RU76642U1 - DEVICE FOR BIOLOGICAL CLEANING OF HOUSEHOLD WASTE WATER AFTER MECHANICAL CLEANING - Google Patents

Abstract

The utility model relates to devices used for biological treatment of domestic wastewater after mechanical treatment. The device contains a series-hydraulically connected multi-chamber aeration tank, consisting of interconnected chambers in which a plastic carrier of fouling microorganisms equipped with aeration devices is placed, a thin-layer shelf sedimentation tank and a disinfection device. Each of the aeration chamber chambers is divided into an aeration zone and a settling zone. The aeration zone is formed due to two parallel grids, between which a large-porous, open-pore plastic carrier of fouling microorganisms circulating in the entire volume of the zone is placed. A tray with toothed weirs for supplying purified water is mounted above the upper grid. An aeration device is installed under the lower grid, under which a settling zone is located, bounded below by the bottom of the corresponding chamber, having a longitudinal section in the form of an inverted cone. The zone of settling of each chamber except the last is separated from its aeration zone by a vertical partition that does not reach the bottom of the settling zone, and at the same time, it is separated from the aeration zone of the subsequent chamber by a partition that has a through window in the upper part connected to the tray with gear spillways. In the well, formed by these partitions, between the first and second chambers there is a shelf thin-layer block for the deposition of a heavy suspension. The last aeration tank chamber at the border with a thin-layer shelf sedimentation tank has a partition that does not reach the bottom of the settling zone. The bottom of a thin-layer shelf sedimentation tank is made conical in a longitudinal vertical section and forms a settling zone. In this zone and in the zones of sedimentation of each of the chambers of the aeration tank, pipelines with valves are placed to remove sediments under hydrostatic pressure. This embodiment of the device provides improved biological indicators of the treated wastewater with increased loads on pollution and wastewater consumption, to improve the technological characteristics of the device and, accordingly, reduce operating costs by increasing the speed of removal and processing of wastewater pollution.

Description

The utility model relates to devices used for biological treatment of domestic wastewater after mechanical treatment.

Of the many known from various sources, the closest in purpose and in terms of characteristics to the claimed utility model is the biological treatment plant for domestic wastewater KKV.9 (KKV - 315.911.X + D), designed and manufactured by RE ### U352ETILOVS un CO ( Jelgava, Latvia). According to her passport (2003), it is a device made in the form of a block of tanks, namely, a receiving chamber, a multi-chamber aeration tank, coagulation and flocculation chambers, which are hydraulically and connected in series, as well as a secondary thin-layer shelving tank equipped with a pump, from which purified from impurities water is supplied to the device for disinfection. The first and last aeration chamber chambers are partially filled with a floating plastic carrier and the two chambers are filled with a plastic block carrier of fouling microorganisms, which is distributed throughout the volume of the aeration chamber chambers. These chambers are equipped with aeration devices, while they have flat bottoms and communicate with each other by means of bottom slots.

In the specified device, the purified water after mechanical cleaning from the receiving chamber to the first chamber of the aeration tank is supplied from below, biological products are also introduced there. Then, the water containing the excess microflora formed, through the corresponding bottom slots enters first into the second, and then into the third and fourth chambers of the aeration tank. Under the influence of oxygen from the air from the aeration device, fouling microorganisms mounted on plastic carriers process the contaminants and excess microflora in the water that remain in the water and come from the previous chambers. From the fourth (and last in this case) chamber of the aeration tank, the purified water with the microflora contained in it passes through the bottom slit into the coagulation and flocculation chambers, into which the coagulant and flocculant are directly fed and mixed with water for

binding dissolved compounds of nitrogen, phosphorus and enlargement of suspended particles. The resulting mixture enters a thin-layer shelf sump, from which it is fed to the disinfection device. The precipitate formed in the sump is removed by the pump and partially fed into the coagulation and flocculation chambers.

The disadvantages of the known device, selected as the closest analogue - the prototype of the claimed utility model, are as follows. Due to the design features of the aeration tank and the use of floating and block plastic carriers in the process of water purification, excess microflora is removed from the corresponding chambers of the aeration tank to neighboring ones, as well as the formation and accumulation of sediment at the bottom of the chambers. At the same time, siltation of the surfaces of the block plastic carrier occurs. This requires a periodic shutdown of the device to clean it and clean the block plastic carrier. In addition, the need to ensure forced circulation of the secondary sediment and its removal, as well as the introduction of part of it into the coagulation and flocculation chambers, require additional energy costs. In addition, the cost-effectiveness of the device is adversely affected by the need to use biological products, coagulant and flocculant, the removal of microflora with purified water into the disinfecting device affects its sanitary performance.

The objective of the claimed utility model is to create the design of a device for the biological treatment of domestic wastewater after mechanical treatment, which is characterized by increased constructive, technological and operational characteristics compared to the prototype, which are ensured by creating conditions for circulation in the entire volume of the aerated zone of each chamber of the large-porous aeration tank with open pores of the plastic carrier, eliminating the removal of excess microflora from the chambers, as well as forced Dalen accumulating at the bottom chambers sludge aeration tank.

As a result of solving this problem, it becomes possible to provide improved biological indicators of the treated wastewater with an increase in pollution loads and wastewater consumption, as well as to increase the rate of removal and processing of wastewater pollution, to improve the technological characteristics of the device and, accordingly, reduce operating costs.

The specified technical result is achieved in that, in contrast to the known in the device for biological treatment of domestic wastewater after mechanical treatment, containing a series-hydraulically connected multi-chamber aeration tank, consisting of interconnected chambers, which are placed

a plastic carrier of fouling microorganisms and equipped with aeration devices, a thin-layer shelf sedimentation tank and a disinfection device, each of the aeration chamber chambers is divided into an aeration zone and a settling zone, the first zone formed by two parallel grids, between which a large-pore circulation circulating throughout the entire volume of the zone with open pores, the plastic carrier of fouling microorganisms, while a tray with serrated weirs is mounted above the upper grid for supplying purified water, under the aeration device is installed on the bottom grid, and the settling zone below the aeration device is bounded by the bottom of the corresponding chamber, having a longitudinal section in the form of an inverted cone, the settling zone of each chamber except the last is separated from its aeration zone by a vertical partition that does not reach the bottom of the settling zone, and at the same time it is separated from the aeration zone of the subsequent chamber by a septum reaching the bottom, having a through window in the upper part, connected to a tray with serrated weirs, comb in the well, formed by these partitions, between the first and second chambers there is a shelf thin-layer block for sedimentation of heavy suspension, and the last aeration tank chamber at the border with a thin-layer shelf settler has a partition that does not reach the bottom of the settling zone, the bottom of the thin-layer shelf settler is conical in longitudinal vertical section and forms a zone of sedimentation, in the specified zone and in the zones of sedimentation of each of the chambers of the aeration tank there are pipelines with valves to remove sediment under the hydrostat pressure.

Moreover, the above-mentioned plastic carrier of fouling microorganisms circulating in the entire volume of each aeration zone is made large-pore and has open pores of up to 8 mm, the transverse sizes of fractions are from 15 to 25 mm, longitudinal from 30 to 50 mm, and occupies in each aeration zone, where posted, up to 10% of its volume.

The indicated technical results can only be obtained by implementing the entire set of essential features characterizing the claimed utility model. A comparison of the essential features of the claimed model with the characteristics of the closest analogue selected as a prototype gives reason to assert that the utility model meets the eligibility criterion of "novelty."

Figure 1 shows the design of the device for biological treatment of domestic wastewater after mechanical treatment (top view)

Figure 2 presents a section I-I of figure 1.

The device contains a multi-chamber aeration tank 1, consisting of interconnected chambers 2, partially filled with large-pore open-pore plastic carrier 3 of fouling microorganisms. Each chamber 2 is equipped with an aeration device made of horizontally mounted aerators 4 connected to a common air supply line 4. The last chamber 2 of the aeration tank 1 is connected to a thin-layer shelf settler 5 containing a thin-layer shelf unit 6. The settler 5 is connected to the disinfection device 8 by means of a discharge pipe 7 .

Each chamber 2 of the aeration tank 1 is divided into an aeration zone 9 and a settling zone 10. The aeration zone 9 is formed by two parallel upper grids 11 and lower 12. Between the grids 11 and 12, a large-porous open-pore plastic carrier 3 is placed. The aeration device is installed in the chamber 2 under the lower grid 12. The settling zone 10 is located under the aeration zone 9 and is bounded below by the bottom of the chamber 2, which has an inverted cone shape in longitudinal section. The settling zone 10 of each chamber 2, with the exception of the one directly located in front of the thin-layer shelf sedimentation tank 5, is separated from the aeration zone 9 by a vertical partition 13 not reaching the bottom of the settling zone 10, and from the aeration zone of the subsequent chamber 2 is separated by a partition 14 reaching the bottom of the settling zone 10. Partitions 13 and 14 form wells 15. The partition 14 in its upper part has a through window 16 connected to the tray 17 with gear weirs. In the well 15 between the first and second chambers 2, a shelf thin-layer block 6 is installed across the upward flow of water to deposit a heavy suspension. The chamber 2, directly connected to the thin-layer shelf settler 5, has a partition 13 not reaching the bottom of the settling zone 10. The bottom of the thin-layer shelf settler 5 is conical in longitudinal vertical section and forms the lower part of the settling zone 10. In the lower parts of the settling zones 10 of each chamber 2 and a thin-layer shelf sump 5 installed nozzles of vertical pipelines 18 with valves to remove sediment under hydrostatic pressure.

All pipelines 18 are combined into a single pipeline 19, the upper end of which is open and raised above the walls of the device to provide the necessary hydrostatic pressure.

Plastic carriers 3 of fouling microorganisms partially fill the chamber 2 with the possibility of circulation in the entire volume of the aeration zone 10, made

are large-pore and have open pores up to 8 mm, the transverse sizes of the fractions are from 15 to 25 mm, longitudinal from 30 to 50 mm and occupy in each aeration zone 10, where they are located, up to 10% of its volume.

The device operates as follows.

After mechanical cleaning, domestic wastewater enters the device from above through an inlet pipe 20 into a tray 17 with gear spills, overflows into the aeration zone 9 of the first of the chambers 2 of the multi-chamber aeration tank 1, partially filled with fractions of a large-pore open-pore plastic carrier 3. During operation of the device, large-pore a plastic carrier 3 is forced to circulate in each aeration zone 9 of the multi-chamber aeration tank 1, rising under the influence of ascending air bubbles coming from the aerators 4 , to the upper grid holding them 11. The presence of open pores in a large-porous plastic carrier 3 allows the fouling microorganisms to populate not only the surface of the carrier 3, but also its volume, which ensures an increase in their mass (dose of activated sludge) and, accordingly, the rate of removal and processing of waste contaminants water. The above-mentioned sizes of fractions of a large-porous plastic carrier 3 and their amount in each aeration zone 9 make it possible to ensure their mixing and circulation in the entire volume of aeration zones 9 after microflora overgrowth, while oxygen is used by microorganisms to oxidize wastewater pollution, and microorganisms that populate the internal volume of the carrier 3, carry out denitrification with nitrogen removal. Fouling the biocenoses of the fouling microorganisms, the fractions of the large-porous plastic carrier 3 are heavier and begin to move down to the lower mesh holding them 12. During the circulation up and down, the fractions of the large-porous plastic carrier 3 are freed from excess microflora, which diffuses into water, increasing the concentration of free-floating microflora (active sludge), which excludes siltation of the large-porous plastic carrier 3 and intensifies the process of water purification and the binding (coagulation) of the suspension, according to Tupa with raw water. The free-floating microflora and biocenoses of fouling microorganisms living on a circulating large-porous open-pore plastic carrier 3, with a bulk density close to the bulk density of water, together maintain a balance in mass and qualitative composition in each aeration zone 9 depending on the type and amount of pollution in water, carry out the mineralization of organic substances, nitrification and denitrification. Partially purified water with 9 suspended substances contained in it removed from the aeration zones,

excess and dead microflora (with excess activated sludge) enter the sedimentation zone 10, where they precipitate, accumulating on the conical bottom of each chamber 2.

Partitions 13, not reaching the bottom of the settling zone 10, installed in each chamber 2 except the last, prevent the breakthrough of air bubbles from the aeration zone 9 into the settling zone 10.

The removal of wastewater from the settling zone 10 of each previous chamber 2 is carried out through the window 16 and the tray 17 with gear weirs by overflowing them into the aeration zone 9 of the next chamber 2 of the multi-chamber aeration tank 1.

Shelf thin-layer block 6, located between the first and second chambers 2, is designed to effectively defend a large number of coagulated microflora, free-floating in the aeration zone 9, suspended solids contained in wastewater entering the device, and removed from the aeration zone 9 of the first chamber 2 of the aeration tank 1 microflora (excess activated sludge), which allows you to refuse to enter the coagulant into the purified source water.

The sediment accumulated at the bottom of the first chamber 2 of the multi-chamber aeration tank 1 is removed through a pipe 18 with a shutter under hydrostatic pressure into the sediment transport pipe 19 with a periodic shutter opening.

In the subsequent chambers 2, the wastewater treatment is carried out in a similar manner with the removal of sediment from the settling zones 10 when the valves are opened on the pipelines 18 into the sediment transportation pipeline 19.

From the last chamber 2 of the aeration tank 1, the purified water through a slot in the partition 13 enters a thin-layer shelf settler 5, in which water passes through a shelf thin-layer block 6, where it settles completely and enters the tray 21 to drain the biologically purified water through the discharge pipe 7 into the device for disinfection 8.

Sludge accumulated at the bottom of a thin-layer shelf sedimentation tank 5 is removed through a pipe 18 with a shutter under hydrostatic pressure into the sediment transport pipe 19 when the shutter is opened, similar to removing sediment from the chambers 2 of the multi-chamber aeration tank 1.

The manufacture of a device made in accordance with the claimed utility model is technically feasible on modern technological equipment used to produce products of a similar purpose.

Claims (2)

1. A device for biological treatment of domestic wastewater after mechanical treatment, containing a series-hydraulically connected multi-chamber aeration tank, consisting of interconnected chambers, in which is placed a plastic carrier of fouling microorganisms equipped with aeration devices, a thin-layer shelf sump and a disinfection device, characterized in that each of the chambers of the aeration tank is divided into an aeration zone and a settling zone, and the first zone is formed by two parallel sets k, between which a large-porous, open-pore plastic carrier of fouling microorganisms circulating throughout the entire zone of the zone is placed, while a tray with serrated weirs for supplying purified water is mounted above the upper grid, an aeration device is installed under the lower grid, and a settling zone located below under the aeration device bounded by the bottom of the corresponding chamber, having a longitudinal section in the form of an inverted cone, the zone of sedimentation of each chamber, with the exception of the latter, is separated from its zone It is connected with a vertical partition that does not reach the bottom of the settling zone, and is simultaneously separated from the aeration zone of the subsequent chamber by a partition reaching the bottom, which has a through window in the upper part, connected to a tray with serrated weirs, and in the well formed by these partitions, between the first and second cameras installed a shelf thin-layer unit for the deposition of heavy suspended matter, and the last aeration tank chamber at the border with a thin-layer shelf sedimentation tank has a partition that does not reach the bottom of the settling zone, the bottom is kosloynogo shelf sump formed in a longitudinal vertical section and forms a conical settling zone in said band and in the settling zones of each of the aeration tank chambers arranged conduits to the gate to remove sediments under hydrostatic pressure. 2. A device for biological treatment of domestic wastewater after mechanical treatment according to claim 1, characterized in that the large-porous circulating plastic carrier of fouling microorganisms with a bulk density close to the bulk density of water has open pores of up to 8 mm, transverse fractions from 15 to 25 mm, and longitudinal from 30 to 50 mm and occupies in each aeration zone where it is located, up to 10% of its volume.