JP2002346335A - Gas treatment apparatus - Google Patents

Abstract

PROBLEM TO BE SOLVED: To generate a stable streamer discharge. SOLUTION: A gas treatment apparatus treats a treatment component contained in gas by generating the streamer discharge. A needle-shaped discharge electrode (21) which is arranged in a gas passage, is connected with a high voltage power source for the application of a positive voltage, and discharges electricity between it and a counter electrode (22) is provided. A carbon dioxide supply means (40) which discharges carbon dioxide into the gas passage (13) to increase the concentration of carbon dioxide around the tip of the discharge electrode (21) is provided. Carbon dioxide is discharged so that the concentration of carbon dioxide around the discharge electrode (21) is 0.5% or above.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a gas treatment apparatus, and more particularly to a measure against streamer discharge.

[0002]

2. Description of the Related Art Conventionally, there has been known a gas processing apparatus which generates plasma by electric discharge and reacts components to be treated such as harmful components and odor components in a gas with active species generated in the plasma to decompose and remove the same. ing. As this type of gas processing apparatus, there is an apparatus in which a needle-like discharge electrode and a mesh-like counter electrode are arranged in a gas passage, and a power supply for pulse generation is connected to both electrodes. With such a configuration of the gas processing apparatus, a streamer discharge can be generated between both electrodes. In the streamer discharge, the active species diffuse and flow in an umbrella shape, so that the processing capability of the component to be treated is significantly improved.

For example, Japanese Patent Application Laid-Open Nos. 8-155249 and 9-869 disclose apparatuses for performing a gas treatment by generating a streamer discharge between a needle electrode and a planar electrode.

[0004]

However, streamer discharge has the advantage of significantly improving the processing capability, but has the problem that it is difficult to generate a stable streamer discharge. In other words, the streamer discharge has a problem that the adjustment of the applied voltage is delicate and may not occur depending on the surrounding conditions.

[0005] The present invention has been made in view of the above, and has as its object to generate a stable streamer discharge.

[0006]

According to the present invention, the concentration of carbon dioxide around a discharge electrode is increased. In other words, the inventor of the present application has newly found that the concentration of carbon dioxide is deeply involved in the generation of streamer discharge as a result of years of intensive research.

The inventor of the present application has conducted an experiment to investigate the effect of the concentration of carbon dioxide in the reaction vessel on the occurrence of streamer discharge using a reaction vessel having a needle-shaped discharge electrode connected to a DC power supply. Was. A positive voltage was applied to the discharge electrode from a DC power supply.

FIG. 3 shows an example of the experimental results. FIG. 3 shows the correlation between the voltage applied to the discharge electrode and the ozone concentration. Ozone is generated by discharge, and the amount of ozone increases with an increase in the amount of discharge, but the amount of ozone varies depending on the form of discharge.

For example, as shown in FIG. 3, in a discharge in air (carbon dioxide concentration: 0.03%), a corona discharge occurs at an applied voltage of about 4.5 KV, and the discharge amount decreases as the applied voltage increases. As it increases, the ozone concentration increases linearly.

When carbon dioxide is supplied such that the carbon dioxide concentration becomes 0.5%, the ozone concentration increases linearly with an increase in the applied voltage, as in the case of the concentration of 0.03%. Then, when the applied voltage becomes about 8 KV, a streamer discharge occurs, and the ozone concentration becomes about twice as high as that when the concentration is 0.03%. When a voltage of about 8 KV is applied in air, corona discharge occurs and no streamer discharge occurs.

When carbon dioxide is supplied so that the carbon dioxide concentration becomes 1.5%, the applied voltage is about 5 kV.
As a result, the streamer discharge is generated stably, so that the ozone concentration becomes extremely high. Then, as the applied voltage increases,
The ozone concentration increases markedly in a curve. When a voltage of about 5 KV is applied when carbon dioxide is 1% or less, corona discharge occurs and streamer discharge does not occur.

That is, as the concentration of carbon dioxide around the discharge electrode increases, the amount of streamer discharge increases and the applied voltage at which streamer discharge occurs decreases. It can be said that streamer discharge can be stably generated by increasing the carbon dioxide concentration.

Therefore, based on the above experimental results, the present invention is to supply carbon dioxide so as to increase the concentration of carbon dioxide around the discharge electrode.

Specifically, the first solution means is based on the premise that a gas processing apparatus that generates a streamer discharge in a gas passage (13) through which a gas flows to process a component to be processed contained in the gas is provided. Discharging means (20) which is disposed in the gas passage (13) and is connected to a power supply (24) and discharges between a needle-like discharge electrode (21) to which a positive voltage is applied and a counter electrode (22). ) And carbon dioxide supply means (40) for causing carbon dioxide to flow out in the gas passage (13) so that the carbon dioxide concentration at least around the tip of the discharge electrode (21) increases.

A second solution is the carbon dioxide supply means (40) according to the first solution, wherein the carbon dioxide supply source (48) is connected to the carbon dioxide supply source (48); A carbon dioxide passage (41) having an outlet (44) is provided upstream of the discharge electrode (21) in the gas passage (13).

According to a third aspect of the present invention, in the first aspect, the carbon dioxide supply means (40) is connected to the carbon dioxide supply source (48). A connection passage (51), connected to the connection passage (51),
An electrode passage (52) formed in the discharge electrode (21) and having an outlet (44) opened at the tip of the discharge electrode (21).

According to a fourth aspect of the present invention, in the first aspect of the invention, the carbon dioxide supply means (40) has a carbon dioxide concentration around the discharge electrode (21) of 0.1. It is configured to allow carbon dioxide to flow out to 5% or more.

According to a fifth aspect of the present invention, in the first aspect of the present invention, the carbon dioxide supply means (40) has a carbon dioxide concentration around the discharge electrode (21) of one. It is configured to discharge carbon dioxide so as to have a concentration of 0.5% or more.

According to a sixth aspect of the present invention, in any one of the first to fifth aspects, the power supply (24) is a DC power supply.

That is, in the first solution, the gas containing the component to be processed flows through the gas passage (13). A positive voltage is applied to the discharge electrode (21) from the power supply (24) to perform discharge between the discharge electrode (21) and the counter electrode (22). At this time, the carbon dioxide supply means (40) causes the carbon dioxide to flow out into the gas passage (13), so that the carbon dioxide concentration at least around the tip of the discharge electrode (21) is increasing. Therefore, a streamer discharge is stably generated from the tip of the discharge electrode (21). The active species generated by the streamer discharge react with the component to be treated in the gas to decompose the component to be treated.

Further, in the second solution, the first solution
In the above solution, the carbon dioxide discharged from the carbon dioxide supply means (40) flows into the carbon dioxide passage (41) from the carbon dioxide supply source (48), and is upstream of the discharge electrode (21) in the gas passage (13). Flows into the side. The carbon dioxide flowing into the gas passage (13) flows around the discharge electrode (21) together with the gas containing the component to be treated. Therefore, at least the concentration of carbon dioxide around the tip of the discharge electrode (21) increases. Then, a stable streamer discharge is generated from the tip of the discharge electrode (21).

Further, in the third solution, the first solution
The carbon dioxide supplied by the carbon dioxide supply means (40) flows from the carbon dioxide supply source (48) through the connection passage (51). The carbon dioxide flowing through the connection passage (51) flows into the electrode passage (52) formed in the discharge electrode (21), and flows out from the outlet (44) opened at the tip of the discharge electrode (21). Therefore, the concentration of carbon dioxide around the tip of the discharge electrode (21) increases. Then, a stable streamer discharge is generated from the tip of the discharge electrode (21).

In the fourth solution, the first solution
In any one of the third to third solutions, the carbon dioxide supply means (40) discharges carbon dioxide and discharges the carbon dioxide.
The carbon dioxide concentration around the tip in 1) is 0.5%
That is all. Streamer discharge is performed between the discharge electrode (21) and the counter electrode (22) in this atmosphere.

Further, in the fifth solution means, the first solution
To the third solution, the carbon dioxide supply means (40) supplies carbon dioxide, and the discharge electrode (21)
, The carbon dioxide concentration becomes 1.5% or more. In this atmosphere, the discharge electrode (21) and the counter electrode (2
Streamer discharge occurs between 2).

In the sixth solution, the first solution
The power supply (24).
Supplies DC power to the discharge electrode (21).

[0026]

Therefore, according to the first solution,
Since the carbon dioxide is caused to flow at least so as to increase the carbon dioxide concentration around the tip of the discharge electrode (21), a stable streamer discharge can be generated. Therefore, the processing capability of the component to be processed in the gas can be significantly improved.

Further, by increasing the concentration of carbon dioxide around the tip of the discharge electrode (21), a stable streamer discharge can be generated without arc discharge even when a DC power supply is used. it can.

According to the second solution, carbon dioxide can be discharged with a simple structure.

According to the third solution, the concentration of carbon dioxide around the tip of the discharge electrode (21) can be reliably increased.

Further, according to the fourth solution, stable streamer discharge can be generated even at an applied voltage at which streamer discharge does not occur in air. As a result, the processing ability of the component to be processed can be significantly improved. Further, even when the outflow of carbon dioxide cannot be increased, a stable streamer discharge can be generated.

According to the fifth solution, the applied voltage at which a stable streamer discharge occurs can be reduced. As a result, power consumption can be reduced. Also, by increasing the carbon dioxide concentration, the amount of streamer discharge can be increased. As a result, the processing capability of the component to be processed can be further improved.

Further, according to the sixth aspect of the present invention, by using an inexpensive DC power supply, the apparatus can be manufactured at a lower cost than using a power supply for pulse generation.

[0033]

Embodiments of the present invention will be described below in detail with reference to the drawings.

Embodiment 1 of the present invention, as shown in FIG. 1, is a gas treatment apparatus (1) for purifying air by decomposing and removing odorous or harmful components which are components to be treated in air.

The gas treatment device (1) includes a casing (1)
0), a gas passage (13) is formed, and each functional component is housed in the gas passage (13). In the casing (10), a dust collecting filter (11), a discharging means (20), an ozone decomposition catalyst (25), and a centrifugal fan (12) are housed as functional components. Further, the gas processing device (1) includes a carbon dioxide supply means (40).

An air suction port (15) for sucking air into the gas passage (13) is formed on one side surface (left side surface in the figure) of the casing (10), and the gas passage (1) is formed on the upper surface.
An air outlet (16) for blowing out purified air from 3) is formed. The air outlet (16) is formed on the upper surface of the casing (10) at the edge opposite to the air inlet (15) (right edge in the figure). The air inlet (15) is provided with a suction grill (15a), and the air outlet (16) is provided with a blow grill (16a).

The dust collecting filter (11) is provided in the gas passage (1).
It is located inside the suction grille (15a) in 3). The dust collection filter (11) is configured to capture dust contained in the intake air.

The centrifugal fan (12) has an air outlet (1
6) It is located on the lower side. Centrifugal fan (1
2) is configured to blow out the sucked air through the air outlet (16) to the outside of the casing (10). The centrifugal fan (12) supplies power and changes the rotation speed of the centrifugal fan (12).
a) is connected.

The discharge means (20) includes a discharge electrode (21) and a counter electrode (22). The two electrodes (21) are used to decompose components to be treated such as odor components and harmful components in the air. , 2
It is configured to perform discharge between 2) and generate plasma.

The discharge electrode (21) is disposed so as to be located upstream of the gas passage (13) with respect to the counter electrode (22).

The discharge electrode (21) is formed in a needle shape extending from a plurality of projections (23) provided on a flat plate (28). Each discharge electrode (21) is configured to extend from the tip of each projection (23) toward the counter electrode (22). The flat plate (28) is arranged so as to cross the gas passage (13), and has a large number of openings (29) through which air passes.

The counter electrode (22) is formed in a plate shape having a large number of openings (33) for passing air. The counter electrode (22) is made of, for example, a mesh material, a punching metal, or the like. Counter electrode (22)
Are arranged so as to cross the gas passage (13), and are configured such that air passes in a direction perpendicular to the plane of the counter electrode (22).

The discharge electrode (21) is connected to a high voltage power supply (24) via a flat plate (28). The high voltage power supply (24)
Is connected to the counter electrode (22). The high-voltage power supply (24) is arranged below the gas passage (13), and is configured to supply DC power to the discharge electrode (21). That is, the discharge electrode (21) is configured so that a positive voltage is applied by the high-voltage power supply (24).

The ozone decomposing catalyst (25) is provided downstream of the counter electrode (22) in the gas passage (13), and is configured to decompose ozone generated by discharge from the discharge electrode (21). .

The carbon dioxide supply means (40) includes a gas cylinder (48) as a carbon dioxide supply source and a carbon dioxide passage (41), and the carbon dioxide concentration at least around the tip of the discharge electrode (21) increases. So that carbon dioxide flows out in the gas passage (13). The carbon dioxide passage (41) has a straight tubular outlet (42) disposed upstream of the discharge electrode (21) in the gas passage (13), and a gas passage (13) connected to the outlet (42). )
And an inflow part (43) arranged below the inflow part. The gas cylinder (48) is connected to one end of the inflow section (43).

Outflow part (42) of the carbon dioxide passage (41)
Is fixed at one end to the lower end of the gas passage (13), and is disposed so as to cross the gas passage (13). Outflow (4
In 2), a plurality of openings (44) are formed. The opening (44) is formed at an outlet for carbon dioxide.

The inflow section (43) of the carbon dioxide passage (41)
Is disposed below the gas passage (13) in parallel with the gas passage (13), and is provided with a flow meter (45) and a motor-operated valve (46). The motor-operated valve (46) is arranged closer to the connection end of the gas cylinder (48) with respect to the flow meter (45). The electric valve (46) and the flow meter (45) are connected to a controller (not shown). This controller uses a centrifugal fan (1
It is also connected to the fan power supply (12a) in 2).

The controller is configured to adjust the opening of the motor-operated valve (46) in order to adjust the carbon dioxide concentration. The controller derives the air volume sucked into the gas passage (13) from the rotation speed of the centrifugal fan (12),
The degree of opening of the motor-operated valve (46) is adjusted based on the air volume and the flow rate of carbon dioxide detected by the flow meter (45). The controller operates the electric valve (4) so that the carbon dioxide concentration around the discharge electrode (21) becomes 1.5%.
6) It is configured to adjust the opening degree.

-Operating operation- The operating operation of the gas processing apparatus (1) will be described.

When the operation of the gas treatment device (1) is started,
When the centrifugal fan (12) starts up, a positive voltage is applied to the discharge electrode (21), and the motor-operated valve (4
6) is opened by the specified opening.

When the centrifugal fan (12) is started, external air is drawn into the gas passage (13) from the air suction port (15). Then, dust is removed from the air sucked into the gas passage (13) by the dust collection filter (11).

When the electric valve (46) is opened, carbon dioxide flows through the carbon dioxide passage (41). Meanwhile, the discharge electrode (21)
However, DC power is supplied from the high-voltage power supply (24), and discharge occurs between the counter electrode (22).

The opening of the motor-operated valve (46) is adjusted based on the flow rate detected by the flow meter (45) provided in the carbon dioxide passage (41) and the air flow derived from the rotation speed of the centrifugal fan (12). The gas passage (13) has an opening (44) of an outflow portion (42).
A predetermined flow rate of carbon dioxide flows out of the apparatus. As a result, the concentration of carbon dioxide around the tip of the discharge electrode (21) is adjusted to 1.5%.

The carbon dioxide flowing out into the gas passage (13)
The dust is mixed with air from which dust has been removed by the dust collecting filter (11), flows through the gas passage (13), passes through the opening (29) of the flat plate (28), and flows around the discharge electrode (21). Discharge electrode (2
Since the carbon dioxide concentration around the tip in 1) is 1.5%, a stable streamer discharge is performed between the discharge electrode (21) and the counter electrode (22). Then, the active species generated by the streamer discharge react with the component to be treated in the air, and decompose the component to be treated.

At this time, since the stable streamer discharge is generated, the component to be treated is decomposed very efficiently. By adjusting the concentration of carbon dioxide to 1.5%, a stable streamer discharge is generated at a lower voltage than before.

Then, the air in which the components to be treated have been decomposed passes through the ozone decomposition catalyst (25). At this time, the ozone contained in the air is reduced to oxygen and becomes purified air. The purified air is blown out of the casing (10) from the air outlet (16) by the centrifugal fan (12).

According to the first embodiment, since the carbon dioxide is caused to flow at least so as to increase the carbon dioxide concentration around the tip of the discharge electrode (21), a stable streamer is provided. Discharge can be generated. Therefore, the processing capability of the component to be processed in the gas can be significantly improved.

By increasing the concentration of carbon dioxide around the tip of the discharge electrode (21), a stable streamer discharge can be generated without arc discharge even when a DC power supply is used. it can.

Since the carbon dioxide passage (41) is provided in the gas passage (13) on the upstream side of the discharge electrode (21), carbon dioxide can be discharged with a simple structure.

Further, since the carbon dioxide is caused to flow out so that the carbon dioxide concentration becomes 1.5%, the applied voltage at which a stable streamer discharge occurs can be reduced. As a result, power consumption can be reduced. Also, by increasing the carbon dioxide concentration, the amount of streamer discharge can be increased. As a result, the processing capability of the component to be processed can be further improved.

In addition, by using an inexpensive DC power supply, the apparatus can be manufactured at a lower cost than using a pulse generation power supply.

[0062]

[Embodiment 2] The gas treatment apparatus (1) of Embodiment 2 is different from Embodiment 1 in that carbon dioxide flows out from the tip of the discharge electrode (21).

The discharge means (20) includes a discharge electrode (21) and a counter electrode (22). The two electrodes (21, 21) are used to decompose components to be treated such as odor components and harmful components in the air. twenty two)
It is configured to generate a plasma by performing a discharge between them.

The discharge electrode (21) is arranged so as to be located on the upstream side of the gas passage (13) with respect to the counter electrode (22).

The discharge electrode (21) has a needle shape extending from a plurality of projections (23) provided on a flat plate (28). Each discharge electrode (21) is configured to extend from the tip of each projection (23) toward the counter electrode (22). The flat plate (28) is arranged so as to cross the gas passage (13), and has a large number of openings (29) through which air passes.

The counter electrode (22) is formed in a plate shape having a number of openings (33) through which air passes. The counter electrode (22) is made of, for example, a mesh material, a punching metal, or the like. Counter electrode (22)
Are arranged so as to cross the gas passage (13), and are configured such that air passes in a direction perpendicular to the plane of the counter electrode (22).

The discharge electrode (21) is connected to a high-voltage power supply (24) via a flat plate (28). The high voltage power supply (24)
Is connected to the counter electrode (22). The high-voltage power supply (24) is arranged below the gas passage (13), and is configured to supply DC power to the discharge electrode (21). That is, the discharge electrode (21) is configured so that a positive voltage is applied by the high-voltage power supply (24).

The carbon dioxide supply means (40) includes a gas cylinder (48) serving as a carbon dioxide supply source and the gas cylinder (48).
Are provided, and a connection passage (51) to which is connected, and an electrode passage (52) formed in each discharge electrode (21).

The connection passage (51) is configured such that an inflow passage (53) disposed below the gas passage and a flat plate passage (54) formed in the flat plate (28) are connected to be able to communicate with each other. Have been. The inflow passage (53) consists of a flow meter (45) and an electric valve (46)
The gas cylinder (48) is connected to one end. The motor-operated valve (46) is arranged closer to the connection end of the gas cylinder (48) with respect to the flow meter (45). The flat plate passage (54) has a lower end connected to the inflow passage (53), and is formed in the flat plate (28) so as to cross the gas passage (13). One end of the flat plate passage (54) is branched, and the branched passage (54a) penetrates a substantially central portion of the projection (23).

Each of the electrode passages (52) is a flat plate passage (54).
Is configured to communicate with the branch passage (54a).
Each electrode passage (52) is connected to the branch passage (54a) of the flat plate passage (54) at the tip of the projection (23). Each of the electrode passages (52) penetrates a substantially central portion in the discharge electrode (21), and has one end opening to the tip of the discharge electrode (21).
4) is formed.

-Operating operation- The operating operation of the gas processing apparatus (1) will be described.

When the operation of the gas treatment device (1) is started,
When the centrifugal fan (12) starts, a positive voltage is applied to the discharge electrode (21), and the electric valve (46) in the inflow passage (53) is opened by a predetermined opening.

When the centrifugal fan (12) is started, external air is drawn into the gas passage (13) from the air suction port (15). Then, dust is removed from the air sucked into the gas passage (13) by the dust collection filter (11). Then, the air from which the dust has been removed passes through the opening (29) of the flat plate (28).

When the electric valve (46) is opened, carbon dioxide flows through the connection passage (51) and each electrode passage (52). The carbon dioxide supplied from the gas cylinder (48) flows into the inflow passage (5
From 3), it flows to the flat plate passage (54), and further branches to the branch passage (54a) formed in the projection (23), and flows through each electrode passage (52) formed in the discharge electrode (21). Then, the carbon dioxide flows out of the outlet (44) formed at the tip of the discharge electrode (21) into the gas passage (13). The opening of the motor-operated valve (46) is adjusted based on the detected flow rate of the flow meter (45) provided in the carbon dioxide passage (41) and the airflow derived from the rotation speed of the centrifugal fan (12). . As a result, the carbon dioxide concentration around the tip of the discharge electrode (21) becomes 1.
Adjusted to 5%.

The discharge electrode (21) is supplied with DC power from the high-voltage power supply (24) and discharges with the counter electrode (22). At this time, since carbon dioxide flows out from the tip of the discharge electrode (21) and the concentration of carbon dioxide around the tip of the discharge electrode (21) is adjusted to 1.5%, stable streamer discharge is performed. Then, the active species generated by the streamer discharge react with the component to be treated in the air, and decompose the component to be treated.

At this time, since the stable streamer discharge is generated, the component to be treated is decomposed very efficiently. By adjusting the concentration of carbon dioxide to 1.5%, a stable streamer discharge is generated at a lower voltage than before.

Then, the air in which the components to be treated have been decomposed passes through the ozone decomposition catalyst (25). At this time, the ozone contained in the air is reduced to oxygen and becomes purified air. The purified air is blown out of the casing (10) from the air outlet (16) by the centrifugal fan (12).

-Effects of Embodiment 2- According to Embodiment 2, since the carbon dioxide is caused to flow out from the tip of the discharge electrode, the concentration of carbon dioxide around the tip of the discharge electrode (21) is surely increased. Can be done.

Other configurations, functions and effects are the same as those of the first embodiment.
Is the same as

<Other Embodiments of the Invention> In each of the above embodiments, the controller adjusts the opening of the motor-operated valve (46) so that the carbon dioxide concentration around the discharge electrode (21) becomes 0.5%. It may be configured to adjust. In this case, it is necessary to increase the applied voltage compared to when the carbon dioxide concentration is 1.5%. However, even when the supply amount of carbon dioxide cannot be increased, a stable streamer discharge can be generated. By setting the carbon dioxide concentration to 0.5%, stable streamer discharge can be generated even at an applied voltage at which streamer discharge does not occur in air.

In each of the above embodiments, the high-voltage power supply (24) may be configured to supply pulsed power.

In each of the above embodiments, the controller controls the motor-operated valve (46) based on the air flow derived from the rotation speed of the centrifugal fan (12) and the flow detected by the flow meter (45).
The configuration is not limited to the configuration in which the opening degree is adjusted. The point is that the carbon dioxide concentration around the tip of the discharge electrode (21) may be adjusted.

[Brief description of the drawings]

FIG. 1 is a cross-sectional view illustrating an entire configuration of a gas processing apparatus according to a first embodiment.

FIG. 2 is a partially enlarged view illustrating a configuration of a carbon dioxide supply unit in a gas processing apparatus according to a second embodiment.

FIG. 3 is a characteristic diagram showing a correlation between voltage and ozone concentration.

[Explanation of symbols]

 (13) Gas passage (21) Discharge electrode (22) Counter electrode (24) High voltage power supply (40) Carbon dioxide supply means (41) Carbon dioxide passage (44) Opening (outlet) (48) Gas cylinder (51) Connection Passage (52) Electrode passage

Continued on the front page (72) Inventor Kenkichi Kagawa 1304 Kanaokacho, Sakai City, Osaka Prefecture Daikin Industries, Ltd. Sakai Seisakusho Kanaoka Factory F-term (reference) 4G042 CA01 CC10 4G075 AA03 BA01 BA05 BB05 CA15 CA18 CA47 CA57 DA02 EA02 EB01 EB41 EC02 EC21 EE36 FC02

Claims (6)

[Claims] A gas processing apparatus for generating a streamer discharge in a gas passage (13) through which a gas flows to treat a component to be treated contained in the gas, wherein the gas treatment device is disposed in the gas passage (13). On the other hand, discharging means (20) for discharging between a needle-shaped discharge electrode (21) connected to a power supply (24) to which a positive voltage is applied and a counter electrode (22); A) a carbon dioxide supply means for discharging carbon dioxide in the gas passage (13) so as to increase the carbon dioxide concentration around the front end in (1). 2. The carbon dioxide supply means according to claim 1, wherein the carbon dioxide supply means comprises a carbon dioxide supply source.
And an outlet (44) connected to the carbon dioxide supply source (48) and upstream of the discharge electrode (21) in the gas passage (13).
And a carbon dioxide passage (41) having an opening. 3. The carbon dioxide supply means (40) according to claim 1, wherein the carbon dioxide supply means (40) comprises a carbon dioxide supply source (48).
And a connection passage (51) to which the carbon dioxide supply source (48) is connected, and a discharge electrode (2) connected to the connection passage (51).
1) Formed in the outlet (4) at the tip of the discharge electrode (21)
4) A gas processing device comprising: an electrode passage (52) having an opening. 4. The carbon dioxide supply means (40) according to any one of claims 1 to 3, wherein the carbon dioxide supply means (40) supplies carbon dioxide such that a carbon dioxide concentration around the discharge electrode (21) becomes 0.5% or more. A gas treatment device configured to be discharged. 5. The carbon dioxide supply means (40) according to any one of claims 1 to 3, wherein the carbon dioxide supply means (40) is provided so that a carbon dioxide concentration around the discharge electrode (21) becomes 1.5% or more. A gas treatment device configured to discharge gas. 6. The gas processing apparatus according to claim 1, wherein the power supply is a DC power supply.