JP3939010B2 - Sewage treatment equipment - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a sewage treatment apparatus that purifies sewage, and more particularly to a sewage treatment apparatus that removes phosphorus from sewage.
[0002]
[Prior art]
As this type of sewage treatment apparatus, for example, one described in JP-A-7-108296 (C02F 3/30) is known.
[0003]
In this publication, iron dissolving devices for eluting iron ions are arranged at various positions of the sewage treatment device, and iron ions eluted from the iron dissolving device are reacted with orthophosphoric acid in the sewage to aggregate as a water-insoluble phosphorus compound. A configuration for removing phosphorus from wastewater by precipitation is disclosed.
[0004]
However, since the sewage water level in the sewage treatment apparatus provided with the iron dissolving device varies depending on the use state, for example, when a large amount of water such as bath water temporarily flows into the sewage treatment apparatus, the sewage water level increases. Then, there is a possibility that the terminal of the electrode is immersed in sewage, the terminal part is disconnected due to corrosion or the like, and iron ions are not eluted and phosphorus cannot be removed.
[0005]
In order to solve this problem, a method of estimating the rise of the sewage water level and arranging the electrode in a high position in advance is also conceivable, but in this configuration, it is necessary to increase the vertical dimension of the electrode, However, there is a drawback that the cost is increased by increasing the size of the electrode, and the workability at the time of electrode replacement is lowered due to an increase in the weight of the electrode.
[0006]
In addition, the electrodes above the normal sewage level are exposed from the sewage for most of the day, and the gas generated from the sewage deteriorates not only to the electrode surface but also to the inside of the electrode, increasing the electrical resistance and applying a voltage to the electrode. When the current supplied to the electrode is reduced, the amount of iron ions eluted from the electrode is reduced, and the phosphorus removal efficiency is lowered.
[0007]
[Problems to be solved by the invention]
This invention is made | formed in order to solve the said subject, and makes it a subject to provide the sewage treatment apparatus which can perform stable phosphorus removal irrespective of the fluctuation | variation of a sewage water level.
[0008]
[Means for solving the problem]
  The first means for solving the above problems is as follows.An anaerobic tank into which domestic wastewater flows, an aerobic tank into which sewage treated in the anaerobic tank flows, a precipitation separation tank or a treated water tank into which sewage treated in the aerobic tank flows, and the aerobic tank Or a return path for returning the sewage in the sedimentation separation tank or the treated water tank to the anaerobic tank, and providing a partition in the anaerobic tank for separating the sewage returned from the return path from household wastewater. An electrode made of iron or aluminum that elutes aluminum ions is disposed in the partition portion, and a float is attached to the electrode.
[0010]
  To solve the above problemsSecondThe means is an anaerobic tank into which domestic wastewater flows, an aerobic tank into which sewage treated in the anaerobic tank flows, a precipitation separation tank or a treated water tank into which sewage treated in the aerobic tank flows, A return path for returning the sewage in the aerobic tank, the sedimentation separation tank or the treated water tank to the anaerobic tank, and providing a partition in the anaerobic tank for separating the sewage returned from the return path from domestic wastewater. An electrode made of an iron material or aluminum that elutes iron ions or aluminum ions is disposed in the partition part at a position that is off from directly below the discharge port of the return path, and a float is attached to the electrode.
[0011]
  To solve the above problemsFirstMeans of orSecondIn this means, it is preferable to provide an anaerobic filter bed for precipitating and separating domestic wastewater in the anaerobic tank, and to provide a communication part communicating with the anaerobic filter bed in the partition part.
[0012]
  To solve the above problemsSecondIn this means, it is preferable to provide a storage portion for storing the float in the partition portion and preventing the float from moving in the lateral direction.
[0013]
  To solve the above problemsThirdThe means is an anaerobic tank into which domestic wastewater flows, an aerobic tank into which sewage treated in the anaerobic tank flows, a precipitation separation tank or a treated water tank into which sewage treated in the aerobic tank flows, A return path for returning the sewage in the aerobic tank, the sedimentation separation tank or the treated water tank to the anaerobic tank, and iron ions or aluminum by energization in the return path immersed in the aerobic tank, the precipitation separation tank or the treated water tank. An electrode made of iron or aluminum that elutes ions is disposed, and a float is attached to the electrode.
[0014]
  To solve the above problems4thThe means is an anaerobic tank into which domestic wastewater flows, an aerobic tank into which sewage treated in the anaerobic tank flows, a precipitation separation tank or a treated water tank into which sewage treated in the aerobic tank flows, A return path for returning the sewage in the aerobic tank, the precipitation separation tank, or the treated water tank to the anaerobic tank, and the electrode made of iron or aluminum that elutes iron ions or aluminum ions when energized is immersed in the anaerobic tank. In addition to being disposed in the road, a float is attached to the electrode.
[0015]
  To solve the above problems5thThe means is an anaerobic tank into which domestic wastewater flows, an aerobic tank into which sewage treated in the anaerobic tank flows, a precipitation separation tank or a treated water tank into which sewage treated in the aerobic tank flows, A return path for returning the sewage in the aerobic tank, the precipitation separation tank or the treated water tank to the anaerobic tank, and an electrode made of iron material or aluminum that elutes iron ions or aluminum ions when energized is provided in the middle of the return path In addition to being disposed in the sewage storage section, a float is attached to the electrode.
[0016]
  To solve the above problemsThirdMeans of5thIn the above means, it is preferable to provide a storage portion for storing the float in the return pipe and preventing the float from moving in the lateral direction.
[0017]
  To solve the above problems6thThe means includes a first anaerobic tank into which domestic wastewater flows, a second anaerobic tank into which sewage treated in the first anaerobic tank flows, and a treatment in the second anaerobic tank. An advection pipe into which the treated sewage flows, an aerobic tank into which the sewage in the advection pipe flows, a precipitation separation tank or a treated water tank into which sewage treated in the aerobic tank flows, and the aerobic tank or the precipitation separation A return path for returning the sewage in the tank or the treated water tank to the first anaerobic tank, and an electrode made of iron or aluminum that elutes iron ions or aluminum ions when energized is disposed in the advection tube, and a float is provided on the electrode. It is characterized by wearing.
[0018]
  To solve the above problems6thIn this means, it is preferable that a float is accommodated in the advection pipe and a storage portion for preventing the float from moving in the lateral direction is provided.
[0019]
  To solve the above problems7thThe means includes an anaerobic tank into which miscellaneous wastewater flows, an aerobic tank into which sewage treated in the anaerobic tank flows, an air diffuser pipe disposed in the aerobic tank and having an air outlet, and the diffuser. A blower that communicates with the trachea and supplies air into the aerobic tank, and an electrode made of iron or aluminum that elutes iron ions or aluminum ions when energized is disposed in the aerobic tank and above the air diffuser. And a float is attached to the electrode.
[0020]
  To solve the above problems8thThe means includes an anaerobic tank into which miscellaneous wastewater flows, an aerobic tank into which sewage treated in the anaerobic tank flows, an air diffuser pipe disposed in the aerobic tank and having an air outlet, and the diffuser. A blower that communicates with the trachea and supplies air into the aerobic tank, and an electrode made of iron or aluminum that elutes iron ions or aluminum ions when energized is disposed in the aerobic tank and floats on the electrode And a second air diffuser communicating with the blower is disposed below the electrode.
[0021]
  To solve the above problems7thMeans of or8thThe aerobic tank is provided with a convection pipe for transferring the sewage flowing from the anaerobic tank to the lower part of the aerobic tank, an electrode equipped with a float is provided in the convection pipe, and the lower opening of the advection pipe is formed in the aeration pipe. It is preferable to dispose the float in the advection pipe and provide a storage section for preventing the float from moving in the lateral direction while being disposed at the upper position.
[0022]
  To solve the above problems9thThe means comprises an anaerobic tank into which domestic wastewater flows, an aerobic tank into which sewage treated in the anaerobic tank flows, and a precipitation separation tank into which sewage treated in the aerobic tank flows, An electrode made of an iron material or aluminum that elutes iron ions or aluminum ions is disposed in the precipitation separation tank, and a float is attached to the electrode.
[0023]
  To solve the above problems10thThe means comprises an anaerobic tank into which domestic wastewater flows, an aerobic tank into which sewage treated in the anaerobic tank flows, and a precipitation separation tank into which sewage treated in the aerobic tank flows, An electrode made of iron or aluminum that elutes iron ions or aluminum ions by means of the above is disposed in the precipitation separation tank, a float is attached to the electrode, and return means for returning the sewage containing ions eluted from the electrode to the anaerobic tank Is provided.
[0025]
DETAILED DESCRIPTION OF THE INVENTION
The first embodiment of the present invention will be described in detail below based on the sewage treatment apparatus shown in FIGS.
[0026]
Reference numeral 1 denotes a treatment tank buried in the ground. The inside of the treatment tank 1 is divided into a first anaerobic tank 5, a second anaerobic tank 24, a biofilm filtration tank 32, a treated water tank 42 and a disinfectant, which will be described later, by a first partition wall 2, a second partition wall 3 and a third partition wall 4. The tank 43 is partitioned.
[0027]
5 is a first anaerobic tank having an inlet 6 through which sewage such as domestic wastewater flows, and 7 is a first anaerobic filter bed disposed in the first anaerobic tank 5 through which sewage flowing from the inlet 6 passes. In addition, the hard-to-decompose contaminants mixed in the sewage flowing from the inlet 6 are separated by precipitation, the organic matter is anaerobically decomposed by the anaerobic microorganisms attached to the first anaerobic filter bed 7, and organic nitrogen is removed. Change to ammoniacal nitrogen.
[0028]
Reference numeral 8 denotes a first advection pipe vertically disposed in a notch formed in the first anaerobic filter bed 7, and an inflow portion into which sewage returned from a return pipe 46 described later flows and a float 9 described later. While providing the upper opening which has a storage part to accommodate, the lower opening is provided in the bottom part of the 1st anaerobic tank 5 below the 1st anaerobic filter bed 7.
[0029]
The domestic wastewater that flows in from the inflow port 6 passes through the first anaerobic filter bed 7 so that foreign substances such as toilet paper are removed and flows into the first advection pipe 8 from the lower opening of the first advection pipe 8. The iron ion elution efficiency is prevented from lowering due to the adhering contaminants contained in the daily wastewater on the surface of the electrode 12 described later disposed in the first advection pipe 8. The first advection pipe 8 constitutes a partition portion that separates domestic wastewater flowing from the inlet 6 and sewage returned from the return pipe 46.
[0030]
9 is formed in a shape substantially corresponding to the shape of the storage portion of the first convection tube 8, a float made of foamed polystyrene, resin or the like disposed in the first convection tube 8, and 10 is formed in the float 9. It is a rectangular hole. An electrode body 11 is engaged with the hole 10 formed in the float 9. The mounting method of the electrode body 11 and the float 9 is not limited to the engagement, and a method such as fixing with a bolt or a nut or fixing by a claw fitting may be used.
[0031]
The electrode body 11 is a pair of electrodes 12 made of an iron material, holds the electrodes 12 at a predetermined interval, and connects a handle portion 14 having a handle 13, a terminal 15 formed on the electrode 12, and a connector 16. It is composed of an electric wire 17.
[0032]
By connecting the connector 16 to a power supply device 18 that supplies a DC constant current, a DC constant current is supplied between the electrodes 12, and iron ions are eluted from the electrodes 12. The electrode body 11 and the power supply device 18 constitute an elution device that elutes iron ions. Since the float 9 is attached to the electrode body 11, the first anaerobic tank 5 in the case where a large amount of water such as bath water flows in temporarily or when it is not used for a long time due to a long trip or the like is used. Stable iron ions can be supplied to the first anaerobic tank 5 regardless of fluctuations in the sewage water level.
[0033]
Reference numeral 19 denotes a first air diffuser disposed below the electrode 12 and having a number of air outlets, and is connected to the first blower 21 via a first supply pipe 20. By releasing the air supplied from the first blower 21 from the air outlet, the electrode 12 is washed to prevent the sludge from adhering, and the divalent iron ion eluted from the electrode 12 reacts with orthophosphoric acid. Oxidizes to iron ions.
[0034]
22 is a second advection pipe disposed in the first anaerobic tank 5, and the sewage that has been anaerobically decomposed by the first anaerobic filter bed 5 and the iron ions supplied from the electrode 12 are supplied to the upper part of the first partition wall 2. It supplies to the 2nd anaerobic tank 24 mentioned later through the 1st water supply port 23 which penetrates.
[0035]
Reference numeral 24 is a second anaerobic tank partitioned from the first anaerobic tank 5 by the first partition wall 2, and 25 is a second anaerobic filter bed disposed in the second anaerobic tank 24. Floating substances are captured by 25 and organic matter is anaerobically decomposed by anaerobic microorganisms, and organic nitrogen is changed to ammonia nitrogen.
[0036]
Reference numeral 26 denotes a third advection pipe disposed in the second anaerobic tank 24, and sewage that has been anaerobically decomposed by the second anaerobic filter bed 25 flows into the third advection pipe 26.
[0037]
27 is a metering pumping chamber disposed in the second anaerobic tank 24, 28 is a water intake pipe having a check valve 29, one end communicating with the metering pumping chamber 29 and the other end of a third advection tube. It is within 26. 30 communicates with the fixed pressure feed chamber 29, a second blower for supplying air into the constant pressure feed chamber 29, 31 communicates with the constant pressure feed chamber 27 and a fourth advection pipe 34 to be described later, This is a transfer pipe for supplying the sewage water to the fourth advection pipe 34 through the constant pressure feed chamber 27. By supplying air from the second blower 30 into the fixed pressure feeding chamber 27, the sewage flowing into the fixed pressure feeding chamber 27 from the intake pipe 28 is pumped and supplied into the fourth advection pipe 34 through the transfer pipe 31. It is supposed to be.
[0038]
32 is a biofilm filter tank partitioned from the second anaerobic tank 24 by the second partition wall 3, 33 is a biofilm filter medium which is disposed in the biofilm filter tank 32 and promotes the culture of aerobic microorganisms, 34 A fourth advection pipe which is provided in the biofilm filtration tank 32 and separates from the biofilm filtration material 33 and into which sewage supplied from the transfer pipe 31 flows, is provided above the second air diffuser pipe 35 which will be described later. The sewage flowing out from the lower opening passes through the biofilm filter medium 33.
[0039]
Reference numeral 35 denotes a second air diffuser disposed at the bottom of the biofilm filtration tank 32, which forms a large number of air outlets and is connected to the third blower 36 via the second supply pipe 37. The air supplied from the air outlet is released to maintain the biofilm filtration tank 33 in an aerobic state, and the sewage is aerobically decomposed by aerobic microorganisms. Nitrogen is changed to nitrate or nitrite nitrogen.
[0040]
38 is a sludge return pipe that communicates the upper part of the first anaerobic tank 5 and the lower part of the biofilm filtration tank 32 and returns the sediment deposited on the bottom of the biofilm filtration tank 32 to the first anaerobic tank 5, and 39 is the sludge return pipe. The first pump is connected to 38 and supplies the sewage in the biofilm filtration tank 32 into the sludge return pipe 38.
[0041]
Reference numeral 40 denotes a fifth advection pipe communicating with the biological membrane filtration tank 32 above the biological membrane filter medium 33 and the bottom of the treated water tank 42 described later, and 41 is connected to the fifth advection pipe 40 and sewage in the biological membrane filtration tank 32. Is a second pump that supplies the water to the treated water tank 42 via the fifth advection pipe 40.
[0042]
42 is a treated water tank partitioned through the biofilm filtration tank 32 and the third partition wall 4, and the sewage that has been aerobically decomposed in the biofilm filtration tank 32 and flows in through the fifth advection pipe 40 is converted into sludge and supernatant. To separate.
[0043]
43 is a disinfection tank provided in the upper part of the treated water tank 42, and the supernatant liquid separated in the treated water tank 42 flows in. 44 is a sterilization device provided in the sterilization tank 43, and disinfects the sewage that has flowed into the sterilization tank 43 with chemicals such as chlorine based in the sterilization apparatus 44. 45 is a drain opening communicating with the sterilization tank 43, and the treated water sterilized in the sterilization tank 43 is drained out of the treatment tank 1.
[0044]
46 is a return pipe communicating the treated water tank 42 and the inflow portion of the first advection pipe 8, and 47 is a third air diffuser pipe disposed in the return pipe 46 of the treated water tank 42. The sewage water in the treated water tank 42 is sucked into the return pipe 46 by discharging the air supplied from the fourth blower 48 from the air blower outlet, and connected to the fourth blower 48. It is designed to be transported. The first advection pipe 8 and the return pipe 46 constitute a return path for returning the sewage in the treated water tank 42 to the first anaerobic tank 5.
[0045]
The first blower 21, the second blower 30, the third blower 36, the fourth blower 48, the power supply device 18 and the like are controlled by a control unit (not shown).
[0046]
49 is a first inspection opening provided at a position facing the first anaerobic tank 5 and the second anaerobic tank 24, and 50 is a first lid for closing the first inspection opening 49 so that it can be opened and closed. When the sludge accumulated on the bottoms of the first anaerobic tank 5 and the second anaerobic tank 24 is removed by suction, or when the electrode body 11 is maintained, it opens and closes.
[0047]
Reference numeral 51 denotes a second inspection opening provided at a position facing the biofilm filtration tank 32, and 52 denotes a second lid that closes the second inspection opening 51 so as to be freely opened and closed. 53 is a third inspection opening provided at a position facing the sterilizer 44, and 54 is a third lid for closing the third inspection opening 53 so as to be openable and closable. It opens and closes when refilling.
[0048]
Thus, the sewage discharged from the household flows into the first anaerobic tank 5 from the inflow port 6, and toilet paper or the like in the sewage is collected by the first anaerobic filter bed 7 disposed in the first anaerobic tank 5. Relatively coarse solids and contaminants are removed, and a preliminary treatment for smoothly performing the treatment in each treatment tank that flows later is performed, and the removed solids, contaminants and the first anaerobic filter bed 7 The sewage passing through the sewage is anaerobically decomposed by the action of the anaerobic microorganisms, BOD is reduced, and sludge generated by the sewage decomposition accumulates at the bottom of the first anaerobic tank 5. In addition, organic nitrogen changes to ammonia nitrogen by the action of anaerobic microorganisms.
[0049]
The sewage that has been anaerobically decomposed as new sewage flows into the first anaerobic tank 5 flows from the second advection pipe 22 into the second anaerobic tank 24. The sewage flowing into the second anaerobic tank 24 is anaerobically decomposed by the action of anaerobic microorganisms living in the second anaerobic filter bed 25, and the BOD is reduced and flows into the third advection pipe 26. The sludge generated by this accumulates at the bottom of the second anaerobic tank 24. In addition, organic nitrogen changes to ammonia nitrogen by the action of anaerobic microorganisms.
[0050]
The sewage in the third advection pipe 26 flows from the intake pipe 28 into the fixed pressure feeding chamber 27. When air is supplied from the second blower 30 into the metering pressure feeding chamber 27, the water intake pipe 28 is closed by the check valve 29, and the sewage in the metering pressure feeding chamber 27 is pumped by air pressure, and the fourth advection through the transfer pipe 31. Supplied to tube 34.
[0051]
When a predetermined time elapses from the operation of the second blower 30 and the control unit stops the second blower 30, sewage flows again from the intake pipe 28 into the constant pressure feed chamber 27 as the pressure in the constant pressure feed chamber 27 decreases. The controller causes the second blower 30 to operate intermittently, so that the sewage in the third advection pipe 26 can be supplied to the fourth advection pipe 34 every predetermined time.
[0052]
The sewage supplied into the fourth advection pipe 34 descends through the fourth advection pipe 34, flows out from the lower opening of the fourth advection pipe 34, and rises due to the air supply from the second aeration pipe 35, and biofilm It is aerobically decomposed by the action of aerobic microorganisms adhering to the surface of the filter medium 33, decomposes organic phosphates and the like into orthophosphoric acid, and decomposes ammoniacal nitrogen into nitrate or nitrite nitrogen. Further, a part of the sludge generated by the decomposition of the sewage is captured by the biofilm filter medium 33, and a part thereof is deposited on the bottom of the biofilm filtration tank 32.
[0053]
The sewage that has passed through the biofilm filter medium 33 and has been purified by the biofilm filter medium 33 flows into the treated water tank 42 through the fifth advection pipe 40 by controlling the second pump 41. The sewage supernatant flowing into the treatment water tank 42 flows into the disinfection tank 43 and is sterilized by a sterilizer 44 equipped with chemicals such as chlorine to kill germs such as pathogenic bacteria. Drained.
[0054]
By controlling the fourth blower 48 and discharging the air supplied from the fourth blower 48 from the air outlet of the third air diffuser 47, the sewage in the treated water tank 42 is returned to the first advection pipe 46 via the return pipe 46. 8 will be returned. Nitrate and nitrite nitrogen in the sewage returned to the first advection pipe 8 is reduced by denitrifying bacteria in the sewage flowing from the lower opening of the first advection pipe 8 and diffused into the air as nitrogen gas. At the same time, the sewage in the first advection pipe 8 is supplied with iron ions eluted from the electrode 12 by supplying a constant DC current between the electrodes 12.
[0055]
The iron ions eluted from the electrode 12 are oxidized to trivalent iron ions that react with orthophosphoric acid by the air supplied from the first air diffuser 19, and the electrode 12 is oxidized by the air supplied from the first air diffuser 19. It is washed to prevent adhesion of sludge and the like. Since the orthophosphoric acid in the sewage that has reacted with the iron ions eluted from the electrode 12 becomes a water-insoluble phosphorus compound and precipitates at the bottom of the first anaerobic tank 5, the phosphorus compound can be treated together with the sludge treatment in the first anaerobic tank 5. And sludge removal work can be reduced.
[0056]
The electrode body 11 equipped with the float 9 tries to move in the lateral direction by the air supplied from the first air diffuser 19 or the sewage supplied from the return pipe 46, but the shape of the float 9 is changed to that of the first advection pipe 8. Since the electrode body 11 is substantially matched to the shape of the storage portion, the lateral movement of the electrode body 11 can be prevented by the first advection tube 8, and when the electrode body 11 moves laterally, the terminal 15, the connector 16 and the supply An excessive force is applied to the electric wire 17 or the like to cause a disconnection, thereby preventing power supply from the power supply device 18 to the electrode 12 from being stopped.
[0057]
In order to prevent clogging of the biofilm filter 33, water-insoluble phosphorus compounds, sludge, biofilm, etc. adhering to the biofilm filter medium 33 are controlled by the control unit at a predetermined time to control the third blower 36 so that the air volume is higher than usual. Is supplied from the second air diffuser 35 to clean the biofilm filter medium 33, and the phosphorus compound, sludge, biofilm and the like are peeled off from the biofilm filter medium 33.
[0058]
After returning the air supply amount from the third blower 36 to normal, the control unit controls the first pump 39 to deposit sediments such as phosphorus compounds deposited on the bottom of the biofilm filtration tank 32 together with the sewage, and the sludge return pipe 38. To the first anaerobic tank 5.
[0059]
If the electrode 12 made of iron is immersed in the sewage in the biofilm filtration tank 32 for a long period of time, an oxide film will be generated on the surface of the electrode 12 and it will be in a passive state, and the elution amount of iron ions will gradually decrease. However, dephosphorization performance decreases.
[0060]
Therefore, it is preferable that a constant DC current is supplied between a pair of electrodes made of iron and the polarity of the current is changed every predetermined time. When used for a long period of time, an oxide film is generated on the surface of the iron material on the anode side, but the surface of the iron material on the cathode side is washed with hydrogen gas generated from the iron material on the cathode side, and no oxide film is generated. Therefore, the elution of iron ions can be maintained substantially constant by changing the polarity at a time interval until an oxide film is generated on the iron material surface on the anode side and the elution amount of iron ions decreases. The performance can be kept constant.
[0061]
Moreover, in this structure, since both electrodes are made of iron material, iron ions are always eluted from the iron material serving as the anode side electrode and supplied to the sewage, so that the dephosphorization performance can always be maintained in a constant state. .
[0062]
In the above configuration, in the present embodiment, a DC constant current of 20 mA is supplied. Moreover, the time interval for switching the polarity of the current may be about 30 minutes or more when the actual elution amount with respect to the theoretical iron ion elution value is about 90% or more, and within 15 days when the oxide film is generated on the iron material surface. In order to improve the durability of the switching element that converts the above and to prevent only the iron material that becomes the anode side electrode from decreasing due to the elution of iron ions, and to make both electrodes substantially uniform reduced state, within 10 days, Preferably, within 5 days, in the present embodiment, the polarity is changed every 6 hours.
[0063]
Alternatively, an iron material may be used at least on the anode side of the electrode, a constant DC current may be supplied to both electrodes, and the supply current may be increased in a pulse shape every predetermined time. In this configuration, by increasing the supply current in a pulsed manner, the oxide film generated on the surface of the anode-side iron material can be peeled off, and the elution of iron ions is maintained substantially constant, and the dephosphorization performance is kept constant. Can be maintained.
[0064]
In the above configuration, in the present embodiment, a 20 mA DC constant current is supplied, and a pulse current of 3 to 4 A is supplied for a total of 24 minutes per 4 hours.
[0065]
Furthermore, the two types of supply current configurations described above are combined, a constant DC current is supplied between a pair of electrodes made of iron material, the polarity of the current is changed every predetermined time, and the supply current is increased in pulses. Also good. When the time until the polarity change is long, an oxide film is formed on the surface of the iron material on the anode side. By changing the polarity, the oxide film can be removed by washing with hydrogen gas. Some time is required until peeling, and since the electric resistance until the oxide film is peeled off is large, power consumption may increase.
[0066]
Therefore, by increasing the supply current in a pulsed manner as described above, the oxide film on the iron material surface converted from the anode to the cathode can be removed in a short time, and an increase in power consumption can be prevented.
[0067]
In this embodiment, the sewage in the treated water tank 42 is returned to the first anaerobic tank 5 via the return pipe 46. However, the sewage in the biofilm filtration tank 32 is returned to the first anaerobic tank 5 via the return pipe 46. It is good also as a structure which returns to the anaerobic tank 5. FIG.
[0068]
FIG. 5 shows a second embodiment, in which a net-like communication portion 55 is provided on the side wall above the first anaerobic filter bed 7 of the first advection pipe 8 arranged in the first embodiment. ing.
[0069]
By adopting this configuration, most of the sewage supplied from the return pipe 46 and eluting iron ions from the electrode 12 flows into the first anaerobic filter bed 7 from the communicating portion 55, and therefore a large amount exists in the first anaerobic filter bed 7. It can be denitrified by denitrifying bacteria to improve nitrogen removal efficiency, and the phosphorus compound can be flocked by the SS component in the first anaerobic filter bed 7 to promote aggregation of the phosphorus compound.
[0070]
FIG. 6 shows a third embodiment, in which the electrode body 11 fitted with the float 9 in the first embodiment is arranged in a first advection pipe 8 provided in the first anaerobic tank 5. Instead, the electrode body 11 equipped with the float 9 is disposed in the third advection pipe 26 provided in the second anaerobic tank 24, and the float 9 is accommodated in the third advection pipe 26. It is the structure which provided the accommodating part which prevents the movement to a horizontal direction.
[0071]
By adopting this configuration, the configuration can be simplified, and stable iron ion elution can be performed regardless of fluctuations in the sewage water level in the second anaerobic tank 24. The phosphorus compound generated by the reaction with the sludge treatment can be performed together with the sludge treatment in the second anaerobic tank 24 or the sludge treatment in the biofilm filtration tank 32.
[0072]
Furthermore, by supplying the sewage in the third advection pipe 26 made alkaline by the electrolysis of the electrode 12 to the aerobic microorganisms whose activity decreases due to acidification accompanying the sewage treatment in the biofilm filtration tank 32, aerobic The microorganisms can be activated to prevent a decrease in the sewage treatment capacity in the biofilm filtration tank 32.
[0073]
Further, orthophosphoric acid re-eluted in the anaerobic state from the phosphorus compound deposited in the first anaerobic tank 5 or the second anaerobic tank 24 is surely regarded as iron ion eluted from the electrode 12 when passing through the first advection pipe 26. Since it is removed again as a phosphorus compound in response to the reaction, phosphorus removal efficiency can be improved.
[0074]
Furthermore, the electrode body 11 equipped with the float 9 tries to move in the lateral direction by the air supplied from the first air diffuser tube 19, but the lateral movement of the electrode body 11 is caused by the storage portion of the third advection tube 26. As the electrode body 11 moves in the lateral direction, an excessive force is applied to the terminal 15, the connector 17, the power supply line 17, etc., and the power is not supplied from the power supply device 18 to the electrode 12. Is preventing.
[0075]
FIG. 7 shows the fourth embodiment. In the first embodiment, the electrode body 11 fitted with the float 9 is arranged in the first advection pipe 8 provided in the first anaerobic tank 5. Instead, the electrode body 11 fitted with the float 9 is disposed in a storage portion provided in the fourth advection pipe 34 provided in the biofilm filtration tank 32 and having an opening above the second air diffusion pipe 34, The float 9 has a configuration in which the shape of the float 9 is substantially matched with the shape of the storage portion of the fourth advection tube 34.
[0076]
With this configuration, air can be supplied from the first air diffuser 19 using the third blower 36 that supplies air to the second air diffuser 35, and the configuration can be simplified. Stable iron ion elution can be performed regardless of fluctuations in the sewage water level in the biofilm filtration tank 32, and sludge treatment in the biofilm filtration tank 32 with phosphorus compounds generated by the reaction with iron ions eluted from the electrode 12 Can be done with.
[0077]
Furthermore, by supplying sewage water that has become alkaline due to the electrolysis of the electrode 12 to aerobic microorganisms whose activity decreases due to acidification associated with sewage treatment in the biofilm filtration tank 32, the aerobic microorganisms are activated and biological A decrease in the sewage treatment capacity of the membrane filtration tank 32 can be prevented.
[0078]
The electrode body 11 fitted with the float 9 tends to move laterally by the air supplied from the first air diffuser 19, but the shape of the float 9 substantially matches the shape of the storage part of the fourth advection tube 34. Therefore, the movement of the electrode body 11 in the lateral direction can be prevented by the fourth advection tube 34, and the electrode body 11 moves in the lateral direction, so that the terminal 15, the connector 17, the power supply line 17, etc. are impossible. It is possible to prevent the power supply device 18 from stopping the power supply from the power supply device 18 to the electrode 12 due to the applied force, and the iron ions eluted from the electrode 12 to be efficiently generated in the biofilm filtration tank 32 by the convection of the sewage through the second air diffuser 35 It can be well stirred and the phosphorus removal performance can be improved.
[0079]
In the present embodiment, the electrode 12 is washed by the first air diffuser 19 and the iron ions eluted from the electrode 12 are oxidized. As shown in FIG. 8 or FIG. 9, the first air diffuser is used. 19 may be removed and the electrode 12 may be cleaned using the second air diffuser 35 and the iron ions eluted from the electrode 12 may be oxidized.
[0080]
FIG. 10 shows a fifth embodiment. In the first embodiment, the wastewater treated in the second anaerobic tank 24 is treated by the biofilm filtration tank 32 and the treated water tank 42. In the first advection pipe 22 provided in the first anaerobic tank 5, the sewage treated in the tank 24 is treated by the contact aeration tank 56 and the sedimentation separation tank 57. In addition to the configuration provided in FIG. 1, the electrode body 11 having the float 9 mounted thereon is provided in the storage portion formed in the partition wall 58 provided in the sedimentation separation tank 57, and the shape of the float 9 is changed to the partition wall. The sewage in the partition wall 58 is returned to the first anaerobic tank 5 by a return pipe 46.
[0081]
With this configuration, the configuration can be simplified, and stable iron ion elution can be performed regardless of fluctuations in the sewage water level in the sedimentation separation tank 57.
[0082]
Further, the phosphorus compound generated in the precipitation separation tank 57 due to the reaction with iron ions eluted from the electrode 12 is formed at the bottom of the precipitation separation tank 57 and inclined to the contact aeration tank 56 side and the lower part of the third partition wall 4. Since it is returned to the contact aeration tank 56 by the communication port 59 formed in the above, sludge treatment work can be reduced.
[0083]
In addition, the sewage containing iron ions eluted in the partition wall 58 is returned to the first anaerobic tank 5, so that the phosphorus compound produced by the reaction between iron ions and orthophosphoric acid is caused by the SS component in the first anaerobic tank 5. Since it is flocked, aggregation of the phosphorus compound can be promoted, and the iron ions in the return pipe 46 are converted into trivalent ions that react with orthophosphoric acid using the air supplied from the third air diffuser 47. Since it can oxidize reliably, phosphorus removal efficiency can be improved.
[0084]
In the present embodiment, the sewage in the sedimentation separation tank 57 is returned to the first anaerobic tank 5 by the air lift pump configured from the return pipe 46, the third diffuser pipe 47, and the fourth blower 48. Even when the sewage in the sedimentation separation tank 57 is returned to the first anaerobic tank 5 by the pneumatic feed pump, the same effects as in the present embodiment can be obtained.
[0085]
In the embodiment of the present invention, an iron material is used for both electrodes as an electrode for supplying a DC constant current to elute iron ions. However, an iron material is used for the anode side electrode, and the cathode side electrode is made of titanium, platinum, or the like. Alternatively, the insoluble material may be used.
[0086]
Furthermore, in the embodiment of the present invention, an iron material is used for both electrodes as an electrode for supplying a constant DC current and eluting iron ions, but a configuration using aluminum may also be used.
[0087]
Further, in the embodiment of the present invention, the configuration in which the electrode 12 equipped with the float 9 is disposed in each tank has been described in detail. However, the return pipe 46 for returning the sewage in the treated water tank 42 to the first anaerobic tank 5. It is good also as a structure which arrange | positions the electrode 12 which attached the float 9 in the inside.
[0088]
【The invention's effect】
  According to the configuration of claim 1 of the present invention,An electrode equipped with a float is installed in the partition where the sewage in the aerobic tank, sedimentation separation tank or treated water tank is returned via the return path, so that the configuration can be simplified and the sewage water level is related. The phosphorus removal performance can be improved by reacting ions that elute stably from the electrode and orthophosphoric acid returned from the return path.
[0090]
Furthermore, the removal of the phosphorus compound generated by the reaction with ions eluted from the electrode can be performed together with the sludge treatment in the anaerobic tank, and the sludge treatment work can be reduced.
[0091]
  Of the present inventionClaim 2According to the configuration, since the electrode equipped with the float is disposed in the partition where the sewage in the aerobic tank, the sedimentation separation tank, or the treated water tank is returned through the return path, and at the lower part of the discharge port of the return path, Simplification can be achieved, and the phosphorus removal performance can be improved by promoting the reaction between ions that are stably eluted from the electrode regardless of the sewage water level and the orthophosphoric acid returned from the return path.
[0092]
Furthermore, the removal of the phosphorus compound generated by the reaction with ions eluted from the electrode can be performed together with the sludge treatment in the anaerobic tank, and the sludge treatment work can be reduced.
[0093]
  Of the present inventionClaim 3According to the configuration, the sewage supplied with iron ions flows out to the anaerobic filter bed through the communication part of the partitioning part, and thus the nitrogen removal efficiency can be improved by the denitrifying bacteria present in the anaerobic filter bed. The phosphorous compound is flocked by the SS component in the anaerobic filter bed to promote the aggregation of the phosphorous compound, and the phosphorus removal efficiency can be further improved.
[0094]
  Of the present inventionClaim 4According to the configuration, since the storage portion that prevents the float from moving in the lateral direction is provided in the partition portion, the movement of the electrode can be prevented by the partition portion, and the electrode moves to supply power to the electrode. Therefore, it is possible to prevent the ion from being released due to an unreasonable force being applied, and to prevent ion elution, and stable ion elution can be performed.
[0095]
  Of the present inventionClaim 5According to the configuration, since the electrode equipped with the float is disposed in the return path soaked in the sewage in the aerobic tank, the sedimentation separation tank or the treated water tank, the configuration can be simplified and the sewage water level can be reduced. Irrespective of the ions that elute stably from the electrode, the phosphorus removal performance can be improved by reacting with the orthophosphoric acid flowing into the return tube.
[0096]
Furthermore, the removal of the phosphorus compound generated by the reaction with the ions eluted from the electrode can be performed together with the sludge treatment in the aerobic tank, the precipitation separation tank or the treated water tank, and the sludge treatment work can be reduced. Play.
[0097]
  Of the present inventionClaim 6According to the configuration, since the electrode equipped with a float is arranged in the return path that soaks in the sewage in the anaerobic tank, the configuration can be simplified, and the elution can be performed stably from the electrode regardless of the sewage water level. The phosphorus removal performance can be improved by reacting the ions to be reacted with orthophosphoric acid returned from the return tube.
[0098]
Furthermore, the removal of the phosphorus compound generated by the reaction with ions eluted from the electrode can be performed together with the sludge treatment in the anaerobic tank, and the sludge treatment work can be reduced.
[0099]
  Of the present inventionClaim 7According to the configuration, since the electrode equipped with the float is disposed in the storage part formed in the return path for returning the sewage in the aerobic tank, the sedimentation separation tank or the treated water tank to the anaerobic tank, the configuration is simplified. In addition, the phosphorous removal performance can be improved by reacting ions that are stably eluted from the electrode regardless of the sewage water level with the orthophosphoric acid in the return pipe.
[0100]
  Of the present inventionClaim 8According to the construction of the present invention, since the housing portion for preventing the float from moving in the lateral direction is provided in the return pipe, the movement of the electrode can be prevented by the return pipe, and the electrode moves to supply power to the electrode. Therefore, it is possible to prevent the ion elution from being performed due to an unreasonable force being applied to the wire and to achieve stable ion elution.
[0101]
  Of the present inventionClaim 9According to the configuration, the configuration can be simplified by providing the electrode equipped with the float in the advection pipe for transferring the sewage in the second anaerobic tank to the aerobic tank, and in the second anaerobic tank. Phosphorus removal performance can be improved by reacting ions eluting from the electrode and orthophosphoric acid returned from the return path regardless of the sewage water level.
[0102]
Furthermore, the removal of the phosphorus compound generated by the reaction with the ions eluted from the electrode can be performed together with the sludge treatment in the second anaerobic tank or the aerobic tank, the sludge treatment work can be reduced, and in the anaerobic state Phosphate ions re-eluting from the phosphorus compound can be removed by reacting with ions eluted from the electrode, and the phosphorus removal performance can be improved.
[0103]
Further, by supplying the sewage changed to alkaline by electrolysis of the electrode to the aerobic tank, it is possible to prevent a decrease in the sewage treatment capacity of the aerobic tank.
[0104]
  Of the present inventionClaim 10According to the configuration, since the accommodating portion for preventing the float from moving in the lateral direction is provided in the convection tube, the movement of the electrode can be prevented by the convection tube, and the electrode moves to supply power to the electrode. Therefore, it is possible to prevent the ion elution from being performed due to an unreasonable force being applied to the wire and to achieve stable ion elution.
[0105]
  Of the present inventionClaim 11According to the configuration, the electrode equipped with the float is provided in the aerobic tank, and the electrode can be cleaned by using the air diffuser that supplies air to the aerobic tank, so that the configuration can be simplified. In addition, stable ion elution can be performed regardless of fluctuations in the sewage water level in the aerobic tank.
[0106]
Furthermore, the removal of phosphorus compounds generated by reaction with ions eluted from the electrode can be performed together with the sludge treatment in the aerobic tank, the sludge treatment work can be reduced, and the electrode is made alkaline by electrolysis of the electrode. By supplying the sewage to the aerobic tank, there is an effect that it is possible to prevent a decrease in the sewage treatment capacity of the aerobic tank.
[0107]
  Of the present inventionClaim 12According to the configuration, the electrode equipped with the float is provided in the aerobic tank, and the electrode is washed by the second air diffuser tube, thereby reliably washing the electrode and stabilizing ion elution. Can be simplified, and stable ion elution can be performed regardless of fluctuations in the sewage water level in the aerobic tank.
[0108]
Furthermore, the removal of phosphorus compounds generated by reaction with ions eluted from the electrode can be performed together with the sludge treatment in the aerobic tank, the sludge treatment work can be reduced, and the electrode is made alkaline by electrolysis of the electrode. By supplying the sewage to the aerobic tank, there is an effect that it is possible to prevent a decrease in the sewage treatment capacity of the aerobic tank.
[0109]
  Of the present inventionClaim 13According to the construction of the present invention, since the housing portion for preventing the float from moving in the lateral direction is provided in the return pipe, the movement of the electrode can be prevented by the return pipe, and the electrode moves to supply power to the electrode. Therefore, it is possible to prevent the ion from being released due to an excessive force applied to the electrode and to prevent ion elution, and it is possible to perform stable ion elution. Stirring can be carried out efficiently in the air tank, and the phosphorus removal performance can be improved.
[0110]
  Of the present inventionClaim 14According to the configuration of the present invention, it is possible to simplify the configuration by disposing an electrode equipped with a float in the sedimentation separation tank, and perform stable ion elution regardless of fluctuations in the sewage water level in the precipitation separation tank. be able to.
[0111]
Furthermore, the removal of the phosphorus compound generated by the reaction with the ions eluted from the electrode can be performed together with the sewage treatment in the precipitation separation tank, and the sludge treatment work can be reduced.
[0112]
  Of the present inventionClaim 15According to the configuration of the present invention, it is possible to simplify the configuration by disposing an electrode equipped with a float in the sedimentation separation tank, and perform stable ion elution regardless of fluctuations in the sewage water level in the precipitation separation tank. be able to.
[0113]
Furthermore, the removal of phosphorus compounds generated by reaction with ions eluted from the electrode can be performed simultaneously with the sludge treatment in the precipitation separation tank, so that the sludge treatment work can be reduced and eluted in the precipitation separation tank. By returning the sewage containing ions to the anaerobic tank, the phosphorus compound produced by the reaction between the ions eluted from the electrode and orthophosphoric acid is flocked by the SS component in the anaerobic tank, thus promoting the aggregation of the phosphorus compound. Thus, the phosphorus removal performance can be improved.
[Brief description of the drawings]
FIG. 1 is a sectional view of a sewage treatment apparatus according to a first embodiment of the present invention.
FIG. 2 is a cross-sectional view seen from the other direction.
FIG. 3 is a perspective view of the elution apparatus.
FIG. 4 is a perspective view of the electrode body.
FIG. 5 is a perspective view of an elution apparatus according to a second embodiment of the present invention.
FIG. 6 is a sectional view of a sewage treatment apparatus according to a third embodiment of the present invention.
FIG. 7 is a sectional view of a sewage treatment apparatus according to a fourth embodiment of the present invention.
FIG. 8 is a cross-sectional view of another embodiment of the sewage treatment apparatus.
FIG. 9 is a cross-sectional view seen from the other direction.
FIG. 10 is a cross-sectional view of a sewage treatment apparatus according to a fifth embodiment of the present invention.
[Explanation of symbols]
5 First anaerobic tank (anaerobic tank)
8 First advection pipe
9 Float
11 Second anaerobic tank (anaerobic tank)
12 electrodes
16 Power supply
32 Biofilm filtration tank (aerobic tank)
42 Treated water tank
46 Return pipe (return path)
56 Contact aeration tank
57 Precipitation separation tank

Claims (15)

  An anaerobic tank into which domestic wastewater flows, an aerobic tank into which sewage treated in the anaerobic tank flows, a precipitation separation tank or a treated water tank into which sewage treated in the aerobic tank flows, and the aerobic tank Or a return path for returning the sewage in the sedimentation separation tank or the treated water tank to the anaerobic tank, and providing a partition in the anaerobic tank for separating the sewage returned from the return path from household wastewater. A sewage treatment apparatus, wherein an electrode made of an iron material or aluminum that elutes aluminum ions is disposed in a partition portion, and a float is attached to the electrode.   An anaerobic tank into which domestic wastewater flows, an aerobic tank into which sewage treated in the anaerobic tank flows, a precipitation separation tank or a treated water tank into which sewage treated in the aerobic tank flows, and the aerobic tank Or a return path for returning the sewage in the sedimentation separation tank or the treated water tank to the anaerobic tank, and providing a partition in the anaerobic tank for separating the sewage returned from the return path from household wastewater. An sewage treatment apparatus characterized in that an electrode made of an iron material or aluminum that elutes aluminum ions is disposed in a partition part and at a position removed from directly under a discharge port of a return path, and a float is attached to the electrode.   The sewage treatment apparatus according to claim 1 or 2, wherein an anaerobic filter bed for precipitating and separating domestic wastewater is provided in the anaerobic tank, and a communicating part communicating with the anaerobic filter bed is provided in the partition part.   The sewage treatment apparatus according to claim 2, wherein a float is stored in the partition part and a storage part for preventing the float from moving in a lateral direction is provided.   An anaerobic tank into which domestic wastewater flows, an aerobic tank into which sewage treated in the anaerobic tank flows, a precipitation separation tank or a treated water tank into which sewage treated in the aerobic tank flows, and the aerobic tank Alternatively, it is provided with a return path for returning the sewage in the precipitation separation tank or the treated water tank to the anaerobic tank, and iron ions or aluminum ions are eluted by energization in the return path immersed in the aerobic tank, the precipitation separation tank or the treated water tank. A sewage treatment apparatus comprising an electrode made of iron or aluminum and a float attached to the electrode.   An anaerobic tank into which domestic wastewater flows, an aerobic tank into which sewage treated in the anaerobic tank flows, a precipitation separation tank or a treated water tank into which sewage treated in the aerobic tank flows, and the aerobic tank Alternatively, a return path for returning the sewage in the sedimentation separation tank or treated water tank to the anaerobic tank, and an electrode made of iron or aluminum that elutes iron ions or aluminum ions when energized is placed in the return path immersed in the anaerobic tank. And a sewage treatment apparatus characterized in that a float is attached to the electrode.   An anaerobic tank into which domestic wastewater flows, an aerobic tank into which sewage treated in the anaerobic tank flows, a precipitation separation tank or a treated water tank into which sewage treated in the aerobic tank flows, and the aerobic tank Alternatively, a sewage storage section provided with a return path for returning the sewage in the sedimentation separation tank or treated water tank to the anaerobic tank, and an electrode made of iron or aluminum that elutes iron ions or aluminum ions when energized is provided in the return path And a sewage treatment apparatus, wherein a float is attached to the electrode.   The sewage treatment apparatus according to any one of claims 5 to 7, further comprising a storage unit that stores the float in the return pipe and prevents the float from moving in a lateral direction.   A first anaerobic tank into which domestic wastewater flows, a second anaerobic tank into which sewage treated in the first anaerobic tank flows, and sewage treated in the second anaerobic tank provided in the second anaerobic tank An inflow advection pipe, an aerobic tank into which sewage in the advection pipe flows in, a precipitation separation tank or a treatment water tank into which sewage treated in the aerobic tank flows, and the aerobic tank, the precipitation separation tank or the treatment water tank A return path for returning the sewage inside to the first anaerobic tank, and an electrode made of iron or aluminum that elutes iron ions or aluminum ions when energized is disposed in the advection tube, and a float is attached to the electrode. A featured sewage treatment device.   The sewage treatment apparatus according to claim 9, wherein a float is accommodated in the advection pipe, and a storage unit that prevents the float from moving in a lateral direction is provided.   An anaerobic tank into which domestic wastewater flows, an aerobic tank into which sewage treated in the anaerobic tank flows, a diffuser pipe disposed in the aerobic tank and having an air outlet, and communicating with the diffuser pipe An air blower that supplies air into the aerobic tank, and an electrode made of iron or aluminum that elutes iron ions or aluminum ions when energized is disposed in the aerobic tank and above the air diffuser, A sewage treatment apparatus, wherein a float is attached to an electrode.   An anaerobic tank into which domestic wastewater flows, an aerobic tank into which sewage treated in the anaerobic tank flows, a diffuser pipe disposed in the aerobic tank and having an air outlet, and communicating with the diffuser pipe A blower for supplying air into the aerobic tank, and an electrode made of iron or aluminum that elutes iron ions or aluminum ions when energized is disposed in the aerobic tank, and a float is attached to the electrode, A sewage treatment apparatus, wherein a second air diffuser communicating with a blower is disposed below the electrode.   The aerobic tank is provided with a convection pipe for transferring sewage flowing from the anaerobic tank to the lower part of the aerobic tank, an electrode equipped with a float is provided in the convection pipe, and the lower opening of the convection pipe is arranged above the aeration pipe. The sewage treatment apparatus according to claim 11 or 12, wherein a sewage treatment apparatus is provided, wherein a float is accommodated in the advection pipe, and a storage portion for preventing the float from moving in the lateral direction is provided.   An anaerobic tank into which domestic wastewater flows, an aerobic tank into which sewage treated in the anaerobic tank flows in, and a precipitation separation tank into which sewage treated in the aerobic tank flows, An sewage treatment apparatus, wherein an electrode made of an iron material or aluminum that elutes aluminum ions is disposed in the precipitation separation tank, and a float is attached to the electrode.   An anaerobic tank into which domestic wastewater flows, an aerobic tank into which sewage treated in the anaerobic tank flows in, and a precipitation separation tank into which sewage treated in the aerobic tank flows, An electrode made of an iron material or aluminum that elutes aluminum ions is arranged in the precipitation separation tank, and a float is attached to the electrode, and a return means is provided for returning the sewage containing ions eluting from the electrode to the anaerobic tank. Sewage treatment equipment characterized by.

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