SU1291554A1 - Aerotank - Google Patents

Abstract

The invention relates to the biological treatment of domestic and industrial wastewater with activated sludge and improves the stability of the treatment process under variable load conditions while reducing costs through the use of multifunctional controlled recycling of active biomass. Aerotank equipped with a pneumatic aeration system and recirculation columns

Description

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The iMH 19 with medium bubble dispersers is equipped with a solid dividing wall 7, on which the dividing valve 13 and the overflow pipe 14 are mounted. The sectional transverse arm 8 separates the aeration tank into the mixing and displacement corridors 9 and 10, the regenerator 11 and the reactive air jet 12, the inlet of the initial waste liquid is made in the form of a tray 16 with the lower communicating with the mixing corridor and the upper communicating, with the reactor: holes 17 and 18, the recirculation columns 19 are round in plan, each

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This invention relates to the biological treatment of domestic and industrial wastewater with activated sludge.

The aim of the invention is to increase the stability of the cleaning process under conditions of variable loads while reducing costs through the use of multifunctional controlled recycling of active biomass.

Figure 1 shows the aeration tank, the plan; figure 2 - section aa. On fig. TO

The aero tank contains a rectangular case 1 with an inlet 2 of the original and an outlet 3 of treated waste liquid, a pneumatic aeration system of constant action, consisting of fine dispersed dispersants 4, connected by air ducts 5 to the blowers 6 of the basic aeration system, continuous separating 7 and separating transverse 8 The partitions separating the body of the aerotank into the mixing 9 and pressure 10 corridors, the regenerator 11 and the reactivator 12 have a separation valve 13 and an overflow pipe 14, the upper edge 15 of which Dena at the liquid level in the aerotank. A tray 16 for the inlet of the original waste liquid is placed on a continuous partition wall with bottom distribution openings 17 communicating

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from the outer casing and the central tube with medium-bubble dispersers located in it, the central tube of the column is coaxially located relative to the outer casing with the formation of a peripheral annular space, where small-bubble dispersers of oxygen-containing gas are introduced, and the peripheral annular space through a connecting pipe connected with the initial section of the mixing corridor. With the passage of fluid through the structure, the process of oxygen dissolution is intensified due to the high rates of its consumption. 2 Il.

a mixing corridor and upper distribution openings 18 communicating with the reactivator. The recirculation columns 19 are

each of the outer casing 20 and the central tube 21 with an expanded lower part 22 where the medium-: non-bubbled dispersants 23 are of periodic operation, connected by ducts 24 to blowers 25 of the controlled aeration system. Fine-bubble dispersers 27 connected by pipeline are introduced into the annular peripheral space 26.

28 to the blowers of the basic or controlled aeration systems., The columns 19 are in communication with the initial section of the mixing corridor via the connecting pipe 29. The narrow slots 30 are formed by the lower edges 31 of the outer covers of the recirculation columns and the bottom 32 of the reactivator. The aerotank operates as follows: Wastewater flows into the rectangular housing 1 of the aerotank and through the lower distribution openings I7 of the distribution tray 16 before the inlet of the original waste liquid enters the mixing corridor 9 of the aerotank, where it is mixed with the active sludge coming from the reactivator 12, after which it forms with mix, ae

permanently operated by fine-bubble dispersers 4, connected by air ducts 5 to the air blowers 6 of the basic aeration system, is directed to the pressure corridor 10. During aeration and movement of the waste water mixture with active sludge along the corridors, the aeration tank is carried out by biochemical oxidation of organic contaminants by microorganisms activated sludge, after which the mixture is discharged outside the construction, for example, into a secondary settling tank where purified waste water is separated from activated sludge, the return part of which is is dissolved in a regenerator 1 1 In the regenerator 11 the activated sludge in the presence of dissolved oxygen in the air supplied finely dispersing basal aeration system 4, oxidizes the previously sorbed contaminants and recovers its original activity.

Further, the flow of regenerated sludge, the sectional transverse partition, 8, enters the reactivator 12, which in this mode of operation, when the dividing valve I3 is closed, operates as a storage tank of active sludge. As the return sludge is supplied to the regenerator II, and then to the reactivator 12, its excess by gravity through the overflow pipe 14 is directed to the beginning of the mixing corridor 8 of the aeration tank and the process cycle repeats (Fig. 1).

In this mode, the aerotank, i.e. at relatively low loads on the structure, the concentration of activated sludge in the aeration tank does not exceed 1-1.5 g / l, and the intensity of the basic aeration system is kept at a minimum level, ensuring mainly mixing of the activated sludge.

During the period of increased wastewater inflow, when the level of wastewater in the tray 16 for intake of the original wastewater increases and some of the wastewater is poured through the distribution upper holes 18 into the reactivator 12, blowers of a controlled aeration system 25 connected by air ducts 24 to the middle bubble dispersers are turned on 23 batch recycling columns 19. The air / water mixture formed with

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in the lower expanded portion 22 of the recirculation columns 19, it rises upward along the central pipes 21 and, overflowing through their upper edges,

5 enters the peripheral annular spaces 26 formed by the outer covers 20 of the recirculation columns 19 and the central pipes 21. The influx of fresh sludge mixture flows through the bottom slots 30 formed by the lower edges 31 of the outer covers 20 of the recirculation columns 19 and the bottom 32 of the reactivator 12. The exhaust air is vented to the atmosphere.

 5 ferus, and the silt mixture along the peripheral annular space 26 moves from top to bottom, taking with it small air bubbles, and enters aerotank mixing corridor 9

20 through the connecting pipes 29 (figure 2).

Receipt of part of the wastewater flow in the period of increased inflow

The waste water directly to the reactivator 12 through the upper distribution openings 18 provides partial deoxygenation of the circulating sludge medium before it enters the recirculation columns 19, which allows an increase in the use of air oxygen. At the moment of the construction work, the separation valve 13 is transferred to the open position and the lack of the sludge mixture, fed from the reactant 12 to the beginning of the mixing corridor 9, is automatically compensated by the same amount of sludge mixture

the end of mixing corridor 9 to the bottom of the reactivator 12, i.e. a multifunctional controlled recirculation loop of the sludge mixture is formed, providing the necessary

influence on the processes of hydrodynamics, biological oxidation and dissolution of oxygen in conditions dynamically. varying load on the structure. During this period of work, due to the mutual ° averaging of the volumes of the reactivator I2 and the mixing corridor 9 of the aerotank. The average concentration of the activated sludge involved in the oxidation processes increases from 1-1.5 to 2-4 g / l, since during the period of accumulation of sludge in the reactivator 12 its concentration is maintained at a level of 6-8 g / l. Thus, during the passage of fluid through the construction process

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oxygen dissolution is intensified due to its high consumption rates. The active microorganisms contained in the recirculating sludge mixture receive an additional load in the part of the incoming wastewater, thus stimulating the oxygen dissolution process. During the period of increased loads on the aerofoam, the rate of oxygen consumption is significantly higher than the average for the structure, which allows for the removal of peak loads, ensures stable operation and reduces the total aeration time of wastewater. As a result of the operation of the controlled aera dai system, and, consequently, of the recirculation chambers, the load on the sludge along the length of the aerotank is equalized. When the amount of recirculating sludge mixture varies depending on the load on the sludge, it becomes possible to control the process of biochemical oxidation of contaminants. At the same time, aeration of constant action is calculated on the mi-hymalnost load, and aeration of periodic action is calculated on the maximum, which significantly reduces the operating costs of electricity.

In addition, the recirculation of the sludge mixture allows additional oxygen to be supplied to the beginning of the aerotank in the presence of biologically active sludge as part of the recirculating mixture and an increase in the utilization rate of oxygen of the supplied air.

In the case of the entry of highly concentrated contaminants, such as industrial wastewater, there is a risk of oxygen deficiency in the initial, most loaded points of the mixing corridor 9 of the aerotank even under the conditions of operation of the controlled aeration system. In order to eliminate the oxygen deficiency in the structure, without resorting to complicated and energy-consuming methods, the required amount of oxygen-containing gas from an external source of technical oxygen or blowers 5 or 25 is supplied via pipeline 28 to small bubble dispersers 27 located in the lower part of the annular peripheral space 26 formed by the central pipes 21 and outer covers 20 recirculated 46

cyoing columns 19. The countercurrent collision of bubbles of oxygen-containing gas and the flow of sludge mixture occurring in the annular peripheral space 26 greatly increases the effect of its use and intensifies the processes of mass transfer of oxygen into the liquid, eliminating its deficiency in the structure.

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Thus, as a result of the use of multifunctional recycling of the sludge mixture, it is possible for the operational control of hydrodio.

the aerotank oxygen mode, biokinetics and oxygen mode in a fairly wide range of dynamic changes in the incoming load, at least 40% energy is saved

the volume of the structure is reduced by 50-60% with the achievement of stable indicators of treated water.

Claims (1)

Invention Formula Aerotank containing the prodigal-1y1 body with the inlet of the original and the release of the treated waste liquid, a dividing longitudinal partition, a system of pneumatic aeration. with fine bubble dispersers and recirculation columns of the sludge mixture with medium bubble dispersers installed in them, this is due to the fact that, in order to ensure the stability of the cleaning process under conditions of variable loads while reducing costs by using a multifunctional controlled recycling biomass, it is provided with a transverse sectional partition dividing the walls of the hull, dividing the hull into a mixing and displacement corridor, a regenerator and a reactant, transverse the partition is provided with a separating valve located on its section between the reactive reactor and the mixing corridor, and an overflow pipe, the upper edge of which is located at the liquid level in the aeration tank, the inlet of the source liquid is equipped with a tray placed on the longitudinal partition wall with the mixing the corridor and the upper communicating holes with the reactivator, the recirculation of the column is filled with round, connecting each of the outer casing and At the bottom of the pipe, the upper edge of the columns is located above the liquid level in the reactor, the medium-bubble aerators are located in the lower part of the central eight pipes, and small-pot dispergators - between the casing and the central pipe; the columns are equipped with connecting pipes, connecting them with the initial section of the mixing corridor. 15 Editor N. Gunko Compiled by L. Sukhanova Tehred AJKpasMVK Proofreader M.Samvorsk Order 200/26  Circulation 852Subscribe VNIIPI USSR State Committee for inventions and discoveries 3035, Moscow, Zh-35, Raushsk nab., 4/5 Production and printing company, GGGU dGulGproektna GT FIG. 2