RU2060967C1 - Method and aggregate for deep biochemical sewage purification - Google Patents

Abstract

FIELD: middle size and small towns and separate building sewage deep biochemical purification. SUBSTANCE: initial sewage water during its feeding for primary settling is treated by ozone in amount of 6.0 - 60.0 mg/land then it is fed for aeration into aerotank 8, that causes destruction of complex organic molecules in initial water and breaks aggregating stability of its dispersion system. That results in intensification of suspensions settling processes in primary settler 1 and in additional settler 19 an also bioprocesses in aerotank 8. Sludge mixture in biofilter 10 made in the form of thin layer settling module is separated and biofilm gets into section 11, from which it is fed for recirculation aerator 9 made in the form of water-air ejector. Clarified in secondary settler 12 water is passing through micro filter 13 and collect into tank 14 and reservoir 15 for purified water. In the latter purified water is also subjected to treatment by ozone using ejector 16 and ozonizer 17 in amount of 2.0 - 20.0 mg/l for disinfection and removal of residuals of difficultly oxidizing impurities. Dimensions of aggregate are 1.5 -2.0 times less than dimensions of known such aggregates, power usage is minimum for volumes of less than 10000 m³/ day. EFFECT: significantly decreased dimensions of aggregate and power consumption.

Description

 The invention relates to the treatment of wastewater and can be used for the treatment of domestic and close to them in the composition of the wastewater of medium and small settlements and detached houses and cottages.

 A known method of biochemical wastewater treatment, including aeration of wastewater with activated sludge, sludge and ozonation of treated water before it is clarified [1] However, the known method is not efficient enough and does not provide a high degree of wastewater treatment.

 Closest to the proposed method, the known method of biological wastewater treatment, including aeration and repeated ozonation of wastewater during aeration and in the presence of activated sludge [2] However, the known method is complex and time-consuming to use, requires a large number of reagents and costs.

 A well-known installation for deep biological wastewater treatment, containing a primary sump, aeration tank with an aerator, a secondary sump with thin-layer modules, a stabilizer with fillers in the form of porous and ruff loading and technological pipelines [3] The known installation is difficult to manufacture and work, requires large capital and operating costs and does not provide deep water treatment when changing the composition of wastewater.

 The aim of the invention is to increase the degree of wastewater treatment and the intensification of the purification process, as well as the creation of an installation for deep biochemical treatment of various composition and amount of wastewater, inexpensive and labor-intensive.

 This is achieved by the fact that in the method of deep biochemical wastewater treatment, including primary sedimentation, aeration and secondary sedimentation, the wastewater is treated with ozone in the amount of 6.0-60.0 mg / l before primary sedimentation, and purified ozone is also treated with secondary ozone water in an amount of 2.0-20.0 mg / L. In addition, the ozone-treated wastewater after initial sedimentation is further sedimented before being fed to aeration, after aeration, the sludge mixture is subjected to biofiltration, and the precipitate formed is recycled and mixed with aerated wastewater, after secondary sedimentation and microfiltration is performed before secondary ozonation.

 Ozonation of the initial wastewater when it is supplied for primary sedimentation allows the destruction of complex organic molecules of proteins, polysaccharides, synthetic polymers, soap soluble in water and others, that is, to violate the aggregate stability of dispersed systems, and water is a complex dispersed system containing a liquid phase, solid phase suspended particles, as well as colloids and suspensions. When the stability of the system is violated, intensive processes of coagulation and precipitation of suspended particles and colloids begin during the initial sedimentation. The use of a dose of ozone of less than 6.0 mg / l in a wide range of source wastewater is impractical in composition and quantity, since it does not provide a sufficient degree of destruction of the solid phase, coagulation and sedimentation rate, and treatment of wastewater with a dose of over 60.0 mg / l does not is necessary to accelerate the process of deposition of the solid phase and increases the cost of the process. Primary ozonation in this range can significantly increase the specific rate of oxidation of contaminants by microorganisms (activated sludge) during aeration and also reduce this stage of wastewater treatment.

 Ozonation of water after a secondary sump allows you to disinfect water, reduce it to traces of COD and BOD, reduce the content of ammonia nitrogen and surfactant in the water, that is, get deeply purified water suitable for consumption. The proposed ozone dose range of 2.0-20.0 mg / L is optimal for wastewater of various composition and amount. Using less than 2.0 mg / l does not provide the necessary degree of disinfection of purified water and reducing its color. The use of more than 20.0 mg / l of ozone is impractical, since according to the tests carried out, the processes of disinfection and removal of residues of difficultly oxidized contaminants are practically not accelerated.

 This goal is also achieved by the fact that the installation for deep biochemical wastewater treatment, containing a primary sump, aeration tank with an aerator, a secondary sump and pipelines for supplying raw water, discharging purified water, recycling activated sludge and sludge, is equipped with an ejector installed in the upper part of the primary sump for primary ozonation with a receiving chamber and an ozonizer, as well as a purified water tank located after the secondary sedimentation tank and an ejector for the final oz nirovaniya with ozone treatment. In addition, the installation is equipped with an additional sump communicated with the primary sump and aeration tank for additional sedimentation of coagulated wastewater coming from the primary sump with significantly contaminated source water. To improve the circulation of the silt mixture in the aeration tank, the aerator is made in the form of a water-air ejector. The aeration tank is equipped with a biofilter installed at the outlet of the sludge mixture, made in the form of a thin-layer sedimentation module with the formation in the lower part of the compartment of a precipitated biofilm in communication with the aerator in the form of an ejector. The secondary sump is equipped with a microfilter installed at the outlet of water with a clarified water tank. The activated sludge recirculation pipeline connects the lower parts of the secondary sump, the biofilm compartment and the primary and secondary sumps.

 The drawing shows a installation for deep biochemical wastewater treatment in longitudinal section.

 The installation contains a primary sump 1, in which in its upper part an ejector 2 is coaxially mounted for primary ozonation of the initial wastewater entering this sump. The ejector is located in the receiving chamber 3, made in the form of guide walls for circulation of a mixture of wastewater and ozone. The source water is supplied through pipeline 4 and ozone from the ozonizer 5. To release water from the sump 1, a window 6 and a chamber 7 are provided in its wall. In the aeration tank 8, the aerator 9 is located in its upper part and is made in the form of a water-air ejector. At the outlet of the sludge mixture from the aeration tank, a biofilter 10 is installed, made in the form of a thin-layer sedimentation module with the formation in its lower part of the compartment 11 for the precipitated biofilm in communication with the air-air ejector of the aerator 9. The secondary clarifier 12 at the outlet of the clarified water has a microfilter 13 s capacity of 14 to collect it. The clarified and filtered water tank 15 has an ejector 16 installed in its upper part for final ozonation and an ozonator 17 communicated with it. The purified and disinfected water is removed through a pipe 18, and the sludge from the primary sump 1 and additional sump 19 through the pipe 20, recirculation of activated sludge from the secondary sump to the aeration tank and the primary and secondary sump through pipeline 21.

 Installation for deep biochemical wastewater treatment when implementing the proposed method in it works as follows.

 The source wastewater through pipeline 4 enters the ejector 2, into which an ozone-air mixture is supplied from ozonator 5. At the outlet of the ejector 2 diffuser, the mixture of wastewater with the ozone-air mixture forms a foam; the volume ratio of wastewater and air-water mixture is 1: 1-1: 2.5 . Thanks to this process, ozone and oxygen are rapidly absorbed by the wastewater, and the fast oxidation processes of the destruction of complex organic molecules begin. The receiving chamber 3 in the form of guide walls provides directional circulation of the specified mixture first down and then up along the periphery of the primary sump, while suspended suspensions and coagulating colloids and suspensions are actively precipitated from the wastewater. If almost all ozone has been consumed for the oxidation of contaminants, and in sedimentation tank 1 there is a sufficient amount of suspended particles by the cleaning technology, water enters the aerotank 8 for biological treatment. If the processes of decomposition of suspensions in the primary sump are not completed, the wastewater initially treated with ozone through the window 6 and chamber 7 enters the additional sump 19, where suspensions and coagulating colloids and suspensions are completely deposited, and from it through the overflow pre-treated water enters the aeration tank . In the tank 8, water is aerated by one of the known methods. The invention proposed the implementation of the aerator in the form of a water-air ejector, which provides directional circulation of the sludge mixture in the volume of the aeration tank and an active biological cleaning process. From the aeration tank, the sludge mixture enters the biofilter 10, where the biofilm of activated sludge is separated from the water in a thin-layer sedimentation. The biofilm is collected under a biofilter in compartment 11, from where it is fed to the inlet of a water-air ejector-aerator 9 to activate biological processes in aeration tank 8. After separation of the biofilm, water enters the secondary clarifier 12 for clarification, from which clarified water is microfiltered, and the sediment is fed to recirculation in the aeration tank 8, as well as in the primary and secondary sedimentation tanks. The water filtered through a microfilter 13 is collected in a container 14, from which it is supplied to a tank 15, where it is treated with ozone using an ejector 16, which delivers an ozone-air mixture with an ozone dose of 2.0-20.0 mg / l ozonizer 17. This final ozonation provides disinfection of purified water, reduction of ammonium nitrogen and surfactant content, as well as reduction of COD and BOD of water. In the thin-layer module for settling the biofilter 10, not only the biofilm is separated from the water, but also the processes of denitrification and regeneration of activated sludge under anaerobic conditions. The activated sludge partially enters through the ejector of the aerator 9 into the aeration tank, and partly in the form of excess sludge to the sludge recirculation system and through pipelines 21 is supplied to the primary sump 1 and additional sump 19. Anaerobic digestion of the primary sludge stabilized by the ozone-air mixture and excess activated sludge takes place in these sumps from aeration tank 8. Mineralized sediment from sedimentation tanks 1 and 19 is discharged through pipeline 20.

PRI me R 1. Purification is subjected to source wastewater, characterized by the following indicators, mg / l: BOD _p = 200; With _plat = 220; total nitrogen 30; ammonium nitrogen 20; phosphates 10. This water is treated with ozone in the form of an ozone-air mixture with an ozone concentration of 12 mg / l under conditions of a primary sump 1 using an ejector 4. After aeration, biofiltration, clarification and microfiltration, the water is subjected to final treatment with ozone in the form of an ozone-air mixture with an ozone concentration of 6 mg / l As a result of the complete wastewater treatment, the following indicators of purified and disinfected water were obtained, mg / l: BOD _p 3; With a _platoon 2; total nitrogen 7; ammonium nitrogen 0.3; phosphates 0.5.

PRI me R 2. For processing serves more polluted wastewater, characterized by the following indicators, mg / l: BOD _p = 400; With a _plat 330; total nitrogen 60; ammonium nitrogen 35; phosphates 15. The primary ozonation of this water is carried out with an ozone-air mixture with an ozone concentration of 40 mg / l. Active coagulation and sedimentation of contaminants are observed in the primary and secondary sedimentation tanks. The final ozonation of clarified water is carried out with an ozone-air mixture with an ozone dose of 15 mg / L. As a result of complete water treatment, the following indicators of purified and disinfected water were obtained, mg / l: BOD _p 3, C _pl 3, total nitrogen 8; ammonium nitrogen 0.4; phosphates 0.6.

 The above examples allow us to conclude that the proposed method and installation for deep biochemical wastewater treatment is highly effective.

 The method and installation can increase the ability to separate in the primary sump, accelerate the biological process in the aeration tank and get purified and disinfected water at the outlet with the lowest rates for BOD and other contaminants. The invention allows to reduce the dimensions and metal consumption of the installation by 1.5-2 times.

Claims (11)

 1. The method of deep biochemical wastewater treatment, including primary sedimentation of wastewater, aeration and secondary sedimentation of the sludge mixture, ozonation, the supply of source wastewater, the release of treated water and sludge, as well as recycling of activated sludge, characterized in that when the source of wastewater for primary sedimentation, it is treated with ozone in an amount of 6.0 to 60.0 mg / l, and after secondary sedimentation, purified water is also treated with ozone in an amount of 2.0 to 20.0 mg / l.  2. The method according to claim 1, characterized in that after the initial sieving of the ozone-treated wastewater, it is further defended before being fed to aeration.  3. The method according to claim 1, characterized in that after aeration, the sludge mixture is subjected to biofiltration by thin-layer sedimentation, and the precipitated precipitate is sent for recycling and mixed with aerated wastewater.  4. The method according to claim 1, characterized in that after secondary sedimentation and before being fed to the final ozone treatment, the water is microfiltered.  5. Installation for deep biochemical wastewater treatment, containing a primary sump, aeration tank with an aerator, a secondary sump, pipelines for supplying initial waste water, discharging purified water and removing sludge and recycling activated sludge, characterized in that it is equipped with a primary sump installed in the upper part an ejector for primary ozonation of waste water with a receiving chamber and an ozonizer, as well as a purified water tank with an ejector for final ozonation and an ozonizer.  6. Installation according to claim 5, characterized in that it is equipped with an additional sump communicated with the primary sump and aeration tank.  7. Installation according to claim 5, characterized in that the aeration tank aerator is made in the form of a water-air ejector.  8. Installation according to claim 5, characterized in that the aeration tank is equipped with a biofilter made in the form of a thin-layer sedimentation module with the formation of a biofilm collection compartment in its lower part.  9. Installation according to claims 5, 7 and 8, characterized in that the aeration tank aerator in the form of a water-air ejector is connected to the biofilter biofilm collection compartment.  10. The installation according to claim 5, characterized in that it is equipped with a microfilter installed at the outlet of the water from the secondary sump and the capacity of the purified water.  11. Installation according to claims 5, 6 and 8, characterized in that it is equipped with pipelines for sludge and activated sludge, communicating the lower parts of the secondary clarifier, a compartment for collecting biofilm, primary and additional clarifiers.