RU2636707C1 - Method and installation for biological wastewater treatment - Google Patents

Abstract

FIELD: chemistry.SUBSTANCE: method includes the supply of wastewater into a corridor-type aeration basin and treatment with activated sludge in zones formed over the entire length of the aerotank - at least, one anaerobic (AN), two anoxic (D1, D2) and two aerobic (N1, N2) zones. In addition, wastewater is sent to the anaerobic (AN), anoxic (D1, D2) zones and water is treated in an additional third anoxic zone (D3) located between the aerobic zones of the aerotank (N1, N2). The method also includes an internal anoxic recycle from the first anoxic (D1) or the second anoxic (D2) zone to the anaerobic (AN) zone, separating the activated sludge in the secondary settling tank and recycling it to the first anoxoid (D1) zone. The installation for carrying out the method includes a wastewater supply device (1), an aerotank (2), a secondary settler (3), mechanical agitators (4), and aerators (5). The aerotank is divided by transverse partitions into, at least, one anaerobic (AN), two anoxic (D1, D2), two aerobic (N1, N2) zones, and contains the additional third anoxic (D3) zone located between the aerobic zones (N1, N2).EFFECT: improving the efficiency and reliability of biological wastewater treatment.20 cl, 4 dwg

Description

Technical field

The invention relates to the field of biological treatment of domestic, urban and industrial wastewater from organic substances, nitrogen and phosphorus compounds, carried out in the aeration tank-secondary sump system.

State of the art

Currently, various technological schemes for biological treatment of wastewater from organic substances, nitrogen and phosphorus compounds are widely known, such as the University of Cape Town Technology (UCT), the process known as the Virginia Initiative (VIP), and the Modified Johannesburg Process ( MJHB), “Modified Technology of the University of Cape Town” (MUCT), “Modified Bardenfo Process” (5-zone Bardenpho process), etc.

The technology known as the Virgin Initiative (VIP) [available at https://www.researchgate.net/figure/273497206_fig11_FIGURE-11-Virginia-Initiative-Process-ANR-anaerobic-zone-ANX-anoxic-zone- AER], involves the treatment of wastewater in series located in the anaerobic (AN), first anoxide (D1), second anoxide (D2), aerobic (N) and deoxy (DO) zones of the aeration tank, the separation of activated sludge in the secondary sump and its recycling in the first anoxide (D1) zone. In this case, the effective removal of nitrogen and phosphorus compounds requires two circuits of internal sludge recirculation (nitrate recycling from the deoxyd zone (DO) to the first anoxide (D1) zone and anoxide recycle from the second anoxide (D2) zone to the anaerobic (AN) zone) .

Modified UCT method or MUCT process [see Henze M. Biological wastewater treatment. - M .: Mir, 2004. - 480 p.] Involves the treatment of water with activated sludge in successively located anaerobic (AN), first anoxide (D1), second anoxide (D2) aerobic (N) and deoxyd (DO) zones of the aeration tank, s subsequent separation of sludge in the secondary sump and its recirculation to the first anoxide (D1) zone. This technology assumes the presence of an internal anoxide recycling from the first anoxide (D1) zone to the anaerobic (AN) zone, as well as an internal nitrate recycling from the deoxide (DO) zone to the second anoxide (D2) zone.

The modified Bardenfo process [see Ulf Jeppsson Modeling Aspects of Wastewater Treatment Processes. - Lund: Printed in Sweden by Reprocentralen, Lund University, 1996 .-- 428 p. (ISBN 91-88934-00-4)] involves treating water with activated sludge in sequentially located anaerobic (AN), first anoxide (D1), first aerobic (N1), second anoxide (D2) and second aerobic (N2) aerotank zones, separation of sludge in the secondary sump and its subsequent recirculation to the anaerobic zone. The Bardenfo modified process also provides for internal nitrate recirculation of the sludge mixture to effectively remove nitrogen and phosphorus compounds. In this case, nitrate recirculation is carried out not from the deoxyd zone, but from the exit of the aerobic nitrification zone.

The absence of a separated deoxyd zone and the pumping of the sludge saturated with dissolved oxygen from the aerobic nitrification zone directly to the denitrifier can lead to a violation of the oxygen regime, an increase in the concentration of dissolved oxygen in the denitrification zone, and a decrease in the rate of the removal of organic substances and nitrate nitrogen in the anoxide zone.

Another disadvantage of the Bardenfo modified process is the weak “protection” of the anaerobic zone from return sludge nitrates. The intake of nitrates contained in the return sludge into the anaerobic zone slows down the main processes of anaerobiosis, resulting in a sharp decrease in the efficiency of purification from phosphorus. Thus, in fact, even with a calculated and stable flow of wastewater for treatment, at least part of the anaerobic zone will work not in the anaerobic, but in the anoxide mode (dissolved oxygen is absent, but chemically bound oxygen is present), i.e. instead of the process of biological purification of phosphorus in the part of the “anaerobic” zone, the process of biological purification of nitrogen nitrates will occur. Under adverse conditions, the entire "anaerobic" zone will actually work in the anoxide mode, which will result in the cessation of the effective removal of phosphorus from wastewater.

The need to use high-performance nitrate recirculation of the sludge mixture required to ensure effective nitrogen removal leads to additional capital and operating costs for biological treatment. In addition, the presence of nitrate recirculation reduces the reliability of the biological wastewater treatment process, since in the event of failure of the nitrate recirculation pumps, it becomes impossible to provide effective biological treatment for both nitrogen and phosphorus.

From the above it follows that in the prior art at the moment there remains a need for an effective method of biological treatment of wastewater from organic substances, nitrogen and phosphorus compounds.

Disclosure of invention

The problem to which the present invention is directed is to improve the method of biological treatment of wastewater from organic substances, as well as nitrogen and phosphorus compounds.

Another objective of the claimed group of inventions is to ensure reliable operation of the aeration tank-secondary sump system for the biological treatment of wastewater from organic substances, nitrogen and phosphorus compounds.

To solve the above problems, a method is proposed that includes supplying wastewater to the aeration tank of the corridor type and treating the water with activated sludge in at least one anaerobic (AN), two anoxic (D1, D2) and one aerobic (N) zones formed along the entire length of the aeration tank, internal anoxide recycling from the first anoxide (D1) or second anoxide (D2) zone to the anaerobic (AN) zone, separation of activated sludge in the secondary sump and its recycling to the first anoxide (D1) zone, which involves treating water with activated sludge at least in two aero GOVERNMENTAL areas, and also in the anoxid additional third (D3) zone located between the aerobic zones of the aeration tank, and also provides a plant for carrying out said method.

By reliably “protecting” the anaerobic zone from nitrates by feeding return sludge (external recycling) to the first anoxide (D1) zone, in which nitrate nitrogen is effectively removed due to the carbon in the waste water (and not endogenous carbon) remaining in the sludge mixture after the first anaerobic (AN) zone, and the subsequent return of the sludge mixture purified during denitrification by an “anoxide” recycle to the anaerobic zone (AN), a stable and effective purification of wastewater from phosphorus is provided. In addition, the presence of an additional denitrification zone (an additional third anoxide (D3) zone) allows maintaining an efficient and stable nitrate purification, i.e. to reduce their content both in purified water and in the return sludge, thereby reducing their entry into the first anoxide zone (D1) and, thus, achieving a guaranteed absence of nitrates in the sludge mixture at the outlet of the first anoxide zone D1.

In addition, the proposed combination and sequence of steps of the method in particular eliminates the use of internal nitrate recycling, which allows for increased efficiency, stability and reliability of biological treatment from organic substances, nitrogen and phosphorus compounds, as it helps to prevent a sharp deterioration in the quality of treatment that occurs in case of failure of the equipment necessary to ensure nitrate recycling.

However, depending on the quality of the wastewater entering the treatment, to intensify the biological treatment of nitrogen and phosphorus, the method can be supplemented with an internal nitrate sludge recirculation loop. In this case, the organization of such recirculation does not require the creation of a special deoxy (DO) zone, since the internal nitrate recycle in this case can be carried out not in the anoxide zone, but in the first aerobic zone, while nitrate recirculation is possible at any point along the length of the first aerobic zone, which in practice allows to minimize the length of the internal recirculation pipeline.

Thus, the technical result achieved by using the claimed group of inventions is to ensure the stability and efficiency of biological wastewater treatment from organic substances, as well as nitrogen and phosphorus compounds, and reliable operation of the biological treatment system of the aeration tank-secondary sump.

The proposed method involves a dispersed supply of wastewater. So wastewater can be supplied to the anaerobic (AN) and one or more anoxide (D1, D2, D3) zones.

In one embodiment of the method, wastewater is supplied to the inlet of anaerobic (AN) and additional third anoxide (D3) zones of the aeration tank.

In another embodiment of the method, the wastewater is supplied to the anaerobic (AN) zone, as well as the first anoxide (D1) and second anoxide (D2) zones.

In yet another embodiment of the method, the wastewater is supplied simultaneously to both the anaerobic and anoxide (D1, D2, D3) zones.

According to one embodiment, the method involves treating water in a series of anaerobic (AN), first anoxide (D1), second anoxide (D2), first aerobic (N1), third anoxide (D3), second aerobic (N2) and deoxyd (DO) aerotank zones, internal anoxide recycling from the first anoxide (D1) or second anoxide (D2) zone to the anaerobic (AN) zone, internal nitrate recycling, separation of activated sludge in the secondary sump, and its recycling to the first anoxide (D1) zone. In this case, the internal nitrate recycling can be carried out from the deoxide (DO) zone to the first anoxide (D1), second anoxide (D2) or third anoxide (D3) zones.

Thus, according to one embodiment, the water is treated in sequentially arranged anaerobic (AN), first anoxide (D1), second anoxide (D2), first aerobic (N1), third anoxide (D3), second aerobic (N2) and deoxyd (DO) ) zones of the aeration tank, and the internal nitrate recycling is carried out from deoxide (DO) to the third anoxide (D3) zone.

According to another embodiment, water treatment is carried out in sequentially arranged anaerobic (AN), first anoxide (D1), second anoxide (D2), first aerobic (N1), third anoxide (D3), second aerobic (N2) and deoxy (DO) zones of the aeration tank and the internal nitrate recycling is carried out from the oxide (DO) to the first anoxide (D1) zone.

In another embodiment, the water is treated in sequentially arranged anaerobic (AN), first anoxide (D1), second anoxide (D2), first aerobic (N1), third anoxide (D3), second aerobic (N2) and deoxy (DO) zones aeration tank, and the internal nitrate recycling is carried out from the oxide (DO) to the second anoxide (D2) zone.

According to another embodiment, the method according to the invention involves treating water in a series of anaerobic (AN), first anoxide (D1), second anoxide (D2), first aerobic (N1), third anoxide (D3), second aerobic (N2) aerotank zones , internal anoxide recycling from the first anoxide (D1) or second anoxide (D2) zone to the anaerobic (AN) zone, the separation of activated sludge in the secondary sump and its recycling to the first anoxide (D1) zone.

In a preferred embodiment, internal nitrate recirculation is not provided.

However, to intensify the biological purification of nitrogen and phosphorus, the above method can be supplemented with an internal nitrate sludge recirculation loop, which can be carried out from the second aerobic (N2) zone to the first aerobic (N1) zone, to the first anoxide (D1) zone, to the second anoxide (D2 ) a zone or from the first aerobic (N1) to the second anoxide (D2) or third anoxide (D3) zone.

In one embodiment of the above method, water treatment is carried out in sequentially arranged anaerobic (AN), first anoxide (D1), second anoxide (D2), first aerobic (N1), third anoxide (D3), second aerobic (N2) aerotank zones, and internal nitrate recycling is carried out from the second aerobic (N2) to the first aerobic (N1) zone.

In another embodiment, the water treatment is carried out in sequentially arranged anaerobic (AN), first anoxide (D1), second anoxide (D2), first aerobic (N1), third anoxide (D3), second aerobic (N2) zones of the aeration tank, and internal nitrate recycling carried out from the second aerobic (N2) to the first anoxide (D1) zone.

In yet another embodiment, the water treatment is carried out in sequentially arranged anaerobic (AN), first anoxic (D1), second anoxic (D2), first aerobic (N1), third anoxic (D3), second aerobic (N2) zones of the aeration tank, and the inner nitrate recycling is carried out from the second aerobic (N2) to the second anoxide (D2) zone.

According to a further embodiment, water treatment is carried out in sequentially arranged anaerobic (AN), first anoxic (D1), second anoxic (D2), first aerobic (N1), third anoxic (D3), second aerobic (N2) zones of the aeration tank, and internal nitrate recycling carried out from the first aerobic (N1) to the second anoxide (D2) zone.

In another additional embodiment, the water treatment is carried out in sequentially arranged anaerobic (AN), first anoxide (D1), second anoxide (D2), first aerobic (N1), third anoxide (D3), second aerobic (N2) zones of the aeration tank, and the inner nitrate recycling is carried out from the second aerobic (N2) to the third anoxide (D3) zone.

According to another embodiment, the method involves treating water in a series of anaerobic (AN), first anoxic (D1), first aerobic (N1), second anoxic (D2), second aerobic (N2), third anoxic (D3) and third aerobic ( N3) aeration tank zones, internal anoxide recycling from the first anoxide (D1) or second anoxide (D2) zone to the anaerobic (AN) zone, separation of activated sludge in the secondary sump and its recycling to the first anoxide (D1) zone.

In a preferred embodiment, internal nitrate recirculation is not provided.

To intensify the biological purification of nitrogen and phosphorus, the above method can be supplemented with an internal nitrate sludge recirculation loop. In this case, the organization of such recirculation does not require the creation of a special deoxy (DO) zone, since the internal nitrate recycle in this case can be carried out not in the anoxide zone, but in the first aerobic zone, while nitrate recirculation is possible at any point along the length of the first aerobic zone, which in practice allows to minimize the length of the internal recirculation pipeline.

In one embodiment, the method involves internal nitrate recycling from the third aerobic (N3) zone to the second aerobic (N2) zone of the aeration tank.

In another embodiment, an internal nitrate recycling is provided from the third aerobic (N3) zone to the first aerobic (N1) zone of the aeration tank.

In yet another embodiment, the internal nitrate recycling is carried out from the second aerobic (N2) zone to the second anoxic (D2) zone of the aeration tank.

In another embodiment of the aforementioned method, internal nitrate recycling is carried out from the third aerobic (N3) zone to the second anoxic (D2) zone of the aeration tank.

In yet another embodiment, the internal nitrate recycling is carried out from the third aerobic (N3) zone to the first anoxide zone (D1) of the aeration tank.

In a preferred embodiment, internal nitrate recycling is provided from the second aerobic zone (N2) to the first aerobic zone (N1).

In a further embodiment, internal nitrate recycling is carried out from the second aerobic zone (N2) to the first anoxide zone (D1).

In yet another embodiment, internal nitrate recycling is provided from the first aerobic zone (N1) to the first anoxide zone (D1).

In another additional embodiment, the internal nitrate recycling is carried out from the third anoxide zone (D3) to the first anoxide zone (D1).

In yet another embodiment, internal nitrate recycling is performed from a third anoxide zone (D3) to a second anoxide zone (D2).

The proposed biological treatment method may also include additional water treatment in the transition anoxide-aerobic (D / N) zone located between the second anoxide (D2) and the first aerobic (N1) zones, the transition anoxide-aerobic (D / N) zone located between the third anoxide (D3) and second aerobic (N2) zones of the aeration tank, and the transition zone is equipped with mechanical mixing devices and protected aerators or both of these transition zones.

In these transition zones, it is preferable to use mechanical mixers and protected disk aerators with a movable membrane that closes when the air supply is cut off, which avoids clogging of the pores and operates the transition zones in either aerobic or anoxic modes.

In a preferred embodiment of the invention, in the anaerobic and anoxic zones of the aeration tank, the sludge mixture is mixed by means of mechanical mixing devices.

In yet another embodiment, in the anaerobic (AN) and anoxide (D1, D2, D3) zones, instead of mixing by means of mechanical mixing devices, low-intensity coarse-bubble or low-intensity medium-bubble aeration is carried out.

In aerobic zones, fine-bubble aeration of the silt mixture is carried out by aerators, in particular, protected disk aerators with a movable membrane, which closes when the air supply is cut off, thereby preventing clogging of pores.

Internal recirculation of the sludge mixture (both anoxic and nitrate recirculation) is preferably carried out by energy-efficient submersible axial pumps.

Another independent aspect of the present invention is the installation for implementing the above method of biological treatment of wastewater from organic substances, nitrogen and phosphorus compounds, which contains a wastewater supply device, aeration tank, divided by transverse partitions into at least one anaerobic (AN), two anoxide (D1, D2) and one aerobic (N) zone, as well as including mechanical mixing devices and aerators, and a secondary sump, and the aeration tank contains at least two aerobic zones and olnitelnuyu tert anoxid (D3) zone located between the aerobic zones of the aeration tank.

According to one preferred embodiment of the installation, the aeration tank is divided into sequentially arranged anaerobic (AN), first anoxide (D1), second anoxide (D2), first aerobic (N1), third anoxide (D3), second aerobic (N2) and deoxyd (DO) zones.

According to another preferred embodiment, the aeration tank is divided into successively arranged anaerobic (AN), first anoxide (D1), second anoxide (D2), first aerobic (N1), third anoxide (D3), second aerobic (N2) zones.

In another preferred embodiment, the aeration tank is divided into successively arranged anaerobic (AN), first anoxide (D1), first aerobic (N1), second anoxide (D2), second aerobic (N2), third anoxide (D3) and third aerobic (N3) zones.

As mentioned above, in a preferred embodiment, for mixing the silt mixture in the anaerobic and anoxic zones of the aeration tank, mechanical mixing devices are installed. However, in a particular embodiment, the anaerobic and anoxic zones of the aeration tank are equipped with means for providing low-intensity coarse-bubble or low-intensity medium-bubble aeration.

To carry out aeration of the silt mixture in the aerobic zones, aerators are installed, in particular disk aerators with a movable membrane.

Brief Description of the Drawings

In FIG. 1 shows a diagram of an apparatus for implementing a method for deep purification of wastewater from organic substances, nitrogen and phosphorus compounds, according to one embodiment of the invention, in which anaerobic (AN), first anoxide (D1), and second anoxide (D2) are provided in the aeration tank , the first aerobic (N1), the third anoxide (D3), the second aerobic (N2) and deoxy (DO) zones.

In FIG. 2 shows a diagram of an apparatus for implementing a wastewater treatment method according to another embodiment of the invention, wherein anaerobic (AN), first anoxide (D1), first aerobic (N1), second anoxide (D2), second aerobic (N2) are provided in the aeration tank , the third anoxide (D3) and third aerobic (N3) zones.

Figure 3 shows a diagram of an installation for implementing a method of wastewater treatment according to another embodiment of the invention, in which one transitional anoxide-aerobic (D / N) zone is additionally provided in the aeration tank.

Figure 4 shows a diagram of an installation for implementing a method of wastewater treatment according to another embodiment of the invention, in which two transitional anoxide-aerobic (D / N) zones are additionally provided in the aeration tank.

In FIG. 1 shows a diagram of an installation designed for biological treatment of wastewater from organic substances of nitrogen and phosphorus compounds, according to one embodiment of the invention.

The implementation of the invention

The installation comprises a device (1) for supplying wastewater, an aeration tank (2) a secondary sump (3), as well as pipelines for recirculating the sludge mixture.

In this exemplary embodiment, the aeration tank (2) has a rectangular shape, however, it should be understood that the shape of the aeration tank may be any suitable for a particular biological treatment plant.

The aeration tank (2) is divided by transverse baffles into successively arranged anaerobic (AN), first anoxide (D1), second anoxide (D2), first aerobic (N1), third anoxide (D3), second aerobic (N2) and deoxy (DO) zones .

For mixing the sludge mixture in the anaerobic (AN) and anoxide (D1, D2, D3) and deoxide (DO) zones of the aeration tank, mechanical mixing devices, for example, mechanical mixers, are installed (4).

Protected aerators are installed in aerobic (N1, N2) zones of the aeration tank, for example, disk aerators (5) with a movable membrane that closes when the air supply is cut off, which avoids clogging of pores.

The method of deep biological treatment, implemented on the above installation, includes the following main steps.

Using the device (1), a dispersed supply of wastewater is provided, namely, one part of the wastewater stream is fed to the inlet of the anaerobic (AN) zone, and the other part is fed to the inlet of an additional third anoxide (D3) zone.

Next, the incoming wastewater is treated with activated sludge sequentially in anaerobic (AN), first anoxic (D1), second anoxic (D2), first aerobic (N1), third anoxic (D3), second aerobic (N2) and deoxide (DO) zones, carry out the separation of activated sludge in the secondary sump (3) and its recycling (return sludge is fed into the first anoxide (D1) zone).

In order to supply the nitrate-free sludge mixture to the anaerobic (AN) zone, internal recirculation from the first anoxide (D1) zone to the anaerobic (AN) zone (anoxide recycling (6)) is carried out.

In addition, for the recycling of nitrates and the intensification of biological treatment, the described method involves an internal nitrate recycling (7), carried out from the deoxide (DO) zone to the second anoxide (D2) zone.

The internal recirculation of the sludge mixture is carried out by submersible axial pumps.

In FIG. 2 shows yet another embodiment of a plant for implementing a biological treatment process that does not involve internal nitrate recycling.

The installation comprises a device (1) for supplying wastewater, an aeration tank (2) a secondary sump (3), as well as pipelines for recirculating the sludge mixture.

The aeration tank (2) is divided by transverse septa into successively arranged anaerobic (AN), first anoxide (D1), first aerobic (N1), second anoxide (D2), second aerobic (N2), third anoxide (D3) and third aerobic (N3) zones.

For mixing the sludge mixture in the anaerobic (AN) and anoxide (D1, D2, D3) and deoxide (DO) zones of the aeration tank, mechanical mixing devices, for example, mechanical mixers, are installed (4).

In aerobic (N1, N2, N3) zones of the aeration tank, disk aerators (5) with a movable membrane are installed.

The above installation can be used to implement the biological treatment method, which includes the following steps.

The first step is the supply of wastewater to the inlet of the anaerobic (AN) zone, as well as to the second anoxide (D2) and additional third anoxide (D3) zones through the device (1).

The incoming wastewater is treated with activated sludge in a series of anaerobic (AN), first anoxide (D1), first aerobic (N1), second anoxide (D2), second aerobic (N2), third anoxide (D3) and third aerobic (N3) areas with subsequent separation of activated sludge in the secondary sump (3) and its recirculation (return sludge is fed to the first anoxide (D1) zone).

The method also involves anoxide recycling (6) (sludge mixture without N-NO ₃ ^- ), carried out from the first anoxide (D1) zone to the anaerobic (AN) zone by means of submersible axial pumps.

In FIG. 3 shows a diagram of a plant designed for the biological treatment of wastewater from organic substances of nitrogen and phosphorus compounds, according to one embodiment of the invention.

The installation comprises a device (1) for supplying wastewater, an aeration tank (2) a secondary sump (3), as well as pipelines for recirculating the sludge mixture.

In this exemplary embodiment, the aeration tank (2) has a rectangular shape, however, it should be understood that the shape of the aeration tank may be any suitable for a particular biological treatment plant.

The aeration tank (2) is divided by transverse partitions into sequentially arranged anaerobic (AN), first anoxic (D1), second anoxic (D2), transitional anoxic-aerobic zones (D / N), first aerobic (N1), third anoxic (D3), the second aerobic (N2) and deoxy (DO) zones.

For mixing the sludge mixture in the anaerobic (AN), anoxide (D1, D2, D3), transitional anoxide-aerobic (D / N) and deoxyd (DO) zones of the aerotank, mechanical mixing devices, for example, mechanical mixers, are installed (4).

In aerobic (N1, N2) and transitional anoxide-aerobic (D / N) zones of the aeration tank, protected aerators are installed, for example, disk aerators (5) with a movable membrane that closes when the air supply is cut off, which avoids clogging of pores.

The method of deep biological treatment, implemented on the above installation, includes the following main steps.

Using the device (1), a dispersed supply of wastewater is provided, namely, one part of the wastewater stream is fed to the inlet of the anaerobic (AN) zone, and the other part is fed to the inlet of an additional third anoxide (D3) zone.

Next, the incoming wastewater is treated with activated sludge sequentially in anaerobic (AN), first anoxic (D1), second anoxic (D2), transitional anoxide-aerobic (D / N), first aerobic (N1), third anoxic (D3), second aerobic (N2) and deoxyd (DO) zones, carry out the separation of activated sludge in the secondary sump (3) and recirculate it (return sludge is fed to the first anoxide (D1) zone).

In order to supply the nitrate-free sludge mixture to the anaerobic (AN) zone, internal recirculation from the first anoxide (D1) zone to the anaerobic (AN) zone (anoxide recycling (6)) is carried out.

In addition, for the recycling of nitrates and the intensification of biological treatment, the described method involves an internal nitrate recycling (7), carried out from the deoxide (DO) zone to the second anoxide (D2) zone.

The internal recirculation of the sludge mixture is carried out by submersible axial pumps or airlift.

In FIG. 4 shows a diagram of a plant for biological treatment of wastewater from organic substances of nitrogen and phosphorus compounds, according to one embodiment of the invention.

The installation comprises a device (1) for supplying wastewater, an aeration tank (2) a secondary sump (3), as well as pipelines for recirculating the sludge mixture.

In this exemplary embodiment, the aeration tank (2) has a rectangular shape, however, it should be understood that the shape of the aeration tank may be any suitable for a particular biological treatment plant.

The aeration tank (2) is divided by transverse septa into successively arranged anaerobic (AN), first anoxic (D1), second anoxic (D2), first transitional anoxic-aerobic zones (D / N1), first aerobic (N1), third anoxic (D3) , the second transitional anoxide-aerobic zone (D / N2), the second aerobic (N2) and deoxydate (DO) zones.

For mixing the sludge mixture in the anaerobic (AN), anoxide (D1, D2, D3), transitional anoxide-aerobic (D / N) and deoxide (DO) zones of the aeration tank, mixing devices, for example, mechanical mixers (4), are installed.

Protected aerators are installed in aerobic (N1, N2) and transitional anoxide-aerobic (D / N) zones of the aeration tank, for example, disk aerators (5) with a movable membrane that closes when the air supply is cut off, which helps to avoid clogging of pores.

The method of deep biological treatment, implemented on the above installation, includes the following main steps.

Using the device (1), a dispersed supply of wastewater is provided, namely, one part of the wastewater stream is fed to the inlet of the anaerobic (AN) zone, and the other part is fed to the inlet of an additional third anoxide (D3) zone.

Next, the incoming wastewater is treated with activated sludge sequentially in anaerobic (AN), the first anoxide (D1), the second anoxide (D2), the first transitional anoxide-aerobic (D / N1), the first aerobic (N1), the third anoxide (D3), the second transitional anoxide-aerobic (D / N2), second aerobic (N2) and deoxyd (DO) zones, carry out the separation of activated sludge in the secondary sump (3) and its recycling (return sludge is fed into the first anoxide (D1) zone).

In order to supply the nitrate-free sludge mixture to the anaerobic (AN) zone, internal recirculation from the first anoxide (D1) zone to the anaerobic (AN) zone (anoxide recycling (6)) is carried out.

In addition, for the recycling of nitrates and the intensification of biological treatment, the described method involves an internal nitrate recycling (7), carried out from the deoxide (DO) zone to the second anoxide (D2) zone.

The internal recirculation of the sludge mixture is carried out by submersible axial pumps or airlift.

Claims (31)

1. A method for biological treatment of wastewater from organic substances, nitrogen and phosphorus compounds, comprising supplying wastewater to the corridor type aeration tank and treating water with activated sludge in at least one anaerobic (AN) formed along the entire length of the aeration tank, two anoxic (D1, D2) and two aerobic zones, internal anoxide recycling from the first anoxide (D1) or second anoxide (D2) zone to the anaerobic (AN) zone, separation of activated sludge in the secondary sump and its recycling to the first anoxide (D1) zone, characterized in that it involves a dispersed flow of wastewater into the anaerobic (AN) and one or more anoxide zones and treatment of water with activated sludge in an additional third anoxide (D3) zone located between the aerobic zones of the aeration tank. 2. The method according to p. 1, characterized in that the wastewater is supplied to the inlet of the anaerobic and additional third anoxide (D3) zones of the aeration tank. 3. The method according to p. 1, characterized in that the water treatment is carried out in sequentially located anaerobic (AN), the first anoxide (D1), the second anoxide (D2), the first aerobic (N1), the third anoxide (D3), the second aerobic ( N2) and deoxy (DO) zones of the aeration tank and involves an internal nitrate recycling from deoxy (DO) to the third anoxide (D3) zone. 4. The method according to p. 1, characterized in that the water treatment is carried out in sequentially arranged anaerobic (AN), the first anoxide (D1), the second anoxide (D2), the first aerobic (N1), the third anoxide (D3), the second aerobic ( N2) and deoxyd (DO) zones of the aeration tank and involves internal nitrate recycling from deoxydated (DO) to the first anoxic (D1) zone. 5. The method according to p. 1, characterized in that the water treatment is carried out in sequentially located anaerobic (AN), the first anoxide (D1), the second anoxide (D2), the first aerobic (N1), the third anoxide (D3), the second aerobic ( N2) and deoxyd (DO) zones of the aeration tank and involves an internal nitrate recycling from deoxydated (DO) to the second anoxic (D2) zone. 6. The method according to p. 1, characterized in that the water treatment is carried out in sequentially arranged anaerobic (AN), the first anoxide (D1), the second anoxide (D2), the first aerobic (N1), the third anoxide (D3), the second aerobic ( N2) zones of the aeration tank and involves internal nitrate recycling from the second aerobic (N2) to the first aerobic (N1) zone. 7. The method according to p. 1, characterized in that the water treatment is carried out in sequentially arranged anaerobic (AN), the first anoxide (D1), the second anoxide (D2), the first aerobic (N1), the third anoxide (D3), the second aerobic ( N2) zones of the aeration tank and involves internal nitrate recycling from the second aerobic (N2) to the first anoxide (D1) zone. 8. The method according to p. 1, characterized in that the water treatment is carried out in sequentially located anaerobic (AN), the first anoxide (D1), the second anoxide (D2), the first aerobic (N1), the third anoxide (D3), the second aerobic ( N2) zones of the aeration tank and involves internal nitrate recycling from the second aerobic (N2) to the second anoxide (D2) zone. 9. The method according to p. 1, characterized in that the water treatment is carried out in sequentially arranged anaerobic (AN), the first anoxide (D1), the second anoxide (D2), the first aerobic (N1), the third anoxide (D3), the second aerobic ( N2) zones of the aeration tank and involves an internal nitrate recycling from the first aerobic (N1) to the second anoxide (D2) zone. 10. The method according to p. 1, characterized in that the water treatment is carried out in sequentially located anaerobic (AN), the first anoxide (D1), the second anoxide (D2), the first aerobic (N1), the third anoxide (D3), the second aerobic ( N2) zones of the aeration tank and involves internal nitrate recycling from the second aerobic (N2) to the third anoxide (D3) zone. 11. The method according to any one of paragraphs. 3-10, characterized in that they carry out additional water treatment in the transitional aerobic-anoxide (N / D) zone located between the first aerobic (N1) and second anoxide (D2) zones and / or transitional anoxide-aerobic (D / N) the zone located between the third anoxide (D3) and second aerobic (N2) zones of the aeration tank, and the transition zone is equipped with mechanical mixing devices and protected aerators. 12. The method according to p. 1, characterized in that the water treatment is carried out in a series of anaerobic (AN), first anoxide (D1), first aerobic (N1), second anoxide (D2), second aerobic (N2), third anoxide ( D3) and the third aerobic (N3) zones of the aeration tank. 13. The method according to p. 12, characterized in that it involves an internal nitrate recycling from the third aerobic (N3) zone to the second aerobic (N2) zone of the aeration tank. 14. The method according to p. 12, characterized in that it involves an internal nitrate recycling from the third aerobic (N3) zone to the first aerobic (N1) zone of the aeration tank. 15. The method according to p. 12, characterized in that it involves an internal nitrate recycling from the second aerobic (N2) zone to the second anoxic (D2) zone of the aeration tank. 16. The method according to p. 12, characterized in that it involves an internal nitrate recycling from the third aerobic (N3) zone to the second anoxic (D2) zone of the aeration tank. 17. The method according to p. 12, characterized in that it involves an internal nitrate recycling from the third aerobic (N3) zone to the first anoxide zone (D1) of the aerotank zone. 18. The method according to p. 12, characterized in that it involves an internal nitrate recycling from the second aerobic zone (N2) to the first aerobic zone (N1). 19. The method according to p. 12, characterized in that it involves an internal nitrate recycling from the second aerobic zone (N2) to the first anoxide zone (D1). 20. The method according to p. 12, characterized in that it involves an internal nitrate recycling from the first aerobic zone (N1) to the first anoxide zone (D1). 21. The method according to p. 12, characterized in that it involves an internal nitrate recycling from the third anoxide zone (D3) to the first anoxide zone (D1). 22. The method according to p. 12, characterized in that it involves an internal nitrate recycling from the third anoxide zone (D3) to the second anoxide zone (D2). 23. The method according to p. 12, characterized in that it involves additional treatment of water in the transition anoxic-aerobic (D / N) zone located between the second anoxic (D2) and second aerobic (N2) zones of the aeration tank, and / or transitional aerobic an anoxide (N / D) zone located between the first aerobic (N1) and second anoxide (D2) zones of the aeration tank, and / or an aerobic-anoxide transition (N / D) zone located between the third anoxide (D3) and third aerobic (N3 ) zones, and the transition zone is equipped with mechanical mixing devices and protected air tori. 24. The method according to p. 1, characterized in that in the anaerobic and anoxic zones carry out mechanical stirring or low intensity coarse or low intensity medium bubble aeration. 25. Installation for implementing the method according to any one of paragraphs. 1-24, which contains a device for supplying wastewater, an aeration tank, divided by transverse partitions into at least one anaerobic (AN), two anoxic (D1, D2) and two aerobic zones, as well as including mechanical mixing devices and aerators and a secondary sump, characterized in that the aeration tank contains an additional third anoxide (D3) zone located between the aerobic zones of the aeration tank, and the water supply device is configured to distribute wastewater into the anaerobic (AN) and one or several anoxide zones. 26. Installation according to p. 25, characterized in that the aeration tank is divided into successively arranged anaerobic (AN), the first anoxide (D1), the second anoxide (D2), the first aerobic (N1), the third anoxide (D3), the second aerobic (N2 ) and deoxy (DO) zones. 27. The installation according to p. 25, characterized in that the aeration tank is divided into successively arranged anaerobic (AN), first anoxide (D1), second anoxide (D2), first aerobic (N1), third anoxide (D3), second aerobic ( N2) zones. 28. Installation according to p. 25, characterized in that the aeration tank is divided into successively arranged anaerobic (AN), the first anoxic (D1), the first aerobic (N1), the second anoxic (D2), the second aerobic (N2), and the third anoxic (D3 ) and the third aerobic (N3) zone. 29. Installation according to any one of paragraphs. 24-28, characterized in that the aeration tank further comprises a transitional aerobic-anoxide (N / D) zone located between the first aerobic (N1) and second anoxide (D2) zones, and / or a transition anoxic-aerobic (D / N) zone located between the third anoxide (D3) and second aerobic (N2) zones, the transition zone provided with mechanical mixing devices and protected aerators. 30. Installation according to p. 25, characterized in that in the anaerobic and anoxide zones carry out mechanical mixing or low intensity coarse or low intensity medium bubble aeration.

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