RU52397U1 - DEVICE FOR BIOLOGICAL SEWAGE TREATMENT - Google Patents

Abstract

The utility model relates to devices for the biological treatment of domestic, urban and industrial wastewater from organic substances, nitrogen and phosphorus compounds. A device for biological treatment of domestic, urban and industrial wastewater from organic substances, nitrogen and phosphorus compounds includes a sewage supply pipe, a corridor type aeration tank with at least one anaerobic, anoxic and aerobic zones formed along the aeration tank, divided among themselves transverse partitions with windows, as well as a return sludge recirculation pipeline. In the zones formed in the aeration tank, aerators are installed, connected by an air duct to an air supply source. In the anaerobic and anoxic zones of the aeration tank, a load is placed to immobilize microorganisms. The loading for immobilization of microorganisms is made in the form of plane loading blocks formed of vertically arranged alternating flat and corrugated sheets 0.5-5.0 m high. Bottom perforated aerators are installed in the anaerobic and anoxic zones to create a sludge mixture in the zones of coarse aeration, and aerobic bottom porous aerators are installed in the zone to create a sludge mixture in the fine bubble aeration zone.

Description

The utility model relates to devices for the biological treatment of domestic, urban and industrial wastewater from organic substances, nitrogen and phosphorus compounds.

A device for biological wastewater with a high content of organic pollutants is known, comprising a pool having a mixing and acidification zone arranged consecutively in the main flow of water, a zone of severe pollution for anaerobic decomposition of water to form methane, equipped with a device for recycling activated sludge, and a zone of low pollution for subsequent anaerobic decomposition of the liquid with the formation of methane and a secondary clarification zone, equipped with a discharge device for recirculation while the mixing and acidification zone, the zone of severe pollution, the zone of weak pollution and the zone of secondary clarification are separated by partitions, and the zone of severe pollution and the zone of weak pollution are covered with a gas-tight film on top (RF patent No. 2208596, IPC C 02 F 3 / 30, 2003 publication).

A disadvantage of the known device is the low efficiency of wastewater treatment from nitrogen and phosphorus compounds.

A known installation for deep biological wastewater treatment, containing a sequentially installed anaerobic bioreactor, an aerobic bioreactor, a sump equipped with an airdift with an activated sludge recirculation pipe, a post-treatment bioreactor with loading for attached microflora and a disinfection chamber. Anaerobic bioreactor is made with a pyramidal bottom for collecting sediment and with

a central septum not reaching the bottom, forming a biosorption chamber, on the periphery of which there is a load for attached microflora. The biosorption chamber is equipped at the bottom with an aerator. The activated sludge recirculation pipeline is connected to the biosorption chamber and to the aerobic bioreactor. As the loading for the attached microflora in the anaerobic bioreactor and in the bioreactor of purification, finely porous polymeric material is used (RF patent No. 2220918, IPC C 02 F 3/30, publication 2004).

The disadvantages of the known device include the increased risk of clogging the load of the anaerobic reactor with sediment due to its bioflotation and removal from the sedimentary zone.

A device for biochemical treatment of household wastewater and similar industrial wastewater from organic, nitrogen-containing and phosphorus-containing substances, containing a quenching chamber, a flow averager, denitrifier with loading, aeration tanks of the first and second stage, sump, filter with loading moreover, the quenching chamber of the water pressure is located in the averager of the water flow, made in the form of an anaerobic reactor, connected by means of an adjustable backflow through the first partition from den a trifixer connected through an adjustable direct second overflow in the second partition to the first stage aeration tank, which, in turn, is connected through the third third overflow in the third partition to the second stage aeration tank, made in the form of a loading nitrifier, connected through the fourth fourth overflow in the fourth partition with a sump, which is connected through a fifth direct cross-flow in the fifth partition with a filter, while the first stage aeration tank and nitrifier are equipped with an aeration system, a water flow averager, the denitrifier and sump are equipped with hydraulic mixing and recirculation systems

with pumps, the denitrification and nitrificator loading is made in the form of cartridges, and the filter loading is made floating (RF patent No. 2225367, IPC C 02 F 3/30, 2004 publication).

A disadvantage of the known device is the duration of the wastewater treatment process and its low intensity.

The task of creating the proposed utility model is to develop a device that allows to intensify the process of biological wastewater treatment, to increase the reliability and efficiency of wastewater treatment with different contents of organic pollutants.

The essence of the claimed utility model is as follows.

A device for biological treatment of domestic, urban and industrial wastewater from organic substances, nitrogen and phosphorus compounds includes a sewage supply pipe, a corridor type aeration tank with at least one anaerobic, anoxic and aerobic zones formed along the aeration tank, divided among themselves transverse partitions with windows, as well as a return sludge recirculation pipeline. In the zones formed in the aeration tank, aerators are installed, connected by an air duct to an air supply source. In the anaerobic and anoxic zones of the aeration tank, a load is placed to immobilize microorganisms. The loading for immobilization of microorganisms is made in the form of plane loading blocks formed of vertically arranged alternating flat and corrugated sheets 0.5-5.0 m high. Bottom perforated aerators are installed in the anaerobic and anoxic zones to create a sludge mixture in the zones of coarse aeration, and aerobic bottom porous aerators are installed in the zone to create a sludge mixture in the fine bubble aeration zone.

Sheets of flat loading blocks are made of resistant polymer material.

Blocks flat loading made with a specific surface area of 40-150 m ² / m ³ .

The aerobic zone is equipped with an airlift connected by a pipeline to the anoxide zone.

Perforated aerators in the anaerobic and anoxic zones, and porous aerators in the aerobic zone, respectively, are combined into aeration modules, each of which is made in the form of an air duct connected to the air supply source and perforated or porous aerators connected to it.

The porous aerator is made in the form of a tube formed of fiberglass, impregnated with a composition of thermosetting resins followed by its polymerization to form an ordered microporous structure with a predetermined distance between the pores over the entire wall thickness of the pipe.

The perforated aerator is made in the form of a pipe formed from fiberglass with a diameter of perforation holes of at least 3 mm.

The aerobic zone can be equipped with an airlift connected by a pipeline to the anoxide zone.

The number and arrangement of individual zones along the entire length of the aeration tank can vary depending on the specific properties of the wastewater supplied to the treatment.

In a particular embodiment of the device, the anaerobic, anoxic and aerobic zones are arranged in series in the aeration tank, and the inlet of the anaerobic zone is in communication with the return sludge recirculation pipeline.

In another particular embodiment of the device, the first anoxide zone, the anaerobic zone,

the first aerobic zone, the second anoxide zone and the second aerobic zone, while the inputs of the anoxide and aerobic zones are connected to the sewage supply pipe, and the inlet of the first anoxide zone is connected to the return sludge recirculation pipeline.

In another particular embodiment of the device, the first aerobic zone, the anoxide zone, the anaerobic zone and the second aerobic zone are sequentially located in the aeration tank, while the inlets of the first aerobic, anoxide and anaerobic zones are connected to the sewage supply line, and the inlet of the first aerobic zone is connected to the recirculation pipeline return sludge.

In yet another particular embodiment of the device, the first anoxide zone, the anaerobic zone, the second anoxide zone, the first aerobic zone, the second aerobic zone are sequentially located in the aeration tank, while the inputs of the anoxide and anaerobic zones are connected to the sewage supply pipe, the output of the first aerobic zone is communicated by airlift with the entrance of the second anoxide zone, and the entrance of the first anoxide zone is in communication with the recirculation sludge recirculation pipeline.

In addition, in the last zone of the aeration tank (aerobic zone), plane loading blocks formed from vertically arranged alternating flat and corrugated sheets with a height of 0.5-5.0 m can be placed, and bottom perforated aerators to create coarse-bubble aeration of the silt mixture are installed.

The proposed device is illustrated by the technological schemes of wastewater treatment, shown in figures 1-4.

The device includes a sewage water supply pipe 1, corridor type aeration tank 2 containing anaerobic 3, anoxic 4 and aerobic 5. In the anaerobic 3 and anoxic 4 zones, plane loading blocks 6 are arranged in the form of vertically arranged

alternating flat and corrugated sheets with a height of 0.5-5.0 m from resistant polymer material.

Bottom perforated aerators 7 are located in the anaerobic and anoxic zones, located away from the projection of the plane loading blocks on the bottom of the aeration tank, and bottom porous aerators 8 are placed in the aerobic zone. Air is supplied to the aerators through pipeline 9. An airlift 10 is installed in aerobic zone 5 a pipe 11 with an anoxic zone 4. After the aeration tank, a secondary settling tank 12 is placed, the activated sludge from which is recycled through a pipe 13.

The proposed device operates as follows.

Wastewater through pipeline 1 enters the aeration tank and passes in an predetermined order anaerobic 3, anoxic 4 and aerobic 5 zones.

The number, size and arrangement of zones can be varied and adapted to a specific wastewater treatment process.

Oxygen-free conditions in the anaerobic and anoxic zones are created by mixing with air supplied by perforated aerators and organizing a circulation flow of the sludge mixture in these zones, while the flow of sludge mixture passes through the surface loading blocks from top to bottom at a speed of 0.05-0.5 m / sec

The location of the planar loading blocks 6, made in the form of vertically arranged alternating flat and corrugated sheets with a height of 0.5-5.0 m of polymer material, and the designated speed of circulation of the sludge mixture through them, provide the optimal hydrodynamic regime for the development and functioning of the biofilm.

Passing from top to bottom through flat loading units, the sludge mixture quickly loses residual oxygen and nitrates. As a result, not

Anaerobic conditions with a high acetate content are created only in the biofilm, but also in the volume between the loading elements. This stimulates the development of phosphoric bacteria, which quickly absorb acetate under anaerobic conditions and synthesize intracellular pH (poly-β-hydroxybutyrate) from it, using the energy of hydrolysis of cell polyphosphates to orthophosphates (orthophosphates are released by phosphoric bacteria into the medium, i.e., secondary phosphate wastewater pollution).

In anoxic and anaerobic zones due to low intensity (minimum permissible aeration intensity, at which activated sludge is kept in suspension within 2-2.5 m ³ / h of air per 1 m ² of surface area of the aeration tank) coarse-bubble (diameter of air bubbles is more than 6 -8 mm) aeration by porous aerators creates practically oxygen-free conditions (the concentration of dissolved oxygen is only 0.05 mg / l). Denitrification (bioreduction of nitrates to molecular nitrogen) by activated sludge occurs in the entire volume of the zone. In addition, denitrification is intensively taking place in the surface layer of the biofilm, where nitrates penetrate. Anaerobic conditions are created in the depths of the biofilm and acid fermentation of organic substances proceeds intensively with the formation, mainly, of acetate.

Placing flat loading blocks made of alternating flat and corrugated sheets of resistant polymer material in the anoxic and anaerobic zones allows intensifying and stabilizing the biological treatment process by increasing the total concentration of biomass (activated sludge and biofilms) and higher resistance of biofilm microorganisms to flow rate fluctuations and wastewater pollution.

Flat loading allows you to create anaerobic conditions (no oxygen and nitrates) even when aerating the silt mixture with perforated aerators, i.e. without the use of expensive bourgeois. In addition, conditions are created for the development of a specific microbial cenosis on the loading surface, which increases the rate of denitrification and biological dephosphation.

Then, when the sludge mixture flows into the aerobic zone of the aeration tank, phosphorus bacteria quickly consume phosphates from the wastewater, which are stored in the form of polyphosphates inside the cells (this ensures additional purification of wastewater from phosphates). At the same time, there is aerobic growth and reproduction of phosphoric bacteria synthesizing biomass using RNV accumulated under anaerobic conditions as a carbon source.

The porous Kreal aerators used in the aerobic zone used to implement the wastewater treatment method are described in Patent PM 32487. The porous aerator is made in the form of a tube formed of fiberglass, impregnated with a composition of thermosetting resins followed by its polymerization and having an ordered microporous structure with a given distance between pores. Porous aerators create finely bubbled (the diameter of air bubbles does not exceed 4 mm) aeration with high efficiency of mass transfer of oxygen from air to water, which provides the necessary saturation of water with oxygen (the intensity of aeration created in the aerobic zone by bottom porous aerators provides a concentration of dissolved oxygen in the aerobic zone of not less than 2 mg / l).

Perforated aerators are used as mixing devices to maintain activated sludge in suspension and to create anoxic and anaerobic zones necessary for removal

nitrates in the process of denitrification. They are made of the same materials and have the same dimensions as the porous tubular aerators, but the walls of the perforated aerators are impervious to air and contain holes with a diameter of at least 3 mm. The mass transfer efficiency of oxygen is 3-3.5 times lower than for porous aerators. With a low intensity of aeration (2-2.5 m ³ / h of air per 1 m ^{2 of} the surface area of the aeration tank) this makes it possible to create practically oxygen-free conditions (C0 <0.05 mgO ₂ / l) necessary for the implementation of effective purification from nitrogen and phosphorus .

Aerators are placed as a part of aeration modules, which are arranged in several rows with an interval of up to 1.1 m, forming a wide aerated strip corresponding to the width of the aerated structure, which additionally increases the efficiency of oxygen use of aerated air and allows maintaining activated sludge in suspension even at low aeration intensity (up to 2-2.5 m ³ / h of air per 1 m ^{2 of} the surface area of the aeration tank).

The use of effective aerators with a wide aeration band in the aerobic zone leads to an increase in the rate of biooxidation of organic substances and ammonia nitrogen due to an increase in the concentration of dissolved oxygen, and due to the dispersed supply of wastewater, an increase in the dose of activated sludge occurs.

The aeration system formed in this way makes it possible to create aerobic, anoxic and anaerobic zones in the aeration tank using two types of Kreal aerators and different aeration intensities.

On this basis, technologies for the treatment of wastewater from nitrogen and phosphorus (nitridenitrification and biological dephosphorization technologies) have been developed and are being implemented while reducing air consumption for aeration.

The advantage of the proposed device is the intensification of the process of biological wastewater treatment, increasing the efficiency of treatment and reducing the time of wastewater treatment.

Claims (12)

1. A device for the biological treatment of domestic, urban and industrial wastewater from organic substances, nitrogen and phosphorus compounds, containing a sewage supply pipe, a corridor type aeration tank with at least one anaerobic, anoxic and aerobic zones formed along the length of the aeration tank, separated by transverse partitions with windows, as well as a recirculation sludge recirculation pipe, while in the formed zones aerators are installed, connected by an air duct to the air supply source, and in the ane In the opposite and anoxic zones, a loading for immobilizing microorganisms is placed, characterized in that the loading for immobilizing microorganisms is made in the form of plane loading blocks formed of vertically arranged alternating flat and corrugated sheets with a height of 0.5-5.0 m, while in anaerobic and anoxic bottom perforated aerators are installed in the zones to create a coarse-bubble aeration of the sludge mixture, and bottom porous aerators are installed in the aerobic zone to create a fine-bubble a radio-sludge mixture. 2. The device according to claim 1, characterized in that the sheets of the blocks of flat loading are made of resistant polymer material. 3. The device according to claim 1, characterized in that the planar loading blocks are made with a specific surface of 40-150 m ² / m ³ . 4. The device according to claim 1, characterized in that the perforated aerators in the anaerobic and anoxic zones, and the porous aerators in the aerobic zone, are combined respectively into aeration modules, each of which is made in the form of a duct connected to the air supply source and perforated connected to it or porous aerators. 5. The device according to claim 1, characterized in that the porous aerator is made in the form of a tube formed of fiberglass impregnated with a composition of thermosetting resins followed by its polymerization to form an ordered microporous structure with a predetermined distance between the pores over the entire wall thickness of the pipe. 6. The device according to claim 1, characterized in that the perforated aerator is made in the form of a pipe formed from fiberglass with a diameter of perforation holes of at least 3 mm. 7. The device according to claim 1, characterized in that the aerobic zone is equipped with an airlift, connected by a pipe to the anoxide zone. 8. The device according to claim 1, characterized in that the anaerobic, anoxic and aerobic zones are sequentially located in the aeration tank, and the inlet of the anaerobic zone is in communication with the return sludge recirculation pipeline. 9. The device according to claim 1, characterized in that the first anoxide zone, the anaerobic zone, the first aerobic zone, the second anoxide zone and the second aerobic zone are successively located in the aeration tank, while the inputs of the anoxide and aerobic zones are in communication with the sewage supply pipe, and the inlet of the first anoxide zone is in communication with the return sludge recirculation pipeline. 10. The device according to claim 1, characterized in that the first aerobic zone, the anoxide zone, the anaerobic zone and the second aerobic zone are sequentially located in the aeration tank, while the inlets of the first aerobic, anoxide and anaerobic zones are in communication with the sewage supply pipe, and the inlet of the first the aerobic zone is in communication with the return sludge recirculation pipeline. 11. The device according to claim 1, characterized in that the first anoxide zone, the anaerobic zone, the second anoxide zone, the first aerobic zone, the second aerobic zone are sequentially located in the aeration tank, while the inputs of the anoxide and anaerobic zones are in communication with the sewage supply line, output the first aerobic zone is communicated by airlift with the inlet of the second anoxide zone, and the entrance of the first anoxide zone is communicated with the return sludge recirculation pipeline. 12. The device according to any one of claims 1 to 11, characterized in that in addition to the last aerobic zone of the aeration tank are placed flat loading blocks formed of vertically arranged alternating flat and corrugated sheets with a height of 0.5-5.0 m, and bottom perforated aerators for creating coarse aeration of the silt mixture.