KR20140104359A - Water treatment apparatus - Google Patents

Abstract

A water treating device of the present invention is equipped with a treating tank accommodating treated water and an electric discharge decomposing unit creating a producer conducting treatment of the treated water by generating discharge reaction in the gas introduced in the treated water and, at the same time, decomposing nitrogenous compound by generating discharge reaction in the nitrogenous compound produced when electric discharge reaction is generated in the gas.

Description

[0001] WATER TREATMENT APPARATUS [0002]

The present invention relates to a water treatment apparatus for treating various kinds of water.

BACKGROUND ART Conventionally, there has been known a water treatment apparatus which generates a discharge reaction on a gas containing air and generates various radicals etc. effective for water treatment from the gas. For example, Japanese Patent No. 4101979 discloses a water treatment apparatus having a treatment tank for containing water to be treated and a discharge means for generating a discharge reaction to a gas containing air introduced into the water to be treated . The discharge device includes a pair of electrodes arranged on both sides of the treatment tank and a power source electrically connected to the pair of electrodes. A gas (oxygen rich gas or the like) containing air from the bottom is blown into the treatment tank, and the gas becomes bubbles and floats in the water to be treated. The power source applies an AC pulse voltage to a pair of electrodes, thereby generating an electric field between a pair of electrodes in the water to be treated. The bubbles floating between the pair of electrodes in the water to be treated generate an in-bubble discharge due to the action of the electric field. As a result, hydroxyl radicals (OH radicals), ozone, ultraviolet rays, etc., which are effective for the water treatment, are generated from the bubbles, and treatment (disinfection, disinfection, etc.) of the water to be treated in the treatment tank is performed.

In the water treatment apparatus as in the prior art described above, since the gas to be a target of the discharge reaction includes air, nitrogen oxides are generated together with the radicals when a discharge occurs in the bubbles by the action of the electric field. It is desired that the emission of nitrogen oxides be reduced.

An object of the present invention is to suppress the emission of nitrogen oxides generated when the for-treatment water is treated.

As a means for solving the above problems, the water treatment apparatus of the present invention is a water treatment apparatus comprising a treatment tank for containing treated water, a gas introduced into the for-treatment water or a gas introduced into the for- A discharge power source for applying a voltage for generating a discharge reaction to a gas passing between the pair of discharge electrodes to the pair of discharge electrodes, A pair of discharge decomposing electrodes for generating a discharge reaction in the gas to be discharged and a voltage for causing a discharge reaction to a gas passing between the pair of discharge decomposing electrodes to be applied to the pair of discharge decomposing electrodes And a power source for discharging decomposition applied thereto.

According to the above-described configuration, a discharge reaction is generated in the gas introduced into the for-treatment water or the gas introduced into the for-treatment water by using the pair of discharge electrodes, thereby generating a product for processing the for- At the same time, the nitrogen oxides can be decomposed by causing a discharge reaction to the nitrogen oxides generated when a discharge reaction occurs in the gas using a pair of the electrodes for decomposing discharge.

According to the present invention, effective treatment of the for-treatment water by a product (various kinds of radicals, ozone, ultraviolet rays, etc.) generated when a discharge reaction occurs in a gas introduced into the for- Both suppression of the emission of the nitrogen oxide by the decomposition of the nitrogen oxide produced when the discharge reaction occurs in the gas is achieved. Concretely, the discharge reaction occurs again with the nitrogen oxide generated when the discharge reaction occurs in the gas, so that the nitrogen oxide is decomposed into nitrogen and oxygen, so that the discharge of the nitrogen oxide is suppressed.

In the water treatment apparatus described above, the discharge electrode and the discharge disassembling electrode may be separate members, and the discharge power source and the discharge disassembly power source may be separate members.

In this case, the voltage applied by the discharge power source, that is, the voltage required for generating the discharge reaction in the gas passing between the pair of discharge electrodes, and the voltage applied by the discharge breakdown electrode, that is, The voltage required for generating a discharge reaction in the nitrogen oxide passing between the electrodes for discharge decomposition can be managed by appropriate voltages.

And an introduction flow path for introducing the gas into the for-treatment water from the outside of the treatment tank when the discharge electrode and the discharge dissociating electrode are separate members, the discharge electrode being disposed in the introduction flow path, And the discharge decomposing electrode may be arranged in the lead-out passage. Here, the introduction flow path may be made of an insulating material, and a pair of the discharge power sources may be embedded in the introduction flow path.

And an introduction flow path for introducing the gas into the to-be-treated water from the outside of the treatment tank when the discharge electrode and the discharge decomposition electrode are separate members, One of the pair of the discharge power sources is disposed inside the gas chamber, and the other of the pair of discharge power sources is disposed in the for-treatment water And an outflow channel for leading the gas out of the treatment tank, and the discharge decomposition electrode may be arranged in the outflow channel.

When the discharge electrode and the discharge decomposing electrode are separate members, the pair of discharge electrodes is made of a flat member having a plurality of holes, and the pair of discharge electrodes are horizontally And an outflow channel which is disposed opposite to the water to be treated in a state of being spaced apart from each other in the up-and-down direction and leads the gas out of the treatment tank, and the discharge decomposing electrode is arranged in the outflow channel.

When the discharging electrode and the discharging electrode are separate members, the discharging flow path may be opened to the atmosphere. In this way, since the nitrogen oxide is released into the atmosphere in the state of being decomposed into nitrogen and oxygen, the emission of nitrogen oxides from the water treatment apparatus is suppressed.

In the above-described water treatment apparatus, a pair of dual electrodes serve as both the discharge electrode and the discharge decomposition electrode, and one common power source also serves as the discharge power source and the discharge breakdown power source, And a circulation flow path connected to the treatment tank, and a pair of the electrodes can be arranged in the circulation flow path.

In this manner, the nitrogen oxides circulate in the water treatment apparatus through the circulation flow path, thereby suppressing the emission of nitrogen oxides from the water treatment apparatus. Further, since the nitrogen oxide passing through the circulation flow path is decomposed into nitrogen and oxygen by a discharge treatment, there is no need to separately provide dedicated means for decomposing nitrogen oxides, so that the entire structure of the apparatus is simplified.

INDUSTRIAL APPLICABILITY As described above, according to the present invention, it is possible to suppress the emission of nitrogen oxide generated when the for-treatment water is treated.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a view schematically showing the configuration of a water treatment apparatus according to a first embodiment of the present invention. Fig.
2 is a view schematically showing a configuration of a water treatment apparatus according to a second embodiment of the present invention.
3 is a view schematically showing a configuration of a water treatment apparatus according to a third embodiment of the present invention;
4 is a view schematically showing a configuration of a water treatment apparatus according to a fourth embodiment of the present invention.
5 is a view showing a modification of the discharging means;

(First Embodiment)

A water treatment apparatus according to a first embodiment of the present invention will be described with reference to Fig. This water treatment apparatus is a device used to sterilize water to be treated such as ballast water of ships, wastewater from various factories or establishments, water of water supply and sewage treatment plants, drinking water, etc., and microorganisms in the water to be treated, to be.

As shown in Fig. 1, this water treatment apparatus includes a treatment tank 10 for containing water to be treated and a discharge disassembling means 15. As shown in Fig.

The treatment tank 10 accommodates the for-treatment water, and corresponds to a ballast tank of a ship or a pool in which drain water is stored.

The discharge disassembling means (15) of this embodiment has a discharging means (20) and a disassembling means (30).

The discharge means 20 includes an introduction flow path 24 for introducing the gas from the outside of the treatment tank 10 into the for-treatment water, a pair of discharge electrodes 21 disposed in the introduction flow path 24, And a discharge power source 23 for applying a voltage to the discharge electrode 21 of the discharge cell 21 via the wiring 22. [

The introduction flow path 24 is formed in a cylindrical shape surrounding a predetermined space and is inserted into a through hole formed in the upper wall 10a of the treatment tank 10 and the lower portion thereof is inserted into a through hole And is fixed to the upper wall 10a in a state of being immersed in the treated water. The introduction flow path 24 is formed of an insulating material. A connection passage 25 is connected to the introduction passage 24 and a pump 26 for discharging the gas to the introduction passage 24 is provided in the connection passage 25. A bubble subdivision portion 27 for subdividing the bubble B generated when the gas is introduced into the for-treatment water is mounted at the lower end of the introduction flow path 24. The bubble subdividing part 27 is made of a perforated plate or a mesh-like (mesh-like) member. The bubble subdivision section 27 makes the bubble B discharged from the introduction flow path 24 into the for-treatment water into a so-called micro bubble state having a bubble diameter of 100 m or less.

A pair of discharge electrodes (21) are arranged opposite to each other in a space in the introduction flow path (24). More specifically, the pair of discharge electrodes 21 are arranged to face each other along the inner surface of the introduction flow path 24 in a state of being spaced apart from each other in the direction (diameter direction) perpendicular to the axial direction of the introduction flow path 24 have.

The discharge power source 23 applies a voltage for generating a plasma discharge between the pair of discharge electrodes 21 to the pair of discharge electrodes 21. In the present embodiment, DC power is used as the discharge power source 23.

Next, a discharge reaction occurring in the discharge means 20 will be described.

When the gas passes between the pair of discharge electrodes 21 in a state where the voltage is being applied by the discharge power source 23, the gas is subjected to the plasma discharge treatment. Specifically, oxygen contained in the gas undergoes the supply of the electrons e and reacts as shown in the following reaction formula (1).

O ₂ + 2e → ₂ and O + 2e ... (One)

Oxygen radicals (O) are generated by the discharge reaction of the reaction formula (1). At the time of the discharge reaction, ultraviolet rays are also generated. The generated oxygen radical (O ·) is as shown in the following reaction formula (2) reacts with water (H ₂ 0) included in the gas to generate the hydroxy radical (· OH).

· O + H ₂ O → 2 · OH ... (2)

Furthermore, the oxygen radicals generated based on the reaction formula (1) react with the surrounding oxygen, thereby generating ozone (0 ₃ ). In addition, hydrogen peroxide (H ₂ O ₂ ) may be produced by, for example, reacting an oxygen radical with water. In this manner, the discharge means 20 generates a discharge reaction by causing a gas to generate a product. The oxygen radicals, hydroxy radicals, ultraviolet rays, ozone, and hydrogen peroxide, which are generated by the discharging means 20, all have a sterilizing effect and a killing effect on microorganisms and the like. Particularly, the hydroxy radical has the highest reactivity among the molecular species called active oxygen and has the strongest oxidizing power, so that the hydroxy radical exerts a very high effect on sterilization and destruction of microorganisms.

During the discharge reaction, nitrogen oxides are also generated, as shown in the following reaction formula (3).

N ₂ + x O ₂ ? 2NO x ... (3)

In general, nitrogen oxides are harmful to human bodies and the environment, and therefore, it is desired that decomposition treatment is properly performed.

The decomposition means 30 is means for decomposing nitrogen oxides generated during the discharge reaction. The decomposition means 30 includes an extraction channel 34 for extracting nitrogen oxides from the treatment tank, a pair of decomposition electrodes 31 disposed in the extraction channel 34, a pair of decomposition electrodes 31 And a decomposition power supply 33 for applying a voltage through the wiring 32 to the decomposition power supply 33.

The outflow channel 34 is formed in a cylindrical shape surrounding a predetermined space and its lower end is fixed to the upper wall 10a of the treatment tank 10. [ The upper end of the leading passage 34 is open to the atmosphere. The lead-out passage 34 is formed of an insulating material.

The pair of decomposing electrodes 31 are disposed opposite to each other in a state of being spaced apart from each other in the lead-out passage 34. More specifically, the pair of decomposing electrodes 31 are disposed so as to be opposed to each other along the inner surface of the lead-out passage 34 while being spaced from each other in a direction (radial direction) perpendicular to the axial direction of the lead-out passage 34 have.

The decomposition power source 33 applies a voltage for causing a plasma discharge reaction to the gas passing between the pair of decomposition electrodes 31 to the pair of decomposition electrodes 31. In the present embodiment, a DC power source is used as the decomposition power source 33.

Next, the discharge reaction occurring in the decomposition means 30 will be described.

When nitrogen oxides pass between a pair of decomposing electrodes 31 in a state in which voltage is applied by the decomposing power supply 33, the discharge reaction shown in the following reaction formula (4) occurs in this nitrogen oxide .

NOx → N ₂ + xO ₂ ... (4)

In this way, the decomposition means 30 decomposes the nitrogen oxide into nitrogen and oxygen.

In other words, the discharge decomposing means 15 generates a discharge reaction to a gas containing air to be introduced into the water to be treated, thereby generating a product (various kinds of radicals, ozone, ultraviolet rays, etc.) The nitrogen oxide is decomposed by causing a discharge reaction to the nitrogen oxide generated when the discharge reaction occurs.

Next, the driving operation of the water treatment apparatus of the present embodiment will be described.

When the pump 26 is driven with the voltage being applied to the pair of discharge electrodes 21 by the discharge power source 23 and the gas is sent between the pair of discharge electrodes 21, Discharge reaction occurs. As a result, the product is produced and nitrogen oxides are generated at the same time.

These products and nitrogen oxides are released into the water to be treated via the bubble subdividing section 27, and become a large number of bubbles B and diffuse into the water to be treated. At this time, microbes contained in the for-treatment water and the like are killed by the product (oxygen radical, hydroxy radical, ultraviolet ray, ozone and hydrogen peroxide), and the treated water is sterilized.

Thereafter, a gas containing nitrogen oxides is introduced into the outflow channel 34. At this time, the nitrogen oxide is decomposed into nitrogen and oxygen between a pair of decomposing electrodes 31 in a state where the voltage is applied by the decomposing power source 33, and these nitrogen and oxygen are released into the atmosphere.

As described above, according to the water treatment apparatus of the present embodiment, effective treatment of the water to be treated by a product (various kinds of radicals, ozone, ultraviolet rays, etc.) generated when a discharge reaction occurs in a gas introduced into the for- And suppression of the emission of the nitrogen oxide by the decomposition of the nitrogen oxide generated when the discharge reaction occurs in the gas is achieved. Concretely, the discharge reaction occurs again with the nitrogen oxide generated when the discharge reaction occurs in the gas, so that the nitrogen oxide is decomposed into nitrogen and oxygen, so that the discharge of the nitrogen oxide is suppressed.

Since the discharge disassembling means 15 of the present embodiment has the discharging means 20 and the disassembling means 30, the voltage applied by the discharging power source 23, that is, And a voltage to be applied by the decomposition power source 33, that is, to cause a discharge reaction to the nitrogen oxide passing between the pair of decomposition electrodes 31 And the voltage required for each of them can be managed with appropriate voltages.

Then, although the lead-out flow path 34 is opened to the atmosphere, since the nitrogen oxide is released into the atmosphere in the state of being decomposed into nitrogen and oxygen, the discharge of the nitrogen oxide from the water treatment apparatus is suppressed.

(Second Embodiment)

A second embodiment of the present invention will be described with reference to Fig. In the second embodiment, only the parts different from those of the first embodiment are described, and the description of the same structure, operation, and effect as those of the first embodiment is omitted.

The discharge disassembling means 15 of the present embodiment is a disassembling means that applies voltage to a pair of discharge electrodes 21 through a circulation flow path 28, a pair of discharge electrodes 21, And has a discharge power source 23. The configuration other than the circulating flow path 28 is the same as that of the first embodiment.

The circulation flow path 28 is formed in a cylindrical shape surrounding a predetermined space, and both ends are connected to the treatment tank 10. More specifically, the circulation flow path 28 is fixed to the upper wall 10a in such a state that one end thereof is immersed in the for-treatment water and the other end thereof is not immersed in the treated water. A pair of discharge electrodes 21 are provided in a space in the circulation flow passage 28 and a pump 26 is provided in the circulation flow passage 28. Further, the bubble subdivided portion 27 is attached to one end of the circulation flow passage 28.

In the water treatment apparatus of the present embodiment, when the pump 26 is driven and the gas reaches between the pair of discharge electrodes 21, a discharge reaction occurs in the gas there, and the product and nitrogen oxides are generated. Thereafter, the nitrogen oxide flows into the circulation flow path 28 from the other end side of the circulation flow path 28, reaches the space between the pair of discharge electrodes 21, and is decomposed into nitrogen and oxygen by discharge treatment there .

According to the water treatment apparatus of the present embodiment, the nitrogen oxides circulate in the water treatment apparatus through the circulation flow path 28, so that the emission of nitrogen oxides from the water treatment apparatus is suppressed. Since the nitrogen oxide passing through the circulating flow path 28 is subjected to discharge treatment and decomposed into nitrogen and oxygen, it is not necessary to separately provide a dedicated means for decomposing the nitrogen oxide. Therefore, the configuration of the discharge decomposition means 15 Simplified. That is, in the discharge disassembling means 15 of the present embodiment, the pair of discharge electrodes 21 serve as the pair of decomposing electrodes 31 of the first embodiment, and the discharge power source 23 serves as the first And a pair of decomposition power sources 33 of the same type.

(Third Embodiment)

A third embodiment of the present invention will be described with reference to Fig. The difference from the first embodiment of the third embodiment is the configuration of the discharge means 20. [ In the third embodiment, only the differences from the first embodiment will be described, and the description of the same structure, operation, and effect as those of the first embodiment will be omitted.

The discharging means 20 of the present embodiment is provided with a discharging path 24 for applying a voltage to a pair of discharging electrodes 21 through an introduction flow path 24, a pair of discharging electrodes 21, And a power source 23. A bubble saturating means 29 for forming a gas chamber 29a is connected to the lower end of the introduction flow path 24. The bubbling means 29 has an insulating wall portion that surrounds the gas chamber 29a. The introduction passage 24 is connected to the gas chamber 29a. The wall portion of the vaporization means 29 is formed of a porous material, more specifically a porous ceramic material, which does not allow passage of liquid while permitting gas to pass therethrough. The configurations of the connection passage 25 and the pump 26 are the same as those of the first embodiment.

In this embodiment, one of the pair of discharge electrodes 21 is disposed in the gas chamber 29a, and the other is disposed in the for-treatment water. When a voltage is applied between the pair of discharge electrodes 21, plasma is generated in the gas chamber 29a. The product (various kinds of radicals, ozone, ultraviolet rays, etc.) generated by the generation of the plasma is discharged into the water to be treated through the wall portion of the vaporization means 29. At this time, the gas containing the product by the vaporizing means 29 becomes innumerable bubbles which are microbubbles. The discharge power source 23 of the present embodiment applies a high-frequency high-voltage pulse (a pulse voltage of several tens kV) between the pair of discharge electrodes 21.

In the water treatment apparatus, bubbles are influenced by an electric field between one of the electrodes disposed in the water to be treated among the pair of discharge electrodes 21 and the bubbling means 29, . As a result, the for-treatment water can be sterilized more effectively. Further, since plasma discharge is generated in the gas chamber 29a, the electric power to be applied to the discharge electrode 21 can be suppressed as compared with the case of generating in water. The nitrogen oxide generated by the treatment of the for-treatment water is led to the lead-out passage 34, decomposed into nitrogen and oxygen between the pair of decomposition electrodes 31, and then discharged out of the treatment tank 10.

As described above, also in the water treatment apparatus of the present embodiment, the same effect as that of the first embodiment can be obtained.

(Fourth Embodiment)

A fourth embodiment of the present invention will be described with reference to Fig. The difference from the first embodiment of the fourth embodiment is the structure of the discharge means 20. [ In the fourth embodiment, only the parts different from the first embodiment are described, and the description of the same structure, operation, and effect as those of the first embodiment is omitted.

The discharging means 20 of the present embodiment has a pair of discharge electrodes 21 and a discharge power source 23 for applying a voltage to the pair of discharge electrodes 21 through the wiring 22.

The pair of discharge electrodes 21 of the present embodiment are disposed to face the for-treatment water in a state of being substantially horizontally spaced apart from each other in the vertical direction. The pair of discharge electrodes 21 is made of a flat member having a plurality of holes, for example, a mesh-like (net-like) flat member.

The discharge power source 23 applies, for example, a high voltage pulse having a frequency of several tens kHz to several hundred kHz to the pair of discharge electrodes 21. The discharge power source 23 applies a high voltage pulse to the pair of discharge electrodes 21 to generate a negative voltage at the lower electrode of the pair of discharge electrodes 21 and to generate a positive voltage at the upper electrode. do.

In the present embodiment, the introduction passage 24 is fixed to the bottom wall 10b of the treatment tank 10. One end of the introduction flow path 24 is connected to the discharge port of the pump 26 and the other end thereof is fixed to the bottom wall 10b of the treatment tank 10. The gas discharged from the pump 26 is discharged as a large number of bubbles B into the water to be treated in the treatment tank 10 through the introduction flow path 24. The bubbles (B) discharged into the water to be treated are micro bubbles. A large number of bubbles B discharged into the water to be treated float in the for-treatment water to reach the lower electrode of the pair of discharge electrodes 21, and through the mesh (hole) of the lower electrode And between the pair of discharge electrodes 21. Bubbles B supplied between the pair of discharge electrodes 21 float up again and move toward the upper electrode.

In this embodiment, when the bubble B discharged into the for-treatment water comes into contact with or approaches the lower electrode, it receives the supply of the electrons e from the lower electrode. Between the discharge electrodes 21, the discharge reactions shown in the above reaction formulas (1) to (3) repeatedly occur in the bubbles to which electrons are supplied. Thereby, various kinds of radicals are continuously generated, and the for-treatment water can be sterilized more effectively. The nitrogen oxides generated by the treatment of the for-treatment water are led to the lead-out passage 34, decomposed into nitrogen and oxygen between the pair of decomposition electrodes 31, and then discharged out of the treatment tank 10.

As described above, also in the water treatment apparatus of the present embodiment, the same effect as that of the first embodiment can be obtained.

It is also to be understood that the embodiments disclosed herein are illustrative and non-restrictive in all respects. The scope of the present invention is defined by the appended claims rather than the description of the embodiments, and includes all modifications within the meaning and range equivalent to the claims.

For example, in the first embodiment, a pair of discharge electrodes 21 of the discharge means 20 are arranged in the space of the introduction flow path 24, that is, a pair of discharge electrodes 21 As shown in Fig. 5, the pair of discharge electrodes 21 may be embedded in an introduction flow path 24 made of an insulating material. In this case, as the discharge power source 23, a high frequency AC power source is used. The high frequency AC power source applies a high frequency AC voltage for generating a discharge between the pair of discharge electrodes 21 to the pair of discharge electrodes 21. When a voltage is applied to the pair of discharge electrodes 21 by the discharge power source 23, a silent discharge (barrier discharge) is generated in the space in the introduction flow path 24 between the pair of discharge electrodes 21, Lt; / RTI > Oxygen radicals, ozone, and ultraviolet rays are generated from the gas passing through the introduction flow path 24 by the silent discharge, like the plasma discharge. Further, in the case of the silent discharge, since the electric charge does not move between the pair of discharge electrodes 21, consumption of the pair of discharge electrodes 21 is suppressed. The same is true for the decomposition means 30 of the first embodiment, the discharge decomposition means 15 of the second embodiment, the decomposition means 30 of the third embodiment and the decomposition means 30 of the fourth embodiment to be. Further, only one electrode of the pair of discharge electrodes 21 may be covered with an insulating material.

In each of the above embodiments, an example of decomposing nitrogen oxides is shown, but the decomposition object is not limited to this. For example, when sulfur is contained in a gas passing between a pair of discharge electrodes 21, a sulfur oxide is generated when a discharge reaction occurs in the gas, and this sulfur oxide is also supplied to the decomposing means 30 . Further, the decomposition means 30 can decompose carbon monoxide or carbon dioxide.

Claims (8)

A treatment tank for containing water to be treated,
A pair of discharge electrodes for generating a discharge reaction in a gas introduced into the for-treatment water or a gas introduced into the for-treatment water,
A discharge power source for applying a voltage for causing a discharge reaction to a gas passing between the pair of discharge electrodes to the pair of discharge electrodes,
A pair of discharge decomposing electrodes for causing a discharge reaction to be generated in the gas derived from the treatment tank,
And a discharge decomposition power source for applying a voltage for causing a discharge reaction to a gas passing between the pair of discharge decomposition electrodes to the pair of discharge decomposition electrodes. The water treatment apparatus according to claim 1, wherein the discharge electrode and the discharge disassembling electrode are separate members, and the discharge power source and the discharge disassembly power source are separate members. 3. The water treatment apparatus according to claim 2, further comprising an introduction flow path for introducing gas into the for-treatment water from the outside of the treatment tank, wherein the discharge electrode is disposed in the introduction flow path,
And an extraction flow path for leading the gas out of the treatment tank, wherein the discharge decomposition electrode is disposed in the extraction flow path. 4. The fuel cell system according to claim 3, wherein the introduction passage is made of an insulating material,
Wherein a pair of the discharge power sources are embedded in the introduction flow path. The treatment apparatus according to claim 2, further comprising an introduction flow path for introducing the gas into the for-treatment water from the outside of the treatment tank,
A bubble-saturating means for containing a gas chamber is connected to the processing-side end of the introduction passage,
One of the pair of the discharge power supplies is disposed inside the gas chamber, the other of the pair of discharge power sources is disposed in the for-treatment water,
And an extraction flow path for leading the gas out of the treatment tank, wherein the discharge decomposition electrode is disposed in the extraction flow path. The plasma display panel according to claim 2, wherein the pair of the discharge electrodes are made of a flat member having a plurality of holes,
The pair of the discharge electrodes are horizontally arranged so as to be opposed to each other in the state of being vertically spaced from each other,
And an extraction flow path for leading the gas out of the treatment tank, wherein the discharge decomposition electrode is disposed in the extraction flow path. The water treatment apparatus according to any one of claims 3 to 6, wherein the lead passage is opened in the atmosphere. The plasma display apparatus according to claim 1, wherein a pair of dual electrodes serve as both the discharge electrode and the discharge decomposition electrode, and one common power source also serves as the discharge power source and the discharge breakdown power source,
Wherein the circulation flow path has both ends connected to the treatment tank, and a pair of the common electrodes is disposed in the circulation flow path.

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