JP2000229298A - Anaerobic waste water treating system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To drastically improve efficiency in decomposing waste water by using a bio-gas obtained in an anaerobic waste water treatment to lower dissolved oxygen concn. in the waste water and consequently to activate an anaerobe used in a fermenter. SOLUTION: When the dissolved oxygen concn. of waste water 2 stored in the pH regulation tank 30 of a pH regulator 6 is higher than a specified value, this fact is detected by a dissolved oxygen concn. meter, the bio-gas 8 obtained in a fermenter 10 is desulfurized by the line consisting of the fermenter 10, a desulfurizer 11, a gas circulator 13 and the diffuser pipe 29 of a deoxygenation tank 28 of the pH regulator 6. A part of the desulfurized gas 12 is introduced into the waste water 2 in the deoxygenation tank 28, and the dissolved oxygen in the waste water 2 stored in the deoxygenation tank 28 is liberated into the gas phase.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an anaerobic wastewater treatment system for treating high-concentration organic wastewater, and more particularly to an anaerobic bacterium for treating oxygen contained in wastewater before decomposing the wastewater with anaerobic bacteria. The present invention relates to an anaerobic wastewater treatment system that reduces the concentration and activates anaerobic bacteria, thereby ensuring high treatment efficiency.

[0002]

2. Description of the Related Art As a wastewater treatment system for treating high-concentration organic wastewater, a system utilizing aerobic treatment typified by a standard activated sludge method has been widely used.

[0003] However, in recent years, anaerobic wastewater treatment, which is energy saving type, especially UASB (Upflow Anaerobic
An anaerobic wastewater treatment system using what is called Sludge Blanket (upflow type anaerobic sludge bed) has been developed, and is often used to treat highly concentrated organic wastewater.

FIG. 3 is a schematic diagram showing an example of an anaerobic wastewater treatment system using such an upward anaerobic sludge bed.

An anaerobic wastewater treatment system 10 shown in FIG.
1 is wastewater 10 such as high-concentration organic wastewater to be treated.
Wastewater storage device 103 for storing PAC and NaO in wastewater 102 discharged from the wastewater storage device 103.
H, a polymer, etc. are injected to coagulate oils and solids contained in the wastewater 102, and then coagulated pressurized flotation devices 104 for floating as flocs 111, and discharged from the coagulated pressurized flotation devices 104. PH adjusting device 1 for adjusting the pH value, temperature, etc. of wastewater 102 containing floc 111
05 and the anaerobic bacteria 112,
A fermentation device 108 that decomposes wastewater 102 discharged from the wastewater 5 into biogas 106 and treated water 107
And the biogas 10 discharged from the fermentation device 108
And a desulfurization device 109 for removing the sulfur component in 6.

The wastewater storage device 103 includes a pipe 113 for taking in wastewater 102 such as high-concentration organic wastewater to be treated.
A flow control tank 114 for storing the wastewater 102 supplied via the pipe 113; a pipe 115 for guiding the wastewater 102 stored in the flow control tank 114 to the coagulation pressure flotation device 104; When the wastewater 102 stored in the flow rate adjustment tank 114 is guided to the coagulation pressure flotation device 104, a flow rate adjustment tank pump 116 is provided.

The coagulation pressure flotation device 104 takes in the wastewater 102 supplied from the wastewater storage device 103,
A mixing tank 117 for injecting AC and mixing the wastewater 102 with PAC, and a reaction tank 118 for neutralizing the wastewater 102 by injecting NaOH while taking in the wastewater 102 mixed with PAC by the mixing tank 117. While taking in the wastewater 102 neutralized by the reaction tank 118, the polymer is injected to coagulate the oil and solids in the wastewater 102, and the flocculation tank 119 which enlarges the floc 111.
And a floating tank 120 for taking in the wastewater 102 whose flocs 111 have been enlarged by the flocculation tank 119, a compressor 121 for sucking ambient air to generate the air 110, and a floating tank for the air 110 obtained by the compressor 121. A pipe 122 leading to the inside 120, a pipe 123 leading the wastewater 102 stored in the floating tank 120 to the middle of the pipe 122, and a wastewater 102 inserted in the middle of the pipe 123 and stored in the floating tank 120. Piping 1
A pump 124 is turned on to mix the wastewater 102 and the air 110 to diffuse the air 110 into the wastewater 102 stored in the floating tank 120 to float the floc 111 when guided into the inside of the floating tank 120. , Floating tank 120
1 (Wastewater containing floc 111)
02 to the pH adjusting device 105.

[0008] The pH adjusting device 105 includes a wastewater 102 containing flocs 111 supplied from a coagulation pressure flotation device 104.
And a pH adjusting tank 126 for storing water.
The temperature of the wastewater 102 stored in the wastewater 102 is measured, and steam is injected into the wastewater 102 on the basis of the measurement result.
Temperature controller 1 for adjusting the temperature of 2 to a temperature suitable for anaerobic treatment
27 and the wastewater 102 stored in the pH adjusting tank 126.
Of the wastewater 102 based on the measurement result.
PH adjuster 128 for injecting NaOH into the wastewater 102 to adjust the pH value of the wastewater 102 to a pH suitable for anaerobic treatment, and a stirrer for stirring the wastewater 102 stored in the pH adjustment tank 126. 129, a pipe 130 for guiding the wastewater 102 whose pH value, temperature and the like have been adjusted in the pH adjusting tank 126 to the fermenter 108, and a pipe 130 inserted in the middle of the pipe 130, and the pH value and the temperature in the pH adjusting tank 126. Wastewater 102 adjusted etc.
And a pump 131 which is turned on when introducing the fermentation device 108 to the fermentation device 108.

[0009] The fermentation device 108 stores the wastewater 102 containing the floc 111 supplied from the pH adjusting device 105, and decomposes the organic components of the wastewater 102 by the anaerobic bacteria 112, and treats the treated water 107 and biogas ( A methane fermentation tank 132 that separates the methane fermentation tank 132 into a gas composed of methane gas, carbon dioxide gas, and the like.
A gas collector 133 for collecting the biogas 106 obtained when the wastewater 102 stored in the wastewater 102 is decomposed, and the biogas 10 collected by the gas collector 133.
6 to a desulfurization device 109, and a pipe 135 for leading treated water 107 obtained when the wastewater 102 stored in the methane fermentation tank 132 is decomposed to a sewer or aerobic wastewater treatment system at a later stage. Have.

The desulfurizer 109 removes a sulfur component in the biogas 106 supplied from the fermenter 108 to a gas that can be effectively used as a fuel or a gas that can be released into the atmosphere. Up to the desulfurization mechanism 136 for reducing the concentration of hydrogen sulfide and the desulfurization mechanism 13
And a pipe 137 that guides the gas 138 discharged from the fuel cell 6 to a subsequent processing system or the like.

Next, the operation will be described.
In 3, the wastewater 102 to be treated is taken in and stored, and is supplied to the coagulation pressure flotation device 104 while adjusting the flow rate of the wastewater 102 so as to have a predetermined fixed flow rate.

The coagulation pressure flotation device 104 takes in the wastewater 102 supplied from the wastewater storage device 103,
PAC, NaOH, and a polymer are sequentially injected into the wastewater 102 taken in, and the oil content and the fixed content contained in the wastewater 102 are aggregated to increase the size of the floc 111 and “4 to 5 kg” in the wastewater 102. After air 110 is injected at a pressure of / cm ² ″ to float the flocs 111, the wastewater 102 containing the flocs 111 is supplied to the pH adjusting device 105.

In the pH adjusting device 105, the wastewater 10 containing the flocs 111 supplied from the coagulation pressure flotation device 104 is used.
The pH value and temperature of wastewater 102 are measured based on the measurement results, and the pH value and temperature of wastewater 102 are adjusted to a pH value suitable for anaerobic treatment.
After the temperature is raised, it is supplied to the fermenter 108.

In the fermenter 108, the pH controller 105
The organic component of the wastewater 102 is decomposed by the anaerobic bacteria 112 while storing the wastewater 102 containing the floc 111 supplied from the reactor, and the biogas 106 containing the methane gas and the carbon dioxide gas obtained by this is converted into the desulfurization device 10.
9, and the treated water 107 is supplied to a sewer or a downstream aerobic wastewater treatment system.

The desulfurizer 109 removes a sulfur component in the biogas 106 supplied from the fermenter 108,
After reducing the concentration of hydrogen sulfide to a gas that can be effectively used as fuel or a gas that can be released into the atmosphere, the gas 138 obtained by the desulfurization treatment is supplied to the subsequent treatment system.

[0016]

However, in such a conventional anaerobic wastewater treatment system 101,
Air 110 is blown into the wastewater 102 in a flotation tank 120 that constitutes the coagulation pressure flotation device 104, and the flocs 111 in the wastewater 102 are floated on the upper side of the wastewater 102 by a method of blowing the flocs 111 in the wastewater 102. Since the collected oxygen is collected and supplied to the pH adjusting device 105, the concentration of dissolved oxygen contained in the wastewater 102 after the coagulation pressure flotation treatment is substantially saturated (for example, “10 mg / L”).
Become.

For this reason, the pH adjusting device 105
Even after adjusting the pH value and temperature, the dissolved oxygen
g / L ”or less, which may hinder the anaerobic bacteria 112 used in the fermentation device 108, for example, methane bacteria having absolute anaerobicity, and reduce the efficiency of the decomposition treatment of the wastewater 102. There was something.

The present invention has been made in view of the above circumstances, and in claim 1, using biogas obtained in anaerobic wastewater treatment,
Provided is an anaerobic wastewater treatment system that can lower the dissolved oxygen concentration in wastewater, thereby activating anaerobic bacteria used in fermentation equipment and greatly improving the efficiency of wastewater decomposition treatment It is intended to be.

According to the present invention, the concentration of dissolved oxygen contained in the wastewater can be maintained within a certain range by using the biogas obtained in the anaerobic wastewater treatment, thereby reducing the power consumption. An object of the present invention is to provide an anaerobic wastewater treatment system capable of activating anaerobic bacteria used in a fermentation apparatus while suppressing the effluent treatment to a low level and greatly improving wastewater decomposition treatment efficiency.

According to the third aspect, the concentration of dissolved oxygen in the wastewater can be reduced by using the treated water obtained by the anaerobic wastewater treatment, thereby activating the anaerobic bacteria used in the fermenter. An object of the present invention is to provide an anaerobic wastewater treatment system that can significantly improve the efficiency of wastewater decomposition treatment.

According to the fourth aspect, the concentration of dissolved oxygen contained in the wastewater can be maintained within a certain range by using the treated water obtained by the anaerobic wastewater treatment, thereby reducing power consumption. An object of the present invention is to provide an anaerobic wastewater treatment system capable of activating anaerobic bacteria used in a fermentation apparatus while suppressing the effluent treatment to a low level and greatly improving wastewater decomposition treatment efficiency.

[0022]

In order to achieve the above object, according to the present invention, according to the present invention, the biogas supplied to the wastewater is disposed before the step of treating wastewater with anaerobic bacteria. A deoxygenating device that diffuses air into the wastewater to expel oxygen dissolved in the wastewater into the gas phase, and removes a part of biogas obtained when the wastewater is decomposed by the anaerobic bacteria. A gas recirculation device for leading to an oxygen device.

According to a second aspect of the present invention, in the anaerobic wastewater treatment system according to the first aspect, the concentration of dissolved oxygen in the wastewater is measured before the wastewater is treated by the anaerobic bacteria. , Turn on the gas recirculation device /
A biogas adjusting device for adjusting the amount of biogas supplied to the deoxygenating device by turning off or controlling the inverter is provided.

According to a third aspect of the present invention, the wastewater is disposed before the step of treating the wastewater with anaerobic bacteria, and the supplied treated water is mixed into the wastewater to reduce the concentration of oxygen dissolved in the wastewater. A concentration reducing device for reducing the concentration of the wastewater; and a treated water recirculation device for guiding a part of treated water obtained when the wastewater is decomposed by the anaerobic bacteria to the concentration reducing device.

According to a fourth aspect of the present invention, in the anaerobic wastewater treatment system according to the third aspect, the concentration of dissolved oxygen in the wastewater is measured before the wastewater is treated by the anaerobic bacteria. And a process water control device for controlling the process water recirculation device on / off or controlling the inverter to control the amount of the process water supplied to the concentration reducing device.

According to the first aspect of the present invention, a part of the biogas obtained when the wastewater is decomposed by the anaerobic bacteria is taken in by the gas recirculation device, and the biogas is introduced into the deoxygenation device, and the wastewater is introduced into the wastewater. Aeration is performed to expel oxygen dissolved in the wastewater into the gas phase. As a result, the concentration of dissolved oxygen in the wastewater is reduced, the anaerobic bacteria used in the fermenter are activated, and the efficiency of the wastewater decomposition treatment is greatly improved.

According to a second aspect of the present invention, before the wastewater is treated by the anaerobic bacteria, the concentration of dissolved oxygen in the wastewater is measured, and based on the measurement result, the gas recirculation device is turned on / off by the biogas adjusting device. Alternatively, the amount of biogas supplied to the deoxygenating device is adjusted by controlling the inverter.
As a result, the concentration of dissolved oxygen contained in the wastewater is maintained within a certain range using the biogas obtained in the anaerobic wastewater treatment, and is used in the fermentation apparatus while keeping the power consumption low. It activates anaerobic bacteria and greatly improves the efficiency of wastewater decomposition treatment.

According to the third aspect, the treated water recirculation device
A part of the treated water obtained when the wastewater is decomposed by the anaerobic bacteria is taken in, and the wastewater is led to a concentration reducing device to lower the concentration of the wastewater and reduce the dissolved oxygen concentration. As a result, the concentration of dissolved oxygen in the wastewater is reduced, the anaerobic bacteria used in the fermenter are activated, and the efficiency of the wastewater decomposition treatment is greatly improved.

According to a fourth aspect of the present invention, in the anaerobic wastewater treatment system according to the third aspect, the concentration of dissolved oxygen in the wastewater is measured before the wastewater is treated by the anaerobic bacteria. On / off control of the treated water recirculation device or inverter control by the water amount adjustment device,
Adjust the amount of treated water to be supplied to the concentration reduction device. As a result, the concentration of dissolved oxygen contained in the wastewater is maintained within a certain range using the treated water obtained in the anaerobic wastewater treatment, and the wastewater is used in the fermentation apparatus while keeping the power consumption low. It activates anaerobic bacteria and greatly improves the efficiency of wastewater decomposition treatment.

[0030]

DESCRIPTION OF THE PREFERRED EMBODIMENTS <Configuration of First Embodiment> FIG.
1 is a schematic configuration diagram showing a first embodiment of an anaerobic wastewater treatment system according to the present invention, which corresponds to claims 1 and 2. FIG.

An anaerobic wastewater treatment system 1a shown in FIG.
Is a wastewater storage device 3 for storing wastewater 2 such as high-concentration organic wastewater to be treated, and PAC, NaOH, polymers, etc. are injected into the wastewater 2 discharged from the wastewater storage device 3 to generate wastewater. After coagulating oil, solids, and the like contained in 2, a flocculating and pressurizing flotation device 4 for floating flock 5 using air 27 and floc 5 discharged from this coagulating and pressurizing flotation device 4 are combined. The wastewater 2 discharged from the pH adjuster 6 is decomposed by an anaerobic bacterium 7 and a pH adjuster 6 for adjusting the pH value, temperature, dissolved oxygen concentration and the like of the wastewater 2 containing biogas 8 and treated water 9. A desulfurization device 11 for removing sulfur components in the biogas 8 discharged from the fermentation device 10, and a part of the gas 12 discharged from the desulfurization device 11 to a pH adjusting device 6. Return to And a gas recirculation system 13 to reduce the dissolved oxygen concentration in 2.

The wastewater storage device 3 includes a pipe 14 for taking in wastewater 2 such as high-concentration organic wastewater to be treated, a flow rate adjusting tank 15 for storing the wastewater 2 supplied through the pipe 14, A pipe 16 for guiding the wastewater 2 stored in the regulating tank 15 to the coagulation pressure flotation device 4, and a coagulation pressure flotation device interposed in the middle of the pipe 16 for storing the wastewater 2 stored in the flow rate regulation tank 15. 4 is provided with a flow control tank pump 17 which is turned on when leading to 4.

The coagulation pressure flotation device 4 takes in the wastewater 2 supplied from the wastewater storage device 3 and injects PAC, mixes the wastewater 2 and PAC, and mixes the wastewater 2 and PAC. While injecting NaOH while taking in the wastewater 2 mixed with the wastewater 2, the wastewater 2 neutralized by the reaction tank 19
, A flocculation tank 20 for injecting a polymer and coagulating oil and solids in the wastewater 2 to increase the size of the floc 5, and a flotation tank for capturing the wastewater 2 in which the floc 5 is enlarged by the flocculation tank 20 21, a compressor 22 that draws in ambient air to generate air 27, a pipe 23 that guides the air 27 obtained by the compressor 22 into the floating tank 21, and a wastewater 2 stored in the floating tank 21. When the wastewater 2 inserted in the middle of the pipe 24 and guided in the middle of the pipe 24 and stored in the floating tank 21 is introduced into the pipe 23, the wastewater 2 is turned on, and the wastewater 2 and the air 27 are turned on. And a pump 25 for diffusing the air 27 into the wastewater 2 stored in the floating tank 21;
A piping 26 is provided for guiding wastewater (wastewater including flocs 5) 2 overflowing from the upper part of the floating tank 21 to the pH adjusting device 6.

The pH adjusting device 6 is provided with a deoxygenation tank 28 for storing the wastewater 2 containing the flocs 5 supplied from the coagulation pressure flotation device 4, and is disposed in the deoxygenation tank 28. The gas 12 is diffused into the wastewater 2,
A diffuser 29 for driving dissolved oxygen in the wastewater 2 into the gas phase;
Wastewater 2 whose dissolved oxygen concentration has been reduced by the deoxygenation tank 28
The temperature of the wastewater 2 is measured by measuring the temperature of the wastewater 2 stored in the pH adjustment tank 30 and the temperature of the wastewater 2 based on the measurement result. Temperature controller 31 for adjusting the temperature to a temperature suitable for anaerobic treatment;
The pH value of the wastewater 2 stored in the H adjustment tank 30 is measured, and based on the measurement result, NaOH is injected into the wastewater 2 to adjust the pH value of the wastewater 2 to a pH value suitable for anaerobic treatment. The dissolved oxygen concentration of the wastewater 2 stored in the controller 32 and the pH value adjusting tank 30 is measured. When the dissolved oxygen concentration of the wastewater 2 becomes “2 mg / L” or more based on the measurement result, reflux is performed. An instruction signal is generated, and when it becomes “1 mg / L” or less, a dissolved oxygen concentration meter 33 that stops generating the reflux instruction signal and a stirrer that stirs the wastewater 2 stored in the pH adjustment tank 30. And the pH in the pH adjustment tank 30.
A pipe 35 for guiding the wastewater 2 whose value, temperature, etc. are adjusted to the fermentation apparatus 10, and a wastewater 2 whose pH value, temperature, etc. are adjusted in the pH adjustment tank 30 and inserted in the middle of the pipe 35, And a pump 36 that is turned on when leading to 10.

The fermenter 10 decomposes the organic components of the wastewater 2 by the anaerobic bacteria 7 while storing the wastewater 2 containing the flocs 5 supplied from the pH adjuster 6, and treats the treated water 9 and biogas ( Methane fermentation tank 37 for separation into a gas composed of methane gas, carbon dioxide gas, etc.)
And a gas collector 38 for collecting biogas 8 obtained when the wastewater 2 stored in the methane fermentation tank 37 is decomposed, and the biogas 8 collected by the gas collector 38 is sent to the desulfurizer 11. A pipe 39 is provided for guiding the treated water 9 obtained when the wastewater 2 stored in the methane fermentation tank 37 is decomposed to a sewer system or a downstream aerobic wastewater treatment system.

The desulfurizer 11 removes a sulfur component in the biogas 8 supplied from the fermenter 10 to a gas that can be effectively used as a fuel or a gas that can be released into the atmosphere. Until then, a desulfurization mechanism 41 for reducing the concentration of hydrogen sulfide and a pipe 42 for guiding the gas 12 discharged from the desulfurization mechanism 12 to the gas recirculation device 13 are provided.

The gas recirculation device 13 is inserted in the middle of a pipe 42, and is connected to two valves 43 and 44 that are opened when the gas 12 discharged from the desulfurization device 10 is supplied to a subsequent processing system or the like. Out of the pipe 42, the gas 12 in the pipe 42 is connected between the valve 43 and the valve 44, and the gas 12 in the pipe 42 is provided in the deoxygenation tank 28 of the pH adjuster 6.
9 and a pipe 45 inserted in the middle of the pipe 45,
When the reflux instruction signal is output from the dissolved oxygen concentration meter 33, when the reflux instruction signal is output from the dissolved oxygen concentration meter 33 when the valve 46 is opened and inserted in the middle of the pipe 45, A blower 47 is provided which, when turned on, takes in the gas 12 in the pipe 42 and supplies it to the diffuser 29 of the deoxygenation tank 28.

<Operation of the First Embodiment> First, in the wastewater treatment apparatus 3, the wastewater 2 to be treated is taken in and stored, and the wastewater 2 is treated so as to have a predetermined constant flow rate. While adjusting the flow rate, it is supplied to the coagulation pressure flotation device 4.

The coagulation pressure flotation device 4 includes a wastewater storage device 3
PAC, NaOH, and a polymer are sequentially injected into the wastewater 2 taken in while the wastewater 2 supplied from the wastewater 2 is taken in, and the oil and fixed components contained in the wastewater 2 are aggregated to make the floc 5 larger. , 4 to 5 kg in wastewater 2
/ Cm ² ”pressure and air 27 injected.
, And the wastewater 2 containing the flocs 5 is supplied to the pH adjusting device 6.

In the pH adjusting device 6, when the gas 12 is supplied from the gas recirculation device 13, the coagulation pressure flotation device 4
Wastewater 2 containing flocs 5 supplied from
To dissolve dissolved oxygen in the wastewater 2 into the gaseous phase, measure its pH value and temperature, and adjust the pH value and temperature of the wastewater 2 to a pH suitable for anaerobic treatment based on the measurement results.
After setting the value and temperature, this is supplied to the fermentation apparatus 10. In parallel with this operation, the dissolved oxygen concentration in the wastewater 2 supplied to the fermenter 10 is measured, and when the dissolved oxygen concentration of the wastewater 2 becomes “2 mg / L” or more, a reflux instruction signal is generated. This is supplied to the gas recirculation device 13. When the concentration of dissolved oxygen in the wastewater 2 becomes “1 mg / L” or less, the supply of the reflux instruction signal to the gas reflux device 13 is stopped.

In the fermenter 10, while storing the wastewater 2 containing the floc 5 supplied from the pH adjuster 6, the organic components of the wastewater 2 are decomposed by the anaerobic bacteria 7.
The obtained biogas 8 containing methane gas and carbon dioxide gas is supplied to a desulfurization device 11, and the treated water 9 is supplied to a sewer or a downstream aerobic wastewater treatment system.

In the desulfurizer 11, the sulfur component in the biogas 8 supplied from the fermenter 10 is removed to obtain a gas which can be effectively used as fuel or a gas which can be released into the atmosphere. After reducing the concentration of hydrogen sulfide, the gas 12 obtained by the desulfurization treatment is supplied to the gas recirculation device 13.

In the gas recirculation device 13, while the gas 12 supplied from the desulfurization device 11 is supplied to a subsequent processing system or the like, when the dissolved oxygen concentration meter 33 outputs a reflux instruction signal, a part of the Deoxygenation tank 28
To reflux.

As described above, in the first embodiment,
While adjusting the flow rate and the like of the wastewater 2 to be treated, PAC, NaOH, a polymer, and the like are injected into the wastewater 2 to coagulate an oil component, a solid component, and the like. The floc 5 containing solids and the like is floated, and the gas 12 is further diffused into the wastewater 2 containing the floc 5 to drive out dissolved oxygen in the wastewater 2 into the gas phase.
After adjusting the pH value (pH value), the temperature, etc., the organic components in the wastewater 2 are decomposed using the anaerobic bacteria 7, and the treated water 9 obtained by the decomposition is supplied to a downstream aerobic wastewater treatment system or the like. In addition to the supply, the hydrogen sulfide in the biogas 8 was removed, and a part of the gas 12 thus obtained was supplied to the subsequent processing system while being refluxed to the pH adjusting device 6. For this reason, the concentration of dissolved oxygen in the wastewater 2 can be reduced by using the biogas 8 obtained in the anaerobic wastewater treatment.
Activates anaerobic bacteria 7 used in
Can greatly improve the decomposition processing efficiency of the present invention (the effect of claim 1).

In the first embodiment, the dissolved oxygen concentration in the wastewater 2 is measured by the dissolved oxygen concentration meter 33, and the wastewater 2 stored in the pH adjusting tank 30 is measured based on the measurement result. When the dissolved oxygen concentration becomes “2 mg / L” or more, the gas reflux operation of the gas recirculation device 13 is started to reduce the dissolved oxygen concentration in the wastewater 2, and the wastewater stored in the pH adjustment tank 30. 2 dissolved oxygen concentration is "1m
g / L ”or less, the gas recirculation operation of the gas recirculation device 13 was stopped to prevent the concentration of dissolved oxygen in the wastewater 2 from further decreasing. The dissolved oxygen concentration can be prevented from lowering unnecessarily, whereby the power consumption of the entire system can be suppressed while maintaining the decomposition treatment capacity of the anaerobic bacteria 7 high (the effect of claim 2). .

<Second Embodiment> FIG. 2 is a schematic diagram showing a second embodiment of the anaerobic wastewater treatment system according to the present invention, which corresponds to the third and fourth aspects of the present invention. In this figure, the same parts as those in FIG. 1 are denoted by the same reference numerals.

An anaerobic wastewater treatment system 1b shown in FIG.
Is different from the anaerobic wastewater treatment system 1a shown in FIG.
0, a treated water recirculation device 50 is provided, and the treated water 9 discharged from the fermentation device 10, that is, under anaerobic conditions,
A part of the treated water 9, which is considered to have a dissolved oxygen concentration of approximately “0 mg / L” and a BOD (biochemical oxygen demand) of “several hundred mg / L”, is transferred to the deoxygenation tank 28 of the pH controller 10. And the wastewater 2 stored in the deoxygenation tank 28
In the wastewater 2 to reduce the concentration of dissolved oxygen contained in the wastewater 2.

The treated water recirculation device 50 is provided with a pipe 5 for taking in the treated water 9 overflowing from the upper part of the fermenter 10.
1, a treated water tank 52 for storing the treated water 9 supplied via the pipe 51, a pipe 53 for guiding the treated water 9 stored in the treated water tank 52 to a downstream aerobic wastewater treatment system or the like, A pipe 54 for guiding the biogas 8 from the treated water 9 stored in the treated water tank 52 to the pipe 39 of the fermentation apparatus 10 and a treated water 9 stored in the treated water tank 52
A pipe 55 leading to the deoxygenation tank 28 of the H adjusting device 6;
When the reflux instruction signal is output from the dissolved oxygen concentration meter 33 provided in the H adjusting device 6, it is turned on and the treated water 9 stored in the treated water tank 52 is deoxygenated by the pH adjusting device 6. A circulation pump 56 for supplying to the tank 28.

Then, the residence time of the wastewater 2 in the deoxygenation tank 28 and the pH adjustment tank 30 is set to a considerably long time, for example, a normal time, so that the amount of the treated water 9 refluxed from the treatment water tank 52 to the deoxygenation tank 28 can be increased. 6 to 9 times longer than 20 minutes
Double the time (2 hours to 3 hours)
The residence time of the treated water 9 in the treated water tank 52 is set to about 20 minutes, and the rising speed of the wastewater 2 in the methane fermentation tank 37 is set to the maximum value, that is, the self-agglomerated material (granules) deposited in the lower part of the methane fermentation tank 37 is set. ) Can be maximized while preventing outflow of “0.5 m
/ H "to" 2.0 m / h ", the methane fermentation tank 37
The rising speed of the waste water 2 at the time is set to “2.0 m / h”, and the dissolved oxygen concentration meter 3 provided in the pH adjusting device 6
When the reflux instruction signal is output from the processing tank 3,
The treated water 9 stored in the wastewater 2 is supplied to a deoxygenation tank 28 of the pH adjusting device 6, the concentration of the wastewater 2 stored in the deoxygenation tank 28 is reduced, and the concentration of dissolved oxygen in the wastewater 2 is reduced to “ 2m
g / L ”or less.

As described above, in the second embodiment,
The treated water 9 discharged from the fermenter 10, that is, under anaerobic conditions, the dissolved oxygen concentration is almost "0 mg / L", B
A part of the treated water 9 whose OD (biochemical oxygen demand) is considered to be “several hundred mg / L” is led to the deoxidation tank 28 of the pH adjusting device 10, and is stored in the deoxygenation tank 28. The concentration of the wastewater 2 is reduced to lower the concentration of dissolved oxygen contained in the wastewater 2. Therefore, the concentration of dissolved oxygen in the wastewater 2 can be reduced by using the treated water 9 obtained by the anaerobic wastewater treatment, thereby activating the anaerobic bacteria 7 used in the fermenter 10. Thus, the efficiency of the decomposition treatment of the wastewater 2 can be greatly improved (the effect of claim 3).

In the second embodiment, the dissolved oxygen concentration in the wastewater 2 is measured by the dissolved oxygen concentration meter 33, and the wastewater 2 stored in the pH adjusting tank 30 is measured based on the measurement result. When the dissolved oxygen concentration becomes “2 mg / L” or more, the treated water reflux operation of the treated water reflux device 50 is started to reduce the dissolved oxygen concentration in the wastewater 2, and
When the dissolved oxygen concentration of the wastewater 2 stored in the adjustment tank 30 becomes “1 mg / L” or less, the treated water recirculation device 50
Was stopped so that the concentration of dissolved oxygen in the wastewater 2 did not decrease any more. For this reason, the concentration of dissolved oxygen contained in the wastewater 2 can be prevented from lowering more than necessary, whereby the power consumption of the entire system is kept low while maintaining the decomposition treatment capacity of the anaerobic bacteria 7 high. (Effect of Claim 4).

In the first and second embodiments, the gas recirculation device 13 and the treated water recirculation device 50 are used based on the dissolved oxygen concentration of the wastewater 2 stored in the pH adjusting tank 30.
Is turned on / off. However, based on a control method other than such on / off control, for example, based on the dissolved oxygen concentration of the wastewater 2 stored in the pH adjusting tank 30, the gas is returned from the gas recirculation device 13. An inverter control method for continuously controlling the flow rate of the gas 12 and the flow rate of the treated water 9 recirculated from the treated water recirculation device 50 may be used.

Also in this case, as in the first and second embodiments, the concentration of dissolved oxygen contained in the wastewater 2 can be prevented from lowering more than necessary. The power consumption of the entire system can be suppressed low while maintaining the ability to decompose the bacterium 7 at a high level (the effects of claims 2 and 4).

[0054]

As described above, according to the present invention, in the anaerobic wastewater treatment system of the first aspect, the concentration of dissolved oxygen in the wastewater is reduced by using the biogas obtained in the anaerobic wastewater treatment. As a result, the anaerobic bacteria used in the fermenter can be activated, and the efficiency of the wastewater decomposition treatment can be greatly improved.

In the anaerobic wastewater treatment system according to claim 2,
Using biogas obtained from anaerobic wastewater treatment, the concentration of dissolved oxygen contained in the wastewater can be maintained within a certain range, thereby reducing power consumption and using it in fermentation equipment. The activated anaerobic bacteria can be activated, and the efficiency of wastewater decomposition treatment can be greatly improved.

In the anaerobic wastewater treatment system according to the third aspect,
The concentration of dissolved oxygen in the wastewater can be reduced by using the treated water obtained in the anaerobic wastewater treatment, which activates the anaerobic bacteria used in the fermentation equipment and improves the efficiency of the wastewater decomposition treatment Can be greatly improved.

In the anaerobic wastewater treatment system according to the fourth aspect,
Using the treated water obtained in the anaerobic wastewater treatment, it is possible to maintain the concentration of dissolved oxygen contained in the wastewater within a certain range, thereby reducing power consumption,
Activate anaerobic bacteria used in fermentation equipment,
The efficiency of wastewater decomposition treatment can be greatly improved.

[Brief description of the drawings]

FIG. 1 shows an anaerobic wastewater treatment system according to the present invention.
1 is a schematic configuration diagram showing a first embodiment corresponding to claims 1 and 2; FIG.

FIG. 2 shows an anaerobic wastewater treatment system according to the present invention;
FIG. 11 is a schematic configuration diagram showing a second embodiment corresponding to claims 3 and 4.

FIG. 3 is a schematic configuration diagram showing an example of a conventionally known anaerobic wastewater treatment system.

[Explanation of symbols]

1a, 1b: Anaerobic wastewater treatment system 2: Wastewater 3: Wastewater storage device 4: Coagulation pressure flotation device 5: Floc 6: pH adjustment device 7: Anaerobic bacteria 8: Biogas 9: Treated water 10: Fermentation device 11 : Desulfurization unit 12: Gas 13: Gas reflux unit 14, 16, 23, 24, 26, 35, 39, 40, 4
2, 45, 51, 53, 54, 55: Piping 15: Flow control tank 17: Flow control tank pump 18: Mixing tank 19: Reaction tank 20: Coagulation tank 21: Floating tank 22: Compressor 25, 36: Pump 27: Air 28: deoxygenation tank (deoxygenation device, concentration reduction device) 29: acid trachea (deoxygenation device, treated water volume control device) 30: pH control tank 31: temperature controller 32: pH controller 33: dissolved oxygen concentration meter (Biogas adjusting device) 34: Stirrer 37: Methane fermentation tank 38: Gas collector 41: Desulfurization mechanism 43, 44, 46: Valve 47: Blower 50: Treated water recirculation device 52: Treated water tank 56: Circulation pump

Claims (4)

[Claims] Claims: 1. An apparatus disposed before a step of treating wastewater with anaerobic bacteria, in which supplied biogas is diffused into the wastewater and oxygen dissolved in the wastewater is converted into a gas phase. An anaerobic wastewater treatment characterized by comprising: a deoxygenation device to be expelled; and a gas recirculation device for guiding a part of biogas obtained when the wastewater is decomposed by the anaerobic bacteria to the deoxygenation device. system. 2. The anaerobic wastewater treatment system according to claim 1, wherein the concentration of dissolved oxygen in the wastewater is measured before the wastewater is treated by the anaerobic bacteria.
An anaerobic wastewater treatment system, comprising: a biogas adjusting device that adjusts the amount of biogas supplied to the deoxygenating device by on / off control or inverter control of the gas recirculation device. 3. A method for reducing the concentration of oxygen dissolved in wastewater, which is disposed before the step of treating wastewater with anaerobic bacteria and mixing the supplied treated water into the wastewater. An anaerobic wastewater treatment system, comprising: a device; and a treated water recirculation device that guides a part of treated water obtained when the wastewater is decomposed by the anaerobic bacteria to the concentration reducing device. 4. The anaerobic wastewater treatment system according to claim 3, wherein the concentration of dissolved oxygen in the wastewater is measured before the wastewater is treated by the anaerobic bacteria, and based on the measurement result,
An anaerobic wastewater treatment system, comprising: a treated water amount adjusting device that adjusts an amount of treated water supplied to the concentration reduction device by controlling the on / off control or the inverter of the treated water recirculation device.