JP4687597B2 - Activated sludge treatment method and activated sludge treatment apparatus for wastewater - Google Patents

Description

  The present invention relates to an activated sludge treatment method and an activated sludge treatment apparatus for wastewater, and in particular, activated sludge treatment for wastewater that can efficiently remove nitrogen and phosphorus without the growth of filamentous bacteria that make it difficult to separate activated sludge from wastewater. The present invention relates to a method and an activated sludge treatment apparatus.

  In the treatment of wastewater using activated sludge, bacteria that act as denitrification of nitrate nitrogen, nitrification of ammonia nitrogen, and incorporation of phosphate phosphorus into activated sludge progress by bacteria in activated sludge. Each has a different appropriate environment. Denitrifying bacteria that perform denitrification reduce nitrate nitrogen (nitric acid, nitrous acid) to nitrogen under anaerobic conditions, and nitrifying bacteria that perform nitrification oxidize ammonia nitrogen under aerobic conditions. Nitrate ions. Phosphorus-accumulating bacteria that take up phosphate phosphorus take up phosphorus under aerobic conditions and release phosphorus under anaerobic conditions. In particular, when there is no nitrate nitrogen in the environment, the organic matter is taken up under anaerobic conditions, which is advantageous for growth.

There are two types of activated sludge treatment of wastewater: batch treatment and continuous treatment. In batch treatment, ammonia is nitrified and dehydrated by switching the environment alternately between anaerobic and aerobic conditions. It is a method of removing ammonia in waste water by performing nitrogen treatment. In the continuous treatment, the waste water is continuously treated as the waste water gradually moves through a plurality of continuous tanks with different environments. Is the method. The following patent document 1 discloses the activated sludge treatment method of waste water by a batch type.
JP-A-8-267087

  In order for denitrification by denitrifying bacteria to proceed, organic matter as nutrients is necessary, but after nitrification has proceeded under aerobic conditions, organic matter in the wastewater has been decomposed and lost, so sludge in batch processing In order to repeat the process, it is necessary to add organic matter from the outside as in Patent Document 1 described above. When this addition is performed using organic matter in the wastewater, nitric acid due to ammonia contained in the additional wastewater remains after the treatment. For this reason, in order to reduce the concentration of residual nitric acid in batch processing, the waste water is partially discharged / replenished. However, the nitric acid concentration is not zero, and nitric acid denitrification has been completed. Since the organic matter is consumed before doing so, phosphorus accumulating bacteria do not work effectively. Therefore, it is practically difficult to remove both nitrogen and phosphorus.

  For this reason, continuous treatment has been adopted as a treatment method for removing both nitrogen and phosphorus, by repeating anaerobic conditions and aerobic conditions, and providing a partial wastewater reflux path. Nitrogen and phosphorus are being removed.

  However, in the continuous treatment, there is a problem that filamentous bacteria that are difficult to propagate in the batch method propagate to form filamentous bulking in the wastewater, making it difficult to settle and separate the activated sludge from the wastewater. In order to solve this, it is necessary to make various improvements in the structural design so that the backflow of wastewater does not easily occur. However, it is difficult to determine the optimum dimensions and structure of each tank, and the design is performed in anticipation of the change width. Then, it becomes easy to use excessive facilities, the construction cost rises, and problems such as blockage of operations such as blockage of the flow path occur.

  The present invention can easily change and optimize conditions such as time for each process of sludge treatment without requiring complicated changes in processes and equipment, and prevent wastewater from growing while preventing the growth of filamentous bacteria making sludge separation difficult. It is an object of the present invention to provide an activated sludge treatment method for wastewater that can efficiently remove nitrogen and efficiently remove phosphorus.

  In addition, the present invention is an activated sludge treatment of wastewater that has a simple structure and can efficiently remove nitrogen from wastewater while preventing the growth of filamentous bacteria that makes sludge separation difficult, and is also effective for efficient removal of phosphorus. It is an object to provide an apparatus.

  In order to solve the above-mentioned problems, the present inventors have conducted extensive research, and as a result, improved batch processing and processing using multiple tanks, nitrogen and phosphorus can be efficiently removed, and filamentous bacteria can be removed. The present inventors have found that the problem due to breeding can be solved, and have completed the present invention.

According to one aspect of the present invention, an activated sludge treatment method for wastewater includes denitrification of nitrate nitrogen under anaerobic conditions and ammonia state under aerobic conditions using activated sludge as wastewater in a single treatment tank. Sludge treatment for nitrifying nitrogen; Sorting operation for removing a part of treated wastewater containing activated sludge after the sludge treatment from the treatment tank to the separation tank ; Part of the treated wastewater taken out to the separation tank separation operation to separate from the collecting and activated sludge treated effluent contained; a portion of the activated sludge separation, and supplying a new waste water in the pretreatment tank aft under anaerobic conditions, of the activated sludge The remaining part is a pretreatment to be discarded together with the taken-in phosphorus ; and new wastewater containing the activated sludge after the pretreatment is transferred from the pretreatment tank to the remaining wastewater to be treated in the treatment tank after the sorting operation. Having a reflux operation to add, the sludge treatment, the fractionation operation, Serial separation operation, and summarized in that repeating the lower processing and the return operation.

  In the above pretreatment, denitrification of residual nitrate nitrogen of the part of activated sludge is substantially completed using organic substances contained in the new wastewater, whereby phosphorous phosphorus is added together with the nitrification in the sludge treatment. Is taken into activated sludge.

Moreover, according to one aspect of the present invention, the activated sludge treatment apparatus for waste water is a treatment tank for containing waste water and activated sludge; anaerobic using the activated sludge for the waste water contained in the treatment tank . A treatment mechanism provided in the treatment tank, having an oxygen supply means capable of switching operation for performing sludge treatment for denitrification of nitrate nitrogen under conditions and nitrification of ammonia nitrogen under aerobic conditions ; Drainage means for discharging a part of the treated wastewater containing the activated sludge treated by the sludge from the treatment tank; containing the part of the treated wastewater discharged from the treatment tank; A separation tank that collects and separates the wastewater to be treated and discards the wastewater to be treated ; a pretreatment tank for supplying fresh wastewater to a part of the separated activated sludge to be subjected to anaerobic conditions; and new wherein in the pretreatment tank And summarized in that with a recirculation means for supplying the activated sludge wastewater was placed under anaerobic conditions is supplied to the processing bath.

  The amount of the new wastewater supplied in the pretreatment means is an amount capable of supplying sufficient organic matter to substantially complete the denitrification of residual nitrate nitrogen in the part of the activated sludge, In the sludge treatment performed by the treatment mechanism, phosphate phosphorus is taken into the activated sludge together with the nitrification.

  According to the present invention, nitrogen and phosphorus can be suitably removed according to a batch process, so that the growth of filamentous bacteria that inhibit the sludge sedimentation can be prevented and wastewater treatment can be performed efficiently. Moreover, the improvement in the activated sludge treatment apparatus for performing wastewater treatment is simple, and does not require complicated operation and process management, and can easily and efficiently proceed with wastewater treatment. In addition, when the water quality of the wastewater changes, it can be flexibly dealt with by changing the time spent for each process such as denitrification, nitrification, sedimentation, etc., so there is no need for large-scale equipment modification.

  Filamentous bacteria that impede sludge settling and separation tend to propagate in relation to the wastewater that is circulated in the continuous treatment of wastewater, and the concentration of organic matter is low (organic concentration is low) : About 13.6 mg-COD / L or less) It was found that filamentous bacteria propagate predominantly over floc-producing bacteria in wastewater under microaerobic conditions. That is, in a portion where waste water that has been nitrified under aerobic conditions is added to waste water under anaerobic conditions with a high organic concentration, the concentration of organic matter is low and filamentous bacteria are likely to propagate. In addition, since the anaerobic wastewater and the aerobic wastewater are mixed in a large aquarium, wastewater with a microaerobic condition is always generated, and filamentous bacteria are also likely to propagate. Based on this, in continuous treatment where it is difficult to change the organic concentration of wastewater abruptly and it is difficult to prevent microaerobic conditions, the condition that filamentous bacteria are likely to grow inevitably occurs, preventing the growth of filamentous bacteria. It is difficult to do. However, the formation of such a gradual concentration gradient can be avoided in a batch process in which wastewater is supplied all at once in a short period of time, and the microaerobic state is also switched between an aerobic condition and an anaerobic condition. Since it can occur only in a very short time, if it can be improved so that both nitrogen removal and phosphorus removal can proceed in batch processing, both nitrogen and phosphorus can be efficiently removed from wastewater while solving the problem of filamentous bacteria.

  The present invention relates to an improvement of the batch-type treatment as described above, and uses a means for applying a pretreatment for making the reproduction of phosphorus-accumulating bacteria dominant in addition to the batch-type treatment bath for performing activated sludge treatment. A part of the activated sludge is taken out from the wastewater, and the phosphorus accumulation bacteria are preferentially propagated by the pretreatment means to increase the phosphorus accumulation capacity of the activated sludge, and this is returned to the treatment tank to increase the phosphorus accumulation capacity of the wastewater. Perform removal. Hereinafter, the activated sludge treatment method of the present invention and the activated sludge treatment apparatus used therefor will be described in detail.

  FIG. 1 shows an embodiment of an activated sludge treatment apparatus for wastewater according to the present invention. The treatment apparatus 1 includes a treatment tank 10 for storing waste water W and activated sludge S, and a pipe 20 and a pump which are drainage means for discharging a part of the waste water W to be treated containing activated sludge S from the treatment tank 10. 21, a separation tank 30 and a pump 31 provided as separation means for collecting and separating the activated sludge S contained in the treated wastewater W discharged from the treatment tank 10 from the treated wastewater W, and one of the separated activated sludge S A new waste water Wa is supplied to the section, and the lower treatment tank 40 is a lower treatment means for performing the lower treatment under anaerobic conditions, and the new waste water Wa and the activated sludge S after the lower treatment are supplied to the treatment tank 10. It has the piping 50 and the pump 51 which are the recirculation | reflux means for supplying.

  The treatment tank 10 is equipped with a treatment mechanism for performing sludge treatment of waste water, and the treatment mechanism is an oxygen supply means capable of switching operation to adjust waste water and activated sludge in the treatment tank to an aerobic condition. An aeration device 11 and a stirring device 12 for mixing waste water and activated sludge. The sludge treatment performed in the treatment tank 10 includes an anaerobic process for adjusting wastewater to an anaerobic condition and an aerobic process for adjusting subsequent wastewater to an aerobic condition. In the anaerobic process, the waste water W and the activated sludge S are mixed in the treatment tank 10 by the stirring device 12, and at this time, the inside of the tank is shut off from outside air as necessary in order to obtain an anaerobic state. If the dissolved oxygen is negligible, it is not necessary to shut off the outside air. In this step, nitrate nitrogen in the wastewater W is reduced by the activity of the denitrifying bacteria and released from the wastewater W as nitrogen. That is, denitrification proceeds. Agitation prevents local water quality changes in the wastewater. If denitrification is completed and nitrate nitrogen disappears, the phosphorus accumulating bacteria are activated and the phosphorus accumulating bacteria become dominant in reproduction. In the next aerobic process, the stirrer 12 is stopped and air is blown into the waste water W and the activated sludge S from the aerator 11 so as to be in an aerobic state, and the ammonia nitrogen in the waste water W is oxidized by nitrifying bacteria and nitric acid. Produce. At this time, the phosphorus-accumulating bacteria propagate using the organic matter that has been taken in and also take up phosphorous phosphorus. At this stage, the phosphorus-accumulating bacteria must be contained in the sludge so that the removal of phosphate phosphorus in the wastewater can proceed satisfactorily. In the treatment tank 10, the opportunity for the phosphorus-accumulating bacteria to have an advantage in reproduction is extremely limited. Therefore, it is necessary to separately perform a process for enabling the propagation of phosphorus accumulating bacteria in the sludge and the enhancement of the phosphorus uptake ability. In addition, if the bacteria that have incorporated phosphorus are separated and discarded from the wastewater, they will be released again into the wastewater under anaerobic conditions, so that it is necessary to dispose of sludge for phosphorus removal as the wastewater treatment is repeated. These are performed in the separation tank 30 and the pretreatment tank 40 described later.

  Part of the waste water W and activated sludge S after denitrification, nitrification and phosphorus uptake in the treatment tank 10 are discharged by the pipe 20 and the pump 21 extending from the treatment tank 10 and accommodated in the separation tank 30. Is done.

  In the separation tank 30, waste water containing sludge separated from the treatment tank 10 is separated into activated sludge S and waste water W. In this embodiment, activated sludge S is collected at the bottom of the separation tank by sedimentation separation. As the separation means, a mechanical separation means for scraping and collecting sludge such as rake may be used. The waste water W separated from the activated sludge S is discarded from the separation tank 30 via the pipe 32 using the pump 31. The activated sludge S remains in the separation tank 30 in the state of the concentrated sludge containing the waste water W. From the viewpoint of the efficiency of the subsequent pretreatment, the separation efficiency is increased as much as possible so that the waste water W remaining in the activated sludge S is small. It is desirable.

  In this embodiment, a pipe 41 extending to the pretreatment tank 40 is connected to the separation tank 30, and a part of the concentrated sludge S in the separation tank 30 uses a conveying means such as a pump 42. 40. The remaining sludge is discharged from the separation tank 30 in order to remove phosphorus taken in by the phosphorus accumulating bacteria from the processing system, and is discarded after being subjected to incineration. However, if the activated sludge S has a sufficient phosphorus uptake capacity for the phosphorus accumulating bacteria and can further take up phosphorus, the concentrated sludge in the separation tank 30 may be supplied to the pretreatment tank 40. This determination can be made based on the measured value of the phosphoric acid concentration of the wastewater in the separation tank 30.

  In the sewage treatment tank 40, new waste water Wa is supplied to the sludge supplied from the separation tank 30 by using a water feeding means such as a pump 43, and if necessary, the inside of the tank is cut off from the outside air to remove the newly collected water. Waste water Wa and activated sludge S are placed under anaerobic conditions. The pretreatment tank 40 is equipped with a stirring device 44 for mixing the waste water Wa and the activated sludge S, and the activated sludge S is dispersed by stirring the waste water Wa to prevent local quality change. Sludge activation becomes uniform. In this state, the remaining nitrate nitrogen from the waste water W contained in the activated sludge S is converted to nitrogen by the denitrifying bacteria, and the denitrification is completed to eliminate the nitrate nitrogen (in the present application, such nitrate nitrogen is eliminated). The anaerobic state is described as absolute anaerobic), and the phosphorus accumulating bacteria are activated to take in abundant organic matter in the wastewater, and the phosphorus accumulating bacteria that incorporate the organic matter have an advantage in reproduction over other bacteria. Therefore, the phosphorus accumulation capacity of the activated sludge S increases by growing in a later aerobic state. The phosphorus storage capacity of the sludge discarded from the separation tank 30 to the outside of the system is replenished by the phosphorus storage capacity corresponding to the increase due to this multiplication. In order for the pretreatment to function effectively, the amount of the new waste water Wa supplied to the concentrated sludge makes the absolute nitrogen anaerobic by substantially completing the denitrification of nitrate nitrogen remaining in the activated sludge S. It is important to be able to supply a sufficient amount of organic matter (ie more than the complete equivalent). Since wastewater after sludge treatment has a small organic mass, filamentous bacteria may grow in the sludge depending on handling, but in the pretreatment tank 40, sludge comes into contact with new wastewater with a high organic concentration. The growth of filamentous bacteria is prevented. The lower treatment tank 40 also functions as a means for avoiding unintentional growth of filamentous bacteria in the treatment tank 10. Since the organic concentration of the wastewater after the sludge treatment in the treatment tank 10 is close to zero, adding new wastewater directly to the treatment tank 10 may promote the growth of filamentous bacteria depending on the mixing situation, especially before treatment. The possibility increases when the organic concentration of the wastewater is about 100 mg-COD / L or less. However, when it passes through the pretreatment tank 40, nitrifying bacteria and floc-forming bacteria activated in the pretreatment tank 40 are present. Since it is introduced together with the waste water, the nitrifying bacteria and the floc-forming bacteria ingest the organic matter before the filamentous bacteria are activated in the treatment tank 10, which is effective in suppressing the propagation of filamentous bacteria. Therefore, the pretreatment tank 40 is a useful means even when it becomes absolutely anaerobic in the pretreatment tank and the phosphorus accumulating bacteria are not activated due to fluctuations in the quality of the wastewater or separation efficiency of the separation tank. Further, if the present invention is applied to wastewater treatment that does not require phosphorus removal, the lower treatment tank 40 can be used as a means for ensuring the prevention of filamentous bacterial growth. In this case, denitrification is performed in the lower treatment tank 40. It is not necessary to complete.

  If oxygen is supplied to the concentrated sludge S prior to the above-mentioned pretreatment, the organic matter in the residual wastewater and the stored organic matter accumulated in the sludge are oxidatively decomposed and the bacteria in the sludge are starved, so the new wastewater Wa When the organic substance is supplied, the rate at which the bacteria take up the organic substance increases, and the effectiveness of the pretreatment is improved. This oxygen supply is possible by an aeration process, and can be efficiently carried out by providing an aeration apparatus 45 for supplying a gas such as oxygen or air containing this in the lower treatment tank 40 and blowing air or the like. In addition, it can replace with the aeration apparatus 45 and can also obtain the same effect using a stirring apparatus. In this case, the combined oxygen of nitric acid is consumed (denitrified) instead of oxygen.

  The new waste water Wa and activated sludge S after the pretreatment are recirculated by the pump 51 via the pipe 50 and supplied to the treatment tank 10. The amount of water in the treatment tank 10 returns to the full water level (indicated by a broken line F in the figure), and the residual waste water W added with the new waste water Wa is activated by the activated sludge S containing activated phosphorus-accumulating bacteria after the pretreatment. Sludge treatment is performed again. The empty pretreatment tank 40 after reflux may contain new wastewater and be used as a reservoir for raw wastewater.

  As described above, while supplying new waste water Wa to the pretreatment tank 40 intermittently, by repeating the above-described sludge treatment, fractionation operation, separation operation, pretreatment and reflux operation, the ammonia state in the wastewater Nitrogen and phosphate phosphorus are removed, and the wastewater to be treated whose nitrate nitrogen concentration is reduced to an acceptable low concentration is discharged from the separation tank 30 of the activated sludge treatment apparatus. The phosphorus in the wastewater is taken up by the phosphorus accumulating bacteria in the activated sludge and discarded together with a part of the activated sludge S collected in the separation tank 30. At this time, the volume of the waste water discharged from the separation tank 30 and the volume of the new waste water Wa supplied to the activated sludge S in the lower treatment tank 40 are made equal to each other, so that the waste water subjected to the sludge treatment in the treatment tank 10. The volume (total amount) becomes constant.

  In general, sedimentation and separation of activated sludge requires a long time. Therefore, if the sludge treatment of wastewater in the treatment tank 10 is advanced in parallel with the separation operation in the separation tank 30, it is advantageous in terms of efficiency of the treatment and operation. The three tanks 10, 30, and 40 of the sludge treatment apparatus 1 can be utilized without waste. For this purpose, for example, as an initial treatment, pretreatment is performed in advance in the pretreatment tank 40 with new wastewater and activated sludge, and a portion of the wastewater and sludge after the sludge treatment is separated into the separation tank 30. After replenishing (the state shown in FIG. 1) the treatment tank 10 with the treated waste water Wa and activated sludge S, the separation operation and the sludge treatment can proceed in parallel. The amount of wastewater that can be treated can be increased, which is substantially equivalent to a reduction in time required for treatment. In this case, when the sludge treatment is completed while the activated sludge after the separation is subjected to the pretreatment, the fractionation operation from the treatment tank 10 may be performed in parallel. (Sludge treatment / separation-waste water disposal-separation / waste water) The treatment and operation are repeated with one cycle of preparative-reflux).

  In the sludge treatment in the treatment tank 10, ammonia nitrogen contained in the new wastewater to be added remains as nitrate nitrogen in the wastewater after the sludge treatment. The concentration of nitrate nitrogen in the wastewater is about the same as the ammonia nitrogen concentration in the wastewater at the start of the treatment, that is, after the first sludge treatment. The waste water to be treated is discarded from the separation tank 30. In a state where wastewater treatment has become steady, the concentration ratio between the ammonia nitrogen concentration of the wastewater before treatment and the nitrate nitrogen concentration of the wastewater after sludge treatment depends on the volume of wastewater (total amount) subjected to sludge treatment and the pretreatment Is substantially equivalent to the ratio of the volume of new wastewater added in step (water ratio), the ammonia nitrogen concentration of wastewater before treatment is A, and the nitrate nitrogen concentration of wastewater discharged from the device after treatment is N, treatment Assuming that the volume of waste water to be sludge treated in the tank 10 is V and the volume of new waste water added in the lower treatment tank is v, the nitrate nitrogen concentration N of the discharged waste water is N = A × (v / V ) And depends on the proportion of new wastewater. Assuming that Nmax is the maximum nitrate nitrogen concentration allowed for the water to be discarded, in order to satisfy N ≦ Nmax, the volume v of new wastewater to be added is roughly set by v ≦ (Nmax / A) × V. it can. In other words, the water amount ratio v / V can be roughly set based on the concentration ratio Nmax / A, and by appropriately adjusting the water amount ratio, the nitrate nitrogen concentration of the discharged wastewater to be treated is suitably used. Can be close to the concentration. At this time, the minimum value of the volume v of the new wastewater is an amount necessary for the pretreatment to be effective, and the maximum value is an amount at which the nitrate nitrogen concentration of the wastewater to be discarded becomes Nmax, and v is large. As the organic mass supplied to the treatment tank 10 increases, the anaerobic process proceeds well. However, since the wastewater after the sludge treatment has a high nitrate nitrogen concentration at the start of the treatment, it is necessary to reduce the wastewater to be treated. For this purpose, the initial water amount ratio v / V is set to be smaller than the value set according to the concentration ratio described above, and the amount of waste water in the initial sludge treatment is set to be less than the total amount V. (For example, Vv), and there is a method of adding new wastewater after pretreatment without separating and separating the wastewater after sludge treatment, and the method is appropriately selected in consideration of various situations.

  In the regularization by the above repetition, the phosphorus accumulating bacteria in the activated sludge S are activated in the pretreatment tank 40 and propagated in the aerobic process, thereby increasing the phosphorus accumulating ability of the activated sludge, but new waste water is By being repeatedly added, the amount of phosphorus in the treatment system reaches the saturation amount of bacterial uptake. Therefore, when the uptake saturation amount is reached, only a part of the activated sludge S in the separation tank 30 is subjected to the pretreatment as described above. However, until the uptake saturation amount is reached, all of the activated sludge in the separation tank is subjected to the pretreatment. be able to. Whether or not the intake saturation has been reached can be determined based on the monitoring result of the phosphate phosphorus concentration of the wastewater after the sludge treatment, and can be detected by the increase of the phosphorus concentration of the wastewater. The amount of activated sludge to be discarded depends on the amount of phosphorus added by the new wastewater, and is set in consideration of the amount of phosphorus uptake that can be increased by the pretreatment. The amount of activated sludge used in the sludge treatment is generally about 0.2 to 0.6 kg COD / (kg activated sludge / day) per kg of organic matter treated per day, but the total amount of activated sludge S. It is preferable to discard about 3-7 dry mass% (or volume%) per day.

  In the above description, it is assumed that the quality of the wastewater supplied to the activated sludge treatment apparatus 1 is constant and does not contain nitrate nitrogen. However, when the concentration of ammonia nitrogen in the wastewater fluctuates, this fluctuation can be dealt with. The concentration of nitrate nitrogen in the wastewater to be treated is adjusted by appropriately adjusting the water volume ratio and anaerobic / aerobic time distribution according to changes in the concentration ratio while constantly monitoring the ammonia nitrogen concentration of the wastewater. It can control suitably.

  If the separation of the waste water and the sludge in the separation tank 30 is complete, the amount of the waste water recirculated from the lower treatment tank 40 to the treatment tank 10 is equal to the above-described new waste water quantity v. Since it is difficult to accurately grasp the collection / separation status of the wastewater, the wastewater remains in the separated sludge and the residual wastewater amount v ′ is added (v + v ′). Since the amount v of new wastewater necessary for effectively performing the pretreatment depends on the amount of nitrate nitrogen remaining in the wastewater, the amount of new wastewater v is required to increase as the amount of residual wastewater v ′ increases. The amount (v + v ′) of waste water collected and refluxed from the treatment tank 10 is doubled. Therefore, in order to reduce the nitrate nitrogen concentration of wastewater after sludge treatment, it is fundamentally necessary to reduce the amount of residual wastewater v ′. Therefore, the balance of the storage capacity of the tank of the activated sludge treatment apparatus 1 is determined in consideration of the separation efficiency in the separation tank 30 as described above. For example, when the ammonia nitrogen concentration A of wastewater is 10 times the permissible nitrate nitrogen concentration Nmax and v = v ′ in the separation tank 30, the water amount ratio is 1/10, the separation tank 30 and the pretreatment tank The capacity of 40 is (v + v ′) = 2v, which is 1/5 of the capacity of the processing tank.

  The capacity required for the separation tank 30 and the pretreatment tank 40 described above can be regarded as the same (however, the change in the amount of additional wastewater due to the change in the quality of the wastewater is taken into consideration in the capacity). The above-described embodiment can be modified so that two tanks (first and second tanks) are used alternately. Specifically, the wastewater discharged from the treatment tank 10 is accommodated in the first tank, and the wastewater is removed by adding the new wastewater to the sludge in the first tank after the sludge is settled and the wastewater is removed. Next, the wastewater to be treated that is separated from the treatment tank 10 is accommodated in the second tank, and similarly, sedimentation separation and discharge of the wastewater are performed, and the pretreatment is performed in the second tank. What is necessary is just to recirculate | reflux the waste water which performed the pretreatment in the 1st tank to the processing tank after fractionation to a 2nd tank. In this embodiment, means 41 and 42 for conveying sludge from the separation tank 30 to the lower treatment tank 40 are unnecessary, and instead, the discharge destination can be switched between the first tank and the second tank. A switching valve or the like is provided as means for configuring the piping and changing the discharge destination for discharging the wastewater from the treatment tank 10. The stirring device 44 used in the pretreatment tank is provided in both the first and second tanks. When the aeration treatment is performed on the sludge before the pretreatment, the aeration means 45 is provided in both the first and second tanks, and the operation is switched and controlled.

  When the time required for the separation operation in the separation tank 30 is extremely long compared to the time required for the sludge treatment (anaerobic treatment + aerobic treatment) in the treatment tank 10, in order to efficiently use the sludge treatment apparatus 1, for example, A) The sludge treatment in the treatment tank 10 is repeated, b) The sludge separation operation is divided into two stages, and the initial stage separation is performed in the treatment tank 10.

  In the a), since the wastewater after the aerobic treatment is insufficient in organic matter, it is necessary to replenish the organic matter by adding wastewater so that denitrification in the anaerobic treatment can proceed before the sludge treatment is repeated. Therefore, when the sludge treatment in the treatment tank 10 is repeated, the amount of wastewater in the first sludge treatment is set in consideration of the amount of wastewater added when the sludge treatment is repeated.

  In b), the activated sludge S is collected in the lower part of the treatment tank 10 and concentrated to some extent by performing a separation operation such as sedimentation on the wastewater that has been subjected to the sludge treatment in the treatment tank 10. When the separation tank 30 (or one of the first and second tanks) becomes empty, the semi-concentrated sludge in the treatment tank 10 is discharged to the separation tank 30. In this case, since the ratio of the sludge to the wastewater in the discharge is increased, the amount of sludge to be subjected to the pretreatment through the separation operation can be increased, which is advantageous in enhancing the phosphorus storage capacity. The amount of concentrated sludge discharged and collected at this time is ideally adjusted so that the amount of wastewater contained in the concentrated sludge becomes the amount of the above-mentioned new wastewater v. Separation is incomplete and the residual wastewater v ′ is included (v + v ′) and is adjusted in consideration of the separation efficiency, and the operation in the separation tank 30 is optimized so that this approaches the new wastewater amount v. Such adjustment can be realized, for example, by installing a sludge interface meter in the separation tank 30 and reflecting the separation state in the separation tank 30 in the discharge amount in the sorting operation. Specifically, when the concentrated sludge discharged to the separation tank 30 is separated, the amount of the wastewater to be treated in the supernatant that can be discharged from the separation tank 30 and the amount of the collected waste water are separated by detecting the interface position with a sludge interface meter. The ratio of the supernatant treated wastewater to the concentrated sludge is determined. The difference between the amount of waste water to be treated and the new amount of waste water v is obtained, and by reducing the concentrated sludge discharged from the treatment tank 10 by a ratio corresponding to this difference, the amount of residual waste water v ′ during the separation operation is reduced. It can be reduced corresponding to the separation efficiency, and can be activated with high efficiency by subjecting more sludge and phosphorus accumulating bacteria to a pretreatment.

  As described above, since only a part of the wastewater treated in the treatment tank 10 is separated and activated sludge is separated and activated by the pretreatment, the volume for separating activated sludge is small, so that the separation efficiency Easy to increase. In addition, energy required for aeration in the pretreatment can be saved, and the organic matter of the wastewater can be used in a high concentration state, so that the efficiency of activating bacteria is high. Further, since sludge treatment and sludge separation of wastewater can be performed in parallel, the treatment efficiency is high, and it is possible to cope with a smaller apparatus than the conventional batch type apparatus that performs all in a single tank.

  Hereinafter, the activated sludge treatment method and apparatus for wastewater according to the present invention will be specifically described with reference to examples.

  A treatment tank 10 having a capacity of 5 L provided with an aeration device 11 and a stirring device 12, a separation tank 30 having a capacity of 830 ml for settling and separating waste water, and a 830 ml treatment tank 40 provided with an aeration device 45 and a stirring device 44. Using the activated sludge treatment apparatus 1 shown in FIG. 1, the treatment of raw wastewater with an ammonia concentration of 650 mg-N / L, nitric acid / nitrite concentration of 0 mg-N / L, and phosphoric acid concentration of 25 mg-P / L is performed as follows. I went.

  First, as an initial treatment, activated sludge is charged into the treatment tank to fill the raw wastewater (5 L), the outside air is shut off using nitrogen gas to make the anaerobic state, and the stirrer 12 is operated for 52 minutes to make the anaerobic treatment. The denitrification by denitrifying bacteria was advanced. Thereafter, the aeration apparatus 11 was operated to make an aerobic condition, and the nitrification by the lower nitrifying bacteria was advanced by performing the aerobic treatment for 197 minutes, and the sludge treatment was completed. In parallel with the sludge treatment in the treatment tank 10, activated sludge is introduced into the lower treatment tank 40, and air is blown in the aeration apparatus 45 for 59 minutes, and then an anaerobic state is established by blocking from the outside air using nitrogen gas. The raw waste water (830 ml) was filled and stirred for 21 minutes with a stirrer 44 to advance denitrification to make it anaerobic. After 830 ml of waste water containing activated sludge in the treatment tank 10 is discharged to the separation tank 30 by the drainage pump 21, wastewater containing activated sludge in the lower treatment tank 40 is supplied to the treatment tank 10 by the drainage pump 51. .

  Next, the sludge process (52 minutes + 197 minutes) which consists of the anaerobic process and aerobic process same as the above-mentioned was performed for regularization. During the sludge treatment, the wastewater in the separation tank 30 is allowed to settle and separate to concentrate the sludge to the bottom, and then 415 ml of the supernatant wastewater is discarded from the separation tank 30 using the drainage pump 31 and remains in the bottom. The concentrated sludge (including 415 ml of waste water) was transferred to the pretreatment tank 40. After air was blown into the concentrated sludge of the pretreatment tank 40 for 59 minutes with the aeration device 45, the air was cut off from the outside air with nitrogen gas to make it anaerobic, and 415 ml of raw waste water was supplied to it with the stirring device 44 for 21 minutes. Stirring and denitrification proceeded to make it absolutely anaerobic. Thereafter, separation of the wastewater after the sludge treatment (830 ml) and return of the wastewater after the pretreatment to the treatment tank 10 (830 ml) were performed in the same manner as described above. This steadying operation was repeated for a total of 70 times.

  In the above repetition, the concentration of nitric acid and nitrous acid in the wastewater after the sludge treatment in the treatment tank 10 gradually decreases, and after the 60th sludge treatment, the ammonia concentration is 6 mg-N / L and the nitric acid / nitrite concentration is 73 mg-N. / L. Further, the phosphoric acid concentration rapidly decreased and was about 5 mg-P / L after the 60th time, but slightly increased to 8 mg-P / L at the 70th time. For this reason, in the subsequent separation operation, about 4% / day of the residual sludge was discarded along with the disposal of the supernatant wastewater. The wastewater after the pretreatment generally had an ammonia concentration of 325 mg-N / L, nitric acid / nitrite concentration of 0 mg-N / L, and phosphoric acid concentration of 40 mg-P / L.

  After the repetition, sludge treatment in the treatment tank 10 and sedimentation separation in the separation tank 30 were further performed under the same conditions as described above. The wastewater in the treatment tank 10 has an ammonia concentration of 70 mg-N / L before starting sludge treatment, nitric acid / nitrite concentration of 58 mg-N / L, phosphoric acid concentration of 15 mg-P / L, and after anaerobic treatment, an ammonia concentration of 70 mg. -N / L, nitric acid / nitrite concentration 0 mg-N / L, phosphoric acid concentration 20 mg-P / L, after aerobic treatment, ammonia concentration 6 mg-N / L, nitric acid / nitrite concentration 73 mg-N / L, The phosphoric acid concentration was 5 mg-P / L. On the other hand, the waste water in the separation tank 30 is settled and separated, and 415 ml of waste water supernatant (ammonia concentration 6 mg-N / L, nitric acid / nitrite concentration 73 mg-N / L, phosphoric acid concentration 5 mg-N / P) is discarded, At the same time, about 1% of the residual activated sludge was discarded. After the rest was transferred to the pretreatment tank 40 and subjected to aeration treatment in the same manner as above, the raw waste water (ammonia concentration 650 mg-N / L, nitric acid / nitrite concentration 0 mg-N / L, phosphoric acid concentration 25 mg-P / L ) 415 ml was added. At this time, the wastewater in the pretreatment tank 40 had an ammonia concentration of 325 mg-N / L, nitric acid / nitrite concentration of 37 mg-N / L, and phosphoric acid concentration of 15 mg-P / L. After the pretreatment, the wastewater had an ammonia concentration of 325 mg-N / L, nitric acid / nitrite concentration of 0 mg-N / L, and phosphoric acid concentration of 40 mg-P / L.

It is a schematic block diagram which shows the activated sludge processing apparatus of the wastewater which concerns on this invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 10 Treatment tank, 30 Separation tank, 40 Lower treatment tank 12,44 Stirrer, 11,45 Aeration apparatus W, W1, W 'Waste water, S, S1, S2 Activated sludge

Claims (17)

Sludge treatment using activated sludge as wastewater in a single treatment tank for denitrification of nitrate nitrogen under anaerobic conditions and nitrification of ammonia nitrogen under aerobic conditions ;
A preparative operation for removing a part of the waste water to be treated containing activated sludge after the sludge treatment from the treatment tank to the separation tank ;
Collect activated sludge contained in the wastewater of the portion taken to the separation tank separating operation for separating the treated waste water;
Some of the separated the activated sludge, can contact to supply a new waste water in the pretreatment tank under anaerobic conditions, the remainder of the activated sludge, under processing discarded with phosphorus taken; and,
A recirculation operation for adding new wastewater containing the activated sludge after the pretreatment from the pretreatment tank to the remaining wastewater to be treated in the treatment tank after the sorting operation ;
An activated sludge treatment method for wastewater, wherein the sludge treatment, the fractionation operation, the separation operation, the pretreatment and the reflux operation are repeated. The amount of the new wastewater supplied in the pretreatment is such that the amount of organic matter supplied by the new wastewater substantially completes the denitrification of residual nitrate nitrogen of the part of the activated sludge, and the nitrate state it is set to be sufficient to that eliminate nitrogen, thereby activated sludge treatment method of waste water according to claim 1, wherein the incorporation is carried out to phosphorus Santai phosphorus activated sludge with the nitrification in the sludge treatment. The ratio of the amount of waste water to which the sludge treatment is performed and the amount of new waste water in the pretreatment is such that the ammonia nitrogen concentration in the waste water and the treatment target after the sludge treatment in a state where the waste water treatment has become steady by the repetition. It corresponds to a concentration ratio with the nitrate nitrogen concentration of wastewater, and the water amount ratio is set based on the concentration ratio so that the nitrate nitrogen concentration of the treated wastewater becomes a value that allows external disposal. The activated sludge treatment method for wastewater according to 1 or 2.   The reflux operation is performed after the fractionation operation, and the sludge treatment is performed in parallel with the separation operation after the reflux operation, so that the sludge treatment, the fractionation operation, the separation operation, the bottom treatment, and The activated sludge treatment method for wastewater according to any one of claims 1 to 3, wherein the reflux operation is repeated.   The activated sludge treatment method for wastewater according to claim 4, wherein the sorting operation is performed in parallel with the pretreatment.   The amount of new wastewater supplied in the pretreatment is such that the amount of wastewater added to the treatment tank by the reflux operation corresponds to the amount of the part of wastewater to be treated taken out in the sorting operation. The activated sludge treatment method for wastewater according to any one of claims 1 to 5, which is adjusted.   The activated sludge treatment method for wastewater according to any one of claims 1 to 6, wherein the pretreatment further includes an aeration process for aeration of the part of the activated sludge before supplying the new wastewater.   The sludge treatment has an anaerobic process for adjusting the wastewater to an anaerobic condition and an aerobic process for adjusting the wastewater after the anaerobic process to an aerobic condition, and the denitrification proceeds in the anaerobic process. And the activated sludge processing method of the wastewater in any one of Claims 1-7 in which the uptake | capture of the said nitrification and phosphate phosphorus advances in the aerobic process.   The activated sludge treatment method for wastewater according to claim 8, wherein the anaerobic step and the aerobic step are repeated in the sludge treatment according to the time required for the separation operation.   Further, the sludge treatment, the preparative operation, the separation operation, the pretreatment, and an initial treatment for improving the efficiency of repetition of the reflux operation, the initial treatment is an untreated wastewater under anaerobic conditions The activated sludge of wastewater of Claim 4 or 5 which has the 1st operation which adds a wastewater to activated sludge, and the 2nd operation which replenishes the waste water and activated sludge which passed through the 1st operation to the processing tank after the said fractionation operation Processing method. Treatment tank for containing wastewater and activated sludge;
Switchable operation for applying sludge treatment for denitrification of nitrate nitrogen under anaerobic conditions and nitrification of ammonia nitrogen under aerobic conditions using the activated sludge to the wastewater stored in the treatment tank A treatment mechanism provided in the treatment tank, having a suitable oxygen supply means ;
Drainage means for discharging a part of the wastewater to be treated containing activated sludge subjected to sludge treatment by the treatment mechanism from the treatment tank;
A separation tank that accommodates the part of the wastewater to be treated discharged from the treatment tank, collects and separates the activated sludge contained therein from the wastewater to be treated, and discards the wastewater to be treated ;
A pretreatment tank for supplying fresh wastewater to a part of the separated activated sludge and keeping it under anaerobic condition; and
An activated sludge treatment apparatus for wastewater, comprising a reflux means for supplying the activated sludge supplied with the new wastewater in the lower treatment tank and placed under anaerobic conditions to the treatment tank. Before SL separation tank, activated sludge treatment apparatus wastewater according to claim 11 having the lower processing tank is substantially equivalent to carrying capacity. The activated sludge treatment apparatus for wastewater has two tanks that are also used as the separation tank and the lower treatment tank , respectively, and the drainage means alternately turns the two tanks on every discharge from the treatment tank. A part of the wastewater to be treated is supplied, and each of the two tanks is configured to continuously contain the part of the wastewater to be treated and the activated sludge supplied with the new wastewater. The activated sludge treatment apparatus of the wastewater of Claim 11. The amount of the new waste water supplied in the lower processing tank provide sufficient organic to the substantially consummates the denitrification of residual nitrate bodies nitrogen of some of the activated sludge that eliminate the nitrate nitrogen The activated sludge treatment apparatus for wastewater according to any one of claims 11 to 13, wherein the sludge treatment performed by the treatment mechanism is a possible amount, and the phosphorous phosphorus is taken into the activated sludge together with the nitrification. The wastewater activated sludge according to any one of claims 11 to 14, wherein the pretreatment tank or the two tanks further have an aeration means capable of switching operation to aerate activated sludge separated by the separation tank . Processing equipment. Before SL under treatment tank or the two tanks, the activated sludge treatment system of the wastewater according to claim 15, further comprising a water intake means for taking in new waste water. Pre Symbol processing mechanism, activated sludge treatment apparatus wastewater according to any one of claims 11 to 16 having a stirring hand stage for mixing the wastewater and activated sludge.

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