JP2008178792A - Biological reaction method and biological reaction apparatus - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a biological reaction apparatus which can execute microbiological treatment without agitation by a blower, achieve energy saving, and improve biological reaction efficiency by increasing water temperature in winter and producing and utilizing a large amount of various bubbles. <P>SOLUTION: In a bubble-mixing microorganism adhesion tank 40, micro-nano bubbles generated from a micro-nano bubble generator 6, nano bubbles generated from a nano bubble generator 36, microorganisms, and raw wastewater 1 are mixed to make mixed water. In a biological reaction tank 10, the mixed water supplied from the bubble-mixing microorganism adhesion tank 40 is made to flow into a passage, and subjected to biological reaction to make treated water. In a measurement tank 19, the water temperature and quality of the treated water supplied from the biological reaction tank 10 are measured. A water quality controller 28 and a water temperature controller 29 control the operation of the micro-nano bubble generator 6 and the nano bubble generator 36 from the water temperature and quality of the treated water measured in the measurement tank 19. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a biological reaction method and a biological reaction apparatus.

  Conventionally, there are many biological reactors, such as aeration tanks in wastewater treatment and contact oxidation tanks in wastewater reuse facilities, but the agitation power for agitation in the tank is large and energy-saving measures for biological reactors It was a situation that could not be implemented.

  Moreover, the water temperature in the biological reaction apparatus was in a situation where a decrease in the biological reaction efficiency was inevitable when the water temperature decreased in winter.

  Moreover, there existed a fault that the biological reaction rate peculiar to a biological reaction was slow and that the effect of the biological reaction was not clear because the microorganisms were not activated.

  In addition, there has been a biological reaction apparatus using micro-nano bubbles. However, there has not been a biological reaction apparatus that exerts a remarkable bioactive effect on bacteria (also called bacteria) having a particularly small size among microorganisms in biological reactions.

  In short, the biological reaction that can improve the biological reaction efficiency by making it possible to process microorganisms without stirring by a blower, saving energy, raising the water temperature in winter, and producing and using various bubbles in large quantities. The device was not present.

  Here, as a conventional method and apparatus using nanobubbles, there is one described in Japanese Patent Application Laid-Open No. 2004-121962 (Patent Document 1).

  This device and method take advantage of the characteristics of nanobubbles such as reduced buoyancy, increased surface area, increased surface activity, generation of local high-pressure fields, and interfacial activity and bactericidal action by realizing electrostatic polarization. . More specifically, by correlating them with each other, it is possible to realize a high-performance and low-environmental load cleaning of various objects by a dirt component adsorption function, an object surface high-speed cleaning function, and a sterilization function. It discloses that water purification can be performed.

  Conventionally, as a method for generating nanobubbles, there is one described in Japanese Patent Application Laid-Open No. 2003-334548 (Patent Document 2). This method includes a step of decomposing and gasifying a part of the liquid in the liquid, a step of applying ultrasonic waves in the liquid, or a step of decomposing and gasifying part of the liquid and applying ultrasonic waves. Has been.

  Conventionally, as an apparatus for treating waste liquid using ozone microbubbles, there is one described in Japanese Patent Application Laid-Open No. 2004-321959 (Patent Document 3).

  This processing apparatus supplies the microbubble generator with ozone gas generated from the ozone generator and the waste liquid extracted from the lower part of the processing tank via a pressure pump. Further, the generated ozone microbubbles are ventilated into the waste liquid in the treatment tank through the opening of the gas blowing pipe.

However, even with reference to the above three existing technologies, it is difficult to realize a biological reaction apparatus that can save energy and improve the biological reaction efficiency.
JP 2004-121962 A JP 2003-334548 A JP 2004-321959 A

  Therefore, an object of the present invention is to enable microbial treatment even without stirring by a blower and to save energy, to increase the water temperature in winter, to produce and use a large amount of various bubbles, An object of the present invention is to provide a bioreactor capable of improving efficiency.

In order to solve the above problems, the biological reaction method of the present invention comprises:
One or both of the micro-nano bubbles generated from the micro-nano bubble generator and the nano bubbles generated from the nano-bubble generator, the microorganisms, and the water to be treated are mixed in a bubble-mixing microorganism adhesion tank to create mixed water. Process,
Passing the mixed water supplied from the bubble-mixed microorganism adhesion tank to the biological reaction tank through the flow path of the biological reaction tank, and biologically reacting the mixed water to create treated water;
Measuring the temperature and quality of the treated water supplied from the biological reaction tank to the measurement tank;
And a step of controlling the operation of the micro-nano bubble generator and the nano-bubble generator by a control unit based on the temperature and quality of the treated water measured in the measurement tank.

  Here, the micro-nano bubble refers to a bubble having a diameter of about 10 μm to several hundred nm. The said nano bubble means the bubble which has a diameter of several hundred nm or less. The nanobubbles are in a high temperature and high pressure state when the nanobubbles are formed, and generate heat. The nanobubbles are more excellent in activating microorganisms than micronano bubbles.

  According to the biological reaction method of the present invention, the step of creating the mixed water, the step of creating the treated water, the step of measuring the temperature and quality of the treated water, the micro-nano bubble generator, and the generation of nano bubbles Therefore, the present invention has the following effects (i) to (iv).

  In the characteristic point (i), a large amount of electric energy has been consumed in the aeration for the purpose of stirring in the biological reaction tank, but the nanobubbles, the micronanobubbles, the water to be treated, and the microorganisms are mixed, By passing it through the flow path of the reaction tank, the above-mentioned nanobubbles or the above-mentioned micro-nanobubbles adhere to the above-mentioned microorganisms, the above-mentioned microorganisms are activated, and the microorganism treatment is possible even without stirring by a blower.

  In the characteristic point (ii), the heat generated when the nanobubbles are formed is utilized to raise the water temperature of the biological reaction tank in the winter and stabilize the quality of the treated water.

  In the characteristic point (iii), the operation of the micro / nano bubble generator and the nano bubble generator can be controlled according to the water temperature and water quality of the treated water, so that the rational operating conditions can be set according to the water temperature and water quality.

  In feature (iv), by using two types of generators, the micro-nano bubble generator and the nano-bubble generator, and producing and using a large amount of various bubbles as required, various microorganisms (large protozoa) And is effective for the activation of small bacteria).

  Therefore, the microorganism treatment can be performed without the stirring by the blower, energy saving can be achieved, the water temperature in winter can be increased, and various bubbles can be produced and used in large quantities, thereby improving the biological reaction efficiency.

Moreover, the biological reaction apparatus of the present invention is
A micro-nano bubble generator for generating micro-nano bubbles;
A nanobubble generator for generating nanobubbles;
A bubble-mixing microorganism adhesion tank that creates a mixed water by mixing one or both of the micro-nano bubbles generated from the micro-nano bubble generator and the nano bubbles generated from the nano-bubble generator, a microorganism, and water to be treated. When,
A biological reaction tank for producing treated water by passing the mixed water supplied from the bubble-mixed microorganism adhesion tank through a flow path and biologically reacting the mixed water;
A measuring tank for measuring the temperature and quality of the treated water supplied from the biological reaction tank;
The micro-nano bubble generator and a control unit for controlling the operation of the nano-bubble generator based on the temperature and quality of the treated water measured in the measurement tank.

  Here, the micro-nano bubble refers to a bubble having a diameter of about 10 μm to several hundred nm. The said nano bubble means the bubble which has a diameter of several hundred nm or less. The nanobubbles are in a high temperature and high pressure state when the nanobubbles are formed, and generate heat. The nanobubbles are more excellent in activating microorganisms than micronano bubbles.

  According to the biological reaction device of the present invention, since the micro-nano bubble generator, the nano-bubble generator, the bubble-mixed microorganism adhesion tank, the biological reaction tank, the measurement tank, and the control unit, The following features (i) to (iv) are obtained.

  In the characteristic point (i), a large amount of electric energy has been consumed in the aeration for the purpose of stirring in the biological reaction tank, but the nanobubbles, the micronanobubbles, the water to be treated, and the microorganisms are mixed, By passing it through the flow path of the reaction tank, the above-mentioned nanobubbles or the above-mentioned micro-nanobubbles adhere to the above-mentioned microorganisms, the above-mentioned microorganisms are activated, and the microorganism treatment is possible even without stirring by a blower.

  In the characteristic point (ii), the heat generated when the nanobubbles are formed is utilized to raise the water temperature of the biological reaction tank in the winter and stabilize the quality of the treated water.

  In the characteristic point (iii), the operation of the micro / nano bubble generator and the nano bubble generator can be controlled according to the water temperature and water quality of the treated water, so that the rational operating conditions can be set according to the water temperature and water quality.

  In feature (iv), by using two types of generators, the micro-nano bubble generator and the nano-bubble generator, and producing and using a large amount of various bubbles as required, various microorganisms (large protozoa) And is effective for the activation of small bacteria).

  Therefore, the microorganism treatment can be performed without the stirring by the blower, energy saving can be achieved, the water temperature in winter can be increased, and various bubbles can be produced and used in large quantities, thereby improving the biological reaction efficiency.

  Moreover, in the biological reaction apparatus of one Embodiment, the said nano bubble generator has a pump with a head of 40 m or more.

  According to the biological reaction device of this embodiment, the nanobubble generator has a pump with a head of 40 m or more, and therefore can efficiently generate nanobubbles.

  Moreover, in the biological reaction apparatus of one Embodiment, the said micro nano bubble generator has a pump with a head of 15 m or more.

  According to the bioreactor of this embodiment, the micro / nano bubble generator has a pump with a head of 15 m or more, and therefore can efficiently generate micro / nano bubbles.

In one embodiment of the biological reaction device,
A raw water tank to which the treated water is supplied;
The micro / nano bubble generator containing the micro / nano bubble generator and containing the micro / nano bubbles in the water to be treated supplied from the raw water tank and supplying the bubble mixed microorganism adhesion tank,
The nanobubble generator is accommodated, and has a nanobubble generator tank containing nanobubbles in the treated water supplied from the biological reaction tank and supplying it to the bubble mixed microorganism adhesion tank.

  According to the biological reaction apparatus of this embodiment, since the raw water tank, the micro-nano bubble generation tank, and the nano-bubble generation tank are included, the micro-nano bubbles and the nano bubbles can be reliably generated.

  Moreover, in the biological reaction apparatus of one Embodiment, it has the sludge return pump which returns the sludge of the most downstream part of the flow path of the said biological reaction tank to the said bubble mixing microorganism adhesion tank.

  According to the biological reaction apparatus of this embodiment, since the sludge in the most downstream part of the flow path of the biological reaction tank has the sludge return pump that returns the sludge to the bubble mixed microorganism adhesion tank, the microorganisms contained in the sludge Can be returned to the bubble mixed microorganism adhesion tank, the microorganism can be activated, and the biological reaction efficiency can be improved.

In one embodiment of the biological reaction device,
The nano bubble generator is
A gas-liquid mixing circulation pump having a microbubble generating unit;
A valve connected to the microbubble generator and adjusting the flow rate of air to the microbubble generator;
A gas shearing unit that is connected to the downstream side of the gas-liquid mixing circulation pump and shears microbubbles generated from the gas-liquid mixing circulation pump into nanobubbles.

  Here, the microbubble refers to a bubble having a diameter of 10 μm to several tens of μm.

  According to the biological reaction device of this embodiment, the nanobubble generator is connected to the gas-liquid mixing circulation pump having a microbubble generating unit and the microbubble generating unit to control the flow rate of air to the microbubble generating unit. The gas-liquid mixing circulation pump has a valve to be adjusted and a gas shearing part that is connected to the downstream side of the gas-liquid mixing circulation pump and shears microbubbles generated from the gas-liquid mixing circulation pump into nanobubbles. , Producing a microbubble, and then introducing the microbubble into the gas shearing part to produce nanobubbles in the gas shearing part, and the valve is used to supply the microbubble generating part. Since the amount of air can be accurately controlled, nanobubbles can be accurately and stably manufactured.

  In one embodiment, the flow path of the biological reaction tank is a meandering flow path formed so as to alternately pass through a shallow portion and a deep portion at least once.

  According to the bioreaction apparatus of this embodiment, the flow path of the biological reaction tank is a meandering flow path formed so as to alternately pass through the shallow part and the deep part at least once. In addition, the moving distance of the mixed water becomes long, and at the same time, the contact between the microbial sludge and the water to be treated increases, so that sufficient stirring can be performed.

  Moreover, in the biological reaction apparatus of one Embodiment, the deep part of the water depth of the flow path of the said biological reaction tank has a depth of 10 m or more.

  According to the biological reaction apparatus of this embodiment, the deep part of the flow path of the biological reaction tank has a depth of 10 m or more. Therefore, in the deep part, the bubble size is further reduced by the water pressure. Therefore, it becomes easy to adhere to microbial sludge. As a result, the biological reaction process can be performed efficiently.

  Moreover, in the biological reaction apparatus of one Embodiment, at least one of a total organic carbon meter and a chemical oxygen demand meter is used for the measurement of the quality of the said treated water in the said measurement tank.

  According to the biological reaction apparatus of this embodiment, since at least one of the total organic carbon meter and the chemical oxygen demand meter is used for measuring the quality of the treated water in the measurement tank, the organic matter in the treated water is used. The concentration can be accurately measured, and it can be determined whether or not the treated water can be reliably treated.

  In one embodiment, the nanobubble generator is a gas-liquid mixed gas shearing nanobubble generator.

  According to the bioreaction apparatus of this embodiment, the nanobubble generator is a gas-liquid mixed gas shearing type nanobubble generator, so that after mixing the gas and the liquid, the gas is sheared. It can occur in large quantities.

  In one embodiment, the micro / nano bubble generator is a submersible pump type micro / nano bubble generator or a swirl type micro / nano bubble generator.

  According to the bioreaction apparatus of this embodiment, the micro / nano bubble generator is an underwater pump type micro / nano bubble generator or a swirling flow type micro / nano bubble generator, so that an existing generator can be easily secured. Moreover, two types of generators can be selectively used, and can be freely selected according to the purpose, and an optimum system suitable for the purpose can be configured.

  Moreover, in the biological reaction apparatus of one Embodiment, the said to-be-processed water is any one of waste water raw water, waste water treated water, water for use, surfactant containing waste water, and culture medium containing water.

  According to the biological reaction apparatus of this embodiment, the treated water is any one of raw waste water, waste water treated water, irrigation water, surfactant-containing waste water, and medium-containing water, and thus has wide application. The processing effect in each direction can be expected.

  In one embodiment of the biological reaction apparatus, the water to be treated is a hydroponic liquid after hydroponics of a plant intended for circulation use, aquaculture water after aquaculture, aquaculture water from a fish farming facility, and Any one of the exhibition circulation water from the aquarium facility.

  According to the biological reaction apparatus of this embodiment, the treated water is a hydroponic liquid after hydroponics of a plant intended for circulation use, aquaculture water after aquaculture, reclaimed water from a fish farming facility, and Since it is any one of the exhibition circulating water from the aquarium facility, the treated water is treated as circulating water to improve the water quality, and at the same time, there is a water saving effect by circulation use.

  According to the biological reaction method of the present invention, the step of creating the mixed water, the step of creating the treated water, the step of measuring the temperature and quality of the treated water, the micro-nano bubble generator, and the generation of nano bubbles A process that controls the operation of the machine, so that microbial treatment can be achieved even without stirring by a blower, energy saving can be achieved, water temperature in winter can be raised, and various bubbles can be produced and used in large quantities. Thus, the biological reaction efficiency can be improved.

  According to the biological reaction device of the present invention, since the micro-nano bubble generator, the nano-bubble generator, the bubble-mixed microorganism adhesion tank, the biological reaction tank, the measurement tank, and the control unit, Microbial treatment is possible even without stirring by a blower, energy saving can be achieved, the water temperature in winter can be raised, and various bubbles can be produced and used in large quantities to improve biological reaction efficiency.

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

(First embodiment)
FIG. 1 is a diagram schematically showing a first embodiment of the biological reaction apparatus of the present invention. The biological reaction apparatus of the present invention is a raw water tank 2, a micro / nano bubble generation tank 4, a bubble mixed microorganism adhesion tank 40, a biological reaction tank 10, and a measurement tank 19 to which raw wastewater 1 as treated water is sent in order. And have.

  A nanobubble generation tank 22 is connected to the downstream side of the biological reaction tank 10, and the bubble mixed microorganism adhesion tank 40 is connected to the downstream side of the nanobubble generation tank 22. A next process processing device 21 is connected to the downstream side of the measuring tank 19.

  The raw water tank 2 is supplied with the waste water raw water 1. The micro / nano bubble generation tank 4 accommodates a micro / nano bubble generator 6 that generates micro / nano bubbles. In the micro / nano bubble generation tank 4, the waste water raw water 1 supplied from the raw water tank 2 by the raw water tank pump 3 contains micro / nano bubbles and supplies it to the bubble mixed microorganism adhesion tank 40.

  The nanobubble generator 22 accommodates a nanobubble generator 36 that generates nanobubbles. In the nanobubble generation tank 22, nanobubbles are contained in the treated water supplied from the biological reaction tank 10 and supplied to the bubble mixed microorganism adhesion tank 40.

  In the bubble-mixing microorganism adhesion tank 40, one or both of the micro-nano bubbles generated from the micro-nano bubble generator 6 and the nano bubbles generated from the nano-bubble generator 36, the microorganisms, and the raw waste water 1 are mixed. To make mixed water.

  In the biological reaction tank 10, the mixed water supplied from the bubble mixed microorganism adhesion tank 40 is passed through a flow path, and the mixed water is biologically reacted to prepare treated water.

  In the measurement tank 19, the temperature and quality of the treated water supplied from the biological reaction tank 10 are measured. A control unit is provided for controlling the operation of the micro-nano bubble generator 6 and the nano-bubble generator 36 based on the temperature and quality of the treated water measured in the measurement tank 19.

  That is, the measurement tank 19 is provided with a water quality detector 20 for detecting the quality of the treated water and a water temperature detector 30 for detecting the temperature of the treated water. The control unit includes a water quality controller 28 connected to the water quality meter detection unit 20 via a signal line 9, and a water temperature controller 29 connected to the water quality meter detection unit 20 via a signal line 9. . As the water quality controller 28, at least one of a total organic carbon meter and a chemical oxygen demand meter is used.

  Here, the micro-nano bubble refers to a bubble having a diameter of about 10 μm to several hundred nm. The said nano bubble means the bubble which has a diameter of several hundred nm or less. The nanobubbles are in a high temperature and high pressure state when the nanobubbles are formed, and generate heat. The nanobubbles are more excellent in activating microorganisms than micronano bubbles. Microbubbles refer to bubbles having a diameter of 10 μm to several tens of μm. Normal bubbles (bubbles) rise in the water and eventually disappear on the surface by popping bread.

  The nano bubble generator 36 is a gas-liquid mixed gas shear type nano bubble generator. Examples of nanobubble generators include products manufactured by Kyowa Kikai Co., Ltd.

  The nano-bubble generator 36 is connected to the gas-liquid mixing / circulation pump 24 having the micro-bubble generator 25 and the micro-bubble generator 25 via an air pipe 26 to reduce the flow rate of air to the micro-bubble generator 25. A valve 32 to be adjusted, and a gas shearing portion 27 that is connected to the downstream side of the gas-liquid mixing circulation pump 24 and shears microbubbles generated from the gas-liquid mixing circulation pump 24 into nanobubbles.

  The gas-liquid mixing circulation pump 24 is connected to the water quality controller 28 and the water temperature controller 29 via a signal line 9. As the gas-liquid mixing and circulating pump 24, for example, a pump having a lift of 40 m or more (preferably a lift of 60 m or more) is used.

  As the micro-nano bubble generator 6, an underwater pump type micro-nano bubble generator is used. As an underwater pump type micro / nano bubble generator, for example, there is a product of Nomura Electronics Co., Ltd.

  The micro / nano bubble generator 6 is connected to the water quality controller 28 and the water temperature controller 29 via a signal line 9. The micro / nano bubble generator 6 has a pump with a lift of 15 m or more. The micro / nano bubble generator 6 may be a swirl type micro / nano bubble generator.

  A blower 8 is connected to the micro / nano bubble generator 6 by an air pipe 7. The blower 8 is connected to the water quality controller 28 and the water temperature controller 29 via a signal line 9.

  The flow path of the biological reaction tank 10 is a serpentine flow path formed so as to alternately pass through a shallow portion and a deep portion at least once. The biological reaction tank 10 is a so-called vertical channel tank. The deep part of the flow path of the biological reaction tank 10 has a depth of 10 m or more.

  More specifically, the meandering flow path is composed of seven small water tanks formed by dividing the biological reaction tank 10 by six partition plates 12. Then, the mixed water naturally flows sequentially from the upper part (the shallow part of the water depth) to the lower part (the deep part of the water depth) in the seven small water tanks, passes through the entire biological reaction tank 10, and reaches the downstream side. It is configured to reach the aquarium.

  A sludge return pump 37 is installed in the most downstream part of the flow path of the biological reaction tank 10, and the sludge return pump 37 causes the sludge in the most downstream part of the flow path to the bubble mixed microorganism adhesion tank 40. Will be returned.

  A submerged membrane 16 is installed at the most downstream portion of the flow path of the biological reaction tank 10, and the submerged membrane pump 16 includes a first submerged membrane pump 17 and a second submerged membrane pump 18, respectively. ,It is connected. Here, the submerged film 16 is a film present in the liquid.

  The first submerged membrane pump 17 secures the treated water by solid-liquid separation and introduces it into the measurement tank 19.

  The operation of the second submerged membrane pump 18 is controlled by the water quality controller 28 and the water temperature controller 29 via the signal line 9. On the other hand, the second submerged membrane pump 18 secures the treated water by solid-liquid separation and introduces it into the nanobubble generation tank 22. The treated water introduced into the nanobubble generation tank 22 contains nanobubbles by the nanobubble generator 36 and is again introduced into the bubble mixed microorganism adhesion tank 40.

  An air diffuser 13 is installed at the most downstream portion of the flow path of the biological reaction tank 10, and the air diffuser 13 is connected to the blower 14 by piping. The bubbles 15 discharged from the air diffuser 13 wash the submerged film 16 with air.

  Next, use of the biological reaction apparatus having the above configuration will be described.

  First, each operation condition of the submersible pump type micro nano bubble generator 6 and the nano bubble generator 36 will be described.

  The signals of the water quality meter detection unit 20 and the water temperature meter detection unit 30 are received and converted by the water quality controller 28 and the water temperature controller 29, and the converted signals are sent to the submersible pump type micro-nano bubble generator 6 and the nano bubble generator 36. Transmit and control their operation.

  The operating conditions of the submersible pump type micro / nano bubble generator 6 and the nano bubble generator 36 are as follows.

The relationship with water quality is as follows (a) to (d).
(a) When the water quality deteriorates, operate both the nanobubble generator 36 and the submerged pump type micro / nanobubble generator 6 (especially using the activation of bacteria that affect the biological reaction by nanobubbles)
(b) When the water quality is slightly better than the target water quality, the submersible pump type micro / nano bubble generator 6 is operated.
(c) When the water quality is slightly worse than the target water quality, the nanobubble generator 36 is operated.
(d) When the water quality is considerably better than the target water quality, both the nano bubble generator 36 and the submersible pump type micro nano bubble generator 6 are stopped.

The relationship with the water temperature is as follows (e) to (g).
(e) When the water temperature is lower than the target water temperature, the nanobubble generator 36 is operated (using heat generated when the nanobubbles are formed).
(f) When the water temperature is higher than the target water temperature, the submersible pump type micro / nano bubble generator 6 is operated.
(g) When the water temperature is higher than the target water temperature and the water quality is considerably good, both the nano bubble generator 36 and the submersible pump micro nano bubble generator 6 are stopped.

  Then, the raw waste water 1 is introduced into the raw water tank 2 and introduced into the micro / nano bubble generation tank 4 by the raw water tank pump 3.

  The conditions under which the submersible pump type micro / nano bubble generator 6 is operated under the above conditions in the measurement tank 19 are (a) when the water quality deteriorates, (b) when the water quality is slightly better than the target water quality, and (f) the water temperature. Is higher than the target water quality.

  On the other hand, the conditions under which the nanobubble generator 36 is operated are (a) when the water quality is deteriorated, (c) when the water quality is somewhat worse than the target water quality, and (e) when the water temperature is lower than the target water temperature.

  In the submersible pump type micro / nano bubble generator 6, air necessary for generating the micro / nano bubbles is used by taking in air generated by the blower 8 through the air pipe 7. When micro-nano bubbles are generated, a micro-nano bubble water flow 5 is generated.

  Depending on the condition of the treated water in the measurement tank 19, that is, (g) when the water temperature is higher than the target water temperature and the water quality is considerably good, the submersible pump type micro / nano bubble generator 6 is stopped.

  Next, the water to be treated that has exited the micro / nano bubble generation tank 4 is introduced into the bubble mixed microorganism adhesion tank 40 by overflow. Nanobubble water generated in the nanobubble generation tank 22 may be introduced into the bubble mixed microorganism adhesion tank 40.

  In the measurement tank 19, the condition of treated water, that is, (a) when the water quality deteriorates, (c) when the water quality is slightly worse than the target water quality, (e) when the water temperature is lower than the target water temperature, nanobubbles Water is introduced.

  Nanobubble water is generated from the nanobubble generator 36 and introduced into the bubble-mixed microorganism adhesion tank 40.

  Nanobubbles have biological activity especially against small bacteria among microorganisms and generate heat when forming nanobubbles. Therefore, when the conditions are necessary, the nanobubbles are automatically sent to the bubble-mixing microorganism adhesion tank 40. Introduced under control.

  Therefore, when (a) the water quality in the measurement tank 19 deteriorates, (c) when the water quality is somewhat worse than the target water quality, (e) when the water temperature is lower than the target water temperature, nanobubble water is introduced.

  The mechanism of nanobubble generation in the nanobubble generator 36 is implemented in the following first step and second step.

  As the first step, the microbubble generator 25 controls the pressure hydrodynamically, sucks gas from the negative pressure forming portion, moves the fluid at high speed, forms the negative pressure portion, generate. To make it easier to understand, the microbubble cloudy water is produced by effectively self-mixing and dissolving water and air and pumping them.

  As a second step, in the gas shearing portion 27, high-speed fluid motion is performed to form a negative pressure portion, microbubbles are generated, introduced into the gas shearing portion 27 through a water pipe, and sheared as fluid motion. To generate nanobubbles from microbubbles.

  Here, when nanobubbles are generated from microbubbles, heat is generated, and the mechanism will be described.

  When the microbubble water generated by the gas-liquid mixing / circulation pump 24 having the microbubble generating unit 25 is pumped to the gas shearing unit 27 through a water pipe under high pressure, the gas shearing unit 27 performs high-speed fluid motion. By shearing, nanobubbles are generated from microbubbles, and at the same time, an ultra-high temperature limit reaction field is formed. That is, when generating nanobubbles from microbubbles using a high-lift pump, heat is generated by forming free radicals from an ultra-high temperature extreme reaction field. This heat is the mechanism by which heat is generated by the nanobubble generator.

  Further, nanobubble formation will be described from the viewpoint of air. From the suction side of the gas-liquid mixing circulation pump 24, treated water in the nanobubble generation tank 22 is self-supplied, and an air amount adjusting valve 32 is opened and the air pipe 26 is passed through. The microbubble generator 25 has a special casing structure by self-supplying air, and “mixes, agitates, and pressurizes” liquid treated water and air as a gas to form microbubbles first. .

  Then, the formed microbubbles are introduced into the gas shearing portion 27 through the water pipe and sheared as fluid motion to generate nanobubbles from the microbubbles, and the treated water containing the nanobubbles is discharged from the nanobubble discharge port 23. It flows into the nanobubble generation tank 22.

  The air suction amount of the submersible pump type micro / nano bubble generator 6 is, for example, 5 liters / minute. The air suction amount of the nanobubble generator 36 is 0.7 liter / min, for example.

  Microbial sludge in the biological reaction tank 10 is returned from the return sludge pump 37 and introduced into the bubble mixed microorganism adhesion tank 40. Nanobubbles or micro-nanobubbles adhere to the microorganisms contained in the sludge returned and introduced from the return sludge pump 37, and are effective in maintaining the aerobic properties of the microorganisms. In particular, as the bubble size becomes ultrafine at the nano level, it lasts longer in water and becomes effective in activating small bacteria that effectively act on the treatment among microorganisms.

  The meaning of the bubble mixed microorganism adhesion tank 40 is a tank in which nanobubbles or micro / nano bubbles are mixed and nano bubbles or micro / nano bubbles adhere to microorganisms.

  The mixed water exiting the bubble mixed microorganism adhesion tank 40 is introduced into the biological reaction tank 10. In the biological reaction tank 10, as shown in the water flow 11, the mixed water moves over time through the serpentine channel to the most downstream portion of the serpentine channel.

  Depending on the operating conditions, nanobubbles and micro-nanobubbles adhere to microorganisms containing various bacteria in the mixed water and maintain microbial activity.

  Therefore, even if there is no agitation by aeration, a certain amount of agitation by passing through the meandering flow path and the activity of microorganisms can be maintained.

  The first submerged membrane pump 17 secures the treated water by solid-liquid separation from the biological reaction tank 10 and introduces it into the measurement tank 19. The second submerged membrane pump 18 secures the treated water by solid-liquid separation from the biological reaction tank 10 and introduces it into the nanobubble generation tank 22.

  The treated water introduced into the nanobubble generation tank 22 contains nanobubbles by the nanobubble generator 36 and is again introduced into the bubble mixed microorganism adhesion tank 40.

  And the treated water which came out of the measurement tank 19 is introduce | transduced into the next process processing apparatus 21, and the further advanced process etc. are implemented according to the objective.

  In short, the biological reaction method of the present invention is such that one or both of the micro-nano bubbles generated from the micro-nano bubble generator 6 and the nano bubbles generated from the nano-bubble generator 36, the microorganism, and the water to be treated are attached to the bubble mixed microorganism. Mixing in the tank 40 to create mixed water, and passing the mixed water supplied from the bubble mixed microorganism adhesion tank 40 to the biological reaction tank 10 through the flow path of the biological reaction tank 10, A process of preparing the treated water by biological reaction, a process of measuring the temperature and quality of the treated water supplied from the biological reaction tank 10 to the measuring tank 19, and the process measured in the measuring tank 19 And controlling the operation of the micro-nano bubble generator 6 and the nano-bubble generator 36 by the control unit based on the water temperature and water quality of water.

  According to the biological reaction apparatus having the above-described configuration, the micro / nano bubble generator 6, the nano bubble generator 36, the bubble mixed microorganism adhesion tank 40, the biological reaction tank 10, the measurement tank 19, and the control unit. Therefore, the following effects (i) to (iv) are obtained.

  According to the biological reaction method having the above configuration, the step of creating the mixed water, the step of creating the treated water, the step of measuring the water temperature and quality of the treated water, the micro-nano bubble generator 6 and the nano bubbles And a step of controlling the operation of the generator 36, and thus has the following effects (i) to (iv).

  In the characteristic point (i), a large amount of electric energy has been conventionally consumed for aeration for the purpose of stirring in the biological reaction tank 10, but the nanobubbles, the micronanobubbles, the water to be treated, and the microorganisms are mixed, By passing through the flow path of the biological reaction tank 10, the nanobubbles or the micro / nanobubbles adhere to the microorganisms, the microorganisms are activated, and the microorganism treatment is possible without stirring by the blower.

  Specifically, nanobubbles and micro-nanobubbles flow with sludge in the meandering flow path of the biological reaction tank 10, and microorganisms are activated, and the quality of treated water can be maintained without stirring by aeration. Agitation by aeration that consumes a large amount of electric energy is unnecessary, and the activity of microorganisms can be maintained and processed by agitation that flows through a serpentine flow path by a small sludge return pump 37.

  Here, the point which agitation in the said biological reaction tank 10 becomes unnecessary by using the said nano bubble is demonstrated in detail. Since nanobubbles last longer in water and nanobubbles have a negative charge, they adhere to substances in the water to be treated and microorganisms being returned to sludge, and move with the water to be treated and microorganisms, eliminating the need for stirring. . Nanobubbles can be processed by physically oxidizing organic substances due to the effect of activating microorganisms by adhering to microorganisms during movement and the high oxidizing power of nanobubbles.

  In the characteristic point (ii), the heat generated when the nanobubbles are formed is utilized to raise the water temperature of the biological reaction tank 10 in the winter season and stabilize the quality of the treated water.

  Specifically, heat is generated when the microbubbles generated by the microbubble generating unit 25 are formed into nanobubbles by the gas shearing unit 27. That is, physical bubbles are applied to the microbubble water generated by the microbubble generator 25 by the gas shearing unit 27 to decompose water molecules to form nanobubbles that are unstable free radicals. When this free radical is formed, heat is generated.

  In the characteristic point (iii), the operation of the micro / nano bubble generator 6 and the nano bubble generator 36 can be controlled by the water temperature and water quality of the treated water, and the rational operation conditions can be set according to the water temperature and water quality. .

  In feature (iv), by using two types of generators, the micro-nano bubble generator 6 and the nano-bubble generator 36, and producing and using a large amount of various bubbles as required, various microorganisms (large It is effective for activation of protozoa and small bacteria.

  Specifically, nanobubbles are effective against small bacteria (bacteria), and micronanobubbles are effective against large protozoa. That is, by using nanobubbles, the activation of bacteria (bacteria) having a particularly small size is remarkably increased and the performance is improved as compared with the case of using micronanobubbles.

  Therefore, the microorganism treatment can be performed without the stirring by the blower, energy saving can be achieved, the water temperature in winter can be increased, and various bubbles can be produced and used in large quantities, thereby improving the biological reaction efficiency.

  Moreover, since the said nano bubble generator 36 has a pump with a lift of 40 m or more, it can generate nano bubbles efficiently. In addition, Preferably, it is a pump with a lift of 60 m or more.

  Moreover, since the said micro nano bubble generator 6 has a pump with a lift of 15 m or more, it can generate micro nano bubbles efficiently.

  Moreover, since it has the said raw | natural water tank 2, the said micro nano bubble generation tank 4, and the said nano bubble generation tank 22, the said micro nano bubble and the said nano bubble can be generated reliably.

  Moreover, since it has the sludge return pump 37 which returns the sludge of the most downstream part of the flow path of the said bioreaction tank 10 to the said bubble mixing microorganism adhesion tank 40, the said microorganisms contained in the said sludge are converted into the said bubble mixing microorganisms. It can return to the adhesion tank 40, the said microorganisms can be activated, and biological reaction efficiency can be improved.

  The nanobubble generator 36 includes a gas-liquid mixing / circulation pump 24 having a microbubble generator 25 and a valve 32 connected to the microbubble generator 25 to adjust the flow rate of air to the microbubble generator 25. And a gas shearing section 27 that is connected to the downstream side of the gas-liquid mixing circulation pump 24 and shears microbubbles generated from the gas-liquid mixing circulation pump 24 into nanobubbles. In the two-stage method, the microbubbles are introduced into the gas shearing portion 27, and the nanobubbles are manufactured by the gas shearing portion 27, and the microbubbles are produced by the valve 32. Since the amount of air to the generator 25 can be accurately controlled, nanobubbles can be accurately and stably manufactured.

  Further, the flow path of the biological reaction tank 10 is a meandering flow path formed so as to alternately pass through a shallow portion and a deep portion at least once. At the same time, the contact between the microbial sludge and the water to be treated increases, and sufficient agitation can be performed.

  Moreover, since the deep part of the flow path of the biological reaction tank 10 has a depth of 10 m or more, the bubble size is further reduced by the water pressure in the deep part of the water, and easily adheres to microbial sludge. Become. As a result, the biological reaction process can be performed efficiently.

  In addition, since the quality of the treated water in the measurement tank 19 is measured using at least one of the total organic carbon meter and the chemical oxygen demand meter, the concentration of organic substances in the treated water can be accurately measured, It can be determined whether or not the treated water can be reliably treated.

  Further, the nanobubble generator 36 is a gas-liquid mixed gas shearing type nanobubble generator 36, and therefore, after mixing the gas and the liquid, the gas is sheared, so that a large amount of nanobubbles can be generated. It is.

  Moreover, since the said micro nano bubble generator 6 is a submersible pump type micro nano bubble generator or a swirl type micro nano bubble generator, it can secure an existing generator easily. Moreover, two types of generators can be selectively used, and can be freely selected according to the purpose, and an optimum system suitable for the purpose can be configured.

  Moreover, since the said to-be-processed water is drainage raw water, its use is wide and it can anticipate the process effect in each direction.

(Second Embodiment)
FIG. 2 shows a second embodiment of the biological reaction apparatus of the present invention. The difference from the first embodiment will be described. In the second embodiment, the biological reaction vessel 10 is filled with a string-type polyvinylidene chloride filler 31 as a filler. In the second embodiment, the same parts as those in the first embodiment are denoted by the same reference numerals, and detailed description thereof is omitted.

  Therefore, among the microorganisms, small bacteria activated by nanobubbles are immobilized on the string-type polyvinylidene chloride filling 31 as a filler, and the action of the bacteria is more activated and stabilized, so that the biological reaction tank 10 Will improve the processing capacity.

(Third embodiment)
FIG. 3 shows a third embodiment of the biological reaction apparatus of the present invention. If the point which is different from the said 1st Embodiment is demonstrated, in this 3rd Embodiment, the to-be-processed water introduced into the raw | natural water tank 2 is the waste water treated water 33. FIG. Note that in the third embodiment, the same portions as those in the first embodiment are denoted by the same reference numerals, and detailed description thereof is omitted.

  In this way, since the wastewater treated water 33 is a treatment target, the wastewater treated water 33 can be rationally treated by further activating microorganisms including bacteria with nanobubbles or micronanobubbles.

  Therefore, it is easy to reuse, and at the same time, the running cost can be reduced and the quality of the reused water can be improved.

(Fourth embodiment)
FIG. 4 shows a fourth embodiment of the biological reaction apparatus of the present invention. The difference from the third embodiment will be described. In the fourth embodiment, the biological reaction vessel 10 is filled with a string-type polyvinylidene chloride filler 31 as a filler. In the fourth embodiment, the same parts as those in the third embodiment are denoted by the same reference numerals, and detailed description thereof is omitted.

  Therefore, among the microorganisms, small bacteria activated by nanobubbles are immobilized on the string-type polyvinylidene chloride filling 31 as a filler, and the action of the bacteria is more activated and stabilized, so that the biological reaction tank 10 Will improve the processing capacity.

(Fifth embodiment)
FIG. 5 shows a fifth embodiment of the biological reaction apparatus of the present invention. If the point which is different from the said 1st Embodiment is demonstrated, in this 5th Embodiment, the to-be-processed water introduced into the raw | natural water tank 2 is the water 34. 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.

  In this way, since the water 34 is the target of treatment, the water 34 can be rationally treated by activating microorganisms including bacteria with nanobubbles or micronanobubbles.

  Therefore, not only the water treatment becomes easy, but also the running cost can be reduced and the quality of the treated water can be improved.

(Sixth embodiment)
FIG. 6 shows a sixth embodiment of the biological reaction apparatus of the present invention. The difference from the fifth embodiment will be described. In the sixth embodiment, the biological reaction tank 10 is filled with a string-type polyvinylidene chloride filler 31 as a filler. In the sixth embodiment, the same parts as those in the fifth embodiment are denoted by the same reference numerals, and detailed description thereof is omitted.

  Therefore, among the microorganisms, small bacteria activated by nanobubbles are immobilized on the string-type polyvinylidene chloride filling 31 as a filler, and the action of the bacteria is more activated and stabilized, so that the biological reaction tank 10 Will improve the processing capacity.

(Seventh embodiment)
FIG. 7 shows a seventh embodiment of the biological reaction apparatus of the present invention. If the point which is different from the said 1st Embodiment is demonstrated, in this 7th Embodiment, the to-be-processed water introduced into the raw | natural water tank 2 is the surfactant containing waste_water | drain 35. FIG. Note that 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.

  As described above, since the surfactant-containing wastewater 35 is a treatment target, the surfactant-containing wastewater 35 can be rationally treated by further activating microorganisms including bacteria with nanobubbles or micronanobubbles.

  Therefore, not only the treatment of the surfactant-containing wastewater 35 becomes easy, but also the running cost can be reduced and the water quality of the surfactant-containing wastewater 35 after the treatment can be improved.

(Eighth embodiment)
FIG. 8 shows an eighth embodiment of the biological reaction apparatus of the present invention. The difference from the seventh embodiment will be described. In the eighth embodiment, the biological reaction tank 10 is filled with a string-type polyvinylidene chloride filler 31 as a filler. In the eighth embodiment, the same parts as those in the seventh embodiment are denoted by the same reference numerals, and detailed description thereof is omitted.

  Therefore, among the microorganisms, small bacteria activated by nanobubbles are immobilized on the string-type polyvinylidene chloride filling 31 as a filler, and the action of the bacteria is more activated and stabilized, so that the biological reaction tank 10 Will improve the processing capacity.

(Ninth embodiment)
FIG. 9 shows a ninth embodiment of the biological reaction apparatus of the present invention. If the point which is different from the said 1st Embodiment is demonstrated, in this 9th Embodiment, the to-be-processed water introduced into the raw | natural water tank 2 will be the culture medium containing water 38 used by fermentation or brewing. A culture tank 39 is used as a biological reaction tank. In the ninth embodiment, the same parts as those in the first embodiment are denoted by the same reference numerals, and detailed description thereof is omitted.

  As described above, since the culture medium-containing water 38 is a treatment target, the culture medium-containing water 38 is further activated with nanobubbles or micro-nanobubbles, and microorganisms including bacteria can be activated to perform fermentation and brewing rationally.

  Therefore, not only can fermentation and brewing be facilitated, but also running costs can be reduced, productivity in fermentation and brewing can be improved, and quality of fermentation and brewing products can be improved.

(Tenth embodiment)
FIG. 10 shows a tenth embodiment of the biological reaction apparatus of the present invention. The difference from the ninth embodiment will be explained. In the tenth embodiment, a culture tank 39 as a biological reaction tank is filled with a string-like polyvinylidene chloride filler 31 as a filler. . Note that, in the tenth embodiment, the same portions as those in the ninth embodiment are denoted by the same reference numerals, and detailed description thereof is omitted.

  Therefore, among the microorganisms, small bacteria activated by nanobubbles are immobilized on the string-type polyvinylidene chloride filling 31 as a filler, and the action of the bacteria is more activated and stabilized, so that the culture tank 39 Processing capacity will be improved.

(Experimental example)
An experimental apparatus corresponding to the first embodiment of FIG. 1 was manufactured. In this experimental apparatus, the influent water is the drainage raw water 1, the capacity of the raw water tank 2 is 2 m ³ , the capacity of the micro / nano bubble generation tank 4 is 1 m ^3, and the capacity of the bubble mixed microorganism adhesion tank 40 is 0.5 m ³ , The experiment was conducted with the biological reaction tank 10 having a capacity of 10 m ³ , the measuring tank 19 having a capacity of 1 m ³ , and the nanobubble generating tank 22 having a capacity of 1 m ³ .

  In other words, the trial operation of the experimental apparatus was performed for one month, and then the total organic carbon concentration of the raw drainage water 1 flowing into the raw water tank 2 was measured and found to be 940 ppm. When the quality of the treated water obtained from the measuring tank 19 was measured to measure the final treated water, the total organic carbon concentration was 86 ppm. Therefore, the organic matter of the wastewater raw water 1 can be treated reliably.

  In addition, this invention is not limited to the above-mentioned embodiment. For example, the treated water may be a hydroponic solution after hydroponic cultivation of plants for the purpose of recycling, aquaculture water after aquaculture, recreational water from a fish farming facility, and exhibition circulating water from an aquarium facility. Any one of them may be used, and the water to be treated is treated as circulating water to improve the water quality, and at the same time, there is a water saving effect due to the circulation use.

It is a schematic diagram which shows 1st Embodiment of the biological reaction apparatus of this invention. It is a schematic diagram which shows 2nd Embodiment of the biological reaction apparatus of this invention. It is a schematic diagram which shows 3rd Embodiment of the biological reaction apparatus of this invention. It is a schematic diagram which shows 4th Embodiment of the biological reaction apparatus of this invention. It is a schematic diagram which shows 5th Embodiment of the biological reaction apparatus of this invention. It is a schematic diagram which shows 6th Embodiment of the biological reaction apparatus of this invention. It is a schematic diagram which shows 7th Embodiment of the biological reaction apparatus of this invention. It is a schematic diagram which shows 8th Embodiment of the biological reaction apparatus of this invention. It is a schematic diagram which shows 9th Embodiment of the biological reaction apparatus of this invention. It is a schematic diagram which shows 10th Embodiment of the biological reaction apparatus of this invention.

Explanation of symbols

1 Wastewater raw water (treated water)
2 Raw Water Tank 3 Raw Water Tank Pump 4 Micro / Nano Bubble Generation Tank 5 Micro / Nano Bubble Water Flow 6 Micro / Nano Bubble Generator (Air Submersible Type) 7 Air Pipe 8 Blower 9 Signal Line 10 Biological Reaction Tank 11 Water Flow 12 Partition Plate 13 Aeration Pipe 14 Blower 15 Bubble 16 Submerged membrane 17 First submerged membrane pump 18 Second submerged membrane pump 19 Measuring tank 20 Water quality meter detection unit 21 Next process treatment device 22 Nanobubble generation tank 23 Nanobubble discharge port 24 Gas-liquid mixing circulation pump 25 Microbubble generation Part 26 Air piping 27 Gas shearing part 28 Water quality controller 29 Water temperature controller 30 Water temperature sensor detection part 31 String-type polyvinylidene chloride filling 32 Valve (for adjusting the amount of air) 33 Wastewater treated water (treated water)
34 Water (treated water)
35 Surfactant-containing wastewater (treated water)
36 Nanobubble generator 37 Sludge return pump 38 Medium-containing water (treated water)
39 Culture tank (biological reaction tank)
40 Bubble mixing microorganism adhesion tank

Claims (14)

One or both of the micro-nano bubbles generated from the micro-nano bubble generator and the nano bubbles generated from the nano-bubble generator, the microorganisms, and the water to be treated are mixed in a bubble-mixing microorganism adhesion tank to create mixed water. Process,
Passing the mixed water supplied from the bubble-mixed microorganism adhesion tank to the biological reaction tank through the flow path of the biological reaction tank, and biologically reacting the mixed water to create treated water;
Measuring the temperature and quality of the treated water supplied from the biological reaction tank to the measurement tank;
And a step of controlling the operation of the micro-nano bubble generator and the nano-bubble generator by a control unit based on the temperature and quality of the treated water measured in the measurement tank. A micro-nano bubble generator for generating micro-nano bubbles;
A nanobubble generator for generating nanobubbles;
A bubble-mixing microorganism adhesion tank that creates a mixed water by mixing one or both of the micro-nano bubbles generated from the micro-nano bubble generator and the nano bubbles generated from the nano-bubble generator, a microorganism, and water to be treated. When,
A biological reaction tank for producing treated water by passing the mixed water supplied from the bubble-mixed microorganism adhesion tank through a flow path and biologically reacting the mixed water;
A measuring tank for measuring the temperature and quality of the treated water supplied from the biological reaction tank;
A biological reaction apparatus comprising: the micro / nano bubble generator and a control unit that controls the operation of the nano bubble generator based on the temperature and quality of the treated water measured in the measurement tank. The biological reaction apparatus according to claim 2, wherein
The said nano bubble generator has a pump with a lift of 40 m or more, The biological reaction apparatus characterized by the above-mentioned. The biological reaction apparatus according to claim 2, wherein
The micro-nano bubble generator has a pump with a lift of 15 m or more. The biological reaction apparatus according to claim 2, wherein
A raw water tank to which the treated water is supplied;
The micro / nano bubble generator containing the micro / nano bubble generator and containing the micro / nano bubbles in the water to be treated supplied from the raw water tank and supplying the bubble mixed microorganism adhesion tank,
A bioreactor containing the nanobubble generator and having a nanobubble contained in the treated water supplied from the bioreactor and supplying the bubble-mixed microorganism adhesion tank . The biological reaction apparatus according to claim 2, wherein
A biological reaction apparatus comprising a sludge return pump for returning sludge in the most downstream portion of the flow path of the biological reaction tank to the bubble mixed microorganism adhesion tank. The biological reaction apparatus according to claim 2, wherein
The nano bubble generator is
A gas-liquid mixing circulation pump having a microbubble generating unit;
A valve connected to the microbubble generator and adjusting the flow rate of air to the microbubble generator;
A biological reaction apparatus, comprising: a gas shearing unit that is connected to a downstream side of the gas-liquid mixing circulation pump and shears microbubbles generated from the gas-liquid mixing circulation pump into nanobubbles. The biological reaction apparatus according to claim 2, wherein
The biological reaction apparatus is characterized in that the flow path of the biological reaction tank is a meandering flow path formed so as to alternately pass through a shallow part and a deep part at least once. The biological reaction device according to claim 8, wherein
The biological reaction apparatus characterized in that the deep portion of the flow path of the biological reaction tank has a depth of 10 m or more. The biological reaction apparatus according to claim 2, wherein
A biological reaction apparatus characterized in that at least one of a total organic carbon meter and a chemical oxygen demand meter is used for measuring the quality of the treated water in the measurement tank. The biological reaction apparatus according to claim 2, wherein
The nano-bubble generator is a gas-liquid mixed gas shear type nano-bubble generator. The biological reaction apparatus according to claim 2, wherein
The bioreactor characterized in that the micro / nano bubble generator is an underwater pump type micro / nano bubble generator or a swirl type micro / nano bubble generator. The biological reaction apparatus according to claim 2, wherein
The biological reaction apparatus, wherein the water to be treated is any one of raw waste water, treated waste water, irrigation water, surfactant-containing waste water, and medium-containing water. The biological reaction apparatus according to claim 2, wherein
The treated water is a hydroponic solution after hydroponics of plants for the purpose of recycling, aquaculture water after aquaculture, farm water from fish farming facilities, and exhibition circulating water from aquarium facilities. A biological reaction apparatus characterized by being one of them.

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