JP4685676B2 - Wastewater treatment equipment - Google Patents

Description

The present invention relates to wastewater treatment apparatus, for example, it relates to wastewater treatment apparatus that processes the wastewater containing organic matter of the organic fluorine compounds generated in the semiconductor factory or a liquid crystal factory.

  An organic fluorine compound, which is an example of an organic substance contained in waste water, is a chemically stable substance. This organic fluorine compound has excellent properties particularly from the viewpoints of heat resistance and chemical resistance, and is therefore widely used as industrial materials such as surfactants and antireflection films.

  However, since this organofluorine compound is a chemically stable substance, it is difficult for microorganisms to decompose. Therefore, when it is released into the environment, it causes environmental pollution. For example, perfluorooctasulfonic acid (PFOS) and perfluorooctanoic acid (PFOA) as the organic fluorine compounds are concerned about the influence on the ecosystem because the degradation in the ecosystem does not proceed.

  That is, since the above-mentioned perfluorooctasulfonic acid (PFOS) and perfluorooctanoic acid (PFOA) are chemically stable, a high temperature of about 1000 ° C. or higher is required for thermal decomposition. That is, perfluorooctasulfonic acid and perfluorooctanoic acid are extremely difficult to decompose by treatment with conventional microorganisms or photocatalysts.

  By the way, as a conventional technique, a method and an apparatus for using nanobubbles are described in Patent Document 1 (Japanese Patent Laid-Open No. 2004-121962). This prior art utilizes characteristics such as surface active action and bactericidal action due to the phenomenon that nanobubbles have reduced buoyancy, increased surface area, increased surface activity, generation of local high-pressure field, and realization of electrostatic polarization. . More specifically, in this prior art, by interlinking them, various objects can be washed with high functionality and low environmental load by the adsorption function of dirt components, the high-speed cleaning function of the object surface, and the sterilization function. It is said that the polluted water can be purified.

  As another conventional technique, a method for generating nanobubbles is described in Patent Document 2 (Japanese Patent Laid-Open No. 2003-334548). In this prior art, in a liquid, (i) a step of decomposing and gasifying part of the liquid, (ii) a step of applying ultrasonic waves in the liquid, or (iii) decomposing and gasifying a part of the liquid It is comprised from the process and the process of applying an ultrasonic wave.

  Furthermore, as another conventional technique, a waste liquid treatment apparatus using ozone microbubbles is described in Patent Document 3 (Japanese Patent Laid-Open No. 2004-321959). In this prior art, ozone gas generated from the ozone generator and waste liquid extracted from the lower part of the treatment tank are supplied to the microbubble generator via a pressure pump. Moreover, in this prior art, the produced | generated ozone microbubble is ventilated in the waste liquid in a processing tank from the opening part of a gas blowing pipe.

However, in the conventional wastewater treatment equipment using the above-mentioned microbubbles and nanobubbles, wastewater containing organic substances such as organic fluorine-based compounds that are chemically stable substances could not be efficiently decomposed at low cost. .
JP 2004-121962 A Japanese Patent Laid-Open No. 2003-334548 JP 2004-321959 A

Accordingly, an object of the present invention is to provide a wastewater treatment apparatus organics (e.g. organic fluorine compounds) Ru can be decomposed efficiently.

In order to solve the above-described problem, a wastewater treatment method of one reference example introduces wastewater into a first micro / nano bubble generation tank, and includes the micro / nano bubbles in the waste water,
Introducing the waste water containing the micro / nano bubbles from the first micro / nano bubble generation tank to the first microorganism treatment facility and treating the waste water with microorganisms;
Introducing the waste water containing micro-nano bubbles from the first microorganism treatment facility into the second micro-nano bubble generation tank, and allowing the waste water to contain micro-nano bubbles;
Introducing the waste water containing the micro-nano bubbles from the second micro-nano bubble generation tank to the second microorganism treatment facility, and treating the waste water with microorganisms;
Introducing the waste water into the third micro / nano bubble generating tank from the second microorganism treatment facility, and adding the micro / nano bubbles to the waste water;
A step of introducing waste water containing the micro-nano bubbles from the third micro / nano bubble generation tank to a third microorganism treatment facility and treating the waste water with microorganisms.

According to the wastewater treatment method of this reference example , the first, second, and third microbial treatment facilities are subjected to three stages of microbial treatment on the wastewater, and the first and second microbial treatment facilities are subjected to the first and second microbial treatment facilities. 2. From the third micro / nano bubble generating tank, waste water containing micro / nano bubbles is introduced. Therefore, even if the micro / nano bubbles in the waste water are consumed by the aerobic microorganisms in each microorganism treatment facility, the micro / nano bubbles can be replenished from each micro / nano bubble generation tank to each microorganism treatment facility each time. Therefore, micro-nano bubbles can be effectively used in each microorganism treatment facility, and microorganisms that are propagated in each microorganism treatment facility can be activated. Therefore, according to the wastewater treatment method of this reference example , organic matter (for example, an organic fluorine compound) can be efficiently decomposed by microorganisms.

Moreover, in the waste water treatment method of one reference example, the waste water is an organic waste water containing an organic fluorine compound.

According to the wastewater treatment method of this reference example , the organic fluorine compound contained in the organic wastewater can be efficiently microbially decomposed.

In the wastewater treatment method of one reference example , the organic wastewater contains at least one of perfluorooctasulfonic acid or perfluorooctanoic acid.

According to the wastewater treatment method of this reference example , perfluorooctasulfonic acid (PFOS) or perfluorooctanoic acid (PFOA) contained in organic wastewater can be efficiently microbially decomposed.

Moreover, in the wastewater treatment apparatus of the present invention , a first micro / nano bubble generation tank that contains micro / nano bubbles in the waste water while introducing the waste water,
A first microbial treatment facility for microbially treating the wastewater containing micro-nano bubbles while introducing waste water containing micro-nano bubbles from the first micro-nano bubble generation tank;
A second micro / nano bubble generating tank in which the waste water from the first microorganism treatment facility is introduced and the waste water contains micro / nano bubbles;
A third microbial treatment facility for microbially treating the wastewater containing micro-nano bubbles while introducing the waste water containing micro-nano bubbles from the second micro-nano bubble generation tank;
A third micro / nano bubble generating tank in which waste water from the third microorganism treatment facility is introduced and micro waste bubbles are contained in the waste water;
E Bei a third microbial treatment facility for microbial treatment of waste water containing the micro-nano bubble with waste water containing micro-nano bubbles from the third micro-nano bubble generation tank is introduced,
The first microbial treatment facility is a first microbial tank having an air lift pump that stirs and circulates waste water in the tank.
The second microorganism treatment facility is a second microorganism tank having an air lift pump for stirring and circulating the waste water in the tank,
The third of microbial treatment facilities, Ru activated carbon adsorption tower der.

According to the waste water treatment apparatus of the present invention, the waste water is subjected to the three-stage microorganism treatment by the first, second and third microorganism treatment facilities, and the first and second microorganism treatment facilities are classified into the first and second stages. Then, the waste water containing micro-nano bubbles is introduced from the third micro-nano bubble generation tank. Therefore, even if the micro / nano bubbles in the waste water are consumed by the aerobic microorganisms in each microorganism treatment facility, the micro / nano bubbles can be replenished from each micro / nano bubble generation tank to each microorganism treatment facility each time. Therefore, micro-nano bubbles can be effectively used in each microorganism treatment facility, and microorganisms that are propagated in each microorganism treatment facility can be activated. Therefore, according to the wastewater treatment apparatus of this embodiment, organic matter (for example, an organic fluorine compound) can be efficiently microbially decomposed.

  Moreover, as for the waste water treatment equipment of one embodiment, the above-mentioned waste water is organic waste water containing an organic fluorine compound.

  According to the wastewater treatment apparatus of this embodiment, the organic fluorine compound contained in the organic wastewater can be efficiently microbially decomposed.

Moreover, in the waste water treatment apparatus of one embodiment, the organic waste water is
It contains at least one of perfluorooctasulfonic acid and perfluorooctanoic acid.

  According to the wastewater treatment apparatus of this embodiment, perfluorooctasulfonic acid or perfluorooctanoic acid contained in organic wastewater can be efficiently decomposed by microorganisms.

Moreover, in the wastewater treatment apparatus of the present invention , the first microorganism treatment facility is a first microorganism tank having an air lift pump for stirring and circulating the wastewater in the tank,
The second microorganism treatment facility is a second microorganism tank having an air lift pump for stirring and circulating the waste water in the tank,
The third microbial treatment facility is an activated carbon adsorption tower.

According to the waste water treatment apparatus of the present invention, since the waste water in the first and second microorganism tanks is stirred and circulated by the air lift pump, energy saving can be achieved as compared with the case of stirring by a normal aeration method. it can. In addition, since the third microbial treatment facility in the final stage is an activated carbon adsorption tower, it is possible to reliably microbially decompose organic matter such as an organic fluorine compound contained in the waste water.

  In the wastewater treatment apparatus of one embodiment, the first microbial tank has a submerged membrane for solid-liquid separation of the water to be treated and the microorganism.

  According to the wastewater treatment apparatus of this embodiment, the concentration of microorganisms in the first microorganism tank can be increased by the submerged membrane, and the microorganism treatment can be stabilized. Here, the submerged membrane refers to a membrane installed in the liquid, and various ultrafiltration membranes can be adopted as the membrane, for example.

Moreover, in the wastewater treatment apparatus of one embodiment, the second microorganism tank is supplied with water to be treated in the tank from the air lift pump and sprinkles the water to be treated downward,
The water to be treated is sprinkled by the sprinkling tank part and the sprinkling part having activated carbon,
And an immersion part having activated carbon that is disposed below the watering part and into which the water to be treated that has passed through the watering part is introduced and is immersed in the water to be treated.

  According to the wastewater treatment apparatus of this embodiment, in the second microorganism tank, the water to be treated is sequentially introduced from the watering tank section to the watering section and the immersion section, and activated microorganisms propagated on the activated carbon in the watering section and the immersion section. Organic substances such as organic fluorine compounds contained in the water to be treated can be decomposed. That is, the activated carbon of the sprinkling part and the immersion part reasonably adsorbs organic substances such as organic fluorine compounds, and after this adsorption, activated microorganisms that have propagated on the activated carbon can decompose the organic substances such as organic fluorine compounds.

  Moreover, in the waste water treatment apparatus of one Embodiment, it has the rapid filtration tower installed in the back | latter stage of the said 3rd micro-nano bubble generation tank after the said 2nd microorganisms processing equipment.

  According to the wastewater treatment apparatus of this embodiment, the rapid filtration tower can physically remove the suspended matter contained in the water to be treated, and the suspended matter adheres to the activated carbon of the latter activated carbon adsorption tower. By preventing the deterioration of the performance of the activated carbon adsorption treatment by the activated carbon adsorption tower. Therefore, the activated carbon adsorption tower can adsorb organic substances such as organic fluorine compounds in the waste water to the activated carbon, propagate on the activated carbon, and efficiently microbially decompose organic substances such as organic fluorine compounds by microorganisms activated by micro-nano bubbles. .

  Moreover, in the waste water treatment apparatus of one Embodiment, it has a return part which returns a part of to-be-processed water discharged | emitted from the said submerged membrane of a said 1st microorganisms tank to a said 1st micro nano bubble generation tank.

  According to the wastewater treatment apparatus of this embodiment, the return unit can add micro / nano bubbles to the treated water by returning the treated water from the first microorganism tank to the first micro / nano bubble generating tank, The treated water can be treated again in the first microorganism tank. Therefore, when the micro-nano bubbles contained in the water to be treated in the first microorganism tank are consumed by the microorganisms and the treatment performance by the microorganisms in the first microorganism tank deteriorates, by operating the return unit, The microbial treatment performance in one microbial tank can be recovered, and the microbial treatment ability of organic wastewater can be improved. Here, the submerged membrane means a membrane installed in the liquid, and various filtration membranes can be adopted as this membrane.

  Moreover, in the waste water treatment apparatus of one Embodiment, it has a return part which returns a part of to-be-processed water of a said 2nd microorganism tank to a said 1st micro nano bubble generation tank.

  According to the wastewater treatment apparatus of this embodiment, when the return unit returns a part of the water to be treated in the second microorganism tank to the first micro / nano bubble generation tank, the micro / nano bubbles can be added to the water to be treated. At the same time, the water to be treated can be treated again in the first and second microorganism tanks. Therefore, in the first and second microbial tanks, when the micro-nano bubbles of the water to be treated are consumed by the microorganisms, and the microbial treatment performance in the first and second microbial tanks is deteriorated, the return unit is operated. Thus, the microbial treatment performance in the first and second microbial tanks can be recovered.

  Moreover, in the waste water treatment apparatus of one embodiment, the first microorganism tank includes a plurality of stages of microorganism treatment units into which waste water from the first micro / nano bubble generation tank is sequentially introduced, and the microorganism treatment unit of the final stage. Has the above-mentioned submerged membrane, and further includes a return unit that returns the microbial sludge from the last-stage microorganism treatment unit to the first-stage microorganism treatment unit.

  According to the wastewater treatment apparatus of this embodiment, the first microorganism tank has a plurality of microorganism treatment units, and the microorganism treatment unit in the final stage can increase the microorganism concentration with the submerged film, and The high-concentration microbial sludge from the microbial treatment section is returned to the first-stage microbial treatment section. As a result, high-concentration microbial sludge containing micro-nano bubbles can be circulated and stirred in a plurality of stages of microbial treatment units, and the microbial treatment ability of organic matter can be significantly improved.

  In one embodiment of the waste water treatment apparatus, the activated carbon adsorption tower has an upper part having a string-type vinylidene chloride packing and a lower part having an activated carbon layer.

  According to the wastewater treatment apparatus of this embodiment, the activated carbon adsorption tower propagates a large amount of microorganisms in the upper string-type vinylidene chloride packing, and after this propagation, the microorganisms are detached from the string-type vinylidene chloride packing. Thus, a large amount of microorganisms can be propagated on the activated carbon in the lower activated carbon layer, which is the next stage, to reliably treat organic substances such as organic fluorine compounds.

  In one embodiment of the waste water treatment apparatus, the activated carbon adsorption tower has an upper part having a ring-type vinylidene chloride packing and a lower part having an activated carbon layer.

  According to the wastewater treatment apparatus of this embodiment, the activated carbon adsorption tower propagates a large amount of microorganisms in the upper ring-type vinylidene chloride packing, and after this propagation, the microorganisms are detached from the ring-type vinylidene chloride packing, A large amount of microorganisms can be propagated on the activated carbon in the lower activated carbon layer, which is the next stage, to reliably treat organic substances such as organic fluorine compounds.

According to the waste water treatment apparatus of the present invention, the waste water is subjected to the three-stage microorganism treatment by the first, second and third microorganism treatment facilities, and the first and second microorganism treatment facilities are classified into the first and second stages. Then, the waste water containing micro-nano bubbles is introduced from the third micro-nano bubble generation tank. Therefore, even if the micro / nano bubbles in the waste water are consumed by the aerobic microorganisms in each microorganism treatment facility, the micro / nano bubbles can be replenished from each micro / nano bubble generation tank to each microorganism treatment facility each time. Therefore, micro-nano bubbles can be effectively used in each microorganism treatment facility, and microorganisms that are propagated in each microorganism treatment facility can be activated. Therefore, according to the present invention, organic matter (for example, an organic fluorine compound) can be efficiently decomposed by microorganisms.

  Hereinafter, the present invention will be described in detail with reference to the illustrated embodiments.

(First embodiment)
FIG. 1 schematically shows a first embodiment of the wastewater treatment apparatus of the present invention. The first embodiment includes a raw water tank 1, a first micro / nano bubble generation tank 3, a first microorganism tank 9, a second micro / nano bubble generation tank 17, a second microorganism treatment tank 23, a rapid filtration tower 31 and a third filtration tank. A micro / nano bubble generation tank 32, an activated carbon adsorption tower 38, and a treated water tank 41 are provided. The first and second microbial tanks 9 constitute first and second microbial treatment facilities, respectively, and the activated carbon adsorption tower 38 constitutes a third microbial treatment facility.

  The raw water tank 1 is introduced with organic fluorine compound-containing organic wastewater as wastewater to be treated. Here, the organic fluorine compound-containing / organic waste water means waste water in which organic fluorine-containing waste water and general organic waste water are mixed. The raw water tank 1 is provided with a raw water tank pump 2A, and the flow rate is adjusted by a valve 2B, which is then introduced into the first micro / nano bubble generating tank 3.

  In the first micro / nano bubble generation tank 3, a micro / nano bubble generator 4 is installed in the tank, and devices related to the micro / nano bubble generator 4 are installed. The micro / nano bubble generator 4 generates a water flow 5 (micro / nano bubble flow) with fine bubbles (micro / nano bubbles) to be discharged. This water flow 5 becomes a circulating water flow in the first micro / nano bubble generation tank 3 and agitates the inside of the tank. The micro / nano bubble generator 4 generates a micro / nano bubble flow, and mixes the organic fluorine compound containing / organic waste water and the micro / nano bubble as water to be treated. The necessary amount of circulating water is supplied to the micro / nano bubble generator 4 by the circulation pump 8, and the necessary air is adjusted by the air suction pipe 7 and the valve 6 and supplied to the micro / nano bubble generator 4. Thereby, the micro / nano bubble generator 4 generates optimal micro / nano bubbles.

  The water to be treated containing the micro / nano bubbles exiting the first micro / nano bubble generation tank 3 is introduced into the lower part of the first microorganism tank 9 at the next stage. The first microorganism tank 9 includes a first microorganism part 53, a second microorganism part 54, a third microorganism part 55, and a fourth microorganism part 56. The first microbial part 53, the second microbial part 54, the third microbial part 55, and the fourth microbial part 56 are each divided by partition walls 10A, 10B, and 10C. In the fourth microorganism part 56, the air lift pump 12, the submerged membrane 14 and the submerged membrane pump 15 which is an accessory thereof are installed. The submerged membrane 14 is a membrane installed in a liquid, and various ultrafiltration membranes can be adopted as the membrane, for example. The air diffuser 13 connected from the blower 16 by piping is an air diffuser for cleaning the submerged film 14 with air.

  Further, in the air lift pump 12, the air from the blower 16 is discharged from the middle of the pipe P1, and a large amount of microbial sludge in the fourth microbial part 56 is moved to the lower part of the first microbial part 53 with less energy. Yes. Therefore, the sludge flow 57 (water flow 11) is generated in the first microbial part 53, the second microbial part 54, the third microbial part 55, and the fourth microbial part 56, and the agitation in the tank of the first microbial tank 9 is possible. It becomes. In the air lift pump 12, air and drainage are bubbled from the pipe P1 and flow through the pipe P2. When this flow reaches the pipe P3, air is discharged from the upper opening P3-1 of the pipe P3, while the waste water flows downward along the pipe P3.

  In addition, since the micronano bubbles are mixed with the water to be treated in the first micro / nano bubble generation tank 3, the aerobic state continues to the fourth microorganism part 56. This eliminates the need for aeration using a combination of a normal blower and an air diffuser, and can achieve significant energy savings.

  In the first microorganism tank 9, most of the organic substances contained in the treated water in the organic fluorine compound-containing / organic waste water and a part of the organic fluorine compound are decomposed by the microorganisms activated by the micro-nano bubbles.

  Next, the water to be treated is introduced from the first microorganism tank 9 to the second micro / nano bubble generation tank 17 through the pipe L1 connected to the submerged membrane pump 15. The second micro / nano bubble generation tank 17 is provided with a micro / nano bubble generator 18 and devices related thereto. A water flow 19 is generated by fine bubbles (micro nano bubbles) discharged from the micro nano bubble generator 18. This water flow 19 becomes a circulating water flow in the second micro / nano bubble generation tank 17 and agitates the inside of the tank. That is, the micro / nano bubble generator 18 generates the micro / nano bubble flow 19 and agitates the water to be treated. Supply of the necessary amount of circulating water to the micro / nano bubble generator 18 is performed by the circulation pump 22, and necessary air is adjusted by the air suction pipe 21 and the valve 20, so that the optimum micro / nano bubbles are generated from the micro / nano bubble generator 18. .

  Next, the water to be treated is introduced from the second micro / nano bubble generation tank 17 to the second microorganism tank 23. The second microorganism tank 23 includes a watering tank 29 as a watering tank part forming the upper part of the water tank, a watering part 48 forming an intermediate part, and a lower immersion part 49. The activated carbon 28 accommodated in the mesh bag 27 installed in the immersion part 49 is always immersed in the water to be treated. On the other hand, the activated carbon 28 accommodated in the net bag 27 installed in the water sprinkling part 48 is not always immersed, and in contact with the water to be treated from the water sprinkling tank 29, the activated water 28 comes into contact with the water to be treated. Yes.

  In both the water sprinkling part 48 and the immersion part 49, the activated carbon 28 accommodated in the mesh bag 27 is filled in a region surrounded by the vertical partition plate 25 and the bottom horizontal porous plate 26.

  Water to be treated at the lower part of the second microorganism tank 23 is transferred to the upper watering tank 29 by the air lift pump 24, and then sprinkled into the watering part 48 under natural flow, and further moved to the immersion part 49. . Air is supplied from the blower 16 to the air lift pump 24.

  In the sprinkling part 48 and the immersion part 49, organic substances such as organic fluorine compounds in the water to be treated are decomposed by microorganisms that have been adsorbed by the activated carbon 28 and then propagated on the activated carbon 28 and activated by the micro-nano bubbles. That is, in the second microorganism tank 23, since the activated carbon 28 is filled in a large amount, the organic fluorine compound in the water to be treated is adsorbed by the activated carbon 28 and then decomposed by the propagated and activated microorganisms.

  And the to-be-processed water containing the organic fluorine compound which remain | survives in this 2nd microorganism tank 23 is connected by the 2nd microorganism pump 30 connected to the piping L5 extended up and down to the lowest part of the 2nd microorganism tank 23. Then, it is sequentially transferred to the rapid filtration tower 31, the third micro / nano bubble generation tank 32, and the activated carbon adsorption tower 38. The rapid filtration tower 31 is filled with coal-based anthracite, and mainly mainly filters suspended substances in the water to be treated.

  The third micro / nano bubble generation tank 32 has a sealed structure, and is installed in the middle of the piping between the rapid filtration tower 31 and the activated carbon adsorption tower 38. If the third micro / nano bubble generation tank 32 is designed to be compact and installed in the middle of the piping, it can be installed in a small space. In the third micro / nano bubble generation tank 32, a micro / nano bubble generator 33 and devices related to the micro / nano bubble generator 33 are installed. The micro / nano bubble generator 33 generates a water flow 34 using fine bubbles (micro / nano bubbles) to be discharged. This water stream 34 becomes a circulating water stream in the third micro / nano bubble generating tank 32 and agitates the inside of the tank. That is, the micro / nano bubble generator 33 generates the micro / nano bubble flow 34 and agitates the water to be treated. Supply of the necessary amount of circulating water to the micro / nano bubble generator 33 is performed by the circulation pump 37, and necessary air is adjusted by the air suction pipe 36 and the valve 35, and optimal micro / nano bubbles are generated from the micro / nano bubble generator 33. .

  Next, the water to be treated containing the micro / nano bubbles in the third micro / nano bubble generation tank 32 is transferred to the activated carbon adsorption tower 38, and most of the organic fluorine compound is adsorbed to the activated carbon in the activated carbon adsorption tower 38. And most of the organic fluorine compounds adsorbed by the microorganisms propagated and activated on the activated carbon will be decomposed.

  Thus, according to the wastewater treatment apparatus of the first embodiment, the first microorganism tank 9, the second microorganism tank 23, and the activated carbon adsorption that constitute the first, second, and third microorganism treatment facilities with respect to the wastewater. The tower 38 performs three-stage microbial treatment, and introduces waste water containing micro-nano bubbles from the first, second, and third micro-nano bubble generation tanks 3, 17, and 32 into each of the three-stage microbial treatment facilities. Therefore, even if the micro / nano bubbles in the waste water are consumed by the aerobic microorganisms in each microorganism treatment facility 9, 23, 38, each micro-nano bubble generation tank 3, 17, 32 can replenish micro-nano bubbles. Therefore, micro-nano bubbles can be effectively used in each microorganism treatment facility 9, 23, 38, and microorganisms proliferating in each microorganism treatment facility 9, 23, 38 can be activated. Therefore, according to the waste water treatment apparatus of this embodiment, the organic waste water containing the organic fluorine compound can be efficiently microbially decomposed.

  Next, the treated water exiting the activated carbon adsorption tower 38 is transferred to the treated water tank 41 with the valve 39 closed and the valve 40 opened when the treatment is sufficient. On the other hand, when the treated water exiting the activated carbon adsorption tower 38 is incomplete, the valve 39 is opened, the valve 40 is closed, and the treated water is returned to the watering tank 29 of the second microorganism tank 23 and processed again. The Alternatively, the water to be treated may be treated while circulating between the second microorganism tank 23 and the activated carbon adsorption tower 38 with the valve 39 half open and the valve 40 half open. The opening and closing and the opening degree of the valves 39 and 40 may be set according to the data of the treated water quality at the outlet of the activated carbon adsorption tower 38 to determine the operation method.

  Here, three types of bubbles will be described.

  (i) Normal bubbles (bubbles) rise in the water and eventually disappear on the surface by popping bread.

  (ii) Microbubbles are fine bubbles having a diameter of 10 (μm) to several tens (μm) or less, shrink in water, and eventually disappear (completely dissolve).

  (iii) Nanobubbles are said to be bubbles that are smaller than microbubbles (100 to 200 nm with a diameter of 1 (μm) or less) and can exist in water forever. Micro-nano bubbles can be described as bubbles in which micro-bubbles and nano-bubbles are mixed.

  In the above embodiment, the wastewater introduced into the raw water tank 1 contains an organic fluorine compound as an organic compound, but the wastewater contains other organic compounds or organic substances such as a volatile organic compound other than the organic fluorine compound. It may be. Moreover, in the said embodiment, although activated carbon 28 was installed in the 2nd microorganism tank 23, charcoal other than activated carbon may be installed. Needless to say, not only the three-stage microorganism treatment facilities 9, 23, and 38, but also the fourth-stage and subsequent microorganism treatment facilities may be installed.

(Second embodiment)
Next, FIG. 2 shows a second embodiment of the waste water treatment apparatus of the present invention. In the second embodiment, the first, second, and third microorganism parts 53, 54, and 55 of the first microorganism tank 9 of FIG. 1 are each filled with a string-like polyvinylidene chloride filler 42 as a filler. Only the difference is from the first embodiment described above. Therefore, in the second embodiment, the same parts as those in the first embodiment described above are denoted by the same reference numerals and detailed description thereof will be omitted, and parts different from those in the first embodiment will be described.

  As shown in FIG. 2, in the second embodiment, a string-like polyvinylidene chloride filler 42 as a filler in the first, second, and third microorganism parts 53E, 54E, and 55E of the first microorganism tank 9E. Filled. A large amount of microorganisms activated by the micro / nano bubbles propagates in the string-like polyvinylidene chloride filling 42. The microorganisms propagated at a high concentration in the string-type polyvinylidene chloride filler 42 as the filler will first decompose the organic matter containing the organic fluorine compound and relatively easily decomposed in the organic waste water.

  Then, the organic fluorine compound contained in the organic wastewater is decomposed by the activated microorganisms in the second microorganism tank 23 and the activated carbon adsorption tower 38 as in the first embodiment. .

(Third embodiment)
Next, FIG. 3 shows a third embodiment of the waste water treatment apparatus of the present invention. This third embodiment differs from the first embodiment described above only in that the third micro / nano bubble generating tank 32 of FIG. 1 is filled with a string-type polyvinylidene chloride filler 43 as a filler. . Therefore, in the third embodiment, the same parts as those in the first embodiment are denoted by the same reference numerals and detailed description thereof is omitted, and parts different from those in the first embodiment will be described.

  As shown in FIG. 3, in the third embodiment, a string-type polyvinylidene chloride filler 43 as a filler is filled in the third micro / nano bubble generating tank 32F. Therefore, in the third embodiment, a large amount of microorganisms activated by the micro / nano bubbles generated in the third micro / nano bubble generation tank 32F propagate in the string-like polyvinylidene chloride filler 43 as a filler.

  Also, some of the microorganisms that have propagated in a high concentration in the string-type polyvinylidene chloride packing 43 as a filler are separated from the string-type polyvinylidene chloride packing 43 and transferred to the activated carbon adsorption tower 38, and activated carbon. The activated carbon in the adsorption tower 38 is also propagated in large quantities.

  It has been found that the organic fluorine compound contained in the water to be treated can be decomposed by microorganisms adsorbed on activated carbon and then activated. Therefore, after a large amount of microorganisms are propagated in the string-like polyvinylidene chloride filling 43 in the third micro / nano bubble generation tank 32F, the microorganisms are naturally separated and the activated microorganisms are moved into the activated carbon adsorption tower 38. . In the activated carbon adsorption tower 38, the organic fluorine compound adsorbed by the activated carbon is surely decomposed by a large amount of activated microorganisms.

(Fourth embodiment)
Next, FIG. 4 shows a fourth embodiment of the waste water treatment apparatus of the present invention. In the fourth embodiment, the pipe L1 connected to the submerged membrane pump 15 connected to the submerged membrane pump 14 of the fourth microbial unit 56 of the first microbial vessel 9 of FIG. Only the point which has the branch pipe L2 which goes to and the branch pipe L3 which goes to the 1st micro nano bubble generation tank 3 differs from the above-mentioned 1st Embodiment. The branch pipe L3 constitutes a return unit. Therefore, in the fourth embodiment, the same parts as those in the first embodiment are denoted by the same reference numerals and detailed description thereof is omitted, and parts different from those in the first embodiment are described.

  As shown in FIG. 4, in the fourth embodiment, the pipe L1 connected to the submerged membrane pump 15 is branched into a branch pipe L2 and a branch pipe L3. Valves 44 and 45 are installed in the branch pipes L2 and L3, respectively. Therefore, in the fourth embodiment, the water to be treated at the outlet of the submerged membrane pump 15 is supplied to the second micro / nano bubble generation tank 17 and the first micro / nano bubble generation tank 3 via the pipe L1 and the branch pipes L2 and L3. It is transported to both.

  Therefore, according to the fourth embodiment, the branch pipe L3 as the return unit returns the water to be treated from the first microorganism tank 9 to the first micro / nano bubble generation tank 3 so that the micro / nano bubbles are added to the water to be treated. At the same time, the water to be treated can be treated again in the first microorganism tank. Therefore, when the micro-nano bubbles contained in the water to be treated in the first microorganism tank 9 are consumed by microorganisms and the treatment performance by microorganisms in the first microorganism tank 9 deteriorates, not only the valve 44 but also the valve 45 is opened. By operating the return unit, the microbial treatment performance in the first microbial tank 9 can be recovered, and the microbial treatment ability of the organic waste water can be improved. Here, the submerged membrane 14 refers to a membrane installed in a liquid, and various ultrafiltration membranes can be adopted as this membrane, for example.

  That is, in this fourth embodiment, when the amount of micro / nano bubbles is insufficient in the first microorganism tank 9 and the treatment efficiency by microorganisms is poor, the object to be treated is between the first micro / nano bubble generation tank 3 and the first microorganism tank 9. Since water can be circulated many times, the performance of microbial treatment can be improved.

(Fifth embodiment)
Next, FIG. 5 shows a fifth embodiment of the waste water treatment apparatus of the present invention. In the fifth embodiment, not only the pipe L7 connected to the rapid filtration tower 31 but also the branch pipe L8 toward the first micro / nano bubble generation tank 3 is connected to the second microorganism tank pump 30 of FIG. However, this is different from the first embodiment. Therefore, in the fifth embodiment, the same parts as those in the first embodiment are denoted by the same reference numerals and detailed description thereof is omitted, and parts different from those in the first embodiment will be described.

  As shown in FIG. 5, in this fifth embodiment, not only the treated water from the second microorganism tank 23 is supplied to the rapid filtration tower 31 via the second microorganism tank pump 30 and the pipe L7, It can return to the 1st 1st micro nano bubble generation tank 3 via piping L8 which makes a return part. A valve 46 is installed in the pipe L7, and a valve 47 is installed in the pipe L8.

  In the fifth embodiment, by returning the water to be treated from the second microorganism tank 23 to the first micro / nano bubble generating tank 3, the micro / nano bubbles can be added to the water to be treated, and at the same time, the water to be treated is first, It can process again in the 2nd microorganism tanks 9 and 23. Therefore, in the first and second microorganism tanks 9 and 23, the micro-nano bubbles in the water to be treated are consumed by microorganisms, and the amount of micro-nano bubbles in the first and second microorganism tanks 9 and 23 is insufficient, so that the microorganism treatment performance is achieved. Can be recovered, the microbial treatment performance in the first and second microbial tanks 9 and 23 can be recovered. Moreover, since the water to be treated is circulated many times between the first micro / nano bubble generation tank 3 and the first and second microorganism tanks 9 and 23, the treatment performance by microorganisms can be improved.

  In the fifth embodiment, both the valve 46 and the valve 47 are opened, and a part of the water to be treated is circulated to the first and second microorganism tanks 9 and 23 through the pipe L8, while the remaining water to be treated is discharged. It can be transferred to the rapid filtration tower 31 through the pipe L7. Here, the opening degree of the valve 46 and the opening degree of the valve 47 may be set according to the operating conditions in the first and second microorganism tanks 9 and 23 and the activated carbon adsorption tower 38.

(Sixth embodiment)
Next, FIG. 6 shows a sixth embodiment of the waste water treatment apparatus of the present invention. The sixth embodiment is a return sludge pump as a return unit that returns the microbial sludge below the fourth microbial unit 56 in the final stage of the first microbial tank 9 of FIG. 1 to the first microbial unit 53 in the first stage. 58. Only the point provided with the return pipe L10 is different from the first embodiment. Therefore, in the sixth embodiment, the same parts as those in the first embodiment described above are denoted by the same reference numerals and detailed description thereof will be omitted, and parts different from those in the first embodiment will be described.

  As shown in FIG. 6, in this sixth embodiment, the microbial sludge below the fourth microbial part 56 of the first microbial tank 9 is returned by the return sludge pump 58 to the first microbial part 53 via the return pipe L10. is doing. Therefore, in the sixth embodiment, the number of circulated high-concentration microbial sludge in the first microbial tank 9 by returning the microbial sludge via the return pipe L10 together with the circulation by the air lift pump 12 described above. Will increase.

  In the circulation by the air lift pump 12 in the first microorganism tank 9, since aerobic by air is maintained, it is convenient for aerobic microorganisms but is not compatible with anaerobic microorganisms. On the other hand, when the first microorganism tank 9 is a deep microorganism tank, many anaerobic microorganisms are generated. The anaerobic microorganisms are returned to the first microorganism section 53 by the return pump 58 and the return pipe L10. Is suitable. By returning by the return pump 58, digestion of sludge and denitrification of nitrogen by anaerobic microorganisms can be expected.

(Seventh embodiment)
Next, FIG. 7 shows a seventh embodiment of the waste water treatment apparatus of the present invention. The seventh embodiment differs from the first embodiment only in that an activated carbon adsorption tower 38G is provided instead of the activated carbon adsorption tower 38 of FIG. Therefore, in the seventh embodiment, the same portions as those in the first embodiment are denoted by the same reference numerals and detailed description thereof is omitted, and portions different from those in the first embodiment are described.

  As shown in FIG. 7, in the seventh embodiment, the activated carbon adsorption tower 38G is filled with a string-type polyvinylidene chloride filler 51 as a filler in the upper part and with an activated carbon layer 50 in the lower part. is doing. Therefore, in this activated carbon adsorption tower 38G, the microorganisms activated by the micro / nano bubbles propagate in a large amount on the string-type polyvinylidene chloride filler 51 as a filler. In addition, microorganisms that have propagated at a high concentration in the string-type polyvinylidene chloride filler 51 as a filler partially peel from the string-type polyvinylidene chloride filler 51 and move to the activated carbon layer 50 to adsorb the activated carbon. The activated carbon layer 50 in the tower 38G also propagates in large quantities.

  Thereby, the activated carbon adsorption tower 38G discovered that organic substances, such as an organic fluorine compound, which adsorb | sucked organic substances, such as an organic fluorine compound which the to-be-processed water contains, to activated carbon, and were activated after that can decompose | disassemble. That is, after a large amount of microorganisms were propagated in the string-type polyvinylidene chloride packing 51 in the activated carbon adsorption tower 38G, the microorganisms were naturally peeled off and the activated microorganisms were moved to the activated carbon layer 50 to adsorb the activated carbon. The organic fluorine compound is reliably decomposed.

(Eighth embodiment)
Next, FIG. 8 shows an eighth embodiment of the waste water treatment apparatus of the present invention. The eighth embodiment differs from the first embodiment only in that an activated carbon adsorption tower 38H is provided instead of the activated carbon adsorption tower 38 of FIG. Therefore, in the eighth embodiment, the same parts as those in the first embodiment are denoted by the same reference numerals and detailed description thereof is omitted, and parts different from those in the first embodiment will be described.

  As shown in FIG. 8, in this eighth embodiment, the activated carbon adsorption tower 38H is filled with a ring-type polyvinylidene chloride filling 52 as a filler in the upper part of the inside and with an activated carbon layer 50 in the lower part of the inside. ing. Therefore, in this activated carbon adsorption tower 38H, microorganisms activated by the micro / nano bubbles propagate in a large amount in the ring-type polyvinylidene chloride packing 52 as a filler. Further, a part of the microorganisms propagated in a high concentration in the ring-type polyvinylidene chloride packing 52 as a packing material are detached from the ring-type polyvinylidene chloride packing 52 and transferred to the activated carbon layer 50, and the activated carbon adsorption tower 38H. A large amount of the activated carbon layer 50 is also propagated.

  Thereby, the activated carbon adsorption tower 38H discovered that organic substances, such as an organic fluorine compound, which adsorb | sucked organic substances, such as an organic fluorine compound which the to-be-processed water contains, to activated carbon, and were activated after that can decompose | disassemble. That is, after a large amount of microorganisms are propagated in the ring-type polyvinylidene chloride packing 52 in the activated carbon adsorption tower 38H, the microorganisms are naturally separated and the activated microorganisms are moved to the activated carbon layer 50 to adsorb the activated carbon. The fluorine compound is reliably decomposed.

(Experimental example)
An experimental apparatus corresponding to the waste water treatment apparatus of the first embodiment shown in FIG. 1 was manufactured. In this experimental apparatus, the capacity of the raw water tank 1 is about 5 m ³ , the capacity of the first micro-nano bubble generation tank 3 is about 1 m ³ , the capacity of the first microorganism tank 9 is about 20 m ^3, and the second micro-nano bubble generation tank The capacity of 17 was about 1 m ³ and the capacity of the second microorganism tank 23 was about 10 m ³ . The capacity of the rapid filtration tower 31 was 1 m ³ , the capacity of the third micro / nano bubble generation tank 32 was about 1 m ^3, and the capacity of the activated carbon adsorption tower 38 was 3 m ³ . A test run was conducted for about two months after introducing organic fluorine compound-containing organic wastewater into this experimental apparatus.

  After this test run, the concentration of PFOS (perfluorooctane sulfonic acid) in the waste water at the inlet to the raw water tank 1 and the concentration of PFOS (perfluorooctane sulfonic acid) in the treated water at the outlet of the activated carbon adsorption tower 38 are measured. The removal rate of PFOS was measured and found to be 98%.

It is a figure which shows typically 1st Embodiment of the waste water treatment equipment of this invention. It is a figure which shows typically 2nd Embodiment of the waste water treatment equipment of this invention. It is a figure which shows typically 3rd Embodiment of the waste water treatment equipment of this invention. It is a figure which shows typically 4th Embodiment of the waste water treatment equipment of this invention. It is a figure which shows typically 5th Embodiment of the waste water treatment equipment of this invention. It is a figure which shows typically 6th Embodiment of the waste water treatment equipment of this invention. It is a figure which shows typically 7th Embodiment of the waste water treatment equipment of this invention. It is a figure which shows typically 8th Embodiment of the waste water treatment equipment of this invention.

DESCRIPTION OF SYMBOLS 1 Raw water tank 2 Raw water tank pump 3 1st micro nano bubble generation tank 4 Micro nano bubble generator 5 Water flow 6 Valve 7 Air suction pipe 8 Circulation pump 9, 9E 1st microorganism tank 10A-10C Partition wall 11 Water flow 12 Air lift pump 13 Scattering Trachea 14 Submerged membrane 15 Submerged membrane pump 16 Blower 17 Second micro / nano bubble generation tank 18 Micro / nano bubble generator 19 Water flow 20 Valve 21 Air suction pipe 22 Circulation pump 23 Second microorganism tank 24 Air lift pump 25 Partition plate 26 Porous plate 27 Net bag 28 Activated carbon 29 Sprinkling tank 30 Second microorganism tank pump 31 Rapid filtration tower 32, 32F Third micro / nano bubble generation tank 33 Micro / nano bubble generator 34 Water flow 35 Valve 36 Air suction pipe 37 Circulation pump
38, 38G, 38H Activated carbon adsorption tower 39 Valve 40 Valve 41 Treated water tank 42 String-type polyvinylidene chloride filler 43 String-type polyvinylidene chloride filler 44-47 Valve 48 Sprinkling part 49 Immersion part 50 Activated carbon layer
51 String-type polyvinylidene chloride filler 52 Ring-type polyvinylidene chloride filler 53, 53E First microorganism part 54, 54E Second microorganism part 55, 55E Third microorganism part
56 4th microorganism part 57 Sludge flow 58 Return sludge pump

Claims (9)

A first micro / nano bubble generating tank in which the waste water is introduced and the waste water contains micro / nano bubbles;
A first microbial treatment facility for microbially treating the wastewater containing micro-nano bubbles while introducing waste water containing micro-nano bubbles from the first micro-nano bubble generation tank;
A second micro / nano bubble generating tank in which the waste water from the first microorganism treatment facility is introduced and the waste water contains micro / nano bubbles;
A second microbial treatment facility for microbially treating the wastewater containing the micro-nano bubbles while the waste water containing the micro-nano bubbles is introduced from the second micro-nano bubble generation tank;
A third micro / nano bubble generating tank in which the waste water from the second microbial treatment facility is introduced and the waste water contains micro / nano bubbles;
A wastewater containing micro-nano bubbles is introduced from the third micro-nano bubble generating tank, and a third microorganism treatment facility for microbial treatment of the waste water containing the micro-nano bubbles,
The first microbial treatment facility is a first microbial tank having an air lift pump that stirs and circulates waste water in the tank.
The second microorganism treatment facility is a second microorganism tank having an air lift pump for stirring and circulating the waste water in the tank,
The waste water treatment apparatus, wherein the third microorganism treatment facility is an activated carbon adsorption tower. The waste water treatment apparatus according to claim 1 ,
The first microorganism tank is
A wastewater treatment apparatus having a submerged membrane for solid-liquid separation of water to be treated and microorganisms. The waste water treatment apparatus according to claim 1 ,
The second microorganism tank is
The water to be treated in the tank is introduced from the air lift pump and the water sprinkling tank for sprinkling the water to be treated downward,
The water to be treated is sprinkled by the sprinkling tank part and the sprinkling part having activated carbon,
A wastewater treatment apparatus comprising: an immersion unit that is disposed below the watering unit and into which the water to be treated that has passed through the watering unit is introduced and has activated carbon that is immersed in the water to be treated. The waste water treatment apparatus according to claim 1 ,
A wastewater treatment apparatus comprising a rapid filtration tower installed after the second microorganism treatment facility and before the third micro / nano bubble generation tank. The waste water treatment apparatus according to claim 2 ,
A wastewater treatment apparatus comprising a return unit that returns a part of the water to be treated discharged from the submerged membrane of the first microorganism tank to the first micro / nano bubble generation tank. The waste water treatment apparatus according to claim 1 ,
A wastewater treatment apparatus comprising a return section for returning a part of water to be treated in the second microorganism tank to the first micro / nano bubble generation tank. The waste water treatment apparatus according to claim 2 ,
The first microorganism tank is
Comprising a plurality of stages of microorganism treatment units into which waste water from the first micro / nano bubble generation tank is sequentially introduced,
The final stage microbial treatment part has the above-mentioned submerged membrane,
Furthermore, the waste water treatment apparatus provided with the return part which returns microbial sludge from the said microorganisms processing part of the last stage to the microorganisms processing part of the 1st stage. The waste water treatment apparatus according to claim 1 ,
The activated carbon adsorption tower is
An upper portion having a string-like vinylidene chloride filling;
A wastewater treatment apparatus comprising a lower part having an activated carbon layer. The waste water treatment apparatus according to claim 1 ,
The activated carbon adsorption tower is
A top having a ring-type vinylidene chloride filling;
A wastewater treatment apparatus comprising a lower part having an activated carbon layer.

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