RU2255050C1 - Sewage water biological purification system - Google Patents

Abstract

FIELD: biological purification constructions for purifying of domestic and industrial water by means of active silt.

SUBSTANCE: system has aeration tank, primary and secondary settlers, pumping station adapted for supplying of silt mixture from aeration tank into primary settler, pipes for supplying of basic sewage water and purified water, silt mixture and return active silt, bypass pipe with locking-regulating fittings, and sediment removal apparatus mounted in primary settler and connected with aeration tank. Apparatus has partition wall equipped with bypass openings and adapted for dividing said apparatus into two equal parts. Bypass pipe is positioned for supplying of basic sewage water into aeration tank.

EFFECT: provision for standard quality of purified water and maintaining loading of silt at abrupt increase in volume of basic sewage, and increased capacity of purification constructions above design value.

1 dwg, 1 tbl

Description

The invention relates to the biological treatment of wastewater with activated sludge and can be used in wastewater treatment plants for the treatment of domestic and industrial wastewater.

It is well known that after their treatment, wastewater is discharged into rivers and lakes, therefore very stringent requirements are always imposed on the quality indicators of treatment. A common problem of all existing biological wastewater treatment facilities is the ability to provide regulatory parameters for the quality of treatment in conditions of fluctuations in the treatment regime, and especially with “salvo emissions” of wastewater. During this period, the dose of sludge in aeration tanks is significantly reduced, and this cannot but affect the quality of treatment.

A known method of extended aeration of wastewater, which consists in prolonged aeration of a mixture of wastewater and activated sludge recirculated from secondary sumps, in which wastewater treatment and stabilization of sludge are simultaneously carried out (SNiP 2.04.03-85 Sewerage. Outdoor networks and structures. M., Stroyizdat, 198b, p. 39).

The disadvantages of this method are the large volumes of structures, as well as the excessive consumption of air for aeration due to the need to maintain a minimum intensity of mixing of the silt mixture.

A device for aerobic biological wastewater treatment with activated sludge containing a biofilter with loading, a wastewater supply tray, aeration tank with aerators, a secondary sump with a layer of settling activated sludge, a recirculation pump and a return sludge pipe. In order to deeply remove ammonia nitrogen and intensify the biological cleaning process, the biofilter is made in the form of a float with a nozzle located in the upper part of the aeration tank corridors (RF patent No. 2172300, class C 02 F 3/00, publ. 08/20/2001).

The device allows you to increase up to 20-30% the mass of sludge in the system “aeration tank - secondary sump” due to the attached microorganisms developing on the nozzle. However, the presence of a large number of floats disrupts the transverse circulation of the sludge mixture necessary for the normal functioning of microorganisms. Huge material costs for the installation of floats and operational difficulties associated with the regeneration of carriers of attached biomass significantly reduce the positive effect of this proposal. In addition, bioreactors are designed to provide cleaning at maximum flow, and at minimum costs, these structures are underloaded.

The closest in technical essence to the claimed technical solution is a biological treatment system, protected by author. St.V. USSR No. 1481211, cl. C 02 F 3/02, publ. 05/23/89

The system contains aeration tank, primary and secondary sedimentation tanks, a pumping station, pipelines for supplying initial and treated effluents, sludge mixture and return activated sludge. In order to increase the stability of work with uneven flow of wastewater, the system is equipped with bypass pipelines with shut-off and control valves, one of which has an aeration tank. One of the bypass pipelines is connected to the pressure pipe of the return sludge and the pipe of the sludge mixture, and the second to the pipe of the sludge mixture and the suction pipe of the return sludge.

With a maximum supply of source wastewater, all sludge discharged from the sedimentary zone of the secondary sump enters the aeration tank. With a decrease in wastewater flow, the gate valve on the bypass pipe opens slightly and part of the sludge enters the secondary sump through this pipeline.

This system eliminates the redistribution of masses associated with fluctuations in the flow rate of wastewater between the aeration tank and the secondary sump and allows maintaining the concentration of sludge in the aeration tank. However, with an increase in wastewater inflow, it is absolutely necessary to increase the dose of sludge in the aeration tank to maintain the established parameters, but this is not possible in this system. In the above scheme, there is a need for additional aeration of the sludge circulating through the secondary sump to prevent the denitrification process, which complicates the operating conditions.

In addition, the well-known biological treatment system allows to ensure the stability of the facilities only within the installed capacity of the facilities, excluding, if necessary, the possibility of increasing the productivity of facilities beyond the design. With an increase in the hydraulic load on the structures, the concentration of suspended solids significantly decreases and the primary sedimentation tanks cease to fulfill their functions in full, turning into transit tanks.

These disadvantages limit the possibility of using the described biological treatment system for uneven flow of wastewater, especially with a sharp increase in their volume.

The present invention solves the problem of ensuring regulatory parameters of the quality of treated wastewater and preserving the load on the sludge with a sharp increase in the volume of source wastewater, and also allows you to increase the capacity of facilities in excess of the design capacity due to the rational use of existing tanks.

To achieve the specified technical result in the known biological wastewater treatment system containing aeration tank, primary and secondary sumps, a pumping station, pipelines for supplying the source and treated effluents, sludge mixture and return activated sludge, as well as a bypass pipe with shut-off and control valves, the following significant differences:

- the system is equipped with a device for removing sediment installed in the primary sump and connected to the aeration tank;

- the aeration tank has a longitudinal partition dividing it into two equal parts with bypass openings;

- the pumping station is installed with the ability to ensure the supply of sludge mixture from the aeration tank to the primary sump, and the bypass pipeline - the source drains into the aeration tank.

The installation of a bypass pipeline with the possibility of supplying the initial effluent to the aeration tank, bypassing the primary sump, allows you to increase the dose of sludge in the aeration tank in proportion to the increase in organic pollution load due to an increase in the volume of secondary sumps.

Separation of the aeration tank available in the system into two equal parts, i.e. into two aeration tanks, with the help of a longitudinal partition with bypass holes, in case of increasing hydraulic load, the system “primary sump - aeration tank - secondary sump” can be divided into two systems “aeration tank - secondary sump”, thereby improving the sedimentation conditions of the sludge mixture due to a twofold increase in volume zones of sedimentation.

The presence in the primary sump of a device for removing sediment connected to the aeration tank allows you to quickly switch from pumping raw sludge to the sludge circulation mode to quickly increase its mass.

The installation of a pumping station with the ability to ensure the supply of sludge mixture from the aeration tank to the primary sump allows to increase the circulation of sludge in proportion to the volume of incoming effluents to prevent the removal of sludge mass with purified water.

These design differences make it possible to provide such a scheme for treating wastewater with an increase in hydraulic load up to 50% over the design one, which allows to increase the dose of sludge in the aeration tank from 2-3 g / l to 3-5 g / l, as a result of which the load on the sludge does not increase and quality indicators of treated effluents are not deteriorating. This ensures compliance with the regulatory requirements, according to which, with an increase in the dose of sludge in aeration tanks by 2 times, ceteris paribus, the specific surface of the secondary sumps should be increased by 1.4-1.5 times.

The drawing shows a diagram of the proposed biological treatment system.

The system contains a primary sump 1, a secondary sump 2, an aeration tank divided by a partition 3 with bypass holes 4 into two equal parts 5a and 5b, as well as a pumping station 6 installed with the possibility of feeding the sludge mixture into the primary sump 1 and connected to it by a pipe 7. The system is equipped with a device for removing sludge 8 and an airlift 9, located in settlers 1 and 2 and connected to aeration tanks 5a and 5b by pipelines 10 and 11, respectively.

The pipeline 12 of the source wastewater is connected to the inlet of the primary sump 1, the outlet of the sludge zone of which is connected by a pipe 13 to the inlet of the aeration tank 5a. The exit from the aeration tank 5b is connected by a sludge mixture conduit 14 to the inlet of the secondary sump 2.

To remove the treated effluents from the secondary sump, a pipe 15 connected to the sludge zone of the sump 2 is used. The system is also equipped with a bypass pipe 16 with shut-off and control valves 17 installed with the possibility of supplying the initial effluents to the aeration tank. Pipelines 18 and 19 are designed to supply crude sediment from sump 1 for treatment and removal of treated effluents, respectively.

The proposed biological wastewater treatment system operates as follows.

Under normal conditions, the initial wastewater through line 12 enters the primary sump 1, from which the settled wastewater is passed through line 13 to the inlet of the aeration tank 5a, is moved through it, mixed with activated sludge, and through the bypass holes 4 in the baffle 3 enter the aeration tank 5b. Next, the sludge mixture through pipeline 14 enters the secondary sump 2, the purified waste fluid through pipeline 15 is discharged for further processing, and the circulating activated sludge by airlift 9 is fed through pipeline 10 to the beginning of the aerotank 5a.

In the case of a sharp (up to 30-50% over the design) increase in the quantity of effluents, activated sludge is removed from the secondary settling tank 2 with purified water, which negatively affects both the quality indicators of the treated effluents and the operation of the aeration tank. To prevent the removal of sludge, pipelines 12 and 13 are connected using the bypass pipe 16, which allows the wastewater to be supplied directly to the aeration tanks, bypassing the primary sump 1. The sludge mixture from the end of the aeration tank 5a is fed into the primary sump by pump station 6, which allows two times reduce the hydraulic load on the secondary sump 2. The sludge from the primary sump 1, which in this case acts as a secondary sump, is pumped by the device 8 to the aerotank 5b, and the treated effluent yayutsya on line 19.

When the hydraulic load is reduced to the design, the operation of the treatment plant is ensured according to the usual scheme, while the pipeline 16 is blocked and the initial waste water enters the primary sump, the pump station 7 is turned off, and the device 8 switches to pumping the raw sludge from the primary sump 1 using the pipeline 18.

The proposed biological wastewater treatment system was tested on one of the three processing lines of the OSK in Berezovsky, Kemerovo region. The results of industrial tests showed that even with a significant increase in the hydraulic load on the treatment plant (from 5 to 8 thousand m ² / day), standard parameters of the quality indicators of treatment were provided, the dose of activated sludge was increased, and the sludge index was significantly reduced (see the Table).

Thus, the reconstruction made it possible not only to increase the productivity of the facilities by 60%, but also to significantly improve the quality of effluents. At the same time, an economic effect was achieved due to the refusal to build additional facilities in the amount of 5 million rubles.

Table No.
p / p The name of indicators One measured. Indicators Before reconstruction After reconstruction 1 2 3 4 5 1 Block performance thousand m ³ / day 5 8 2 Weighted content
substances: - before cleaning mg / l 130.0 130.0 - after cleaning mg / l 18.0 12.0 3 BPK20: - before cleaning mg / l 110.0 110.0 - after cleaning mg / l 15.0 10.0 4 Nitrogen content ammonium: - before cleaning mg / l 8.0 8.0 - after cleaning mg / l 3.0 1.0 5 Silt dose g / l 3.0 5.0 6 Silt index cm ³ / g 100.0 60.0

Claims (1)

Biological wastewater treatment system containing aeration tank, primary and secondary sedimentation tanks, a pumping station, pipelines for supplying initial and treated effluents, sludge mixture and return activated sludge, as well as a bypass pipeline with shut-off and control valves, characterized in that it is equipped with a removal device sediment installed in the primary sump and connected to the aeration tank, which has a longitudinal partition with bypass holes, dividing it into two equal parts, while the pumping station is installed phenomenon to supply the mixed liquor from the aeration tank into the primary settling tank, and the bypass conduit - raw sewage in the aeration tank.