RU65493U1 - THIN-LAYER SILVER UNIT - Google Patents

Abstract

The invention relates to devices for implementing the process of separation of silt mixtures of biological wastewater treatment and can be used in sewage treatment plants of cities and industrial enterprises.

The basis of the invention is the task of improving the device for separating large quantities of sludge mixtures with thin-layer sedimentation, in which due to the blocking of several settling tanks having pyramidal bottoms, providing them with special devices simplify the collection of condensed return activated sludge from the shelves of thin-layer modules, reduce the length of the communications of the supply of sludge mixtures , removal of condensed return activated sludge and clarified wastewater, increase the uniformity of discharge from the volume of sludge reservoirs of condensed return activated sludge, collection and removal of clarified wastewater from the surface of the settling tanks.

The solution to this problem is achieved by the fact that the removal of accumulations of activated sludge from the shelf modules is carried out exclusively by bubbling, supplying all communications for entering the sludge mixtures into the settling tanks with electrified gates and a controller for turning the gate motors on and off, all air supply pipelines to the bubbler system under the shelf modules with electrified valves, controlled by the gate controller, performing discharge taps of condensed return activated sludge and clarified wastewater through special wells with unflooded vodoslivami.1 c.p. f-ly, 6 ill.

Description

The proposed utility model relates to devices for separating a sludge mixture of biological treatment plants of urban and close to them by the composition of high-capacity industrial wastewater.

Known blocked secondary sumps for separating sludge mixtures of vertical, radial and horizontal types [1], including a distribution chamber with shut-off and regulating devices for equalizing the flows of sludge mixtures in separate settling tanks, communications for introducing sludge mixtures and draining clarified waste water and return activated sludge , the settling tanks themselves, equipped with drainage trays of clarified waste water and devices for the output of return activated sludge, for example, sludge sosami.

Known interlocked secondary sedimentation tanks occupy large areas of land. The load on clarified wastewater does not exceed 1.5 ... 2.0 m ³ / h per square meter of water in the settling tanks when the estimated wastewater flow rate is passed. The overflow edge of the drainage trays of clarified wastewater should be strictly horizontal, which is difficult to accomplish with large diameters, for example, radial sedimentation tanks. However, even the strict horizontal horizontality of the overflow edges does not ensure the uniformity of the overflow of water along the length of the catchment with strong winds.

The closest in technical essence to the device that is proposed is a wastewater treatment plant, in which a device including a settling tank equipped with shelf modules for thin-layer separation of the silt mixture into clarified wastewater is used as a desilter for sludge mixture leaving the aeration tank and condensed return activated sludge, with devices to prevent the entry of air bubbles into the settling zone, to quench the flow rate of the sludge mixture under the shelf space, munikatsiyami with shut-off and control valves for input sludge mixture removing clarified effluent and condensed return activated sludge device for removal from the shelf space of the activated sludge accumulations, water collection trays for the uniform collection of clarified waste water area of the water table on shelving units [2]. The device allows you to have 3 ... 5 times greater water loads on the mirror of the settling tank. However, such a device for separating the sludge mixture has become widespread for small-capacity plants due to deficiencies in the system for emptying shelf modules from accumulations of activated sludge and the inability to uniformly collect condensed return sludge from a large bottom area if the device is located directly in aeration tanks.

The basis of the invention is the task of improving the device for separating sludge mixtures of large quantities, in which due to the blocking of several settling tanks having pyramidal bottoms, it is easier to collect condensed return activated sludge, isolated and separately controlled by automation when making devices for removing accumulations of activated sludge from shelf modules , a rational mutual arrangement of the individual nodes of the device is achieved by reducing the length of communications and increasing even NOSTA O underflow return of activated sludge from the settling tank shelf modules and clusters mixed liquor shelf modules.

The problem is solved in that in the block of thin-layer sludge separators, which includes several settling tanks, from 2 to 4 pieces equipped with shelf modules, communications for supplying sludge mixture to each settling tank, for discharging condensed return activated sludge and clarified sewage, and devices for removal from shelf modules of accumulations of activated sludge, shut-off and control valves include the following differences:

- each settling tank is made with a pyramidal bottom having a slope of the side faces of at least 45 °, equipped with a system of bubble perforated pipes laid under the shelf module with a pitch of not more than 0.2 m perpendicular to the planes of the module shelves; with an electrified valve on the air supply pipe to the sparging pipe system and a controller controlling this valve; a set of drainage trays placed perpendicular to the planes of the shelf modules with a step equal to twice the width of the drainage channels, above the shelf modules at least half the width of the drainage channel from the bottom of the plates of the shelf module, with the cross section of the channels corresponding to the hydraulically best possible section estimated wastewater flow rate;

- communication pipelines for the removal of condensed return activated sludge from each settling tank are reduced to a receiving well, where the flow of condensed return activated sludge is carried out through an unburied spillway;

- pipelines for the supply of sludge mixture to the block of thin-layer sludge separators are reduced to one collecting well in its lower part, and the exits to each separate settling tank are made in its upper part and are equipped with an electrified gate controlled by the controller of the system for supplying air to the bubble pipes of the settling tank;

- the drainage trays of each settling tank of the thin-layer sludge separator unit are combined into one drainage tray, bringing the clarified sewage

water to a single drainage well for the block, where overflow of clarified wastewater into the well is carried out through an unfilled spillway.

The conducted patent studies showed that neither the patent nor the scientific and technical literature contain information about the blocks of thin-layer desilters of the design and execution described in the claims, which gives grounds to assert that they meet the patent "novelty" criterion.

A comparative analysis of the device that is proposed, with well-known technical solutions, including with the prototype, shows that there are significant advantages of performing secondary settling tanks for the separation of sludge mixtures of large quantities of wastewater using blocks of thin-layer sludge separators.

The advantages that are achieved indicate that the tasks that are solved are performed at the inventive level, since they do not follow, obviously, from solutions known in the art and therefore meet the patentability criterion of "inventive step".

The block of thin-layer sludge separators, which is proposed, is illustrated by drawings, where Fig. 1 shows a plan for the placement of settling tanks and communications in a block; Figure 2. - a cross section of one of the settling tanks in the block; Figure 3 is a cross section of a distribution well for supplying a sludge mixture to individual settling tanks in a block; Figure 4 is a cross-sectional view of the receiving well of the discharge of the condensed return activated sludge from the block; Figure 5 is a cross-section of a drainage well of clarified wastewater with a single drainage tray connected to it from one of the settling tanks of the block; 6 is a plan of a bubbler system of perforated pipes under the shelf module of one of the settling tanks of the block.

The thin layer desilter unit includes:

1. slop tanks;

2. pipelines for supplying silt mixture to the block;

3. distribution well of the silt mixture of the block;

4. electrified gate supply of sludge mixture to a separate settling tank;

5. the bosom of the inlet of the sludge mixture into the settling tank;

6. shelf module of a settling tank;

7. The pyramidal bottom of the settling tank;

8. catchment tray of clarified wastewater;

9. combining the drainage tray of the settling tank;

10. The drainage well of the clarified waste water of the unit;

11. non-flooded spillway of clarified wastewater from a separate settling tank;

12. a pipeline for discharge of condensed return activated sludge;

13. the receiving well of the condensed return activated sludge;

14. unfilled spillway of condensed return activated sludge;

15. a pipeline for supplying compressed air to a block of thin-layer desilters;

16. pipeline for supplying compressed air under the shelf module;

17. electrified valve on the pipelines 16;

18. controller control valves 17 and gates 4;

19. bubbled perforated air supply pipes under the shelf module;

20. A partition not reaching the bottom of the settling tank separating the sinus 5 from the shelf module 6;

21. the inclined plate of the shelf module 6;

22. frame shelf module 6;

23. overflow windows in the enclosing wall of the settling tank 1;

24. tray inlet of sludge mixture into a separate settling tank 1;

25. intermediate support for shelf modules 6;

26. the distribution tray of the sludge mixture in the bosom 5;

The block of thin-layer sludge separators contains 2 ... 4 settling tanks 1, each equipped with a shelf module 6, including inclined plates 21 in the frame 22, while the shelf modules 6 are separated inside the tank 1 from the inlet pipelines 24 from two opposite sides by partitions 20 forming between the walls tank 1 and baffles 20 of the sinus 5, in which the sludge mixture moves from top to bottom to the pyramidal bottom 7; beneath the shelf module 6 there is a system of bubbler perforated pipes 19 connected through a compressed air supply pipe 16 with an electrified valve 17 controlled by a controller 18 with an air supply pipe 15 from the blower station, as well as an intermediate support 25 for the shelf modules 6, which allows to reduce the length of individual modules and their weight.

The inlet of the sludge mixture from aeration tanks is organized by means of a pipe 2, which reaches the distribution well 3 of the sludge mixture and then through the electrified gates 4 to supply the sludge mixture to each separate sludge tank 1 through the sludge inlet trays 24 in the sinuses 5. The shelf modules 6 consist of frames 22 and fixed in them with a pitch of 50 mm at an angle to the horizontal plane of 60 ° of the plates 21.

The sludge mixture coming from the sinuses 5 to the pyramidal bottom 7 loses its speed due to the presence of oncoming jets organized by placing the sinuses 5 on two opposite sides of the settling tank 1 and its flow is divided under the action of gravitational forces into two flows, one of which contains heavy sludge particles of condensed return activated sludge rush to the base of the pyramidal bottom 7 and then through the pipeline 12 through the flooded weir 14

a receiving well from which it is sent to a sludge pumping station for returning condensed activated sludge to biological wastewater treatment in aeration tanks. The second stream - the stream of clarified wastewater, passing through the shelf space of the shelf modules, is additionally freed from sludge particles attracted by the surface of the shelves modified by the grown biofilm, poured into the drainage trays 8 and then through the overflow windows 23 in the enclosing wall of the settling tank moves to the uniting tray 9 of the settling tank reservoir 1 and through the non-flooded spillway 11 clarified waste water is discharged into the drainage well 10 and then sent for further treatment to special facilities of the dairy heel by gravity or by pumping of the pump station.

The block of thin-layer desilters works as follows.

The sludge mixture from aeration tanks of any known modification is fed by gravity through pipeline 2 to the block of thin-layer sludge separators into the distribution well 3. From it, through the electrified gates 4, the sludge mixture flows through the inlet trays 24 through the distribution trays 26 into the sinus 5 of the inlet of the sludge mixture of each settling tank 1. B in the sinuses 5, the sludge mixture moves from top to bottom with a speed of not more than 20 mm / s, which ensures the release of the sludge mixture from air bubbles and other gases in the sludge mixture. The uniform distribution of the sludge mixture along the length and width of the sinuses is guaranteed by the design of the distribution trays 26. The distribution trays 26 are perforated with perforated and slotted perforations both from the side surfaces and the bottom to prevent siltation. Coming out of the sinuses 5 on opposite sides of the settling tank towards each other, the mud flows quench the energy of oncoming motion due to friction and, under the influence of gravitational forces, are divided into two flows, one of which is heavier, rushes down to the pyramidal bottom 7, where it enters in the pipe 12 of the discharge of condensed return activated sludge, and the second, lighter, rises up and moving in the shelf modules

between the inclined plates 21, it is additionally freed from sludge particles settling and adhering to the upper plane of the plates 21 both due to gravity and due to adhesion to the modified biofilm of the surface of the plates 21 fixed in the frames 22.

After passing the shelf modules 6, the clarified wastewater is poured into the drainage trays through the overflow windows 23 and then moves to the unifying drainage well 10 through the non-flooded spillway 11 of the clarified wastewater, and then for subsequent treatment. Since the shelf space is silted up due to the continuous adherence of activated sludge particles on the plane of the inclined plates 21, it is necessary to remove adhering sludge particles in order to prevent their decay due to the lack of oxygen for respiration of aerobic microorganisms of activated sludge, and denitrification of nitrated sewage due to the consumption of organic cellular substances membranes, the release of molecular nitrogen that floats sludge particles and reduces the efficiency of clarification water.

A signal for cleaning the shelf space can be an increase in the amount of nitrite in the clarified wastewater or the operation of the contacts of the controller 18 for controlling electrified valves 17 on the pipeline 16 for supplying compressed air to a separate settling tank 1 from the pipeline 15 for supplying compressed air to the high-capacity thin-layer sludge separator, powered by a blower station. The opening of the signal 18 of the electrified valve 17 is combined with the closure of the corresponding electrified gate 4 for supplying the sludge mixture to this settling tank 1 and stopping the flow of sludge into the cleaned sludge tank 1, which excludes the flow of sludge mixed with air from the tank into the drainage gutters 8. B for at least 10 minutes, air enters under the shelf modules 6 through perforated bubble tubes 19, creating

high turbulence of the wastewater, guaranteeing tearing of silt particles from the tilted plates of 21 shelf modules 6. To avoid large vibration of the shelf modules 6 under the influence of air flows and due to their high windage, the shelf modules are fixed in the middle to the intermediate supports 25. After 10 minutes of bubbling, the controllers 18 first close electrified valve 17 for supplying air to the settling tank 1 and only after another 30 minutes open the electrified gate 4 for supplying the sludge mixture to this settling tank 1.

All actions of the controller 18 are carried out according to a special program established during the commissioning period, when guaranteed periods of minimum inflow of wastewater to the sewage treatment plant are identified.

Discontinuing the supply of the mixture to one of the settling tanks 1 inevitably increases its flow to the other settling tanks in the block of thin-layer sludge separators, but this increase is within the acceptable range due to a decrease in the total inflow of wastewater to the treatment plant.

Achieving the task of improving the device for separating sludge mixtures at high productivity by blocking several settling tanks while simplifying the design of the device, removing condensed return activated sludge and accumulations of activated sludge from the shelf modules, reducing the length of the communications is ensured by the fact that, in contrast to the prototype, in thin-layer due to the presence of several settling tanks in the unit during hours of minimal wastewater inflow, possibility of switching off of one of the settling tank and holding therein the cleaning action plates inclined shelf modules of clusters of activated sludge adhered. At the same time, the supply of sludge mixture to other settling tanks increases within the permissible limits by the amount of incoming sludge mixture.

The transfer of a specific settling tank is carried out automatically, at the command of the controller programmed to turn on the electrical components of the unit during commissioning. The new system for cleaning module shelves from accumulation of activated sludge eliminates the need for the installation of pulsating tanks of water level in settling tanks and the corresponding communications of the sludge mixture and air, and, therefore, simplifies the design of a thin-layer sludge separator.

Simplification of the removal of condensed return activated sludge and increased uniformity of its removal from settling tanks is achieved by the fact that the condensed return activated sludge is discharged from the pyramidal bottoms with an angle of inclination of the walls of at least 45 °, eliminating the delay to creep of the sludge, and the presence of a collection well and a free spout through the flooded spillway - removal of condensed return activated sludge from it. Since there is no sludge pumping device that directly takes away from the pyramidal bottom of the sludge pumping tank, the uniformity of the removal of condensed return sludge is proportional to the inflow of sludge mixture to each sludge tank and the proportion set during commissioning using spillways at the drainage wells for clarified wastewater and condensed return active silt, that is, the solution of the task.

Replacing high-capacity thin-layer sludge separators with blocks, for example, radial sumps, with a water mirror load in the sumps of not more than 1.5 m ³ / m ² · h, reduces the area of secondary sumps by 4 ... 5 times, which is extremely important for cramped conditions for the placement of large sewage treatment plants, and especially during the reconstruction of existing treatment plants.

Claims (1)

The block of thin-layer sludge separators, including settling tanks, shelf modules, communication systems for supplying sludge mixture, distributing it over the settling tanks, discharging condensed return activated sludge and collecting clarified waste water, supplying air and distributing it under the shelf modules, a system for removing accumulations from the plates of shelf modules activated sludge, characterized in that the system for removing accumulations of activated sludge from the plates of the shelf modules is made exclusively by shutting down one of the sludge from operation reservoirs and sparging the plates of the shelf modules it is equipped with sludge inlet communications, electrified gates, a controller and electrified valves for air supply to each separate sludge tank, and the uniformity of the discharge of condensed return activated sludge was achieved using pyramidal bottoms of all sludge tanks in the block , non-flooded spillways at the drains on the wells of clarified wastewater and the receiving wells of the condensed return activated sludge.