JP2002307083A - Accelerated oxidation treatment apparatus - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an accelerated oxidation treatment apparatus which can be miniaturized by securing a proper amount of ozone to be injected and a proper quantity of ultraviolet rays to be radiated for raw water corresponding to the condition of the raw water and improving the decomposition efficiency of organic substances contained in the raw water. SOLUTION: The apparatus has a plurality of oxidation treatment units 1 which are connected with each other. Each unit 1 has an ozone spraying area 2 in which an ozone sprayer 10 for spraying ozone is installed and an ultraviolet emission area 3 in which an ultraviolet ray emitting device 11 is installed. A necessary number of the units 1 are connected with each other to clean the raw water.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a device for promoting oxidation treatment of water to be treated.

[0002]

2. Description of the Related Art In recent years, as pollution of treated water such as industrial wastewater or domestic wastewater has progressed, water environmental pollution has become a social problem. In particular, it has been pointed out that the upstream of the river, which is a water source for water supply, contains trace amounts of persistent substances such as pesticides, dioxins, and environmental hormones.
In addition, it is pointed out that the downstream area of the river is further contaminated with chemical substances such as organic chlorine-based detergents, pesticides, synthetic detergents, dyes, and the like. In addition, the pollution of the water environment by the effluent from the landfill for industrial waste and domestic waste is extremely serious.

[0003] Against the background of such water environment pollution, purification of raw water and wastewater is required by water environment conservation techniques such as treatment with activated carbon, membrane treatment, ozone treatment, ultraviolet treatment and biological treatment. Purification processing of the water to be treated is being performed.

[0004] Among such water environment preservation technologies, advanced oxidation technology (AOP: Advanced Oxidation Processes) combining each of ozone, ultraviolet light and hydrogen peroxide.
s) is drawing attention.

FIG. 5 is a block diagram showing a conventional accelerated oxidation treatment apparatus for purifying (enhanced oxidation) water to be treated by an accelerated oxidation technique.

The accelerated oxidation treatment apparatus includes a raw water intake pump 22 and a hydrogen peroxide storage tank 4 connected to the raw water intake pump 22.
And an ozone generation device 12 attached to the ozone treatment tank 23. A water storage tank 25 is connected to the ozone treatment tank 23 via an ultraviolet irradiation tank 24, and the drainage ozone treatment device 13 is attached to the water storage tank 25.

The water to be treated is sent to an ozone treatment tank 23 by a raw water intake pump 22. At this time, hydrogen peroxide is injected from the hydrogen peroxide storage tank 4 into the water to be treated sent to the ozone processing tank 23. Ozone is injected into the water to be treated sent to the ozone treatment tank 23 by the ozone generator 12. As a result, the ozone and the hydrogen peroxide react to form O 2
H radicals are generated. Since OH radicals have a stronger oxidizing power than ozone, hardly decomposable substances that cannot be treated with ozone alone are also decomposed by OH radicals. The water to be treated is
It is sent from the ozone treatment tank 23 to the ultraviolet irradiation tank 24 and irradiated with ultraviolet rays. Thereby, the water to be treated is directly photodegraded by the ultraviolet rays, and the oxidation by the OH radical is promoted, so that the decomposition efficiency of the hardly decomposable substance can be further improved. The ozonized gas contained in the water to be treated, which has been purified in the ultraviolet irradiation tank 24, is sent to the waste ozone treatment device 13 and decomposed and exhausted. In addition, ultraviolet irradiation tank 2
The to-be-processed water purified in 4 is sent to another treatment tank or discharged.

[0008] By performing such an accelerated oxidation treatment using a combination of ozone, ultraviolet light and hydrogen peroxide, it is possible to improve the decomposition efficiency of hardly decomposable substances, decolorization, deodorization, and bactericidal action. In addition, a purification process that does not generate secondary waste can be performed.

[0009]

As described above, the water to be treated is effectively purified by the accelerated oxidation treatment.

[0010] However, when ozone is not sufficiently injected into the water to be treated, it is considered that the decomposition efficiency of the hardly decomposable substance is deteriorated.

Further, the amount of the hardly decomposable substance contained in the water to be treated fluctuates, and the ultraviolet transmittance of the water to be treated fluctuates depending on the turbidity of the water to be treated. It is not always optimally set according to the state of the water to be treated. Therefore, depending on the state of the water to be treated, it is conceivable that the decomposition of the hardly decomposable substances contained in the water to be treated becomes insufficient even in the accelerated oxidation treatment.

The ozonized gas contained in the purified water to be treated is sent to the waste ozone treatment device 13 and is decomposed and exhausted. It is also conceivable that the energy efficiency will decrease.

Further, it is conceivable that the provision of the exhaust ozone treatment device 13 results in an increase in the size of the accelerated oxidation treatment device.

The present invention has been made in consideration of the above points, and according to the state of the water to be purified,
Provided is an accelerated oxidation treatment apparatus capable of securing an appropriate amount of ozone injection and irradiation of ultraviolet rays into water to be treated, improving the decomposition efficiency of organic substances contained in the water to be treated, and reducing the size of the apparatus. With the goal.

[0015]

According to the present invention, there is provided an accelerated oxidizing water treatment apparatus comprising a plurality of interconnected oxidizing units for promoting oxidizing treatment of supplied water to be treated. An accelerated oxidation treatment apparatus characterized by having an ozone scattering area in which an ozone scattering apparatus is installed and an ultraviolet irradiation area in which an ultraviolet irradiation apparatus is installed.

According to the present invention, according to the state of the water to be treated, a desired number of stages of the oxidation treatment units can be connected to each other to purify the water to be treated.

Preferably, each of the oxidation treatment units is partitioned by a unit partition plate whose upper or lower part is open, and the ozone scattering region and the ultraviolet irradiation region of each of the oxidation treatment units are upper or lower. Of these, a part of the unit partition plate on the side opposite to the open portion is separated by an area partition plate that is open.

Preferably, the volume of the ozone scattering region of each oxidation processing unit is larger than the volume of the ultraviolet irradiation region.

Preferably, an exhaust ozone transport pipe is connected to a gas phase portion of the ozone spray area of each oxidation treatment unit, and the exhaust ozone transport pipe is connected to an ozone spray area located at a subsequent stage through an ozone return pipe. It is connected to an ozone diffuser.

Preferably, a hydrogen peroxide injection device is further provided, and the hydrogen peroxide is injected from the hydrogen peroxide injection device into the water to be treated in a stage preceding the oxidation processing unit or in an ozone scattering region of the oxidation processing unit.

Preferably, the apparatus further comprises a light transmittance detector for detecting the light transmittance of the water to be treated supplied to the oxidation treatment unit, and each of the oxidation treatment units is detected based on the detected value of the light transmittance detector. Is controlled by the control device.

[0022]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS First Embodiment An embodiment of the present invention will be described below with reference to the drawings.

FIG. 1 is a diagram showing a first embodiment of the present invention. Here, FIG. 1 is a configuration diagram showing an accelerated oxidation treatment apparatus that accelerates the supplied water to be treated.

In FIG. 1, the accelerated oxidation treatment apparatus has four oxidation treatment units 1 connected to each other.

Each oxidation treatment unit 1 has an ozone spray area 2 in which an ozone spray apparatus 10 for spraying ozone is installed.
And an ultraviolet irradiation region 3 in which an ultraviolet irradiation device 11 for irradiating ultraviolet light is installed. The volume of the ozone scattering region 2 of each oxidation processing unit 1 is larger than the volume of the ultraviolet irradiation region 3.

Each oxidation treatment unit 1 is partitioned by a unit partition plate 5 whose upper part is open.
Further, the ozone scattering region 2 and the ultraviolet irradiation region 3 of each oxidation treatment unit 1 are partitioned by a region partition plate 6 whose lower part is partially open.

An ozone generator 12 is connected to each of the ozone sprayers 10, and the ozone generator 12 supplies ozone to each of the ozone sprayers 10. Further, an ultraviolet lamp power supply 17 that is a power supply of the ultraviolet irradiation device 11 is attached to each oxidation processing unit 1, and a gas phase portion located above each oxidation processing unit 1 is connected to the exhaust gas ozone transport pipe 7 through an ozone transport pipe 7. It is connected to an exhaust ozone treatment device 13.

Next, the operation of the present embodiment having such a configuration will be described.

The water to be treated, which is newly supplied to the accelerated oxidation treatment apparatus and subjected to the purification treatment, is sent above the ozone spraying area 2 of the first-stage oxidation treatment unit 1.

The water to be treated sent to the ozone spraying area 2 is
Ozone is sprayed by the ozone spraying device 10 to form bubbles in the water to be treated. The ozone which has become bubbles is taken into the water to be treated by dissolving in the water to be treated and remaining as microbubbles. The ozone thus taken into the water to be treated decomposes organic substances contained in the water to be treated into low molecular organic substances. Ozone is taken into the water to be treated by being sprayed by the ozone spraying device 10, and the ozonized gas once discharged from the water to be treated stays in the gas phase and dissolves at the interface of the water to be treated. The water is also taken into the water to be treated.

The water to be treated in the ozone spray area 2 is supplied from above, and then sent to the ultraviolet irradiation area 3 through the lower part of the area partition plate 6. For this reason, the water to be treated in the ozone spraying area 2 becomes a downward flow from above the ozone spraying area 2 to below. As a result, ozone is efficiently taken into the to-be-treated water while the to-be-treated water goes from above to below the ozone spraying area 2. Further, while the water to be treated goes from above to below the ozone spraying area 2, the ozone efficiently decomposes organic substances contained in the water to be treated.

Next, the water to be treated sent to the ultraviolet irradiation region 3 is irradiated with ultraviolet light by the ultraviolet irradiation device 11 under the conditions of Planck's constant h and the frequency of ultraviolet light v. OH) is produced.

That is, the ozone dissolved in the water to be treated reacts as follows.

O ₃ + H ₂ O → O ₂ + H ₂ O ₂ H ₂ O ₂ → 2 · OH Alternatively, ozone dissolved in the water to be treated reacts as follows.

O ₃ + H ₂ O → O ₂ + 2 · OH Ozone bubbles remaining in the water to be treated react as follows.

O ₃ → O ₂ + OH ₂ O + O → H ₂ O ₂ H ₂ O ₂ → 2 · OH The hydro radical thus generated is a stronger oxidizing agent than ozone. In particular, hydroradicals also decompose hardly decomposable substances that cannot be decomposed by ozone. Therefore, the organic matter contained in the water to be treated is rapidly and effectively decomposed by the hydroradical in the ultraviolet irradiation region 3, and the decomposition rate by the hydroradical is several times to several tens times higher than the decomposition rate by ozone.

The water to be treated in the ultraviolet irradiation area 3 is supplied from the ozone spraying area 2 through the lower part of the area partition plate 6, passes through the upper part of the unit partition plate 5, and spreads the ozone in the second-stage oxidation unit 1 b. Sent to area 2. For this reason, the water to be treated in the ultraviolet irradiation region 3 becomes an upward flow in the ultraviolet irradiation region 3 from below to above. Thereby, while the to-be-treated water goes upward from below the ultraviolet irradiation region 3, the hydroradicals efficiently decompose organic substances contained in the to-be-treated water.

The water to be treated sent to the second-stage oxidation processing unit 1b is divided into an ozone spraying area 2 and an ultraviolet irradiation area 3
, The same purification treatment as in the first-stage oxidation treatment unit 1a is performed. Then, the water to be treated is 3
It is sent to the oxidation treatment unit 1c at the stage, and further sent to the oxidation treatment unit 1d at the fourth stage, and the same purification treatment is performed.

The water to be treated, which has undergone the purification treatment in the fourth-stage oxidation treatment unit 1d, is then sent to another treatment device or discharged.

The ozonized gas which is not taken into the water to be treated of each oxidation treatment unit 1 and is discharged to the gas phase of each oxidation treatment unit 1 is sent to a waste ozone treatment device 13 through a waste ozone transport pipe 7. The waste ozone treatment device 13
Is decomposed and exhausted.

In this embodiment, the four oxidation treatment units 1 are connected to each other, but the present invention is not limited to this. Since the amount of organic substances such as hardly decomposable substances contained in the water to be treated supplied to the accelerated oxidation treatment apparatus is not always constant, the degree of purification treatment required for the water to be treated is not constant. Therefore, the degree of purification treatment of the water to be treated can be adjusted by increasing or decreasing the number of the oxidation treatment units 1 constituting the accelerated oxidation treatment device according to the state of the water to be treated.

Since the volume of the ozone spraying area 2 is larger than the volume of the ultraviolet irradiation area 3, the residence time of the water to be treated in the ozone scattering area 2 is longer than the residence time of the water to be treated in the ultraviolet irradiation area 3. Is also long. This promotes the incorporation of ozone into the water to be treated in the ozone spraying area 2 and promotes the decomposition of organic substances contained in the water to be treated by ozone.

The unit partition plate 5 may have a lower part opened instead of an upper part. In this case, the area partition plate 6 needs to be open at the top. This allows
The water to be treated has a downward flow in the ozone spraying area 2 and has an upward flow in the ozone spraying area 2.

As described above, according to the present embodiment, the purification treatment of the water to be treated can be performed by connecting the oxidation treatment units 1 of a desired number of stages to each other. By increasing or decreasing the number of stages of the oxidation treatment unit 1, it is possible to perform appropriate treatment of the water to be treated.

The water to be treated in the ozone spraying area 2 of each oxidation treatment unit 1 is a downward flow from above the ozone spraying area 2 to below. In addition, each oxidation treatment unit 1
The water to be treated in the ultraviolet irradiation region 3 is an upward flow from below to above. Thus, in the ozone spraying region 2, the uptake of ozone in the water to be treated is promoted, and the decomposition of organic substances by ozone is promoted. On the other hand, in the ultraviolet irradiation region 3, the decomposition of organic substances by hydroradicals is promoted.

Further, by making the volume of the ozone spraying area 2 larger than the volume of the ultraviolet irradiation area 3, the residence time of the water to be treated in the ozone spraying area 2 is increased, and the ozone uptake of the water to be treated is increased. As well as promoting the decomposition of organic substances by ozone.

Second Embodiment FIG. 2 is a diagram showing a second embodiment of the present invention. Here, FIG. 2 is a configuration diagram showing an accelerated oxidation treatment apparatus that performs an accelerated oxidation treatment of the supplied water to be treated.

In the second embodiment shown in FIG. 2, the accelerated oxidation treatment apparatus includes an ozone concentration meter 1
8 and a switching valve 8 are attached. A valve control device 14 is attached to the switching valve 8, and the valve control device 14 is connected to an ozone concentration meter 18. The switching valve 8 is connected via an ozone return pipe 7a to an ozone spraying device 10 installed in the ozone spraying area 2 of a fourth-stage oxidation processing unit 1d located at a later stage of each oxidation processing unit 1. ing. A blower 19 is attached to the ozone return pipe 7a between the switching valve 8 and the ozone spraying device 10 of the fourth-stage oxidation processing unit 1d. Another configuration is the first configuration shown in FIG.
This is substantially the same as the embodiment.

In FIG. 2, the same parts as those in the first embodiment shown in FIG. 1 are denoted by the same reference numerals, and detailed description is omitted.

The ozone spray area 2 of each oxidation processing unit 1
Of the ozone sprayed by the ozone spraying device 10 in
The ozonized gas discharged into the gas phase of each oxidation processing unit 1 without being taken into the water to be treated is sent to the exhaust ozone treatment device 13 through the exhaust ozone transport pipe 7.

At this time, the ozone concentration of the ozonized gas carried by the exhausted ozone carrying pipe 7 is detected by the ozone concentration meter 18. The valve control device 14 switches the switching valve 8 based on the detected ozone concentration value sent from the ozone concentration meter 18 to convert the ozonized gas flowing through the exhausted ozone transport pipe 7 into the exhausted ozone treatment device 13 or the fourth stage oxidation treatment. It is sent to the ozone spraying device 10 of the unit 1d. That is, when the detected value of ozone concentration exceeds a value that is considered to have a negative effect on the human body and the environment, the switching valve 8 is switched by the valve control device 14, and the ozonized gas is supplied to the blower 19 and the ozone return pipe. 7
It is sent to the ozone spraying device 10 of the fourth-stage oxidation processing unit 1d via a. On the other hand, when the value detected by the ozone concentration meter 18 does not exceed a predetermined value, the switching valve 8 is switched by the valve control device 14 and the ozonized gas is sent to the exhaust ozone treatment device 13. The ozonized gas sent to the exhaust ozone treatment device 13 is decomposed and exhausted in the exhaust ozone treatment device 13.

As described above, the ozonized gas discharged without being taken into the water to be treated is sent to the ozone spraying apparatus 10 installed in the ozone spraying area 2 of the oxidation treatment unit 1d.
By spraying on the water to be treated in the ozone spraying area 2,
It is possible to reuse the ozonized gas discharged without being taken into the water to be treated. Thereby, the consumption efficiency of ozone in the accelerated oxidation treatment device is increased, and the total amount of ozone injected for purifying the water to be treated can be reduced.

The ozonized gas discharged without being taken into the water to be treated may be sent to the ozone spraying device 10 of any of the oxidation treatment units 1.

As described above, according to the present embodiment, the valve control device 14 switches the switching valve 8 based on the ozone concentration detection value of the ozone concentration meter 18 so that the water is discharged without being taken into the water to be treated. The ozonized gas is sent to the ozone spraying device 10 installed in the ozone spraying area 2 of the oxidation treatment unit 1 and sprayed again on the water to be treated. Thereby, the consumption efficiency of ozone in the enhanced oxidation treatment device can be increased, and the total amount of ozone injected for purifying the water to be treated can be reduced by the enhanced oxidation treatment device. Operating costs can be reduced.

Third Embodiment FIG. 3 shows a third embodiment of the present invention. Here, FIG. 3 is a configuration diagram showing an accelerated oxidation treatment apparatus that performs an accelerated oxidation treatment of the supplied water to be treated.

In the third embodiment shown in FIG. 3, the accelerated oxidation treatment apparatus has a hydrogen peroxide supply pump 20, and the hydrogen peroxide supply pump 20 is located at the preceding stage of each oxidation treatment unit 1. First stage oxidation unit 1
Hydrogen peroxide is supplied to the water to be newly supplied to a, and hydrogen peroxide is supplied to the ozone spraying area 2 of each oxidation treatment unit 1. The hydrogen peroxide supply pump 20 is provided with a hydrogen peroxide storage tank 4, and the hydrogen peroxide supply pump 20 and the hydrogen peroxide storage tank 4 constitute a hydrogen peroxide injection device. The other configuration is substantially the same as that of the second embodiment shown in FIG.

In FIG. 3, the same portions as those of the second embodiment shown in FIG. 2 are denoted by the same reference numerals, and detailed description is omitted.

Hydrogen peroxide is supplied from the hydrogen peroxide storage tank 4 to the water to be newly supplied to the first-stage oxidation processing unit 1a and the water to be processed in the ozone spraying area 2 of each oxidation processing unit 1. Hydrogen peroxide is supplied via a pump 20. As a result, in each of the ozone spraying regions 2, hydrogen peroxide and ozone react as described below to generate hydro radicals (.OH).

O ₃ + H ₂ O ₂ → OH + HO ₂ + O ₂ H ₂ O ₂ → HO ₂ ⁻ + H ⁺ O ₃ + HO ₂ ⁻ → OH + O ₂ ⁻ + O ₂ Therefore, in the ozone scattering area 2 of each oxidation processing unit 1. Also, since the organic matter is decomposed by the hydroradical, the decomposition of the organic matter contained in the water to be treated is promoted.

As described above, according to the present embodiment, in the ozone spraying area 2 of each oxidation processing unit 1, hydrogen peroxide and ozone react with each other to generate hydroradicals. In 2 also, the decomposition of the organic substance by the hydroradical is performed. Thereby, the decomposition of the organic matter contained in the water to be treated is performed more efficiently, and the amount of the water to be treated that can be subjected to the purification treatment in the accelerated oxidation treatment apparatus can be increased.
By reducing the number of installation stages of the oxidation treatment unit 1, the size of the accelerated oxidation treatment device can be reduced.

Fourth Embodiment FIG. 4 is a diagram showing a fourth embodiment of the present invention. Here, FIG. 4 is a configuration diagram showing an accelerated oxidation treatment apparatus that performs an accelerated oxidation treatment of the supplied water to be treated.

In the fourth embodiment shown in FIG. 4, the accelerated oxidation treatment apparatus has a light transmittance detector 21 provided at the entrance of the first-stage oxidation treatment unit 1a. The light transmittance of the water to be treated newly supplied to the accelerated oxidation treatment apparatus is detected by the total 21.
The light transmittance detector 21 has an ultraviolet lamp power supply 17.
Lamp power control device 15 for controlling the ozone control valve 9 for controlling the ozone control valve 9 for controlling the amount of ozone sprayed by the ozone spray device 10 in the ozone spray region 2 of each oxidation treatment unit 1. Is connected. Other configurations are substantially the same as those of the third embodiment shown in FIG.

In FIG. 4, the same portions as those of the third embodiment shown in FIG. 3 are denoted by the same reference numerals, and detailed description thereof will be omitted.

The light transmittance of the water to be newly supplied to the accelerated oxidation treatment apparatus is detected by the light transmittance detector 21. The detection value of the light transmittance detector 21 is sent to the ultraviolet lamp power supply control device 15 and the ozone adjustment valve control device 16.

The ozone adjusting valve controller 16 adjusts the amount of ozone sprayed by the ozone spraying device 10 in the ozone spraying area 2 of each oxidation treatment unit 1 based on the value detected by the light transmittance detector 21. Control.
That is, when the turbidity of the water to be treated supplied to the accelerated oxidation treatment apparatus increases and the light transmittance decreases, the ozone adjustment valve 9 is opened to increase the amount of ozone sprayed on the water to be treated, When the turbidity of the water to be treated decreases and the light transmittance increases, the ozone control valve 9 is closed to reduce the amount of ozone sprayed on the water to be treated.

The ultraviolet lamp power supply controller 15 adjusts the input power or the excitation air frequency of the ultraviolet lamp power supply 17 attached to each oxidation processing unit 1 based on the detection value of the light transmittance detector 21 to Lamp power supply 17
Control. That is, when the turbidity of the water to be treated supplied to the accelerated oxidation treatment apparatus increases, the input power of the ultraviolet lamp power supply 17 or the excitation air frequency is increased to increase the ultraviolet light output of the ultraviolet lamp. Further, when the turbidity of the water to be treated supplied to the accelerated oxidation treatment apparatus is reduced, the input power of the ultraviolet lamp power supply 17 or the excitation air frequency is reduced to lower the ultraviolet light output of the ultraviolet lamp. Thereby, the irradiation amount of the ultraviolet rays to the water to be treated is adjusted.

As described above, the treatment efficiency of the water to be treated can be improved by adjusting the amount of the ozone sprayed and the amount of the ultraviolet irradiation in accordance with the turbidity of the water to be treated supplied to the accelerated oxidation treatment apparatus. In addition, the energy efficiency of the operation of the accelerated oxidation treatment apparatus can be improved. Further, regardless of the turbidity of the water to be treated, a constant amount of the water to be treated can always be purified by the accelerated oxidation treatment apparatus.

As described above, according to the present embodiment, the amount of ozone sprayed to the water to be treated and the amount of ultraviolet irradiation to the water to be treated are changed according to the turbidity of the water to be treated newly supplied to the accelerated oxidation treatment apparatus. Can be adjusted. Therefore, it is possible to perform the purification treatment corresponding to the state of the water to be treated, and to improve the treatment efficiency of the water to be treated and the operating energy efficiency of the accelerated oxidation treatment apparatus. Can be purified in an accelerated oxidation treatment apparatus.

[0069]

As described above, according to the present invention,
By increasing or decreasing the number of stages of the oxidation treatment unit according to the state of the water to be treated, it is possible to secure an appropriate ozone injection amount and an ultraviolet irradiation amount according to the state of the water to be treated, and perform an appropriate purification treatment. .

[Brief description of the drawings]

FIG. 1 is a configuration diagram showing a first embodiment of an advanced oxidation treatment apparatus according to the present invention.

FIG. 2 is a configuration diagram showing a second embodiment of the accelerated oxidation treatment apparatus according to the present invention.

FIG. 3 is a configuration diagram showing a third embodiment of the advanced oxidation treatment apparatus according to the present invention.

FIG. 4 is a configuration diagram showing a fourth embodiment of the accelerated oxidation treatment apparatus according to the present invention.

FIG. 5 is a configuration diagram showing a conventional accelerated oxidation treatment apparatus.

[Explanation of symbols]

 Reference Signs List 1 oxidation treatment unit 1a first-stage oxidation treatment unit 1b second-stage oxidation treatment unit 1c third-stage oxidation treatment unit 1d fourth-stage oxidation treatment unit 2 ozone spraying area 3 ultraviolet irradiation area 4 hydrogen peroxide storage tank Reference Signs List 5 Unit partition plate 6 Area partition plate 7 Discharge ozone transport pipe 7a Ozone return pipe 8 Switching valve 9 Ozone adjustment valve 10 Ozone spraying device 11 Ultraviolet irradiation device 12 Ozone generator 13 Discharge ozone treatment device 14 Valve control device 15 Ultraviolet lamp power supply control Apparatus 16 Ozone adjustment valve controller 17 Ultraviolet lamp power supply 18 Ozone concentration meter 19 Blower 20 Hydrogen peroxide supply pump 21 Light transmittance detector 22 Raw water intake pump 23 Ozone treatment tank 24 Ultraviolet irradiation tank 25 Water tank

 ──────────────────────────────────────────────────続 き Continuing on the front page (72) Inventor Kenji Taguchi 1-1-1, Shibaura, Minato-ku, Tokyo Inside the Toshiba head office (72) Inventor Takae Kubo 1-1-1, Shibaura, Minato-ku, Tokyo No. 1 In the head office of Toshiba Corporation (72) Inventor Kotaro Iyasu 1 in Toshiba-cho, Fuchu-city, Tokyo (72) Inventor Yukio Ohashi 1 in Toshiba-cho, Fuchu-shi, Tokyo Shares F-term in the Toshiba Fuchu Office (reference) 2G059 AA05 BB05 EE01 KK01 4D037 AA05 AB14 AB16 AB18 BA18 CA11 CA12 4D050 AA02 AB15 AB19 BB02 BB09 BD03 BD06 CA07

Claims (6)

[Claims] 1. An accelerated oxidizing water treatment apparatus comprising a plurality of oxidizing units connected to each other, wherein each oxidizing unit is provided with an ozone spraying device. An accelerated oxidation treatment apparatus comprising a spray area and an ultraviolet irradiation area provided with an ultraviolet irradiation apparatus. 2. Each of the oxidation processing units is partitioned by a unit partition plate whose upper or lower part is open, and the ozone scattering region and the ultraviolet irradiation region of each of the oxidation processing units are one of the upper and lower units. 2. The accelerated oxidation treatment apparatus according to claim 1, wherein the partition plate is partitioned by a region partition plate in which a part of the partition plate on a side opposite to the opening is open. 3. The accelerated oxidation processing apparatus according to claim 1, wherein the volume of the ozone spraying area of each oxidation processing unit is larger than the volume of the ultraviolet irradiation area. 4. An exhaust ozone transport pipe is connected to a gas phase portion of an ozone spray area of each oxidation treatment unit, and the exhaust ozone transport pipe is connected to an ozone spray area of a downstream ozone spray area via an ozone return pipe. The accelerated oxidation treatment apparatus according to any one of claims 1 to 3, wherein the apparatus is connected to an apparatus. 5. A hydrogen peroxide injection device, wherein hydrogen peroxide is injected from the hydrogen peroxide injection device into the water to be treated in a stage preceding the oxidation processing unit or in an ozone spraying region of the oxidation processing unit. The accelerated oxidation treatment apparatus according to claim 1. 6. The apparatus according to claim 1, further comprising a light transmittance detector for detecting the light transmittance of the water to be treated supplied to the oxidation processing unit, wherein the ozone spraying of each oxidation processing unit is performed based on the detection value of the light transmittance detector. The accelerated oxidation treatment apparatus according to any one of claims 1 to 5, wherein the apparatus or the ultraviolet irradiation apparatus is controlled by a control device.