KR100473639B1 - BNR(Biological Nutrient Removal) system and method by organic acids generated from sewage sludge - Google Patents

Abstract

The advanced sewage treatment system and treatment method according to the present invention minimizes sludge discharge and improves physical properties such as sedimentation and dehydration by decomposing and oxidizing sludge generated in existing sewage and wastewater treatment facilities using a continuous organic acid production apparatus. It is an object of the present invention to provide an advanced sewage treatment system and treatment method using the generated organic acid as a carbon source for advanced sewage treatment instead of supplying an external carbon source.

The present invention for achieving the above object, receiving the effluent from the primary sedimentation battery, by using the organic material contained in the inlet mixed with a return sludge solid-liquid separated from the secondary sedimentation battery to release the phosphorus in the microbial cells in the anaerobic state Anaerobic maturation; A denitrification tank that reduces and removes nitrate nitrogen of the effluent flowing out of the anaerobic tank with nitrogen gas; Aeration tank for nitrifying the effluent of the denitrification tank; First conveying means for conveying the internal sludge containing the high concentration of nitrate nitrogen produced in said aeration tank to said denitrification tank; A secondary sedimentation battery which receives the effluent discharged from the aeration tank and solid-liquid separates and discharges the upper effluent with low organic matter concentration; Second conveying means for conveying sludge solid-liquid separated from the secondary settler to the anaerobic tank; A thickening tank provided with excess sludge for disposal of sludge solid-liquid separated in the secondary settler; And an organic acid production apparatus which maintains a predetermined high temperature and high pressure state, heats excess sludge provided in the concentration tank, decomposes and oxidizes in a liquid state, and provides an organic acid generated in the oxidation process to the denitrification tank. In another aspect, the present invention provides a sewage treatment system, comprising: a first step of injecting a catalyst into an inlet sludge and heating by heat exchange means; A second step of transferring the heated sludge to a thermal oxidation reactor; Injecting an oxidant into the sludge introduced into the thermal oxidation reactor, and decomposing and oxidizing the liquid into a liquid state under a predetermined temperature, pressure, and stirring speed; A fourth step of separating the catalyst by cooling the organic acid generated in the thermal oxidation reactor by heat exchange means; A fifth step of transferring the catalyst-separated reactant to a storage tank, precipitating by-products generated by unreacted reaction in the storage tank, and recovering an organic acid to be transferred to a denitrification tank; A sixth step of transferring the mixed sludge liquid transferred from the organic acid and the anaerobic tank introduced into the denitrification tank to the aeration tank; A seventh step of removing organic matter and nitrifying the aeration tank and returning the nitrified mixed sludge solution to the denitrification tank; An eighth step of increasing the nitrogen removal rate by removing the nitrate nitrogen returned from the organic acid generated during the sludge oxidation process in the denitrification tank; A ninth step of returning a portion of the sludge precipitated by solid-liquid separation of the microorganisms grown in the aeration tank in a secondary settling cell; A tenth step of releasing phosphorus in the sludge using the whole amount of organic matter of the influent sewage under anaerobic conditions and transferring it to the aeration tank which is an aerobic condition; And it provides an advanced sewage treatment method comprising the eleventh step to intake excess phosphorus in the aeration tank sludge conveyed in the anaerobic tank.

Description

Advanced sewage treatment system and organic sewage treatment method using organic acid produced from sewage sludge {BNR (Biological Nutrient Removal) system and method by organic acids generated from sewage sludge}

The present invention decomposes and oxidizes sludge produced in existing sewage and wastewater treatment facilities using a continuous organic acid production device to minimize the discharge of sludge, improve physical properties such as precipitation and dehydration, and supply the generated organic acid to an external carbon source. Instead, it relates to an advanced sewage treatment system and method using the carbon source for advanced sewage treatment.

In general, effluents containing nitrogen and phosphorus are nutrients or limiting factors, such as accelerating eutrophication of lakes and reservoirs, or promoting the growth of algae and aquatic plants, such as algae and red algae, in shallow rivers. It acts as an element. Therefore, in order to prevent eutrophication, nutrient components in the sewage and wastewater have to be removed before they enter the body of the river or the like.

As a treatment method of sewage and wastewater treatment facilities to prevent such sublimation, many excellent biological treatment methods are applied in terms of economic efficiency. Among the biological treatment methods, organic matters using microorganisms such as standard activated sludge method are removed. Microorganisms grown during the removal process are generated as waste sludge.

In the process of sludge generated from organic matter removal and sludge disposal, sludge from primary and secondary sediments is collected in a concentration tank, and the concentrated sludge is transferred to an anaerobic digestion tank.

The digester supernatant of high concentration after the medium temperature digestion of about 35 ° C. in the digester is transferred to the aeration tank of the standard activated sludge process, and the remaining sludge is injected into the chemical to increase the dehydration efficiency. It is finally disposed of by landfill or incineration by a transport vehicle for disposal.

Recently, due to the ban on landfilling of sludge in landfill facilities, it is being temporarily disposed of by mixing with other waste such as construction waste and using it as a landfill agent. In this case, landfill shortages are accelerating, and additionally, complex water treatment processes are required to treat leachate discharged from landfills.

In order to incinerate the sludge, the water content of the dehydrated sludge should be lowered to about 20 to 30%, and additional auxiliary fuel is required as the heat of the sludge is insufficient, and a large dust collection facility is required to collect air pollutants generated during incineration. There are many problems.

The real scale facility to which wet oxidation of the sludge is applied is a Zimpro process installed in a sewage treatment facility in Chicago, USA. The wet oxidation system for oxidizing the organic matter contained in the sludge is composed of a high pressure reactor capable of withstanding relatively high temperatures and pressures, a heat exchange means, an oxygen transfer system, and a high pressure pump capable of injecting sludge into the high pressure reactor.

The sludge TS concentration is about 3 to 5%, and the oxygen amount is about 1 to 2% of the total gas amount in the reactor. The mechanical stirring system for mixing the reactants inside the reactor was operated without installation.

The operation factor of the Zimpro process maintains a reaction time of about 40 to 60 minutes at a reaction temperature of 260 ° C. or higher, a high temperature of 70 to 120 atm, and a high pressure, at which time the COD removal rate reaches approximately 70 to 80%.

However, as the main problem of the Zimpro process is the corrosion of reactors, the scale formation of the heat exchange means and the degree of corrosion, the annual maintenance cost is greatly increased and treated as a high cost technology. There is a problem that can not apply a conventional stirring facility.

As such, sewage and wastewater treatment facilities up to now only treat organic matter and suspended solids, but as eutrophication of rivers and lakes becomes severe, nitrogen and phosphorus in wastewater and wastewater are reduced to reduce nitrogen and phosphorus, which are the causes of eutrophication. Sewage treatment is essential for removal.

Conventional nitrogen and phosphorus removal methods include physicochemical treatments and biological treatments. The physicochemical treatments include degassing and denitrifying nitrogen by injecting air while increasing the pH of wastewater. Selective adsorption using ion-exchange materials is a method of treating nitrogen and precipitation of phosphorus using coagulants such as slaked lime.

However, in the case of such physicochemical methods, maintenance costs are high, and most biological treatment methods having excellent economical efficiency are applied.

In this biological treatment method, the biological nitrogen removal method is a nitrogen-nitrogen (NH ₄ ⁺ -N) in the sewage in the aerobic condition rich in dissolved oxygen by the nitrifying bacteria (nitrobactor) nitrous nitrogen (NO ₂ ^-- N) And a nitrification step of oxidizing to nitric nitrate (NO ₃ ^-- N), followed by a denitrification process of reducing nitrate nitrate to nitrogen gas by denitrification bacteria (nitrosomonas) in an oxygen-free condition. do.

Such biological nitrogen removal requires an aerobic step and an anaerobic step, which requires dissolved oxygen in the aerobic nitrification process and an organic carbon source in the anoxic denitrification step. At this time, when the carbon source, which is an organic component in the influent sewage, is used or insufficient, an external carbon source such as methanol is injected to induce efficient denitrification.

Next, in the removal method of biological phosphorus, phosphorus is removed by dephosphorus bacteria in anaerobic process, which stores the ingested organic matter in the form of PHH (PolyHydro-β-Butyrate) in the cell. At this time, the energy required for storage is obtained in the hydrolysis process in which ATP (Adenosin Tri Phosphate) in the cell is broken down into Adenosine Di Phosphate (ADP), and in this process, orthophosphate (PO ₄ ^{3). -} is released is -P) in the form of a.

In the next aerobic phase, the phosphorus in the influent sewage is removed by absorbing an amount of phosphorus several times more than the amount of phosphorus released in the anaerobic stage for the growth and resynthesis of the dephosphorus bacteria.

In general, the simultaneous removal of biological nitrogen and phosphorus is carried out in a process in which anaerobic conditions, anoxic conditions, and aerobic conditions are formed, and various methods have been developed and put into practice in domestic wastewater treatment facilities.

At present, it is applied to Sewage Advanced Treatment Facility as A2 / O method for biological and nitrogen removal.

The A2O method is composed of anaerobic conditions, anoxic conditions and aerobic conditions sequentially. As described in the biological nitrogen removal method, the phosphorus released from the aerobic reactor is removed by appropriately removing the microorganism sludge which absorbed a larger amount of phosphorus in the aerobic reactor.

On the other hand, the phosphorus release process is carried out in the anaerobic state without oxygen. When the oxygen molecules are combined with nitrate nitrogen (NO ₃ ^-- N) into the anaerobic reactor, the release of phosphorus inhibits the denitrification in the anoxic stage. There is a problem that the process affects the removal of phosphorus.

Accordingly, the present invention has been proposed to solve the above problems, to minimize the discharge of excess sludge generated in the biological sewage treatment process to reduce the maintenance cost, and to reduce the nitrogen removal efficiency even under low influent organic load In addition, the purpose of the present invention is to provide an advanced sewage treatment system and method capable of increasing the simultaneous removal rate of nitrogen and phosphorus by improving the nitrogen removal rate of the entire system.

The present invention, by using the continuous thermal oxidation method of the concentrated sludge generated in the biological treatment facilities of sewage and wastewater to generate the organic acid as a carbon source to use the total nitrogen removal rate by using as a carbon source for denitrification in advanced sewage and wastewater treatment facilities In addition, the present invention provides an advanced sewage treatment system and method for improving the simultaneous removal rate of nitrogen and phosphorus from the entire system by reducing phosphorus nitrate flowing into the anaerobic tank from the secondary settler and stably removing phosphorus. have.

In order to achieve the above object, the present invention, receiving the effluent from the primary sedimentation battery, by using the organic material contained in the inlet mixed with the return sludge solid-liquid separated from the secondary sedimentation battery to release the phosphorus in the microbial cells in the anaerobic state Anaerobic maturation; A denitrification tank that reduces and removes nitrate nitrogen of the effluent flowing out of the anaerobic tank with nitrogen gas; Aeration tank for nitrifying the effluent of the denitrification tank; First conveying means for conveying the internal sludge containing the high concentration of nitrate nitrogen produced in said aeration tank to said denitrification tank; A secondary sedimentation battery which receives the outflow water discharged from the aeration tank and solid-liquid separation and discharges the upper outflow water having a low organic matter concentration; Second conveying means for conveying sludge solid-liquid separated from the secondary settler to the anaerobic tank; A thickening tank provided with excess sludge for disposal of sludge solid-liquid separated in the secondary settler; And an organic acid production apparatus which maintains a predetermined high temperature and high pressure state, heats excess sludge provided in the concentration tank, decomposes and oxidizes in a liquid state, and provides an organic acid generated in the oxidation process to the denitrification tank. Provide sewage treatment system.

In addition, the present invention is a first step of injecting a catalyst, and transfer the sludge heated by the heat exchange means to the thermal oxidation reactor; Injecting an oxidant into the sludge introduced into the thermal oxidation reactor, and decomposing and oxidizing the liquid to a liquid state under a predetermined temperature, pressure, and stirring speed; A third step of separating the catalyst by cooling the organic acid generated in the thermal oxidation reactor by heat exchange means; A fourth step of transferring the catalyst-separated reactant to a storage tank, precipitating by-products generated by unreacted reaction in the storage tank, and recovering an organic acid to be transferred to a denitrification tank; A fifth step of transferring the mixed sludge liquid transferred from the organic acid and the anaerobic tank introduced into the denitrification tank to the aeration tank; A sixth step of removing organic matter and nitrifying from the aeration tank and returning the nitrified mixed sludge solution to the denitrification tank; A seventh step of increasing the nitrogen removal rate by removing the nitrate nitrogen returned from the organic acid generated during the sludge oxidation process in the denitrification tank; An eighth step of returning a portion of the sludge precipitated by solid-liquid separation of the microorganisms grown in the aeration tank in a secondary settling cell; A ninth step of releasing phosphorus in the sludge using the whole amount of organic matter of the influent sewage under anaerobic conditions and transferring it to the aeration tank which is an aerobic condition; And it provides a high sewage treatment method comprising the tenth step to intake excess phosphorus in the aeration tank sludge conveyed in the anaerobic tank.

Hereinafter, the advanced sewage treatment system and the advanced sewage treatment method according to the present invention will be described with reference to the accompanying drawings.

1 is an explanatory view schematically showing the configuration and processing of the advanced sewage treatment system according to the present invention.

As shown in the figure, the advanced sewage treatment system according to the present invention, the sludge is solid-liquid separated from the secondary sedimentation battery 40 to be described later using the organic material contained in the inflow water flowing out from the primary sedimentation battery (11) Anaerobic tank (10) and mixed with and to release the phosphorus in the microbial cells in the anaerobic state; A denitrification tank 20 for mixing the effluent flowing out of the anaerobic tank 10 and the sludge conveyed internally after nitrifying in the aeration tank 30 to be described later to reduce and remove nitrate nitrogen with nitrogen gas; Aeration tank 30 for nitrifying the effluent of the denitrification tank 20 and internally conveying the mixed sludge liquid having a high nitrate nitrogen concentration and the effluent of the denitrification tank to the denitrification tank; First conveying means (31) for conveying the inner sludge (31) containing the high concentration of nitrate nitrogen produced in said aeration tank (30) to said denitrification tank (20); A secondary sedimentation battery 40 for receiving the effluent discharged from the aeration tank 30 and separating the solid-liquid and discharging the upper effluent with low organic matter concentration; Second conveying means (41) for conveying sludge solid-liquid separated from the secondary needle battery (40) to the anaerobic tank (10); A concentrating tank (50) provided with excess sludge for disposal of sludge solid-liquid separated from the secondary needle battery (40); And maintains a predetermined high temperature and high pressure state, heats the excess sludge provided in the concentrating tank 50, decomposes and oxidizes in a liquid state, and provides the organic acid generated in the oxidation process to the denitrification tank 20. Organic acid production apparatus 100 is included.

The anaerobic tank 10 and the denitrification tank 20 are provided with stirring means 12 and 21 for uniformly mixing the sludge contained therein.

The organic acid production apparatus 100 will be described with reference to FIG. 2 as follows. Figure 2 is a block diagram showing a continuous organic acid production apparatus for sewage sludge decomposition and advanced sewage treatment according to the present invention.

As shown in the figure, the organic acid production apparatus 100 is mounted to the outlet of the concentration tank 50, a plurality of thermal oxidation reactor 110 to decompose and oxidize the excess sludge passed through the concentration tank 50 in a liquid state. 120; Catalyst injection and recovery means (130) for injecting and recovering a catalyst into the thermal oxidation reactor (110) (120) to reduce energy and increase oxidation rate; Temperature pressure control means (140) for controlling the first and second thermal oxidation reactors (110, 120) to be maintained at a predetermined pressure and temperature; Heating means (111, 121) for heating the respective reactors (110, 120) to a predetermined temperature; Oxidant supply means (150) for supplying an oxidant to the thermal oxidation reactor (110) (120) to oxidize the sludge in each reactor; Heat exchange means (160) for cooling and heating the high temperature product of each reactor (110) (120) and the low temperature concentrated sludge supplied to the reactor by heat exchange; And a storage tank 170 for supplying the organic acid generated in each of the reactors 110 and 120 to the denitrification tank 20 for reducing and removing nitrate nitrogen with nitrogen gas, and discharging the by-product generated in the reaction process from the bottom. ).

In addition, oxidant dispersing means 112 and 122 which are provided under each of the thermal oxidation reactors 110 and 120 to disperse the oxidant supplied into the reactor 110 and 120 by the oxidant supplying means 150. More).

The thermal oxidation reactor (110, 120), the first thermal oxidation reactor of the continuous mixing tank (CSTR: Continuous Stirred Tank Reactor) comprising a stirring means 112 for stirring so that the introduced sludge is mixed well with the oxidant (110), and the second column thermal oxidation reactor of the bubble column type (bubble column) to increase the contact capacity, including an oxidant dispersing means (122) for dispersing and supplying the oxidant through the fine pores so that the introduced sludge is mixed with the oxidant ( 120).

The temperature pressure control means 140 is connected to the pressure sensor 181 and the pressure sensor 181 for measuring the pressure in the first thermal oxidation reactor 110, the pressure control to adjust the pressure in the reactor Means 182, temperature sensors 183 and 184 for measuring the temperature in the first and second thermal oxidation reactors 110 and 120, and the temperature sensors 183 and 184, It consists of heating means (111, 121) for controlling the temperature in the first and second thermal oxidation reactor (110, 120).

The reaction conditions of the reactor 110, 120 is preferably lowered to 200 ℃ ~ 240 ℃, 40 atm or less, the reaction time is preferably within 1 hour.

The catalyst injected by the catalyst injection and recovery means 130 is CuSO ₄ , FeSO ₄ , Fe (SO ₄ ) ₃ , MnSO ₄ , Cu (NO ₃ ) ₂ , Mn (NO ₃ ), which are nitrates or sulfates of transition metals. It is preferable to select one of the _two ).

The oxidant added to increase the oxidation efficiency of the sludge by the oxidant supply means 150 preferably includes at least one of air, oxygen, hydrogen peroxide, and sulfuric acid.

Reference numeral 190 is a sludge injection pump for injecting sludge generated in the sewage treatment process into the reactor.

Referring to the operation of the advanced sewage treatment apparatus according to the present invention configured as described above are as follows.

First, in the anaerobic tank 10, by using the organic material contained in the inflow water flowing from the primary sedimentation battery (11) and mixed with the sludge separated from the solid-liquid separation in the secondary sedimentation battery (40) to release phosphorus in the microorganism cells in the anaerobic state Let's do it.

The effluent flowing out of the anaerobic tank 10 is mixed with the sludge conveyed internally after nitrification from the aeration tank 30 by the first transfer means 31 in the denitrification tank 20 to reduce the nitrogen nitrate to nitrogen gas to be removed. do. At this time, the hydraulic retention time of the influent in the denitrification tank 20 is preferably set to 1-3 hours.

The effluent water discharged from the aeration tank 30 is solid-liquid separated in the secondary needle battery 40, the upper effluent water having a low organic concentration in the secondary needle battery 40 is discharged to the outside, the remaining sludge to the denitrification tank 20. Is returned.

Sludge solid-liquid separated from the secondary needle battery 40 is conveyed to the anaerobic tank 10 by the second conveying means 41.

The excess sludge for disposal of the sludge of the secondary sedimentation battery 40 is concentrated to be transferred to the concentration tank 50, and the sludge provided in the concentration tank 50 is provided to the organic acid production apparatus 100 and heated, and then in a liquid state. Decompose and oxidize in At this time, the organic acid generated in the oxidation process of the organic acid production apparatus 100 is provided to the denitrification tank (20). Here, the sludge flowing out of the concentration tank 50 is introduced into the organic acid production apparatus 100 without pretreatment in a state where the total solid concentration is 3% -4%.

Sludge introduced into the organic acid production apparatus 100, the catalyst is injected by the catalyst injection and recovery means 130, is heated by the heat exchange means 150.

The heated sludge is sent to each thermal oxidation reactor (110) (120), at least one oxidant of air, oxygen or hydrogen peroxide supplied by the oxidant supply means 150 to the sludge transferred to the reactor (110) (120) Is injected and decomposed and oxidized into a liquid state by the heating means 111 and 121 under a constant temperature, pressure, and stirring speed by the heating pressure control means.

At this time, the oxidant dispersing means 112 and 122 provided in the lower portion of each reactor 110, 120 promotes the dispersion of the injected oxidant, thereby sludge in each reactor 110, 120 The decomposition oxidation of is more active.

Through the above process, the organic acid generated in the reactors 110 and 120 is cooled by the heat exchange means 160 to separate the catalyst, and the catalyst-separated reactant is transferred to the storage tank 170 to separate the residual sludge and the organic acid.

In the storage tank 170, by-products generated by unreacted precipitate, and the entire amount of organic acid, which is a carbon source, is recovered and transferred to the denitrification tank 20 to repeat a series of advanced sewage treatment processes.

Briefly describing the advanced sewage treatment flow process of the advanced sewage treatment system according to the present invention operating as described above, the sludge heated by the catalyst and heat exchange means 160 to the thermal oxidation reactor (110, 120) A first step of conveying; A second step of injecting air, oxygen, or hydrogen peroxide, which is an oxidant, into the sludge introduced into the reactors 110 and 120 and decomposing and oxidizing the liquid in a liquid state under a predetermined temperature, pressure, and stirring speed; A third step of separating the catalyst by cooling the organic acid generated in the thermal oxidation reactor (110) (120) by heat exchange means (160); A fourth step of transferring the catalyst-separated reactant to a storage tank, depositing a by-product generated by unreacted reaction in the storage tank, recovering the total amount of the supernatant (organic acid), and then transferring the reactant to the denitrification tank 20; The denitrification tank 20 includes a fifth step of transferring the mixed sludge liquid transferred from the introduced organic acid and the anaerobic tank 10 to the aeration tank 30; In the aeration tank 30, the organic matter is removed and nitrified, and a sixth step of returning the nitrified mixed sludge solution to the denitrification tank 20; The denitrification tank 20 includes a seventh step of increasing the nitrogen removal rate of the entire system by removing the nitrate nitrogen returned from the organic acid generated during the sludge oxidation process; An eighth step of returning a part of the sludge precipitated by solid-liquid separation of the microorganisms grown in the aeration tank 30 to the anaerobic tank 10; A ninth step of releasing phosphorus in the sludge using the whole amount of organic matter of the influent sewage under anaerobic conditions and transferring it to the aeration tank 30 which is an aerobic condition; And a tenth step of allowing the sludge transferred from the anaerobic tank 10 to consume excess phosphorus in the aeration tank 30.

In the aeration tank 30, the nitrate nitrogen generated in the aeration tank 30 is treated in a denitrification tank 20 by using a supernatant containing an influent source organic material and an organic acid, thereby allowing the anaerobic tank 10 in the secondary settling cell 40. The nitrate nitrogen contained in the return sludge is reduced, so as not to affect the phosphorus discharge in the anaerobic tank 10.

As described above, the advanced sewage treatment apparatus and method having an organic acid production apparatus according to the present invention minimizes the discharge volume and improves the properties of residual sludge by thermal oxidation of waste sludge generated in a conventional biological sewage and wastewater treatment facility. In addition, they produce useful carbon sources for denitrification in advanced sewage treatment. By lowering the reaction conditions to 200 ° C. to 240 ° C. and 40 atm or less, and reducing the reaction time to less than 1 hour, major problems of the thermal oxidation process, such as suppressing the corrosion of the reactor and reducing maintenance costs, can be solved.

In addition, by generating a useful carbon source for denitrification during the advanced sewage treatment, by adding the generated carbon source to the denitrification tank of the sewage treatment plant, the nitrogen removal rate of the entire system can be improved, and as a result, the mixed sludge liquid returned from the secondary settler As the concentration of nitrate nitrogen is reduced and the total amount of organic matter from the influent sewage is consumed in the anaerobic tank, phosphorus is released from the anaerobic tank. Not only can it be improved, but the sludge treatment and disposal costs can be reduced.

The present invention described above is not limited to the above-described embodiment and the accompanying drawings, and various substitutions, modifications, and changes are possible within the scope without departing from the technical spirit of the present invention. It will be evident to those who have knowledge of.

As described above, the advanced sewage treatment system and treatment method according to the present invention can suppress corrosion of a reactor that generates an organic acid, which is a useful carbon source for denitrification, and has an effect of reducing maintenance costs.

In addition, the maintenance cost is reduced by minimizing the discharge of excess sludge from the advanced sewage treatment process, and the nitrogen removal efficiency of the entire system is improved by improving the nitrogen removal efficiency even under low influent organic load, and the nitrogen and phosphorus simultaneously. This can increase the removal rate.

In addition, by using the continuous thermal oxidation method, the concentrated sludge generated in biological treatment facilities of sewage and wastewater is generated as organic carbon, which is a carbon source, and used as a carbon source for denitrification in advanced sewage and wastewater treatment facilities. In addition to reducing costs and improving the total nitrogen removal rate, it is possible to reduce the concentration of nitrate nitrogen flowing into the anaerobic tank from the secondary settler to stably remove phosphorus, thereby increasing the simultaneous removal rate of nitrogen and phosphorus throughout the system.

1 is an explanatory view schematically showing the configuration and processing of the advanced sewage treatment system according to the present invention.

Figure 2 is a schematic diagram showing the configuration of a continuous organic acid production apparatus for sewage sludge decomposition and advanced sewage treatment according to the present invention.

* Explanation of symbols for main parts of the drawings

10: anaerobic tank 11: primary settler

20: denitrification tank 30: aeration tank

31: first transport means 40: secondary rechargeable battery

41: second transport means 50: concentration tank

100: organic acid production apparatus 110, 120: thermal oxidation reactor

111, 121: heating means 112, 122: oxidant dispersing means

130: catalyst supply and recovery means 140: temperature pressure control means

150: oxidant supply means 160: heat exchange means

170: storage tank 181: pressure sensor

182: pressure regulating means 183, 184: temperature sensor

190: sludge injection pump

Claims (9)

An anaerobic tank that receives the effluent from the primary settler and mixes with the return sludge separated from the solid solution in the second settler using organic materials contained in the inlet to release phosphorus in the microbial cells in the anaerobic state; A denitrification tank that reduces and removes nitrate nitrogen of the effluent flowing out of the anaerobic tank with nitrogen gas; Aeration tank for nitrifying the effluent of the denitrification tank; First conveying means for conveying the internal sludge containing the high concentration of nitrate nitrogen produced in said aeration tank to said denitrification tank; A secondary sedimentation battery which receives the effluent discharged from the aeration tank and solid-liquid separation, and discharges the sludge having a low concentration in the produced sludge to the outside; Second conveying means for conveying the sludge having a high concentration in the sludge separated into solid-liquid separated from the secondary immersion cell to the anaerobic tank; A thickening tank provided with excess sludge for disposal of sludge solid-liquid separated in the secondary settler; A plurality of thermal oxidation reactors for decomposing and oxidizing excess sludge provided in the concentration tank into a liquid state; Catalyst injection and recovery means for injecting and recovering a catalyst into the thermal oxidation reactor; Heating pressure control means for controlling the thermal oxidation reactor to be maintained at a predetermined pressure and temperature; Heating means for heating the thermal oxidation reactor to a predetermined temperature; Oxidant supply means for supplying an oxidant to the thermal oxidation reactor to oxidize the sludge contained in the thermal oxidation reactor; Heat exchange means for cooling and heating the high temperature product of the thermal oxidation reactor and the low temperature concentrated sludge supplied to the thermal oxidation reactor by heat exchange; And A storage tank for supplying the organic acid generated in the thermal oxidation reactor to the denitrification tank and discharging the by-products generated during the reaction to the bottom. Advanced sewage treatment system comprising a. The method of claim 1, The anaerobic tank and the denitrification tank are provided with stirring means for uniformly mixing the sludge contained therein. Advanced sewage treatment system. The method of claim 1, The thermal oxidation reactor, A first thermal oxidation reactor of a continuous mixing tank type including stirring means for stirring the introduced sludge to mix well with the oxidizing agent; And It consists of a bubble column type second thermal oxidation reactor which supplies the oxidant through the fine pores so that the introduced sludge is mixed with the oxidant to improve the contact ability. Advanced sewage treatment system. The method of claim 1, The temperature pressure control means, A pressure sensor for measuring the pressure in the reactor; A pressure regulating means connected to the pressure sensor and regulating a pressure in the thermal oxidation reactor; A temperature sensor for measuring a temperature in the thermal oxidation reactor; And Is connected to the temperature sensor, consisting of a temperature control means for controlling the temperature in the thermal oxidation reactor Advanced sewage treatment system. The method of claim 1, The thermal oxidation reactor It is characterized by having a reaction condition to lower the temperature to 200 ℃ ~ 240 ℃, 40 atm or less, the reaction time within 1 hour Advanced sewage treatment system. The method of claim 1, The oxidant comprises one or more of air, oxygen, hydrogen peroxide, sulfuric acid Advanced sewage treatment system. The method of claim 1, The catalyst is selected from any one of transition metal nitrate or sulfate of CuSO ₄ , FeSO ₄ , Fe (SO ₄ ) ₃ , MnSO ₄ , Cu (NO ₃ ) ₂ , Mn (NO ₃ ) ₂ Advanced sewage treatment system. A first step of injecting a catalyst into the sludge and heating it by a heat exchange means to transfer the catalyst to a thermal oxidation reactor; Injecting an oxidant into the sludge introduced into the thermal oxidation reactor, and decomposing and oxidizing the liquid to a liquid state under a predetermined temperature, pressure, and stirring speed; A third step of separating the catalyst by cooling the organic acid generated in the thermal oxidation reactor by heat exchange means; A fourth step of transferring the catalyst-separated reactant to a storage tank, precipitating by-products generated by unreacted reaction in the storage tank, and recovering an organic acid to be transferred to a denitrification tank; A fifth step of transferring the mixed sludge liquid transferred from the organic acid and the anaerobic tank introduced into the denitrification tank to the aeration tank; A sixth step of removing organic matter and nitrifying from the aeration tank and returning the nitrified mixed sludge solution to the denitrification tank; A seventh step of increasing the nitrogen removal rate by removing the nitrate nitrogen returned from the organic acid generated during the sludge oxidation process in the denitrification tank; An eighth step of returning a portion of the sludge precipitated by solid-liquid separation of the microorganisms grown in the aeration tank in a secondary settling cell; A ninth step of releasing phosphorus in the sludge using the whole amount of organic matter of the influent sewage under anaerobic conditions and transferring it to the aeration tank which is an aerobic condition; And Step 10 to intake excess phosphorus in the aeration tank sludge conveyed from the anaerobic tank Advanced sewage treatment method comprising a. The method of claim 8, The ten step, The nitrate nitrogen generated in the aeration tank is treated in a denitrification tank using a supernatant containing inflow source organic matter and organic acid, and the nitrate nitrogen contained in the reaction sludge is reduced in the anaerobic tank in the secondary settler, and the phosphorus discharge in the anaerobic tank is reduced. Unaffected Advanced sewage treatment method.