400 through the catalytic reactor 300 is decomposed and removed from the air by the corona discharge generated in the plasma reactor 400.

Thus, the air discharged from the plasma reactor 400 is discharged to the outside of the tunnel.

The tunnel air purification apparatus according to an embodiment of the present invention may be configured such that air having moisture and fine dust removed through the dehumidifier 100 and the dust collector 200 is returned to the catalyst reactor 300 and the plasma reactor 400). Therefore, the air discharged to the outside of the tunnel is in a state in which the carbon monoxide is removed by the catalytic reaction of the catalytic reactor 300 and the decomposition and removal of the volatile organic compounds by the corona discharge of the plasma reactor 400 is completed.

While the present invention has been described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims. Accordingly, the true scope of the present invention should be determined by the technical idea of the appended claims.

100: dehumidifier 200: dust collector
300: catalytic reactor 400: plasma reactor
500: blower

Claims (4)

A dehumidifier installed inside the tunnel for removing moisture from the air in the tunnel;
A dust collector connected to the dehumidifier to remove fine dust in the air introduced from the dehumidifier;
A catalytic reactor connected to the dust collector to remove carbon monoxide in the air introduced from the dust collector through a catalytic reaction;
A plasma reactor connected to the catalytic reactor to remove volatile organic compounds in the air flowing from the catalytic reactor through a corona discharge; And
And a blower for generating a suction force to be sequentially transferred to the dust collector, the catalytic reactor, and the plasma reactor after the air in the tunnel is introduced through the dehumidifier,
Wherein the plasma reactor comprises:
A main body having a pair of discharge electrodes spaced apart from each other and having a dielectric body disposed between the discharge electrodes,
And a power supply unit connected to the discharge electrode, for generating a corona discharge on the high dielectric material while supplying a voltage to the discharge electrode,
Wherein the high-dielectric-constant material is barium titanate. The method according to claim 1,
And a room temperature catalyst is provided inside the catalytic reactor. delete The method according to claim 1,
A slider dash is connected between the power supply unit and the discharge electrode,
And the voltage supplied to the discharge electrode through the slider duck is 3.3 to 3.5 kV.

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