RU2780614C2 - System for controlling a biological waste water treatment unit - Google Patents

Abstract

FIELD: water treatment.

SUBSTANCE: system relates to the field of water discharge and to systems for controlling the process of waste water treatment, and can be used in creating of new or reconstructing existing stations for the treatment of domestic waste water, household waste water concentrated by organic pollutants and that close thereto in the composition. System includes pipelines for the supply and discharge of water, removal of excess activated sludge; a biological treatment unit; a pump for pumping out the activated sludge; aerators. The biological treatment unit consists of a bioreactor made in the form of consecutively connected zones: anaerobic, anoxic, and aerobic zones, intended for removing nitrogen and performing biological dephosphorisation, and a settling tank. A first recirculation flow is formed between the anoxic and anaerobic zones, the second one is formed between the aerobic and anoxic zones, the third one is formed between the secondary settling tank and the anoxic zone of the bioreactor. Installed on the first recirculation flow is a BOD concentration monitoring sensor. Installed on the first, second and third recirculation flows are flow meters, remote-control shutoff valving, sensors for determining the concentration of nitrate nitrogen, ammonium nitrogen, and phosphates, temperature sensors, pH sensors, sensors for the concentration of activated sludge. Apparatus is equipped with units for determining the parameters of the inflowing waste water, the first, second, and third recirculation streams, and treated water. The apparatus also comprises a parameter setting module, a comparison module, and a parameter control module. The parameter setting module comprises a unit for setting the concentration of substances incoming into the anaerobic zone, a unit for setting the concentration of substances incoming into the anoxic zone, and a unit for setting the concentration of dissolved oxygen in the aerobic zone. The comparison module contains comprises units for comparing the concentration in the first, second, and third recirculation flows, a unit for comparing the concentration in the waste water supply pipeline, and a unit for comparing the concentration in the treated water discharge pipeline. The parameter control module comprises a shutoff valving control unit, a pump control unit, and an air-blowing control unit.

EFFECT: increase in the quality of biological treatment of waste water due to the adjustment of the parameters of the recirculation flows and the maintained optimal values of concentration in the biological waste water treatment system.

1 cl, 1 dwg

Description

The system relates to the field of wastewater disposal, as well as to systems for managing the wastewater treatment process and can be used to create new or reconstruct existing domestic treatment plants, household wastewater concentrated in organic pollutants and wastewater close to them in composition.

A known method of biological treatment of wastewater from phosphates, according to which biological treatment is carried out under conditions of reduced aeration intensity using an inert feed material, fouling with a biofilm, in direct contact with which a metal is introduced, creating conditions for biological corrosion, while the spent biofilm with sorbed contaminants removed directly from the aeration zone (RF Patent 2197436, C02F 3/02, 2003).

The disadvantages of the known method is the high air consumption for aeration, as well as the fact that the technology used does not allow the removal of nitrogen compounds.

The closest analogue to the claimed invention is an automated device for the treatment of domestic wastewater, see patent for invention RU 2711619 C1, publ. 01/17/2020), including a pressure pipeline connected in series, a mechanical treatment unit containing a mechanical grate, a garbage container, a sand trap with a thin-layer module, a sand collection container, a wastewater supply pipeline, a biological treatment unit consisting of four series-connected reactors and a sump , an activated sludge pump, an activated sludge recirculation supply pipeline, aerators, an activated sludge accumulator, an activated sludge dewatering plant, a sedimentation tank with thin-layer modules, an aftertreatment unit, a water discharge pipeline after aftertreatment, a disinfection unit, a treated water discharge pipeline, and a sedimentation tank the biological treatment unit is made in the form of a collection tank, the post-treatment unit is made in the form of a collection tank, the water outlet pipeline after post-treatment is made in the form of a purified water outlet pipeline, the biological treatment unit, consisting of four series-connected reactors, is made in the form of rings th bioreactor, consisting of three communicating concentric zones - anaerobic, anoxic, aerobic, intended for nitrogen removal and biological dephosphorization, where in each zone there is an agitator that creates a horizontal flow, moreover, aerators are installed only in one half of the annular zone of the bioreactor and an additional pump is introduced for pressure pipeline, wastewater collection tank connected to it, temperature control sensor, discharge tray, primary clarifier, ultrasonic waste accumulation level sensor on a mechanical grate, comparison unit, waste accumulation level adjuster, actuator, control valve, upper and lower sand level sensors , switch, outlet valve, waste water pipeline pump, agitators, blower, dissolved oxygen measuring device, ring bioreactor pH and temperature measuring device, totalizer, oxygen, temperature, pH transmitters, comparators, spectrometric analyzers for monitoring COD, total nitrogen and phosphorus, a collection tank, a sensor for monitoring the concentration of the sludge mixture in the ring bioreactor, a sludge mixture concentration controller, a comparison unit, a timer, a drive, a pump for feeding activated sludge to recirculation, upper and lower sludge level sensors, a starter, suction pump, flow meter, BOD concentration control sensor, first, second and third BOD concentration controllers, first, second and third BOD concentration comparison units, reagent dispenser.

The disadvantage of this device is the impossibility of controlling the process of biological treatment with changes in such parameters of incoming wastewater as flow rate, concentration of pollutants.

Since these parameters in household, rainwater and integrated sewage systems are constantly changing and depend on many external factors, it is impossible to predict them with a sufficient degree of accuracy. The known system does not allow responding to changes in these parameters.

The objective of the present invention is to expand the scope of the known system, since the combined use of distinctive features will allow the use of new functionality, namely, to improve the quality of biological wastewater treatment by adjusting the parameters of recirculation flows and maintaining optimal concentrations in the biological wastewater treatment system.

A new application is to improve the quality of biological wastewater treatment by adjusting the parameters of recirculation flows and maintaining optimal concentrations in the biological wastewater treatment system, taking into account changes in the parameters of incoming wastewater.

The problem is solved so that in a known device, including at least:

sewage supply pipeline;

a biological treatment unit consisting of a bioreactor made in the form of sequentially connected zones - anaerobic, anoxic, aerobic, intended for nitrogen removal and biological dephosphorization, and a sump;

pipeline for the removal of purified water;

activated sludge pump;

the third recirculation flow between the secondary clarifier and the anoxic zone of the bioreactor,

aerators;

a device for measuring the concentration of dissolved oxygen;

a device for measuring pH and temperature;

spectrometric analyzers for COD and phosphorus monitoring;

flowmeter;

blower.

In accordance with the present invention:

wastewater that has undergone mechanical treatment is taken as wastewater;

the activated sludge pump is configured to supply activated sludge for recirculation and/or remove excess sludge and to change the amount of activated sludge supplied for recycling and/or removal;

the blower is configured to change the amount of supplied air;

a pH measuring device is installed on the wastewater supply pipeline;

spectrometric analyzers for monitoring COD and phosphorus are installed on the wastewater supply pipeline.

In addition, the device is additionally equipped with:

the first recirculation flow between the anoxic and anaerobic zones;

a second recirculation flow between the aerobic and anoxic zones;

flow meters, shut-off and control valves with remote control, sensors for determining the concentration of nitrate nitrogen, sensors for determining the concentration of ammonium nitrogen, sensors for determining the concentration of phosphates, temperature sensors, pH sensors, sensors for determining the concentration of activated sludge installed on the first, second and third recirculation streams,

BOD concentration control sensors installed on the first recirculation flow,

excess sludge removal pipeline,

shut-off and control valves with remote control and a flow meter installed on the pipeline for removing excess sludge,

a flow meter, a sensor for determining the concentration of nitrate nitrogen, a sensor for determining the concentration of ammonium nitrogen, a sensor for determining the concentration of suspended solids installed on the wastewater supply pipeline,

a sensor for determining the concentration of nitrate nitrogen, a sensor for determining the concentration of ammonium nitrogen, a sensor for determining the concentration of phosphates, a sensor for determining the concentration of suspended solids, a BOD concentration control sensor installed on the treated water discharge pipeline,

a block for determining the parameters of incoming wastewater through the wastewater supply pipeline,

blocks for determining the parameters of the first, second and third recirculation flows,

a block for determining the parameters of waste water in the pipeline for the removal of purified water,

a parameter setting module containing a block for setting the concentration of substances in those entering the anaerobic zone, a block for setting the concentration of substances in entering the anoxic zone, a block for setting the concentration of dissolved oxygen in the aerobic zone,

a comparison module containing blocks for comparing the concentration in the first, second and third recirculation streams, a block for comparing the concentration in the wastewater supply pipeline, a block for comparing the concentration in the purified water outlet pipeline,

a parameter control module containing a shut-off and control valve control unit, a pump control unit, and a blower control unit.

Wherein

the outputs of the flow meter, the sensor for determining the concentration of nitrogen nitrates, the sensor for determining the concentration of ammonium nitrogen, the spectrometric analyzer for monitoring phosphorus, the device for measuring temperature, the device for measuring pH, the sensor for determining the concentration of suspended solids, the spectrometric analyzer for monitoring COD are connected to the input of the unit for determining the parameters of incoming waste water through the wastewater supply pipeline,

outputs of flow meters, sensors for determining the concentration of nitrate nitrogen, sensors for determining the concentration of ammonium nitrogen, sensors for determining the concentration of phosphates, temperature sensors, sensors for determining pH, sensors for determining the concentration of activated sludge, installed on the first, second and third recirculation flows, are connected to the inputs of the blocks for determining the parameters of the first, the second and third recirculation streams, respectively,

the output of the BOD concentration control sensor installed on the first recirculation flow is connected to the input of the block for determining the parameters of the first recirculation flow,

the outputs of the flow meter, the sensor for determining the concentration of nitrate nitrogen, the sensor for determining the concentration of ammonium nitrogen, the sensor for determining the concentration of phosphates, the sensor for determining the concentration of suspended solids, the BOD concentration control sensor are connected to the input of the unit for determining the parameters of waste water in the treated water discharge pipeline,

the outputs of the blocks for determining the parameters of incoming wastewater through the wastewater supply pipeline, the first, second and third recirculation flows, for determining the parameters of wastewater in the treated water discharge pipeline are connected to the input of the parameter setting module and the comparison module,

the output of the device for measuring the concentration of dissolved oxygen is connected to the input of the parameter setting module,

the outputs of the parameter setting module and the comparison module are connected to the parameter control module,

the output of the parameter control module is connected to shut-off and control valves, pump drive, blower.

Distinctive features of the proposed Device for controlling the biological wastewater treatment unit are:

1. Selection as waste water, waste water that has undergone mechanical treatment;

2. Performing a pump for pumping out activated sludge with the possibility of supplying activated sludge for recycling and / or removing excess sludge;

3. Performing a pump for pumping activated sludge with the possibility of changing the amount of activated sludge supplied for recycling and/or removal;

4. Performing a blower with the possibility of changing the amount of air supplied;

5. Installation of a pH measuring device on the wastewater supply pipeline;

6. Installation of spectrometric analyzers for monitoring COD and phosphorus on the wastewater supply pipeline;

7. Additional supply of the first recirculation flow between the anoxic zone and the anaerobic zones;

8. Additional supply of recirculation flow between the aerobic and anoxic zones;

9. Additional supply with flow meters installed on the first, second and third recirculation flows;

10. Additional supply of shut-off and control valves with remote control installed on the first, second and third recirculation flows;

11. Additional supply with sensors for determining the concentration of nitrogen nitrates installed on the first, second and third recirculation flows;

12. Additional supply with sensors for determining the concentration of ammonium nitrogen, installed on the first, second and third recirculation flows;

13. Additional supply with sensors for determining the concentration of phosphates installed on the first, second and third recirculation flows;

14. Additional supply with temperature sensors installed on the first, second and third recirculation flows;

15. Additional supply with pH sensors installed on the first, second and third recirculation flows;

16. Additional supply with sensors for determining the concentration of activated sludge installed on the first, second and third recirculation flows;

17. Additional supply with a BOD concentration control sensor installed on the first recirculation stream;

18. Additional supply of pipeline for removal of excess sludge;

19. Additional supply of shut-off and control valves with remote control installed on the pipeline for removing excess sludge;

20. Additional supply with a flow meter installed on the pipeline for removing excess sludge;

21. Additional supply with a flow meter installed on the wastewater supply pipeline;

22. Additional supply with a sensor for determining the concentration of nitrogen nitrates installed on the sewage supply pipeline;

23. Additional supply with a sensor for determining the concentration of ammonium nitrogen, installed on the wastewater supply pipeline;

24. Additional supply with a sensor for determining the concentration of suspended solids installed on the sewage supply pipeline;

25. Additional supply with a sensor for determining the concentration of nitrogen nitrates installed on the pipeline for the removal of purified water;

26. Additional supply with a sensor for determining the concentration of ammonium nitrogen, installed on the pipeline for the removal of purified water;

27. Additional supply with a sensor for determining the concentration of phosphates, installed on the pipeline for the removal of purified water;

28. Additional supply with a sensor for determining the concentration of suspended solids installed on the pipeline for the removal of purified water;

29. Additional supply with a sensor for determining the concentration of BOD, installed on the pipeline for the removal of purified water;

30. Additional supply with a block for determining the parameters of incoming wastewater through the wastewater supply pipeline,

31. Additional supply with blocks for determining the parameters of the first, second and third recirculation flows;

32. Additional supply with a block for determining the parameters of waste water in the pipeline for the removal of purified water;

33. Additional supply with a parameter setting module;

34. Inclusion in the module for setting the parameters of the block for setting the concentration of substances in entering the anaerobic zone;

35. Inclusion in the module for setting the parameters of the block for setting the concentration of substances in those entering the anoxic zone;

36. Inclusion in the module for setting the parameters of the block for setting the concentration of dissolved oxygen in the aerobic zone;

37. Additional supply with a comparison module;

38. Inclusion in the comparison module of blocks for comparing the concentration in the first, second and third recirculation streams;

39. Inclusion in the comparison module of a block for comparing the concentration in the wastewater supply pipeline;

40. Inclusion in the comparison module of a block for comparing the concentration in the pipeline for the removal of purified water;

41. Additional supply with a parameter control module;

42. Inclusion in the parameter control module of the control unit for shut-off and control valves;

43. Inclusion in the control module of the parameters of the pump control unit;

44. Inclusion in the parameter control module of the blower control unit;

45. Connecting the outputs of the flow meter, sensor for determining the concentration of nitrogen nitrates, sensor for determining the concentration of nitrogen ammonium, spectrometric analyzer for monitoring phosphorus, temperature measuring device, pH measuring device, sensor for determining the concentration of suspended solids, spectrometric analyzer for monitoring COD with the input of the parameter determination unit incoming wastewater through the wastewater supply pipeline;

46. Connecting the outputs of flow meters, sensors for determining the concentration of nitrate nitrogen, sensors for determining the concentration of ammonium nitrogen, sensors for determining the concentration of phosphates, temperature sensors, sensors for determining pH, sensors for determining the concentration of activated sludge installed on the first, second and third recirculation flows with the inputs of the blocks for determining the parameters of the first , second and third recirculation streams, respectively;

47. Connecting the output of the BOD concentration control sensor installed on the first recirculation stream with the input of the block for determining the parameters of the first recirculation stream;

48. Connecting the output of the flow meter, the sensor for determining the concentration of nitrate nitrogen, the sensor for determining the concentration of ammonium nitrogen, the sensor for determining the concentration of phosphates, the sensor for determining the concentration of suspended solids, the BOD concentration control sensor with the input of the block for determining the parameters of waste water in the pipeline for the removal of purified water;

49. Connecting the outputs of the blocks for determining the parameters of incoming wastewater through the sewage supply pipeline, the first, second and third recirculation flows, determining the parameters of wastewater in the treated water discharge pipeline with the input of the parameter setting module and the comparison module;

50. Connection of the output of the device for measuring the concentration of dissolved oxygen with the input of the parameter setting module;

51. Connection of the output of the parameter setting module with the input of the parameter control module;

52. Connection of the output of the comparison module with the input of the parameter control module;

53. Connecting the output of the parameter control module with shut-off and control valves;

54. Connection of the output of the parameter control module with the pump drive;

55. Connecting the output of the parameter control module to the blower.

According to the information available to the authors, the distinguishing feature No. 1, 2, 8, 9, 26-30 is known in the technical literature, while the rest are not, which meets the condition of patentability "novelty".

The combined use in the claimed device of these distinctive features allows you to get a positive effect, which is that the scope of the device is expanding, because it can be used to solve the problem of improving the efficiency of biological wastewater treatment, by using in the biological wastewater treatment system the regulation of the amount of activated sludge in areas with different methods of wastewater treatment in a biological reactor, taking into account the qualitative and quantitative composition of substances in wastewater . As well as changes in the composition of water during its purification in these areas. This is achieved due to the presence of distinguishing features No. 1-55.

The invention is explained with the aid of the drawings below.

Fig. 1 is a general view of an example of a control device for a biological wastewater treatment unit.

The control device for the biological wastewater treatment unit contains (Fig. 1):

wastewater supply pipeline 1,

biological treatment unit 2, which includes a bioreactor 3 and a sump 4. Bioreactor 3 consists of at least sequentially connected zones, anaerobic 5, anoxic 6 and aerobic 7. At the same time, aerators 8 are stopped in the aerobic zone.

At the same time, recirculation flows are organized inside the biological treatment unit 2 between:

anoxic zone 6 and anaerobic zone 5 the first recirculation stream 9,

aerobic zone 7 and anoxic zone 6 the second recirculation stream 10,

settler 4 and anoxic zone 6 the third recirculation stream 11, the supply of activated sludge to the third recirculation stream 11 is carried out by the pump 12 for pumping out activated sludge with the possibility of changing the amount of activated sludge supplied for recirculation, for example, equipped with an adjustable drive 13.

Device 14 for measuring the concentration of dissolved oxygen.

In accordance with the present invention, another number is allowed, as well as the sequence of the zones and the recirculation flows between them.

Flow meter 15, valves 16 with remote control, sensor 17 for determining the concentration of nitrate nitrogen, sensor 18 for determining the concentration of ammonium nitrogen, sensor 19 for determining the concentration of phosphates, sensor 20 for temperature, sensor 21 for determining pH, sensor 22 for determining the concentration of activated sludge are installed on the third recirculation stream 11.

The pipeline 23 for removing excess sludge with shut-off and control valves 24 installed on it with remote control and a flow meter 25.

Flow meter 26, shut-off and control valves 27 with remote control, pump 28 for supplying activated sludge to recirculation, equipped with an adjustable drive 29, sensor 30 for determining the concentration of nitrate nitrogen, sensor 31 for determining the concentration of ammonium nitrogen, sensor 32 for determining the concentration of phosphates, sensor 33 for temperature, sensor 34 for determining pH, sensor 35 for determining the concentration of activated sludge, sensor 36 for controlling the concentration of BOD installed on the first recirculation stream 9.

Flow meter 37, shut-off and control valves 38 with remote control, pump 39 for feeding activated sludge to recirculation, equipped with an adjustable drive 40, sensor 41 for determining the concentration of nitrate nitrogen, sensor 42 for determining the concentration of ammonium nitrogen, sensor 43 for determining the concentration of phosphates, temperature sensor 44, sensor 45 for determining pH, sensor 46 for determining the concentration of activated sludge installed on the second recirculation stream 10.

Flow meter 47, sensor 48 for determining the concentration of nitrate nitrogen, sensor 49 for determining the concentration of ammonium nitrogen, spectrometric analyzer 50 for monitoring phosphorus, device 51 for measuring temperature, device 52 for measuring pH, sensor 53 for determining the concentration of suspended solids, spectrometric analyzer 54 for monitoring COD installed to the pipeline 1 for supplying waste water.

The pipeline 55 for the removal of purified water.

The flow meter 56, the sensor 57 for determining the concentration of nitrate nitrogen, the sensor 58 for determining the concentration of ammonium nitrogen, the sensor 59 for determining the concentration of phosphates, the sensor 60 for determining the concentration of suspended solids, the sensor 61 for controlling the BOD concentration are installed on the pipeline 55 for the removal of purified water.

Flow meter outputs 47, sensor 48 for determining the concentration of nitrogen nitrates, sensor 49 for determining the concentration of nitrogen ammonium, spectrometric analyzer 50 for monitoring phosphorus, device 51 for measuring temperature, device 52 for measuring pH, sensor 53 for determining the concentration of suspended solids, spectrometric analyzer 54 for monitoring COD connected to the input of block 62 for determining the parameters of incoming wastewater through pipeline 1.

The outputs of the flow meter 26, the sensor 30 for determining the concentration of nitrate nitrogen, the sensor 31 for determining the concentration of ammonium nitrogen, the sensor 32 for determining the concentration of phosphates, the temperature sensor 33, the sensor 34 for determining pH, the sensor 35 for determining the concentration of activated sludge, the sensor 36 for controlling the concentration of BOD are connected to the input of block 63 determining the parameters of the first recirculation flow 9.

The outputs of the flow meter 37, the sensor 41 for determining the concentration of nitrate nitrogen, the sensor 42 for determining the concentration of ammonium nitrogen, the sensor 43 for determining the concentration of phosphates, the temperature sensor 44, the sensor 45 for determining pH, the sensor 46 for determining the concentration of activated sludge are connected to the input of the block 64 for determining the parameters of the second recirculation stream 10 .

The outputs of the flowmeter 15, the sensor 17 for determining the concentration of nitrate nitrogen, the sensor 18 for determining the concentration of ammonium nitrogen, the sensor 19 for determining the concentration of phosphates, the temperature sensor 20, the sensor 21 for determining pH, the sensor 22 for determining the concentration of activated sludge are connected to the input of block 65 for determining the parameters of the third recirculation stream 11 .

The output of the flowmeter 25 is connected to the input of the block 65 for determining the parameters of the third recirculation flow 11.

The outputs of the flow meter 56, the sensor 57 for determining the concentration of nitrate nitrogen, the sensor 58 for determining the concentration of ammonium nitrogen, the sensor 59 for determining the concentration of phosphates, the sensor 60 for determining the concentration of suspended solids, the sensor 61 for controlling the BOD concentration are connected to the input of the block 66 for determining the parameters of treated waste water in the pipeline 55 outlet purified water.

Parameter setting module 67, comprising a block 68 for setting the concentration of substances in those entering the anaerobic zone 5, a block 69 for setting the concentration of substances in entering the anoxic zone 6, a block 70 for setting the concentration of dissolved oxygen in the aerobic zone 7.

A comparison module 71 comprising a concentration comparison unit 72 in the third recirculation stream 11, a concentration comparison unit 73 in the second recirculation stream 10, a concentration comparison unit 74 in the wastewater supply line 1, a concentration comparison unit 75 in the first recirculation stream stream 9, a comparison unit 76 concentration in the pipeline 55 outlet of purified water.

The output of the block 62 for determining the parameters of the incoming wastewater through the pipeline 1, the output of the block 63 for determining the parameters of the first recirculation stream 9, the output of the block 64 for determining the parameters of the second recirculation stream 10, the output of the block 65 for determining the parameters of the third recirculation stream 11, are connected to the input of the module 67 for setting parameters and input module 71 comparison.

The output of the block 66 for determining the parameters of treated waste water in the pipeline 55 discharge of treated water is connected to the input of the comparison module 71.

The output of the device 14 measuring the concentration of dissolved oxygen is connected to the input of the module 67 settings.

Blower 77 with the possibility of changing the amount of air supplied is connected to aerators 8 by air duct 78.

Module 79 control parameters, containing block 80 control valves, block 81 control pumps, block 82 blower control.

The outputs of the module 67 setting parameters and module 71 comparison is connected to the input of the module 79 control parameters.

The output of the parameter control module 79 is connected:

with shut-off and control valves 27 with remote control,

with shut-off and control valves 38 with remote control,

with shut-off and control valves 16 with remote control,

with shut-off and control valves 24 with remote control,

with adjustable drive 29,

with adjustable drive 40,

with adjustable drive 13,

with blower 77.

The control unit of the biological wastewater treatment works as follows.

Wastewater after mechanical treatment through the sewage supply pipeline 1 enters the biological treatment unit 2, sequentially into the anaerobic zone 5, the anoxic zone 6, the aerobic zone 7 of the bioreactor 3. At the same time:

the flow meter 47 determines the flow rate of incoming wastewater;

the nitrogen concentration of nitrates is determined by the sensor 48 for determining the concentration of nitrogen nitrates;

the concentration of ammonium nitrogen is determined by the sensor 49 to determine the concentration of ammonium nitrogen;

the concentration of phosphorus is determined by the spectrometric analyzer 50 for monitoring phosphorus;

the temperature is measured by the temperature measuring device 51;

The pH is measured by the pH measuring device 52;

the concentration of suspended solids is determined by the sensor 53 for determining the concentration of suspended solids;

COD is determined by the spectrometric analyzer 54 for monitoring COD.

Parameters of incoming wastewater through pipeline 1 from the outlets of the flow meter 47, sensor 48 for determining the concentration of nitrate nitrogen, sensor 49 for determining the concentration of ammonium nitrogen, spectrometric analyzer 50 for monitoring phosphorus, device 51 for measuring temperature, device 52 for measuring pH, sensor 53 for determining the concentration of suspended substances, spectrometric analyzer 54 for COD monitoring are transferred to the input of block 62 for determining the parameters of incoming wastewater through pipeline 1.

In bioreactor 3 of block 2 of biological treatment, recirculation flows are organized between:

anoxic zone 6 and anaerobic zone 5 the first recirculation stream 9, using a pump 28 for supplying activated sludge to recirculation, equipped with an adjustable drive 29;

aerobic zone 7 and anoxic zone 6, the second recirculation stream 10, using a pump 39 for feeding activated sludge to recirculation, equipped with an adjustable drive 40.

In this case, the parameters of the recirculation flows are determined.

First recirculation stream 9:

the flow rate is determined by the flow meter 26;

the nitrate nitrogen concentration is detected by the nitrate nitrogen concentration detection sensor 30;

the concentration of ammonium nitrogen is determined by the sensor 31 for determining the concentration of ammonium nitrogen;

the concentration of phosphates is determined by the sensor 32 to determine the concentration of phosphates;

the temperature is determined by the temperature sensor 33;

pH is determined by the sensor 34 determine the pH;

the concentration of activated sludge is determined by the sensor 35 for determining the concentration of activated sludge;

the BOD concentration is detected by the BOD concentration control sensor 36 .

The parameters of the first recirculation flow 9 from the outputs of the flow meter 26, the sensor 30 for determining the concentration of nitrate nitrogen, the sensor 31 for determining the concentration of ammonium nitrogen, the sensor 32 for determining the concentration of phosphates, the sensor 33 for temperature, the sensor 34 for determining pH, the sensor 35 for determining the concentration of activated sludge, the sensor 36 for controlling concentration BOD are transmitted to the input of block 63 to determine the parameters of the first recirculation stream.

Second recirculation stream 10:

the flow rate is determined by the flow meter 37;

the nitrate nitrogen concentration is detected by the nitrate nitrogen concentration detection sensor 41;

the concentration of ammonium nitrogen is determined by the sensor 42 to determine the concentration of ammonium nitrogen;

the concentration of phosphates is determined by the sensor 43 to determine the concentration of phosphates;

the temperature is determined by the temperature sensor 44;

the pH is determined by the sensor 45 determine the pH;

the concentration of activated sludge is determined by the sensor 46 for determining the concentration of activated sludge.

The parameters of the second recirculation flow 10 from the outputs of the flow meter 37, the sensor 41 for determining the concentration of nitrate nitrogen, the sensor 42 for determining the concentration of ammonium nitrogen, the sensor 43 for determining the concentration of phosphates, the temperature sensor 44, the sensor 45 for determining pH, the sensor 46 for determining the concentration of activated sludge are transmitted to the input of block 64 determining the parameters of the second recirculation flow.

After the bioreactor 3, the waste water enters the sump 4, where the sludge mixture is separated into purified water and activated sludge.

From the sump 4 activated sludge through the third recirculation flow 11 pump 12 for pumping activated sludge equipped with an adjustable drive 13 is fed into the anoxic zone 6 of the bioreactor 3. At the same time, part of the activated sludge is removed for processing through the pipeline 23 for removing excess sludge. The excess sludge consumption is determined by the flowmeter 25.

Parameters of the third recirculation stream 11:

the flow rate is determined by the flow meter 15;

the nitrogen concentration of nitrates is determined by the sensor 17 for determining the concentration of nitrogen nitrates;

the concentration of ammonium nitrogen is determined by the sensor 18 for determining the concentration of ammonium nitrogen;

the concentration of phosphates is determined by the sensor 19 to determine the concentration of phosphates;

the temperature is determined by the temperature sensor 20;

pH is determined by the sensor 21 determine the pH;

the concentration of activated sludge is determined by the sensor 22 for determining the concentration of activated sludge.

The flow of excess sludge from the outlet of the flow meter 25 and the parameters of the third recirculation flow 11 from the outputs of the flow meter 15, the sensor 17 for determining the concentration of nitrate nitrogen, the sensor 18 for determining the concentration of ammonia nitrogen, the sensor 19 for determining the concentration of phosphates, the temperature sensor 20, the sensor 21 for determining pH, the sensor 22 for determining activated sludge concentrations are also transmitted to the input of block 65 for determining the parameters of the third recirculation stream 11.

Purified waste water is discharged through the pipeline 55 discharge of purified water. At the same time, the parameters of treated wastewater are determined:

the flow rate is determined by the flow meter 56;

the nitrate nitrogen concentration is detected by the nitrate nitrogen concentration detection sensor 57;

the concentration of ammonium nitrogen is determined by the sensor 58 for determining the concentration of ammonium nitrogen;

the concentration of phosphates is determined by the sensor 59 to determine the concentration of phosphates;

the concentration of suspended solids is determined by the sensor 60 for determining the concentration of suspended solids;

the BOD concentration is detected by the BOD concentration control sensor 61 .

The parameters of the treated wastewater from the outputs of the flow meter 56, the sensor 57 for determining the concentration of nitrate nitrogen, the sensor 58 for determining the concentration of ammonium nitrogen, the sensor 59 for determining the concentration of phosphates, the sensor 60 for determining the concentration of suspended solids, the sensor 61 for controlling the concentration of BOD are transmitted to the input of block 66 for determining the parameters of the treated wastewater water in the pipeline 55 for the removal of purified water.

In block 62 for determining the parameters of incoming waste water through pipeline 1, at least the mass flow rates of substances in incoming waste water are determined.

In block 63 for determining the parameters of the first recirculation stream 9, at least the mass flow rates of substances in the first recirculation stream 9 are determined.

In block 64 for determining the parameters of the second recirculation stream 10, at least the mass flow rates of substances in the second recirculation stream 10 are determined.

In block 65 for determining the parameters of the third recirculation stream 11, at least the mass flow rates of substances in the third recirculation stream 11 and the excess sludge pipeline 23 are determined.

In the block 66 for determining the parameters of the treated waste water in the pipeline 55 discharge of purified water is the determination of at least the mass flow of substances in the treated waste water.

From the output of block 62 for determining the parameters of incoming wastewater through pipeline 1, the concentration and mass flow rates of substances in incoming wastewater through pipeline 1 are transmitted to the input of module 67 for setting parameters.

From the output of block 63 for determining the parameters of the first recirculation stream 9, the concentration and mass flow rates of substances in the first recirculation stream 9 are transmitted to the input of the parameter setting module 67.

From the output of the block 64 for determining the parameters of the second recirculation stream 10, the concentration and mass flow rates of substances in the second recirculation stream 10 are transmitted to the input of the module 67 for setting the parameters.

From the output of block 65 for determining the parameters of the third recirculation stream 11, the concentration and mass flow rates of substances in the third recirculation stream 11 are transmitted to the input of the parameter setting module 67.

The device 14 for measuring the concentration of dissolved oxygen determines the actual concentration of dissolved oxygen in the aerobic zone 7 of the bioreactor 3. The values of the actual concentrations of dissolved oxygen from the output of the device 14 for measuring the concentration of dissolved oxygen are transmitted to the input of the parameter setting module 67 .

In block 68 for setting the concentration of substances in entering the anaerobic zone 5, in block 69 for setting the concentration of substances in entering the anoxic zone 6, in block 70 for setting the concentration of dissolved oxygen in aerobic zone 7, the parameters required to ensure the process of high-quality biological wastewater treatment are determined and set. water. For example, the concentration of suspended solids in zone 5 of bioreactor 3, the concentration of activated sludge in zone 6 of bioreactor 3 and oxygen in the aerobic zone 7 of bioreactor 3.

From the output of the module 67 setting parameters, the parameters required to ensure the process of high-quality biological wastewater treatment are transmitted to the input of the module 79 control parameters.

From the output of the block 62 for determining the parameters of the incoming wastewater through the pipeline 1 to the input of the comparison module 71, the concentrations and mass flow rates of substances in the incoming wastewater through the pipeline 1 are transmitted.

From the output of block 63 for determining the parameters of the first recirculation stream 9, the concentrations and mass flow rates of substances in the first recirculation stream 9 are transmitted to the input of the comparison module 71.

From the output of the block 64 for determining the parameters of the second recirculation stream 10, the concentrations and mass flow rates of substances in the second recirculation stream 10 are transmitted to the input of the comparison module 71.

From the output of block 65 for determining the parameters of the third recirculation stream 11, the concentrations and mass flow rates of substances in the third recirculation stream 11 are transmitted to the input of the comparison module 71.

From the output of the block 66 for determining the parameters of the treated waste water in the pipeline 55 to the input of the comparison module 71, the concentrations and mass flow rates of substances in the treated waste water are transmitted.

In the concentration comparison unit 72 in the third recirculation stream 11, the concentration comparison unit 73 in the second recirculation stream 10, the concentration comparison unit 74 in the sewage supply pipeline 1, the concentration comparison unit 75 in the first recirculation stream stream 9, the concentration comparison unit 76 in the pipeline 55 removal of purified water of the comparison module 71, the comparison of the actual process parameters with the parameters determined by the technological documentation is carried out. The results of the comparison from the output of the module 71 are transmitted to the input of the module 79 of the parameter control.

In the control unit 80 of the shut-off and control valves, the degree of opening of the shut-off and control valves installed on the recirculation flows 9, 10, 11 and the pipeline 23 for removing excess sludge is determined.

From the output of the parameter control module 79, the degree of opening is transmitted:

shut-off and control valves 27 with remote control;

shut-off and control valves 38 with remote control;

shut-off and control valves 16 with remote control;

shut-off and control valves 24 with remote control.

This allows you to change the amount of activated sludge in the first recirculation stream 9, the second recirculation stream 10 and the third recirculation stream 11 and the amount of activated sludge discharged for processing through the excess sludge pipeline 23.

In the pump control unit 81, the required amount of activated sludge to be supplied in the first recirculation stream 9, the second recirculation stream 10 and the third recirculation stream 11 is determined, and the operation characteristics of the pumps 12, 28, 39 and variable drives 13, 29, 40 required for this. required pumps are transferred to adjustable drives 13, 29, 40. For example, the speed of rotation of the shaft of pumps 12, 28, 39. This will improve the quality of wastewater treatment by maintaining the required concentrations of substances in the anaerobic zone 5, anoxic zone 6, aerobic zone 7 of block 2 biological treatment.

In the blower control unit 82, the amount of air required for biological wastewater treatment is determined, and these values are transmitted to the blower 77, which is configured to change the amount of air supplied through the air duct 78 to the aerators 8. This will improve the quality of wastewater treatment by supplying the amount of required air and reduce energy consumption for air supply.

Thus, the proposed method is characterized by "industrial applicability". The application of this invention will improve the quality of biological wastewater treatment by adjusting the parameters of recirculation flows and maintaining optimal values of the concentrations of substances in the biological wastewater treatment system.

Claims (42)

A control system for a biological wastewater treatment unit, which at least includes sewage pipeline, biological treatment unit, consisting of a bioreactor made in the form of sequentially connected zones - anaerobic, anoxic, aerobic, intended for nitrogen removal and biological dephosphorization, and a sump, pipeline for the removal of purified water, activated sludge pump, the third recirculation flow between the secondary clarifier and the anoxic zone of the bioreactor, aerators, a device for measuring the concentration of dissolved oxygen, device for measuring pH and temperature, spectrometric analyzers for COD and phosphorus monitoring, flowmeter, blower, characterized in that waste water that has undergone mechanical treatment is accepted as waste water, the pump for pumping out activated sludge is configured to supply activated sludge for recycling and/or remove excess sludge and with the possibility of changing the amount of activated sludge supplied for recycling and/or removal, the blower is configured to change the amount of supplied air, a pH measuring device is installed on the wastewater supply pipeline, spectrometric analyzers for monitoring COD and phosphorus are installed on the wastewater supply pipeline, and the device is additionally equipped the first recirculation flow between the anoxic and anaerobic zones, the second recirculation flow between the aerobic and anoxic zones, flow meters, shut-off and control valves with remote control, sensors for determining the concentration of nitrate nitrogen, sensors for determining the concentration of ammonium nitrogen, sensors for determining the concentration of phosphates, temperature sensors, pH sensors, sensors for determining the concentration of activated sludge installed on the first, second and third recirculation streams, BOD concentration control sensor installed on the first recirculation flow, excess sludge removal pipeline, shut-off and control valves with remote control and a flow meter installed on the pipeline for removing excess sludge, a flow meter, a sensor for determining the concentration of nitrate nitrogen, a sensor for determining the concentration of ammonium nitrogen, a sensor for determining the concentration of suspended solids installed on the wastewater supply pipeline, a sensor for determining the concentration of nitrate nitrogen, a sensor for determining the concentration of ammonium nitrogen, a sensor for determining the concentration of phosphates, a sensor for determining the concentration of suspended solids, a BOD concentration control sensor installed on the treated water discharge pipeline, a block for determining the parameters of incoming wastewater through the wastewater supply pipeline, blocks for determining the parameters of the first, second and third recirculation flows, a block for determining the parameters of waste water in the pipeline for the removal of purified water, a parameter setting module containing a block for setting the concentration of substances in those entering the anaerobic zone, a block for setting the concentration of substances in entering the anoxic zone, a block for setting the concentration of dissolved oxygen in the aerobic zone, a comparison module containing blocks for comparing the concentration in the first, second and third recirculation streams, a block for comparing the concentration in the wastewater supply pipeline, a block for comparing the concentration in the purified water outlet pipeline, a parameter control module containing a shut-off and control valve control unit, a pump control unit, a blower control unit, wherein the outputs of the flow meter, the sensor for determining the concentration of nitrogen nitrates, the sensor for determining the concentration of ammonium nitrogen, the spectrometric analyzer for monitoring phosphorus, the device for measuring temperature, the device for measuring pH, the sensor for determining the concentration of suspended solids, the spectrometric analyzer for monitoring COD are connected to the input of the unit for determining the parameters of incoming waste water through the wastewater supply pipeline, outputs of flow meters, sensors for determining the concentration of nitrate nitrogen, sensors for determining the concentration of ammonium nitrogen, sensors for determining the concentration of phosphates, temperature sensors, sensors for determining pH, sensors for determining the concentration of activated sludge, installed on the first, second and third recirculation flows, are connected to the inputs of the blocks for determining the parameters of the first, the second and third recirculation streams, respectively, the output of the BOD concentration control sensor installed on the first recirculation flow is connected to the input of the block for determining the parameters of the first recirculation flow, the outputs of the flow meter, the sensor for determining the concentration of nitrate nitrogen, the sensor for determining the concentration of ammonium nitrogen, the sensor for determining the concentration of phosphates, the sensor for determining the concentration of suspended solids, the BOD concentration control sensor are connected to the input of the unit for determining the parameters of waste water in the treated water discharge pipeline, the outputs of the blocks for determining the parameters of incoming wastewater through the wastewater supply pipeline, the first, second and third recirculation flows, for determining the parameters of wastewater in the treated water discharge pipeline are connected to the input of the parameter setting module and the comparison module, the output of the device for measuring the concentration of dissolved oxygen is connected to the input of the parameter setting module, the outputs of the parameter setting module and the comparison module are connected to the parameter control module, the output of the parameter control module is connected to shut-off and control valves, pump drive, blower.

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