RU168469U1 - Block compartments of a cylindrical tank for biological wastewater treatment - Google Patents

Abstract

The block compartment of the cylindrical reservoir for biological wastewater treatment is designed to accommodate WWTP in the territory of existing sewage treatment plants when they fail due to insufficient performance or due to the destruction of the enclosing structures due to corrosion. The block compartment of a cylindrical tank for biological wastewater treatment includes a cylindrical metal tank with a lid, divided into compartments of denitrification, nitrification of wastewater with free-floating activated sludge, a secondary sump, an aerobic mineralization compartment for sewage sludge, a bioreactor for post-treatment, communication of water and sludge flows, air ducts and bubblers aeration and regeneration. 2 ill.

Description

The block compartment of the cylindrical reservoir for biological wastewater treatment is designed to accommodate WWTP in the territory of existing sewage treatment plants when they fail due to insufficient performance or due to the destruction of the enclosing structures due to corrosion.

It is known to use existing facilities for converting them into facilities for a new purpose, for example, two-tier sedimentation tanks with gutters for settling nitridenitrification with biocenoses of free-floating and attached microorganisms into bioreactors (Kulikov N.I. et al. Biological wastewater treatment in Sochi: Publishing House Doria, 2013, 280 p.) [1].

Economically, such re-equipment is profitable, environmentally sound, but limited by the productivity of the resulting structure.

Closest to the proposed solution is the construction of a capacitive structure for the conditions of Siberia (Kulikov N.I. et al. RF Patent No. 80843. Block module for biological wastewater treatment in Siberia. Patent holder: N.I. Kulikov, publ. February 27, 2009 Bulletin No. 8) [2].

The block of compartments in the prototype has a significant drawback - the maintenance staff is forced to work in the atmosphere of wastewater discharge in equipment and capacitive structures.

The objectives of the utility model are to reduce the cost of a treatment plant by 3-5 times, reduce operating costs, for example, consume electricity, reduce the area allocated for a treatment plant and place SPZ (sanitary protection zones), simplify the operation of a treatment plant.

These tasks are accomplished by equipping the denitrification compartments with mechanical mixers, and the nitrification and aerobic mineralization compartments with axial pumps and agitators for agitating free-floating activated sludge, equipping the aftertreatment bioreactor compartment with a receiver and compressor to compress the air and supply it to the brush nozzle regeneration bubblers.

As a result of equipping the denitrifiers and nitrifiers with a sorption nozzle, the biological purification processes were replaced by sorption processes, which accelerated water purification by 3-5 times and accordingly reduced the size of the denitrification and nitrification compartments.

The introduction of a sorption nozzle into the compartments of the capacitive structure allows to keep a larger number of specific microorganisms in the compartments and significantly accelerate the cleaning process, and, therefore, reduce the size of the treatment plant and its SPZ and simplify the operation of the capacitive structure by reducing maintenance personnel.

The proposed utility model includes a cylindrical reservoir of a tower structure, divided into compartments of nitrification and denitrification, a secondary sedimentation tank, an aerobic mineralizer and a bioreactor of tertiary treatment with a ruff nozzle, closed on top with a sealed lid with a pipe outlet with air and gas emissions from the equipment and capacitive structures for cleaning and rational use gas components. The device is distinguished by the fact that the service personnel and mechanical wastewater treatment facilities do not work in it, the averaging of water flows and the treatment of sludge from the treatment plant are located outside the cylinder compartment block, but mechanical mixers in the denitrification compartments and a pump in the nitrification and denitrification compartment are involved.

The proposed technical solution is illustrated by the drawings shown in FIG. 1, 2, where in FIG. 1 shows a top view of a cylindrical tank with divisions into compartments of denitrification, nitrification, secondary sedimentation tank, aerobic mineralization of a mixture of sewage sludge and activated sludge, a bioreactor for wastewater treatment and compartments of denitrification and secondary sedimentation tank, in vertical section, FIG. 2 - shows a scan of vertical sections of all compartments of a block of a cylindrical tank.

When completing a new capacitive structure in the form of a cylindrical metal tank, treated inside and out with corrosion coatings.

In FIG. 1, 2 the following positions are involved:

1. The cylindrical tank.

1.1. Cylinder Tank Cover 1.

1.2. Denitrification compartments.

1.2.1. The first denitrification compartment.

1.2.2. Second denitrification compartment.

1.3. Nitrification compartments.

1.3.1. First nitrification compartment.

1.3.2. Second nitrification compartment.

1.4. Wastewater treatment bioreactor compartment.

1.4.1. Cartridges with a brush nozzle 1.4.2.

1.4.2. Ruffle nozzle.

1.5. Compartment for aerobic mineralization of sewage sludge.

1.6. The central pipe of a secondary settler 1.7.

1.6.1. Pipe for the flow of purified water from the second nitrification compartment 1.3.2. into the central pipe 1.6 of the secondary sump 1.7.

1.7. Secondary sedimentation tank.

1.7.1. Drainage tray of a secondary settler 1.7.

1.8. Airlift pumping circulating sludge mixture.

1.8.1. Aeration pipeline.

1.9. Pipeline for the circulating flow of nitrified water.

1.10. Pipeline for pumping sludge mixture from the denitrification compartment 1.2. to aerobic mineralizer 1.5.

1.11. Pipeline for excess activated sludge from a secondary sump 1.7. to aerobic mineralizer 1.5 ..

1.12. Sludge mixture transfer pump from the denitrification compartment 1.2. to aerobic mineralizer 1.5 ..

1.13. Pipeline for discharge of compacted stabilized sediment from an aerobic mineralizer 1.5. on the apparatus for dewatering stabilized sludge 13.

1.14. Sealed activated sludge pump.

1.15. Post-treatment bioreactor emptying pump.

1.16. Discharge pipe.

2. Mechanical stirrer.

3. Blower.

4. Ducts.

5. Aeration bubblers.

6. Bubblers of regeneration.

6.1. Ruffle nozzle.

7. Precipitation processing unit.

Works block compartments of the cylindrical tank as follows.

The wastewater filtered and averaged over the flow rate and composition enters the first compartment of the denitrifier 1.2.1 (Fig. 2) inside the cylindrical tank 1 with a dome-shaped cover 1.1., Where it is mixed with the circulation stream of nitrified water 1.9 coming from the compartment of the nitrifier 1.3.2 using airlift 1.8.

Due to the absence of primary sedimentation tanks, the ratio between the BOD of _FULL and the concentration of ammonium nitrogen N-NH ₄ ⁺ exceeds 6: 1, therefore, anammox biocenosis is not required.

From compartments 1.2.1 and 1.2.2. denitrification 1.2 silt mixture flows into the compartments 1.3.1. and 1.3.2 nitrification 1.3. To mix the two flows of wastewater in the compartments of the 1.2 denitrifier, mechanical mixers 2 are used (Fig. 2). The nitrification compartments 1.3 (Fig. 1) are also equipped with agitators 2 for agitating activated sludge to the level of aeration bubblers 5, receiving air from the blowers 3 through air ducts 4. The nitrified sludge mixture flows into the central pipe 1.6 of the secondary clarifier 1.7 through the pipeline 1.6.1. Partially purified water flows from the secondary clarifier 1.7 along the drainage channel 1.7.1. in the compartment of the bioreactor tertiary treatment 1.4 (Fig. 1, 2), equipped with cassettes 1.4.1. with a brush nozzle 1.4.2. and bubblers 6 regeneration of cartridges 1.4.1. air from the receiver. Pipeline 1.11 excess activated sludge from the secondary sump 1.7. is fed to aerobic mineralizer 1.5, where after stabilization for at least 5-6 days in a mixture with sludge from the denitrification compartments 1.2 supplied to them by pump 1.12 through the sludge mixture transfer pipeline 1.10, it settles when the air supply is turned off for a period of at least 10 hours, and silt water is discharged into the cost averager. From aerobic mineralizer 1.5. compacted stabilized sediment is discharged to the precipitation processing unit 7 by pump 1.14. through the pipeline 1.13. The water purified in the after-treatment bioreactor compartment 1.4 is sent to the Ural Federal District and further to consumers.

The aftertreatment bioreactor compartment 1.4 is emptied during the regeneration of the ruff using pump 1.15 into the denitrification compartment 1.2.1 via the evacuation pipe 1.16. Mixing of water in the compartments of the bioreactor tertiary treatment 1.4. produced by airlift 1.8. through the aeration pipeline 1.8.1.

Claims (1)

Block of compartments of a cylindrical tank for biological wastewater treatment, including a cylindrical metal tank with a lid, divided into compartments of denitrification, nitrification of wastewater with free-floating activated sludge, a secondary settling tank, aerobic mineralization of sewage sludge, a bioreactor of post-treatment, communication of water and sediment flows, air ducts and bubblers aeration and regeneration, characterized in that the denitrification compartments are equipped with mechanical mixers, and the nitrification and aerobic mineralization compartments - pumps and agitators for resuspension of the activated sludge, the bioreactor aftertreatment compartment has a receiver and a compressor for compressing air and supplying it into spargers Ershovoy nozzle regeneration.

Images