JPH1147774A - Ozone water making apparatus - Google Patents

Abstract

PROBLEM TO BE SOLVED: To efficiently make ozone water at a low cost. SOLUTION: This ozone water making apparatus is equipped with an electrolytic ozone forming apparatus 1 forming ozone by electrolysis and a discharge ozone forming apparatus 14 forming ozone by a discharge method. Gas containing oxygen and ozone formed from the anode 3 of the electrolytic ozone forming apparatus is guided to a gas-liquid contact device 1 and ozone in the gas is transferred to water by using a gas-liquid contact device 11 and the remaining oxygen gas 21 is introduced into the discharge ozone forming apparatus 14 as raw material gas and ozone formed by the discharge ozone forming apparatus 14 is refluxed to the gas-liquid contact device 11.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

The present invention relates to the water, to ozone water production apparatus for producing ozone water to be used for disinfection of water disinfection and foods such as pool [ozone (O ₃₎ water containing].

[0002]

2. Description of the Related Art A conventional ozone water producing apparatus using an electrolysis method will be described with reference to FIG. FIG. 3 is a diagram schematically showing a configuration of the ozone water producing apparatus. As shown in FIG. 3, a conventional ozone water producing apparatus using an electrolytic method is composed of an electrolytic ozone generating apparatus 1, a gas-liquid separation apparatus. , Circulation pumps 9, 10, gas-liquid contactor 11, gas-liquid separator 12,
It comprises a supply pump 13, a DC power supply device 25, a hydrogen gas treatment device 26 and the like.

In an electrolysis ozone generator 1, a PbO ₂ electrode (anode, anode) 3 is joined to one side of an ion exchange membrane 2 and a Pt electrode (cathode, cathode) 4 is joined to the other side. Exchange membrane 2 and electrodes 3 and 4
The electrodes 3 and 4 are configured to be sandwiched between power supply bodies 5 and 6. The electrodes 3 and 4 are respectively provided with a power feeder 5
6, a DC voltage is applied by a DC power supply device 25, and power is supplied.

A circulating pump 9,
Pure water is supplied by 10 and oxygen (O ₂ ) and ozone (O ₃ ) are supplied from the electrode 3 by energization of the DC power supply 25.
Is generated and hydrogen (H ₂ ) is generated from the electrode 4, and gas-liquid separation is performed in the gas-liquid separators 7 and 8, respectively. The reaction formula at the electrode (cathode) 4 is as follows, and the reaction formula at the electrode (anode) 3 is as follows.

[0005] _{^{2H + + 2e → H 2 ↑}} ... 2H 2 O → O 2 ↑ + 4H + + 4e ... 3H 2 O → O 3 ↑ + 6H + + 6e ... ozone in pure water 20 from the electrode 3 side Since the target ozone water is included, the pure water 20 may be used as it is as ozone water, but since pure water is expensive, gas-liquid separation as described above is usually performed. The performed and extracted ozone gas is sent to the gas-liquid contactor 11.

In the gas-liquid contactor 11, the ozone gas is brought into contact with inexpensive city water (supply water, tap water) 16 and contained in the water 16 to produce ozone water. In the gas-liquid contactor 11, the oxygen gas generated by the electrode 3 together with the ozone gas comes into contact with the water 16 at the same time. Therefore, the oxygen is separated in the gas-liquid separator 12, and the finally obtained product ozone water 17 is obtained. Is sent out by the supply pump 13.

The pure water remaining after the extraction of oxygen / ozone and hydrogen in the gas-liquid separators 7 and 8 is
It is circulated and supplied to the electrodes 3 and 4 by the circulation pumps 9 and 10. The pure water circulation system on the circulation pump 9 side includes:
Supplementary pure water 19 is additionally supplied as appropriate.

Further, the hydrogen 18 generated from the electrode 4 is
Emitted as it is, or as shown in FIG.
The gas is sent to the hydrogen gas processing device 22, where it is converted into harmless substances by catalytic combustion with oxygen extracted by the gas-liquid separator 12. next,
FIG. 4 shows a conventional ozone water producing apparatus using a discharge method.
This will be described with reference to FIG. FIG. 4 is a view schematically showing the configuration of the ozone water producing apparatus. As shown in FIG. 4, the conventional ozone water producing apparatus using the discharge method has the same gas-liquid contactor 11, Gas-liquid separator 12, supply pump 1
In addition to 3, a discharge method ozone generator 14 is provided. Note that, in FIG. 4, the above-mentioned reference numerals in FIG. 3 indicate the same or substantially the same portions.

The discharge method ozone generator 14 generates ozone by performing a silent corona discharge on air introduced from the outside. The air containing ozone generated by the discharge method ozone generator 14 is sent to the gas-liquid contactor 11. Then, in the same manner as described above, the air is supplied to the gas-liquid contactor 11 using inexpensive city water (supply raw water, tap water)
And ozone water is produced by making the water 16 contain.

At this time, in the gas-liquid contactor 11, the air and the ozone gas simultaneously come into contact with the water 16, so that the air is separated in the gas-liquid separator 12 and the finally obtained ozone water 17 is supplied to the supply pump. 13 sent out.

[0011]

However, the conventional apparatus for producing ozone water using the above-described electrolysis method has the following problems. (1) Ozone generation efficiency (current efficiency) is at most 15-20%
Only the remaining 80-85% is pure oxygen. In other words, 80 to 85% of the current is used for oxygen generation in the above reaction formula, and only 15 to 20% of the current is used for the reaction for generating ozone shown in the formula, thus requiring a large amount of electric power. Then, the power cost per unit amount of the produced ozone water also increases.

(2) The problem is the treatment of the hydrogen gas generated at the cathode (cathode).
As shown in FIG. 3, the treatment is performed by catalytic combustion or flame combustion using a hydrogen gas treatment device 26. However, since the mixture of hydrogen and oxygen is extremely dangerous in handling, it is necessary to detect / monitor the gas concentration. Further, the conventional ozone water producing apparatus using the above-described discharge method has a problem that the ozone concentration of the finally generated ozone water (reference numeral 17 in FIG. 4) is low (for example, about 3 to 4%). In order to increase ozone concentration and ozone generation efficiency, it is sufficient to supply oxygen instead of air as a raw material supply gas to the discharge method ozone generator (reference numeral 14 in FIG. 4). An oxygen generation / separation device using a cooling method or the like is required, which increases the cost. When oxygen is used as the raw material supply gas, ozone water having an ozone concentration of 6 to 8% is produced.

The present invention has been made in view of the above problems, and has as its object to provide an ozone water producing apparatus capable of efficiently producing ozone water at low cost.

[0014]

In order to achieve the above object, an ozone water producing apparatus (claim 1) of the present invention comprises an electrolytic ozone generating apparatus for generating ozone by an electrolytic method, and an ozone water generating apparatus for generating ozone by an electrolytic method. A gas containing oxygen and ozone generated from the anode of the electrolytic ozone generator is introduced into a gas-liquid contactor, and the ozone in the gas is converted to the water side using the gas-liquid contactor. And the remaining oxygen gas is introduced into the discharge method ozone generator as a raw material gas, and the ozone generated by the discharge method ozone generator is configured to be returned to the gas-liquid contactor. .

At this time, a gas-liquid separator for separating oxygen gas from water from the gas-liquid contactor is provided between the gas-liquid contactor and the discharge ozone generator, and the gas-liquid separator separates the oxygen gas from the water. Oxygen gas may be introduced into the discharge method ozone generator as a source gas (claim 2), or a pressure monitoring unit that monitors the pressure of the gas-liquid separator, and the pressure monitoring unit monitors the pressure. A current controller for controlling the current of the electrolytic ozone generator according to the pressure may be provided.

Further, the ozone water producing apparatus of the present invention (claim 4) comprises an electrolytic ozone producing apparatus for producing ozone by an electrolytic method and a fuel cell, and is produced from the anode of the electrolytic ozone producing apparatus. The gas containing oxygen and ozone is led to the gas-liquid contactor, and the gas-liquid contactor is used to transfer ozone in the gas to the water side, and the remaining oxygen gas and hydrogen gas generated from the cathode of the electrolytic ozone generator Are respectively introduced into the fuel cell as a cathode gas and an anode gas of the fuel cell, and the output of the fuel cell is supplied to a DC power supply of an electrolytic ozone generator.

At this time, air may be additionally mixed with oxygen gas to be supplied to the fuel cell as a cathode gas (claim 5), or between the electrolytic ozone generator and the fuel cell. A gas-liquid separator for separating hydrogen gas from water containing hydrogen generated from the cathode of the electrolytic ozone generator is provided, and the hydrogen gas separated by the gas-liquid separator is introduced into the fuel cell as anode gas, The anode gas may be circulated between the fuel cell and the gas-liquid separator (claim 6).

[0018]

Embodiments of the present invention will be described below with reference to the drawings. (A) Description of First Embodiment FIG. 1 is a view schematically showing a configuration of an ozone water producing apparatus as a first embodiment of the present invention. As shown in FIG. The water producing apparatus includes a solution ozone generator 1, gas-liquid separators 7, 8, circulation pumps 9, 10, gas-liquid contactor 11, gas-liquid separator 12, supply pump 13, and DC power supply shown in FIG. A conventional ozone water producing apparatus comprising a discharge method ozone generator 14 similar to that shown in FIG. 4, an ozone gas circulation blower 15, a gas-liquid separator pressure controller (pressure monitoring unit) 2
2 and a current controller 23 are additionally provided. In FIG. 1, the same reference numerals as those described above indicate the same or substantially the same parts.

In the electrolysis ozone generator 1, a PbO ₂ electrode (anode, anode) 3 is joined to one side of the ion exchange membrane 2 and Pt is
An electrode (cathode, cathode) 4 is joined, and the ion exchange membrane 2 and the electrodes 3 and 4 are sandwiched between an anode-side power supply 5 and a cathode-side power supply 6 for these electrodes 3 and 4. I have. A DC voltage is applied to the electrodes 3 and 4 from the DC power supply device 25 via power feeders 5 and 6, respectively, and power is supplied.

Pure water is supplied to the electrodes 3 and 4 by an anode-side circulation pump 9 and a cathode-side circulation pump 10, respectively. Oxygen (O ₂ ) and ozone (O ₂ ) ₃ ) is generated and hydrogen (H ₂ ) is generated from the electrode 4, and gas-liquid separation is performed in the anode-side gas-liquid separator 7 and the cathode-side gas-liquid separator 8, respectively.

In the anode-side gas-liquid separator 7, pure water 2 containing oxygen and ozone generated on the electrode (anode) 3 side is used.
Oxygen and ozone are separated and extracted from 0 and sent to the gas-liquid contactor 11. In the cathode-side gas-liquid separator 8,
Hydrogen gas 18 is separated and extracted from pure water containing hydrogen generated on the electrode (cathode) 4 side. Then, in the gas-liquid contactor 11, the gas containing oxygen and ozone from the gas-liquid separator 7 is brought into contact with city water (raw water for supply, tap water) 16 and transferred to and contained in the water 16 side. However, gas-liquid contactor 1
In the method 1, the oxygen gas (including a trace amount of ozone) 21 is extracted and separated in the gas-liquid separator 12 because the oxygen gas generated at the electrode 3 simultaneously contacts the water 16 together with the ozone gas. The raw material gas is introduced and supplied to the device 14.

The discharge-type ozone generator 14 generates ozone by performing a silent corona discharge on the oxygen gas 21 introduced from the gas-liquid separator 21. The gas containing ozone generated by the discharge method ozone generator 14 is supplied to the gas-liquid contactor 11 by the ozone gas circulation blower 15.
Refluxed. If moisture is contained in the gas 21 to the discharge method ozone generator 14, the discharge efficiency is reduced. Therefore, it is desirable to remove moisture in advance by means such as zeolite adsorption.

The ozone water remaining after the oxygen gas 21 is extracted by the gas-liquid separator 12 is the ozone water 1 which is finally obtained.
7 is sent out by the supply pump 13. Further, in this embodiment, a gas-liquid separator pressure controller (pressure monitoring unit, PIC) 22 capable of monitoring and controlling the pressure of the gas-liquid separator 12 is provided, and the gas-liquid separator pressure controller 22 is provided.
Ozone generator 1 according to the pressure monitored by
Is provided with a current controller 23 for controlling the current.

The pure water remaining after the extraction of oxygen / ozone and hydrogen in the gas-liquid separators 7 and 8 is
It is circulated and supplied to the electrodes 3 and 4 by the circulation pumps 9 and 10. The pure water circulation system on the circulation pump 9 side includes:
Supplementary pure water 19 is additionally supplied as appropriate. Further, in the first embodiment, the hydrogen gas 18 extracted by the gas-liquid separator 8 is either emitted as it is, as in the prior art, or sent to the hydrogen gas processing device 22 as shown in FIG. In the hydrogen gas treatment device 22, the gas-liquid separator 1
It is converted to harmless by catalytic combustion with the oxygen extracted in step 2.

In the above-described ozone water producing apparatus according to the first embodiment of the present invention, the ozone generation efficiency (current efficiency) of the electrolytic ozone generator 1 is at most only 15 to 20%, and the remaining 80 to 85%. Pays attention to pure oxygen.
Since the solubility of oxygen and ozone in water is about five times higher in ozone, the ozone is almost completely dissolved in water 16 in the gas-liquid contactor 11. Therefore, the gas 21 separated and extracted by the gas-liquid separator 12 becomes almost pure oxygen (including a trace amount of ozone), and the ozone generation efficiency of the discharge ozone generator 14 can be increased.

In addition, since oxygen is circulated and used by the circulation pump 15, the amount of oxygen required for the discharge-type ozone generator 14 is generated by the electrolytic-type ozone generator 1, so that the ozone water 17 is efficiently used without waste. Can be manufactured. Further, the pressure of the gas-liquid separator 12 is monitored by the pressure controller 22, and the current controller 23
Controlling the current from the DC power supply 25 to the electrolytic ozone generator 1 by the
And the amount of oxygen required by the discharge method ozone generator 14 can be balanced, and the discharge method ozone generator 14 can efficiently generate ozone.

For example, when the pressure of the gas-liquid separator 12 is increased (the discharge method ozone generator 14 is in an excessive oxygen state).
In the case where the amount of oxygen generated is reduced by lowering the current to the electrolysis ozone generator 1 and the pressure of the gas-liquid separator 12 becomes low (a state where oxygen is insufficient in the discharge ozone generator 14), Increases the amount of oxygen generation by increasing the current to the electrolytic ozone generator 1.

As described above, according to the ozone water producing apparatus as the first embodiment of the present invention, the electrolytic ozone producing apparatus 1
Oxygen generated by the discharge is used as the ozone generator 14 by the discharge method.
And ozone is also generated by the discharge method, so that the ozone water 17 can be efficiently produced at low cost. (B) Description of Second Embodiment FIG. 2 is a view schematically showing a configuration of an ozone water producing apparatus as a second embodiment of the present invention. As shown in FIG. The water producing apparatus includes a fuel cell 1 in addition to the electrolytic ozone generator 1, gas-liquid separators 7, 8, gas-liquid contactor 11, and DC power supply 25 as described above.
A, a cathode blower 32, an anode blower 33 and the like are newly added and attached. In FIG. 2, the same reference numerals as those described above indicate the same or substantially the same parts.

In the fuel cell 1A, an anode (Pt electrode, anode) 3a is joined to one side of the ion exchange membrane 2a, and a cathode (Pt electrode, cathode) 4a is joined to the other side.
The ion exchange membrane 2a, the anode 3a and the cathode 4a are sandwiched between an anode-side current collector 5a and a cathode-side current collector 6a for extracting current from the anode 3a and the cathode 4a.

The fuel cell 1A thus configured is connected in series to the electrolytic ozone generator 1 and the DC power supply 25 via the anode-side current collector 5a and the cathode-side current collector 6a. In the electrolysis ozone generator 1, pure water is supplied to the anode 3 and the cathode 4 by the anode-side circulation pump 9 and the cathode-side circulation pump 10, respectively.
5 and the fuel cell 1A, oxygen and ozone are generated from the anode 3 and hydrogen is generated from the cathode 4 and gas-liquid separation is performed in the anode-side gas-liquid separator 7 and the cathode-side gas-liquid separator 8, respectively. Is performed.

That is, in the anode-side gas-liquid separator 7, pure water 2 containing oxygen and ozone generated on the anode 3 side is used.
Oxygen and ozone are separated and extracted from 0 and sent to the gas-liquid contactor 11. In the cathode-side gas-liquid separator 8,
Hydrogen gas 18 is separated and extracted from pure water containing hydrogen generated on the cathode 4 side. Then, similarly to the first embodiment, a gas containing oxygen and ozone generated from the anode 3 of the electrolytic ozone generator 1 (gas from the gas-liquid separator 7) is led to the gas-liquid contactor 11. In the second embodiment, while the ozone in the gas is transferred to the water 16 using the heater 11, the oxygen gas remaining in the gas-liquid contactor 11 and the hydrogen generated from the cathode 4 of the electrolytic ozone generator 1 are used in the second embodiment. Gas 18 (gas from gas-liquid separator 8) is introduced into cathode 4a and anode 3a of fuel cell 1A as a cathode gas and an anode gas, respectively, of fuel cell 1A.

In the second embodiment, as described above, the fuel cell 1A is connected in series to the DC power supply 25, and the output of the fuel cell 1A is supplied to the DC power supply 25 to After the voltage of the DC power supply 25 is increased to a predetermined voltage, the power of the DC power supply 25 is supplied to the electrolytic ozone generator 1. Further, in the second embodiment,
In addition to the oxygen gas supplied to the fuel cell 1A as the cathode gas, the air 37 is additionally mixed, and the anode gas is
It is configured to circulate between the fuel cell 1A and the gas-liquid separator 8 through the anode gas circulation line 36 by the anode blower 33.

The gas-liquid separator 7 has make-up water (pure water).
30 are supplied. Further, a cathode blower 32 is provided between the gas-liquid separator 7 and the gas-liquid contactor 11, and the cathode blower 32 allows the cathode gas to circulate through the cathode gas circulation line 35. .

Further, in the example shown in FIG.
Although FIG. 2 (see FIG. 1) is omitted, a gas-liquid separator 12 may be provided downstream of the gas-liquid contactor 11 as in the first embodiment. In FIG. 2, reference numeral 28 denotes the circulation pump 9.
Anode water circulated by the circulating pump 10 and cathode water circulated by the circulating pump 10 are shown. Next, the operation of the ozone water producing apparatus according to the second embodiment of the present invention configured as described above will be described.

The following reaction occurs at the anode 2 of the electrolytic ozone generator 1. _{3H 2 O → O 3 ↑ +} 6H + + 6e ... 2H 2 O → O 2 ↑ + 4H + + 4e ... Here, among the reaction of the anode 2, the reaction of the formula is about 20
%, The reaction of the formula accounts for about 80%. In addition, since water is consumed by such a reaction, in this embodiment, makeup water (pure water) 30 is supplied to the gas-liquid separator 7.

The oxygen and ozone generated at the anode 2 are separated and extracted from the pure water 20 by the gas-liquid separator 7 and then sent to the gas-liquid contactor 11 by the blower 32.
In the gas-liquid contactor 11, the ozone dissolves in the feed water 16 sprayed from above. Usually, raw water 16
Since oxygen is saturated with air, almost no oxygen is dissolved in water 16. Thus, the water 16 in the gas-liquid contactor 11
The oxygen remaining without dissolving in the fuel cell is supplied to the cathode 4a of the fuel cell 1A by the operation of the blower 32.

On the other hand, the hydrogen ions H ⁺ generated by the reaction formulas (1) and (2) move to the cathode 4 through the ion exchange membrane 2, and hydrogen is generated by the following reaction formula. 2H ⁺ + 2e → H ₂ … The water containing hydrogen generated on the cathode 4 side is guided to the gas-liquid separator 8, and the hydrogen gas 18 separated by the gas-liquid separator 8 is supplied to the blower 33. Operation of the fuel cell 1A
Is supplied to the anode 3a.

[0038] In the cathode 4a of the fuel cell 1A ^{_{is, O 2/2 + 2H +}} + 2e → H 2 O ... ' becomes reactions occur in the anode ^{_{3a, H 2 → 2H + +}} 2e ...' occurs becomes reactions As a result, water is generated and electric power is generated.

In order to realize the entire reaction of ozone generation represented by the formulas (1) to (4), the power feeders 4, 5
By adding various resistances, the current density is 100 A / dm
^In the case of ² , a voltage of 2.8 to 3.5 V is required. Note that the theoretical ozone generation potential is 1.52 V, which is slightly higher than the hydrogen / oxygen generation potential from water of 1.23 V. Assuming that the ozone generation ratio is 20%, the ratio of hydrogen and oxygen generated as described above is × 0 from 2H ₂ O → 2H ₂ + O ₂ ... 3H ₂ O → 3H ₂ + O ₃ . as _{.8 + × 0.2, H 2:} 2 × 0.8 + 3 × 0.2 = 2.2 mole O _2: 0.8 moles O _3: a 0.2 molar.

To operate the fuel cell 1A, hydrogen
1.1 moles of oxygen, corresponding to 2 moles, are required, 0.3
Mole deficiency. In the present embodiment, this deficiency is supplemented by additionally mixing the air 37. Thereby, when the current density is 100 A / dm ² , a voltage of 0.6 to 0.8 V is obtained by the fuel cell 1 </ b> A.
The voltage required for the subtraction and the DC power supply is 2.0 to
It is reduced to 2.9V.

As described above, according to the ozone water producing apparatus as the second embodiment of the present invention, the electrolytic ozone producing apparatus 1
The fuel cell 1A can be operated by using the hydrogen and oxygen generated in the above, and power can be supplied. Hydrogen gas which is extremely dangerous in handling can be diffused or treated by catalytic combustion or flame combustion as in the past. Therefore, the ozone water 17 can be efficiently used at a low cost.

The present invention is not limited to the above-described first and second embodiments, but can be variously modified and implemented without departing from the spirit of the present invention.

[0043]

As described above in detail, according to the ozone water producing apparatus of the present invention, the oxygen generated by the electrolytic ozone generator is supplied to the discharge ozone generator, and the oxygen is produced by the discharge method. Since ozone can be generated efficiently, ozone water can be efficiently produced at low cost.

At this time, the pressure of the gas-liquid separator is monitored by the pressure monitoring unit, and the current of the electrolytic ozone generator is controlled by the current controller according to the monitoring result. Since the amount of generation and the required amount of oxygen in the discharge ozone generator can be balanced, there is also an effect that ozone can be efficiently generated in the discharge ozone generator.

Further, according to the ozone water producing apparatus of the present invention (claims 4 to 6), power can be supplied by operating the fuel cell using hydrogen or oxygen generated by the electrolytic ozone producing apparatus. Therefore, hydrogen gas which is extremely dangerous in handling can be effectively used, and ozone water can be efficiently produced at low cost.

[Brief description of the drawings]

FIG. 1 is a diagram schematically showing a configuration of an ozone water producing apparatus as a first embodiment of the present invention.

FIG. 2 is a diagram schematically showing a configuration of an ozone water producing apparatus as a second embodiment of the present invention.

FIG. 3 is a diagram schematically showing a configuration of a conventional ozone water producing apparatus using an electrolysis method.

FIG. 4 is a diagram schematically showing a configuration of a conventional ozone water producing apparatus using a discharge method.

[Explanation of symbols]

DESCRIPTION OF SYMBOLS 1 Electrolysis-type ozone generator 1A Fuel cell 2, 2a Ion exchange membrane 3 PbO ₂ electrode (anode, anode) 3a Anode (anode, Pt) 4 Pt electrode (cathode, cathode) 4a Cathode (cathode, Pt) 5 Anode power supply Body 5a Anode-side current collector 6 Cathode-side power supply 6a Cathode-side current collector 7 Anode-side gas-liquid separator 8 Cathode-side gas-liquid separator 11 Gas-liquid contactor 12 Gas-liquid separator 14 Discharge method ozone generator 17 Ozone water 22 Gas-liquid separator pressure controller (pressure monitoring unit) 23 Current controller 25 DC power supply 36 Anode gas circulation line

Claims (6)

[Claims] 1. An electrolysis ozone generator for generating ozone by an electrolysis method, and a discharge ozone generator for generating ozone by a discharge method, wherein oxygen and ozone generated from an anode of the electrolysis ozone generator are provided. Is introduced into the gas-liquid contactor, the ozone in the gas is transferred to the water side using the gas-liquid contactor, and the remaining oxygen gas is introduced into the discharge method ozone generator as a raw material gas. An ozone water producing apparatus, wherein ozone generated by a discharge method ozone generating apparatus is configured to be returned to the gas-liquid contactor. 2. A gas-liquid separator for separating oxygen gas from water from the gas-liquid contactor is provided between the gas-liquid contactor and the discharge method ozone generator, and separated by the gas-liquid separator. 2. The ozone water producing apparatus according to claim 1, wherein the supplied oxygen gas is introduced into the discharge method ozone generator as a raw material gas. 3. A pressure monitoring unit for monitoring a pressure of the gas-liquid separator, and a current controller for controlling a current of the electrolytic ozone generator according to the pressure monitored by the pressure monitoring unit. The ozone water producing apparatus according to claim 2, wherein: 4. An electrolysis ozone generator for generating ozone by an electrolysis method, and a fuel cell, wherein a gas containing oxygen and ozone generated from an anode of the electrolysis ozone generator is guided to a gas-liquid contactor. Using the same gas-liquid contactor, the ozone in the gas is transferred to the water side, and the remaining oxygen gas and the hydrogen gas generated from the cathode of the electrolytic ozone generator are separated into the cathode gas and the anode gas of the fuel cell, respectively. An ozone water producing apparatus characterized in that the ozone water producing apparatus is configured to be introduced into the fuel cell and to supply the output of the fuel cell to a DC power supply of the electrolytic ozone generator. 5. The ozone water producing apparatus according to claim 4, wherein air is additionally mixed with oxygen gas supplied to said fuel cell as a cathode gas. 6. A gas-liquid separator for separating hydrogen gas from water containing hydrogen generated from a cathode of the electrolytic ozone generator, between the electrolytic ozone generator and the fuel cell. The hydrogen gas separated by the gas-liquid separator is introduced into the fuel cell as an anode gas, and the anode gas is circulated between the fuel cell and the gas-liquid separator. The ozone water producing apparatus according to claim 4 or claim 5.