JPH11285691A - Waste water treating device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To easily and adequately treat waste water with a simple constitution. SOLUTION: This device is provided with a first high pressure pump 2 for sucking the waste water and discharging, a chemical injection part 3 for injecting a chemical for oxidation bleaching into the waste water sucked with the first pump 2, an ejector 5 having an ozone injection part 4 for injecting the ozone into the waste water and allowing it to react with the chemical, a second low pressure pump 6 installed oppositely faced to a discharging part 22 of the first pump 2, a pressure reduction valve 7 provided on a waste water conduction part (a sucking part 62) of the second pump 6, and a waste water treating tank 8 for injecting the waste water reduced pressure with the pressure reduction valve 7 and treating.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a wastewater treatment apparatus for sterilizing, decolorizing, deodorizing and detoxifying industrial wastewater, industrial wastewater or domestic wastewater.

[0002]

2. Description of the Related Art Conventionally, as shown in Japanese Patent Application Laid-Open No. 8-155436, for example, two floating blades, one of which has a high discharge pressure and the other has a low discharge pressure, are provided in a flotation apparatus in the field of wastewater treatment. A pump having a low discharge pressure is connected by connecting a discharge pipe of both pumps with a pressure-resistant pipe, and connecting a supply pipe for supplying water with air to a suction port of a high discharge pressure pump of the two pumps. At the suction port, a nozzle equipped with a flow rate control valve for controlling the flow rate and pressure is installed, and a fine bubble generator that generates fine bubbles from the nozzle using a pressure difference when both pumps are operated is used.
It has been practiced that fine bubbles generated by the fine bubble generator are attached to suspended matter in wastewater, so that they float on the water surface and can be easily removed.

[0003]

In the flotation / separation apparatus using the above-mentioned microbubble generator, even though the suspended matter in the wastewater can be lifted and removed, the fine bubbles are dissolved in the wastewater. Since it cannot be attached to contaminants, it cannot be separated by flotation, and the contaminants cannot be rendered harmless.

[0004] In order to remove the pollutants dissolved in the wastewater, ozone is injected into the wastewater and its oxidation action causes
Decomposes various pollutants dissolved in wastewater to make them harmless,
It has also been practiced that it can be easily removed. However, in order to reliably treat pollutants in wastewater using the above-mentioned ozone, an ozone concentration of about 50 to 100 ppm is conventionally required, so that a large-capacity ozone generator must be used. However, there is a problem in that the size of the device increases and the equipment cost increases. In addition, when a large-sized ozone generator is used as described above, a large amount of waste ozone is generated. Therefore, there is a problem that a large-scale processing apparatus for treating the waste ozone is required.

The present invention has been made in view of such circumstances, and provides a wastewater treatment apparatus capable of easily and properly treating wastewater with a simple configuration.

[0006]

The invention according to claim 1 is
A high-pressure first pump for sucking and discharging waste water,
A chemical injection part for injecting a chemical for oxidative bleaching into the wastewater sucked by the pump, an ejector having an ozone injection part for injecting ozone into the wastewater, and a discharge part of the first pump installed opposite to each other. A low-pressure second pump,
A pressure reducing valve provided on the drainage outlet side of the second pump;
And a wastewater treatment tank into which wastewater decompressed by the pressure reducing valve is injected and treated.

According to the above configuration, the oxidizing bleaching agent injected from the agent injection unit and the ozone injected from the ozone injection unit of the ejector reduce the discharge pressure of the first pump and the second pump. While receiving and stirring,
By being effectively dissolved in the waste water by receiving the pressure adjusting action of the pressure reducing valve, the oxidative bleaching of pollutants in the waste water by the chemicals is promoted. Further, after the drainage discharged from the drainage outlet of the second pump is depressurized by the pressure reducing valve and then injected into the drainage treatment tank, the gas dissolved in the drainage is rapidly vaporized and a large amount of fine particles are discharged. Bubbles are generated, which adhere to the substance oxidized and bleached by the above-mentioned chemicals, and the flotation is promoted.

According to a second aspect of the present invention, in the wastewater treatment apparatus according to the first aspect, an air injection section for injecting air is provided in the ejector instead of the ozone injection section.

According to the above configuration, the oxidizing bleaching agent injected from the agent injection portion and the air injected from the air injection portion of the ejector are caused by the discharge pressure of the first pump and the second pump. While being agitated, it is effectively dissolved in the waste water by receiving the pressure regulating action of the pressure reducing valve, thereby promoting the oxidative bleaching of the pollutants in the waste water by the chemical.

According to a third aspect of the present invention, in the wastewater treatment apparatus according to the first aspect, an ozone recovery section for recovering undissolved ozone is provided between the second pump and the pressure control valve. The ozone collected in the collection section is returned to the installation section of the ejector and re-supplied.

According to the above configuration, the undissolved ozone recovered in the ozone recovery section is returned to the installation section of the ejector and re-supplied, thereby effectively reducing the amount of waste ozone discharged. In addition, even when a small-sized ozone supply device is used, it is possible to supply a sufficient amount of ozone to treat wastewater.

According to a fourth aspect of the present invention, in the wastewater treatment apparatus according to any one of the first to third aspects, an ultraviolet irradiation device is provided between the first pump and the second pump. .

[0013] According to the above configuration, the wastewater passing between the first pump and the second pump is irradiated with ultraviolet rays by the ultraviolet irradiation device, whereby the oxidation of pollutants dissolved in the wastewater is promoted. As a result, the wastewater is effectively bleached, and fungi and viruses in the wastewater are effectively sterilized.

According to a fifth aspect of the present invention, in the wastewater treatment apparatus according to any one of the first to third aspects, an injection portion for an anionic coagulant is provided between the first pump and the second pump. , An injection section for a cationic coagulant is provided between the second pump and the pressure control valve.

According to the above construction, the fine particles in the waste water which are difficult to be treated with the oxidative bleaching agent by the anionic flocculant and the cationic flocculant injected into the waste water from the injection section of the flocculant. The ionic substances are aggregated and flocculated, and the flocs are effectively removed by floating separation or sedimentation.

[0016]

FIG. 1 shows an embodiment of a wastewater treatment apparatus according to the present invention. This wastewater treatment device includes a wastewater storage tank 1 for storing wastewater, a high-pressure first pump 2 for sucking and discharging wastewater in the wastewater storage tank 1, and a wastewater sucked by the first pump 2. A chemical injection part 3 for injecting a chemical for oxidative bleaching, an ejector 5 having an ozone injection part 4 for injecting ozone into the wastewater, and a low pressure installed opposite to the discharge part 22 of the first pump 2 Second
The pump 6 includes a pump 6, a pressure reducing valve 7 provided on the drainage outlet side of the second pump 6, and a wastewater treatment tank 8 into which wastewater reduced in pressure by the pressure reducing valve 7 is injected.

The drug injection section 3 is connected to a connecting pipe 9 connecting the inside of the drainage storage tank 1 and the inlet of the ejector 5, and is supplied with sodium hypochlorite (NaClO) supplied from a drug supply device (not shown). ), A bleaching agent or a chemical for oxidative bleaching, such as sodium chlorate (NaClO ₂ ), is injected into the connecting pipe 9.

As shown in FIG. 2, the ejector 5 includes an outer tube 51 covering the connecting tube 9, a reduced diameter portion 52 provided at the tip of the outer tube 51, and a downstream side thereof. The ozone injecting section 4 is connected to the outer tube 51. Then, from the ozone supply device (not shown), the outer tube 51
The ozone injected between the pressure reducing section 52 and the connecting pipe 9
The wastewater that has passed through the connecting pipe 9 and the ozone in the reduced diameter portion 52 and the increased diameter portion 53 are effectively mixed.

The enlarged diameter portion 53 of the ejector 5 is connected to the suction portion 21 of the first pump 2 by a connecting pipe 10. The discharge part 22 of the first pump 2 and the discharge part 61 of the second pump 6 are connected to the connecting pipe 11 made of a transparent material.
The drainage discharged from the discharge part 22 of the first pump 2 is supplied to the discharge part 61 of the second pump 6 through the connection pipe 11 and the discharge pressure of the second pump 6 is reduced. Receiving and stirring. A high-pressure pump is used as the first pump 2, and the discharge pressure thereof is set to be higher than the discharge pressure of the second pump 6. 6 and is drawn out from the suction part 62 thereof.

A connection pipe 12 is connected to the suction section 62 serving as a drainage outlet of the second pump 6.
2 is introduced into the wastewater treatment tank 8. The connection pipe 12 is provided with a pressure-reducing valve 7 for reducing the pressure of the drainage discharged from the drainage discharge section of the second pump 6 and discharging the drainage to the drainage treatment tank 8. The high pressure state is maintained. Further, an ultraviolet irradiating device 13 for irradiating the wastewater passing through the inside of the connecting pipe 11 with ultraviolet light is provided at the installation portion of the connecting pipe 11.

In the above configuration, in order to treat the wastewater stored in the wastewater storage tank 1, the first and second pumps 2, 6
Is operated to suck the wastewater in the wastewater storage tank 1 into the connecting pipe 9 by the suction force of the first pump 2 and to inject a predetermined amount of the oxidizing bleaching chemical from the chemical injection part 3 into the wastewater. At the same time, a predetermined amount of ozone is injected from the ozone injection section 4 of the ejector 5 to mix the waste water, the oxidizing bleaching agent, and ozone.

The waste water discharged from the discharge part 22 of the first pump 2 is irradiated with ultraviolet rays from the ultraviolet irradiation device 13 when passing through the connecting pipe 11 and receives the discharge pressure of the second pump 6. While being agitated, the water is supplied from the drainage outlet (suction part 62) of the second pump 6 to the installation part of the pressure reducing valve 7 through the connecting pipe 12, and after the pressure is reduced by the pressure reducing valve 7, the wastewater treatment is performed. It is poured into the tank 8.
The contaminants of the wastewater injected into the wastewater treatment tank 8 are oxidized and bleached by the oxidizing and bleaching agent and ozone dissolved therein to change into harmless substances.

Then, due to the pressure drop phenomenon when the waste water decompressed by the pressure reducing valve 7 is injected into the waste water treatment tank 8, the gas dissolved in the waste water is rapidly vaporized and a large number of fine bubbles are generated. Then, it adheres to the harmless substance converted to the harmless substance and floats on the water surface. The suspended substance floating on the water surface of the wastewater treatment tank 8 is collected by being scraped by a conventionally known scraping means provided in the wastewater treatment tank 8 or the like. In addition, it is good also as a structure provided with the conventionally well-known sedimentation separation means which separates and collects the sedimentation substance which settled in the said wastewater treatment tank 8.

A high-pressure first pump 2 for sucking and discharging wastewater as described above, and a chemical injection section 3 for injecting a chemical for oxidative bleaching into the wastewater sucked by the first pump 2
And an ejector 5 having an ozone injection unit 4 for injecting ozone into the wastewater and mixing the wastewater with the chemical.
A low-pressure second pump 6 installed opposite to the discharge section 22 of the first pump 2, a pressure reducing valve 7 provided on the drainage outlet side of the second pump 6, and a pressure reducing valve 7. And a wastewater treatment tank 8 in which wastewater decompressed by the above is injected and treated, so that contaminants dissolved in wastewater, which were difficult to treat with a conventional flotation device, can be effectively treated with a simple configuration. The wastewater can be appropriately sterilized, decolorized, deodorized, and detoxified.

That is, the oxidizing bleaching agent and ozone injected from the agent injection unit 3 and the ozone injection unit 4 and mixed into the waste water by the ejector 5 are supplied to the first pump 2 and the second pump 6. Agitating by the discharge pressure and maintaining the upstream side in a high pressure state by the pressure regulating action of the pressure reducing valve 7 make it possible to effectively dissolve the oxidative bleaching agent and ozone in the wastewater. it can. Therefore, without supplying a large amount of ozone as in the conventional apparatus, the oxidizing and bleaching agent composed of sodium hypochlorite and the like and the synergistic action of ozone effectively oxidize pollutants in the wastewater to be harmless. It can be converted to a substance and the wastewater can be effectively bleached.

For example, a trade name Di manufactured by Mitsubishi Chemical Corporation
100 bp dye of mira Red B (RRB)
effluent mixed at a concentration of 500 m
Liter / h, and 1
Sodium hypochlorite is injected to a concentration of 00 ppm, ozone is injected from the ozone injection unit 4 at a flow rate of 0.79 g / h to a concentration of 1 ppm, and After treating the waste water by irradiating it with ultraviolet light having a wavelength of 0.7 nm at a power of 240 W, an experiment was performed to measure the change in absorbance, and data as shown in FIG. 3A was obtained. From this data, it was confirmed that the use of the wastewater treatment apparatus effectively oxidized and bleached the dyes in the wastewater and significantly improved the transparency of the wastewater.

On the other hand, without injecting a chemical for oxidative bleaching, such as sodium hypochlorite, from the chemical injecting section 3, the concentration of 0.79 g / cm 3 was obtained from the ozone injecting section 4 so that the concentration became 1 ppm. h at a flow rate of h
After treating the wastewater by irradiating ultraviolet rays from the ultraviolet irradiation device 13, an experiment was performed to measure the change in the absorbance. As a result, data as shown in FIG. 3B was obtained. It was confirmed that there was little improvement.

In order to confirm the effect of irradiating ultraviolet rays with the ultraviolet irradiating device 13, the dye, sodium hypochlorite and ozone were mixed into water in a beaker at the same concentration as in the above experimental example. When an experiment was performed to measure the change in absorbance by stirring the mixture, data as shown in FIG. 3C was obtained. From this data, it was confirmed that in the case where the ultraviolet irradiation device 13 was omitted, when the dye and the ozone were oxidized and bleached by the chemical and ozone, the promoting effect of the ultraviolet light was not obtained, and the effect of improving the transparency was reduced. Was done.

Further, as shown in the above embodiment, the first
The ultraviolet irradiation device 1 between the pump 2 and the second pump 6
3 is arranged to irradiate the wastewater passing through the connecting pipe 11 with ultraviolet rays, there is obtained an effect that bacteria and viruses in the wastewater can be effectively sterilized by the sterilization effect of ultraviolet rays. Will be done. When a photocatalytic substance such as titanium oxide, titanium dioxide, or zinc oxide is provided in a portion of the connecting pipe 11 where the ultraviolet rays are irradiated, the photocatalytic action further reduces pollutants dissolved in the wastewater. It can be effectively oxidized and bleached.

When the oxygen demand of contaminants dissolved in the wastewater treated by the wastewater treatment device is relatively small, an air injection unit for injecting air instead of the ozone injection unit 4 is replaced by an ejector 5. And air may be supplied from the air injection section into the drainage water.

As shown in FIG. 4, an ozone recovery section 14 for recovering undissolved ozone is provided between the second pump 6 and the pressure control valve 7, and the ozone recovery section 14 A return pipe 16 is provided to connect the waste ozone injecting section 15 provided in the enlarged diameter section 53 of the ejector 5 so that the ozone collected in the ozone collecting section 14 is returned to the waste ozone injecting section 15 of the ejector 5. May be configured.

With this configuration, the amount of waste ozone discharged to the outside from the wastewater treatment device can be effectively reduced, so that the treatment device for treating waste ozone can be reduced in size. Can be In addition, since the amount of ozone newly injected from the ozone supply device (not shown) via the ozone injection unit 4 can be reduced,
Even when the ozone supply device is downsized, it is possible to supply a sufficient amount of ozone to treat wastewater. In order to effectively mix the ozone injected from the waste ozone injection unit 15 and the chemical for oxidative bleaching injected from the chemical injection unit 3, as shown in FIG.
It is desirable that a nozzle constituting the waste ozone injection unit 15 is introduced into the large-diameter portion 53, and the opening of the nozzle is directed toward the small-diameter portion 52 of the ejector 5.

As shown in FIG. 4, an injection section 17 of an anionic coagulant A is provided between the first pump 2 and the second pump 6, and a second pump and a pressure control valve are provided between the second pump and the pressure control valve. An injection section 18 for the cationic coagulant B is provided, and an anionic coagulant A
When the composition is configured to inject the cationic coagulant B, fine particles and ionic substances in the wastewater which are difficult to be treated with the oxidative bleaching agent can be flocculated by aggregation. In addition, a pipe 19 for collecting the floating substance 20 is provided in the wastewater treatment tank 8, and the floating substance 2 collected through the pipe 19 for recovery is provided.
And a storage tank 21 for storing floating substances 20 formed of flocs or the like agglomerated by the aggregating agents A and B, thereby more effectively treating the contaminants in the wastewater. can do.

[0034]

As described above, according to the first aspect of the present invention, a high-pressure first pump for sucking and discharging wastewater and a chemical for oxidative bleaching are contained in the wastewater sucked by the first pump. An ejector having an ozone injector for injecting ozone into the wastewater;
A low-pressure second pump installed opposite to the discharge section of the pump, a pressure reducing valve provided on a drain outlet side of the second pump, and drainage depressurized by the pressure reducing valve are injected and processed. And a wastewater treatment tank, which was dissolved in the wastewater by the synergistic action of the oxidizing bleaching agent composed of sodium hypochlorite and the like and ozone without requiring a large amount of ozone as in the conventional apparatus. The pollutants can be effectively oxidized and converted into harmless substances, and the wastewater can be effectively bleached and deodorized.

According to the second aspect of the present invention, since the ejector is provided with an air injection portion for injecting air instead of the ozone injection portion, the oxidizing bleaching agent injected from the drug injection portion and the ejector With the air injected from the air injection section, the air can be stirred by the discharge pressures of the first pump and the second pump, and can be effectively dissolved in the drainage by receiving the pressure adjusting action of the pressure reducing valve. Therefore, there is an advantage that the oxidative bleaching of pollutants in the wastewater by the oxidative bleaching agent can be effectively promoted without providing an ozone supply device.

According to a third aspect of the present invention, an ozone recovery section for recovering undissolved ozone is provided between the second pump and the pressure control valve, and the ozone recovered by the ozone recovery section is provided. Because it was configured to return to the installation part of the ejector and resupply, effectively reducing the amount of waste ozone discharged to the outside from the wastewater treatment device,
It is possible to reduce the size of a processing apparatus for treating waste ozone, and to supply a sufficient amount of ozone to treat wastewater even if the amount of ozone injected from the ozone supply apparatus is reduced. Therefore, there is an advantage that the size of the ozone supply device can be reduced.

Further, in the invention according to claim 4, the ultraviolet irradiation device is disposed between the first pump and the second pump.
The oxidative bleaching action of contaminants caused by the above-mentioned chemicals and ozone can be promoted by ultraviolet rays emitted from an ultraviolet irradiation device, and the bacteria and viruses in wastewater can be effectively sterilized by the sterilizing effect of ultraviolet rays. is there.

The invention according to claim 5 provides an anionic coagulant injection section between the first pump and the second pump and a cationic coagulant between the second pump and the pressure control valve. Is provided, there is an advantage that the fine particles and ionic substances in the wastewater which are difficult to be treated with the oxidizing and bleaching agent are flocculated by agglomeration, and can be efficiently collected and treated.

[Brief description of the drawings]

FIG. 1 is an explanatory view showing an embodiment of a wastewater treatment device according to the present invention.

FIG. 2 is a sectional view showing a specific configuration of an ejector.

FIG. 3 is a graph showing a change in absorbance.

FIG. 4 is an explanatory view showing another embodiment of the wastewater treatment device according to the present invention.

FIG. 5 is a sectional view showing another example of the ejector.

[Explanation of symbols]

 REFERENCE SIGNS LIST 1 drainage storage tank 2 first pump 3 chemical injection section 4 ozone injection section 5 ejector 6 second pump 7 pressure reducing valve 8 wastewater treatment tank 14 ozone recovery section 15 waste ozone injection section 16 return pipe 17 anion coagulant injection section 18 Injection part of cationic coagulant

────────────────────────────────────────────────── ─── Continued on the front page (51) Int.Cl. ⁶ Identification code FI C02F 1/50 560 C02F 1/50 560C 560Z 1/00 1/00 F 1/32 1/32 1/52 1/52 Z 1 / 74 1/74 Z 1/76 ZAB 1/76 ZABA 1/78 1/78 (72) Inventor Hiroaki Okamoto 2-21-27 Minami-Zao-cho, Fukuyama City, Hiroshima Pref.

Claims (5)

[Claims] 1. A high-pressure first pump for sucking and discharging wastewater, a chemical injection unit for injecting a chemical for oxidative bleaching into wastewater sucked by the first pump, and injecting ozone into the wastewater. An ejector having an ozone injecting section,
A low-pressure second pump installed opposite to the discharge section of the first pump, a pressure reducing valve provided on a drain outlet side of the second pump, and drainage depressurized by the pressure reducing valve are injected. A wastewater treatment apparatus, comprising: a wastewater treatment tank that is subjected to wastewater treatment. 2. The wastewater treatment device according to claim 1,
A wastewater treatment apparatus, wherein an air injection section for injecting air is provided in the ejector instead of the ozone injection section. 3. The wastewater treatment device according to claim 1,
An ozone recovery section for recovering undissolved ozone is provided between the second pump and the pressure control valve, and the ozone recovered in the ozone recovery section is returned to the installation section of the ejector so as to be resupplied. A wastewater treatment device characterized by comprising. 4. The wastewater treatment device according to claim 1, wherein an ultraviolet irradiation device is disposed between the first pump and the second pump. 5. The wastewater treatment apparatus according to claim 1, wherein an injection section for an anionic coagulant is provided between the first pump and the second pump, and the pressure of the second pump is reduced. A wastewater treatment device comprising a cationic coagulant injection section provided between the control valve and the control valve.